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TRANSCRIPT
Premium Altivar IclA Magelis
System User Guide [source code]
3300
3774
.01
Mar 2006
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Contents Application Source Code ...................................................................................................... 3 Typical Applications.............................................................................................................. 3 System................................................................................................................................... 4
Architecture ..................................................................................................................... 4 Installation ....................................................................................................................... 7
Hardware ............................................................................................................................................... 9 Software ...............................................................................................................................................24 Communication ....................................................................................................................................26
Implementation .............................................................................................................. 32 Communication ....................................................................................................................................34 HMI .......................................................................................................................................................65 PLC.......................................................................................................................................................86 Devices.................................................................................................................................................98 Performance .......................................................................................................................................103
Appendix ........................................................................................................................... 104 Detailed Component List ............................................................................................. 104 Component Protection Classes................................................................................... 108 Component Features ................................................................................................... 109
Contact .............................................................................................................................. 118
Introduction This document is intended to provide a quick introduction to the described System.
It is not intended to replace any specific product documentation. On the contrary, it offers additional information to the product documentation, for installing, configuring and starting up the system. A detailed functional description or the specification for a specific user application is not part of this document. Nevertheless, the document outlines some typical applications where the system might be implemented.
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Abbreviations
Word / Expression Signification AC Alternating Current Advantys SE product name for a family of I/O modules Altivar SE product name for a family of VSDs CB Circuit Breaker DC Direct Current EDS Electronic Data Sheet E-OFF Emergency-off switch Harmony SE product name for a family of switches and indicators HMI Human Machine Interface I/O Input/Output IclA (ICLA) SE product name for a compact drive Lexium/Lexium05 SE product name for a family of servo-drives Magelis SE product name for a family of HMI-Devices Micro SE product name for a middle range family of PLCs PC Personal Computer Phaseo SE product name for a family of power supplies PLC Programmable Logic Computer Powersuite An SE software product for configuring ALTIVAR drives Premium SE product name for a middle range family of PLCs Preventa SE product name for a family of safety devices PS Power Supply SE Schneider Electric Sycon SE product name of a Field bus programming software Telefast SE product name for a series of distributed I/O devices Tesys U SE product name for a decentralized I/O System (Small Terminal
Block) Twido SE product name of a middle range family of PLCs TwidoSoft SE product name for a PLC programming software Unity (Pro) SE product name for a PLC programming software Vijeo Designer An SE software product for programming Magelis HMI devices VSD Variable Speed Drive WxHxD Dimensions : Width, Height and Depth XBT-L1000 An SE software product for programming Magelis HMI devices
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Application Source Code
Introduction Examples of the source code and wiring diagrams used to attain the system function as
described in this document can be downloaded from our „Village“ website under this link.
Typical Applications
Introduction Here you will find a list of the typical applications, and their market segments, where
this system or subsystem can be applied: Industrial Large automated machine or plant components with decentralized machine
modules Remote automation systems used to supplement large and medium-sized
machines Machines Packaging systems Textile and printing machines Woodworking and metal working Food & Drug Filling lines
Application Description Image
Metal working This machine is used for bending sheet metal.
Woodworking machines This application cuts profiles in
the edges of wood panelling.
Filling machine As a component of a bottling
system, the bottles are aligned and filled.
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System
Introduction The system chapter describes the architecture, the dimensions, the quantities and different
types of components used within this system.
Architecture
General The control section of this application consists of a Premium PLC which can be operated via
a connected Magelis HMI panel at the user level. The machine section is implemented using an Altivar 31 variable speed drive and IclA compact drives which are connected to the PLC via the CANopen bus system. The remote control cubicle consists of the STB I/O platform, motor starters and an additional HMI terminal. A pre-assembled cable is used between the motor starters and I/O platform. The HMI is connected to the I/O platform directly via Modbus. The STB I/O platform and external FTB I/O modules communicate with the PLC via the CANopen bus. The solution illustrated below offers two optional safety packages: A Preventa evaluation unit featuring an emergency-off function that can be accessed via a tamper-proof emergency-off switch and a second evaluation unit of the same type which ensures door safety within the context of this application due to the use of door contact switches.
Layout
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Components Hardware:
Compact master switch (NSC100N) with undervoltage release Preventa safety relay XCS door-safety switch XALK locking-type emergency-off switch with rotary unlocking (tamper-proof) TeSys D motor contactor GV2-ME motor circuit-breaker (short-circuit and overcurrent protection) for the compact
drive’s power supply GV2-L motor circuit-breaker (short-circuit protection) for the variable speed drive Phaseo ABL7RP and ABL7UPS power supply units Altivar ATV31 variable speed drive with integrated CANopen interface Intelligent IclA compact drive with CANopen connection cable Modular TeSys U load contactors with parallel wiring module Advantys STB I/O platform with CANopen interface Advantys FTB I/O module with CANopen (IP67) Magelis XBT-G full-graphic display terminal and Magelis XBT-N text display terminal XALD pushbutton housing with control and signaling units and XVB signal beacon Premium PLC with CANopen card and Ethernet port Telefast terminal block Standard AC motors Software: Unity Pro XL V2.1 SyCon V2.9 Advantys Configuration Software V2.0 CANopen Symbol Tool V1.4 PowerSuite V2.0 Vijeo-Designer V4.20 XBT-L1000 V4.42
Quantities of Components
For a complete and detailed list of components, the quantities required and the order numbers, please refer to the components list at the rear of this document.
Degree of Protection
Not all the components in this configuration are designed to withstand the same environmental conditions. Some components may need additional protection, in the form of housings, depending on the environment in which you intend to use them. For environmental details of the individual components please refer to the list in the appendix of this document and the appropriate user manual.
Supply voltage 400 V AC Total supply output ~ 10 kW Speed drive rated powers 3x 0.18 kW Motor brake Not fitted AC motors 3x 0.37 kW Connector cross-section 5x 2.5mm² (L1, L2, L3, N, PE)
Technical Data
Safety category Cat. 3 (optional)
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Safety Note The standard and level of safety you apply to your application is determined by your
system design and the overall extent to which your system may be a hazard to people and machinery. As there are no moving mechanical parts in this application example, category 3 (according to EN954-1) has been selected as an optional safety level. Whether or not the above safety category should be applied to your system should be ascertained with a proper risk analysis. This document is not comprehensive for any systems using the given architecture and does not absolve users of their duty to uphold the safety requirements with respect to the equipment used in their systems or of compliance with either national or international safety laws and regulations
Dimensions The dimensions of the devices used (e.g., the PLC, variable speed drive and power
supply) are suitable for installation inside a control cabinet measuring 1600x600x300 mm (WxHxD). In addition, the display and control elements required to control the system can be integrated into the control cabinet door along with an emergency-off switch with an acknowledgement button.
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Installation
Introduction This chapter describes the steps necessary to set up the hardware and configure the
software required to fulfill the described function of the application.
Assembly
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Notes The purpose of configuring this application is to enable operation of the devices used.
The components and programs listed below represent a cross-section of the components required for the purposes of control and signal transmission. This document does not claim to be comprehensive and does not absolve users of their duty to check the safety requirements of their equipment and to ensure compliance with relevant national and international rules and regulations in this respect. Safety category 3, which is suggested here as one possible option, is not necessarily required/adequate for all applications. The safety category required is defined by a risk analysis which must be defined and verified for each individual system.
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Hardware
General The components designed for installation in a control cabinet (i.e., safety modules, line
circuit breakers, contactors, motor circuit-breakers, and Advantys STB I/O modules) can be snapped onto a 35 mm top-hat rail.
The master switch, Premium PLC, signal beacon, Phaseo power supply unit, and Altivar variable speed drive are screwed directly onto the mounting plate. If you are using the Altivar 31, these components can also be snapped onto a top-hat rail using an adapter.
The emergency-off and door-safety switches, as well as the housing for the display and acknowledge indicators, are designed for backplane assembly in the field. With the exception of the door-safety switch, all switches can also be installed directly in a control cabinet (e.g., in cabinet door) without their housings.
There are two options for installing XB5 pushbuttons or indicator lamps: These pushbuttons or switches can be installed either in a 22 mm hole, e.g., drilled into the front door of the control cabinet or in a type XALD housing suitable for up to 5 pushbuttons or indicator lamps. The XALD pushbutton housing is designed for both backplane assembly and direct wall mounting.
In the case of the Magelis terminals, a cut-out is required in the front of the housing in order to facilitate securing to the housing by means of brackets/spring clamps.
The IclA compact drive and IP67 I/O modules are mounted outside the control cabinet. 400 V/3~ wiring for load circuits (ATV, TeSys U) 240 V~ wiring for power supplies 24 V- wiring for control circuits and PLC power supply, display terminals, I/O modules,
HMI and compact drives The individual components must be connected in accordance with the detailed circuit diagram in order to ensure that they function correctly. CANopen cables are installed for the communication link between the PLC and the devices inside the control cabinet. CANopen bus cables are also fitted between the PLC and the relevant remote STB I/O islands, IP67 I/O modules and IclA compact drives.
