EMpro - multifunctional energy measuring
devices for DIN rail mounting
User manual
�User manual
EMpro - multifunctional energy measuring devices for DIN rail
mounting
2020-03-05
UM EN EMpro DIN rail, Revision 00
This user manual is valid for:
Order No.
2907983
2908307
2907980
2907985
2907954
2907955
2907984
2908308
2907971
2907976
109357_en_00
Designation
EEM-MA370
EEM-MA371
EEM-MA370-R
EEM-MA371-R
EEM-MB370
EEM-MB371
EEM-MB370-PN
EEM-MB371-PN
EEM-MB370-EIP
EEM-MB371-EIP
PHOENIX CONTACT GmbH & Co. KG • Flachsmarktstraße 8 • 32825 Blomberg • Germany
phoenixcontact.com
�Table of contents
Table of contents
1
2
For your safety ...........................................................................................................................7
1.1
Identification of warning notes ...............................................................................7
1.2
Qualification of users .............................................................................................7
1.3
Field of application of the product ..........................................................................8
1.3.1
Intended use ..........................................................................................8
1.3.2
Product changes ....................................................................................8
1.4
Safety notes...........................................................................................................8
Device description .....................................................................................................................9
2.1
3
4
5
Product overview .................................................................................................13
Mounting and installation .........................................................................................................15
3.1
Mounting..............................................................................................................15
3.2
Installation ...........................................................................................................16
3.2.1
Pin assignment ....................................................................................17
3.2.2
Supply ..................................................................................................19
3.2.3
Grid types .............................................................................................20
Operating and indication elements ...........................................................................................25
4.1
Energy measuring device with display.................................................................25
4.2
Energy measuring device without display ............................................................25
4.3
Energy measuring device without display, with additional PROFINET interface .................................................................................................................26
4.4
Energy measuring device without display, with additional Ethernet/IP interface .................................................................................................................27
4.5
Technical data of the display ...............................................................................28
4.6
Displaying the events...........................................................................................29
4.7
Operating elements on the display (softkeys) ......................................................30
Basic device configuration .......................................................................................................31
5.1
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Basic device configuration via the display ...........................................................31
5.1.1
Step 1: Language selection ..................................................................31
5.1.2
Step 2: Network settings ......................................................................32
5.1.3
Step 3: IPv4 ..........................................................................................32
5.1.4
Step 4: Grid type ..................................................................................33
5.1.5
Step 5a: Current input (energy measuring device with current
transformer) .........................................................................................34
5.1.6
Step 5b: Current input (energy measuring device with Rogowski coil) ...................................................................................................35
5.1.7
Step 6: Voltage input ............................................................................35
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�EMpro - multifunctional energy measuring devices for DIN rail mounting
5.1.8
5.1.9
5.1.10
5.2
6
7
8
Step 7: Configuration overview ............................................................36
Step 8: Setting a personal PIN .............................................................36
Step 9: Activating the PIN ....................................................................36
Basic device configuration via the web server .....................................................37
5.2.1
Step 1: Network settings ......................................................................38
5.2.2
Step 2: Selecting the grid type .............................................................39
5.2.3
Step 3: Configuration of the current input (current transformer) ...........40
5.2.4
Step 3: Configuration of the current input (Rogowski coil) ....................41
5.2.5
Step 4: Voltage input ............................................................................43
5.2.6
Optional: Voltage transducer ................................................................44
5.2.7
Step 5: Configuration overview ............................................................45
Navigation structure and display ..............................................................................................47
6.1
Menu structure on the display..............................................................................47
6.2
Menu structure on the web server........................................................................48
Device settings and information ...............................................................................................51
7.1
Selecting the language ........................................................................................51
7.2
Date and time ......................................................................................................52
7.2.1
Reading the date and time ...................................................................52
7.2.2
Setting the date and time manually ......................................................53
7.2.3
Synchronizing the date and time with an SNTP server .........................54
7.2.4
Time zones ..........................................................................................55
7.2.5
Summer time rule .................................................................................57
7.3
Adjusting the display (contract, brightness, illumination time of backlight)...........58
7.3.1
Adjusting the contrast of the display .....................................................58
7.3.2
Adjusting the brightness of the display .................................................59
7.3.3
Adjusting the illumination time of the backlight .....................................60
7.3.4
Selecting the format of the standard display (IEC or IEEE) ..................62
7.3.5
Activating color change for alarm .........................................................63
7.3.6
Selecting the refresh time for displaying measured values ...................64
7.3.7
Adjusting the display via the web server ..............................................65
7.4
Device information...............................................................................................66
7.5
Resetting the device to default settings ...............................................................67
Configuration ...........................................................................................................................71
8.1
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Access and passwords........................................................................................72
8.1.1
Editing access data via the display ......................................................72
8.1.2
Editing access data via the web server ................................................73
8.1.3
Deactivating the configuration via the display ......................................74
8.1.4
Deactivating the Modbus communication interface ..............................75
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�Table of contents
8.2
9
Transferring configuration data ............................................................................77
8.2.1
Exporting configuration data ................................................................77
8.2.2
Importing configuration data .................................................................78
8.2.3
Direct transfer of configuration data .....................................................79
Measuring technology ..............................................................................................................81
9.1
Meter readings.....................................................................................................81
9.1.1
Energy meters ......................................................................................82
9.1.2
Energy resettable .................................................................................83
9.1.3
Tariff meter ...........................................................................................84
9.1.4
Operating hours counter ......................................................................85
9.2
Statistics ..............................................................................................................86
9.2.1
Average values ....................................................................................86
10 Functions .................................................................................................................................93
10.1
Digital input..........................................................................................................93
10.1.1 Impulse counter ...................................................................................95
10.1.2 Tariff selection ......................................................................................97
10.1.3 Synchronization of average values ......................................................99
10.1.4 Acknowledgment of alarms ................................................................101
10.2
Digital output......................................................................................................102
10.2.1 Impulse ..............................................................................................104
10.2.2 Device state .......................................................................................106
10.2.3 Manually ............................................................................................108
10.2.4 Alarm .................................................................................................109
10.2.5 Rotary field direction ..........................................................................114
10.2.6 Deactivating the digital output ............................................................116
10.3
Tariff selection ...................................................................................................118
10.3.1 Tariff selection via the communication interface .................................119
10.3.2 Tariff selection using a time schedule ................................................120
10.4
Logic gate ..........................................................................................................123
10.5
Data logging ......................................................................................................128
10.6
Firmware update................................................................................................131
10.6.1 Execution ...........................................................................................131
10.6.2 Security ..............................................................................................133
11 Communication ......................................................................................................................135
11.1
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Ethernet .............................................................................................................138
11.1.1 IP addressing .....................................................................................138
11.1.2 Configuration of the communication interface ....................................139
11.1.3 Status of the communication interface ...............................................140
11.1.4 Security ..............................................................................................140
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�EMpro - multifunctional energy measuring devices for DIN rail mounting
11.2
Modbus .............................................................................................................140
11.2.1 Function .............................................................................................140
11.2.2 Modbus/RTU ......................................................................................141
11.2.3 Modbus/TCP ......................................................................................145
11.2.4 Modbus gateway ................................................................................145
11.3
PROFINET ........................................................................................................147
11.3.1 Software .............................................................................................147
11.3.2 Preparing the GSDML file ..................................................................147
11.3.3 Integrating the GSDML file .................................................................147
11.3.4 Integrating hardware ..........................................................................150
11.3.5 Integrating modules and submodules ................................................156
11.3.6 Linking process data ..........................................................................161
11.3.7 Assigning a device name ...................................................................162
11.3.8 Function check ...................................................................................167
11.4
Configuration .....................................................................................................168
11.4.1 Modbus/RTU ......................................................................................168
11.4.2 Modbus/TCP ......................................................................................168
11.4.3 Modbus gateway ................................................................................168
11.5
Safety ................................................................................................................169
11.6
Data types and registers ....................................................................................170
11.7
Register table ....................................................................................................172
11.8
Contents of the register table.............................................................................172
11.9
Description of the register table .........................................................................172
12 Technical data .......................................................................................................................177
A
Appendix for document lists....................................................................................................181
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A1
List of figures .....................................................................................................181
A2
List of tables ......................................................................................................187
A3
Index..................................................................................................................189
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�For your safety
1
For your safety
Read this user manual carefully and keep it for future reference.
1.1
Identification of warning notes
This symbol indicates hazards that could lead to personal injury.
There are three signal words indicating the severity of a potential injury.
DANGER
Indicates a hazard with a high risk level. If this hazardous situation is not
avoided, it will result in death or serious injury.
WARNING
Indicates a hazard with a medium risk level. If this hazardous situation is not
avoided, it could result in death or serious injury.
CAUTION
Indicates a hazard with a low risk level. If this hazardous situation is not avoided,
it could result in minor or moderate injury.
This symbol together with the NOTE signal word warns the reader of actions
that might cause property damage or a malfunction.
Here you will find additional information or detailed sources of information.
1.2
Qualification of users
The use of products described in this user manual is oriented exclusively to:
– Electrically skilled persons or persons instructed by them. The users must be familiar
with the relevant safety concepts of automation technology as well as applicable standards and other regulations.
– Qualified application programmers and software engineers. The users must be familiar
with the relevant safety concepts of automation technology as well as applicable standards and other regulations.
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�EMpro - multifunctional energy measuring devices for DIN rail mounting
1.3
1.3.1
Field of application of the product
Intended use
The EMpro energy measuring devices described in this user manual are suitable for installation in electrical systems with different voltage levels and performance classes.
Keep in mind that electrical systems pose hazards due to high voltages, high short-circuit
currents, electric arcs and/or other hazards.
1.3.2
Product changes
Modifications to hardware and firmware of the device are not permitted.Incorrect operation
or modifications to the device can endanger your safety or damage the device. Do not repair
the device yourself. If the device is defective, please contact Phoenix Contact.
1.4
Safety notes
WARNING: Risk of death due to electric shock
Only use external current transformers with reinforced or double isolation. Install current
transformers and corresponding measuring devices only when the power supply of the
system is disconnected.
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
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Installation should be carried out as described in the installation notes. Accessing circuits within the device is prohibited.
Always disconnect the device from the energy supply before performing any work on it.
Short-circuit the secondary side of each current transformer.
Use an appropriate voltage measuring device to ensure that no voltage is present.
Re-install all the equipment, doors, and covers on the device before switching on the
device again.
Ensure that the control cabinet is grounded in accordance with DIN EN 61439-1.
Ensure that the control cabinet door in which the device is installed is grounded.
Provide a switch/circuit breaker close to a device, which is marked as the disconnecting
device for this device.
Provide overcurrent protection (16 A) for the supply voltage within the installation.
To protect the device against mechanical or electrical damage, install it in a suitable
housing with an appropriate degree of protection in accordance with IEC 60529.
If the device is not used as described in the documentation, the provided protection
may be impaired.
The housing of the device is equipped with basic insulation against neighboring devices up to 300 V OVC III (overvoltage category). Please note that a minimum clearance
of 6 mm to neighboring elements must be maintained to achieve double insulation.
The device is maintenance-free. Repairs may only be carried out by the manufacturer.
The device must be stopped if it is damaged, was subjected to an impermissible load,
stored incorrectly or if it malfunctions.
Check that the measuring device is working correctly by measuring a known voltage
and a known current.
Ground each current transformer on the secondary side.
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�Device description
2
Device description
The EMpro energy measuring devices (EEM-MA..., EEM-MB... types) are universally
deployable, high-precision, network-compatible measuring devices, with or without LC
display, that can measure, evaluate and process voltages and currents in one, two and
three-phase power supply systems. For voltage measurements, up to four inputs are
available; for current measurements, up to three inputs are available. You can use EMpro
energy measuring devices in TN and IT systems.
Typical installation locations of EMpro energy measuring devices are:
– Switchgear and controlgear assemblies, switchgear and controlgear assembly
systems
– Control cabinets
To enable versatile use, EMpro energy measuring devices are available for the following
installation methods:
– For front panel installation or with DIN rail adapter, with LC display, with control buttons
(included in the EMpro product family, but not described in this user manual)
– For mounting on a DIN rail, with LC display, with control buttons
– For mounting on a DIN rail, with LC display, with control buttons, without LC display,
without control buttons
Your advantages:
– Precise knowledge of load profiles allows load management, optimization of the
electrical energy usage and optimization of energy consumption from the public supply
network and own production (e.g., CHP, PV system).
