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Premium PLCs
TSX 57/PCX 57
Communication
Network and Bus Interfaces
Installation manual Volume 4
TSX DM 57 xx eng
2
Document Set
At a Glance
This documentation is made up of 5 Volumes: l l
Volume 1 l l
Racks/Supplies/Processors
Implementation/Diagnostics/Maintenance l
Standards and operating conditions l
Process supply
Volume 2 l l
Discrete interfaces l
Safety
Volume 3 l l
Counting l
Motion control
Volume 4 l l
Communication l
Network and bus interfaces
Volume 5 l l
Analog
Weighing
Document Set
TSX DM 57 xx
3
Document Set
4
TSX DM 57 xx
Table of Contents
About the Book . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
Part I
Terminal Port Communication . . . . . . . . . . . . . . . . . . . . 15
Chapter 1
Terminal Port. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
1.1
Communication with a programming/adjustment terminal . . . . . . . . . . . . . . . . . 21
Communicating with a man-machine interface console . . . . . . . . . . . . . . . . . . . 22
UNI-TELWAY master/slave communication . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23
1.2
Programming/adjustment terminal and man-machine interface console . . . . . . 30
1.3
Chapter 2
TSX P ACC 01 device . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 47
5
6
2.1
2.2
Connecting to Premium and Atrium PLCs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 55
TSX P ACC 01 connector pin configuration. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 57
2.3
Part II
Processor-integrated master FIPIO communication . . . 65
Chapter 3
Processor-integrated master FIPIO communication . . . . . . . 67
Integrated FIPIO link on Premium/Atrium processors . . . . . . . . . . . . . . . . . . . . . 70
Part III
AS-i bus interface: TSX SAY 100 module . . . . . . . . . . . . 73
Chapter 4
AS-i bus interface module: TSX SAY 100 . . . . . . . . . . . . . . . . 75
4.1
Overview of AS-i products from the Schneider catalog . . . . . . . . . . . . . . . . . . . . 78
4.2
Specific Display Panels on the TSX SAY 100 Module . . . . . . . . . . . . . . . . . . . . 93
4.3
4.4
Moving between the different display modes . . . . . . . . . . . . . . . . . . . . . . . . . . 101
Viewing the state of input/output bits for each slave . . . . . . . . . . . . . . . . . . . . . 103
4.5
Operating modes of the TSX SAY 100 module. . . . . . . . . . . . . . . . . . . . . . . . . 105
Operating modes of the TSX SAY 100 module. . . . . . . . . . . . . . . . . . . . . . . . . 105
4.6
Part IV
AS-i V2 bus interface: TSX SAY 1000 module . . . . . . . 111
Chapter 5
AS-i V2 Bus Interface Module: TSX SAY 1000 . . . . . . . . . . . . 113
5.1
Overview of AS-i Products from the Schneider Catalog . . . . . . . . . . . . . . . . . . 116
Introduction to the Main Constituent Elements . . . . . . . . . . . . . . . . . . . . . . . . . 117
5.2
Description of the TSX SAY 1000 Module . . . . . . . . . . . . . . . . . . . . . . . . . . . . 121
Specific Display Panels on the TSX SAY 1000 Module . . . . . . . . . . . . . . . . . . 128
Technical Characteristics of the AS-i V2 Bus . . . . . . . . . . . . . . . . . . . . . . . . . . 129
5.3
5.4
5.5
Operating Modes of the TSX SAY 1000 Module. . . . . . . . . . . . . . . . . . . . . . . . 135
Operating Modes of the TSX SAY 1000 Module. . . . . . . . . . . . . . . . . . . . . . . . 135
7
8
5.6
5.7
Part V Communication: TSX SCY 11601/21601 modules and
PCMCIA cards . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 143
Chapter 6
At a Glance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 145
Chapter 7
Installing TSX SCY 11601/21601 modules . . . . . . . . . . . . . . . 149
7.1
7.2
7.3
7.4
TSX SCY 21601 module's host channel compatibility . . . . . . . . . . . . . . . . . . . . 155
TSX SCY 21601 Host Channel Compatibility . . . . . . . . . . . . . . . . . . . . . . . . . . 155
7.5
7.6
7.7
7.8
Connection of TSX SCY 21601 to Uni-Telway field bus . . . . . . . . . . . . . . . . . . 164
Reminder on adapting RS 485 distributed line for the TSX SCY 21601 . . . . . . 166
Connection of TSX SCY 11601/21601 modules to the Jbus/Modbus field bus . 169
Reminder on single line polarization in RS 485 . . . . . . . . . . . . . . . . . . . . . . . . . 170
Character Mode connection for TSX SCY 21601 . . . . . . . . . . . . . . . . . . . . . . . 174
Consumption of TSX SCY 11601/21601 modules. . . . . . . . . . . . . . . . . . . . . . . 175
Chapter 8
Installing PCMCIA cards . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 177
8.1
8.2
8.3
Connecting the PCMCIA card reception channel . . . . . . . . . . . . . . . . . . . . . . . 183
Precautions when connecting PCMCIA . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 184
Product references for PCMCIA cards and installation . . . . . . . . . . . . . . . . . . . 186
8.4
Point to point connection in Character Mode (DTE <==> DTE) . . . . . . . . . . . . 194
Uni-Telway, Modbus or Character Mode via Modem . . . . . . . . . . . . . . . . . . . . 195
8.5
TSX SCP 112 connection with April 5000/7000 PLCs . . . . . . . . . . . . . . . . . . . 202
8.6
Connection to the UNI-TELWAY network . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 209
Multi-protocol asynchronous link connection RS 422 . . . . . . . . . . . . . . . . . . . . 214
8.7
8.8
8.9
Connection of the TSX MBP 100 card . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 218
General principle for connecting the PCMCIA card. . . . . . . . . . . . . . . . . . . . . . 220
Grounding the TSX MBP CE 030/060 cable . . . . . . . . . . . . . . . . . . . . . . . . . . . 221
Connecting the TSX MBP CE 030/060 cable to Modicon connection device 990 NAD
8.10
8.11
Precautions when connecting PCMCIA cards. . . . . . . . . . . . . . . . . . . . . . . . . . 227
Precautions for connecting PCMCIA cards . . . . . . . . . . . . . . . . . . . . . . . . . . . . 227
8.12
9
10
Chapter 9
TSX SCA 64 connection device . . . . . . . . . . . . . . . . . . . . . . . 229
9.1
9.2
9.3
9.4
9.5
9.6
Connecting the shield to the local ground and to the two ends of the cable
Connecting the shield to the local ground at one end of the cable and to the local
ground via a surge suppressor at the other end . . . . . . . . . . . . . . . . . . . . . . . . 242
Connecting the shielding to the local ground at one end and isolating it from the
9.7
Device Configuration and Transmission Pair Polarization . . . . . . . . . . . . . . . . . 244
4-wire Configuration with 2-pair Polarization via External Power Supply . . . . . 245
4-wire Configuration with Polarization of One Pair by the Master Station and the
2-wire Configuration with M+, M- Pair Polarization by the Master Station or a Slave
9.8
Part VI Communication : modules TSX ETY 110/4102/PORT/5102
et et TSW WMY 100 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 257
Chapter 10
Communication: TSX ETY 110 module . . . . . . . . . . . . . . . . . 259
10.1
10.2
10.3
10.4
10.5
10.6
10.7
10.8
Chapter 11
Communication: Modules TSX ETY 4102/PORT/5102. . . . . . 275
11.1
11.2
11.3
11.4
Installation of TSX ETY 4102/PORT/5102 Modules . . . . . . . . . . . . . . . . . . . . . 279
Wiring/Unwiring with Power Switched on . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 282
11.5
11.6
11.7
11.8
11.9
Part VII
Communication: PCMCIA Modem card . . . . . . . . . . . . 291
Chapter 12
Installing the TSX MDM 10 module . . . . . . . . . . . . . . . . . . . . . 293
12.1
11
12
12.2
12.3
12.4
12.5
12.6
Index
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 307
About the Book
At a Glance
Document Scope
This manual describes how to install network and bus interfaces on PLCs from the
Premium and Atrium range.
It is made up of 7 sections:
1. Communication on the processor’s terminal port
2. FIPIO communication master integrated into processors
3. AS-i bus interface: TSX SAY 100module
4. AS-i bus interface: TSX SAY 1000module
5. Communication: TSX SCY 21601 module and PCMCIA cards
6. Communication: TSX ETY 110/410/PORT/510 modules
7. Communication: TSX MDM 10 PCMCIA Modem card
User Comments
We welcome your comments about this document. You can reach us by e-mail at
TSX DM 57 xx
13
About the Book
14
TSX DM 57 xx
Terminal Port Communication
I
At a Glance
Aim of this Part
What's in this
Part?
This part introduces the communication function via the Terminal Port for Premium and Atrium processors
This part contains the following chapters:
Chapter
1
2
Chapter Name
Terminal Port
TSX P ACC 01 device
Page
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15
Terminal Port
16
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Terminal Port
1
At a Glance
Aim of this
Chapter
What's in this
Chapter?
This Chapter introduces the functions of the Terminal Port for Premium and Atrium processors.
This chapter contains the following sections:
Section
1.1
1.2
1.3
Topic
Introduction to the terminal port
Connections
Appendices
Page
17
TSX DM 57 xx
Terminal Port
1.1
Introduction to the terminal port
At a Glance
Aim of this
Section
What's in this
Section?
This Section introduces the communication function from the Terminal port of a PLC.
This section contains the following topics:
Topic
Introduction to the terminal port
Communication with a programming/adjustment terminal
Communicating with a man-machine interface console
UNI-TELWAY master/slave communication
Character string communication
Page
18
TSX DM 57 xx
Terminal Port
Introduction to the terminal port
At a Glance
Premium PLCs
As the terminal port uses master UNI-TELWAY, slave UNI-TELWAY and character l l l string communication methods; the following documentation must be referred to for installing the hardware and software for these different methods of communication:
TSX DG UTW E: UNI-TELWAY Bus communication (user guide).
TSX DR NET E: X-WAY communication (reference manual).
TLX DS COM PL7 xx E: Micro/Premium PLC communication (software installation manual).
The terminal port on Premium processors is a non-insulated RS 485 link made up of two 8-pin mini-DIN connectors. These two connectors function identically and are found on the processor. They are marked with TER and AUX and are used to physically connect two pieces of equipment together at the same time, such as a programming/adjustment terminal and a man-machine interface console.
Illustration:
TSX DM 57 xx
The TER connector also allows power to be supplied to a device which does not have its own power supply (RS 485/RS 232 connecting cable converter, insulating device TSX P ACC 01 (See
TSX P ACC 01 device, p. 47), etc).
The terminal port functions by default in master UNI-TELWAY mode. Via configuration it is possible to switch to UNI-TELWAY slave or character mode.
Note: The communication mode (e.g. master UNI-TELWAY, UNI-TELWAY slave or character mode) is the same on both the TER and AUX connectors.
19
Terminal Port
Atrium PLCs
Atrium processors have one single TER terminal port which is identical in all respects to the TER terminal port on Premium PLCs. This is a non-insulated RS 485 link which is made up of a 8-pin mini DIN connector which is used to physically link up a device, such as a programming/adjustment terminal or a man-machine interface console.
Illustration:
20
This connector is used to supply power to a device which does not have its own power supply (connecting cable converter RS 485/RS 232, insulating device TSX P
ACC 01 (See
TSX P ACC 01 device, p. 47), etc).
The terminal port functions by default in master UNI-TELWAY mode. Via configuration it is possible to switch to UNI-TELWAY slave or character mode.
Note: Using a TSX P ACC 01 insulating device makes it possible to duplicate the terminal port in order to use two TER and AUX ports like on the Premium PLC processor
TSX DM 57 xx
Terminal Port
Communication with a programming/adjustment terminal
General
Configured in master UNI-TELWAY (default function), the terminal port is used to connect a programming/adjustment terminal.
Premium station:
Atrium station:
Programming/adjustment terminal
FT 2010/FTX 517 - PC
TSX DM 57 xx
PCX 57
Programming/ adjustment terminal
Host PC
Programming/ adjustment terminal
FT 2010/FTX 517 - PC
Note: When using an Atrium Station, the programming terminal is generally the PC which accepts the PCX 57 processor. However, as for a Premium station, the programming terminal can also be a PC type terminal connected to the processor port.
21
Terminal Port
Communicating with a man-machine interface console
General
Configured in master UNI-TELWAY mode (default function), the terminal port makes it possible to manage man-machine interface device.
The man-machine interface device uses UNI-TE protocol to communicate with the local PLC and the other stations on the network architecture.
When using a Premium PLC, the man-machine interface terminal should be connected to the AUX connector in order to free the TER connector for possible connection of a programming/adjustment terminal.
Premium station:
Master Premium
22
Atrium station:
CCX 17 slave
Host PC
Master Atrium
CCX 17 slave
TSX DM 57 xx
Terminal Port
UNI-TELWAY master/slave communication
General
The default communication mode for the terminal port is master UNI-TELWAY. It is mainly used to link up a programming terminal and a slave man-machine interface console.
Illustration:
Master Premium
Client
Slave
Client/Server
Slave
Client/Server
FT 2010/FTX 517
CCX 17
Note: When using an Atrium PLC or if the processor only has one terminal port, this type of connection can be made by using a TSX P ACC 01 device. (See
TSX
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23
Terminal Port
Character string communication
General
This mode is used to connect up a printer or specialized console (screen control, table controller etc.) to the terminal port of a Premium or Atrium PLC.
Illustration
Premium
TSX RKY
24
Atrium or
Control screen or
Loop Controller
Printer
Control screen or
Loop Controller or
Printer
TSX DM 57 xx
Terminal Port
1.2
Connections
At a Glance
Aim of this
Section
What's in this
Section?
This Section deals with the different connections of the Terminal port.
This section contains the following topics:
Topic
Connections
Programming/Adjustment terminal
Man-machine interface console
Programming/adjustment terminal and man-machine interface console
Modem on terminal port
Master UNI-TELWAY
Slave UNI-TELWAY
Inter-PLC UNI-TELWAY
Inter-device UNI-TELWAY
Master PLC type TSX model 40
Character String
Summary table of terminal port connections
Page
TSX DM 57 xx
25
Terminal Port
Connections
General
The connector marked TER is used to connect any device which supports UNI-
TELWAY protocol, in particular devices which do not have their own power supply
(RS 485/RS 232 connector cable converters, TSX P ACC 01 (See TSX P ACC 01
device, p. 47) isolation device, etc).
The connector marked AUX (only on Premium PLCs) only enables devices which have a power supply to be connected (eg. man-machine interface console, thirdparty devices, etc).
The terminal port has three function modes: l l l
Master UNI-TELWAY (default configuration)
Slave UNI-TELWAY
Character string
Illustration:
Atrium
Premium
Methods of connection
Note: For Premium PLCs with two connectors (TER and AUX), the operating mode defined in configuration (master UNI-TELWAY, slave UNI-TELWAY, character mode) is the same for both connectors.
l l l l l l
According to the operating mode selected in configuration, the terminal port is used to connect:
Premium PLC programming and adjustment terminals
Man-machine interface devices
Another PLC, using the TSX P ACC 01 connection device
UNI-TELWAY devices (sensors/actuators, speed controller etc.)
A printer or a control screen (link in character string mode)
A modem
Note: Connecting a Premium/Atrium PLC slave to a UNI-TELWAY Bus requires the use of a TSX P ACC 01 device.
26
TSX DM 57 xx
Terminal Port
Programming/Adjustment terminal
General
Terminals with their own power supply (FTX 417, FTX 517) can be connected to both TER and AUX connectors on Premium processors.
If a terminal does not have its own power supply, it must be connected to the processor TER connector.
The programming terminal uses UNI-TE protocol to program, adjust or diagnose the local PLC and all the station devices.
If the PLC is connected to a network architecture, the transparency network enables the programming terminal to reach all the devices in the architecture.
The product reference for the different connection cables is given below.
TSX DM 57 xx
27
Terminal Port
Examples of connection:
Premium
TSX RKY
OR
PC/FT2100
Host
PC
Programming/adjustment
FTX 517
Atrium
PC/
FT2100
Programming/adjustment
OR
Programming/adjustment
FTX 517
Programming/adjustment
28
TSX DM 57 xx
Terminal Port
Man-machine interface console
General
XBT-Z968
The man-machine interface device uses UNI-TE protocol to communicate with the local PLC and the other stations in the network architecture.
A man-machine console with its own power supply on a Premium PLC must be connected to the AUX port in order to leave the TER port free for a terminal which needs a power supply (FTX 117 Adjust for example).
The product references for connector cables between the terminal port and a CCX
17 man-machine interface console are given below.
Examples of connection:
Premium TSX RKY
CCX 17: MMI console
T CCX CB10 002
(provided with the CCX 17)
Host PC
T CCX CB10 002
(provided with the CCX 17)
XBT-Z968
CCX 17: MMI console
TSX DM 57 xx
29
Terminal Port
Programming/adjustment terminal and man-machine interface console
General
The terminal port on a Premium processor can manage two devices in multidrop: the programming/adjustment terminal and an man-machine interface console.
Each of the two connectors on the processor can receive one of these devices.
Examples of connection:
T FTX CBF 020
XBT-Z 968
FTX 517:
Programming/ adjustment terminal
T CCX CB10 002
(provided with the CCX 17)
CCX 17:
MMI console
Note: Each connected terminal can be disconnected without disrupting the operation of the other. For an Atrium PLC or if the processor only has one terminal port, this type of connection can be made by using a TSX P ACC01 (See TSX P
30
TSX DM 57 xx
Terminal Port
Modem on terminal port
General
Modem characteristics
The terminal port on Premium PLCs is compatible with a modem connection in all protocols: Master UNI-TELWAY, Slave UNI-TELWAY and Character string.
The modem which is to be connected must have the following characteristics:
1. Support 10 or 11 bits per character if the terminal port is used in UNI-TELWAY mode: l l
1 bit for Start
8 bits of Data
1 bit for Stop l l
Odd parity or without parity
2. Operate without any data compression if the terminal port is used in UNI-
TELWAY.
3. Be able to be "forced DTR signal" configured for its RS 232 serial port (if the modem is used in response mode), as this signal is not connected by the cable.
4. Operate without flow control (neither hardware: RTS/CTS, or software: XON/
XOFF) for its RS 232 serial port, as the cable to be used for the terminal port can only carry TX, RX and GND signals.
5. Operate without data carrier check. Warning: this operating mode also uses RTS and CTS control signals.
6. Accept an incoming telephone call while characters arrive at its RS 232 serial port
(if a modem/telephone network is used in response mode on a terminal port configured in master UNI-TELWAY).
Note: It is strongly recommended that you check with your dealer that the abovementioned characteristics are offered by the intended modem.
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31
Terminal Port
Examples
Connecting to a Premium PLC:
Note: Connection on an
Atrium is identical.
TSX CTC 09 adapter if necessary
Modem
TSX PCX 1130 l l
In Master UNI-TELWAY mode with the terminal port connected to a modem/ telephone network in response mode, this modem must have all the above characteristics (1 to 6).
In character string mode with the terminal port connected to a modem via a specialized line, this modem must have the characteristics of 3 to 5 above.
Configuring the terminal port
l l
In UNI-TELWAY mode the following parameters must be observed and set in the configuration in PL7 software:
The wait timeout must be between 100 and 250 ms
In master mode the number of configured slaves must correspond to the actual l number of slaves present on the bus.
In slave mode the number of addresses must correspond to those used.
32
TSX DM 57 xx
Terminal Port
Master UNI-TELWAY
General
This is the terminal port default operating mode. It is principally used for: l Connecting a programming/adjustment terminal and a man-machine interface console if a Premium PLC is used.
l Connecting a programming/adjustment terminal or man-machine interface console in the case of an Atrium PLC with only one terminal port.
Examples of connection:
Premium master
T FTX CBF 020
XBT-Z 968
Client
Client/Server
FTX 517
slave
Client/Server
T CCX CB10 002
(provided with the
CCX 17) slave
CCX 17
Important information
TSX DM 57 xx
Note: In the case of an Atrium station where the processor only has one terminal port, this type of connection can be made by using a TSX P ACC 01
The master can scan up to eight link addresses: l l
Link addresses 1,2 and 3 are reserved for the programming terminal.
The five other addresses are available for connecting a device such as a manmachine interface, slave PLC, sensors/actuators or any other slave device which supports UNI-TE protocol. Addresses 4 and 5 are reserved for a man-machine interface console, it one is used (addresses are forced by using a XBT-Z 968 cable).
This functioning mode is immediately operational. Within the limits of the default configuration, no installation phase is required to connect a device to this type of link.
33
Terminal Port
Slave UNI-TELWAY
General
The UNI-TELWAY slave protocol of the terminal port is used to build a slave
Premium or Atrium PLC into a UNI-TELWAY bus managed by a Premium or Atrium
PLC (PCMCIA communication card or terminal port).
For this connection to be possible it is essential to use a TSX P ACC 01 connection device.
Examples of connection:
Premium master
Communication card
PCMCIA
TSX SCP 114
S1=ON
S2=ON
TSX P
ACC 01
TSX
SCA 50
TSX SCP CU 4030 cable
UNI-TELWAY bus
TSX
SCA 50
TSX
SCA 62
TSX CSC 015
S1=ON
S2=ON
TSX P
ACC 01
Premium
Slave
ATV 16
Slave
TSX 17-20
Slave l l l
A slave PLC manages up to three consecutive link addresses:
Ad0 (system address
Ad1 (client application address)
Ad2 (listen application address)
Atrium
Slave
34
TSX DM 57 xx
Terminal Port
Inter-PLC UNI-TELWAY
General
The terminal port on Premium processors allows two PLCs to be connected, one the master and the other the slave.
For this connection to be possible it is essential to use a TSX P ACC 01 (See TSX
P ACC 01 device, p. 47) connection device. The different options for connecting this
device are given later.
Example of connecting two
Premium PLCs
Illustration:
Premium master
Premium slave
TSX PCX 1031
FT 2100 slave
T FTX CB 1020/1050
TSX P ACC 01
S1=ON
S2=ON
TSX DM 57 xx
35
Terminal Port
Example of connecting a
Premium PLC and an Atrium
PLC
Illustration:
Premium master
TSX PCX 1031
TSX RKY
FT 2100 slave
Atrium slave
T FTX CB 1020/1050
TSX P ACC 01
S1=ON
S2=ON
36
TSX DM 57 xx
Terminal Port
Inter-device UNI-TELWAY
General
Example
The terminal port on Premium/Atrium PLCs enables them to be connected to a UNI-
TELWAY bus in order to communicate with devices such as speed controllers, sensor/actuators or with other PLCs
Connecting a Premium/Atrium (master or slave) PLC to a UNI-TELWAY bus requires the use of a TSX P ACC 01 (See
TSX P ACC 01 device, p. 47) device.
Examples of connection:
FTX 417 slave
Premium master
T FTX CBF 020
S1=ON
S2=ON
TSX P ACC 01
TSX SCA 50
UNI-TELWAY bus
TSX SCA 62
TSX DM 57 xx
CCX 17
ATV 16 slave
The connected devices communicate with the PLC using UNI-TE protocol.
Communication between the different components is allowed.
The programming terminal can directly access all these devices to carry out adjustments and diagnostics functions.
Note: To install TSX SCA 50 and TSX SCA 62 devices, consult the TSX DG UTW manual:
UNI-TELWAY Bus communication.
37
Terminal Port
Master PLC type TSX model 40
General
A TSX/PMX model 40 PLC can also be configured in master mode on a UNI-
TELWAY bus and can control slave Premium/Atrium PLCs
Example of connection
FT 2... slave
TSX 107-40 master
TSX PCX 1031
S1=ON
S2=ON
TSX P ACC 01
TSX CSB 015
S1=ON
S2=ON
TSX SCA 62
Premium slave
UNI-TELWAY bus
TSX P ACC 01
Premium slave
Note: To install TSX SCA 50 and TSX SCA 62 devices, consult the TSX DG UTW manual: UNI-TELWAY Bus communication
38
TSX DM 57 xx
Terminal Port
Character String
General
The terminal port, when configured in character mode, can be used to connect a device such as a printer, display screen or a specialized console (table controller for example).
Examples of connection:
Premium
TSX RKY
TSX DM 57 xx
OR
RS485/RS 232 converter cable
TSX PCX 1031
Control screen does not manage the RTS signal
Loop
Controller
Host PC
Atrium
Converter cable RS485/
RS 232 TSX PCX 1031
Control screen does not manage the RTS signal
OR
RS485/RS 232 converter cable
TSX PCX 1031
RS485/RS 232 converter cable
TSX PCX 1031
RS485/RS 232 converter cable
TSX PCX 1031
Printer
Loop
Controller
RS485/RS 232 converter cable
TSX PCX 1031
OR
OR
Printer
39
Terminal Port
Note: In order to ensure all types of connection TSX PCX 1031 and TSX PCX 1130 cables are delivered with adapters: l The TSX PCX 1031 cable is delivered with two adapters/converters: l
TSX CTC 07: male 9-pin to female 25-pin.
l l
TSX CTC 08: male 9-pin to male 25-pin.
The TSX PCX 1130 cable is delivered with one adapter/converter: l
TSX CTC 09: male 9-pin to male 25-pin.
