Emerson 5081-A FoundAtIoN™ Fieldbus two-Wire Chlorine, dissolved oxygen, and ozone transmitter Instruction Manual

Instruction Manual LIQ_MAN_5081A-FF/rev.M January 2015 5081-A FouNdAtIoN™ Fieldbus two-Wire Chlorine, dissolved oxygen, and ozone transmitter ESSENTIAL INSTRUCTIONS READ THIS PAGE BEFORE PROCEEDING! Rosemount Analytical designs, manufactures, and tests its products to meet many national and international standards. Because these instruments are sophisticated technical products, you must properly install, use, and maintain them to ensure they continue to operate within their normal specifications. the following instructions must be adhered to and integrated into your safety program when installing, using, and maintaining Rosemount Analytical products. Failure to follow the proper instructions may cause any one of the following situations to occur: Loss of life; personal injury; property damage; damage to this instrument; and warranty invalidation. • Read all instructions prior to installing, operating, and servicing the product. If this Instruction Manual is not the correct manual, telephone 1-800-654-7768 and the requested manual will be provided. Save this Instruction Manual for future reference. • If you do not understand any of the instructions, contact your Rosemount representative for clarification. • Follow all warnings, cautions, and instructions marked on and supplied with the product. • Inform and educate your personnel in the proper installation, operation, and maintenance of the product. • Install your equipment as specified in the Installation Instructions of the appropriate Instruction Manual and per applicable local and national codes. Connect all products to the proper electrical and pressure sources. • to ensure proper performance, use qualified personnel to install, operate, update, program, and maintain the product. • When replacement parts are required, ensure that qualified people use replacement parts specified by Rosemount. unauthorized parts and procedures can affect the product’s performance and place the safe operation of your process at risk. Look alike substitutions may result in fire, electrical hazards, or improper operation. • Ensure that all equipment doors are closed and protective covers are in place, except when maintenance is being performed by qualified persons, to prevent electrical shock and personal injury. CAUTION If a 375 or 475 universal Communicator is used with these transmitters, the software within the 375 or 475 may require modification. If a software modification is required, please contact your local Emerson Process Management Service Group or National Response Center at 1-800-654-7768. About This Document this manual contains instructions for installation and operation of the Model 5081-A Foundation Fieldbus two-Wire Chlorine, dissolved oxygen, and ozone transmitter. the following list provides notes concerning all revisions of this document. Rev. Level Date Notes A 6/02 this is the initial release of the product manual. the manual has been reformatted to reflect the Emerson documentation style and updated to reflect any changes in the product offering. B 11/02 Revised drawings on pages 13-16. C 1/03 Fixed minor typos. d 4/03 Specs updates. E 6/03 Agency certification update. F 11/03 updated Flat Mount drawing on page 10. I 1/11 Removed “polyester” from enclosure specifiations, updated © info J 5/11 updated Baseefa/Atex label drawing pg 24. K 03/12 update addresses - mail and web L 11/12 Added Fieldbus specifications, updated ItK revision and CE certifications M 10/14 Changed agency water exposure testing description to “type”. Emerson Process Management 2400 Barranca Parkway Irvine, CA 92606 uSA tel: (949) 757-8500 Fax: (949) 474-7250 http://www.rosemountanalytical.com © Rosemount Analytical Inc. 2014 MODEL 5081-A TABLE OF CONTENTS 5081-A MICROPROCESSOR TRANSMITTER TABLE OF CONTENTS Section 1.0 1.1 1.2 1.3 1.4 1.5 1.6 1.7 1.8 1.9 1.10 1.11 1.12 1.13 1.14 Title DESCRIPTION AND SPECIFICATIONS ................................................................ Features and Applications........................................................................................ Specifications - General........................................................................................... Specifications - oxygen ........................................................................................... Specifications - Free Chlorine.................................................................................. Specifications - pH ................................................................................................... Specifications - total Chlorine.................................................................................. Specifications - ozone ............................................................................................. transmitter display during Calibration and Programming ...................................... Infrared Remote Controller ..................................................................................... FouNdAtIoN Fieldbus ................................................................................................ General Specifications ............................................................................................. Asset Management Solutions (AMS) ....................................................................... ordering Information ............................................................................................... Accessories ............................................................................................................. Page 1 1 2 3 3 3 3 3 4 4 5 5 6 8 8 2.0 2.1 2.2 2.3 2.4 INSTALLATION ....................................................................................................... unpacking and Inspection........................................................................................ orienting the display Board ..................................................................................... Installation................................................................................................................ Power Supply Wiring................................................................................................ 9 9 9 9 12 3.0 3.1 3.2 3.3 WIRING.................................................................................................................... Wiring Model 499A oxygen, Chlorine, and ozone Sensors .................................... Wiring Model 499ACL-01 (Free Chlorine) Sensors and pH Sensors....................... Wiring Model Hx438 and Gx448 Sensors................................................................ 13 13 14 16 4.0 INTRINSICALLy SAFE AND ExPLOSION PROOF INSTALLATIONS.................. 17 5.0 5.1 5.2 5.3 5.4 5.5 5.6 DISPLAy AND OPERATION WITH INFRARED REMOTE CONTROLLER........... display Screens ....................................................................................................... Infrared Remote Controller (IRC) - Key Functions................................................... Menu tree................................................................................................................ diagnostic Messages............................................................................................... Security .................................................................................................................... using Hold ............................................................................................................... 31 31 32 33 33 33 33 6.0 6.1 6.2 6.3 6.4 OPERATION WITH FOUNDATION FIELDBUS AND THE DELTAv CONTROL SySTEM . overview .................................................................................................................. AI Block Configuration ............................................................................................. transducer Block operations — Configuration and Calibration .............................. Model 5081-A-FF — device Summary .................................................................... 35 35 36 37 38 i MODEL 5081-A TABLE OF CONTENTS TABLE OF CONTENTS CONT’D Section 7.0 7.1 7.2 7.3 7.4 7.5 7.6 7.7 7.8 Title PROGRAMMING..................................................................................................... General .................................................................................................................... default Settings........................................................................................................ temperature Settings............................................................................................... display ..................................................................................................................... Calibration Setup..................................................................................................... Line Frequency ........................................................................................................ pH Measurement ..................................................................................................... Barometric Pressure ................................................................................................ Page 42 42 42 44 46 48 51 52 56 8.0 8.1 8.2 8.3 CALIBRATION — TEMPERATURE........................................................................ Introduction .............................................................................................................. Procedure using the infrared remote controller........................................................ Procedure using deltaV ........................................................................................... 58 58 59 59 9.0 9.1 9.2 9.3 9.4 9.5 9.6 9.7 CALIBRATION — OxyGEN ................................................................................... Introduction .............................................................................................................. Procedure — Zeroing the Sensor using the infrared remote controller ................... Procedure — Zeroing the Sensor using deltaV....................................................... Procedure — Air Calibration using the infrared remote controller............................ Procedure — Air Calibration using deltaV ............................................................... Procedure — In-Process Calibration using the infrared remote controller............... Procedure — In-Process Calibration using deltaV .................................................. 60 60 61 62 63 64 65 66 10.0 10.1 10.2 10.3 10.4 10.5 10.6 CALIBRATION — FREE CHLORINE ..................................................................... Introduction .............................................................................................................. Procedure — Zeroing the Sensor using the infrared remote controller ................... Procedure — Zeroing the Sensor using deltaV....................................................... Procedure — Full Scale Calibration using the infrared remote controller ................ Procedure — Full Scale Calibration using deltaV ................................................... dual Slope Calibration ............................................................................................. 67 67 68 69 70 71 72 11.0 11.1 11.2 11.3 11.4 11.5 11.6 CALIBRATION — TOTAL CHLORINE ................................................................... Introduction .............................................................................................................. Procedure — Zeroing the Sensor using the infrared remote controller ................... Procedure — Zeroing the Sensor using deltaV....................................................... Procedure — Full Scale Calibration using the infrared remote controller ................ Procedure — Full Scale Calibration using deltaV ................................................... dual Slope Calibration ............................................................................................. 74 74 75 76 77 78 79 12.0 12.1 12.2 12.3 12.4 12.5 CALIBRATION — OzONE ...................................................................................... Introduction .............................................................................................................. Procedure — Zeroing the Sensor using the infrared remote controller ................... Procedure — Zeroing the Sensor using deltaV....................................................... Procedure — Full Scale Calibration using the infrared remote controller ................ Procedure — Full Scale Calibration using deltaV ................................................... 81 81 82 82 84 85 ii MODEL 5081-A TABLE OF CONTENTS TABLE OF CONTENTS CONT’D Section Title Page 13.0 13.1 13.2 13.3 13.4 13.5 13.6 13.7 13.8 13.9 CALIBRATION — pH .............................................................................................. Introduction .............................................................................................................. Procedure — Auto Calibration using the infrared remote controller......................... Procedure — Auto Calibration using deltaV ............................................................ Procedure — Manual Calibration using the infrared remote controller .................... Procedure — Manual Calibration using deltaV ....................................................... Standardization using the infrared remote controller ............................................... Standardization using deltaV................................................................................... pH Slope Adjustment using the infrared remote controller....................................... pH Slope Adjustment using deltaV .......................................................................... 86 86 87 88 89 90 91 92 93 94 14.0 14.1 14.2 14.3 14.4 DIAGNOSTICS ........................................................................................................ General .................................................................................................................... diagnostic Messages for dissolved oxygen............................................................ diagnostic Messages for ozone and total Chlorine ................................................ diagnostic Messages for Free Chlorine................................................................... 95 95 95 95 96 15.0 15.1 15.2 15.3 15.4 15.5 15.6 15.7 15.8 15.9 15.10 15.11 15.12 15.13 TROUBLESHOOTING ........................................................................................... Warning and Fault Messages .................................................................................. troubleshooting When a Warning or Fault Message is Showing ............................ temperature Measurement and Calibration Problems ............................................ oxygen Measurement and Calibration Problems .................................................... Free Chlorine Measurement and Calibration Problems........................................... total Chlorine Measurement and Calibration Problems........................................... ozone Measurement and Calibration Problems ...................................................... pH Measurement and Calibration Problems ............................................................ Simulating Input Currents — dissolved oxygen...................................................... Simulating Input Currents — Chlorine and ozone................................................... Simulating Inputs — pH ........................................................................................... Simulating temperature ........................................................................................... Measuring Reference Voltage.................................................................................. 97 97 99 102 103 105 107 108 110 112 112 113 114 115 16.0 16.1 16.2 MAINTENANCE ...................................................................................................... overview .................................................................................................................. transmitter Maintenance ......................................................................................... 116 116 116 17.0 RETURN OF MATERIAL......................................................................................... 118 Appendix Title A BAROMETRIC PRESSURE AS A FUNCTION OF ALTITUDE............................... Page 119 LIST OF TABLES Number Title 6-1 6-2 7-1 16-1 Page Analog Input Block Configuration Values ............................................................................... Model 5081-A-FF Parameters and Methods ......................................................................... default Settings ..................................................................................................................... Replacement Parts for Model 5081-A transmitter.................................................................. iii 36 39 42 117 MODEL 5081-A TABLE OF CONTENTS LIST OF FIGURES Number Title 1-1 1-2 1-3 1-4 1-5 1-6 2-1 2-2 2-3 2-4 3-1 3-2 3-3 3-4 3-5 3-6 3-7 3-8 3-9 4-1 4-2 4-3 4-4 4-5 4-6 4-7 4-8 4-9 4-10 5-1 5-2 5-3 5-4 6-1 9-1 10-1 10-2 11-1 11-2 11-3 12-1 13-1 15-1 15-2 15-3 15-4 15-5 15-6 16-1 Page transmitter display during Calibration and Programming...................................................... Infrared Remote Controller ..................................................................................................... Functional Block diagram for the Model 5081-A-FF transmitter............................................ Asset Management Solutions (AMS) Configuration Screen ................................................... Asset Management Solutions (AMS) Measurement Screen .................................................. Model 5081-A Mounting and dimensional drawings .............................................................. Mounting the Model 5081-A on a Flat Surface ....................................................................... using the Pipe Mounting Kit to attach the Model 5081-A to a pipe......................................... Power Supply Wiring .............................................................................................................. typical Fieldbus Network Electrical Wiring Configuration....................................................... Amperometric sensors with standard cable............................................................................ Amperometric sensors with optimum EMI/RFI cable or Variopol cable .................................. Free Chlorine sensor with standard cable and 399VP-09 pH sensor without internal ........... preamplifier ............................................................................................................................. Free Chlorine sensor with standard cable and 399-14 pH sensor with internal preamplifier.. Free Chlorine sensor with standard cable and 399-09-62 pH sensor without internal .......... preamplifier ............................................................................................................................. Free Chlorine sensor with optimum EMI/RFI cable or Variopol cable and 399VP-09 pH ...... sensor without internal preamplifier ........................................................................................ Free Chlorine sensor with optimum EMI/RFI cable or Variopol cable and 399-14 pH sensor with internal preamplifier ......................................................................................................... Free Chlorine sensor with optimum EMI/RFI cable or Variopol cable and 399-09-62 pH ...... sensor without internal preamplifier ........................................................................................ Hx438 and Gx448 sensors ..................................................................................................... FMRC Explosion-Proof Installation ......................................................................................... FM Intrinsically-Safe Installation Label ................................................................................... FM Intrinsically-Safe Installation ............................................................................................. CSA Intrinsically-Safe Installation Label ................................................................................. CSA Intrinsically-Safe Installation ........................................................................................... BASEEFA/AtEX Intrinsically-Safe Installation Label .............................................................. Process display Screen.......................................................................................................... CSA Intrinsically-Safe Installation (1 of 2)............................................................................... BAS/AtEX Intrinsically-Safe Label 5081-A-FI ........................................................................ FM Intrinsically-Safe Installation 5081-A-FI ........................................................................... Process display Screen.......................................................................................................... Program display Screen ......................................................................................................... Infrared Remote Controller ..................................................................................................... Menu tree............................................................................................................................... Functional Block diagram for the Model 5081-A-FF transmitter............................................ Sensor Current as a Function of dissolved oxygen Concentration ....................................... Sensor Current as a Function of Free Chlorine Concentration............................................... dual Slope Calibration ............................................................................................................ determination of total Chlorine............................................................................................... Sensor Current as a Function of total Chlorine Concentration............................................... dual Slope Calibration ............................................................................................................ Sensor Current as a Function of ozone Concentration.......................................................... Calibration Slope and offset ................................................................................................... Simulate dissolved oxygen ..................................................................................................... Simulate chlorine and ozone .................................................................................................. Simulate pH ............................................................................................................................ three-wire Rtd Configuration ................................................................................................ Simulating Rtd Inputs ............................................................................................................ Checking for a Poisoned Reference Electrode....................................................................... Exploded View of Model 5081-A transmitter .......................................................................... iv 4 4 5 5 6 7 10 11 12 12 13 13 14 14 15 15 15 15 16 17 18 19 21 22 24 25 26 27 28 31 31 32 34 35 60 67 72 74 74 79 80 86 112 112 113 114 114 115 116 MODEL 5081-A SECTION 1.0 DESCRIPTION AND SPECIFICATIONS SECTION 1.0 DESCRIPTION AND SPECIFICATIONS • MEASuRES dissolved oxygen (ppm and ppb level), free chlorine, total chlorine, and ozone. • SECoNd INPut FoR pH SENSoR ALLoWS AutoMAtIC pH CoRRECtIoN for free chlorine measurement. No expensive reagents needed. • AutoMAtIC BuFFER RECoGNItIoN for pH calibration. • RoBuSt tYPE 4X ENCLoSuRE protects the transmitter from hostile environments. • uSES FouNdAtIoN FIELdBuS® dIGItAL CoMMuNICAtIoNS. 1.1 FEATURES AND APPLICATIONS the 5081-A transmitter with the appropriate sensor measures dissolved oxygen (ppm and ppb level), free chlorine, total chlorine, and ozone in a variety of process liquids. the transmitter is compatible with Rosemount Analytical 499A amperometric sensors for oxygen, chlorine, and ozone; and with Hx438 and Gx448 steam-sterilizable oxygen sensors. For free chlorine measurements, both automatic and manual pH correction are available. pH correction is necessary because amperometric chlorine sensors respond only to hypochlorous acid, not free chlorine, which is the sum of hypochlorous acid and hypochlorite ion. to measure free chlorine,most competing instruments require an acidified sample. Acid lowers the pH and converts hypochlorite ion to hypochlorous acid. the Model 5081-A eliminates the need for messy and expensive sample conditioning by using the sample pH to correct the chlorine sensor signal. If the pH is relatively constant, a fixed pH correction can be used. If the pH is greater than 7.0 and fluctuates more than about 0.2 units, continuous measurement of pH and automatic pH correction is necessary. Corrections are valid to pH 9.5. the transmitter fully compensates oxygen, ozone, free chlorine, and total chlorine readings for changes in membrane permeability caused by temperature changes. For pH measurements — pH is available with free chlorine only — the 5081-A features automatic buffer recognition and stabilization check. Buffer pH and temperature data for commonly used buffers are stored in the analyzer. Glass impedance diagnostics warn the user of an aging or failed pH sensor. data are displayed in 0.8 in. (20 mm) high seven-segment numerals. pH (chlorine only) and temperature appear in 0.3 inch (7 mm) high digits. the transmitter has a rugged, weatherproof, corrosion-resistant enclosure (type 4X and IP65) of epoxypainted aluminum. the enclosure also meets explosion-proof standards. the transmitter uses FouNdAtIoN Fieldbus digital communication. digital communications allows access to AMS (Asset Management Solutions). use AMS to set up and configure the transmitter, read process variables, and troubleshoot problems from a personal computer anywhere in the plant. A handheld infrared remote controller or the 375 or 475 communicator can also be used for programming. ® FouNdAtIoN is a registered trademark of Fieldbus Foundation. 1 MODEL 5081-A SECTION 1.0 DESCRIPTION AND SPECIFICATIONS 1.2 SPECIFICATIONS - GENERAL Housing: Cast aluminum with epoxy coating. type 4X (IP65). Neoprene o-ring cover seals. 0600 II 1 G Baseefa02AtEX1284 EEx ia IIC t4 tamb = -20°C to +65°C Dimensions: 160.5 mm x 175.3 mm x 161.3 mm (6.3 in. x 6.9 in. x 6.4 in.) See drawing. IECEx BAS 09.0159X Ex ia IIC t4 Ga Conduit Openings: ¾-in. FNPt Ambient Temperature: -4 to 149°F (-20 to 65°C) Storage Temperature: -22 to 176°F (-30 to 80°C) Relative Humidity: 0 to 95% (non-condensing) Weight/Shipping Weight: 10 lb/10 lb (4.5/5.0 kg) Display: two-line LCd; first line shows process variable (oxygen, ozone, or chlorine), second line shows temperature and output current. For pH/chlorine combination, the second line can be toggled to show pH. Fault and warning messages, when triggered, alternate with temperature and output readings. Process variable: 7 segment LCd, 0.8 in. (20 mm) high. temperature/output/pH: 7 segment LCd, 0.3 in. (7mm) high. display board can be rotated 90 degrees clockwise or counterclockwise. during calibration and programming, messages and prompts appear in the second line. ATEx ATEx and IECEx Special Conditions for Use: the model 5081 enclosure is made of aluminum alloy and is given a protective polyurethane paint finish. However, care should be taken to protect it from impact or abrasion if located in a zone 0 hazardous area. Non-Incendive: Class I, div. 2, Groups A-d dust Ignition Proof Class II & III, div. 1, Groups E-G type 4X Enclosure Class I, div. 2, Groups A-d Suitable for Class II, div. 2, Groups E-G t4 tamb = 70°C Explosion-Proof: Class I, div. 1, Groups B-d Class II, div. 1, Groups E-G Class III, div. 1 Class I, Groups B-d Class II, Groups E-G Class III tamb = 65°C max Temperature range: 0-100°C (0-150°C for steam sterilizable sensors) Repeatability (input): ±0.1% of range Temperature resolution: 0.1°C Input Ranges: 0-330 nA, 0.3-4 µA, 3.7-30 µA, 27-100 µA Accuracy using RTD: ±0.5°C between 0 and 50°C, ±1°C above 50°C Accuracy using 22k NTC: ±0.5°C between 0 and 50°C, ±2°C above 50°C RFI/EMI: EN-61326 HAzARDOUS AREA CLASSIFICATION: Intrinsic Safety: Class I, II, III, div. 1 Groups A-G t4 tamb = 70°C Exia Entity Class I, Groups A-d Class II, Groups E-G Class III t4 tamb = 70°C 2 Linearity (input): ±0.3% of range FOUNDATION Fieldbus: Four (4) AI blocks assignable to measurement (oxygen, ozone, or chlorine), temperature, pH, and sensor current. MODEL 5081-A SECTION 1.0 DESCRIPTION AND SPECIFICATIONS 1.3 SPECIFICATIONS — OxyGEN 1.6 SPECIFICATIONS — TOTAL CHLORINE Measurement Range: 0-99 ppm (mg/L), 0-200% saturation Measurement Range: 0-20 ppm (mg/L) as Cl2 Resolution: 0.01 ppm, 0.1 ppb for 499A trdo sensor Resolution: 0.001 ppm (Autoranges at 0.999 to 1.00 and 9.99 to 10.0) Temperature correction for membrane permeability: automatic between 0 and 50°C (can be disabled) Temperature correction for membrane permeability: automatic between 5 and 35°C (can be disabled) Calibration: air calibration (user must enter barometric pressure) or calibration against a standard instrument Calibration: against grab sample analyzed using portable test kit. SENSORS — OxyGEN: SENSOR — TOTAL CHLORINE: Model 499A do-54 for ppm level Model 499A CL-02-54 (must be used with SCS 921) Model 499A trdo-54 for ppb level Hx438 and Gx448 steam-sterilizable oxygen sensors 1.7 SPECIFICATIONS — OzONE 1.4 SPECIFICATIONS — FREE CHLORINE Measurement Range: 0-10 ppm (mg/L) Measurement Range: 0-20 ppm (mg/L) as Cl2 Resolution: 0.001 ppm (Autoranges at 0.999 to 1.00 and 9.99 to 10.0) Resolution: 0.001 ppm (Autoranges at 0.999 to 1.00 and 9.99 to 10.0) Temperature correction for membrane permeability: automatic between 5 and 35°C (can be disabled) Temperature correction for membrane permeability: automatic between 0 and 50°C (can be disabled) Calibration: against grab sample analyzed using portable test kit. pH Correction: Automatic between pH 6.0 and 9.5. Manual pH correction is also available. SENSOR — OzONE: Calibration: against grab sample analyzed using portable test kit. SENSOR — FREE CHLORINE: Model 499A CL-01-54 1.5 SPECIFICATIONS — pH Model 499A oZ-54 ACCESSORIES POWER SUPPLy: use the Model 515 Power Supply to provide dc loop power to the transmitter. the Model 515 provides two isolated sources at 24Vdc and 200 mA each. For more information refer to product data sheet 71-515. Application: pH measurement available with free chlorine only Measurement Range: 0-14 pH Resolution: 0.01 pH Sensor Diagnostics: Glass impedance (for broken or aging electrode) and reference offset. Reference impedance (for fouled reference junction) is not available. Repeatability: ±0.01 pH at 25°C SENSORS — pH: use Model 399-09-62, 399-14, or 399VP-09. See pH sensor product data sheet for complete ordering information. 