MERLIN GERIN
compact master switch
NSC100N
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Preventa safety relay
XPS AF5130
Door-safety switch
XCS TA791
EMERGENCY-OFF
Switch (tamper-proof)
XALK178G
Contactor
LC1-D12BL
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Motor circuit-breaker
GV2-L08
Motor circuit-breaker
GV2-ME08
Phaseo
power supply
ABL-7RP2403
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Phaseo
power supply
ABL-7RP2405
Phaseo
power supply
ABL-7UPS24200
Altivar 31
variable speed drive
ATV31H018M2
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Berger Lahr IclA
intelligent compact drive
IFE71/2CAN-DS
IclA
intelligent compact drive
Structure
1 EC motor 2 Electronic housing 3 Cable-gland slide-in module 4 I/O slide-in module with industrial socket
connection 5 DIP switches for settings 6 Electronic housing cover, not to be removed 7 Connector housing cover, to be removed for
installation 8 Cover with industrial socket connection for DC
supply and field bus IN/OUT connection 9 Electrical interface
IclA intelligent compact
drive
Connections
1 Power supply 2 Profibus DP field bus interface 3 CAN or RS485 field bus interface 4 24 V signal interface
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IclA intelligent compact
drive
Supply voltage connection
PIN Signal Meaning 1 V DC 24/35 V DC supply voltage 2 GND GND for supply voltage, connected
internally to GND of CAN, RS485 and 24 V signal interface
IclA
intelligent compact drive
CANopen bus
connection
PIN Signal Meaning 3 CAN_H CAN signal interface 6 CAN_L CAN signal interface 4 GND Connected internally to the power
supply GND
TeSys U
module contactor
LUB12, LUCA05BL, LUFC00, LU9BN11C
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Advantys STB
I/O platform (IP20)
FTXCNTL12
Advantys STB
fieldbus coupler module
CANopen
FTXCNTL12
1 Fieldbus interface 2 Top rotary switch 3 Bottom rotary switch 4 Supply interface 5 LED panel 6 Attachment screw 7 Card slot for memory
module 8 Cover for CFG port
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Advantys STB
field power supply
STB PDT3100
1 +24 V DC sensor bus power 2 -24 V DC return line for sensor power supply 3 +24 V DC actuator bus power 4 –24 V DC return line for actuator power supply
Advantys STB
digital 24 V DC input module
STB DDI3610
1 +24 V DC to sensor 1 (top) and sensor 4 (bottom) 2 Input from sensor 1 (top) and sensor 4 (bottom) 3 +24 V DC to sensor 2 (top) and sensor 5 (bottom) 4 Input from sensor 2 (top) and sensor 5 (bottom) 5 +24 V DC to sensor 3 (top) and sensor 6 (bottom) 6 Input from sensor 3 (top) and sensor 6 (bottom)
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Advantys STB
digital 24 V DC output module
STB DDO3600
1 Output to actuator 1 (top) and actuator 4 (bottom) 2 Field-power-supply return line from actuators 1 and 4 3 Output to actuator 2 (top) and actuator 5 (bottom) 4 Field-power-supply return line from actuators 2 and 5 5 Output to actuator 3 (top) and actuator 6 (bottom) 6 Field-power-supply return line from actuators 3 and 6
Advantys STB
relay output module
STB DRC3210
1 Relay ground connections 2 NO contact connections 3 NC contact connections 4 Safety ground connection point for field device (bottom)
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Advantys STB
analog current input module
STB ACI1230
1 Inputs from sensor 1 (top) and sensor 2 (bottom) 2 Return lines from sensor 1 (top) and sensor 2 (bottom)
Advantys STB
analog current output module
STB ACO1210
1 Outputs to actuator 1 (top) and actuator 2 (bottom) 2 Field-power-return lines from actuator 1 (top) and
actuator 2 (bottom)
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Advantys FTB
I/O module (IP67)
FTB1CN12E04SPO
Signal beacon
XVB-C
Magelis
text display
XBT-N401
Magelis
full-graphic display terminal
XBT-G4330
Ethernet port
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Premium
PLC processor module
TSX P571634
1 Display module 3 TER port 4 AUX port 5 PCMCIA slot for memory card 6 PCMCIA slot communication card 8 Ethernet port 10 RESET button
Premium
PLC power supply module
Premium CANopen
machine bus
TSX CPP110
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Premium
digital input module
TSX DEY16D2
Premium
digital output module
TSX DSY16T2
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Premium
analog input module
TSX AEY1600
with
Telefast 2 terminal block
ABE 7CPA02
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Premium
analog output module
TSX ASY410
Premium
Ethernet module
TSX ETY4103
Ethernet port
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Software
General Software is primarily used for programming the Premium PLC and configuring the CANopen
communication as well as for generating the visualization displays. The PLC is programmed using the Unity Pro XL programming tool. The CANopen bus is configured using the SyCon software. Within the context of the STB I/O module, the Advantys Configuration Software is used for island configuration and to create the EDS file that is essential for the CANopen communication. The HMI application on the XBT-G4330 Magelis display terminal is configured using Vijeo Designer. For the XBT-N401 text display, the XBT-L1000 software tool is available. Although Altivar 31 variable speed drives can be parameterized using the front panel, the PowerSuite software is a more user-friendly option. As well as providing a convenient means of setting speed-drive parameters, this software also enables data to be saved and archived. These functions are extremely useful as they mean that parameters can be restored rapidly whenever service tasks need to be performed. The software can also help with online parameter optimization. The software is also supplied with the variable speed drive. To use the software packages, your PC must have the appropriate Microsoft Windows
operating system installed: Windows 2000 or Windows XP
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The software tools have the following default installation paths: Unity Pro XL C:\Program Files\Schneider Electric\Unity Pro SyCon C:\Program Files\Schneider Electric\SyCon Advantys Configuration Software C:\Program Files\Schneider Electric\Advantys PowerSuite ATV31 C:\Program Files\Schneider Electric\PowerSuite.Launch Vijeo Designer C:\Program Files\Schneider Electric\VijeoDesigner XBT-L1000 C:\Program Files\Schneider Electric\XBT-L1000
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Communication
General The following methods of communication are used between devices:
CANopen Uni-Telway Modbus Parallel cabling The machine bus enabling communication between the PLC and fieldbus devices is implemented in the form of CANopen. Uni-Telway is used between the PLC and display terminal (Magelis XBT-G). Modbus is used for data exchange between the Advantys STB and remote HMI (Magelis XBT-N). Parallel cabling uses a pre-assembled cable to connect the I/O platform (Advantys STB) to the motor starter. This rules out the possibility of cabling errors.
Programming Cable
TSX PCX 1031
Serial link between PC with Unity Pro and PLC (TER/AUX) to enable programming
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Communication Cable
XBT Z968
And
Cable Adapter
XBTZG999
The cable is required to make the connection between the XBTG HMI (COM1, SUB-D-25) and the PLC (TER or AUX, MiniDin).
Programming Cable
XBT Z915
Used for programming the XBTN HMI via the serial interface on the PC, with HMI software.
Programming Cable
STB XCA 4002
To establish a connection between the Advantys STB and the configuration software, the cable is attached to the CFG port on the Advantys and the serial interface on the PC.
Data Cable
XBT Z988
The XBTZ988 data cable is required to connect the XBTN HMI to the Advantys STB (CFG port).
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Programming Cable
VW3 A8 106 The Altivar drives are parameterized via the serial interface on the PC using PowerSuite. The cable can be connected to the speed drives directly or to the CANopen taps via the PowerSuite port.
CANopen Machine Bus
TSX CPP110
The CANopen interface card (1) is inserted into the second PCMCIA slot on the Premium PLC. The connector is mounted on a top-hat rail and has a 9-pin sub-D socket.
CANopen Plug
TSX CAN KCDF 90T
Connection of the CANopen cable to the TSXCPP110. Plug incl. terminating resistor.
CANopen cable
TSX CAN CD50 Flexible cable.
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CANopen tap
VW3 CAN TAP2 Connection of two Altivar 31 variable speed drives. Port for configuring speed drive using PowerSuite. Switch-based terminating resistor.
CANopen branching cable
VW3 CAN RR1
Connection between tap and Altivar 31. Two RJ54 connectors.
CANopen tap
VW3 CAN TDM4 Connection of IclA and Advantys STB to 9-pin sub-D ports. Switch-based terminating resistor.
Pin Description CH Polarity CAN_H CL Polarity CAN_L CG Ground V+ Optional power supply
CANopen branching cable
TSX CAN CADD1
Connection between tap and Advantys STB. Two female 9-pin sub-D connectors.
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Power Supply Cable
0062501470030
Open-ended industrial socket connection for DC supply from IclA compact drive. Length: 3 m.
CANopen Connector Set
0062501526001
Connector set for assembly of CANopen cables for industrial socket connections. 1 x M12 male connector 1 x M12 female connector 1 x M12 protective cap
CANopen Bus Connection Cable
FTXCN3210
Series connection of FTB modules starting from the VW3 CAN TDM4 CANopen tap.
PIN Signal Color 1 Shld - 2 V+ Red 3 GND Black 4 CAN_H White 5 CAN_L Blue
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Power Supply
Connection Cable
FTXDP2210 Linking up the power supply from one FTB module to the next.
PIN Signal Wire 1 0 V 1 2 0 V 2 3 PE Green/yellow 4 +24 V DI 3 5 +24 V DO 4
Advantys FTB
CANopen Terminating Resistor
FTXCNTL12
Connection to final FTB module via BUS OUT connector.
Connection Cable
LU9R10
Parallel connection of LUF C00 communication module on TeSys U with EPI2145 special module of STB platform. Two RJ54 connectors.
1 EPI2145 STB module 2 LUF C00
communication module on TeSys U
3 LU9R10 connection cable
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Implementation
Introduction The implementation chapter describes all the steps necessary to initialize, to configure, to
program and start-up the system to achieve the application functions as listed below.
Function
Instructions for switching on and functional description 1. Activate all safety devices and motor circuit-breakers. 2. Activate the master mains switch. 3. Clear the emergency off. 4. Establish and acknowledge door safety. 5. Wait until the red lamp goes off. 6. Error messages (which are indicated by the blue lamp) can be reset using the “Reset”
button if necessary. 7. Now you can select Auto, HMI or Manu mode on the main screen. 8. A pending bus-node connection error will be indicated by the “CANopen” button
lighting up red. Individual bus-node stati are listed in the “CANopen” diagnostics window.
9. Select HMI mode: By selecting individual devices you can access various operational modes and set certain speed and position parameters. Error messages are also shown in more detail.
10. Select Manu mode: In this mode, you can control the TeSys U module contactors using the remote terminal and buttons.
11. Select Auto mode: Once Auto mode has been activated, you can initiate an automatic control process via the Start button. The individual drives are started and stopped one after the other, running in different directions and at various speeds. Auto mode stops whenever an error occurs and starts up again once a restart is made.
Signal Beacon
The signal beacon indicates the various system states and consists of 5 signaling elements: Blue lamp: CANopen bus or logic error – lamp lights up Red lamp: Fault indication for emergency-off/safety violations - lamp flashes Green lamp: State: System ready – lamp lights up Operation: System running normally – lamp flashes Yellow lamp: Automatic operation: System running in Auto mode – lamp lights up Siren: Error or fault pending – siren sounds for 3 seconds (1 Hz)
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Functional Layout
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Communication
Introduction This chapter describes the data passed via the communications bus (e.g., Modbus
Plus or TCP/IP) that is not bound directly with digital or analog hardware. The list contains: The device links Direction of data flow symbolic name and Bus address of the device concerned.
