Operating Instructions TB82 Transmitter Series FOUNDATION Fieldbus Four-Electrode Conductivity Transmitters Model TB82EC ABB File Name: ABB_Transmitter_TB82EC_om_D202
ABB Incorporated The Company ABB Incorporated is an established world force in the design and manufacture of instrumentation for industrial process control, flow measurement, gas and liquid analysis and environmental applications. QMI ISO 9001 As a part of ABB, a leader in process automation technology, we offer customers application expertise, service and support worldwide. We are committed to teamwork, high quality manufacturing, advanced technology and unrivalled service and support.
CONTENTS INTRODUCTION The TB82EC Four-Electrode Conductivity FOUNDATION Fieldbus (FF) Transmitters are a modular range of field mounted, microprocessorbased instruments. Accurate and reliable measurement of solution conductivity is provided, in the even most difficult and hazardous industrial environments. Section Page CONTENTS ...............................................................3 INTRODUCTION........................................................3 SUPPLEMENTARY DOCUMENTATION..................
TRANSPORT PRODUCT IDENTIFICATION After factory calibration, the instrument is packed in a carton, intended to provide protection from physical damage. The following data plates shown in Figure 1 identify the instrument. The Nameplate (Reference A) provides information concerning the product identity code (i.e., nomenclature), product name, operating voltage range, output type, serial number, test personnel badge number, and dielectric strength verification stamp.
PRINCIPLE OF OPERATION The TB82EC Four-Electrode Conductivity FOUNDATION Fieldbus Transmitter provides on-line measurement of liquid properties in industrial environments using an advanced microprocessorbased technology. Transmitter power and digital communication based on the FOUNDATION Fieldbus protocol is provided by fieldbus wiring. The TB82EC transmitter can be installed indoors or outside due to its IP65 and NEMA 4X environmental enclosure ratings.
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INSTALLATION Besides the normal precautions for storage and handling of electronic equipment, the transmitter contains static sensitive devices. Since semiconductors can be damaged by the direct discharge of static electricity, avoid contact with terminal block conductors and electronic components on the circuit board. When mounting the transmitter, choose a location that has ample clearance for the removal of the front bezel and rear cover.
ELECTRICAL CONNECTIONS The terminal blocks located in the rear of the transmitter accept wire sizes from 12 to 24 AWG. Pin-style terminals should be used for all connections. The terminal block label identifies all electrical connections and should be followed when wiring the transmitter. Observance to polarity is not required; however, polarity indications have been provided for consistence. Voltage requirements are listed in the Specifications and must be observed.
. . . ELECTRICAL CONNECTIONS To ensure fault-free communication, the bus must be properly terminated at both ends. Only approved bus terminators must be used for intrinsically safe circuits. The specific noise immunity and emitted interference are only guaranteed when bus screening is fully effective (e.g., ensuring that screening is maintained through any existing junction boxes.) Appropriate equi-potential bonding must be provided to avoid differences in potential among the individual plant components.
Icon Exit to MEASURE FAULT Info SELECT ENTER NEXT YES NO MENU Key Function Escapes back to the Measure Mode from all other modes or programming states of operation. This function is not available in the Measure Mode. Accesses information on diagnostic problem or error conditions. Displays this information as a short text string and code. This function is only available in the Measure Mode. Selects the mode or programming state of operation shown in the secondary display region.
CALIBRATE MODE The Calibrate Mode of Operation provides the ability to calibrate the sensor and temperature inputs. These functions include process variable, temperature, edit, and reset calibration. Figure 10 shows the Calibrate States and key assignments for each state. CONCAL MEASURE 12.3 MEASURE CALIBRATE OUT/HOLD CONFIGURE SECURITY DISPLAY mS/cm TB.OOS? Process Variable Calibrate State MEASURE 12.3 12.
EDT.CAL MEASURE TMPCAL MEASURE 12.3 MEASURE CALIBRATE OUT/HOLD CONFIGURE SECURITY DISPLAY mS/cm TB.OOS? 12.3 MEASURE CALIBRATE OUT/HOLD CONFIGURE SECURITY DISPLAY SPT/TUNE mS/cm TB.OOS? MEASURE YES YES MEASURE NO Calibration data can only be viewed. 1.000 NO PV SLP Toggle between degrees C and degrees F. Show last selected units.
