2924692 [PHOENIX]
MACX MCR-EX-T-UI-UP;型号: | 2924692 |
厂家: | PHOENIX CONTACT |
描述: | MACX MCR-EX-T-UI-UP |
文件: | 总40页 (文件大小:785K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
MACX MCR-EX-T-UI-UP...
Temperature transducers with intrinsically safe
input for temperature sensors, voltage signals,
resistance-type sensors and potentiometers
Data sheet
104601_en_04
© PHOENIX CONTACT 2012-05-21
1
Description
The configurable and programmable MACX
Features such as sensor type, connection method, measur-
ing range, measuring unit, filter, alarm signal and output
range can be configured using the IFS-CONF software and
a device-specific DTM (Device Type Manager).
MCR-EX-T-UI-UP... temperature transducer is used for the
intrinsically safe (Ex i) operation of all standard temperature
sensors (RTDs and thermocouples), voltage signals, re-
mote resistance-type sensors and potentiometers. The tem-
perature input signals are output in a linearized format at the
output. In addition to an analog current and voltage output,
the module also has a switching output. The power supply
has been designed as a wide range power supply.
Features
–
Input for all standard temperature sensors (RTDs and
thermocouples), voltage signals, remote resistance-
type sensors and potentiometers.
–
–
–
–
With intrinsically safe inputs [Ex ia] IIC
Current and voltage output
Switching output (1 PDT relay)
Configuration via software (FDT/DTM) or operator inter-
face (IFS-OP-UNIT)
The devices can be installed in zone 2 in the protection type
“n” (EN 60079-15).
The temperature transducer can be configured with the
standard configuration (see example: “Order key” on
page 6) or order-specific according to the order key and is
delivered calibrated and ready for operation. Possible set-
tings for the modules configured according to the order
(MACX MCR...-C) can be found in the order key on page
page 6.
–
–
–
–
–
Up to SIL 2 according to EN 61508 on output 4 ... 20 mA
3-way electrical isolation
Installation in zone 2 permitted
Wide range power supply 19.2 ... 253 V AC/DC
With screw or spring-cage connection
The set configuration is shown on the label on the side of the
housing.
WARNING: Explosion hazard
The device is an item of associated electrical equipment for intrinsically safe circuits. It is designed for
use in zone 2, if specific conditions are observed.
When installing and operating the device, the applicable safety directives (including national safety directives), ac-
cident prevention regulations, as well as general technical regulations must be observed.
WARNING: Explosion hazard
Please observe the safety regulations and installation notes on page 11.
Make sure you always use the latest documentation.
It can be downloaded at www.phoenixcontact.net/catalog.
This data sheet is valid for the products listed in Section 3 “Ordering data” .
MACX MCR-EX-T-UI-UP...
2
1
2
3
4
5
6
Table of contents
Description.................................................................................................................................. 1
Table of contents ........................................................................................................................ 2
Ordering data.............................................................................................................................. 5
Order key ................................................................................................................................... 6
Technical data ............................................................................................................................ 7
Minimum span and measuring accuracies.................................................................................. 9
6.1
Pt and Ni-RTD inputs........................................................................................................................................ 9
6.2
Cu-RTD inputs................................................................................................................................................... 9
6.3 NI1000 input (Landis & Gyr), KTY 81-110, KTY 84-130 (Philips) .............................................................. 9
6.4 Thermocouple input.......................................................................................................................................... 9
6.5 Cold junction error...............................................................................................................................9
6.6
6.7
6.8
6.9
Voltage signal input .......................................................................................................................................... 9
R transducers and resistors ............................................................................................................................ 9
Potentiometer.................................................................................................................................................. 10
Output signals ................................................................................................................................................. 10
7
8
Safety regulations and installation notes....................................................................................11
7.1
Installation and operation...............................................................................................................................11
7.2 Safety regulations for installation in potentially explosive areas .............................................................. 11
7.3
Use in safety-related applications (SIL 2).................................................................................................... 12
Installation .................................................................................................................................13
8.1
Basic circuit diagrams ................................................................................................................................... 13
Structure........................................................................................................................................................... 13
Dimensions...................................................................................................................................................... 14
Mounting .......................................................................................................................................................... 14
8.2
8.3
8.4
8.5 Connecting the cables ......................................................................................................................14
8.6 Power supply................................................................................................................................................... 14
8.7 Sensor types.....................................................................................................................................15
8.7.1 Thermocouple (TC) with internal cold junction compensation ...................................................................... 15
8.7.2 Thermocouple (TC) with external or without cold junction compensation.....................................................15
8.7.3 Voltage input ................................................................................................................................................ 15
8.7.4 Potentiometer............................................................................................................................................... 15
8.7.5 Resistance thermometer (RTD).................................................................................................................... 15
8.7.6 Measuring resistances ................................................................................................................................. 15
8.8
8.9
Current output ................................................................................................................................................. 15
Voltage output ................................................................................................................................................. 15
8.10 Switching output................................................................................................................................16
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MACX MCR-EX-T-UI-UP...
8.11 Switching output behavior with manual acknowledgement (latching) .................................................... 17
8.11.1 Switching behavior (2): Undertemperature limit (≤ SPH) .............................................................................. 17
8.11.2 (Switching behavior (3): Overtemperature limit (≥ SPH)............................................................................... 17
8.11.3 Switching behavior (4): Undertemperature limit with hysteresis (≤ SPL) ...................................................... 18
8.11.4 Switching behavior (5): Overtemperature limit with hysteresis (≥ SPH)........................................................ 18
8.11.5 Switching behavior (6): Temperature range limit (≤ SPL and ≥ SPH) ........................................................... 19
8.11.6 Switching behavior (7): Temperature range limit (≥ SPL and ≤ SPH) ........................................................... 19
8.12 Monitoring function ......................................................................................................................................... 20
8.13 Operating modes ............................................................................................................................................ 20
8.13.1 SIL ON/SIL OFF ........................................................................................................................................... 20
8.13.2 Service mode ............................................................................................................................................... 20
9
Configuration .............................................................................................................................20
9.1
Delivered state/standard configuration........................................................................................................ 21
9.2 Zero adjust, adjustment via buttons S2 and S3 (only possible with SIL OFF) ....................................... 21
9.3 Span adjust, adjustment via buttons 2 and 4 (only possible with SIL OFF)............................................ 21
9.4 Force output......................................................................................................................................21
9.5
Cable compensation, 2-wire RTD or RTD 1 with 2 x RTD ........................................................................ 21
9.6 Cable compensation RTD 2 with 2 x RTD or TC with external cold junction compensation (TC + CJ
external) ........................................................................................................................................................... 22
9.7
Automatic potentiometer adjustment (teach-in) ......................................................................................... 22
9.8 Manual acknowledgement of switching outputs (latch function).............................................................. 22
9.9 LED status indicators ........................................................................................................................22
10 Password...................................................................................................................................23
11 Flow chart, operator interface ....................................................................................................23
11.1 Menu structure ................................................................................................................................................ 24
11.2 Key for start screen......................................................................................................................................... 25
11.3 Key for SETTINGS - MENU .......................................................................................................................... 25
11.4 Key for SETTINGS - Configure..................................................................................................................... 25
11.5 Key for SETTINGS - Service......................................................................................................................... 26
11.6 Key for SETTINGS - Save ............................................................................................................................. 26
11.7 Key for input..................................................................................................................................................... 27
11.7.1 Key for input configuration (analog input) ..................................................................................................... 27
11.8 Key for output .................................................................................................................................................. 29
11.8.1 Key for output configuration (analog output)................................................................................................. 29
11.9 Key for error handling..................................................................................................................................... 30
11.10 Key for switch .................................................................................................................................................. 30
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MACX MCR-EX-T-UI-UP...
12 IFS-OP-UNIT operator interface error codes .............................................................................30
13 Configuration with the service PC ..............................................................................................31
13.1 System requirements ..................................................................................................................................... 31
13.2 Configuring the user characteristic curve ..........................................................................................31
14 Comparison of safety data.........................................................................................................31
15 Application examples.................................................................................................................32
15.1 Current output ................................................................................................................................................. 32
15.2 Voltage output ................................................................................................................................................. 32
15.3 Switching output.............................................................................................................................................. 33
Appendix
Safety-related applications (SIL 2) ............................................................................................................................. A-1
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MACX MCR-EX-T-UI-UP...
3
Ordering data
Temperature transducer, Ex i
Description
Type
Order No.
2865654
2924689
2811763
2924692
Pcs. / Pkt.
Standard configuration/in-stock article, with screw connection
Standard configuration/in-stock article, with spring-cage connection
Order configuration/KMAT, with screw connection
Order configuration/KMAT, with spring-cage connection
MACX MCR-EX-T-UI-UP
MACX MCR-EX-T-UI-UP-SP
MACX MCR-EX-T-UI-UP-C
MACX MCR-EX-T-UI-UP-SP-C
1
1
1
1
Accessories
Description
Type
Order No.
2811899
2811886
Pcs. / Pkt.
1
1
1
Operator interface for the configuration of compatible MACX modules.
Cradle unit, for snapping the operating and display unit onto the DIN rail
IFS-OP-UNIT
IFS-OP-CRADLE
Programming adapter for MACX MCR... devices. With USB interface for pro- IFS-USB-PROG-ADAPTER
gramming with the IFS-CONF software
2811271
Cold junction compensation connector for thermocouples
MACX MCR-EX-CJC
2925002
1
For additional accessories, please refer to the INTERFACE catalog from Phoenix Contact.
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MACX MCR-EX-T-UI-UP...
4
Order key
Order key for temperature transducer MACX-MCR-EX-T-UI-UP(-SP)-C (standard configuration entered as an example)
Order No.
Safety Integrity
Level (SIL)
Sensor type
Connection
method
Cold junction
compensation
Measuring range:
Start End
Measuring
unit
Output range
OUT02
Factory calibration certificate
= FCC
2811763
/
ON
/
PT100
/
4
/
0
/
-50
/
150
/
C
/
/
NONE
2811763 ꢀ
ON ꢀ active
See below
2
3
4
ꢀ 2-wire
ꢀ 3-wire
ꢀ 4-wire
0
1
ꢀ off, e.g. with
RTD, R,
See
See
C
F
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
°C
°F
ꢀ
OUT15
OUT16
OUT01
OUT15
OUT25
OUT26
OUT02
OUT05
OUT03
OUT06
OUT04
OUT13
OUT14
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
0...5 mA
0...10 mA
0...20 mA
0...5 mA
1...5 mA
2...10 mA
4...20 mA
0...5 V
NONE ꢀ without FCC
MACX MCR-EX-
T-UI-UP-C
below
below
potentiometer,
mV
NONE ꢀ not active
O
P
V
%
YES
ꢀ with FCC (a fee is
charged)
2924692 ꢀ
mV
MACX MCR-EX-
T-UI-UP-SP-C
ON only with output
range = OUT02
ꢀ on, e.g. with TC
YESPLUS ꢀ Factory calibration
certificate with
0...10 V
5 measuring points
(a fee is charged)
1...5 V
2...10 V
-5...+5 V
-10...+10 V
others freely
configurable in the
software
Other setting options can be configured
with the IFS-CONF software.
Smallest measuring
range
-
Freely configurable user characteristic with
30 interpolation points
Resistance thermometers RTD
Others can be selected or are freely
configured in the software.