Precautions of
Use
The TSX PCX 1031 cable ensures RS 485/RS 232 conversion and provides
’peripheral slave’ information for the printer. It does not function on the AUX port and
the connected device must manage the RTS signal.
To use the TSX PCX 1031 cord, one of the following TER port configurations must be used: l l l l
7 data bits + 1 or 2 stop bits + 1 parity bit,
7 data bits + 2 stop bits,
8 data bits + 1 stop bit or 1 parity bit,
8 data bits + 2 stop bits.
The TSX PCX 1031 and TSX PCX 1130 cables should only be connected to the
PLC's TER port in order to supply power to the RS 485/RS 232 conversion desktop.
To avoid signal conflicts, no devices should be attached to the PLC's AUX port.
40
TSX DM 57 xx
Terminal Port
Summary table of terminal port connections
General
The table below can be used to define the cable linking terminal port connectors of a Premium/Atrium PLC to peripheral devices.
Connection cable TER
Port
TSX CB 1020
TSX CB 1050
T FTX CBF 020
TSX PCX 1031
X
X
TSX PCX 1031
XBT-Z938
TSX P ACC 01
TSX PCX 1031
TSX PCX 1130
X
X
X
X
X
AUX
Port
X
Example of connected devices
TSX P ACC 01
X
X
FTX 517, FTX 417
FT 2100, RS 232 programming and adjustment terminals
Graphics terminals and printers managing RTS signal
CCX 17, XBT
Connection to UNI-TELWAY
Devices not managing RTS signal DTE<-->DTE type:
RS 232 programming terminals, printers
Devices not managing RTS signal DTE<-->DCE type:
Modem
TSX DM 57 xx
41
Terminal Port
Adjustment of cables
TSX PCX 1031 and
TSX PCX 1130
The two cables TSX PCX 1031 and TSX PCX 1130 convert RS 485 and RS 232 signals. They authorize the connection of the terminal port to RS 232 devices which do not manage RTS.
Both are equipped with a switch which enables the PLC to be positioned in either
Master of Slave mode. The switch is accessible internally by removing the metal cover containing the electronics.
The management of the switch is as follows:
Switch position M
Switch position S
PL7 Master UNI-
TELWAY configuration
UNI-TELWAY Master with PL7 configuration
UNI-TELWAY Slave with default configuration
PL7 Slave UNI-
TELWAY configuration
UNI-TELWAY Master with default configuration
UNI-TELWAY Slave with PL7 configuration
PL7 character mode configuration
UNI-TELWAY Master with default configuration
Character Mode with
PL7 configuration
Illustration:
Master mode M Slave mode S
42
TSX DM 57 xx
Terminal Port
1.3
Appendices
At a Glance
Aim of this
Section
What's in this
Section?
This Section contains the appendices relating to the Terminal port.
This section contains the following topics:
Topic
Characteristics of the terminal port
Terminal port connector pin configuration
Page
TSX DM 57 xx
43
Terminal Port
Characteristics of the terminal port
General
The following table describes the characteristics of the terminal port:
Structure
Physical interface
Transmission
Protocol
UNI-TELWAY mode (master or slave)
non-isolated RS 485
Master/slave multidrop
Binary rate
Character Mode
non-isolated RS 485
19,200 bits/s by default, modifiable from
1,200 to 19,200 bits/s (1 start bit; 8 data bits; even, odd or no parity; 1 stop bit).
No protocol
9,600 bits/s by default, modifiable from 1,200 to 19,200 bits/s (7 or 8 data bits; even, odd or no parity; with or without echo).
Configuration Number of devices Maximum eight (eight addresses managed by the master). In slave mode, addresses 4,
5, 6 are selected by default. In master mode, the reserved addresses are: l l
1, 2 and 3 for the programming terminal
4 and 5 if a CCX 17 is present
The other addresses are available.
Utilities
Length
UNI-TE
10 meters maximum
One (point to point) device
10 meters maximum
Point to point requests with maximum 128byte reports at the initiative of every connected device. There is no broadcast at the initiative of the master.
Maximum 120-byte character string. Messages must end with
$0D (carriage return).
Other functions Transparent communication between all devices within a network architecture via the master.
-
Safety
Monitoring
A control character on each frame, acknowledgement and possible repetition.
Table indicating bus state, device states and error counters accessible on slaves
No error reported.
No flow control.
Note: Using a TSX P ACC 01 (See
TSX P ACC 01 device, p. 47) connection
device means the RS 485 link can be used in isolated mode.
Note: We strongly recommend that, after use, you do not leave a TSX PCU 103• or TSX PCX 1031 cable connected to the Uni-telway bus at one end and unconnected at the other.
44
TSX DM 57 xx
Terminal Port
Terminal port connector pin configuration
General
The terminal port connectors marked TER and AUX are 8-pin mini-DIN which can be locked.
The signals are given below:
TSX DM 57 xx
1 D (B)
2 D (A)
3 not connected
4 /DE
5 /DTP (1 = master)
6 not connected
7 0 volt
8 5 volts
1 D (B)
2 D (A)
3 not connected
4 /DE
5 /DTP (1 = master)
6 not connected
7 0 volt
8 not connected l l
Note: The operation of the terminal port depends on two parameters:
Signal status/DTP (0 or 1), fixed by cabling accessory (TSX P ACC 01 cable).
Software configuration of the terminal port defined in PL7.
The table below defines the functioning mode of the terminal port according to these two parameters:
PL7 configuration Signal /DTP = 0
Master UNI-
TELWAY
Terminal port in UNI-TELWAY slave mode (default)
Slave UNI-
TELWAY
Character mode
Terminal port in UNI-TELWAY slave mode
Signal /DTP = 1
Terminal port in UNI-TELWAY master mode
Terminal port in UNI-TELWAY master mode (default)
Terminal port in character mode Terminal port in UNI-TELWAY master mode (default)
45
Terminal Port
46
TSX DM 57 xx
TSX P ACC 01 device
2
At a Glance
Aim of this
Chapter
What's in this
Chapter?
This Chapter introduces the functions of the TSX P ACC 01 connection device.
This chapter contains the following sections:
Section
2.1
2.2
2.3
Topic
At a Glance
Hardware installation
Example of topologies
Page
TSX DM 57 xx
47
TSX P ACC 01
2.1
At a Glance
At a Glance
Aim of this
Section
What's in this
Section?
This Section describes the general characteristics of the TSX P ACC 01 device.
This section contains the following topics:
Topic
Functionalities
External appearance
Page
48
TSX DM 57 xx
TSX P ACC 01
Functionalities
General
The TSX P ACC 01 unit is a cabling accessory that connects to the TER connector of the Premium/Atrium PLC processor via an integral cable fitted with a mini-DIN connector at one end.
This is used to: l
Connect several devices to the terminal port of Premium/Atrium PLCs. For this purpose, it is fitted with two mini-DIN connectors, marked TER and AUX, which are functionally identical to the TER and AUX connectors of the Premium PLC l l l processors.
Isolate Uni-Telway signals in order to extend Premium PLC terminal port links to over 10 meters for the purpose of connecting the PLC to a Uni-Telway bus.
l l
Adapt the bus when the unit is connected to one of the ends of the Uni-Telway bus.
Set the operating mode of the terminal port:
Uni-Telway master
Uni-Telway slave or Character Mode
Note: The TER and AUX ports of the TSX P ACC 01 unit are not isolated from one another, nor from the TER port of the supplying PLC.
Note: We strongly recommend that, after use, you do not leave a TSX PCU 103• or TSX PCX 1031 cable connected to the Uni-telway bus at one end and unconnected at the other.
TSX DM 57 xx
49
TSX P ACC 01
External appearance
General
This device is made from zamak and of the same type as Uni-Telway branching or connection devices (TSX SCA 50 and TSX SCA 62). It is designed to be mounted in a cabinet. Its protection index is IP20.
Illustration:
Terminal ports
Connection cable to TER port for Premium PLC (length 1 m)
50
TSX DM 57 xx
TSX P ACC 01
2.2
Hardware installation
At a Glance
Aim of this
Section
What's in this
Section?
This Section deals with installing hardware for connection devices TSX P ACC 01.
This section contains the following topics:
Topic
Dimensions and mounting
Internal view
Connection to Uni-Telway Buses
Connecting to Premium and Atrium PLCs
Switch configuration
TSX P ACC 01 connector pin configuration
Page
TSX DM 57 xx
51
TSX P ACC 01
Dimensions and mounting
General
The TSX P ACC 01 device is installed on a AM1-PA••• perforated board or on a DIN rail with a LA9 D09976 mounting plate.
Illustration:
AM1-PA...
AM1-DE/DP
=
2 x Ø 5.5
50
=
52
TSX DM 57 xx
Internal view
Illustration
S2
Z
JA
JB
S M
S1 Selects functioning mode (master or slave),
S2 Adapts the line end,
JA and JB Connection terminals on the Uni-Telway Bus.
TSX P ACC 01
TSX DM 57 xx
53
TSX P ACC 01
Connection to Uni-Telway Buses
General
The TSX P ACC 01 device is connected to the Uni-Telway Bus using connection terminals JA and JB as shown below:
Illustration:
Shielding
Insulating sleeve
(essential)
White
Red
White
Blue
54
TSX DM 57 xx
TSX P ACC 01
Connecting to Premium and Atrium PLCs
General
When the TSX P ACC 01 device has to be supplied, it must be connected by its built-in cable to the TER connector on the PLC processor.
The device can be connected and disconnected when the PLC is switched on.
Illustration:
Premium
TSX RKY
Host PC
Atrium
TSX P ACC 01
TSX P ACC 01
Note:
Only one TSX P ACC 01 device can be connected to a Premium/Atrium PLC.
TSX DM 57 xx
55
TSX P ACC 01
Switch configuration
General
l
Configuring line end adaptation
l
Line ends are adapted by the S2 switch as indicated below.
Configuring the operating mode
The operating mode is selected by switch S1 as indicated below.
Illustration:
End of line position
UNI-TELWAY
UNI-TELWAY slave or character mode
Other positions
UNI-TELWAY master
Note: The operating mode selected only concerns the connection cable leading to the TER connector on the PLC processor.
56
TSX DM 57 xx
TSX P ACC 01
TSX P ACC 01 connector pin configuration
General
The TSX P ACC 01 device has two parallel connectors, marked TER and AUX.
The signals are given below :
1 D(B)
2 D(A)
3 not connected
4 not connected
5 not connected
6 not connected
7 0 V
8 5 V
1 D(B)
2 D(A)
3 not connected
4 not connected
5 not connected
6 not connected
7 not connected
8 not connected
TSX DM 57 xx
57
TSX P ACC 01
2.3
Example of topologies
At a Glance
Aim of this
Section
What's in this
Section?
This Section introduces examples of how to use the TSX P ACC 01 device.
This section contains the following topics:
Topic
Connectable devices
UNI-TELWAY master mode
UNI-TELWAY slave mode
Connection between two PLCs
Page
58
TSX DM 57 xx
TSX P ACC 01
Connectable devices
General
The functionalities of the TER and AUX ports of the TSX P ACC 01 unit are identical to those of the TER and AUX connectors from the Premium/Atrium PLC processors.
l The unit's TER connector is used to connect any device supporting UNI-TELWAY protocol, in particular non-supplied devices (RS 485/RS 232 converter lead, l etc.).
The unit's AUX connector cannot be used to connect devices with a power supply
(operator dialog console, third party devices, etc.).
Note: The TSX P ACC 01 unit is supplied by the TER connector of the PLC to which it is connected. The unit's TER connector can therefore be used to supply self-powered devices (CCX 17, etc.) or non- powered devices (RS 485/RS 232 converter lead, etc.).
If you wish to connect the terminal port of a second PLC to one of the ports of the
TSX P ACC 01 unit, it is essential that you use the AUX connectors (from the unit and the PLC) in order not to put the supplies of the two PLCs into conflict.
Note: We strongly recommend that, after use, you do not leave a TSX PCU 103• or TSX PCX 1031 cable connected to the Uni-telway bus at one end and unconnected at the other.
Example 1:
Premium master Premium slave
T FTX CB 1020/1050
TSX P ACC 01
TSX DM 57 xx
59
TSX P ACC 01
Example 2:
Premium master
TSX RKY
T FTX CB 1020/1050
TSX P ACC 01
Atrium slave
60
TSX DM 57 xx
TSX P ACC 01
UNI-TELWAY master mode
Example
A TSX P ACC 01 device is connected to a UNI-TELWAY link master PLC as in the example below.
Switches S1 and S2 must be positioned on OFF (master mode).
Example on a Premium station:
FT 2100 slave
Premium master
Addresses 1, 2, 3
TSX PCX 1031
S1=OFF
S2=OFF
TSX SCA 50
Address 6
ATV 16
slave
UNI-TELWAY bus
TSX P ACC 01
TSX SCA 62
XBT-Z 968
TSX CSC 015
T CCX CB 10 002
CCX 17
slave
Addresses 4/5
TSX 17-20
slave
Addresses 7/8
1000 meters maximum
TSX DM 57 xx
61
TSX P ACC 01
Example on an Atrium station:
TSX RKY
FT 2100 slave host PC
Atrium master
Addresses 1, 2, 3
TSX PCX 1031
S1=OFF
S2=OFF
TSX SCA 50
UNI-TELWAY bus
TSX P ACC 01
XBT-Z 968
TSX SCA 62
Address 6
ATV 16
slave
TSX CSC 015
T CCX CB 10 002
CCX 17
slave
TSX 17-20
slave
Addresses 4/5
Addresses 7/8
1000 meters maximum
62
TSX DM 57 xx
TSX P ACC 01
UNI-TELWAY slave mode
Example
A TSX P ACC 01 device is connected to a UNI-TELWAY link slave PLC as in the example below.
Note: Important: For a PLC to be able to operate in slave mode it must be connected to a TSX P ACC 01 device by the cable built into it.
Illustration:
FT 2100
TSX 107-40 master
S1=ON
S2=ON
TSX P ACC 01
UNI-TELWAY bus
TSX CSB 015
S1=ON
S2=ON
TSX P ACC 01
TSX SCA 62
Premium
XBT-Z 968
TCCX CB10 002
CCX 17
1000 meters maximum
Atrium slave
TSX DM 57 xx
63
TSX P ACC 01
Connection between two PLCs
Reminders
If the user wants to connect the terminal port of a second PLC on one of the ports of the TSX P ACC 01 device, the AUX port must be used to avoid power supply conflicts in the two PLCs.
FT 2100
Note: Important: For a PLC to be able to work in slave mode it must be connected to a TSX P ACC 01 device by the device’s built-in cable.
In the example given below the TSX P ACC 01 device must therefore be connected to the UNI-TELWAY slave PLC by the device’s integrated cable. Its S1 switch must be positioned on ON
If the device if not placed on a UNI-TELWAY bus, the position of the S2 switch does not matter.
Illustration:
Premium master
Premium slave
T FTX CB1
020/050
S1=ON
S2=not significant
TSX PCX 1031
TSX P ACC 01
XBT-Z 968
T CCX CB10 002
CCX 17
64
TSX DM 57 xx
Processor-integrated master
FIPIO communication
II
At a Glance
Aim of this Part
What's in this
Part?
This Part deals with the master FIPIO communication function, which is integrated into Premium/Atrium processors.
This part contains the following chapters:
Chapter
3
Chapter Name
Processor-integrated master FIPIO communication
Page
TSX DM 57 xx
65
Integrated FIPIO
66
TSX DM 57 xx
Processor-integrated master
FIPIO communication
3
At a Glance
Aim of this
Chapter
What's in this
Chapter?
This Chapter deals with the FIPIO communication function integrated into Premium/
Atrium processors.
This chapter contains the following topics:
Topic
Review of the FIPIO bus
Integrated FIPIO link on Premium/Atrium processors
Examples of architecture
Page
67
TSX DM 57 xx
Integrated FIPIO
Review of the FIPIO bus
General
Main characteristics
68
FIPIO is a field bus which is used to centralize inputs/outputs of a PLC station and its industrial peripherals nearest to the section which is operating.
From a PLC station whose processor has a built-in FIPIO link, the FIPIO bus is used to connect 1 to 127 devices such as: l l l l l l l
Momentum remote input/output modules (discrete and analog)
TBX remote input/output modules (discrete and analog)
CCX 17 command consoles
ATV 16 variable speed controllers
Devices which conform to standard profiles
Agent PLCs, PC
...
The FIPIO field bus can be used in a single architecture (mono-station) or in a more complex architecture (multi-station) where several FIPIO segments can be brought together by a local network at a higher level such as FIPWAY or Ethernet TCP_IP for example.
Structure
Nature
Topology
Access method
Communication
Privileged exchanges
Open field bus, conforming to World FIP standards.
Links devices through chaining or branching.
Managed by a bus arbiter
By exchange of variables which can be accessed by the user in the form of PL7 objects and X-WAY datagrams.
Cyclical exchange of status variables and remote input/output commands
Transmission
Binary flow
Medium
1Mb/s.
Shielded twisted pair (150 Ohms of characteristic impedance).
Configuration
Number of connection points
Number of segments
PLC
128 logic connection points for whole architecture
15 maximum (in cascade format) using electrical or optical relays
(14 maximum in cascade format).
One PLC (address connection point 0)
TSX DM 57 xx
Integrated FIPIO
Configuration
Programming terminal One programming terminal (must be connected to connection point 63).
Length The length of a segment depends on its type of branches: l l
1000 meters maximum without relay.
15000 meters maximum between the devices which are the furthest apart.
TSX DM 57 xx
69
Integrated FIPIO
Integrated FIPIO link on Premium/Atrium processors
General
Some processors have as standard an integrated master FIPIO link which makes it possible to connect the PLC station to a FIPIO bus.
Illustration:
Link
FIPIO
Link
FIPIO
Premium processor
Link
FIPIO
Atrium processor
Connecting to the FIPIO bus
The processor has a SUB D 9-pin connector which is used to link it to the FIPIO bus using a TSX FP ACC12 connector.
Illustration:
70
TSX FP
ACC12
TSX FP
ACC12
The complete procedure for installing a FIPIO bus (architecture, type of cable to use, cabling accessories etc.) is discussed in the FIPIO Bus reference manual.
Note: The master FIPIO link integrated into processors should not be taken into account when counting the station channels.
TSX DM 57 xx
Examples of architecture
Premium station
Illustration:
Premium
X Bus
TSX RKY
Integrated FIPIO
TBX
Momentum
CCX 17
ATV
PC
TSX DM 57 xx
71
Integrated FIPIO
Atrium station
Illustration:
PC Atrium
TBX
Momentum
CCX 17
ATV
PC
TSX RKY
72
TSX DM 57 xx
AS-i bus interface: TSX SAY 100 module
III
At a Glance
Aim of this Part
What's in this
Part?
This Part deals with the AS-i bus interface module: TSX SAY 100.
This part contains the following chapters:
Chapter
4
Chapter Name
AS-i bus interface module: TSX SAY 100
Page
TSX DM 57 xx
73
TSX SAY 100
74
TSX DM 57 xx
AS-i bus interface module:
TSX SAY 100
4
At a Glance
Aim of this
Chapter
What's in this
Chapter?
This Chapter only deals with hardware installation of the TSX SAY 100 interface l l module, AS-i bus master on a Premium/Atrium PLC. For the complete installation of an AS-i bus you must refer to the following manuals:
AS-i bus reference manual
AS-i installation section in the Premium PLC Applications Manual - Applications,
Volume 1.
This chapter contains the following sections:
Section
4.1
4.2
4.3
4.4
4.5
4.6
Topic
Review of the AS-i bus
Description of the TSX SAY 100 module
Input/output object addressing
AS-i Bus diagnostics
Operating modes of the TSX SAY 100 module
Precautions of use
Page
75
TSX DM 57 xx
TSX SAY 100
4.1
Review of the AS-i bus
At a Glance
Aim of this
Section
What's in this
Section?
This Section introduces the main characteristics of the AS-i bus.
This section contains the following topics:
Topic
Review of the AS-i bus
Overview of AS-i products from the Schneider catalog
Introduction to the main constituent elements
Example of AS-i bus topology
Main characteristics of the AS-i bus
Page
76
TSX DM 57 xx
TSX SAY 100
Review of the AS-i bus
General
The AS-i bus is a field bus (level 0) and can be used to connect sensors/actuators.
This allows "Discrete" type information to be routed between a bus master and sensor/actuator slaves.
AS-i is made up of three major basic elements: l l l
A dedicated power supply providing 30 VDC voltage.
A bus master.
Slaves (sensors and actuators).
The main types of sensors/ actuators
1. Communication sensors/actuators:
With a built-in AS-i function they link up directly to the AS-i bus via a passive distributor or a T-piece connection.
2. The traditional IP65 sensors/actuators:
They connect to the bus via an AS-i interface (active distributor or Telefast IP20 discrete input-output bus interface). These interfaces connect the sensors and traditional actuators to the AS-i bus and provide them with dialog capacity on the bus.
Illustration:
Active distributor
Passive distributor
Connection T
AS-i Bus
AS-i function integrated
AS-i function integrated
AS-i function via interface
Traditional product
124 products maximum
(124 input information and 124 output information)
Communicating product Communicating product
31 products (sensors or actuators)
TSX DM 57 xx
77
TSX SAY 100
Overview of AS-i products from the Schneider catalog
General
Actuators
AS-i
Non-exhaustive list of AS-i products from the Schneider catalog:
Man/machine dialog
Sensors
AS-i
Column lit
Start-up motor
Detector photoelectric
Inductive proximity detector
Button box
Keyboard
12 keys
Master Supply
Distributor active
2E/2S
4S
4E
For connection by M12 ports of sensors/actuators/units of dialog and signaling standards:
• inductive sensors.
• capacity switches.
• photoelectric barriers.
• end of run.
•
LEDs
• relays.
• solenoid valve.
Distributor passive
Bus interface
Telefast
4 channels for AS-i sensors/actuators connection equipped with
M12 sockets.
AS-i bus interface/discrete input-output.
•
4 I
•
4 O
•
8 I/O (4I + 4O)
For connection by screw or pull-out terminals of dialog sensors/ actuators/units of dialog and signaling standards:
•
2 or 3 wire inductive sensors.
• capacity switches.
• end of run.
•
LEDs
• relays.
• contactors.
• solenoid valve.
• resistance.
78
TSX DM 57 xx
Introduction to the main constituent elements
Cable
This transmits data and carries the power. It can be made up from: l l either an unshielded, polarized twin-wire AS-i ribbon cable.
Or a standard round, shielded or unshielded twin-wire cable.
Illustration:
TSX SAY 100
Active distributors
Guiding ribbon cable
Round cable
IP67 sealed interfaces for connecting sensors/actuators using M12 connectors.
These distributors are used to connect "traditional", non-communicating sensors/ actuators.
Illustration:
Active distributor for ribbon cable
Active distributor for round cable
TSX DM 57 xx
79
TSX SAY 100
Passive distributors
IP67 sealed interfaces for connecting sensors/actuators using M12 connectors.
These distributors do not have any electronics and can therefore be used to connect the "communicating" sensors/actuators.
Illustration:
Passive distributor for ribbon cable
Passive distributor for round cable
SB2 Telefast discrete inputsoutputs/bus interface
IP20 sealed interface with built-in ASi- function. It enables connection to all types of
"traditional" non-communicating sensors/actuators via screw terminal blocks.
Illustration:
AS-i actuators
The direct motor starters and toggle switches in sealed boxes (IP54 and IP65) ensure electrical motors are controlled and protected up to 4KW at 400 VAC.
Illustration:
80
TSX DM 57 xx
AS-i sensors
TSX SAY 100 l Photo-electric detectors:
They ensure that all kinds of objects (opaque, reflective etc) are detected with 5 basic systems: barrier, reflex, polarized reflex, proximity and proximity with background blanked out. They offer an IP67 protection level.
Inductive proximity detectors: l
They detect all metal objects and provide information for the check functions on whether an object is present or not. They offer an IP67 protection level.
Illustration:
Man-machine interface products
l Button boxes:
These are made up of dialog tools, which are perfectly adapted to exchanging information between the operator and machine.
l
Keyboards:
Man/machine dialog tools, these have 12 touch sensitive keys. The information delivered is coded in BCD on 4 bits. They offer an IP65 protection level.
Illustration:
Signaling elements
l Illuminated columns:
Optical or sound signaling elements.
TSX DM 57 xx
81
TSX SAY 100
Bus master
Built into a Premium/Altrium PLC station, the TSX SAY 100 module (AS-i bus master) manages all data exchanges on the AS-i bus.
Illustration:
AS-i power supply
Premium/Atrium station
AS-i dedicated power supply, designed to supply the components connected to the
AS-i bus.
The distribution of this power supply uses the same medium as that used for data exchange.
Illustration:
Connecting and branching accessories
T-piece connectors are used to make connections to the AS-i bus. These are designed for linking to AS-i ribbon cables or to ribbon/round cable branches.
Illustration:
T for ribbon cable
Branch ribbon/round cable
82
TSX DM 57 xx
TSX SAY 100
Example of AS-i bus topology
General
Illustration:
Premium
AS-i master
AS-i Bus
Supply
AS-i
Sensors/actuators communicating
Interfaces with traditional sensors/ actuators
TSX DM 57 xx
83
TSX SAY 100
Main characteristics of the AS-i bus
General
AS-i is a system in which exchange management is ensured by a single master who calls in succession, by scanning the bus, each detected slave and awaits a response.
