Emerson 245 Sanitary Flow-Through Toroidal Conductivity Sensor Instruction Manual

Instruction Manual LIQ_MAN_245 Rev. D January 2014 245 Sanitary Flow-Through Toroidal Conductivity Sensor About This Document This manual contains instructions for installation and operation of the 245 Sanitary Flow-Through Toroidal Conductivity Sensor. The following list provides notes concerning all revisions of this document. Rev. Level Date Notes A 2/04 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 1/08 Addition of section 1.7 on page 5 C 3/12 Update pages 12 and 16 D 01/14 The manual has been reformatted to reflect the Emerson documentation style and updated to reflect any changes in the product offering. Wiring diagrams were also added under Section 1. 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, for example, ANSI B16.5. Connect all products to the proper electrical and pressure sources. • To ensure proper performance, qualified personnel should install, operate, and maintain the product. • When replacement parts are required, ensure that qualified people use replacement parts specified by Rosemount Analytical. Replacement of original components with those constructed from alternative materials will void any CSA, FM, and BASEEFA/CENELEC agency approvals that were applicable to the original device. Furthermore, replacement of original components with those constructed from alternative materials might change the pressure, temperature, and/or performance specifications from those of the original configuration. Ensure replacement parts are compatible with process requirements. Unauthorized parts and procedures can affect the product’s performance, place the safe operation of your process at risk, and 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. DANGER HAZARDOUS AREA INSTALLATION Installations near flammable liquids or in hazardous area locations must be carefully evaluated by qualified on site safety personnel. This sensor is not Intrinsically Safe or Explosion Proof. To secure and maintain an intrinsically safe installation, the certified safety barrier, transmitter, and sensor combi nation must be used. The installation system must comply with the governing approval agency (FM, CSA, BASEEFA/CENELEC, or ATEX) hazardous area classification requirements. Consult your analyzer/ transmitter instruction manual for details. Replacement of original components with those constructed from alternative materials will void any CSA, FM, and BASEEFA/CENELEC agency approvals that were applicable to the original device. Proper installation, operation and servicing of this sensor in a Hazardous Area Instal lation is entirely the responsibility of the user. CAUTION: SENSOR/PROCESS APPLICATION COMPATIBILITY The wetted sensor materials may not be compatible with process com position and operating conditions. Replacement of original components with those constructed from alternative materials might change the pressure, temperature, and/or performance specifications from those of the original sensor configuration. Application compat ibility is entirely the responsibility of the user. Instruction Manual LIQ_MAN_245 Table of Contents January 2014 Contents Section 1: 245 Sensor 1.1 1-1 1-2 1.2 1-3 1.3 1-4 1.4 1-5 1.5 1-6 1.6 1-7 1.7 1-8 1.8 Features and Applications................................................................................ 1 Specifications..................................................................................................1 Ordering Information......................................................................................2 Installation....................................................................................................... 3 Calibration....................................................................................................... 4 Calibration Verification.................................................................................... 5 Wiring.............................................................................................................. 5 Maintenance................................................................................................... 7 Section 2: Troubleshooting....................................................................................9 Section 3: Return of Materials........................................................................ 