PT100
ꢀ
Pt 100 acc. to IEC/EN 60751
-200
-200
-200
-200
-200
-200
-200
-200
-200
-200
-60
850
850
850
850
850
850
850
850
850
850
250
250
180
180
160
500
200
180
150
300
°C
°C
°C
°C
°C
°C
°C
°C
°C
°C
°C
°C
°C
°C
°C
°C
°C
°C
°C
°C
20 K
20 K
20 K
20 K
20 K
20 K
20 K
20 K
20 K
20 K
20 K
20 K
20 K
20 K
20 K
100 K
100 K
100 K
20 K
20 K
PT200
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
Pt 200 acc. to IEC/EN 60751
PT500
Pt 500 acc. to IEC/EN 60751
-
Output behavior in the event of a short circuit,
sensor break, or overrange/underrange is
freely configurable or can be set according to
NE43 (standard configuration: NE43 upscale)
PT1000
PT100S
PT1000S
PT100G
PT1000G
PT100J
PT1000J
NI100
Pt 1000 acc. to IEC/EN 60751
Pt 100 acc. to Sama RC21-4-1966
Pt 1000 acc. to Sama RC21-4-1966
Pt 100 acc. to GOST 6651
Pt 1000 acc. to GOST 6651
-
-
Filter setting (standard configuration: 1)
Pt 100 acc. to JIS C1604/1997
Pt 1000 acc. to JIS C1604/1997
Ni 100 acc. to DIN 43760/DIN IEC 60751
Ni 1000 acc, to DIN 43760/DIN IEC 60751
Ni 100 acc. to Sama RC21-4-1966
Ni 1000 acc. to Sama RC21-4-1966
Ni 1000 (Landis & Gyr)
Restart after failsafe
(standard configuration: ON)
NI1000
NI100S
NI1000S
NI1000L
CU10
-60
-
Switching behavior: Switching output ?
(limit values, times, etc.) (standard
configuration: OFF)
-60
-60
-50
Cu 10 acc. to Sama RC21-4-1966
-70
CU50
Cu 50/Cu 100 acc. to GOST 6651 (
ꢁ
= 1.428)
-50
CU53
Cu 53 acc. to GOST 6651 (ꢁ = 1.426)
-50
KTY81
KTY84
KTY81-110 (Philips)
-55
KTY84-130 (Philips)
-40
Thermocouples TC
B
E
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
acc. to IEC/EN 60584 (Pt30Rh-Pt6Rh)
acc. to IEC/EN 60584 (NiCr-CuNi)
acc. to IEC/EN 60584 (Fe-CuNi)
acc. to IEC/EN 60584 (NiCr-Ni)
acc. to IEC/EN 60584 (NiCrSi-NiSi)
acc. to IEC/EN 60584 (Pt13Rh-Pt)
acc. to IEC/EN 60584 (Pt10Rh-Pt)
acc. to IEC/EN 60584 (Cu-CuNi )
acc. to DIN 43760 (Fe-CuNi)
acc. to DIN 43760 (Cu-CuNi)
C ASTM JE988 (2002)
500
-230
-210
-250
-250
-50
-50
-200
-200
-200
0
1820
1000
1200
1372
1300
1768
1768
400
°C
°C
°C
°C
°C
°C
°C
°C
°C
°C
°C
°C
°C
°C
°C
°C
°C
50 K
50 K
50 K
50 K
50 K
50 K
50 K
50 K
50 K
50 K
50 K
50 K
50 K
50 K
50 K
50 K
50 K
Others can be selected in the software.
J
K
N
R
S
T
L
900
U
600
CA
DA
A1G
A2G
A3G
MG
LG
2315
2315
2500
1800
1800
100
D ASTM JE988 (2002)
0
A-1 GOST 8.585-2001
0
A-2 GOST 8.585-2001
0
A-3 GOST 8.585-2001
0
M GOST 8.585-2001
-200
-200
L
GOST 8.585-2001
800
Remote resistance-type sensors R
(2-, 3-, 4-wire)
RES03
RES05
RES06
RES09
RES10
RES12
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
Resistance 0...150 ꢀ
Resistance 0...600 ꢀ
Resistance 0...1200 ꢀ
Resistance 0...6250 ꢀ
Resistance 0...12,500 ꢀ
Resistance 0...50,000 ꢀ
0
0
0
0
0
0
150
600
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
Others can be selected in the software.
10% of the selected
measuring range
1200
6250
12500
50000
Potentiometers
POT03
POT05
POT06
POT09
POT10
POT12
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
Potentiometer 0...150 ꢀ
Potentiometer 0...600 ꢀ
Potentiometer 0...1200 ꢀ
Potentiometer 0...6250 ꢀ
Potentiometer 0...12,500 ꢀ
Potentiometer 0...50,000 ꢀ
0
0
0
0
0
0
100
100
100
100
100
100
%
%
%
%
%
%
3-wire
Others can be selected in the software.
10% of the selected
measuring range
Voltage signals mV
V04
ꢀ
Voltage (mV)
-1000
+1000
mV
10% of nominal
span
Others can be selected in the software.
9
Temperature conversion guide for °C to °F:
T [°F] = – T [°C] + 32
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5
Technical data
Input
Resistance thermometer
Thermocouple sensor
Pt, Ni, Cu sensors: 2-, 3-, 4-wire
B, E, J, K, N, R, S, T, L, U, CA, DA, A1G, A2G, A3G, MG, LG
(see example, “Order key” on page 6)
Resistor
0 Ω ... 50 kΩ
Potentiometer
Voltage
0 Ω ... 50 kΩ
-1000 mV ... 1000 mV
Output
Output signal
4 mA ... 20 mA with SIL ON
(further output signals can be configured with SIL OFF)
Maximum output signal
Voltage output
Current output
±11 V
22 mA
Load
Voltage output
≥ 10 kΩ
Current output
≤ 600 Ω (at 20 mA)
Behavior in the event of a sensor error
According to NE 43 (or freely definable)
Switching output
Contact type
1 PDT contact
Contact material
AgSnO2, hard gold-plated
30 V AC (30 V DC)
0.5 A (30 V AC) / 1 A (30 V DC)
Maximum switching voltage
Maximum switching current
Cycles
5
With ohmic load
1 x 10
General data
Supply voltage range
Current consumption
Power consumption
Temperature coefficient
Step response (0 ... 99 %)
With SIL
24 V ... 230 V AC/DC (-20%/+10%, 50/60 Hz)
< 50 mA (24 V DC)
< 1.5 W
0.01 %/K, maximum
Typ. 1000 ms
Typ. 700 ms
Without SIL
Transmission error, total
Electrical isolation
Input/output
< 0.1% (e.g., for PT100, 300 K span, 4 ... 20 mA)
4-way, between input/output/power supply/switching output
375 V P (according to EN 60079-11)
Input/power supply
Input/switching output
Output/power supply
Power supply/switching output
Ambient temperature
Operation
375 V P (according to EN 60079-11)
375 V P (according to EN 60079-11)
300 V rms reinforced insulation (according to EN 61010/50178)
300 V rms reinforced insulation (according to EN 61010/50178)
-20 °C ... +65°C
Storage/transport
Permissible humidity (operation)
Shock
-40 °C ... +85°C
5% ... 95% (no condensation)
15g, IEC 60068-2-27
Vibration
5g, IEC 60068-2-6
Status indicators
Green LED (supply voltage, PWR)
Red LED, flashing (cable error, sensor error, ERR)
Red LED (module error, ERR)
Yellow LED (switching output)
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MACX MCR-EX-T-UI-UP...
General data [...]
Housing material
PA 66-FR
Color
Green
Degree of protection
Pollution degree
IP20
2
Dimensions (width x height x depth)
Inflammability class according to UL 94
Design
17.5 x 99 x 114.5 mm
V0
Terminal housing for mounting on DIN rails
Conformance
EMC directive 2004/108/EC
Ex directive (ATEX)
1
EN 61326-1; EN 61000-6-2 ; EN 61000-6-4
EN 60079-0, EN 60079-11, EN 60079-15, EN 61241-0, EN 61241-11
1
During the interference, there can possibly be small deviations.
Safety data according to ATEX for intrinsically safe circuits
Maximum voltage (Uo)
6 V
Maximum current (Io)
Maximum power (Po)
Gas group
Maximum external inductance (Lo)
Maximum external capacity (Co)
Maximum internal inductance (Ci)
Maximum internal inductance (Li)
7.4 mA
11 mW
Ex ia IIC
100 mH
1.3 µF
44 nF
Ex ia IIB
100 mH
6.8 µF
10 mH
1.7 µF
44 nF
1 mH
2.6 µF
44 nF
10 mH
9.2 µF
44 nF
1 mH
15 µF
44 nF
44 nF
Negligible
Maximum voltage U
253 V AC (125 V DC)
m
Approvals
ATEX
X II (1)G [Ex ia] IIC; X II (1)D [Ex iaD]
X II 3 G Ex nAC ic IIC / IIB / IIA T4 X
[Ex ia] IIC; [Ex iaD]; Ex nAC ic IIC T4
Applied for
IBExU 10 ATEX 1044
IBExU 10 ATEX 1044
IECEx IBE 10.0004X
IECEx approval
UL, USA/Canada
Functional safety (SIL)
Can be used up to SIL 2
Connection data MACX MCR-EX-T-UI-UP
Conductor cross section
Solid (minimum/maximum)
Stranded (minimum/maximum)
AWG/kcmil (minimum/maximum)
Stripping length
2
2
2
0.2 mm /2.5 mm
2
0.2 mm /2.5 mm
24/14
7 mm
Connection method
Plug-in screw connection
Tightening torque
Minimum 0.5 Nm/maximum 0.6 Nm
Connection data MACX MCR-EX-T-UI-UP-SP
Conductor cross section
Solid (minimum/maximum)
Stranded (minimum/maximum)
AWG/kcmil (minimum/maximum)
Stripping length
2
2
2
0.2 mm /1.5 mm
2
0.2 mm /1.5 mm
24/16
8 mm
Connection method
Spring-cage connection
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MACX MCR-EX-T-UI-UP...
6.5
Cold junction error
6
Minimum span and measuring
accuracies
Cold junction error: ± 1 K, maximum
(with internal cold junction compensation).
With external compensation it depends on the quality of the
cold junction and the sensor used.
6.1
Pt and Ni-RTD inputs
Minimum measuring span:
With 10 Ω ≤ R < 100 Ω : 100 K
0
0
6.6
Voltage signal input
With 100 Ω ≤ R ≤ 10 kΩ : 20 K
Minimum measuring span:
10% of the nominal span of the respective range.
Measuring accuracy:
-1000 ... 1000 mV : 0.01% (of measuring range)
-500 ... 500 mV : 0.01% (of measuring range)
-250 ... 250 mV : 0.01% (of measuring range)
-125 ... 125 mV : 0.01% (of measuring range)
Measuring accuracy:
For 10 Ω ≤ R < 100 Ω : 0.2 K x 100 Ω / R
0
0
= 0.1% x (100 Ω/R ) x (200 K/measuring span)
0
For 100 Ω ≤ R ≤ 1 kΩ : 0.2 K
0
= 0.1% x (200 K/measuring span)
For 1 kΩ < R ≤ 10 kΩ : 0.4 K
0
= 0.1% x (400 K/measuring span)
-60 ...
-30 ...
-15 ...
60 mV : 0.01% (of measuring range)
30 mV : 0.01% (of measuring range)
15 mV : 0.01% (of measuring range)
6.2
Cu-RTD inputs
Minimum measuring span:
6.7
R transducers and resistors
For 10 Ω ≤ R < 100 Ω: 100 K
0
For 100 Ω ≤ R ≤ 10 kΩ: 20 K
0
50% of measuring range ≤ (nominal value of R transducer +
lead resistance) ≤ measuring range
Minimum measuring span: 10% of the selected measuring
range
Measuring accuracy:
For 10 Ω ≤ R < 100 Ω : 0.5 K x 100 Ω/R
0
0
= 0.1% x (100 Ω/R ) x (500 K/measuring span)
0
For 100 Ω ≤ R ≤ 1 kΩ : 0.5 K
0
Measuring accuracy:
= 0.1% x (500 K/measuring span)
0 ...
0 ...
0 ...
0 ...
