YOKOGAWA TRAINING
Section 1. CS3000 System Overview
SECTION 1 CS3000 SYSTEM OVERVIEW
CONTENTS 1
CS3000 HARDWARE CONFIGURATION _______________________ __________________________ ___ 1-2 1.1
Operating Operating Environmen Environmentt of System System Generation Generation Function Function __________ _______________ _____ 1-2
1.2
HIS – Human Human Interface Interface Station __________ _______________ __________ __________ __________ __________ ______ _ 1-3
1.2.1 1.2.2
1.3
Hardware Operating Environment_____________ ___________________________ 1-3 V net Interface Card______________________________________ _____________ 1-4
Control Station Overview_________________________________________ 1-8
1.3.1 Configurat Configuration ion of PFCS _______________ ______________________ ______________ _______________ _______________ ___________ ____ 1-9 1.3.2 Configurat Configuration ion of Rack Mountable Mountable LFCS (CS3000) (CS3000) ______________ _____________________ ___________ ____ 1-10 1.3.3 Configurat Configuration ion of a Rack Mountable Mountable FFCS ______________ _____________________ ______________ ___________ ____ 1-11 1.3.4 Configura Configuration tion of Rack Mountabl Mountablee KFCS (CS3000) (CS3000) _______________ ______________________ ____________ _____ 1-12
1.4 1.4.1 1.4.2 1.4.3
1.5 1.5.1 1.5.2 1.5.3 1.5.4 1.5.5
1.6 1.6.1 1.6.2
LFCS - I/O CONFIGURATI CONFIGURATION ON __________ _______________ __________ __________ __________ _________ ____ 1-13 LFCS - The RIO Bus Networ Network k _______________ ______________________ _______________ _______________ ___________ ____ 1-13 LFCS/PFC LFCS/PFCS S - Types of I/O Module Module Nests Nests ______________ ______________________ _______________ __________ ___ 1-14 LFCS/PFCS - Combination of I/O Nests and I/O Modules Modules____________________ ____________________ 1-21
KFCS/FFCS KFCS/FFCS - I/O CONFIGU CONFIGURATI RATION ON __________ _______________ __________ __________ ________ ___ 1-23 KFCS - The FIO Bus Bus Network Network _______________ ______________________ ______________ _______________ ____________ ____ 1-23 FFCS – I/O Bus Bus Network Network ______________ _____________________ ______________ _______________ _______________ _________ __ 1-25 KFCS/FF KFCS/FFCS CS - Types of Nodes ______________ ______________________ ________________ _______________ ___________ ____ 1-26 KFCS/FFC KFCS/FFCS S – FIO Modules ______________ ______________________ _______________ ______________ ______________ _______ 1-27 FIO Module Connection Connection _______________ ______________________ _______________ _______________ _______________ _________ _ 1-29
Otherr Hardware Othe Hardware __________ _______________ __________ __________ __________ __________ __________ __________ _______ __ 1-30 Bus Converter Converter ______________ _____________________ _______________ _______________ _______________ _______________ __________ ___ 1-30 Optical Optical Bus Repeaters Repeaters _______________ ______________________ ______________ _______________ _______________ ___________ ____ 1-31
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Section 1. CS3000 System Overview
1 CS3000 HARDWARE CONFIGURATION 1.1 Operating Environment of System Generation Function The CS 3000 system consists of the HIS (Human Interface Station) that handles the operation and monitoring functions, the FCS (Field Control Station) that carries out the control function, and control bus (V net) that connects those stations. The system generation functions work in the HIS and general-purpose PC’s.
Vnet
Figure 1.1
Basic Configuration
- Speed: 10Mb/s - Type: Token Passing
Number of Stations per Domain = 64 Number of Domains = 16 (CS3000 only) HIS – 16 Maximum per Domain FCS – 48 Maximum per Domain BCV – 1,000 Tags per Second (approx.) (a pprox.)
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Section 1. CS3000 System Overview
1 CS3000 HARDWARE CONFIGURATION 1.1 Operating Environment of System Generation Function The CS 3000 system consists of the HIS (Human Interface Station) that handles the operation and monitoring functions, the FCS (Field Control Station) that carries out the control function, and control bus (V net) that connects those stations. The system generation functions work in the HIS and general-purpose PC’s.