The communication series frame carries: l
4 data bits (D0 to D3), which are the image of inputs or outputs according to the nature of the interface.
l 4 parametering bits (P0 to P3), which are used to set the operating modes of the interface.
P0 to P3 bits are used for "intelligent" devices, including AS-i ASIC (specific integrated circuit). Operation can be modified while it is running.
The address of the slave is coded on 5 bits.
At the request of the AS-i master, outputs are set and the inputs for AS-i devices are sent in the slave’s response.
Slave addressing
Each slave connected to the AS-i bus must have an address between 1 and 31
(coding on 5 bits).
The slaves delivered from the factory have the address 0 (the address of the slave is memorized in a non-volatile format).
Addresses are programmed using a terminal specifically for addressing, a XZMC11.
Note: When replacing a faulty slave whose address has been set, the address of the slave to be replaced can be updated automatically.
Identification of slaves
All slave devices connected to the AS-i bus are identified by: l l
An I/O Code (input/output distribution code).
An identification code, which completes the functional identification of the slave.
These identifications allow the AS-i master to recognize the configuration which is present on the bus
These different profiles have been developed by the AS-i Association. They are used to distinguish modules such as for inputs, outputs, mixed modules, "intelligent" device families, etc.
Maximum number of inputs/outputs
An AS-i bus can support a maximum of 31 slaves.
Each slave can have a maximum of 4 inputs and/or 4 outputs.
This makes it possible to manage a maximum of 124 inputs + 124 outputs, or 240 discrete inputs/outputs when all active devices have 4 inputs and outputs.
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AS-i cable
Topology and maximum length of AS-i bus
The topology of the AS-I bus is flexible. It can be perfectly adapted to meet the user’s needs (point to point, on line, tree structure etc.).
In every case, the total length of all the branches of the bus must not exceed 100 meters without a relay.
AS-i bus cycle time
The AS-i cable is a twin-wire link on which communications and power supply for the connected devises are transmitted.
The link does not need to be twisted.
The cross-section of wires can be from 2 x 0.75 mm
2
, 2 x 1.5 mm
2
or 2 x 2.5 mm
2
, according to the current consumed by the devices.
Reliability, flexibility
This is the cycle time between slave(s) and the TSX SAY 100 module.
The AS-i system always transmits information which is the same length to each slave on the bus. The AS-i cycle time depends on the number of slaves connected to the bus.
In the presence of 31 functioning slaves, this time period will be a maximum of 5 ms.
Reliable operation is ensured by the transmission process used (Manchester current and coding modulation). The master monitors the line supply voltage and the data sent. It detects transmission errors as well as slave failures, and sends the information to the PLC.
Exchanging or connecting a new slave during operation does not disturb communications between the master and the other slaves.
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TSX SAY 100
4.2
Description of the TSX SAY 100 module
At a Glance
Aim of this
Section
What's in this
Section?
This Section deals with hardware installation and the characteristics of the TSX SAY
100 module.
This section contains the following topics:
Topic
Physical presentation
Mounting/installation
Connections
Displaying module states
Specific Display Panels on the TSX SAY 100 Module
Technical characteristics
Personnel safety
Page
86
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Physical presentation
General
The TSX SAY 100 module comes as a standard format module.
Illustration:
TSX SAY 100
Front panel
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87
TSX SAY 100
Description of
TSX SAY 100 module
The module is made up of the following elements:
1. A display panel consisting of 4 LEDs for displaying the operating modes of the module: l
RUN LED (green): lit indicates normal functioning mode of the module.
l
ERR LED (red): lit indicates a module error.
l
COM LED (green): lit indicates data exchanges on the AS-i network.
l
I/O LED (red): lit indicates an external input/output error on the AS-i bus.
2. Display panel consisting of 32 LEDs (0 to 31) which enable AS-i bus diagnostics, and display the state of each slave connected to the bus.
3. AS-i LED (red): lit indicates an AS-i power supply error.
4. Bus LED (green): lit indicates that display panel2 is in BUS display mode (slaves displayed on the bus).
5. I/O LED (green): lit indicates that display panel 2 is in Slave "SLV" display mode
(displays status of input/output bits for a selected slave).
6. Push button "
↑↓
" designed for local diagnostics of the AS-i bus. You can move between the different AS-i bus diagnostic modes by pressing this button (long or quick presses), combined with the "+/-" push button.
7. Push button "+/
−
" designed for local diagnostics of the AS-i bus. You can move between the different AS-i diagnostics modes by pressing this button (long or quick presses), combined with the "
↑↓
" push button.
8. CANNON SUB D connector for connection to AS-i bus.
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Mounting/installation
General
The TSX SAY 100 module can be mounted in any position on the TSX RKY rack, except for those positions dedicated to processors and power supply.
Note: In the event where the module is mounted on a remote X Bus rack, the maximum allowed distance from the processor must be 175 meters minus the length of the X Bus (max. 100 m).
Inserting and extracting the module is the same as the general procedure for inserting and extracting modules on Premium PLCs (see the Premium PLC installation manual.)
Example of mounting a TSX SAY 100 module:
Number of modules per station
Note: The module can be mounted and removed with both PLC and AS-i bus power switched on.
The maximum number of modules per Premium/Atrium PLC station depends on the type of processor installed:
Processors
57-1xx
57-2xx
57-3xx/57-4xx
2
4
Maximum number of AS-i bus connections
8
2
4
Maximum number of TSX
SAY 100 modules
8
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TSX SAY 100
Connections
AS-i bus cables
AS-i bus cables carry the signals and supply the sensors and actuators connected to the bus with 30 VDC.
Types of AS-i cables:
Cable type Characteristics
Polarized AS-i ribbon cable Color: yellow. Wire crosssection: 1.5 mm
2
Illustration
Standard round cable
Wire cross-section: 1.5 mm
2
or
2.5 mm
2
(Blue) (Brown)
Cable routing
Link-up connector
(Blue)
(Brown)
Recommended cable: product reference H05VV-F2x1.5, conforms to the DIN VDE
0281standard. Wire cross-section: 1.5 mm
2
.
The AS-i cable and the power cables carrying higher power levels must be in separate ducts which are protected by a metal screen.
When using a shared route for control cables it is essential that the connections on these control links should conform to the technology rules (eg. the discharge diode or limiters on the terminals of self-inductive elements etc.).
A set (connector + cover) is delivered with the module, which is used to connect the module to the AS-i bus. This connector must be linked to the cable of the AS-i bus and assembled by the user according to the procedure described later.
Illustration:
Connector
Cover
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TSX DM 57 xx
Connection of module to bus
TSX SAY 100
To connect a module to the bus, follow the procedure below:
1 Connect the 2 wires of the AS-i cable to the connector, taking the polarities into account:
In the special event that a shielded cable is used, this should be connected to the central terminal.
2 Mount the connector in its cover and fix the cable to it:
3 Click the cover shut:
4 Mount the unit on the module:
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Displaying module states
General
This is carried out with 4 LEDs RUN, ERR, COM, I/O which are located on the module. Their state (LED off, flashing or on) provides information on the operating mode of the module.
LED state:
LEDs
RUN
(green)
ERR (red)
On
Module operating normally
Serious internal fault, module broken down
Flashing
Module self-testing (1)
Off
Faulty module, or module switched off
Module self-testing (1)
Fault: system OK but: l l application fault or
AS-i bus error
Module self-testing (1)
Communication on AS-i bus
No internal error
No communication on
AS-i bus
COM
(green)
-
I/O (red) Input/output error Module self-testing (1) Module operating normally
(1) the 4 LEDs flash simultaneously during self-testing mode when the module is switched on.
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Specific Display Panels on the TSX SAY 100 Module
General
3 LEDs: AS-i, Bus and I/O display information specific to the TSX SAY 100 module.
View of the 3 LEDs:
AS-i LED
Bus LED
I/O LED
AS-i LED (red)
LED state
LED on
Flashing LED
LED off
Meaning
Module operating normally
Supply fault on the AS-i bus
Automatic addressing initialized
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Bus and I/O LEDs
These two LEDs display the view mode selected: l l
Bus display mode or
Slave display mode.
Display module LED state
Bus LED on, I/O
LED off
Meaning
The 32 LED display panel located at the front of the module is in BUS display mode and displays all the slaves present on the bus.
Bus LED off, I/O
LED on
The 32 LED display panel located on the front of the module is in Slave display mode (SLV) with display of the input/ output status for a selected slave.
Bus LED off, I/O
LED off
The 32 LED display panel located on the front of the module is in Slave display mode (SLV) with display of the address of the slave selected.
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Technical characteristics
AS-i Bus
Characteristics
AS-i bus maximum cycle time
Maximum number of slaves on the AS-i bus
Maximum length of AS-i bus (all branches mixed without relay)
Maximum number of inputs/outputs
Nominal supply voltage for AS-i bus
Value
5ms
31
100 meters
124 inputs + 124 outputs
30 VDC
TSX SAY 100 module
Characteristics
Programming the TSX SAY 100 module
PLC current consumed on 5V
AS-i current consumed on 30 V
Dissipated power
Protection from polarity inversion on AS-i bus inputs
Value
from PL7 Junior or PL7 Pro software
Response time with 31 slaves (1) for a PLC cycle time of 10 ms
Typically 27 ms, 37 ms maximum
Calculation of AS-i scanning time for n slaves
(normal operation)
156
µ s x (n+2) if n<31 156
µ s x (n+1) if n=31
Typically 110 mA / 150 mA maximum
Typically 50 mA / 60 mA maximum
2.5 W max.
Yes
Degree of protection
Operating temperature
AS-i master profile
Standards and service conditions
IP20
0 to 60 degrees Celsius
M2
Conforms to those of Premium PLCs
(see Volume 1)
(1) Logical response time + time between an AS-i input activated on the bus, processed in the PLC application and applied to an AS-i output.
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TSX SAY 100
Personnel safety
General
To ensure personnel safety it is essential: l l l
To earth the ground terminal of the PLC.
To use an AS-i VLSV (very low safety voltage) supply, nominal voltage 30 VDC.
For PLCs which are connected to an alternating current network, a differentiel circuit breaker must be placed upstream of this network, and this will cut off the
PLC power supply source if ground leakage if detected.
l For PLCs which are connected to a direct current supply source you must ensure that the supply placed upstream of the PLC is VLVS.
l To use certified AS-i products on the bus.
Due to its type of technology and connection, the TSX SAY 100 module only receives 5 VDC and its 0V is linked to the PLC ground.
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4.3
Input/output object addressing
Addressing input/output objects
General
Example
Acquisition of inputs and update of slave device outputs connected to the AS-i bus are carried out automatically. This occurs at the start and end of each cycle respectively of the task in which the TSX SAY 100 module is configured.
The program user has access to these inputs and outputs via the language objects whose syntax is as follows:
%
Symbol
I or Q
Type of object
I=input
Q=output
\ xy.0
\
Module/channel address of the TSX SAY 100
x=rack number
y=position number
0=channel 0 of the module
n
No. of slave
0 to 31
.
i
Rank of bit
0 to 3
Particular example of rack 0:
%I\2.0\1.3 indicates: input 3 of slave 1, channel 0 of the TSX SAY 100 module, positioned in rack slot 0.
%Q\2.0\31.0 indicates: output 0 of slave 31, channel 0 of the TSX SAY 100 module, positioned in slot 2 of rack 0.
Illustration:
TSX DM 57 xx
Addresses slaves
Slave
Addresses inputs/outputs of slaves
4E
@1 @3
4S
AS-i Bus
@5
1S
0
@31
2E & 2S
0 3 0 3 0 1 0 1
%I\2.0\1.0
%I\2.0\1.3
%Q\2.0\3.0
%Q\2.0\3.3
%Q\2.0\5.0
%I\2.0\31.0
%Q\2.0\31.0
%I\2.0\31.1
%Q\2.0\31.1
Note: The physical address of an AS-i slave is programmed by the portable console XZM C11
97
TSX SAY 100
4.4
AS-i Bus diagnostics
At a Glance
Aim of this
Section
What's in this
Section?
This Section deals with the diagnostics mode carried out by the TSX SAY 100 module.
This section contains the following topics:
Topic
Introduction to AS-i Bus diagnostics
Moving between the different display modes
Display of slaves on the AS-i bus
Viewing the state of input/output bits for each slave
Page
98
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Introduction to AS-i Bus diagnostics
General
The module display panel is used for: l l
Displaying the presence of each slave on the AS-i bus (Bus mode).
Displaying the state of input/output bits of each slave present on the bus (Slave mode "SLV").
These modes can be accessed by a combination of actions on the push buttons (
↑↓ and +/-) on the TSX SAY 100 module.
Illustration:
TSX DM 57 xx
99
TSX SAY 100
Display modes
Table giving the 2 display modes of the module:
Bus mode Slave mode (SLV)
View of AS-i bus image. Each
LED 1 to 31 corresponds to a slave address on the bus.
l l
LED on: slave present flashing LED: slave expected and not detected, or not expected l and detected.
LED off: slave not expected and not detected.
View of selected slave address.
l
LED on: number of slave selected.
Illustration: Illustration:
View of input/output bit state l l for slave selected.
l
LEDs 0 to 3 display the state of the input bits.
l
LEDs 4 to 7 display the state of the output bits.
LED on: bit in state 1.
LED off: bit in state 0 or not significant
Illustration:
100
View mode is displayed with the Bus LED on and the I/O
LED off.
View mode is displayed by
Bus and I/O LEDs both off.
View mode is displayed by the Bus LED off and the I/O
LED on.
TSX DM 57 xx
TSX SAY 100
Moving between the different display modes
Illustration
This illustration shows how to move between the different display modes:
Display of image of the AS-i bus
(default display)
On
Off
Presence slaves 1 to 31
Hold down on
↑↓
Status bits input
Status bits output
Display of bits of I/O of the slave selected
Hold down
+/−
Change direction:
Short press on
↑↓
Off
On
Number of slave
Hold down on
↑↓
Display of address of the selected slave
Change slave:
Short press on +/-
Off
Off
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101
TSX SAY 100
Display of slaves on the AS-i bus
General
This mode is displayed by default when the module is switched on, and is used to display: l l l
The expected and detected slaves (LED permanently on).
The unexpected and undetected slaves (LEDs off).
The expected and undetected slaves (LEDs flashing).
Illustration:
↑↓
Display panels
Bus Display
LEDs showing the mode displayed
The image of the AS-i network is displayed on the entire display panel. Each LED represents an AS-i bus slave address.
You can move between the different modes by a combination of actions on the push buttons
↑↓
and +/- : see
Moving between the different display modes, p. 101.
Two LEDs "Bus" and "I/O" indicate the current display mode.
In the current example, the "BUS" LED is on and the LED "I/O" is off which indicates l l that the display is in Bus mode.
In the illustration above, the display panel indicates that:
Slaves 1, 4, 10 and 20 (LEDs on) are present.
Slave 11 (flashing LED) is present and not expected, or expected and missing.
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Viewing the state of input/output bits for each slave
General
In this mode (Slave "SLV"), the display panel is used to view the state of input/output bits for each slave present on the bus.
Procedure to be followed
To access the state of input/output bits for a slave from BUS mode, proceed as follows:
Order Action
5 Pressfor more than one secondon the button +/
−
Result
1 Press for more than one second on the button
↑↓
2 Press quickly on the +/- button
The display switches to Slave "SLV" mode.
The display of the slave address goes
up from 1 to 31.
3 Press quickly on the button
↑↓
The direction of the slave address scan is reversed.
4 Press quickly on the +/- button The display of the slave address goes
down from 31 to 1.
l l
LEDs 0 to 3 display the state of input bits for the slave selected (1).
LEDs 4 to 7 display the state of output bits for the slave selected (1).
6 Press quickly on the +/- button
7
8
9
Press quickly on the button
↑↓
Press quickly on the +/- button
Pressfor more than one second on the button +/
−
(1)
LED on = bit on state 1
LED off = bit on state 0 or no input or output
The state of inputs-outputs for the
following slave is displayed.
The direction of the slave address scan is reversed.
The state of input-outputs for the
previous slave is displayed.
The display shows again the number of slave selected.
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TSX SAY 100
Illustration
Slave Number
(example: 10)
State of bits (example:
%I\2.0\10.0 et %I\2.0\10.1=1)
↑↓
Change direction:
Short press on
↑↓
Change slave:
Short press on
+/−
Slave Display
Status of output bits
(example: %Q\2.0\10.2 and
%Q\2.0\10.3=1
Channel Display
104
TSX DM 57 xx
4.5
TSX SAY 100
Operating modes of the TSX SAY 100 module
Operating modes of the TSX SAY 100 module
General
Output fallback position
For more information, refer to the section on AS-i installation in the Premium PLCs
Applications Manual - Basic Applications, Volume 1.
The fallback mode is set in the configuration screen (see Premium PLCs
Applications Manual) and can be read in the word %KWxy.0.19:X0: l l
%Kwxy.0.19:X0 = 1: fallback to 0
%KWxy.0.19:X0 = 0: maintain state
(x = rack address, y = module address)
Operation:
When the AS-i channel changes to STOP: l
With fallback to 0 option: outputs are forced to 0, then communication stops on the medium.
l
With maintain state option: outputs are maintained, then communication stops on the medium.
Automatic slave addressing
When this function is enabled in the module configuration, it allows the replacement of a faulty slave with a slave of the same type without stopping the AS-i bus, and without the need for special action: l
If the replacement slave is programmed with the same address and has the same profile, it will be automatically inserted in the list of slaves detected, then l activated. If this is not the case, the ERR and AS-i LEDs will flash simultaneously.
If the new slave has never been used (address 0, new slave) and has the same profile, the slave automatically takes on the address of the replaced slave and is therefore in the list of detected slaves and the list of active slaves. If this is not the case, the ERR and AS-i LEDs will flash simultaneously.
These actions are only possible if one and only one slave is faulty in the configuration.
Processor error
If there is a communication break with the processor, the module switches to
SAFETY position.
Communication breaks are caused by the following: l Triggering of the processor watchdog if the TSX SAY 100 module is positioned in the rack supporting the processor.
l Disconnection of the X Bus cable if the TSX SAY 100 module is positioned in an extension rack.
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105
TSX SAY 100
Module fault
In the event of a serious fault on the TSX SAY 100 module (faulty component, etc.) the module stops communicating with the X Bus and with the AS-i Bus. The same type of behavior occurs when a module is removed with the power on.
Removing a module with power switched on
Should a module be removed with the power switched on, communication with the
X Bus stops and the processor indicates a module fault.
Communication with the AS-i bus is also interrupted without notice. In this case, the slaves with a watchdog set their outputs in the desired state, and the others remain in position and cannot be set to 0 since the module cannot guarantee communication.
Inserting a module with power switched on
After switching on the TSX SAY 100 module, it waits to receive configuration from the processor or for one of the push buttons
↑↓
or +/- to be pressed, otherwise it remains at a stop.
AS-i supply fault
When an AS-i supply module fault occurs, communication stops with: l Slaves with a watchdog positioning their outputs in the desired state, except if the slave takes its power from the AS-i.
l
Slave commands switch to 0 due to lack of power.
This fault is indicated by the AS-i LED.
Break in the AS-i medium
There are several ways in which a break in the medium can occur:
1. There is a break in the medium as it exits the module:
Behavior is the same as that for a power outage, with all slaves disappearing and a supply fault being indicated.
2. There is a break in the medium after the TSX SAY 100 module and the AS-i supply:
All slaves disappear and no indication of supply fault.
3. There is a break in the medium after the TSX SAY 100 module, the AS-i supply and some slaves:
Slaves located after the break disappear and no indication of supply fault.
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4.6
Precautions of use
At a Glance
Aim of this
Section
What's in this
Section?
This Section deals with the precautions to be taken when installing an AS-i bus.
This section contains the following topics:
Topic
24 V auxiliary supply
Multiple addressing
Page
TSX DM 57 xx
107
TSX SAY 100
24 V auxiliary supply
Recommendations
When slaves use a 24 V auxiliary supply, the disappearance of this supply is not managed by the TSX SAY 100 module.
Information on the disappearance of this supply can be accessed by using a 24 V input.
108
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TSX SAY 100
Multiple addressing
Recommendations
When one or more slaves are connected, make sure that you do not assign an address which is already being used by a slave on the bus.
If slave address is doubled then two scenarios may occur:
1. The two slaves with identical addresses have the same profile and manage identical I/Os: the AS-i master bus does not detect any error.
2. The two slaves with identical addresses manage different I/Os: the AS-i master bus can detect transmission errors when accessing the I/O from one of the two slaves.
TSX DM 57 xx
109
TSX SAY 100
110
TSX DM 57 xx
AS-i V2 bus interface:
TSX SAY 1000 module
IV
At a Glance
Aim of this Part
What's in this
Part?
This part deals with the AS-i V2 TSX SAY 1000 bus interface module.
This part contains the following chapters:
Chapter
5
Chapter Name
AS-i V2 Bus Interface Module: TSX SAY 1000
Page
TSX DM 57 xx
111
TSX SAY 1000
112
TSX DM 57 xx
AS-i V2 Bus Interface Module:
TSX SAY 1000
5
At a Glance
Aim of this
Chapter
What's in this
Chapter?
This chapter deals with hardware installation of the TSX SAY 1000 interface module,
AS-i V2 bus master on a Premium/Atrium PLC.
This chapter contains the following sections:
Section
5.1
5.2
5.3
5.4
5.5
5.6
5.7
Topic
Introduction to the AS-i Bus
Description of the TSX SAY 1000 Module
Input/Output Object Addressing
AS-i Bus Diagnostics
Operating Modes of the TSX SAY 1000 Module
Precautions of Use
AS-i V2 Certification
Page
113
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TSX SAY 1000
5.1
Introduction to the AS-i Bus
At a Glance
Aim of this
Section
What's in this
Section?
This section introduces the main characteristics of the AS-i bus.
This section contains the following topics:
Topic
Introduction to the AS-i Bus
Overview of AS-i Products from the Schneider Catalog
Introduction to the Main Constituent Elements
Main Characteristics of the AS-i V2 Bus
Page
114
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TSX SAY 1000
Introduction to the AS-i Bus
General
The main types of sensors/ actuators
The AS-i bus is a field bus (level 0) and can be used to connect sensors/actuators.
This allows "Discrete" or analog type information to be routed between a bus master and sensor/actuator slaves.
AS-i is made up of three major basic elements: l l l
A dedicated power supply providing voltage of about 30 VDC.
A bus master.
Slaves (sensors, actuators and others).
1. Communication sensors/actuators:
With a built-in AS-i function they link up directly to the AS-i bus via a passive distributor or a T-piece connection.
2. Traditional sensors/actuators:
These connect to the bus via an AS-i interface (active distributor or TOR Telefast input-output bus interface). These interfaces connect the sensors and traditional actuators to the AS-i bus and provide them with dialog capacity on the bus.
Illustration:
Active distributor
Passive distributor
Connection T
AS-i Bus
AS-i function integrated
AS-i function integrated
AS-i function via interface
Traditional product
Maximum 434 I/O
248 input
186 output
Communicating Communicating
Maximum 62 slaves
(maximum 31 standard or 62 maximum)
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115
TSX SAY 1000
Overview of AS-i Products from the Schneider Catalog
General
Actuators
AS-i
Non-exhaustive list of AS-i products from the Schneider catalog:
Man/machine dialog
Sensors
AS-i
Column lit
Start-up motor
Inductive photoelectric
Inductive proximity detector
Button box
12 Key keyboard
Master Supply
Distributor active
2I/2O
4O
4I
For connection by M12 ports of sensors/actuators/units of dialog and signaling standards:
• inductive sensors.
• capacity switches.
• photoelectric barriers.
• end of run.
•
LEDs
• relays.
• solenoid valve.
Distributor passive
Bus interface
Telefast
4 channels for AS-i sensors/actuators connection equipped with
M12 sockets.
AS-i bus interface/discrete input-output.
•
4 I
•
4 O
•
8 I/O (4I + 4O)
For connection by screw or pull-out terminals of dialog sensors/ actuators/units of dialog and signaling standards:
•
2 or 3 wire inductive sensors.
• capacity switches.
• end of run.
•
LEDs
• relays.
• contactors.
• solenoid valve.
• resistance.
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Introduction to the Main Constituent Elements
Cable
This transmits data and carries the power. It can be made up from: l l either an unshielded, polarized twin-wire AS-i ribbon cable.
Or a standard round, shielded or unshielded twin-wire cable.
Illustration:
TSX SAY 1000
Bus Master
Guiding ribbon cable
Round cable
Built into a Premium/Atrium PLC station, the TSX SAY 1000 module (AS-i bus master) manages all data exchanges on the AS-i bus.
Illustration:
AS-i Power
Supply
TSX SAY 1000 Premium/Atrium station
AS-i dedicated power supply, designed to supply the components connected to the
AS-i bus.
The distribution of this power supply uses the same medium as that used for data exchange.
Illustration:
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117
TSX SAY 1000
Main Characteristics of the AS-i V2 Bus
General
AS-i is a system in which exchange management is ensured by a single master which, by scanning the bus, calls each slave in succession and awaits a response.