75 Ω : 0.10% (of measuring range)
150 Ω : 0.05% (of measuring range)
300 Ω : 0.02% (of measuring range)
600 Ω : 0.01% (of measuring range)
For 1 kΩ < R ≤ 10 kΩ : 1.0 K
0
= 0.1% x (1000 K/measuring span)
6.3
NI1000 input (Landis & Gyr), KTY 81-110,
KTY 84-130 (Philips)
0 ... 1200 Ω : 0.01% (of measuring range)
0 ... 2400 Ω : 0.01% (of measuring range)
0 ... 4800 Ω : 0.01% (of measuring range)
0 ... 6250 Ω : 0.02% (of measuring range)
0 ... 12500 Ω : 0.02% (of measuring range)
0 ... 25000 Ω : 0.02% (of measuring range)
0 ... 50000 Ω : 0.02% (of measuring range)
Minimum measuring span: 20 K
Measuring accuracy: 0.2 K
6.4
Thermocouple input
Minimum measuring span with TC: 50 K
Measuring accuracy of the input with TC signals:
TC type E, J, K, N, T, L, U, M, Lr
Without cold junction error: 0.30 K
TC types B, R, S, C, D, A1, A2, A3
Without cold junction error: 0.50 K
Example:
R transducer with nominal value: 1000 Ω
Measuring range to be selected: 0 ... 1200 Ω
Minimum measuring span: 10% of the selected measuring
range = 120 Ω
Measuring accuracy: 0.01% of the selected measuring
range = 120 mΩ
104601_en_04
PHOENIX CONTACT
9
MACX MCR-EX-T-UI-UP...
6.8
Potentiometer
50% of measuring range ≤ (nominal value of potentiometer
+ lead resistance) ≤ measuring range
Minimum measuring span: 10% of the selected measuring
range
Measuring accuracy:
0 ...
0 ...
0 ...
0 ...
75 Ω : 0.10% (of measuring range)
150 Ω : 0.05% (of measuring range)
300 Ω : 0.02% (of measuring range)
600 Ω : 0.02% (of measuring range)
0 ... 1200 Ω : 0.02% (of measuring range)
0 ... 2400 Ω : 0.02% (of measuring range)
0 ... 4800 Ω : 0.02% (of measuring range)
0 ... 6250 Ω : 0.10% (of measuring range)
0 ... 12500 Ω : 0.10% (of measuring range)
0 ... 25000 Ω : 0.10% (of measuring range)
0 ... 50000 Ω : 0.10% (of measuring range)
Example:
Potentiometer with nominal value: 1000 Ω
Measuring range to be selected: 0 ... 1200 Ω
Minimum measuring span: 10% of the selected measuring
range = 120 Ω
Measuring accuracy: 0.02% of the selected measuring
range = 240 mΩ
6.9
Output signals
Analog output error
2 mV
2 mV
4 µA
0.01% at -10 ... 10 V
0.02% at 0 ... 10 V
0.02% at 0 ... 20 mA
104601_en_04
PHOENIX CONTACT 10
MACX MCR-EX-T-UI-UP...
7
Safety regulations and installation notes
7.1
Installation and operation
7.2
Safety regulations for installation in poten-
tially explosive areas
WARNING: Sensor does not conform to the
specification
Regulations for intrinsically safe circuits
Make sure that the connected sensors are only
used in the specified area (see “Order key” on
page 6).
WARNING: Explosion hazard
The devices are approved for intrinsically safe (Ex
i) circuits up to zone 0 (gas) and Ex zone 20
(dust). The technical safety values of the intrinsi-
cally safe field devices have to match the specifi-
cations of this package slip or otherwise the EC-
type examination certificate.
WARNING: Sensor wiring
Check the structure for functionally correct wiring
(see “Basic circuit diagrams” on page 13).
Follow the installation instructions.
WARNING: Explosion hazard
NOTE: Installation, operation, and maintenance
may only be carried out by qualified specialist per-
sonnel.
If the device has been used in non-intrinsically
safe circuits, it must not be used again in intrinsi-
cally safe circuits. Label the device clearly as be-
ing not intrinsically safe.
When installing and operating the device, the applicable
safety directives (including national safety directives), acci-
dent prevention regulations, as well as general technical
regulations must be observed.
WARNING: Explosion hazard
If the device has been used in non-intrinsically
safe circuits, it must not be used again in intrinsi-
cally safe circuits. Label the device clearly as be-
ing not intrinsically safe.
NOTE:
Do not open the device or making changes to it.
Do not repair the device yourself; replace it with
an equivalent device. Repairs may only be per-
formed by the manufacturer. The manufacturer is
not liable for damage resulting from violation.
Installation in zone 2
WARNING: Explosion hazard
The device is associated equipment of the Ex-i
protection type and is suitable for installation in
zone 2.
NOTE: The IP20 degree of protection (IEC
60529/EN 60529) of the device is intended for
use in a clean and dry environment. Do not sub-
ject the device to mechanical and/or thermal
loads that exceed the specified limits.
Observe the specified conditions for use in potentially ex-
plosive areas.
WARNING: Explosion hazard
NOTE: Only specified devices from Phoenix
Contact may be connected to the 12-pos. S-
PORT interface.
Install the device in a suitable, approved housing
with a minimum of IP54 degree of protection.
At the same time, observe IEC 60079-14/EN
60079-14 requirements.
For safety data, please refer to this data sheet and the cer-
tificates (EC-type examination certificate, and other approv-
als, if necessary).
WARNING: Explosion hazard
Disconnect the block power supply before:
–
Connecting or disconnecting cables of non-
intrinsically safe circuits.
WARNING: Explosion hazard
Use only category 3G modules (ATEX 94/9/EC).
104601_en_04
PHOENIX CONTACT 11
MACX MCR-EX-T-UI-UP...
WARNING: Explosion hazard
The device must be stopped and immediately re-
moved from the Ex area if it is damaged, was sub-
jected to an impermissible load, stored incorrectly
or if it malfunctions.
Installation in areas with a danger of dust explosions
WARNING: Explosion hazard
The device is not designed for installation in ar-
eas with a danger of dust explosions.
Connection to the intrinsically safe circuit in areas with
a danger of dust explosions (zones 20, 21 and 22) is only
permitted if the equipment connected to this circuit is ap-
proved for this zone (e.g., category 1D, 2D or 3D).
WARNING: Explosion hazard
If, however, you wish to use the device in zone 22,
it must be installed in a housing that complies with
IEC/EN 61241-1. In doing so, observe the maxi-
mum surface temperatures. Observe the require-
ments of IEC/EN 61241-14.
NOTE: Install the device in a suitable housing
with IP54 protection.
7.3
Use in safety-related applications (SIL 2)
When using the MACX MCR-EX-T-UI-UP... in safety-relat-
ed applications, observe the instructions in the appendix, as
the requirements differ for safety-related functions. .
The switching output is not intended for safety-re-
lated applications.
104601_en_04
PHOENIX CONTACT 12
MACX MCR-EX-T-UI-UP...
8.2
MACX MCR-...
Structure
8
Installation
NOTE: Electrostatic discharge!
7 mm
0,5-0,6 Nm
5-7 lb In
The device contains components that can be
damaged or destroyed by electrostatic discharge.
When handling the device, observe the neces-
sary safety precautions against electrostatic dis-
charge (ESD) according to EN 61340-5-1 and EN
61340-5-2.
1.3
1.2
1.1
1
32825
2.3
Ex–BTloemmberg,
2.2
2.1
MA
Germany
CX
S
upp
Ord.
M
perature
CR
24V ly
–
3.3
No.: –EX–T–UI–UP
2865654
Transducer/Ex
(–20%...+10V%,
...
230Volta
3.2
AC/gDeC
U
3.1
:
m
=
=
253V
1,5W
P
50Hz/60Hz)
N
Inpu
RTD, t
–Temperaturmessumform
TC,
A
0
na
–
mV,
/
lo
20mA
g
Poti,
–O
U
ut
≃
1.1
R
m
=
=
≃
N
253V
30V
igita (Zone
U
10V
m
C
D
0,5A
1.2
2.3
1
2
Take precautions against electrostatic discharge
before opening the front cover.
er
1.3
1
2.2 3.3
2
3.2
1
l
–O
2)
1
1
2.1
4
(30V
u
6
C
T
t
2.2
U
o
u
amb –20°...+A
5)°C/
t
2.3
I
M
U
o
/
u
OUT
G
N
D
ax.
t
1
A
3.1
(30V
V
O
3.2
a
lues –4°...+149°F
DC)
V
DC
=
=
=
6,0
7,4
11
I
3.3
O
P
O
mA
see
μc
mW
manual
WARNING
S
-
P
O
R
3
4
DO
NOT
AND
T
5.1
SEPARATE
INSTALLED
5.2
www.phoenixcontact.com
WHEN
R
5.3
PW
I
N
4.1
4.2
ZONE
8.1
Basic circuit diagrams
ENERGIZED
DAT
ERR
2
4.3
O
D
IN
MCR-EX-T-UI-UP
Sensor / Field
PLC / DCS
OUT
IN
+
5
MACX
passive
4.3
4.2 5.3
5.2
-
Poti
-
4.3 4.3
3.3
GND 3.3 3.3
OUT 3.2
+
I
4.2 4.2
4.1 4.1
3.2
+
UOUT 3.1 3.1
RTD1
RTD
2.3 2.3 14
2.2 2.2 11
2.1 2.1 12
4.3
4.2
4.1
ϑ
ϑ
ϑ
Figure 3 Structure MACX MCR-EX-T-UI-UP
MACX MCR-...-SP
DI
ϑ
5.3 5.3
5.2 5.2
5.1 5.1
NC 1.3
8 mm
RTD2
ϑ
1.2
1.1
Power
24V ...230V AC/DC
1.3
1.2
1.1
2.3
1
32825
2.2
Zone 0,1,2
Zone 20,21,22
Ex–BTloemmberg,
Supply
2.1
M
Zone 2
AC
G
ermany
perature
X
N
Ord.
M
C
R
.
:
3.3
24V
(–20%...+10V%o, ltage:
–
–EX–T–UI–UP–SP
2924689
3.2
o
...
230V
3.1
Transducer/Ex
U
P
=
=
AC/DC
m
253V
1,5W
50Hz/60Hz)
N
Input
RTD,
–Temperaturm
TC,
Analog–Out
mV,
Figure 1
Sensor connection - resistance thermometers
and potentiometers
0
Poti,
2)
–
20mA
U
≃
1.1
R
essum
m
=
=
≃
N
253V
/
U
10V
m
C
form
Digi3ta0Vl–Out
1.2
.3
2
3
1
2
(Zone
er
.2
.2
.3
1.3
1
2
3
1
0,5A
1
1
2.1
4
(30V
T
2.2
U
amb
–
AC)
out
20°...+65°C/
2.3
I
Max.
out
/
O
U
G
N
D
1
A
T
3.1
U
=
(
Values –4°..3.+01V49D°CF)
O
O
O
3.2
6
7
8
9
6
I
=
,
3.3
0
V
DC
7
P
,
4
m
=
A
mW
11
see
μ
c
m
anu
WARNING
al
S
-
P
O
R
DO
AND
T
NOT
5.1
SEPARATE
INSTALLED
5.2
www.phoenixcontact.com
R
PW
5.3
WHEN
IN
4.1
ZONE
ENERGIZED
4.2
AT
D
2
4.3
Sensor / Field
PLC / DCS
OUT
IN
ERR
DO
IN
passive
MCR-EX-T-UI-UP-SP
MACX MCR-EX-CJC
4.3 4.3
4.2 4.2
-
+
-
MACX
3.3
GND 3.3 3.3
OUT 3.2
.3
.3
TC
4
5
.2
.2
+
4
5
I
3.2
-
+
+
UOUT 3.1 3.1
4.1 4.1
2.3 2.3 14
2.2 2.2 11
2.1 2.1 12
4.3
4.2
4.1
DI
Figure 4
Structure MACX MCR-EX-T-UI-UP-SP
5.3 5.3
5.2 5.2
5.1 5.1
NC 1.3
mV
TC
1.2
1.1
1
2
3
4
5
6
7
8
Plug-in COMBICON connectors
Power
-
24V ...230V AC/DC
+
S-PORT (12-pos. programming interface)
Button S3 (UP), adjustment and reset functions
Button S2 (DOWN), adjustment and reset functions
DIP switch S1 for service mode
PWR LED, green, power supply
DAT LED, green, no function at present
Zone 0,1,2
Zone 20,21,22
Zone 2
Figure 2
Sensor connection - thermocouples and mV
sources
LED ERR, red, module, cable and sensor error, under-
range or overrange, service mode
9
DO LED, yellow, status of switching output
104601_en_04
PHOENIX CONTACT 13
MACX MCR-EX-T-UI-UP...