– Meaningful load profiles are an important aid for planning system expansions and
building new systems.
– Energy costs can be assigned to individual functional divisions or cost centers.
– A transparent overview of the energy flows increases the awareness of energy
consumption, uncovers waste of energy and makes it possible to identify system
components and equipment that harbor potential energy savings.
– Critical system states can be detected, reported and registered. Such critical system
states can, e.g., be caused by overload, unbalanced load, undervoltage, voltage and
current distortion by non-linear consumers, etc. Detection of critical system states
makes it possible to quickly react to such states in order to prevent potential decreases
in availability or energy supply failures. When critical system states are detected in time,
measures can be taken to ensure permanent system availability.
– Seamless communication with control systems via Modbus/RTU, Modbus/TCP,
PROFINET and EtherNet/IP™ and with higher-level energy management systems via
standard TCP/IP networks (Ethernet, RJ45)
– Intuitive configuration and operation of EMpro energy measuring devices with four front
buttons or integrated web server
Numerous parameters that are important for operating an electrical system are determined
by means of the voltages and currents measured by the EMpro energy measuring devices.
Apparent power, active power and reactive power are measured in all four quadrants
(consumption, supply).
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�EMpro - multifunctional energy measuring devices for DIN rail mounting
EMpro energy measuring devices have an integrated web server. It enables:
– Convenient configuration
– Data logging
– Mains quality evaluations
– Detailed recording of energy flows
A configurable digital input and a configurable digital output are also available.
Communication interfaces to higher-level control systems are integrated in the device,
depending on the type.
Currents can be measured with current transformers or Rogowski coils. If you use Rogowski
coils, you do not need an external measuring transducer. EMpro energy measuring devices
can be connected directly to Rogowski coils from any manufacturer. Different device types
are deployed depending on whether current transformers or Rogowski coils are used.
Voltages can be measured directly, or by means of voltage transducers.
Voltages and currents are measured using the principle of true r.m.s. value measurement
(TRMS) up to the 63rd harmonic, which enables detailed assessment of the mains quality.
When EMpro energy measuring devices with LC display are used, it is possible to locally
display measurement values and perform configuration tasks locally by means of buttons.
All EMpro energy measuring devices have a Modbus communication interface and an
integrated web server. Other communication interfaces are available, depending on the
type. Via the web server, all relevant measurement values and parameters can be displayed
and the energy measuring devices can be configured. On the web interface, settings can be
configured for the following, among others:
– Grid types
– Mean values
– Four energy meters for apparent power, active power, reactive power,
consumption/supply
– Energy tariff meter
– Logging
– Alarms and conduct in the event of alarms
– Network (TCP/IP)
– Interfaces with higher-level control systems
– Digital output (with logic functions)
– Digital input
– Pulse counter
– Date/time (realtime clock, SNTP compatible)
– Identifier (of metering point)
– Display
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�Device description
Other features of the EMpro energy measuring devices are:
– Firmware update function
– Password protection (local and web-based management (WBM))
– Deactivation of control buttons for configuration
– Sealable connection fields
– Export, import and direct transfer of configuration data
– Color changes on display (white, red) in the event of errors/events
The following measurement values/parameters are shown on the LC displays of EMpro
energy measuring devices:
– Voltage U [V] (L-L, L-N)
– Current I [A]
– Frequency f [Hz]
– Active power P [W] (string, total)
– Reactive power Q [var] (string, total)
– Apparent power S [VA] (string, total)
– Power factor PF, λ
– Active power factor, active factor cos Φ
– Phase shift angle, phase angle Φ (U-U, U-I)
– Total harmonic distortion (ratio) of the voltage, THD U (L-L, L-N)
– Total harmonic distortion (ratio) of the current, THD I
– Energy E [Wh, varh, VAh] (consumption/supply)
– Energy tariff meter E [Wh, varh, VAh] (consumption, supply, meter 1-4)
For the measurement values/parameters voltage U (L-L), U (L-N), current I, frequency f,
active power P, reactive power Q and apparent power S, it is possible to switch between:
– Instantaneous = Instantaneous value
– Min = Minimum value (can be reset)
– Max = Maximum value (can be reset)
– AVG = Current average value
– AVG Min = Minimum average value (can be reset)
– AVG Max = Maximum average value (can be reset)
All the measures described above are also available via the web server that has been
integrated into the EMpro energy measuring device. In the web browser, the data cannot
only be displayed numerically, but also in the form of a convenient analog display with trend
charts.
A variety of hardware and software interfaces can be used to communicate with higher-level
control systems. At the time of writing this document, the following interfaces are available:
– Modbus/RTU (RS-485)
– Modbus/TCP (Ethernet)
– PROFINET (Ethernet, Dual Port)
– EtherNet/IP (Ethernet, Dual Port)
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�EMpro - multifunctional energy measuring devices for DIN rail mounting
A variety of parameters from the EMpro energy measuring device can be read or configured
in order to communicate with higher-level control systems. These parameters, the
associated addresses, additional information and help texts are available in the web server.
All information required for setting up communication with higher-level control systems is
contained in a register table in the integrated web server. It is therefore usually not
necessary to look up parameters in the paper copy of the documentation.
The register table contains:
– Device data
– Device information
– Device configuration (digital input/digital output)
– Network (TCP/IP)
– Interfaces for higher-level control systems (e.g., Modbus/RTU, Modus/TCP,
PROFINET, EtherNet/IP™)
– Control and status registers
– Device control
– Device status
– Measuring system control
– Process data
– Measured values
– Counter values
– Pulse counter
– Statistics
– Total harmonic distortion THD
– Harmonics
– Voltage quality
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�Device description
2.1
Product overview
Table 2-1
Product overview
Description
Current transformer
Rogowski connection
Modbus/TCP with display
EEM-MA370
EEM-MA371
2907983
2908307
EEM-MB370
EEM-MB371
2907954
2907955
Modbus/TCP with display +
Modbus/RTU
EEM-MA370-R
EEM-MA371-R
2907980
2907985
Modbus/TCP without display +
PROFINET
EEM-MB370-PN
EEM-MB371-PN
2907984
2908308
Modbus/TCP without display +
EtherNet/IP™
EEM-MB370-EIP
EEM-MB371-EIP
2907971
2907976
Modbus/TCP without display
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DIN rail devices
Current measuring input
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�Mounting and installation
3
Mounting and installation
3.1
Mounting
You can snap the device onto a DIN rail in the control cabinet. The mounting position can
be freely selected, but will be determined by the readability of the LCD.
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Figure 3-1
Mounting
Figure 3-2
Removal
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�EMpro - multifunctional energy measuring devices for DIN rail mounting
3.2
Installation
DANGER: Risk of electric shock
If the device is disconnected, the secondary side of the relevant current transformers must
be short circuited.
Install the current sensors and corresponding measuring devices only when the power
supply of the system is disconnected.
When the current transformer is operated with an open secondary circuit, hazardous
voltages may occur at the secondary terminal blocks.
When measuring by means of current transformers or Rogowski coils, the accuracy is
greatly influenced by the quality of the current sensors used.
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�Mounting and installation
3.2.1
Pin assignment
3.2.1.1
Current transformer
Maximum tightening torque for the relevant screws: 0.5 Nm ... 0.6 Nm.
DI DO
-
+
-
I1
I2
I3
S1 S2 S1 S2 S1 S2
EMpro
+
1
U12
U23
U31
400,0v
400,0v
400,0v
2
3
4
L N(L)
V1 V2 V3 VN
Figure 3-3
ETH
Pin assignment example
I1, I2, I3
Current measuring input, current transformer
DI+, DI-
Digital input
DO+, DO-
Digital output
L, N(L)
Supply
V1, V2, V3, VN
Voltage measuring input
FE
Functional ground
RJ45
Ethernet connection (Modbus)
LED
Status
Optional (depending on the version):
1 x RS-485
RS-485 connection (Modbus/RTU)
2x ETH RJ45
Ethernet connection (PROFINET)
Ethernet connection (EtherNet/IP™)
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3.2.1.2
Rogowski coil
DI DO
-
+
-
RC1 RC2 RC3
W1 B1 W2 B2 W3 B3
EMpro
+
1
U12
U23
U31
400,0v
400,0v
400,0v
2
3
4
L N(L)
V1 V2 V3 VN
Figure 3-4
ETH
Pin assignment example
RC1, RC2, RC3
Current measuring input, Rogowski coil
DI+, DI-
Digital input
DO+, DO-
Digital output
L, N(L)
Supply
V1, V2, V3, VN
Voltage measuring input
FE
Functional ground
RJ45
Ethernet connection (Modbus)
LED
Status
Optional (depending on the version):
1 x RS-485
RS-485 connection (Modbus/RTU)
2x ETH RJ45
Ethernet connection (PROFINET)
Ethernet connection (EtherNet/IP™)
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�Mounting and installation
3.2.2
Supply
You can connect the device supply as follows:
1. Connection (L/N)
2. Connection (L/L)
Connection L/N
L N(L)
L1´
L2´
L3´
N´
PE´
L1
L2
L3
N
PE
Figure 3-5
Connection L/N
Connection L/L
L
L
L1´
L2´
L3´
N´
PE´
L1
L2
L3
N
PE
Figure 3-6
Connection L/L
Supply voltage range:
100 V AC ... 230 V AC ±20%
150 V DC ... 250 V DC ±20%
Fuse:
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�EMpro - multifunctional energy measuring devices for DIN rail mounting
3.2.3
Grid types
The device is designed for connection to various network types in two-, three- or fourconductor networks with symmetrical or asymmetrical load.
Where current sensors are concerned, a differentiation is made between current
transformers and Rogowski coils, depending on the device type.
