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GE IS215VCMIH2CC Bus Master Controller Module Communication Converter Card

Functional Description

The IS215VCMIH2CC is a GE-developed bus master controller module that is part of the Mark VI control system.

It is part of the Mark VI control system.The VCMI bus master controller plays a key role in the system architecture as an integrated communications interface that coordinates the exchange of data and commands.

As the link between the master controller and the array of I/O boards, the VCMI ensures smooth and efficient communication channels and facilitates seamless integration of the various components.

In addition, VCMI’s importance is reflected in its connection to the wider system control network, known as the IONet, which plays a vital role in coordinating communications across the network infrastructure.

Features

A distinctive feature of the VCMI is that it acts exclusively as a VMEbus master within the control and input/output racks.

The VCMI is responsible for the VMEbus, a standardized computer bus structure, and oversees the coordination of data transfer and control signals within these racks.

The VCMI manages the assignment of unique identification (ID) to all boards in the rack and their associated terminal boards.

This ID management function ensures that the various components within the rack are identified and interacted with in a systematic and organized manner, thereby increasing the overall efficiency and reliability of the system.

The VCMI Bus Master Controller is a multifaceted communications hub that seamlessly www.abb-drive.com connects controllers, I/O boards and the broader system control network.

As a VME Bus Master Controller in a given rack, it enhances its ability to manage and optimize the flow of information, ultimately improving the performance and cohesiveness of the integrated system.

Board Type: 6U High VME Boards

The boards specified are classified as 6U High VME boards and are dimensioned to meet the widely adopted VME standard. At 6U high, the boards conform to a standard form factor and are compatible with a range of systems and platforms that meet the same specifications.

At 0.787 inches wide, this VME board integrates seamlessly into the VME chassis, contributing to the modularity and scalability of the overall system.

Processors

Texas Instruments TMS320C32 32-bit Digital Signal Processor: At the heart of this VME board is the highly capable Texas Instruments TMS320C32.

This processor is a 32-bit digital signal processor (DSP) known for its ability to handle complex mathematical calculations and signal processing tasks.

The TMS320C32 is a rugged, purpose-built processor ideally suited for applications requiring high-speed, efficient digital signal processing, and is therefore well suited to the intended function of this board.

Memory

Dual-port memory, 32-bit transfer configuration 32 Kbytes: The memory architecture of this VME board is designed for optimal performance and data processing.

The board is equipped with dual-ported memory, which facilitates simultaneous access to data from multiple sources, increasing overall efficiency.

The memory configuration includes 32 Kbytes of SRAM (Static Random Access Memory) in a 32-bit transfer setup.

This memory selection meets the requirements of data-intensive applications, ensuring fast access and retrieval of information.

SRAM, 64k x 32; Flash, 128k x 8: For further memory specifications, the boards are equipped with 64k x 32 SRAM, providing a large cache for storing and processing data in real time.

In addition, a 128k x 8 Flash memory further extends the board’s storage capacity, providing non-volatile memory for program storage and data retention.

This dual-memory configuration meets the diverse needs of the applications supported by the board, balancing speed and data persistence.

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SBS IP-Quadrature Quadrature Decoder IndustryPack Module

Product Description

IP-Quadrature provides high density, cost-effective flexible implementation of four quadrature decoder channels. Channels may also be used as general purpose counters. Four independent channels provide 24-bit resolution, programmable modes, programmable polarity, interrupt capability, differential or single-ended (RS-422 or TTL/CMOS) input, read-on-the-fly capability, and a count frequency of 0 to 10 MHz.

Quadrature encoders are popular sensors that provide accurate, low cost incremental motion sensing. Most commonly, they are shaft encoders that provide 512 to 2048 counts per revolution.

They are also commonly used as linear encoders with resolutions down to 0.005 inch. They are available in nearly any length desired. Most encoders are now optical, using molded assemblies consisting of a pair of LEDs, lenses, photo-sensors, and simple electronics. For rotary motion the assembly senses alternating opaque and clear lines on a rotating wheel. For linear motion the alternating lines may be on a fixed bar and the sensor assembly moves, or vice-versa. The pair of LED and photo-sensors are offset about one-half line width so that direction of motion may be sensed by observing the relative phase of the two outputs. Typical quadrature encoder outputs are a pair of digital logic signals that are nominally 90° out of phase. Some encoders also provide an

“index” pulse output once per revolution to provide absolute position information. Most modern encoders run from +5 volts and provide CMOS/TTL logic outputs and/or RS-422 differential logic outputs. RS-422 is recommended where possible because of its inherent noise immunity and the ability to run long distances. TTL logic levels should normally be restricted to cables less than ten feet in length. Quadrature encoders are available from Hewlett-Packard, US digital, and other sources.