8.3
Dimensions
8.5
Connecting the cables
–
Screw terminal blocks (for MACX MCR-EX-T-UI-UP);
litz wires provided with ferrules.
17,5
99
Permissible cable cross section: 0.2 mm2 to 2.5 mm2
–
Spring-cage terminal blocks (for
MACX MCR-EX-T-UI-UP-SP); litz wires provided with
ferrules.
Permissible cable cross section: 0.2 mm2 to 1.5 mm2
–
–
Install intrinsically safe and non-intrinsically safe cables
separately.
Screw connection:
•
Insert the conductor into the corresponding con-
nection terminal block.
•
Use a screwdriver to tighten the screw in the open-
ing above the connection terminal block.
–
Spring-cage connection:
Figure 5
Dimensions (in mm)
•
Insert a screwdriver into the opening above the
connection terminal block.
8.4
Mounting
•
Insert the conductor into the corresponding con-
nection terminal block.
WARNING: Explosion hazard
If the module has been used in non-intrinsi-
cally safe circuits, it must not be used again in
intrinsically safe circuits.
The module must be clearly labeled as non-intrin-
sically safe.
8.6
Power supply
The power supply has been designed as a wide range
power supply (19.2 ... 253 V AC/DC). The module is sup-
plied with voltage via connection terminal blocks 1.1 and
1.2.
Figure 6
Mounting and removal
–
–
–
Mount the module on a 35 mm DIN rail according to EN
60715.
Install the module in a suitable housing to meet the re-
quirements for the protection class.
Before startup, check for correct function and wiring of
the MACX MCR-EX-T-UI-UP..., in particular the wiring
and marking of the intrinsically safe circuits.
104601_en_04
PHOENIX CONTACT 14
MACX MCR-EX-T-UI-UP...
8.7.6 Measuring resistances
Up to 75 Ω: RL ≤ 2.5 Ω for each lead.
8.7
Sensor types
The sensor types that can be used and their specific proper-
ties can be found in Section “Order key” on page 6
Depending on the connection method, the following termi-
nal points are to be connected for temperature measure-
ment (see Figure 1 on page 13).
Up to 150 Ω: RL ≤ 5 Ω for each lead.
Up to 300 Ω: RL ≤ 10 Ω for each lead.
The terminal points 4.2 and 4.3 are used for measuring dif-
fering resistances.
8.7.1 Thermocouple (TC) with internal cold junction
compensation
8.8
Current output
–
Thermocouple connection: Terminals 4.1 “+“, 4.2 “-“
The current output can be freely configured between 0 and
20 mA. The minimum span is 4 mA. In safety-related appli-
cations (SIL = ON), the output is fixed at 4 ...20 mA.
Use the MACX MCR-EX-CJC cold junction com-
pensation connector provided (Order No.
2925002).
–
Connection: Terminals 3.2 “+“, 3.3 “-“
8.9
Voltage output
TC+CJ: Use the cold junction compensation con-
nector provided at connection terminal blocks
4.1, 4.2 and 4.3.
The voltage output cannot be used for safety-re-
lated applications (SIL = ON).
8.7.2 Thermocouple (TC) with external or without
cold junction compensation
The voltage output can be freely configured between -10
and +10 V. The minimum span is 2 V.
–
Connection: Terminals 3.1 “+“, 3.3 “-“
–
Thermocouple connection: Terminals 5.1 “+“, 5.2 “-“
TC+CJ external: Use the external cold junction
compensation sensor (e.g., PT100) at connection
terminal blocks 4.2 and 4.3.
8.7.3 Voltage input
Connection: Terminals 5.1 “+“, 5.2 “-“
8.7.4 Potentiometer
Connection: Terminals 4.1, 4.2, 4.3
–
–
8.7.5 Resistance thermometer (RTD)
RL ≤ 25 Ω for each lead.
–
–
2-wire connection method: Terminals 4.2, 4.3
The cable resistance can be compensated with the help
of the IFS-CONF PC program, the IFS-OP-UNIT opera-
tor interface or in service mode (DIP switch).
3-wire connection method: Terminals 4.1, 4.2, 4.3
In the case of the 3-wire connection method, ensure
that all three cable resistances are the same.
–
–
4-wire connection method: Terminals 4.2, 4.3, 5.1, 5.2
2 x 2-wire connection method
Terminals RTD 1: 4.2, 4.3
Terminals RTD 2: 5.1, 5.2
104601_en_04
PHOENIX CONTACT 15
MACX MCR-EX-T-UI-UP...
8.10 Switching output
Switching behavior 6
Switching output picks up between
Switching output 1 has one PDT. The behavior of the switch-
ing output can be selected. The switching points SPL1 and
SPH2 can be configured across the entire sensor range:
SPL1 and SPH2.
1
0
SPL
SPH
Switching behavior of the switching output
Switching behavior 0
Switching behavior 7
Switching output is permanently
dropped.
Switching output drops out between
1
SPL1 and SPH2.
1
0
0
SPL
SPH
1
2
SPL = Set Point Low (lower switching point)
SPH = Set Point High (upper switching point)
Switching behavior 1
Switching output is permanently
picked up.
.
1
0
The switching output is not intended for safety-re-
lated applications.
Switching behavior 2
If only the switching output is to be used, the cur-
rent output (connection terminal blocks 3.2 and
3.3) must be short circuited or subjected to a load.
Switching output picks up when SPH2
1
is exceeded.
0
SPH
Switching behavior 3
Switching output drops out when SPH2
is underrange.
1
0
SPH
Switching behavior 4
Switching output picks up when SPL2
is exceeded and drops out when SPH1
0
1
is underrange (hysteresis).
SPL
SPH
Switching behavior 5
Switching output drops out when SPL2
is exceeded and picks up when SPH1
is underrange (hysteresis).
0
1
SPL
SPH
104601_en_04
PHOENIX CONTACT 16
MACX MCR-EX-T-UI-UP...
8.11.2 (Switching behavior (3): Overtemperature limit
8.11 Switching output behavior with manual ac-
knowledgement (latching)
(≥ SPH)
Latching: No automatic restart after exceeding
limit value (SPH: SET Point High) or falling below
limit value (SPL: Set Point Low).
1
0
SPH
Disable the option “Restart after fail safe” in the
configuration software.
Normal operating state < SPH
Step
1
Measure
Measured
value
< SPH and module are acti-
vated
8.11.1 Switching behavior (2): Undertemperature limit
(≤ SPH)
2
3
Relay
Measured
value
ON
≥ SPH
1
0
SPH
4
5
6
Relay
Measured value
Relay
OFF
< SPH
Normal operating state > SPH
Remains OFF (latches) until
delay time has passed and
then acknowledged manu-
ally
Step
1
Measure
Measured
value
> SPH and module are acti-
vated
2
3
Relay
ON
Measured
value
≤ SPH
Acknowledgement is only possible when
there is no critical state anymore and the de-
lay time has passed.
4
5
6
Relay
OFF
Measured value
Relay
> SPH
Critical operating state ≥ SPH
Remains OFF (latches) until
delay time has passed and
then acknowledged manu-
ally
Step
1
Measure
Measured
value
≥ SPH and module are acti-
vated
2
3
Relay
Measured
value
OFF
< SPH
Acknowledgement is only possible when
there is no critical state anymore and the de-
lay time has passed.
4
Relay
Remains OFF (latches) until
delay time has passed and
then acknowledged manu-
ally
Critical operating state ≤ SPH
Step
1
Measure
Measured
value
Relay
Measured
value
≤ SPH and module are acti-
vated
Acknowledgement is only possible when
there is no critical state anymore and the de-
lay time has passed.
2
3
OFF
> SPH
4
Relay
Remains OFF (latches) until
delay time has passed and
then acknowledged manu-
ally
Acknowledgement is only possible when
there is no critical state anymore and the de-
lay time has passed.
104601_en_04
PHOENIX CONTACT 17
MACX MCR-EX-T-UI-UP...
8.11.3 Switching behavior (4): Undertemperature limit
8.11.4 Switching behavior (5): Overtemperature limit
with hysteresis (≤ SPL)
with hysteresis (≥ SPH)
0
1
0
1
SPL
SPH
SPL
SPH
Normal operating state > SPL
Normal operating state < SPH
Step
1
Measure
Measured
value
Step
1
Measure
Measured
value
> SPL and module are acti-
vated
< SPH and module are acti-
vated
2
3
Relay
Measured
value
ON
≤ SPL
2
3
Relay
Measured
value
ON
≥ SPH
4
5
6
Relay
Measured value
Relay
OFF
> SPH
4
5
6
Relay
Measured value
Relay
OFF
< SPL
Remains OFF (latches) until
delay time has passed and
then acknowledged manu-
ally
Remains OFF (latches) until
delay time has passed and
then acknowledged manu-
ally
Acknowledgement is only possible when
there is no critical state anymore and the de-
lay time has passed.
Acknowledgement is only possible when
there is no critical state anymore and the de-
lay time has passed.
Critical operating state ≤ SPL
Critical operating state ≥ SPH
Step
1
Measure
Measured
value
Step
1
Measure
Measured
value
≤ SPL and module are acti-
vated
≥ SPH and module are acti-
vated
2
3
Relay
Measured
value
OFF
> SPH
2
3
Relay
Measured
value
OFF
< SPL
4
Relay
Remains OFF (latches) until
delay time has passed and
then acknowledged manu-
ally
4
Relay
Remains OFF (latches) until
delay time has passed and
then acknowledged manu-
ally
Acknowledgement is only possible when
there is no critical state anymore and the de-
lay time has passed.
Acknowledgement is only possible when
there is no critical state anymore and the de-
lay time has passed.
104601_en_04
PHOENIX CONTACT 18
MACX MCR-EX-T-UI-UP...
8.11.5 Switching behavior (6): Temperature range lim-
8.11.6 Switching behavior (7): Temperature range lim-
it (≤ SPL and ≥ SPH)
it (≥ SPL and ≤ SPH)
1
0
1
0
SPL
SPH
SPL
SPH
Normal operating state > SPL and < SPH
Normal operating state < SPL and > SPH
Step
1
Measure
Measured
value
Step
1
Measure
Measured
value
> SPL and < SPH module
are activated
a) < SPL and module are acti-
vated
2
3
Relay
Measured
value
Relay
Measured value
Relay
ON
b) > SPH and module are acti-
vated
≤ SPL or ≥ SPH
2
3
Relay
Measured
value
Relay
Measured value
Relay
ON
4
5
6
OFF
> SPL or < SPH
Remains OFF (latches) until
delay time has passed and
then acknowledged manu-
ally
a) ≥ SPL and ≤ SPH
b) ≤ SPH and ≥ SPL
OFF
4
5
6
< SPL or > SPH
Remains OFF (latches) until
delay time has passed and
then acknowledged manu-
ally
Acknowledgement is only possible when
there is no critical state anymore and the de-
lay time has passed.
Acknowledgement is only possible when
there is no critical state anymore and the de-
lay time has passed.
Critical operating state ≤ SPL and ≥ SPH
1
Measured
value
a) ≤ SPL and module are acti-
vated
Critical operating state ≥ SPL and ≤ SPH
b) ≥ SPH and module are acti-
Step
1
Measure
Measured
value
vated
≥ SPL and ≤ SPH and mod-
ule are activated
2
3
Relay
Measured
value
OFF
a) > SPL and < SPH
b) < SPH and > SPL
2
3
Relay
Measured
value
OFF
< SPL or > SPH
4
Relay
Remains OFF (latches) until
delay time has passed and
then acknowledged manu-
ally
4
Relay
Remains OFF (latches) until
delay time has passed and
then acknowledged manu-
ally
Acknowledgement is only possible when
there is no critical state anymore and the de-
lay time has passed.
