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WAGO 750-489 Manual Download Page 126

126  Commissioning 

WAGO-I/O-SYSTEM 750 

 

 

750-489 4AI RTD/TC/Strain Gauge Ex i 

Manual 

 

Version 1.1.0, valid from FW Version 02 

 

7.1.1.2  Information Bar 

•  Item number: 750-489 

•  Item description: 4AI RTD/TC/Strain Gauge Ex i 

•  Version: 01.01.xx(xx) 

7.1.1.3  Buttons 

Table 139: Buttons 

Button 

Function  Explanation 

 

[Exit] 

Closes the parameterization dialog.  

The connection to the I/O module is interrupted. 

 

[Open] 

Opens the dialog for loading a saved parameter file. 

 

[Save] 

Opens the dialog for saving parameterization 

information in a parameter file. 

 

[Read] 

Reads the current parameterization from the I/O 

module. 

 

[Write] 

Writes the modified parameters to the I/O module. 

 

[Factory 

Settings] 

Resets all I/O module settings to factory settings  

Note

: The values for the user calibration are also reset 

to their default values. Therefore, after the factory 

settings are restored, modified values must be modified 

again and written to the I/O module. 

Tip:

 Make a note of any value settings before resetting 

the I/O module. 

 

[Help] 

Opens an I/O module help dialog. 

 

 

 

Summary of Contents for 750-489

Page 1: ...Manual WAGO I O SYSTEM 750 750 489 4AI RTD TC Strain Gauge Ex i 4 Channel Analog Input RTD TC Strain Gauge Intrinsically Safe Version 1 1 0 valid from FW Version 02 ...

Page 2: ... 571 8 87 84 45 55 E Mail support wago com Every conceivable measure has been taken to ensure the accuracy and completeness of this documentation However as errors can never be fully excluded we always appreciate any information or suggestions for improving the documentation E Mail documentation wago com We wish to point out that the software and hardware terms as well as the trademarks of compani...

Page 3: ...14 2 1 4 1 2 Packaging 15 2 2 Safety Advice Precautions 16 3 Device Description 19 3 1 View 22 3 2 Connectors 23 3 2 1 Data Contacts Local Bus 23 3 2 2 Power Jumper Contacts Field Supply 24 3 2 3 CAGE CLAMP Connectors 25 3 3 Display Elements 26 3 4 Operating Elements 26 3 5 Schematic Diagram 27 3 6 Technical Data 28 3 6 1 Device Data 28 3 6 2 Power Supply 28 3 6 3 Communication 28 3 6 4 Inputs 29 ...

Page 4: ...Type T S5 FB250 Format Celsius 56 4 4 4 Temperature Measurements RTD TC with High Resolution 57 4 5 Temperature Measurement Fahrenheit 59 4 5 1 Pt100 Pt200 Pt500 Pt1000 EN 60751 60 4 5 1 1 Standard Format Fahrenheit 60 4 5 1 2 S5 FB250 Format Fahrenheit 60 4 5 2 Ni100 Ni120 Ni200 Ni500 Ni1000 TK6180 DIN 43760 Ni1000 TK5000 DIN 43760 61 4 5 2 1 Standard Format Fahrenheit 61 4 5 2 2 S5 FB250 Format ...

Page 5: ...n 80 4 6 3 13 TC Type R and Type S Standard Format Kelvin 81 4 6 3 14 TC Type R and Type S S5 FB250 Format Kelvin 81 4 6 3 15 TC Type T Standard Format Kelvin 82 4 6 3 16 TC Type T S5 FB250 Format Kelvin 82 4 6 4 Temperature Measurements RTD TC with High Resolution 83 4 6 4 1 Standard Format Kelvin 83 4 6 4 2 S5 FB250 Format Kelvin 84 4 7 Resistance Measurement 85 4 7 1 Resistance Measurement 1 0 ...

Page 6: ...n Bar 126 7 1 1 3 Buttons 126 7 1 1 4 Menu 127 7 1 2 Settings via the Menu 127 7 1 2 1 Common 127 7 1 2 2 Channel Settings 129 7 1 2 3 Scaling 132 7 1 2 4 Calibration 135 7 1 2 5 Calculation 138 7 2 Configuration and Parameterization with e COCKPIT 140 7 3 Configuration and Parameterization via GSD File 140 7 3 1 750 489 4AI RTD TC Strain Gauge Ex i Configuration 140 7 3 1 1 PROFIBUS DP Fieldbus C...

Page 7: ...on Examples 156 11 1 1 Marking for Europe According to ATEX and IECEx 156 11 1 2 Marking for the United States of America NEC and Canada CEC 160 11 2 Installation Regulations 163 11 2 1 Special Notes including Explosion Protection 163 11 2 2 Special Notes Regarding UL Hazardous Location 165 12 Service 166 12 1 Firmware Update Downgrade 166 12 2 Recalibration 167 12 3 WAGO UII Unique Item Identifie...

Page 8: ...le to the I O module 750 489 4AI RTD TC Strain Gauge Ex i The I O module 750 489 shall only be installed and operated according to the instructions in this manual and in the manual for the used fieldbus coupler or controller Consider power layout of the WAGO I O SYSTEM 750 In addition to these operating instructions you will also need the manual for the used fieldbus coupler or controller which ca...

Page 9: ...ustrations is copyright protected Any further use of this Manual by third parties that violate pertinent copyright provisions is prohibited Reproduction translation electronic and phototechnical filing archiving e g photocopying as well as any amendments require the written consent of WAGO Kontakttechnik GmbH Co KG Minden Germany Non observance will involve the right to assert damage claims ...

Page 10: ... Injury Indicates a moderate risk potentially hazardous situation which if not avoided could result in death or serious injury Personal Injury Indicates a low risk potentially hazardous situation which if not avoided may result in minor or moderate injury Damage to Property Indicates a potentially hazardous situation which if not avoided may result in damage to property Damage to Property Caused b...

Page 11: ...t this Documentation 11 750 489 4AI RTD TC Strain Gauge Ex i Manual Version 1 1 0 valid from FW Version 02 Additional Information Refers to additional information which is not an integral part of this documentation e g the Internet ...

Page 12: ... paths and data files are marked in italic type e g C Program Files WAGO Software Menu Menu items are marked in bold letters e g Save A greater than sign between two names means the selection of a menu item from a menu e g File New Input Designation of input or optional fields are marked in bold letters e g Start of measurement range Value Input or selective values are marked in inverted commas e ...

Page 13: ...vironments All changes to the coupler or controller should always be carried out by qualified personnel with sufficient skills in PLC programming 2 1 3 Use of the 750 Series in Compliance with Underlying Provisions Fieldbus couplers controllers and I O modules found in the modular WAGO I O SYSTEM 750 receive digital and analog signals from sensors and transmit them to actuators or higher level con...

Page 14: ...ired by the user The following actions will result in the exclusion of liability on the part of WAGO Kontakttechnik GmbH Co KG Repairs Changes to the hardware or software that are not described in the operating instructions Improper use of the components Further details are given in the contractual agreements Please send your request for modified and new hardware or software configurations directl...

Page 15: ...osal of electrical and electronic equipment can be harmful to the environment and human health 2 1 4 1 2 Packaging Packaging contains materials that can be reused PPWD 94 62 EU and 2004 12 EU packaging guidelines apply throughout Europe Directives and laws may vary nationally Environmentally friendly disposal of the packaging protects the environment and allows sustainable and efficient use of res...

Page 16: ...te protection against contact Prevent fire from spreading outside of the enclosure Offer adequate protection against UV irradiation Guarantee mechanical stability Restrict access to authorized personnel and may only be opened with tools Ensure disconnect and overcurrent protection The device is intended for installation in automation technology systems Disconnect protection is not integrated Conne...

Page 17: ...ls having seeping and insulating properties The components are not resistant to materials having seeping and insulating properties such as aerosols silicones and triglycerides found in some hand creams If you cannot exclude that such materials will appear in the component environment then install the components in an enclosure being resistant to the above mentioned materials Clean tools and materi...

Page 18: ...c discharge The devices are equipped with electronic components that may be destroyed by electrostatic discharge when touched Please observe the safety precautions against electrostatic discharge per DIN EN 61340 5 1 3 When handling the devices please ensure that environmental factors personnel work space and packaging are properly grounded ...

Page 19: ...olt 30 mV 60 mV 120 mV 250 mV 500 mV 1000 mV 2000 mV Potentiometer setting 0 100 Thermistor PTC 1 Settings for channel 1 and channel 3 2 Settings for channel 2 and channel 4 Assigning the connections is described in section Connections Connection examples are given in section Connecting Devices Connection Example s One green status LED per channel indicates the operating status and error free loca...

Page 20: ...ieldbus Coupler 750 341 09 750 342 19 750 352 14 750 362 02 750 363 03 Controller 750 823 03 750 841 21 750 842 19 750 843 03 750 852 14 750 862 02 750 871 09 750 872 05 750 873 05 750 880 14 750 881 14 750 882 14 750 885 14 750 890 02 750 891 02 750 893 03 Application Controller BA 750 884 14 PFC100 750 810x 13 PFC200 750 82xx 13 DeviceNet Fieldbus Coupler 750 306 4M ECO Fieldbus Coupler 750 346 ...

Page 21: ...t 750 489 Bus System Fieldbus Coupler Controller PFC Item No Firmware Version Modbus Fieldbus Coupler 750 315 300 000 01 750 316 300 000 01 Controller 750 815 300 000 01 750 816 300 000 01 EtherCat Fieldbus Coupler 750 354 05 BACnet Fieldbus Coupler 750 330 09 750 332 02 Controller 750 829 09 750 832 02 750 831 13 KNX Controller 750 849 05 750 889 14 ...

Page 22: ... 6 Legend for Figure View Pos Description Details See Section 1 Marking possibility with Mini WSB 2 Status LEDs Device Description Display Elements 3 Data contacts Device Description Connectors 4 CAGE CLAMP connectors Device Description Connectors 5 Power jumper contacts Device Description Connectors 6 Release tab Mounting Inserting and Removing Devices ...