The general purpose input structure permits differential input from line drivers (RS-422 levels) or www.abb-drive.com single-ended logic level input (“TTL”) directly from most sensors. Programmable TTL resistive terminators provide for flexible high-quality signal termination.

There are three inputs per channel. For normal quadrature operation the two quadrature inputs are called X and Y. These inputs are sometimes called A and B lines from encoders. The X and Y inputs are normally driven 90° out of phase. There is also a control input on each channel called Z.

Its function is programmable, but it typically operates, if used, as an index or latch input.

There is a programmable prescaler for each channel that may be set for X1, X2 or X4 operation.

Vectored interrupts are fully supported. Interrupts are individually maskable. Selectable conditions are interrupt on borrow and interrupt on match (compare).

RS-422 differential input lines are normally terminated with 120Ω resistors. Users may remove these socketed resistor networks or replace them with a different value if desired.

Each channel consists of a programmable input section, a 24-bit up/down counter block, a 24-bit capture/match register, and a 24-bit output latch. The output latch permits accurate “on-the-fly” reading of quadrature position values. The capture/match register may be used as either a hardware “capture” register to record exact mechanical position or to provide an interrupt any arbitrary programmable quadrature position value.

The all CMOS design is inherently low power. Up to 16 quadrature channels may be implemented in one host system slot.

Key Features

• Four quadrature decoder channels, independently programmable

• Any channel may also act as a general purpose counter

• 24-bit resolution per channel

• DC to 10 MHz general purpose count rates

• DC to 1.2 MHz quadrature count rates (higher count rate in X1 and X2 modes)

• Counters readable “on the fly”—24-bit output register

• 24-bit register for capture or match interrupt on each channel

• Inputs may be differential or single-ended

• Direct connection to most sensors

• Programmable TTL resistor termination

• Each channel has a programmable control input

• Control input may be used to capture exact position on the fly

• Each channel may be used as a general purpose up/down counter

• Full programmable interrupt support

• Programmable modes; programmable prescaler: 1X, 2X, 4X.

• Individually programmable polarities for Count and Control inputs

• All CMOS

• Up to 16 counter channels per VME slot

Main Features

High-precision decoding of orthogonal signals

Wide operating temperature range for industrial environments

Compact industrial package form factor

Easy integration with compatible systems

Applications

Motion control systems

Position sensing and feedback

Robotics and automation

Industrial machinery

GE IS215AEPAH1A Fan Control Card Printed Circuit Boards

The IS215AEPAH1A AEPA card module assembly is manufactured by GE Energy for use with the Mark VIe wind turbine control system family.

Product Description.

This IS215AEPAH1A printed circuit board was originally designed for General Electric’s Mark VIe series.

This Mark VIe series is a line of wind turbine system control and system control component products.

These products are actually manufactured by GE Energy, an alternative energy manufacturing company that exists as a shell company for retailers of the General Electric industrial giant.

This is a revised printed circuit board, modified from its original IS215AEPAH1 parent board by including a single-function revision rated “A”.

This GE Energy Mark VIe Wind Turbine Series PCB can be more accurately defined as an alternative energy power assembly by its functional description.

Hardware Tips and Specifications www.abb-drive.com

This IS215AEPAH1A Alternative Energy Power Assembly may be best understood when its hardware elements are contextualized according to the intended function of this printed circuit board.

The first descriptor for the function of this AEPA-abbreviated product is present in its functional description as an alternative energy power supply assembly.

This functional description happens to be an exact match to the AEPA functional acronym for this product, a rare blessing for a specialized Mark VIe series product.

The series to which this IS215AEPAH1A board belongs actually provides additional insight into the functionality of this product.

Considering the place of the IS215AEPAH1A PCB in the Mark VIe family of wind turbine control systems, it is not surprising that this GE Energy board is dedicated to wind turbine applications.

Now that the functional status of this IS215AEPAH1A PCB as an alternative energy power supply assembly has been described.

Then it is possible to highlight some of the hardware specifications available for this Mark VIe wind turbine series product.

Considering this product’s place in the specialized and recently developed Mark VIe wind turbine family, little original product-specific instruction manual material detailing the hardware of this IS215AEPAH1A PCB exists online.