Communication series frame for slaves with standard AS-i address settings: l 4 data bits (D0 to D3), which are the image of inputs or outputs according to the l type of interface,
4 parametering bits (P0 to P3), which are used to set the operating modes of the interface.
Communication series frame for slaves with extended address settings: l 3 or 4 data bits, which are the image of inputs (4 bits, D0 to D3) or outputs (3 bits,
D0 to D2) depending on the type of interface, l
3 parametering bits (P0 to P2), which are used to set the operating modes of the interface.
All slave devices connected to the AS-i bus are identified by at least one "I/O Code" and one "ID code" which completes the functional identification of the slave.
Some slaves have an ID1 code, which defines the internal functions of the slave: on analog slaves, for example, ID1 shows the slave's analog channel number.
Note: The frame base is the same for analog slaves as it is for TOR slaves.
There is ascending compatibility between AS-i and AS-i V2. This means that all slaves on the market are supported by SAY 1000.
Slave
Addressing
Each slave connected to the AS-i bus must have an address which lies between 1 and 31, either with "Bank" /A, or with "Bank" /B for extended address settings.
The slaves delivered from the factory have the address 0 (the address of the slave is memorized in a non-volatile format).
Addresses are programmed using a specialized addressing terminal.
Note: When replacing a faulty slave whose address has been set, the address of the slave to be replaced can be updated automatically.
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Identification of
Slaves
l l
All standard address setting slaves connected to the AS-i bus are identified by:
An I/O Code (input/output distribution code),
An identification code, which completes the functional identification of the slave.
All extended address setting slaves connected to the AS-i bus are identified by: l l l l
An I/O Code (input/output distribution code),
An identification code which completes the functional identification of the slave.
An ID1 code which defines the internal functions of the slave,
An identification code (ID2) which completes the functional identification of the slave.
These identifications allow the AS-i master to recognize the configuration, which is present on the bus.
These different profiles have been developed by the AS-i Association. They are used to distinguish between input, output and mixed modules, "intelligent" device families, etc.
Maximum
Number of
Inputs/Outputs
AS-i Cable
l l
On the same bus, an AS-i bus can support a maximum of:
31 4I and/or 4O standard address setting slaves, with addresses from 1 to 31
62 extended address setting slaves with 4I and/or 3O , using addresses from 1
A/B to 31 A/B.
This makes it possible to manage a maximum of 248 inputs +186 outputs (thus 434 inputs/outputs) when all extended slaves have 4 inputs and 3 outputs.
The AS-i cable is a twin-wire link on which communications and power supply for the connected devises are transmitted.
The link does not need to be twisted.
The cross-section of wires can be from 2 x 0.75 mm
2
, 2 x 1.5 mm
2
or 2 x 2.5 mm
2
, according to the current consumed by the devices.
Topology and
Maximum Length of AS-i Bus
The topology of the AS-i bus is flexible. It can be perfectly adapted to meet the user’s needs (point to point, on line, tree structure etc.).
In every case, the total length of all the branches of the bus must not exceed 100 meters without a relay.
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TSX SAY 1000
AS-i Bus Cycle
Time
Reliability,
Flexibility
This is the cycle time between slave(s) and the TSX SAY 1000 module.
The AS-i system always transmits information, which is the same length to each slave on the bus. The AS-i cycle time depends upon the number of slaves connected to the bus in the presence of functioning slaves.
The scan time t represents the exchange time between a master and n active slaves
(a maximum of 31 on /A or /B).
So, for: l l up to 19 active slaves, t = 3ms
20 to 31 active slaves t = (1+n) * 0.156ms
When two slaves A and B have the same address, each slave in the pair is scanned every two cycles.
This means that for 31 extended address setting slaves configured in /A, + 31 extended address setting slaves configured in /B. the scan time will be 10 ms.
l l
Maximum cycle time: maximum 5 ms for 31 standard or extended address setting slaves, maximum 10 ms for 62 extended address setting slaves.
Reliable operation is ensured by the transmission process used (Manchester current and coding modulation). The master monitors the line supply voltage and the data sent. It detects transmission errors as well as slave failures, and sends the information to the PLC.
Exchanging or connecting a new slave during operation does not disturb communications between the master and the other slaves.
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5.2
Description of the TSX SAY 1000 Module
TSX SAY 1000
At a Glance
Aim of this
Section
What's in this
Section?
This Section deals with hardware installation and the characteristics of the TSX SAY
1000 module.
This section contains the following topics:
Topic
Physical Introduction
Mounting/Installation
Connections
Displaying Module States
Specific Display Panels on the TSX SAY 1000 Module
Technical Characteristics of the AS-i V2 Bus
Personnel Safety
Page
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121
TSX SAY 1000
Physical Introduction
General
The TSX SAY 1000 module comes as a standard format module.
Illustration:
PWR OK
Description of
TSX SAY 1000 module
Front panel
The module is made up of the following elements:
1. A display panel consisting of 4 LEDs for displaying the operating modes of the module: l l
RUN LED (green): lit indicates normal functioning mode of the module.
ERR LED (red): when lit, this indicates a module error.
I/O LED (red): when lit, this indicates an AS-i bus error.
l l
/B LED (green): displays standard or /A address setting slaves.
2. Display panel consisting of 32 LEDs (0 to 31) which enable AS-i bus diagnostics, and display the state of each slave connected to the bus.
3. PWR OK LED (green): when lit, this indicates that power supply is consistent.
4. FAULT LED (red): when lit, this indicates faults associated with the AS-i bus.
5. A/B push button: this button informs the user of the status of devices on the bus by switching from bank A to bank B.
6. MODE push button: holding this button down causes initialization of slaves and a change to OFF-LINE. This then allows the user to programs the slaves through their infrared interface, or to connect the new diagnostic pocket to the bus. To return to normal mode, just press and hold this button again.
7. CANNON SUB D connector for connection to AS-i bus.
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Mounting/Installation
General
The TSX SAY 1000 module can be mounted in any position on the TSX RKY rack or extension rack, except for those positions dedicated to processors and power supply.
Note: Where the module is mounted on a remote X Bus rack, the maximum distance from the processor should be 175 meters minus the length of the X Bus
(100 meters max.).
The module should be inserted and extracted using a flat or cross tipped screwdriver. These operations can be carried out whether the power is on or off, with no adverse effects on the module or the rack holding it.
Example of mounting a TSX SAY 1000 module:
Number of
Modules per
Station
Note: The module can be mounted and removed with both PLC and AS-i bus power switched on.
The maximum number of modules per Premium/Atrium PLC station depends on the type of processor installed:
Processors
57-1xx
57-2xx
57-3xx/57-4xx
4
8
Maximum number of TSX SAY 100 or SAY 100 modules
2
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TSX SAY 1000
Connections
Connecting to the X Bus
Connection to the AS-i Bus
The module connects automatically to BUSX once it is inserted into its rack. If the module is inserted into the base rack, connection to the central unit and power supply module is implicit.
There is no particular order in which devices (Power Supply, Bus or Slave Master) must be connected to the AS-i network, but the unit as a whole is not guaranteed to be operational during this installation phase.
The AS-i network itself does not need to be grounded. Power supply and PLC devices must, however, adhere to standard installation requirements. You are advised not to place the AS-i network near cables carrying high currents.
The network's connection system is provided for connection to a trapezoid standard multiwire AS-icable (0.75mm to 2.5mm). Regardless of the topology carried over, the combined length of AS-inetwork cabling should not exceed 100m without relay.
AS-i Bus Cables
AS-i bus cables carry the signals and supply the sensors and actuators connected to the bus with 30 VDC.
Types of AS-i cables:
Cable type Characteristics
Polarized AS-i ribbon cable Color: yellow. Wire crosssection: 1.5 mm
2
Illustration
A²S-i A²S-i +
(Blue) (Brown)
Standard round cable
Wire cross-section: 1.5 mm
2
or
2.5 mm
2
A²S-i A²S-i +
(Blue)
(Brown)
Recommended cable: product reference H05VV-F2x1.5 (flat cable), conforms to the DIN VDE 0281standard. Wire cross-section: 1.5 mm
2
.
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Cable Routing
Link-up
Connector
TSX SAY 1000
The AS-i cable and the power cables carrying higher power levels must be in separate ducts, which are protected by a metal screen.
When using a shared route for control cables it is essential that the connections on these control links should conform to the technology rules (eg. the discharge diode or limiters on the terminals of self-inductive elements etc.).
A set (connector + cover) is delivered with the module, which is used to connect the module to the AS-i bus. This connector must be linked to the cable of the AS-i bus and assembled by the user according to the procedure described later.
Illustration:
Connector
Cover
Connection of
Module to Bus
To connect a module to the bus, follow the procedure below:
1 Connect the 2 wires of the AS-i cable to the connector, taking the polarities into account:
(Brown)
(Blue)
In the special event that a shielded cable is used, this should be connected to the central terminal.
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125
TSX SAY 1000
2 Mount the connector in its cover and fix the cable to it:
3 Click the cover shut:
4 Mount the unit on the module:
126
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TSX SAY 1000
Displaying Module States
General
This is carried out with 4 LEDs: RUN, ERR, A/B, I/O which are located on the module. Their state (LED off, flashing or on) provides information on the operating mode of the module.
LED state:
LEDs
On Flashing(**) Off
RUN (green) Module OK and configured
ERR (red) Serious non-rectifiable Module fault
Awaiting configuration
Rectifiable module fault (PL7 configuration, AS-i power supply)
/B (green) /A configured slaves display -
I/O (red)
0 to 31
(green)
AS-i bus Fault
Slave number OK (projected, present and active)
HS Module or autotest fault
Module OK
/B configured extended address settings slaves display
Fault or awaiting user configuration AS-i Bus OK
Slave Number /OK (*) Slave number not projected and absent
(**) all LEDS flash during module autotests.
(*) a slave is declared /OK when one of the conditions required for correct operation is not satisfied, regardless of the error level: l Error Level 1: l l
Slave declared but not detected,
Slave detected but not declared l l l l
Error Level 2:
Slave has different profile from declared slave,
Slave profile incompatible with address,
Slave with incorrect subprofile.
l l l l
Error Level 3: l
Slave refuses parameters, l
Slave has auxiliary power supply fault,
Analog data fault (channel fault),
Other faults linked to analog slave characteristics,
Input / Output or auxiliary power supply overload, l
External error:
- thermal relay,
- slave autotests NOK.
The user must connect his/her programming tool to access detailed information on the faulty slave. The local display can only show a malfunction in its related slave.
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TSX SAY 1000
Specific Display Panels on the TSX SAY 1000 Module
General
2 LEDs: PWR OK and FAULT give specific information on the TSX SAY 1000 module.
View of the 2 LEDs:
TSX SAY 1000
PWR OK LED
FAULT LED
PWR OK
FAULT
A/B
MODE
AS-i+
AS-i-
PWR OK LED
(green):
LED state
LED on
FAULT LED
(Red)
LED off
LED state
LED on
LED off
Meaning
Power Supply consistent
Power Supply inconsistent
Meaning
AS-i bus faults
No faults
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Technical Characteristics of the AS-i V2 Bus
AS-i V2 Bus
Technical Characteristics:
Characteristic
Maximum cycle time of bus: l l
- 1 to 19 slaves = 3ms,
- 20 to 62 slaves = (1+n)*156s
where n = number of active slaves.
Maximum number of slaves on the bus.
Maximum length of AS-i bus cables: all branches without relay with two relays
Maximum number of I/O managed by the bus
Nominal bus supply voltage
Value
maximum 5 ms for 31 standard or extended address setting slaves, maximum 10 ms for 62 extended address setting slaves.
31 standard address setting slaves, or,
62 extended address setting slaves.
100 meters
300 meters standard address setting slaves: 124 inputs + 124 outputs extended address setting slaves: 248 inputs + 186 outputs
30 VDC
TSX SAY 1000
Module
Technical Characteristics:
Characteristic
Programming the TSX SAY 1000 module
Value
from PL7 Junior, PL7 Pro V4.2, or P-Unit software
Response time with 31 slaves (1) for a PLC cycle time of 10 ms Typically 27 ms, 37 ms maximum
PLC current consumed on 5V Typically 100 mA / 150 mA maximum
Current consumed on 30 V AS-i/AS-i
Power dissipation
Protection against polarity inversion on bus inputs
Degree of protection
Typically 50 mA / 60 mA maximum
2.5 W max.
Yes
IP20
Isolated voltage
Operating temperature
500 VDC
0 to 60 degrees Celsius
AS-i master profile
Standards and service conditions
M2e
Conforms to those of Premium PLCs (see Volume
1)
(1) Logical response time + time between an AS-i input activated on the bus, processed in the PLC application and applied to an AS-i output.
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TSX SAY 1000
Personnel Safety
General
To ensure personnel safety it is essential: l l l
To earth the ground terminal of the PLC.
To use an AS-i VLSV (very low safety voltage) supply, nominal voltage 30 VDC.
For PLCs which are connected to an alternating current network, a differentiel circuit breaker must be placed upstream of this network, and this will cut off the
PLC power supply source if ground leakage if detected.
l For PLCs which are connected to a direct current supply source you must ensure that the supply placed upstream of the PLC is VLVS.
l To use certified AS-i products on the bus.
Due to the type of technology and connection, the TSX SAY 1000 module only receives 5 VDC and its 0V is linked to the PLC ground.
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5.3
Input/Output Object Addressing
Addressing Input/Output Objects
General
Example
Acquisition of inputs and update of slave device outputs connected to the AS-i bus are carried out automatically. This occurs at the start and end of each cycle respectively of the task in which the TSX SAY 1000 module is configured.
The user program has access to these inputs and outputs via language objects whose syntax for standard or extended address setting slot /A and /B slaves is as follows:
% I or Q
Symbol Type of object
I=input
Q=output
W=analog
\ xy.0
\
Module/channel address of the TSX SAY 1000
x=rack number
y=position number
0=channel 0 of the module
n
.
No. of slave:
1 to 31 for /A
101 to 131 for /B
i
Rank of bit
0 to 3
Particular example of rack 0:
%I\2.0\1.3 indicates: input 3 of slave TOR /A 1, channel 0 of the TSX SAY 1000 module, positioned in rack 0 slot 2.
%Q\2.0\103.0 indicates: input 0 of slave TOR /B 103, channel 0 of the TSX SAY
1000 module, positioned in rack 0 slot 2.
%IW\2.0\31.0 indicates: input 0 of slave ANA /A 31, channel 0 of the TSX SAY 1000 module, positioned in rack 0 slot 2.
Illustration:
TSX DM 57 xx
Addresses slaves
Slave
Addresses inputs/outputs of slaves
4I
@1
4I
@103
AS-i Bus
@5
1S
0
@31
4I & 4O
0 3 0 3
%I\2.0\1.0
%I\2.0\1.3
%Q\2.0\103.0
%Q\2.0\103.3
%Q\2.0\5.0
0 1 0 1
%IW\2.0\31.0
%QW\2.0\31.0
%IW\2.0\31.1
%QW\2.0\31.1
131
TSX SAY 1000
Note: The physical address of an AS-i slave is programmed by the XZM C11 portable console.
An analog slave is configured only on slot /A.
The number of an extended TOR /B slave lies between 101 and 131.
The number of a standard TOR /A slave, or an ANA slave (which is always standard) lies between 1 and 31.
When a standard address setting slave is set at /A, an extended address setting slave at /B cannot have the same address. Only two extended address setting slaves can have the same address at /A and /B.
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5.4
AS-i Bus Diagnostics
Introduction to AS-i Bus Diagnostics
General
The module display panel displays the presence and operating status of each slave on the AS-i bus.
Illustration:
Diagnostics of the AS-i Bus
Table giving diagnostics of module's standard- and extended address setting slaves:
View of standard- or extended address setting slaves on bank A:
/B LED off
View of extended address setting slaves on bank B:
/B LED light
View of AS-i bus image. Each LED from 1 to
31 corresponds to a standard or extended slave address on the bus.
l l
LED on: slave active
LED off: slave not expected and not detected.
l
LED flashes rapidly: peripheral fault on slave.
l
LED flashing slowly: configuration fault on slave.
View of AS-i bus image. Each LED 1 to 31 corresponds to an extended address setting slave address on the bus.
l l
LED on: slave present
LED off: slave not expected and not detected.
l
LED flashes rapidly: peripheral fault on slave.
l
LED flashing slowly: configuration fault on slave.
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TSX SAY 1000
View of standard- or extended address setting slaves on bank A:
/B LED off
View of extended address setting slaves on bank B:
/B LED light
Diagnostics example with 5 slaves addressed at 1, 4, 10, 11, 20:
In brief : l l l
LEDs for slaves 1, 4, 10, 20 are lit, therefore these slaves are active, slave 11's LED is flashing, so it is faulty, the other LEDs are off because no slaves are expected or detected at these addresses.
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5.5
TSX SAY 1000
Operating Modes of the TSX SAY 1000 Module
Operating Modes of the TSX SAY 1000 Module
General
For more information, refer to the section on AS-i installation in the Premium PLCs
Applications Manual - Basic Applications, Volume 1(Ref.: TLX DS 57 PL7 V4.2).
Output Fallback
Position
Since some AS-i V2 slaves have an internal watchdog based on a communication shutdown, when there is a fallback the module will function in the following way: l l l l fault detection (PLC stop, UC fault, module fault), bus automatically switched OFF LINE by bus master.
Consequences for slaves present on the bus:
"old generation" slaves: output maintenance,
"new generation" slaves: preprogrammed fallback positions are implemented in the slave.
Automatic Slave
Addressing
When this function is enabled in the module configuration, it allows the replacement of a faulty slave with a slave of the same type without stopping the AS-i bus, and without the need for special action: l
If the replacement slave is programmed with the same address and has the same profile, it will be automatically inserted in the list of slaves detected, then l activated. If this is not the case, the ERR and AS-i LEDs will flash simultaneously.
If the new slave has never been used (address 0, new slave) and has the same profile, the slave automatically takes on the address of the replaced slave and is therefore in the list of detected slaves and the list of active slaves. If this is not the case, the ERR and AS-i LEDs will flash simultaneously.
These actions are only possible if one and only one slave is faulty in the configuration.
Communication
Fault
If there is a break in communication with the CPU, following a CPU watchdog (where the SAY 1000 module is located in the main rack) or a retraction of the BUSx cable
(where the SAY 1000 module is located in the extension rack), the module switches to security mode and stops communication on the AS-i bus.
Module Fault
In the event of a serious fault on the TSX SAY 1000 module (faulty component, etc.) the module stops communicating with the X Bus and with the AS-i Bus. The same type of behavior occurs when a module is removed with the power on.
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TSX SAY 1000
Removing a
Module with
Power Switched
On
Should a module be removed with the power switched on, communication with the
X Bus stops and the processor indicates a module fault.
Communication with the AS-i bus is also interrupted without notice. In this case, the slaves with a watchdog set their outputs in the desired state, and the others remain in position and cannot be set to 0 since the module cannot guarantee communication.
Inserting a module with power switched on
After voltage is applied to the TSX SAY 1000 module, it expects to receive a configuration via PL7. If this does not occur it remains in stop mode.
AS-i Supply Fault
When there is an AS-i power supply fault communication stops and the slaves behave differently.
l slaves with a watchdog positioning their outputs in the defined state, except if the slave takes its power from the AS-i.
l all slave commands switch to 0 due to lack of power.
From a language point of view, all slaves seem faulty, and the absence of AS-i power supply is indicated in the Channel Status.
Break in the AS-i
Medium
There are several ways in which a break in the medium can occur:
1. There is a break in the medium as it exits the module:
Behavior is the same as that for a power outage, with all slaves disappearing and a supply fault being indicated.
2. There is a break in the medium after the TSX SAY 1000 module and the AS-i supply:
All slaves disappear and no indication of supply fault.
3. There is a break in the medium after the TSX SAY 1000 module, the AS-i supply and some slaves:
Slaves located after the break disappear and no indication of supply fault.
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5.6
Precautions of Use
At a Glance
Aim of this
Section
What's in this
Section?
This Section deals with the precautions to be taken when installing an AS-i bus.
This section contains the following topics:
Topic
24 VDC Auxiliary Supply
Multiple Address Settings
Page
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137
TSX SAY 1000
24 VDC Auxiliary Supply
Recommendations
When slaves use a 24 VDC auxiliary supply, the disappearance of this supply is not managed by the TSX SAY 1000 module.
Information on the disappearance of this supply can be accessed by using a 24 VDC input.
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Multiple Address Settings
Recommendations
When one or more slaves are connected, make sure that you do not assign an address, which is already being used by a slave on the bus.
WARNING
Double slave addressing
The two slaves with identical addresses have the same profile and manage identical I/Os: the AS-i master bus does not detect any error.
The two slaves with identical addresses manage different I/Os: the ASi master bus can detect transmission errors when accessing the I/O from one of the two slaves.
Failure to follow this precaution can result in death, serious injury, or equipment damage.
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TSX SAY 1000
5.7
AS-i V2 Certification
AS-i V2 Certification
Description
No.
Header:
Vendor:
Product name:
Order No. :
Release:
Master profile:
Date:
List of implemented functions:
List of implemented functions
12
13
14
15
8
9
10
11
6
7
4
5
2
3
A
1
16.0
16.1
16.2
Functions or calls at host interface
Image, Status = Read_IDI ()
Status = Write_OD (Image)
Status = Set_Permanent_Parameter (S_Addr, S_Param)
S_Param, Status = Get_Permanent_Parameter (S_Addr)
Status, RS_Param = Write_Parameter (S_Addr, S_Param)
Status, S_Param = Read_Parameter (S_Addr)
Status = Store_Actual_Parameters
Status = Set_Permanent_Configuration (S_Addr,S_ Config)
S_Param, Status = Get_Permanent_Parameter (S_Addr)
Status = Store_Actual_Configuration ()
Status, S_Config = Read_Actual_Configuration (S_Addr)
Status = Set_LPS (S_List)
Status, S_List = Get_LPS ()
Status, S_List = Get_LAS ()
Status, S_List = Get_LDS ()
Status, Flags = Get_Flags ()
Status, Flag = Get_Flag_Config_OK ()
Status, Flag = Get_Flag_LDS.0 ()
TSX SAY 1000
Mark/
Profile
*
*
*
*
*
*
*
*
-
-
*
*
*
*
*
*
*
*
140
Remark/ implemented by
TSX SAY 1000
TSX SAY 1000
TSX SAY 1000
TSX SAY 1000
TSX SAY 1000
TSX SAY 1000
TSX SAY 1000
TSX SAY 1000
TSX SAY 1000
TSX SAY 1000
TSX SAY 1000
TSX SAY 1000
TSX SAY 1000
TSX SAY 1000
TSX SAY 1000
TSX SAY 1000
TSX DM 57 xx
No.
List of implemented functions
18
19
20
21.1
21.2
22.1
22.2
22.3
16.3
16.4
16.5
16.6
16.7
16.8
16.9
17
B
1
23
24
2
22.4
22.5
22.6
22.7
Status, Flag = Get_Flag_Auto_Address_Assign ()
Status, Flag = Get_Flag_Auto_Prog_Available ()
Status, Flag = Get_Flag_Configuration_Active ()
Status, Flag = Get_Flag_Normal_Operation_Active ()
Status, Flag = Get_Flag_APF ()
Status, Flag = Get_Flag_Offline_Ready ()
Status, Flag = Get_Flag_Periphery_OK ()
Status = Set_Operation_Mode (Mode)
Status = Set_Offline_Mode (Mode)
Status = Activate_Data_Exchange (Mode)
Status = Change_Slave_Address (S_Addr1, S_Addr2)
Status = Set_Auto_Adress_Enable (Mode)
Mode = Get_Auto_Adress_Enable ()
Status, Resp = Cmd_Reset_AS-i_Slave (S_Addr, RESET)
Status, Resp = Cmd_Read_IO_Configuration (S_Addr, CONF)
Status, Resp = Cmd_Read_Identification_Code(S_Addr, IDCOD)
Status, Resp = Cmd_Read_Status (S_Addr, STAT)
* Status, Resp = Cmd_Read_Reset_Status (S_Addr,STATRES)
Status, Resp = Cmd_Read_Ext_ID-Code_1 (S_Addr, IDCOD1)
Status, Resp = Cmd_Read_Ext_ID-Code_2 (S_Addr, IDCOD2)
Status, S_List = Get_ List of Periphery Faults ()
Status = Write_Extended_ID-Code_1(S_Ext_ID-Code_1)
Integrated support of slave profiles
Analog slave profile S7.3 support integrated
Analog slave profile S7.4 support integrated
( - ) = not implemented functions
( * ) = implemented functions
*
-
*
-
*
*
*
*
*
*
*
*
*
*
*
*
Mark/
Profile
*
*
-
-
-
-
-
-
TSX SAY 1000
Remark/ implemented by
TSX SAY 1000
TSX SAY 1000
TSX SAY 1000
TSX SAY 1000
TSX SAY 1000
TSX SAY 1000
TSX SAY 1000
TSX SAY 1000
TSX SAY 1000
TSX SAY 1000
TSX SAY 1000
TSX SAY 1000
TSX SAY 1000
TSX SAY 1000
TSX SAY 1000
TSX SAY 1000
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141
TSX SAY 1000
142
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Communication:
TSX SCY 11601/21601 modules and PCMCIA cards
V
At a Glance
Aim of this Part
What's in this
Part?