Device Links Within the context of this application, the CANopen, Modbus and Uni-Telway bus
systems are used along with Ethernet to transfer the configuration. The following devices are connected via CANopen: - One Premium PLC, bus address 1 - Three Altivar 31 variable speed drives, bus addresses 2 – 4 - Two IclA IFE7 compact drives, bus addresses 5 and 6 - Three Advantys FTB I/O modules, bus addresses 7 - 9 - One Advantys STB I/O platform, bus address 10 Only two devices are connected via Modbus: - Advantys STB I/O platform, CFG port, bus address 1 - Magelis XBT-N panel (no bus address assigned) Only two devices communicate with each other via Uni-Telway: - Premium PLC, CPU module AUX port - Magelis XBT-G terminal, COM1 Two devices are configured via Ethernet: - Premium PLC, Ethernet port, IP address 192.168.100.72 - Magelis XBT-G terminal, Ethernet port, IP address 192.168.100.73
Startup Proceed as follows to establish communication between the devices:
- Set the CANopen address and transmission rate for all devices - Create the EDS file for the STB island using the Advantys configuration tool - Configure the CANopen bus using the SyCon software - Generate the variable import file for Unity Pro using the CANopen Symbol Tool - Exchange data between the XBT-N terminal and Premium PLC via STB module
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Datalink Premium-CPU (CANopen-Master, #1) Altivar31_1 (CANopen-Slave#2) Drive_1 <> PLC Data Direction ATV -> PLC Address Name Index Designation %MW1000 ATV01_STATE / state 6041 Drivecom status register %MW1001 ATV01_STATE / rpm 6044 Control effort Data Direction SPS -> ATV Address Name Index Designation %MW1500 ATV01_CTRL / cmd 6040 Drivecom command register %MW1501 ATV01_CTRL / rpm 6042 Target velocity Datalink Premium-CPU (CANopen-Master, #1) Altivar31_2 (CANopen-Slave#3) Drive_2 <> PLC Data Direction ATV -> PLC Address Name Index Designation %MW1002 ATV02_STATE / state 6041 Drivecom status register %MW1003 ATV02_STATE / rpm 6044 Control effort Data Direction PLC -> ATV Address Name Index Designation %MW1502 ATV02_CTRL / cmd 6040 Drivecom command register %MW1503 ATV02_CTRL / rpm 6042 Target velocity Datalink Premium-CPU (CANopen-Master, #1) Altivar31_3 (CANopen-Slave#4) Drive_3 <> PLC Data Direction ATV -> PLC Address Name Index Designation %MW1004 ATV03_STATE / state 6041 Drivecom status register %MW1005 ATV03_STATE / rpm 6044 Control effort Data Direction PLC -> ATV Address Name Index Designation %MW1504 ATV03_CTRL / cmd 6040 Drivecom command register %MW1505 ATV03_CTRL / rpm 6042 Target velocity Datalink Premium-CPU (CANopen-Master, #1) IclA_IFE_01 (CANopen-Slave#5) IclA_1 <> PLC Data Direction IclA -> PLC Address Name Index Designation %MW1006 ICLA01_IN[0] 301E.4 pdo4_driveStat %MW1007 ICLA01_IN[1] 301E.3 pdo4_modeStat %MW1008 ICLA01_IN[2] 301E.7 pdo4_Act8 %MW1009 ICLA01_IN[3] 301E.8 pdo4_Act32 Data Direction PLC -> IclA Address Name Index Designation %MW1506 ICLA01_OUT[0] 301E.1 pdo4_driveCtrl %MW1507 ICLA01_OUT[1] 301E.2 pdo4_modeCtrl %MW1508 ICLA01_OUT[2] 301E.5 pdo4_Ref16 %MW1509 ICLA01_OUT[3] 301E.6 pdo4_Ref32
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Datalink Premium-CPU (CANopen-Master, #1) IclA_IFE_02 (CANopen-Slave#6) IclA_2 <> PLC Data Direction IclA -> PLC Address Name Index Designation %MW1010 ICLA02_IN[0] 301E.4 pdo4_driveStat %MW1011 ICLA02_IN[1] 301E.3 pdo4_modeStat %MW1012 ICLA02_IN[2] 301E.7 pdo4_Act8 %MW1013 ICLA02_IN[3] 301E.8 pdo4_Act32 Data Direction PLC -> IclA Address Name Index Designation %MW1510 ICLA02_OUT[0] 301E.1 pdo4_driveCtrl %MW1511 ICLA02_OUT[1] 301E.2 pdo4_modeCtrl %MW1512 ICLA02_OUT[2] 301E.5 pdo4_Ref16 %MW1513 ICLA02_OUT[3] 301E.6 pdo4_Ref32 Datalink Premium-CPU (CANopen-Master, #1) Adv_FTB_01 (CANopen-Slave#7) FTB_1 <> PLC Data Direction FTB -> PLC Address Name Index Designation %MW1014 6000.1 Digital Input 8 Bits Pin4 6000.2 Digital Input 8 Bits Pin2 Data Direction PLC -> FTB Address Name Index Designation %MW1514 6200.1 Write Outputs 5 to 8 Datalink Premium-CPU (CANopen-Master, #1) Adv_FTB_02 (CANopen-Slave#8) FTB_2 <> PLC Data Direction FTB -> PLC Address Name Index Designation %MW1015 6000.1 Digital Input 8 Bits Pin4 6000.2 Digital Input 8 Bits Pin2 Data Direction PLC -> FTB Address Name Index Designation %MW1515 6200.1 Write Outputs 5 to 8 Datalink Premium-CPU (CANopen-Master, #1) Adv_FTB_03 (CANopen-Slave#9) FTB_3 <> PLC Data Direction FTB -> PLC Address Name Index Designation %MW1016 6000.1 Digital Input 8 Bits Pin4 6000.2 Digital Input 8 Bits Pin2 Data Direction SPS -> FTB Address Name Index Designation %MW1516 6200.1 Write Outputs 5 to 8
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Datalink Premium-CPU (CANopen-Master, #1) Adv_STB_01 (CANopen-Slave#10) STB_1 <> PLC Data Direction STB -> PLC Address Name Index Designation %MW1017 6000.1 Digital Input Block No.1 6000.2 Digital Input Block No.2 %MW1018 6000.3 Digital Input Block No.3 6000.4 Digital Input Block No.4 %MW1019 6000.5 Digital Input Block No.5 6000.6 Digital Input Block No.6 %MW1020 6000.7 Digital Input Block No.7 6000.8 Digital Input Block No.8 %MW1021 6000.9 Digital Input Block No.9 6000.A Digital Input Block No.10 %MW1022 6000.B Digital Input Block No.11 6000.C Digital Input Block No.12 %MW1023 6000.D Digital Input Block No.13 6000.E Digital Input Block No.14 %MW1024 6000.F Digital Input Block No.15 6000.10 Digital Input Block No.16 %MW1025 6000.11 Digital Input Block No.17 6000.12 Digital Input Block No.18 %MW1026 6000.13 Digital Input Block No.19 6000.14 Digital Input Block No.20 %MW1027 6000.15 Digital Input Block No.21 6000.16 Digital Input Block No.22 %MW1028 6000.17 Digital Input Block No.23 6000.18 Digital Input Block No.24 %MW1029 6000.19 Digital Input Block No.25 6000.1A Digital Input Block No.26 %MW1030 6401.1 Analog Input Block No.1 %MW1031 6401.2 Analog Input Block No.2 %MW1032 HMI_SPS_WD1 2200 2-byte Special Input Object %MW1033 HMI_SPS_WD2 2201 2-byte Special Input Object %MW1034 HMI_SPS_WD3 2202 2-byte Special Input Object %MW1035 HMI_SPS_WD4 2203 2-byte Special Input Object Data Direction PLC -> STB Address Name Index Designation %MW1517 6200.1 Digital Output Block No.1 6200.2 Digital Output Block No.2 %MW1518 6200.3 Digital Output Block No.3 6200.4 Digital Output Block No.4 %MW1519 6411.1 Analog Output Block No.1 %MW1520 6411.2 Analog Output Block No.2 %MW1521 SPS_HMI_WD1 3200 2-byte Special Output Object %MW1522 SPS_HMI_WD2 3201 2-byte Special Output Object %MW1523 SPS_HMI_WD3 3202 2-byte Special Output Object %MW1524 SPS_HMI_WD4 3203 2-byte Special Output Object
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Datalink Premium SPS (Uni-Telway) XBT-G4330 (Uni-Telway) HMI <> PLC Data Direction HMI -> PLC Address Name Address Designation %MW20.6 ATV01_Right_hmi %MW20:X06 ATV01.ATV_Right %MW20.7 ATV01_Left_hmi %MW20:X07 ATV01.ATV_Left %MW20.8 ATV01_Fast_hmi %MW20:X08 ATV01.ATV_Fast %MW21 ATV01_RPM1_hmi %MW21 ATV01.ATV_RPM1 %MW25.6 ATV02_Right_hmi %MW25:X06 ATV02.ATV_Right %MW25.7 ATV02_Left_hmi %MW25:X07 ATV02.ATV_Left %MW25.8 ATV02_Fast_hmi %MW25:X08 ATV02.ATV_Fast %MW26 ATV02_RPM1_hmi %MW26 ATV02.ATV_RPM1 %MW30.6 ATV03_Right_hmi %MW30:X06 ATV03.ATV_Right %MW30.7 ATV03_Left_hmi %MW30:X07 ATV03.ATV_Left %MW30.8 ATV03_Fast_hmi %MW30:X08 ATV03.ATV_Fast %MW31 ATV03_RPM1_hmi %MW31 ATV03.ATV_RPM1 %MW35.0 ATV_EStop_hmi %MW35:X00 ATV_EStop %MW35.1 ATV_Ackn_hmi %MW35:X01 ATV_Ackn %MW50.0 Icla01_power_hmi %MW50:X00 IclA01.IclA_Power %MW50.1 Icla01_stop_hmi %MW50:X01 IclA01.IclA_Stop %MW50.2 Icla01_reset_hmi %MW50:X02 IclA01.IclA_Reset %MW50.3 Icla01_start_hmi %MW50:X03 IclA01.IclA_Start %MW50.4 Icla01_op_dimset_hmi %MW50:X04 IclA01.IclA_op_dimset %MW50.5 Icla01_op_refmov_hmi %MW50:X05 IclA01.IclA_op_refmov %MW50.6 Icla01_op_ptpabs_hmi %MW50:X06 IclA01.IclA_op_ptpabs %MW50.7 Icla01_op_ptprel_hmi %MW50:X07 IclA01.IclA_op_ptprel %MW50.8 Icla01_op_vel_hmi %MW50:X08 IclA01.IclA_op_vel %MW52 Icla01_rpm_hmi %MW52 IclA01.IclA_RPM %MW53 Icla01_dest_hmi %MD53 IclA01.IclA_Dest %MW60.0 Icla02_power_hmi %MW60:X00 IclA02.IclA_Power %MW60.1 Icla02_stop_hmi %MW60:X01 IclA02.IclA_Stop %MW60.2 Icla02_reset_hmi %MW60:X02 IclA02.IclA_Reset %MW60.3 Icla02_start_hmi %MW60:X03 IclA02.IclA_Start %MW60.4 Icla02_op_dimset_hmi %MW60:X04 IclA02.IclA_op_dimset %MW60.5 Icla02_op_refmov_hmi %MW60:X05 IclA02.IclA_op_refmov %MW60.6 Icla02_op_ptpabs_hmi %MW60:X06 IclA02.IclA_op_ptpabs %MW60.7 Icla02_op_ptprel_hmi %MW60:X07 IclA02.IclA_op_ptprel %MW60.8 Icla02_op_vel_hmi %MW60:X08 IclA02.IclA_op_vel %MW62 Icla02_rpm_hmi %MW62 IclA02.IclA_RPM %MW63 Icla02_dest_hmi %MD63 IclA02.IclA_Dest %MW40.0 TeSysU_1_HMI %MW40:X01 TeSys01.ON %MW40.1 TeSysU_2_HMI %MW40:X02 TeSys02.ON %MW40.2 TeSysU_3_HMI %MW40:X03 TeSys03.ON %MW82.0 Set_Auto_hmi %MW82:X00 Set_Auto_hmi %MW82.1 Set_HMI_hmi %MW82:X01 Set_HMI_hmi %MW82.2 Set_Manu_hmi %MW82:X02 Set_Manu_hmi %MW82.3 Set_AutoStart_hmi %MW82:X03 Set_AutoStart_hmi
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Data Direction PLC -> HMI Address Name Address Designation %MW20.0 ATV01_MotErr %MW20:X00 ATV01.ATV_MotErr %MW20.1 ATV01_MotEs %MW20:X01 ATV01.ATV_MotEs %MW20.2 ATV01_MotFa %MW20:X02 ATV01.ATV_MotFa %MW20.3 ATV01_MotLe %MW20:X03 ATV01.ATV_MotLe %MW20.4 ATV01_MotRi %MW20:X04 ATV01.ATV_MotRi %MW20.5 ATV01_MotSl %MW20:X05 ATV01.ATV_MotSl %MW23 ATV01_ASPD %MW23 ATV01.ATV_ActualSpe
ed %MW25.0 ATV02_MotErr %MW25:X00 ATV02.ATV_MotErr %MW25.1 ATV02_MotEs %MW25:X01 ATV02.ATV_MotEs %MW25.2 ATV02_MotFa %MW25:X02 ATV02.ATV_MotFa %MW25.3 ATV02_MotLe %MW25:X03 ATV02.ATV_MotLe %MW25.4 ATV02_MotRi %MW25:X04 ATV02.ATV_MotRi %MW25.5 ATV02_MotSl %MW25:X05 ATV02.ATV_MotSl %MW28 ATV02_ASPD %MW28 ATV02.ATV_ActualSpe
ed %MW30.0 ATV03_MotErr %MW30:X00 ATV03.ATV_MotErr %MW30.1 ATV03_MotEs %MW30:X01 ATV03.ATV_MotEs %MW30.2 ATV03_MotFa %MW30:X02 ATV03.ATV_MotFa %MW30.3 ATV03_MotLe %MW30:X03 ATV03.ATV_MotLe %MW30.4 ATV03_MotRi %MW30:X04 ATV03.ATV_MotRi %MW30.5 ATV03_MotSl %MW30:X05 ATV03.ATV_MotSl %MW33 ATV03_ASPD %MW33 ATV03.ATV_ActualSpe
ed %MW51.0 Icla01_conf_runs %MW51:X00 IclA01.IclA_conf_runs %MW51.1 Icla01_conf_error %MW51:X01 IclA01.IclA_conf_error %MW51.3 Icla01_Powered %MW51:X03 IclA01.IclA_Powered %MW51.4 Icla01_error %MW51:X04 IclA01.IclA_error %MW51.5 IclA01_stopped %MW51:X05 IclA01.IclA_stopped %MW51.6 IclA01_finish %MW51:X06 IclA01.IclA_finish %MW55 IclA01_Position %MD55 IclA01.IclA_Position %MW61.0 Icla02_conf_runs %MW61:X00 IclA02.IclA_conf_runs %MW61.1 Icla02_conf_error %MW61:X01 IclA02.IclA_conf_error %MW61.3 Icla02_Powered %MW61:X03 IclA02.IclA_Powered %MW61.4 Icla02_error %MW61:X04 IclA02.IclA_error %MW61.5 IclA02_stopped %MW61:X05 IclA02.IclA_stopped %MW61.6 IclA02_finish %MW61:X06 IclA02.IclA_finish %MW65 IclA02_Position %MD65 IclA02.IclA_Position %MW1027.8 STB_13_EPI2145_1RUN %MW1027:X08 TeSys01.Ready %MW1027.9 STB_13_EPI2145_1FLT %MW1027:X09 TeSys01.RUN %MW1027.10 STB_13_EPI2145_1RDY %MW1027:X10 TeSys01.Foult %MW1027.11 STB_13_EPI2145_2RUN %MW1027:X11 TeSys02.Ready %MW1027.12 STB_13_EPI2145_2FLT %MW1027:X12 TeSys02.RUN %MW1027.13 STB_13_EPI2145_2RDY %MW1027:X13 TeSys02.Foult %MW1027.14 STB_13_EPI2145_3RUN %MW1027:X14 TeSys03.Ready %MW1027.15 STB_13_EPI2145_3FLT %MW1027:X15 TeSys03.RUN %MW1028.8 STB_13_EPI2145_3RDY %MW1028:X08 TeSys03.Foult %MW81.0 HMI_Estop %MW81:X00 HMI_Estop %MW81.1 HMI_Door %MW81:X01 HMI_Door %MW81.2 HMI_Auto_Mode %MW81:X02 HMI_Auto_Mode %MW81.3 HMI_HMI_Mode %MW81:X03 HMI_HMI_Mode %MW81.4 HMI_Manu_Mode %MW81:X04 HMI_Manu_Mode %MW81.5 HMI_Auto_Started %MW81:X05 HMI_Auto_Started %MW81.6 HMI_DriveFault %MW81:X06 HMI_DriveFault