That said, this initial Mark VIe series label identifies the board as an alternative energy power supply assembly with special component versions.

This IS215 series label has dual naming capabilities for this IS215AEPAH1A product; it also outlines its status as a domestic GE printed circuit board.

The original manufacturing location of this PCB can be traced more specifically to GE’s plant location in Salem, Virginia.

In this IS215AEPAH1A part number, the IS215 series label is followed by an example of the AEPA functional acronym.

It is itself followed by the H1 series grouping label, which, like the IS215 series label mentioned earlier, provides a dual naming convention for this product.

This H1 grouping label indicates that the product is a conformal coated printed circuit board with Mark VIe series grouping.

While the conformal style of PCB coating specific to this power supply assembly is well documented, given its widespread use on General Electric circuit boards, the first Mark VIe grouping of this part is the Mark VIe grouping.

The true meaning of the first set of Mark VIe series alignments for this component has been lost.

The last A digit of the IS215AEPAH1A part number is a reference to a Class A functional revision of this part, which may significantly affect the performance specifications and original measured dimensions of this IS215AEPAH1A product.

Eaton DPM-MC2 Communication Card

Aims and purposes of this document

The purpose of this document is to provide a reference for connecting, commissioning and operating the DPM-MC2 Communication Card.

Use of the card

The DPM-MC2 card can only be used in MICRO PANEL MC2 series devices equipped with the corresponding slot.

The DPM-MC2 card is a PROFIBUS master. The development is based on the EN50170 standard.

The card can only be mounted and dismounted when the device is powered off.

Function and control indicators

Connector assignment

The plug connectors and connector assignment comply with the www.abb-drive.com Profibus standard (EN50170). Only the transceiver signals and the power terminals for line termination are provided.

The power supply terminals DGND (0V, pin 5) and VP (+5V, pin 6) are only intended for powering the cable terminals (terminals) and must not be used for any other purpose. the CNTR-P signal (pin 4) is used in conjunction with a repeater.

Bus segments must be terminated at both ends.

No more than 2 bus terminals must be activated per bus segment!

At least one of the two bus terminals must be powered by the bus station!

Maintenance, repair, disposal

Maintenance

Repairs can only be carried out by the manufacturer or an authorized service center. In this case, please contact your local MICRO PANEL dealer or Micro Innovation’s technical support department.

The warranty does not apply if any modifications are made to the device that are not described in this document.

Shipping

The original packaging must be used when transporting the device.

Disposal

Memory cards that are no longer in use must be disposed of properly or returned to the manufacturer or seller for proper disposal.

Prosoft MVI69-PDPS PROFIBUS DP Slave Communication Module

PROFIBUS DP Slaves

Communication modules

MVI69-PDPS

The MVI69 PROFIBUS DP Slave Communication Module allows CompactLogix I/O

compatible processors to connect easily with PROFIBUS DP master devices.

Features and Benefits

The PROFIBUS DP Slave Protocol Driver supports the PROFIBUS V0 slave protocol, providing robust data transfer capabilities between the module and CompactLogix processors.

User-configurable data mapping and DP port operation make the interface an easy-to-use and powerful data transfer tool.

The MVI69 Module Configuration/Commissioning www.abb-drive.com Serial Port connects a PC to the module for configuration, status, monitoring, and troubleshooting (a serial cable is included with the product).

After editing on the PC, the configuration file is downloaded and stored on the MVI69 module.

PROFIBUS DP slaves can access the input and output images of the device with up to 244 bytes of input and output data and up to 400 bytes in total.

Users can map these input and output data blocks into the module’s data memory for maximum flexibility and data transfer with other protocols.

General Specifications

– Single slot – 1769 backplane compatible

– Module is treated as an input/output module with access to processor memory for data transfer between the processor and the module

– Ladder logic is used to transfer data between the module and the processor. A ladder example file is included.

– Obtains configuration data from a configuration text file downloaded to the module. Sample configuration file included.

– Supports CompactLogix and MicroLogix 1500 LRP controllers except 1769-L23E-QBFC1B, 1769-L16x, and 1769-L18x.

Functional Specifications

PROFIBUS slaves have access to the input and output images of the device with up to 122 words of input and output data and up to 200 words in total.

– All standard baud rates up to 12 Mbps are supported.