OUTPUT/HOLD MODE The Output/Hold Mode of Operation provides the ability to view a limited number of Transducer Block (TB) and Analog Input (AI) Function Block parameters. Fieldbus Foundation requirements prevent local adjustments using the HMI of the transmitter for function block parameters other than those located in the TB. Parameter viewing is limited to the TB Process Variable Range, AI Block mode status, AI Output Value, AI Field Value, and AI Process Value. OUT/HOLD 0.00 MEASURE 12.3 TB.
Any changes to the transmitter configuration must be saved. Pressing the Exit to MEASURE key prompts the user to “SAVE?” their changes. Pressing the YES key saves the new configuration and returns the transmitter to the Measure Mode. The NO key discards the changes and returns the transmitter to the Measure Mode. Upon exiting from the Modify state, the TB mode is returned from Out-Of-Service to its previously set state. Analyzer State The Analyzer State sets the type of measurement (i.e.
To define the end-point and break point values, a plot of temperature-compensated conductivity against solute concentration must be divided into five line segments that best approximate the shape of the conductivity-to-concentration curve. The beginning of the first and end of the fifth line segment identify the end-points of the approximation and output range. function that converts the conductivity measurements to concentration values. All concentration values have a fixed decimal point location.
50 45 40 Break Points Actual Conductivity-to-Concentration Curve Ammonium Nitrate (%) 35 30 25 20 15 10 5 0 0 50 100 150 200 250 300 350 400 Conductivity (mS/cm) Figure 21 – Conductivity-to-Concentration Break Point Determination Temperature Sensor State Temperature Compensation State The Temperature Sensor State configures the transmitter for use with a Pt100, 3 kohm Balco, 4.75 kohm Network or no RTD (NONE). Temperature has a marked effect on the conductance of solutions.
adjusted by completing a temperature calibration to the desired temperature value. The options for temperature compensation are grouped into two sets: MANUAL and AUTO (Automatic). MANUAL temperature compensation contains no additional options and is locked to a specific process temperature independent of the selected temperature sensor. If a different fitted temperature is desired, the new temperature can be State STD.
1.40 1.20 1.00 K/Kstd 0.80 0.60 Break Points Actual Non-linear Relationship 0.40 0.20 0.00 0 20 40 60 80 100 120 140 160 180 200 Temperature (C) Figure 25 – User-Defined Temperature Compensation Break Point Determination Diagnostic State CONFIG EXIT The Diagnostic State contains a toggle to enable (ON) or disable (OFF) built-in dirty sensor diagnostic detection. Dirty sensor detection monitors the drive level necessary to make the conductivity measurement.
SECURITY MODE The Security Mode of Operation establishes password protection against unauthorized changes to transmitter functions. Password protection can be assigned to the Calibrate and Configure Modes of Operation. Additional Security functions are available in the Resource Block and will be discussed in Resource Block Section. SECUR Bypass if no items are password protected.
UTILITY MODE The Utility Mode of Operation provides access to powerful functions not used during normal operating conditions. These functions have been separated into two categories: Factory and User. Factory functions are strictly reserved for factory personnel. User functions include Reset Configuration to default settings, Reset Security password, Reset All parameters to default settings, Software Reboot, FF Identification and Damping functions.
Since this identifier must have a unique value, the FF.ID state is password protected. To access to this screen, a user must contact the factory for further instructions. Transmitter Identification (FF.ID) State There are several ways to identify a transmitter in the network, and more precisely, three different addressing levels are used to characterize a FOUNDATION Fieldbus device. Damping State The Damping State applies a lag function on the process input.
The transmitter provides support for all Virtual Communication Relations (VCR). These relationships represent the rules for communication between objects connected on the fieldbus. Below is a brief description of these communication relationships. Report/Distribution VCR Type This type of communication is typically used by fieldbus devices to send alarm notifications or trend reports to a Master Device.