Page 23: ...3 2 Connectors 3 2 1 Data Contacts Local Bus Communication between the head station and the I O modules as well as the system supply of the I O modules is carried out via the local bus The contacting for the local bus consists of 6 data contacts which are available as self cleaning gold spring contacts Figure 2 Data Contacts ...

Page 24: ...cts Figure 3 Power Jumper Contacts Table 7 Legend for Figure Power Jumper Contacts Contact Type Function 1 Spring contact Potential transmission Uv for field supply 2 Spring contact Potential transmission 0 V for field supply 3 Blade contact Potential feed in 0 V for field supply 4 Blade contact Potential feed in Uv for field supply Do not exceed maximum current via power contacts The maximum curr...

Page 25: ...el 1 I1 6 left Constant current negative channel 1 2 I2 3 left Constant current positive channel 2 I2 7 left Constant current negative channel 2 E2 4 left Test conductor positive channel 2 E2 8 left Test conductor negative channel 2 3 E3 1 right Test conductor positive channel 3 E3 5 right Test conductor negative channel 3 I3 2 right Constant current positive channel 3 I3 6 right Constant current ...

Page 26: ...reen Channel 2 ready for operation Error AI 2 D Red Channel 2 underflow overflow measurement underrange over range internal error 3 Function AI 3 E Green Channel 3 ready for operation Error AI 3 F Red Channel 3 underflow overflow measurement underrange over range internal error 4 Function AI 4 G Green Channel 4 ready for operation Error AI 4 H Red Channel 4 underflow overflow measurement underrang...

Page 27: ...Manual Version 1 1 0 valid from FW Version 02 3 5 Schematic Diagram Figure 6 Schematic Diagram Figure 7 Galvanic Isolation Power from SELV PELV power supply only All field signals and field supplies connected to this I O module 750 489 must be powered from SELV PELV power supply s ...

Page 28: ...ransmission via spring contacts Power consumption field supply 24 VDC Max 120 mA module with no external load Current consumption system supply 5 VDC Typ 60 mA Power loss Typ 1 6 W Power consumption Typ 1 6 W Isolation per EN IEC 60079 11 per EN UL 61010 2 201 300 VAC system supply 1200 VDC system supply channel Power supply Via local bus 5 VDC system power supply and via power jumper contacts 24 ...

Page 29: ...4 V Ud 15 mV 30 mV 60 mV Thermistor PTC mV transmitter 30 mV 60 mV 120 mV 250 mV 500 mV 1000 mV 2000 mV Potentiometer setting 0 100 Sensor connection RTD R 2 wire 3 wire 4 wire TC Millivolt 2 wire Resolution Measured value resolution 16 bit switchable 0 1 C F K Digit 0 01 C F K Digit only valid for measurement range 50 C 150 C Resolution in process image 0 1 K of full scale value 0 01 K of full sc...

Page 30: ...s etc can be configured via WAGO I O CHECK e COCKPIT and device descriptions e g GSDML Factory setting 1 For RTD R TC Millivolt conversion time depends on module setting 2 Achieving this value requires recalibration on the user s end see Section Calibration Table 14 Technical Data Sensor Types Measurement Ranges Sensor Type Measurement Range PT100 EN60751 200 C 850 C PT200 EN60751 PT500 EN60751 PT...

Page 31: ...easurement Ranges Sensor Type Measurement Range Type K 200 C 1372 C Type N 200 C 1300 C Type R 50 C 1768 C Type S Type T 200 C 400 C mV transmitter 30 mV 60 mV 120 mV 250 mV 500 mV 1000 mV 2000 mV Resistor Bridge Strain gauge bridge supply Uref 2 2 475 V Strain gauge bridge voltage Ud 15 mV Strain gauge bridge voltage Ud 30 mV Strain gauge bridge voltage Ud 60 mV ...

Page 32: ...f the connected device 1 of the specified values Li Ci Ex ia IIC 0 19 H 100 µF Ex ia IIB 0 78 H 1000 µF Ex ia IIA 1 57 H 1000 µF Ex ia I 2 57 H 1000 µF Maximum permissible external inductance Lo and capacitance Co which may also be used as concentrated capacitors and inductors Lo Co Ex ia II C 100 mH 2 5 µF 50 mH 3 µF 20 mH 3 5 µF 10 mH 3 9 µF 0 01 mH 28 µF 0 001 mH 600 µF Ex ia II B 100 mH 14 µF ...

Page 33: ...o harmful substances Acc to IEC 60068 2 42 and IEC 60068 2 43 Maximum pollutant concentration at relative humidity 75 SO2 25 ppm H2S 10 ppm Special conditions Ensure that additional measures for components are taken which are used in an environment involving dust caustic vapors or gases ionizing radiation 3 6 7 Connection Type Table 17 Technical Data Field Wiring Wire connection CAGE CLAMP Cross s...

Page 34: ... Description The following approvals have been granted to 750 489 I O modules Conformity Marking UL E175199 for use in Ordinary Location The following Ex approvals have been granted to 750 489 I O modules TÜV 12 ATEX 106032 X II 3 1 G Ex ec ia Ga IIC T4 Gc I M1 Ex ia Ma I II 1 D Ex ia Da IIIC IECEx TUN 12 0039 X Ex ec ia Ga IIC T4 Gc Ex ia Ma I Ex ia Da IIIC UL E198726 for Use in Hazardous Locatio...

Page 35: ... Manual Version 1 1 0 valid from FW Version 02 More information about approvals Detailed references to the approvals are listed in the document Overview Approvals WAGO I O SYSTEM 750 which you can find via the internet under www wago com DOWNLOADS Documentation System Description ...

Page 36: ... General requirements IEC 60079 0 Explosive atmospheres Equipment protection by increased safety e IEC 60079 7 Explosive atmospheres Equipment protection by intrinsic safety i IEC 60079 11 UL Ordinary Locations UL Standard for Safety for Industrial Control Equipment UL 61010 2 201 UL Hazardous Locations STANDARD FOR SAFETY Nonincendive Electrical Equipment for Use in Class I and II Division 2 and ...

Page 37: ...ow or underflow bit B1 is set to 1 Bit B2 is not used The measured value is then mapped with a resolution of thirteen bits to bits B3 B15 The WAGO I O CHECK commissioning tool can be used to parameterize the required operating mode Alternatively the I O module can also be parameterized via PROFIBUS and PROFINET device description GSD file The parameterization description can be found in section Co...

Page 38: ... are implemented identically for all channels Therefore the following description in this section applies to all status bytes of the I O module Table 21 Status Byte CH1_S0 Status Byte CH1_S0 Byte 0 Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 RegCom General Error Overflow Underflow User Overrange User Under range Overrange Underrange Underrange Measurement underrange 0 The field side input volt...

Page 39: ...or General error internal error 0 No error present or bit 0 measurement underrange bit 1 measurement overrange bit 4 underflow or bit 5 overflow is not set 1 General error present bit 0 measurement underrange bit 1 measurement overrange bit 4 underflow or bit 5 overflow is set Internal error present fieldbus power supply undervoltage or ADC error bit 0 measurement underrange bit 1 measurement over...

Page 40: ...iew of Standard Format and S5 FB250 Format Sensor type Standard Measurement range Representation Two s complement sign magnitude S5 FB250 format Reso lution Raw value range Reso lution Raw value range Channel deactivated Celsius Pt100 EN 60751 200 C 850 C 0 1 C 2000 8500 1 0 C 200 850 Pt200 Pt500 Pt1000 Ni100 DIN 43760 60 C 250 C 600 2500 60 250 Ni120 Ni200 Ni500 Ni1000 Ni1000 TK5000 TC Type B DIN...

Page 41: ...328 1832 TC Type J 346 F 2192 F 3460 21920 346 2192 TC Type K 328 F 2502 F 3280 25020 328 2502 TC Type N 328 F 2372 F 3280 23720 328 2372 TC Type R 58 F 3214 F 580 32140 58 3214 TC Type S 58 F 3214 F 580 32140 58 3214 TC Type T 328 F 752 F 3280 7520 328 752 Kelvin Pt100 EN 60751 73 2 K 1123 2 K 0 1 K 732 11232 1 0 K 73 1123 Pt200 Pt500 Pt1000 Ni100 DIN 43760 213 2 K 523 2 K 2132 5232 213 523 Ni120...

Page 42: ...uring range 5 0 Ohm 4 0 kOhm 0 16 Ohm 1 6 Ohm PTC 0 Ohm 4 0 kOhm 0 16 Ohm 1 6 Ohm Potentiometer 0 100 0 005 0 20000 0 05 0 2000 Voltage measuring Voltage measuring range 1 30 mV 30 mV 0 0012 mV 25000 25000 0 012 mV 2500 2500 Voltage measuring range 2 60 mV 60 mV 0 0024 mV 0 024 mV Voltage measuring range 3 120 mV 120 mV 0 0048 mV 0 048 mV Voltage measuring range 4 250 mV 250 mV 0 01 mV 0 1 mV Volt...

Page 43: ...rocess of Calculating Measured Value from Process Value Temperature Measurements This yields the following formulas for converting the local bus process value to the measured value Standard format Standard resolution 𝐓𝐓 𝐱𝐱 𝒙𝒙 𝟏𝟏𝟏𝟏 High resolution 𝐓𝐓 𝐱𝐱 𝒙𝒙 𝟏𝟏𝟏𝟏𝟏𝟏 S5 FB250 format Standard resolution 𝐓𝐓 𝐱𝐱 𝒙𝒙 𝟖𝟖 High resolution 𝐓𝐓 𝐱𝐱 𝒙𝒙 𝟖𝟖 𝟏𝟏𝟏𝟏 𝒙𝒙 𝟖𝟖𝟖𝟖 where x INT16 process value and T is a float dou...