3 MODEL 5081-A SECTION 1.0 DESCRIPTION AND SPECIFICATIONS 1.8 TRANSMITTER DISPLAy DURING CALIBRATION AND PROGRAMMING (Figure 1-1) 1. Continuous display of oxygen, chlorine, or ozone reading. 1 2 F A u L t 7 2. units: ppm, ppb, or % saturation. 4. Submenus, prompts, and diagnostic readings appear hear. 6 3 CALIBRATE PRoGRAM 5. Commands available in each submenu or at each prompt appear here. dIAGNoSE CALIbrAtE 6. Hold appears when the transmitter is in hold. 7. Fault appears when the transmitter detects a sensor or instrument fault. ppm H o L d 3. Current menu appears here. 5 ExIT NExT ENTER 4 FIGURE 1-1. TRANSMITTER DISPLAy DURING CALIBRATION AND PROGRAMMING the program display screen allows access to calibration and programming menus. 1.9 INFRARED REMOTE CONTROLLER (Figure 1-2) 4. 1. Pressing a menu key allows the user access to calibrate, program, or diagnostic menus. 3. 2. Press ENtER to store data and settings. Press NEXt to move from one submenu to the next. Press EXIt to leave without storing changes. 3. use the editing keys to scroll through lists of allowed settings or to change a numerical setting to the desired value. 1. 2. 4. Pressing HoLd puts the transmitter in hold and sends the output current to a pre-programmed value. Pressing RESEt causes the transmitter to abandon the present operation and return to the main display. FIGURE 1-2. INFRARED REMOTE CONTROLLER 4 MODEL 5081-A SECTION 1.0 DESCRIPTION AND SPECIFICATIONS 1.10 FOUNDATION FIELDBUS (FIGURE 1-3) Figure 1-3 is the block diagram for the 5081-A-FF transmitter. AMS Inside from Rosemount Analytical allows plant personnel to read process variables and completely configure FouNdAtIoN Fieldbus transmitters. FIGURE 1-3. FUNCTIONAL BLOCK DIAGRAM FOR MODEL 5081-A TRANSMITTER WITH FOUNDATION FIELDBUS 1.11 GENERAL SPECIFICATIONS Model: 5081-A-FF Amperometric Fieldbus transmitter Type: oxygen, Chlorine and ozone transmitter Device ITK Profile: 6 (Released for ItK 6.0.0 / 6.0.1) Manufacturer Identification (MANUFAC_ID): 0x524149 Device Type (DEv_TyPE): 0x4083 Device Revision (DEv_REv): 0x03 Linkmaster: Yes Number of Link Objects: 20 vCR’s supported: 20 Mandatory Features: • Resource Block • Alarm and Events • Function Block Linking • trending • Multi-Bit Alert Reporting • Field diagnostics Additional Features: • Common Software download • Block Instantiation • Supports deltaV Auto Commissioning • • • • Supports deltaV Auto Replacement Supports deltaV Firmware Live download PlantWeb Alerts with re-annunciation / multibit Supports Easy Configuration Assistant Function Blocks (Execution Time): • 4 – Analog Input Blocks (15 mseconds) • AI Block Channels: Channel 1: oxygen, Chlorine, ozone Channel 2: temperature Channel 3: Sensor Current Channel 4: pH (Free Chlorine only) • Proportional Integral derivative (25 mseconds) Power: • two Wire device; Fieldbus Polarity Insensitive • Current draw: 21 mA • device Certifications: IS / FISCo • Maximum certified input Voltage for IS: 30V • Maximum certified input current for IS: 300mA • Maximum certified input power for IS: 1.3W • Internal Capacitance (Ci): 0 nF • Internal Inductance (Li): 0 μH 5 MODEL 5081-A SECTION 1.0 DESCRIPTION AND SPECIFICATIONS 1.12 ASSET MANAGEMENT SOLUTIONS (AMS) (FIGURE 1-4) Rosemount Analytical AMS windows provide access to all transmitter measurement and configuration variables. the user can read raw data, final data, and program settings and can reconfigure the transmitter from anywhere in the plant. Figures 1-4 and 1-5 show two of the many configuration and measurement screens available. FIGURE 1-4. ASSET MANAGEMENT SOLUTIONS (AMS) CONFIGURATION SCREEN FIGURE 1-5. ASSET MANAGEMENT SOLUTIONS (AMS) MEASUREMENT SCREEN 6 MODEL 5081-A SECTION 1.0 DESCRIPTION AND SPECIFICATIONS MILLIMETER INCH FIGURE 1-6. MODEL 5081-A MOUNTING AND DIMENSIONAL DRAWINGS 7 MODEL 5081-A SECTION 1.0 DESCRIPTION AND SPECIFICATIONS 1.13 ORDERING INFORMATION the Model 5081-A Transmitter is intended for the determination of oxygen (ppm and ppb level), free chlorine, total chlorine, and ozone. For free chlorine measurements, which often require continuous pH correction, a second input for a pH sensor is available. the transmitter is housed in a weatherproof, corrosion-resistant enclosure. A hand-held infrared remote controller is required to configure and calibrate the transmitter. MODEL 5081-A SMART TWO-WIRE MICROPROCESSOR TRANSMITTER CODE FF REQUIRED SELECTION Foundation Fieldbus digital output CODE 20 21 REQUIRED SELECTION Infrared remote controller included Infrared remote controller not included CODE 60 AGENCy APPROvALS No approval 5081-A -FF -20 -60 ExAMPLE 1.14 ACCESSORIES MODEL/PN 515 dC loop power supply (see product data sheet 71-515) 24479-00 Infrared remote controller (required, one controller can operate any 5081 transmitter) 2002577 2-in. pipe mounting kit 9241178 Stainless steel tag, specify marking AMS software 8 DESCRIPTION to order AMS software, call Rosemount Measurement at (800) 999-9307 MODEL 5081-A SECTION 2.0 INSTALLATION SECTION 2.0 INSTALLATION 2.1 2.2 2.3 2.4 Unpacking and inspection Orienting the display board Installation Power supply wiring 2.1 UNPACKING AND INSPECTION Inspect the shipping container. If it is damaged, contact the shipper immediately for instructions. Save the box. If there is no apparent damage, remove the transmitter. Be sure all items shown on the packing list are present. If items are missing, notify Rosemount Analytical immediately. 2.2 ORIENTING THE DISPLAy BOARD the display board can be rotated 90 degrees, clockwise or counterclockwise, from the original position. to reposition the display: 1. Loosen the cover lock nut until the tab disengages from the end, unscrew the cap. 2. Remove the three bolts holding the circuit board stack. 3. Lift and rotate the display board 90 degrees into the desired position. 4. Position the display board on the standoffs. Replace and tighten the bolts. 5. Replace the end cap. 2.3 INSTALLATION 2.3.1 General information 1. the transmitter tolerates harsh environments. For best results, install the transmitter in an area where temperature extremes, vibrations, and electromagnetic and radio frequency interference are minimized or absent. 2. to prevent unintentional exposure of the transmitter circuitry to the plant environment, keep the cover lock in place over the circuit end cap. See Figure 2-1. to remove the circuit end cap loosen the lock nut until the tab disengages from the cap. then unscrew the cover. 3. the transmitter has two ¾-inch conduit openings, one on each side of the housing. See Figure 2-1. 4. use weathertight cable glands to keep moisture out of the analyzer. If both a chlorine and pH sensor are being used, install a cable gland with a dual hole seal insert. 5. If conduit is used, plug and seal the connections at the transmitter housing to prevent moisture from getting inside the transmitter. NOTE Moisture allowed to accumulate in the housing can affect the performance of the transmitter and may void the warranty. 9 MODEL 5081-A SECTION 2.0 INSTALLATION 2.3.2 Mounting on a flat surface. MILLIMETER INCH FIGURE 2-1. Mounting the Model 5081-A on a flat surface 10 MODEL 5081-A SECTION 2.0 INSTALLATION 2.3.3 Pipe Mounting. MILLIMETER INCH dWG. No. 40508104 REV. G dWG. No. 40508103 REV. C FIGURE 2-2. Using the pipe mounting kit (PN 2002577) to attach the Model 5081-A to a pipe. 11 MODEL 5081-A SECTION 2.0 INSTALLATION 2.4 POWER SUPPLy WIRING Refer to Figures 2-3 and 2-4. Run the power/signal wiring through the opening nearest terminals 15 and 16. use shielded cable and ground the shield at the power supply. to ground the transmitter, attach the shield to the grounding screw on the inside of the transmitter case. A third wire can also be used to connect the transmitter case to earth ground. (9 - 32 VdC) NOTE For optimum EMI/RFI immunity, the power supply/output cable should be shielded and enclosed in an earth-grounded metal conduit. do not run power supply/signal wiring in the same conduit or cable tray with AC power lines or with relay actuated signal cables. Keep power supply/signal wiring at least 6 ft (2 m) away from heavy electrical equipment. (9 - 32 VdC) dWG. No. 40308122 REV. B FIGURE 2-3. Power Supply Wiring Model 5081 transmitter Model 5081 transmitter FIGURE 2-4. Typical Fieldbus Network Electrical Wiring Configuration 12 MODEL 5081-A SECTION 3.0 SENSOR WIRING SECTION 3.0 SENSOR WIRING 3.1 3.2 3.3 Wiring Model 499A oxygen, chlorine, and ozone sensors Wiring Model 499ACL-01 (free chlorine) and pH sensors Wiring Model Hx438 and Gx448 sensors NOTE The Model 5081-A transmitter leaves the factory configured for use with the Model 499ADO sensor (ppm dissolved oxygen). If a 499ADO sensor is not being used, turn to Section 7.5.3 and configure the transmitter for the desired measurement (ppb oxygen, oxygen measured using a steam-sterilizable sensor, free chlorine, total chlorine, or ozone) before wiring the sensor to the transmitter. Operating the transmitter and sensor for longer than five minutes while the transmitter is improperly configured will greatly increase the stabilization time for the sensor. Be sure to turn off power to the transmitter before wiring the sensor. 3.1 WIRING MODEL 499A OxyGEN, CHLORINE, AND OzONE SENSORS All 499A sensors (499Ado, 499Atrdo, 499ACL-01, 499ACL-02, and 499AoZ) have identical wiring. use the pigtail wire and wire nuts provided with the sensor when more than one wire must be attached to a single terminal. FIGURE 3-1. Amperometric sensors with standard cable. FIGURE 3-2. Amperometric sensors with optimum EMI/RFI cable or variopol cable. 13 MODEL 5081-A SECTION 3.0 SENSOR WIRING 3.2 WIRING MODEL 499ACL-01 (Free Chlorine) SENSORS AND pH SENSORS If free chlorine is being measured and the pH of the liquid varies more than 0.2 pH unit, a continuous correction for pH must be applied to the chlorine reading. therefore, a pH sensor must be wired to the transmitter. this section gives wiring diagrams for the pH sensors typically used. When using the 499ACL-01 (free chlorine) sensor with a pH sensor, use the RTD in the pH sensor for measuring temperature. DO NOT use the RTD in the chlorine sensor. the pH sensor Rtd is needed for temperature measurement during buffer calibration. during normal operation, the Rtd in the pH sensor provides the temperature measurement required for the free chlorine membrane permeability correction. Refer to the table to select the appropriate wiring diagram. Most of the wiring diagrams require that two or more shield wires be attached to a single terminal. use the pigtail wire and wire nuts provided with the chlorine sensor to make the connection. Insulate and tape back unused wires. Free chlorine sensor cable pH sensor Figure Standard 399VP-09 3-3 Standard 399-14 3-4 Standard 399-09-62 3-5 EMI/RFI or Variopol 399VP-09 3-6 EMI/RFI or Variopol 399-14 3-7 EMI/RFI or Variopol 399-09-62 3-8 FIGURE 3-3. Free chlorine sensor with standard cable and 399vP-09 pH sensor without internal preamplifier. 14 FIGURE 3-4. Free chlorine sensor with standard cable and 399-14 pH sensor with internal preamplifier. If the preamplifier is in the sensor, a default setting in the transmitter must be changed. See Section 7.8.3. MODEL 5081-A SECTION 3.0 SENSOR WIRING FIGURE 3-5. Free chlorine sensor with standard cable and 399-09-62 pH sensor without internal preamplifier. FIGURE 3-6. Free chlorine sensor with optimum EMI/RFI cable or variopol cable and 399vP-09 pH sensor without internal preamplifier. FIGURE 3-7. Free chlorine sensor with optimum EMI/RFI cable or variopol cable and 399-14 pH sensor with internal preamplifier. If the preamplifier is in the sensor, a default setting in the transmitter must be changed. See Section 7.8.3. FIGURE 3-8. Free chlorine sensor with optimum EMI/RFI cable or variopol cable and 399-09-62 pH sensor without internal preamplifier. 15 MODEL 5081-A 3.3 WIRING Hx438 AND Gx448 SENSORS FIGURE 3-9. Hx438 and Gx448 Sensors. 16 SECTION 3.0 SENSOR WIRING RIGID METAL CONDUIT AND APPROVED SEALS 8 NOTES: UNLESS OTHERWISE SPECIFIED 1. INSTALLATION MUST CONFORM TO THE NEC. 7 2. SEAL REQUIRED AT EACH CONDUIT ENTRANCE. 3 USE ONLY APPROVED CONDUIT SEALS AND FITTINGS. AMPEROMETRIC SENSOR OPTIONAL pH SENSOR/ PREAMP/J-BOX 3 6 W 6 2 RESERVED F OR 70 5081-A-FF-67 °C 10 pH/O R IN P WIRING LABEL I BE RA T E D 9 pH/ORP GUARD 3 1 -5V 1 4 RELEASE DATE 10-11-02 ECO NO 8286 C REV +- .030 +- .010 FINISH ANGLES TOLERANCES +- .5 3 DIMENSIONS ARE IN INCHES REMOVE BURRS & SHARP EDGES .020 MAX MACHINED FILLET RADII .020 MAX NOMINAL SURFACE FINISH 125 MATERIAL .XX .XXX UNLESS OTHERWISE SPECIFIED 3 FIGURE 4-1. FMRC Explosion-Proof Installation 5 CLASS I, DIV 1, GPS B-D CLASS II, DIV 1, GPS E-G CLASS III, DIV 1 70°C MAX HAZARDOUS AREA 4 RIGID METAL CONDUIT AND APPROVED SEALS 16 HT/F (+) F A B C SAFE AREA 4 RT SEN D SE RT 5 IN D /B - 00 51 8 41 92 PN 3 RTD RTN 1 ED ERV RES T MUS NG RI 8 3 15 HT/FF (-) 2 14 CATHODE/ RESERVED 4 7 -IN REF 7 D 6 F RE ARD GU 5 8 SOL GND 11 5 9 RECOMMENDED SENSORS: 499ATrDO 499AOZ 499ADO 499ACL 6 12 7 10 13 E/ D ANO RVED E RES 1 13 12 V +5 14 8787 D SEE ECO 2 N. KOUMBIS J. FLOCK THIS FILE CREATED USING SOLID EDGE PROJECT ENGR APVD CHECKED J. FLOCK DRAWN APPROVALS POWER SUPPLY 32 VDC MAX 05 /07/ 02 05 /07/ 02 05 /07/ 02 2 REVISION Emerson DATE 1 REV REV REV REV REV REV D Emerson Process Management, Rosemount Analytical Division 2400 Barranca Pkwy Irvine, CA 92606 REVISIONS NOT PERMITTED W/O AGENCY APPROVAL FM BJ/ JF CHK/APPROVED THIS DOCUMENT IS CERTIFIED BY NK 08-02-04 BY SCALE SIZE D NONE DWG NO. TYPE 1400212 1 SHEET 1 OF 1 06-01 REV D SCHEM, SYSTEM FMRC EXP PROOF 5081-A-FF TITLE DESCRIPTION DATE D1 SAFE AREA ECO LTR A B C D 1400212 16 15 8 This document contains information proprietary to Rosemount Analytical, and is not to be made available to those who may compete with Rosemount Analytical. MODEL 5081-A SECTION 4.0 INTRINSICALLy SAFE & ExPLOSION PROOF INSTALLATIONS SECTION 4.0 INTRINSICALLy SAFE & ExPLOSION PROOF INSTALLATIONS 17 SECTION 4.0 INTRINSICALLy SAFE & ExPLOSION PROOF INSTALLATIONS FIGURE 4-2. FM Intrinsically-Safe Installation Label MODEL 5081-A 18 SECTION 4.0 INTRINSICALLy SAFE & ExPLOSION PROOF INSTALLATIONS FIGURE 4-3. FM Intrinsically-Safe Installation (1 of 2). MODEL 5081-A 19 SECTION 4.0 INTRINSICALLy SAFE & ExPLOSION PROOF INSTALLATIONS FIGURE 4-3. FM Intrinsically-Safe Installation (2 of 2). MODEL 5081-A 20 SECTION 4.0 INTRINSICALLy SAFE & ExPLOSION PROOF INSTALLATIONS FIGURE 4-4. CSA Intrinsically-Safe Installation Label MODEL 5081-A 21 A B INFRARED RED REMOTE CONTROL UNIT (RMT PN 23572-00) FOR USE IN CLASS I AREA ONLY 6 9 7 8 8 NOTES: UNLESS OTHERWISE SPECIFIED Voc OR Vt NOT GREATER THAN 30 V Isc OR It NOT GREATER THAN 300 mA Pmax NOT GREATER THAN 0.9 W 7 6 5 12 11 4 RELEASE DATE 10-16-02 5081-A-FF MODEL NO. 25 5.99 ECO NO. 8324 REV C FINISH ANGLES TOLERANCES + - 3 DIMENSIONS ARE IN INCHES REMOVE BURRS & SHARP EDGES .020 MAX MACHINED FILLET RADII .020 MAX NOMINAL SURFACE FINISH 125 + .030 + - .010 MATERIAL .XX .XXX UNLESS OTHERWISE SPECIFIED Imax (mA) 300 PART NO. THIS DWG CONVERTED TO SOLID EDGE 2 10/16/02 PROJECT ENGR APVD J. FLOCK 10/16/02 CHECKED J. FLOCK 04/17/02 DATE 27.8 UNSPECIFIED POWER SUPPLY 30 VDC MAX DESCRIPTION BILL OF MATERIAL Uniloc 0 Li (mH) REV REV REV REV REV REV Rosemount Analytical, Uniloc Division 2400 Barranca Pkwy Irvine, CA 92606 REVISIONS NOT PERMITTED W/O AGENCY APPROVAL CSA THIS DOCUMENT IS CERTIFIED BY DATE 5-6-04 BJ 1 BY SCALE SIZE D NONE DWG NO. TYPE 1400198 1 SHEET 1 OF SCHEMATIC, INSTALLATION 5081-A-FF XMTR CSA TITLE 147 mW 105.64 mA 13.02 Vdc Ci (nF) N. KOUMBIS APPROVALS DRAWN ITEM Pmax (W) 1.3 Pt It Vt MODEL 5081-A-FF TB1-1 THRU 12 TABLE II OUTPUT PARAMETERS 5081-A-FF ENTITY PARAMETERS SUPPLY / SIGNAL TERMINALS TB 1-15, 16 Vmax (Vdc) 30 REVISION DESCRIPTION UNCLASSIFIED AREA SEE ECO 2 TO PREVENT IGNITION OF FLAMMABLE OR COMBUSTIBLE ATMOSPHERES, DISCONNECT POWER BEFORE SERVICING. TABLE III 3.1 12.3 0.96 21.69 C D 8925 D SAFETY BARRIER (SEE NOTES 1 & 9) ECO LTR SUBSTITUTION OF COMPONENTS MAY IMPAIR INTRINSIC SAFETY OR SUITABILITY FOR DIVISION 2. OUTPUT PARAMETERS Ca La (uF) (mH) TABLE I WARNING- WARNING- 3 A, B GAS GROUPS NI CLASS I, DIV 2 GRPS A-D CLASS II, DIV 2 GRPS E-G IS CLASS I, GRPS A-D CLASS II, GRPS E-G CLASS III HAZARDOUS AREA 4 FIGURE 4-5. CSA Intrinsically-Safe Installation (1 of 2) 1. ANY SHUNT ZENER DIODE SAFETY BARRIER APPROVED BY CSA HAVING THE FOLLOWING OUTPUT PARAMETERS: SUPPLY/SIGNAL TERMINALS TB1-15, 16 2. THE MODEL 5081-A-FF TRANSMITTER INCLUDES INTEGRAL PREAMPLIFIER CIRCUITRY. AN EXTERNAL PREAMPLIFIER MAY BE ALSO USED. THE OUTPUT PARAMETERS SPECIFIED IN TABLE II ARE VALID FOR EITHER PREAMPLIFIER. THE CAPACITANCE AND INDUCTANCE OF THE LOAD CONNECTED TO THE SENSOR TERMINALS MUST NOT EXCEED THE VALUES SPECIFIED IN TABLE I WHERE Ca Ci (SENSOR) + Ccable; La Li (SENSOR) + Lcable. 3. INTRINSICALLY SAFE APPARATUS (MODEL 5081-A-FF, FIELDBUS TERMINATOR AND ANY ADDITIONAL FIELDBUS DEVICES) AND ASSOCIATED APPARATUS (SAFETY BARRIER) SHALL MEET THE FOLLOWING REQUIREMENTS: THE VOLTAGE (Vmax) AND CURRENT (Imax) OF THE INTRINSICALLY SAFE APPARATUS MUST BE EQUAL TO OR GREATER THAN THE VOLTAGE (Voc OR Vt) AND CURRENT (Isc OR It) WHICH CAN BE DELIVERED BY THE ASSOCIATED APPARATUS (SAFETY BARRIER). IN ADDITION, THE MAXIMUM UNPROTECTED CAPACITANCE (Ci) AND INDUCTANCE (Li) OF THE INTRINSICALLY SAFE APPARATUS, INCLUDING INTERCONNECTING WIRING, MUST BE EQUAL OR LESS THAN THE CAPACITANCE (Ca) AND INDUCTANCE (La) WHICH CAN BE SAFELY CONNECTED TO THE APPARATUS. (REF. TABLE III). 4. PREAMPLIFIER TYPE 23546-00, 23538-00 OR 23561-00 MAY BE UTILIZED INSTEAD OF THE MODEL 5081-A-FF TRANSMITTER INTEGRAL PREAMPLIFIER CIRCUIRTY. A WEATHER RESISTANT ENCLOSURE MUST HOUSE THE TYPE 23546-00 REMOTE PREAMPLIFIER. 5. INSTALLATION SHOULD BE IN ACCORDANCE WITH ANSI/ISA RP12.06.01 "INSTALLATION OF INTRINSICALLY SAFE SYSTEMS FOR HAZARDOUS (CLASSIFIED) LOCATIONS" AND THE CANADIAN ELECTRICAL CODE (CSA C22.1). 6. SENSORS WITHOUT PREAMPS SHALL MEET THE REQUIREMENTS OF SIMPLE APPARATUS AS DEFINED IN ANSI/ISA RP12.6 AND THE CEC (CSA C22.1). THEY CAN NOT GENERATE NOR STORE MORE THAN 1.2V, 0.1A, 25mW, AND 20uJ. SEE TABLES I AND II. 7. DUST-TIGHT CONDUIT SEAL MUST BE USED WHEN INSTALLED IN CLASS II AND CLASS III ENVIRONMENTS. 8. RESISTANCE BETWEEN INTRINSICALLY SAFE GROUND AND EARTH GROUND MUST BE LESS THAN 1.0 Ohm. 9. THE ENTITY CONCEPT ALLOWS INTERCONNECTION OF INTRINSICALLY SAFE APPARATUS WITH ASSOCIATED APPARATUS WHEN THE FOLLOWING IS TRUE: FIELD DEVICE INPUT ASSOCIATED APPARATUS OUTPUT Voc, Vt OR Uo; Vmax OR Ui Isc, It OR Io; Imax OR Ii Po; Pmax OR Pi Ci+ Ccable; Ca, Ct OR Co La, Lt OR Lo Li+ Lcable. 10. ASSOCIATED APPARATUS MANUFACTURER'S INSTALLATION DRAWING MUST BE FOLLOWED WHEN INSTALLING THIS EQUIPMENT. 11. CONTROL EQUIPMENT CONNECTED TO ASSOCIATED APPARATUS MUST NOT USE OR GENERATE MORE THAN 250 Vrms OR Vdc. 12. THE ASSOCIATED APPARATUS MUST BE CSA APPROVED. 13. NO REVISION TO DRAWING WITHOUT PRIOR CSA APPROVAL. D1 MODEL 5081-A-FF XMTR 5 2 D 10-96 REV D QTY JF CHK A B C D 1400198 C D AMPEROMETRIC SENSOR FIELDBUS CSA INTRINSIC SAFETY INSTALLATION 6 3 2 7 10 8 5 4 1 13 14 16 15 22 This document contains information proprietary to Rosemount Analytical, and is not to be made available to those who may compete with Rosemount Analytical. MODEL 5081-A SECTION 4.0 INTRINSICALLy SAFE & ExPLOSION PROOF INSTALLATIONS A B C D 8 RECOMMENDED CABLE PN 9200273 (UNPREPPED) PN 23646-01 PREPPED 10 COND, 2 SHIELDS, 24 AWG. SEE NOTE 2 INFRARED RED REMOTE CONTROL UNIT (RMT PN 23572-00) FOR USE IN CLASS I AREA ONLY PH SENSOR WITH TC AMPEROMETRIC SENSOR +PH SENSOR AMPEROMETRIC SENSOR 7 PREAMP (NOTE 4) RECOMMENDED CABLE 4 WIRES SHIELDED 22 AWG, SEE NOTE 2 TB14 5 7 10 6 CSA APPROVED PREAMP THAT MEETS REQUIREMENTS OF NOTE 3 PREAMP (NOTE 4) CSA APPROVED PREAMP THAT MEETS REQUIREMENTS OF NOTE 3 +PH SENSOR AMPEROMETRIC SENSOR +PH SENSOR MODEL 5081-A-FF XMTR MODEL 5081-A-FF XMTR MODEL 5081-A-FF XMTR MODEL 5081-A-FF XMTR 8 AMPEROMETRIC SENSOR 6 9 7 10 8 This document contains information proprietary to Rosemount Analytical, and is not to be made available to those who may compete with Rosemount Analytical. 1 2 3 4 1 2 3 4 1 2 3 4 5 4 3 2 5 5 13 12 4 NI CLASS I, DIV 2 GRPS A-D CLASS II, DIV 2 GRPS E-G IS CLASS I, GRPS A-D CLASS II, GRPS E-G CLASS III HAZARDOUS AREA 4 3 3 2 SCALE NONE TYPE 1400198 1 SHEET 2 OF UNSPECIFIED POWER SUPPLY 30 VDC MAX SAFETY BARRIER (SEE NOTES 1 & 9) DWG NO. UNSPECIFIED POWER SUPPLY 30 VDC MAX SAFETY BARRIER (SEE NOTES 1 & 9) SIZE UNSPECIFIED POWER SUPPLY 30 VDC MAX SAFETY BARRIER (SEE NOTES 1 & 9) 1 UNSPECIFIED POWER SUPPLY 30 VDC MAX D UNCLASSIFIED AREA 2 SAFETY BARRIER (SEE NOTES 1 & 9) FIGURE 4-5. CSA Intrinsically-Safe Installation (2 of 2) 1 6 6 6 6 5 5 5 7 7 7 7 8 8 8 9 9 9 10 10 10 14 16 15 13 14 11 11 11 11 12 12 12 16 15 13 14 16 15 13 14 2 06-01 REV D A B C D 1400198 16 15 MODEL 5081-A SECTION 4.0 INTRINSICALLy SAFE & ExPLOSION PROOF INSTALLATIONS 23 24 1.30 ±.02 .650 ±.015 MATERIAL: AISI 300 SERIES STAINLESS STEEL .015 ± .005 THICK. MATERIAL TO BE ANNEALED & PASSIVATED. MAXIMUM HARDNESS BRINELL 190. 1 E2 4X R .25 .140 ±.005 FINISH MATERIAL 4 1 REVISION 8-20-02 ENG APVD J. FLOCK THIS FILE CREATED USING SOLID EDGE 8-20-02 CHECKED J. FLOCK 4-18-02 DATE DESCRIPTION B. JOHNSON APPROVALS SEE ECO DRAWN ECO LQD10245 Emerson Baseefa Certified Product No modifications permitted without the approval of the Authorized Person Related Drawing E ANALYTICAL ROSEMOUNT SCALE: 2:1 WEIGHT: SHEET 1 OF 1 LABEL, I.S. BAS/ATEX 5081-A-FF SIZE DWG NO REV E B 9241472-00 TITLE REV REV REV REV REV REV REVISIONS NOT PERMITTED W/O AGENCY APPROVAL Baseefa THIS DOCUMENT IS CERTIFIED BY DATE CHECKED/APPROVED BY CH 3-21-11 JP/DOC PROCESS MANAGEMENT FIGURE 4-6. BASEEFA/ATEx Intrinsically-Safe Installation Label NO CHANGE WITHOUT BASEEFA APPROVAL. 2. NOTES: UNLESS OTHERWISE SPECIFIED ARTWORK IS SUPPLIED BY ROSEMOUNT ANALYTICAL. 3. LTR E 2.180 ±.005 REV D DIMENSIONS ARE IN INCHES REMOVE BURRS & SHARP EDGES MACHINE FILLET RADII .020 MAX NOMINAL SURFACE FINISH: 125 ANGLES ± 1/2°. .XX ± .03 .XXX ± .010 DIRECTION OF NATURAL GRAIN .125 FINISH: SILKSCREEN BLACK EPOXY PAINT (BAKED). 2X FULL RAD ECO NO 8226 O .125 4 E1 2.56 ±.02 RELEASE DATE 08-09-02 B .120 ±.015 This document contains information proprietary to Rosemount Analytical, and is not to be made available to those who may compete with Rosemount Analytical. MODEL 5081-A SECTION 4.0 INTRINSICALLy SAFE & ExPLOSION PROOF INSTALLATIONS 9241472-00 A B 7 8 6 5 5-6-04 GAS GROUPS NI CLASS I, DIV 2 GRPS A-D CLASS II, DIV 2 GRPS E-G IS CLASS I, GRPS A-D CLASS II, GRPS E-G CLASS III HAZARDOUS AREA 4 3 8 NOTES: UNLESS OTHERWISE SPECIFIED 7 MODEL NO. 4 RELEASE DATE ECO NO. 8925 REV A 17.5 Vmax (Vdc) FINISH ANGLES TOLERANCES + - 3 DIMENSIONS ARE IN INCHES REMOVE BURRS & SHARP EDGES .020 MAX MACHINED FILLET RADII .020 MAX NOMINAL SURFACE FINISH 125 + .030 + - .010 MATERIAL .XX .XXX UNLESS OTHERWISE SPECIFIED Imax (mA) 380 DRAWN J. FLOCK THIS DWG CREATED IN SOLID EDGE PROJECT ENGR APVD 2 5/6/04 5/6/04 5/3/04 DATE 27.8 UNSPECIFIED POWER SUPPLY 30 VDC MAX DESCRIPTION BILL OF MATERIAL Uniloc 0 Li (mH) 1 D SCALE SIZE NONE DWG NO. REV REV REV REV REV REV Rosemount Analytical, Uniloc Division 2400 Barranca Pkwy Irvine, CA 92606 REVISIONS NOT PERMITTED W/O AGENCY APPROVAL CSA 1400294 TYPE DATE THIS DOCUMENT IS CERTIFIED BY BY 1 SHEET 1 OF SCHEMATIC, INSTALLATION 5081-A-FI XMTR CSA TITLE 147 mW 105.64 mA 13.02 Vdc Ci (nF) B. JOHNSON APPROVALS PART NO. Pmax (W) 5.32 CHECKED J. FLOCK 5081-A-FI ENTITY PARAMETERS SUPPLY / SIGNAL TERMINALS TB 1-15, 16 ITEM 25 21.69 D TABLE III It 12.3 5.99 C Pt Vt 3.1 0.96 MODEL 5081-A-FI TB1-1 THRU 12 TABLE II OUTPUT PARAMETERS A, B 5081-A-FI REVISION DESCRIPTION UNCLASSIFIED AREA 2 TO PREVENT IGNITION OF FLAMMABLE OR COMBUSTIBLE ATMOSPHERES, DISCONNECT POWER BEFORE SERVICING. OUTPUT PARAMETERS Ca La (uF) (mH) TABLE I ECO CSA APPROVED ASSOCIATED APPARATUS SUITABLE FOR FISCO SEE NOTE 8 AND TABLE III LTR SUBSTITUTION OF COMPONENTS MAY IMPAIR INTRINSIC SAFETY OR SUITABILITY FOR DIVISION 2. FIGURE 4-7. CSA Intrinsically-Safe Installation (1 of 2) 6 1. THE MODEL 5081-A-FI TRANSMITTER INCLUDES INTEGRAL PREAMPLIFIER CIRCUITRY. AN EXTERNAL PREAMPLIFIER MAY BE ALSO USED. THE OUTPUT PARAMETERS SPECIFIED IN TABLE II ARE VALID FOR EITHER PREAMPLIFIER. THE CAPACITANCE AND INDUCTANCE OF THE LOAD CONNECTED TO THE SENSOR TERMINALS MUST NOT EXCEED THE VALUES SPECIFIED IN TABLE I WHERE Ca Ci (SENSOR) + Ccable; La Li (SENSOR) + Lcable. 2. INTRINSICALLY SAFE APPARATUS (MODEL 5081-A-FI, FIELDBUS TERMINATOR AND ANY ADDITIONAL FIELDBUS DEVICES) AND ASSOCIATED APPARATUS (SAFETY BARRIER) SHALL MEET THE FOLLOWING REQUIREMENTS: THE VOLTAGE (Vmax) AND CURRENT (Imax) OF THE INTRINSICALLY SAFE APPARATUS MUST BE EQUAL TO OR GREATER THAN THE VOLTAGE (Voc OR Vt) AND CURRENT (Isc OR It) WHICH CAN BE DELIVERED BY THE ASSOCIATED APPARATUS (SAFETY BARRIER). IN ADDITION, THE MAXIMUM UNPROTECTED CAPACITANCE (Ci) AND INDUCTANCE (Li) OF THE INTRINSICALLY SAFE APPARATUS, INCLUDING INTERCONNECTING WIRING, MUST BE EQUAL OR LESS THAN THE CAPACITANCE (Ca) AND INDUCTANCE (La) WHICH CAN BE SAFELY CONNECTED TO THE APPARATUS. (REF. TABLE III). 3. PREAMPLIFIER TYPE 23546-00, 23538-00 OR 23561-00 MAY BE UTILIZED INSTEAD OF THE MODEL 5081-A-FI TRANSMITTER INTEGRAL PREAMPLIFIER CIRCUIRTY. A WEATHER RESISTANT ENCLOSURE MUST HOUSE THE TYPE 23546-00 REMOTE PREAMPLIFIER. 4. INSTALLATION SHOULD BE IN ACCORDANCE WITH ANSI/ISA RP12.06.01 "INSTALLATION OF INTRINSICALLY SAFE SYSTEMS FOR HAZARDOUS (CLASSIFIED) LOCATIONS" AND THE CANADIAN ELECTRICAL CODE (CSA C22.1). 5. SENSORS WITHOUT PREAMPS SHALL MEET THE REQUIREMENTS OF SIMPLE APPARATUS AS DEFINED IN ANSI/ISA RP12.6 AND THE CEC (CSA C22.1). THEY CAN NOT GENERATE NOR STORE MORE THAN 1.5V, 0.1A, 25mW, AND 20uJ. SEE TABLES I AND II. 6. DUST-TIGHT CONDUIT SEAL MUST BE USED WHEN INSTALLED IN CLASS II AND CLASS III ENVIRONMENTS. 7. RESISTANCE BETWEEN INTRINSICALLY SAFE GROUND AND EARTH GROUND MUST BE LESS THAN 1.0 Ohm. 8. THE ENTITY CONCEPT ALLOWS INTERCONNECTION OF INTRINSICALLY SAFE APPARATUS WITH ASSOCIATED APPARATUS WHEN THE FOLLOWING IS TRUE: FIELD DEVICE INPUT ASSOCIATED APPARATUS OUTPUT Voc, Vt OR Uo; Vmax OR Ui Isc, It OR Io; Imax OR Ii Po; Pmax OR Pi Ci+ Ccable; Ca, Ct OR Co La, Lt OR Lo Li+ Lcable. WARNING- 9 WARNING- 11 9. ASSOCIATED APPARATUS MANUFACTURER'S INSTALLATION DRAWING MUST BE FOLLOWED WHEN INSTALLING THIS EQUIPMENT. 12 10. CONTROL EQUIPMENT CONNECTED TO ASSOCIATED APPARATUS MUST NOT USE OR GENERATE MORE THAN 250 Vrms OR Vdc. 11. THE ASSOCIATED APPARATUS MUST BE CSA APPROVED. 12. NO REVISION TO DRAWING WITHOUT PRIOR CSA APPROVAL. INFRARED RED REMOTE CONTROL UNIT (RMT PN 23572-00) FOR USE IN CLASS I AREA ONLY MODEL 5081-A-FI XMTR 5 A 2 10-96 REV A QTY CHK A B C D 1400294 C D AMPEROMETRIC SENSOR FISCO CSA INTRINSIC SAFETY INSTALLATION 6 3 2 7 10 8 5 4 1 13 14 16 15 This document contains information proprietary to Rosemount Analytical, and is not to be made available to those who may compete with Rosemount Analytical. MODEL 5081-A SECTION 4.0 INTRINSICALLy SAFE & ExPLOSION PROOF INSTALLATIONS 25 A B C D 8 RECOMMENDED CABLE PN 9200273 (UNPREPPED) PN 23646-01 PREPPED 10 COND, 2 SHIELDS, 24 AWG. SEE NOTE 1 INFRARED RED REMOTE CONTROL UNIT (RMT PN 23572-00) FOR USE IN CLASS I AREA ONLY PH SENSOR WITH TC AMPEROMETRIC SENSOR +PH SENSOR AMPEROMETRIC SENSOR 7 PREAMP (NOTE 4) RECOMMENDED CABLE 4 WIRES SHIELDED 22 AWG, SEE NOTE 1 6 MODEL 5081-A-FI XMTR MODEL 5081-A-FI XMTR MODEL 5081-A-FI XMTR 5 5 12 4 NI CLASS I, DIV 2 GRPS A-D CLASS II, DIV 2 GRPS E-G IS CLASS I, GRPS A-D CLASS II, GRPS E-G CLASS III HAZARDOUS AREA 4 3 3 FIGURE 4-8. CSA Intrinsically-Safe Installation (2 of 2) TB14 5 7 10 CSA APPROVED PREAMP THAT MEETS REQUIREMENTS OF NOTE 2 PREAMP (NOTE 4) CSA APPROVED PREAMP THAT MEETS REQUIREMENTS OF NOTE 2 +PH SENSOR AMPEROMETRIC SENSOR +PH SENSOR MODEL 5081-A-FI XMTR 8 AMPEROMETRIC SENSOR 6 9 7 10 8 This document contains information proprietary to Rosemount Analytical, and is not to be made available to those who may compete with Rosemount Analytical. 4 3 2 1 4 3 2 1 4 3 2 1 13 14 5 4 3 2 1 6 6 6 6 5 5 5 7 7 7 7 8 8 8 9 9 9 10 10 10 16 15 13 14 11 11 11 11 12 12 12 16 15 13 14 16 15 13 26 14 2 SCALE TYPE 1400294 1 SHEET 2 OF UNSPECIFIED POWER SUPPLY 17.5 VDC MAX SAFETY BARRIER (SEE NOTE 8) NONE UNSPECIFIED POWER SUPPLY 17.5 VDC MAX SAFETY BARRIER (SEE NOTE 8) DWG NO. UNSPECIFIED POWER SUPPLY 17.5 VDC MAX SAFETY BARRIER (SEE NOTE 8) SIZE UNSPECIFIED POWER SUPPLY 17.5 VDC MAX 1 SAFETY BARRIER (SEE NOTE 8) D UNCLASSIFIED AREA 2 2 06-01 REV A A B C D 1400294 16 15 MODEL 5081-A SECTION 4.0 INTRINSICALLy SAFE & ExPLOSION PROOF INSTALLATIONS 1.30 ±.02 .650 ±.015 NO CHANGE WITHOUT BASEEFA APPROVAL. 2. LTR B FINISH MATERIAL 4 1 REVISION 5-6-04 ENG APVD J. FLOCK THIS FILE CREATED USING SOLID EDGE 5-6-04 CHECKED J. FLOCK 5-3-04 DATE DESCRIPTION B. JOHNSON APPROVALS SEE ECO DRAWN ECO LQD10245 DIMENSIONS ARE IN INCHES REMOVE BURRS & SHARP EDGES MACHINE FILLET RADII .020 MAX NOMINAL SURFACE FINISH: 125 ANGLES ± 1/2°. .XX ± .03 .XXX ± .010 4X R .25 .140 ±.005 2.180 ±.005 REV A FIGURE 4-9. BAS/ATEx Intrinsically-Safe Label 5081-A-FI MATERIAL: AISI 300 SERIES STAINLESS STEEL .015 ± .005 THICK. MATERIAL TO BE ANNEALED & PASSIVATED. MAXIMUM HARDNESS BRINELL 190. B2 NOTES: UNLESS OTHERWISE SPECIFIED ARTWORK IS SUPPLIED BY ROSEMOUNT ANALYTICAL. 3. 1 .125 O .125 ECO NO 8925 DIRECTION OF NATURAL GRAIN FINISH: SILKSCREEN BLACK EPOXY PAINT (BAKED). 