DEVICE BLOCKS All variables and parameters of the transmitter are structured in blocks with respect to their assignment of components or functions. This structure is termed the Function Block Application Process (FBAP) and has been designed to support five primary operational characteristics: 1. Configuration and definition of function blocks 2. Configuration of function block links 3. Alert processing 4. Access to information for operator interface, remote operation, diagnostics, and configuration 5.
• Field Device Resource Block Transducer Block AI Block Channel Values Object Dictionary indices at which the blocks start: Resource Block – 259 Analog Input 1 – 350 Analog Input 2 – 390 Transducer Block – 430 Channel Algorithm Sensor Block Parameters Out • Acyclic Data Cyclic Data • Fieldbus Figure 30 – FBAP Interaction Diagram • Function blocks contain Fieldbus Foundation-defined parameters that have been defined by the specifications governing this communications technology.
The Resource Block includes data and parameters that defined the overall operation of the device. These parameters describe the hardware specific characteristics of the device. The following table lists the Resource Block parameter information.
RESOURCE BLOCK (cont’d) FREE_TIME 4 D R - 4 4 S S R/W R/W 640000 640000 Fault State 1 N R 1 1 1 D D S R/W R/W R 1 1 8 1 S R/W Max_Notify CONFIRM_TIME Set Fault State Clear Fault State Max Notifications Limit of Notifications Confirmation Time 4 S R/W 640000 34 WRITE_LOCK Write Locking 1 S R/W 1 35 UPDATE_EVT BLOCK_ALM 37 ALARM_SUM 1 1 8 2 2 1 1 8 2 1 2 2 2 2 D D D D D D D D D D D D D S R/W R R R R R/W R R R R R R R R/W 0 0 0 0 0 36 Unacknowledged Update State Time
The Transducer Block contains block parameters that configure the device’s functionality. It insulates the sensor characteristics and signal conditioning from the other device Function Blocks. Specifically, it interprets the sensor signal based on configured values, applies factory and process calibration data, compensates for temperature and process effects, and converts the resulting values in the configured Engineering Units that can be used by the Analog Input Blocks contained within the device.
CONDUCTIVITY/CONCENTRATION TRANSDUCER BLOCK IDX Name Description Bytes ST AR Default Valid Range 0 1 2 3 4 5 BLOCK_OBJ ST_REV TAG_DESC STRATEGY ALERT_KEY MODE_BLK Block Object Static Revision TAG Description Strategy Alert Key Target Actual Permitted Normal 62 2 32 2 1 1 1 1 1 S S S S N D S S R R/W R/W R/W R/W R R/W R/W 0 Spaces 0 0 OOS 1 to 255 Auto, OOS Auto, OOS Auto Auto, OOS Auto, OOS 0 – Off 1 – On 6 BLOCK_ERR Block error 2 D R 7 UPDATE_EVT 8 BLOCK_ALM 1 1 8 2 2 1 1 8 2 1
CONDUCTIVITY/CONCENTRATION TRANSDUCER BLOCK (cont’d) IDX Name Description Bytes ST AR Default 20 SENSOR_SN SENSOR_CAL_ METHOD SENSOR_CAL_ LOC SENSOR_CAL_ DATE SENSOR_CAL_ WHO Serial Number 32 N R All blanks Calibration Method 1 S R/W 104 Calibration Location 32 S R/W All blanks Calibration Date 7 S R/W All blanks Personnel Name 32 S R/W All blanks 4 D R 1 D R 2 S R/W 21 22 23 24 25 26 SECONDARY_ VALUE_1 SECONDARY_ VALUE_UNIT_1 27 SECONDARY_ 28 VALUE_2 SECONDAR
CONDUCTIVITY/CONCENTRATION TRANSDUCER BLOCK (cont’d) IDX Name Description Bytes ST AR Default Valid Range Note 37 USRDEF_TC_ CURVE_ MODIFY_ OPTION User Defined Temperature Compensation Modify Option 1 S R/W 0 (Modify individual entry) 0 – Individual Entry 1- Entire Table Note H R/W x, y 0, 1.8 25, 1.00 50, 0.69 75, 0.50 100, 0.38 156, 0.