Page 44: ...nge of 30 mV Standard format 𝐔𝐔 𝐱𝐱 𝒙𝒙 𝟐𝟐𝟐𝟐𝟐𝟐𝟐𝟐𝟐𝟐 𝟑𝟑𝟑𝟑 𝒎𝒎𝒎𝒎 S5 FB250 format 𝐔𝐔 𝐱𝐱 𝒙𝒙 𝟖𝟖 𝟐𝟐𝟐𝟐𝟐𝟐𝟐𝟐 𝟑𝟑𝟑𝟑 𝒎𝒎𝒎𝒎 E g for a measurement range of 4 kΩ Standard format 𝐑𝐑 𝐱𝐱 𝒙𝒙 𝟐𝟐𝟐𝟐𝟐𝟐𝟐𝟐𝟐𝟐 𝟒𝟒𝟒𝟒𝟒𝟒𝟒𝟒 𝛀𝛀 S5 FB250 format 𝐑𝐑 𝐱𝐱 𝒙𝒙 𝟖𝟖 𝟐𝟐𝟐𝟐𝟐𝟐𝟐𝟐 𝟒𝟒𝟒𝟒𝟒𝟒𝟒𝟒 𝛀𝛀 E g for a measurement range strain gauge Ud 15 mV Standard format 𝐔𝐔 𝐱𝐱 𝒙𝒙 𝟐𝟐𝟐𝟐𝟐𝟐𝟐𝟐𝟐𝟐 𝟏𝟏𝟏𝟏 𝒎𝒎𝒎𝒎 S5 FB250 format 𝐔𝐔 𝐱𝐱 𝒙𝒙 𝟖𝟖 𝟐𝟐𝟐𝟐𝟐𝟐𝟐𝟐 𝟏𝟏𝟏𝟏 𝒎𝒎𝒎𝒎 E g for a measurem...

Page 45: ...ers Figure 10 Process of Calculating Measured Value from Process Value Resistance Voltage Measurements This yields the following formulas for converting the local bus process value to the measured value Standard format 𝐟𝐟 𝐱𝐱 𝒙𝒙 𝟐𝟐𝟐𝟐𝟐𝟐𝟐𝟐𝟐𝟐 𝟏𝟏𝟏𝟏𝟏𝟏 S5 FB250 format 𝐟𝐟 𝐱𝐱 𝒙𝒙 𝟖𝟖 𝟐𝟐𝟐𝟐𝟐𝟐𝟐𝟐 𝟏𝟏𝟏𝟏𝟏𝟏 where x INT16 process value and f is a float double ...

Page 46: ...ius RTD TC measurement with Celsius setting with S5 FB250 format activated the temperature values are represented at a resolution of one digit per 1 0 C The status information is represented in bit 0 to bit 2 and the digitized measured value in bit 3 to bit 15 Representation in the tables Corresponding monitoring must be switched on The Underflow Overflow Underrange and Overrange areas require tha...

Page 47: ...0001 0011 0100 0x2134 8500 850 1 0010 0001 0011 0101 0x2135 8501 0x42 On Overrange 875 0 0010 0010 0010 1110 0x222E 8750 875 1 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 1 Process values below 0 are represented in binary form as the two s complement 4 4 1 2 S5 FB250 Format Celsius Table 24 Pt100 Pt200 Pt500 Pt1000 EN 60751 Setting S5 FB250 Format Celsius Temperature C Numeric Value Status B...

Page 48: ...ge 250 0 0000 1001 1100 0100 0x09C4 2500 250 1 0000 1001 1100 0101 0x09C5 2501 0x42 On Overrange 275 0 0000 1010 1011 1110 0x0ABE 2750 275 1 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 1 Process values below 0 are represented in binary form as the two s complement 4 4 2 2 S5 FB250 Format Celsius Table 26 Ni100 Ni120 Ni200 Ni500 Ni1000 Setting S5 FB250 Format Celsius Temperature C Numeric Val...

Page 49: ...9C3 2499 250 0 0000 1001 1100 0100 0x09C4 2500 0x00 Off Nominal range 1820 0 0100 0111 0001 1000 0x4718 18200 1820 1 0100 0111 0001 1001 0x4719 18201 0x42 On Overrange 1845 0 0100 1000 0001 0010 0x4812 18450 1845 1 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 4 4 3 2 TC Type B S5 FB250 Format Celsius Table 28 TC Type B Setting S5 FB250 Format Celsius Temperature C Numeric Value Status Byte He...

Page 50: ... 0 0101 1011 0110 1000 0x5B68 23400 2340 1 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 1 Process values below 0 are represented in binary form as the two s complement 4 4 3 4 TC Type C S5 FB250 Format Celsius Table 30 TC Type C Setting S5 FB250 Format Celsius Temperature C Numeric Value Status Byte Hex Error LED Range Binary XFÜ1 Hex Dec 26 0 1000 0000 0000 0 010 0x8002 32766 0x50 On Underfl...

Page 51: ...25 0 0010 1000 0000 1010 0x280A 10250 1025 1 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 1 Process values below 0 are represented in binary form as the two s complement 4 4 3 6 TC Type E S5 FB250 Format Celsius Table 32 TC Type E Setting S5 FB250 Format Celsius Temperature C Numeric Value Status Byte Hex Error LED Range Binary XFÜ1 Hex Dec 226 0 1000 0000 0000 0 010 0x8002 32766 0x50 On Unde...

Page 52: ...25 0 0010 1111 1101 1010 0x2FDA 12250 1225 1 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 1 Process values below 0 are represented in binary form as the two s complement 4 4 3 8 TC Type J S5 FB250 Format Celsius Table 34 TC Type J Setting S5 FB250 Format Celsius Temperature C Numeric Value Status Byte Hex Error LED Range Binary XFÜ1 Hex Dec 236 0 1000 0000 0000 0 010 0x8002 32766 0x50 On Unde...

Page 53: ... 0 0011 1110 1001 0010 0x3692 13970 1397 1 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 1 Process values below 0 are represented in binary form as the two s complement 4 4 3 10 TC Type K S5 FB250 Format Celsius Table 36 TC Type K Setting S5 FB250 Format Celsius Temperature C Numeric Value Status Byte Hex Error LED Range Binary XFÜ1 Hex Dec 226 0 1000 0000 0000 0 010 0x8002 32766 0x50 On Under...

Page 54: ... 0 0011 0011 1100 0010 0x33C2 13250 1325 1 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 1 Process values below 0 are represented in binary form as the two s complement 4 4 3 12 TC Type N S5 FB250 Format Celsius Table 38 TC Type N Setting S5 FB250 Format Celsius Temperature C Numeric Value Status Byte Hex Error LED Range Binary XFÜ1 Hex Dec 226 0 1000 0000 0000 0 010 0x8002 32766 0x50 On Under...

Page 55: ... 0 0100 0110 0000 1010 0x460A 17930 1793 1 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 1 Process values below 0 are represented in binary form as the two s complement 4 4 3 14 TC Type R and Type S S5 FB250 Format Celsius Table 40 TC Type R and Type S Setting S5 FB250 Format Celsius Temperature C Numeric Value Status Byte Hex Error LED Range Binary XFÜ1 Hex Dec 76 0 1000 0000 0000 0 010 0x800...

Page 56: ... 0001 0000 1001 1010 0x109A 4250 425 1 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 1 Process values below 0 are represented in binary form as the two s complement 4 4 3 16 TC Type T S5 FB250 Format Celsius Table 42 TC Type T Setting S5 FB250 Format Celsius Temperature C Numeric Value Status Byte Hex Error LED Range Binary XFÜ1 Hex Dec 226 0 1000 0000 0000 0 010 0x8002 32766 0x50 On Underflow...

Page 57: ...00 as a process value Table 43 Temperature Measurement Setting with High Resolution Option Standard Format Celsius Temperature C Numeric Value1 Status Byte Hex Error LED Range Hex Dec 60 01 0x8000 32768 0x50 On Underflow 60 00 0xE890 6000 0x41 On Underrange 50 01 0xEC77 5001 50 00 0xEC78 5000 0x00 Off Nominal range 150 00 0x3A98 15000 150 01 0x3A99 15001 0x42 On Overrange 160 00 0x3E80 16000 160 0...

Page 58: ... 0 000 0xF060 4000 0x00 Off Nominal range 150 0 0010 1110 1110 0 000 0x2EE0 12000 150 1 0010 1110 1110 1 001 0x2EE9 12009 0x42 On Overrange 160 0 0011 0010 0000 0 001 0x3201 12801 160 1 0111 1111 1111 1 010 0x7FFA 32762 0x60 On Overflow 1 Status bits X not used F error Ü overflow Table 46 Type C TC Setting with High Resolution Option S5 FB250 Format Celsius Temperature C Numeric Value Status Byte ...

Page 59: ...enheit RTD TC measurement with Fahrenheit setting with S5 FB250 format activated the temperature values are represented at a resolution of one digit per 1 0 F The status information is represented in bit 0 to bit 2 and the digitized measured value in bit 3 to bit 15 Representation in the tables Corresponding monitoring must be switched on The Underflow Overflow Underrange and Overrange areas requi...

Page 60: ...101 0000 0100 0x3D04 15620 1562 1 0011 1101 0000 0101 0x3D05 15621 0x42 On Overrange 1607 0 0011 1110 1100 0110 0x3EC6 16070 1607 1 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 1 Process values below 0 are represented in binary form as the two s complement 4 5 1 2 S5 FB250 Format Fahrenheit Table 48 Pt100 Pt200 Pt500 Pt1000 EN 60751 Setting S5 FB250 Format Fahrenheit Temperature F Numeric Val...

Page 61: ...nge 482 0 0001 0010 1101 0100 0x12D4 4820 482 1 0001 0010 1101 0101 0x12D5 4821 0x42 On Overrange 527 0 0001 0100 1001 0110 0x1496 5270 527 1 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 1 Process values below 0 are represented in binary form as the two s complement 4 5 2 2 S5 FB250 Format Fahrenheit Table 50 Ni100 Ni120 Ni200 Ni500 Ni1000 Setting S5 FB250 Format Fahrenheit Temperature F Nume...