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Datalink Advantys STB (Modbus-Master,#1) XBT-N401 (Modbus-Slave) HMI <> STB Data Direction HMI -> STB Address Name Address Designation 49488 HMI_SPS_WD1 %MW9487 Set Drive 49489 HMI_SPS_WD2 %MW9488 49490 HMI_SPS_WD3 %MW9489 49491 HMI_SPS_WD4 %MW9490 49488.0 HMI_SPS_WD1, Bit 0 %MW9487:X0 Set TeSysU_1_ON 49488.1 HMI_SPS_WD1, Bit 1 %MW9487:X1 Set TeSysU_2_ON 49488.2 HMI_SPS_WD1, Bit 2 %MW9487:X2 Set TeSysU_3_ON Data Direction STB -> HMI Address Name Address Designation 44097 SPS_HMI_WD1 %MW4096 State 44098 SPS_HMI_WD2 %MW4097 Mode 44099 SPS_HMI_WD3 %MW4098 44100 SPS_HMI_WD4 %MW4099 45416.0 EPI_2_13_1_Schalter %MW5415:X0 TeSysU_1_READY 45416.1 EPI_2_13_1_Schaltschütz %MW5415:X1 TeSysU_1_FOULT 45416.2 EPI_2_13_1_Schutzschalter %MW5415:X2 TeSysU_1_RUN 45416.3 EPI_2_13_2_Schalter %MW5415:X3 TeSysU_2_READY 45416.4 EPI_2_13_2_Schaltschütz %MW5415:X4 TeSysU_2_FOULT 45416.5 EPI_2_13_2_Schutzschalter %MW5415:X5 TeSysU_2_RUN 45416.6 EPI_2_13_3_Schalter %MW5415:X6 TeSysU_3_READY 45416.7 EPI_2_13_3_Schaltschütz %MW5415:X7 TeSysU_3_FOULT 45418.0 EPI_2_13_3_Schutzschalter %MW5417:X0 TeSysU_3_RUN
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The PLC example program uses different hardware, discretes and memory words The following list contains keys to aid the understanding of the addressing system used.
Type Address Comment
Digital Inputs %Ir.m.x Digital inputs are hardware orientated: r as Rack number, m as slot number, x as Input number. E.g.: Emergency-off response at %I0.3.0
Digital Outputs %Qr.m.x Digital outputs are hardware orientated: r as Rack number, m as slot number, x as output number
E.g.: Manual Mode Indicator at %Q0.5.1
Analog Inputs %IWr.m.c Analog inputs are hardware orientated: r as Rack number, m as Slot number, c as channel number. E.g.: Emergency-off response at %IW0.3.0
Analog Outputs %QWr.m.c Analog outputs are hardware orientated: r as Rack number, m as Slot number, c as channel number. E.g.: Emergency-off response at %QW0.3.0
CANopen Inputs %MW0 bis %MW31
CANopen-Inputs are written as Memory Words, single bits can be accessed as %MWi.x. E.g.: 2nd ATV Status word at %MW2
CANopen Outputs %MW100 bis %MW131
CANopen-Outputs are read as Memory words, single bits can be accessed as %MWi.x. E.g.: 3rd. ATV control word at %MW104
Data for Visu %MW200 bis %MW299
Data for the visualization is stored in memory words. Single bits can be written using the function BIT_TO_WORD E.g.: Motor speed at %MW220
Data from Visu %MW300 bis %MW399
Data from the visualization is stored in memory words. Single bits can be extracted using the function WORD_TO_BIT E.g.: Motor speed at %MW220
General Addressing
CANopen Status %CHr.m.c CANopen Status data can be read from the data structure T_COM_CPP110 (IODDT). Channel-Address: r as Rack number, m as Slot number, c as channel number. E.g.: Status CANopen %CH0.1.1
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CANopen The address and transmission rate must be specified for all the devices on the
CANopen bus.
Altivar 31 Setting the address and transmission rate (manually)
1 The CANopen address and transmission rate are set manually via the control buttons on the device.
2 First, use the control buttons to
select the Communication submenu.
In the Communication menu, the CANopen address must be set in the AdC0 parameter. In the example software provided, the values 2 to 4 have been set aside for the three speed drives. Press ENT to confirm the setting.
In the Communication menu, you must also set the transmission rate in the BdC0 parameter to the value 250.0 (kbaud). Alternatively, the address and transmission rate can also be parameterized using the PowerSuite configuration software (see "Devices – Altivar 31).
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IcIA IFE7 Setting the address and transmission rate
1 The CANopen address and transmission rate are set manually using the DIP switches and the rotary switch in the cable connector of the drive. The address can be varied between 1 and 127 using switches S1 and S2. S3 can be used in addition to define the drive as the last device on the bus by activating the CAN terminating resistor. Set the transfer rate using the rotary switch and select a value of 250 kbaud (switch setting 4) to enable operation with the Premium PLC.
2 The table summarizes the switch settings for the desired CANopen address. Addresses 5 (000 0101b) and 6 (000 011 b) must be assigned to the drives.
Advantys FTB Setting the address and transmission rate
1 The CANopen address and transmission rate are set manually on the modules via rotary switches. There are two rotary switches for the address and one for the transmission rate. In the example software, both FTB modules are configured with the addresses 7 to 9 and the transmission rate is set to 250.0 kbaud. Alternatively, you can set the system to detect the transmission rate automatically.
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Advantys STB Setting the address and transmission rate
1 To set the CANopen address and transmission rate, you will need a screwdriver to turn the rotary switches on the Advantys island head.
2 Setting the baud rate:
1 Disconnect island voltage. 2 Set bottom rotary switch (ONES) to any of the positions after the number 9 (baud rate). 3 Set the baud rate on the top rotary switch (TENS). Select position 4 for a transmission rate of 250 kbaud. 4 Reconnect island voltage.
3 Setting the CANopen address: 1 Disconnect island voltage. 2 Set the bottom rotary switch (ONES) to the position that corresponds to the desired address in terms of the ONES place value. If the desired address is 010, the correct position is 0. 3 Set the top rotary switch (TENS) to the position that corresponds to the desired address in terms of the TENS and HUNDREDS place values. If the desired address is 010, the correct position is 1. 4 Reconnect the island voltage.
Notes:
Although addresses can be set manually, addresses 128 and 129 are not available for selection, as CANopen only supports addresses from 0 to 127.
After configuring the CANopen address, it is recommended that you leave the rotary switches in this address position so that, when the system is switched on, the island is always detected at the same address.
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Advantys Software
The Advantys Configuration Software must be used to make the configuration settings for the Advantys STB island, transfer them to the island and also to create the EDS file required for CANopen communication.
Creating a New Project
1 After starting the Advantys software, you must create a new workspace.
2 To do this, you must specify
the path, the workspace name and the name of the first island.
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Configuring the hardware
1 Select the network interface to serve as the island head for CANopen STB NCO 2212. Do this by dragging and dropping from the catalog browser or double-clicking in the catalog browser. The catalog browser is located on the right-hand side of the window.
2 Switch to the Parameters view
by double-clicking the tab in the header and (as necessary) specify the number of registers to be exchanged via the Advantys module within the context of communication between the PLC and HMI. For details, please see “HMI Magelis XBT-N”. Note: In the example project 4 words are reserved in each case.
3 Next add the remaining nodes: STB PDT3100, STB DDI3610, STB DDO3600, STB XBE1000, STB XBE1200, STB PDT3100, STB DRC3210, STB ACI1230, STB ACO1210, STB EPI2145 and do not forget about bus connection STB XMP 1100.
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I/O data image
1 You can use the I/O Image Overview… menu item (in the Island menu) or the equivalent icon to call the function for assigning the I/O to the memory areas.
2 The information concerning the
selected data is displayed in the description field. Alternatively, the project can also be printed out. The printout will contain the same information.
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Downloading the configuration
1 Start by selecting the Build option in the Island menu or the equivalent icon to generate a machine-readable version from the completed configuration.
2 An information window will
appear while the build is in progress. Once the build process is complete, a message will appear in the log window at the bottom of the screen informing you of whether or not the operation was successful.
3 If this is the first time that a connection to the island has been established, the connection settings must first be specified by selecting Connection Settings from the Online menu. In the case of a serial connection, the settings must be made as shown in the screenshot here.
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4 Connect the STBXCA4002 programming cable so that the configuration can be downloaded. You can now establish a connection to the island by selecting Connect in the Online menu. Notice: If no build has been performed, the software will now initiate an automatic build.
5 Once the connection has been
established, the Advantys software detects that the machine-readable version generated does not match the current configuration in the island and presents you with an option to Download or Upload. Select Download and confirm the security prompt with YES.
6 A progress bar appears during download. Once the download process is complete a message appears asking whether the island should now be set to the Running state. Click OK. Alternatively, the island can be started by selecting Run from the Online menu.
7 As soon as the island has been
successfully started, you may disconnect. The island configuration is now complete. The file with the saved configuration, i.e. the “island” file (STB_CANopen.isl), can be found under the following path: C:\Program Files\Schneider Electric\Advantys\Projects\ AdvantysSTB
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Creating the EDS file for SyCon
1 As the EDS file is required to integrate the island into a CANopen network, you should select Export STB_CANopen from the File menu.
2 You must specify the path and
file name. The default setting can generally be left as it is. Progress can be tracked in the log window and once the export process is complete you can shut the configuration software down.
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Sycon Software
The CANopen bus is configured using the SyCon software. The individual devices are identified as bus nodes, then addresses are assigned and the master function is allocated to the Premium PLC. Subsequently, the individual device data that is to be transferred during operation (PDO) is configured and the device configurations (SDO) are defined where applicable. Finally, the general bus settings are entered, e.g., the baud rate is specified.
Creating a New Project
1 Start the Sycon software, then start a new project by selecting File->New. Select the CANopen bus in the next dialog.
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Importing *.eds description files into SyCon
1 In order that the speed drives, compact drives, STB island and FTB modules can be connected to the CANopen bus via the SyCon software, every type of device used must first be integrated into the SyCon software. Do this using the *eds description files (and the three additional image files).
2 After creating the project, select the Copy EDS menu item from the File menu. Note: Integration is not possible, and this menu is not available, until a new project has been created.
3 In the dialog, select the file for
the corresponding Altivar 31 (the last two digits of the file name indicate the version – in this case V1.2) and start the process. Note: You must repeat the process if more than one device or device type is involved.