Acknowledgement is only possible when
there is no critical state anymore and the de-
lay time has passed.
104601_en_04
PHOENIX CONTACT 19
MACX MCR-EX-T-UI-UP...
8.13.2 Service mode
8.12 Monitoring function
Service mode can be selected at any time via the
IFS-OP-UNIT operator interface and the configuration soft-
ware, e.g., IFS-CONF or via DIP switch S1.
The temperature transducer is equipped with monitoring
functions for the input and output range.
Input monitoring function
If settings are changed during service mode and service
mode is then exited, the temperature transducer performs a
warm start in order to apply the newly set values. If no
changes are made, the transducer starts up in normal mea-
suring mode without a warm start. The switching output
switches according to its configuration.
The input monitoring function for line break and short circuit
refers to the sensor connected to the input. When an error is
detected, the output signal is set to the configured error
value. In the case of RTD sensors and resistance-type sen-
sors, short-circuit failures are detected resistance values <
1 Ω.
In service mode, it is also possible to simulate the output sig-
nal independently of the input signal (force). In this case, in
safety-related applications the safety function of the device
is deactivated and the initial value for the analog output sig-
nal is 2 mA, which allows subsequent devices to detect the
deviation from normal operation as a result of the measured
value being underrange.
Short circuits of thermocouples and mV sources cannot be
detected, since 0 V can be a valid signal.
On RTD sensors, resistance-type sensors and potentiome-
ters, a line break is detected when the current flow through
the sensor is faulty.
As soon as the fault has been eliminated, the temperature
transducer continues to perform its normal functions. (see
“LED status indicators” on page 22, Line faults)
During service mode, the switching output is deactivated
and remains in its idle position.
Output monitoring function
The current output can be monitored for line breaks and
maximum load. This is activated via the configuration. In
safety-related applications (SIL = ON), the output monitor-
ing is always active. The voltage output is not monitored. As
soon as the fault has been eliminated, the temperature
transducer continues to perform its normal functions. (see
“LED status indicators” on page 22, Line faults)
9
Configuration
WARNING: Explosion hazard
When configuring in zone 2, the PC used must be
approved for use in zone 2.
R
ess
A
V
m
=
=
/
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253
30
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um
10
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8.13 Operating modes
–
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1
A
Out
1
4
2
(30
.
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T
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.
3
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3
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4
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°
6,0
I
3
.
3
1
=
=
4
D
9°
7,
P
C
F
4
m
A
If the configuration is modified using the
IFS-OP-UNIT operator interface and PC-based
software (e.g., IFS-CONF) or via DIP switch, the
changes made must always be checked again
and released before transfer to the temperature
transducer.
11
see
μc
m
manua
W
WA
S3
S
R
l
-P
O
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DO
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5
2
2
3
.
.
4
5
After the transfer, the new data in the temperature
transducer is applied by means of activation and
a warm start.
Figure 7
Position of the DIP switch and buttons
8.13.1 SIL ON/SIL OFF
When a DIP switch from S1-2 ... S1-8 (ON) is
switched on, the device is switched to service
mode. The red ERR LED flashes (1.2 Hz) and a
diagnostic I/O fault is displayed in the start
screen.
The temperature transducer can either be operated in SIL
ON or SIL OFF. The standard configuration is SIL ON with
DIP switch S1 set to the OFF position. With the order config-
uration, customer-specific configurations can be selected in
the order key (see “Order key” on page 6).
104601_en_04
PHOENIX CONTACT 20
MACX MCR-EX-T-UI-UP...
9.1
Delivered state/standard configuration
9.4
Force output
Switch position DIP-S1
When SIL is activated, the analog output starts at
2 mA and the switching output is deactivated.
1
2
3
4
5
6
7
8
OFF OFF OFF OFF OFF OFF OFF OFF
•
•
Set the adjustment by setting DIP switch S1-4 to ON.
Observe the analog output and set with the S2 (de-
scending value) or S3 (ascending value) button.
The specification/simulation is reset and ended by set-
ting DIP switch S1-4 back to OFF.
9.2
Zero adjust, adjustment via buttons S2
and S3 (only possible with SIL OFF)
•
•
•
Set the adjustment by setting DIP switch S1-2 to ON.
Observe the analog output and set it with button S2 (de-
scending value) or S3 (ascending value)
or
Switch position DIP-S1
1
2
3
4
5
6
7
8
OFF OFF OFF ON
OFF OFF OFF OFF
press the buttons S2 and S3 simultaneously time for >
3 seconds to reset the cable compensation.
9.5
•
Cable compensation, 2-wire RTD or RTD 1
with 2 x RTD
Set the cable compensation RTD 1 via DIP switches
S1-1 to OFF and
S1-5 to ON.
Short circuit the sensor.
Apply the current measured value as the cable resis-
tance by pressing the S2 button.
•
Save the set value by setting DIP switch S1-2 back to
OFF.
Switch position DIP-S1
1
2
3
4
5
6
7
8
OFF ON OFF OFF OFF OFF OFF OFF
•
•
9.3
Span adjust, adjustment via buttons 2 and
4 (only possible with SIL OFF)
•
Save the set value by setting DIP switch S1-5 back to
OFF.
•
•
Set the adjustment by setting DIP switch S1-3 to ON.
Observe the analog output and set it with button S2 (de-
scending value) or S3 (ascending value)
or
Pressing buttons S2 and S3 simultaneously for > 3 seconds
resets the cable compensation.
Switch position DIP-S1
press the buttons S2 and S3 simultaneously time for >
3 seconds to reset the cable compensation.
1
2
3
4
5
6
7
8
•
•
Save the set value by setting DIP switch S1-3 back to
OFF.
Pressing buttons S2 and S3 simultaneously for > 3 sec-
onds resets the adjustment.
OFF OFF OFF OFF ON OFF OFF OFF
Switch position DIP-S1
1
2
3
4
5
6
7
8
OFF OFF ON OFF OFF OFF OFF OFF
104601_en_04
PHOENIX CONTACT 21
MACX MCR-EX-T-UI-UP...
9.6
•
Cable compensation RTD 2 with 2 x RTD or
TC with external cold junction compensa-
tion (TC + CJ external)
9.9
LED status indicators
3
.
1
2
.
1
1
.
1
3
.
2
32825
2
.
2
B
1
.
l
2
omberg,
Ex
M
A
C
X
–
Set the cable compensation RTD 2 via DIP switches
S1-1 to ON and
S1-5 to ON.
Short circuit the sensor.
Apply the current measured value as the cable resis-
tance by pressing the S2 button.
T
Germany
em
Supp
Ord
.
–
N
3
M
o
.
perature
3
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.:
2
l
... y
R
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.
–
3
EX
(
–
o
–
1
20% 230
l
.
Atage
T
292
3
T
–
V
10%,
U
I
–
UP
...+
U
P
ransducer
4
:
689
m
=
C
/
253
DC
–
SP
V
50
N
=
Hz/
1,5
I
60
nput
W
/Ex
Hz
)
–
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T
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na
–
em
pe
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ra
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Pot
og
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–
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i
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6
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•
Save the set value by setting DIP switches S1-1 and S1-
5 back to OFF.
4
I-
.
3
D
U
R
.
com
R
E
-
X
-
IN
DO
MCR
C
A
+
M
Pressing buttons S2 and S3 simultaneously for > 3 seconds
resets the cable compensation.
3
.
.
4
5
2
.
2
.
3
4
5
Switch position DIP-S1
1
2
3
4
5
6
7
8
Figure 8
No. LED
LED status indicators
Color Description
ON OFF OFF OFF ON
OFF OFF OFF
9.7
Automatic potentiometer adjustment
(teach-in)
6
PWR Green
ON
Supply voltage
Indicates the readiness for opera-
tion of the temperature trans-
ducer if supply voltage is avail-
able.
The temperature transducer is
configured without device supply
via programming adapter IFS-
USB-PROG-ADAPTER.
•
•
•
•
•
•
Set the teach-in by setting DIP switch S1-6 to ON.
Set potentiometer to start of range.
Press the S2 button.
Set potentiometer to end of range.
Press the S3 button.
Save the new measuring range by setting
DIP switch S1-6 back to OFF.
7
8
DAT
ERR
Green
Red
No function at present
Error
Pressing buttons S2 and S3 simultaneously for > 3 seconds
resets both values.
Switch position DIP-S1
ON
Module error
Flashing Service mode active
(1.2 Hz)
1
2
3
4
5
6
7
8
OFF OFF OFF OFF OFF ON OFF OFF
flashing
(2.4 Hz)
Line fault
9.8
Manual acknowledgement of switching
outputs (latch function)
9
DO
Yellow
ON
Switching output 1
Switching output active
•
•
•
Set manual acknowledgment by setting DIP switch S1-
7 to ON.
Press buttons S2 and S3 simultaneously for > 3 sec-
onds.
Reset DIP switch S1-7 to OFF.
Switch position DIP-S1
1
2
3
4
5
6
7
8
OFF OFF OFF OFF OFF OFF ON OFF
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PHOENIX CONTACT 22
MACX MCR-EX-T-UI-UP...
the various operating functions that can be selected are
shown in the display.
10 Password
The device is protected by means of a four-digit password
set in the factory in order to prevent impermissible changes
to the configuration.
When active, the SIL functionality is displayed in
the start screen.
Default setting: 1111
Example: Display of SIL ON
For safety-related applications, the password set
in the factory must always be changed.
INPUT 1
If the password is lost, it is not possible to reset it.
In this case, please contact Phoenix Contact.
SIL
OK
If, however, only data from the device is to be displayed or
the device is to be used in non-safety-related applications,
the password can be deactivated.
Example: Display of SIL OFF
Setting: 0000
The device can be accessed either via the IFS-OP-UNIT
(Order No.: 2811899) or via a service PC with connected
programming adapter IFS-USB-PROG-ADAPTER (Order
No.: 2811271) and the IFS-CONF configuration software.
INPUT 1
OK
Further information on configuration with the
IFS-OP-UNIT or the IFS-CONF configuration
software can be found in the relevant user manu-
al.
For safety reasons, the SIL function cannot be
switched on again via the IFS-OP-UNIT operator
interface.
WARNING: If Functional Safety is activated by a
reconfiguration or changes are made to the active
Functional Safety configuration, the rules under
Installation and startup must be observed.
SIL can be switched off/deactivated via the SIL
OFF menu item.
To reactivate/switch on the SIL function, PC-
based configuration software, e.g., IFS-CONF is
required.
WARNING: Limitations on safety-related ap-
plications
Only 4 ... 20 mA, limited programming of output
current in the event of line faults
(2 mA ≤ IOut ≤ 3.6 mA or IOut ≥ 21 mA)
If no input is entered for five minutes during con-
figuration, the configuration is ended and any un-
saved data will be lost.
WARNING: Once new configuration data has
been written, the device performs a warm start
that changes the properties of the device. The fol-
lowing control device must be adapted to these
modifications.
NOTE: Transfer and activate the configuration af-
ter the password has been changed.
11 Flow chart, operator interface
Configuration with the IFS-OP-UNIT
If you wish to use the MACX MCR-EX-T-UI-UP in combina-
tion with the IFS-OP-UNIT and with the IFS-OP-CRADLE,
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PHOENIX CONTACT 23
MACX MCR-EX-T-UI-UP...
11.1 Menu structure
Input 1
Input 2
Input Diff
Output
only 2 x RTD2
and differential measurement
only 2 x RTD2
Modul-
information
Diagnostic
OK
OK / ESC
OK / ESC
OK / ESC
OK / ESC
OK / ESC
Settings
Backlight
Language
Configure
Input
Input Conf
CJ on/off
CJ Value
Temp-Unit
Filter
OK / ESC
Output
OK / ESC
Outp. Conf
Check
B/LB
Reset Cor.
Err.handl.
2W-Comp.C1
2W-Comp.C2
OK / ESC
Switch
OK / ESC
Switch 1
On-Delay
Off-Delay
Acknowled.