2X FULL R 4 B1 2.56 ±.02 RELEASE DATE 5-6-04 B ANALYTICAL ROSEMOUNT REVISIONS NOT PERMITTED W/O AGENCY APPROVAL REV REV REV REV REV REV SCALE: 2:1 WEIGHT: SHEET 1 OF 1 LABEL, I.S. BAS/ATEX 5081-A-FI SIZE DWG NO REV B B 9241472-01 TITLE PROCESS MANAGEMENT Emerson Baseefa Certified Product No modifications permitted without the approval of the Authorized Person Related Drawing Baseefa THIS DOCUMENT IS CERTIFIED BY DATE CHECKED/APPROVED BY CH 3-21-11 JP/DOC B .120 ±.005 This document contains information proprietary to Rosemount Analytical, and is not to be made available to those who may compete with Rosemount Analytical. MODEL 5081-A SECTION 4.0 INTRINSICALLy SAFE & ExPLOSION PROOF INSTALLATIONS 9241472-01 27 A B 4 5 6 7 (La/Ra OR Lo/Ro) 8 NOTES: UNLESS OTHERWISE SPECIFIED 7 5 25 5.99 C D 4 RELEASE DATE ECO NO. 8933 REV B 17.5 IIC/ A,B,C,D,E,F,G 5081-A-FI 5-6-04 17.5 IIB/ C,D,E,F,G 5081-A-FI 360 380 .XX FINISH ANGLES TOLERANCES + 1/2 DIMENSIONS ARE IN INCHES 3 REMOVE BURRS & SHARP EDGES .020 MAX MACHINED FILLET RADII .020 MAX NOMINAL SURFACE FINISH 125 + .030 + .010 - MATERIAL .XXX 1 DATE ANY FM APPROVED ASSOCIATED APPARATUS BY CHK PART NO. DATE THIS DWG CREATED IN SOLID EDGE 2 5/6/04 PROJECT ENGR APVD J. FLOCK 5/6/04 CHECKED J. FLOCK 5/3/04 5 5 Ci (nF) DESCRIPTION Uniloc BILL OF MATERIAL REV REV REV REV REV REV D SIZE DWG NO. Rosemount Analytical, Uniloc Division 2400 Barranca Pkwy Irvine, CA 92606 1400292 TYPE B REVISIONS NOT PERMITTED W/O AGENCY APPROVAL FM THIS DOCUMENT IS CERTIFIED BY 1 SHEET 1 OF 2 SCHEMATIC, INSTALLATION 5081-A-FI XMTR FM APPROVALS TITLE 10 10 Li (uH) SCALE NONE 147 mW 105.64 mA 13.02 Vdc MODEL 5081-A-FI TB1-1 THRU 12 B. JOHNSON APPROVALS DRAWN ITEM 2.52 5.32 Pmax (W) Pt It Vt OUTPUT PARAMETERS DISCONNECT POWER BEFORE SERVICING. TABLE II 10-96 B REV QTY TO PREVENT IGNITION OF FLAMMABLE OR COMBUSTIBLE ATMOSPHERES, Imax (mA) UNLESS OTHERWISE SPECIFIED Vmax (Vdc) GROUPS MODEL NO. REVISION DESCRIPTION NON-HAZARDOUS LOCATIONS 2 ANY FM APPROVED TERMINATOR ECO SUBSTITUTION OF COMPONENTS MAY IMPAIR INTRINSIC SAFETY OR SUITABILITY FOR DIVISION 2. LTR 5081-A-FI FISCO PARAMETERS SUPPLY / SIGNAL TERMINALS TB 1-15, 16 TABLE III 3.1 12.3 0.96 21.69 A, B WARNINGGAS GROUPS TABLE I WARNING- ANY FM APPROVED TERMINATOR OUTPUT PARAMETERS Ca La (uF) (mH) ANY FM APPROVED INTRINSICALLY SAFE APPARATUS IS CLASS I, II, III, DIVISION 1, GROUPS A, B, C, D, E, F, G; NI CLASS I, DIVISION 2, GROUPS A,B,C,D; SUITABLE CLASS II, DIVISION 2, GROUPS F & G; SUITABLE CLASS III, DIVISION 2 HAZARDOUS (CLASSIFIED) LOCATIONS 3 FIGURE 4-10. FM Intrinsically-Safe Installation 5081-A-FI (1 of 2) 6 1. THE MODEL 5081-A-FI TRANSMITTER INCLUDES INTEGRAL PREAMPLIFIER CIRCUITRY. AN EXTERNAL PREAMPLIFIER MAY BE ALSO USED. THE OUTPUT PARAMETERS SPECIFIED IN TABLE II ARE VALID FOR EITHER PREAMPLIFIER. THE CAPACITANCE AND INDUCTANCE OF THE LOAD CONNECTED TO THE SENSOR TERMINALS MUST NOT EXCEED THE VALUES SPECIFIED IN TABLE I WHERE Ca Ci (SENSOR) + Ccable; La Li (SENSOR) + Lcable. 2. PREAMPLIFIER TYPE 23546-00, 23538-00 OR 23561-00 MAY BE UTILIZED INSTEAD OF THE MODEL 5081-A-FI TRANSMITTER INTEGRAL PREAMPLIFIER CIRCUIRTY. A WEATHER RESISTANT ENCLOSURE MUST HOUSE THE TYPE 23546-00 REMOTE PREAMPLIFIER. 3. INSTALLATION SHOULD BE IN ACCORDANCE WITH ANSI/ISA RP12.06 "INSTALLATION OF INTRINSICALLY SAFE SYSTEMS FOR HAZARDOUS (CLASSIFIED) LOCATIONS" (EXCEPT CHAPTER 5 FOR FISCO INSTALLATIONS) AND THE NATIONAL ELECTRICAL CODE (ANSI/NFPA 70) SECTIONS 504 AND 505. 4. SENSORS WITHOUT PREAMPS SHALL MEET THE REQUIREMENTS OF SIMPLE APPARATUS AS DEFINED IN ANSI/ISA RP12.6 AND THE NEC, ANSI/NFPA 70. THEY CAN NOT GENERATE NOR STORE MORE THAN 1.5V, 0.1A, 25mW OR A PASSIVE COMPONENT THAT DOES NOT DISSIPATE MORE THAN 1.3W. SEE TABLES I AND II. 5. DUST-TIGHT CONDUIT SEAL MUST BE USED WHEN INSTALLED IN CLASS II AND CLASS III ENVIRONMENTS. 6. RESISTANCE BETWEEN INTRINSICALLY SAFE GROUND AND EARTH GROUND MUST BE LESS THAN 1.0 Ohm. 7. THE ENTITY CONCEPT ALLOWS INTERCONNECTION OF INTRINSICALLY SAFE APPARATUS WITH ASSOCIATED APPARATUS WHEN THE FOLLOWING IS TRUE: FIELD DEVICE INPUT ASSOCIATED APPARATUS OUTPUT Vmax OR Ui Voc, Vt OR Uo; Imax OR Ii Isc, It OR Io; Pmax OR Pi Po; Ca, Ct OR Co 3Ci + 3Ccable; La, Lt OR Lo; OR Lc/Rc (La/Ra OR Lo/Ro) AND Li/Ri 3Li + 3Lcable. 8. ASSOCIATED APPARATUS MANUFACTURER'S INSTALLATION DRAWING MUST BE FOLLOWED WHEN INSTALLING THIS EQUIPMENT. 9. CONTROL EQUIPMENT CONNECTED TO ASSOCIATED APPARATUS MUST NOT USE OR GENERATE MORE THAN 250 Vrms OR Vdc. 10. THE CONFIGURATION OF ASSOCIATED APPARATUS MUST BE FACTORY MUTUAL APPROVED UNDER THE ASSOCIATED CONCEPT. 11. NO REVISION TO DRAWING WITHOUT PRIOR FACTORY MUTUAL RESEARCH APPROVAL. INFRARED RED REMOTE CONTROL UNIT (RMT PN 23572-00) FOR USE IN CLASS I AREA ONLY MODEL 5081-A-FI XMTR 9 4 A B C D 1400292 C D 8 3 2 SIMPLE APPARATUS SUCH AS: AMPEROMETRIC SENSOR 5 10 FISCO FM INTRINSIC SAFETY INSTALLATION 6 11 7 12 1 13 14 16 15 8 This document contains information proprietary to Rosemount Analytical, and is not to be made available to those who may compete with Rosemount Analytical. MODEL 5081-A SECTION 4.0 INTRINSICALLy SAFE & ExPLOSION PROOF INSTALLATIONS A B C D 8 RECOMMENDED CABLE PN 9200273 (UNPREPPED) PN 23646-01 PREPPED 10 COND, 2 SHIELDS, 24 AWG. SEE NOTE 1 INFRARED RED REMOTE CONTROL UNIT (RMT PN 23572-00) FOR USE IN CLASS I AREA ONLY PH SENSOR WITH TC MODEL 5081-A-FI XMTR MODEL 5081-A-FI XMTR MODEL 5081-A-FI XMTR 5 6 MODEL 5081-A-FI XMTR 5 5 3 4 ANY FM APPROVED INTRINSICALLY SAFE APPARATUS ANY FM APPROVED INTRINSICALLY SAFE APPARATUS ANY FM APPROVED INTRINSICALLY SAFE APPARATUS ANY FM APPROVED INTRINSICALLY SAFE APPARATUS IS CLASS I, II, III, DIVISION 1, GROUPS A, B, C, D, E, F, G; NI CLASS I, DIVISION 2, GROUPS A,B,C,D; SUITABLE CLASS II, DIVISION 2, GROUPS F & G; SUITABLE CLASS III, DIVISION 2 3 HAZARDOUS (CLASSIFIED) LOCATIONS 4 ANY FM APPROVED TERMINATOR ANY FM APPROVED TERMINATOR ANY FM APPROVED TERMINATOR ANY FM APPROVED TERMINATOR FIGURE 4-10. FM Intrinsically-Safe Installation 5081-A-FI (2 of 2) 6 TB14 5 7 10 FM APPROVED PREAMP THAT MEETS REQUIREMENTS OF NOTE 1 PREAMP (NOTE 2) RECOMMENDED CABLE 4 WIRES SHIELDED 22 AWG, SEE NOTE 1 SIMPLE APPARATUS SUCH AS: AMPEROMETRIC SENSOR +PH SENSOR SIMPLE APPARATUS SUCH AS: AMPEROMETRIC SENSOR 7 PREAMP (NOTE 2) FM APPROVED PREAMP THAT MEETS REQUIREMENTS OF NOTE 1 +PH SENSOR SIMPLE APPARATUS SUCH AS: AMPEROMETRIC SENSOR +PH SENSOR SIMPLE APPARATUS SUCH AS: AMPEROMETRIC SENSOR 6 9 7 8 8 10 3 2 This document contains information proprietary to Rosemount Analytical, and is not to be made available to those who may compete with Rosemount Analytical. 4 3 2 1 4 3 2 1 4 3 2 1 6 6 6 5 5 5 12 1 4 13 14 16 15 13 14 7 7 7 7 8 8 8 9 9 9 10 10 10 11 11 11 11 12 12 12 16 15 13 14 16 15 13 14 1 2 DWG NO. SCALE NONE SIZE D ANY FM APPROVED TERMINATOR ANY FM APPROVED TERMINATOR ANY FM APPROVED TERMINATOR ANY FM APPROVED TERMINATOR TYPE 1400292 1 SHEET 2 OF 2 ANY FM APPROVED ASSOCIATED APPARATUS ANY FM APPROVED ASSOCIATED APPARATUS ANY FM APPROVED ASSOCIATED APPARATUS ANY FM APPROVED ASSOCIATED APPARATUS NON-HAZARDOUS LOCATIONS 2 06-01 B REV A B C D 1400292 16 15 MODEL 5081-A SECTION 4.0 INTRINSICALLy SAFE & ExPLOSION PROOF INSTALLATIONS 29 30 MODEL 5081-A SECTION 5.0 DISPLAy AND OPERATION WITH INFRARED REMOTE CONTROLLER SECTION 5.0 DISPLAy AND OPERATION WITH INFRARED REMOTE CONTROLLER 5.1 5.2 5.3 5.4 5.5 5.6 Display Screens Infrared Remote Controller (IRC) - Key Functions Menu Tree Diagnostic Messages Security Using Hold 5.1 DISPLAy SCREENS Figure 5-1 shows the process display screen. Figure 5-2 shows the program display screen. Concentration of oxygen, ozone, or chlorine transmitter output signal in mA or % of full scale temperature in °C or °F FIGURE 5-1. Process Display Screen If the transmitter is configured to measure free chlorine, a second screen showing pH can be displayed by pressing the é or ê key on the remote controller. Concentration of oxygen, ozone, or chlorine Appears when a disabling condition has occurred (see Section 8.3.2) units of display (ppm, ppb, or %) F A u L t ppm H o L d Appears when transmitter is in hold (see Section 8.3.2) Active menu: CALIBRAtE, PRoGRAM, or dIAGNoSE CALIBRATE PRoGRAM dIAGNoSE CALIbrAtE Commands for submenus, prompts, or diagnostics ExIT NExT ENTER Submenus, prompts, and diagnostic measurements appear here FIGURE 5-2. Program Display Screen the program display screen allows access to calibration and programming menus. 31 MODEL 5081-A SECTION 5.0 DISPLAy AND OPERATION WITH INFRARED REMOTE CONTROLLER 5.2 INFRARED REMOTE CONTROLLER (IRC) - KEy FUNCTIONS the infrared remote controller is used to calibrate and program the transmitter and to display diagnostic messages. See Figure 5-3 for a description of the function of the keys. Hold the IRC within 6 feet of the transmitter, and not more than 15 degrees from the center of the display window. RESET - Press RESEt to end the current operation and return to the main display. Changes will Not be saved. RESET does NOT return the transmitter to factory default settings. ARROW KEyS - use é and ê keys to increase or decrease a number or to scroll through items in a list. use the ç or è keys to move the cursor across a number. A flashing word or numeral shows the position of the cursor. CAL - Press CAL to access the calibration menu. HOLD - Press HoLd to access the prompts used for turning on or off the hold function. ENTER - Press ENtER to move from a submenu to the first prompt under the submenu. Pressing ENtER also stores changes in memory and advances to the next prompt. NExT - Press NEXt to advance to the next submenu or to leave a message screen. ExIT - Press EXIt to end the current operation. Changes are Not saved. PROG - Press PRoG to access the program menu. DIAG - Press dIAG to read diagnostic messages. FIGURE 5-3. Infrared Remote Controller. 32 MODEL 5081-A SECTION 5.0 DISPLAy AND OPERATION WITH INFRARED REMOTE CONTROLLER 5.3 MENU TREE the Model 5081-A transmitter has three menus: CALIBRAtE, PRoGRAM, and dIAGNoSE. under the Calibrate and Program menus are several submenus. under each submenu are a number of prompts. the dIAGNoSE menu shows the reader diagnostic variables that are useful in troubleshooting. Figure 5-4, on the following page, shows the complete menu tree. 5.4 DIAGNOSTIC MESSAGES Whenever a warning or fault limit has been exceeded, the transmitter displays diagnostic fault messages. the display alternates between the main display and the diagnostic message. See Section 15.0 for the meaning of fault and warning messages. 5.5 SECURITy 5.5.1 Purpose. use the security code to prevent program settings and calibrations from accidentally being changed. to program a security code, refer to Section 7.5. PRoGRAM Id EXIt 000 ENtER 1. If settings are protected with a security code, pressing PRoG or CAL on the remote controller causes the Id screen to appear. 2. use the arrow keys to enter the security code. Press ENtER. 3. If the security code is correct, the first submenu appears. If the code is incorrect, the process display reappears. 4. to retrieve a forgotten code number, enter 555 at the Id prompt. the present security code will appear. 5.5.2 Change security code using Fieldbus. Access: deltaV Explorer/transducer Block/Properties Identification tab Parameter: Security Code for Infrared Remote (LoCAL_oPERAtoR_INtERFACE_tAG) Enter desired security code (0 - 999) 5.6 USING HOLD during calibration, the sensor may be exposed to solutions having concentration outside the normal range of the process. to prevent false alarms and undesired operation of chemical dosing pumps, place the transmitter in hold during calibration. Activating hold keeps the transmitter output at the last value or sends the output to a previously determined value. See Section 7.3, output Ranging, for details. After calibration, reinstall the sensor in the process stream. Wait until readings have stabilized before deactivating Hold. to activate or deactivate Hold: 1. Press HoLd on the remote controller. 2. the HoLd prompt appears in the display. Press é or ê to toggle Hold between On and OFF. 3. Press ENtER to save. 33 34 tman type C Cur 000 temp Output Code sensor stnd Unit ppm if Cl (free & total) if o3 -- dIsplay Unit ppm if o2 25 .0 taUto On temp Cal . 100 10 . 005 delta All stabilise span Cal Cal setup time Grab spl press 760 (All) 025 .0 temp adj temp In process sensor Cal air cal (o2 only) sensor 0 CALIBRATE . 401 PRoMPt SUBMENU MENU std 00 .0 if o2 Line 60 060 GFL GFH 0100 1500 ImptC On diaG OFF roffst Enter diaGnostIC Pamp trans if on PH 59.16 pH slope 07 .00 slope std pH (free chlorine only) Line freq . 700 Salnty bf2 00 .05 SlOpe snGl . 700 Cal bf2 bf1 Cal bf1 Man Cal if chlorine limit 0 Cal bf2 10 .00 Cal bf2 bf1 Cal bf1 auto Cal ph Cal . 700 if off pman dELtA . 002 010 StAbiLiSE bUFFEr Std 760 Unit nnHG baUtO On tIME faUlts 5081-a-Ht bar press 0 Current sensitvty sensor Cur type 02 DIAGNOSE bar press pH Cal Next Man -- PROGRAM MAIN DISPLAy MODEL 5081-A SECTION 5.0 DISPLAy AND OPERATION WITH INFRARED REMOTE CONTROLLER FIGURE 5-4. Menu Tree MODEL 5081-A SECTION 6.0 OPERATION WITH FOUNDATION FIELDBUS AND THE DELTAv CONTROL SySTEM SECTION 6.0 Operation with FOUNDATION Fieldbus and the Deltav Control System 6.1 OvERvIEW this section covers basic transmitter operation and software functionality. For detailed descriptions of the function blocks common to all Fieldbus devices, refer to Fisher-Rosemount Fieldbus FouNdAtIoN Function Blocks manual, publication number 00809-4783. Figure 6-1 illustrates how the conductivity signal is channeled through the transmitter to the control room and the FouNdAtIoN Fieldbus configuration device. Software Functionality. the Model 5081-A software is designed to permit remote testing and configuration of the transmitter using the Fisher-Rosemount deltaV Control System, or other FouNdAtIoN fieldbus compliant host. Transducer Block. the transducer block contains the actual measurement data. It includes information about sensor type, engineering units, reranging, damping, temperature compensation, calibration, and diagnostics. Resource Block. the resource Block contains physical device information, including available memory, manufacturer identification, type of device, and features. FOUNDATION Fieldbus Function Blocks. the Model 5081-A includes four Analog Input (AI) function blocks and one PId Block as part of its standard offering. Analog Input. the Analog Input (AI) block processes the measurement and makes it available to other function blocks. It also allows filtering, setting alarms, and changing engineering units. PID Block. the PId Block receives a measurement from an AI block, performs PId control action, and makes the control signal available to an Analog output (Ao) block. FIGURE 6-1. Functional Block Diagram for the Model 5081-A Transmitter with FOUNDATION Fieldbus 35 MODEL 5081-A SECTION 6.0 OPERATION WITH FOUNDATION FIELDBUS AND THE DELTAv CONTROL SySTEM 6.2 AI Block Configuration the 5081A-FF has channels assignable to the measured value (oxygen, ozone, or chlorine), temperature, sensor current, and pH (free chlorine only). For proper operation, the AI Block must be assigned to the channel corresponding to the desired measurement, and the units in the Xd_SCALE parameter of the AI Block must match the units of the measurement. table 6-1, below, shows the channel assignments and units for each mode of the 5081A-FF. TABLE 6-1. Analog Input Block Configuration values 36 MODEL 5081-A SECTION 6.0 OPERATION WITH FOUNDATION FIELDBUS AND THE DELTAv CONTROL SySTEM 6.3 Transducer Block Operations — Configuration and Calibration 6.3.1 Deltav Explorer Transducer Block Interface 1. Context Menu the deltaV Explorer exposes methods for changing the process variable, zeroing and standardizing the sensors, calibrating oxygen sensors in air, standardizing the temperature measurement, and standardizing and buffer calibrating the pH sensor (free chlorine only). 2. transducer Block Properties the transducer Block Properties Windows allow full configuration of the 5081A-FF. the transducer Block must be put in the out of Service Mode (ooS) to allow configuration parameters to be changed. the following parameters are exposed on each tab: • Mode Tab: Allows the transducer Block to be switched between the Auto and out of Service Modes. • Measurement Tab: Shows all of the 5081A-FF live measurements and their status. • Amperometric Sensor Tab: Contains all of the configuration and calibration parameters for the oxygen, chlorine, or ozone sensor. • Temperature Compensation Tab: Contains all of the configuration parameters for temperature compensation and the temperature measurement. • Identification Tab: Contains serial and revision numbers and the passcode for the infrared remote controller. • pH Compensation (free chlorine only): Contains all of the configuration, calibration, and diagnostic parameters for the pH sensor. 37 MODEL 5081-A SECTION 6.0 OPERATION WITH FOUNDATION FIELDBUS AND THE DELTAv CONTROL SySTEM 3. transducer Block Status the transducer Block Status Windows show all of the diagnostic faults, warnings, and errors. the meaning of these diagnostic messages and troubleshooting procedures for them can be found in the troubleshooting section of this manual. In addition to current diagnostic messages, the transducer Block Status Windows also show the last three fault conditions: fault_history_0, fault_history_1, and fault_history_2, respectively. 6.4 Model 5081-A-FF — Device Summary Manufacturer: Rosemount Analytical (524149) Device Type: 4083 Device Revision: 1 Function Blocks: Four (4) AI Blocks, one (1) PId Block Link Active Scheduler: Yes ITK version: 6.0 Channels: 1 — Measurement (oxygen, chlorine, or ozone) 2 — temperature 3 — Sensor Current 4 — pH Measurement (Free Chlorine Mode only) NOTE In the sections of this manual describing operation with deltaV, oxygen, chlorine, and ozone measurements are referred to collectively as amperometric measurements. the sensors are called amperometric sensors. 38 MODEL 5081-A SECTION 6.0 OPERATION WITH FOUNDATION FIELDBUS AND THE DELTAv CONTROL SySTEM TABLE 6-2. Model 5081-A-FF Parameters and Methods Table 6-2 continued on following page. 39 MODEL 5081-A SECTION 6.0 OPERATION WITH FOUNDATION FIELDBUS AND THE DELTAv CONTROL SySTEM TABLE 6-2. Model 5081-A-FF Parameters and Methods (continued) Table 6-2 continued on following page. 40 MODEL 5081-A SECTION 6.0 OPERATION WITH FOUNDATION FIELDBUS AND THE DELTAv CONTROL SySTEM TABLE 6-2. Model 5081-A-FF Parameters and Methods (continued) 41 MODEL 5081-A SECTION 7.0 PROGRAMMING SECTION 7.0 PROGRAMMING 7.1 7.2 7.3 7.4 7.5 7.6 7.7 7.8 General Default Settings Temperature Settings Display Calibration Setup Line Frequency pH Measurement Barometric Pressure 7.1 GENERAL this section describes how to do the following: 1. enable and disable automatic temperature correction 2. program the type measurement (oxygen, ozone, or chlorine) 3. setup stabilization criteria for calibration 4. enable automatic pH correction for chlorine measurements 5. choose units for barometric pressure (oxygen only) 6. choose limits for diagnostic fault messages Each section contains definitions of terms used, programming instructions using the infrared remote controller, and programming instructions using deltaV. 7.2 DEFAULT SETTINGS table 7-1 lists the default settings for the 5081-A transmitter. the transmitter is configured at the factory to measure oxygen. IMPORTANT Before changing any default settings, configure the transmitter for the measurement you want to make: oxygen, free chlorine, total chlorine, or ozone. Changing the measurement ALWAyS returns the transmitter to factory default settings. 42 MODEL 5081-A SECTION 7.0 PROGRAMMING TABLE 7-1. Default Settings ITEM tEMP tAUtO tMAn CHOICES DEFAULT on or off -25.0 to 150°C on 25°C Display type of measurement units (oxygen only) units (ozone only) Sensor (oxygen only) temperature units output current units Security code dISPLAy tyPE Unit Unit SEnSor tEMP OutPut CodE oxygen, ozone, free chlorine, total chlorine ppm, ppb, or % ppm or ppb 499Ado, 499Atrdo, Hx438 or Gx338, other biopharm °C or °F mA or % of full scale 000 to 999 oxygen ppm ppm 499Ado °C mA 000 C. Calibration Setup 1. Stabilization criteria a. time b. change if oxygen (ppm or ppb) if oxygen (%) if ozone if chlorine 2. Salinity (oxygen only) 3. Slope (chlorine only) 4. Maximum zero limit a. if oxygen (ppm) b. if oxygen (ppb) c. if oxygen (%) d. if ozone e. if chlorine CAL SEtUP StAbiLiSE tiME dELtA 00 to 99 sec 10 sec 0.01 to 9.99 ppm 1 to 100 % 0.01 to 9.99 ppm 0.01 to 9.99 ppm 0.0 to 36.0 single or dual 0.05 ppm 1% 0.01 ppm 0.05 ppm 0.0 single 00.00 to 10.00 ppm 000.0 to 999.9 ppb 000.0 to 999.9 % 00.00 to 10.00 ppm 00.00 to 10.00 ppm 0.05 ppm 2.0 ppb 1% 0.01 ppm 0.05 ppm A. Temperature compensation 1. Automatic 2. Manual B. 1. 2. 3. 4. 5. 6. 7. MNEMONIC SALnty SLOPE LiMit D. Line Frequency LinE FrEq 50 or 60 Hz 60 Hz E. 1. 2. 3. 4. HArt AddrESS PrEAMb bUrSt Id 00 to 15 05 to 20 on or off 0000000 to 9999999 00 05 off 0000000 pH MAn PAMP dIAgnOStIC rOFFSEt diAG IMPtC on or off 0.00 to 14.00 transmitter or sensor on 7.00 transmitter 0 to 999 on or off on or off 60 off on GFH GFL PH CAL bAUtO buFFEr StAbiLiSE tiME dELtA 0 to 2000 MW 0 to 900 MW 1000 MW 10 MW on or off see table in Section 13.1 standard 0 to 99 sec 0.02 to 0.50 10 sec 0.02 mm hg, kPa, atm, bar, in Hg 0 to 9999 mm Hg 760 mm Hg HART Address Preamble Burst Id F. 1. 2. 3. 4. pH Settings (free chlorine only) Automatic pH correction Manual pH correction Location of preamplifier pH sensor diagnostics a. reference offset b. diagnostics (1) glass impedance temperature correction (2) glass impedance high (3) glass impedance low 5. Calibration settings a. automatic buffer calibration b. buffer selection list c. stabilization criteria (1) time (2) change G. Pressure settings (oxygen only) a. units b. pressure for % sat calculations BAr PrESS Unit % SAt P 43 MODEL 5081-A SECTION 7.0 PROGRAMMING 7.3 TEMPERATURE SETTINGS 7.3.1 Purpose this section describes how to do the following: 1. Enable and disable automatic temperature compensation 2. Set a manual temperature compensation value for oxygen, chlorine, ozone, and pH measurements 3. tell the transmitter the type of temperature element in the sensor 7.3.2 Definitions 1. AutoMAtIC tEMPERAtuRE CoMPENSAtIoN - oXYGEN, CHLoRINE, ANd oZoNE. the oxygen, chlorine, and ozone sensors used with the 5081-A transmitter are membrane-covered amperometric sensors. the permeability of the membrane, or the ease with which the analyte passes through the membrane, is a function of temperature. As temperature increases, permeability increases, and the analyte diffuses more readily through the membrane. Because sensor current depends on diffusion rate, a temperature increase will cause the sensor current and transmitter reading to increase even though the concentration of analyte remained constant. A correction equation in the software automatically corrects for changes in membrane permeability caused by temperature. temperature is also used in the pH correction applied to free chlorine readings and in automatic air calibration of oxygen sensors. In automatic temperature correction, the transmitter uses the temperature measured by the sensor for all calculations in which temperature is used. 2. MANuAL tEMPERAtuRE CoMPENSAtIoN - oXYGEN, CHLoRINE, ANd oZoNE. In manual temperature compensation, the transmitter uses the temperature entered by the user for membrane permeability and pH corrections and for air calibration calculations. It does not use the actual process temperature. do NOT use manual temperature correction unless the measurement and calibration temperatures differ by no more than about 2°C. Manual temperature correction is useful if the sensor temperature element has failed and a replacement sensor is not available. 3. AutoMAtIC tEMPERAtuRE CoMPENSAtIoN - pH. the transmitter uses a temperature-dependent factor to convert measured cell voltage to pH. In automatic temperature compensation the transmitter measures the temperature and automatically calculates the correct conversion factor. temperature is also used in automatic buffer calibration. For maximum accuracy, use automatic temperature correction. 4. MANuAL tEMPERAtuRE CoMPENSAtIoN - pH. In manual temperature compensation, the transmitter converts measured voltage to pH using the temperature entered by the user. It does not use the actual process temperature. do Not use manual temperature compensation unless the process temperature varies no more than about 2°C or the pH is between 6 and 8. Manual temperature compensation is useful if the sensor temperature element has failed and a replacement sensor is not available. 44 MODEL 5081-A SECTION 7.0 PROGRAMMING 7.3.3 Procedure using the infrared remote controller 1. Press PRoG on the remote controller. PRoGRAM tEMP EXIt 2. Press NEXt until the tEMP submenu appears. Press ENtER. NEXt ENtER PRoGRAM tAUtO EXIt ON ENtER PRoGRAM tMAn EXIt 025 .0 ENtER 3. the screen displays the tAUtO (automatic temperature compensation) prompt. Press é or ê to toggle between On and OFF. Press ENtER to save. 4. If you disable tAuto, the tMAN prompt appears. use the arrow keys to change the temperature to the desired value. to enter a negative number, press è or ç until no digit is flashing. then press é or ê to display the negative sign. The temperature entered in this step will be used in all measurements (oxygen, chlorine, ozone, or pH), no matter what the process temperature is. Press ENtER to save. 5. Press RESEt to return to the process display. 7.3.4 Procedure using Deltav Access: deltaV Explorer/transducer Block/Properties/temperature Compensation 1. Parameter: Auto/Manual Selection (SENSoR_tEMP_CoMP) Select automatic or manual temperature compensation 2. If manual temperature compensation was chosen: Parameter: Manual temperature (SENSoR_tEMP_MAN_VALuE) Enter temperature value to be used with manual temperature compensation. 45 MODEL 5081-A SECTION 7.0 PROGRAMMING 7.4 DISPLAy 7.4.1 Purpose this section describes how to do the following: 1. Configure the transmitter to measure oxygen, free chlorine, total chlorine, or ozone 2. Choose concentration units 3. Set the temperature units to °C or °F 4. Set the output to current or percent of full scale 5. Enter a security code. 7.4.2 Definitions 1. MEASuREMENt. the transmitter can be configured to measure dissolved oxygen (ppm and ppb level), free chlorine, total chlorine, or ozone. 2. FREE CHLoRINE. Free chlorine is the product of adding sodium hypochlorite (bleach), calcium hypochlorite (bleaching powder), or chlorine gas to fresh water. Free chlorine is the sum of hypochlorous acid (HoCl) and hypochlorite ion (oCl-) 3. totAL CHLoRINE. total chlorine is the sum of free and combined chlorine. Combined chlorine generally refers to chlorine oxidants in which chlorine is combined with ammonia or organic amines. Monochloramine, used to disinfect drinking water, is an example of combined chlorine. the term total chlorine also refers to other chlorine oxidants such as chlorine dioxide. to measure total chlorine, the sample must first be treated with a mixture of acetic acid and potassium iodide. total chlorine reacts with iodide to produce an equivalent amount of iodine, which the sensor measures. 4. outPut CuRRENt. the transmitter generates a 4-20 mA output signal directly proportional to the concentration of oxygen, chlorine, or ozone in the sample. the output signal can be displayed as current (in mA) or as percent of full scale. 5. SECuRItY CodE. the security code unlocks the transmitter and allows access to all menus. 7.4.3 Procedure using the infrared remote controller PRoGRAM 1. Press PRoG on the remote controller. dISPLAY EXIt NEXt ENtER PRoGRAM tYPE EXIt 3. Press é or ê to display the desired measurement. Press ENtER to save. 02 ENtER PRoGRAM Unit EXIt PPb ENtER PRoGRAM sensor Sd01 EXIt 2. Press NEXt until the diSPLAy submenu appears. Press ENtER. ENtER O2 CLrA tCL FCL O3 dissolved oxygen (go to step 4) Monochloramine total chlorine Free chlorine ozone (go to step 7) Although monochloramine is a choice, a monochloramine sensor is NOT currently available from Rosemount Analytical. 4. If you chose O2 in step 3, the screen at left appears. Press é or ê to display the desired units: ppm, ppb, or %. Press ENtER to save. Also, refer to step 6 for recommended settings to make for different types of sensors. 5. the screen at left appears. Press é or ê to display the type of sensor. Press ENtER to save. AdO trdO SdO1 SdO2 499Ado 499Atrdo Hx438 or Gx448 steam-sterilizable sensor Steam-sterilizable sensor from other manufacturer Refer to step 6 for recommended sensor/unit combinations. 46 Procedure continued on following page. MODEL 5081-A SECTION 7.0 PROGRAMMING 6. For best results make the following settings based on the sensor being used. Sensor 499Ado 499Atrdo Gx448 Hx438 Units ppm or % ppb ppm or % ppm or % PRoGRAM Unit 7. If you chose O3 in step 3, the screen at left appears. Press é or ê to toggle between ppm and ppb. Press ENtER to save. PPb ENtER EXIt 8. Press RESEt to return to the main display. 7.4.4 Procedure using Deltav 1. Access: deltaV Explorer/Context menu Change Process Variable type (method_change_pv_type). Select desired measurement (PV) Although monochloramine is a choice, a monochloramine sensor is NOT currently available from Rosemount Analytical. 2. If you chose o2, select a sensor from the following table: AdO trdO SdO1 SdO2 499Ado 499Atrdo Hx438 or Gx448 steam-sterilizable sensor Steam-sterilizable sensor from other manufacturer Access: deltaV Explorer/transducer Block/Properties, Amperometric Sensor tab Parameter: oxygen Sensor type (SENSoR_tYPE_oXYGEN) Select desired sensor 3. on the Amperometric Sensor tab Parameter: Primary Value unit (PRIMARY_VALuE_uNIt) Select the desired units. For best results, make the following settings based on the sensor used: Sensor 499Ado 499Atrdo Gx448 Hx438 Units ppm or % ppb ppm or % ppm or % 47 MODEL 5081-A SECTION 7.0 PROGRAMMING 7.5 CALIBRATION SETUP 7.5.1 Purpose this section describes how to do the following: 1. Enter stabilization criteria for calibration 2. Enter an upper limit for sensor zero 3. Enter a salinity value for air calibration of dissolved oxygen sensors 4. Enable dual slope calibration for free and total chlorine sensors. 7.5.2 Definitions 1. StABILIZAtIoN CRItERIoN. the transmitter can be programmed not to accept calibration data until the reading has remained within a specified concentration range for a specified period of time. For example, a stability criterion of 0.05 ppm for 10 seconds means that calibration data will not be accepted until the reading changes less than 0.05 ppm over a 10-second period. the transmitter calculates the concentration using the present calibration data, or in the case of a first time calibration, the default sensitivity. 2. SENSoR ZERo LIMIt. Even in the complete absence of the substance being determined, all amperometric sensors generate a small current called the zero or residual current. the transmitter compensates for the residual current by subtracting it from the measured current before converting the result to a concentration value. the zero current varies from sensor to sensor. the transmitter can be programmed not to accept a zero current until the value has fallen below a reasonable limit. 