This Part deals with installing hardware for TSX SCY 11601/21601 communication modules and PCMCIA communication cards.
This part contains the following chapters:
Chapter
6
7
8
9
Chapter Name
At a Glance
Installing TSX SCY 11601/21601 modules
Installing PCMCIA cards
TSX SCA 64 connection device
Page
143
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TSX SCY 11601/21601
144
TSX DM 57 xx
At a Glance
6
At a Glance
Subject of this
Chapter
What's in this
Chapter?
This chapter deals with the general features on TSX SCY11601/ 21601 modules and PCMCIA communication cards.
This chapter contains the following topics:
Topic
General communication architecture
Operating standards
Page
TSX DM 57 xx
145
At a Glance
General communication architecture
General
Illustration:
146
TSX DM 57 xx
At a Glance
Operating standards
General
TSX SCY 11601/21601 modules and PCMCIA communication cards comply with the following international norms and standards: l l l l l
US Standards: UL508, IEC 1131-2
CANADA Standards: CSA C22.2/1 42
Compliance with regulation: FCC-B
EC labeling
PCMCIA mechanical standard type III E l PCMCIA 2.01
The built-in link of the TSX SCY 11601 module complies with communication standards: l
Modbus/Jbus l XWAY
The built-in link of the TSX SCY 21601 module complies with communication standards: l l l
UNI-TELWAY
Modbus/Jbus
XWAY
The TSX FPP 20 PCMCIA FIPWAY card and TSX FFP 10 FIPIO agent comply with communication standards: l l l l l l
FIP protocol (link, network management)
PCMCIA
XWAY
TSX SCP 111, 112 and 114 PCMCIA cards comply with communication standards:
UNI-TELWAY, Modbus/Jbus protocols
PCMCIA
XWAY
TSX DM 57 xx
147
At a Glance
148
TSX DM 57 xx
Installing TSX SCY 11601/21601 modules
7
At a Glance
Subject of this
Chapter
What's in this
Chapter?
This chapter deals with the hardware installation of TSX SCY 11601/21601 modules.
This chapter contains the following sections:
Section
7.1
7.2
7.3
7.4
7.5
7.6
7.7
7.8
Topic
At a Glance
Description
Built-in Channel Specifications
TSX SCY 21601 module's host channel compatibility
Installation
Operation
Module Visual Diagnostics
Built-in Channel Connection
Page
TSX DM 57 xx
149
TSX SCY 11601/21601
7.1
At a Glance
At a Glance
TSX SCY 11601:
General
The TSX SCY11601 communication module is used to communicate via a JBUS/
MODBUS link.
It comprises a communication channel, channel 0, mono-protocol, isolated RS485 asynchronous serial link supporting the JBUS/MODBUS protocol.
TSX SCY 21601:
General
The TSX SCY 21601 communication module is used to host PCMCIA communication cards.
It comprises two communication channels: l A multi-protocol built-in channel (channel 0), isolated RS485 asynchronous serial link, supporting UNI-TELWAY, Jbus/Modbus or Character Mode protocols.
l A PCMCIA host channel (channel 1) which supports the following protocols: l
UNI-TELWAY, Jbus/Modbus and Character Mode on an RS 232-D, Current
Loop, or RS 485 link, corresponding to cards TSX SCP 111, 112 and 114.
l
FIPWAY cell network corresponding to the TSX FPP 20card.
Notes for the two modules
Note: Important: The built-in channel on TSX SCY 11601/21601 modules is only compatible with a two wire RS 485 link.
Note: The TSX SCY 11601/21601 communication modules are only compatible with SV software version
≥
3.0 Premium/Atrium processors (as indicated on the side label of the processor module).
150
TSX DM 57 xx
TSX SCY 11601/21601
7.2
Description
Description
TSX SCY 11601 module: General
The TSX SCY 11601 module is a standard format module which can be inserted into one of the slots on a Premium/Atrium PLC station rack.
Note: The X bus remote is not authorized for this module.
The TSX SCY 11601 module is made up of the following components:
1. Three indicator LEDs on the front of the module: l RUN and ERR show the module's l status.
CH0 displays the status of the built-in serial link channel (channel 0) communication.
2. Built-in channel (Channel 0) equipped with a 25 pin SUB-D female connector, half duplex mode (channel 0) RS 485 base link: l Jbus/Modbus
Illustration:
1
2
TSX DM 57 xx
151
TSX SCY 11601/21601
TSX SCY 21601 module: General
The TSX SCY 21601 module is a standard format module which can be inserted into one of the slots on a Premium/Atrium PLC station rack.
Note: The X bus remote is not authorized for this module.
The TSX SCY 21601 module is made up of the following components:
1. Three indicator LEDs on the front of the module: l RUN and ERR show the module's status.
l CH0 displays the status of the built-in serial link channel (channel 0) communication.
2. Built-in channel equipped with a 25 pin
SUB-D female connector, half duplex mode (channel 0) RS 485 base link: l l
UNI-TELWAY
Jbus/Modbus l Character Mode
3. PCMCIA type III (channel 1) card host channel.
Illustration:
Channel 0: built-in channel
Channel 1: host channel
152
TSX DM 57 xx
TSX SCY 11601/21601
Insertable cards
(TSX SCY 21601)
Different types of communication cards which can be built into the TSX SCY 21601 module's host channel:
Type
TSX SCP 111
Description Illustration
Multiprotocol card (UNI-TELWAY, Modbus/Jbus,
Character Mode), RS 232 D, 9 non-isolated signals.
TSX SCP 112
Multiprotocol card (UNI-TELWAY, Modbus/Jbus,
Character Mode), current loop (BC 20 mA).
TSX SCP 114
Multiprotocol card (UNI-TELWAY, Modbus/Jbus,
Character Mode), RS 485, RS 422 compatible isolated.
TSX FPP 20
FIPWAY network cards
TSX DM 57 xx
153
TSX SCY 11601/21601
7.3
Built-in Channel Specifications
Built-in Channel Specifications
General
Specifications
The built-in channel of TSX SCY 11601/21601 modules includes: l l l l
An RS 485 Physical Interface.
A twisted double pair medium.
The TSX SCY 11601 includes: Modbus/Jbus protocol,
The TSX SCY 21601 includes: UNI-TELWAY, Modbus/Jbus and Character Mode protocols.
Specifications of the built-in link for the following 3 protocols:
Type
Flow
UNI-TELWAY
(21601)
Master-Slave
9600 bits/sec.
Parameters can be set from 1200 to
19200 bits/sec.
28
98
Number of devices
Number of slave addresses
Length of bus without branching
1000 m
Message Size
Utilities
240 bytes
UNI-TE Masterslave, Slave-slave,
Messaging Requests
Modbus/Jbus
Master-Slave
9600 bits/sec.
Parameters can be set from 1200 to
19200 bits/sec.
32
98 for the 21601,
247 for the 11601,
1,300 m
256 bytes
Word/bit Reading
Word/bit Writing
Diagnostics
Character Mode
(21601)
Half duplex
-
-
9600 bits/sec.
Parameters can be set from 1200 to
19200 bits/sec.
1,000 m
4 Kb
Character string
Send, Character string Receive
154
TSX DM 57 xx
7.4
TSX SCY 11601/21601
TSX SCY 21601 module's host channel compatibility
TSX SCY 21601 Host Channel Compatibility
General
The cards supported by the host channel are: l l
PCMCIA cards: TSX SCP 111, 112, 114 which communicate with Premium/
Atrium, 1000 Series and Modicon PLCs and other UNI-TELWAY, Jbus/Modbus and Character Mode compatible products. PCMCIA cards are also Jbus/Modbus l l l compatible with 1000 Series PLCs
The TSX FPP 20 card is compatible with the following FIPWAY devices:
Model 40 PLCs (TSX 47-455, TSX 67-455, etc) in versions later than 5.0.
TSX 17 PLCs
PC compatibles connected with TSX FPC10 and TSX FPC 20cards.
Note: The TSX FPP 10 card is not supported by the host channel.
TSX DM 57 xx
155
TSX SCY 11601/21601
7.5
Installation
Installation
General
Maximum number of modules
The TSX SCY 11601/21601 modules can be installed in a Premium/Atrium PLC station rack.
They are part of an X-WAY network architecture based on Series 7, Micro, Premium and Atrium PLCs.
The TSX SCY 11601 communication module brings the following to a PLC station: l A JBUS/MODBUS isolated mono-protocol RS 485 communication channel.
The TSX SCY 21601 communication module brings the following to a PLC station: l l
A multi-protocol isolated RS 485 communication channel.
A standard PCMCIA communication card slot.
The TSX SCY 11601/21601 modules can be installed in any available slot in a
Premium/Atrium PLC station rack.
A TSX SCY 11601 module supports up to a maximum of 1 application-specific communication channel, namely the RS 485 channel built into the module.
A TSX SCY 21601 module can support a maximum of 2 application-specific communication channels, a built-in RS 485 channel and a channel from the PCMCIA card which can be integrated into the module.
Since the maximum number of application-specific channels managed by a PLC station depends on the type of processor installed, the number of TSX SCY 11601 l l
or TSX SCY 21601 modules in a station will therefore rely on:
The type of processor installed.
The number of application-specific channels already used, other than communication channels.
Consequently, the user must perform an evaluation on his/her PLC station to find out how many application-specific channels are already in use, and thus determine the number of TSX SCY 11601 or TSX SCY 21601 modules which may be used.
Note: Application-specific channel recognition is defined in the Installation Manual for Premium TSX DM 57 PLCs_Volume 1.
156
TSX DM 57 xx
TSX SCY 11601/21601
A reminder of the number of application-specific channels managed by each type of processor:
Processors
TSX P57103/TSX P57153
TSX P57203 / TSX P57253 / TSX P572623 / TSX
P572823 - PCX 57203
TSX P57303/TSX P57353 - PCX 57353 / TSX P573623 32
TSX P57453 / TSX P574823 64
Number of applicationspecific channels
8
24
Connection/
Disconnection
TSX SCY 11601/21601 modules can be connected or disconnected whilst the
power is on. These devices do not have a memory save function.
When one of the two modules is disconnected from the rack, its internal memory is erased. The module goes through an initialization phase once it is reconnected.
A TSX SCY 21601 module which has a PCMCIA card installed may be disconnected when the power is on.
Note: However, PCMCIA cards, used in TSX SCY 21601 may not be
disconnected while the power is on.
TSX DM 57 xx
157
TSX SCY 11601/21601
7.6
Operation
Operation
TSX SCY 11601 module: General
The TSX SCY 11601 module manages a communication channel (channel 0): l channel 0: Jbus/Modbus protocol on an RS 485 half duplex isolated, standardized physical link, with a speed limited to 19200 bits per second.
TSX SCY 21601:
General
The TSX SCY 21601 module manages two independent communication channels which each have their own functions: l channel 0 processes UNI-TELWAY, Jbus/Modbus and Character Mode protocols on an RS 485 half duplex isolated, standardized physical link, with a speed limited to 19200 bits per second.
l channel 1 can take one of the following PCMCIA communication cards: l
Field Bus: TSX SCP 111 (RS232), TSX SCP 112 (current loop), TSX SCP 114 l
(RS 422/RS 485) UNI-TELWAY, Jbus/Modbus and Character mode cards.
Cell network: TSX FPP 20 FIPWAY card.
The choice of PCMCIA card and protocol is made when the TSX SCY 21601 module's communication channels are configured using PL7 Junior and PL7 Pro software.
158
TSX DM 57 xx
TSX SCY 11601/21601
7.7
Module Visual Diagnostics
Module Visual Diagnostics
General
Three LEDs are located on the front panel of TSX SCY 11601/21601 modules.
These LEDs provide information on the operating status of the module and on the
communication status of the built-in serial link channel.
Illustration:
RUN (green)
ERR (red)
CH0 (yellow)
The communication status of the host channel is determined using the ERR and
COM LEDs in the PCMCIA cards on the serial or FIPWAY link (See Visual
diagnostics of PCMCIA cards, p. 190)
TSX DM 57 xx
159
TSX SCY 11601/21601
Meaning of the LEDs:
RUN ERR
(1)
CH0
(1)
(2)
(1)
Comments
Module powered-down or module failure
No communication on the built-in channel
Communication on the built-in channel
Serious fault on the built-in channel
Configuration fault.
No device OK on the channel
Faulty device on the built-in channel (for TSX
SCY 21601 only)
Autotests in progress l l
Off On
(1) = Indifferent state,
(2) = Line activity.
Flashing
160
TSX DM 57 xx
TSX SCY 11601/21601
7.8
Built-in Channel Connection
At a Glance
Aim of this
Section
What's in this
Section?
This section describes the different ways to connect the built-in channel of TSX SCY
11601/21601modules.
This section contains the following topics:
Topic
At a Glance
Connection of TSX SCY 21601 to Uni-Telway field bus
Reminder on adapting RS 485 distributed line for the TSX SCY 21601
Example of Uni-Telway architecture
Connection of TSX SCY 11601/21601 modules to the Jbus/Modbus field bus
Reminder on single line polarization in RS 485
Example of Modbus architecture
Connecting the TSX SCA 50 unit
Character Mode connection for TSX SCY 21601
Consumption of TSX SCY 11601/21601 modules
Page
TSX DM 57 xx
161
TSX SCY 11601/21601
At a Glance
TSX SCY 11601 module: General
Cabling accessories designed to connect the TSX SCY 11601 module's RS 485 base link allow the following connection: l Connection to the Jbus/Modbus network via a TSX SCA 50 unit through the TSX
SCY CM 6030 cable or a TSX SCA 64 unit through the TSX SCY CM 6530 cable.
Illustration:
TSX SCY CM 6030 Cable
TSX SCY 11601 or
TSX SCY CM 6530 Cable
RS 485 Built-in Channel
TSX SCA 64
Bus
162
TSX DM 57 xx
TSX SCY 11601/21601
TSX SCY 21601 module: General
Cabling accessories designed to connect the TSX SCY 21601 module's RS 485 base link allow the following connections: l
Connection to the UNI-TELWAY network via a TSX SCA 50 unit through the TSX
SCY CU6030 cable or a TSX SCA 62 unit through the TSX SCY CU 6530cable.
l Connection to the Jbus/Modbus network via a TSX SCA 50 or TSX SCA 64 unit l through the TSX SCY CM 6530 cable.
Connection to standard RS 485 devices using a connector adapted to the link via the TSX SCY CU 6030 or TSX SCY CM 6030cable.
Illustration:
TSX SCY 21601
TSX SCY CU6030 cable for UNI-TELWAY
TSX SCY CM 6030 Cable for Jbus/Modbus
RS 485 Built-in
Channel
TSX SCY CU 6530 Cable for UNI-TELWAY
TSX DM 57 xx
163
TSX SCY 11601/21601
Connection of TSX SCY 21601 to Uni-Telway field bus
General
The module's built-in communication channel is connected to the Uni-Telway field bus by the TSX SCY CU 6030 connection cable, via the TSX SCA 50 connection device.
Illustration:
25 pin SUB-D connector
Uni-Telway lead: TSX SCY CU 6030
Uni-Telway lead: TSX SCY CU 6530
Description of leads
Lead TSX SCY CU 6030:
TSX SCA 50 Device Connection
Red
White
White
Blue
164
TSX DM 57 xx
Lead TSX SCY CU 6530:
5 V
4,7 k
Ω
0 V
J1
20
13
25
6
12
19
24
0 V
4,7 k
Ω
8
0 V
0 V
D (A)
D (B)
TSX SCY 11601/21601
TSX SCA 62 connection unit
15
8
0 VL
0 VL
7
14
15-pin SUB-D connector
D (A)
D (B)
TSX DM 57 xx
165
TSX SCY 11601/21601
Reminder on adapting RS 485 distributed line for the TSX SCY 21601
General
This adaptation is used for Uni-Telway networks.
Diagram of normal Uni-Telway network architecture:
Zc Zc
Connection of network units
The network is made up of one shielded twisted pair. The connection of the network's different units is carried out as follows:
1
2
3
4
Link all outputs labeled + (Tx+, Rx+) to the network wire labeled: L+.
Link all outputs labeled - (Tx-, Rx-) to the network wire labeled: L-
Adapt the network's impedance using two adaptation nodes (Zc) located on the two end stations of the network.
For of distributed polarization of the network, link the L+ 5 V wire to the L- 0 V wire via two polarization resistors (Pr = 4,7 K
Ω
). Do this for each station. This polarization will keep the network stable while not in use.
166
TSX DM 57 xx
Integral
Characteristics
Integral characteristics are: l l
Up to 32 stations
Maximum range: about 1300 m l l l Bus Topology l
≤
15 m Branching
2 wire half duplex l
Adapting the line end on end units
Adapting the Pr = 4.7 K
Ω
distributed line
TSX SCY 11601/21601
TSX DM 57 xx
167
TSX SCY 11601/21601
Example of Uni-Telway architecture
Example
168
TSX DM 57 xx
TSX SCY 11601/21601
Connection of TSX SCY 11601/21601 modules to the Jbus/Modbus field bus
General
The built-in channel is linked to the bus via the TSX SCA 50 device through the TSX
SCY CM 6030 connection cable.
Illustration of TSX SCY 21601:
Built-in channel with
25 pin SUB-D connector
Jbus/Modbus lead: TSX SCY CM 6030
Lead description
TSX SCY CM 6030 lead description
Ω
Ω
-
Ω
Green/White
White/Green
Orange/White
White/Orange
D(A)
D(B)
White/Blue
Blue/White
TSX DM 57 xx
169
TSX SCY 11601/21601
Reminder on single line polarization in RS 485
General
Single line polarization is the polarization used for Modbus type networks.
General architecture diagram of a RS 485 network:
The senders are symbolized by:
The receivers are symbolized by:
Connection of network stations
1
2
3
4
The network is made up of one shielded twisted pair. The different stations of the network are connected as follows:
Link all outputs labeled + (Tx+, Rx+) to the network wire labeled: L+.
Link all outputs labeled - (Tx-, Rx-) to the network wire labeled: L-
Adapt the impedance of the network to the average of the two adaptation elements (Rc) located on the two end stations of the network.
For distributed polarization of the network, connect the wire L+ to 5 V and the wire L- to 0 V via the two polarization resistors (Rp = 470
Ω
).
This polarization continuously circulates a current in the network.
The adaptation can be made anywhere in the network (in practice it is generally made at master level).
There must be single polarization for the entire network, whatever its range.
170
TSX DM 57 xx
Integral
Characteristics
Integral characteristics are: l l l
Up to 32 stations l l
Maximum range: about 1,300 m l Bus Topology l
≤
15 m Branching
2 wire half duplex
Line end adaptation at the end stations
Adaptation of distributed line Rp = 470
Ω
TSX SCY 11601/21601
TSX DM 57 xx
171
TSX SCY 11601/21601
Example of Modbus architecture
Example
172
TSX DM 57 xx
TSX SCY 11601/21601
Connecting the TSX SCA 50 unit
Modbus without line adaptation
Illustration:
0 V
5 V
470
Ω
470
Ω
J1
21
9
6
24 nc nc
EMI - D (A)
EMI + D (B)
TSX SCY CM 6030 cable
TSX SCA 50
Orange/White
White/Orange
1
D(A)
D(B)
4
5
150
Ω
11
23 nc nc
Modbus with line adaptation and polarization
Illustration:
0 V
5 V
470
Ω
470
Ω
150
Ω
J1
21
9
6
24
TSX SCY CM 6030 cable
EMI - D (A)
EMI + D (B)
Green/White
White/Green
Orange/White
White/Orange
TSX SCA 50
1
4 D(A)
5 D(B)
11
23
White/Blue
Blue/White
TSX DM 57 xx
173
TSX SCY 11601/21601
Character Mode connection for TSX SCY 21601
General
The TSX SCY CM 6030 cable should be used to connect the TSX SCY 21601 module with an RS 485 standard device.
Users should connect the Character Mode TSX SCY 21601 to a Half duplex RS 485 standard device using the TSX SCY CM 6030 connection cable, adding a connector adapted for the intended device to the end of the cable, and linking the necessary signals (see lead connection in
Connecting the TSX SCA 50 unit, p. 173).
Illustration:
TSX SCY CM 6030 Cable
Two wire
RS 485 device
174
TSX DM 57 xx
TSX SCY 11601/21601
Consumption of TSX SCY 11601/21601 modules
Values
This table shows the consumption of TSX SCY 11601 and TSX SCY 21601 modules without a PCMCIA card (for 21601) or connection to the built-in channel:
Voltage
5 Volts
Typical Current
350 mA
Maximum Current Power dissipation
420 mA 2.1 W max.
TSX DM 57 xx
175
TSX SCY 11601/21601
176
TSX DM 57 xx
Installing PCMCIA cards
8
At a Glance
Aim of this
Chapter
What's in this
Chapter?
This Chapter deals with the hardware installation of PCMCIA communication cards onto Premium/Atrium PLCs.
This chapter contains the following sections:
8.8
8.9
8.10
8.11
8.12
Section
8.1
8.2
8.3
8.4
8.5
8.6
8.7
Topic
At a Glance
Description
Connecting the PCMCIA card reception channel
Connection of TSX SCP 111 card
Connection of the TSX SCP 112 card
Connection of the TSX SCP 114 card
Connection of the TSX FPP 20 card
Connection of the TSX FPP 10 card
Connection of the TSX MBP 100 card
Summary of connection devices
Precautions when connecting PCMCIA cards
Consumption of PCMCIA cards
Page
177
TSX DM 57 xx
PCMCIA installation
8.1
At a Glance
At a Glance
General
Premium/Atrium PLC stations connect to communication networks, buses and links through PCMCIA communication cards.
The card to be connected is a metal device whose dimensions comply with PCMCIA extended type III.
PCMCIA cards are installed in the reception slot of the processor and/or
TSX SCY 21601 module in PLCs from the Premium family.
PCMCIA cards can also be used in devices which have type III reception, such as
CCX 17, FT 2100 terminals or PC-compatible third-party devices, for example.
Illustration:
Micro
Premium
178
Premium
Atrium
Note: It is prohibited to connect PCMCIA cards when the power is switched on.
PCMCIA cards are installed, operated and maintained using PL7 Junior/PL7 Pro programming and operation software for all PLCs in the Premium family.
TSX DM 57 xx
TSX SCP 11 cards.
PCMCIA installation
Series link PCMCIA cards.
Each TSX SCP 111, 112, 114 PCMCIA card supports a different physical layer. This family comprises three products:
Product reference
TSX SCP 111
Physical layer
RS 232-D link.
Illustration
TSX SCP 112
TSX SCP 114
Current loop link (20 mA).
RS 485 link (RS 422 compatible)
All three cards, TSX SCP 111, 112 and 114, support the following communication l l l protocols:
Modbus/Jbus protocol
UNI-TELWAY protocol
Character Mode asynchronous link
TSX FFP 20 card
FIPWAY network PCMCIA card:
Functions
The TSX FPP 20 PCMCIA card supports the FIP physical layer. It is used to connect a Premium/
Atrium station to a FIPWAY network, as well as to connect to devices of manufacturers who wish to connect their products to the FIPWAY network.
The card is fitted with four rotary switches (marked
"1" in the illustration) which make it possible to encode the network number and station.
Illustration
TSX DM 57 xx
179
PCMCIA installation
TSX MBP 100 card
Modbus + network PCMCIA card:
Functions
The TSX MBP 100 PCMCIA card is used to connect a Premium/Atrium PLC station to the
Modbus+ network.
Illustration
TSX FPP 10 card
FIPIO bus agent PCMCIA card:
Functions
The TSX FPP 10 PCMCIA card is used to connect a Premium/Atrium PLC station to a
FIPIO bus.
It ensures the link with TSX 47-107 PLCs and
April 5000
Illustration
180
TSX DM 57 xx
PCMCIA installation
8.2
Description
Description
General
PCMCIA type III (extended) communication cards are built into a metal device with the following dimensions: l l l
Length: 85.5 mm
Width: 51 mm
Height: 10 mm
The front of the card is designed to display the functioning of communications as well as the physical connection to the network.
Mechanical configuration
The mechanical configuration of the card must be adapted by mounting a removable cover, depending on the type of installation desired:
Type of installation Configuration
Installation on a
Premium type processor or on a
TSX SCY 21601 communication module.
Removable cover with wings. Screws are provided to fix it to the reception module
(marked 3 on illustration)
Installation on an Atrium type processor.
Removable cover with wings. Screws are provided to fix it to the
Atrium processor
(marked 2 on illustration).
Installation onto a PC compatible device.
Removable cover
(marked 1 on illustration).
Illustration
TSX DM 57 xx
181
PCMCIA installation
Note: The covers with wings, mounted on PCMCIA cards, prevent any accidental removal when switched on and guarantee that the card remains in good working order.
The two covers (1) and (3) are provided with the PCMCIA card. Cover (2) is provided with the Atrium processor.
Connection to the network is achieved by connecting the linking cable to the front of the card. A guidance system is used to prevent anything being mounted incorrectly.
The product reference label informs the user of the type of physical layer supported by the card.
182
TSX DM 57 xx
8.3
PCMCIA installation
Connecting the PCMCIA card reception channel
At a Glance
Aim of this
Section
What's in this
Section?