Linebreak
Shorted
OK / ESC
OK / ESC
OK / ESC
Service
Password
Save Conf
Backup
Restore
Reset SW1
Change PW
SIL OFF
Reset
OK / ESC
OK / ESC
Save
Transfer
Password
Activate
OK / ESC
Restart
Modul
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PHOENIX CONTACT 24
MACX MCR-EX-T-UI-UP...
11.2 Key for start screen
Display of input and output signals, module and diagnostic information.
Display of the actual value of input 1
Input 1
Display of the actual value of input 2, only if a second RTD is configured with the 2-wire connection
method.
Input 2
Input Diff
Output
Display of the actual value of the differential measurement with 2 x RTD with the 2-wire connection
method.
Display of the actual value of the analog output
Modul-
information
Display of module information (order designation, firmware version, config version)
Module diagnostics (simulation, module error, I/O error)
Diagnostic
11.3 Key for SETTINGS - MENU
The active configuration is read out from the module.
Settings
Backlight
Language
Setting for the background illumination (on, off, autodim)
Setting for the menu language (English, German)
11.4 Key for SETTINGS - Configure
Configuration of input, output, fault behavior and switching outputs
Configure
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PHOENIX CONTACT 25
MACX MCR-EX-T-UI-UP...
11.5 Key for SETTINGS - Service
Access to the menu items of the service area
Service
Password
Save Conf
Reset SW1
Change PW
Input of a 4-digit numeric password in order to open the service area
(if the password is 0000, the password prompt is switched off)
Access to the menu items for the backup and restore functionality of the module configuration
Resets switching output 1 when it is snapped on (latching behavior)
Changes the set password
(change only becomes effective when the configuration has been transmitted to the module and acti-
vated)
Changes the setting from SIL ON to SIL OFF.
SIL OFF
NOTE: It is only possible to switch on the SIL function via PC-based configuration software,
e.g., IFS-CONF.
Resets the IFS-OP-UNIT and the connected module.
Reset
Backup
Restore
Saves the active configuration of the connected, compatible module in the IFS-OP-UNIT operator inter-
face (copy function)
Transmits the saved module configuration from the internal memory of the IFS-OP-UNIT operator inter-
face to the connected module (copy function).
Then activate the configuration by selecting Yes in the Activate menu item.
11.6 Key for SETTINGS - Save
Access to the menu items for the transmission and activation of the module configuration
Save
Transmits the configuration from the IFS-OP-UNIT operator interface to the connected module
Transfer
Password
Activate
Input of a 4-digit numeric password in order to transmit the configuration
(if the password is 0000, the password prompt is switched off).
Activation of the module configuration (Yes/No)
Following activation, the module performs a warm start.
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PHOENIX CONTACT 26
MACX MCR-EX-T-UI-UP...
11.7 Key for input
Access to the menu items for the configuration of the input
Input
(see “Key for input configuration (analog input)” on page 27)
11.7.1 Key for input configuration (analog input)
Setting for the dependent parameters of the input mode, sensor type, start and end of range, associated
inputs, switching behavior, switching points
Input Conf
CJ on/off
CJ Value
Temp-Unit
Filter
Cold junction compensation with TC + CJ and TC + CJ ext. (on, off)
Correction of the cold junction value with CJ = On,
specification of the cold junction value with CJ = Off (-20 ... 65 K).
Setting for the temperature unit (°C, °F)
Setting for the filter factor (1 ... 10)
Setting for the cable resistance for RTD 2-wire connection method, channel 1 (0 ... 50 ꢀ).
Setting for the cable resistance for RTD 2-wire connection method, channel 2 (0 ... 50 ꢀ).
2W-Comp.C1
2W-Comp.C2
Configuration selection, input configuration
Input Conf
Input Configuration
ESC
OK
OK
Y
OK
OK
OK
ESC
OK
Varialble RTD
Base
Input Conf
Sensortype
RTD Base
RStart IN1
REnd IN1
N
Mode= 2x RTD2
OK
OK
OK
Y
OK
OK
Difference
RStart IN2
REnd IN2
Difference
Diff RStart
Diff REnd
N
Mode= TC + CJ extern
OK
Y
OK
OK
OK
OK
OK
OK
Varialble RTD
Base
CJ Sensor
CJ RTDBase
Con. IN AO
Con. IN SW1
Mode SW1
SPL SW1
SPH SW1
N
Input Conf
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PHOENIX CONTACT 27
MACX MCR-EX-T-UI-UP...
Setting for the sensor mode
Input Conf
Sensortype
RTD Base
RStart IN1
REnd IN1
RStart IN2
REnd IN2
Difference
(RTD4, RTD3, RTD2, 2 x RTD2, TC + CJ, TC + CJ ext., potentiometer, mV).
Setting for the sensor type depending on sensor mode
(Pt, Ni, CU, KTY..., USER, for more see “Order key” on page 6).
RTD basic resistance for sensor types with a variable basic resistance
(e.g., when 100 is selected, the basic resistance is 100 ꢀ)
Start of range for input 1 depending on sensor type, e.g., -50°C (°C, °F, ꢀ, %, mV).
End of range for input 1 depending on sensor type, e.g., 150°C (°C, °F, ꢀ, %, mV)
Start of range for input 2 depending on sensor type and only for 2 x RTD with 2-wire connection method,
e.g., -50°C (°C, °F, ꢀ).
End of range for input 2 depending on sensor type and only for 2 x RTD with 2-wire connection method,
e.g., 150°C (°C, °F, ꢀ)
Setting for the differential measurement only for 2 x RTD with 2-wire connection method and not resis-
tance
(off, differential, absolute value differential)
Start of range for differential, only with differential and absolute value differential (°C, °F)
End of range for differential, only with differential and absolute value differential (°C, °F)
Sensor type of the cold junction, only with TC + CJ ext.
Diff RStart
Diff REnd
CJ Sensor
CJ RTDBase
Con. IN AO
Con. IN SW1
Mode SW1
SPL SW1
RTD basic resistance of the cold junction, only with TC + CJ ext.
Associated input of the analog output (input 1, input 2, differential), appears only in sensor mode 2 x RTD2
(2 x RTD 2-wire connection method)
Associated input of the switching output (input 1, input 2, differential), appears only in sensor mode 2 x
RTD2 (2 x RTD 2-wire connection method)
Mode of switching output (0 ... 7)
(see “Switching output” on page 16)
Setpoint low of switching output (appears only if mode > 3)
(see “Switching output” on page 16).
Setpoint high of switching output (appears only if mode > 1)
(see “Switching output” on page 16)
SPH SW1
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PHOENIX CONTACT 28
MACX MCR-EX-T-UI-UP...
11.8 Key for output
Access to the menu items for the configuration of the output
Output
(see “Key for output configuration (analog output)” on page 29)
11.8.1 Key for output configuration (analog output)
Setting for the dependent parameters of the analog output – mode, start and end of range, display of cor-
rection values, fault behavior (OR, UR, LB, KS)
Outp. Conf
Check
B/LB
Monitoring of output load/short circuit (Yes/No), only configurable with SIL = OFF
Resets the correction values of the output
Reset Cor.
Configuration selection, output configuration
Outp. Conf
Output Configuration
OK / ESC
OK
OK
OK
OK
Outp. Conf
RangeStart
RangeEnd
Corr. Start
Corr. End
ESC
OK
OK
OK
OK
Outp. Conf
Overrange
Underrange
Linebreak
Shorted
Start of range for output – setting only possible with SIL = OFF, 4 mA (0 ... 20 mA, -10 ... 10 V)
End of range for output – setting only possible with SIL = OFF, 20 mA (0 ... 20 mA, -10 ... 10 V)
Display of the start correction value for the analog output (mA, V)
RangeStart
RangeEnd
Corr.Start
Corr.End
Display of the end correction value for the analog output (mA, V)
Analog output value when overrange NE43 Upsc. / NE43 Downsc.
Overrange
Underrange
Linebreak
Shorted
(Configurable for fault behavior = freely definable)
Analog output value for underrange NE43 Upsc. / NE43 Downsc.
(Configurable for fault behavior = freely definable)
Analog output value in the event of line break NE43 Upsc. / NE43 Downsc.
(Configurable for fault behavior = freely definable)
Analog output value in the event of a short circuit on the line NE43 Upsc. / NE43 Downsc.
(Configurable for fault behavior = freely definable)
104601_en_04
PHOENIX CONTACT 29
MACX MCR-EX-T-UI-UP...
11.9 Key for error handling
Setting for the fault behavior (NE43 increasing, NE43 decreasing, freely definable)
Err.handl.
11.10 Key for switch
Access to the menu items for setting the switching output
Switch
Access to the menu items for setting the switching output
Setting for the switch-on delay for the switching output (0 ... 10 s)
Setting for the off delay for the switching output (0 ... 10 s)
Manually acknowledge switching output (latching) (Yes/No)
Switch 1
On-Delay
Off-Delay
Acknowled.
Linebreak
Shorted
Behavior for switching output in the event of an error - line break (on, off, no response)
Behavior for switching output in the event of an error - short circuit (on, off, no response).
12 IFS-OP-UNIT operator interface
error codes
The following error codes are shown directly in the display
of the IFS-OP-UNIT operator interface when they occur.
Error code
Description
Error 0
Copy error
Module type in the IFS-OP-UNIT is differ-
ent from the connected module.
Error 1,2,3
Checksum error
Please contact Phoenix Contact.
104601_en_04
PHOENIX CONTACT 30
MACX MCR-EX-T-UI-UP...
13.2 Configuring the user characteristic curve
13 Configuration with the service PC
Freely configurable user characteristic curve for
individual adaptation of resistance temperature
detectors (RTD) and thermocouples (TC).
When making changes to the configuration data, use the
IFS-CONF software
(free download: www.phoenixcontact.net/catalog).
The user characteristic curve is created with the PC-based
IFS-CONF software and stored in the temperature trans-
ducer.
Information on configuration, parameterization
and service options (e.g., online monitoring) and
their execution can be found in the online help of
the software and in the associated user manuals
of the DTMs (Device Type Manager).
The user characteristic curve is either selected
with the IFS-CONF or with the IFS-OP-UNIT soft-
ware.
•
Connect the device and PC with the help of the IFS-
USB-PROG-ADAPTER programming adapter (Order
No. 2811271).
14 Comparison of safety data
3
.
1
2
.
1
1
.
1
WARNING: Explosion hazard
3
3
.
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Compare the safety data before connecting a de-
vice located in the intrinsically safe area to the
MACX MCR-EX-T-UI-UP....
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ransducer
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Field devices:
Temperature transducers:
Ui, Ii, Pi, Li, Ci
Uo, o, Po, Lo, Co
A
11
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The values for Uo, Io, Po, Lo and Co can be found under
“Safety data according to ATEX for intrinsically safe circuits”
on page 8.
-
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Requirements for intrinsic safety (simple circuits):
Ui ≥ Uo
Ii ≥ Io
Figure 9
IFS-USB-PROG-ADAPTER
Changes to the configuration and parameterization data can
be made during operation with a connected Ex measuring
circuit as well as in a disconnected state.
Pi ≥ Po
Li + Lc ≤ Lo
Ci + Cc ≤ Co
(Lc and Cc depend on the cables/lines used).
13.1 System requirements
–
IBM PC or compatible computer with 400 MHz or higher
with at least 256 Mbyte RAM
–
–
–
–
At least 15 Mbyte available hard disk space
Free USB interface, at least USB 1.1.
Screen resolution of 1024 x 768 pixels
Windows 2000 SP4, Windows XP SP2
The drivers for the IFS-USB-PROG-ADAPTER
USB programming adapter are installed automat-
ically.
104601_en_04
PHOENIX CONTACT 31
MACX MCR-EX-T-UI-UP...