3. SALINItY (dISSoLVEd oXYGEN oNLY). the solubility of oxygen in water depends on the concentration of dissolved salts in the water. Increasing the concentration decreases the solubility. If the salt concentration is greater than about 1000 ppm, the accuracy of the measurement can be improved by applying a salinity correction. Enter the salinity as parts per thousand (‰). one percent is ten part per thousand. 4. duAL SLoPE CALIBRAtIoN (FREE ANd totAL CHLoRINE oNLY). Free and total chlorine sensors from Rosemount Analytical (Model 499ACL-01 and 499ACL-02) become non-linear at high concentrations of chlorine. dual slope calibration allows the analyzer to correct for the non-linearity of the sensor. For more information see Section 10.4 or 11.4. 7.5.3 Procedure using the infrared remote controller 1. Press PRoG on the remote controller. PRoGRAM 2. Press NEXt until the CAL SEtUP submenu appears. Press ENtER. Cal setUp EXIt NEXt ENtER PRoGRAM span Cal EXIt NEXt ENtER PRoGRAM 3. the screen displays the SPAn CAL prompt. to set the stabilization criteria, press ENtER. 4. the screen displays the StABiLiSE prompt. Press ENtER. stabilise EXIt NEXt ENtER 5. Set the stabilization time between 0 and 99 seconds. the default value is 10 seconds. Press ENtER to save. PRoGRAM tIME EXIt 10 ENtER Procedure continued on following page. 48 MODEL 5081-A SECTION 7.0 PROGRAMMING PRoGRAM delta 0 . 05 EXIt ENtER PRoGRAM Stabilise EXIt NEXt ENtER PRoGRAM slope SngL EXIt ENtER PRoGRAM salnty 0. 0 0 EXIt 6. Set the stabilization range to between 0.01 and 9.99 ppm. the default values are shown in the table. Press ENtER to save. oxygen Free chlorine total chlorine ozone 0.05 0.05 0.05 0.01 ppm or 1% ppm ppm ppm 7. the display returns to the StABiLiSE prompt. Press NEXt. the next screen depends on the measurement being made. For free or total chlorine see step 8. For oxygen, see step 9. For ozone see step 10. 8. If the measurement is free or total chlorine, the SLOPE prompt appears. use é or ê to toggle between SnGL (single) or duAL (dual) slope. Press ENtER. Go to step 10. NOTE For the vast majority of applications, single slope calibration is acceptable. Dual slope calibration is useful in fewer than 5 % of applications. 9. If the measurement is oxygen, the SALnty (salinity) prompt appears. use the arrow keys to enter the salinity of the water. Press ENtER. Go to step 10. ENtER 10. the display returns to the SPAn CAL screen. Press NEXt. PRoGRAM span Cal EXIt NEXt ENtER 11. the 0 CAL screen appears. Press ENtER. PRoGRAM 0 Cal EXIt NEXt ENtER PRoGRAM limit EXIt 00 . 00 ENtER 12. Enter the desired zero limit. the units are the same as the units programmed in Section 7.5. default limits are given in the table. oxygen (ppm) oxygen (ppb) oxygen (% saturation) Free chlorine total chlorine ozone 0.05 ppm 2.0 ppb 1% 0.05 ppm 0.05 ppm 0.01 ppm or 10 ppb 13. Press RESEt to return to the main display. 49 MODEL 5081-A SECTION 7.0 PROGRAMMING 7.5.4 Procedure using Deltav Access: deltaV Explorer/transducer Block/Properties, Amperometric Sensor tab 1. Parameter: Amperometric Stabilize time (AMP_SPAN_StABILIZE_tIME) Set the stabilization time between 0 and 99 seconds. the default value is 10 seconds. 2. Parameter: Amperometric Stabilize Value (AMP_SPAN_StABILIZE_VALuE) Set the stabilization range to between 0.01 and 9.99 ppm. the default values are shown in the table: oxygen Free chlorine total chlorine ozone 0.05 0.05 0.05 0.01 ppm or 1% ppm ppm ppm 3. Parameter: Salinity (SALINItY). Enter the salinity of the water. 4. Parameter: Zero Limit (AMP_ZERo_StABILIZE_VALuE) Enter the desired zero limit. default limits are given in the table: oxygen (ppm) oxygen (ppb) oxygen (% saturation) Free chlorine total chlorine ozone 50 0.05 ppm 2.0 ppb 1% 0.05 ppm 0.05 ppm 0.01 ppm or 10 ppb MODEL 5081-A SECTION 7.0 PROGRAMMING 7.6 LINE FREQUENCy 7.6.1 Purpose this section describes how to maximize noise rejection by entering the frequency of the mains power into the transmitter. 7.6.2 Procedure using the infrared remote controller. 1. Press PRoG on the remote controller. PRoGRAM 2. Press NEXt until the LinE FrEq submenu appears. Press ENtER. line fre9 EXIt NEXt ENtER 3. use é or ê to toggle the line frequency between 50 and 60 Hz. Press ENtER to save. PRoGRAM line EXIt 60 ENtER 4. Press RESEt to return to the main display. 51 MODEL 5081-A SECTION 7.0 PROGRAMMING 7.7 pH MEASUREMENT NOTE The pH measurement submenu appears only if the transmitter has been configured to measure free chlorine. pH is not available with any other measurement. 7.7.1 Purpose this section describes how to do the following: 1. Enable and disable automatic pH correction for free chlorine measurements 2. Set a pH value for manual pH correction 3. Enable and disable pH sensor diagnostics 4. Set upper and lower limits for glass impedance diagnostics 5. Enable and disable automatic pH calibration 6. Set stability criteria for automatic pH buffer calibration. 7.7.2 Definitions 1. AutoMAtIC pH CoRRECtIoN. Free chlorine is the sum of hypochlorous acid (HoCl) and hypochlorite ion (oCl-). the relative amount of each depends on pH. As pH increases, the concentration of HoCl decreases and the concentration of oCl- increases. Because the sensor responds only to HoCl, a pH correction is necessary to properly convert the sensor current into a free chlorine reading. the transmitter uses both automatic and manual pH correction. In automatic pH correction the transmitter continuously monitors the pH of the sample and corrects the free chlorine reading for changes in pH. In manual pH correction, the user enters the pH of the sample. Generally, if the pH changes more than about 0.2 units over short periods of time, automatic pH correction is best. If the pH is relatively steady or subject only to seasonal changes, manual pH correction is adequate. 2. REFERENCE oFFSEt. the transmitter reading can be changed to match the reading of a second pH meter. If the difference (converted to millivolts) between the transmitter reading and the desired value exceeds the programmed limit, the transmitter will not accept the new reading. to estimate the millivolt difference, multiply the pH difference by 60. 3. pH SENSoR dIAGNoStICS. the transmitter continuously monitors the pH sensor for faults. A fault means that the sensor has failed or is possibly nearing failure. the only pH sensor diagnostic available in the 5081-A is glass impedance. 4. GLASS IMPEdANCE. the transmitter monitors the condition of the pH-sensitive glass membrane in the sensor by continuously measuring the impedance across the membrane. typical impedance is 100 to 500 MW. A low impedance (<10 MW) means the glass membrane has cracked and the sensor must be replaced. An extremely high impedance (>1000MW) implies that the sensor is aging and may soon need replacement. High impedance might also mean that the glass membrane is no longer immersed in the process liquid. 5. AutoMAtIC pH CALIBRAtIoN. the transmitter features both automatic and manual pH calibration. In automatic calibration, screen prompts direct the user through a two-point buffer calibration. the transmitter recognizes the buffers and uses temperature-corrected values in the calibration. the table in Section 13.1 lists the standard buffers the transmitter recognizes. the transmitter also recognizes several technical buffers: Merck, Ingold, and dIN 19267. during automatic calibration, the transmitter does not accept data until programmed stability limits have been met. 6. MANuAL pH CALIBRAtIoN. If automatic pH calibration is deactivated, the user must perform a manual calibration. In manual calibration the user judges when readings are stable and manually enters the buffer values. Because manual calibration greatly increases the chance of making an error, the use of automatic calibration is strongly recommended. 52 52 MODEL 5081-A SECTION 7.0 PROGRAMMING 7.7.3 Procedure using the infrared remote controller 1. Press PRoG on the remote controller. PRoGRAM pH EXIt On NEXt ENtER 2. Press NEXt until the PH submenu appears. On will be flashing, indicating that the pH measurement and automatic pH correction of free chlorine has been enabled. to keep automatic pH correction enabled, press ENtER. Go to step 3. to disable automatic pH correction, use é or ê to change On to OFF and press ENtER. the MAn prompt appears. use the arrow keys to enter the pH of the sample. Press ENtER to save. Press RESEt to return to the main display. PRoGRAM pamp = trans EXIt NEXt ENtER 3. the screen displays the PAMP (preamplifier) prompt. Press é or ê to toggle between trAnS and SnSr. trAnS Preamplifier is in the transmitter SnSr Preamplifier is in the sensor or in a remote junction box Press ENtER to save. PRoGRAM dIagnostIC EXIt NEXt ENtER 4. the screen displays the dIAgnOStIC submenu header. Prompts under this header allow the user to change the reference offset and pH sensor diagnostic limits. the default settings are: reference offset 60 mV pH sensor diagnostics off to keep the default settings, press NEXt. Go to step 11. to change the reference offset or to enable or make changes to the glass diagnostic settings, press ENtER. Go to step 5. PRoGRAM rOffset 060 EXIt ENtER PRoGRAM dIag EXIt Off EXIt On ENtER PRoGRAM GfH EXIt 6. the dIAg (diagnostics) prompt appears. Press é or ê to toggle between OFF (disable) or On (enable). Press ENtER to save. ENtER PRoGRAM ImptC 5. the rOFFSEt (reference offset) prompt appears. use the arrow keys to change the offset to the desired value in mV. Press ENtER to save. 1000 ENtER 7. the IMPtC (glass impedance temperature correction) prompt appears. Press é or ê to toggle between OFF (disable) or On (enable). Because glass impedance is a strong function of temperature, correcting glass impedance for temperature effects is strongly recommended. Press ENtER to save. 8. the GFH (glass fault high) prompt appears. use the arrow keys to change the setting to the desired value. the default setting is 1000 MW. Entering 0000 disables the feature. Press ENtER to save. When the glass electrode impedance exceeds the limit, the transmitter displays the GLASSFAIL diagnostic message and sets a fault condition. PRoGRAM GfL EXIt 0010 ENtER 9. the GFL (glass fault low) prompt appears. use the arrow keys to change the setting to the desired value. the default setting is 10 MW. Entering 0000 disables the feature. Press ENtER to save. When the glass electrode impedance falls below the limit, the transmitter displays the GLASSFAIL diagnostic message and sets a fault condition. 53 MODEL 5081-A SECTION 7.0 PROGRAMMING PRoGRAM dIagnostIC NEXt EXIt ENtER PRoGRAM PH Cal NEXt EXIt ENtER 10. once diagnostic limits have been set, the display returns to the dIAgnOStIC submenu header. Press NEXt. 11. the PH CAL submenu header appears. Prompts under this header allow the user to enable or disable automatic buffer calibration, select the buffers to be used, and set stabilization criteria for pH calibration. the default settings are: Automatic buffer calibration Buffers Stabilization on Standard (see Section 7.8.2) <0.02 pH in 10 seconds to make changes to the pH calibration parameters, press ENtER. Go to step 12. to leave settings at their default values press EXIt to leave the submenu. PRoGRAM baUtO On EXIt ENtER 12. the bAUtO (automatic buffer calibration) prompt appears. Press é or ê to toggle between OFF (disable) or On (enable). Press ENtER to save. Keeping automatic buffer calibration enabled is strongly recommended. PRoGRAM buffer Std EXIt ENtER 13. the buFFEr prompt appears. Press é or ê to scroll through the list of available buffers. See Section 13.1 for a list of the buffer values. Std ErC InG din Standard buffers Merck buffers Ingold buffers dIN 19267 buffers Press ENtER to save. PRoGRAM stabilise EXIt ENtER 14. the StAbiLiSE (stabilize) prompt appears. to change stabilization criteria, press ENtER. to leave stabilization criteria at the default values, press EXIt. PRoGRAM time EXIt 1 .0 ENtER PRoGRAM delta EXIt 16. Set the stabilization range to between 0.02 and 0.50 pH. Press ENtER to save. 0 . 02 ENtER 54 15. Set the stabilization time between 0 and 99 seconds. the default value is 10 seconds. Press ENtER to save. 17. Press RESEt to return to the main display. MODEL 5081-A SECTION 7.0 PROGRAMMING 7.7.4 Procedure using Deltav Access: deltaV Explorer/transducer Block/Properties, pH Compensation tab 1. pH Compensation (Auto/Manual) and Preamp Location Parameter: pH Compensation/Preamp Location (PH_CoMPENSAtIoN_ModE) Select the pH compensation mode and preamp location from the following table: Description value Digital Equivalent Automatic pH Compensation with Preamp in transmitter Auto, Int. 0 Manual pH Compensation with Preamp in transmitter Man, Int. 1 Automatic pH Compensation with Sensor Preamp Auto, Sensor 2 Manual pH Compensation with Sensor Preamp Man, Sensor 3 2. If manual pH compensation was chosen, Parameter: Manual pH Value (MANuAL_PH_VALuE) Enter the desired manual pH value. 3. to enable/disable impedance diagnostic: Parameter: Impedance diagnostics (ENABLE_dIAGNoStIC_FAuLt_SEtPoINt) Enter the desired value. 4. Enter the high glass impedance fault limit. the default is 1000 MW. Parameter: Glass Fault High Setpoint (GLASS_FAuLt_HIGH_SEtPoINt) 5. Enter the low glass impedance fault limit. the default is 10 MW. Parameter: Glass Fault Low Setpoint (GLASS_FAuLt_LoW_SEtPoINt) 6. Enable or disable glass impedance temperature correction. Because glass impedance is a strong function of temperature, correcting glass impedance for temperature effects is strongly recommended. Parameter: Impedance temperature Compensation (IMPEdANCE_tEMPERAtuRE_CoMPENSAtIoN_PH) 7. Enter the reference offset limit. default is 60 mV. Parameter: Zero offset Error Limit (ZERo_oFFSEt_ERRoR_LIMIt) 8. Select manual buffer calibration or automatic buffer calibration using the buffers listed in the table below. More information on the buffers listed can be found in Section 13.1. using automatic buffer calibration is strongly recommended. Description value Digital Equivalent Manual 0 Standard buffers Std 1 dIN 19267 buffer dIN 2 Ingold buffers Ingold 3 Merck buffers Merck 4 Manual buffer calibration Parameter: Buffer Calibration (BuFFER_StANdARd) 9. Set the stabilize time for automatic buffer calibration. the range is 0 to 99 sec. the default is 10 sec. Parameter: pH Stabilize time (PH_StABILIZE_tIME) Enter the desired value. 10. Set the stabilization value for automatic buffer calibration. the range is 0.02 to 0.50 pH. the default is 0.02 pH. Parameter: pH Stabilize Value (PH_StABILIZE_VALuE) Enter the desired value. 55 MODEL 5081-A SECTION 7.0 PROGRAMMING 7.8 BAROMETRIC PRESSURE NOTE The barometric pressure submenu appears only if the transmitter has been configured to measure oxygen. 7.8.1 Purpose this section describes how to do the following 1. Set the units for barometric pressure 2. Enter a pressure other than the calibration pressure for percent saturation measurements. 7.8.2 Definitions 1. BARoMEtRIC PRESSuRE. Because the current generated by an amperometric oxygen sensor is directly proportional to the partial pressure of oxygen, the sensor is generally calibrated by exposing it to water saturated air. See Section 9.1 for more information. to calculate the equivalent concentration of oxygen in water in ppm, the transmitter must know the temperature and barometric pressure. this submenu lets the user specify the units for barometric pressure. 2. PERCENt SAtuRAtIoN PRESSuRE. oxygen is sometimes measured in units of percent saturation. Percent saturation is the concentration of oxygen divided by the maximum amount of oxygen the water can hold (the saturation concentration) at the temperature and pressure of the measurement. Generally, the pressure during the measurement is assumed to be the same as the pressure when the sensor was calibrated. If the measurement and calibration pressures differ, the measurement pressure can be entered as a separate variable. 7.8.3 Procedure using the infrared remote controller 1. Press PRoG on the remote controller. PRoGRAM bar press EXIt NEXt ENtER PRoGRAM Unit nnHG EXIt ENtER 2. Press NEXt until the bAr PRESS submenu appears. Press ENtER. 3. the Unit prompt appears. Press é or ê to scroll through the list of units: nnHG 1000PA Atn bAr InHG mm Hg kPa atm bar in Hg Press ENtER to save. PRoGRAM % sat p EXIt 4. If % saturation units were selected in Section 7.5, the % SAt P (saturation pressure) prompt appears. Press NEXt. NEXt PRoGRAM p man EXIt 760 5. use the arrow keys to enter the desired pressure. the transmitter will use this pressure to calculate percent saturation. Press ENtER. ENtER 6. Press RESEt to return to the main display. 56 MODEL 5081-A SECTION 7.0 PROGRAMMING 7.8.4 Procedure using Deltav Access: deltaV Explorer/transducer Block/Properties, Amperometric Sensor tab 1. Enter the desired barometric pressure units from the following: mm Hg kPa atm bar in Hg Parameter: Barometric Pressure unit (BAR_PRESSuRE_uNIt) 2. If % saturation units were selected, enter the desired % saturation pressure. Parameter: Percent Saturation Pressure (PERCENt_SAtuRAtIoN_PRESSuRE) 57 MODEL 5081-A SECTION 8.0 CALIBRATION — TEMPERATURE SECTION 8.0 CALIBRATION — TEMPERATURE 8.1 INTRODUCTION All four amperometric sensors (oxygen, ozone, free chlorine, and total chlorine) are membrane-covered sensors. As the sensor operates, the analyte (the substance to be determined) diffuses through the membrane and is consumed at an electrode immediately behind the membrane. the reaction produces a current that depends on the rate at which the analyte diffuses through the membrane. the diffusion rate, in turn, depends on the concentration of the analyte and how easily it passes through the membrane (the membrane permeability). Because the membrane permeability is a function of temperature, the sensor current will change if the temperature changes. to correct for changes in sensor current caused by temperature, the transmitter automatically applies a membrane permeability correction. Although the membrane permeability is different for each sensor, the change is about 3%/°C at 25°C, so a 1°C error in temperature produces about a 3% error in the reading. temperature plays an additional role in oxygen measurements. oxygen sensors are calibrated by exposing them to water-saturated air, which, from the point of view of the sensor, is equivalent to water saturated with atmospheric oxygen (see Section 9.1 for more information). during calibration, the transmitter calculates the solubility of atmospheric oxygen in water using the following steps. First, the transmitter measures the temperature. From the temperature, the transmitter calculates the vapor pressure of water and, using the barometric pressure, calculates the partial pressure of atmospheric oxygen. once the transmitter knows the partial pressure, it calculates the equilibrium solubility of oxygen in water using a temperature-dependent factor called the Bunsen coefficient. overall, a 1°C error in the temperature measurement produces about a 2% error in the solubility calculated during calibration and about the same error in subsequent measurements. temperature is also important in the pH measurement required to correct free chlorine readings. 1. the transmitter uses a temperature dependent factor to convert measured cell voltage to pH. Normally, a slight inaccuracy in the temperature reading is unimportant unless the pH reading is significantly different from 7.00. Even then, the error is small. For example, at pH 12 and 25°C, a 1°C error produces a pH error less than ±0.02. 2. during auto calibration, the transmitter recognizes the buffer being used and calculates the actual pH of the buffer at the measured temperature. Because the pH of most buffers changes only slightly with temperature, reasonable errors in temperature do not produce large errors in the buffer pH. For example, a 1°C error causes at most an error of ±0.03 in the calculated buffer pH. Without calibration the accuracy of the temperature measurement is about ±0.4°C. Calibrate the transmitter if 1. ±0.4°C accuracy is not acceptable 2. the temperature measurement is suspected of being in error. Calibrate temperature by making the transmitter reading match the temperature measured with a standard thermometer. 58 MODEL 5081-A SECTION 8.0 CALIBRATION — TEMPERATURE 8.2. PROCEDURE USING THE INFRARED REMOTE CONTROLLER 1. Place the sensor and a calibrated reference thermometer in a container of water at ambient temperature. Be sure the temperature element in the sensor is completely submerged by keeping the sensor tip at least three inches below the water level. Stir continuously. Allow at least 20 minutes for the standard thermometer, sensor, and water to reach constant temperature. CALIBRAtE tEMP AdJ NEXt EXIt 2. Press CAL on the remote controller. ENtER CALIBRAtE tEMP EXIt 025 .0 ENtER 3. Press NEXt until the tEMP AdJ submenu appears. Press Enter. 4. the tEMP prompt appears. use the arrow keys to change the display to match the temperature measured using the standard thermometer. Press ENtER to save. 5. the tEMP AdJ sub-menu appears. Press RESEt to return to the main display. 8.3. PROCEDURE USING Deltav 1. Place the sensor and a calibrated reference thermometer in a container of water at ambient temperature. Be sure the temperature element in the sensor is completely submerged by keeping the sensor tip at least three inches below the water level. Stir continuously. Allow at least 20 minutes for the standard thermometer, sensor, and water to reach constant temperature. 2. Access: deltaV Explorer/Context Menu Standardize temperature (method_sv_cal) Method Steps: a. Is temperature stable?: Yes; No; Abort b. If yes is chosen, enter the new temperature value. 59 MODEL 5081-A SECTION 9.0 CALIBRATION — OxyGEN SECTION 9.0 CALIBRATION — OxyGEN 9.1 INTRODUCTION As Figure 9-1 shows, oxygen sensors generate a current directly proportional to the concentration of dissolved oxygen in the sample. Calibrating the sensor requires exposing it to a solution containing no oxygen (zero standard) and to a solution containing a known amount of oxygen (full-scale standard). the zero standard is necessary because oxygen sensors, even when no oxygen is present in the sample, generate a small current called the residual current. the analyzer compensates for the residual current by subtracting it from the measured current before converting the result to a dissolved oxygen value. New sensors require zeroing before being placed in service, and sensors should be zeroed whenever the electrolyte solution is replaced. the recommended zero standard is 5% sodium sulfite in water, although oxygen-free nitrogen can also be used. The Model 499A TrDO sensor, used for the determination of trace (ppb) oxygen levels, has very low residual current and does not normally require zeroing. the residual current in the 499A trdo sensor is equivalent to less than 0.5 ppb oxygen. the purpose of the full-scale standard is to establish the slope of the calibration curve. Because the solubility of atmospheric oxygen in water as a function of temperature and barometric pressure is well known, the natural choice for a full-scale standard is air-saturated water. However, air-saturated water is difficult to prepare and use, so the universal practice is to use air for calibration. From the point of view of the oxygen sensor, air and air-saturated water are identical. the equivalence comes about because the sensor really measures the chemical potential of oxygen. Chemical potential is the force that causes oxygen molecules to diffuse from the sample into the sensor where they can be measured. It is also the force that causes oxygen molecules in air to dissolve in water and to continue to dissolve until the water is saturated with oxygen. once the water is saturated, the chemical potential of oxygen in the two phases (air and water) is the same. oxygen sensors generate a current directly proportional to the rate at which oxygen molecules diffuse through a membrane stretched over the end of the sensor. the diffusion rate depends on the difference in chemical potential between oxygen in the sensor and oxygen in the sample. An electrochemical reaction, which destroys any oxygen molecules entering the sensor, keeps the concentration (and the chemical potential) of oxygen inside the sensor equal to zero. therefore, the chemical potential of oxygen in the sample alone determines the diffusion rate and the sensor current. When the sensor is calibrated, the chemical potential of oxygen in the standard determines the sensor current. Whether the sensor is calibrated in air or air-saturated water is immaterial. the chemical potential of oxygen is the same in either phase. Normally, to make the calculation of solubility in common units (like ppm do) simpler, it is convenient to use water-saturated air for calibration. Automatic air calibration is standard. the user simply exposes the sensor to water-saturated air and keys in the barometric pressure. the transmitter monitors the sensor current. When the current is stable, the transmitter stores the current and measures the temperature. From the temperature, the transmitter calculates the saturation vapor pressure of water. Next, it calculates the pressure of dry air by subtracting the vapor pressure from the barometric pressure. using the fact that dry air always contains 20.95% oxygen, the transmitter calculates the partial pressure of oxygen. once the transmitter knows the partial pressure of oxygen, it uses the Bunsen coefficient to calculate the equilibrium solubility of atmospheric oxygen in water at the prevailing temperature. At 25°C and 760 mm Hg, the equilibrium solubility is 8.24 ppm. often it is too difficult or messy to remove the sensor from the process liquid for calibration. In this case, the sensor can be calibrated against a measurement made with a portable laboratory instrument. the laboratory instrument typically uses a membrane-covered amperometric sensor that has been calibrated against water-saturated air. 60 FIGURE 9-1. Sensor Current as a Function of Dissolved Oxygen Concentration MODEL 5081-A SECTION 9.0 CALIBRATION — OxyGEN 9.2 PROCEDURE — zEROING THE SENSOR USING THE REMOTE CONTROLLER 1. Place the sensor in a fresh solution of 5% sodium sulfite (Na2So3) in water. Be sure air bubbles are not trapped against the membrane. the current will drop rapidly at first and then gradually reach a stable zero value. to monitor the sensor current, go to the main display. Press dIAG followed by NEXt. the SenSor Cur prompt appears. Press ENtER to view the sensor current. Note the units: nA is nanoamps; mA is microamps. the table gives typical zero values for Rosemount Analytical sensors. Sensor 499Ado 499Atrdo Hx438 and Gx448 Zero Current <50 nA <5 nA <1 nA A new sensor or a sensor in which the electrolyte solution has been replaced may require several hours (occasionally as long as overnight) to reach a minimum current. do Not StARt tHE ZERo RoutINE uNtIL tHE SENSoR HAS BEEN IN ZERo SoLutIoN FoR At LEASt tWo HouRS. 2. Press CAL on the remote controller. 3. the SEnSor O prompt appears. Press ENtER. CALIBRAtE sensor 0 EXIt NEXt ENtER CALIBRAtE 0 at EXIt 0 . 05 ENtER 4. the screen shows the value (in units selected in Section 7.5.3) below which the reading must be before the zero current will be accepted. Assume the units are ppm. the screen shows 0.02. therefore, the reading must be below 0.02 ppm before the zero will be accepted. For a 499Ado sensor 0.02 ppm corresponds to about 50 nA. to change the zero limit value, see Section 7.6.3. Press ENtER. NOTE the number shown in the main display may change. during the zero step, the previous zero current is suppressed, and the concentration shown in the main display is calculated assuming the residual current is zero. once the transmitter accepts the new zero current, it is used in all subsequent measurements. CALIBRAtE time delay EXIt CALIBRAtE ENtER 5. the tiME dELAy message appears and remains until the zero current is below the concentration limit shown in the previous screen. If the current is already below the limit, tiME dELAy will not appear. to bypass the time delay, press ENtER. 6. O donE shows that the zero step is complete. Press EXIt. 0 done EXIt 7. Press RESEt to return to the main display. 61 MODEL 5081-A SECTION 9.0 CALIBRATION — OxyGEN 9.3 PROCEDURE — zEROING THE SENSOR USING Deltav 1. Place the sensor in a fresh solution of 5% sodium sulfite (Na2So3) in water. Be sure air bubbles are not trapped against the membrane. the current will drop rapidly at first and then gradually reach a stable zero value. to monitor the sensor current, go to the main display. Press dIAG followed by NEXt. the SenSor Cur prompt appears. Press ENtER to view the sensor current. Note the units: nA is nanoamps; mA is microamps. the table gives typical zero values for Rosemount Analytical sensors. Sensor 499Ado 499Atrdo Hx438 and Gx448 Zero Current <50 nA <5 nA <1 nA A new sensor or a sensor in which the electrolyte solution has been replaced may require several hours (occasionally as long as overnight) to reach a minimum current. do Not StARt tHE ZERo RoutINE uNtIL tHE SENSoR HAS BEEN IN ZERo SoLutIoN FoR At LEASt tWo HouRS. 2. Access: deltaV Explorer/Context Menu Zero Amperometric Sensor (method_sensor_zero) Method Steps: a. displayed: Current oxygen Measurement Zero limit Is PV less than limit?: Yes; No; Abort NOTE Selecting “Yes” to an oxygen measurement greater than the zero limit will cause the measurement to be accepted as the zero value. Selecting “No” will cause the oxygen measurement to be re-read. the new oxygen measurement may be closer to the zero limit. If the oxygen measurement is significantly greater than the zero limit, the method should be aborted (“Abort”) and restarted after sufficient time for the oxygen reading to approach the zero limit. b. If “Yes” is chosen, the Current oxygen Reading and the new Zero Current Value are displayed. the method then concludes. 62 MODEL 5081-A SECTION 9.0 CALIBRATION — OxyGEN 9.4 PROCEDURE — AIR CALIBRATION USING THE INFRARED REMOTE CONTROLLER 1. Remove the sensor from the process liquid. use a soft tissue and a stream of water from a wash bottle to clean the membrane. Blot dry. the membrane must be dry during air calibration. 