11 3.1 3.2 3.3 General.......................................................................................................... 11 Warranty Repair.............................................................................................11 Non-Warranty Repair.....................................................................................11 List of Tables 1.1 2.1 2.2 Nominal Cell Constants for 245 Sensors.......................................................... 4 Resistance Values for RTD................................................................................ 9 Sensor Wire Resistance Values with Instrument Cable Disconnect................... 9 List of Figures Figure Figure 1-11-1 Figure 1-2 Figure 1-2 Figure 1-3 Figure 1-3 Figure 1-4 Figure 1-4 Figure 1-5 Figure 1-5 Figure 1-6 Figure 1-6 Figure 1-7 Figure 1-7 Figure 1-8 Figure 1-8 Figure 1-9 Figure 1-9 Figure 1-10 Figure 1-10 Figure 2-1 Figure 2-1 Sanitary Flow-Through Toroidal Conductivity Sensor......................... 2 245 Junction Box with RTD Diagram.................................................4 Sensor to Junction Box Wiring........................................................... 5 Extension Cable................................................................................ 6 Wiring Extension Cable to 54ec......................................................... 6 Wiring Extension cable to 1056 and 56............................................. 6 Wiring Extension cable to Xmt-T (Panel Mount)................................ 6 Wiring Extension Cable to Xmt-T (Pipe/Wall Mount)......................... 7 Wiring Extension Cable to 1066-T..................................................... 7 Wiring Extension Cable to 5081T...................................................... 7 Sensor Circuit for Troubleshooting.................................................. 10 Table of Contents i Table of Contents January 2014 This page left blank intentionally Instruction Manual LIQ_MAN_245 Instruction Manual LIQ_MAN_245 245 Sensor January 2014 Section 1: 245 Sensor 1.1 Features and Applications The 245 Sanitary Flow-Through Toroidal Conductivity Sensor is intended for use in the pharmaceutical, biopharmaceutical, and food and beverage industries where a conductivity sensor that does not obstruct the process flow is required. The sensor consists of two toroids surrounding a PEEK liner through which the liquid flows. An alternating voltage applied to the first toroid induces a voltage in the liquid, which causes an ionic current to flow. The ionic current is directly proportional to the conductance of the liquid. The ionic current, in turn, induces a proportional current in the second toroid. The analyzer measures this current and displays the conductivity of the liquid. For a current to flow in the second toroid, a complete electric circuit must exist around the toroids. The sample passing through the toroid openings forms part of the circuit. The metal mounting flanges at the end of the sensor, which contact the liquid and are connected by the metal housing passing outside the toroids, complete the circuit. The 245 sensor is available with 0.5, 1.0, 1.5, and 2 inch Tri Clamp connections. The liner meets the requirements of 21CFR177.2415, and the O-rings meet 21CFR177.2600. Both the liner and the O-rings are compliant with USP Class VI requirements. The 245 sensor is easy to install. It clamps into the process piping between two Tri Clamp flanges. Installation of special grounding rings is not needed because contact rings are already built into the sensor. A junction box to facilitate wiring is included. Conductivity depends strongly on temperature, and conductivity measurements are typically corrected to a reference value. A Pt 100 or Pt 1000 RTD, provided by the user, can be wired into the sensor junction box, allowing the analyzer to measure temperature and use it for automatic temperature correction. The 245 is not sensitive to flow rate or direction. It does not obstruct the process flow. The 245 Sanitary Flow-Through Conductivity Sensor is compatible with the 1056, 56, 5081T, and 1066-T. 1.2 Specifications Installation Type: Flow through Conductivity Range: Consult analyzer product data