This Section describes the installation of PCMCIA cards in the reception channel of the TSX SCY 21601 module.
This section contains the following topics:
Topic
Precautions when connecting PCMCIA
Connecting PCMCIA cards
Product references for PCMCIA cards and installation
Mounting cards and cables
PCMCIA card operation display
Visual diagnostics of PCMCIA cards
Page
TSX DM 57 xx
183
PCMCIA installation
Precautions when connecting PCMCIA
General
CAUTION
The PCMCIA card must be handled with the power switched off
Failure to follow this precaution can result in injury or equipment damage.
When removing or inserting the card, the unit is not guaranteed to be operational.
There is no procedure for a warm start between the PCMCIA card and the TSX SCY
21601 reception device.
In the event that the operating environment does not allow the application to be stopped by switching off the PLC processor, you are recommended to remove the
TSX SCY 21601 module with the PCMCIA card.
The PCMCIA card must be equipped with a PLC version cover and be screwed in the TSX SCY 21601 reception module before the unit is switched on (see
Mechanical configuration, p. 181).
184
TSX DM 57 xx
PCMCIA installation
Connecting PCMCIA cards
General
Connecting PCMCIA cards requires specific cables and connection devices, depending on the type of models.
Series link cards
Product references of cables and branch devices to be used with series link
PCMCIA cards according to the different protocols:
PCMCIA card
TSX SCP 111
(RS 232)
TSX SCP 112
(Current Loop)
TSX SCP 114
(RS 422/RS 485)
UNI-TELWAY
TSX SCP CD 1030/1100 in point to point mode
TSX SCP CC 1030 in multidrop mode via a modem
TSX SCP CX 2030
TSX SCP CU 4030 and TSX
SCA 50
Jbus/Modbus
TSX SCP CD 1030/1100 in point to point mode
Character Mode
TSX SCP CD 1030/1100
TSX SCP CC 1030 in multidrop mode via a modem
TSX SCP CX 2030 TSX SCP CX 2030
TSX SCP CM 4030 and TSX
SCA 50
TSX SCP CU 4030 and TSX
SCP CM 4030
FIPWAY network card
The TSX FPP 20 FIPWAY card is connected via the reception channel using a
TSX FPCG 10 or TSX FPCG 30 cable.
Modbus+ Card
The TSX MBP 100 Modbus+ card is connected via the reception channel using a
TSX MBP CE 030 (3 m) or TSX MBP CE 060 (6 m).
TSX DM 57 xx
185
PCMCIA installation
Product references for PCMCIA cards and installation
Installation
Table showing options for installing PCMCIA cards in processor reception channels and in the TSX SCY 21601 module:
Product references Processor reception channel TSX SCY 21601 reception channel
TSX SCP 111
TSX SCP 112
Yes
Yes
Yes
Yes
TSX SCP 114
TSX FPP 10
TSX FPP 20
TSX MBP 100
Yes
Yes
Yes
Yes
Yes
No
Yes
No
Applicationspecific channels and network connections
186
Table showing the number of application-specific channels or network connections used by PCMCIA cards:
Product references Number of application-specific channels
Card in the processor Card in the TSX SCY
21601 module
TSX SCP 111
TSX SCP 112
TSX SCP 114
TSX FPP 10
TSX FPP 20
TSX MBP 100
0
0
0
0
-
-
1
-
1
1
-
-
1
1
-
-
-
-
Number of
Network
Connection s
Reminder of the number of application-specific channels and network connections managed by the type of processor:
Processors
TSX P57103/TSX P57153
TSX P57203 / TSX P57253 / TSX P572623 / TSX
P572823 - PCX 57203
TSX P303 / TSX P57353/ TSX P573623 - PCX
57353
TSX P57453 / TSX P574823
32
64
Applicationspecific channels
8
24
2
4
Network connections
8
8
TSX DM 57 xx
PCMCIA installation
Mounting cards and cables
Details about
PCMCIA cards
Illustration:
TSX DM 57 xx
PCMCIA cards are made up of the following elements:
2
3
Number Designation
1 Equipped card
4
Body made of zamac
PCMCIA connector
Upper cover
5
6
Removable cover
Linking cable with ferule
Comments
Receives electronic components.
-
Connector with 20 connection points.
Houses the product reference label which shows the type of PCMCIA card
Ensures the card is displayed in its slot. The names of the two LEDs are printed on the front of the removable cover. This cover is also used to fix the PCMCIA card on the processor or on the
TSX SCY 21601 module.
The ferule placed on the end of the PCMCIA card cable side prevents the cable being pinched by the removable cover. This ferule also eliminates the risk of causing a bending radius which can damage the quality of the link.
187
PCMCIA installation
Assembly
To assemble the transmission support for the card first remove the cover which is screwed on the device then follow the instructions below:
Step
1
2
3
4
5
Instruction
Connect the cable
Place the appropriate cover on the device, taking care to insert the ferule in the slot provided in order to fix the cable to the card.
Illustration
Screw on the cover
Insert the card in the slot provided in the host device.
Screw in the card to stop it being moved when switched on, and to ensure it functions effectively.
Receptor
Processor or
TSX SCY 21601
188
TSX DM 57 xx
PCMCIA installation
PCMCIA card operation display
General
Illustration
Two diagnostics LEDs are located on the front of the card. They inform the user on how exchanges between the device supporting the PCMCIA card and the related device are functioning.
Number Description
1 Error "ERR" LED (normally off) displays errors.
This is red
2 The "COM" communication LED displays the line activity.
This LED is: l
Yellow on the TSX SCP 111-112-114,
TSX FPP 10 and TSX FPP 20 cards.
l
Green on the TSX MBP 100 card.
Diagram
TSX DM 57 xx
189
PCMCIA installation
Visual diagnostics of PCMCIA cards
General
Cards
TSX SCP 111/
112/114 and
TSX FPP 10/20
Depending on their state, LEDs of the PCMCIA card indicate the operating mode for communication, as well as the card diagnostics.
State of LEDs:
ERR COM Meaning
Device switched off No dialog
Operating normally
Corrective actions
Check supply, Card inoperational
-
(1) Serious error
Functional error
Functional error
Change the card
Check the configuration and the connection to the communication bus
Check the configuration
Key: Off On Flashing (1) = Indifferent state
Note: The "ERR" LED of the card TSX FPP 20, when flashing, indicates that an l l l external error has appeared. These errors are:
Line error
Station already present on the network
Incorrect station-network address coding (rotary switch coding)
190
TSX DM 57 xx
TSX MBP 100 cards
PCMCIA installation
State of LEDs:
ERR COM Meaning
Device switched off No dialog
Operating normally
Corrective actions
Check supply, Card inoperational
-
(1)
(2) Serious error Change the card
Functional error: Card not configured, communication cannot start on the network.
Functional error
Configure the card using: PL7
Junior or PL7 Pro
Check the configuration and the connection to the Modbus+ network. The way the COM LED flashes indicates the type of problem (see below)
Off On Flashing
(1) = The way the COM LED flashes indicates the operating state of the network (see below) - (2) = Indifferent state
Meaning of COM LED flashing:
State of COM LED
6 flashes/second
1 flash/second
2 flashes, followed by a 2 second pause
Meaning
Node is functioning normally It receives and transmits the network token. All the nodes on a network which are functioning flash in this way.
The node is off-line just after power up or after leaving the 4 flashes/sec. mode. In this state, the node monitors the network and establishes a table of active nodes. After remaining in this state for 5 seconds, the node attempts to switch to a normal operating state, indicated by 6 flashes per second.
The node detects the token transmitted among the other nodes, but never receives the token. Check if there is an open circuit or a faulty terminator on the network.
TSX DM 57 xx
191
PCMCIA installation
State of COM LED Meaning
3 flashes, followed by a 1.7 second pause
The node does not detect any token transmitted among the other nodes. It regularly searches for the token but cannot find another node to pass the token to it. Check if there is an open circuit or a faulty terminator on the network.
4 flashes, followed by a 1.4 second pause
The node has detected a valid node message using a network address identical to its own address. The node remains in this state for as long as it continues to detect the duplicated address. If the duplicated address has not been detected within 5 seconds, the node changes mode and flashes once per second.
192
TSX DM 57 xx
PCMCIA installation
8.4
Connection of TSX SCP 111 card
At a Glance
Aim of this
Section
What's in this
Section?
This Section deals with installing hardware for TSX SCP 111 PCMCIA cards.
This section contains the following topics:
Topic
Point to point connection in Character Mode (DTE <==> DTE)
Uni-Telway, Modbus or Character Mode via Modem
Page
TSX DM 57 xx
193
PCMCIA installation
Point to point connection in Character Mode (DTE <==> DTE)
General
The TSX SCP 111 RS 232 D physical support card is inserted either in the processor or in the TSX SCY 21601 module. It is connected to the related device with the TSX
SCP CD 1030/1100 cable.
The devices to be connected are DTE to DTE (Data Terminal Equipment ). For example: terminal, printer, etc.
Illustration:
TSX SCP 111
Printer
TSX SCP CD 1030 (length 3 m) or TSX SCP CD 1100 (length 10 m)
Description of
TSX SCP CD
1030 cable
Illustration:
The PCMCIA 20-pin mini-connector supports the signals:
Blue/white rings
White/blue rings
White/orange rings
Orange/white rings
Green/white rings
White/green rings
194
TSX DM 57 xx
PCMCIA installation
Uni-Telway, Modbus or Character Mode via Modem
General
The PCMCIA card is connected to a Uni-Telway, Modbus or Character Mode bus, via a modem and a telephone link (DTE/DCE type), using a TSX SCP CC 1030 cable.
The connected devices are DCE type, for example a modem or a converter.
Illustration:
TSX SCP 111
Modem
TSX SCP CC 1030 (length 3 m)
Description of the
TSX SCP CC
1030 cable
Illustration:
The PCMCIA 20-pin mini-connector supports the signals:
White/blue rings
Blue/white rings
White/orange rings
Orange/white rings
White/green rings
Green/white rings
White/brown rings
Brown/white rings
White/gray rings
Gray/white rings
Connector
SUB-D 25M
TSX DM 57 xx
195
PCMCIA installation
8.5
Connection of the TSX SCP 112 card
At a Glance
Aim of this
Section
What's in this
Section?
This Section deals with the hardware installation for TSX SCP 112 PCMCIA cards.
This section contains the following topics:
Topic
Connection of the TSX SCP 112 card
Connecting in point to point mode
Multidrop connection
Dynamic performance
TSX SCP 112 connection with April 5000/7000 PLCs
Page
196
TSX DM 57 xx
PCMCIA installation
Connection of the TSX SCP 112 card
General
The PCMCIA TSX SCP 112 card is used to connect a Premium/Atrium PLC station to a loop link with a current of 20 mA in point to point or multidrop.
Note: In all cases the power supply is: 24 V
±
20%, external to the TSX SCP
112 card, and must provide the current required for the current loop supply .
The TSX SCP CX 2030 cable is used for this type of connection (length 3 m).
Description of the TSX SCP CX 2030 cable:
The PCMCIA 20-pin mini-connector supports the signals:
J1
9 + Alim
13 EMI mlp
19 + REC
17 - REC
2 EMI pap
20 - Alim
White/Blue
Orange/White
White/Green
Green/White
White/Orange
Blue/White
Note: A screw terminal block needs to be installed to connect the TSX SCP 112 card.
TSX DM 57 xx
197
PCMCIA installation
Connecting in point to point mode
General
The diagram below describes the wiring principles for TSX SCP 112 loop current
PCMCIA cards in point to point. Point to point is only carried out according to 20 mA mode when idle.
Illustration:
Station 1
SCP 112
9
19
17
2
20
Station 2
SCP 112
9
19
17
2
20
+
-
24 V
Junction block 1
Junction block 2
Note: Important: the cable shielding must be connected at the shortest point in the junction blocks.
198
TSX DM 57 xx
PCMCIA installation
Multidrop connection
General
Multidrop is only carried out in 0 mA idle mode. The send cable and receive cable are set in parallel. The master is set by the software.
Example of connection of n TSX SCP 112 cards:
Station 1
TSX SCP 112
Station 2
TSX SCP 112
Station 3
TSX SCP 112
TSX DM 57 xx
Rc
Junction block 1
Junction block 2
Rc = resistance of optional load
Junction block n
Note: Important: the cable shielding must be connected at the shortest point in the junction blocks.
199
PCMCIA installation
Dynamic performance
General
The flow of a current loop link is limited by the cross-section and the length or the cable used.
The user should refer to the two charts below to evaluate the performance which can be obtained using this application.
Point to point
These curves are given for a shielded two pair cable (send through one pair, reception through the other) while observing all the precautions of use. speed in Kbps cable 1 mm
2
4500 m max.
cable 0.64 mm
2
2500 m max.
cable 0.34 mm
2
1300 m max.
Multidrop
The chart below is given for a shielded cable with a conductor cross-section of 0.34 mm
2
. The connection is made according to the parallel multidrop diagram below.
Using conductors with a larger cross-section improves the quality of the signals transmitted:
Number of connected stations
200
TSX DM 57 xx
TSX DM 57 xx
PCMCIA installation
Multidrop link performance is optimized when there are more connected stations.
The line is busier, which improves the quality of the transmitted signal.
When the connection is made according to the diagram above (See General,
p. 199), the number of stations can be increased artificially (to a maximum of 16
stations) by loading the line at one of its ends.
This can be carried out by incorporating a load resistance.
This load resistance can be connected to any junction block providing it is between pins 17 and 19 of cards TSX SCP 112.
The value of Lr resistance simulating the load of "N" stations is determined by the formula:
Rc =
----------------
N
U
×
20
R in K
Ω
U = external supply voltage
N = station number to be simulated
Example:
An installation is physically made up of 6 stations connected in multidrop with an external 24 V supply.
The performance of the line is that of 10 stations, simulating the load of 4 additional stations by a resistance:
Rc =
---------------
4
24
×
20
= 0 3K
Ω
Note: The load resistance must not have an inductive effect or there is a risk that it will not operate.
Use a thick layer of resistance.
201
PCMCIA installation
TSX SCP 112 connection with April 5000/7000 PLCs
General
PCMCIA card TSX SCP 112 20 mA current loop is used to connect April communication modules JBU0220 and JBU0250. The multidrop connection of
PCMCIA card TSX SCP 112 to modules JBU0220 and JBU0250 is carried out in
series mode. To connect April modules refer to reference manual TEM60000E.
Note: Important: You must configure card TSX SCP 112 in point to point mode in the PL7 configuration screen, for both the point to point or the multidrop series.
Note: The current loop authorizes a current of 20 mA when idle, in point to point as well as in multidrop mode.
If a slave is switched off the sender of this slave become active and the line is available.
If the loop supply is offset on one of the slaves, switching this slave off will cause communication to be interrupted.
Point to point link: Module
JBU0220 or active JBU0250
Illustration
White/Blue
White/Green
Green/White
White/Orange
Passive master or slave:
Blue/White
202
Master or slave active
TSX DM 57 xx
PCMCIA installation
Point to point link: active
TSX SCP 112 card
Illustration:
White/Blue
White/Green
Green/White
White/Orange
Blue/White
Master or slave active
Mixed terminal links
Illustration:
White/Blue
White/Green
Green/White
Master or slave: passive receiving active sending
White/Orange
Blue/White
TSX DM 57 xx
Master or slave passive
Master or slave: passive receiving active sending
203
PCMCIA installation
Multidrop type link
The following examples describe the different wiring possibilities for card
TSX SCP 112 with modules JBU0220/0250.
Note: Important: The 24 V supply of each TSX SCP 112 present on the loop must be connected, whether passively or actively, otherwise the link will not function.
These supplies must not have any shared (potential) point between them. Do not connect the -24 V supply to the earth.
Example 1: Active master TSX SCP 112 multidrop
White/Blue
White/Green
Green/White
Master active
White/Orange
Blue/White
Slave 1 passive
204
Slave 2 passive
TSX DM 57 xx
Example 2: active send/receive JBU0220/0250 multidrop
PCMCIA installation
TSX DM 57 xx
Master active sending/receiving
White/Blue
White/Green
Slave 1 passive
Green/White
White/Orange
Blue/White
Slave 2 passive
205
PCMCIA installation
Example 3: Multidrop master JBU0220/0250 active send/receive - slaves
TSX SCP 112
White/Blue
White/Green
Green/White
Master active sending/receiving
White/Orange
Blue/White
White/Blue
White/Green
Slave 1 passive
Green/White
White/Orange
Blue/White
Slave 2 passive
206
TSX DM 57 xx
TSX DM 57 xx
Example 4: Multidrop active master TSX SCP 112
White/Blue
White/Green
Green/White
White/Blue
White/Green
Green/White
PCMCIA installation
Master active sending/receiving
White/Orange
White/Orange
Blue/White Blue/White
Slave 1 passive
Slave 2 passive
207
PCMCIA installation
8.6
Connection of the TSX SCP 114 card
At a Glance
Aim of this
Section
What's in this
Section?
This Section deals with the hardware installation of TSX SCP 114 PCMCIA cards.
This section contains the following topics:
Topic
Connection to the UNI-TELWAY network
Connecting to the Modbus/Jbus bus
Multi-protocol asynchronous link connection RS 422
Page
208
TSX DM 57 xx
PCMCIA installation
Connection to the UNI-TELWAY network
General
Type of connection
Card TSX SCP 114, physical support RS 485, connects to the UNI-TELWAY network using cable TSX SCP CU 4030 via the connection device TSX SCA 50, or by cable TSX SCP CU 4530 (provided with SUB-D 15 pin connector) via device
TSX SCA 62. The card is inserted in the processor or in module TSX SCY 21601.
The TSX SCA 50 is passive and made up of a printed circuit board fitted with 3 sets of screw terminal blocks. It is used to connect a station by branching on the main section of a UNI-TELWAY bus.
It ensures continuing operation of electrical signals, shielding and end of line adaptation function.
The cable of the PCMCIA card has bare wires at its ends which the user must connect to the terminal located inside the device.
Illustration:
TSX SCP 114
TSX SCP CU 4030
Note: The branching device configures the wiring system of the card and a branching type of connection system.
TSX DM 57 xx
209
PCMCIA installation
Description of the
TSX SCP CU
4030 cable
Illustration:
The PCMCIA 20-pin mini-connector supports the signals:
TSX SCA 50 device
Red
White
White
Blue
Connection via a
TSX SCA 62 device
Illustration:
TSX SCP 114
TSX SCP CU 4530
210
TSX DM 57 xx
Description of the
TSX SCP CU
4530 cable
Illustration:
The PCMCIA 20-pin mini-connector supports the signals:
Ω
Ω
PCMCIA installation
TSX SCA 62 device
Red
White
White
Blue
15-pin SUB-D
TSX DM 57 xx
211
PCMCIA installation
Connecting to the Modbus/Jbus bus
General
Type of connection
The TSX SCP 114 PCMCIA card is connected to the Modbus bus using the linking cable TSX SCP CM 4030. This cable is connected to the branching device TSX SCA
50.
The cable of the PCMCIA card has bare wires at its ends which the user must connect to the terminal located inside the device.
Illustration:
TSX SCP 114
TSX SCP CM 4030
Note: The length of the cable used (3 m), makes it possible to link a device to a
TSX SCA 50 connection device located within a 3 meter radius of the card. This length ensures connection inside a standard cabinet
Description of the
TSX SCP CM
4030 cable
Illustration:
The PCMCIA 20-pin mini-connector supports the signals:
Green/White
White/Green
Orange/White
White/Orange
Brown/White
212
TSX DM 57 xx
PCMCIA installation
Connecting
Modbus to
TSX SCA 50 device
Note: Important: on a Modbus/Jbus bus you must: l l
Polarize the line, in general in only one spot (usually on the master device) with
470
Ω
resistance. Connect R pull-down
to EMI- (D(A)) and R pull-up
to EMI+ (D(B)).
Adapt the line on the two end devices with a resistance of 150
Ω
between EMI+ and EMI- (EMI+ is already connected internally by the card).
Important: to connect TSX SCP 114 card to a PLC Series 1000 (S1000), EMI+ must be connected to L-.
Connection with no line terminator:
TSX SCA 50
Green/White
White/Green
TSX DM 57 xx
Connection of a SCA 50 with line terminator:
Green/White
White/Green
Orange/White
White/Orange
Brown/White
TSX SCA 50
213
PCMCIA installation
Multi-protocol asynchronous link connection RS 422
General
Type of connection
Connecting the TSX SCP 114 card in Character Mode does not require any specific accessories.
The product reference for the RS 485/RS 422 PCMCIA card linking cable is
TSX SCP CX 4030. It is 3 meters in length.
The TSX SCP 114 PCMCIA card is connected in point to point to an RS 422A standard device VAX station type.
Illustration:
TSX SCP 114
Industrial computer
TSX SCP CX 4030
214
TSX DM 57 xx
PCMCIA installation
Description of the
TSX SCP CX
4030 cable
Illustration:
The PCMCIA 20-pin mini-connector supports the signals:
J1
470
Ω
18
GND
10
VCC
470
Ω
EMI -
12
EMI +
11
9
20
REC -
1
REC +
2
5
ADP Rec
13
ADP 150r
0 V iso
16
4
Green/White
White/Green
White/Orange
Orange/White
Brown/White
See also
Character Mode connection for TSX SCY 21601, p. 174 (TSX SCY 21601
module integrated link)
TSX DM 57 xx
215
PCMCIA installation
8.7
Connection of the TSX FPP 20 card
Connecting the TSX FPP 20 card
General
The TSX FPP 20 PCMCIA card is connected to the Fipway network using a connector such as TSX FP ACC4 or TSX FP ACC 12.
To connect the PCMCIA card to the ACC4/ACC12 connector the user has the choice of: l l
Either a 1 m cable, product reference TSX FP CG 010.
Or a 3 m cable, product reference TSX FP CG 030.
The elements required for connecting a Premium/Atrium PLC to the Fipway network are:
TSX FP ACC 4
216
TSX FPP 20
Receptor
Processor or
TSX SCY 21601
Note: Important: TSX FP CG 010/030 cables connect and disconnect from the
PCMCIA card only when power is switched off.
TSX DM 57 xx
PCMCIA installation
8.8
Connection of the TSX FPP 10 card
Connecting the TSX FPP 10 card
General
The TSX FPP 10 PCMCIA card is connected to the FIPWAY bus using a connector such as TSX FP ACC 4 or TSX FP ACC 12.
To connect the PCMCIA card to the ACC4/ACC12 connector the user has the choice of: l l
Either a 1 m cable, product reference TSX FP CG 010.
Or a 3 m cable, product reference TSX FP CG 030.
Elements required for connecting a Premium/Atrium PLC to the remote inputs/ outputs FIPIO bus:
Receptor
Processor
TSX FPP 10
TSX DM 57 xx
Note: Important: cables (TSX FP CG 010/030) are connected and disconnected from the PCMCIA card only when power is switched off.
217
PCMCIA installation
8.9
Connection of the TSX MBP 100 card
At a Glance
Aim of this
Section
What's in this
Section?
This Section deals with the hardware installation of TSX MBP 100 PCMCIA Modbus
Plus cards.
This section contains the following topics:
Topic
Connecting the TSX MBP100 card
General principle for connecting the PCMCIA card
Grounding the TSX MBP CE 030/060 cable
Connecting the TSX MBP CE 030/060 cable to Modicon connection device
990 NAD 230 00
Page
218
TSX DM 57 xx
PCMCIA installation
Connecting the TSX MBP100 card
General
The TSX MBP 100 PCMCIA card is connected to the Modbus Plus network using the TSX MBP CE 030 branch cable, 3 m long, or the TSX MBP CE 060, 3 m long.
This cable is connected to Modicon branch device (local site tap) 990NA23000.
For information on how to install a Modbus Plus network, see the Modicon Manual
" Modbus Plus Network-Installation and Planning Manual" Product Reference 890
USE 100 01".
TSX DM 57 xx
219
PCMCIA installation
General principle for connecting the PCMCIA card
Principle
Illustration:
PCMCIA card
TSX MBP 100
TSX MBP CE 030/060 cable
Description of the TSX MBP CE 030/060 cable:
Branching device
Modicon 990 NAD 230 00
(Local Site Tap)
Screening braid
GND
White
Blue
GND
GND
Loop clamp
External shielding
White
Orange
Note: Important: The cable’s main shielding is grounded using a metal clamp in contact with the screening braid, which itself is fixed to the frame supporting the rack.
This cable must be grounded, even if there is no PCMCIA card present.
220
TSX DM 57 xx
PCMCIA installation
Grounding the TSX MBP CE 030/060 cable
Procedure
The cable connecting the PCMCIA card to the Modicon branching device must be grounded as shown below:
1 Clip the loop clamp onto the cable.
This loop clamp is delivered with the
Modicon branching device (Local Site
Tap), product reference 990 NAD 230 00.
TSX MBP 100
Cable
TSX MBP CE 030 or
TSX MBP CE 060
Loop clamp
2 Fix the clamp + cable unit to the frame.
The frame itself is connected to the ground.
TSX DM 57 xx
221
PCMCIA installation
Connecting the TSX MBP CE 030/060 cable to Modicon connection device 990
NAD 230 00
General
Connection procedure
TSX MBP CE 030/060 cables are made up of two distinct sets of shielded twisted pair wires and one external shielded ground wire, which makes a total of seven wires.