Page 62: ...2D3 4819 482 0 0001 0010 1101 0100 0x12D4 4820 0x00 Off Nominal range 3270 0 0111 1111 1011 1100 0x7FBC 32700 3270 1 0111 1111 1011 1101 0x7FBD 32701 0x42 On Overrange 3275 0 0111 1111 1110 1110 0x7FEE 32750 3275 1 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 4 5 3 2 TC Type B S5 FB250 Format Fahrenheit Table 52 TC Type B Setting S5 FB250 Format Fahrenheit Temperature F Numeric Value Status B...

Page 63: ... 0 0111 1111 1110 1110 0x7FEE 32750 3275 1 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 1 Process values below 0 are represented in binary form as the two s complement 4 5 3 4 TC Type C S5 FB250 Format Fahrenheit Table 54 TC Type C Setting S5 FB250 Format Fahrenheit Temperature F Numeric Value Status Byte Hex Error LED Range Binary XFÜ1 Hex Dec 14 0 1000 0000 0000 0 010 0x8002 32766 0x50 On U...

Page 64: ... 0 0100 1001 0101 0010 0x4952 18770 1877 1 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 1 Process values below 0 are represented in binary form as the two s complement 4 5 3 6 TC Type E S5 FB250 Format Fahrenheit Table 56 TC Type E Setting S5 FB250 Format Fahrenheit Temperature F Numeric Value Status Byte Hex Error LED Range Binary XFÜ1 Hex Dec 374 0 1000 0000 0000 0 010 0x8002 32766 0x50 On ...

Page 65: ... 0 0101 0111 0110 0010 0x5762 22370 2237 1 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 1 Process values below 0 are represented in binary form as the two s complement 4 5 3 8 TC Type J S5 FB250 Format Fahrenheit Table 58 TC Type J Setting S5 FB250 Format Fahrenheit Temperature F Numeric Value Status Byte Hex Error LED Range Binary XFÜ1 Hex Dec 392 0 1000 0000 0000 0 010 0x8002 32766 0x50 On ...

Page 66: ... 0 0110 0011 0111 1110 0x637E 25470 2547 1 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 1 Process values below 0 are represented in binary form as the two s complement 4 5 3 10 TC Type K S5 FB250 Format Fahrenheit Table 60 TC Type K Setting S5 FB250 Format Fahrenheit Temperature F Numeric Value Status Byte Hex Error LED Range Binary XFÜ1 Hex Dec 374 0 1000 0000 0000 0 010 0x8002 32766 0x50 On...

Page 67: ... 0 0101 1110 0110 1010 0x5E6A 24170 2417 1 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 1 Process values below 0 are represented in binary form as the two s complement 4 5 3 12 TC Type N S5 FB250 Format Fahrenheit Table 62 TC Type N Setting S5 FB250 Format Fahrenheit Temperature F Numeric Value Status Byte Hex Error LED Range Binary XFÜ1 Hex Dec 374 0 1000 0000 0000 0 010 0x8002 32766 0x50 On...

Page 68: ...9 0 0111 1111 0100 1110 0x7F4E 32590 3259 1 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 1 Process values below 0 are represented in binary form as the two s complement 4 5 3 14 TC Type R and Type S S5 FB250 Format Fahrenheit Table 64 TC Type R and Type S Setting S5 FB250 Format Fahrenheit Temperature F Numeric Value Status Byte Hex Error LED Range Binary XFÜ1 Hex Dec 104 0 1000 0000 0000 0 0...

Page 69: ...97 0 0001 1111 0010 0010 0x1F22 7970 797 1 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 1 Process values below 0 are represented in binary form as the two s complement 4 5 3 16 TC Type T S5 FB250 Format Fahrenheit Table 66 TC Type T Setting S5 FB250 Format Fahrenheit Temperature F Numeric Value Status Byte Hex Error LED Range Binary XFÜ1 Hex Dec 374 0 1000 0000 0000 0 010 0x8002 32766 0x50 On...

Page 70: ... corresponds to 32 F 302 F i e 3200 30200 as a process value Table 67 Temperature Measurement Setting with High Resolution Option Standard Format Fahrenheit Temperature F Numeric Value1 Status Byte Hex Error LED Range Hex Dec 76 01 0x8000 32768 0x50 On Underflow 76 00 0xE250 7600 0x41 On Underrange 58 01 0xE957 5801 58 00 0xE958 5800 0x00 Off Nominal range 302 00 0x75F8 30200 302 01 0x75F9 30201 0...

Page 71: ...000 0xEDE0 4640 0x00 Off Nominal range 302 0 0101 1110 0110 0 000 0x5E60 24160 302 1 0101 1110 0110 1 001 0x5E69 24169 0x42 On Overrange 320 0 0110 0100 0000 0 001 0x6401 25601 320 1 0111 1111 1111 1 010 0x7FFA 32762 0x60 On Overflow 1 Status bits X not used F error Ü overflow Table 70 Type C TC Setting with High Resolution Option S5 FB250 Format Fahrenheit Temperature F Numeric Value Status Byte ...

Page 72: ...in RTD TC measurement with Kelvin setting with S5 FB250 format activated the temperature values are represented at a resolution of one digit per 1 0 K The status information is represented in bit 0 to bit 2 and the digitized measured value in bit 3 to bit 15 Representation in the tables Corresponding monitoring must be switched on The Underflow Overflow Underrange and Overrange areas require that ...

Page 73: ...00 Off Nominal range 1123 2 0010 1011 1110 0000 0x2BE0 11232 1123 3 0010 1011 1110 0001 0x2BE1 11233 0x42 On Overrange 1148 2 0010 1100 1101 1010 0x2CDA 11482 1148 3 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 4 6 1 2 S5 FB250 Format Kelvin Table 72 Pt100 Pt200 Pt500 Pt1000 EN 60751 Setting S5 FB250 Format Kelvin Temperature K Numeric Value Status Byte Hex Error LED Range Binary XFÜ1 Hex Dec...

Page 74: ... 0101 0100 0x0854 2132 0x00 Off Nominal range 523 2 0001 0100 0111 0000 0x1470 5232 523 3 0001 0100 0111 0001 0x1471 5233 0x42 On Overrange 548 2 0001 0101 0110 1010 0x156A 5482 548 3 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 4 6 2 2 S5 FB250 Format Kelvin Table 74 Ni100 Ni120 Ni200 Ni500 Ni1000 Setting S5 FB250 Format Kelvin Temperature K Numeric Value Status Byte Hex Error LED Range Bina...

Page 75: ...46F 5231 523 2 0001 0100 0111 0000 0x1470 5232 0x00 Off Nominal range 2093 2 0101 0001 1100 0100 0x51C4 20932 2093 3 0101 0001 1100 0101 0x51C5 20933 0x42 On Overrange 2118 2 0101 0010 1011 1110 0x52BE 21182 2118 3 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 4 6 3 2 TC Type B S5 FB250 Format Kelvin Table 76 TC Type B Setting S5 FB250 Format Kelvin Temperature K Numeric Value Status Byte Hex ...

Page 76: ...1011 0x651B 25883 0x42 On Overrange 2613 2 0110 0110 0001 0100 0x6614 26132 2613 3 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 4 6 3 4 TC Type C S5 FB250 Format Kelvin Table 78 TC Type C Setting S5 FB250 Format Kelvin Temperature K Numeric Value Status Byte Hex Error LED Range Binary XFÜ1 Hex Dec 247 0 1000 0000 0000 0 010 0x8002 32766 0x50 On Underflow 248 0 0000 0111 1100 0 001 0x07C1 1985...

Page 77: ...1101 0x31BD 12733 0x42 On Overrange 1298 2 0011 0010 1011 0110 0x32B6 12982 1298 3 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 4 6 3 6 TC Type E S5 FB250 Format Kelvin Table 80 TC Type E Setting S5 FB250 Format Kelvin Temperature K Numeric Value Status Byte Hex Error LED Range Binary XFÜ1 Hex Dec 47 0 1000 0000 0000 0 010 0x8002 32766 0x50 On Underflow 48 0 0000 0001 1000 0 001 0x0181 385 0x...

Page 78: ...1101 0x398D 14733 0x42 On Overrange 1498 2 0011 1010 1000 0110 0x3A86 14982 1498 3 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 4 6 3 8 TC Type J S5 FB250 Format Kelvin Table 82 TC Type J Setting S5 FB250 Format Kelvin Temperature K Numeric Value Status Byte Hex Error LED Range Binary XFÜ1 Hex Dec 37 0 1000 0000 0000 0 010 0x8002 32766 0x50 On Underflow 38 0 0000 0001 0011 0 001 0x0131 305 0x...

Page 79: ...101 0x4045 16453 0x42 On Overrange 1670 2 0100 0001 0011 1110 0x413E 16702 1670 3 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 4 6 3 10 TC Type K S5 FB250 Format Kelvin Table 84 TC Type K Setting S5 FB250 Format Kelvin Temperature K Numeric Value Status Byte Hex Error LED Range Binary XFÜ1 Hex Dec 47 0 1000 0000 0000 0 010 0x8002 32766 0x50 On Underflow 48 0 0000 0001 1000 0 001 0x0181 385 0x...

Page 80: ...0101 0x3D75 15733 0x42 On Overrange 1598 2 0011 1110 0110 1110 0x3E6E 15982 1598 3 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 4 6 3 12 TC Type N S5 FB250 Format Kelvin Table 86 TC Type N Setting S5 FB250 Format Kelvin Temperature K Numeric Value Status Byte Hex Error LED Range Binary XFÜ1 Hex Dec 47 0 1000 0000 0000 0 010 0x8002 32766 0x50 On Underflow 48 0 0000 0001 1000 0 001 0x0181 385 0...

Page 81: ...1101 0x4FBD 20413 0x42 On Overrange 2066 2 0101 0000 1011 0110 0x50B6 20662 2066 3 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 4 6 3 14 TC Type R and Type S S5 FB250 Format Kelvin Table 88 TC Type R and Type S Setting S5 FB250 Format Kelvin Temperature K Numeric Value Status Byte Hex Error LED Range Binary XFÜ1 Hex Dec 197 0 1000 0000 0000 0 010 0x8002 32766 0x50 On Underflow 198 0 0000 0110...