2. Pour some water into a beaker and suspend the sensor with the membrane about 0.5 inch (1 cm) above the water surface. to avoid drift caused by temperature changes, keep the sensor out of the direct sun. 3. Monitor the dissolved oxygen reading and the temperature. once readings have stopped drifting, begin the calibration. It may take 10 -15 minutes for the sensor reading in air to stabilize. Stabilization time may be even longer if the process temperature is appreciably different from the air temperature. For an accurate calibration, temperature measured by the sensor must be stable. 4. Press CAL on the remote controller. CALIBRAtE Sensor Cal EXIt NEXt 5. Press NEXt. the SEnSor CAL submenu appears. Press ENtER. ENtER CALIBRAtE 6. the Air CAL prompt appears. Press ENtER. A ir Cal EXIt NEXt ENtER CALIBRAtE 7. the screen shows the units selected for barometric pressure. Press NEXt. nnHG EXIt NEXt CALIBRAtE Press 8. use the arrow keys to enter the barometric pressure. Press ENtER. 760 .0 EXIt ENtER CALIBRAtE time delay EXIt ENtER NOTE Be sure to enter the actual barometric pressure. Weather forecasters and airports usually report barometric pressure corrected to sea level; they do not report the actual barometric pressure. to estimate barometric pressure from altitude, see Appendix A. 9. the tiME dELAy message appears and remains until the sensor reading meets the stability criteria set in Section 7.6. to bypass the time delay, press ENtER. CALIBRAtE Cal dOne EXIt 10. this screen appears when the calibration is complete. the concentration shown in the main display is the solubility of atmospheric oxygen in water at ambient temperature and barometric pressure. Press EXIt. 11. to return to the main display, press RESEt. 12. during calibration, the transmitter calculates the sensitivity (nA/ppm) of the sensor. to check the sensitivity, go to the main display. Press dIAG. Press NEXt until the SenSitvty (sensitivity) prompt appears. Press ENtER to display the sensitivity in nA/ppm. typical values at 25°C are given in the table. Sensor 499Ado 499Atrdo Hx438 and Gx448 nA/ppm 1,800 - 3,100 3,600 - 6,100 4.8 - 9.8 63 MODEL 5081-A SECTION 9.0 CALIBRATION — OxyGEN 9.5 PROCEDURE — AIR CALIBRATION USING Deltav 1. Remove the sensor from the process liquid. use a soft tissue and a stream of water from a wash bottle to clean the membrane. Blot dry. the membrane must be dry during air calibration. 2. Pour some water into a beaker and suspend the sensor with the membrane about 0.5 inch (1 cm) above the water surface. to avoid drift caused by temperature changes, keep the sensor out of the direct sun. 3. Monitor the dissolved oxygen reading and the temperature. once readings have stopped drifting, begin the calibration. It may take 10 -15 minutes for the sensor reading in air to stabilize. Stabilization time may be even longer if the process temperature is appreciably different from the air temperature. For an accurate calibration, temperature measured by the sensor must be stable. 4. Access: deltaV Explorer/Context Menu Air Calibrate oxygen Sensor (method_oxygen_air_cal) Method Steps: a. displayed: Current oxygen Measurement Current temperature Measurement Prompt: Are values stable?: Yes; No; Abort If “No” is chosen, current values are re-read. b. If “Yes” is chosen: Prompt: Select Pressure units. Enter desired pressure units. c. Prompt: Enter barometric pressure. d. displayed: Current oxygen Measurement Current temperature Measurement New Sensitivity Value Method concludes. typical values for sensitivity at 25C are given in the table: Sensor 499Ado 499Atrdo Hx438 and Gx448 64 nA/ppm 1,800 - 3,100 3,600 - 6,100 4.8 - 9.8 MODEL 5081-A SECTION 9.0 CALIBRATION — OxyGEN 9.6 PROCEDURE — IN-PROCESS CALIBRATION USING THE REMOTE CONTROLLER 1. the transmitter and sensor can be calibrated against a standard instrument. For oxygen sensors installed in aeration basins in waste treatment plants, calibration against a second instrument is often preferred. For an accurate calibration be sure that: a. the standard instrument has been zeroed and calibrated against water-saturated air following the manufacturer's instructions. b. the standard sensor is inserted in the liquid as close to the process sensor as possible. c. Adequate time is allowed for the standard sensor to stabilize before calibrating the process instrument. 2. Press CAL on the remote controller. CALIBRAtE Sensor Cal EXIt NEXt 3. Press NEXt. the SEnSor CAL submenu appears. Press ENtER. ENtER CALIBRAtE 4. Press NEXt. the Air CAL prompt appears. Press NEXt. A ir Cal EXIt NEXt ENtER CALIBRAtE In ProCess EXIt 5. the In ProCESS prompt appears. Press ENtER. ENtER CALIBRAtE time delay EXIt NEXt CALIBRAtE 7. the GrAb SPL (grab sample) message appears. Press ENtER. Grab spl EXIt ENtER CALIBRAtE Cal EXIt 6. the tiME dELAy message appears and remains until the sensor reading meets the stability criteria set in Section 7.6. to bypass the time delay, press ENtER. 3 . 20 8. use the arrow keys to change the flashing display to the value indicated by the standard instrument. Press ENtER to save. ENtER 9. Press RESEt to return to the main display. 65 MODEL 5081-A SECTION 9.0 CALIBRATION — OxyGEN 9.7 PROCEDURE — IN-PROCESS CALIBRATION USING Deltav 1. the transmitter and sensor can be calibrated against a standard instrument. For oxygen sensors installed in aeration basins in waste treatment plants, calibration against a second instrument is often preferred. For an accurate calibration be sure that: a. the standard instrument has been zeroed and calibrated against water-saturated air following the manufacturer's instructions. b. the standard sensor is inserted in the liquid as close to the process sensor as possible. c. Adequate time is allowed for the standard sensor to stabilize before calibrating the process instrument. 2. Access: deltaV Explorer/Context Menu Calibrate Amperometric Sensor (method_pv_cal) Method Steps: a. displayed: Current PV Measurement Prompt: Is value stable?: Yes; No; Abort If “No” is chosen, the PV measurement is re-read. b. If “Yes” is chosen, the PV measurement and the new sensitivity value are shown. the method concludes. 66 MODEL 5081-A SECTION 10.0 CALIBRATION - FREE CHLORINE SECTION 10.0 CALIBRATION — FREE CHLORINE 10.1 INTRODUCTION As Figure 10-1 shows, a free chlorine sensor generates a current directly proportional to the concentration of free chlorine in the sample. Calibrating the sensor requires exposing it to a solution containing no chlorine (zero standard) and to a solution containing a known amount of chlorine (full-scale standard). the zero standard is necessary because chlorine sensors, even when no chlorine is in the sample, generate a small current called the residual current. the transmitter compensates for the residual current by subtracting it from the measured current before converting the result to a chlorine value. New sensors require zeroing before being placed in service, and sensors should be zeroed whenever the electrolyte solution is replaced. Either of the following makes a good zero standard: • deionized water containing about 500 ppm sodium chloride. dissolve 0.5 grams (1/8 teaspoonful) of table salt in 1 liter of water. do Not uSE dEIoNIZEd WAtER ALoNE FoR ZERoING tHE SENSoR. tHE CoNduCtIVItY oF tHE ZERo WAtER MuSt BE GREAtER tHAN 50 mS/cm. • tap water known to contain no chlorine. Expose tap water to bright sunlight for at least 24 hours. the purpose of the full-scale standard is to establish the slope of the calibration curve. Because stable chlorine standards do not exist, the sensor must be calibrated against a test run on a grab sample of the process liquid. Several manufacturers offer portable test kits for this purpose. observe the following precautions when taking and testing the grab sample. • take the grab sample from a point as close to the sensor as possible. Be sure that taking the sample does not alter the flow of the sample to the sensor. It is best to install the sample tap just downstream from the sensor. • Chlorine solutions are unstable. Run the test immediately after taking the sample. try to calibrate the sensor when the chlorine concentration is at the upper end of the normal operating range. Free chlorine measurements made with the 499ACL-01 sensor also require a pH correction. Free chlorine is the sum of hypochlorous acid (HoCl) and hypochlorite ion (oCl-). the relative amount of each depends on the pH. As pH increases, the concentration of HoCl decreases and the concentration of oCl- increases. Because the sensor responds only to HoCl, a pH correction is necessary to properly convert the sensor current into a free chlorine reading. the transmitter uses both automatic and manual pH correction. In automatic pH correction, the transmitter continuously monitors the pH of the solution and corrects the free chlorine reading for changes in pH. In manual pH correction, the transmitter uses a fixed pH value entered by the user to make the correction. Generally, if the pH changes more than about 0.2 units over short periods of time, automatic pH correction is best. If the pH is relatively steady or subject only to seasonal changes, manual pH correction is adequate. during calibration, the transmitter must know the pH of the sample. If the transmitter is using automatic pH correction, the pH sensor (properly calibrated) must be in the process liquid before starting the calibration. If the transmitter is using manual pH correction, be sure to enter the pH value before starting the calibration. the Model 499ACL-01 free chlorine sensor loses sensitivity at high concentrations of chlorine. the 5081-A transmitter has a dual slope feature that allows the user to compensate for the nonlinearity of the sensor. However, for the vast majority of applications, dual slope calibration is unnecessary. FIGURE 10-1. Sensor Current as a Function of Free Chlorine Concentration 67 67 MODEL 5081-A SECTION 10.0 CALIBRATION - FREE CHLORINE 10.2 PROCEDURE — zEROING THE SENSOR USING THE REMOTE CONTROLLER 1. Place the sensor in the zero standard (see Section 10.1). Be sure no air bubbles are trapped against the membrane. the sensor current will drop rapidly at first and then gradually reach a stable zero value. to monitor the sensor current, go to the main display. Press dIAG followed by NEXt. the SEnSor Cur prompt appears. Press ENtER to view the sensor current. Note the units: nA is nanoamps; µA is microamps. typical zero current for a free chlorine sensor is -10 to +10 nanoamps. A new sensor or a sensor in which the electrolyte solution has been replace may require several hours (occasionally as long as overnight) to reach a minimum zero current. do Not StARt tHE ZERo RoutINE uNtIL tHE SENSoR HAS BEEN IN ZERo SoLutIoN FoR At LEASt tWo HouRS. 2. Press CAL on the remote controller. CALIBRAtE Sensor 0 EXIt NEXt 3. the SEnSor O prompt appears. Press ENtER. ENtER CALIBRAtE 0 at EXIt . 002 ENtER 4. the screen shows the value (in units ppm) below which the reading must be before the zero current will be accepted. the screen shows 0.02. therefore, the reading must be below 0.02 ppm before the zero will be accepted. For a typical 499ACL-01 sensor, 0.02 ppm corresponds to about 7 nA. to change the zero limit value, see Section 7.6.3. Press ENtER. NOTE the number shown in the main display may change. during the zero step, the previous zero current is suppressed, and the concentration shown in the main display is calculated assuming the residual current is zero. once the transmitter accepts the new zero current, it is used in all subsequent measurements. CALIBRAtE time delay EXIt ENtER 5. the tiME dELAy message appears and remains until the zero current is below the concentration limit shown in the previous screen. If the current is already below the limit, tiME dELAy will not appear. to bypass the time delay, press ENtER. CALIBRAtE 0 dOne EXIt 68 6. O donE shows that the zero step is complete. Press EXIt. 7. Press RESEt to return to the main display. MODEL 5081-A SECTION 10.0 CALIBRATION - FREE CHLORINE 10.3 PROCEDURE — zEROING THE SENSOR USING Deltav 1. Place the sensor in the zero standard (see Section 10.1). Be sure no air bubbles are trapped against the membrane. the sensor current will drop rapidly at first and then gradually reach a stable zero value. to monitor the sensor current, go to the main display. Press dIAG followed by NEXt. the SEnSor Cur prompt appears. Press ENtER to view the sensor current. Note the units: nA is nanoamps; µA is microamps. typical zero current for a free chlorine sensor is -10 to +10 nanoamps. A new sensor or a sensor in which the electrolyte solution has been replace may require several hours (occasionally as long as overnight) to reach a minimum zero current. do Not StARt tHE ZERo RoutINE uNtIL tHE SENSoR HAS BEEN IN ZERo SoLutIoN FoR At LEASt tWo HouRS. 2. Access: deltaV Explorer/Context Menu Zero Amperometric Sensor (method_sensor_zero) Method Steps: a. displayed: Current Free Chlorine Measurement Zero limit Prompt: Is PV less than limit?: Yes; No; Abort NOTE Selecting “Yes” to a free chlorine measurement greater than the zero limit will cause the measurement to be accepted as the zero value. Selecting “No” will cause the free chlorine measurement to be re-read. the new free chlorine measurement may be closer to the zero limit. If the free chlorine measurement is significantly greater than the zero limit, the method should be aborted (“Abort”) and restarted after sufficient time for the free chlorine reading to approach the zero limit. b. If “Yes” is chosen, the Current Free Chlorine Reading and the new Zero Current Value are displayed. the method then concludes. 69 MODEL 5081-A SECTION 10.0 CALIBRATION - FREE CHLORINE 10.4 PROCEDURE — FULL SCALE CALIBRATION USING THE REMOTE CONTROLLER 1. Place the sensor in the process liquid. If automatic pH correction is being used, calibrate the pH sensor (see Section 13.0) and place it in the process liquid. If manual pH correction is being used, measure the pH of the process liquid and enter the value (see Section 7.8). Adjust the sample flow until it is within the range recommended for the chlorine sensor. Refer to the sensor instruction sheet. 2. Adjust the chlorine concentration until it is near the upper end of the control range. Wait until the reading is stable before starting the calibration. 3. Press CAL on the remote controller. CALIBRAtE Sensor Cal EXIt NEXt 4. Press NEXt. the SEnSor CAL submenu appears. ENtER CALIBRAtE time delay EXIt NEXt 5. Press ENtER. the tiME dELAy message appears and remains until the sensor reading meets the stability criteria set in Section 7.6. to bypass the time delay, press ENtER. NOTE As soon as the stability criteria are met (or ENtER is pressed to bypass the time delay), the transmitter stores the sensor current. therefore, if the chlorine level in the process liquid drifts while the sample is being tested, there is no need to compensate for the change when entering test results in step 7. CALIBRAtE Grab spl EXIt ENtER 6. the GrAb SPL (grab sample) prompt appears. take a sample of the process liquid and immediately determine the concentration of free chlorine in the sample. Press ENtER. CALIBRAtE Cal EXIt 3 . 20 ENtER 7. use the arrow keys to change the flashing display to the concentration of chlorine determined in the grab sample. Press ENtER to save. 8. Press RESEt to return to the main display. 9. during calibration, the transmitter calculates the sensitivity (nA/ppm) of the sensor. to check the sensitivity, go to the main display. Press dIAG. Press NEXt until the SenSitvty (sensitivity) prompt appears. Press ENtER to display the sensitivity in nA/ppm. the sensitivity of a 499ACL-01 sensor is 250 - 350 nA/ppm at 25°C and pH 7. 70 MODEL 5081-A SECTION 10.0 CALIBRATION - FREE CHLORINE 10.5 PROCEDURE — FULL SCALE CALIBRATION USING Deltav 1. Place the sensor in the process liquid. If automatic pH correction is being used, calibrate the pH sensor (see Section 13.0) and place it in the process liquid. If manual pH correction is being used, measure the pH of the process liquid and enter the value (see Section 7.8). Adjust the sample flow until it is within the range recommended for the chlorine sensor. Refer to the sensor instruction sheet. 2. Adjust the chlorine concentration until it is near the upper end of the control range. Wait until the reading is stable before starting the calibration. 3. Access: deltaV Explorer/Context Menu Calibrate Amperometric Sensor (method_pv_cal) Method Steps: a. displayed: Current PV Measurement Prompt: Is value stable?: Yes; No; Abort If “No” is chosen, the PV measurement is re-read. b. If “Yes” is chosen, the PV measurement and the new sensitivity value are shown. the method concludes. 71 MODEL 5081-A SECTION 10.0 CALIBRATION - FREE CHLORINE 10.6 DUAL SLOPE CALIBRATION Figure 10-2 show the principle of dual slope calibration. Between zero and concentration C1, the sensor response is linear. When the concentration of chlorine becomes greater than C1, the response is non-linear. In spite of the non-linearity, the response can be approximated by a straight line between point 1 and point 2. dual slope calibration is rarely needed. It is probably useful in fewer than 5% of applications. 1. Be sure the transmitter has been configured for dual slope calibration. See Section 7.6. 2. Zero the sensor. See Section 10.2. 3. Place the sensor in the process liquid. If automatic pH correction is being used, calibrate the pH sensor (Section 13.0) and place it in the process liquid. If manual pH correction is being used, measure the pH of the process liquid and enter the value. See Section 7.8. Adjust the sample flow until it is within the range recommended for the chlorine sensor. Refer to the sensor instruction sheet. FIGURE 10-2. Dual Slope Calibration 4. Press CAL on the remote controller. Press NEXt. CALIBRAtE Sensor Cal EXIt NEXt 5. the SEnSor CAL prompt appears. Press ENtER. ENtER CALIBRAtE Cal pt1 EXIt NEXt ENtER 6. the CAL Pt 1 prompt appears. Adjust the chlorine concentration until it is near the upper end of the linear range of the sensor. Press ENtER. CALIBRAtE time delay EXIt NEXt 7. the tiME dELAy message appears and remains until the sensor reading meets the stability criteria set in Section 7.6. to bypass the time delay, press ENtER. NOTE As soon as the stability criteria are met (or ENtER is pressed to by-pass the time delay), the transmitter stores the sensor current. therefore, if the chlorine level in the process liquid drifts while the sample is being tested, there is no need to compensate for the change when entering test results. CALIBRAtE Grab spl EXIt 72 ENtER 8. the GrAb SPL (grab sample) prompt appears. take a sample of the process liquid and immediately determine the concentration of free chlorine in the sample. Press ENtER. MODEL 5081-A SECTION 10.0 CALIBRATION - FREE CHLORINE CALIBRAtE Pt1 3 . 00 EXIt ENtER 9. the Pt1 prompt appears. use the arrow keys to change the flashing display to the concentration of chlorine determined in the grab sample. Press ENtER to save. CALIBRAtE Cal pt2 EXIt NEXt ENtER 10. the CAL Pt 2 prompt appears. Adjust the concentration of chlorine until it is near the top end of the range, i.e., near concentration C2 shown in Figure 10-2. Press ENtER. CALIBRAtE time delay EXIt NEXt 11. the tiME dELAy message appears and remains until the sensor reading meets the stability criteria set in Section 7.6. to bypass the time delay, press ENtER. CALIBRAtE Grab spl EXIt ENtER 12. the GrAb SPL (grab sample) prompt appears. take a sample of the process liquid and immediately determine the concentration of free chlorine in the sample. Press ENtER. CALIBRAtE Pt2 EXIt 6 . 00 ENtER 13. the Pt2 prompt appears. use the arrow keys to change the flashing display to the concentration of chlorine determined in the grab sample. Press ENtER to save. 14. Press RESEt to return to the main display. 73 74 MODEL 5081-A SECTION 11.0 CALIBRATION - TOTAL CHLORINE SECTION 11.0 CALIBRATION — TOTAL CHLORINE 11.1 INTRODUCTION total chlorine is the sum of free and combined chlorine. the continuous determination of total chlorine requires two steps. See Figure 11-1. First, the sample flows into a conditioning system (SCS 921) where a pump continuously adds acetic acid and potassium iodide to the sample. the acid lowers the pH, which allows total chlorine in the sample to quantitatively oxidize the iodide in the reagent to iodine. In the second step, the treated sample flows to the sensor. the sensor is a membrane-covered amperometric sensor, whose output is proportional to the concentration of iodine. Because the concentration of iodine is proportional to the concentration of total chlorine, the analyzer can be calibrated to read total chlorine. Figure 11-2 shows a typical calibration curve for a total chlorine sensor. Because the sensor really measures iodine, calibrating the sensor requires exposing it to a solution containing no iodine (zero standard) and to a solution containing a known amount of iodine (full-scale standard). the zero standard is necessary because the sensor, even when no iodine is present, generates a small current called the residual current. the transmitter compensates for the residual current by subtracting it from the measured current before converting the result to a total chlorine value. New sensors require zeroing before being placed in service, and sensors should be zeroed whenever the electrolyte solution is replaced. the best zero standard is sample without reagent added. the purpose of the full-scale standard is to establish the slope of the calibration curve. Because stable total chlorine standards do not exist, the sensor must be calibrated against a test run on a grab sample of the process liquid. Several manufacturers offer portable test kits for this purpose. observe the following precautions when taking and testing the grab sample. • • take the grab sample from a point as close as possible to the inlet of the SCS921 sample conditioning system. Be sure that taking the sample does not alter the flow through the SCS921. Sample flow must remain between 80 and 100 mL/min. FIGURE 11-1. Determination of Total Chlorine Chlorine solutions are unstable. Run the test immediately after taking the sample. try to calibrate the sensor when the chlorine concentration is at the upper end of the normal operating range. the Model 499ACL-02 (total chlorine) sensor loses sensitivity at high concentrations of chlorine. the 5081-A transmitter has a dual slope feature that allows the user to compensate for the non-linearity of the sensor. However, for the vast majority of applications, dual slope calibration is unnecessary. FIGURE 11-2. Sensor Current as a Function of Total Chlorine Concentration 75 MODEL 5081-A SECTION 11.0 CALIBRATION - TOTAL CHLORINE 11.2 PROCEDURE — zEROING THE SENSOR USING THE REMOTE CONTROLLER 1. Complete the startup sequence described in the SCS921 instruction manual. Adjust the sample flow to between 80 and 100 mL/min, and set the sample pressure to between 3 and 5 psig. 2. Remove the reagent uptake tube from the reagent bottle and let it dangle in air. the peristaltic pump will simply pump air into the sample. 3. Let the system run until the sensor current is stable. the current will drop rapidly at first and then gradually reach a stable value. to monitor the sensor current, go to the main display. Press dIAG followed by NEXt. the SEnSor Cur prompt appears. Press ENtER to view the sensor current. Note the units: nA is nanoamps; µA is microamps. typical zero current for a total chlorine sensor is -10 to +30 nanoamps. A new sensor or a sensor in which the electrolyte solution has been replaced may require several hours (occasionally as long as overnight) to reach a minimum zero current. do Not StARt tHE ZERo RoutINE uNtIL tHE SENSoR HAS BEEN IN ZERo SoLutIoN FoR At LEASt tWo HouRS. 4. Press CAL on the remote controller. CALIBRAtE Sensor 0 EXIt NEXt 5. the SEnSor O prompt appears. Press ENtER. ENtER CALIBRAtE 0 at EXIt . 002 ENtER 6. the screen shows the value (in units ppm) below which the reading must be before the zero current will be accepted. the screen shows 0.02. therefore, the reading must be below 0.02 ppm before the zero will be accepted. For a typical 499ACL-02 sensor, 0.02 ppm corresponds to about 20 nA. to change the zero limit value, see Section 7.6.3. Press ENtER. NOTE the number shown in the main display may change. during the zero step, the previous zero current is suppressed, and the concentration shown in the main display is calculated assuming the residual current is zero. once the transmitter accepts the new zero current, it is used in all subsequent measurements. CALIBRAtE time delay EXIt ENtER 7. the tiME dELAy message appears and remains until the zero current is below the concentration limit shown in the previous screen. If the current is already below the limit, tiME dELAy will not appear. to bypass the time delay, press ENtER. CALIBRAtE 0 dOne EXIt 76 8. O donE shows that the zero step is complete. Press EXIt. 9. Press RESEt to return to the main display. MODEL 5081-A SECTION 11.0 CALIBRATION - TOTAL CHLORINE 11.3 PROCEDURE — zEROING THE SENSOR USING Deltav 1. Complete the startup sequence described in the SCS921 instruction manual. Adjust the sample flow to between 80 and 100 mL/min, and set the sample pressure to between 3 and 5 psig. 2. Remove the reagent uptake tube from the reagent bottle and let it dangle in air. the peristaltic pump will simply pump air into the sample. 3. Let the system run until the sensor current is stable. the current will drop rapidly at first and then gradually reach a stable value. to monitor the sensor current, go to the main display. Press dIAG followed by NEXt. the SEnSor Cur prompt appears. Press ENtER to view the sensor current. Note the units: nA is nanoamps; µA is microamps. typical zero current for a total chlorine sensor is -10 to +30 nanoamps. A new sensor or a sensor in which the electrolyte solution has been replaced may require several hours (occasionally as long as overnight) to reach a minimum zero current. do Not StARt tHE ZERo RoutINE uNtIL tHE SENSoR HAS BEEN IN ZERo SoLutIoN FoR At LEASt tWo HouRS. 4. Access: deltaV Explorer/Context Menu Zero Amperometric Sensor (method_sensor_zero) Method Steps: a. displayed: Current total Chlorine Measurement Zero limit Prompt: Is PV less than limit?: Yes; No; Abort NOTE Selecting “Yes” to a total chlorine measurement greater than the zero limit will cause the measurement to be accepted as the zero value. Selecting “No” will cause the total chlorine measurement to be re-read. the new total chlorine measurement may be closer to the zero limit. If the total chlorine measurement is significantly greater than the zero limit, the method should be aborted (“Abort”) and restarted after sufficient time for the total chlorine reading to approach the zero limit. b. If “Yes” is chosen, the Current total Chlorine Reading and the new Zero Current Value are displayed. the method then concludes. MODEL 5081-A SECTION 11.0 CALIBRATION - TOTAL CHLORINE 11.4 PROCEDURE — FULL SCALE CALIBRATION USING THE REMOTE CONTROLLER 1. If the sensor was just zeroed, place the reagent uptake tube back in the bottle. once the flow of reagent starts, it takes about one minute for the sensor current to begin to increase. It may take an hour or longer for the reading to stabilize. Be sure the sample flow stays between 80 and 100 mL/min and the pressure is between 3 and 5 psig. 2. Adjust the chlorine concentration until it is near the upper end of the control range. Wait until the controller reading is stable before starting the calibration. 3. Press CAL on the remote controller. CALIBRAtE Sensor Cal EXIt NEXt 4. Press NEXt. the SEnSor CAL submenu appears. ENtER CALIBRAtE time delay EXIt NEXt 5. Press NEXt. the tiME dELAy message appears and remains until the sensor reading meets the stability criteria set in Section 7.6. to bypass the time delay, press ENtER. NOTE As soon as the stability criteria are met (or ENtER is pressed to bypass the time delay), the transmitter stores the sensor current. therefore, if the chlorine level in the process liquid drifts while the sample is being tested, there is no need to compensate for the change when entering test results in step 7. CALIBRAtE Grab spl EXIt ENtER 6. the GrAb SPL (grab sample) prompt appears. take a sample of the process liquid and immediately determine the concentration of total chlorine in the sample. Press ENtER. CALIBRAtE Cal EXIt 3 . 20 ENtER 7. use the arrow keys to change the flashing display to the concentration of chlorine determined in the grab sample. Press ENtER to save. 8. Press RESEt to return to the main display. 9. during calibration, the transmitter calculates the sensitivity (nA/ppm) of the sensor. to check the sensitivity, go to the main display. Press dIAG. Press NEXt until the SenSitvty (sensitivity) prompt appears. Press ENtER to display the sensitivity in nA/ppm. the sensitivity of a 499ACL-02 sensor is about 1300 nA/ppm at 25°C. 78 MODEL 5081-A SECTION 11.0 CALIBRATION - TOTAL CHLORINE 11.5 PROCEDURE — FULL SCALE CALIBRATION USING Deltav 1. If the sensor was just zeroed, place the reagent uptake tube back in the bottle. once the flow of reagent starts, it takes about one minute for the sensor current to begin to increase. It may take an hour or longer for the reading to stabilize. Be sure the sample flow stays between 80 and 100 mL/min and the pressure is between 3 and 5 psig. 2. Adjust the chlorine concentration until it is near the upper end of the control range. Wait until the controller reading is stable before starting the calibration. 3. Access: deltaV Explorer/Context Menu Calibrate Amperometric Sensor (method_pv_cal) Method Steps: a. displayed: Current PV Measurement Prompt: Is value stable?: Yes; No; Abort If “No” is chosen, the PV measurement is re-read. b. If “Yes” is chosen, the PV measurement and the new sensitivity value are shown. the method concludes. MODEL 5081-A SECTION 11.0 CALIBRATION - TOTAL CHLORINE 11.6 DUAL SLOPE CALIBRATION Figure 11-3 show the principle of dual slope calibration. Between zero and concentration C1, the sensor response is linear. When the concentration of chlorine becomes greater than C1, the response is non-linear. In spite of the non-linearity, the response can be approximated by a straight line between point 1 and point 2. dual slope calibration is rarely needed. It is probably useful in fewer than 5% of applications. 1. Be sure the transmitter has been configured for dual slope calibration. See Section 7.6. 2. Zero the sensor. See Section 11.2. 