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ABB REX610 Protection and control functions

Digital relays are based on the use of microprocessors. The first digital relay was released in 1985.

One of the major differences between traditional electromechanical relays and static relays is the way the relays are wired.

Electromechanical and static relays have fixed wiring and are set to manual.

Digital relays, on the other hand, are programmable www.abb-drive.com relays whose characteristics and behavior can be programmed. Most digital relays are also multifunctional.

Scope

Modern Protection Relays

Multi-function protection

Product Advantages

Provide continuity of power to consumers

Protecting network assets

Prevent life-threatening electrical accidents

Product Features

Self-checking facility

Low load relays for improved accuracy

Fast fiber optic communication with substation LAN

Adaptive relay program

Allows storage of historical data

Time Stamping

Security in Distribution Automation

General Security in Distribution Automation

Technological advances and breakthroughs have led to a significant evolution of the power grid. As a result, the emerging “Smart Grid” and “Internet of Things” are rapidly becoming a reality. At the heart of these intelligent advances are specialized IT systems – a variety of control and automation solutions, such as distribution automation systems.

solutions, such as distribution automation systems. Automation systems are becoming increasingly interconnected in order to provide comprehensive real-time information to end-users and to achieve higher reliability and greater control. To address the increased risks associated with these interconnections, ABB offers a wide range of cybersecurity products and solutions for automation systems and critical infrastructure.

The new generation of automation systems utilizes open standards such as IEC 61850 and commercially available technologies, in particular communication protocols based on Ethernet and TCP/IP. They can also be connected to external networks, such as office intranet systems and the Internet. These changes in technology, including the adoption of open IT standards, have brought significant benefits from an operational standpoint, but they have also created cybersecurity issues previously known only to office or corporate IT systems.

To address cybersecurity risks, open IT standards are equipped with cybersecurity mechanisms. These mechanisms have been developed in a large number of enterprise applications and are proven technologies. They enable the design, development and continuous improvement of cybersecurity solutions for control systems, including distribution automation applications.

ABB recognizes the importance of cybersecurity and its role in improving the safety of power distribution networks. Customers investing in new ABB technologies can rely on system solutions that prioritize reliability and safety.

At ABB, we are meeting cybersecurity requirements at the system level and at the product level to support cybersecurity standards or recommendations from organizations such as NERC CIP, IEC 62351. IEC 62443. IEEE 1686. ENISA, and BDEW white papers.

System Hardening Ground Rules

Today’s distribution automation systems are essentially specialized IT systems.

Therefore, several of the rules for hardening automation systems apply to these systems as well. From an automation system perspective, protection and control relays are at the bottom of the hierarchy, closest to the actual main processes. It is important to apply the “defense-in-depth” information security concept, whereby each layer in the system is capable of protecting the automation system, and therefore the protection and control relays are part of this concept. The following points should be considered when planning system protection.

– Recognize and familiarize yourself with all parts of the system and the system’s communication links

– Remove all unnecessary communication links from the system

– Rate the safety level of the remaining connections and improve them using applicable methods

– Harden the system by removing or deactivating all unused processes, communication ports, and services

– Check that all applicable parts of the entire system are backed up

– Collect and store backups of system components and keep them up to date

– Remove all unnecessary user accounts

– Define password policies

– Change default passwords and use strong passwords

– Check that strong encryption and authentication is used for links from the substation to higher-level systems

– Separate public (untrusted) from automated (trusted) networks

– Isolate traffic and networks

– Use firewalls and demilitarized zones

– Evaluate systems regularly

– Use malware protection in workstations and keep it up to date It is important to utilize defense-in-depth concepts when designing automated system security. Connecting devices directly to the Internet is not recommended without adequate additional security components. Security controls should be used for the different layers and interfaces in the system. In addition to product features, strong security means enabling and using available features and enforcing their use according to company policy. Proper training of personnel accessing and using the system is also required.