The definitions of the grid types are as follows:
1PH
One-phase network
2W
Two conductors
1CT
One current transformer
Alternative:
1RC
3.2.3.1
One Rogowski coil
Current transformer (CT)
1PH-2W-1CT
V1 V2 V3 VN
6
I1
I2
I3
S1 S2 S1 S2 S1 S2
L1
L2
L3
N
PE
L1´
L2´
L3´
N´
PE´
Figure 3-7
One-phase network, two conductors, one current transformer
2PH-2W-1CT
V1 V2 V3 VN
L1
L2
L3
N
PE
Figure 3-8
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6
I1
I2
I3
S1 S2 S1 S2 S1 S2
L1´
L2´
L3´
N´
PE´
Two-phase network, two conductors, one current transformer
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�Mounting and installation
3PH-3W-1CT
V1 V2 V3 VN
6
I1
I2
I3
S1 S2 S1 S2 S1 S2
L1
L2
L3
N
PE
L1´
L2´
L3´
N´
PE´
Figure 3-9
Three-phase network, three conductors, one current transformer
3PH-3W-2CT
V1 V2 V3 VN
6
I1
I2
I3
S1 S2 S1 S2 S1 S2
L1
L2
L3
L1´
L2´
L3´
PE
PE´
Figure 3-10
Three-phase network, three conductors, two current transformers
3PH-3W-3CT
V1 V2 V3 VN
6
I1
I2
I3
S1 S2 S1 S2 S1 S2
L1
L2
L3
N
PE
L1´
L2´
L3´
N´
PE´
Figure 3-11
Three-phase network, three conductors, three current transformers
3PH-4W-1CT
V1 V2 V3 VN
L1
L2
L3
N
PE
Figure 3-12
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6
I1
I2
I3
S1 S2 S1 S2 S1 S2
L1´
L2´
L3´
N´
PE´
Three-phase network, four conductors, one current transformer
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3PH-4W-3CT
V1 V2 V3 VN
6
I1
I2
I3
S1 S2 S1 S2 S1 S2
L1
L2
L3
N
PE
L1´
L2´
L3´
N´
PE´
Figure 3-13
Three-phase network, four conductors, three current transformers
2PH-3W-2CT
V1 V2 V3 VN
L1
L2
L3
N
PE
Figure 3-14
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6
I1
I2
I3
S1 S2 S1 S2 S1 S2
L1´
L2´
L3´
N´
PE´
Two-phase network, three conductors, two current transformers
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�Mounting and installation
3.2.3.2
Rogowski coil (RCP)
1PH-2W-1RC
V1 V2 V3 VN
6
RC1
RC2
RC3
W1 B1 W2 B2 W3 B3
L1´
L2´
L3´
N´
PE´
L1
L2
L3
N
PE
Figure 3-15
One-phase network, two conductors, one Rogowski coil
2PH-2W-1RC
V1 V2 V3 VN
6
RC1
RC2
RC3
W1 B1 W2 B2 W3 B3
L1
L2
L3
N
PE
L1´
L2´
L3´
N´
PE´
Figure 3-16
Two-phase network, two conductors, one Rogowski coil
3PH-3W-1RC
V1 V2 V3 VN
L1
L2
L3
N
PE
Figure 3-17
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6
RC1
RC2
RC3
W1 B1 W2 B2 W3 B3
L1´
L2´
L3´
N´
PE´
Three-phase network, three conductors, one Rogowski coil
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3PH-3W-3RC
V1 V2 V3 VN
6
RC1
RC2
RC3
W1 B1 W2 B2 W3 B3
L1´
L2´
L3´
N´
PE´
L1
L2
L3
N
PE
Figure 3-18
Three-phase network, three conductors, three Rogowski coils
3PH-4W-1RC
V1 V2 V3 VN
6
RC1
RC2
RC3
W1 B1 W2 B2 W3 B3
L1
L2
L3
N
PE
L1´
L2´
L3´
N´
PE´
Figure 3-19
Three-phase network, four conductors, one Rogowski coil
3PH-4W-3RC
V1 V2 V3 VN
6
RC1
RC2
RC3
W1 B1 W2 B2 W3 B3
L1
L2
L3
N
PE
L1´
L2´
L3´
N´
PE´
Figure 3-20
Three-phase network, four conductors, three Rogowski coils
2PH-3W-2RC
V1 V2 V3 VN
L1
L2
L3
N
PE
Figure 3-21
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6
RC1
RC2
RC3
W1 B1 W2 B2 W3 B3
L1´
L2´
L3´
N´
PE´
Two-phase network, three conductors, two Rogowski coils
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�Operating and indication elements
4
Operating and indication elements
4.1
Energy measuring device with display
EMpro
3
1
U12
U23
U31
400,0v
400,0v
400,0v
2
2
3
4
1
1
2
3
LCD display, two-color backlit
Operating buttons 1...4 for displaying measured values and for changing the
configuration
Pulse LED
4.2
Energy measuring device without display
3
Impuls
2
Status
1
Reset
Figure 4-1
1
2
3
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EEM-MB-370
Reset button
Status LED
Pulse LED
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4.3
Energy measuring device without display, with
additional PROFINET interface
5
Impuls
4
DCP
3
BF
2
Status
1
Reset
Figure 4-2
1
2
3
4
5
EEM-MB-370-PN
Reset button
Status LED
PROFINET status BF
PROFINET status DCP
Pulse LED
Table 4-1
Name
Color/status
Description of PROFINET communication
BF
Red
PROFINET communication
Off
Communication OK
On (red)
Fault in the communication controller or no physical connection to the PROFINET network
Flashing
PROFINET timeout
DCP
Green
Flashing
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DCP flashing
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�Operating and indication elements
4.4
Energy measuring device without display, with
additional Ethernet/IP interface
5
Impuls
4
MS
3
NS
2
Status
1
Reset
Figure 4-3
1
2
3
4
5
EEM-MB370-EIP
Reset button
Status LED
Ethernet/IP status: NS (network status)
Ethernet/IP status: MS (module status)
Pulse LED
Table 4-2
Name
Color/status
Description of Ethernet/IP communication
MS
Green/red
Module status
Off
Supply voltage not present
Flashing (green)
Device is not configured
On (green)
No error
Flashing (red)
Repairable error/peripheral error/message,
e.g., overload, output driver, IFS device error, configuration error
On (red)
Internal error
Replace the device.
Flashing (green/red)
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Self test
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Table 4-2
NS
4.5
Green/red
Network status
Off
Supply voltage not present
Flashing (green)
IP address assigned, but no EtherNet/IP
connection
On (green)
EtherNet/IP connection configured, cyclic
data transmission OK
Flashing (red)
EtherNet/IP™ connection timeout, connection interrupted
On (red)
IP address conflict
Flashing (green/red)
Self test
Technical data of the display
Technical data
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Display technology
FSTN positive, transflective
Resolution of devices for installation on
front panel
128 x 80
Viewing angle
Min. 30° (horizontal and vertical)
Backlight
White and red
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�Operating and indication elements
4.6
Table 4-3
Icon
Displaying the events
Displaying the events
Meaning
Voltage transducer configured
Measured values faulty (flashing)
Tariff 1 set
Tariff 2 set
Tariff 3 set
Tariff 4 set
Network connected
Warning
User logged in
User logged out
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4.7
Table 4-4
Icon
Operating elements on the display (softkeys)
Meaning of the softkeys
Meaning
Open/close settings menu
Scroll up
Scroll down
Select menu page
Exit menu page
Edit setting
Apply modified setting
Increment (increase)
Decrement (decrease)
Next position
Confirm query
Reject query/first configuration: go back to start
Reset: the displayed values are reset
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�Basic device configuration
5
Basic device configuration
The first time the energy measuring device is switched on, the installation wizard for the first
configuration (basic device configuration) automatically starts. In the basic device
configuration, you can edit the default settings of the device. Depending on the
requirements, you can perform the basic device configuration via the display or via the
integrated web server.
Menu-driven configuration is available for the following parameters:
– Language
– Network settings
– Grid type
– Current input
– Voltage input
5.1
1.
To start the first configuration (basic device configuration) of your energy measuring
device, press the
button.
Figure 5-1
5.1.1
Figure 5-2
1.
2.
109357_en_00
Basic device configuration via the display
Starting the basic device configuration
Step 1: Language selection
Language selection
Use the
and
buttons to select the desired language.
To proceed, press the
button.
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5.1.2
Figure 5-3
1.
2.
Figure 5-4
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Network settings
If you do not want to edit the network settings, press the
button.
If you want to edit the network settings, press the
button.
5.1.3
1.
2.
3.
4.
5.
Step 2: Network settings
Step 3: IPv4
IPv4
To enter a network setting, use the
or
buttons to scroll to the desired setting.
To open edit mode, press the
button.
To scroll through the possible values, use the buttons
and
.
Next, apply the settings by pressing the
button.
After you have entered all settings, press the
button.
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�Basic device configuration
5.1.4
Step 4: Grid type
Current transformer
Figure 5-5
Selection of grid type with current transformers
Rogowski coil
Figure 5-6
1.
2.
Selection of grid type with Rogowski coils
Use the
or
buttons to select the desired grid type.
To proceed, press the
button.
Explanations and information on the various grid types are available in Section “Grid
types” on page 20.
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5.1.5
Figure 5-7
1.
2.
3.
Step 5a: Current input (energy measuring device with
current transformer)
Current input (energy measuring device with current transformer)
To open the edit mode for the “Primary” device setting, press the
To set the primary current, press the buttons
and
.
To apply the change, press the
button.
button.
To set the secondary current, proceed in the same way as for setting the primary current.
4.
5.
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To invert the current inputs, activate the checkbox below the appropriate current input
with the
button.
To continue the basic device configuration, press the
button.
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�Basic device configuration
5.1.6
Figure 5-8
1.
2.
3.
Step 5b: Current input (energy measuring device with
Rogowski coil)
Current input (energy measuring device with Rogowski coil)
Use the
button to open the edit mode of the “Manufacturer” device setting.
To make changes, use the buttons
and
.
To apply the change, press the
button.
The same procedure applies to editing the nominal current.
4.
5.
To activate or deactivate a checkbox, press the
button.
To continue the basic device configuration, press the
button.
5.1.7
Figure 5-9
1.
2.
3.
4.
5.
6.
109357_en_00
Step 6: Voltage input
Voltage input
If you use a voltage transducer, activate the checkbox with the
button. When you
activate the checkbox, the primary and secondary voltage is displayed.
If no voltage transducer is used, enter the nominal voltage by means of the
and
buttons.
Select it with the
button.
Use the buttons
and
to make changes.
To save the changes, press the
button.
To proceed, press the
button.
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5.1.8
Figure 5-10
1.
2.
3.
Figure 5-11
2.
button.
Step 8: Setting a personal PIN
Setting a personal pin
To ensure safe operation, you can select a personal PIN. To this end, press the
button.
If you do not want to change the PIN, press the
button.
5.1.10
Figure 5-12
1.
2.
3.
4.
Configuration conclusion
Use the buttons
and
to check your configured settings.
If you are satisfied with the first configuration, finish it by pressing the
To restart the first configuration, press the
button.
5.1.9
1.
Step 7: Configuration overview
Step 9: Activating the PIN
Activating the PIN
To activate the PIN, press the
button.
Use the buttons
and
to enter the desired PIN.
To apply the changes, press the
button.
To finish the basic device configuration, press the
button.
To ensure safe operation, we recommend changing the access data for the display!
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�Basic device configuration
For additional information, please refer to Section “Configuration” on page 71.
5.2
Basic device configuration via the web server
We recommend using the integrated web server to perform the device configuration. You
can access the web server directly after you have switched on the device. An installation
wizard guides you through the basic device configuration process.
By default, a static IP address is set for the device.
To start the basic device configuration via the web server, open the Internet browser. Enter
the following URL:
IP address:
192.168.1.2
Subnet mask:
255.255.255.0
Default gateway:
0.0.0.0
DHCP:
Off
DNS server:
0.0.0.0
Make sure that your computer and the energy measuring device are in the same network.
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5.2.1
Step 1: Network settings
The first step in the basic device configuration is the network settings.
Navigation on the web
server
“Network settings”
Figure 5-13
Network settings
Status
Here, an overview of the current network configuration is displayed.
Settings
Enter the desired network settings as appropriate for the respective application.
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�Basic device configuration
5.2.2
Step 2: Selecting the grid type
The second step is the selection of the grid type for the application.
Figure 5-14
Grid type
Taking the device installation into account, select the desired grid type from the options
provided in the overview.
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5.2.3
Step 3: Configuration of the current input (current
transformer)
Depending on the device selection and the associated device-specific current sensors,
the current input setting may vary.
Configuring the current input is the third step of the basic device configuration.
Figure 5-15
Current input, current transformer
Primary
Enter the primary current of the application here.
Secondary
Select the secondary current (1 A or 5 A) of the current transformer.
Inversion
With this function, the respective phase of the current transformer is inverted by the
firmware. It is no longer necessary to rewire the two conductors.
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�Basic device configuration
5.2.4
Step 3: Configuration of the current input (Rogowski coil)
Depending on the device selection and the associated device-specific current sensors,
the current input setting may vary.
Configuring the current input is the third step of the basic device configuration.
Figure 5-16
Current input (Rogowski coil)
Primary
Enter the primary current of the application here.
Preselection
Select a Rogowski coil of Phoenix Contact. You do not have to configure any other settings.
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Invert I1
With this function, the respective phase of the Rogowski coil is inverted by the firmware. It
is no longer necessary to rewire the two conductors.
If you use Rogowski coils of manufacturers other than Phoenix Contact, you have to
configure additional settings.
Amplitude transmission
factor
Enter the amplitude transmission factor (mV/kA) of the Rogowski coil.
Internal resistance
Enter the internal resistance (Ω) of the Rogowski coil.
Refer to the documentation of the Rogowski coil for the amplitude transmission factor.
Refer to the documentation of the Rogowski coil for the internal resistance.
Inversion
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With this function, the respective phase of the Rogowski coil is inverted by the firmware. It
is no longer necessary to rewire the two conductors.
PHOENIX CONTACT
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�Basic device configuration
5.2.5
Step 4: Voltage input
If you use a voltage transducer in your application, activate the checkbox here.
Subsequently follow the next steps.
Figure 5-17
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Voltage input
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5.2.6
Figure 5-18
Optional: Voltage transducer
Voltage input with voltage transducer
Primary
Enter the primary voltage of the voltage transducer.
Secondary
Enter the secondary voltage of the voltage transducer.
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�Basic device configuration
5.2.7
Figure 5-19
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Step 5: Configuration overview
Configuration overview
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�EMpro - multifunctional energy measuring devices for DIN rail mounting
Check all settings and close the basic device configuration.