To connect the cable to the Modicon device follow the procedure below:
Step
1
2
Action
Identify the wires: l
A first set of wires marked with the colors White and Orange, with one stripped shielded wire.
l
A second set of wires marked with the colors White and Blue, with one stripped shielded wire.
l
The external shielded wire
Note: It is important to correctly identify the two sets of twisted pairs since the two white wires are not interchangeable
Set up the cable according to the dimensions given in the following illustration.
Illustration:
Blue/White
White/Orange
3 Insert the cable in the Modicon device and keep it in place using a clip.
222
TSX DM 57 xx
TSX DM 57 xx
Step
4
PCMCIA installation
Action
Connect the wires to the device, following the diagram below.
Diagram:
Branching device Modicon 990 NAD 230 00
5
Terminal
O
W
GND
W
BLU
Wire color
Orange
White
2 set shielding
White
Blue
Ground wire, external shielding
Cable clip
TSX MBP CE 030/060 cable
Remove the plastic hood from the terminal to connect each wire:
6 Place each wire in the corresponding terminal slot:
223
PCMCIA installation
Step
7
Action
Replace the hoods, and using a screwdriver press them to engage the wires in their slots:
8 Finally, fix an open terminal to the external shielding wire either by soldering or crimping, and connect it to the ground screw of the device as shown in stage 4 of the drawing.
224
TSX DM 57 xx
PCMCIA installation
8.10
Summary of connection devices
Summary of connection devices
TSX SCP 111 card
Type of cable
Modem cable
Standard cable
Product reference Designation
TSX SCP CC 1030 Connection cable via Modem DTE/DCE
9 signals RS 232D, L=3 m.
TSX SCP CD 1030
TSX SCP CD 1100
Connection cable DTE/DTE RS 232D,
L=3 m or 10 m.
TSX SCP 112 card
TSX SCP 114 card
Type of cable
Current loop cable
Type of cable
Universal cable
UNI-TELWAY cable
Modbus cable
Connection device
Connection device
Converter device
TSX FPP 10 and
TSX FPP 20 cards
Type of cable
FIPWAY/FIPIO cable
FIPWAY/FIPIO cable
Connection device
Connection device
Product reference Designation
TSX SCP CX 2030 Current loop cable 20 mA, L=3 m.
Product reference Designation
TSX SCP CX 4030 Universal cable type RS 485 and RS
422A, L=3 m.
TSX SCP CU 4030 Cable type RS 485, L=3 m.
TSX SCP CM 4030 Cable type RS 485, L=3 m.
TSX SCA 50 Connection device screwed to bus for
RS 485 series link.
TSX SCA 62
TSX SCA 72
Connection device via connector to bus for RS 485 series link.
RS 232D/RS 485 converter device.
Product reference Designation
TSX FP CG 010 Connection cable, L=1 m.
TSX FP CG 030
TSX FP ACC4
TSX FP ACC12
Connection cable, L=3 m.
FIPWAY/FIPIO connection device.
FIPWAY/FIPIO connection device.
TSX DM 57 xx
225
PCMCIA installation
TSX MBP 100 card
Type of cable
Modbus+ cable
Modbus+ cable
Product reference Designation
TSX MBP CE 030 Connection cable, L=3 m.
TSX MBP CE 060 Connection cable, L=6 m.
226
TSX DM 57 xx
8.11
PCMCIA installation
Precautions when connecting PCMCIA cards
Precautions for connecting PCMCIA cards
Important
Cards must be connected or disconnected in the host device (processor or
TSX SCY 21601) when the device is switched off.
The ferule, placed in direct contact with the PCMCIA card device, is used to handle electrical interference carried by the link cable braids.
TSX DM 57 xx
227
PCMCIA installation
8.12
Consumption of PCMCIA cards
Consumption of PCMCIA cards
TSX SCP 111
Table of consumption:
Voltage
5 volts
Typical current
140 mA
Maximum current
300 mA
Dissipated power
1.5 W max.
TSX SCP 112
TSX SCP 114
Table of consumption:
Voltage
5 volts
Typical current
120 mA
Maximum current
300 mA
Dissipated power
1.5 W max.
Table of consumption:
Voltage
5 volts
Typical current
150 mA
Maximum current
300 mA
Dissipated power
1.5 W max.
TSX FPP 10 and
TSX FPP 20
Table of consumption:
Voltage
5 volts
Typical current
280 mA
Maximum current
330 mA
Dissipated power
1.65 W max.
TSX MBP 100
Table of consumption:
Voltage
5 volts
Typical current
220 mA
Maximum current
310 mA
Dissipated power
1.55 W max.
228
TSX DM 57 xx
TSX SCA 64 connection device
9
At a Glance
Aim of this
Chapter
What's in this
Chapter?
This Chapter introduces the functions of the TSX SCA 64 connection device.
This chapter contains the following sections:
Section
9.1
9.2
9.3
9.4
9.5
9.6
9.7
9.8
Topic
General Introduction
Physical Description
Dimensions and Mounting
Installation
Wiring the TSX SCP CM 4530
Bus Cable Shield Cabling
Device Configuration and Transmission Pair Polarization
Adapting the Line End
Page
TSX DM 57 xx
229
TSX SCA 64
9.1
General Introduction
General Introduction
General
In 2-wire Mode
The TSX SCA 64 unit is a cabling accessory, which allows a 2 or 4 wire mode communication module to be connected to a Modbus, Jbus or Jnet.
In this mode, connectable communication interfaces are: l the built-in channel of the TSX SCY 11601/21601 modules, via a TSX CM 6530 cable, l the TSX SCP/JNP 114 PCMCIA card, via a TSX SCP CM 6530 cable.
Note: Connection can be made to either the JM or the JS connector, regardless of channel configuration (master or slave).
Illustration
This diagram shows the general principal for connecting in 2-wire mode for a TSX
SCY 21601.
or
Bus or
1 = JM connector
2 = JS connector
Bus Bus
230
TSX DM 57 xx
In 4-wire Mode
Illustration
TSX SCA 64
In this mode, the connectable communication interface is: l l l a PCMCIA TSX SCP/JNP 114 card, via a TSX SCP CM 4530 cable, through a
TSX SCP CM 6530 cable.
Connect the TSX SCP CM 6530 cable to the:
JM connector if the PCMCIA card channel is configured in master mode,
JS connector if the PCMCIA card channel is configured in slave mode.
This diagram shows the general principal for connecting in 4-wire mode.
(slave channel)
Bus or
(master
1 = JM connector
2 = JS connector
Bus Bus
TSX DM 57 xx
231
TSX SCA 64
9.2
Physical Description
Physical Description
Illustration
This diagram shows the assembly plan for the TSX SCA 64 connection device.
232
TSX DM 57 xx
Nodes
TSX DM 57 xx
TSX SCA 64
The following table describes the different nodes, which make up the connection device.
2
3
No. Description
1 Cover screws
Device Cover
Screws fixing restart ground clamps
4
5
Restart ground clamps
Metallic part guaranteeing ground link between the 2 cables
6 SUB D 15 pin female (JM) connector able to receive: l in 2-wire mode: the male connector of a TSX SCY CM 6530 or TSX SCP CM 4530 connection cable, whether the channel is master or slave, l in 4-wire mode: the male connector of a TSX SCP CM 4530 connection cable, if the channel is master, l or a TSX SCA 10 line terminator if the device is located at the beginning or end of the line, l or a male analyzer connection cable connector
1 micro-switch allowing configuration in 2-or 4-wire operation 7
8
9
SUB D 15 pin female (JS) connector able to receive: l in 2-wire mode: the male connector of a TSX SCY CM 6530 or TSX SCP CM 4530 connection cable, whether the channel is master or slave, l in 4-wire mode: the male connector of a TSX SCP CM 4530 connection cable, if the channel is slave, l or a TSX SCA 10 line terminator if the device is located at the beginning or end of the line, l or a male analyzer connection cable connector
3 micro-switches allowing polarization mode to be configured
10 Terminal to connect green/yellow ground wire
11 Connection terminals for the main connection cables assuring continuing operation of the bus
12 Device Connection Base
13 Screw holes (4 diameter) to fix the device to a board or panel (60mm apart)
14 Main 2 or 3 pair cable guaranteeing continuing operation of the bus (max. 10 diameter), for connection to JA
15 5VDC power supply cable (for external polarization if required) for connection to JC
16 Main 2 or 3 pair cable guaranteeing continuing operation of the bus (max. 10 diameter), for connection to JB
17 Green/yellow device grounding cable
18 Main cable with corresponding ground format connected to local ground via a surge suppressor
233
TSX SCA 64
No. Description
19 Power supply cable and green/yellow ground wire
20 Main cable with corresponding ground format connected to local ground
Note: Nodes 14 and 16 are not included with the TSX SCA 64 device.
234
TSX DM 57 xx
TSX SCA 64
9.3
Dimensions and Mounting
Dimensions and Mounting
Dimensions
This diagram shows the dimensions of the RSX SCA 64 connection device.
Mounting/Fixing
The device can be mounted either: l l on a board or panel, secured with 2 M4 screws (min. length 20mm), on a DIN profile - Refs. AM1-DP 200 or AM1-DE 200 (Schneider catalog references).
TSX DM 57 xx
235
TSX SCA 64
Drilling Template
This diagram shows the plan for mounting on a board or panel.
(1) Screw hole diameter must be suitable for M4 screw
236
TSX DM 57 xx
TSX SCA 64
9.4
Installation
Required
Hardware
Procedure
Installation
Installing the TSX SCA 64 device requires: l l a 2.5mm wide flat tipped screwdriver, a cross tipped screwdriver (PZ01).
The labels in the text below correspond with those found in the description of the device.
Step
1
2
3
11
12
8
9
4
5
6
7
10
Action
Unscrew screw 1 with a PZ01 screwdriver, open cover 2.
Fix device connection base to its support: l l either a DIN AM1-DP200 or AM1-DE 200 profile, or a board or panel, and secure with 2 M4 screws (min. length 20mm).
Prepare main cables 14 and 16 according to the connection type selected, as indicated on the following pages.
Position the ground clamps 4 onto the cables.
Position the ground link 5, if necessary, according to the type of connection selected, as indicated on the following pages.
Connect the main cables (and the power supply cable if necessary) to terminal 11 according to the type of connection selected, as indicated on the following pages.
The cable wires should have DZ5-CE005 cable ends (for the main cables) and
DZ5-CE007 cable ends (for the power supply cable).
Use a 2.5mm wide flat tipped screwdriver.
Torque on terminal screw
≤
0.25 N.m.
Screw on the ground clamps and link with the screws 3, using a cross tipped
PZ01 screwdriver.
Connect the green/yellow ground wire 17 to connection terminal 10.
Secure the cables with nylon clips. (Attach the green/yellow wire to the power supply cable if it is present).
Set the micro-switches 7 et 9 to the desired configuration; see configurations on following pages.
Break the scored tabs on the cover 2 to make way for the cables.
Mount the cover 2 and secure it with the screw 1 using a cross tipped PZ01 screwdriver.
TSX DM 57 xx
237
TSX SCA 64
9.5
Wiring the TSX SCP CM 4530
Wiring the TSX SCP CM 4530
Illustration
J1 connector
(PCMCIA side)
12 Tx-
11 Tx+
20 Pull down
18 Pull up
1 Rx-
2 Rx+
16 0 volt
Green/White
White/Green
White/Blue
Blue/White
White/Orange
Orange/White
Brown/White
15-way SUBD connector
7
14
15
12
16
13
8
238
TSX DM 57 xx
TSX SCA 64
9.6
Bus Cable Shield Cabling
At a Glance
Aim of this
Section
What's in this
Section?
This section describes the different local grounding principles for the bus.
This section contains the following topics:
Topic
Local Grounding the Bus: General
Connecting the shield to the local ground and to the two ends of the cable
(recommended cable type)
Connecting the shield to the local ground at one end of the cable and to the local ground via a surge suppressor at the other end
Connecting the shielding to the local ground at one end and isolating it from the ground at the other end.
Page
TSX DM 57 xx
239
TSX SCA 64
Local Grounding the Bus: General
Introduction
Principle
Illustration
The bus can be grounded in three different ways: l l connecting the shield to the local ground and to the two ends of the cable, connecting the shield to the local ground at one end and to the local ground via a surge suppressor at the other end, l connecting the shielding to the local ground at one end and isolating it from the ground at the other end.
l l
Opposite each main cable path, a copper pad grounds the cable shields:
The path shown 20 locally grounds the cable shielding.
The path shown 18 locally grounds the cable shielding via a surge suppressor.
This diagram shows the principle for locally grounding the device as a whole.
Local ground
Cable
Preparation
Template:
Introduction
Certain precautions must be taken in order to ensure correct placement of the bus l l cables: following the stripping template, using the following cable ends: l
DZ5-CE005 for the main cables, l
DZ5-CE007 for the power supply cable.
This diagram shows the local grounding principle for the device as a whole.
Shielding
240
TSX DM 57 xx
TSX SCA 64
Connecting the shield to the local ground and to the two ends of the cable
(recommended cable type)
Principle
The two grounding tracks should be linked via the ground link 5 shown. End devices differ in that they only have one cable. Where this is the case, the ground link 5 shown is not required as long as the cable is positioned in slot 20 shown in the diagram.
Illustration
This diagram shows the principle for locally grounding the cable.
TSX DM 57 xx
Connecting several devices together:
241
TSX SCA 64
Connecting the shield to the local ground at one end of the cable and to the local ground via a surge suppressor at the other end
Principle
Only cable 16 shown is connected to the local ground, cable 14 shown is connected to the local ground via a surge suppressor.
Note: Ground link5 shown is not used
Illustration
This diagram shows the principle for locally grounding the cable.
242
Connecting several devices together:
TSX DM 57 xx
TSX SCA 64
Connecting the shielding to the local ground at one end and isolating it from the ground at the other end.
Principle
Only cable 16 shown is connected to the local ground, cable shielding 14 shown is isolated from the ground by a thermo-retractable tube (not included).
Note: In this case, ground link5 shown is not used.
Illustration
This diagram shows the principle for locally grounding the cable.
Thermo-retractable isolating tube
TSX DM 57 xx
Connecting several devices together:
Shielding isolated by thermo-retractable tube
243
TSX SCA 64
9.7
Device Configuration and Transmission Pair
Polarization
At a Glance
Aim of this
Section
What's in this
Section?
This section contains the different configurations of the TSX SCA 64 device.
This section contains the following topics:
Topic
4-wire Configuration with 2-pair Polarization via External Power Supply
4-wire Configuration with Polarization of One Pair by the Master Station and the Other by a Slave Station
2-wire Configuration with M+, M- Pair Polarization by the Master Station or a
Slave Station
Page
244
TSX DM 57 xx
4-wire Configuration with 2-pair Polarization via External Power Supply
TSX SCA 64
Introduction
Main cables 14 and 16 are 3-pair cables: l l l one M+, M- pair, one S+, S- pair, one VL, 0VL pair.
Power supply cable 15 is linked to an external 5VDC power supply.
Green/yellow wire 17 is connected to the module's ground terminal.
Note: each pair is only polarized once on the whole bus.
Illustration
This diagram shows a configuration with shielding connection at one end only.
TSX DM 57 xx
245
TSX SCA 64
Positioning of
Micro-switches
W1
W2
W3
W4
This table shows micro-switch positions.
Micro-switches Position on device receiving power supply
4F
OFF
OFF
ON
Other devices
4F
OFF
OFF
ON/OFF
246
TSX DM 57 xx
TSX SCA 64
4-wire Configuration with Polarization of One Pair by the Master Station and the
Other by a Slave Station
Introduction
Main cables 14 and 16 are 3-pair cables: l l l one M+, M- pair, one S+, S- pair, one 0VL, OVL pair.
Green/yellow wire 17 is connected to the module's ground terminal.
Note: each pair is only polarized once on the whole bus.
Illustration
This diagram shows a configuration with M+ M- pair polarization by the connected master station.
TSX DM 57 xx
247
TSX SCA 64
Positioning of
Micro-switches
W1
W2
W3
W4
This table shows micro-switch positions
Micro-switches Positions on master station device
4F
OFF
ON
OFF
Illustration
This diagram shows a configuration with S+ S- pair polarization by one of the connected slave stations.
248
TSX DM 57 xx
Positioning of
Micro-switches
W1
W2
W3
W4
This table shows micro-switch positions.
Micro-switches Positions on one of the slave stations
4F
ON
OFF
OFF
other slave stations
4F
OFF
OFF
OFF
TSX SCA 64
TSX DM 57 xx
249
TSX SCA 64
2-wire Configuration with M+, M- Pair Polarization by the Master Station or a
Slave Station
Introduction
Main cables 14 and 16 are 2-pair cables: l one M+, M- pair, l one 0VL, 0VL pair.
Green/yellow wire 17 is connected to the module's ground terminal.
Note: This pair is only polarized once on the whole bus.
Illustration
This diagram shows a configuration with shielding connection at one end only.
250
TSX DM 57 xx
TSX SCA 64
Positioning of
Micro-switches
W1
W2
W3
W4
This table shows micro-switch positions.
Micro-switches Position on master station device
2F
OFF
ON
OFF
slave stations
2F
OFF
OFF
OFF
Illustration
This diagram shows a configuration with shielding connection at one end only.
TSX DM 57 xx
251
TSX SCA 64
Positioning of
Micro-switches
W1
W2
W3
W4
This table shows micro-switch positions.
Micro-switches Position on one of the slave stations other stations (master/slaves)
2F
ON
2F
OFF
OFF
OFF
OFF
OFF
252
TSX DM 57 xx
TSX SCA 64
9.8
Adapting the Line End
Line End Adaptation
At a Glance
Illustration
Each end of the bus cable must have a line end jack adaptor. This line end jack adapter can be plugged into free connectors on either JM (master) or JS (slave) on
TSX SCA 64 devices, located at the ends of the bus.
A TSX SCA 10 kit consisting of 2 SUB D 15 pin connectors plus accessories (cover, screws, wiring etc.) enables the user to configure and set up the line end jacks.
This view shows a line end jack.
SCA 64 mounting example
This example shows a communication bus with 4 TSXx SCA 64 connection devices.
To TSX SCY 21601 modules
Line end jack
Line end jack
TSX DM 57 xx
Bus Bus Bus
253
TSX SCA 64
Installing line end jacks: At a
Glance
Configurations are attained by plugging each SUB D 15 pin 2-wire connector
(supplied) into the sockets, enabling line adaptation. Two types of configuration are possible depending upon the type of stations present on the bus: l Configuration 1 l
All stations present on the bus are Modbus stations: if this is the case, the line end jacks should be configured as shown below (resistance-type adaptation).
This diagram shows configuration 1: Modbus stations on the bus.
Pair S+, S-
Cabling view
Resistance type adaptation
Mounting procedure
254
Pair M+, Ml
Configuration 2 l
Stations present on the bus are Modbus and Uni-Telway stations: if this is the case, the line end jacks should be configured as shown below (resistance-type and series capacity adaptation).
This diagram shows configuration 2: Modbus and Uni-Telway stations on the bus. :
Pair M+, M-
Cabling view
Resistance and series capacity type adaptation
Pair S+, S-
Installation
Status
1
2
5
6
3
4
7
Action
Plug the wires supplied into the SUB D 15 pin connectors in accordance with the desired configuration.
Put the connector into place in one of the half-covers (the connector can be either way up).
Attach the latch screw.
Put the sleeve into place.
Cover it all with the other half-cover, taking care not to damage the wires.
Screw in or clip on the two half-covers (depending upon the type included).
Use the blank labels provided to show utilization.
Note:Cable clamps and/or other accessories should not be used.
TSX DM 57 xx
TSX SCA 64
Connecting an
Analyzer
The JM or JS connectors on the TSX SCA 64 device can support a frame analyzer, which is connected by a SUB D 15 (male) pin connector. Signals relating to each pair are available on the device connectors as indicated in the diagram below.
This diagram shows the connections for different pairs of the analyzer cable.
TSX SCA 64 device
15 pin (female) SUB D connector
RxM
RxS
TSX DM 57 xx
255
TSX SCA 64
256
TSX DM 57 xx
Communication : modules
TSX ETY 110/4102/PORT/5102 et et TSW WMY 100
VI
Présentation
Objet de cet intercalaire
What's in this
Part?
Cet intercalaire traite de la mise en oeuvre matérielle des coupleurs réseau
ETHERNET TSX ETY 110, TSX ETY 4102/PORT/5102 et TSX WMY 100, dans un automate Premium/Atrium.
This part contains the following chapters:
Chapter
10
11
Chapter Name
Communication: TSX ETY 110 module
Communication: Modules TSX ETY 4102/PORT/5102
Page
257
TSX DM 57 xx
TSX ETY 110/4102/PORT/5102 et TSX WMY 100
258
TSX DM 57 xx
Communication: TSX ETY 110 module
10
At a Glance
Aim of this
Chapter
What's in this
Chapter?
This Chapter deals with installing the Ethernet network module TSX ETY 110, in a
Premium/Atrium PLC.
This chapter contains the following sections:
Section
10.1
10.2
10.3
10.4
10.5
10.6
10.7
10.8
Topic
At a Glance
Description
Characteristics of the Ethernet channel
Installing the TSX ETY 110 module
Connection via the AUI interface
10baseT Interface
Display panel, diagnostics
Electrical features
Page
259
TSX DM 57 xx
TSX ETY 110
10.1
At a Glance
At a Glance
General
Communication module TSX ETY 110 is used to communicate in an Ethernet architecture. It is made up of a communication channel which offers two types of connections: l
Connection to an ETHWAY network supporting common words and X-WayUNI-
TE message-handling services on an ETHWAY profile.
l
Connection to a TCP-IP network supporting the X-WayUNI-TE messagehandling service.
This module also ensures transparent routing of X-WayUNI-TE messages from a
TCP-IP network to an X-Waynetwork, and vice versa.
Please refer to the Ethernet reference manual for wiring an ETHWAY architecture.
260
TSX DM 57 xx
TSX ETY 110
10.2
Description
Description
General
Module TSX ETY 110 is a single (half size) module which is inserted in a rack slot of a Premium PLC station.
Description:
Illustration: 1. Display panel indicating state of module.
2. Standard connector for 10baseT
(RJ45) interface.
3. Standard connector for 10base5
(AUI) interface.
4. Thumbwheel to define station number and network number.
1
2
3
4
TSX DM 57 xx
261
TSX ETY 110
10.3
Characteristics of the Ethernet channel
Characteristics of Ethernet channel
General
The module is made up of two standard interfaces for connecting to a network: l
One 10baseT interface on front panel of the module, comprising an RJ45 l connector, which is used for a point to point link via a linking cable made up of two twisted pairs of impedance 100
Ω ±
15
Ω
.
A 10base5 or AUI interface on front panel of module comprising a SUB-D 15-pin connector, used to link to network by branching. This interface is also used to supply active connection devices (Taps). It complies with the IEC 802 3 standard and is used to connect any device which complies with this standard.
The type of connection is recognized automatically as soon as connection is made to the network.
Services and operations supported by the module:
TCP-IP services
Ethway services
Common services
UNI-TE
UNI-TE
Common words
Application to application l l l l l l l l
Client/server mode.
Synchronous requests of 256 bytes.
Asynchronous requests of 1 Kbyte.
Client/server mode.
Synchronous requests of 256 bytes.
Asynchronous requests of 1 Kbyte.
Shared database of 256 words
Message exchange in point to point 256 bytes max.
l l l
X-Wayinter-network routing
X-WAY/UNI-TE routing
Module diagnostics
Note: The Ethernet driver supports the Ethernet II and (LCC+SNAP) 802.3 formats on TCP-IP and LCC 802.3 on Ethway.
262
TSX DM 57 xx
TSX ETY 110
10.4
Installing the TSX ETY 110 module
At a Glance
Aim of this
Section
What's in this
Section?
This Section deals with installing module TSX ETY 110 in a PLC.
This section contains the following topics:
Topic
At a Glance
Selecting the Type of Processor
Wiring/Unwiring with power switched on
Station address coding
Page
TSX DM 57 xx
263
TSX ETY 110
At a Glance
General
The communication module TSX ETY 110 is mounted in the rack slot of a Premium/
Atrium PLC station. It can be installed in any available slot (except in the offset X
Bus racks), on condition that the supply constraints of the rack are observed (see
Electrical characteristics, p. 274).
264
TSX DM 57 xx
TSX ETY 110
Selecting the Type of Processor
Selection Guide
Selecting the processor to control the PLC station will depend on the number of network connections required.
Processors Number of network connections
1
Number of ETY 110 modules per station (*)
1
TSX 57 P 1../2..
PCX 57 253
TSX P 57 3...
PCX 57 353
TSX P 57 4..
3 3
4 4
(*) on condition of a consumption report on the 5V, compatible with the supply selected.
TSX DM 57 xx
265
TSX ETY 110
Wiring/Unwiring with power switched on
The module
The link
Module TSX ETY 110 can be wired or unwired with power switched on without disrupting the operation of the station.
The module does not have a RAM internal backup memory function: this will be erased when power is switched off.
The module initializes itself when power is switched on. A communication break can be expected during this intervention.