Page 82: ...1101 0x1A4D 6733 0x42 On Overrange 698 2 0001 1011 0100 0110 0x1B46 6982 698 3 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 4 6 3 16 TC Type T S5 FB250 Format Kelvin Table 90 TC Type T Setting S5 FB250 Format Kelvin Temperature K Numeric Value Status Byte Hex Error LED Range Binary XFÜ1 Hex Dec 47 0 1000 0000 0000 0 010 0x8002 32766 0x50 On Underflow 48 0 0000 0001 1000 0 001 0x0181 385 0x41 ...

Page 83: ...nsors the defined temperature range corresponds to 273 15 K 327 K i e 27315 32700 as a process value Table 91 Temperature Measurement Setting with High Resolution Option Standard Format Kelvin Temperature K Numeric Value Status Byte Hex Error LED Range Hex Dec 213 14 0x8000 32768 0x50 On Underflow 213 15 0x5343 21315 0x41 On Underrange 223 14 0x572A 22314 223 15 0x572B 22315 0x00 Off Nominal range...

Page 84: ... 0x45B8 17848 0x00 Off Nominal range 327 0 0110 0110 0011 0 000 0x6630 26160 327 1 0110 0110 0011 1 001 0x6639 26169 0x42 On Overrange 327 5 0110 0110 0101 1 001 0x6659 26201 327 6 0111 1111 1111 1 010 0x7FFA 32762 0x60 On Overflow 1 Status bits X not used F error Ü overflow Table 94 Type C TC Setting with High Resolution Option S5 FB250 Format Kelvin Temperature K Numeric Value Status Byte Hex Er...

Page 85: ...lues for the sensors normalized to 2500 In the measuring range 0 250 Ohm for example a measured value of 250 Ω corresponds to a normalized process value of 2500 Note Be aware that the status information is represented in bit 0 to bit 2 and the digitized measured value in bit 3 to bit 15 Therefore the normalized measured value is shifted by three bits in the process image Thus a normalized measured...

Page 86: ...00 250 01 0110 0001 1010 1001 0x61A9 25001 0x42 On Overrange 275 0110 1011 0110 1100 0x6B6C 27500 275 01 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 4 7 1 2 S5 FB250 Format Table 96 Setting Resistance Measurement 1 S5 FB250 Format Resistance Ω Numeric Value Status Byte Hex Error LED Range Binary XFÜ1 Hex Dec 0 0 1000 0000 0000 0 010 0x8002 32766 0x50 On Underflow 0 0000 0000 0000 0 000 0x000...

Page 87: ... 500 02 0110 0001 1010 1001 0x61A9 25001 0x42 On Overrange 550 0110 1011 0110 1100 0x6B6C 27500 550 02 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 4 7 2 2 S5 FB250 Format Table 98 Setting Resistance Measurement 2 S5 FB250 Format Resistance Ω Numeric Value Status Byte Hex Error LED Range Binary XFÜ1 Hex Dec 0 0 1000 0000 0000 0 010 0x8002 32766 0x50 On Underflow 0 0000 0000 0000 0 000 0x0000 ...

Page 88: ...0 04 0110 0001 1010 1001 0x61A9 25001 0x42 On Overrange 1100 0110 1011 0110 1100 0x6B6C 27500 1100 04 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 4 7 3 2 S5 FB250 Format Table 100 Setting Resistance Measurement 3 S5 FB250 Format Resistance Ω Numeric Value Status Byte Hex Error LED Range Binary XFÜ1 Hex Dec 0 0 1000 0000 0000 0 010 0x8002 32766 0x50 On Underflow 0 0000 0000 0000 0 000 0x0000 ...

Page 89: ...00 08 0110 0001 1010 1001 0x61A9 25001 0x42 On Overrange 2200 0110 1011 0110 1100 0x6B6C 27500 2200 08 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 4 7 4 2 S5 FB250 Format Table 102 Setting Resistance Measurement 4 S5 FB250 Format Resistance Ω Numeric Value Status Byte Hex Error LED Range Binary XFÜ1 Hex Dec 0 0 1000 0000 0000 0 010 0x8002 32766 0x50 On Underflow 0 0000 0000 0000 0 000 0x0000...

Page 90: ...00 16 0110 0001 1010 1001 0x61A9 25001 0x42 On Overrange 4016 0110 0010 0000 1100 0x620C 25100 4016 16 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 4 7 5 2 S5 FB250 Format Table 104 Setting Resistance Measurement 5 S5 FB250 Format Resistance Ω Numeric Value Status Byte Hex Error LED Range Binary XFÜ1 Hex Dec 0 0 1000 0000 0000 0 010 0x8002 32766 0x50 On Underflow 0 0000 0000 0000 0 000 0x0000...

Page 91: ...6 0110 0001 1010 1001 0x61A9 25001 0x42 On Overrange 4016 0110 0010 0000 1100 0x620C 25100 4016 16 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 4 7 6 2 S5 FB250 Format Table 106 Setting Resistance Measurement PTC S5 FB250 Format Resistance Ω Numeric Value Status Byte Hex Error LED Range Binary XFÜ1 Hex Dec 0 0 1000 0000 0000 0 010 0x8002 32766 0x50 On Underflow 0 0000 0000 0000 0 000 0x0000 0...

Page 92: ...ted in one word 16 bits at a resolution of one digit per 0 005 Table 107 Setting Resistance Measurement Potentiometer Standard Format Percent Numeric Value Status Byte Hex Error LED Range Binary Hex Dec 0 0 1000 0000 0000 0000 0x8000 32768 0x50 On Underflow 0 0 0000 0000 0000 0000 0x0000 0 0x00 Off Nominal range 25 0 0001 0111 1000 1000 0x1388 5000 50 0 0010 0111 0001 0000 0x2710 10000 75 0 0011 1...

Page 93: ...hree bits in the process image Thus a normalized measured value of 2000 corresponds to a process value of 16000 Table 108 Setting Resistance Measurement Potentiometer S5 FB250 Format Percent Numeric Value Status Byte Hex Error LED Range Binary XFÜ1 Hex Dec 0 0 1000 0000 0000 0 010 0x8002 32766 0x50 On Underflow 0 0 0000 0000 0000 0 000 0x0000 0 0x00 Off Nominal range 25 0 0000 1111 1010 0 000 0x0F...

Page 94: ...the two s complement The voltage underranges and overranges relate to manufacturer range violations S5 FB250 Format For voltage measurements with S5 FB250 format enabled the I O module outputs the measured values for the sensors normalized to 2500 The defined measuring range of 30 mV 30 mV for example corresponds to a possible process value of 2500 2500 Note Be aware that the status information is...

Page 95: ...2C 12500 15 0 0011 0000 1101 0100 0x30D4 12500 30 0 0110 0001 1010 1000 0x61A8 25000 30 0012 0110 0001 1010 1001 0x61A9 25001 0x42 On Overrange 35 0 0111 0001 1110 1110 0x71EE 29167 35 0012 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 1 Process values below 0 are represented in binary form as the two s complement 4 8 1 2 S5 FB250 Format Table 110 Setting Voltage Measurement 1 30 mV S5 FB250 F...

Page 96: ...2 On Overrange 70 0 0111 0001 1110 1110 0x71EE 29167 70 0024 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 1 Process values below 0 are represented in binary form as the two s complement 4 8 2 2 S5 FB250 Format Table 112 Setting Voltage Measurement 2 60 mV S5 FB250 Format Voltage mV Numeric Value Status Byte Hex Error LED Binary Range Hex Binary XFÜ1 Hex Dec 70 024 1000 0000 0000 0 010 0x8002 ...

Page 97: ... On Overrange 140 0 0111 0001 1110 1110 0x71EE 29167 140 0048 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 1 Process values below 0 are represented in binary form as the two s complement 4 8 3 2 S5 FB250 Format Table 114 Setting Voltage Measurement 3 120 mV S5 FB250 Format Voltage mV Numeric Value Status Byte Hex Error LED Binary Range Hex Binary XFÜ1 Hex Dec 140 048 1000 0000 0000 0 010 0x80...

Page 98: ...42 On Overrange 290 0 0111 0001 0100 1000 0x7148 29000 290 01 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 1 Process values below 0 are represented in binary form as the two s complement 4 8 4 2 S5 FB250 Format Table 116 Setting Voltage Measurement 4 250 mV S5 FB250 Format Voltage mV Numeric Value Status Byte Hex Error LED Binary Range Hex Binary XFÜ1 Hex Dec 290 1 1000 0000 0000 0 010 0x8002...

Page 99: ...x42 On Overrange 580 0 0111 0001 0100 1000 0x7148 29000 580 02 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 1 Process values below 0 are represented in binary form as the two s complement 4 8 5 2 S5 FB250 Format Table 118 Setting Voltage Measurement 5 500 mV S5 FB250 Format Voltage mV Numeric Value Status Byte Hex Error LED Binary Range Hex Binary XFÜ1 Hex Dec 580 2 1000 0000 0000 0 010 0x800...

Page 100: ...2 On Overrange 1160 0 0111 0001 0100 1000 0x7148 29000 1160 04 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 1 Process values below 0 are represented in binary form as the two s complement 4 8 6 2 S5 FB250 Format Table 120 Setting Voltage Measurement 6 1000 mV S5 FB250 Format Voltage mV Numeric Value Status Byte Hex Error LED Binary Range Hex Binary XFÜ1 Hex Dec 1160 4 1000 0000 0000 0 010 0x8...

Page 101: ...01 0x42 On Overrange 2320 0 0111 0001 0100 1000 0x7148 29000 2326 08 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 1 Process values below 0 are represented in binary form as the two s complement 4 8 7 2 S5 FB250 Format Table 122 Setting Voltage Measurement 7 2000 mV S5 FB250 Format Voltage mV Numeric Value Status Byte Hex Error LED Binary Range Hex Binary XFÜ1 Hex Dec 2326 8 1000 0000 0000 0 0...

