JUMO dTRANS T06 Operating Instructions Manual
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JUMO dTRANS T06 Operating Instructions Manual

Multifunctional four-wire-transmitter in mounting rail case in accordance
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Summary of Contents for JUMO dTRANS T06

  • Page 2: Operating Overwiew

    Operating overwiew...

  • Page 3: Table Of Contents

    Table of contents Operating overwiew ............2 Brief description .
  • Page 4 Table of contents Display and control elements............26 Setting the display after device is switched on .
  • Page 5 Table of contents 6.7.2 Calculations of the DIN EN ISO 13849-1 performance level – 707071/X - 23/XXX (AC240V) ....47 6.7.3 Calculations of the DIN EN ISO 13849-1 performance level – 707071/X - 29/XXX (DC24V) ....47 6.7.4 Risk reduction through the control system .
  • Page 6 Table of contents 7.4.3 Temperature difference ............... .66 7.4.4 Temperature compens.
  • Page 7 Table of contents 7.5.9 Signal from diagnosis error ..............70 7.5.10 Simulation output .
  • Page 8 Table of contents 8.2.2 Operating hours since last configuration ............78 Hardware recognition.
  • Page 9 Table of contents 10.6 Switch on / switch off SIL extra code ..........93 10.7 Checking of safety relevant system settings .

  • Page 10: Brief Description

    1 Brief description Brief description The transmitter acquires the temperature through an RTD temperature probe or a thermocouple (double thermocouple). The transmitter can also acquire standard signals such as .current 0(4) to 20 mA or voltage 0 to (1)10 V. Additionally resistance transmitter with three-wire circuit, or resistance/potentiometer with two-wire/three-wire/four-wire circuit can be acquired.

  • Page 11: Safety Information

    Safety information Symbol Meaning Explanation Important in- This symbol refers to important information about the product, its handling, or additional benefits. formation Danger This symbol indicates that personal injury from electrocution may occur if the appropriate precau- tionary measures are not taken. Caution This symbol in connection with the signal word indicates that material damage or data loss will oc- cur if the respective precautionary measures are not taken.

  • Page 12: Identifying The Device Version

    2 Identifying the device version Identifying the device version The nameplate is glued laterally to the device. SIL approval Voltage supply AC 110 to 240 V: Voltage supply DC 24 V: Caution The voltage supply that is connected must correspond to the voltage specified on the nameplate!

  • Page 13: Scope Of Delivery

    Basic type TRANS T06 Junior 707071 dTRANS T06 Version Standard with default settings Customer-specific configuration (specifications in plain text) Voltage supply AC 110 to 240 V +10/-15 %, 48 to 63 Hz DC 24 V +10/-15 % Extra codes None...

  • Page 14: Accessories

    2 Identifying the device version Accessories Item Part no. Setup program on CD-ROM, multilingual 00668006 USB cable A-connector to Micro-B connector, length 3 m, for type 707071 00616250 Screw-on end clamp for mounting rail 00528648 Device software version, fabrication number Chapter 8.1 "Version"...
  • Page 15 Any interference with the inside of the device is prohibited! Repairs may be only performed by JUMO in the company's headquarters in Fulda. If you have any problems, please contact the nearest branch office or the head office.

  • Page 16: Mounting

    3 Mounting Mounting Dimensions...

  • Page 17: Mounting Site, Din-Rail Mounting

    Mounting site, DIN-rail mounting Warning The device is not suitable for installation in potentially explosive areas. The device is clipped to a 35 mm DIN-rail (DIN EN 60715) from the front and locked into place by pressing downwards. The ambient conditions at the installation site must meet the requirements specified in the technical data.

  • Page 18: Dismounting

    3 Mounting Dismounting Place screwdriver in release catch and press upwards (1). Remove housing upwards (2).

  • Page 19: Galvanic Isolation

    Galvanic isolation Analog input Analog output AC 1800 V RS485- Interface USB-Interface extra code) AC 520 V Relay output limit value Display (extra code) AC 4260 V Membrane keyboard » AC 4260 V Voltage supply DC 24 V +10/-15 % AC 110 to 2 0 V +10/-15 %,48 to 63 Hz Use of the USB interface The USB interface is only designed for service use over a limited period, since the device switches the output signal to safe...