For your own safety, we recommend changing the access data for the web server!
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�Navigation structure and display
6
Navigation structure and display
6.1
Figure 6-1
109357_en_00
Menu structure on the display
Menu structure on the display
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6.2
Figure 6-2
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Menu structure on the web server
Menu structure on the web server
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�Navigation structure and display
The figure shows the start screen of the web server in operating mode after the basic device
configuration has been completed.
The following information appears in the header:
– Order designation
– Equipment identification (EID) of the device, which you can name as desired
– A defined measuring point, which you can name as desired
– Language selection
The menu tree contains the following:
109357_en_00
Home:
Reading measured data and measurement values
Settings:
Configuring the device and device parameters
System:
Managing rights and provision of information and data
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�Device settings and information
7
Device settings and information
7.1
Selecting the language
The language selection for the display and the web server can differ. Thus, changing the
language via the display does not affect the language set in the web server, and vice versa.
Navigation on the display
“Language”
Figure 7-1
“Language” menu
Figure 7-2
Language selection
You can select the display language via the display.
The default setting for the language is English.
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7.2
Date and time
When the device is switched off, or in the event of a power loss, the device retains the system time for at least one day.
This is usually adequate for maintenance and installation work.
7.2.1
Navigation on the display
Reading the date and time
“Date / Time”
Figure 7-3
“Date / Time” menu
Figure 7-4
Settings: “Date / Time”
On the device display, you can only read the date and time settings.
The date and time settings can only be changed via the integrated web server or the Modbus communication interface.
The web server provides the following modes for setting the date and time:
– Manual
– SNTP server
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�Device settings and information
7.2.2
Navigation on the web
server
Setting the date and time manually
“Settings, Date / Time, Settings, “Manually” mode
Figure 7-5
“Settings, Date / Time, Settings, “Manually” mode
Status
Here, the current date and current time is shown.
Settings
Here, you can change the settings for the date and time.
Time zone
Here, you can select a time zone. You can find a list of all time zones in Section “Time zones”
on page 55.
Summer time rule
Here, you can select a summer time rule. A description of the summer time rules can be
found in Section “Summer time rule” on page 57.
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7.2.3
Navigation on the web
server
Synchronizing the date and time with an SNTP server
“Settings, Date / Time, Settings, “SNTP Server” mode
Figure 7-6
Menu: “Settings, Date / Time, Settings, “SNTP Server”” mode
Settings
Here, you can change the settings for the date and time.
Mode
Via the “SNTP server” Modbus, the internal clock of the device is automatically synchronized with an SNTP server (Simple Network Time Protocol).
SNTP server
Enter the address or the URL of the SNTP server and check the entered address by clicking
“Check connection”.
Polling cycle
Enter the desired polling rate in seconds (s).
Time zone
Here, you can select a time zone. You can find a list of all time zones in Section “Time zones”
on page 55.
Summer time rule
Here, you can select a summer time rule. A description of the summer time rules can be
found in Section “Summer time rule” on page 57.
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�Device settings and information
7.2.4
Navigation on the web
server
Time zones
“Settings, Date / Time, Settings, “Time zones”
GMT -12:00
GMT -11:00
Pacific (Midway, Niue, Samoa)
GMT -10:00
Pacific (Hawaii, Honolulu, Tahiti)
GMT -09:30
Pacific (Marquesas)
GMT -09:00
America (Anchorage, Yakutat, Alaska)
GMT -08:00
America (Los Angeles, Vancouver, Tijuana)
GMT -07:00
America (Denver, Edmonton, Phoenix, Yellowknife)
GMT -06:00
America (Chicago, Cancun, Mexico City, Costa Rica, Winnipeq)
GMT -05:00
America (Cayman, Bogota, Havana, Lima, New York, Panama, Toronto)
GMT -04:30
America (Caracas)
GMT -04:00
America (Asuncion, Barbados, Grenada, Santiago)
GMT -03:30
America (St. Johns), Canada (Newfoundland)
GMT -03:00
America (Buenos Aires, Cordoba, Bahia, Recife, Sao Paulo)
GMT -02:00
America (Noronha), Atlantic (South Georgia)
GMT -01:00
Atlantic (Azores, Cape Verde)
GMT 00:00
Africa (Accra, Dakar) Europe (Lisbon, Madeira, Reykjavik, Dublin, London)
GMT +01:00
Africa (Lagos, Tunis)
Europe (Amsterdam, Belgrade, Berlin, Brussels, Copenhagen, Paris,
Rome)
GMT +02:00
Africa (Cairo, Johannesburg)
Europe (Helsinki, Athens, Riga, Sofia)
GMT +03:00
Africa (Mogadishu, Nairobi),
Asia (Baghdad, Bahrain, Kuwait, Quatar),
Europe (Minsk, Kaliningrad)
GMT +04:00
Asia (Tehran, Baku, Dubai)
Europe (Moscow, Volgograd)
India (Mahe, Mauritius, Reunion)
GMT +04:30
Asia (Kabul)
GMT +05:00
Asia (Dushanbe, Tashkent)
India (Maldives)
109357_en_00
GMT +05:30
Asia (Calcutta, Colombo)
GMT +05:45
Asia (Kathmandu)
GMT +06:00
Asia (Almaty, Bishkek, Dacca, Yekaterinburg, Thimbu)
GMT +06:30
Asia (Rangoon), India (Cocos)
GMT +07:00
Asia (Bangkok, Jakarta, Novosibirsk, Omsk)
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GMT +08:00
Asia (Brunei, Hong Kong, Kuala Lumpur, Singapore, Taipei, Manila),
Australia (Perth, West)
GMT +08:45
Australia (Eucla)
GMT +09:00
Asia (Irkutsk, Seoul, Tokyo)
GMT +09:30
Australia (Adelaide, Darwin, North, South)
GMT +10:00
Asia (Yakutsk)
Australia (Brisbane, Melbourne, Queensland, Sydney, Tasmania)
GMT +11:00
Asia (Vladivostok)
GMT +11:30
Pacific (Norfolk)
GMT +12:00
Asia (Kamchatka)
Pacific (Guadalcanal)
Pacific (Auckland, Fiji, Majuro)
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GMT +12:45
Pacific (Chatham)
GMT +13:00
Pacific (Apia, Enderbury, Tongatapu)
GMT +14:00
Pacific (Kiritimati)
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�Device settings and information
7.2.5
Navigation on the web
server
Summer time rule
“Settings, Date / Time, Settings, Summer time rule”
Figure 7-7
Menu: “Settings, Date / Time, Settings, Summer time rule”
Status
Here, the current date and current time is shown.
Settings
Here, you can change the settings for the date and time.
You can select the summer time rule for Europe or the USA, or set a summer time rule manually. If you set the summer time rule manually, you can specify the start and end of the summer time rule:
– Month
– Day of week
– Hours
– Minutes
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7.3
7.3.1
Navigation on the display
Adjusting the display (contract, brightness, illumination time of backlight)
Adjusting the contrast of the display
“Display, Contrast”
Contrast
Figure 7-8
Menu: “Display, Contrast”
Figure 7-9
Settings: “Display, Contrast”
You can set the contrast of the display. The default setting for the contrast is 50%.
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�Device settings and information
7.3.2
Navigation on the display
Adjusting the brightness of the display
“Display, Brightness“
Figure 7-10
Menu: “Display, Brightness“
Figure 7-11
Settings: “Display, Brightness“
You can adjust the brightness of the display. The default setting for the brightness of the display is 100%.
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7.3.3
Navigation on the display
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Adjusting the illumination time of the backlight
“Display, Permanent light, Illumination time”
Figure 7-12
Menu: “Display, Permanent light”
Figure 7-13
Settings: “Display, Permanent light”
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�Device settings and information
Permanent light
When the “Permanent light” checkbox is enabled, the white backlight of the display is on
permanently.
Figure 7-14
Settings: “Illumination time”
Permanent light
When the “Permanent light” checkbox is disabled, the white backlight of the display is off.
Illumination duration
When the “Permanent light” checkbox is disabled, you can freely define the duration for
which the backlight remains lit.
The default setting for the illumination time is 20 seconds.
You can also change the settings for the illumination time via the web server.
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7.3.4
Navigation on the display
Standard display
Selecting the format of the standard display (IEC or IEEE)
“Display, Standard display”
Figure 7-15
Menu: “Display, Standard display”
Figure 7-16
Settings: “Display, Standard display”
You can choose between the formats IEC and IEEE for displaying the measured values and
the associated units.
The default setting is IEC.
You can also change the format for the standard displays via the web server (see Section
“Adjusting the display via the web server” on page 65).
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�Device settings and information
7.3.5
Navigation on the display
Alarm light
Activating color change for alarm
“Display, Alarm light”
Figure 7-17
Menu: “Display, Alarm light”
Figure 7-18
Settings: “Display, Alarm light”
The backlight of the display can change from white to red in the event of an error (color
change).
When the “Alarm light” checkbox is enabled, the color change is active.
In the default setting, the color change is enabled.
You can also change the settings for the alarm light via the web server (see “Red color
change in case of error” on page 65).
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7.3.6
Navigation on the display
Refresh rate
Selecting the refresh time for displaying measured values
“Display, Refresh time”
Figure 7-19
Menu: “Display, Refresh time”
Figure 7-20
Settings: “Display, Refresh time”
You can choose between three refresh times for displaying the measured values:
– 500 ms
– 1s
– 2s
The default setting for the refresh time is 1 s.
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�Device settings and information
7.3.7
Navigation on the web
server
Adjusting the display via the web server
“Settings, Display”
Figure 7-21
Web server: “Settings, Display”
Status
Here, the current settings for the display are shown. It is also possible to modify them here.
Standard display
Here, you can choose between the formats “IEC” or “IEEE”.
Activate configuration via
display
If this checkbox has been enabled, you can configure the device via the display.
Illumination duration
Here, you can select between:
– Steady off
– Set duration (in hh:mm:ss)
– Steady on
Red color change in case
of error
If this checkbox is enabled, the color change in the event of an error is active. If this checkbox is disabled, the color change in the event of an error is inactive. In the default setting,
this checkbox is enabled.
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7.4
Navigation on the display
Device information
“Device info”
Figure 7-22
Menu: “Device info”
Figure 7-23
Display: “Device info”
The following device information can be read on the display:
– Hardware version
– Firmware version
– Device label
– Article number
– UUID
– Date and time of production
– Serial number
– Bootloader revision
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�Device settings and information
7.5
Navigation on the display
Resetting the device to default settings
“System, Factory reset”
Figure 7-24
Menu: “System, Factory reset”
Figure 7-25
Menu: “System, Factory reset”
With the device PIN, the device can be reset to the default settings.
In the process, all configurations are lost and the device is returned to the delivery state.
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�Device settings and information
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�Configuration
8
Configuration
The device configuration is set by default as follows.
Configuration via the
display
You can use the control buttons on the front of the device to enter the basic device configuration and configure settings on the display.
Configuration via web
server
The web server is the tool provided for device configuration. In addition to offering intuitive
operation, it has been designed for not only entering the basic device configuration, but also
for performing all other configurations.
Configuration via Modbus
In addition to the web server, the Modbus communication interface can also be used for device configuration.
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8.1
Access and passwords
For your own safety, change the access data.
8.1.1
Navigation on the display
Editing access data via the display
“System, PIN xxxx”
Figure 8-1
Menu: “System, PIN xxxx”
Figure 8-2
Settings: “System, PIN xxxx”
The default setting for the PIN is “0100”.
1.
2.
Under “PIN”, change the preset PIN for access permission.
Subsequently apply it by confirming the change.
In addition to the option to change the PIN, the device also offers an option for deactivating
the PIN.
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�Configuration
8.1.2
Navigation on the web
server
Editing access data via the web server
“System, User management, Change password”
Figure 8-3
Menu: “System, User management, Change password”
The default setting for the password is “adm1n”.
1.
2.
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Under “Change password”, change the preset password for access permission.
Confirm the change by clicking the “Change password” button.
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8.1.3
Navigation on the web
server
Deactivating the configuration via the display
“Settings, Display”
Figure 8-4
Menu: “Settings, Display”
The device provides an option for protection against manipulative access: You can prevent
access to the device and thus changes to the configured data by disabling the “Activate
configuration via display” checkbox.