CONDUCTIVITY/CONCENTRATION TRANSDUCER BLOCK (cont’d) IDX Name 49 TEMP_ CAL_UNIT 50 PV_CAL_SLOPE PV_CAL_SLOPE_ UNIT 51 Description Temperature Calibration Value Units PV Calibration Slope PV Calibration Slope Unit Bytes ST AR Default Valid Range 2 S R/W 1001 (°C) Table 4 4 S R/W 100% 20 to 500 % 2 N R 1342 (%) 1342 (%) -20 to +20 µS/cm (Sensor Group A) 52 PV_CAL_OFFSET PV Calibration Offset 4 S R/W 0 µS/cm -4 to +4 µS/cm (Sensor Group B) -0.8 to +0.
The Analog Input Function Block can be mapped to one out of the five outputs channels from the Transducer Block and makes this information available to other function blocks on the fieldbus network. The CHANNEL parameter selects the input from the Transducer Block.
ANALOG INPUT 1 - FUNCTION BLOCK IDX Name Description Bytes ST AR Default Valid Range 0 1 2 3 4 5 BLOCK_OBJ ST_REV TAG_DESC STRATEGY ALERT_KEY MODE_BLK Block Object Static Revision TAG Description Strategy Alert Key Target Actual Permitted Normal 62 2 32 2 1 1 1 1 1 S S S S N D S S R R/W R/W R/W R/W R R/W R/W 0 Spaces 0 0 OOS OOS, Auto, Man Auto 1 to 255 OOS, Auto, Man 6 BLOCK_ERR Block error 2 D R 7 PV 8 OUT 9 SIMULATE Process value Status Measured Value Status Simulate Status Si
ANALOG INPUT 1 - FUNCTION BLOCK (cont’d) IDX Name Description Bytes ST AR Default 21 BLOCK_ALM 22 ALARM_SUM 1 1 8 2 1 2 2 2 2 D D D D D D D D S R/W R R R R R R R R/W 0 0 0 0 0 0 0 0 0 23 ACK_OPTION 2 S R/W 0 24 25 26 27 28 29 30 31 32 33 ALARM_HYS HI_HI_PRI HI_HI_LIM HI_PRI HI_LIM LO_PRI LO_LIM LO_LO_PRI LO_LO_LIM HI_HI_ALM 34 HI_ALM 35 LO_ALM 36 LO_LO_ALM Unacknowledged Alarm State Time Stamp Sub-code Value Current Unacknowledged Unreported Disabled Automatic Acknowledge Option
ANALOG INPUT 2 - FUNCTION BLOCK IDX Name 0 1 2 3 4 5 BLOCK_OBJ ST_REV TAG_DESC STRATEGY ALERT_KEY MODE_BLK Description Bytes ST AR Default Valid Range Static Revision TAG Description Strategy Alert Key Target Actual Permitted Normal 62 2 32 2 1 1 1 1 1 S S S S N D S S R R/W R/W R/W R/W R R/W R/W 0 Spaces 0 0 OOS OOS, Auto, Man Auto 1 to 255 OOS, Auto, Man 6 BLOCK_ERR Block error 2 D R 7 PV 8 OUT 9 SIMULATE Process value Status Measured Value Status Simulate Status Simulate Value
ANALOG INPUT 2 - FUNCTION BLOCK (cont’d) IDX Name Description Bytes ST AR Default 21 BLOCK_ALM 22 ALARM_SUM 1 1 8 2 1 2 2 2 2 D D D D D D D D S R/W R R R R R R R R/W 0 0 0 0 0 0 0 0 0 23 ACK_OPTION 2 S R/W 0 24 25 26 27 28 29 30 31 32 33 ALARM_HYS HI_HI_PRI HI_HI_LIM HI_PRI HI_LIM LO_PRI LO_LIM LO_LO_PRI LO_LO_LIM HI_HI_ALM 34 HI_ALM 35 LO_ALM 36 LO_LO_ALM Unacknowledged Alarm State Time Stamp Sub-code Value Current Unacknowledged Unreported Disabled Automatic Acknowledge Option
Note. A) PRIMARY_VALUE_TYPE parameter establishes the type of measurement the device is performing. The default measurement type is Conductivity. When writing to this parameter (i.e., switching the device measurement type to Concentration), the device should be kept in OOS mode until all the necessary TB and AI variables are properly configured. B) PRIMARY_VALUE is the output from the TB and the default input for AI1. This value is used by the XD_SCALE parameter.