Vnet
Figure 1.1
Basic Configuration
- Speed: 10Mb/s - Type: Token Passing
Number of Stations per Domain = 64 Number of Domains = 16 (CS3000 only) HIS – 16 Maximum per Domain FCS – 48 Maximum per Domain BCV – 1,000 Tags per Second (approx.) (a pprox.)
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Section 1. CS3000 System Overview
1.2 HIS – Human Interface Station 1.2.1 Hardware Operating Environment The CS3000 Operator Station and Engineering functions run on a standard PC under Windows 2000. 2000. The requirements for the PC are listed below. Main Memory, Hard Disk Capacity Main memory and hard disk size required for the PC depends on the installed packages as indicated in the table below. Table 1.2
Required Main Memory Size
Table 1.3
Required Hard Disk Size
Software Environment: Windows 2000, Service Pack 1 or 2
See Installation Manual, Section 3 for more details.
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Section 1. CS3000 System Overview
1.2.2 V net Interface Card V net interface card (VF701) is a communication card which is installed to a PC/ATcompatible personal computer. The VF701 has two ports in order to support dual communication. The operation and monitoring function by personal computer is feasible by installing a VF701 to the PCI slot of a personal computer with the PC software installed and by connecting a V net cable to the VF701.
1.2.2.1
Front panel of the V net interface card ♦
RCV lamp
This lamp illuminates when the communication carrier is received from the V net. It is turned off otherwise. ♦
SND lamp
This lamp illuminates when the data is transmitted to the V net and is turned off other-wise. ♦
BNC connector
VL net and VF701 is connected here. It is necessary to connect a T-connector to this BNC connector.
Figure 1.5
Front panel of the V net interface card
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1.2.2.2
Section 1. CS3000 System Overview
Setting the V net station address The station address of a V net is defined by a combination of a domain number and a station number. The DIP switches for setting the domain number and station number are located on the printed circuit board of the VF701. (Refer to the figure.)
Figure 1.6
Location of the DIP switches on the VF701
If necessary, change set the domain number and station number settings as follows:
Figure 1.7
DIP switches for setting the station address
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1.2.2.3
Section 1. CS3000 System Overview
Setting the domain number Set 1 to a single network system. Unless specified, the DIP switch is shipped with all the bits OFF. Domain is a range of stations connected by single V net. Set the domain number in the range of 1 to 16. Set the DIP switches as shown in the following table to set the necessary domain number. Bit 2 and 3 of the DIP switches are always 0.
Switch 8 7 6 5 4
Value 1 2 4 8 16
MSB: Most Significant Bit LSB: Least Significant Bit Figure 1.8
DIP switches for setting the domain number Table 1.3
Domain numbers and the switch positions
Setting of the DIP switch 0: The switch is flipped to the right in the diagram above. 1: The switch is flipped to the left in the diagram above.
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1.2.2.4
Section 1. CS3000 System Overview
Setting the station number Set the station number in the range of 1 to 64 (24 for CS1000). Set the DIP switches as shown in the following table to set the necessary station number. Switch 8 7 6 5 4 3 2
Value 1 2 4 8 16 32 64
MSB: Most Significant Bit LSB: Least Significant Bit Figure 1.9
DIP switches for setting the station number
Table 1.4
Station numbers and the switch positions
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Section 1. CS3000 System Overview
1.3 Control Station Overview The hardware commonly used as field control stations in CENTUM CS 1000 and CENTUM CS 3000 systems are the PFCS, LFCS and KFCS. • • • •
KFCS – Distributed Field Control Station with fast remote I/O (FIO) FFCS – Compact Field Control Station with FIO PFCS – Compact Field Control Station with local I/O. LFCS – Distributed Field Control Station with remote I/O (RIO)
These types are further divided into the following models:
♦
AFG30S/D rack mountable field control station, FIO (KFCS) AFG40S/D field control station with cabinet, FIO
♦
AFF50S/D compact field control station (using FIO modules)
♦ ♦
AFG7xS/D migration type field control station, RIO – V, XL I/O AFG8xS/D migration type field control station, FIO – V, XL I/O
♦
PFCS/D compact field control station, local I/O (using RIO modules)
♦
AFG10S/D rack mountable field control station, RIO (LFCS) AFG20S/D field control station with cabinet, RIO
♦
♦
(note: the AFS is similar to the AFG, but with the older style CPU) All these field control station models are generically referred to as FCSs.