3. Place the sensor in the process liquid. If automatic pH correction is being used, calibrate the pH sensor (Section 13.0) and place it in the process liquid. If manual pH correction is being used, measure the pH of the process liquid and enter the value. See Section 7.8. Adjust the sample flow until it is within the range recommended for the chlorine sensor. Refer to the sensor instruction sheet. FIGURE 11-3. Dual Slope Calibration 4. Press CAL on the remote controller. Press NEXt. CALIBRAtE Sensor Cal EXIt NEXt 5. the SEnSor CAL prompt appears. Press ENtER. ENtER CALIBRAtE Cal pt1 EXIt NEXt ENtER 6. the CAL Pt 1 prompt appears. Adjust the chlorine concentration until it is near the upper end of the linear range of the sensor. Press ENtER. CALIBRAtE time delay EXIt NEXt 7. the tiME dELAy message appears and remains until the sensor reading meets the stability criteria set in Section 7.6. to bypass the time delay, press ENtER. NOTE As soon as the stability criteria are met (or ENtER is pressed to by-pass the time delay), the transmitter stores the sensor current. therefore, if the chlorine level in the process liquid drifts while the sample is being tested, there is no need to compensate for the change when entering test results. CALIBRAtE Grab spl EXIt 80 ENtER 8. the GrAb SPL (grab sample) prompt appears. take a sample of the process liquid and immediately determine the concentration of total chlorine in the sample. Press ENtER. MODEL 5081-A SECTION 11.0 CALIBRATION - TOTAL CHLORINE CALIBRAtE Pt1 3 . 00 EXIt ENtER 9. the Pt1 prompt appears. use the arrow keys to change the flashing display to the concentration of chlorine determined in the grab sample. Press ENtER to save. CALIBRAtE Cal pt2 EXIt NEXt ENtER 10. the CAL Pt 2 prompt appears. Adjust the concentration of chlorine until it is near the top end of the range, i.e., near concentration C2 shown in Figure 11-3. Press ENtER. CALIBRAtE time delay EXIt NEXt 11. the tiME dELAy message appears and remains until the sensor reading meets the stability criteria set in Section 7.6. to bypass the time delay, press ENtER. CALIBRAtE Grab spl EXIt ENtER 12. the GrAb SPL (grab sample) prompt appears. take a sample of the process liquid and immediately determine the concentration of total chlorine in the sample. Press ENtER. CALIBRAtE Pt2 EXIt 6 . 00 ENtER 13. the Pt2 prompt appears. use the arrow keys to change the flashing display to the concentration of chlorine determined in the grab sample. Press ENtER to save. 14. Press RESEt to return to the main display. 81 MODEL 5081-A SECTION 12.0 CALIBRATION - OzONE SECTION 12.0 CALIBRATION — OzONE 12.1 INTRODUCTION As Figure 12-1 shows, an ozone sensor generates a current directly proportional to the concentration of ozone in the sample. Calibrating the sensor requires exposing it to a solution containing no ozone (zero standard) and to a solution containing a known amount of ozone (full-scale standard). the zero standard is necessary because ozone sensors, even when no ozone is in the sample, generate a small current called the residual current. the transmitter compensates for the residual current by subtracting it from the measured current before converting the result to an ozone value. New sensors require zeroing before being placed in service, and sensors should be zeroed whenever the electrolyte solution is replaced. Either of the following makes a good zero standard: • deionized water. • tap water known to contain no ozone. Expose tap water to ozone-free air for several hours. the purpose of the full-scale standard is to establish the slope of the calibration curve. Because stable ozone standards do not exist, the sensor must be calibrated against a test run on a grab sample of the process liquid. Several manufacturers offer portable test kits for this purpose. observe the following precautions when taking and testing the grab sample. • take the grab sample from a point as close to the sensor as possible. Be sure that taking the sample does not alter the flow of the sample to the sensor. It is best to install the sample tap just downstream from the sensor. • ozone solutions are unstable. Run the test immediately after taking the sample. try to calibrate the sensor when the ozone concentration is at the upper end of the normal operating range. FIGURE 12-1. Sensor Current as a Function of Ozone Concentration 82 MODEL 5081-A SECTION 12.0 CALIBRATION - OzONE 12.2 PROCEDURE — zEROING THE SENSOR USING THE REMOTE CONTROLLER 1. Place the sensor in the zero standard (see Section 12.1). Be sure no air bubbles are trapped against the membrane. the sensor current will drop rapidly at first and then gradually reach a stable zero value. to monitor the sensor current, go to the main display. Press dIAG followed by NEXt. the SEnSor Cur prompt appears. Press ENtER to view the sensor current. Note the units: nA is nanoamps; µA is microamps. typical zero current for an ozone sensor is -10 to +10 nanoamps. A new sensor or a sensor in which the electrolyte solution has been replace may require several hours (occasionally as long as overnight) to reach a minimum zero current. do Not StARt tHE ZERo RoutINE uNtIL tHE SENSoR HAS BEEN IN ZERo SoLutIoN FoR At LEASt tWo HouRS. 2. Press CAL on the remote controller. CALIBRAtE Sensor 0 EXIt NEXt 3. the SEnSor O prompt appears. Press ENtER. ENtER CALIBRAtE 0 at EXIt . 002 ENtER 4. the screen shows the value (in units ppm) below which the reading must be before the zero current will be accepted. the screen shows 0.02. therefore, the reading must be below 0.02 ppm before the zero will be accepted. For a typical ozone sensor, 0.02 ppm corresponds to about 7 nA. to change the zero limit value, see Section 7.6.3. Press ENtER. NOTE the number shown in the main display may change. during the zero step, the previous zero current is suppressed, and the concentration shown in the main display is calculated assuming the residual current is zero. once the transmitter accepts the new zero current, it is used in all subsequent measurements. CALIBRAtE time delay EXIt ENtER 5. the tiME dELAy message appears and remains until the zero current is below the concentration limit shown in the previous screen. If the current is already below the limit, tiME dELAy will not appear. to bypass the time delay, press ENtER. CALIBRAtE 0 dOne EXIt 6. O donE shows that the zero step is complete. Press EXIt. 7. Press RESEt to return to the main display. 83 MODEL 5081-A SECTION 12.0 CALIBRATION - OzONE 12.3 PROCEDURE — zEROING THE SENSOR USING Deltav 1. Place the sensor in the zero standard (see Section 12.1). Be sure no air bubbles are trapped against the membrane. the sensor current will drop rapidly at first and then gradually reach a stable zero value. to monitor the sensor current, go to the main display. Press dIAG followed by NEXt. the SEnSor Cur prompt appears. Press ENtER to view the sensor current. Note the units: nA is nanoamps; µA is microamps. typical zero current for an ozone sensor is -10 to +10 nanoamps. A new sensor or a sensor in which the electrolyte solution has been replace may require several hours (occasionally as long as overnight) to reach a minimum zero current. do Not StARt tHE ZERo RoutINE uNtIL tHE SENSoR HAS BEEN IN ZERo SoLutIoN FoR At LEASt tWo HouRS. 2. Access: deltaV Explorer/Context Menu Zero Amperometric Sensor (method_sensor_zero) Method Steps: a. displayed: Current ozone Measurement Zero limit Prompt: Is PV less than limit?: Yes; No; Abort NOTE Selecting “Yes” to a ozone measurement greater than the zero limit will cause the measurement to be accepted as the zero value. Selecting “No” will cause the ozone measurement to be re-read. the new ozone measurement may be closer to the zero limit. If the ozone measurement is significantly greater than the zero limit, the method should be aborted (“Abort”) and restarted after sufficient time for the ozone reading to approach the zero limit. b. If “Yes” is chosen, the Current ozone Reading and the new Zero Current Value are displayed. the method then concludes. 12.4 PROCEDURE — FULL SCALE CALIBRATION USING THE REMOTE CONTROLLER 1. Place the sensor in the process liquid. Adjust the sample flow until it is within the range recommended for the sensor. Refer to the sensor instruction sheet. 2. Adjust the ozone concentration until it is near the upper end of the control range. Wait until the reading is stable before starting the calibration. 3. Press CAL on the infrared remote controller. CALIBRAtE Sensor Cal EXIt NEXt 4. Press NEXt. the SEnSor CAL submenu appears. ENtER CALIBRAtE time delay EXIt 84 NEXt 5. Press NEXt. the tiME dELAy message appears and remains until the sensor reading meets the stability criteria set in Section 7.6. to bypass the time delay, press ENtER. NOTE As soon as the stability criteria are met (or ENtER is pressed to bypass the time delay), the transmitter stores the sensor current. therefore, if the chlorine level in the process liquid drifts while the sample is being tested, there is no need to compensate for the change when entering test results in step 7. MODEL 5081-A SECTION 12.0 CALIBRATION - OzONE CALIBRAtE Grab spl EXIt ENtER 6. the GrAb SPL (grab sample) prompt appears. take a sample of the process liquid and immediately determine the concentration of ozone in the sample. Press ENtER. CALIBRAtE Cal EXIt 3 . 20 ENtER 7. use the arrow keys to change the flashing display to the concentration of ozone determined in the grab sample. Press ENtER to save. 8. Press RESEt to return to the main display. 9. during calibration, the transmitter calculates the sensitivity (nA/ppm) of the sensor. to check the sensitivity, go to the main display. Press dIAG. Press NEXt until the SenSitvty (sensitivity) prompt appears. Press ENtER to display the sensitivity in nA/ppm. the sensitivity of a 499AoZ sensor is about 350 nA/ppm at 25°C. 12.5 PROCEDURE — FULL SCALE CALIBRATION USING Deltav 1. Place the sensor in the process liquid. Adjust the sample flow until it is within the range recommended for the sensor. Refer to the sensor instruction sheet. 2. Adjust the ozone concentration until it is near the upper end of the control range. Wait until the reading is stable before starting the calibration. 3. Access: deltaV Explorer/Context Menu Calibrate Amperometric Sensor (method_pv_cal) Method Steps: a. displayed: Current PV Measurement Prompt: Is value stable?: Yes; No; Abort If “No” is chosen, the PV measurement is re-read. b. If “Yes” is chosen, the PV measurement and the new sensitivity value are shown. the method concludes. 85 MODEL 5081-A SECTION 13.0 CALIBRATION - pH SECTION 13.0 CALIBRATION — pH 13.1 INTRODUCTION A new pH sensor must be calibrated before use. Regular recalibration is also necessary. A pH measurement cell (pH sensor and the solution to be measured) can be pictured as a battery with an extremely high internal resistance. the voltage of the battery depends on the pH of the solution. the pH meter, which is basically a voltmeter with a very high input impedance, measures the cell voltage and calculates pH using a conversion factor. the value of the voltage-to-pH conversion factor depends on the sensitivity of the pH sensing element (and the temperature). the sensing element is a thin, glass membrane at the end of the sensor. As the glass membrane ages, the sensitivity drops. Regular recalibration corrects for the loss of sensitivity. pH calibration standards, also called buffers, are readily available. two-point calibration is standard. Both automatic calibration and manual calibration are available. Auto calibration avoids common pitfalls and reduces errors. Its use is recommended. In automatic calibration the transmitter recognizes the buffer and uses temperature-corrected pH values in the calibration. the table below lists the standard buffers the controller recognizes. the transmitter also recognizes several technical buffers: Merck, Ingold, and dIN 19267. temperature-pH data stored in the controller are valid between at least 0 and 60°C. pH at 25°C (nominal pH) Standard(s) 1.68 NISt, dIN 19266, JSI 8802, BSI (see note 1) 3.56 NISt, BSI 3.78 NISt 4.01 NISt, dIN 19266, JSI 8802, BSI 6.86 NISt, dIN 19266, JSI 8802, BSI 7.00 (see note 2) 7.41 NISt 9.18 NISt, dIN 19266, JSI 8802, BSI 10.01 NISt, JSI 8802, BSI 12.45 NISt, dIN 19266 Note 1: NISt is National Institute of Standards, dIN is deutsche Institute für Normung, JSI is Japan Standards Institute, and BSI is British Standards Institute. Note 2: pH 7 buffer is not a standard buffer. It is a popular commercial buffer in the united States. during automatic calibration, the controller also measures noise and drift and does not accept calibration data until readings are stable. Calibration data will be accepted as soon as the pH reading is constant to within the factory-set limits of 0.02 pH units for 10 seconds. the stability settings can be changed. See Section 7.8. In manual calibration, the user judges when pH readings are stable. He also has to look up the pH of the buffer at the temperature it is being used and enter the value in the transmitter. once the transmitter completes the calibration, it calculates the calibration slope and offset. the slope is reported as the slope at 25°C. Figure 13-1 defines the terms. the transmitter can also be standardized. Standardization is the process of forcing the transmitter reading to match the reading from a second pH instrument. Standardization is sometimes called a one-point calibration. 86 FIGURE 13-1. Calibration Slope and Offset MODEL 5081-A SECTION 13.0 CALIBRATION - pH 13.2 PROCEDURE — AUTO CALIBRATION USING THE REMOTE CONTROLLER 1. Verify that auto calibration has been enabled. See Section 7.8. 2. obtain two buffer solutions. Ideally, the buffer pH values should bracket the range of pH values to be measured. 3. Remove the sensor from the process liquid. If the temperature of the process and buffer are appreciably different, place the sensor in a container of tap water at the buffer temperature. do not start the calibration until the sensor has reached the buffer temperature. thirty minutes is usually adequate. 4. Press CAL on the remote controller. CALIBRAtE PH Cal EXIt 5. Press NEXt until the PH CAL submenu appears. Press ENtER. NEXt ENtER CALIBRAtE 6. the AUtO CAL submenu appears. Press ENtER. AUtO CAL EXIt NEXt ENtER CALIBRAtE CAL bF1 EXIt NEXt ENtER CALIBRAtE bf1 EXIt ENtER 7. the CAL bF1 prompt appears. Rinse the sensor and place it in the first buffer. Be sure the glass bulb and reference junction are completely submerged. Swirl the sensor. the main display will show the pH of the buffer based on the previous calibration. Press ENtER. 8. bF1 flashes until the pH reading meets the stability criteria programmed in Section 7.8. CALIBRAtE bf1 4 . 01 EXIt ENtER CALIBRAtE CAL bF2 EXIt NEXt ENtER 9. once the reading is stable, the display changes to look like the figure at left. the flashing number is the nominal pH, that is, the pH of the buffer at 25°C. If the flashing number does not match the nominal pH, press é or ê until the correct pH appears. Press ENtER to save. 10. the CAL bF2 prompt appears. Remove the sensor from the first buffer. Rinse the sensor and place it in the second buffer. Be sure the glass bulb and reference junction are completely submerged. Swirl the sensor. the display will show the pH of the buffer based on the previous calibration. Press ENtER. CALIBRAtE bF2 EXIt NEXt ENtER 11. bF2 flashes until the pH reading meets the stability criteria programmed in Section 7.8. CALIBRAtE bf2 EXIt 10 . 00 ENtER 12. once the reading is stable, the display changes to look like the figure at left. the flashing number is the nominal pH, that is, the pH of the buffer at 25°C. If the flashing number does not match the nominal pH, press é or ê until the correct pH appears. Press ENtER to save. 13. Press RESEt to return to the main display. 87 MODEL 5081-A SECTION 13.0 CALIBRATION - pH 13.3 PROCEDURE — AUTO CALIBRATION USING Deltav 1. Verify that auto calibration has been enabled. See Section 7.8. 2. obtain two buffer solutions. Ideally, the buffer pH values should bracket the range of pH values to be measured. 3. Remove the sensor from the process liquid. If the temperature of the process and buffer are appreciably different, place the sensor in a container of tap water at the buffer temperature. do not start the calibration until the sensor has reached the buffer temperature. thirty minutes is usually adequate. 4. Access: deltaV Explorer/Context Menu pH Buffer Calibration (method_ph_buffer_cal) NOTE For automatic buffer calibration to occur, the parameter Buffer Standard (BuFFER_StANdARd) must be set to a buffer standard, and not “Manual”. Method Steps: a. Prompt: Place sensor in buffer 1. b. displayed: Current pH Measurement Current temperature Measurement Message: c. Waiting for pH input to stabilize. displayed: Current pH Measurement Current temperature Measurement Prompt: Is buffer = x.xx pH?: Yes; Next Buffer; Previous Buffer use the next or previous buffer buttons to choose the Buffer 1 value being used. Select “Yes” when that buffer value is reached. d. Prompt: Place sensor in buffer 2. e. displayed: Current pH Measurement Current temperature Measurement Message: f. Waiting for pH input to stabilize. displayed: Current pH Measurement Current temperature Measurement Prompt: Is buffer = y.yy pH?: Yes; Next Buffer; Previous Buffer use the next or previous buffer buttons to choose the Buffer 2 value being used. Select “Yes” when that buffer value is reached. g. If there are calibration errors, they will be displayed, and the corresponding errors will be shown in deltaV Explorer/Status/Errors tab. h. displayed: Current pH Measurement Current temperature Measurement New pH Slope Value New pH Zero offset Value the method concludes. 88 MODEL 5081-A SECTION 13.0 CALIBRATION - pH 13.4 PROCEDURE — MANUAL CALIBRATION USING THE REMOTE CONTROLLER 1. Verify that manual calibration has been enabled. See Section 7.8. 2. obtain two buffer solutions. Ideally, the buffer pH values should bracket the range of pH values to be measured. Also obtain a reliable thermometer. 3. Remove the sensor from the process liquid. If the temperature of the process and buffer are appreciably different, place the sensor in a container of tap water at the buffer temperature. do not start the calibration until the sensor has reached the buffer temperature. thirty minutes is usually adequate. 4. Press CAL on the remote controller. CALIBRAtE 5. Press NEXt until the PH CAL prompt appears. Press ENtER. PH CAL EXIt NEXt ENtER CALIBRAtE 6. the MAn CAL message appears. Press ENtER. MAn CAL EXIt NEXt ENtER CALIBRAtE CAL bf1 EXIt NEXt ENtER 7. the CAL bF1 prompt appears. Rinse the sensor and the thermometer and place them in the first buffer. Be sure the glass bulb and reference junction are completely submerged. Swirl the sensor. the main display will show the pH of the buffer based on the previous calibration. Press ENtER. CALIBRAtE bf1 04 . 01 EXIt ENtER 8. Wait until the pH reading in the main display is constant. use the arrow keys to change the flashing display to the value of the buffer at the measurement temperature. Press ENtER. CALIBRAtE CAL bf2 EXIt NEXt ENtER 9. the CAL bF2 prompt appears. Rinse the sensor and the thermometer and place them in the second buffer. Be sure the glass bulb and reference junction are completely submerged. Swirl the sensor. the main display will show the pH of the buffer based on the previous calibration. Press ENtER. CALIBRAtE bf2 EXIt 10 . 00 ENtER 10. Wait until the pH reading in the main display is constant. use the arrow keys to change the flashing display to the value of the buffer at the measurement temperature. Press ENtER. 11. Press RESEt to return to the main display. 89 MODEL 5081-A SECTION 13.0 CALIBRATION - pH 13.5 PROCEDURE — MANUAL CALIBRATION USING Deltav 1. Verify that manual calibration has been enabled. See Section 7.8. 2. obtain two buffer solutions. Ideally, the buffer pH values should bracket the range of pH values to be measured. Also obtain a reliable thermometer. 3. Remove the sensor from the process liquid. If the temperature of the process and buffer are appreciably different, place the sensor in a container of tap water at the buffer temperature. do not start the calibration until the sensor has reached the buffer temperature. thirty minutes is usually adequate. 4. Access: deltaV Explorer/Context Menu pH Buffer Calibration (method_ph_buffer_cal) NOTE For manual buffer calibration to occur, the parameter Buffer Standard (BuFFER_StANdARd) must be set to “manual”. Method Steps: a. Prompt: Place sensor in buffer 1. b. displayed: Current pH Measurement Current temperature Measurement Prompt: Are values stable?: Yes; No; Abort Selecting “No” will cause the measurements to be re-read. c. If “yes” is chosen: displayed: Current pH Measurement Current temperature Measurement Prompt: Enter buffer 1 value. d. Prompt: Place sensor in buffer 2. e. displayed: Current pH Measurement Current temperature Measurement Prompt: Are values stable?: Yes; No; Abort Selecting “No” will cause the measurements to be re-read. f. If “yes” is chosen: displayed: Current pH Measurement Current temperature Measurement Prompt: Enter buffer 2 value. g. If there are calibration errors, they will be displayed, and the corresponding errors will be shown in deltaV Explorer/Status/Errors tab. h. displayed: Current pH Measurement Current temperature Measurement New pH Slope Value New pH Zero offset Value the method concludes. 90 MODEL 5081-A SECTION 13.0 CALIBRATION - pH 13.6 STANDARDIzATION USING THE INFRARED REMOTE CONTROLLER 1. the pH measured by the transmitter can be changed to match the reading from a second or reference instrument. the process of making the two readings agree is called standardization, or one-point calibration. 2. during standardization, the difference between the two pH values is converted to the equivalent voltage. the voltage, called the reference offset, is added to all subsequent measured cell voltages before they are converted to pH. If a sensor that has been calibrated with buffers is then standardized and placed back in a buffer, the measured pH will differ from the buffer pH by an amount equivalent to the standardization offset. 3. Install the sensor in the process liquid. once readings are stable, measure the pH of the liquid using a reference instrument. Normally, it is acceptable to test a grab sample. Because the pH of the process liquid may change if the temperature changes, measure the pH immediately after taking the grab sample. For poorly buffered samples, it is best to determine the pH of a continuously flowing sample from a point as close as possible to the process sensor. 4. Press CAL on the remote controller. CALIBRAtE PH CAL EXIt 5. Press NEXt until the PH CAL submenu appears. Press ENtER. NEXt ENtER CALIBRAtE 6. Press NEXt until the Std PH submenu appears. Press ENtER. Std PH EXIt NEXt ENtER CALIBRAtE Std EXIt 07 . 00 ENtER 7. Be sure the process pH and temperature are stable. Measure the pH of the process liquid using the reference instrument. use the arrow keys to change the flashing display to match the reading from the reference meter. Press ENtER to save. 8. Press RESEt to return to the main display. 91 MODEL 5081-A SECTION 13.0 CALIBRATION - pH 13.7 STANDARDIzATION USING Deltav 1. the pH measured by the transmitter can be changed to match the reading from a second or reference instrument. the process of making the two readings agree is called standardization, or one-point calibration. 2. during standardization, the difference between the two pH values is converted to the equivalent voltage. the voltage, called the reference offset, is added to all subsequent measured cell voltages before they are converted to pH. If a sensor that has been calibrated with buffers is then standardized and placed back in a buffer, the measured pH will differ from the buffer pH by an amount equivalent to the standardization offset. 3. Install the sensor in the process liquid. once readings are stable, measure the pH of the liquid using a reference instrument. Normally, it is acceptable to test a grab sample. Because the pH of the process liquid may change if the temperature changes, measure the pH immediately after taking the grab sample. For poorly buffered samples, it is best to determine the pH of a continuously flowing sample from a point as close as possible to the process sensor. 4. Access: deltaV Explorer/Context Menu Standardize pH (method_standardize_ph) Method Steps: a. displayed: Current pH Measurement Current temperature Measurement Prompt: Are values stable?: Yes; No; Abort Selecting “No” will cause the measurements to be re-read. b. If “yes” is chosen: displayed: Current pH Measurement Current temperature Measurement New pH Zero offset the method concludes. 92 MODEL 5081-A SECTION 13.0 CALIBRATION - pH 13.8 pH SLOPE ADJUSTMENT USING THE INFRARED REMOTE CONTROLLER 1. If the slope of the glass electrode is known form other measurements, it can be entered directly into the transmitter. the slope must be entered as the slope at 25°C. to calculate the slope at 25°C from the slope at temperature t°C, use the equation: slope at 25°C = (slope at t°C) 298 t°C + 273 Changing the slope overrides the slope determined from the previous buffer calibration. 2. Press CAL on the remote controller. CALIBRAtE 3. Press NEXt until PH CAL appears. Press ENtER. pH CAL EXIt NEXt ENtER CALIBRAtE 4. Press NEXt until PH SLOPE appears. Press ENtER. pH slOpe EXIt NEXt ENtER CALIBRAtE slOpe EXIt 59 . 16 5. the SLOPE prompt appears. use the arrow keys to change the flashing display to the desired slope. Press ENtER to save. ENtER 6. Press RESEt to return to the main display. 93 MODEL 5081-A SECTION 13.0 CALIBRATION - pH 13.9 pH SLOPE ADJUSTMENT USING Deltav 1. If the slope of the glass electrode is known form other measurements, it can be entered directly into the transmitter. the slope must be entered as the slope at 25°C. to calculate the slope at 25°C from the slope at temperature t°C, use the equation: slope at 25°C = (slope at t°C) 298 t°C + 273 Changing the slope overrides the slope determined from the previous buffer calibration. 2. Access: deltaV Explorer/transducer Block/Properties, pH Compensation tab Parameter: pH slope (PH_SLoPE) Enter desired pH slope value. 94 MODEL 5081-A SECTION 14.0 DIAGNOSTICS SECTION 14.0 DIAGNOSTICS 14.1 GENERAL the 5081-A transmitter can display diagnostic information that is useful in troubleshooting. the diagnostics available depend on the measurement being made. to read diagnostic information, go to the main display and press dIAG on the infrared remote controller. Press NEXt until the mnemonic for the desired information appears. Refer to the appropriate section below for more information. 14.2 DIAGNOSTIC MESSAGES FOR DISSOLvED OxyGEN TyPE O2 SEnSor Cur transmitter is measuring oxygen. Press NEXt to view diagnostics. Press ENtER to display raw current from sensor (note units). SEnSitvty Press ENtER to display sensitivity. Sensitivity is calculated during calibration. It is the measured current divided by concentration. O CurrEnt Press ENtER to display the zero current measured during calibration (note units). bAr PreSS Press ENtER to display the barometric pressure used by the transmitter during air calibration. 5081-A-FF this is the model number. Press ENtER to display the software revision (SFtr) level. Press NEXt to show the hardware revision (HArdr) level. FAULtS Press ENtER to scroll through existing fault messages. 14.3 DIAGNOSTIC MESSAGES FOR OzONE AND TOTAL CHLORINE TyPE O3 or tCL SEnSor Cur transmitter is measuring ozone (or total chlorine). Press NEXt to view diagnostics. Press ENtER to display raw current from sensor (note units). SEnSitvty Press ENtER to display sensitivity. Sensitivity is calculated during calibration. It is the measured current divided by concentration. O CurrEnt Press ENtER to display the zero current measured during calibration (note units). 5081-A-FF this is the model number. Press ENtER to display the software revision (SFtr) level. Press NEXt to show the hardware revision (HArdr) level. FAULtS Press ENtER to scroll through existing fault messages. 95 MODEL 5081-A SECTION 14.0 DIAGNOSTICS 14.4 DIAGNOSTIC MESSAGES FOR FREE CHLORINE TyPE FCL SEnSor Cur transmitter is measuring free chlorine. Press NEXt to view diagnostics. Press ENtER to display raw current from sensor (note units). SEnSitvty Press ENtER to display sensitivity. Sensitivity is calculated during calibration. It is the measured current divided by concentration. O CurrEnt Press ENtER to display the zero current measured during calibration (note units). PH InPut Current pH sensor input voltage in millivolts. SLOPE Sensor slope in millivolts per unit pH. Slope is calculated during buffer calibration. See Figure 13.1. OFFSt Sensor voltage in millivolts in pH 7 buffer. GIMP Glass impedance in MW. 5081-A-FF FAULtS 96 Press ENtER to view pH diagnostics. Press NEXt to skip pH diagnostics. this is the model number. Press ENtER to display the software revision (SFtr) level. Press NEXt to show the hardware revision (HArdr) level. Press ENtER to scroll through existing fault messages. MODEL 5081-A SECTION 15.0 TROUBLESHOOTING SECTION 15.0 TROUBLESHOOTING 15.1 15.2 15.3 15.4 15.5 15.6 15.7 15.8 15.9 15.10 15.11 15.12 15.13 WARNING, FAULT, AND ERROR MESSAGES TROUBLESHOOTING WHEN A WARNING OR FAULT MESSAGE IS SHOWING TEMPERATURE MEASUREMENT AND CALIBRATION PROBLEMS OxyGEN MEASUREMENT AND CALIBRATION PROBLEMS FREE CHLORINE MEASUREMENT AND CALIBRATION PROBLEMS TOTAL CHLORINE MEASUREMENT AND CALIBRATION PROBLEMS OzONE MEASUREMENT AND CALIBRATION PROBLEMS pH MEASUREMENT AND CALIBRATION PROBLEMS SIMULATING INPUT CURRENTS - DISSOLvED OxyGEN SIMULATING INPUT CURRENTS - CHLORINE AND OzONE SIMULATING INPUTS - pH SIMULATING TEMPERATURE MEASURING REFERENCE vOLTAGE 15.1 WARNING, FAULT, AND ERROR MESSAGES the Model 5081-A transmitter continuously monitors the sensor and transmitter for conditions that cause erroneous measurements. When a problem occurs, the transmitter displays either a warning or fault message. A warning alerts the user that a potentially disabling condition exists. there is a high probability that the measurement is in error. A fault alerts the user that a disabling condition exists. If a fault message is showing, all measurements should be regarded as erroneous. When a WARNING condition exists: 1. the main display remains stable; it does not flash. 2. A warning message appears alternately with the temperature and output readings in the second line of the display. See Section 15.4 for an explanation of the warning messages and suggested ways of correcting the problem. When a FAULT exists: 1. the main display flashes. 2. the words FAuLt and HoLd appear in the main display. 3. A fault message appears alternately with the temperature and output readings in the second line of the display. See Section 15.4 for an explanation of the fault messages and suggested ways of correcting the problem. 4. the output current will remain at the present value or go to the programmed fault value. See Section 7.3 for details on how to program the current generated during a fault condition. 