Page 102: ...tage measurements with S5 FB250 format enabled the I O module outputs the measured values for the sensors normalized to 2500 The defined measuring range of 15 mV 15 mV for example corresponds to a possible process value of 2500 2500 Note Be aware that the status information is represented in bit 0 bit 2 and the digitized measured value in bit 3 bit 15 Therefore the normalized measured value is shi...

Page 103: ...0x42 On Overrange 2490 0 0110 0001 0100 0100 0x6144 24900 2490 1 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 1 Process values below 0 are represented in binary form as the two s complement S5 FB250 Format Table 124 Setting Strain Gauge Bridge Supply Uref 2 4 V S5 FB250 Format Voltage mV Numeric Value Status Byte Hex Error LED Binary Range Hex Binary XFÜ1 Hex Dec 2 0 1000 0000 0000 0 010 0x80...

Page 104: ...1 0x42 On Overrange 17 5 0111 0001 1110 1110 0x71EE 29167 17 5006 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 1 Process values below 0 are represented in binary form as the two s complement S5 FB250 Format Table 126 Setting Strain Gauge Bridge Voltage Ud 15 mV S5 FB250 Format Voltage mV Numeric Value Status Byte Hex Error LED Binary Range Hex Binary XFÜ1 Hex Dec 17 506 1000 0000 0000 0 010 0...

Page 105: ...1 0x42 On Overrange 35 0 0111 0001 1110 1110 0x71EE 29167 35 0012 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 1 Process values below 0 are represented in binary form as the two s complement S5 FB250 Format Table 128 Setting Strain Gauge Bridge Voltage Ud 30 mV S5 FB250 Format Voltage mV Numeric Value Status Byte Hex Error LED Binary Range Hex Binary XFÜ1 Hex Dec 35 012 1000 0000 0000 0 010 0...

Page 106: ...1 0x42 On Overrange 70 0 0111 0001 1110 1110 0x71EE 29167 70 0024 0111 1111 1111 1111 0x7FFF 32767 0x60 On Overflow 1 Process values below 0 are represented in binary form as the two s complement S5 FB250 Format Table 130 Setting Strain Gauge Bridge Voltage Ud 60 mV S5 FB250 Format Voltage mV Numeric Value Status Byte Hex Error LED Binary Range Hex Binary XFÜ1 Hex Dec 70 024 1000 0000 0000 0 010 0...

Page 107: ...onality of data and power jumper contacts Do not touch the contacts Avoid contaminating the contacts Do not place the I O modules on the gold spring contacts Do not place the I O modules on the gold spring contacts in order to avoid soiling or scratching Pay attention to potential equalization from the environment The devices are equipped with electronic components that may be destroyed by electro...

Page 108: ... on the right side For some I O modules the grooves are closed on the top Therefore I O modules featuring a power jumper contact on the left side cannot be snapped from the top This mechanical coding helps to avoid configuration errors which may destroy the I O modules Therefore insert I O modules only from the right and from the top Requirements for Clearances and Creepage Distances For all secti...

Page 109: ... such a way that the groove and spring are connected to the preceding and following components Figure 11 Inserting I O Module Example 2 Press the I O module into the assembly until the I O module snaps into the carrier rail Figure 12 Snap the I O Module into Place Example 3 Check that the I O module is seated securely on the carrier rail and in the assembly The I O module must not be inserted croo...

Page 110: ... for the data contacts and power contacts if any to the head station or to the preceding and if applicable following I O module are established 5 2 2 Removing the I O Module 1 Remove the I O module from the assembly by pulling the release tab Figure 13 Removing the I O Module Example Electrical connections for data or power jumper contacts are disconnected when removing the I O module ...

Page 111: ...nnected to each CAGE CLAMP Do not connect more than one conductor at one single connection If more than one conductor must be routed to one connection these must be connected in an up circuit wiring assembly for example using WAGO feed through terminals 1 For opening the CAGE CLAMP insert the actuating tool into the opening above the connection 2 Insert the conductor into the corresponding connect...

Page 112: ...ficient an end module 750 600 no distance modules are required Do not exceed maximum current via power contacts The maximum current available from the Supply Module Ex i 750 606 or 750 625 000 001 is 1 A When configuring the system ensure that this current is not exceeded If exceeded an additional potential feed module must be used Keep the air and creep distances between intrinsically safe segmen...

Page 113: ...subsequent I O modules via the power contacts designed as spring contacts Figure 15 Supply Principle Ex i Table 131 Legend for Figure Ex i Power Supply Concept No Explanation 1 Fieldbus coupler controller 2 Ex i supply module 750 606 750 625 000 001 3 Ex i I O modules 4 End module US System supply 24 VDC UF1 Field supply 24 VDC UF2 Field supply 2 24 VDC 750 606 with electronic fuse and diagnostics...

Page 114: ...n 1 Fieldbus coupler controller 2 Filter module if required 3 Ex i supply module 4 Ex i I O modules 5 End module Overvoltage categories and rated surge voltage see EN 61010 2 201 6 2 1 Power Supply Concept for Marine Applications in Ex i Use the appropriate filter module in marine applications Power to the Ex i supply module is supplied via the appropriate filter module when using Ex i I O modules...

Page 115: ... 002 or Filter module 24 VDC HI 750 626 020 000 or Filter module 24 VDC HI T 750 626 025 001 3 Supply module 24 VDC 750 602 or Supply module 24 VDC with fuse 750 601 or Supply module 24 VDC with fuse and diagnostics 750 610 4 Filter module 24 VDC HI GF 750 624 020 002 or Filter module 24 VDC HI 750 624 020 000 5 Supply module 24 VDC Ex i with diagnostics 750 606 or Supply module 24 VDC Ex i 750 62...

Page 116: ...Filter module 24 VDC HI GF 750 626 020 002 or Filter module 24 VDC HI 750 626 020 000 or Filter module 24 VDC HI Temperature 750 626 025 001 3 Filter module 24 VDC HI GF 750 626 020 002 or Filter module 24 VDC HI 750 626 020 000 or Filter module 24 VDC HI T 750 626 025 001 4 Supply module 24 VDC Ex i with diagnostics 750 606 or Supply module 24 VDC Ex i 750 625 000 001 5 Ex I I O modules 6 End Mod...

Page 117: ...isable the channel of unused inputs to avoid unwanted error messages Section Configuration and Parameterization with WAGO IO CHECK describes how one channel or the channel diagnostics of individual inputs of the I O module can be switched on off 6 3 1 RTDs Resistance Thermometers Figure 19 Connection Example RTD Resistance Thermometer 2 and 3 Wire Technology Figure 20 Connection Example RTD Resist...

Page 118: ... 750 750 489 4AI RTD TC Strain Gauge Ex i Manual Version 1 1 0 valid from FW Version 02 6 3 2 TCs Thermocouples Figure 21 Connection Example TC Thermocouple 6 3 3 Millivolt Transmitters Figure 22 Connection Example Millivolt Transmitter ...

Page 119: ... RTD TC Strain Gauge Ex i Manual Version 1 1 0 valid from FW Version 02 6 3 4 Potentiometer Setting Figure 23 Connection Example Resistance Measurement Potentiometer Setting 6 3 5 PTC Probes Thermistors Figure 24 Connection Example PTC Probe Thermistor ...

Page 120: ...e reference voltage Uref E1 Measurement input of the reference voltage Uref I1 Output reference voltage Uref I1 Output reference voltage Uref I2 Not used I2 Not used E2 Measurement input of the bridge voltage Ud E2 Measurement input of the bridge voltage Ud 2 E3 Measurement input of the reference voltage Uref E3 Measurement input of the reference voltage Uref I3 Output reference voltage Uref I3 Ou...

Page 121: ... is selected for a channel in the configuration this sensor type must actually be connected to the corresponding inputs of the I O module This ensures recalibration to the new sensor Otherwise precise measured values are not displayed This applies to resistance based sensors in particular Scale input channels see also Section Scaling Measured Values Read out diagnostic information Output process d...

Page 122: ...rrange Diagnosis process alarm lower user limit value Diagnosis process alarm upper user limit value User limit values Scaling Calibration 7 1 Configuration and Parameterization with WAGO I O CHECK The I O Module 750 489 is supported by the WAGO I O CHECK commissioning tool staring with version 03 22 01 01 WAGO I O CHECK can be used to conveniently and completely configure and parameterize the I O...

Page 123: ...s in a parameter file before you begin parameterization This allows you to always use the original values should the parameterization be incorrect Behavior after overwriting with WAGO I O CHECK If WAGO I O CHECK is used to overwrite a parameterization made with the GSD file the I O module operates with the WAGO I O CHECK settings until the 750 333 and 750 833 Fieldbus Couplers Controllers are rest...

Page 124: ...ure has been identified in WAGO I O CHECK it appears in the overview area To open specific parameterization dialogs for the 750 489 I O Module proceed as follows 1 Select the I O module The representation of the I O module is marked 2 Right click to open the context menu and select the Settings menu item The parameterization dialog appears This forms the basis for the following explanation ...

Page 125: ...on bar including item number name version number and version date of the I O module 3 Buttons 4 Menu 5 Application area with the parameters 6 Status bar The individual areas are explained in more detail in the following sections 7 1 1 1 Title Bar The title bar in the parameterization dialog contains the program icon the window title and the button for closing the application window The window titl...

Page 126: ...for loading a saved parameter file Save Opens the dialog for saving parameterization information in a parameter file Read Reads the current parameterization from the I O module Write Writes the modified parameters to the I O module Factory Settings Resets all I O module settings to factory settings Note The values for the user calibration are also reset to their default values Therefore after the ...

Page 127: ...e Menu Menu Item Description Common General settings for all channels of the module Channel 1 Channel specific settings for channel 1 Channel 2 Channel specific settings for channel 2 Channel 3 Channel specific settings for channel 3 Channel 4 Channel specific settings for channel 4 Scaling Scaling settings for channels 1 4 Calibration Calibration settings for channels 1 4 Calculation Displays the...