ABB REB611 Busbar Protection Relay

DESCRIPTION

The REB611 is a specialized busbar protective relay for split-phase short-circuit protection, control and monitoring of single busbars.

The REB611 is suitable for high impedance based applications in utility substations and industrial power systems.

In addition, the relay can be used in restricted earth fault and residual earth fault applications to protect generators, motors, transformers and reactors.

The 611 series relays fully support the IEC 61850 standard for communication and interoperability of substation automation equipment.

This includes fast GOOSE (Generic Object Oriented Substation Event) messaging, and can now also benefit from the extended interoperability offered by version 2 of the standard.

The relays further support the Parallel Redundancy Protocol (PRP) and the High Availability Seamless Redundancy Protocol (HSR).

The 611 series relays can use both IEC 61850 and Modbus® communication protocols.

The REB611 is a member of the ABB Relion® product family and part of the 611 protection and control product family.

The 611 series relays are characterized by a compact and withdrawable unit design.

The 611 series offers simplified yet powerful functionality for most applications. After entering the application-specific parameter set, the installed relay is ready for operation.

The IEC 61850 standard further increases communication capabilities and interoperability between substation automation equipment, adding flexibility and value for end users and electrical system manufacturers.

The REB611 is a specialized busbar protective relay designed for split-phase short-circuit protection, control and monitoring of single busbars.

The REB611 is used for high impedance based applications in utility substations and industrial power systems.

In addition, this protective relay can be used in restricted earth fault and residual earth fault applications to protect generators, motors, transformers and reactors.The REB611 is available in one standard configuration.

The REB611 is a member of the ABB Relion product family and is part of its 611 protection and control series of relays. The REB611 is a member of the ABB Relion product family.

Range

Busbar and ideal multi-purpose back-up protection relays

Product Benefits

Pre-configured features for busbar protection applications

Relays are delivered pre-configured and factory tested to reduce engineering and commissioning time

Self-healing communication based on HSR/PRP using an optional second Ethernet bus

Compact design makes it suitable for both new and retrofit installations

Pull-out plug-in design for quick installation and testing

Product Features

Bus and ideal multi-purpose backup protection

Powerful and user-friendly web browser-based human machine interface (HMI), including input/output (I/O) matrix with visualization options

Application-specific standard configurations reduce relay setup and commissioning time

Supports IEC 61850 version 1 and 2. including binary GOOSE messages

Pre-configured solutions for utility distribution and industrial applications

ABB REV615 Capacitor bank protection and control relay

Compact and versatile solution for utility and industrial distribution systems

The REV615 is a specialized capacitor bank protection and control relay for the protection, control, measurement and monitoring of capacitor banks used for reactive power compensation in utility and industrial distribution systems.

Compact multifunctional solution for utility and industrial distribution systems, integrating protection, control, monitoring and supervision in one relay.

Provides a wide range of protection and control functions for H-bridge, dual Y-connected and single Y-connected capacitor banks and feeder cables as well as harmonic filter circuits.

The REV615 is a member of the ABB Relion product family and is part of its 615 Protection and Control Series of relays.

Scope

Protection of capacitor banks and harmonic filter circuits

Product advantages

Off-the-shelf standard configuration for quick and easy setup with customized features

Pull-out plug-in design for quick installation and testing

Large graphic display for customizable SLDs, accessible locally or via an easy-to-use web browser-based HMI

Extensive lifecycle services

Product Features

Capacitor bank overload and unbalance protection, non-directional overcurrent and directional ground fault protection, voltage and frequency based protection and measurement functions

Current-based unbalance protection, compensation for natural unbalance, and current-based capacitor bank switching resonance protection

Optional arc protection and high-speed output

Supports IEC 61850 version 1 and 2. including HSR and PRP,www.abb-drive.com  GOOSE messaging, and IEC 61850-9-2 LE to minimize wiring and supervised communications

IEEE 1588 V2 for high-precision time synchronization and maximum benefits of Ethernet communications at the substation level

Supports Modbus, DNP3 and IEC 60870-5-103 communication protocols

Applications

The REV615 is designed for primary protection of H-bridge, double Y-type and single Y-type connected capacitor banks and feeder cables.