You can continue to use the control buttons of the device to read measurement values.
If the “Activate configuration via display” checkbox is disabled, it is not possible to use the
function for deactivating the web server. The display and web server cannot be deactivated
simultaneously.
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�Configuration
8.1.4
Deactivating the Modbus communication interface
You can prevent device access via the Modbus communication interface by deactivating
the communication interface (“WBM active”).
Navigation on the display
“System, PIN active/WBM active (web-based management)”
Figure 8-5
Menu: “System, PIN active/WBM active”
Figure 8-6
Setting: “System, WBM active”
Figure 8-7
Setting: “System, PIN active”
If you disable the “WBM active” checkbox, the device no longer allows access via the
communication interface.
Through this deactivation, access to the web server is also prohibited.
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This precludes use of the function for deactivating the control buttons. The display and web
server cannot be deactivated simultaneously.
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�Configuration
8.2
Transferring configuration data
If you want to apply existing configurations to other devices, you can transmit the
configuration data as follows:
– Exporting configuration data
– Importing configuration data
– Direct transfer of configuration data
8.2.1
Navigation on the web
server
Exporting configuration data
“System, Configuration data, Export configuration”
Figure 8-8
Menu: “System, Configuration data, Export configuration”
If you want to export the entire device configuration, all checkboxes except the network
configuration are enabled.
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To perform a 1:1 device exchange, or to download an identical device configuration, click
“Select all”. All checkboxes in the overview are enabled.
Another option is to perform a partial configuration by only enabling the required
checkboxes. In this case, only the selected configuration is downloaded.
Press the “Download” button to download the configuration.
8.2.2
Navigation on the web
server
Importing configuration data
“System, Configuration data, Import configuration“
Figure 8-9
Menu: “System, Configuration data, Import configuration”
If you want to load an existing configuration file onto the device, you can use the “Choose
file” button to select it.
Use the “Import” button to load the selected file onto the device.
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�Configuration
8.2.3
Navigation on the web
server
Direct transfer of configuration data
“System, Configuration data, Transfer configuration”
Figure 8-10
Menu: “System, Configuration data, Transfer configuration”
By directly transferring the configuration data, you prevent caching on a local computer.
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If you want to transfer the entire device configuration directly from one device to another,
use the “Select all” button to enable all checkboxes in the overview. The network connection
is not activated. If you want to include the network configuration, select it additionally.
Observe the following:
– You have to know the IP addresses and passwords of the devices.
– All devices have to be accessible via the network.
In addition to transferring the entire device configuration, you can also perform a partial
transfer of the configuration by selecting the required checkboxes.
Enter the device addresses and passwords into the respective fields.
To check the connection to the entered device, click the “Check connection” button.
Click the “Transfer” button to transfer the selected configuration data to the devices.
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�Measuring technology
9
Measuring technology
9.1
Navigation on the web
server
Meter readings
“Home, Meter readings”
Figure 9-1
Menu: “Home, Meter readings”
The device provides various meter readings for measuring the energy data. These are
described in the following sections.
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Navigation on the display
9.1.1
Energy meters
9.1.1.1
Energy meter, total
“E, Energy total”
Navigation on the display
Energy total
Figure 9-2
Menu: “E, Energy total”
Figure 9-3
Menu: “E, Energy total”
This energy meter is always counting.
This energy meter cannot be reset.
The following energy data is recorded:
– Active energy: supply (Ea+), consumption (Ea-)
– Reactive energy: supply (Er+), consumption (Er-)
– Apparent energy (Es)
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�Measuring technology
9.1.2
Navigation on the display
Energy resettable
“E, Energy resettable”
Navigation on the display
Figure 9-4
Menu: “E, Energy resettable”
Figure 9-5
Menu: “E, Energy resettable”
Energy resettable
This energy meter is always counting. This energy meter can be reset.
Reset
The reset can be performed by means of the web server, the control buttons on the display,
or the Modbus communication interface.
The following energy data is recorded:
– Active energy: supply (Ea+), consumption (Ea-)
– Reactive energy: supply (Er+), consumption (Er-)
– Apparent energy (Es)
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9.1.3
Navigation on the display
Tariff meter
“Tar, Tariff meter 1...4“
Figure 9-6
Menu: “Tar, Tariff meter 1...4”
Figure 9-7
Menu: “Tar, Tariff meter 1”
Tariff meter (1…4)
If a tariff meter is selected/activated, counting is always performed on this meter. Tariff meters 1...4 can be reset.
Reset
The reset can be performed by means of the web server, the control buttons on the display,
or the Modbus communication interface.
The following energy data is recorded for each tariff meter:
– Active energy: supply (Ea+), consumption (Ea-)
– Reactive energy: supply (Er+), consumption (Er-)
– Apparent energy (Es)
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�Measuring technology
9.1.4
Navigation on the display
Operating hours counter
“Device info, Operating hours/Load operation”
Figure 9-8
Menu: “Device info, Operating hours/Load operation”
Figure 9-9
Menu: “Device info, Operating hours/Load operation”
The device provides two different operating hour counters.
Operating hours (T_tot)
This counter keeps running as long as the device is supplied with voltage.
Load operation (T_load)
This counter is a load counter that starts running from a configurable power threshold (in W).
The default setting for the power threshold is 100 W. The value can be configured via the
Modbus communication interface.
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9.2
9.2.1
Statistics
Average values
The device makes it possible to determine average values based on the available
measurement data.
The average is generated for the following measurement values:
– Voltages: phase to phase U12, U23, U31
– Voltages: phase to neutral conductor U1, U2, U3
– Frequency
– Currents I1, I2, I3, IN
– Active power: consumption, supply
– Reactive power: consumption, supply
– Apparent power
The measurement values are divided into groups. These groups can be configured
independently of each other.
The following groups have been formed:
– Voltages
– Frequency
– Currents
– Power
– Predictions
For each average value, the minimum and maximum averages are always recorded and
displayed. The data can be called up via the web server, the display and via the
communication interface.
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�Measuring technology
There are three different types of average value generation:
– AVG over fixed interval
– AVG over rolling interval
– AVG over sliding interval
The average value types are described in the following sections.
The figures show the three different types of average value calculation. Select a time
interval that the measuring device will then use for calculating the average.
Navigation on the web
server
“Settings, Average values”
Figure 9-10
Status
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Menu: “Settings, Average values”
Here, the current status of the average value generation is shown.
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Figure 9-11
Settings
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Menu: “Average values, Settings”
Here, enter the configuration in hh:mm:ss for the average value generation. The average
values can be synchronized via the digital input by enabling the checkbox.
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�Measuring technology
9.2.1.1
Interval with fixed
measuring interval length
The intervals follow each other consecutively at the measurement interval length. The
requirement is calculated and updated at the end of each interval.
Figure 9-12
9.2.1.2
Interval with sliding
measuring interval length
AVG over fixed interval (fixed block)
Sliding average value (sliding block)
The intervals slide and have a set measuring interval length. The average value is
generated and updated with the sliding speed. During each update, the average is
generated for the last completed interval.
Figure 9-13
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AVG over fixed interval (fixed block)
Sliding average value (sliding block)
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9.2.1.3
Interval with rolling block
There is a set interval and a subinterval. The subinterval has to be an integer factor of the
interval. Example: If the selected interval is 15 minutes, three 5-minute subintervals have to
be selected to match it. The average value is generated and updated at the end of each
completed subinterval.
Figure 9-14
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Rolling average value (rolling block)
Rolling average value (rolling block)
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9.2.1.4
Interval with fixed
measuring interval length
The intervals follow each other consecutively at the measurement interval length. All
recorded individual values within the generated average values have the same weight.
Figure 9-15
9.2.1.5
Interval with fixed
measuring interval length
Prediction calculation (equally weighted average)
Prediction calculation (weighted average)
The intervals follow each other consecutively at the measurement period length. The last
acquired, individual value within the generated average values has the highest weight. As
each new value is recorded, the weight of the individual values decreases (exponentially).
Figure 9-16
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Trend calculation (equally weighted average)
Prediction generation (weighted average)
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�Functions
10 Functions
10.1
Digital input
The digital input complies with IEC 61131-2 Type 3. It includes the following functions:
– Impulse counter
– Tariff selection
– Synchronization of average values
– Acknowledgment of alarms
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Figure 10-1
Digital input
Status
The “Status” area shows the current status of the digital input.
Linked functions
The digital input has been configured with a defined function.
By clicking the respective link, you can access the configuration page for the function.
Settings
An identifier can be assigned to the digital input. With the checkbox, it can be activated or
deactivated.
In the default settings, the digital input is activated.
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�Functions
10.1.1
Impulse counter
The impulse counter counts the pulses generated by an external device.
It is possible to assign a measuring unit (volume, weight, distance, electrical power or an
own unit), as well as the valency.
Navigation on the web
server
“Settings, Impulse counter”
Figure 10-2
Menu: “Settings, Impulse counter”
Status
The “Status” area shows the current status of the digital input.
Settings
Set the impulse counter in accordance with your requirements.
Activated
The impulse counter can be activated/deactivated with the checkbox.
Valency
The impulse corresponds to the set value and is thus an additional multiplier. The valid value
range is 1 … 65535.
Unit
Select a unit from the drop-down menu, or assign an own unit by selecting “Custom”.
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Unit: You can select between the following units:
– kWh
– kVAh
– kvarh
– ml
– l
– m³
– g
– kg
– t
– m
– km
– Custom
You can use the “Custom” option to define an own unit.
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�Functions
10.1.2
Tariff selection
A switchover from one tariff to another can be performed via the digital input. Depending on
the status of the input signal, tariff meter 1 or tariff meter 2 is used. Two of the four tariffs of
the device can be used via the digital input.
Via the web server, you can manually configure up to four tariffs (identifiers 1 to 4) and read
them via the communication interface.
Navigation on the web
server
“Settings, Tariffs”
Figure 10-3
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Menu: “Settings, Tariffs, Digital input”
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Status
The “Status” area shows the current status of the digital input.
Settings
Set the impulse counter according to your requirements.
Identifier
Define the two identifiers (names) for your tariffs.
Mode
Specify the digital input as method for using the tariff selection.
Digital input
Define the status of the digital input in relation to the identifier.
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�Functions
10.1.3
Synchronization of average values
By means of the digital input, the synchronization pulse can be used for starting the
respective average value generation.
Navigation on the display
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“UL-L, UL-L ...”
Figure 10-4
Menu: “UL-L”
Figure 10-5
Menu: “UL-L, UL-L instantaneous“ (instantaneous values, instantaneous)
Figure 10-6
Menu: “UL-L, UL-L Min“ (min. values, min)
Figure 10-7
Menu: “UL-L, UL-L Max“ (max. values, max)
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Figure 10-8
Menu: “UL-L, UL-L AVG Min“ (minimum average values, AVG min)
Figure 10-9
Menu: “UL-L, UL-L AVG“ (average values, AVG)
Figure 10-10
Menu: “UL-L, UL-L AVG max“ (max. average values, AVG max)
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�Functions
Navigation on the web
server
“Settings, Average values”
Figure 10-11
Menu: “Settings, Average values, Status”
The digital input can be used to synchronize the average value generation. This function is
used, e.g., when energy requirements have been defined that are not to be exceeded.
When the average values are not synchronized, the measuring results might not correspond
to the relevant energy requirements.
10.1.4
Acknowledgment of alarms
In most applications, configured alarms that occur in the event of an error in the application
are self-acknowledging. After the error status has been restored to the normal status
(operation) of the applications, the alarm message disappears again.
You can save an error status in the application until it is manually reset via the digital input.
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10.2
Digital output
The digital output complies with IEC 61131-2 Type 3. It can be configured via the web server
or the Modbus communication interface.
Navigation on the web
server
“Settings, Digital output”
Figure 10-12
Menu: “Settings, Digital output”
Status
The “Status” area shows the current status of the digital output.
Identifier
The identifier can be used to assign a user-specific designation to the digital output.
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Idle level
There are two possible statuses for the idle level.
– NC: Normally closed
– NO: Normally open
The default setting for the digital output is NC (normally closed).
Only one function can be configured at a time.