Page 128: ...ed On Bit 0 overflow set in the event of measurement overrange underrange Bit 1 error set in the event of overflow underflow Bit 2 always 0 Off Status indicators not displayed Interference frequency suppression The input filter is used to suppress interfering mains frequency signal components The frequency depends on the application location and can be set with module level granularity 0 10 Hz The...

Page 129: ...ain the channel specific parameters of the I O module The parameter list is identical for all channels If you change a value a pen symbol appears to the left of the parameter in question and the Write button which had been grayed out before is enabled Click the Write button to save any settings you have been made and apply them to the I O module Figure 29 Menu Item Channel 1 Example ...

Page 130: ...on technology Thermocouple This channel operates using 2 wire connection technology Voltage This channel operates using 2 wire connection technology Sensor type Measuring range This parameter can be used to set the sensor type or measuring range The selection of the sensor type measuring range is dependent on the signal type setting Pt100 Pt200 Pt500 Pt1000 Ni100 Ni120 Ni200 Ni500 Ni1000 Ni1000 TK...

Page 131: ... temperature values 0 1 The resolution of the temperature value is 0 1 C F K digit 0 01 The resolution of the temperature value is 0 01 C F K digit Compensation resistor mΩ In this parameter you can input the line resistance that needs to be taken into account in the calculation of the measured values for 2 wire RTD measurement Input field 0 65535 Compensation resistance in mΩ Channel diagnosis Th...

Page 132: ...upper user limit value exceed diagnosis is switched off On Diagnosis upper user limit value exceed diagnosis is switched on Diagnosis Lower user limit value undershot This parameter can be used to switch diagnostics on off for a lower user limit value undershot Off Lower user limit value undershot diagnosis is switched off On Lower user limit value undershot diagnosis is switched on Upper user lim...

Page 133: ...select the corresponding channel Checking unchecking the box has an immediate effect When the box is checked the setting is written immediately to the I O module it is not necessary to click the Write button Click the Write button to save any settings you have made and apply them to the I O module Scaling is saved permanently i e still available after the node is restarted Figure 30 Scaling Menu I...

Page 134: ...d must fall within the range 2 0000 1 9999 A resolution of 1 16384 has already been taken into account for the decimal input Process value Output field The process value can be constant or deliberately kept changeable it can be represented as a fixed decimal value with unit or as a hexadecimal according to the measurement range Show values in hexadecimal The hexadecimal representation can be switc...

Page 135: ... the following information Use a low noise high precision calibrator for the calibration The accuracy of the calibrator must be higher than that of the device to be calibrated by a factor of ten Disconnect all cables if there are any from the I O module to the system Use a separate 24 V power supply to supply the node Use short shielded cables to connect to the calibrator Calibrate each channel se...

Page 136: ... with unit or as a hexadecimal according to the measurement range Show values in hexadecimal Hexadecimal representation can be switched on or off Hexadecimal representation is enabled Hexadecimal representation is disabled Area for displaying errors Underflow Underflow in the sensor lines Overflow Overflow in the sensor lines Measuring range underflow The field side input voltage or field side inp...

Page 137: ...from FW Version 02 Proceed as follows 1 Select the channel to calibrate by switching to the corresponding tab 2 Click the Start Calibration button A dialog opens 3 Follow the instructions in the dialog Figure 32 User Calibration Dialog Offset Correction Figure 33 User Calibration Dialog Gain Correction ...

Page 138: ... instructions directly Therefore it is not necessary to click the Write button After the calibration the process values will correspond to the reference values over the entire range The measuring circuits can be calibrated in the same way independently of each other The calibration process is performed on a channel basis therefore before the calibration process be sure to select the corresponding ...

Page 139: ...asurements Standard format T x x 0 1 Standard format high resolution T x x 0 01 S5 FB250 T x x 0 125 S5 FB250 high resolution T x x 0 0125 Voltage Measurements Example 30 mV Standard format U x x 0 0012 S5 FB250 U x x 0 0015 Example SG Uref 2 4 V Standard format U x x 0 1 S5 FB250 U x x 0 125 Example SG Ud 15 mV Standard format U x x 0 0006 S5 FB250 U x x 0 00075 Resistance Example 0 250 Ω Standar...

Page 140: ... the I O module operates with the WAGO I O CHECK settings until the 750 333 and 750 833 Fieldbus Couplers Controllers are restarted After restart the I O module is re parameterized via PROFIBUS using the GSD settings 7 3 1 750 489 4AI RTD TC Strain Gauge Ex i Configuration 7 3 1 1 PROFIBUS DP Fieldbus Couplers Controllers 750 333 0xx 000 750 833 0xx 000 When the aforementioned PROFIBUS DP fieldbus...

Page 141: ... 025 000 750 377 025 000 When the aforementioned PROFINET IO fieldbus couplers are used the process image size is configured by selecting the corresponding GSD entry Table 146 PROFINET IO Configuration GSD Entry PA Length Byte Data Type Inst Module Sub Module I O 750 489 4AI RTD TC Strain Gauge Ex i 4AI INT16 4 I 8 n a INT16 4 4AI UINT8 INT16 4 I O 12 12 UINT8 INT16 ...

Page 142: ...ain Gauge Ex i Parameterization 7 3 2 1 PROFIBUS DP Fieldbus Couplers Controllers 750 333 0xx 000 750 833 0xx 000 On the PROFIBUS DP fieldbus devices the I O module can be provided with operating parameters using the PROFIBUS GSD files under the category Device Specific Parameters Figure 36 Example Device Specific Parameters Dialog with PROFIBUS DP ...

Page 143: ...7 3 2 2 PROFINET IO Fieldbus Couplers 750 375 025 000 750 377 025 000 On the PROFIBUS IO fieldbus couplers the I O module can be provided with operating parameters using the PROFIBUS GSD file under the category Specific Module Channel Parameters Figure 37 Example Specific Module Channel Parameters Dialog with PROFINET IO ...

Page 144: ...Hz 400 Hz Siemens S5 format I O module deactivated Siemens S5 format Common Off activated On Sensor type Measuring range Channel x x 0 3 Channel deactivated Signal type Channel x x 1 4 Sensor type Measuring range Channel x x 1 4 Channel deactivated RTD 2L Pt100 RTD 2 wire Pt100 RTD 2L Pt200 Pt200 RTD 2L Pt500 Pt500 RTD 2L Pt1000 Pt1000 RTD 2L Ni100 Ni100 RTD 2L Ni120 Ni120 RTD 2L Ni200 Ni200 RTD 2...

Page 145: ...Type R Type R TC Type S Type S TC Type T Type T U 30 mV Voltage 30 mV U 60 mV 60 mV U 120 mV 120 mV U 250 mV 250 mV U 500 mV 500 mV U 1000 mV 1000 mV U 2000 mV 2000 mV SG Uref 2 4V 1 SG Uref 2 4V 1 SG Ud 15 mV 2 SG Ud 15 mV 2 SG Ud 30 mV 2 SG Ud 30 mV 2 SG Ud 60 mV 2 SG Ud 60 mV 2 Smoothing channel x x 0 3 deactivated Smoothing Channel x x 1 4 deactivated weak weak medium medium strong strong Numb...

Page 146: ...erflow Channel x x 1 4 Off 1 true On Diagnosis Underflow Channel x x 0 3 0 false Diagnosis Underflow Channel x x 1 4 Off 1 true On Diagnosis Measuring range overflow Channel x x 0 3 0 false Diagnosis Measuring range overflow Channel x x 1 4 Off 1 true On Diagnosis Overflow Channel x x 0 3 0 false Diagnosis Overflow Channel x x 1 4 Off 1 true On Process alarm Lower user limit value undershot Channe...

Page 147: ...istor mOhm Channel x x 0 3 0 65535 Compensation resistor mΩ Channel x x 1 4 0 65535 User scaling Channel x x 0 3 deactivated User scaling Channel x x 1 4 Checkbox deactivated activated Checkbox activated Offset Channel x x 0 3 32768 0 32767 Offset Channel x x 1 4 32768 0 32767 Gain Channel x x 0 3 32768 16384 32767 Gain Channel x x 1 4 2 0000 1 0000 1 9999 Factory setting The resolution of 1 16384...

Page 148: ... factor The scaling offset is the offset on the y axis When these two values are input the result is a scaled process value The following general scaling equation applies 𝑦𝑦2 𝑦𝑦1 𝐺𝐺𝐺𝐺𝐺𝐺𝐺𝐺 𝑟𝑟𝑟𝑟𝑟𝑟𝑟𝑟𝑟𝑟𝑟𝑟𝑟𝑟𝑟𝑟 𝑐𝑐𝑐𝑐𝑐𝑐𝑐𝑐𝑐𝑐𝑐𝑐𝑐𝑐 16384 𝑂𝑂𝑂𝑂𝑂𝑂𝑂𝑂𝑂𝑂𝑂𝑂 The variables have the following meanings Table 150 Variable Legend Scaling Measured Values Variable Meaning Function y2 Scaled process value y1 Unscaled process...

Page 149: ...requires reference values to be available for temperatures of the object to be measured Example 1 Requirements The WAGO node must be installed in the control cabinet the temperature in the control cabinet must have settled and be constant A thermocouple line must be laid up to the measuring point but not yet welded on there 1 Connect a calibrator to the open ends of the thermocouples 2 Use WAGO IO...

Page 150: ...ue Max FSV full scale value For calibrating the offset value for TCs a value can be set on the calibrator at which no voltage occurs at the clamping point That is typically the cold junction temperature However a value at which the sensor itself does not yet provide any appreciable voltage e g 600 C for B types can be used In the event that WAGO I O CHECK cannot be used the following must be obser...

Page 151: ...e limiting value violation monitoring You can activate or deactivate these diagnostics separately in WAGO I O CHECK see Section Commissioning Parameterization with WAGO I O CHECK The I O module only ever allows one error to be indicated A dedicated bit in the status byte is assigned to each error The associated status bit is set if an error status is detected Some errors cause multiple error statu...

Page 152: ...ge to the status byte Error LED does not light up Off On The upper measurement range value is output as a process value Error bit is set bit 0 underrange or bit 1 overrange General error bit 6 general error is set Error LED lights up On Off Process value is saturated Error bit is set bit 4 underflow or bit 5 overflow General error bit 6 general error is set Error LED lights up On On Process value ...