In addition, the REV615 can be used to protect harmonic filter circuits when the harmonic component is not higher than the 11th.

The REV615 is available in two standard configurations, both of which provide three-phase overload protection, current-based unbalance protection (natural unbalance compensation), and current-based capacitor bank switching resonance protection.

The overload protection includes an integrated undercurrent function that detects the disconnection of the capacitor bank and inhibits the closing of the circuit breaker when the capacitor bank is partially charged.

Three-phase thermal overload protection is available for reactors and resistors in harmonic filter circuits.

The REV615 also provides non-directional overcurrent and ground fault protection for capacitor banks and their feeder cables.

Standard configuration B also provides directional ground fault, residual voltage, voltage unbalance, and over- and under-voltage protection.

Standard configuration A is pre-configured for H-bridge connected capacitor banks with three-phase unbalance protection.

Standard configuration B is pre-configured for capacitor banks with double Y-bridge connection and has single current unbalance protection.

The standard configurations can be customized to meet the requirements of the application with the IEC 61850-compliant protection and control IED manager PCM600.

ABB REJ603 Self-Powered Feeder Protector

The REJ603 relay is used for selective short-circuit and earth-fault protection of feeders in secondary distribution networks, as well as for transformer protection in utilities and industry.

The relay is a self-powered digital relay that does not require an external auxiliary supply voltage, making it ideal even for installations in remote areas where auxiliary power is not available.

The relay operates from a current transformer.

The REJ603 is mainly used in Ring Main Units (RMUs) in distribution networks.

The relay provides earth current measurement by internal calculation, or it can measure earth current from an external core balanced current transformer (CBCT).

The main features of the relay are

Self-powered three-phase non-directional overcurrent and earth fault protection with DMT and IDMT characteristics

Dual earth fault measurement modes – internal vector summing or external CBCT inputs

Integration of IDMT curves (IEC and special) in a single product to meet the time-coordinated www.abb-drive.com requirements of secondary distribution protection

Protection blocking via second harmonic measurement to ensure stability during transformer magnetic surges

Capacitive discharge pulse output for low-energy trip coils

Built-in manual reset electromechanical sign for trip indication

Easy setup via DIP switches, protected by transparent cover

Compact design and mounting for ring main unit (RMU) applications

Test equipment for testing the entire program, including primary CTs, relays and trip coils

Operating instructions

The combined overcurrent and earth fault relay is a secondary relay that is connected to the current transformer of the protected object.

In addition to the measurements (inputs), the relay receives from the current transformer the energy required for its own operation and for tripping the circuit breakers.

There are two LEDs on the front panel. The green “Ready” indicator lights up when the minimum current required for operation is available, indicating that the relay is operating.

When a fault is detected, the relay will trip the circuit breaker according to the setting.

The relay will also perform periodic internal health checks and notify the user of any faults within the relay.

Internal relay faults are indicated by the red LED “IRF” indicator.

The overcurrent device will operate when the phase current exceeds the set run time for timed operation or the calculated run time for inverse time limit operation.

Operation. Similarly, the high level I>> of the overcurrent device will actuate when the set operation time has expired.

The ground fault unit operates when the ground fault current exceeds the set operation time for timed operation or the calculated operation time for inverse time limit operation.

Similarly, the high level I0>> of the ground-fault unit operates when the set operation time expires.

The low-level rectification stage of the overcurrent unit and the low-level rectification stage of the ground-fault unit can have a deterministic time or inverse deterministic minimum time (IDMT) characteristic.

When the IDMT characteristic is selected, four standard time/current curves and three special time/current curves are available.

The standard curves conform to BS142 and IEC 60255 and are referred to as normal inverse time, extreme inverse time, extreme inverse time and long time inverse time.