– Configuration data is stored in the non-volatile memory of the MVI69 module

– Supports extended diagnostic data (DPV0)

– Automatic baud rate detection at all valid PROFIBUS V0 baud rates

– Multiple modules in one rack

Other Products

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GE VMIVME-1150 64-bit Optically Coupled Digital Input Board

-64 optically coupled digital inputs

-5 V to 48 VDC input range

-High isolation, 1.000 V continuous, 7.500 V pulse voltage

-Filter input options

-Dual I/O connectors

-Contact closure sensing

-Voltage or current source input options

-Positive or negative true input options

-Dual Eurocard form factor with front panel

8-bit or 16-bit data transfer

-Unprivileged or supervisory I/O access

-Highly reliable DIN-compatible input connectors

Functional Features

Board Features:

This 64-bit optically coupled digital input board is designed and optimized for the VME bus.

The VMIVME-1150 is highly isolated and provides a flexible, low cost, high noise immunity 8-byte digital input port. The functional block diagram is shown below.

Compatibility:

The VMIVME-1150 is a standard double height printed circuit board that is electrically and mechanically compatible with the VME bus.

Input Organization:

Eight input ports, each eight bits wide. The ports are organized as eight consecutive 8-bit read-only registers.

Addressing Scheme:

Each 8-bit port is individually addressable anywhere within an 8-bit or 16-bit boundary.

Short-circuit monitoring or short-circuiting anywhere within unprivileged I/O space.

Board Address:

The board address is selected by the on-board DIP switches. Runs in any available slot on the VMEbus backplane except slot 1.

VMEbus Access:

The address modifier bits are decoded to support short supervised or unprivileged short I/O access. A jumper is www.abb-drive.com provided to support this option. The board is factory configured for short supervised I/O access.

VME Bus Reply:

The DTACK reply is a response to a data select (DS0 or DS1) and the decoded board address.

Board Address.

Data Transfer Type:

D8. D16

Access Time

Maximum 250 milliseconds

Data Polarity

Sorted by positive or negative true. This depends on the input assertion of the board. To assert an input, current must flow through the LED in the optocoupler.

For positive “true” boards, this current will indicate a logic “1” to the VME bus. If the board is ordered with negative true logic, the board will display a logic zero to the VMEbus when current is flowing through the LED.

Input Characteristics

Signal Conditioning:

The input can be either a voltage or current source with a voltage range of 5 to 48 V. The input can be either a voltage or current source with a voltage range of 5 to 48 V.

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GE VMIVME-1111 64-bit High Voltage Digital Input Board with Built-in Tests

Functions

– 64-bit differential or high voltage digital inputs

– Each group of 32 inputs can be monitored by jumper selection:

Contact closure, voltage source, current sink, or differential signal.

– Open provides logic zero or (jumper selectable) logic one.

– Input filter options

– On-board built-in test logic

– Front panel with fault LEDs

– Front panel with fault LEDs for fault detection and isolation

– User selectable input voltage thresholds (1.25 to 66V)

RS422/RS485-compatible differential line receiver provides ± 7V noise immunity

– 8-, 16-, or 32-bit data transmission

– Dual Eurocard form factor

– High-reliability DIN-type I/O connectors

– Compatible with GE Fanuc Embedded Systems’ family of intelligent I/O controllers (901x and 906x series)

– Boot Replacement Option

– Software compatible with VMIVME-1110

Functional Features

Compatibility: Compatible with VMEbus specification. Double height form factor.

Input Connector Type: Dual 64-pin connector – DIN 41612

Input/Output Organization Eight input ports; eight bits wide. Addressable to any address within the www.abb-drive.com short-circuit monitor and/or short-circuit unprivileged I/O map. Control and Status Register (CSR) addresses are independently selectable.

Addressing Scheme: Each of the eight ports can be addressed on 8-, 16-, or 32-bit boundaries. One CSR can be addressed on 8-bit boundaries. 13 jumpers provide unlimited short data I/O address mapping options.

Differential Signal Input Characteristics: Common Mode Input Voltage Range: -30 to +66 V. Common Mode Input Voltage Range: -7 to +12 V. Input Sensitivity ± 100 mV. High Input Impedance (33 kΩ).

Single-Ended Signal Input Characteristics: High input impedance (33kΩ). Threshold accuracy of 1% (typical) over the entire 66V range.

Signal Conditioning Input Filter Terminator Option: The board can be ordered with an input signal filter circuit.

For differential inputs, the circuit consists of a series resistor and capacitor connected across the signal input. For single-ended inputs, the circuit provides an input dither filter with a user-selectable time constant.

Built-in Test: The board is designed with internal self-test logic to test all active components.