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Section 1. CS3000 System Overview
1.3.1 Configuration of PFCS The figure below shows the maximum configuration of a PFCS with an expansion rack. The units composing a PFCS are listed in the table below the figure.
Figure 1.10
Table 1.5
Configuration of PFCS
Units Comprising PFCS
For more information, refer to Instruction Manual 33Q6C20-01E, Section A2.1
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Section 1. CS3000 System Overview
1.3.2 Configuration of Rack Mountable LFCS (CS3000) The figure below shows the configuration of a rack mountable duplexed LFCS. For a single CPU model, cards and units are installed in the right half of the nest. For the units and cards composing an LFCS, see the table in Section 1.3.5.
Figure 1.11
Processor
Configuration of Rack Mountable LFCS (CS3000)
- AFS – 25 MHz RISC processor - AFG – 133 MHz RISC processor
For more information, refer to Instruction Manual 33Q6C20-01E, Section A2.2
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Section 1. CS3000 System Overview
1.3.3 Configuration of a Rack Mountable FFCS The figure below shows a rack mountable duplexed compact FCS (FFCS). The I/O cards that are plugged into this unit are the same as for the KFCS described below.
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Section 1. CS3000 System Overview
1.3.4 Configuration of Rack Mountable KFCS (CS3000)
The figure below shows the configuration of a rack mountable duplexed KFCS. For a single CPU model, cards and units are installed in the right half of the nest. For the units and cards composing an KFCS, see the table in Section 1.3.5.
Figure 1.11
Processor
Configuration of Rack Mountable KFCS (CS3000)
- AFS – 25 MHz RISC processor - AFG – 133 MHz RISC processor
For more information, refer to Instruction Manual 33Q6C20-01E, Section A2.4
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Section 1. CS3000 System Overview
1.4 LFCS - I/O CONFIGURATION
1.4.1 LFCS - The RIO Bus Network The Remote I/O Bus is a twisted pair communications bus used for transferring I/O data between the nodes interface units (NIUs) and the FCS. This is required for the LFCS only, as the I/O is integral to the PFCS. Structure of the RIO bus network:
All I/O is installed in I/O Nests. These are installed in NIUs that communicate on the RIO bus to the FCS. The system capacity is as follows: NIUs: NESTS:
8 per FCS 5 per Node (see below for I/O limitations for each nest)
RIO Bus Specifications:
Type: end. Length: Speed:
Shielded Twisted Pair. Requested 750 Ohm terminator at each 750m. Can be extended with repeaters. 1 Mb/s
RIO Bus Function:
The RIO bus is controlled by the RB301 controller card in the FCS, and the RB401 controller card in each node interface unit. The RB301 card scans the bus every 18 msec, reading/writing 2 x 16 bit words from each nest of each node every scan. Note: 1 Analog I/O = 1 Word 1 Digital I/O = 1 Bit RIO Bus – 1 Mbps
Figure 1.4.1 – RIO Bus Network
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Section 1. CS3000 System Overview
1.4.2 LFCS/PFCS - Types of I/O Module Nests There are eight types of I/O module nests, as the table below shows. Table 1.8
I/O Module Nests
Models AMN11 AMN12 (*1) AMN21 AMN31 AMN32 AMN33 AMN34 AMN51 AMN52 AMN71(*2)
Model Names Nest for Analog I/O Modules High-Speed Nest for Analog I/O Modules Nest for Relay I/O Modules Nest for Terminal I/O Modules Nest for Connector I/O Modules Nest for Communication I/O Modules Nest for Multipoint Control Analog I/O Modules Nest for Communication I/O Cards Nest for PROFIBUS Communication Modules Nest for Ethernet Communications Module
*1: Only applies to CS3000 LFCS *2: Only applies to CS3000 PFCS
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1.4.2.1
Section 1. CS3000 System Overview
Model AMN11 Nest for Analog I/O Modules The analog I/O module nest is a dedicated receptacle for multiple analog I/O modules. One analog I/O module nest can accommodate up to 16 I/O modules.
Figure 1.23
External View of Analog I/O Module Nest
Table List of I/O Modules Installable in Analog I/O Module Nest Types
Analog I/O modules
Models AAM10 AAM11 AAM21 APM11 AAM50 AAM51
Names Current/voltage input module (Simplified type) Current/voltage input module mV, thermocouple, RTS input module Pulse input module Current output module Current/voltage output module
Wiring Details for Analog I/O Modules:
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Section 1. CS3000 System Overview
Model AMN21 Nest for Relay I/O Modules Relay I/O modules are installed in relay I/O module nests. Either one of the relay input module Model ADM15R or the relay output module Model ADM55R can be installed in this nest.