TABLE 1 TABLE 6 PRIMARY_VALUE_TYPE Codes 113 Conductivity 117 Concentration LINEARIZATION_TYPE Codes Table 1 Direct 2 Indirect 3 Indirect Square root TABLE 2 Engineering unit codes related PRIMARY_VALUE_TYPE 1302 mS/cm for PRIMARY_VALUE_TYPE = (Conductivity) 1586 µS/cm for PRIMARY_VALUE_TYPE = (Conductivity) 1342 % for PRIMARY_VALUE_TYPE = (Concentration) 1423 ppm for PRIMARY_VALUE_TYPE = (Concentration) 1424 ppb for PRIMARY_VALUE_TYPE = (Concentration) 1588 no units for PRIMARY_VALUE_TYPE = (Concentrat
Channel PV: Conductivity or Concentration Sensor Input Transducer Block SV1: Temperature Analog Input Function Block 1 OUT SV2: Concentration or Conductivity Channel Analog Input Function Block 2 OUT Figure 33 - Possible Connections Between the TB and AI’s The table below gives a summary of the relation between the selected measurement and available variables/channels that can be used as an input for the Analog Input Function Blocks.
Note. A Cold Startup will adjust several parameters to a defined default value. Cold Startup may be used to reset the initial operating condition of the transmitter. When the Cold Start switch is in the ON position on transmitter power up, critical transmitter parameters will be reset to default values. The SW3 switch must be in the OFF position to ensure user configured data is not overwritten on transmitter power up.
SIMPLE FAULT FINDING If the transmitter does not appear to be working satisfactory, carry out the following troubleshooting checks before contacting your nearest Service Center or Factory Representative. If the instrument is to be returned for repair, ensure that it is adequately packed using the original polystyrene box or high-density chip foam. The Return Materials Authorization (RMA) number must be sent with the instrument. Equipment returned to ABB Inc.
DIAGNOSTIC INFORMATION The TB82EC FF transmitter performs a number of diagnostic checks on hardware, software, and sensor functions. If a nonconforming condition is detected, the user is alerted to faults locally by a flashing FAULT indicating icon and remotely by a configuration and/or system/host tool. When using the local HMI, diagnostic faults are interrogated using the FAULT Info key in the Measure Mode. A short text string and fault code is alternately shown in the secondary display region.
Fault Code PC12 Fault Text String TEMP.AD PC20 PC21 PC30 PC31 PC32 PC33 PC34 PC35 PC36 PC37 PC38 PC39 PC40 PC41 PC42 PC43 PC44 PC45 PC46 PC47 PC50 PC51 PC52 PC53 PC54 PC55 PC56 PC57 PC58 PC59 PC60 PC61 PC62 PC63 PC64 PC65 PC66 PC67 PC70 PC72 BAD.SEE NO.F.CAL R0.F.CAL R1.F.CAL R2.F.CAL R3.F.CAL R4.F.CAL G0.F.CAL G1.F.CAL G2.F.CAL G3.F.CAL G4.F.CAL W0.F.CAL W1.F.CAL W2.F.CAL W3.F.CAL W4.F.CAL BA.F.CAL PT.F.CAL RT.F.CAL R0.CHKS R1. CHKS R2. CHKS R3. CHKS R4. CHKS G0. CHKS G1. CHKS G2. CHKS G3. CHKS G4.
Sensor Group C also indicates a potentially bad process calibration or poorly performing sensor. Again, a bad calibration will be reported, and the user returned to the beginning of the calibration cycle. Additional Diagnostic Messages Other diagnostic messages may appear during transmitter programming. These messages include BAD.VAL (bad value) and DENIED. For temperature, a bad calibration will be reported and calibration values will not be accepted for Slope values that are less than 0.
sensor leads (i.e., green, red, white, black, and heavy green leads). The reading must be less than 0.05 nS. where T is in degrees Celsius. The measured resistance should be within the expected value by ± 5%. 2. Check the conductance between the green Drive lead and each of the other sensor leads (i.e., black, white, red, and heavy green leads). The reading must be less than 0.05 nS. Moisture intrusion behind the sensor electrode seal can be detected with the sensor removed from the process.