Special output registers are provided to generate 16-bit data words for worst-case bit patterns to be used as health tests during real-time or off-line operation.

A special test mode bit in the CSR enables the output test register to drive a differential receiver.

The front panel fault LED illuminates at power-up and can be programmed to go out after successful completion of user-defined diagnostics.

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GE VMIVME-7740 VMEbus Single Board Computers

Intel® Pentium® III PGA370 socket-based Single Board Computers (SBCs) supporting Windows® 98 Second Edition,

Windows NT®/Windows® 2000. Windows CE, Linux, VxWorks, QNX, Solaris and LynxOS operating systems.

-Special features for embedded applications

-Up to 192 Mbyte IDE CompactFlash (optional)

Three programmable 16-bit timers

32 Kbyte non-volatile SRAM

-Supports remote Ethernet boot

-Software selectable watchdog timer with reset.

-Supports VMEbus P2 connection to hard disk/floppy drive.

-PMC Expansion Site with VMEbus P2 Inputs/Outputs

-VME64 mode support: A32/A24/D32/D16/D08(EO)/MBLT64/BLT32

-VMEbus interrupt handlers, interrupters, and system controllers

Includes byte-swapping hardware for little-end and big-end data.

-Enhanced bus error handling

-Passive heat sink design (no moving parts)

-Standard features include

-PGA370 socket processor

Up to 512 Mbyte SDRAM using a 144-pin SODIMM

-AGP SVGA controller with 4 Mbyte SDRAM

Two on-board Fast Ethernet controllers supporting 10BaseT and 100BaseTX interfaces

-Front panel Universal Serial Bus (USB) connection

-Onboard Ultra-DMA-33 hard disk drive and floppy drive controller with VMEbus P2 input/output

Two high-performance 16550-compatible serial ports

PS/2-style keyboard and mouse ports on front panel

Built-in real-time clock and micro-speaker

Microprocessor

– The VMIVME-7740 brings the Intel Pentium III processor to VMEbus.

The VMIVME-7740 introduces the Intel Pentium III processor to the VMEbus with processor www.abb-drive.com speeds up to 850 MHz. the Pentium III processor has 32-bit addressing and a 64-bit data bus.

Its superscalar architecture allows three instructions per clock cycle. Dynamic branch prediction units, separate instruction and data caches, and MMX™ technology also increase processor performance.

The Pentium III processor also offers a 256 Kbyte Advanced Transfer Cache (on-chip, full-speed L2 cache) with dual independent bus architecture for high bandwidth and performance.

This L2 cache is clocked at the same frequency as the processor, which improves performance.

Memory

– The VMIVME-7740 accepts a 144-pin SDRAM SODIMM with a maximum memory capacity of 512 Mbyte.

The maximum memory capacity is 512 Mbyte. on-board DRAM is dual-ported to the VME bus.

BIOS

– The system and video BIOS is provided by reprogrammable flash memory.

Super VGA Controller

– High Resolution

The VMIVME-7740 supports high-resolution graphics and multimedia-quality video through the Chips & Technology AGP graphics adapter.

The adapter is complemented by 4 Mbyte of internal high-bandwidth 64-bit data interface synchronous DRAM.

The graphics adapter supports screen resolutions up to 1.600 x 1.200 x 64.000 colors (single view mode).

Ethernet Controller – The VMIVME-7740 supports Ethernet LAN through dual Intel 82559 Ethernet controllers.

Supports 10BaseT and 100BaseTX options through two RJ45 connectors. Remote LAN booting is supported.

Remote Ethernet Booting – The VMIVME-7740 utilizes Lanworks Technologies, Inc. BootWare to provide the ability to remotely boot the VMIVME-7740 using NetWare, TCP/IP, or RPL network protocols.

BootWare Features:

– Support for NetWare, TCP/IP, RPL network protocols

– Unrivaled boot sector virus protection

– Detailed boot configuration screens

– Comprehensive diagnostic capabilities

– Option to disable local boot

– Dual boot option allows user to select either network or local boot

Serial Ports – The VMIVME-7740 has two 16550-compatible serial ports on the front panel. The serial channel has a 16-byte FIFO and supports baud rates up to 56 kilobytes per second.

56 kilobytes per second. Two micro-DB9 to standard DB-9 adapters (VMIC P/N 360-010050-001) are required.

Keyboard and Mouse Interface – The VMIVME-7740 is equipped with a PS/2 combo keyboard and mouse interface. A Y adapter cable is included.