sheet Process Connections: ½ inch, 1 inch, 1 ½ inch, and 2 inch Wetted Materials: 316L stainless steel (mounting flanges); unfilled PEEK (liner); EPDM (O-rings). PEEK liner meets 21CFR177.2415 and USP Class VI. EPDM O-rings meet 21CFR177.2600 and USP Class VI, Surface Finish: Mounting flanges have a 16 micro inch (0.41 um) Ra surface finish. PEEK liner has a 32 micro inch (0.81 um) Ra surface finish. Minimum Temperature: 32 °F (0 °C) Maximum Temperature: 250 °F (121 °C) continuous; 266 °F (130 °C) in steam for 45 minutes Maximum Pressure (½ inch sensor only): 300 psig (2170 kPa abs) Maximum Pressure (all others): 100 psig (791 kPa abs) Shipping Weight: 9 lb (4.5 kg) 245 Sensor 1 245 Sensor January 2014 Instruction Manual LIQ_MAN_245 Figure 1-1 Sanitary Flow-Through Toroidal Conductivity Sensor 1.3 Ordering Information The 245 Sanitary Flow-Through Sensor is configurable to meet the needs of many applications and installations. A NEMA 7D junction box is also included. Compatible instruments include Rosemount Analytical 1056, 56, 5081T, and 1066-T. The extension cable required for wiring from the junction box to the instrument is ordered separately. The customer supplies the mating flanges, clamps, gaskets, and Pt 1000 RTD. Model 245 CODE Sanitary Flow-Through Toroidal Conductivity Sensor LINE SIZE (Required Selection) 01 ½” 02 1” 03 1–½” 04 2” CODE 12 CODE SS CODE PK CODE EP 245 PROCESS CONNECTION (Required Selection) Tri Clamp CONTACT RING MATERIAL (Required Selection) 316L Stainless Steel LINER MATERIAL (Required Selection) unfilled PEEK PROCESS O-RING MATERIAL (Required Selection) EP O-rings -01 -12 -SS -PK -EP EXAMPLE Accessories Part # Description 23909-00 Extension cable, prepped, for connection to instruments 1056, 56, 5081, 1066-T (Specify length) 24086-00 RTD Mounting Accessory Kit, consisting of ¾” NPT tee, nipple, and cable connectors 2 245 Sensor Instruction Manual LIQ_MAN_245 1.4 245 Sensor January 2014 Installation Before starting installation, determine whether the analyzer/transmitter will be calibrated at the bench or on-line. If bench calibration is to be performed, wiring instructions can be found at the end of this section and calibration procedures can be found in Section 1.5. Installation of the 245 Flow Through Sensor is similar to installation of a section of pipe. Consequently, be prepared to use tools, supplies, equipment, and techniques similar to those used to install process pipes. Use common piping practices to minimize torque and bending loads on process connections. Observe all applicable safety standards. Dimensional information is shown in Figure 1-2 below. Note 1. The sensor should be installed into a straight section of piping at least 4 pipe diameters in length on either side of the sensor to optimize sensor performance. 2. The sensor should be installed at an orientation that will keep the sensor filled with process solution at all times during which measurements are being made. Avoid downward flowing solutions as such a configuration might leave the sensor partially empty. Installing the Sensor in the Process Line 1. Install Tri-Clamp flanges onto pipes in accordance with applicable instructions, standards, and local regulations. 2. Position the sensor between the Tri-Clamp flanges with the flange gaskets inserted between each set of flanges. Ensure that the locations of the junction box connection and the RTD are suitable for ease of the remainder of installation, wiring, and use. Installing the Pt100 RTD 1. Use of the optional Pt100 RTD is recommended. Use of a customer-supplied Pt100 or Pt1000 TC mounted in a separate thermowell is also acceptable. 2. Thread the RTD wires into junction box. Wire the RTD to the j-box terminals as indicated in Figure 1-4. Use of optional kit PN 24086-00 is recommended. Extension Cable Hook-Up 1. Sensor cable should not be run in conduit or open trays with any A.C. power wiring, nor routed near heavy electrical equipment. 2. For best sensor/instrument loop performance, using the preprepared extension cable (PN 23909-00) is recommended. (Using a different cable can introduce noise into the signal and/or reduce loop accuracy.) 