Figure 1.24
External View of Relay I/O Module Nest
Table List of I/O Modules Installable in Relay I/O Module Nest Types
Models
Names
Relay input module Relay output module
ADM15R ADM55R
Relay input module Relay output module
Wiring diagram for Relay Inputs:
Wiring diagram for Relay Outputs
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1.4.2.3
Section 1. CS3000 System Overview
Model AMN31 Nest for Terminal I/O Modules Multiplexer modules and digital I/O modules (terminal type) can be installed in the terminal I/O module nest. Up to two I/O modules can be installed in the nest. A combination of multiplexer modules and digita l I/O modules, however, cannot be installed in the same nest.
Figure 1.25
External View of Terminal I/O Module Nest
Table List of I/O Modules Installable in Terminal I/O Module Nest Types Multiplexer module
Digital I/O module
Models
Names
AMM12T AMM22M AMM22T AMM22TJ AMM32T AMM32TJ AMM42T AMM52T ADM11T ADM12T ADM51T ADM52T
Voltage input multiplexer module mV input multiplexer module Thermocouple input multiplexer module Thermocouple input multiplexer module RTD input multiplexer module RTD input multiplexer module 2-wire transmitter input multiplexer module Current output multiplexer module Contact input module (16-point, terminal type) Contact input module (32-point, terminal type) Contact output module (16-point, terminal type) Contact output module (32-point, terminal type)
See IM 33Y6K01-01E, Section 4.2.3
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Section 1. CS3000 System Overview
Model AMN32 Nest for Connector I/O Modules Voltage Multiplexer (connector type) and Digital I/O modules (connector type) can be installed in the connector I/O module nest. Up to 4 I/O modules can be installed in one nest.
Figure 1.26
External View of Connector I/O Module Nest
Table List of I/O Modules Installable in Connector I/O Module Nest Types Digital I/O module
Multiplexer module
Models
Names
ADM11C ADM12C ADM51C ADM52C AMM12C AMM22C AMM25C AMM32C AMM32CJ
Contact input module (16-point, connector type) Contact input module (32-point, connector type) Contact output module (16-point, connector type) Contact output module (32-point, connector type) Voltage input Multiplexer module mV input Multiplexer module Thermocouple input Multiplexer module RTD input Multiplexer module RTD input Multiplexer module
Wiring for 16 Point Digital I/O Wiring for 32 Point Digital I / O
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Section 1. CS3000 System Overview
Model AMN33 Nest for Communication Modules Communication modules are installed in the communication module nest. Up to two modules can be installed in one nest.
Figure 1.27 External View of Communication Module Nest Table List of I/O Modules Installable in Communication Module Nest Type
Model
Name
Communication module
ACM11 ACM12 ACF11
RS-232C Communication module RS-422/RS-485 Communication module Fieldbus Communication Module
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Section 1. CS3000 System Overview
Model AMN34 Nest for Multipoint Control Analog I/O Modules
Multipoint control analog I/O modules are installed in the nest for multipoint control analog I/O modules. Up to two modules can be installed in one nest.
Figure 1.28
External View of Nest for Multipoint Control Analog I/O Module
Table List of I/O Modules Installable in Multipoint Control Analog I/O Module Ne st
Type
Model
Name
Multipoint control analog I/O Module
Multipoint control analog I/O Module
AMC80
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Section 1. CS3000 System Overview
1.4.3 LFCS/PFCS - Combination of I/O Nests and I/O Modules The different types of I/O modules may be installed in different I/O module nests. The varies combinations are possible. The allowed combinations are listed in the following table. Table 1.9 List of Combinations and Max. No. Installable of I/O Module Nests and I/O Modules (1)
*1: The multiplexer module and the digital I/O module cannot be installed in the same I/O module nest. *2: PFCS/SFCS These modules can be installed in Slot 1 or 3 only. Other IOMs cannot be installed in Slot 2 0r 4. These modules and AMM12C can be installed in the same AMN32 Nest for Connector I/O Modules. *3: PFCS/SFCS This module can be combined with AMM12T, AMM22M or AMM22T in the same AMN32. Up to two AMM12C modules can be installed. *4: PFCS/SFCS This module can be installed in the PFCS or SFCS Field Control Station.