5. If the transmitter is in HoLd when the fault occurs, the output remains at the programmed hold value. to alert the user that a fault exists, the word FAuLt appears in the main display, and the display flashes. A fault or diagnostic message also appears. 6. If the transmitter is simulating an output current when the fault occurs, the transmitter continues to generate the simulated current. to alert the user that a fault exists, the word FAuLt appears in the display, and the display flashes. When an ERROR exists: 1. the main display remains stable; it does not flash. 2. A description of the error appears. Error messages typically appear during calibration. 97 MODEL 5081-A SECTION 15.0 TROUBLESHOOTING 15.2 TROUBLESHOOTING WHEN A FAULT, WARNING, OR ERROR MESSAGE IS SHOWING Fault Explanation RTD OPEn Rtd measuring circuit is open. 15.2.1 bAd rtd Rtd resistance is outside the range expected for a Pt100 or 22k NtC. 15.2.1 PHgLASS HI pH glass impedance exceeds programmed limit. 15.2.2 PHgLASS LO pH glass impedance is below programmed limit. 15.2.2 AdC FAIL Analog to digital conversion has failed. 15.2.3 Warning Explanation OuEr rAngE Process variable exceeds the display limit. 15.2.4 In Curr HI Sensor input current exceeds 210 uA. 15.2.4 In Curr LO Sensor input current is a large negative number. 15.2.4 NEED 0 CAL Sensor needs zeroing. Concentration is a large negative number. 15.2.5 tEMP HI temperature reading exceeds 150°C. 15.2.1 tEMP LO temperature reading is less than -15°C 15.2.1 SEnSE OPEn Rtd sense line is open or not connected. 15.2.1 PH In HI mV signal from pH sensor is too big (chlorine only). 15.2.6 NO SOLngnd Solution ground terminal is not connected. 15.2.7 EECHECSUn An EEPRoM byte changed unexpectedly. 15.2.8 EE OF during setup or burn, EEPRoM command list overflowed. 15.2.9 EE Error EEPRoM byte failed to verify. 15.2.10 bAd Gnd Bad ground exists. 15.2.11 FACtCAL transmitter needs factory calibration. 15.2.12 Error Explanation SLOPE HI Glass electrode slope exceeds 62 mV/pH. 15.2.13 SLOPE LO Glass electrode slope is less than 40 mV/pH. 15.2.13 0 OFFSEt Zero offset exceeds programmed limit. 15.2.14 CAL ErrOr Amperometric sensor sensitivity (nA/ppm) is very large or very small 15.2.15 EEProtECt EEPRoM is write protected 15.2.16 98 See Section See Section See Section MODEL 5081-A SECTION 15.0 TROUBLESHOOTING 15.2.1 RTD OPEn, bAd RTd, tEMP HI, tEMP LO, and SenSE OPEn these messages usually mean that the Rtd (or thermistor in the case of the HX438 and GX448 sensors) is open or shorted or there is an open or short in the connecting wiring. 1. Verify all wiring connections, including wiring in a junction box, if one is being used. 2. disconnect the Rtd IN, Rtd SENSE, and Rtd REtuRN leads or the thermistor leads at the transmitter. Be sure to note the color of the wire and where it was attached. Measure the resistance between the Rtd IN and REtuRN leads. For a thermistor, measure the resistance between the two leads. the resistance should be close to the value in the table in Section 15.14.2. If the temperature element is open (infinite resistance) or shorted (very low resistance), replace the sensor. In the meantime, use manual temperature compensation. 3. For oxygen measurements using the HX438 and GX448 sensors, or other steam-sterilizable sensor using a 22kNtC, the temperature High error will appear if the transmitter was not properly configured. See Section 7.4. 15.2.2 pHgLASS HI and pHgLASS LO these messages mean that the pH sensor glass impedence is outside the programmed limits. to read the glass impedance, go to the main display and press dIAG. Scroll to the PH prompt and press ENtER. Press NEXt until GIMP (glass impedance) is showing. the default lower limit is 10 MW. the default upper limit is 1000 MW. Low glass impedance means the glass membrane is broken or cracked. High glass impedance means the membrane is aging and nearing the end of its useful life. High impedance can also mean the pH sensor is not completely submerged in the process liquid. 1. Check sensor wiring, including connections in a junction box. 2. Verify that the sensor is completely submerged in the process liquid. 3. Verify that the software switch identifying the position of the preamplifier is properly set. See Section 7.8.3. 4. Check the sensor response in buffers. If the sensor can be calibrated, it is in satisfactory condition. to disable the GLASS FAIL message reprogram the glass impedance limits to include the measured impedance. If the sensor cannot be calibrated, it has failed and must be replaced. 15.2.3 AdC FAIL the analog to digital converter has probably failed. 1. Verify that sensor wiring is correct and connections are tight. Be sure to check connections at the junction box if one is being used. See Section 3.1 for wiring information. 2. disconnect the sensor(s) and simulate temperature and sensor input. To simulate See Section dissolved oxygen 15.11 ozone, monochloramine, chlorine 15.12 pH 15.13 temperature 15.14 3. If the transmitter does not respond to simulate signals, call the factory for assistance. 99 MODEL 5081-A SECTION 15.0 TROUBLESHOOTING 15.2.4 OuEr rAngE, In Curr HI, and In Curr LO the first two messages imply that the amperometric sensor current is very high (greater than 210 µA) or the sensor current has a very large negative number. Normally, excessive current or negative current implies that the amperometric sensor is miswired or has failed. occasionally, these messages may appear when a new sensor is first placed in service. 1. Verify that wiring is correct and connections are tight. Be sure to check connections at the junction box if one is being used. Pay particular attention the anode and cathode connections. 2. Verify that the transmitter is configured for the correct measurement. See Section 7.4. Configuring the measurements sets (among other things) the polarizing voltage. Applying the wrong polarizing voltage to the sensor can cause a large negative current. 3. If the sensor was just placed in service, put the sensor in the zero solution and observe the sensor current. It should be moving fairly quickly toward zero. to view the sensor current go to the main display and press ê until Input Current appears. Note the units: nA is nanoamps, µA is microamps. 4. Replace the sensor membrane and electrolyte solution and clean the cathode if necessary. See the sensor instruction sheet for details. 5. Replace the sensor. 15.2.5 nEED 0 CAL Need Zero Cal means the measured concentration is a large negative number. the transmitter subtracts the zero current from the measured current before converting the result to a concentration reading. If the zero current is much greater than the measured current, the concentration reading will be negative. 1. Check the zero current and the present sensor current. to view the zero current, go to the main display and press ê until zero Current appears. the value shown is the zero current the last time the sensor was zeroed. to view the present sensor current, go to the main display and press ê until Input Current appears. Note the units: nA is nanoamps, µA is microamps. 2. Refer to the appropriate section for calibrating the sensor. Place the sensor in the zero solution. Verify that the sensor reading is within or at least very close to the zero current limits. It may take as long as overnight for the sensor to reach a stable zero current. 15.2.6 PH In HI pH In means the voltage from the pH measuring cell is too large. 1. Verify all wiring connections, including connections in a junction box. 2. Check that the pH sensor is completely submerged in the process liquid. 3. Check the pH sensor for cleanliness. If the sensor looks fouled or dirty, clean it. Refer to the sensor instruction manual for cleaning procedures. 4. Replace the sensor. 15.2.7 No SOLngnd In the transmitter, the solution ground (Soln GNd) terminal is connected to instrument common. Normally, unless the pH sensor has a solution ground, the reference terminal must be jumpered to the solution ground terminal. HOWEvER, WHEN THE pH SENSOR IS USED WITH A FREE CHLORINE SENSOR THIS CONNECTION IS NEvER MADE. 100 MODEL 5081-A SECTION 15.0 TROUBLESHOOTING 15.2.8 EECHECSUn EE Chksum Error means a software setting changed when it was not supposed to. the EEPRoM may be going bad. Call the factory for assistance. 15.2.9 EEOF EE Buffer Overflow means the software is trying to change too many background variables at once. Remove power from the transmitter for about 30 seconds. If the warning message does not disappear once power is restored, call the factory for assistance. 15.2.10 EE Error EE Write Error usually means at least one byte in the EEPRoM has gone bad. try entering the data again. If the error message continues to appear, call the factory for assistance. 15.2.11 bAd gnd this warning message means there is a problem with the analog circuitry. Call the factory for assistance. 15.2.12 FACtCAL this warning message means the transmitter requires factory calibration. Call the factory for assistance. 15.2.13 SLOPE HI or SLOPE LO once the two-point (manual or automatic) pH calibration is complete, the transmitter automatically calculates the sensor slope at 25°C. If the slope is greater than 62 mV/pH the transmitter displays the SLOPE HI error. If the slope is less than 45 mV/pH, the transmitter displays the SLOPE LO error. the transmitter will not update the calibration. 1. Check the buffers. Inspect the buffer solutions for obvious signs of deterioration, such as turbidity or mold growth. Neutral and slightly acidic buffers are highly susceptible to molds. Alkaline buffers (pH 9 and greater), if they have been exposed to air for long periods, may also be inaccurate. Alkaline buffers absorb carbon dioxide from the atmosphere, which lowers the pH. If a high pH buffer was used in the failed calibration, repeat the calibration using fresh buffer. If fresh buffer is not available, use a lower pH buffer. For example, use pH 4 and pH 7 buffer instead of pH 7 and pH 10 buffer. 2. Allow adequate time for temperature equilibration. If the sensor was in a process liquid substantially hotter or colder than the buffer, place it in a container of water at ambient temperature for at least 20 minutes before starting the calibration. 3. If manual calibration was done, verify that correct pH values were entered. 4. Verify all wiring connections, including connections at a junction box. 5. Check the pH sensor for cleanliness. If the sensor looks fouled or dirty, clean it. Refer to the sensor instruction manual for cleaning procedures. 6. Replace the sensor. 101 MODEL 5081-A SECTION 15.0 TROUBLESHOOTING 15.2.14 0 OFFSEt the -0- OFFSEt message appears if the standardization offset (in mV) exceeds the programmed limit. the default limit is 60 mV, which is equivalent to about a unit change in pH. Before increasing the limit to make the -0- OFFSEt message disappear, check the following: 1. Verify that the reference pH meter is working properly and is properly calibrated. 2. Verify that the process pH sensor is working. Check its response in buffers. 3. If the transmitter is standardized against pH determined in a grab sample, be sure to measure the pH before the temperature of the grab sample changes more than a few degrees. 4. Verify that the process sensor is fully immersed in the liquid. If the sensor is not completely submerged, it may be measuring the pH of the liquid film covering the sensor. the pH of this film may be different from the pH of the bulk liquid. 5. Check the pH sensor for cleanliness. If the sensor looks fouled or dirty, clean it. Refer to the sensor instruction manual for cleaning procedures. 6. A large standardization offset may be caused by a poisoned reference electrode. Poisoning agents can cause the pH to be offset by as much as two pH units. to check the reference voltage, see Section 15.13. 15.2.15 CAL ErrOr CAL ErrOr appears following a calibration attempt if the new sensitivity is much less or much greater than the value typically expected for the sensor. 1. Verify that the sensor is properly wired to the transmitter. 2. Verify that the sample flow past the sensor is correct and that no air bubbles are trapped against the membrane. For recommended sample flows, refer to the sensor instruction sheet. 3. Verify that the membrane is clean. For oxygen sensors being calibrated in air, also verify that the membrane is dry. For free chlorine measurements using continuous pH correction, verify that the pH sensor is clean. 4. Verify that the laboratory test being used to measure concentrations is accurate. 15.2.16 EEProtECt Program settings in the 5081-A can be protected against accidental changes by setting a three-digit security code. Settings can further be protected by removing a jumper (JP-1) from the CPu board. If JP-1 has been removed program, settings cannot be changed. 15.3 TEMPERATURE MEASUREMENT AND CALIBRATION PROBLEMS 15.3.1 Temperature measured by standard was more than 1°C different from transmitter. 1. Is the standard thermometer, Rtd, or thermistor accurate? General purpose liquid-in-glass thermometers, particularly ones that have been mistreated can have surprisingly large errors. 2. Is the temperature element in the sensor completely submerged in the liquid? 3. Is the standard temperature sensor submerged to the correct level? 102 MODEL 5081-A SECTION 15.0 TROUBLESHOOTING 15.4 OxyGEN MEASUREMENT AND CALIBRATION PROBLEMS Problem See Section Zero current is substantially greater than the value in Section 9.2 15.4.1 Zero reading is unstable 15.4.2 Sensor current during air calibration is substantially different from the value in Section 9.3 15.4.3 Process and standard instrument readings during in-process calibration are substantially different 15.4.4 Process readings are erratic 15.4.5 Readings drift 15.4.6 Sensor does not respond to changes in oxygen level 15.4.7 Readings are too low 15.4.8 15.4.1 zero current is substantially greater than the value in Section 9.2. 1. Is the sensor properly wired to the transmitter? See Section 3.0. 2. Is the membrane completely covered with zero solution and are air bubbles not trapped against the membrane? Swirl and tap the sensor to release air bubbles. 3. Is the zero solution fresh and properly made? Zero the sensor in a solution of 5% sodium sulfite in water. Prepare the solution immediately before use. It has a shelf life of only a few days. 4. If the sensor is being zeroed with nitrogen gas, verify that the nitrogen is oxygen-free and the flow is adequate to prevent back-diffusion of air into the chamber. 5. the major contributor to the zero current is dissolved oxygen in the electrolyte solution inside the sensor. A long zeroing period usually means that an air bubble is trapped in the electrolyte. to ensure the 499Ado or 499A trdo sensor contains no air bubbles, carefully follow the procedure in the sensor manual for filling the sensor. If the electrolyte solution has just been replaced, allow several hours for the zero current to stabilize. on rare occasions, the sensor may require as long as overnight to zero. 6. Check the membrane for damage and replace the membrane if necessary 15.4.2 zero reading is unstable. 1. Is the sensor properly wired to the transmitter? See Section 3.0. Verify that all wiring connections are tight. 2. Readings are often erratic when a new or rebuilt sensor is first placed in service. Readings usually stabilize after an hour. 3. Is the space between the membrane and cathode filled with electrolyte solution and is the flow path between the electrolyte reservoir and the membrane clear? often the flow of electrolyte can be started by simply holding the sensor with the membrane end pointing down and sharply shaking the sensor a few times as though shaking down a clinical thermometer. If shaking does not work, perform the checks below. Refer to the sensor instruction manuals for additional information. For 499Ado and 499A trdo sensors, verify that the holes at the base of the cathode stem are open (use a straightened paperclip to clear the holes). Also verify that air bubbles are not blocking the holes. Fill the reservoir and establish electrolyte flow to the cathode. Refer to the sensor instruction manual for the detailed procedure. For Gx438 and Hx438 sensors, the best way to ensure that there is an adequate supply of electrolyte solution is to simply add fresh electrolyte solution to the sensor. Refer to the sensor instruction manual for details. 103 MODEL 5081-A SECTION 15.0 TROUBLESHOOTING 15.4.3 Sensor current during air calibration is substantially different from the value in Section 9.3. 1. Is the sensor properly wired to the transmitter? See Section 3.0. Verify that all connections are tight. 2. Is the membrane dry? the membrane must be dry during air calibration. A droplet of water on the membrane during air calibration will lower the sensor current and cause an inaccurate calibration. 3. If the sensor current in air is very low and the sensor is new, either the electrolyte flow has stopped or the membrane is torn or loose. For instructions on how to restart electrolyte flow see Section 15.4.2 or refer to the sensor instruction manual. to replace a torn membrane, refer to the sensor instruction manual. 4. Is the temperature low? Sensor current is a strong function of temperature. the sensor current decreases about 3% for every °C drop in temperature. 5. Is the membrane fouled or coated? A dirty membrane inhibits diffusion of oxygen through the membrane, reducing the sensor current. Clean the membrane by rinsing it with a stream of water from a wash bottle or by gently wiping the membrane with a soft tissue. If cleaning the membrane does not improve the sensor response, replace the membrane and electrolyte solution. If necessary, polish the cathode. See the sensor instruction sheet for more information. 15.4.4 Process and standard instrument readings during in-process calibration are substantially different. this error warning appears if the current process reading and the reading it is being changed to, ie, the reading from the standard instrument, are appreciably different. 1. Is the standard instrument properly zeroed and calibrated? 2. Are the standard and process sensor measuring the same sample? Place the sensors as close together as possible. 3. Is the process sensor working properly? Check the response of the process sensor in air and in sodium sulfite solution. 15.4.5 Process readings are erratic. 1. 2. 3. 4. 5. 6. Readings are often erratic when a new sensor or a rebuilt sensor is first placed in service. the current usually stabilizes after a few hours. Is the sample flow within the recommended range? High sample flow may cause erratic readings. Refer to the sensor instruction manual for recommended flow rates. Gas bubbles impinging on the membrane may cause erratic readings. orienting the sensor at an angle away from vertical may reduce the noise. the holes between the membrane and electrolyte reservoir might be plugged (applies to Models 499A do and 499A trdo sensors only). Refer to Section 15.4.2. Verify that wiring is correct. Pay particular attention to shield and ground connections. Is the membrane in good condition and is the sensor filled with electrolyte solution? Replace the fill solution and electrolyte. Refer to the sensor instruction manual for details. 15.4.6 Readings drift. 1. 2. 3. 4. 5. 104 Is the sample temperature changing? Membrane permeability is a function of temperature. For the 499Ado and 499Atrdo sensors, the time constant for response to a temperature change is about five (5) minutes. therefore, the reading may drift for a while after a sudden temperature change. the time constant for the Gx438 and Hx448 sensors is much shorter; these sensors respond fairly rapidly to temperature changes. Is the membrane clean? For the sensor to work properly oxygen must diffuse freely through the membrane. A coating on the membrane will interfere with the passage of oxygen, resulting in slow response. Is the sensor in direct sunlight? If the sensor is in direct sunlight during air calibration, readings will drift as the sensor warms up. Because the temperature reading lags the true temperature of the membrane, calibrating the sensor in direct sunlight may introduce an error. Is the sample flow within the recommended range? Gradual loss of sample flow will cause downward drift. Is the sensor new or has it been recently serviced? New or rebuilt sensors may require several hours to stabilize. MODEL 5081-A SECTION 15.0 TROUBLESHOOTING 15.4.7 Sensor does not respond to changes in oxygen level. 1. 2. 3. If readings are being compared with a portable laboratory instrument, verify that the laboratory instrument is working. Is the membrane clean? Clean the membrane and replace it if necessary. Check that the holes at the base of the cathode stem are open. use a straightened paper clip to clear blockages. Replace the electrolyte solution. Replace the sensor. 15.4.8 Oxygen readings are too low. 1. 2. Low readings can be caused by zeroing the sensor before the residual current has reached a stable minimum value. Residual current is the current the sensor generates even when no oxygen is in the sample. Because the residual current is subtracted from subsequent measured currents, zeroing before the current is a minimum can lead to low results. Example: the true residual (zero) current for a 499Ado sensor is 0.05 mA, and the sensitivity based on calibration in watersaturated air is 2.35 mA/ppm. Assume the measured current is 2.00 mA. the true concentration is (2.00 - 0.05)/2.35 or 0.83 ppm. If the sensor was zeroed prematurely when the current was 0.2 mA, the measured concentration will be (2.00 - 0.2)/2.35 or 0.77 ppm. the error is 7.2%. Suppose the measured current is 5.00 mA. the true concentration is 2.11 ppm, and the measured concentration is 2.05 ppm. the error is now 3.3%. the absolute difference between the readings remains the same, 0.06 ppm. Sensor response depends on flow. If the flow is too low, readings will be low and flow sensitive. Verify that the flow past the sensor equals or exceeds the minimum value. See the sensor instruction manual for recommended flows. If the sensor is in an aeration basin, move the sensor to an area where the flow or agitation is greater. 15.5 FREE CHLORINE MEASUREMENT AND CALIBRATION PROBLEMS Problem See Section Zero current is substantially outside the range -10 to 10 nA 15.5.1 Zero reading is unstable 15.5.2 Sensor current during calibration is substantially less than about 250 nA/ppm at 25°C and pH 7 15.5.3 Process readings are erratic 15.5.4 Readings drift 15.5.5 Sensor does not respond to changes in chlorine level 15.5.6 Chlorine reading spikes following rapid change in pH (automatic pH correction only) 15.5.7 Readings are too low 15.5.8 15.5.1 zero current is substantially outside the range -10 to 10 nA. 1. Is the sensor properly wired to the transmitter? See Section 3.0. 2. Is the zero solution chlorine-free? take a sample of the solution and test it for free chlorine level. the concentration should be less than 0.02 ppm. 3. Has adequate time been allowed for the sensor to reach a minimum stable residual current? It may take several hours, sometimes as long as overnight, for a new sensor to stabilize. 4. Check the membrane for damage and replace it if necessary. 105 MODEL 5081-A SECTION 15.0 TROUBLESHOOTING 15.5.2 zero reading is unstable. 1. Is the sensor properly wired to the transmitter? See Section 3.0. Verify that all wiring connections are tight. 2. Readings are often erratic when a new or rebuilt sensor is first placed in service. Readings usually stabilize after about an hour. 3. Is the conductivity of the zero solution greater than 50 mS/cm? do Not uSE dEIoNIZEd oR dIStILLEd WAtER to ZERo tHE SENSoR. the zero solution should contain at least 0.5 grams of sodium chloride per liter. 4. Is the space between the membrane and cathode filled with electrolyte solution and is the flow path between the electrolyte reservoir and membrane clear? often the flow of electrolyte and be started by simply holding the sensor with the membrane end pointing down and sharply shaking the sensor a few times as though shaking down a clinical thermometer. If shaking does not work, try clearing the holes around the cathode stem. Hold the sensor with the membrane end pointing up. unscrew the membrane retainer and remove the membrane assembly. Be sure the wood ring remains with the membrane assembly. use the end of a straightened paper clip to clear the holes at the base of the cathode stem. Replace the membrane. Verify that the sensor is filled with electrolyte solution. Refer to the sensor instruction manual for details. 15.5.3 Sensor current during calibration is substantially less than 250 nA/ppm at 25°C and pH 7. 1. Is the temperature low or is the pH high? Sensor current is a strong function of pH and temperature. the sensor current decreases about 3% for every °C drop in temperature. Sensor current also decreases as pH increases. Above pH 7, a 0.1 unit increase in pH lowers the current about 5%. 2. Sensor current depends on the rate of sample flow past the sensor tip. If the flow is too low, chlorine readings will be low. Refer to the sensor instruction sheet for recommended sample flows. 3. Low current can be caused by lack of electrolyte flow to the cathode and membrane. See step 4 in Section 15.5.2. 4. Is the membrane fouled or coated? A dirty membrane inhibits diffusion of free chlorine through the membrane, reducing the sensor current and increasing the response time. Clean the membrane by rinsing it with a stream of water from a wash bottle. do Not use a membrane or tissue to wipe the membrane. 5. If cleaning the membrane does not improve the sensor response, replace the membrane and electrolyte solution. If necessary, polish the cathode. See the sensor instruction sheet for details. 15.5.4 Process readings are erratic. 1. Readings are often erratic when a new sensor or a rebuilt sensor is first placed in service. the current usually stabilizes after a few hours. 2. Is the sample flow within the recommended range? High sample flow may cause erratic readings. Refer to the sensor instruction sheet for recommended flow rates. 3. Are the holes between the membrane and the electrolyte reservoir open. Refer to Section 15.5.2. 4. Verify that wiring is correct. Pay particular attention to shield and ground connections. 5. If automatic pH correction is being used, check the pH reading. If the pH reading is noisy, the chlorine reading will also be noisy. If the pH sensor is the cause of the noise, use manual pH correction until the problem with the pH sensor can be corrected. 6. Is the membrane in good condition and is the sensor filled with electrolyte solution? Replace the fill solution and electrolyte. Refer to the sensor instruction manual for details. 106 MODEL 5081-A SECTION 15.0 TROUBLESHOOTING 15.5.5 Readings drift. 1. Is the sample temperature changing? Membrane permeability is a function of temperature. the time constant for the 499ACL-01 sensor is about five minutes. therefore, the reading may drift for a while after a sudden temperature change. 2. Is the membrane clean? For the sensor to work properly, chlorine must diffuse freely through the membrane. A coating on the membrane will interfere with the passage of chlorine, resulting in slow response. Clean the membrane by rinsing it with a stream of water from a wash bottle. DO NOT use a membrane or tissue to wipe the membrane. 3. Is the sample flow within the recommended range? Gradual loss of sample flow will cause a downward drift. 4. Is the sensor new or has it been recently serviced? New or rebuilt sensors may require several hours to stabilize. 5. Is the pH of the process changing? If manual pH correction is being used, a gradual change in pH will cause a gradual change in the chlorine reading. As pH increases, chlorine readings will decrease, even though the free chlorine level (as determined by a grab sample test) remained constant. If the pH change is no more than about 0.2, the change in the chlorine reading will be no more than about 10% of reading. If the pH changes are more than 0.2, use automatic pH correction. 15.5.6 Sensor does not respond to changes in chlorine level. 1. Is the grab sample test accurate? Is the grab sample representative of the sample flowing to the sensor? 2. Is the pH compensation correct? If the transmitter is using manual pH correction, verify that the pH value in the transmitter equals the actual pH to within ±0.1 pH. If the transmitter is using automatic pH correction, check the calibration of the pH sensor. 3. Is the membrane clean? Clean the membrane and replace it if necessary. Check that the holes at the base of the cathode stem are open. use a straightened paper clip to clear blockages. Replace the electrolyte solution. 4. Replace the sensor. 15.5.7 Chlorine readings spike following sudden changes in pH. Changes in pH alter the relative amounts of hypochlorous acid (HoCl) and hypochlorite ion (oCl-) in the sample. Because the sensor responds only to HoCl, an increase in pH causes the sensor current (and the apparent chlorine level) to drop even though the actual free chlorine concentration remained constant. to correct for the pH effect, the transmitter automatically applies a correction. Generally, the pH sensor responds faster than the chlorine sensor. After a sudden pH change, the transmitter will temporarily over-compensate and gradually return to the correct value. the time constant for return to normal is about five (5) minutes. 15.5.8 Chlorine readings are too low. 1. Was the sample tested as soon as it was taken? Chlorine solutions are unstable. test the sample immediately after collecting it. Avoid exposing the sample to sunlight. 2. Low readings can be caused by zeroing the sensor before the residual current has reached a stable minimum value. Residual current is the current the sensor generates even when no chlorine is in the sample. Because the residual current is subtracted from subsequent measured currents, zeroing before the current is a minimum can lead to low results. See Section 15.4.8 for more information. 3. Sensor response depends on flow. If the flow is too low, readings will be low and flow sensitive. Verify that the flow past the sensor equals or exceeds the minimum value. See the sensor instruction manual for recommended flows. 15.6 TOTAL CHLORINE MEASUREMENT AND CALIBRATION PROBLEMS Refer to the instruction manual for the SCS921 for a complete troubleshooting guide. 