In addition, three special curves are available, namely the RI curve, the HR fuse curve and the FR fuse curve.

GE AT868 Panametrics Liquid Flow Ultrasonic Transmitter

Applications

The AquaTrans AT868 Liquid Flow Transmitter is a complete ultrasonic flow metering system for measuring the following liquids:

– Drinking water

– Wastewater

– Sewage

– Discharge water

– Treated water

– Cooling and heating water

– Other liquids

Features

– Economical, non-intrusive flow measurement

– Simple setup and installation

– Suitable for a wide range of pipe sizes and materials

– Suitable for lined pipes

– Dual channel/dual path versions available

– Velocity, volume and totalized flow

– Built-in keypad for field programming

Liquid Flow Ultrasonic Transmitter

The AquaTrans AT868 Liquid Flow Ultrasonic Transmitter combines state-of-the-art flow measurement capabilities with a low-cost transmitter package that can be mounted directly at the process measurement point.

It can be installed directly at the process measurement point. It is designed for water and wastewater applications in full pipelines.

The all-digital AquaTrans AT868 has no moving parts and requires minimal maintenance.

The on-board microprocessor utilizes patented Correlation Transit-Time™ technology for long-term drift-free operation. Automatically adjusts to changing fluid characteristics and dynamically configurable operating software simplifies programming.

Transit-Time Flow

Measurement Technology

Transit-Time technology uses a pair of transducers, each of www.abb-drive.com which sends and receives a coded ultrasonic signal through the fluid.

As the fluid flows, the signal transmission time in the downstream direction is shorter than in the upstream direction; the difference in transmission time is proportional to the flow rate.

The AquaTrans AT868 measures this time difference and uses programmed pipe parameters to determine flow rate and direction.

Wet or clamp-on sensors

Ultrasonic flow sensors are classified as wetted or non-wetted (clamp-on). Clamp-on sensors are clamped to the outside of the pipe and do not come into contact with the process fluid.

Wetted sensors are mounted inside the pipe or flow meter and come into direct contact with the process fluid.

Clamp-on sensors offer the greatest convenience and flexibility, as well as low installation costs, compared to traditional flow metering technologies.

When properly installed, wetted sensors provide the highest accuracy (better than 1% of reading) in most applications.

Dual Channel Models

An optional second channel measures flow in two pipes or the average of two paths on the same pipe for improved accuracy.

AT868

Specification

Operation and Performance

Fluid Types

Acoustically conductive fluids, including most clean fluids and many fluids with entrained solids or bubbles. Maximum void fraction depends on transducer, interrogation carrier frequency, path length, and duct configuration.

Pipe Size

– Clamp-on transducers: 0.5 to 300 inches (12.7 mm to 7.6 m) and larger

– Wetted sensors: 1“ to 200” (25.4 mm to 5 m) and larger

Pipe wall thickness

3 inches (76.2 mm) maximum

Pipe Materials

All metals and most plastics. Consult GE for concrete, composite, highly corrosive, or lined pipe.

Flow Accuracy (Flow Rate)

0.5% of reading (achievable through process calibration)

Typical clamp-on flow accuracy (velocity)

– Pipe ID > 6 inches (150 mm): ±1% to 2% of reading

– Pipe ID <6 inches (150 mm): ±2% to 5% of reading

Typical wetted flow accuracy (velocity) ±1% of reading

Accuracy depends on pipe size and installation, and whether the measurement is single or dual path

Emerson PR6423 Eddy-Current Displacement Sensor

The PR 6423 is a non-contact eddy current sensor of rugged construction.

Designed for extremely critical turbomachinery applications such as steam, gas, compressor and hydraulic turbomachinery, blowers and fans.

The purpose of the displacement probe is to measure www.abb-drive.com position or shaft motion without contacting the surface under test (rotor).

In sleeve bearing machines, there is a thin film of oil between the shaft and the bearing material.