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Table 1.10 List of Combinations and Max. No. Installable of I/O Module Nests and I/O Modules (2)
*1: The multiplexer module and the digital I/O module cannot be installed in the same I/O module nest. *5: LFCS Only 1 module (Slot 1) can be installed when the operation mode of Model ADM52T is in time proportioning ON/OFF (see table below). *6: LFCS Installation restrictions during operation mode are as shown in the table below (no modules can be installed in Slots marked with N/A) Only 2 modules can be installed in Slots 1 and 3 when the operation mode of ADM51C is in time proportioning ON/OFF. However, when installing one module, a general connector type ADM can be installed in Slots 3 and 4. Only 2 modules can be installed in Slots 1 and 3 when the operation mode of ADM52C is in pulse width output. However, when installing one module, a general connector type ADM can be installed in Slots 3 and 4. Only 1 slot can be installed when the operation mode of ADM52C is in time proportioning ON/OFF. *7: PFCS/SFCS May be installed in PFCS/SFCS. *8: PFCS/SFCS May be installed in PFCS/SFCS. Model ACF11 and model ACM11 or ACM12 cannot be installed in the same AMN33 Nest for Communication Modules. Model ACM11 and ACM12 can be installed in the same AMN33.
Table Restrictions on Installation for Different Operation Mode
For detailed information regarding I/O modules, refer to Instruction Manual 33Y6K01-01E Section 3 & 4.
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Section 1. CS3000 System Overview
1.5 KFCS/FFCS - I/O CONFIGURATION
1.5.1 KFCS - The FIO Bus Network The Fast I/O Bus comprises the ESB local bus and the ER remote bus and is a high speed communications bus used for transferring I/O data between the node interface units (Nodes) and the FCS.
Structure of the FIO bus network:
All I/O is installed in I/O Nests. These are installed in Nodes that communicate on the ESB bus to the FCS. The system capacity is as follows: Nodes: Slots:
10 per FCS 8 per Node (see below for I/O limitations for each nest)
ESB Bus Specifications:
Type: Length: Speed:
Parallel bus connection with internal terminators 10m, non-extendable. 125 Mb/s
ER Bus Specifications:
Type: Length: Speed:
Co-ax, ethernet 128m (thin co-ax)/500m (thick co-ax), extendable with fibreoptic repeaters. 10 Mb/s
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FIO Bus Configuration
The ESB is a high speed parallel local bus on which the Nodes reside. The ER bus is a co-ax ethernet bus for long distance communications, and is connected to the ESB via an ethernet card in a Node. The total of 10 Nodes applies to all Nodes connected to the ESB and ER busses.
Figure 1.5.1 – FIO Bus Network
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1.5.2 FFCS – I/O Bus Network The FFCS is expandable to 3 extra nodes which can be connected using the ESB bus or the remote ER bus. The specifications for these busses are the same as for the KFCS bus. The following schematic shows how they can be configured:
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1.5.3 KFCS/FFCS - Types of Nodes There are two types of nodes, local and remote. The only difference between them is the bus card that is plugged into them.
Figure 1.5.2 – Node Layout
Figure 1.5.3 – Physical Hardware Schematic
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1.5.4 KFCS/FFCS – FIO Modules
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For more information, refer to Instruction Manual 33Y06K01-01E, Section B2
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1.5.5 FIO Module Connection
Figure 1.5.4 – Analog Module Connection Blocks
Figure 1.5.5 – Digital Module Connection Blocks
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Section 1. CS3000 System Overview
1.6 Other Hardware 1.6.1 Bus Converter A Bus Converter allows a connection between two control buses, for example, two V Net buses or V Net to RL Bus (uXL). It manages the flow of data between them be means of a taglist resident within the bus converter. On a plant, the V Net may be separated into 2 or more domain for several reasons: 1. The number of tags or stations in the system exceeds the capacity of the DCS, requiring that it be split between several domains. 2. Isolation between separate areas of plant is required. 3. Two areas of identical plant with identical tagnames can be separated. The bus converter provides a connection between two domains, and allows tag data to be transferred between the two systems in a managed way. Thus data in one domain can be monitored by a HIS in another domain.
Figure 1.29 – Bus Converter Configuration Specifications: Dual redundancy:
Capacity:
Processors Power Supplies V Net Connections 1000 Tags per second (approx.)
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