  • Page 20: Electrical Connection

    4 Electrical connection Electrical connection Installation notes Check to see if the device is installed in a manner appropriate to the application (temperature measurement) and that it is operated within the admissible plant parameters. The device is intended to be installed in switch cabinets, machines, or plants. Ensure that the customer's fuse protection does not exceed 20 A.

  • Page 21: Connection Diagram

    Connection diagram The connection is made via slot-encoded screw terminals. Conductor Admissible cross sec- tion Note: Please ensure that any terminals removed for wiring or device exchange are reconnected at the correct position. Rigid or flexible 0.2 to 2.5 mm Flexible with ferrule with or 0.25 to 2.5 mm without plastic sleeve...

  • Page 22: Analog Input (Part Of The Safety Channel)

    4 Electrical connection Terminals Comment Screw terminals 4.2.1 Analog input (part of the safety channel) RTD temperature probe in two-wire circuit RTD temperature probe in three-wire circuit RTD temperature probe in four-wire circuit Resistance/potentiometer in two-wire circuit 51,52,53,54 41,42,43,44 Resistance/potentiometer in three-wire circuit Resistance/potentiometer in four-wire circuit...
  • Page 23 Terminals Comment Screw terminals Potentiometer/WFG A: Start resistance S: Loop resistance E: End resistance Thermocouple Double thermocouple (galvanically isolated) mV input (0 to 1 V) 4 to 20 mA 51,52,53,54 0 to 20 mA 41,42,43,44 0 to 10 V 4 Electrical connection...

  • Page 24: Analog Output (Part Of The Safety Channel)

    4 Electrical connection Terminals Comment Screw terminals 4.2.2 Analog output (part of the safety channel) Note: If an open current output is detected, this leads to an error. Remedy: Install a 470 Ω resistor until the output in the system is wired correctly. 0(4) to 20 mA 0(2) to 10 V 51,52,53,54...

  • Page 25: Extra Codes

    Terminals Comment Screw terminals USB interface (Device) Micro-B connector, standard (5-pin) 4.2.4 Extra codes Relay output limit value (zero-current state) 11,12,13,14 Relay (changeover contact) with installed micro fuse 21,22,23,24 3.15 A, slow 31,32,33,34 RS485 interface Default setting 4 Electrical connection...

  • Page 26: Startup Of The Device

    5 Startup of the device Startup of the device Display and control elements When the voltage supply is set up, a self-test begins during which the back-lit display shows white pixels for 2 s and then black pixels for 2 s. The LED lights up yellow. The self-test is followed by a language request and then the main measured value appears:...
  • Page 27 Diagram Legend Comment LCD display Black/white with backlight, 64 x96 pixels Keys Increase value / previous menu item Reduce value / next menu item Back / cancel change One level lower in the menu, confirm change • Lights up green if the diagnostic function does not detect any errors. •...

  • Page 28: Extra Code Sil

    5 Startup of the device Extra code SIL For a device with extra code 058, SIL operation is activated per default and shown in the display at the top left. The following specifications apply in SIL operation: 1.) Only the following sensor types can be set at the analog input: Double thermocouple, RTD temperature probe or 4 to 20 mA 2.) Only the signal type 4 to 20 mA can be set at the analog output, simulation cannot be activated and only high or low can be selected as an error signal, not any value.

  • Page 29: Signal Flow

    Signal flow The following example shows which parameters influence the measured value from the analog input to the analog output. 5 Startup of the device...
  • Page 30 5 Startup of the device Here is a summary of the parameters from the figure above:...
  • Page 31 5 Startup of the device...

  • Page 32: Safety Manual

    6 Safety Manual Safety Manual Warning All safety relevant parameters must be validated by the plant operator. In devices with extra code 058 the SIL oper- ation is activated per default. The settings for SIL operation are described in Chapter 5.3 and the default settings in Chapter 7 are marked (bold) and SIL-Parameter are marked yellow.