The oil acts as a damper so that shaft vibrations and position are not transmitted through the bearing to the bearing housing.

The use of bearing box vibration sensors to monitor sleeve bearing machines is discouraged because vibration from shaft motion or position is greatly attenuated through the bearing oil film.

The ideal method of monitoring shaft position and motion is to measure shaft motion and position directly through the bearing or by installing a non-contact eddy current sensor inside the bearing.

The PR 6423 is commonly used to measure vibration in the following equipment

eccentricity, thrust (axial displacement), differential expansion, valve position and air gap.

Non-contact measurement of static and dynamic shaft displacements

– Axial and radial shaft displacement (position)

– Shaft eccentricity

– Shaft vibration (motion)

Meets international standards DIN 45670. ISO 10817-1 and API 670

Rated for use in explosive areas, Eex ib IIC T6/T4

Other displacement transducer options include PR 6422. PR 6423. PR 6424. and PR 6425

Choice of transducers such as CON 011/91. 021/91. 041/91 and cable systems for complete transducers

GE Mark VI Series IS415UCVGH1AE VME Controller Card

Specification

Part Number: IS415UCVGH1AE

Manufacturer: General Electric

Country of manufacture: United States (USA)

Microprocessor: Intel Ultra Low Voltage Celeron 650 MHz

SDRAM: 128 MB

Compact Flash Module: 128 MB

Advanced Transfer Cache: 256 KB

Operating System: QNX

Expansion Site: PMC Expansion

Technology: Surface Mount

Temperature: -30 to 65oC

Product Type: VME Controller Card

Availability: In stock

Series: Mark VI

Functional Description

The IS415UCVGH1AE is a VME controller card developed by GE. It is part of the Mark VI control system.

This motherboard is a high-performance, single-slot computing module designed for robust and efficient operation.

It is powered by Intel’s ultra-low voltage Celeron processors running at 650 MHz, ensuring reliable www.abb-drive.com performance while maintaining low power consumption.

Equipped with 128 MB of Flash memory and 128 MB of Synchronous Dynamic Random Access Memory (SDRAM), the board provides ample storage space and fast data access for seamless task execution.

Features

For network connectivity, the UCVG features two 10BaseT/100BaseTX-compliant Ethernet ports, each utilizing an RJ-45 connector. These Ethernet ports support a variety of communication functions.

The primary Ethernet port on the UCVG is designed for integration with the Universal Data Center (UDH), facilitating configuration tasks and peer-to-peer communications.

This ensures that the UCVG can be easily managed and can communicate efficiently with other devices or systems in the network, making it a suitable choice for a variety of applications that require stable and fast data transmission.

Status LED Indicators

B (Boot): This red LED indicates that the BIOS boot process is currently in progress.

When this LED is on, it indicates that the system is initializing and loading the Basic Input/Output System (BIOS) firmware required for the hardware to communicate with the operating system.

I (IDE Activity): This yellow LED illuminates to indicate that IDE activity is taking place.

This means that the board is actively reading or writing to an IDE storage device, such as a hard disk drive or solid state drive, indicating that a data transfer operation is in progress.

P (Power): The green LED indicates that power is present and the board is receiving the power it needs to operate.

When this LED is on, it confirms that the board is properly powered and ready to operate.

R (Board Reset): This red LED illuminates to indicate that the board is in the reset state.

It indicates that the system is being manually or automatically reset, signaling the restart process that will reinitialize the board’s hardware and software components.

COM Ports

COM1: This port is primarily used for diagnostic purposes, providing the necessary connections for troubleshooting and system monitoring tasks.

It operates at a baud rate of 9600 using an 8 data bits, no parity and 1 stop bit configuration.

With this setup, COM1 serves as a reliable interface for accessing diagnostic information and performing system checks.

COM2: The second COM port is designated for serial Modbus communication, enabling seamless interaction with Modbus-compatible devices or systems.