Note. 1. The transmitter calibration values must be set back to factory values in order for the sensor simulation procedure to be valid. 2. Lead wire and contact resistance becomes a significant part of simulated conductivity for simulated resistance values less than 10 ohms. Measure all resistances going to the transmitter to ensure accurate results. Sensor Group Variable Resistance (ohm) Open 100,000 50,000 5,000 1,000 500 100 50 C Desired Display Value Actual Display Value 0.000 µS/cm 0.050 µS/cm 0.
In addition to the dynamic variable status, Block Error Parameters provide error status of hardware or software components that are associated with and/or directly impact the correct operation of the Transducer Block. The three parameters include BLOCK_ERR, block alarm sub-code, and XD_ERROR. The BLOCK_ERR parameter can have several status conditions. The block alarm sub-code and XD_ERROR parameters provide additional information on the diagnostic condition.
Problem/Error Code and Text Prompt Code Text Problem & Error Description PC45 to xx.F.CAL SEE Temp fac cal errors xx.CHKS SEE PV checksum errors xx.CHKS SEE Temp checksum errors PC47 PC50 to PC64 PC65 to PC67 PC70 GL.AD PC72 DS.AD Ground Loop signal above/below transmitter A/D range. Dirty Sensor diagnostic signal above/below transmitter A/D range.
DISMANTLING AND REASSEMBLY b) Warning. Substitution of any components other than those assemblies listed in this section will compromise the certification listed on the transmitter nameplate. Invalidating the certifications can lead to unsafe conditions that can injure personnel and damage equipment. c) d) Caution.
SPECIFICATIONS Property Process Display Range Conductivity Concentration Temperature Display Range Sensor Full Scale Measurement Ranges Resolution, Display Conductivity Concentration Temperature Accuracy, Display Conductivity Temperature Nonlinearity, Display Conductivity Temperature Repeatability, Display Conductivity Temperature Stability, Display Conductivity Temperature Temperature Compensation Input Types Conductivity/ Concentration Temperature Dynamic Response Ambient Temperature Effect Conductivity
Property Maximum Span (full scale settings) Conductivity Concentration Temperature Damping Supply Voltage Turn-On Time Maximum Sensor Cable Length Sensor Diagnostic Diagnostic Notification Local HMI Environmental Operating temperature LCD Range Storage temperature Mounting Effect Enclosure Classification Size Height Minimum panel depth Maximum panel cutout Recommended panel cutout Weight I-E67-TB82FF-2A February 13, 2002 Characteristic/Value Sensor Group A: 1999 mS/cm Sensor Group B: 1999 S/cm Sensor Grou
Property EMC Requirements Characteristic/Value CE certified: Electromagnetic Conformance IEC61326-1: 2000 EN55011: 1991 (CISPR11: 1990) EN61000-4-2: 1995 EN61000-4-3: 1997 EN61000-4-4: 1995 EN61000-4-5: 1995 EN61000-4-6: 2001 EN61000-4-8: 1994 Agency Approvals1 (pending) Factory Mutual (FM) Intrinsic safety Class I, II, III; Division 1; applicable Groups A, B, C, D, E, F and G; T4 when used with appropriate barriers per Drawing PXXXX.
GLOSSARY OF PROGRAMMING TEXT PROMPTS TEXT STRING 3K.BLCO 4.75K.RTD A GRP AAAAAA ACID AI-.BLK AI-.FV AI-.OUT AI-.PV ANALZR AUTO B GRP BAD.CAL BAD.VAL BASE C GRP CALIBR CON.CAL CONCEN COND CONFIG D.P.POS DAMPNG DENIED DIAGS DISABL EDT.CAL ENABLE FF.ID HARD.LK H2SO4 HCL K1/K25 MANUAL MODIFY NACL NAOH NEUTRL NEW.VAL NEW.VL.C NEW.VL.F NO D.P. NO.ICON NONE OFFSET OUT.CAL OOS OUTPUT PASSWD PT 100 DESCRIPTION 3 kohm Balco (Temperature Compensation). 4.75 kohm RTD Network. Sensor Group A. Alphanumeric Entry.