The SUB-D 15-pin connectors of the AUI interface and the RJ45 connector of the
10baseT interface can be connected or disconnected when power is on. A communication break can therefore be expected in the application in progress.
266
TSX DM 57 xx
TSX ETY 110
Station address coding
General
Four thumbwheels, which can be accessed from the front panel, are used to encode the network number and the station number.
Illustration:
TSX DM 57 xx
MSB
LSB
MSB
LSB
Number of network
Number of station
LSB = least significant bit
MSB = most significant bit
Values of coding possible in hexadecimal:
Network number
0 to 7F
Station number
0 to 3F
Example of coding:
Network 3: 16#03
Station 27: 16#1B
The thumbwheels are to be adjusted as follows:
1
B
0
3
PF
Pf
PF
Pf
Note: Caution: in an Ethernet network, there must only be one MAC address for each station. Before modifying these addresses you must check that they comply with the addressing plan of the carrier.
267
TSX ETY 110
10.5
Connection via the AUI interface
Connection by AUI interface
General
This interface is used to connect all types of devices which comply with the physical layer defined in the OSI 802.3 standard (10base5, 10base2, FOIRL, etc.) through a transceiver.
Module TSX ETY 110 can provide a remote power supply for the transceiver through l l the Sub-D connector with the following characteristics:
Imax = 0.5 mA
12 V-6%<Usupply<15 V+15%
The module is connected to the main cable via a transceiver and by the following branch cables: l l l
TSX ETY CB 005 - Length 5 m
TSX ETY CB 010 - Length 10 m
TSX ETY CB 020 - Length 20 m
The maximum length of a branch may be 50 m. This length can be achieved by connecting several branch cables end to end.
Note: It is essential to use transceivers (TSX ETH ACC2) to connect two modules in point to point.
268
TSX DM 57 xx
Connector pinouts
Topology
7
8
5
6
3
4
1
2
9
10
11
12
13
14
15
Sub-D connector body
Sub-D 15 pins according to the OSI 802.3 standard:
Pin number Use Designation according to
ISO 802.3
CI-S (Control In Shield)
CI-A (Control In A)
DO-A (Data Out A)
DI-S (Data In Shield)
DI-A (Data in A)
VC (Voltage Common) not used not used
CI-B (Control In B)
DO-B (Data Out B)
DO-S (Data Out Shield)
DI-B (Date In B)
VP (Voltage Plus)
VS (Voltage Shield) not used
PG (Protective Ground)
GND
COLL+
TD+
GND
RD+
GND
COLL-
TD-
GND
RD-
12 V
GND
Protective ground
Illustration:
Sender/Receiver
TSX ACC2
TSX ETY 110
TSX ETY CBXXX
Station i
TSX DM 57 xx
Station j
269
TSX ETY 110
Locking
The Sub-D connector is equipped with a sliding lock system The connector is locked by sliding the tab to the bottom. To ensure the module works properly in a disturbed environment it is essential to carry out the locking procedure.
Illustration:
Locking tab
270
TSX DM 57 xx
TSX ETY 110
10.6
10baseT Interface
10baseT interface
General
Pinouts
This interface has a standard type RJ45 connector. These connection cables are widely used in business.
In an industrial environment, you must use a cable with the following characteristics: l l l l
Shielded twisted double pair
Impedance 100
Ω±
15
Ω
(from 1 to 16 MHz)
Maximum attenuation 11.5 dB/100 meters
Maximum length 100 meters
The 10baseT connection is a point to point connection to form a star-shaped network. The stations are connected to concentrators or switches.
Illustration:
TSX DM 57 xx
Reminder of pinouts:
6
7
4
5
8
2
3
Pin
1
Signal
TD+
TD-
RD+ not connected not connected
RDnot connected not connected
271
TSX ETY 110
Topology
This link is used to create a star-shaped network with connections in point to point.
The stations are connected to a concentrator (Hub). The concentrators can also be connected in cascade to increase network size.
Illustration:
Concentrator 1
Stations
Station 1 Station 2
Stations
Concentrator 2
272
TSX DM 57 xx
10.7
Display panel, diagnostics
Display panel, diagnostics
General
The display panel complies with the Premium standard
RUN
COL
RX
ERR
ADR
TX
TSX ETY 110
Diagnostics
Meaning of the diagnostics LEDs:
P
P
P
P
O
F
RUN ERR COL ADR TX
O P ns ns ns
F
F
O
O
O
O
O
O
O
O
O
O
O
O
O
F
O
O
O
O
F
F
F
O
RX
ns
O
O
O
F
F
O
Meaning
Module not operational.
Module not configured or configuration error.
Module running self-test.
Ethernet communication sending.
Ethernet communication receiving.
Ethernet communication in sending/receiving.
Module has detected collision.
P
O
O
O
O
O
P
P
O
O
O
O
Duplicate MAC address.
Network address beyond limits.
P = Permanently on, F = flashing, O = Off, ns = not significant
TSX DM 57 xx
273
TSX ETY 110
10.8
Electrical features
Electrical characteristics
General
Module TSX ETY 110 can be inserted in any rack slot of a Premium/Atrium station
(except in an X Bus offset rack). The module consumption from the supply depends on the selection made from the transceiver remote power supply option.
Table of consumption:
Voltage
5 volts with remote power supply
(RJ45) with remote power supply
(AUI)
Current consumed
Typical Maximum
Dissipated power
Typical Maximum
0.8 A 1.2 A 4 W 6 W
1.2 A 2.5 A 6 W 12.5 W
Note: Caution: Modules TSX ETY 110 on 5 volts have high consumption when the
AUI connection is used. Special attention should therefore be given what sort of devices are in the rack before deciding which kind of supply to choose.
l l
Number of TSX ETY 110 modules which can be connected to a rack:
2 modules with AUI connection.
4 modules with RJ45 connection.
274
TSX DM 57 xx
Communication: Modules
TSX ETY 4102/PORT/5102
11
At a Glance
Aim of this
Chapter
What's in this
Chapter?
This Chapter deals with the hardware installation of ETHERNET network modules
TSX ETY 4102/PORT and TSX ETY 5102 in a Premium/Atrium PLC.
This chapter contains the following sections:
Section
11.1
11.2
11.3
11.4
11.5
11.6
11.7
11.8
11.9
Topic
At a Glance
Description
Ethernet Channel Characteristics
Installation of TSX ETY 4102/PORT/5102 Modules
10/100baseT interface
Display, Diagnostics
Electrical Characteristics
Standards
Operating Conditions
Page
275
TSX DM 57 xx
TSX ETY 4102/PORT TSX ETY 5102
11.1
At a Glance
At a Glance
General
Communication modules TSX ETY 4102/PORT/5102 are used to communicate in l l l l an Ethernet architecture. They are made up of a communication channel whose main features are as follows:
Connection to a TCP/IP network.
Communication in Half and Full Duplex mode by automatic recognition.
Transmission speed from 10 or 100 Mbits/s by automatic recognition.
Connection to network by copper cable via an RJ45 connector.
These modules are used to carry out the following functions: l l l l l
X-WAY UNI-TE and Modbus messaging service on TCP/IP.
I/O Scanner Utility.
SNMP Service.
Web server.
Global Data.
276
TSX DM 57 xx
TSX ETY 4102/PORT TSX ETY 5102
11.2
Description
Description
General
TSX ETY 4102/PORT/5102 modules are standard format modules which are inserted in a slot on the main or extension rack of a Premium PLC station.
Description:
1. Display panel indicating module l l l status:
One green RUN LED.
Two red LEDs: ERR and COL.
Three yellow LEDs: STS, TX and
RX.
2. Standard connector for 10baseT
(RJ45) interface.
Illustration:
1
2
TSX DM 57 xx
277
TSX ETY 4102/PORT TSX ETY 5102
11.3
Ethernet Channel Characteristics
Characteristics of the Ethernet Channel
General
The modules have a standard interface for connecting to a 10/100baseT network and on the front panel there is a RJ45 connector for a pin-to-pin link via a link cable comprising two independent twisted pairs.
Utilities and functions supported by the modules:
Support
TCP-IP
Services
Utility
Messaging
Protocol
UNI-TE
Modbus
I/O Scanner Modbus
SNMP Network management
Web HTTP
Functions
l l l l l l
Client/server mode.
Synchronous requests of 256 bytes.
Asynchronous requests of 1 Kbyte.
Data exchange.
Access to inputs/outputs
Agent SNMP, MIB II, MIB Schneider.
l l
Preset, non-modifiable website on TSX ETY
4102/PORT.
Website which can be modified and increased by increments within the limit of 7.5Mb on TSX
ETY 5102.
l
Client and address server Management of IP addresses
BOOTP/
DHCP
Global Data.
UDP l
Exchange of data between stations
278
TSX DM 57 xx
11.4
TSX ETY 4102/PORT TSX ETY 5102
Installation of TSX ETY 4102/PORT/5102 Modules
At a Glance
Aim of this
Section
What's in this
Section?
This Section deals with the installation of TSX ETY 4102/PORT and TSX ETY 5102 modules in a PLC.
This section contains the following topics:
Topic
At a Glance
Selecting the Type of Processor
Wiring/Unwiring with Power Switched on
Page
TSX DM 57 xx
279
TSX ETY 4102/PORT TSX ETY 5102
At a Glance
General
TSX ETY 4102/PORT/5102 communication modules are mounted in the rack slot of a Premium/Atrium PLC station. They can be installed in any available slot (except in an offset X Bus rack), on condition that the supply constraints of the rack are observed (see
Electrical Characteristics, p. 287).
280
TSX DM 57 xx
TSX ETY 4102/PORT TSX ETY 5102
Selecting the Type of Processor
Selection Guide
Selecting the processor to control the PLC station will depend on the number of network connections required.
Processors Number of network connections
1
Number of ETY 4102/PORT/5102 per station (*)
1
TSX 57 P 1../2..
PCX 57 253
TSX P 57 3...
PCX 57 353
TSX P 57 4..
3 3
4 4
(*) on condition of a consumption report on the 5V, compatible with the supply selected.
Compatibility
Depending on the software version of the processor, all or some of the functions of the TSK-ETY 4102/PORT/5102 modules will be available. The table below gives the compatibility rules.
Software version of the processor
VL < 3.3
Supported functions
Does not accept the modules TSX
ETY4•••/5•••
-
Type to be configured in
PL7
3.3 £ VL < 5.1
TSX ETY 410 or 5101
VL 5.1
Functions limited to those of the
TSX ETY 410/5101 modules
Supports all the functions of the
TSX ETY 4102/PORT/5102 modules
TSX ETY 4102/PORT or
5102
TSX DM 57 xx
281
TSX ETY 4102/PORT TSX ETY 5102
Wiring/Unwiring with Power Switched on
The Module
The link
The TSX ETY 4102/PORT/5102 modules can be wired or unwired when switched on without disrupting the operation of the station.
The modules do not have an internal RAM backup memory function: this will be erased when power is switched off.
The modules reset when switched on. A communication break can be expected during these interventions.
The 10/100baseT interface RJ45 connector can be connected or disconnected when power is on. A communication break can therefore be expected in the application in progress.
282
TSX DM 57 xx
TSX ETY 4102/PORT TSX ETY 5102
11.5
10/100baseT interface
10/100base T Interface
General
This interface has a standard type RJ45 connector.
Refer to the ETHERNET reference manual for the connection accessories that comply with environmental circumstances the PLC requires in an industrial setting.
Pin Assignment
Illustration:
TSX DM 57 xx
Reminder of pin assignment:
6
7
4
5
8
2
3
Pin
1
Signal
TD+
TD-
RD+ not connected not connected
RDnot connected not connected
Note: If there is a connection via a shielded cable, the connector casing on the module is linked up to the ground connection.
283
TSX ETY 4102/PORT TSX ETY 5102
Speed Line
Speed
Adaptation
l l l
The choice of different speed lines for TSX ETY 4102/PORT/5102 modules are as follows:
100 Mb in Half Duplex
10 Mb in Half Duplex
10 Mb in Half Duplex
The speed line cannot be configured by the user. The process of self adaptation is as follows:
1
2
Each unit diffuses its possibilities on the line.
The chosen speed is the fastest of the entity possibilities on the line.
In other words, speed is limited by the slowest entity on the line of which the speed possibility is the weakest.
284
TSX DM 57 xx
TSX ETY 4102/PORT TSX ETY 5102
11.6
Display, Diagnostics
Display panel, Diagnostics
General
The display panel conforms to the Premium standard
RUN
STS
RX
ERR
ADR
TX
l l l
The COL, RX and TX LEDs are managed by the line’s electronics; they indicate:
COL: a collision.
RX: a reception
TX: a transmission.
Diagnostics
Meaning of the diagnostics LEDs:
RUN ERR STS COL TX
O
O
O
O
P
O
O
O
P
P
O
P
O
O
P ns ns ns ns ns ns ns ns ns ns
RX
ns ns ns ns ns
Meaning
No supply to module.
Module running self-test.
Module ready.
Module not operational.
Software operation error. Temporary state causing module reinitialization.
O
P
F
O
P, F ns
P ns ns ns ns ns
Module not configured or configuration in progress.
Module configured, operational.
ns ns F ns ns ns Module configured. Diagnostics according to how the LEDs are flashing: l l
2 flashes: module has no MAC address.
3 flashes: ETHERNET cable not connected on the module or Hub side l
4 flashes: the module IP address is duplicated by another IP address on the network. Conflicting remote device flashing in the same way.
l
5 flashes: module configured as a BOOTP client and is waiting for a BOOTP server response.
P = Permanently on, F = flashing, O = Off, ns = not significant
TSX DM 57 xx
285
TSX ETY 4102/PORT TSX ETY 5102
RUN ERR STS COL TX
P
P
O
O
P
P
O
O
F
O
RX
O
F
Meaning
ETHERNET communication sending.
ETHERNET communication receiving.
P
P
O
O
P
P
O
F
F
F
F
O
ETHERNET communication sending/receiving.
Module has detected collision.
P = Permanently on, F = flashing, O = Off, ns = not significant
286
TSX DM 57 xx
TSX ETY 4102/PORT TSX ETY 5102
11.7
Electrical Characteristics
Electrical Characteristics
General
TSX ETY 4102/PORT/5102 modules can be inserted in any rack slot of a Premium/
Atrium station (except in the X Bus offset rack).
Table of consumption:
Voltage
5 volts
TSX ETY 4102/PORT/5102
Power consumption
Typical Maximum
Power dissipation
Typical Maximum
360 mA 400 mA 1.8 W 2.1 W
TSX DM 57 xx
287
TSX ETY 4102/PORT TSX ETY 5102
11.8
Standards
Norms and Standards
Compliance with
Standards
The TSX ETY 4102/PORT and TSX ETY 5102 modules comply with the following l l l l standards:
UL 508
CSA
IEC 1121-2
Marine classification
288
TSX DM 57 xx
TSX ETY 4102/PORT TSX ETY 5102
11.9
Operating Conditions
Operating Conditions
Applicable
Conditions
l l l
Configuration software:
l l l
PL7 version < 4.1: recognizes TSX ETY 4102/5102 modules as TSX ETY
410/510
PL7 version
≥
4.1: recognizes TSX ETY 4102/5102 modules,
PL7 version
≥
4.3: recognizes processors including the TSX ETY PORT module.
l l
Conditions of use:
l l
Temperature from 0 to +60
°
C
Relative humidity of 10% to 95% (without condensation) to 60
°
C l
Altitude of between 0 and 4500 meters l
Immunity to vibrations complies with the IEC 68-2-6 standard, Fc test
Immunity to shocks complies with the IEC 68-2-27 standard, Ea test
Immunity to free fall, hardware dealt with as per the IEC 68-2-32 standard, l method 1
IP 20 protection index
Storage conditions:
l
Temperature from -40
°
C to +85
°
C l
Relative humidity between 0% and 95% (without condensation) at 60
°
C
TSX DM 57 xx
289
TSX ETY 4102/PORT TSX ETY 5102
290
TSX DM 57 xx
Communication: PCMCIA Modem card
VII
At a Glance
Aim of this Part
What's in this
Part?
This part deals with the TSX MDM 10 PCMCIA modem card.
This part contains the following chapters:
Chapter
12
Chapter Name
Installing the TSX MDM 10 module
Page
TSX DM 57 xx
291
PCMCIA Modem
292
TSX DM 57 xx
Installing the TSX MDM 10 module
12
At a Glance
Aim of this
Chapter
What's in this
Chapter?
This Chapter describes the hardware installation of the PCMCIA Modem card TSX
MDM 10.
This chapter contains the following sections:
Section
12.1
12.2
12.3
12.4
12.5
12.6
Topic
At a Glance
Description
Installation
Connecting adapters
Electrical characteristics
Technical specifications
Page
293
TSX DM 57 xx
TSX MDM 10
12.1
At a Glance
At a Glance
General
The TSX MDM 10 card is used to connect to the switched telephone network (STN) for accessing remote stations following UNI-TELWAY or character mode protocols.
This type of communication is available using the Modem PCMCIA card. It is installed only in the PCMCIA reception slot on a Premium processor version V
≥
3.3.
294
TSX DM 57 xx
12.2
Description
Description
General
The TSX MDM 10 is made up of the following elements:
TSX MDM 10
1. A PCMCIA Modem card
2. A cable for connecting to the dialed-up telephone network
3. An RJ 11 port for connecting to a telephone adapter (4) or directly to a telephone port.
4. A telephone adapter (in line with country of purchase) enabling a link to the telephone network.
TSX DM 57 xx
295
TSX MDM 10
12.3
Installation
At a Glance
Aim of this
Section
What's in this
Section?
This Section deals with installing a PCMCIA Modem card in a Premium PLCTSX
MDM 10.
This section contains the following topics:
Topic
Selecting the type of processor and slot
Wiring/Unwiring with power switched on
Connecting to the telephone network
Page
296
TSX DM 57 xx
TSX MDM 10
Selecting the type of processor and slot
General
The TSX MDM 10 card is to be installed onlyin the PCMCIA reception slot of the processor.
Illustration:
Reception slot for
Premium processor
Reception slot for
TSX SCY 21601
Reception slot for
Atrium processor
Note: Reminder: the TSX MDM 10 card is compatible with all Premium processors version V
≥
3.3.
Note: Reminder: Atrium processors and communication modules TSX SCY 21601 do not accept modem card TSX MDM 10.
TSX DM 57 xx
297
TSX MDM 10
Wiring/Unwiring with power switched on
Precautions
Inserting or removing the TSX MDM 10 communication card is forbidden when the reception module (processor) is switched on.
298
TSX DM 57 xx
Connecting to the telephone network
Procedure
Step
1
To connect the modem to the telephone network proceed as follows:
Action
Connect the RJ 11 port to the telephone adapter if necessary
Illustration
TSX MDM 10
2 Plug in the RJ 11 port or adapter of your telephone line.
If a device is already connected to this port, unplug it then plug in the telephone adapter instead.
Plug in the device to the port panel at the back of the adapter.
3
4
Insert the PCMCIA card in the processor slot provided for this purpose.
Caution: The processor must be switched off while inserting or removing the PCMCIA card
Screw the card into the processor to stop it shifting when power is on.
TSX DM 57 xx
299
TSX MDM 10
12.4
Connecting adapters
Different adapters
At a Glance
The telephone adapters, in line with the country of purchase, are used to ensure connection between an RJ 11 port of PCMCIA card TSX MDM 10 and the wall socket of the telephone network.
To use the TSX MDM 10 card in a different country all you need to do is change the telephone adapter.
List of adapter product references according to the country:
Country
Germany
Belgium
Spain
France
Italy
Product reference
TSX MDM EDT G
TSX MDM EDT B
TSX MDM EDT S
TSX MDM EDT F
TSX MDM EDT T
300
TSX DM 57 xx
12.5
Electrical characteristics
Electrical characteristics
Consumption
This table indicates the consumption of a PCMCIA modem card:
Voltage
5 volts
Typical current
195 mA
TSX MDM 10
TSX DM 57 xx
301
TSX MDM 10
12.6
Technical specifications
At a Glance
Aim of this
Section
What's in this
Section?
This Section deals with the technical specifications for the PCMCIA Modem card
TSX MDM 10.
This section contains the following topics:
Topic
Communication protocols
Operating characteristics
Maximum operating temperature
EC labeling
Page
302
TSX DM 57 xx
TSX MDM 10
Communication protocols
General
The TSX MDM 10 card supports the various ITU-T V.32 communication protocols.
TSX DM 57 xx
303
TSX MDM 10
Operating characteristics
At a Glance
The TSX MDM 10 card has the following characteristics: l l l l
Sends AT commands
Half and Full Duplex communication
Automatic calls and replies
Calls by pulses or tones
304
TSX DM 57 xx
Maximum operating temperature
Values
l l
Without ventilation module TSX FAN... : 50
°
C max.
With ventilation module TSX FAN... : 60
°
C max.
TSX MDM 10
TSX DM 57 xx
305
TSX MDM 10
EC labeling
General
Card TSX MDM 10 conforms to the European Telecommunications Directive DTTC
98/13/EC.
Guaranteed level of immunity to electromagnetic fields: 3 V/m.
Communication faults may appear beyond this threshold (in compliance with
Directive CEM 89/336/EEC, applicable in residential and business areas, and areas of light industry.)
Card TSX MDM 10 also complies with the Low Voltage Directive 73/23 EEC, updated by 93/68/EEC.
306
TSX DM 57 xx
Index
A
C
Characteristics
characteristics
Communication
Man-machine interface console, 22
Connection
connection
Connection to the TSX SCA 64 unit
TSX DM 57 xx
Connection to TSX SCA 64 unit
Consumption
consumption
I
Integrated FIPIO link
M
Mounting
P
pair transmission configuration and polarization
2 wires with polarization of M+, M- pair by the master station or a slave station, 250
4 wires with 2-pair polarization via
307
Index
4 wires with one pair polarization by the master station, the other by a slave station, 247
PCMCIA
physical description of TSX SCA 64 device,
T
Terminal port
Connector pin configuration, 45
Terminal Port Connections
Man-machine interface console, 29
TSX ETY 110
Connection by AUI interface, 268
Ethernet channel characteristics, 262
TSX ETY 4102/5102
TSX ETY 4102/PORT/5102
Ethernet channel characteristics, 278
TSX MDM 10
Telephone network connection, 299
308
TSX P ACC 01
Connecting to Premium/Atrium PLCs, 55
Connector pin configuration, 57
TSX SAY 100
TSX SAY 1000
TSX SCA 64
Cable Template, 240 cabling principles, 240
TSX SCA 64 connection device, 229
TSX SCY 11601
Built-in Channel Specifications, 154
TSX SCY 21601
Built-in Channel Specifications, 154
Host Channel Compatibility, 155
Uni-Telway bus Connection, 164
TSX DM 57 xx
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Table of contents
- 5 Table of Contents
- 13 About the Book
- 18 Introduction to the terminal port
- 25 Connections
- 43 Appendices
- 48 At a Glance
- 51 Hardware installation
- 58 Example of topologies
- 76 Review of the AS-i bus
- 86 Description of the TSX SAY 100 module
- 97 Input/output object addressing
- 98 AS-i Bus diagnostics
- 105 Operating modes of the TSX SAY 100 module
- 107 Precautions of use
- 114 Introduction to the AS-i Bus
- 121 Description of the TSX SAY 1000 Module
- 131 Input/Output Object Addressing
- 133 AS-i Bus Diagnostics
- 135 Operating Modes of the TSX SAY 1000 Module
- 137 Precautions of Use
- 140 AS-i V2 Certification
- 150 At a Glance
- 151 Description
- 154 Built-in Channel Specifications
- 155 TSX SCY 21601 module's host channel compatibility
- 156 Installation
- 158 Operation
- 159 Module Visual Diagnostics
- 161 Built-in Channel Connection
- 178 At a Glance
- 181 Description
- 183 Connecting the PCMCIA card reception channel
- 193 Connection:TSX SCP 111
- 196 Connection:TSX SCP 112
- 208 Connection:TSX SCP 114
- 216 Connection:TSX FPP 20
- 217 Connection:TSX FPP 10
- 218 Connection:TSX MBP 100
- 225 Summary of connection devices
- 227 Precautions when connecting PCMCIA cards
- 228 Consumption of PCMCIA cards
- 230 General Introduction
- 232 Physical Description
- 235 Dimensions and Mounting
- 237 Installation
- 238 Wiring the TSX SCP CM 4530
- 239 Bus Cable Shield Cabling
- 244 Device Configuration and Transmission Pair Polarization
- 253 Adapting the Line End
- 260 At a Glance
- 261 Description
- 262 Characteristics of the Ethernet channel
- 263 Installing the TSX ETY 110 module
- 268 Connection via the AUI interface
- 271 10baseT Interface
- 273 Display panel, diagnostics
- 274 Electrical features
- 276 At a Glance
- 277 Description
- 278 Ethernet Channel Characteristics
- 279 Installation of TSX ETY 4102/PORT/5102 Modules
- 283 10/100baseT interface
- 285 Display, Diagnostics
- 287 Electrical Characteristics
- 288 Standards
- 289 Operating Conditions
- 294 At a Glance
- 295 Description
- 296 Installation
- 300 Connecting adapters
- 301 Electrical characteristics
- 302 Technical specifications