3. One end of extension cable (PN 23909-00) has 8 wires, and the other end has 11 wires. Refer to Figure 1-4. The end with only 8 wires goes into the junction box. The end with 11 wires goes to the instrument. Note If starting with unprepped cable (PN 9200276), remove only as much insulation as is necessary. The instrument end needs 11 leads: four leads from the green-white-blackdrain bundle, three from each of the two coaxial cable bundles (the inner conductor, the insulating braid, and the drain wire), and one from the outermost overall braided-copper shield. For the junction-box end, only 8 leads are used: the white coaxial conductor, its braided shield, the green coaxial conductor, its braided shield, its drain wire, and the green, white, and black conductors from the green-white-black-drain bundle. The remaining shields and drain wires are not used on the J-box end and should be removed -- they should NOT be connected or allowed to short to any other conductor or the junction box. 4. Connect the 8 wires of the extension cable to the terminal block inside the sensor’s junction box as indicated in Figure 1-3 and Figure 1-4. 5. Connect the 11 wires of the instrument-end of the extension cable according to the applicable diagram from Figures 1-5 through 1-9, the Wiring Instruction Sheet, or the instrument’s instructions. 245 Sensor 3 245 Sensor January 2014 Instruction Manual LIQ_MAN_245 Figure 1-2 245 Junction Box with RTD Diagram (use of optional kit PN 24086-00 is recommended) 1.5 Calibration Before starting the calibration, enter the nominal cell constant into the analyzer. See Table 1-1. The accuracy of the nominal cell constant is probably no better than 10%. For greater accuracy, calibrate the sensor. Table 1-1 Nominal Cell Constants for 245 Sensors 1.5.1 Sensor Size Nominal Cell Constant ½” 8 1” 2 1.5” 1.6 2” 1.3 Calibration against a standard solution 1. Obtain a suitable conductivity standard. If the sensor is being used to measure a broad range of conductivity, choose a standard in the midpoint of the operating range. Otherwise, choose a standard near the expected process conductivity. 2. Attach a blank flange to one end of the sensor. Stand the sensor on the sealed end. 3. Decide whether temperature correction is needed. a. If the conductivity of the standard as a function of temperature is known, configure the analyzer to measure raw conductivity (no temperature correction). Also, obtain a calibrated thermometer. Place the thermometer in a beaker of water next to the sensor. DO NOT PUT THE THERMOMETER IN THE SENSOR. b. If the conductivity of the standard is known only at 25 ºC, leave the analyzer slope temperature correction on and set the temperature coefficient to the appropriate value. If the temperature coefficient is not given, consult the manufacturer of the standard. Also, obtain a calibrated Pt 100 RTD and connect it to the analyzer. See Wiring Diagrams. Place the RTD in a beaker of water next to the sensor. DO NOT PUT THE RTD IN THE SENSOR 4. Fill the sensor with standard. Be sure no air bubbles are sticking to the liner and the sensor is completely filled. 5. Wait for the standard and the water in the beaker containing the thermometer or RTD to come to thermal equilibrium. 6. Refer to the analyzer instruction manual and adjust the analyzer display to match the conductivity of the standard at either the temperature of the standard (step 3a) or at 25 ºC (step 3b). 4 245 Sensor Instruction Manual LIQ_MAN_245 1.5.2 245 Sensor January 2014 In-line calibration against a laboratory measurement 1. Install the sensor in the process piping. 2. Obtain and calibrate a laboratory conductivity meter and sensor capable of measuring the conductivity of the process liquid. 3. Collect a sample of the process liquid and measure the conductivity using the laboratory instrument. The temperature of the sample is likely to change during handling. For this reason, use temperature compensation in both the process and laboratory analyzer. Be sure the temperature correction algorithms are identical. 4. Refer to the analyzer instruction manual and adjust the analyzer display to match the conductivity measured in the laboratory. 1.6 Calibration Verification 1.7 Wiring Calibration verification is a way of monitoring changes that might occur in the external toroids during service. It does not detect changes in the contact rings. It is not a calibration. 1. Empty and dry the sensor. 