Page 153: ... status byte Error LED does not light up On On The measured value is output as a process value outside the specified range Error bit is set bit 0 underrange or bit 1 overrange General error is set bit 6 general error Error LED lights up The different types of monitoring must be enabled disabled separately The limiting values for detecting a measurement underrange overrange or an overflow underflow...

Page 154: ... LED Indicators The indicators of the I O module provide information about possible states and cases of error The tables below contain the interpretations of the signals Table 155 Signal Evaluation for Each Channel Status LED Status LED State Possible Interpretation Off Not ready for operation Local bus communication absent or interrupted Channel deactivated Green Operational readiness and uninter...

Page 155: ...n Zone 2 hazardous areas and shall be used in accordance with the marking and installation regulations The following sections include both the general identification of components devices and the installation regulations to be observed The individual subsections of the Installation Regulations section must be taken into account if the I O module has the required approval or is subject to the range...

Page 156: ...AI RTD TC Strain Gauge Ex i Manual Version 1 1 0 valid from FW Version 02 11 1 Marking Configuration Examples 11 1 1 Marking for Europe According to ATEX and IECEx Figure 39 Marking Example per ATEX and IECEx Figure 40 Text Detail Marking Example per ATEX and IECEx ...

Page 157: ...sure IIIC Dust group Explosive dust atmosphere T135 C Maximum surface temperature of the enclosure no dust bin Dc Level of equipment protection EPL Mining I Device group Mining M2 Device category High degree of safety Ex Explosion protection mark d Protection type Pressure tight encapsulation I Electrical devices in potentially explosive mines Mb Level of equipment protection EPL Gases II Device g...

Page 158: ... 750 750 489 4AI RTD TC Strain Gauge Ex i Manual Version 1 1 0 valid from FW Version 02 Figure 41 Marking Example of an Approved I O Module Ex i per ATEX and IECEx Figure 42 Text Detail Marking Example of an Approved I O Module Ex i per ATEX and IECEx ...

Page 159: ...ace temperature of the enclosure no dust bin Dc Level of equipment protection EPL Mining I Device group Mining M2 M1 Device category High level of safety with circuits that offer a very high level of safety Ex Explosion protection mark d Protection type Pressure tight encapsulation ia Ma Protection type and equipment protection level EPL Associated equipment with intrinsically safe circuits I Elec...

Page 160: ...United States of America NEC and Canada CEC Figure 43 Marking Example According to NEC Figure 44 Text Detail Marking Example According to NEC 500 Table 159 Description of Marking Example According to NEC 500 Marking Description CL I Explosion protection gas group DIV 2 Area of application Grp A B C D Explosion group gas group op temp code T4 Temperature class ...

Page 161: ... equipment protection level EPL Associated apparatus with intrinsic safety circuits for use in Zone 20 IIC Group T4 Temperature class Gc Equipment protection level EPL Figure 46 Text Detail Marking Example for Approved Ex i I O Module According to NEC 506 Table 161 Description of Marking Example for Approved Ex i I O Modules According to NEC 506 Marking Description CI I Explosion protection group ...

Page 162: ...ection mark nA Type of protection ia IIIC Type of protection and equipment protection level EPL Associated apparatus with intrinsic safety circuits for use in Zone 20 IIC Group T4 Temperature class Gc Equipment protection level EPL X Symbol used to denote specific conditions of use Gases Ex Explosion protection mark nA Type of protection ia Ga Type of protection and equipment protection level EPL ...

Page 163: ...the printing when replacing components The product is an open system As such the product must only be installed in appropriate enclosures or electrical operation rooms to which the following applies Can only be opened using a tool or key Inside pollution degree 1 or 2 In operation internal air temperature within the range of 0 C Ta 55 C or 20 C Ta 60 C for components with extension number 025 xxx ...

Page 164: ...erface in particular Operating DIP switches coding switches or potentiometers Replacing fuses Wiring connecting or disconnecting of non intrinsically safe circuits is only permitted in the following cases The circuit is disconnected from the power supply The area is known to be non hazardous Outside the device suitable measures must be taken so that the rated voltage is not exceeded by more than 4...

Page 165: ... be connected to telephone networks or telecommunication cables WARNING The radio receiver module 750 642 may only be used to connect to external antenna 758 910 WARNING Product components with fuses must not be fitted into circuits subject to overloads These include e g motor circuits WARNING When installing I O module 750 538 Control Drawing No 750538 in the manual must be strictly observed Addi...

Page 166: ...o not remove the I O module during the update process Do not interrupt the power supply Ensure that communication with the fieldbus coupler controller is not interrupted during the update process Any PLC application running on the controller must be stopped before the update process Before an update via the service interface disconnect the fieldbus cable from the fieldbus coupler controller Do not...

Page 167: ... by the application It may be necessary to perform a recalibration in order to maintain the accuracy despite aging of individual components of the line The operator of the equipment must determine the intervals at which such recalibration is to be performed The corresponding sections on the topic of calibration explain how the recalibration is to be performed with the help of the various commissio...

Page 168: ... Ex i Manual Version 1 1 0 valid from FW Version 02 12 3 WAGO UII Unique Item Identifier Each I O module is provided with a unique WAGO UII Unique Item Identifier Application example The I O module can be permanently assigned a calibration certificate via this UII ...

Page 169: ...ef is detected by the Uref channel E1 E1 and the bridge voltage by the Ud channel E2 E2 The reference voltage is measured by the SG Uref 2 4 V setting and the strain gauge bridge voltage by the SG Ud 15 mV setting Sample equation Technical data of the load cell used e g 5 kg equals 2 𝑚𝑚𝑚𝑚 𝑉𝑉 The weight is calculated as follows 𝑔𝑔 𝑈𝑈𝑈𝑈 2 𝑚𝑚𝑚𝑚 𝑈𝑈𝑈𝑈𝑈𝑈𝑈𝑈 1 𝑉𝑉 5 𝑘𝑘𝑘𝑘 By 𝑈𝑈𝑈𝑈 𝐶𝐶𝐶𝐶2𝐷𝐷1𝐷𝐷0 25000 15 𝑚𝑚𝑚𝑚 s...

Page 170: ...Power Supply Concept for Marine Applications in Ex i Class B shown with 750 626 xxx xxx for Field 2 116 Figure 19 Connection Example RTD Resistance Thermometer 2 and 3 Wire Technology 117 Figure 20 Connection Example RTD Resistance Thermometer 4 Wire Technology 117 Figure 21 Connection Example TC Thermocouple 118 Figure 22 Connection Example Millivolt Transmitter 118 Figure 23 Connection Example R...

Page 171: ...d IECEx 158 Figure 42 Text Detail Marking Example of an Approved I O Module Ex i per ATEX and IECEx 158 Figure 43 Marking Example According to NEC 160 Figure 44 Text Detail Marking Example According to NEC 500 160 Figure 45 Text Detail Marking Example for Approved Ex i I O Module According to NEC 505 161 Figure 46 Text Detail Marking Example for Approved Ex i I O Module According to NEC 506 161 Fi...

Page 172: ...tandard Format and S5 FB250 Format 40 Table 23 Pt100 Pt200 Pt500 Pt1000 EN 60751 Setting Standard Format Celsius 47 Table 24 Pt100 Pt200 Pt500 Pt1000 EN 60751 Setting S5 FB250 Format Celsius 47 Table 25 Ni100 Ni120 Ni200 Ni500 Ni1000 Setting Standard Format Celsius 48 Table 26 Ni100 Ni120 Ni200 Ni500 Ni1000 Setting S5 FB250 Format Celsius 48 Table 27 TC Type B Setting Standard Format Celsius 49 Ta...

Page 173: ...pe J Setting Standard Format Fahrenheit 65 Table 58 TC Type J Setting S5 FB250 Format Fahrenheit 65 Table 59 TC Type K Setting Standard Format Fahrenheit 66 Table 60 TC Type K Setting S5 FB250 Format Fahrenheit 66 Table 61 TC Type N Setting Standard Format Fahrenheit 67 Table 62 TC Type N Setting S5 FB250 Format Fahrenheit 67 Table 63 TC Type R and Type S Setting Standard Format Fahrenheit 68 Tabl...

Page 174: ...le 97 Setting Resistance Measurement 2 Standard Format 87 Table 98 Setting Resistance Measurement 2 S5 FB250 Format 87 Table 99 Setting Resistance Measurement 3 Standard Format 88 Table 100 Setting Resistance Measurement 3 S5 FB250 Format 88 Table 101 Setting Resistance Measurement 4 Standard Format 89 Table 102 Setting Resistance Measurement 4 S5 FB250 Format 89 Table 103 Setting Resistance Measu...

Page 175: ...Marine Applications in Ex i Class A shown with 750 624 xxx xxx for Field 2 115 Table 135 Legend for figure Power Supply Concept for Marine Applications in Ex i Class B shown with 750 626 xxx xxx for Field 2 116 Table 136 Explanation of the Legend for figure Power Supply Concept for Marine Applications in Ex i Class B shown with 750 626 xxx xxx for Field 2 116 Table 137 Terminal Assignment Resistor...

Page 176: ... Example of an Approved I O Module Ex i per ATEX and IECEx 159 Table 159 Description of Marking Example According to NEC 500 160 Table 160 Description of Marking Example for Approved Ex i I O Module According to NEC 505 161 Table 161 Description of Marking Example for Approved Ex i I O Modules According to NEC 506 161 Table 162 Description of Marking Example for Approved Ex i I O Modules According...

Page 177: ...WAGO I O SYSTEM 750 177 750 489 4AI RTD TC Strain Gauge Ex i Manual Version 1 1 0 valid from FW Version 02 ...

Page 178: ...WAGO Kontakttechnik GmbH Co KG Postfach 2880 D 32385 Minden Hansastraße 27 D 32423 Minden Phone 49 571 887 0 Fax 49 571 887 844169 E Mail info wago com Internet www wago com ...

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