It supports flexible baud rate configurations, allowing communication at 9600 or 19200 baud rates, depending on the specific requirements of the Modbus network.

This port facilitates efficient data exchange and control in Modbus-based industrial automation or process control environments.

GE Mark VI Series IS215VCMIH2B VMEbus Master Controller

Specification

Part Number: IS215VCMIH2B

Manufacturer: General Electric

Country of manufacture: USA

Product Type: VMEbus Master Controller

Series: Mark VI

Availability: In stock

The IS215VCMIH2B is a VME communications interface card manufactured by www.abb-drive.com General Electric as part of the Mark VI family for gas turbine control systems.

The VME Bus Master Controller (VCMI) board serves as the communications interface between the controller and I/O boards, as well as with the IONet system control network.

The VCMI also acts as the VMEbus master controller in the control and I/O racks, managing the IDs of all boards in the rack and their associated terminal blocks.

Through the J301 backplane connector, the VCMI card receives analog and digital feedback on power status.

There are two versions of the VCMI board: VCMIH1 and VCMIH2.The board has four port connections on the front panel.

The board has four port connections on the front panel, including three IONet connectors and one serial port. There are three LEDs above each IONet connector.

“TX”, ‘RX’ and ‘CD’ are the labels on them. The panel also contains four LEDs labeled 1. 2. 4. and 8. as well as LED indications labeled Run/Fail/Status (located above the pushbutton reset switch).

The panel attaches to the motherboard using screws.

Features of the IS215VCMIH2B

Board Type: 6U high VME board, 0.787 inches wide

Processor: The TMS320C32 is a 32-bit digital signal processor from Texas Instruments (TI).

Memory

32 KB dual-port memory in 32-bit transfer configuration

256k x 32 SRAM

512k x 8-VCMIH B; 4096K x 8-VCMIH C Flash memory

Communication

H1 version – 10 Mb/s, 1 IONet 10Base2 Ethernet port, BNC connector

H2 version – 3 IONet 10Base2 Ethernet ports, BNC connectors, 10 Mbits/sec

VME Bus Block Transmission: 1 RS-232C serial port with D-plug connector and 9600 baud rate (only)

Frame rate (FR): TMR 20 ms, 80 ms depending on application, simplex 10 ms (100 Hz) TMR 40 ms (25 Hz)

Diagnostics: Monitoring and alarming of the internal power bus for +5 V, 12 V, 15 V and 28 V. The internal power bus can be set to 5.5% of 28 V.

Alarm settings are customizable except for the 28 V power supply, which is set to 5.5% and is typically set to 3.5%.

The accompanying diagrams show three simplex system setups using VCMIs with local and remote I/Os. Each I/O rack has its own VCMI board and many of the I/O racks can be connected to an IONet.

A second IONet port on the VCMI can be used as a parallel IONet to increase data throughput for applications requiring low latency, as shown in the lower half of the accompanying figure.

GE Mark VI Series IS200TRPLH1A Primary Trip Terminal Block

Specification

Part Number: IS200TRPLH1A

Manufacturer: General Electric

Product Type: Primary Trip Terminal Block

Series: Mark VI

Part of the Mark VI GE Speedtronic series, the GE Mark VI IS200TRPLH1A is used as a primary trip terminal board.

General Electric’s IS200TRPLH1A board assembly is used in the company’s Mark VI system for conditioning industrial gas and steam turbine systems.

The Mark VI was one of the last Speedtronic systems developed and released by General Electric.

This board is typically found only on steam turbines. It is compatible with the Mark VI and Mark VIe systems.

It is the terminal card for the primary stroke on large steam turbines. It is the primary overspeed protection on large steam turbine systems.

The board is controlled by the Turbine Protection Controller card, which is usually a VTUR or PTUR board.

It also works in conjunction with the TREL board to provide an emergency/primary interface to the ETD.

The TRPL board feeds the negative side of the 125 VDC to the trip solenoid, while the TREL board provides the positive side. Up to three trip solenoids can be connected to these boards.