2. Attach a resistance decade box to the two yellow wires. See Figure 2-1. 3. Configure the analyzer to measure raw conductivity (no temperature compensation). 4. Adjust the resistance until the analyzer display reads the same number it did during calibration. Record the resistance value, the displayed value, and the temperature. Calibration verification can be used to check the toroids while the sensor is in the process line. 1. Drain the process line. 2. Connect a resistance decade box to the yellow wires. 3. Configure the analyzer to measure raw conductivity. 4. Set the decade box to the value noted in step 4 above. The analyzer reading should match the original reading to within ±20%. NOTE For additional wiring information on this product, including sensor combinations not shown here, please refer to either our online wiring programs or the Manual DVD enclosed with each product. 1056, 1057, 56, 5081, 6081, 54e, and XMT : http://www3.emersonprocess.com/raihome/ sp/liquid/wiring/XMT/ 1066 and sensors with SMART preamps: http://www2.emersonprocess.com/en-US/ brands/rosemountanalytical/Liquid/Sensors/Pages/Wiring_Diagram.aspx 1055: http://www3.emersonprocess.com/raihome/sp/liquid/wiring/1055/ Figure1-3 Sensor to Junction Box Wiring 245 Sensor 5 245 Sensor January 2014 Instruction Manual LIQ_MAN_245 Figure 1-4 Extension Cable Figure1-5 Wiring extension cable to 54ec Figure1-6 Wiring extension cable for 1056 and 56 Figure1-7 Wiring extension cable to Xmt-T (Panel Mount) 6 245 Sensor Instruction Manual LIQ_MAN_245 245 Sensor January 2014 Figure1-8 Wiring extension cable to Xmt-T (Pipe/Wall Mount) REVISIONS WHEN INCH AND METRIC DIMS ARE GIVEN DESCRIPTION LTR MILLIMETER 12-8-10 Figure1-9 Wiring extension cable to 1066-T TB2 DATE REVISED B INCH APVD J. COVEY Figure 1-10 Wiring extension Cable to 5081T TB1 RCV B RTN SENSE RCV A RTD IN RSHLD DRV B SHLD CLEAR WHITE BLACK CLEAR GREEN BLACK BLACK CLEAR GREEN WHITE DRV A DSHLD CLEAR CLEAR SHIELD IS NOT CONNECTED. IT IS PRESENT IN HIGH TEMPERATURE (OPTION-03) ONLY 228-56 APPROVALS NOTES: UNLESS OTHERWISE SPECIFIED C. HOANG 7-7-10 CHECKED J. COVEY 7-23-10 PROJECT ENGR APVD THIS DWG CREATED IN SOLID EDGE Rosemount Analytical, Inc. DATE DRAWN 2400 Barranca Pkwy Irvine, CA 92606 TITLE WIRING MODEL 228-56 SENSOR TO MODEL 1066 B SIZE DWG NO 40106604 REV B 08-95 1.8 Maintenance The only routine maintenance required during the operational life of the sensor is to ensure that there are no deposits plugging the sensor or coating the inside of the contact rings. Some customers find it advantageous to periodically replace process (Tri-Clamp) gaskets to ensure adequate process seals. Rebuilding the sensor must be done at the factory. 245 Sensor 7 245 Sensor January 2014 Instruction Manual LIQ_MAN_245 This page left blank intentionally 8 245 Sensor Instruction Manual Troubleshooting LIQ_MAN_245 January 2014 Section 2: Troubleshooting 2.1 Troubleshooting To check the toroids, recall the data obtained during the Calibration Verification Process (see Section 1.6). With the sensor empty of process fluids (preferably also clean and dry), reapply the resistance to the yellow Cal Loop wires in the junction box. The reading should be within + 20% of its original value. To check the RTD, disconnect RTD leads of the interconnecting cable (PN 23909-00) and measure the resistance across the white and one of the red RTD wire terminals in the junction box. See Figure 1-4. The resistance value should be close to the applicable value shown in Table 2-1. Finally, check the sensor for open connections and short circuits. Be sure to disconnect the cable (PN 23909-00) before checking. See Table 2-2 and Figure 2-1. Table 2-1 Resistance Values for Pt 100 and Pt 1000 RTDs Temperature (°C/°F) 18 / 64.4 19 / 66.2 20 / 68.0 21 / 69.8 22 / 71.6 23 / 73.4 24 / 75.2 25 / 77.0 26 / 78.8 27 / 80.6 Resistance (Ohms) Pt 100 106.9 107.3 107.7 108.1 108.4 108.9 109.2 109.6 110.0 110.4 Pt 1000 1069 1073 1077 1081 1084 1089 1092 1096 1100 1104 Table 2-2. Sensor Wire Resistance Values with Instrument Cable Disconnected (instrument leads and gray wire connected to terminal block, see Figure 2-1) Connection (wire or component connections) Resistance Each twisted pair, WHITE to GRAY 0.4 to 0.9 Ω YELLOW to YELLOW 0.1 to 0.5 Ω WHITE to WHITE > 20 MΩ RED to YELLOW > 20 MΩ RED to each