4 Confirm the import of the
corresponding images.
5 A message appears informing
you that integration is complete.
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Inserting nodes
1 Add the PLC’s interface card to the project as the master for the CANopen bus by selecting Master from the Insert menu or pressing the equivalent button. Select the TSX CPP 110 card in the next dialog. A CANopen address and a name must also be entered.
2 Add each drive to the project
as a node using the Node menu item in the Insert menu. Select the relevant device type in the dialog. A CANopen address and a name must also be entered. This process must be repeated for each drive and all the other devices. Note: You can pre-select the manufacturer and profile in the node filter to speed up the search for the devices in the selection list.
3 Once all devices have been
added there should be nine nodes in the example project. Select ID Table in the View menu to call up the identification table which summarizes all the nodes and their addresses, as well as the mapped PDO objects.
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Configuring Nodes Altivar 31
1 Double-click the device to open the Node Configuration window that is used for all bus-node settings including configuration of the node when the bus starts up and the transfer of data during operation. The dialog is divided into three sections: the top section shows the general configuration, the center section shows the predefined PDO The bottom section shows the PDOs configured for the given nodes and can also be used for configuration or making changes.
2 In the example project, you will need to de-select both pre-defined PDOs by unchecking the relevant boxes or clicking Delete configured PDO.
3 Now select the Receive PDO6
and Transmit PDO6 PDOs for the Altivar 31 speed drive. After double-clicking the PDOs to be activated, the dialog for setting the transmission mode appears. For the Receive PDO, select event triggered with the event when data has changed. In the case of the Transmit PDO, select defined in the device profile and set the Event timer to 100 ms and the Inhibit time to 5 ms.
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4 After the transmission mode has been selected, the PDO is automatically entered as a configured PDO. There is no need for any additional configuration. You must configure a Type 6 PDO to transmit and receive for each speed drive. Note: Click the PDO Contents Mapping button to see the data to be transmitted in the selected PDO. Click the PDO Characteristics button to return to the transmission mode screen for the PDO.
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Configuring Nodes IclA IFE
1 Double-click the device to open the Node Configuration window that is used for all bus-node settings including configuration of the node when the bus starts up and the transfer of data during operation. Double-click both predefined PDOs to activate them for the compact drives. Note: Do not alter the device profile setting (value=0). If this is altered, communication with the drive is disabled and, once changed, the original setting cannot be restored. To restore the setting, delete the device from the configuration and insert it again.
2 After double-clicking on the PDOs to be activated, the dialog for setting the transmission mode appears. For the Receive PDO, select manufacturer specific with the event when data has changed. In the case of the Transmit PDO, select manufacturer specific and set the Event timer to 100 ms and the Inhibit time to 10 ms.
3 After selecting transmission
mode, the PDO is automatically entered as a configured PDO. No additional configuration is needed You must configure a Type 4 PDO to transmit and receive for each compact drive. Note: Clicking the PDO Contents Mapping button displays see the data to be transmitted in the selected PDO. Click the PDO Characteristics button to return to the transmission mode screen for the PDO.
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Configuring Nodes Advantys FTB
1 Double-click the device to open the Node Configuration dialog that is used for all bus-node settings including configuration of the node when the bus starts up and the transfer of data during operation. Four PDOs are pre-defined for the FTB modules but only two are required the application. Here, you should also enter the details of the device object configuration which are to be performed by the bus master before the bus starts up.
2 To call node configuration, click
the Object Configuration button. A separate window appears, listing all the objects in the CANopen object library for the device. Note: The objects only appear in the list if they are also available in the EDS file.
3 Pin 2 of an FTB module can be
used as either diagnostic or I/O channel. To use pin 2 as an I/O channel, object 2000:01 must be selected in the object configuration by double-clicking. Once selected, enter the value 00. Note: Other objects may need to be configured, e.g., the behaviour of the outputs in the event of an error. Note: Configuring PDOs automatically configures other objects.
4 For data transmission, a Receive PDO and a Transmit PDO must be activated in each case. the actual I/O data is transferred via the first PDO 1 (objects 1400 and 1800). Double-click to open the PDO concerned. Note: The other PDOs that are present (objects 1405 and 1805) transmit additional state information.
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5 After double-clicking the PDO you wish to activate, the window for setting the transmission mode appears. For the Receive PDO, select event triggered with the event when data has changed. In the case of the Transmit PDO, select defined in the device profile and set the Event timer to 1000 ms and the Inhibit time to 10 ms.
6 After the transmission mode
has been selected, the PDO is automatically entered as a configured PDO. There is no need for additional configuration. You must configure a Type 1 PDO to transmit and receive for each FTB module. Note: Click the PDO Contents Mapping button to see the data to be transmitted in the selected PDO. Click the PDO Characteristics button to return to the transmission mode screen for the PDO.
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Configuring Nodes Advantys STB
1 Double-click the device to open the Node Configuration window that is used for all bus-node settings including configuration of the node when the bus starts up and the transfer of data during operation. 3 Receive PDOs and 4 Transmit PDOs are preconfigured for the configured STB module. In addition, you will need to activate PDOs 5 and 6 by double-clicking them.
2 After double-clicking the PDOs
to be activated, the window for setting the transmission mode appears. For the receive PDO, select event triggered with the event when data has changed. In the case of the Transmit PDO, select defined in the device profile and set the Inhibit time to 10 ms. In the case of the preconfigured objects, this setting must be checked by pressing the PDO Characteristics button. This is especially true in the case of the Transmit PDO, where the default Inhibit time is set to 0 ms (and it therefore deviates from the setting required for the example project).
3 After the transmission mode has been selected, the PDO is automatically entered as a configured PDO. There is no need for additional configuration. Each and every PDO must be configured for the module. Note: Click the PDO Contents Mapping button to see the data to be transmitted in the selected PDO. Click the PDO Characteristics button to return to the transmission mode screen for the PDO.
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Parameteriz-ing the CANopen Bus
1 The bus parameter window is called up by selecting Bus Parameter from the Settings menu. The master has to be selected in the bus view.
2 The transmission rate is the
only parameter that needs to be changed (to 250 kbaud). Then, you must save the SyCon project. The project file is stored in the following directory: C:\Program Files\Schneider Electric\SyCon\Project\DCI.co.
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CANopen Symbols
The CANopen Symbol Tool enables you to import the variable names and comments from the Advantys STB module configuration into Unity. The symbol names for each Advantys I/O variable are generated automatically by the tool. However, this facility is merely an option intended to make handling variables easier.
Before Starting the Tool
1 The tool requires a Microsoft Access driver (ODBC driver) so that it can read the ISL and CO files. Before starting the tool, make sure that the DSN Microsoft Access Database already exists. If it does not, you must add it. Access the ODBC Data Source Administrator by selecting: Control Panel Administrative Tools Data Sources (ODBC). Select the System DSN tab in the dialog box that appears.
2 If the driver is not available, click Add. In the Create New Data Source window, select Microsoft Access Driver (*.mdb). Click Finish to display the ODBC Microsoft Access Setup dialog box.
3 Enter MS Access Database
under Data Source Name and click OK.
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4 Click OK again in the ODBC Data Source Administrator window. The setting has now been made. Note: This information is also available in the tool's User Guide, which can be called up via the first screen that appears when the tool is started.
Creating the XSY File for Unity
1 Start Excel and select Unity as the target software.
2 Enter the data sources on the
next worksheet. Do this by clicking the buttons next to the fields to specify the file paths. Enter 3 in the Bus Alias field (because the TSX CPP110 bus master has been plugged into slot 3 on the Premium CPU).
3 Click GENERATE UNITY
VARIABLES FILE to create the XSY file. You can inspect the file by clicking: VIEW GENERATED UNITY VARIABLES FILE. Note: For a description of how to import the generated file into Unit, see the section “PLC”.
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Modbus Data is exchanged between the STB module register and the Magelis XBT-N terminal
via Modbus. This process is explained below.
The XBT-N401 terminal has access to the STB island’s register via Modbus. Certain data image register blocks are illustrated below. The data starts at register 40001, which also happens to be the flag-address offset for Modbus communication. All the data image registers can be read from the island head’s CFG port. The configured registers in block 12 (registers 49488 to 49999), which are intended for communication between the HMI and PLC, can also be written from the terminal at the CFG port.
The STB Island’s Data Image Register
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The fieldbus and Modbus I/O images from the Advantys configuration provide the information that is necessary for read and write access to the register addresses. The flag addresses can be ascertained from the Modbus image by subtracting 40001 from the register addresses. The variable addresses of the register entries for the PLC program are determined from the fieldbus image on the basis of the starting words. In the case of bit “j” from input word “i”, the variable address is “%IW\3.10\0.0.0.i-1.j”.
Mapping Overview
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HMI
Magelis XBT-N
Introduction This section describes how to set up visualization on the Magelis text display. The HMI
application for the XBT-N401 is created using the XBT-L1000 HMI software. Proceed as follows to integrate the Human Machine Interface (HMI): Create a new project Configure the HMI Create an application Use the application Example application
Creating a new project
1 Start the XBT-L1000 software and then create a new project.
Configuring the HMI
2 A configuration dialog appears. Select: Type: XBT-N401(2) Protocol: Modbus
In the same dialog, select the Modbus communication protocol parameters.
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3 Set the Modbus protocol parameters. Set the same parameters as those on the Advantys STB CFG port. These are: Speed: 9600 bauds Parity: Even
Click OK to close this dialog and continue with the parameterization by clicking Next.
4 Assign the project name and
then click Next.
5 Enter the symbolic names and
the network address for the connected devices in this window. The network address must match that of the Advantys STB CFG port. The default value for this address is 1.
6 Continue by setting the language. Here you can choose between different languages for the terminal.
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7 Do not make any settings for the terminal and dialogue table. After completing the basic parameters, click Finish. The application pages must now be created.
Creating an application
1 The XBT-L1000 environment consists of the following elements:
1 – Menu bar 2 – Application window 3 – Window containing field
information for the page currently being displayed
4 – Toolbar 5 – Navigation window
(directory structure in the form of a page tree)
2 You can create text objects and links to other pages on an application page by clicking the relevant buttons..
3 Whenever a new page is created it is assigned a page number and a name. You can vary the backlight colour to highlight certain pages.
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4 Some displays are used to access other displays You must insert the links for this function.
5 Properties can be assigned to
the alphanumeric fields. First, specify the variable, which is to activate the field.
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6 Select the source/target from the Equipment drop-down list. Enter Advantys (the master) here. After selecting the variable type from the drop-down list on the right and the format, enter the register address for the variable. “i” indicates the word and “j” the bit within the word. Note: The Modbus register addresses at the STB port are referenced by means of flags. For this purpose, an offset must be observed. Flag word = Reg.add – 40001. For details about register mapping, see “Communication”.
7 Different formats are available for the display. Text is displayed on the basis of a word value. As well as the text which indicates a certain a value, the numerical value itself can be displayed.
8 The Options tab also indicates
whether the variable is read-only, write-only or read/write. A maximum and minimum value can also be assigned to variables here.
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Using the application
1 The application can be simulated offline (without HMI connected) using the simulation function in the XBT-L1000 software. Activate the function by selecting Simulation Activation from the Simulation menu. In the variables window, you can set and read variables.
2 In order to download the
application from the PC to the Magelis XBT-N401, connect the XBT-Z915 communication cable. Start the download process by selecting Export from the Transfers menu. A message will appear to confirm that the application has been transferred successfully.
3 To download an application
that has already been created first access it by selecting Open from the File menu and then transfer it to the HMI.
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Example application
1 The mode is indicated in the central field on the Main Menu page. From here, you can switch to the other pages.
2 If you select a motor, the page
displaying the actual motor status appears. If Manu Mode is currently active, you can control the motor here using the MOD and ENTER buttons. Press ESC to return to the previous page.