Flash Memory – The VMIVME-7740 provides up to 192 Mbytes of IDE CompactFlash flash memory, accessible through the auxiliary IDE port.The VMIVME-7740 BIOS includes an option to allow the board to boot from flash memory.

16-Bit Timers – The VMIVME-7740 provides the user with three 82C54-compatible 16-bit timers (in addition to the system timer). These timers are mapped to I/O space and are fully programmable by software.

Watchdog Timer – The VMIVME-7740 provides a software programmable watchdog timer.

The watchdog timer is enabled under software control. Once the watchdog timer is enabled, the on-board software must access the timer within the specified timer period or a timeout will occur. A user jumper allows the timeout to cause a reset.

Independent of the jumper, software can enable a watchdog timeout to cause a non-maskable interrupt (NMI) or VMEbus SYSFAIL.

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FOXBORO 130M Series Pnuematic Controller

The 130M Series Pnuematic controllers offer manual setpoint adjustment and are the standard controller in the Foxboro® 130 Series.

All Foxboro® 130 Series controllers are designed for high-density control room installations.

These devices are ideally suited for applications where precise control is critical to skilled process management.

The 130M Series is essentially the same as the 130P and 130F Series with the exception of the following features:

130P Series: Has setpoints that are pneumatically modified by remote signals.

130F Series: Remote/local switching to support manual or pneumatic modification of setpoints.

Designed for high-density control room installations, these controllers are suitable for any situation where precise control is required for efficient process management.

The basic controller is the 130M series with manual setpoint adjustment. 130P series is similar to the 130M, but the setpoint can be adjusted pneumatically via a remote signal.

The 130F series is similar to the 130M but includes a remote/local switch for manual or pneumatic setpoint adjustment.

Large Eye-Catching Display

The visibility and legibility of the large, brightly colored pointer located directly behind the clear vertical scale has become the benchmark against which other display concepts are judged.

The system provides a continuous full-scale display of all variables, an effective indication of controller deviations, and easy scale changes without tools.

Separate automatic and manual control units

Both the automatic and manual control units www.abb-drive.com  can be disassembled without disrupting the process.

This design feature avoids costly downtime for servicing the controller.

Completely Unbalanced and Bufferless Transmission

The 130 Series controllers utilize the “integral balancing” method for bufferless transfer. After transfer, the controller simply responds at the integral (reset) rate that

This eliminates any error between setpoint and measurement. In addition to providing easy, unbalanced and unbuffered transmission, this solution preserves the setpoint.

Simple and cost-effective installation

Up to 10 instruments can be accommodated in a multi-unit rack. All air connections are made when the controller is installed in the rack.

Piping costs are minimized as each rack has its own integrated air supply header and individual air shutoff valve.

Easy Maintenance

The 130 Series utilizes a unique pneumatic circuit board that greatly enhances the sophistication of the pneumatic control system. This board eliminates many of the piping and connections found in other controllers.

All components are located on one side of the board and are easily accessible by sliding back the cover on one side.

Force Balance Control Module

The proven force balance control module ensures long service life and reliability. Due to the use of metal bellows, there is virtually no movement in the flexure suspension mechanism, thus providing the user with a clearly superior controller.

Specialized Controllers for Every Application

Foxboro offers the industry’s widest range of optional accessories and specialized control features. In addition to normal control modes, these include single-station ratios, single-station computer setups, auto selectors, differential gaps, and “batch” processing.

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Option FDPI-02 Diagnostic and Panel Interface for ABB converters and inverters

Product Overview

The FDPI-02 Diagnostic and Panel Interface is used to branch the RS-485 panel bus and chain a control panel or PC tool to multiple drives.

This interface device provides a straight-through connection between the control unit and the F-type option module.

It is compatible with the ZCU-xx and BCU-xx control units. The interface unit is installed in the option slot of the control unit.

A small F-type option module can then be mounted on top of the Interface Unit.

The Interface Unit has one RJ-11 and two RJ-45 connectors.The RJ-11 connector is used to connect to the Control Unit.

The RJ-45 connector supports a daisy-chained bus for connection to a PC or control panel (simultaneous control panel and PC communication is not allowed).

Bus termination is required to prevent signal reflection at the end of the bus cable. The interface unit has a panel/PC cable bus termination switch.

The termination switch must be in the terminated position www.abb-drive.com if the device is the first or last device on the bus.

If the control panel is connected to one end of the bus, it will terminate the bus, only the other end must be terminated via termination switch S1.

The following figure shows the layout of the interface unit.

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