  • Page 33: Validity Of The Safety Manual

    Validity of the safety manual Note The evaluation described in this safety manual in terms of functional safety and display of certificates is valid for the specified transmitter in SIL operation, including probe versions. Safety manual (probe for connection to 707071 Variant 1 and 2 ) Special operating statuses 6.3.1 Behavior after a power failure...

  • Page 34: Issue Of An Error Signal (Safe State)

    6 Safety Manual 6.3.4 Issue of an error signal (safe state) In SIL operation, the measured value at the analog input is always issued at the analog output 4 to 20 mA. The limit values according to Namur NE 43 (≤ 3.6 or ≥ 21 mA) are only issued when internal errors, probe errors, or a limit value monitoring function (extra code) are identified.

  • Page 35: Terms And Abbreviations According To Din En 61508 And Din En 61511

    6.5.1 Terms and abbreviations according to DIN EN 61508 and DIN EN 61511. Name Description Actuator Part of a safety-related system that intervenes in the process to achieve a safe state. EUC (equipment under control) Equipment, machine, apparatus, or system used for manufacturing, shaping materials, for transport, medical purposes, or other activities.
  • Page 36 6 Safety Manual Name Description Safe failure Failure of an element and/or subsystem, and/or system involved in implementing the safety function, which a) causes false triggering of the safety function, switching the EUC (or parts of it) to a safe state, or maintaining a safe state;...
  • Page 37 Name Description Rate of undetected dangerous failures per hour Lambda Dangerous Undetect: λ λ Rate of safe failures per hour Lambda Safe: λ Rate of detected safe failures per hour Lambda Safe Detect: λ Rate of undetected safe failures per hour Lambda Safe Undetect: BPCS Basic process control system...

  • Page 38: Safety-Relevant Parameters

    6 Safety Manual 6.5.2 Safety-relevant parameters All following informations relate to the connection-Variant 3. The following parameters were calculated using the formular in Chapter 6.5.5 for T = 1, 3, and 5 years. 6.5.3 Failure rates and SFF for 707071/X – 23/XXX (AC240V) Variant 3 λ...

  • Page 39: Calculation Of Pfd Avg

    6.5.5 Calculation of PFD The operator defines the following topics: Proof test interval T Planned operating duration mission time T the PTC-value for the performed Proof test (A,B or C) The mission time T has to be at least equal the time for the proof test interval T , but not exceed the Lifetime of 10 years.
  • Page 40 6 Safety Manual        " !" &'     ) * * ,  ) * &' ) * ++ * ,  ) * ++ &' ) * + * ,  ) * + + &'...

  • Page 41: Determining The Safety Integrity Level (Sil)

    Determining the safety integrity level (SIL) The achievable safety integrity level is determined by the following safety-related parameters: Average probability of dangerous failures of a safety function on demand (PFD Hardware fault tolerance (HFT) and Safe failure fraction (SFF). The specific safety-related parameters for the 707071 measuring system can be found in the table in the "Safety-related pa- rameters"...

  • Page 42: Safety Integrity Of The Hardware

    6 Safety Manual 6.6.1 Safety integrity of the hardware According to DIN EN 61508, a distinction must be made between systems of type A and systems of type B. A subsystem can be considered to be type A if, for the components required to achieve the safety function, the failure behavior of all components used is sufficiently defined, and the behavior of the subsystem can be fully determined under error conditions;...

  • Page 43: Safety-Relevant System Properties

    6.6.2 Safety-relevant system properties The type 707071 transmitter is realized as a 1oo1D architecture. The following are monitored: Probe break Probe short circuit Random hardware failure in the sensor channel Safety feature Requirement / comment SIL2 Systematic suitability of HW and SW Operating mode in terms of safety func- Operating mode with low and high demand rate possible on a customer-specific tion...