Connection example 3:
15 Application examples
15.1 Current output
Input:
Thermocouple with external or without in-
ternal cold junction compensation or volt-
age input
Connection example 1:
Output:
Current output (4 ... 20 mA) on passive safe
controller
Input:
4-wire RTD
Output:
Current output (4 ... 20 mA) on passive safe
controller
OUT
IN
Sensor / Field
PLC / DCS
4.3
GND 3.3
OUT 3.2
OUT
IN
I
4.2
4.1
Sensor / Field
PLC / DCS
UOUT 3.1
4.3
GND 3.3
OUT 3.2
2.3
2.2
2.1
ϑ
I
4.2
4.1
UOUT 3.1
2.3
2.2
2.1
5.3
5.2
5.1
NC 1.3
TC
-
1.2
Power
24V ...230V AC/DC
=
mV
+
1.1
5.3
5.2
5.1
NC 1.3
1.2
Zone 0,1,2
Power
24V ...230V AC/DC
1.1
Zone 20,21,22
Zone 0,1,2
15.2 Voltage output
Connection example:
Zone 20,21,22
Connection example 2:
Input:
Potentiometer
Input:
Thermocouple with internal cold junction
compensation
Output:
Voltage output (-10 ... 10 V) on passive
controller
Use the MACX MCR-EX-CJC cold junction
compensation connector provided (Order No.
2925002).
OUT
IN
Sensor / Field
PLC / DCS
Poti
4.3
GND 3.3
OUT 3.2
Output:
Current output (4 ... 20 mA) on passive safe
controller
I
4.2
4.1
U OUT 3.1
2.3
2.2
2.1
OUT
IN
Sensor / Field
PLC / DCS
5.3
5.2
5.1
NC 1.3
1.2
4.3
GND 3.3
TC
-
Power
24V ...230V AC/DC
I
OUT 3.2
OUT 3.1
4.2
4.1
1.1
+
U
2.3
2.2
2.1
Zone 0,1,2
Zone 20,21,22
5.3
5.2
5.1
NC 1.3
1.2
Power
24V ...230V AC/DC
1.1
Zone 0,1,2
Zone 20,21,22
104601_en_04
PHOENIX CONTACT 32
MACX MCR-EX-T-UI-UP...
15.3 Switching output
Connection example:
Input:
3-wire RTD
Output:
Voltage output (-10 ... 10 V) on passive
controller
Switching
output:
Dependent on selected switching behavior
OUT
IN
Sensor / Field
PLC / DCS
4.3
GND 3.3
I
OUT 3.2
OUT 3.1
4.2
4.1
ϑ
2.3
2.2
2.1
DI
24 V
5.3
5.2
5.1
NC 1.3
1.2
Power
24V ...230V AC/DC
1.1
Zone 0,1,2
Zone 20,21,22
104601_en_04
PHOENIX CONTACT 33
Appendix - Safety-related applications (SIL 2)
Appendix
A1 Safety-related applications (SIL 2)
Valid hardware and firmware versions
NOTE: Only those devices with SIL designa-
tion and device firmware with revision 0.92 or
higher are certified for SIL 2.
NOTE: The evaluation unit following the measur-
ing transducer (e.g., safety-related PLC) must
recognize these states and correspondingly con-
trol the actuator as the final link in the safety chain.
SIL regulations apply to the following modules:
With the REL versions, an additional signal is generated,
which is compared with up to two specified switching thresh-
olds. When the first threshold is reached, the safety relay is
switched on without confirmation contact and when the sec-
ond threshold is reached, it is switched off. Depending on
the application, the safety for the switching output is imple-
mented by either the series or parallel connection of relays
2 and 3, a fuse connected in series, and by monitoring the
calculated switching value. In the event of deviations of
more than 5%, the device switches to the safe state. The
safe state in this case is an uncontrolled relay.
The hardware is also continuously monitored. If an internal
failure is detected, the measuring transducer also switches
to the safe state (current output < 3.6 mA or > 21 mA or un-
controlled relay).
The transition to the safe state always takes place within the
internal failure detection time of 50 s.
The measuring transducer is released (restarted) by switch-
ing off the supply voltage and switching it back on again, by
resetting the transducer via the serial interface, or by activat-
ing the “Restart” option during configuration. The integrated
startup tests are then performed. If the error is still present,
it will be detected during these tests. If it is still present, the
measuring transducer switches back to the safe state.
Designation
Standard configuration
MACX MCR-T-UI-UP
Order No.
28 11 394
28 11 860
28 11 378
28 11 828
28 65 654
29 24 689
28 65 751
29 24 799
MACX MCR-T-UI-UP-SP
MACX MCR-T-UIREL-UP
MACX MCR-T-UIREL-UP-SP
MACX MCR-EX-T-UI-UP
MACX MCR-EX-T-UI-UP-SP
MACX MCR-EX-T-UIREL-UP
MACX MCR-EX-T-UIREL-UP-SP
Order configuration
MACX MCR-T-UI-UP-C
28 11 873
28 11 970
28 11 514
28 11 831
28 11 763
29 24 692
28 65 722
29 24 809
MACX MCR-T-UI-UP-SP-C
MACX MCR-T-UIREL-UP-C
MACX MCR-T-UIREL-UP-SP-C
MACX MCR-EX-T-UI-UP-C
MACX MCR-EX-T-UI-UP-SP-C
MACX MCR-EX-T-UIREL-UP-C
MACX MCR-EX-T-UIREL-UP-SP-C
The safety-related temperature transducers listed above
from the MACX MCR(-EX)-T-... series have been evaluated
by exida Certification S.A. via a Full Assessment in accor-
dance with IEC 61508 Ed.1.0 to SIL 2.
Certificate number: Phoenix Contact 100134C P0019
C001.
In addition to the safety functions, there are also monitoring
functions for the input and the current output.
Evaluation
Failures which are detected in the measuring transducer
and to which the transducer responds by switching to the
safe state are safe failures (λs).
A1.1 Safety function and safety requirements
The safety-related measuring transducers are used for the
acquisition of a sensor signal (RTD, TC sensors, resistance-
type sensors, mV sources), that is converted into a scaled
signal and from which a standardized “life zero” current sig-
nal is generated. The entire conversion is continuously mon-
itored to a maximum transmission error of 5%. In the event
of greater deviations, the device switches to the safe state.
The safe state is an output signal of either < 3.6 mA or > 21
mA.
Failures where the measuring transducer does not follow a
change of input signal or generates an output signal that de-
viates from the intended value by more than ±5%, are eval-
uated as dangerous failures (λd).
Both safe (λs) and dangerous (λd) failures can be detected
by diagnostic measures. Detected dangerous failures (λdd)
are handled in the same way as safe failures.
The monitoring functions refer to events whose cause is
detected and reported outside of the device.
en Version 04
PHOENIX CONTACT A-1
Appendix - Safety-related applications (SIL 2)
Summary:
A1.2.1 Failure rates: MACX MCR(-EX)-T-UIREL-UP
(-SP)(-C)
Safety/monitor- Output sig- Safe
ing function
Reason
nal range state
Input:
RTD 3-wire connection method
Safety function
4 ... 20 mA < 3.6 mA; Deviation
Output:
Switching output 2 and 3 (redundant)
or
> 5%
–
–
–
–
Type B device (according to EN 61508-2)
Safety Integrity Level (SIL) 2
HFT = 0
> 21 mA
Relay is
not con-
trolled
1oo1d architecture
Input
monitoring
4 ... 20 mA 2 - 3.6
Line fault input
λSD
0
λSU
λDD
λDU
SFF
94%
DCD
mA; >
2.34 *
5.43*
0.43 *
21 mA
10-7
10-7
10-7
92 %
Output monitoring 4 ... 20 mA = 0 mA
Line fault out-
put
0 FIT
234 FIT 543 FIT 43 FIT
The total failure rate is: 1.34 * 10-6
Together with the actual signal transmission, continuous
checks and diagnostic functions are performed in the mea-
suring transducers in order to detect faulty behavior.
The MTBF (Mean Time Between Failures) is therefore
85 years.
The probability of a dangerous failure per hour for “continu-
ous demand” mode and the average probability of failure of
the specified function for “low demand” mode are deter-
mined from the error rate:
The internal failure monitoring time (diagnostics test in-
terval) is the time taken to carry out and repeat these tests in
full. Random hardware faults are detected during this time.
PFDavg values
The internal failure monitoring time is 50 seconds.
T[PROOF] =
PFDavg
1 year
2 years
5 years
A1.2 Safety integrity requirements
=
2.88 * 10-4
4.67 * 10-4
1.01 * 10-3
PFH* = 4.3 * 10-8/h
The calculation is performed assuming a checking interval
(TPROOF) of 1 year and a repair time (MTTR) of 24 hours, a
test coverage (CPT) of 95% and a life time (LT) of 10 years.
On the basis of the value determined for the average proba-
bility of failure PFDavg, the checking interval can be in-
creased to up to 5 years.
As a result of the multiple connection options,
only two device types are considered in the con-
figurations for “RTD 3-wire” or “mV” in the follow-
ing. They represent all configurations with a
variable resistance at the input terminals or volt-
age or thermocouple inputs and always indicate
the most conservative case. The two device types
are:
1. MACX MCR(-EX)-T-UI-UP(-SP)(-C)
The values are valid under the following conditions:
2. MACX MCR(-EX)-T-UIREL-UP(-SP)(-C)
–
The failure rates of the components used remain con-
stant throughout the period of use.
FIT (Failure In Time)
1 FIT is 1 failure in 109 hours
–
The propagation of failures by the device in the system
is not taken into consideration.
–
–
The repair time (replacement) is 24 hours.
The failure rates of the external power supply unit are
not taken into consideration.
–
–
The average temperature at which the device is to be
used is 40°C. In this case, normal industrial conditions
are assumed.
The specified failure rates are based on an average am-
bient temperature of 40°C. For an average ambient
temperature of 60°C, the failure rates must be multiplied
by factor 2.5. Factor 2.5 is based on guide values.
en Version 04
PHOENIX CONTACT A-2
Appendix - Safety-related applications (SIL 2)
1.2.2 Failure rates: MACX MCR(-EX)-T-UIREL-UP
(-SP)(-C)
–
–
The average temperature at which the device is to be
used is 40°C. In this case, normal industrial conditions
are assumed.
The specified failure rates are based on an average am-
bient temperature of 40°C. For an average ambient
temperature of 60°C, the failure rates must be multiplied
by factor 2.5. Factor 2.5 is based on guide values.
Input:
Voltage input mV
Output:
Switching output 2 and 3 (redundant)
–
–
–
–
Type B device (according to EN 61508-2)
Safety Integrity Level (SIL) 2
HFT = 0
1.2.3 Failure rates: MACX MCR(-EX)-T-UI-UP(-SP)
(-C)
1oo1d architecture
λSD
0
λSU
λDD
λDU
SFF
93%
DCD
90%
Input:
Output:
RTD 3-wire connection method
4 ... 20 mA (current output)
2.38 *
5.22*
0.56 *
10-7
10-7
10-7
–
–
–
–
Type B device (according to EN 61508-2)
Safety Integrity Level (SIL) 2
HFT = 0
0 FIT
238 FIT 522 FIT 56 FIT
The total failure rate is: 1.34 * 10-6
The MTBF (Mean Time Between Failures) is therefore
85 years.
The probability of a dangerous failure per hour for “continu-
ous demand” mode and the average probability of failure of
the specified function for “low demand” mode are deter-
mined from the error rate:
1oo1d architecture
λSD
0
λSU
0
λDD
λDU
SFF
94%
DCD
94%
8.05*
0.43 *
10-7
10-7
0 FIT
0 FIT
805 FIT 43 FIT
The total failure rate is: 1.18 * 10-6
PFDavg values
The MTBF (Mean Time Between Failures) is therefore
97 years.
The probability of a dangerous failure per hour for “continu-
ous demand” mode and the average probability of failure of
the specified function for “low demand” mode are deter-
mined from the error rate:
T[PROOF] =
PFDavg
PFH* = 5.6 * 10-8/h
The calculation is performed assuming a checking interval
(TPROOF) of 1 year and a repair time (MTTR) of 24 hours, a
test coverage (CPT) of 95% and a life time (LT) of 10 years.