WHITE > 20 MΩ YELLOW to each WHITE > 20 MΩ ALL except RED to housing EARTH screw > 20 MΩ RED to housing EARTH screw 0.1 to 0.5 Ω Troubleshooting 9 Section Title January 2014 Instruction Manual LIQ_MAN_245 Figure 2-1 Sensor Circuit for Troubleshooting 10 Troubleshooting Instruction Manual LIQ_MAN_245 Return of Materials January 2014 Section 3: Return of Materials 3.1 General To expedite the repair and return of instruments, proper communication between the customer and the factory is important. A return material authorization number is required. Call (949) 757- 8500. The “Return of Materials Request” form is provided for you to copy and use in case the situation arises. The accuracy and completeness of this form will affect the processing time of your materials. 3.2 Warranty Repair The following is the procedure for returning products still under warranty. 1. Contact the factory for authorization. 2. Complete a copy of the “Return of Materials Request” form as completely and accurately as possible. 3. 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 mother unit must be supplied. 4. Carefully package the materials and enclose your “Letter of Transmittal” and the completed copy of the “Return of Materials Request” form. If possible, pack the materials in the same manner as it was received. Important Please see second section of “Return of Materials Request Form”. Compliance to the OSHA requirements is mandatory for the safety of all personnel. MSDS forms and a certification that the instruments have been disinfected or detoxified are required. 5. Send the package prepaid to: Rosemount Analytical Inc. 2400 Barranca Parkway Irvine, CA 92606 Attn: Factory Repair Mark the package: Returned for Repair RMA No. __________ Model No. ________ 3.3 Non-Warranty Repair 1. Contact the factory for authorization. 2. Fill out a copy of the “Return of Materials Request” form as completely and accurately as possible. 3. Include a purchase order number and make sure to include the name and telephone number of the right individual to be contacted should additional information be needed. 4. Do Steps 4 and 5 of Section 4.2. NOTE Consult the factory for additional information regarding service or repair. Return of Materials 11 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. Location type of service, and length of time of service of the device. 2. Description of the faulty operation of the device and the circumstances of the failure. 3. Name and telephone number of the person to contact if there are questions about the returned material. 4. Statement as to whether warranty or non-warranty service is requested. 5. 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.  LIQ_MAN_ABR_245 January 2014 Rev. D The right people, the right answers, right now. Immediate, Reliable Analytical Support Now there’s a way to quickly get the right answers for your liquid analytical instrumentation questions: the Analytical Customer Support Center. Our staff of trained professionals is ready to provide the information you need. If you are placing an order, verifying delivery, requesting application information, or just want to contact an Emerson Process Management representative, a call to the Customer Support Center will provide you with the right people, the right answers, right now. A Worldwide Network of Sales and Service Emerson Process Management’s field sales offices are your source for more information on the fill line of Rosemount Analytical products. Field sales personnel will work closely with you to supply technical data and application information. For more information, please contact your nearest Emerson Process Management sales office. THE AMERICAS HEADQUARTERS Emerson Process Management 2400 Barranca Parkway Irvine, CA 92606 USA Tel: (949) 757-8500 Fax: (949) 474-7250 rosemountanalytical.com ASIA-PACIFIC Emerson Process Management Asia Pacific Private Ltd. 1 Pandan Crescent Singapore 0512 Republic of Singapore Tel: 65.777.8211 Fax: 65.777.0947 EUROPE Emerson Process Management Heath Place Bognor Regis West Sussex PO22 9SH England Tel: 44.1243.863121 Fax: 44.1243.845354 GERMANY Emerson Process Management Process Gas Analyzer Center of Excellence GmbH & Co. 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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.