3 By switching to the Time page you can display the date and time.
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Magelis XBT-G
Introduction This application features a Magelis XBT-G 4330 HMI, which is connected to the PLC via the
Uni-Telway protocol. The Vijeo Designer software is used to program and configure the terminal. The steps to be taken in order to create and upload a program are described on the following pages. Setting up the HMI is done as follows:
Create a new project Specify the hardware Select new driver Check communication settings Properties window Create new variables Create new screen Create text Add switches Animation setup Build and download the project Runtime Installer Example project
Create a new Project
1 The Vijeo Designer environment consists of the following elements:
1 - Navigator 2 - Info display 3 - Inspector 4 - Data list 5 - Feedback zone 6 - Toolbox
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2 Start Vijeo Designer and select Create new Project. Click Next to access further setting options.
3 Enter the project name.
Only one platform is required for the example application so select Project with Single Target.
Specify the hardware
4 Enter the details of the terminal that is being used. Target Name: Touchterminal Target Type: XBTG Series XBTG Model: XBTG4330
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5 The terminal is equipped with an Ethernet port so you need to enter the network settings for the terminal here. You will also need to activate these settings via the touch display when you switch on the terminal for the first time. Note: The IP address should be assigned in accordance with the local network.
Select new driver
6 In order to exchange data with the PLC, the Magelis terminal requires a communication driver. On this screen click Add to open up the New Driver Dialog
7 Now select Schneider Electric
Industries SAS as the manufacturer (at the top) and Uni-Telway as the driver. Uni-Telway Equipment will now appear automatically under Equipment and will be used for communication with the Premium PLC. Confirm the settings by clicking OK.
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8 Once you have added the driver, click Finish to exit the configuration process.
Checking and setting communicat-ion parameters
1 Vijeo-Designer now opens the workspace described above with a blank edit screen on the right-hand side.
2 To check the project’s
download properties select Touchterminal in the navigator. In the Property Inspector, click on Download.
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Property Inspector
3 You can check the settings here and if applicable select a serial link. However, an Ethernet connection offers considerable speed advantages.
4 To check the Uni-Telway
settings in the Navigator, click the Project tab, then right-click UnitTelway01 [COM1] under IO Manager and then select Configuration. The Driver Configuration dialog now appears.
5 Set the Transmission Speed
to 19200. Set the remaining interface parameters as follows: COM Port: COM1 Serial Interface: RS-485 Rcv. Time Out: 3 Sec
The configuration must match the setting for the port on the Premium PLC. Confirm the change by clicking OK.
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6 You can rename the equipment to PremiumPLC by right-clicking on UniTelwayEquipment01 and selecting Rename.
7 Right-click again on the name
PremiumPLC to configure the communication equipment. There is no need to change the address settings as the terminal is directly connected to the PLC. The default values of all the other settings can also be left as they are.
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Create New Variables
1 To create a new variable, you first need to select the Variable tab at the bottom of the navigator. Then right-click Touchterminal in the menu and select: New VariableNew…
2 To create variables, the
following information must be entered: Variable Name Data Type Data Source (= External) Address in the PLC To enter the address, click the button next to the device address field.
3 Memory bits and words are
addressed within the PLC; internal formats such as counters (or similar) have to be transferred to memory words if they are to be displayed on the Magelis terminal. With the Discrete data type, bits are addressed. In this case, you will need to enter the word address and the bit number in the word. Click OK to confirm.
4 As soon as you confirm the input in the variable dialog by clicking OK, the variable appears in the list of variables.
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5 In the case of variables where the data type is Integer and the values can be negative, you must click the IO Settings tab and select 2’s Complement in the Signed field.
Create New Screen
1 Right-click Graphical Panels in the Navigator to add a new panel. You can change the name of a panel by right-clicking on the name in the navigator.
Adding text 1 You can add text by clicking
the relevant icon in the tool bar. Once you have set the size, a dialog appears in which you can specify the text content, font, colour etc.
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2 If Text has been selected, you can use the Property Inspector to change the text element’s position, size, colors, etc.
3 To select the Animation
function, select a text element and then right-click with the mouse. You can also edit the animation data in the Property Inspector (described above).
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4 You can animate the following properties: Color Position Value Visible Select the light bulb icon at the end of the edit box in order to enter variables. A variable name that has been entered but not recognized appears in red. After activation you can select a variable for the value animation and the display format. If additional functions are required (such as trigonometric functions), these can be generated via the calculator icon.
Adding a switch
1 You can add a switch by clicking the relevant icon in the menu bar. Once you have set the size, a dialog appears in which you can specify the switch settings.
2 Here you can define what
happens according to the various user actions. As well as enabling the user to switch panels, switches can also be used to modify variables. Switches can also be animated, e.g. change colour according to their status.
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Build and Download the Project
1 To analyze the project before downloading it to the Touch Panel, Select Build from the menu bar followed by Validate All. The results are listed in the Feedback Zone. You can also the Build All menu item.
2 Select the project in the
navigator. Use the menu item Download All (reached via the right mouse button or the Build menu) to transfer the application to the connected HMI. The connection selected at the outset (Ethernet) is used.
Download Problems Runtime Installer
1 If the download fails, you should check the connection and settings. If the terminal is being used for the first time, it may be necessary to transfer a new runtime version to the terminal first. To do this, go to the Windows Start menu and select: Program Files –> Schneider Electric –> Vijeo-Designer –> Runtime Installer Tools.
2 The Runtime Installer starts up. To ensure successful installation, follow the instructions on the right-hand side of the window. Afterwards, try downloading the project again.
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Example project
1 You can select the operating mode on the startup screen. This also displays the state of safety equipment and any errors. Certain errors can be reset by pressing the Reset button. Use the bar at the bottom to switch between the various displays.
2 The CANopen display provides
information about the state of the CANopen bus nodes.
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Example project Ctd.
3 Use the ATV 31 display to control the speed drive. The target (Set) speed and direction of rotation can be specified here for each device. Along with the LEDs, the Actual Speed provides information about the state of the speed drive. You can clear an error by pressing Reset. Press STOP to initiate a fast stop.
4 Use the IclA display to control the compact drive in its various modes. After selecting the display, you will need to enter the target (Set) speed and position. Use START and STOP to change the operating state. The buttons above the menu bar can be used to switch between the two drives that have been installed.
5 Select the TeSys U display to
control the TeSys U module contactors. The state of the devices appears here. Click the relevant buttons to activate and deactivate the devices.
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Importing/ exporting a project
1 To import a project you must first go to the Navigator window and click the Vijeo-Manager tab. Right-click the Vijeo-Manager node and select Import Project. Note: It is only possible to import Vijeo frame archive files (*.vdz files).
2 To export a project you must
first go to the Navigator window and click the Vijeo-Manager tab. Then you need to right-click the project file you want to export and select Export Project. Note: Projects must first be closed before they can be exported (or renamed). If the selected project is still open, the Export Project will be grayed out. In this case, you should save the project and close it.
3 In the Export Project dialog
box, you must specify where you want the *.vdz project file to be saved. Click Save to export the project file.
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PLC
Introduction The PLC chapter describes the steps required for the initialization and configuration
and the source program required to fulfill the functions.
Pre-conditions
Before carrying out the steps described below, you must ensure the following: That the Unity Pro XL software is installed on the PC That the CO file from the SyCon configuration has been created That the Premium PLC is switched on and being supplied with power That the PLC and the PC are linked to one another via the TSX PCX 1031
programming cable. Setting up the PLC is done as follows: Configure Ethernet communication Configure CANopen communication Import variables table Create application program (logic) Connect to PLC and download program
Creating a New Project
1 After starting Unity, the first thing you need to do is create a new project. To do so, you must first select the correct PLC.
2 Double-click Configuration or
X Bus to open a window that will enable you to configure the hardware. Next, drag and drop the CPU to the correct rack position to allow you to insert the correct power supply from the hardware catalog.
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3 Right-click on the rack to replace it with a larger one. Now insert the other hardware modules into the rack by dragging and dropping them from the hardware catalog. Double-click slot A of the CPU module to add a memory module. Assign the TSX CPP 110 CANopen communication module to slot B. Now save the project.
4 Double-click the CPU module to adjust the number of I/O data items. Data areas are already reserved for this purpose. In our example, the following settings need to be made: %M 256 %MW 2000 %KW 1000
Configuring Ethernet communi- cat-ion
1 First, select New Network under Communication and Networks in the Project Browser.
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2 In the Add Network window, select Ethernet as the network type and enter a name for the network under Change Name. Click OK to create the network. To configure the new network, right-click on it and select Open.
3 Input the following settings in
the exact order in which they appear below: Select the model family
(regular connection). The tool tips show the devices that belong to each model family.
Specify the IP address and subnetwork mask.
Now close the window and confirm the changes.
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4 The configured network must be assigned to the hardware. To do this, switch to the Hardware view and double-click the CPU network connection. The window opposite appears. The following three settings should be made and then applied: Select the channel
(in this example, Channel 0) Select the function
(in this example, ETH TCP IP)
Select the network link (the configured connection)
Close the window to validate your settings.
Project settings
1 In the Project Browser, right-click on Station and then select Project Settings.
2 When the Project Settings
dialog opens, click the Language extensions tab. Under Data types, check the box next to Allow dynamic arrays […]. Press OK to confirm the setting.
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Configuring CANopen communication
1 In the Project Browser, right-click CANopen under Configuration and select Open to access the CANopen configuration.
2 A dialog will appear, where
you should click Select Database to load the CANopen configuration that was created previously. Alternatively, you can click the Hilscher button to create a configuration in the SyCon tool. Once the transfer is complete, the most important data appears underneath the file details. You can also choose here whether to use Unity or SyCon for bus configuration. In the example we are using Unity.
3 The upper part of the dialog is for selecting the bus startup characteristics and the assignment of addresses for the input and output areas. In the example project, automatic bus startup is configured. The number of flag words for the inputs and outputs must be adapted in line with the CANopen configuration. If an incorrect entry is made, the numbers will show up red. The inputs start at address %MW1000 and the outputs at %MW1500. For the inputs and outputs, there are 36 and 25 words respectively.
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4 Clicking the Bus configuration button brings up a new dialog where the individual slaves are listed. If you click on one of the slaves in the list, information such as the I/O addresses assigned is displayed on the right. Note: The addresses are shown from top to bottom in order of their position on the bus in the SyCon software. The CANopen addresses are disregarded.
5 The configuration must be confirmed or validated. You can do this either by closing the configuration window or selecting Validate from the Edit menu. Note: You can only save, close and build the project after you have validated it.
Importing variables tables
1 Right-click on Variables & FB instances in the Project Browser and select the Import option.
2 Only *.XSY and *.TXT files can
be used for importing variables. Select a file and click Import to confirm the process. The variables will now be imported.
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2 Double-click on Variables & FB instances in the Project Browser to open the Data Editor, where you can view and modify variables.
Importing FB types
1 In the Project Browser, right-click on Derived FB Types and then select Import.
2 Only files with the extension
*.XDB can be used for importing FB types. Select a file and click Import to confirm the process. The derived FB type will now be imported together with the associated and derived FB data types.
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FB type ATV 1 The ATV function block is used
to control the Altivar 31 speed drive. The atv_state data type drive status word is applied to ATV_IN. Output ATV_OUT (type atv_ctrl) is associated with the drive control word. The Boolean inputs Left, Right, Fast, Slow and Estop are used to control the speed drive. A rising edge at Ackn triggers a speed-drive reset. The bus state is connected to CommOk. The integer inputs RPM1 and RPM2 are used to set the speed for Fast/Slow operation. The Mot... outputs provide binary state information about the speed drive. Spd provides the motor speed as an integer value.
2 The FB data types relating to the ATV block each contain two words. The atv_state structure contains the DriveCom state register for the speed drive and the current speed. The atv_ctrl structure sets the DriveCom command register and the speed.