On the basis of the value determined for the average proba-
bility of failure PFDavg, the checking interval can be in-
creased to up to 5 yearsif the percentage of the device for
the entire loop is assumed at 10%.
1 year
2 years
5 years
=
3.67 * 10-4
5.99 * 10-4
1.30 * 10-3
PFDavg values
T[PROOF] =
PFDavg
1 year
2 years
5 years
=
2.95 * 10-4
4.76 * 10-4
1.02 * 10-3
PFH* = 4.3 * 10-8/h
The calculation is performed assuming a checking interval
(TPROOF) of 1 year and a repair time (MTTR) of 24 hours, a
test coverage (CPT) of 95% and a life time (LT) of 10 years.
On the basis of the value determined for the average proba-
bility of failure PFDavg, the checking interval can be in-
creased to up to 5 years.
The values are valid under the following conditions:
–
The failure rates of the components used remain con-
stant throughout the period of use.
–
The propagation of failures by the device in the system
is not taken into consideration.
–
–
The repair time (replacement) is eight hours.
The failure rates of the external power supply unit are
not taken into consideration.
The values are valid under the following conditions:
–
The failure rates of the components used remain con-
stant throughout the period of use.
–
The propagation of failures by the device in the system
is not taken into consideration.
en Version 04
PHOENIX CONTACT A-3
Appendix - Safety-related applications (SIL 2)
–
–
The repair time (replacement) is eight hours.
The failure rates of the external power supply unit are
not taken into consideration.
The average temperature at which the device is to be
used is 40°C. In this case, normal industrial conditions
are assumed.
The specified failure rates are based on an average am-
bient temperature of 40°C. For an average ambient
temperature of 60°C, the failure rates must be multiplied
by factor 2.5. Factor 2.5 is based on guide values.
The values are valid under the following conditions:
–
The failure rates of the components used remain con-
stant throughout the period of use.
–
–
–
The propagation of failures by the device in the system
is not taken into consideration.
–
–
The repair time (replacement) is eight hours.
The failure rates of the external power supply unit are
not taken into consideration.
–
–
The average temperature at which the device is to be
used is 40°C. In this case, normal industrial conditions
are assumed.
The specified failure rates are based on an average am-
bient temperature of 40°C. For an average ambient
temperature of 60°C, the failure rates must be multiplied
by factor 2.5. Factor 2.5 is based on guide values.
1.2.4 Failure rates: MACX MCR(-EX)-T-UI-UP(-SP)
(-C)
Input:
Output:
Voltage input mV
4 ... 20 mA (current output)
–
–
–
–
Type B device (according to EN 61508-2)
Safety Integrity Level (SIL) 2
HFT = 0
A1.3 Configuring an SIL device
The measuring transducer can be ordered with a standard
configuration (see 1.) or configured for safety-related appli-
cations (see 2.), or can be configured by users themselves
for safety-related applications (see 3.).
1. The measuring transducers are delivered with a stan-
dard configuration for safety-related applications with a
4 - 20 mA output (see order key).
2. Customer-specific pre-configured devices (-C) can be
delivered for both safety-related applications and “nor-
mal” usage. Configuration data is shown on a label.
3. The measuring transducers can also be configured by
users for both safety-related applications and “normal”
usage.
1oo1d architecture
λSD
0
λSU
0
λDD
λDU
SFF
93%
DCD
93%
7.89*
0.56 *
10-7
10-7
0 FIT
0 FIT
789 FIT 56 FIT
The total failure rate is: 1.19 * 10-6
The MTBF (Mean Time Between Failures) is therefore
96 years.
The probability of a dangerous failure per hour for “continu-
ous demand” mode and the average probability of failure of
the specified function for “low demand” mode are deter-
mined from the error rate:
The configuration can be read out and changed at any time
for all devices.
PFDavg values
For safety-related applications, the password set
in the factory must always be changed.
If the password is lost, it is not possible to change
the configuration.
T[PROOF] =
PFDavg
PFH* = 5.6 * 10-8/h
1 year
2 years
5 years
=
3.75 * 10-4
6.08 * 10-4
1.31 * 10-3
In this case, please contact Phoenix Contact.
The calculation is performed assuming a checking interval
(TPROOF) of 1 year and a repair time (MTTR) of 24 hours, a
test coverage (CPT) of 95% and a life time (LT) of 10 years.
On the basis of the value determined for the average proba-
bility of failure PFDavg, the checking interval can be in-
creased to up to 5 years.
en Version 04
PHOENIX CONTACT A-4
Appendix - Safety-related applications (SIL 2)
Configuring safety-related applications
A1.4 Installation and startup
During installation, always observe the package slips
•
Connect the device and PC with the help of the IFS-
USB-PROG-ADAPTER programming adapter (Order
No. 2811271).
Designation
MNR No.
9055145
9055147
9055146
9055148
PACKB.MACX MCR-T-UI-UP...
PACKB.MACX MCR-EX-T-UI-UP...
PACKB.MACX MCR-T-UIREL-UP...
PACKB.MACX MCR-EX-T-UIREL-UP...
•
Load the IFS-CONF configuration software (free down-
load at:
www.phoenixcontact.net/catalog).
Further information on the FDT frame application (IFS-
CONF) and the device drivers (DTM) can be found in
the IFS-CONF user manual.
The package slip is supplied with the device. It can also be
downloaded at: www.phoenixcontact.net/catalog.
Lockable housing with IP54 protection is recommended for
the installation of the measuring transducer.
•
•
Read out the active configuration.
Enter the password in the IFS-CONF in the “PIN” hard-
ware configuration (set to 1111 in the factory).
•
•
•
•
Check that the configuration of the measuring transduc-
er is correct for the intended application.
Connect the measuring transducer according to the in-
stallation instructions.
Make sure that the connected sensor corresponds to
the configuration.
Check the functionality of the measuring transducer
with connected sensor for correct function.
A calibrated sensor simulator (RTD/TC) and a calibrat-
ed digital multimeter are necessary for checking the
measuring transducer.
•
Activate/deactivate SIL.
In the case of “SIL ON”, it is also possible to deactivate the
“Restart after failsafe” item here.
This means that in the event of a failure, the measuring
transducer enters the failsafe state according to the safety
functions, but is not restarted.
•
Write the modified configuration data to the measuring
transducer.
•
Check that the new configuration data in the control
window is correct and confirm with “OK” or “Cancel” if
not correct.
•
Start up the loop and check that it operates correctly.
A1.5 Notes on operation
NOTE: Installation, operation, and maintenance
may only be carried out by qualified specialist per-
sonnel.
Only the green LED (PWR) is on during normal operation.
If a malfunction occurs during operation and the red LED
(ERR) flashes, there is a line fault. The output current of the
measuring transducer is between 2 … 3.6 mA or is higher
than 21.0 mA (in the case of faults in the sensor circuit) or is
0 mA (in the case of a line break in the output circuit).
Check all signal lines. The device will automatically switch
back to normal operation after the fault has been eliminated.
If a fault occurs during operation and the red LED (ERR) is
permanently on, the device has switched to the “safe state”
(output current is less than 2 mA).
WARNING: If Functional Safety is activated by a
reconfiguration or changes are made to the active
Functional Safety configuration, the rules under
“Installation and startup” must be observed.
WARNING: Limitations on safety-related ap-
plications
Only 4 ... 20 mA, limited programming of output
current in the event of line faults
(2 mA ≤ IOut ≤ 3.6 mA or IOut ≥ 21 mA)
Restart the device in order to return it to normal operation.
•
If no PC/laptop has been connected, you can also inter-
rupt the power supply.
WARNING: Once new configuration data has
been written, the device performs a warm start
that changes the properties of the device. The fol-
lowing control device must be adapted to these
modifications.
•
Or you can carry out a warm start with the help of the
configuration software (Service > Reset).
The measuring transducer should then return to normal op-
eration. If it does not, the measuring transducer must be re-
placed.
WARNING: The device must be write-protected
to prevent improper use. Write protection is cre-
ated by assigning a password.
en Version 04
PHOENIX CONTACT A-5
Appendix - Safety-related applications (SIL 2)
A1.6 Recurring checks (SIL 2)
Phoenix Contact GmbH & Co KG
Abteilung Service und Reparatur
Flachsmarktstr. 8
The function of the entire safety loop must be checked reg-
ularly according to EN 61508 and EN 61511. The intervals
for checking are specified by the intervals of each individual
device within the safety loop.
D-32825 Blomberg
GERMANY
It is the operator's responsibility to select the type of checks
and the checking intervals in the specified time period.
The measuring transducers must be checked at least every
7 years (maximum proof test interval).
Checking must be carried out in such a way that the correct
function of the safety equipment in conjunction with all com-
ponents can be verified.
A1.8 Standards (SIL 2)
The measuring transducers are developed and tested ac-
cording to the following standards:
EN 61508:
2001
Functional safety of electrical/electronic/
programmable electronic safety-related
systems
EN 61326-1:
2006
Electrical equipment for measurement,
control and laboratory use – EMC re-
quirements
Possible procedure for recurring checks for discover-
ing dangerous and undetected device failures.
IEC 61326-3-2: Electrical equipment for measurement,
A calibrated sensor simulator (RTD/TC) and a calibrated
digital multimeter are necessary for checking the measuring
transducer.
2006
control and laboratory use – EMC re-
quirements – Part 3-2: Immunity require-
ments for safety-related systems and for
equipment intended to perform safety-
related functions (functional safety) – In-
dustrial applications with specified elec-
tromagnetic environment
•
Connect the sensor simulator to the input of the mea-
suring transducer using the appropriate connection
method.
•
Connect the digital multimeter to the output in current
measuring mode (20 mA range).
The measuring range limits and intermediate values are
specified with the sensor simulator.
The corresponding output values of the measuring trans-
ducer must be checked on the digital multimeter.
Line faults (break and short circuit) are to be simulated on
the input terminals; the configured residual currents are to
be determined on the output.
If the function test result is negative, the measuring trans-
ducer must be taken out of operation and the process put
into a safe state by other measures.
A1.7 Repair
The devices have a long service life, are protected against
malfunctions, and are maintenance-free. However, if a de-
vice should fail, send it back to Phoenix Contact immedi-
ately. The type of malfunction and possible cause must also
be stated.
Please use the original packaging or other suitable safe
packaging when sending devices back for repairs or recali-
bration.
en Version 04
PHOENIX CONTACT A-6
Appendix - Safety-related applications (SIL 2)
A1.9 Abbreviations
Abbreviation
Meaning
DCD
Diagnostic Cov- Diagnostic coverage:
erage of Dan-
DCD = λDD/(λDU + λDD)
gerous Failures
HFT
Hardware Fault Hardware Fault Tolerance:
Tolerance
Ability of a function unit to con-
tinue with the execution of a de-
manded function despite exist-
ing failures or deviations
λD
Rate of Danger- Proportion of dangerous fail-
ous Failures ures per hour
λDD
Rate of Danger- Proportion of detected danger-
ous Detected
ous failures per hour
Failures
λDU
Rate of Danger- Proportion of undetected dan-
ousUndetected gerous failures per hour
Failures
λS
Rate of Safe
Failures
Proportion of safe failures per
hour
MTBF Mean Time
Between
Mean time between consecu-
tive failures
Failures
PFDavg Average
Probability of
Failure on
Average probability of failure on
demand of a safety function
Demand
PFH
SFF
Probability of a Probability of failure per hour
Dangerous
for the safety function
Failure per Hour
Safe Failure
Fraction
Proportion of safe failures: Pro-
portion of failures without the
potential to set the safety-re-
lated system to a dangerous or
impermissible function state
SIL
Safety Integrity International standard IEC
Level
61508 defines four discrete
safety integrity levels (SIL 1 to
4). Each level corresponds to a
probability range for the failure
of a safety function. The higher
the safety integrity level of
safety-related systems, the
lower the probability that the
demanded safety functions will
not be performed.
PHOENIX CONTACT GmbH & Co. KG • 32823 Blomberg • Germany
www.phoenixcontact.com
en Version 04
A-7
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