The boards have two large terminal blocks with a total of 48 connector points.

Also included are MOV diodes, resistors, transistors, integrated circuits, jumpers, and nine magnetic relays, as well as 3D housing connectors and other plug connectors.

Three voting circuits are connected via relays to three trip solenoids.

The trip circuits include solenoid suppression and voltage www.abb-drive.com monitoring, and the solenoids vote using two-thirds contacts.

What is the purpose of the IS200TRPLH1A?

The IS200TRPLH1A is a termination card for the primary trip on larger steam turbines. On larger steam turbines it is the primary overspeed protection.

How many connector pins does the IS200TRPLH1A have?

There are 48 connector points on the board.

GE Mark VI Series IS215UCVEH2AF VME Boards

Specification

Part Number: IS215UCVEH2AF

Manufacturer: General Electric

Country of manufacture: United States (USA)

Number of Channels: 6

Temperature: -30 to 65oC

Dimensions: 8.6cm wide X 16.2cm high

Product Type: VME Board

Availability: In stock

Series: Mark VI

Functional Description

The IS215UCVEH2AF is a VME board developed by GE. It is part of the Mark VI control system. www.abb-drive.com This single-slot VME (Versa Module Eurocard) board plays a vital role in the operation of the control system. The system utilizes a 300 MHz Intel Celeron microprocessor with 32 MB of DRAM memory. It offers flexibility between 16 MB or 128 MB compact flash modules. In addition, the system includes a 128 KB L2 cache for faster data access. To support the controller functions, an 8K battery-powered SRAM is allocated for use as the NVRAM in the system architecture.

Primary Ethernet Interface (Ethernet 1)

The primary Ethernet interface (Ethernet 1) on this system has the following specifications:

Connection type: Twisted pair 10BaseT/100BaseTX technology and RJ-45 connectors allow for a variety of connection options.

Communication protocol: TCP/IP protocol: Primarily used for communication between the controller and the toolbox, ensuring seamless data exchange within the system.

EGD Protocol: Designed to communicate with CIMPLICITY HMIs and 90-70 series PLCs (Programmable Logic Controllers), facilitating efficient and reliable data transfer.

Ethernet Modbus Protocol: Supports communication between the controller and third-party DCS (Distributed Control System), providing compatibility and integration across different systems.

COM ports

The system contains two miniature 9-pin D connectors dedicated to COM ports:

COM1: Function: Dedicated for diagnostic purposes, maintains a baud rate of 9600 with data configuration set to 8 data bits, no parity and 1 stop bit.

COM2: Purpose: Dedicated for serial Modbus communication, supports variable baud rates of 9600 or 19200. This port facilitates efficient and reliable communication of Modbus related data transactions.

Board Configuration and Connections

Interface Ports: The controller is equipped with two serial RS-232C ports and one Ethernet port. It also includes connectors for external peripherals such as keyboards, mice, and monitors.

On-Board Components: The board contains a high-speed processor, flash memory, and DRAM to efficiently handle processing tasks and store important system data.

Data Acquisition: External data is directed to the IS215UCVEH2AAE via the VCMI communication board. the type of data transfer may vary, using either process I/O (simplex) or polling I/O (TMR) depending on system configuration.

Variants: Multiple versions of the UCV VME controller card exist. the UCVE board model specializes in one to three PROFIBUS-DP masters and focuses on communication applications based on the ISO/OSI model Layer 1 and Layer 2.

Replacement program:

Precaution: Before replacing a UCVE controller. be sure to power down the rack and disconnect all cables connected to the front of the controller. This ensures safety and prevents potential damage during replacement.

Installing a New Controller: Replace the old controller with a new one, ensuring proper fit and connections within the system.

Flash File System: Download the Flash file system to the new controller using a Compact Flash programmer. The TCP/IP address of the controller must be configured before reinitializing the power supply to ensure seamless functionality.

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