  • Page 44: Redundant Use Of The System

    6 Safety Manual Safety feature Requirement / comment 707071 safety architecture 1oo1D This corresponds to architecture category 2 according to DIN EN ISO 13849, i.e. the system has a safety channel and an additional diagnostics channel. Hardware failure tolerance HFT = 0 SFF ≥...

  • Page 45: Sensor Connection Possibilities

    SIL of the used systematic capability max. achievable SIL of the system max. achievable SIL of the system in Sensor (SC) of the used Sensor with 1oo1 sensor system and tempe- redundant use (HFT = 1) of Sensor and rature transmitter architecture temperature transmitter 6.6.4 Sensor connection possibilities...

  • Page 46: Terms And Abbreviations According To Standards Series Din En Iso 13849

    6 Safety Manual 6.7.1 Terms and abbreviations according to standards series DIN EN ISO 13849 Formula symbol or ab- Description Definition breviation or location PL (a, b, c, d, e) Designation for the performance level Table 3 in DIN EN ISO13849-1 AOPD Active opto-electronic protective device (e.g.

  • Page 47: Calculations Of The Din En Iso 13849-1 Performance Level - 707071/X - 23/Xxx (Ac240V)

    PL c The two variants of the dTRANS T06 meet the architecture requirements for a category 2 system. The necessary limit values according to DIN EN ISO 13849-1, Table K.1 for performance level c and the fundamental and established safety principals are adhered to for all voltage versions of type 707071 considered.

  • Page 48: Risk Reduction Through The Control System

    6 Safety Manual The following chart can be used to determine the PL if the MTTF value of the sensor is 100 years. The reached DC for identi- fying the errors of the sensor of the temperature transmitter will be calculated at (HFT = 1) with ≥ 60% in a redundant applica- tion.

  • Page 49: Other Applicable Device Documentation

    Performance level (PL) Average probability of a dangerous failure per hour 1/h ≥ 10 to < 10 ≥ 10 to < 10 NOTE: in addition to the average probability of a dangerous failure per hour, further measures are required to achieve the PL. Other applicable device documentation For the transmitter type 707071, the measures, values, and requirements specified in this operating manual regarding installa- tion, electrical connection, function, and startup must be observed.

  • Page 50: Proof Test A

    6 Safety Manual 6.10.1 Proof test A (corresponds to factory calibration) For a complete check, the device must be removed from the operating facility and sent to the manufacturer. For service addresses see back cover Voltage supply Detection of dangerous undetected failures (λ AC 110 to 240 V +10/-15 %, 48 to 63 Hz 0.750 75 %...

  • Page 51: Proof Test B

    6.10.2 Proof test B Step Action Please note Disconnect all test piece connections. Test piece is completely discon- Test the resistance between the following connections with an ohmmeter: nected from the operating facili- ty and without power supply. 21 to 22: low-resistance, 0 Ω Verification that there is no short 21 to 23: high-resistance, ohmmeter overrun circuit in the area of connections...
  • Page 52 6 Safety Manual Step Action Please note Connect resistance decade for simulation of the input signal that is appropriate for Verification that there is no error the chosen configuration. Verify whether the expected value (display value) corre- status internally if display cor- sponds to the input signal.
  • Page 53 Step Action Please note Set limit value of the relay (function AF7) in the middle of the configured measuring Verification that the relay has not range. Connect positive terminal of a voltage source (24 V ±5 %, 500 mA) to the switched below the configured terminal connection 22 via a resistor (240 Ω, 5 W).
  • Page 54 6 Safety Manual Step Action Please note Restore line to the measurement input connection 51. Both the display and the Verification that in the event of current meter at the analog output must display values that correspond to the in- interruption of the output signal put signal present close to the measuring range end.
  • Page 55 Step Action Please note Switch off test piece and connect current meter using a burden of 500 Ω between Verification that the output driv- connections 42(+) and 41(-). er stage of the analog output Switch on test piece and configure analog output for simulation of current output can drive the maximum permis- signal 21.2 mA.