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FB type ICLA 1 The ICLA function block is
used to control the compact drive via CANopen. There is a communication-PDO array (4 words) for CANopen at both PDO_IN and PDO_OUT. An edge at Config initiates IcIA configuration. Control_IO is used to connect the IO inputs. Address is where the CANopen address is registered. AckError is used for resetting error messages. Inputs Power, Stop, Reset, and Start are supplied by Boolean values. A specific byte combination at Mode sets the operating mode. RPM is used to set the speed and Dest for entry of the target position. ConfRuns, ConfErr, Ready, Error, Stopped, and Finished provide information about the device state and about travel. State is an error status word. Position is where the value for the current position may be found.
2 Only one bit may be set in the input byte for the purpose of setting the operating mode. Each bit position represents a different mode. Bit0 – Sets the position Bit1 – Referencing Bit2 – Point-to-point, absolute Bit3 – Point-to-point, relative Bit5 – Speed profile
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Creating the Application Program
1 Right-click on Sections under MAST, Tasks and Program in the Project Browser and select New Section.
2 A dialog appears in which you
should enter the section name and select the programming language.
3 Right-click in the section
window and select the FFB Input Assistant.
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4 Once you have selected an FFB type, you can assign an instance name. Click OK to position the function block in the section window.
5 Right-click and select
Properties… or double-click on the block to open the Properties window. Here you must define the input data types and input comments.
6 The editor toolbar supports
program creation by enabling program components to be selected quickly. The editor toolbar content changes according to the programming language selected.
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Downloading the program
1 Upon completion of the programming, the entire project must be generated (build or rebuild). To do this, select the relevant menu item or button.
2 Before transferring the program to the PLC, you must first set the PLC connection address. Under Media, select UNTLW01 for a Uni-Telway connection. SYS should be specified as the standard system address. A connection can also be created via TCP/IP if a program with an IP address is already running on the PLC.
3 Once the connection has been set you can transfer the project to the PLC. To do this, select Transfer Project to PLC in the PLC menu.
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Devices
Introduction This chapter describes the steps required to initialize and configure the devices to
attain the described system function.
Altivar 31
General The ATV 31 parameters can also be entered or modified via the front panel. The
advantages of using PowerSuite are that You can save the data onto your PC and duplicate it however you want You can print out the documentation It can help you with online parameter optimization As well as containing the device documentation (installation and programming instructions), the product CD supplied with the Altivar 31 also features a scaled down version of PowerSuite to enable quick and easy parameterization of the variable speed drive.
Connecting the device and reading out data
1 After starting the software, use the Connect function in the Action menu or the equivalent button to establish a connection with the device. Note: Prior to this, you must connect the PC and ATV into the PowerSuite port on the CANopen junction box. Only one speed drive at a time can be connected to the CANopen junction box altivar port (ATV1).
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2 Before the connection is established, you must confirm that you accept the terms of the security warning by pressing ALT+F.
3 Next, you need to enter the
name of the configuration or device.
4 Acknowledge the warning
about transferring the parameters from the device. The current parameters are now transferred from the speed drive to the PC.
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Parameter-izing and transferring data
1 Once the transfer is complete, the speed drive’s online screen appears.
2 In order to make parameter
settings, switch to the configuration screen. To do this, select Configuration from the Display menu… … or use the equivalent icon on the toolbar
3 Select Fast settings in the
configuration view. As a minimum, you must then check the supply-frequency parameters (BFR) and motor parameters: Settings/Drive Parameters –> Motor Characteristics and adjust them as necessary.
4 The CANopen address and
baud rate (trans. speed) can be set for the speed drive under Communication.
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5 Next, close the configuration view and, in the main window, transfer the data to the speed drive by selecting Configure from the Action menu or by pressing the equivalent button.
6 To start the transfer, confirm
the warning message.
1 You can manage the
configurations in the view that is displayed once the connection has been closed. To display an overview of all the configurations created so far, click Display, followed by Configurations. The overview will appear on the left-hand side.
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TeSys U
General Basically, the TeSys U motor control unit comprises:
Power base Control unit Communication module Coil wiring kit Optional: reversing block, Is limiter/isolation block and other modules
Installation Insert the LUCA 05 BL control unit into
the LUB12 power base. To enable communication, slide the LUF C00 communication module with parallel wiring (1) and the LU9B N11C coil wiring kit (2) in underneath the control unit and connect the wiring kit connector to the communication module.
Notice The LUF C00 module with parallel wiring enables motor controls to be connected to
the I/O modules of PLCs quickly and without the need for tools. It replaces conventional systems using a screw terminal block and single-conductor wiring. The module with parallel wiring collects all information regarding the states and control commands of each motor control. The connection module distributes information from the PLC I/O modules to each connected motor control.
Note The following points should be taken into account when selecting components:
1. A 24 V DC LUCx xx BL control unit must be used. The BL extension should be
observed. 2. Different versions of the coil wiring kit are available, depending on which power
base is used. LU9B N11C should be used if the power base has one direction of rotation (LUBxx) and LU9M RC should be used if the power base has two directions of rotation (LU2Bxx).
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Performance
Scan and Cycle time
At the time of going to press, no measurement results were available with respect to scan and cycle times.
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Appendix
Detailed Component List
Hardware-Components
Pos. Amt. Description Part Number Rev./ Vers.
- Master switch 1.1 1 Master switch NSC100N TM16D (MG) 28120 1.2 1 Terminal covers (2x) (MG) 28034 1.3 1 Auxiliary switch OF/SD (MG) 29450 1.4 2 Undervoltage release MN 24VDC (MG) 28085 1.5 1 Locking device (MG) 29370 1.6 1 Undervoltage-release fuse (MG) 25020 1.7 1 Control-voltage tap (MG) 29348
2.1 1 Phaseo power supply 230 V, 72 W, 24V DC
ABL7RP2403
2.2 1 Primary automatic circuit-breaker, 2-pin, 1 A
GB2DB06
- 24V supply Magelis, Safety
- Emergency off
3.1 1 Preventa safety relay XPS-AF XPSAF5130
3.2 1 Mushroom button in integrated housing, tamper-proof, with rotary unlocking
XALK178G
3.3 1 Acknowledgement button – integrated housing
XALD102E
3.4 2 Contactor 5.5 kW, 24 V operation, GL LC1D12BL 3.5 1 Emergency-off fuse + door safety 2 A (MG) 25021 - Premium PLC 4.1 1 Backplane for 12 modules TSXRKY12 4.2 1 Power supply module 230 V, 26 W TSXPSY2600M 4.3 1 Primary automatic circuit-breaker,
2-pin, 1 A GB2DB06
4.4 2 Processor module (Unity), integrated Ethernet
TSXP571634
4.5 1 SRAM memory card,768 kB TSXMRPC768K 4.6 1 CANopen bus master, PCMCIA card TSXCPP110 4.7 2 Digital input module, 16 channels TSXDEY16D2 4.8 1 Digital output module, 16 channels,
(transistor 0.5 A) TSXDSY16T2
4.9 1 Analog input module 16 channels TSXAEY1600 4.10 1 Analog output module, 4 channels,
11 bit +sign TSXASY410
4.11 1 Ethernet, TCP/IP network module, I/Oscanner
TSXETY4103
4.12 4 Terminal block 20-pin, I/O cards TSXBLY01 4.13 2 Telefast terminal block analog input ABE7CPA02 4.14 2 Connection cable SUB-D 25-pin TSXCAP030 4.15 1 Telefast terminal blocks analog input ABE7CPA02 4.16 3 Terminal with integr. microfuse AB1FUSE435U5X 4.17 10 Microfuse 0.5 A, quick-acting ABE7FU050 4.18 10 Microfuse 6.3 A, quick-acting ABE7FU630
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Hardware-Components Pos. Amt. Description Part Number Rev./
Vers. - Magelis XBTG 5.1 1 XBTG touch panel, 256 colors, 7.4‘‘,
serial/Ethernet port XBTG4330
5.2 1 Connection cable: XBTG - PLC 2.5 m XBTZ968 5.3 1 Fuse Magelis XBTG 2 A (MG) 25021
6.1 1 Wall-mounting bracket XVBC12 - Harmony XVB signal beacon 6.2 1 Connection element + cover XVBC21
6.3 1 Light-emitting diode with continuous light, LED 24 V DC, green
XVBC2B3
6.4 1 Light-emitting diode with continuous light, LED 24 V DC, red
XVBC2B4
6.5 1 Light-emitting diode with continuous light, LED 24 V DC, blue
XVBC2B6
6.6 1 Light-emitting diode with continuous light, LED 24 V DC, yellow
XVBC2B8
6.7 1 Audible signal device, 12...48 V XVBC9B 6.8 1 Color-coding kit XVBC22
7.1 3 Altivar 31, CANopen integr. 230 V, 1~, 0.18 kW
ATV31H018M2 - Altivar 31 variable speed drive 7.2 3 DIN-rail mounting kit VW3A11852
7.3 3 Motor circuit-breaker, 4 A VW3A11852
GV2-L08
7.4 3 Auxiliary-switch attachment for motor circuit-breaker
GVAE11
7.5 3 Contactor up to 9 A, 24 V operation, GL
LC1D09BL
8.1 2 EC motor with positioning control, CANopen interface, industrial socket connection
(BL) IFE71/2 CAN-DS/-QDI54/ V-115KPP54
- IclA compact drive
8.2 2 Supply cable, industrial socket connection with open lead end, 3 m
(BL) 0062501470030
8.3 2 Fuse motor current (MG) 25085 8.4 1 Phaseo power supply 400 V, 240 W,
24 V DC ABL7UPS24100
8.5 1 Motor circuit-breaker, transformer fuse
GV2-ME08
8.6 1 Auxiliary-switch attachment for motor circuit-breaker
GVAE11
8.7 2 Contactor up to 9 A, 24 V operation, GL
LC1D09BL
9.1 1 Fuse 16 A 3-pin (MG) 23652 - Remote control cubicle fuse
10.1 1 Phaseo power supply 230 V, 120 W, 24 V DC
ABL7RP2405 - Remote control cubicle 24V supply
10.2 1 Primary automatic circuit-breaker, 2-pin, 1 A
GB2DB06
11.1 1 Preventa safety relay XPS-AF XPSAF5130 - Door safety 11.2 2 Door-safety switch XCSTA791
11.3 2 Actuator for door-safety switch XCSZ12 11.4 1 Acknowledgement button – integrated
housing XALD102E
11.5 1 Contactor up to 9 A, 24 V operation, GL, output supply – STB module
LC1D09BL
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Hardware-Components Pos. Amt. Description Part Number Rev./
Vers. 12.1 1 Fieldbus coupler module for CANopen STB NCO2212 - Advantys STB
I/O platform 12.2 2 Power feeder module 24 V STB PDT3100 12.3 6 Digital input module, 6 channels STB DDI3610 12.4 2 Digital output module, 6 channels STB DDO3600 12.5 1 EOS extension module STB XBE1000 12.6 1 BOS extension module STB XBE1200 12.7 1 Island bus extension cable 0.3 m STB XCA1001 12.8 2 Relay output module, 2 channels STB DRC3210 12.9 1 Analog input module, 2 channels STB ACI1230 12.10 1 Analog output module, 2 channels STB ACO1210 12.11 1 Interface module, 4 x TeSys U, RJ45 STB EPI2145 12.12 1 Bus terminator module island bus STB XMP1100 12.13 2 Backplane for PDT3100 STB XBA2200 12.14 10 Backplane for DDI3610, DD03600,
AVI1230, AVO1210 STB XBA1000
12.15 4 Backplane for XBE1000, XBE1200, DRC3210
STB XBA2000
12.16 1 Backplane for EPI2145 STB XBA3000 12.17 1 Fuse Advantys STB 4 A (MG) 25023 - Magelis XBTN 13.1 1 Text display 8 keys, serial XBTN401 13.2 1 Connection cable: XBTN - STB 2.5 m XBTZ988 13.3 1 Programming cable XBTN - PC XBTZ915 13.4 1 Fuse Magelis XBTN 1A (MG) 25020
14.1 2 Empty housing, 4 recesses XALD04H7 14.2 4 Auxiliary switch block 1 NO contact ZEN-L1111 14.3 1 Lamp holder, LED 24V DC, green ZAL-VB3
- XAL-D Harmony style 5 pushbutton housing
14.4 1 Lamp holder, LED 24 V DC, red ZAL-VB4
14.5 2 Lamp holder, LED 24 V DC, yellow ZAL-VB5 14.6 2 Lamp holder, LED 24 V DC, blue ZAL-VB6 14.7 1 Indicator lamp, round, flat, green ZB5AV033 14.8 1 Indicator lamp, round, flat, red ZB5AV043 14.9 1 Indicator lamp, round, flat, yellow ZB5AV053 14.10 1 Indicator lamp, round, flat, blue ZB5AV063 14.11 1 Illuminated pushbutton, round, flat,
yellow ZB5AW353
14.12 1 Illuminated pushbutton, round, flat, blue ZB5AW363 14.13 1 Pushbutton, round, flat, green “I” ZB5AA331 14.14 1 Pushbutton, round, flat, green “O” ZB5AA432 14.15 1 Flare nut wrench ZB5AZ905
15.1 3 TeSys U power base, 12 A LUB12 15.2 3 Standard control unit 0.25...1.5 kW LUCA05BL 15.3 3 Function module with parallel wiring LUFCOO
- TeSys U module contactor
15.4 3 Coil wiring kit LU9BN11C 15.5 3 Connection cable 1 m, 2x RJ45
connector LU9R10
15.6 1 Contactor up to 9 A, 24 V operation, GL LC1D09BL 16.1 3 I/O module, IP67, 12 In, 4 Out FTB1CN
12E04SPO
16.2 2 Power supply cable 1 m, 5-pin 7/8 connection at both ends
FTXDP2210
16.3 1 Power supply cable 1.5 m, 5-pin 7/8 with open lead end
FTXDP2115
- Advantys FTB I/O module
16.4 1 Cover cap 7/8 connection FTXC78B 16.5 2 Cover cap M12 connection (10x) FTXCM12B 16.6 1 Advantys FTB fuse 2 A (MG) 24886
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Hardware-Components Pos. Amt. Description Part Number Rev./
Vers. 17.1 3 CANopen connector, 9-pin sub-D,
female TSXCANKCDF90T
17.2 2 Altivar junction box, 2x RJ45 ports VW3CANTAP2
- CANopen infrastructure
17.3 3 Altivar branching cable 1 m, 2x RJ45 connector
VW3CANCARR1
17.4 1 Junction box, 4x 9-pin sub-D, male VW3CANTDM4 17.5 2 IclA IFE CANopen connector set,
M12 connector (plug + socket) (BL) 0062501526001
17.6 1 Branching cable 1 m, 2x 9-pin sub-D connector
TSXCANCADD1
17.7 3 Bus connection cable for FTB 1 m, 5-pin M12 angular connection at both ends
FTXCN3210
17.8 1 Terminating resistor M12 for FTB FTXCNTL12 17.9 1 CANopen cable, 50 m TSXCANCD50
Pos. Amt. Description Part Number Rev./ Vers.