– Impulse
– Device status
– Manual
– Alarm
– Rotary field direction
– Deactivated
The digital output is deactivated by default.
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10.2.1
Navigation on the web
server
Impulse
“Settings, Digital output”, “Impulse” function
Figure 10-13
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Menu: “Settings, Digital output”, “Impulse” function
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�Functions
With the “Impulse” function, the following electrical parameters can be transmitted to a
higher-level evaluation unit:
– Active energy (positive, negative)
– Reactive energy (positive, negative)
– Apparent energy
Other configuration parameters are:
Valency
The impulse corresponds to the set value.
The valid value range is 0.01 … 655.35 in kWh.
Impulse duration
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The valid value range is 30 … 900 in ms.
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10.2.2
Device state
The “Device state” function can be used to check whether the device is on or off.
Here, it is also possible to define whether the output is normally closed (NC) or normally
open (NO) in idle state.
Navigation on the web
server
“Settings, Digital output”, “Device state” function
Figure 10-14
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Menu: “Settings, Digital output”, “Device state” function
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�Functions
Status
The “Status” area shows the current status of the digital output.
Identifier
The identifier can be used to assign a user-specific designation to the digital output.
Idle level
There are two possible statuses for the idle level.
– NC: Normally closed
– NO: Normally open
The default setting for the digital output is NO.
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10.2.3
Manually
With the “Manually” function, the digital output can be enabled and disabled via the Modbus
communication interface. Here, you also have to define whether the output is normally
closed (NC) or normally open (NO) in idle state.
Navigation on the web
server
“Settings, Digital output”, “Manually” function
Figure 10-15
Menu: “Settings, Digital output”, “Manually” function
Status
The “Status” area shows the current status of the digital output.
Identifier
The identifier can be used to assign a user-specific designation to the digital output.
Idle level
There are two possible statuses for the idle level.
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�Functions
–
–
NC: Normally closed
NO: Normally open
The default setting for the digital output is NO.
10.2.4
Alarm
The “Alarm” function can be used to react to changes to the measurement values.
You can define upper and lower thresholds for the domain.
If the measured values are outside of these thresholds, the alarm function is activated and
sent via the digital output.
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Navigation on the web
server
Menu: “Settings, Digital output”, “Alarm” function
Figure 10-16
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Menu: “Settings, Digital output”, “Alarm” function
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�Functions
Status
The “Status” area shows the current status of the digital output.
Identifier
The identifier can be used to assign a user-specific designation to the digital output.
Idle level
There are two possible statuses for the idle level.
– NC: Normally closed
– NO: Normally open
Function
Select the “Alarm” function.
Navigation on the web
server
“Settings, Alarm”
Figure 10-17
Status
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Menu: “Settings, Alarm, Status”
The “Status” area shows the current status of the alarms.
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Settings
Set the alarm according to your requirements.
Figure 10-18
Menu: “Settings, Alarm”
Confirm with digital input
You can use the checkbox to define that manual acknowledgment of an alarm is required.
The acknowledgment is performed via the digital input, which has to be configured for this
purpose.
Identifier
The identifier can be used to assign a user-specific designation to the alarms.
Alarm 1…4
You can use the four tabs to define the alarm configuration for each alarm.
Data source
Select the measurement value to be monitored.
High limit and low limit
Use the checkbox to select the monitoring function. Depending on which function you selected, enter the value to be monitored.
Delay
Enter the tripping delay for the alarm in seconds.
Hysteresis
For the switching threshold, a hysteresis in percent is required. Enter it here.
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�Functions
Self-cleared
With this checkbox, you can define that the alarm self-acknowledges after the normal status
has been restored. This way, no manual acknowledgment via the digital input is required.
The integrated logic gate enables multiple use of the digital output for the alarm function.
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10.2.5
Rotary field direction
The recognition of the rotary field direction is used to inform the digital output about the state
of the application. The rotary field direction can be configured for both directions (left, right).
Navigation on the web
server
“Digital output, Settings, “Rotary field direction” function
Figure 10-19
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Menu: “Digital output, Settings, “Rotary field direction”
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Status
The “Status” area shows the current status of the alarms.
Settings
Set the alarm according to your requirements.
Identifier
The identifier can be used to assign a user-specific designation to the function.
Idle level
There are two possible statuses for the idle level.
– NC: Normally closed
– NO: Normally open
The default setting for the digital output is NO.
Function
Select the “Rotary field direction” function from the drop-down menu.
Rotary field direction
Select the appropriate rotary field direction.
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10.2.6
Deactivating the digital output
The digital output can be deactivated, so that no function is assigned to it.
Navigation on the web
server
“Digital output, Settings“, “Deactivated” function
Figure 10-20
Menu: “Digital output, Settings“, “Deactivated” function
Status
The “Status” area shows the current status of the digital output.
Settings
Set the digital output according to your requirements.
Identifier
The identifier can be used to assign a user-specific designation to the function.
Idle level
There are two possible statuses for the idle level.
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–
–
NC: Normally closed
NO: Normally open
The default setting for the digital output is NO.
Function
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Select the “Deactivated” function from the drop-down menu.
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10.3
Navigation on the display
Tariff selection
“Tar, Tariff meter 1...4“
Figure 10-21
Menu: “Tar, Tariff meter”
Figure 10-22
Menu: “Tar, Tariff meter 1”
The device offers various options for selecting between up to 4 tariffs. The following
procedures are possible:
– Using the digital input: 2 tariffs can be used
– Using manual switching via a communication interface: 4 tariffs can be used
– Using a time schedule: 4 tariffs can be used
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10.3.1
Tariff selection via the communication interface
The individual tariffs can also be selected via the Modbus communication interface. With
the addresses in the register tables, a user-specific usage of all tariff meters can be defined,
which is configured completely by means of the controller.
Navigation on the web
server
“Tariffs, Settings”
Figure 10-23
Menu: “Tariffs, Settings”
Status
The “Status” area shows the current status of the tariff function.
Settings
Configure the tariff selection according to your requirements.
Identifier
Define the designations for your tariffs.
Mode
Set the mode to “Manually”.
Tariff meter
Select the desired tariff from the drop-down menu.
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10.3.2
Tariff selection using a time schedule
The individual tariffs can also be selected by using time control. A custom application can
be configured using a configurable time.
The switchover to the respective tariff meter thus purely depends on the time.
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Navigation on the web
server
“Tariffs, Settings”
Figure 10-24
Menu: “Tariffs, Settings”
Status
The “Status” area shows the current status of the tariff function.
Settings
Configure the tariff selection according to your requirements.
Identifier
Define the designations for your tariffs.
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Mode
Set the mode to “Time controlled”.
Tariff meter
Select the desired tariff from the drop-down menu.
Depending on the number of tariffs, you can configure the individual tabs for the tariffs.
Days
Use the checkboxes to select the days of the week.
From/Until
Enter the times for using the tariffs as appropriate for your application.
In the appendix, the configured weekdays and times are shown.
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10.4
Logic gate
The integrated logic gate makes it possible to define several alarm messages for the alarm
function of the digital output. The digital output can be used for this type of multiple
assignment, depending on up to four alarms/thresholds.
Navigation on the web
server
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“Digital output, Settings”, “Alarm” function
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Figure 10-25
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Menu: “Settings, Digital output”, “Alarm” function
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Alarm 1…4:
Select the alarms that are to be linked to the logic gate. You can use the checkbox to invert
the signal.
Logic gate
An operator has to be defined for the function of the logic gate.
Select a logic operator from the drop-down menu:
– AND
– OR
– XOR
– NAND
– NOR
– NXOR
The alarms themselves are configured via “Settings, Alarms”.
Function description of the logic gate
The logic gate links configured statuses of the respective alarms with an assigned logic
function. Various application-specific statuses can be monitored, depending on how the
connections are combined.
Below, you can find explanations on how the logic operators work:
AND operator
Figure 10-26
Logic gate with AND operator
When all alarms are active at the same time, this signal output is set.
If one of the alarms is no longer active, the signal output is reset.
NAND operator
Figure 10-27
Logic gate with NAND operator
When none of the alarms are active, this signal output is set.
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If one of the alarms is active, this signal output is reset.
OR operator
Figure 10-28
Logic gate with OR operator
When one of the alarms is active, the signal output is set.
If none of the alarms are active, this signal output is reset.
NOR operator
Figure 10-29
Logic gate with NOR operator
When none of the alarms are active, this signal output is set.
If one of the alarms is active, this signal output is reset.
XOR operator
Figure 10-30
Logic gate with XOR operator
If an alarm is active, this signal output is set.
If none or several of the alarms are active, this signal output is reset.
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NXOR operator
Figure 10-31
Logic gate with NXOR operator
If none or several of the alarms are active, this signal output is set.
If only one of the alarms is active, this signal output is reset.
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10.5
Data logging
Figure 10-32
Status
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Menu: “Logging“
The “Status” area shows an overview of the current logging data.
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Figure 10-33
“Menu: Logging, Settings”
Log 1...8
Here, you can configure up to eight different logging parameters.
Data source
Select the desired electrical parameter from the drop-down menu for the logging.
Interval
Enter the interval time in minutes. The shortest duration that can be set is 1 minute.
The maximum logging duration depends on the configured interval. For an interval of 15
minutes, the logging capacity is approx. 90 days. If you shorten the interval, the logging
capacity is also reduced (e.g., 10 minute interval/60 days logging capacity).
Circular buffer
If you want to use the FIFO principle (first-in/first-out) for the data logging, activate the
circular buffer.
If you want to define a fixed starting point, deactivate the circular buffer.
The logging automatically stops once the memory is full.
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Figure 10-34
Menu: “Logging, Saved data”
You can view all configured logging data as a chart in the web server.
To do so, select the desired logging data from the drop-down menu.
With your mouse, you can zoom in on the saved data.
By means of the selection box to the right next to the chart, you can export the logging data
as CSV, XLS or PDF file.
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10.6
Firmware update
The device provides a function for updating the firmware. New versions can contain bug
fixes, optimize the performance and expand the functionality.
Update files are provided by Phoenix Contact GmbH & Co. KG. The respective update
containers can be downloaded from the product-specific pages at phoenixcontact.com.
10.6.1
Execution
Figure 10-35
Firmware update
Execution of a firmware update
In this area, you can load a new firmware update onto the device. To perform the update,
you need administrator rights.
An update can only be performed via the web server of the device.
File
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Upload the new firmware file. Click the “Upload” button to begin the process.
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Figure 10-36
Progress and state
Progress and state
Once the firmware file has been uploaded, you can start the update on the device by clicking
“perform update”.
Observe the following when performing a firmware update:
– The update process can take several minutes and should not be interrupted.
– Do not exit the subpage for updating the firmware of the web-based management.
– During the update process, the device restarts and is thus unavailable for a certain
period of time.
– During certain steps of the update process, it is possible that the energy meters of the
system are stopped.
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10.6.2
Security
Executing a firmware update requires read access to the system. Since execution is only
possible via the web server, the access is password-protected.
The update file is protected against manipulation. The system detects and rejects
manipulated update files.
The update process is safeguarded against unintentional interruption or failure. An
executable firmware version is always retained on the system.
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11 Communication
All devices are equipped with an Ethernet interface with an RJ45 socket.
Other communication interfaces can also be available optionally.
– RS-485
– PROFINET
– EtherNet/IP™
X1
Figure 11-1
Table 11-1
X1
Modbus/TCP
Write and read access
All devices are equipped with an integrated Ethernet interface (X1) with an RJ45 socket.
The device configuration is performed via this Ethernet interface.
Other communication interfaces can also be available optionally.
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Modbus/RTU via RS-485
EMpro
RS-485
1
U12
U23
U31
400,0v
400,0v
400,0v
2
3
4
X1
Figure 11-2
Table 11-2
X1
Modbus/TCP
Write and read access
RS-485
Modbus/RTU
Write and read access
The device configuration can be implemented via the Modbus/RTU interface (RS-485) or
via the integrated Ethernet interface.
PROFINET
X2
X3
X1
Figure 11-3
Table 11-3
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X1
Modbus/TCP
Write and read access
X2
PROFINET
Read access
X3
PROFINET
Read access
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The Ethernet interfaces (X2 and X3) do not offer any options for device configuration and
can therefore not be reached via the display or the web server.