  • Page 56: Proof Test C

    6 Safety Manual 6.10.3 Proof test C Step Action Please note Test the current device status of the test piece with the setup program. Status must be 'OK' If active, deactivate SIL operation of the test piece. Verification of the proper function of the Configure analog output for simulation of current output signal.

  • Page 57: Recommended Tests For Temperature Probes

    Warning After the mission time expires, the systems no longer meet the requirements according to their SIL certification. 6.10.4 Recommended tests for temperature probes To ensure safe and reliable operation of the thermometers, the following service and maintenance work must be performed: The following tests are recommended at certain intervals: Every 12 months, the insulation resistance of the measuring circuit must be measured against the protection fitting (for thermocouples: only for the insulated measuring circuit;...
  • Page 58 6 Safety Manual 1000 °C Non-precious metal year Precious metal 2 years 1500 °C 1 year Note The testing intervals for probes specified here are recommendations that must be adapted to the special conditions at the operating location and, if necessary, the user should perform the tests more regularly.
  • Page 59 6 Safety Manual...

  • Page 60: Configuration

    7 Configuration Configuration Overview All the parameters are freely accessible, but they can be locked via a code on the device or with the setup program. Default settings are shown in bold. All parameters are listed in the following tables. Parameters which are not required are automatically hidden depending on the setting.

  • Page 61: Device Data

    Device data Value range Parameter Comment (default setting in bold) 7.2.1 Language German German, English, French, Spanish English French Spanish 7.2.2 Unit A unit for the measured value can be set here. °C, °F, %, text °C °F Text: Via the setup program, 9 characters can be entered here for an- other unit, e.g.

  • Page 62: Display/Operation

    7 Configuration Display/operation Value range Parameter Comment (default setting in bold) 7.3.1 Normal display This sets the view that appears after the voltage supply Main view, bar graph, limit is switched on. value, drag indicator, TAG Chapter 7.1 "Overview" no. and info text, I/O info Main view Bar graph...

  • Page 63: Lighting

    Value range Parameter Comment (default setting in bold) 7.3.4 Lighting Here, the background lighting of the display is set. Always off, Always on, When button is pressed Always off: always switched off Always on: always switched on When button is pressed: The background lighting is only switched on when the keys are operated and it lights up until the time for the timeout backlight has expired.

  • Page 64: Analog Input

    7 Configuration Analog input Value range Parameter Comment (default setting in bold) 7.4.1 Sensor type RTD temperature probe in 2-wire circuit RTD temperature probe in 3-wire circuit RTD temperature probe in 4-wire circuit Resistance/potentiometer in 2-wire circuit Resistance/potentiometer in 3-wire circuit Resistance/potentiometer in 4-wire circuit Resistance transmitter Thermocouple...

  • Page 65: Linearization

    7.4.2 Linearization Comment Measuring range Linear No sensor linearization Pt100 IEC 60751:2008 -200 to +850 °C Pt500, Pt1000 IEC 60751:2008 -200 to +850 °C Pt50 GOST, Pt100 GOST GOST 6651- 2009 A.2 -200 to +850 °C Ni 100, Ni 500, Ni1000 DIN 43760:1987-09 -60 to +250 °C Ni 100 GOST...

  • Page 66: Temperature Difference

    7 Configuration 7.4.2 Linearization Comment Measuring range W3Re-W25Re "D" ASTM E1751M-09 (up to 2315 °C): 2009 -0 to +2315 °C Platinel type PLII -0 to +1395 °C Customer-specific This setting only appears if a customer-specific linearization has been entered via the setup program and transferred to the device.

  • Page 67: Resistance Rx

    Value range Parameter Comment (default setting in bold) 7.4.8 Resistance Rx Parameter appears for setting "resistance/potentiome- 0 to 100, 400, 4,000 or 10,000 Ω ter" with 2, 3 or 4-wire circuit Here, the total ohmic resistance of the potentiometer area covered must be entered. 7.4.9 Line resistance R Here, the line resistance R (2-wire circuit) is entered.