TEXT STRING PUR.H2O PV OFF PV SLP RESET? REV.A10 RST.ALL RST.CAL RST.CON RST.SEC RST.SFT SAVE? SEC.DSP SECUR SLOPE STABL? T.OFFoC T.OFFoF TC.COEF TC.TYPE TB.OOS? TB.PV.LO TB.PV.HI TB.RNGE TC.TYPE TMP TMP.CAL TMP.SLP TMP.SNS TMPoC U.D.UNIT UNITS USER USR.DEF VIEW WRT.ERR X1.COND Y1.CONC DESCRIPTION Pure Water. Process Variable Offset Value for the installed sensor. Process Variable Slope Value for the installed sensor. Query to Reset parameters to default values. Software Revision A10.
TB82EC WORKSHEET Tag: Date: Analyzer Type: CONDUCTIVITY SENSOR GROUP: A B Temperature Sensor: None Temperature Compensation Type: Diagnostics: Security: CONCENTRATION SENSOR GROUP: A B C 0-15% NaOH 0-20% NaCl 0-18% HCl 0-20% H2SO4 User-defined: Engineering Units:__________ COND1:______ CONC1:______ COND2:______ CONC2:______ COND3:______ CONC3:______ COND4:______ CONC4:______ COND5:______ CONC5:______ COND6:______ CONC6:______ C 3k Balco Pt100 Manual Auto: 0-15% NaOH 0-20% NaCl 0-18% HCl 0-20% H
PRODUCTS & CUSTOMER SUPPORT Customer Support A Comprehensive Instrumentation Range ABB Instrumentation provides a comprehensive after sales service via a Worldwide Service Organization. Contact one of the following offices for details on your nearest Service and Repair Center. Analytical Instrumentation • Transmitters On-line pH, conductivity, and dissolved oxygen transmitters and associated sensing systems.
Client Warranty Prior to installation, the equipment referred to in this manual must be stored in a clean, dry environment, in accordance with the Company's published specification. Periodic checks must be made on the equipment's condition. In the event of a failure under warranty, the following documentation must be provided as substantiation: 1. A listing evidencing process operation and alarm logs at time of failure. 2. Copies of operating and maintenance records relating to the alleged faulty unit.
TROUBLE SHEET TROUBLE SHEET WARRANTY REPAIR REPAIR ORDER Rejection or discrepancy reports Copy attached Not available • IDENTIFICATION Customer Purchase order No. Plant Name of person to Instrument contact Nomenclature Model Serial Number • OPERATING CONDITIONS Specify location, environmental conditions, type of service and approximate number of operating hours or date of installation if known.
EC DECLARATION OF CONFORMITY ABB Incorporated 2175 Lockheed Way Carson City, NV 89706 USA We declare under our sole responsibility that the product: TB82EC Foundation Fieldbus Transmitter Series is in conformity with the following standards: Electromagnetic Conformance - IEC61326-1: 2000 EN55011: 1991 (CISPR11: 1990) EN61000-4-2: 1995 Class A 4 kV Contact 6 kV Indirect 10 V/m 1 kV 2kV Line to Earth 1kV Line to Line 3V 30A/m EN61000-4-3: 1997 EN61000-4-4: 1995 EN61000-4-5: 1995 EN61000-4-6: 2001 EN61000-
The Company’s policy is one of continuous product improvement and the right is reserved to modify the information contained herein without notice. ABB ABB Incorporated 2175 Lockheed Way Carson City, NV 89706 USA Tel: 1(775)883-4366 Fax: 1(775)883-4373 I-E67-TB82FF-2A February 13, 2002 ABB Instrumentation Ltd Oldends Lane Stonehouse, Glos. UK, GL10 3TA Tel: +44 (0) 1453-826-661 Fax: +44 (0) 1453-827-856 17 (10.