The interfaces only offer a read function for the data via the dual ports (2xRJ45).
The associated IP addresses are assigned accordingly via the controller.
You can use both communication protocols with only one Ethernet cable. To do so, bridge
Ethernet interfaces X1 and X3. Via the Ethernet interface X2, both protocols (Modbus/TCP
and PROFINET) can now be used in parallel.
EtherNet/IP™
X2
X3
X1
Figure 11-4
Table 11-4
X1
Modbus/TCP
Write and read access
X2
EtherNet/IP™
Read access
X3
EtherNet/IP™
Read access
The Ethernet interfaces (X2 and X3) do not offer any options for device configuration and
can therefore not be reached via the display or the web server.
The interfaces only offer a read function for the data via the dual ports (2xRJ45).
The associated IP addresses are assigned accordingly via the controller.
You can use both communication protocols with only one Ethernet cable. To do so, bridge
Ethernet interfaces X1 and X3. Via Ethernet interface X2, both protocols (Modbus/TCP
and EtherNet/IP™) can now be used in parallel.
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11.1
Ethernet
All device versions are Ethernet-capable via an RJ45 interface. The devices support
10/100 Mbit full/half duplex. It is recommended to use at least Cat.5 cables (EIA/TIA-568).
11.1.1
IP addressing
The EMpro devices can be assigned both a static and a dynamic IP configuration.
Current devices support IPv4.
In the delivery state, the devices use a static IP configuration with the following parameters:
Table 11-5
IP address
192.168.1.2
Subnet mask
255.255.255.0
Default gateway
0.0.0.0
DNS server
0.0.0.0
The entry IP 0.0.0.0, e.g., for the default gateway, indicates that no default gateway has
been configured.
When the dynamic IP assignment is used, the device receives its IP configuration via the
DHCP protocol from another DHCP server in the same network.
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11.1.2
Configuration of the communication interface
You can adapt the following parameters of the network interface:
Table 11-6
Function
Information
Mode
The mode is used to define whether a static IP configuration from the device memory has to be used,
or a dynamic configuration should be performed via
DHCP instead.
Web server
x
Display
x
Register
x
IP address
This setting is only used in static mode. Here, the
static IP address of the device is configured. In dynamic mode, this parameter is supplied by the
DHCP server.
x
x
x
Subnet mask
This setting is only used in static mode. Here, the
static subnet mask of the device is configured. In
dynamic mode, this parameter is supplied by the
DHCP server.
x
x
x
Default gateway
This setting is only used in static mode. Here, the
static IP address of the default gateway to be used
is configured. In dynamic mode, this parameter is
supplied by the DHCP server. The default gateway
is required to allow communication across network
boundaries. This is defined by means of the subnet
mask.
x
x
x
DNS server
This setting is only used in static mode.Here, the
static IP address of the DNS server to be used is
configured. In dynamic mode, this parameter is
supplied by the DHCP server. The DNS server is
used to perform name resolutions, e.g., for an NTP
time server.
x
x
x
Device name
The device supports the NetBios name service.
With this protocol, the device can be addressed
using a host name, without knowing the IP address
of the device. The device has three NetBios names.
Two of these names are manufacturer-specific and
cannot be modified. You can change the third
name. The following names have been defined:
x
x (read only)
x
First manufacturer-specific NetBios name: (e.g., EEM-MA770)
Second manufacturer-specific NetBios name:
eem (e.g.,
eem1234567890)
User-specific NetBios name: (default: )
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11.1.3
Status of the communication interface
If the network interface is ready, this is indicated by the
icon on the display.
The following conditions must be met for the network interface to be ready:
– Device start completed
– Network link established
– IP configuration valid
– Always true for static configurations
– True for dynamic configurations after the IP configuration has been received by the
DHCP server
The current status of the network interface can be viewed via the WBM, the display and
Modbus.
There are two LEDs at the RJ45 socket:
– Green LED for link status, to the left of the RJ45 connector
– Green LED for sending activity, to the right of the RJ45 connector
11.1.4
Security
The users are responsible for securing their networks against unauthorized access.
Up to four clients can access the interface simultaneously.
11.2
11.2.1
Modbus
Function
The Modbus protocol defines both a protocol on the application layer and a transmission
protocol. The application layer protocol is identical for all interface versions. The differences
between Modbus/TCP and Modbus/RTU lie in the transmission protocol.
On the application layer, Modbus supplies a 16-bit address space that can be used to
address 16-bit registers. Using various function codes, read and write operations can be
performed on registers.
For detailed information about the Modbus specification refer to www.modbus.org/.
The EMpro supports the following function codes:
– 03 (0x03) Read holding registers
– 04 (0x04) Read input registers
– 06 (0x06) Write single register
– 16 (0x10) Write multiple registers
Here, it has to be noted that the device does not differentiate between holding and input
registers. Both function codes return the same registers.
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11.2.2
Modbus/RTU
In the case of Modbus/RTU, the Modbus application layer protocol is supplemented with
additional information and physically sent via an RS-485 interface. The start and end of a
Modbus message is coordinated by means of timings.
Modbus/RTU describes a master/slave protocol. Here, the EMpro acts as Modbus/RTU
slave. An exception here is the gateway mode.
The additional information consists of a byte for addressing the device. Valid device
addresses are in the range from 1-247.
The default setting for the devices is address 1. Address 0 is reserved for broadcast
messages in the network and cannot be assigned as an address to a device.
According to the specification, addresses 248-255 are reserved and cannot be assigned to
the device either.
A cyclic redundancy check (CRC) is attached to the Modbus message as additional
information. The CRC is used to detect transmission errors. The calculation and the
polynomial used are documented in the Modbus specification.
The Modbus/RTU protocol is supported by all EMpro versions with an RS-485 interface.
11.2.2.1
Topology
The smallest network via RS-485 (Modbus) that makes sense consists of two devices:
– 1 x master 1 x slave
The typical limit is 32 devices.
– 1 x master 31 x slaves
The largest network via RS-485 (Modbus) that makes sense consists of 248 devices,
because of the addressing:
– 1 x master 247 x slaves
Figure 11-5
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Topology
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11.2.2.2
Using connections and designations
Internal
GND
BΩ
A+
Ω
Figure 11-6
Connections and designations
The RS-485 interface has four assigned terminals.
GND:
Shield of signal line
B- and A+:
Signal lines
Ω:
120 Ω resistor
The non-inverted signal can have the following designations: A, +, A+, TxD+/RxD+, D+
The inverted signal can have the following designations: B, -, B-, TxD-/RxD-, D-
To ensure that the communication is guaranteed even in the event of malfunctions, ensure
that the following conditions are met in the RS-485 network:
– Twisted pair conductors (A and B) (stranding)
– Shielded conductors (GND)
– Termination resistors (and a bias network)
NOTE: If you want to activate the integrated 120 Ω resistor, bridge the terminals Ω and A+.
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11.2.2.3
Figure 11-7
Status
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Parameters for using Modbus via RS-485
Modbus status
The “Status” area gives an overview of the current Modbus configuration.
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Figure 11-8
Modbus settings
Please observe the following:
– Each slave is assigned an address between 1 and 247.
– Each address is used only once.
– There is only one master per RS-485 network.
– All devices use the same parameters for the baud rate, stop bits and parity.
You can configure the following parameters that are supported by the RS-485 interface:
– Baud rates: 2400, 4800, 9600, 19200, 38400, 57600 and 115200 bps
– Stop bits: 1, 2
– Parity: even, odd, none
The parameters can also be set via Modbus/TCP.
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11.2.3
Modbus/TCP
In the case of Modbus/TCP, a special header (Modbus Application Header [MBAP]) is
prefixed to the Modbus header. This Modbus/TCP message is then transmitted via an IPbased network in a TCP frame.
The EMpro acts as Modbus/TCP server and opens port 502 for communication with any
Modbus/TCP clients. This port cannot be configured by the user.
Since TCP is a connection-oriented protocol, a client first has to establish a TCP connection
with the EMpro to exchange data via Modbus/TCP.
The number of Modbus/TCP connections that can be open in parallel on each version of the
EMpro product family is limited to four.
If there are already four open Modbus/TCP connections on the EMpro, additional
connection queries on port 502 are rejected.
Additionally, to enable Modbus/TCP communication, the user has to make sure that this
port is enabled in the network.
The MBAP contains a field that is declared as unit identifier in the specification. This unit
identifier is comparable with the device address of Modbus/RTU. However, it is not relevant
for the EMpro in the case of Modbus/TCP and is ignored by the device since the address
already has a unique address in a network through its IP address. An exception applies if
the device is operated in gateway mode (see Section “Modbus gateway” on page 145).
The Modbus TCP specification recommends using 255 as unit identifier for queries.
All EMpro versions support the Modbus TCP protocol.
11.2.4
Modbus gateway
EMpro versions with an RS-485 interface can optionally be operated in gateway mode.
By default upon delivery, the gateway mode is not active. In this case, the device acts as
Modbus TCP server on the Ethernet interface and as Modbus/RTU slave on the RS-485
interface.
When the gateway function is activated, the device behaves as Modbus gateway on the
Ethernet interface and, in parallel, continues to operate as Modbus TCP server (can be
reached via unit identifier == 255).
On the RS-485 interface, the device now acts as Modbus/RTU master. As master, the
EMpro can now independently send queries in the network (note: there must be no other
master in the system).
As Modbus gateway, the device converts an incoming Modbus TCP message (that does
not have the unit identifier 255 in the MBAP header) into a Modbus RTU message and
forwards it to the appropriate receiver in the Modbus RTU network. On the TCP side,
the unit identifier is used for addressing the Modbus RTU receiver. In turn, the response is
converted from Modbus/RTU format back to Modbus/TCP format and is sent to the
querying client as Modbus/TCP response.
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Broadcast messages in gateway mode
The Modbus specification does not describe the behavior of a gateway device when the unit
identifier in the MBAP header has a value of 0. In the Modbus/RTU network, this value
represents a broadcast message.
There are different interpretations of the behavior of a gateway in this case.
The following questions regarding the behavior of a gateway remain open:
– Forwarding the broadcast in the RTU network.
Since there is no broadcast in the case of Modbus/TCP, it is not defined whether or not
the MBAP address 0 is forwarded in the RTU network by the Modbus gateway.
– Response messages with the unit identifier 0.
Neither is there a definition on whether the gateway itself generates an answer to
messages with a unit identifier of 0.
By default upon delivery, devices of the EMpro product family behave as follows:
The EMpro does not forward messages with unit identifier 0 to the RTU network as
broadcast. Furthermore, the EMpro itself responds to the query as Modbus TCP server.
Timing in gateway mode
As gateway, the EMpro acts as Modbus master on the Modbus/RTU side and forwards
queries to the addressed slaves.
As Modbus/RTU master, the device requires a time-out for queries. If this time-out has
expired without a response from the Modbus/RTU slave, the gateway replies to the
Modbus/TCP client with an error message.
By default upon delivery, the duration for the time-out is 250 ms.
Unsuitable time-out settings both at the gateway and and at the querying Modbus/TCP
client can cause unwanted problems.
Problems can occur if the time-out times at the Modbus/TCP client or EMpro in gateway
mode are too short, or if the ratios between these two time-out times are unfavorable.
The time-out setting has to be individually configured based on the application.
Nevertheless, the following recommendation can be given; they should work in normal
cases.
– The default setting of the EMpro is adequate for most applications.
– If there are slaves with slow response times in the RTU network, the time-out setting of
the gateway should be increased.
– If very slow Baud rates are used on the RS-485, the time-out setting of the gateway
should be increased.
– The time-out duration of the querying Modbus/TCP client should always be longer than
that of the gateway.
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11.3
PROFINET
11.3.1
1.
2.
Software
Check whether the firmware of your energy measuring device is up to date with the
firmware available on the Phoenix Contact homepage. If the firmware is not up to date,
download the current firmware from the specific product site at phoenixcontact.com
(see Section “Firmware update” on page 131).
Download the current GSDML file for your energy measuring device from the Phoenix
Contact website.
Additional requirements:
– Pertinent knowledge of the preferred PROFINET engineering system
– Executable project with configured controller
11.3.2
1.
Preparing the GSDML file
Unpack the ZIP file on your file system.
11.3.3
Integrating the GSDML file
Integrate the GSDML file into your existing engineering system.