  • Page 68: Resistance Ra, Rs And Re

    7 Configuration Value range Parameter Comment (default setting in bold) 0 to 400, 4,000 or 10,000 Ω 7.4.11 Resistance R Dependent on the setting "resistance measuring range" Here, the starting resistance of the potentiometer must be entered. I.e. the resistance (between A and S) of the sliding contact at this position (e.g.

  • Page 69: Analog Output

    Value range Parameter Comment (default setting in bold) 7.4.20 Filter time constant Time constant of the digital input filter 0.0 to 0.1 to 100 sec 2nd order If the input signal changes suddenly, approx. 26 % of the change is recorded following a period that corre- sponds to the filter time constant dF (2 ×...

  • Page 70: Scaling Start

    7 Configuration Value range Parameter Comment (default setting in bold) 7.5.4 Scaling start Here, the output range set above is shown on the set 4 to 20 mA, (the full range of the signal scaling of the signal type. 7.5.5 Scaling end type above is applied per 2 to 8 V is set in Chapter 5.4 "Signal flow"...

  • Page 71: Simulation Output

    Value range Parameter Comment (default setting in bold) 7.5.10 Simulation output An output current / output voltage can be simulated to test the following system. It is also possible to simulate residual currents/voltages. 7.5.11 Simulation value This value is simulated depending on the set signal for 0(4) to 20 mA;...

  • Page 72: Behavior When Leaving The Scaling Range

    7 Configuration 7.5.12 Behavior when leaving the scaling range The standard signal ranges of the analog output are limited as follows according to the recommendation of NAMUR NE 43: Signal type Lower Upper limit limit 4 to 20 mA 3.6 mA 21.2 mA 0 to 20 mA -0.4 mA...

  • Page 73: Limit Value Monitoring

    Limit value monitoring With this function, the relay output can monitor an adjustable limit value. Depending on the set switching behavior, the relay output can switch to "1" or "0" in the event of limit value exceedance. The limit value exceedance can also trigger a fault signal, see Chapter 7.5.8 "Response for limit error" Value range Parameter Comment...

  • Page 74: Rs485 Interface

    7 Configuration Value range Parameter Comment (default setting in bold) 7.6.2 Limit value Here, the fixed switching point (1) is set. Measuring range start to 0 to measuring range end in °C/°F/text 7.6.3 Switch difference The switching differential determines the gap between 0 to 1 to 100 °C/°F/text the switch-on and switch-off threshold (2).

  • Page 75: Service

    Value range Parameter Comment (default setting in bold) 7.7.2 Data format Data bits/stop bits/parity 8/1/no parity, 8/1/odd parity, 8/1/even parity, 8/2/no parity 7.7.3 Device address 1 to 254 Service Value range Parameter Comment (default setting in bold) 7.8.1 Minimum meas. value Minimum measured value is displayed 7.8.2 Maximum meas.

  • Page 76: Current Switching Cycles

    7 Configuration Value range Parameter Comment (default setting in bold) 7.8.6 Current switching cycles Relay switching cycle counter 0 to 30,000 Here, the switching cycles for the relay are only count- ed if the top limit value for relay switching cycles is not set to "0"...

  • Page 77: Device Info

    Device info Version Device software version channel: Device software version diagnostics: Fabrication number: The first 8 digits are the production order number: 02472588 Digit 9 and 10 manufacturing site Fulda: 01 Digit 11 (second row) device version: 0 Digit 12 and 13 year: 2018 Digit 14 and 15 calendar week: 11 Digit 16 to 19 consecutive number: 0003 Inspection ID:...

  • Page 78: Service

    8 Device info Service Value range Parameter Comment (default setting in bold) 8.2.1 Operating hours total Operating hours counter 0 to 99999 hours The counter adds up the operating hours during which the device was connected to the voltage supply. The value cannot be changed and can be used as a mea- sure of how long the device was actually in operation after leaving the factory.
  • Page 79 8 Device info...