107 MODEL 5081-A SECTION 15.0 TROUBLESHOOTING 15.7 OzONE MEASUREMENT AND CALIBRATION PROBLEMS Problem See Section Zero current is substantially outside the range -10 to 10 nA 15.7.1 Zero reading is unstable 15.7.2 Sensor current during calibration is substantially less than about 350 nA/ppm at 25°C 15.7.3 Process readings are erratic 15.7.4 Readings drift 15.7.5 Sensor does not respond to changes in ozone level 15.7.6 ozone readings are too low 15.7.7 15.7.1 zero current is substantially outside the range -10 to 10 nA. 1. Is the sensor properly wired to the transmitter? See Section 3.0. 2. Is the zero solution ozone free? test the zero solution for ozone level. the concentration should be less than 0.02 ppm. 3. Has adequate time been allowed for the sensor to reach a minimum stable residual current? It may take several hours, sometimes as long as overnight, for a new sensor to stabilize. 4. Check the membrane for damage and replace it if necessary. 15.7.2 zero reading is unstable. 1. Is the sensor properly wired to the transmitter? See Section 3.0. Verify that all wiring connections are tight. 2. Readings are often erratic when a new or rebuilt sensor is first placed in service. Readings usually stabilize after about an hour. 3. Is the space between the membrane and cathode filled with electrolyte solution and is the flow path between the electrolyte reservoir and membrane clear? often the flow of electrolyte and be started by simply holding the sensor with the membrane end pointing down and sharply shaking the sensor a few times as though shaking down a clinical thermometer. If shaking does not work, try clearing the holes around the cathode stem. Hold the sensor with the membrane end pointing up. unscrew the membrane retainer and remove the membrane assembly. Be sure the wood ring remains with the membrane assembly. use the end of a straightened paper clip to clear the holes at the base of the cathode stem. Replace the membrane. Verify that the sensor is filled with electrolyte solution. Refer to the sensor instruction manual for details. 15.7.3 Sensor current during calibration is substantially less than 350 nA/ppm at 25°C. 1. Sensor current is a strong function of temperature. the sensor current decreases about 3% for every °C drop in temperature. 2. Sensor current depends on the rate of sample flow past the sensor tip. If the flow is too low, ozone readings will be low. Refer to the sensor instruction sheet for recommended sample flows. 3. Low current can be caused by lack of electrolyte flow to the cathode and membrane. See step 3 in Section 15.7.2. 4. Is the membrane fouled or coated? A dirty membrane inhibits diffusion of ozone through the membrane, reducing the sensor current and increasing the response time. Clean the membrane by rinsing it with a stream of water from a wash bottle or gently wipe the membrane with a soft tissue. If cleaning the membrane does not improve the sensor response, replace the membrane and electrolyte solution. If necessary, polish the cathode. See the sensor instruction sheet for details. 108 MODEL 5081-A SECTION 15.0 TROUBLESHOOTING 15.7.4 Process readings are erratic. 1. Readings are often erratic when a new sensor or a rebuilt sensor is first placed in service. the current usually stabilizes after a few hours. 2. Is the sample flow within the recommended range? High sample flow may cause erratic readings. Refer to the sensor instruction sheet for recommended flow rates. 3. Are the holes between the membrane and the electrolyte reservoir open. Refer to Section 15.7.2. 4. Verify that wiring is correct. Pay particular attention to shield and ground connections. 5. Is the membrane in good condition and is the sensor filled with electrolyte solution? Replace the fill solution and electrolyte. Refer to the sensor instruction manual for details. 15.7.5 Readings drift. 1. Is the sample temperature changing? Membrane permeability is a function of temperature. the time constant for the 499AoZ sensor is about five minutes. therefore, the reading may drift for a while after a sudden temperature change. 2. Is the membrane clean? For the sensor to work properly, ozone must diffuse freely through the membrane. A coating on the membrane will interfere with the passage of ozone, resulting in slow response. Clean the membrane by rinsing it with a stream of water from a wash bottle, or gently wipe the membrane with a soft tissue. 3. Is the sample flow within the recommended range? Gradual loss of sample flow will cause a downward drift. 4. Is the sensor new or has it been recently serviced. New or rebuilt sensors may require several hours to stabilize. 15.7.6 Sensor does not respond to changes in ozone level. 1. Is the grab sample test accurate? Is the grab sample representative of the sample flowing to the sensor? 2. Is the membrane clean? Clean the membrane and replace it if necessary. Check that the holes at the base of the cathode stem are open. use a straightened paper clip to clear blockages. Replace the electrolyte solution. 3. Replace the sensor. 15.7.7 Ozone readings are too low. 1. Was the sample tested as soon as it was taken? ozone solutions are highly unstable. test the sample immediately after collecting it. 2. Low readings can be caused by zeroing the sensor before the residual current has reached a stable minimum value. Residual current is the current the sensor generates even when no ozone is in the sample. Because the residual current is subtracted from subsequent measured currents, zeroing before the current is a minimum can lead to low results. See Section 15.4.8 for more information. 3. Sensor response depends on flow. If the flow is too low, readings will be low and flow sensitive. Verify that the flow past the sensor equals or exceeds the minimum value. See the sensor instruction manual for recommended flows. 109 MODEL 5081-A SECTION 15.0 TROUBLESHOOTING 15.8 pH MEASUREMENT AND CALIBRATION PROBLEMS Problem See Section SLoPE HI or SLoPE Lo message is showing 15.8.1 -0- oFFSEt message is showing 15.8.2 transmitter will not accept manual slope 15.8.3 Sensor does not respond to known pH changes 15.8.4 Process pH is slightly different from the expected value 15.8.5 Process pH reading changes when flow changes 15.8.6 Process pH is grossly wrong and/or noisy 15.8.7 Process readings are noisy 15.8.8 15.8.1 SLOPE HI or SLOPE LO message is showing. Refer to Section 15.2.9 for assistance. 15.8.2 -0- OFFSEt message is showing. Refer to Section 15.2.10 for assistance. 15.8.3 Transmitter will not accept manual slope. If the sensor slope is known from other sources, it can be entered directly into the transmitter. the transmitter will not accept a slope (at 25°) outside the range 45 to 60 mV/pH. If the user attempts to enter a slope less than 45 mV/pH, the transmitter will automatically change the entry to 45. If the user attempts to enter a slope greater than 60 mV/pH, the transmitter will change the entry to 60 mV/pH. See Section 14.8.1 for troubleshooting sensor slope problems. 15.8.4 Sensor does not respond to known pH changes. 1. did the expected pH change really occur? If the process pH reading was not what was expected, check the performance of the sensor in buffers. Also, use a second pH meter to verify the change. 2. Is the sensor properly wired to the transmitter? 3. Is the glass bulb cracked or broken? Check the glass electrode impedance. See Section 14.1 4. Is the transmitter working properly. Check the transmitter by simulating the pH input. 15.8.5 Process pH is slightly different from the expected value. differences between pH readings made with an on-line instrument and a laboratory or portable instrument are normal. the on-line instrument is subject to process variables, for example ground potentials, stray voltages, and orientation effects that may not affect the laboratory or portable instrument. to make the process reading agree with a reference instrument, see Section 13.4. 15.8.6 Process pH reading changes when flow changes. the 399 pH sensor recommended for use with the 5081A transmitter has some degree of flow sensitivity, i.e., changing the sample flow causes the pH reading to change. Flow sensitivity varies from sensor to sensor. Flow sensitivity can be a source of error if the pH and chlorine sensor flow cells are connected in series. the chlorine sensor requires a fairly rapidly flowing sample, and high flows may affect the pH reading. typically, the difference in pH reading from a 399 pH sensor in a rapidly (16 gph) and slowly (<2 gph) flowing sample is less than about 0.05. If the change is greater than 0.05, the pH and chlorine sensors should be installed in parallel streams. 110 MODEL 5081-A SECTION 15.0 TROUBLESHOOTING 15.8.7 Process pH is grossly wrong and/or noisy. Grossly wrong or noisy readings suggest a ground loop (measurement system connected to earth ground at more than one point), a floating system (no earth ground), or noise being brought into the transmitter by the sensor cable. the problem arises from the process or installation. It is not a fault of the transmitter. the problem should disappear once the sensor is taken out of the system. Check the following: 1. Is a ground loop present? a. Verify that the system works properly in buffers. Be sure there is no direct electrical connection between the buffer containers and the process liquid or piping. b. Strip back the ends of a heavy gauge wire. Connect one end of the wire to the process piping or place it in the process liquid. Place the other end of the wire in the container of buffer with the sensor. the wire makes an electrical connection between the process and sensor. c. If offsets and noise appear after making the connection, a ground loop exists. 2. Is the process grounded? a. the measurement system needs one path to ground: through the process liquid and piping. Plastic piping, fiberglass tanks, and ungrounded or poorly grounded vessels do not provide a path. A floating system can pick up stray voltages from other electrical equipment. b. Ground the piping or tank to a local earth ground. c. If noise still persists, simple grounding is not the problem. Noise is probably being carried into the instrument through the sensor wiring. 3. Simplify the sensor wiring. a. First, verify that pH sensor wiring is correct. b. disconnect all sensor wires at the transmitter except pH/mV IN, REFERENCE IN, Rtd IN and Rtd REtuRN. See the wiring diagrams in Section 3.0. If the sensor is wired to the transmitter through a remote junction box containing a preamplifier, disconnect the wires at the sensor side of the junction box. c. tape back the ends of the disconnected wires to keep them from making accidental connections with other wires or terminals. d. Connect a jumper wire between the Rtd REtuRN and Rtd SENSE terminals (see wiring diagrams in Section 3.0). e. If noise and/or offsets disappear, the interference was coming into the transmitter through one of the sensor wires. the system can be operated permanently with the simplified wiring. 4. Check for extra ground connections or induced noise. a. If the sensor cable is run inside conduit, there may be a short between the cable and the conduit. Re-run the cable outside the conduit. If symptoms disappear, there is a short between the cable and the conduit. Likely a shield is exposed and touching the conduit. Repair the cable and reinstall it in the conduit. b. to avoid induced noise in the sensor cable, run it as far away as possible from power cables, relays, and electric motors. Keep sensor wiring out of crowded panels and cable trays. c. If ground loops persist, consult the factory. A visit from a service technician may be required to solve the problem. 15.8.8 Process readings are noisy. 1. What is the conductivity of the sample? Measuring pH is samples having conductivity less than about 50uS/cm can be very difficult. Special sensors (for example, the Model 320HP) are often needed and special attention must be paid to grounding and sample flow rate. NOTE: Measuring free chlorine in samples having low conductivity can also be a problem. Generally, for a successful chlorine measurement, the conductivity should be greater than 50 µS/cm. 2. Is the sensor dirty or fouled? Suspended solids in the sample can coat the reference junction and interfere with the electrical connection between the sensor and the process liquid. the result is often a noisy reading. 3. Is the sensor properly wired to the transmitter? See Section 3.0. 4. Is a ground loop present? Refer to Section 15.8.7. 111 MODEL 5081-A SECTION 15.0 TROUBLESHOOTING 15.9 SIMULATING INPUT CURRENTS - DISSOLvED OxyGEN to check the performance of the transmitter, use a decade box to simulate the current from the oxygen sensor. A. disconnect the anode and cathode leads from terminals 13 & 14 and connect a decade box as shown in Figure 15-1. It is not necessary to disconnect the Rtd leads. B. Set the decade box to the resistance shown in the table. Sensor Polarizing voltage Resistance Expected Current 499Ado -675 mV 34 kW 20 µA 499Atrdo -800 mV 20 kW 40 µA Hx438 and Gx448 -675 mV 8.4 MW 80 nA C. Note the sensor current. to view the sensor current, go to the main display and press dIAG. then press NEXt. SEnSor Cur will appear in the display. Press ENtER. the display will show the sensor current. Note the units: µA is microamps: nA is nanoamps. d. Change the decade box resistance and verify that the correct current is shown. Calculate the current from the equation: current (µA) = voltage (mV) resistance (kW) FIGURE 15-1. Simulate dissolved oxygen. 15.10 SIMULATING INPUT CURRENTS - CHLORINE AND OzONE to check the performance of the transmitter, use a decade box and a battery to simulate the current from the sensor. the battery, which opposes the polarizing voltage, is necessary to ensure that the sensor current has the correct sign. A. disconnect the anode and cathode leads from terminals 13 & 14 and connect a decade box as shown in Figure 15-1. It is not necessary to disconnect the Rtd leads. B. Set the decade box to the resistance shown in the table. Sensor Polarizing voltage Resistance Expected Current 499ACL-01 (free chlorine) 200 mV 28 MW 500 nA 499ACL-02 (total chlorine) 250 mV 675 kW 2000 nA 499AoZ 200 mV 2.7 MW 500 nA C. Note the sensor current. It should be close to the value in the table. the actual value depends on the voltage of the battery. to view the sensor current, go to the main display and press dIAG. then, press NEXt. SEnSor Cur will appear in the display. Press ENtER. the display will show the sensor current. Note the units: uA is microamps: nA is nanoamps. d. Change the decade box resistance and verify that the correct current is shown. Calculate the current from the equation: current (µA) = Vbattery – Vpolarizing (mV) resistance (kW) the voltage of a fresh 1.5 volt battery is about 1.6 volt (1600 mV). 112 FIGURE 15-2. Simulate chlorine and ozone. MODEL 5081-A SECTION 15.0 TROUBLESHOOTING 15.11 SIMULATING INPUTS - pH 15.11.1 General this section describes how to simulate a pH input into the transmitter. to simulate a pH measurement, connect a standard millivolt source to the transmitter. If the transmitter is working properly, it will accurately measure the input voltage and convert it to pH. Although the general procedure is the same, the wiring details depend on whether the preamplifier is in the sensor, a junction box, or the transmitter. 15.11.2 Simulating pH input when the preamplifier is in the analyzer. 1. turn off automatic temperature correction and set the manual temperature to 25°C (Section 7.4). 2. disconnect the pH sensor. Also, disconnect the chlorine sensor anode lead. Connect a jumper wire between the pH IN and REF IN terminals. 3. Confirm that the transmitter is reading the correct mV value. With the main display showing, press dIAG. Press NEXt until the display shows PH. Press ENtER. the display will show InPUt followed by a number. the number is the raw input signal in millivolts. the measured voltage should be 0 mV. 4. Confirm that the transmitter is reading the correct pH value. Go to the main display. Press é or ê. the second line of the display will show the pH. the pH should be approximately 7.00. Because calibration data stored in the analyzer may be offsetting the input voltage, the displayed pH may not be exactly 7.00. 5. If a standard millivolt source is available, disconnect the jumper wire between the pH IN and REF IN terminals and connect the voltage source as shown in Figure 15.3. 6. Calibrate the transmitter using the procedure in Section 13.3. use 0.0 mV for Buffer 1 (pH 7.00) and -177.4 mV for Buffer 2 (pH 10.00). If the analyzer is working properly, it should accept the calibration. the slope should be 59.16 mV/pH, and the offset should be zero. 7. to check linearity, set the voltage source to the values shown in the table and verify that the pH and millivolt readings match the values in the table. voltage (mv) pH (at 25°) 295.8 2.00 177.5 4.00 59.2 6.00 59.2 8.00 177.5 10.00 295.8 12.00 FIGURE 15-3. Simulate pH. 15.11.3 Simulating pH input when the preamplifier is in a junction box. the procedure is the same as described in section 15.11.2. Keep the connection between the analyzer and the junction box in place. disconnect the sensor at the sensor side of the junction box and connect the voltage source to the sensor side of the junction box. 15.11.4 Simulating pH input when the preamplifier is in the sensor. the preamplifier in the sensor converts the high impedance signal into a low impedance signal without amplifying it. to simulate pH values, follow the procedure in Section 15.11.2. 113 MODEL 5081-A SECTION 15.0 TROUBLESHOOTING 15.12 SIMULATING TEMPERATURE 15.12.1 General the transmitter accepts either a Pt100 Rtd (used in pH, 499Ado, 499Atrdo, 499ACL-01, 499ACL-02, and 499AoZ sensors) or a 22k NtC thermistor (used in HX438 and Gx448 do sensors and most steam-sterilizable sensors from other manufacturers). the Pt100 Rtd has a three-wire configuration. See Figure 15-4. the thermistor has a two-wire configuration. 15.12.2 Simulating temperature to simulate the temperature input, wire a decade box to the analyzer or junction box as shown in Figure 15-5. FIGURE 15-4. Three-Wire RTD Configuration. Although only two wires are required to connect the Rtd to the analyzer, using a third wire allows the analyzer to correct for the resistance of the lead wires and for changes in the lead wire resistance with temperature. to check the accuracy of the temperature measurement, set the resistor simulating the Rtd to the values indicated in the table and note the temperature readings. the measured temperature might not agree with the value in the table. during sensor calibration an offset might have been applied to make the measured temperature agree with a standard thermometer. the offset is also applied to the simulated resistance. the controller is measuring temperature correctly if the difference between measured temperatures equals the difference between the values in the table to within ±0.1°C. For example, start with a simulated resistance of 103.9 W, which corresponds to 10.0°C. Assume the offset from the sensor calibration was -0.3 W. Because of the offset, the analyzer calculates temperature using 103.6 W. the result is 9.2°C. Now change the resistance to 107.8 W, which corresponds to 20.0°C. the analyzer uses 107.5 W to calculate the temperature, so the display reads 19.2°C. Because the difference between the displayed temperatures (10.0°C) is the same as the difference between the simulated temperatures, the analyzer is working correctly. 114 FIGURE 15-5. Simulating RTD Inputs. the figure shows wiring connections for sensors containing a Pt 100 Rtd. For sensors using a 22k NtC thermistor (Hx438 and Gx448 sensors), wire the decade box to terminals 1 and 3 on tB6. Temp. (°C) 0 10 20 25 30 40 50 60 70 80 85 90 100 Pt 100 (W) 100.0 103.9 107.8 109.7 111.7 115.5 119.4 123.2 127.1 130.9 132.8 134.7 138.5 22k NTC (kW) 64.88 41.33 26.99 22.00 18.03 12.31 8.565 6.072 4.378 3.208 2.761 2.385 1.798 MODEL 5081-A SECTION 16.0 TROUBLESHOOTING 15.13 MEASURING REFERENCE vOLTAGE Some processes contain substances that poison or shift the potential of the reference electrode. Sulfide is a good example. Prolonged exposure to sulfide converts the reference electrode from a silver/silver chloride electrode to a silver/silver sulfide electrode. the change in reference voltage is several hundred millivolts. A good way to check for poisoning is to compare the voltage of the reference electrode with a silver/silver chloride electrode known to be good. the reference electrode from a new sensor is best. See Figure 15-6. If the reference electrode is good, the voltage difference should be no more than about 20 mV. A poisoned reference electrode usually requires replacement FIGURE 15-6. Checking for a Poisoned Reference Electrode. Refer to the sensor wiring diagram to identify the reference leads. A laboratory silver/silver chloride electrode can be used in place of the second sensor. 115 MODEL 5081-A SECTION 16.0 MAINTENANCE SECTION 16.0 MAINTENANCE 16.1 OvERvIEW this section gives general procedures for routine maintenance of the 5081-A transmitter. the transmitter needs almost no routine maintenance. 16.2 TRANSMITTER MAINTENANCE Periodically clean the transmitter window with household ammonia or glass cleaner. the detector for the infrared remote controller is located behind the window at the top of the transmitter face. the window in front of the detector must be kept clean. Most components of the transmitter are replaceable. Refer to Figure 16-1 and table 16-1 for parts and part numbers. 7 12 8 5 2 9 14 } 1 6 13 FIGURE 16-1. Exploded view of Model 5081-A Transmitter Three screws (part 13 in the drawing) hold the circuit boards in place. Removing the screws allows the display board (part 2) and the CPU board (part 3) to be easily removed. A ribbon cable connects the boards. The cable plugs into the CPU board and is permanently attached to the display board. A 16 pin and socket connector holds the CPU and analog (part 4) boards together. Five screws hold the terminal block (part 5) to the center housing (part 7), and the 16 pins on the terminal block mate with 16 sockets on the back side of the analog board. Use caution when separating the terminal block from the analog board. The pin and socket connection is tight. 116 MODEL 5081-A SECTION 16.0 MAINTENANCE TABLE 16-1. Replacement Parts for Model 5081-A Transmitter Location in Figure 16-1 PN 1 23992-01 PCB stack consisting of the CPu, communication, and analog boards; display board is not included; CPu, communication, and analog boards are factory-calibrated as a unit and cannot be ordered separately 1 lb/0.5 kg 2 23652-01 LCd display PCB 1 lb/0.5 kg 5 33337-02 terminal block 1 lb/0.5 kg 6 23593-01 Enclosure cover, front with glass window 3 lb/1.5 kg 7 33360-00 Enclosure, center housing 4 lb/1.5 kg 8 33362-00 Enclosure cover, rear 3 lb/1.0 kg 9 6560135 desiccant in bag, one each 1 lb/0.5 kg 9550187 o-ring (2-252), one, front and rear covers each require an o-ring 1 lb/0.5 kg Description Shipping Weight 12 note Screw, 8-32 x 0.5 inch, for attaching terminal block to center housing * 13 note Screw, 8-32 x 1.75 inch, for attaching circuit board stack to center housing * 14 33342-00 Cover lock 1 lb/0.5 kg 14 33343-00 Locking bracket nut 1 lb/0.5 kg note Screw, 10-24 x 0.38 inch, for attaching cover lock and locking bracket nut to center housing * NotE: For information only. Screws cannot be purchased from Rosemount Analytical. * Weights are rounded up to the nearest whole pound or 0.5 kg. 117 MODEL 5081-A SECTION 17.0 RETURN OF MATERIAL SECTION 17.0 RETURN OF MATERIAL 17.1 GENERAL. 17.3 NON-WARRANTy REPAIR. to expedite the repair and return of instruments, proper communication between the customer and the factory is important. Call 1-949-757-8500 for a R e tu r n Materials Authorization (RMA) number. the following is the procedure for returning for repair instruments that are no longer under warranty: 1. Call Rosemount Analytical for authorization. 2. Supply the purchase order number, and make sure to provide the name and telephone number of the individual to be contacted should additional information be needed. 3. do Steps 3 and 4 of Section 17.2. 17.2 WARRANTy REPAIR. the following is the procedure for returning instruments still under warranty: 1. Call Rosemount Analytical for authorization. 2. to verify warranty, supply the factory sales order number or the original purchase order number. In the case of individual parts or sub-assemblies, the serial number on the unit must be supplied. 3. Carefully package the materials and enclose your “Letter of transmittal” (see Warranty). If possible, pack the materials in the same manner as they were received. 4. Send the package prepaid to: Emerson Process Management Rosemount Analytical 2400 Barranca Parkway Irvine, CA 92606 Attn: Factory Repair RMA No. ____________ Mark the package: Returned for Repair Model No. ____ 118 NOTE Consult the factory for additional information regarding service or repair. MODEL 5081-A APPENDIx A APPENDIx A BAROMETRIC PRESSURE AS A FUNCTION OF ALTITUDE the table shows how barometric pressure changes with altitude. Pressure values do not take into account humidity and weather fronts. Altitude Barometric Pressure m ft bar mm Hg in Hg kPa 0 0 1.013 760 29.91 101.3 250 820 0.983 737 29.03 98.3 500 1640 0.955 716 28.20 95.5 750 2460 0.927 695 27.37 92.7 1000 3280 0.899 674 26.55 89.9 1250 4100 0.873 655 25.77 87.3 1500 4920 0.846 635 24.98 84.6 1750 5740 0.821 616 24.24 82.1 2000 6560 0.795 596 23.47 79.5 2250 7380 0.771 579 22.78 77.1 2500 8200 0.747 560 22.06 74.7 2750 9020 0.724 543 21.38 72.4 3000 9840 0.701 526 20.70 70.1 3250 10,660 0.679 509 20.05 67.9 3500 11,480 0.658 494 19.43 65.8 119 WARRANTy Seller warrants that the firmware will execute the programming instructions provided by Seller, and that the Goods manufactured or Services provided by Seller will be free from defects in materials or workmanship under normal use and care until the expiration of the applicable warranty period. Goods are warranted for twelve (12) months from the date of initial installation or eighteen (18) months from the date of shipment by Seller, whichever period expires first. Consumables, such as glass electrodes, membranes, liquid junctions, electrolyte, o-rings, catalytic beads, etc., and Services are warranted for a period of 90 days from the date of shipment or provision. Products purchased by Seller from a third party for resale to Buyer ("Resale Products") shall carry only the warranty extended by the original manufacturer. Buyer agrees that Seller has no liability for Resale Products beyond making a reasonable commercial effort to arrange for procurement and shipping of the Resale Products. If Buyer discovers any warranty defects and notifies Seller thereof in writing during the applicable warranty period, Seller shall, at its option, promptly correct any errors that are found by Seller in the firmware or Services, or repair or replace F.o.B. point of manufacture that portion of the Goods or firmware found by Seller to be defective, or refund the purchase price of the defective portion of the Goods/Services. All replacements or repairs necessitated by inadequate maintenance, normal wear and usage, unsuitable power sources, unsuitable environmental conditions, accident, misuse, improper installation, modification, repair, storage or handling, or any other cause not the fault of Seller are not covered by this limited warranty, and shall be at Buyer's expense. Seller shall not be obligated to pay any costs or charges incurred by Buyer or any other party except as may be agreed upon in writing in advance by an authorized Seller representative. All costs of dismantling, reinstallation and freight and the time and expenses of Seller's personnel for site travel and diagnosis under this warranty clause shall be borne by Buyer unless accepted in writing by Seller. Goods repaired and parts replaced during the warranty period shall be in warranty for the remainder of the original warranty period or ninety (90) days, whichever is longer. this limited warranty is the only warranty made by Seller and can be amended only in a writing signed by an authorized representative of Seller. Except as otherwise expressly provided in the Agreement, tHERE ARE No REPRESENtAtIoNS oR WARRANtIES oF ANY KINd, EXPRESS oR IMPLIEd, AS to MERCHANtABILItY, FItNESS FoR PARtICuLAR PuRPoSE, oR ANY otHER MAttER WItH RESPECt to ANY oF tHE GoodS oR SERVICES. RETURN OF MATERIAL Material returned for repair, whether in or out of warranty, should be shipped prepaid to: Emerson Process Management Rosemount Analytical 2400 Barranca Parkway Irvine, CA 92606 the shipping container should be marked: Return for Repair Model _______________________________ the returned material should be accompanied by a letter of transmittal which should include the following information (make a copy of the "Return of Materials Request" found on the last page of the Manual and provide the following thereon): 1. 2. 3. 4. 5. Location type of service, and length of time of service of the device. description of the faulty operation of the device and the circumstances of the failure. Name and telephone number of the person to contact if there are questions about the returned material. Statement as to whether warranty or non-warranty service is requested. Complete shipping instructions for return of the material. Adherence to these procedures will expedite handling of the returned material and will prevent unnecessary additional charges for inspection and testing to determine the problem with the device. If the material is returned for out-of-warranty repairs, a purchase order for repairs should be enclosed. 121 LIQ_MAN_5081A-FF Rev. M January 2015 facebook.com/EmersonRosemountAnalytical 8 AnalyticExpert.com Credit Cards for U.S. Purchases Only. twitter.com/RAIhome youtube.com/user/RosemountAnalytical Emerson Process Management ©2015 Rosemount Analytical, Inc. All rights reserved. 2400 Barranca Parkway Irvine, CA 92606 USA Tel: (949) 757-8500 Fax: (949) 474-7250 The Emerson logo is a trademark and service mark of Emerson Electric Co. Brand name is a mark of one of the Emerson Process Management family of companies. All other marks are the property of their respective owners. rosemountanalytical.com © Rosemount Analytical Inc. 2015 The contents of this publication are presented for information purposes only, and while effort has been made to ensure their accuracy, they are not to be construed as warranties or guarantees, express or implied, regarding the products or services described herein or their use or applicability. All sales are governed by our terms and conditions, which are available on request. We reserve the right to modify or improve the designs or specifications of our products at any time without notice.