An example of the integration is shown below, using the TIA portal V15.
1.
Select “Options, Manage general station description files (GSD)”.
Figure 11-9
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“Options, Manage general station description files (GSD)”
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2.
3.
4.
Select the file that you want to install.
Checkmark the file that you want to install.
Click on “Install”.
Figure 11-10
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Installing the station description file
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The dialog shows that installation has been successful.
5. Close the window by clicking “Close”.
Figure 11-11
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Dialog: “Manage general station description files”
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11.3.4
1.
Integrating hardware
Create a project with any PROFINET-capable controller.
Figure 11-12
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“Devices & networks” in the network view
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2.
Select “Devices & networks, Network view, Hardware catalog, Other field devices,
PROFINET IO , Sensors, Phoenix Contact, EMpro“ and select your installed EMpro
(e.g., EMM-MB371-PN).
Figure 11-13
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Selecting the EMpro from the hardware catalog
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3.
Drag and drop the EMpro from the hardware catalog to the network view.
Figure 11-14
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Adding EMpro to network view
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The EMpro appears in the network view.
Figure 11-15
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EMpro in the network view
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4.
5.
Right-click on the EMpro in the network view.
Select “Assign to new IO controller“.
Figure 11-16
6.
7.
Assigning an I/O controller to the EMpro
Select the desired network interface.
Confirm with “OK”.
Figure 11-17
Selecting the I/O controller
The assignment has now been set up.
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Figure 11-18
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Networking controller and energy measurement device
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11.3.5
1.
2.
3.
Integrating modules and submodules
In the structure tree, switch to the “Device configuration” view.
In the hardware catalog, mark the desired module.
Drag and drop it to the device overview.
Figure 11-19
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Adding a module to the device overview
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Subsequently, the associated submodules appear in the catalog.
Figure 11-20
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Submodules in the hardware catalog
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4.
5.
Select the desired submodules.
Add the submodules under the respective main module using drag-and-drop.
Figure 11-21
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Inserting submodules
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The device overview shows the available modules and submodules.
Figure 11-22
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Available modules and submodules
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6.
Select a configured submodule in the device overview.
If you are a Siemens user, refer to the register table for the respective energy measuring
device for descriptions of the individual process data, which can be downloaded at
phoenixcontact.net/products .
Figure 11-23
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Selecting a submodule in the device overview
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11.3.6
1.
2.
Linking process data
Create PLC variables with unique designations.
Connect these with the I/O variables.
Figure 11-24
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Creating PLC variables and connecting them with I/O variables
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11.3.7
1.
2.
Assigning a device name
Right-click on the device to which you want to assign a name.
Select “Assign device name”.
Figure 11-25
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“Assign device name”
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3.
Click “Update list”.
Figure 11-26
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“Update list”
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4.
5.
Select the device from the table.
Click “Assign name”.
Figure 11-27
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“Assign name”
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The device name has been assigned successfully.
Figure 11-28
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Assigning a PROFINET device name
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Figure 11-29
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Assigning a PROFINET device name
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11.3.8
Function check
You can perform a function check by creating a monitoring table for viewing the online
values.
1. Compile the project.
2. Load it onto your controller.
3. Connect to the controller.
4. To perform a function check, switch to online mode and activate the monitoring by
clicking on the glasses icon.
Figure 11-30
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Monitoring table
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11.4
Configuration
11.4.1
Modbus/RTU
Table 11-7
Function
Information
Activation of
Modbus/RTU
The Modbus/RTU protocol is
activated by default, but can be
deactivated by the user.
x
x
x
Modbus address
The default setting is address
1.
x
x
x
Baud rate
The default setting for the RS485 interface is 19200 bps.
x
x
x
Stop bits
The default setting for the RS485 interface is 1 stop bit.
x
x
x
Parity
The default setting for the RS485 interface is even parity.
x
x
x
11.4.2
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Register
Modbus/TCP
Table 11-8
Modbus/TCP
Function
Information
Activation of
Modbus/TCP
The Modbus/TCP protocol is
activated by default, but can be
deactivated by the user.
11.4.3
Web server Display
Web
server
x
Display
x
Register
x
Modbus gateway
Table 11-9
Modbus gateway
Function
Information
Activation of
the gateway
mode
By default, the gateway mode
is deactivated.
Modbus gateway time-out
The default setting is address
250 ms.
Web
server
x
Display
x
Register
x
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11.5
Safety
On most registers, write commands are PIN-protected. To change register values, the
correct PIN is required. The PIN corresponds to the display PIN.
The PIN can be changed by the user.
To prevent unauthorized write access to the device, change the default PIN during initial
commissioning of the device.
Table 11-10
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PIN
Function
Information
PIN change
The default PIN is 0100.
Web
server
Display
Register
x
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x
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11.6
Data types and registers
The Modbus specifications does not include requirements on how various data types are to
be displayed on the respective register.
The specification only defines that the register has to be represented as “big endian”. This
means that the high byte of a register is sent first, followed by the low byte.
8-bit integer types:
Example: Value = 1 (0x01)
Table 11-11
8-bit integer types
Register address
Register contents (hex)
n
0x0001
16-bit integer types:
Example: Value = 4660 (0x1234)
Table 11-12
16-bit integer types
Register address
Register contents (hex)
n
0x1234
32-bit integer types:
Example: Value = 305419896 (0x12345678)
Table 11-13
32-bit integer types
Register address
Register contents (hex)
n
0x5678
n +1
0x1234
32-bit IEE 754 floating point:
Example: Value = 123.456 (0x42F6E979)
Table 11-14
32-bit IEE 754 floating point
Register address
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Register contents (hex)
n
0xE979
n +1
0x42F6
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ASCII strings:
Example: Value = EEM-MA (0x45, 0x45, 0x4D, 0x2D, 0x4D, 0x41, 0x33, 0x37, 0x30 ->
ASCII coded)
Table 11-15
ASCII strings
Register address
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Register contents (hex)
n
0x4545
n +1
0x2D4D
n +2
0x414D
n +3
0x3733
n +4
0x0030
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11.7
Register table
The register table is available for download from the Phoenix Contact website.
1. Open phoenixcontact.net/products.
2. Enter the order number of your energy measuring device into the search field.
3. In the download area of the product, you will find the register table under
“Miscellaneous”.
11.8
Contents of the register table
The register table contains information that concerns the contents and functions of the
communication interfaces.
The register table encompasses the entire Modbus register.
To get the PROFINET-specific register, filter the empty cells from the “GSDML Module
Name” column, so that only cells that are filled with content remain.
11.9
Description of the register table
Figure 11-31
Register table
Content of the line (CH)
The first line of the register table contains information about the content of the respective
line or column.
H1… Hn: Heading
An“H” with a number indicates a heading. The number behind it indicates the hierarchical
level.
To keep the register entries structured and readable, they are divided by headings.
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R: Register
The “R” stands for Register and designates the lines that each describe a register.
Only lines that also contain registers are relevant for automatic processing of the register
table.
U: Unused
The “U” describes unused entries. These can be ,e.g., address ranges that do not have a
function (yet) and are reserved.
E: End
The “E” describes the end of the table.
Dec: Decimal address
The second column of the register table contains register addresses in decimal form.
Hex: Hexadecimal address
The third column of the register table contains register addresses in hexadecimal form.
Count
The “Count” column displays the number of registers required for the function described in
this line. The required number is directly dependent on the data type.
Short designation
The “Short designation” column contains the abbreviated designations of the registers. The
short designations are unique, so that all other data can be referenced using the short
designations.
Unit
The unit for the process values is given in the “Unit” column. For example, the unit for the
voltages is volt [V].
Divider
The “Divider” column states the divider by which the value is to be divided to get the correct
value. This is necessary, e.g., if the data type is an integer value, but a decimal fraction has
to be entered.
Example:
If the harmonics are specified as percentage with signed integer, but have to be output with
a precision of a tenth of a percent. In this case, for example, 15.2% is used as 152 with
divider 10.
R/W: Read/write access
This column specifies which access is permitted for the respective register.
R: Read only
This register can only be read. Attempting write access to this register causes an error.
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R/W: Read and write
It is possible to both read and write to this register.
W: Write only
This register can only be written. Attempting read access to this register causes an error.
W/R0: Write only and read 0
This register can only be written. Read access to this register results in a zero as response.
Data type
This column contains the data type to be used for decoding the contents of each respective
register.
ASCII
Each register (16 Bit) contains two ASCII characters. When the number is entered, the
number of individual registers contained in the character string is determined.
Example:
Dec:1234567
Hex: 0X31, 0X32, 0X33, 0X34, 0X35, 0X36, 0X37
Zero-terminated: “12345670”
Hex: 0X31, 0X32, 0X33, 0X34, 0X35, 0X36, 0X37, 0X00
Number of registers = 4: Hex: 0X3231, 0X3433, 0X3534, 0X0037
Bit mask
Each bit (bit 15-bit 0) of the register (16 bit) is evaluated individually.
Example: “Resetting the tariff meter”
Bit 0: Reset tariff 1
Bit 1: Reset tariff 2
Bit 2: Reset tariff 3
Bit 3: Reset tariff 4
An individual tariff meter, or any combination of meters from all tariff meters can be reset.
Bool
This data type makes a logical statement.
0: false
1: true
Fl32
IEEE-754-single number 1.8.23 (32 bits, two 16-bit registers):
1 sign bit: positive and negative
8 exponent bits:≈ value range of 38 decimal places
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23 mantissa bits ≈ precision of 6 decimal places
Decimal value range: ±1.175·10-38 to 3.40282·10+38
Register in float
32-bit value from the registers: 0X41340000 = 01000001 00110100 00000000 00000000b
Bit31 = 0: SB, sign bit. This number is positive.
Bit30 - Bit23: E, exponent. In this case: 130.
Bit22 - Bit0: M, mantissa. Here it is 3,407,872.
Z = 11.25
Float in register
Floating-point number X = 11.25
SB, sign bit. This number is positive => Bit31 = 0 / 0X00 / 0b
In this case 130 => Bit30 - Bit23 = 130 / 0X82 / 10000010b
mantissa. Here it is 3,407,872 => Bit22 - Bit0 = 3407872 / 0x340000 / 0110100 00000000
00000000b
32-bit value for the register: 0X41340000 = 01000001 00110100 00000000 00000000b
SInt16
Signed integer:
2 byte, 16 bit
Value range: -215 … 215-1
-32,768 … 32,767
UInt16
Unsigned integer:
2 byte, 16 bit
Value range: 0 … 216-1
0 … 65,535
UInt32
Unsigned integer:
4 byte, 32 bit
Value range: 0 … 232-1
0 … 4294967295
SInt32
Signed integer:
4 byte, 32 bit
Value range: -231 … 231-1
-2147483648 … 2147483647
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UInt8
Only the low byte of the register is evaluated.
1 byte, 8 bit
Value range: 0 … 28-1 = 0 … 255
UInt[]
Array of UInt8 values. Their order follows that of the ASCII registers.
These data types are used, e.g., for the MAC addresses.
Three registers are required for the six bytes.
E.g., 00:A0:45:66:4F:41
Name
Here, the name of the respective register is entered. It may be longer than the short
designation, so that it is readable and expresses the function of the register.
Description
In this column, the function of the register is described in detail.
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�Technical data
12 Technical data
Technical data
General data
Measuring principle
True r.m.s. value measurement (TRMS) up to 63rd harmonic
Measurement value
AC sine
Nominal frequency
50/60 Hz
Frequency range
45 ... 65 Hz
Sampling rate
256 times the signal frequency:
12800 Hz @ FSignal = 50 Hz
15360 Hz @ FSignal = 60 Hz
Degree of protection
IP20 (housing)
IP40 (display)
Dimensions
Width / height / depth
EEM-MB37x(-PN, -EIP [with PN/EIP socket]):
90 mm x 80 mm x 82 mm
EEM-Mx37x(-R):
90 mm x 80 mm x 64 mm
Voltage measurement
Input measuring range, direct
18 V AC ... 690 V AC (Ph/Ph)
11 V AC ... 400 V AC (Ph/N)
Input measuring range using transformer
Primary
60 V AC ... 2,000,000 V AC
Secondary
60 V AC ... 400 V AC
Power consumption
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