  • Page 80: Technical Data

    9 Technical data Technical data Analog input 9.1.1 RTD temperature probe Designation Standard Measuring range Measuring accura- Pt50 GOST 6651-2009 A.2 3.91×10 2/3-wire circuit -200 to +850 °C ±0.5 K 4-wire circuit -200 to +850 °C ±0.3 K Pt100 IEC 60751:2008 3.85×10 2/3-wire circuit -100 to +200 °C...
  • Page 81 Designation Standard Measuring range Measuring accura- Pt100 GOST 6651-2009 A.2 3.91×10 2/3-wire circuit -100 to +200 °C ±0.2 K -200 to +850 °C ±0.4 K 4-wire circuit -100 to +200 °C ±0.15 K -200 to +850 °C ±0.25 K Cu50 GOST 6651-2009 A.3 4.28×10 2/3-wire circuit...

  • Page 82: Thermocouples

    9 Technical data 9.1.2 Thermocouples Designation Standard Measuring range Measuring accuracy Fe-CuNi “L” DIN 43710:1985-12 -200 to +900 °C ±0.1 % Fe-CuNi “J” DIN EN 60584-1:2014 -210 to +1200 °C ±0.1 % from -100 °C Cu-CuNi “U” DIN 43710:1985-12 -200 to +600 °C ±0.1 % from -100 °C Cu-CuNi “T”...

  • Page 83: Standard Signals

    Designation Standard Measuring range Measuring accuracy Measuring range start/end Freely programmable within the limits in steps of 0.1 °C Cold junction Pt1000 internal, thermostat (fixed constant value), adjustable ±1 K Reference point accuracy (internal) Reference point temperature (fixed constant value) -20 to +80 °C adjustable Special features Can also be programmed in °F...

  • Page 84: Resistance Transmitter

    9 Technical data Designation Measuring range Measuring Ambient temperature accuracy influence Measurement information M 3.8 to 20.5 mA ≤ 3.6 mA Failure information A for deviation below measured value/short-circuit ("NAMUR Low") ≥ 21 mA Failure information A for deviation above measured value/probe break ("NAMUR High") The accuracy specifications refer to the maximum measuring range.

  • Page 85: Resistance/Potentiometer

    9.1.5 Resistance/potentiometer Designation Measuring range Measuring accu- Ambient temperature racy influence ±10 Ω ≤ ±0.01 %/K Sensor type resistance/potentiometer max. 10 kΩ Deviation of 22 °C Connection type Potentiometer with 2-, 3- or 4-wire circuit ≤ 50 Ω per line for 3- and 4-wire circuit Sensor line resistance ≤...

  • Page 86: Test Voltages

    9 Technical data Measuring probe Out of range Probe/cable break Probe/cable short circuit Current 4 to 20 mA is detected is detected is detected 0 to 20 mA is detected is not detected is not detected Test voltages Input and output against voltage supply - With voltage supply AC 110 to 240 V +10%, -15% 4260 V - With voltage supply DC 24 V...

  • Page 87: Relay Output (Extra Code)

    Relay output (extra code) Designation Function Limit value relay output Relay (changeover contact) Contact protection circuit: Fuse cut-out 3.15 AT installed in pin branch 30,000 switching operations at a switching capacity of AC 240 V, 3 A, 50 Hz (resistive load) or maximum DC 30 V, 3 A.

  • Page 88: Electrical Data

    9 Technical data Electrical data Voltage supply DC 24 V, +10, -15 % or AC 110 to 240 V +10, -15 %, 48 to 63 Hz Power consumption With voltage supply 240 V: max. 3 W, 8 VA With voltage supply 24 V: max. 3 W Inputs and outputs Conductor cross section Max.

  • Page 89: Approvals/Approval Marks

    Electrical connection Pluggable screw terminals Mounting on Mounting rail 35 mm x 7.5 mm according to DIN IEC 60715 Close mounting Permitted Installation position Vertical Protection type IP20 according to DIN EN 60529 Weight with screw terminals Approx. 200 g 9.11 Approvals/approval marks Test facility Approval mark...

  • Page 90: Setup Program

    10 Setup program Setup program The program and the connecting cable are available as accessories and offer the following possibilities: Easy and comfortable parameterization and archiving via PC Easy parameter duplication for identical types of devices 10.1 Minimum hardware and software require- ments: PC Pentium III or higher 200 MB free hard disk space...