Software-Components
18.1 1 Unity Pro XL single-user license
UNYSPUFUCD20 V2.1
18.2 1 SyCon SYCSPULFUCD29M V2.9 18.3 1 Advantys Configuration
Software incl. RS232 cable STBSPU1000 V2.0
18.4 1 CANopen Symbol Tool V1.4 18.5 1 PowerSuite ATV31 V2.0 18.6 1 Vijeo Designer VJDSPULFUCDV10M V4.20 18.7 1 XBT-L1000 XBTL1003M V4.42
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Component Protection Classes
Mounting Location / Protection Class Component In the field
IP55/IP65 Frontside
IP65 Cabinet
IP20 Master switch NSC100N X IP40 Safety relay XPSAF X Safety position switch X Emergency-off pushbutton housing X
4-button pushbutton housing, empty X
Signalers, all colors, flat X Illuminated pushbuttons, all colors, flat X
Auxiliary switch module with LED + 1 auxiliary switch (1x NO), all colors
X
Contactor, 24 V DC operated, 3-pole AC 3, 1x NO + 1x NC X
Motor circuit-breaker, all types and ratings X
Miniature circuit breaker, all types and ratings X
Motor circuit-breaker, all types and ratings X
Phaseo power supply, all types X Altivar 31 variable speed drive X IclA IFE IP54,
IP41 shaft gland
TeSys U module contactor X Advantys STB I/O platform X Advantys FTB I/O module IP67 XVB signal beacon X XBT-N display terminal X X XBT-G display terminal X X Premium PLC, all modules X
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Component Features
Components Compact NSC100N circuit-breaker
Max. rated current 100 A, 3 poles, manual operation via
rocker arm Breaking capacity at AC 50/60 Hz 240 V – 42 kA
480 V – 18 kA 600 V – 10 kA
Overload and short-circuit protection via integrated
thermo-magnetic tripping system Temperature range: -25 to +70°C Specially designed for machine protection Auxiliary switch, undervoltage release, shunt release,
terminal covers, phase separator, rotary drive, locking device (accessory)
Approvals: UL508/IEC 60947-2/CSA 22-2
Preventa safety relays XPSAF5130 Category 4 to EN 954 Part 1 24 V AC/DC Power consumption < 5VA Monitoring of emergency-off circuits and position switches 3 safety-oriented switching contacts 3 diagnostic LEDs on front panel Adjustable start-button monitoring function Approvals: UL, CSA
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Components Ctd.
Preventa safety position switch XCSTA 10 A short-circuit protection No locking of isolated actuator Convertible operating head, can be operated from 8
directions 2 cable entries Plastic-clad Approvals: UL, CSA
XAL-K pushbutton housing: EMERGENCY-OFF pushbutton Housing for 1-5 front elements, each able to
accommodate a maximum of 3 auxiliary-switch blocks Can be mounted on front element or in housing base Front elements can be labeled however you want Approvals: UL Listed, CSA
TeSys Model D contactors Up to 75 kW at 400 V, AC-3
Integrated quick-acting auxiliary switch, 1 NC contact, 1 NO
contact Various operating voltages, even with low power
consumption Additional auxiliary-switch blocks can be mounted Approvals: UL, CSA
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Components Ctd.
GV2-ME08 motor circuit-breaker Thermo-magnetic tripping Adjustable tripping current
Lockable Temperature range: -25 to +70°C Approvals: UL, CSA, CEBEC, GOST, TSE, BV, GL, LROS,
DNV, PTB, EZU, SETI, RINA
GV2-L08 motor circuit-breaker Magnetic tripping for short-circuit protection Rotary drive for door mounting Lockable Temperature range: -25 to +70°C Approvals: UL, CSA, TSE, BV, GL, LROS, DNV
GB2-DB circuit-breaker Thermal and magnetic protection of transformers, primary 2 poles Maximum operating voltage: 415 V Temperature range: -20 to +60°C CE approval
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Components Ctd.
Phaseo power supply unit: ABL7RE2403, ABL7RE2405 and ABL7UPS24100 Switched-mode electronic power supply with line filter 100..240 V AC 1~/24 V DC (adjustable)
3 A, 5 A or 10 A, secondary Slimline design Indication of input and output voltage (with ABL7RE) via
LEDs Can be connected in parallel (with ABL7RE) Short-circuit-proof and protected against overload with
manual or automatic reset Approvals: UL, CSA, TÜV, Ctick (ABL7UPS: cULus, cRLus)
CANopen junction box VW3CANTAP2 2 CANopen slaves can be connected via RJ45
(Altivar/Lexium) Third port enabling connection of a PC for configuration via
PowerSuite
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Components Ctd.
Altivar variable speed drive: ATV31H018M2 0.18kW, 200V ...240 V AC single-phase
Integrated class B EMC filter Temperature range: - 10..+ 50°C
Speed range from 1 to 50 (0...500 Hz) Speed control with flow vector check Operation via Modbus or CANopen possible 2 analog inputs plus 1 analog output 6 digital inputs 2 or 3 digital state outputs possible Protection of drive and motor Configurable via PowerSuite software Compact design, side-by-side installation also possible on a
DIN rail using bracket VW3A11852 Approvals: UL, CSA, NOM 117, C-Tick
IclA IFE compact drive Output power 74/117 W (24/36 V DC incoming supply) Maximum current consumption: 6 A Torque range 0.17 Nm; 3.1 ... 11 Nm (with gears) High current-free latching torque Speed range of up to 4800 rpm (without gears) Temperature range: 0..+ 65°C
Compact, as motor and electronics form a single unit Quick and easy in respect of installation and EMC Optional industrial plug and socket connection Equipped for communication via CANopen, Profibus DP or
RS485 Operating modes: referencing, manual running, point-to-
point, speed profile Approvals: cRLus, CE
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Components Ctd.
TeSys U module contactor Protection and switching of single or three-phase motors Protection against overcurrents, short-circuits and thermal
overload Modules can be mounted safely and easily by snapping
them onto the power base Power base for one or two directions of rotation Various control units, e.g., for application monitoring
(running time, number of errors, motor-current values), log (error memory), alarms
Communication modules for parallel wiring, Modbus and
AS interface; FIPIO, Profibus-DP, DeviceNet also possible, for example, if gateway modules are used
Use of additional auxiliary switches supported Temperature range: -25..+ 70°C (multifunctional control unit
up to +55°C) Approvals: UL, CSA
Advantys STB I/O module Open, modular I/O system Easy to set up using Advantys Configuration Software Power distribution, signal acquisition and power
management via island bus Fieldbus coupler modules for Ethernet TCP/IP, CANopen,
Modbus Plus, Fipio, INTERBUS, Profibus DP and DeviceNet
Gateway functionality with CANopen extension module EMC-protected Approvals: UL, CSA
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Components Ctd.
Advantys FTB I/O module Suitable for use in harsh environments Also available with metal housing for extreme environments Communication possible via CANopen, DeviceNet,
Profibus-DP or Interbus Combined input/output module Diagnostic state information via LEDs and via the bus for
each channel and for the module so that faults can be pinpointed
Possible to connect Desina sensors with integrated
diagnostic function Outputs protected against short-circuits and overvoltages Temperature range: 0 to +55°C UL Listed certification
Harmony XVB signal beacon Visual and audible signal device with continuous, flashing or
high-speed flashing light Green, red, orange, blue, yellow and transparent lights. A maximum of 5 signaling elements can be combined Stackable and with twist and lock function for easy
installation Temperature range: -25..+ 50°C
Approvals: CSA, UL
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Components Ctd.
Magelis XBT-N401 text display LCD display, backlit, 8 keys (4 of which are freely
configurable and allow for flexible assignment) Compatible with many different devices using Modbus or
Uni-Telway communication Quick programming with no need for formatting, startup
wizard, simulation without PLC Different languages and fonts can be selected Optimum dimensions for straightforward installation 2 spring clamps for easy mounting Temperature range: 0..+ 55°C
Approvals: CE, UL, CSA
Magelis XBT-G4330 display terminal Touch panels (STN/TFT technology) with 24 V DC supply Flat design Brightness and contrast adjustment Supports communication via Uni-Telway, Modbus and (to
some extent) Ethernet TCP/IP Memory expansion via CF card (for application) Temperature range: 0..+ 50°C
Approvals: UL, CSA
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Components Ctd.
Premium PLC Various communication cards for Fipway, Modbus Plus,
Fipio Agent, Uni-Telway, Modbus/Jbus, CANopen, modem, serial interfaces, Ethernet TCP/IP
Memory expansion via PCMCIA card (RAM or Flash
EPROM) Real-time clock Four programming languages in Unity (SFC, LD, ST, IL) Program can be edited in RUN mode Digital and analog input/output modules Control, counter, positioning and communication modules Temperature range: 0..+ 60°C (+5..+55 to IEC 1131-2)
Approvals: UL, CSA, BV, DNV, GL, LR, RINA
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As standards, specifications and designs change from time to time, please ask for confirmation of the information given in this publication. 118
Contact
Author Telephone E-Mail
Schneider Electric GmbH Customer & Market System & Architecture Architecture Definition Support
+49 6182 81 2555 [email protected]