  • Page 91: Forgotten The Code

    10.3 Forgotten the code? If you forget the code, it can be read out via the USB interface and the setup program.  Use Data transfer from device. The read-out code now appears in the setup program in the sub-menu "Display/operation". It can be kept as it is or changed.

  • Page 92: Reset Drag Indicator

    10 Setup program 10.5 Reset drag indicator The drag indicator shows the maximum and minimum measured value. It can be reset with the setup program. The measured value currently shown in the display is set. On the device, see Chapter 7.8.3 "Min.value reset"...

  • Page 93: Switch On / Switch Off Sil Extra Code

    10.6 Switch on / switch off SIL extra code The restrictions for SIL operation can only be deactivated with the setup program. 10.7 Checking of safety relevant system settings Caution To make sure that all parameters after setup are transmitted correctly, the user has to validate the parameters, the safety function (error signal) and has to check the control action of the limit values.

  • Page 94: Error Messages

    11 Error messages Error messages 11.1 Display types Measured value flash- The measured value flashes. The analog output has dropped and displays the negative limit. Press the key for further information. Here, the diagnostics channel has detected an error at the analog output, as can also be seen in the table Chapter 11.3 "Diagnostics channel".

  • Page 95: Safety Channel

    11.2 Safety channel Display Origin Cause/remedy Terminal temperature Internal Terminal temperature outside the limits or probe faulty Reference AD converter Internal Deviation during the reference measurement of the AD converter/ Restart device / return device Not calibrated Internal Channel not calibrated Configuration Internal Configuration data outside the value range.
  • Page 96 11 Error messages Display Origin Cause/remedy Voltage supply Internal The voltage supply is insufficient. Check voltage supply. Frequency deviation Internal Error of the independent time base. Restart device / return device. EEPROM defective Internal Error during internal communication with the EEPROM. Restart device / return device.

  • Page 97: Diagnostics Channel

    11.3 Diagnostics channel Display Origin Cause/remedy Voltage 3 V Internal device Error detected when measuring the 3 V voltage supply Restart device / return device. Voltage 5 V Internal device Error detected when measuring the 5 V voltage supply Restart device / return device. Signal analog output Internal device Analog output signal deviates from the specification of the safety channel.
  • Page 98 11 Error messages Display Origin Cause/remedy Software versions Internal device The software versions of the safety channel and diagnostics channel do not match. Restart device / return device. Internal comm. Internal device Communication between safety channel and diagnostics channel faulty. Restart device / return device.

  • Page 99: Measured Value Recording

    Display Origin Cause/remedy EEPROM access Internal diagnos- An error occurred during EEPROM reading/writing. tics Restart device / return device. USB communication Internal diagnos- Error during communication via USB. Restart device / return device. tics RS485 communication Internal diagnos- Error during RS485 communication. Restart device / return device. tics 11.4 Measured value recording Display...

  • Page 100: What To Do, If

    12 What to do, if ... What to do, if ... Description Cause Remedy The following appears in Setup program transmits data. Wait until data transmission has finished. The safe state is assumed during data transmis- the display: sion (if SIL is active). The data is then exchanged between channel and diagnostics and then the device returns to normal state.
  • Page 101 (without voltage supply). If continuity cannot be measured, the de- vice must be repaired at JUMO. For service addresses see back cover ... The backlight is off. Timeout lighting was activated.
  • Page 102 12 What to do, if ... Description Cause Remedy The LED lights up red Here, all points that indicate a diagnostic er- Is the current output wired correctly? ror must be checked. The current output may not deliver current if the connected device is "too resistive"...
  • Page 103 12 What to do, if ...

  • Page 104: Certificates

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  • Page 106 13 Certificates EU-Conformity...
  • Page 107 EU-Conformity 13 Certificates...
  • Page 108 13 Certificates EU-Conformity...

  • Page 109: China Rohs

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  • Page 110 13 Certificates...

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