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Motorola MVME333-2 Controller Communication Module

Features:

6 serial I/O ports

Supports synchronous and asynchronous communication

128 Kb of dynamic RAM

High-speed bi-directional DMA on two channels

The Motorola MVME333S-2 is a VMEbus intelligent communications controller with six serial I/O www.ge-drive.com ports that can be configured for synchronous or asynchronous and RS-232C or RS-422 electrical protocols.

On-board intelligence includes the MC68010 10 MHz CPU with two slots for firmware and 128 Kb of dynamic RAM for data buffering.

It has firmware for asynchronous protocols on all six channels (up to 9600 baud in both directions on all channels simultaneously).

In addition, there is a high-speed bi-directional DMA for synchronous protocols up to 1 Mb/s on two channels.

MVME330

Provides a high-performance 10 Mbps Ethernet interface with MC68000MPU, MK68590LANCE Ethernet controller, AM7991 Seria!1/0 adapter, and on-board EPROM with power-on self-test routines and kernel software for data rates up to 200 1 Kbytepackets/sec.

MVME331

VMEbus intelligent communications controller with six serial l/0 ports configurable as synchronous or asynchronous, and RS232C or RS-422 electrical protocols. The module also comes with firmware to implement synchronous protocols on all six channels (all channels simultaneously in both directions up to 9600 baud).

MVME332

8-channel intelligent serial communication controller for synchronous and asynchronous communication (RS232C). The module contains the MC68010 and 128K bytes of dynamic RAM, expandable to 512K.

MVME333

Same as the MVME331. but with the addition of high-speed bi-directional DMA on two channels for high-speed (up to 1Mb/sec) synchronous protocols, i.e., X.25 packet-switched networks.

MVME340

The VMEbus Parallel I/O module provides 64 parallel I/O lines: three 24-bit timers; three interrupters; one 32-bit and one 16-bit data channel, or any combination of 16-bit and 8-bit data channels; and 4GB, 16Mb, or 64Kb address ranges.

MVME350

Intelligent Streaming Media Tape Controller Module, M68010 processor-based, 128KB on-board RAM, QlC-02 interface: firmware installed.

MVME390

Color Graphics Controller Module, 1K x 1K Dual-Port Display Memory, Eight Colors in 4096 Palette (3 pIanes), TTL RS170/RS343A: RGB Output, 50/60 Hz Screen Refresh Non-Interlaced.

MVME700

Transition and Mass Storage

l/O transition module, double-height 80 mm Eurocard format, wrap-around board.

MVME701

l/O Transition Module Dual height 80 mm Eurocard, DlN to DB25 and 50-PiN dual row headers provide connectors for the MVME050 serial and parallel ports; and a battery backup (user-installed) for the MVME050 Daytime Clock.

MVME702

Provides Winchester cable termination logic. Provides Winchester cable termination logic.

MVME7O5

I/O conversion module doubleie-high80m:nEurocard format or six-channel serial transceiver module, each channel can be independently configured to RS-2320 or RS-422 standards, with on-board sockets provided for plugging in RS-232C or RS-422 driver and receiver devices which are supplied with the module to provide free space for the user.

MVME706

Same as MVME705 but all channels are now RS-232C compliant.

MVME707

MVME130 RS-232C Power Distribution Board with RS.232C serial l/0 cable assembly. Designed to interface with the MVME130/131.

ABB CM-TCS Temperature Monitoring Relay

The temperature monitoring relay CM-TCS monitors over-temperature, under-temperature or temperature between two thresholds (window monitoring) via a PT100 sensor.

As soon as the temperature falls below or exceeds the threshold, the output relay changes position according to the configured function and the LED display on the front shows the current status.

All devices are available in two different terminal versions. You can choose between the proven screw connection technology (dual-chamber cage connection terminals) or the completely tool-free easy connection technology (push-in terminals).

Features

Configurable over-temperature monitoring, under-temperature monitoring, www.ge-drive.com temperature window monitoring, etc.

All configurations and adjustments via front-operated elements

Precise adjustment via direct reading scale

One or two thresholds

Hysteresis 2-20 % adjustable

Operating temperature range -40… +60°C

Open or closed circuit principle configurable

Short-circuit monitoring and wire break detection

Screw connection technology or simple connection technology possible

Housing material according to the highest fire protection class UL 94 W-0

DlN rail mounting and dismounting without tools

1 x2 co or 2×1 c/o (SPDT configurable)

22.5 mm (0.89 in) wide

3 LEDs to indicate operating status

Various certifications and approvals (see overview, document no. 2CDC112251D0201)

Function

Measuring principle

The measuring principle is based on the voltage drop across the PT100 sensor, which is approximately proportional to the change in resistance. The temperature monitoring relay converts the resistance value to the corresponding threshold value.

Mode of operation

The sensors to be monitored are connected to terminals T1. T2 and T3 according to the wiring diagrams for 2-wire and 3-wire sensors.

Depending on the setting, the device operates according to the open-circuit principle h – Measured values fall below or exceed the thresholds Measured values fall below or exceed the thresholds:

Relay energized or closed-circuit principle g – Measured value below or above threshold: relay de-energized. Relay energized.

All operating states are indicated by the LEDs on the front.

ABB CM-IWx Insulation Monitoring Relay

Reliable insulation monitoring of IT systems

CM-IWx insulation monitoring relays ensure continuous insulation monitoring of IT systems to minimize equipment downtime.

ABB’s CM-IWx insulation monitoring relays for IT systems provide continuous, reliable monitoring.

These devices recognize an insulation fault as it develops and trip once the value falls below a minimum set threshold.

This makes the system more reliable and prevents interruptions caused by severe secondary insulation faults.

Make your monitoring safer and your maintenance smarter with the www.ge-drive.com CM-IWx insulation monitoring relay.

Continuous operation

Reduce downtime with early warning

More time for planned maintenance

Early fault detection by monitoring voltage-free networks

Railroad and marine approved models available

Safety and Protection

Safe and reliable insulation fault detection

Compliance with the latest standards

Solutions for standard and challenging applications

Fast and reliable earth fault detection supports fire protection

Self-diagnostics and wire break detection

Easy to install

Clear indication of device status via LEDs

Easily adjusted using a rotating wheel

Push-in terminals

Features

System voltage monitoring up to 1500 V DC and 1100 V AC

System leakage capacitance monitoring up to 3000 μF

Versatile system monitoring for 2-wire, 3-wire, 4-wire and battery systems

Easily configurable wire break detection

Easily configurable non-volatile fault storage

Isolated systems are often used when an extremely reliable power supply must be guaranteed, such as in emergency lighting systems.

Since the energy released in the event of an earth fault is not sufficient to trigger a circuit breaker or a residual current circuit breaker, different protective devices must be used in the earthbound system.

Insulation monitors continuously determine the insulation resistance to earth and signal if a threshold value is exceeded.

Insulation monitoring relays are the only technical solution for detecting earth faults in unearthed systems.

ABB CM-TCN Intelligent Temperature Monitoring Relay

Device Overview

The CM-TCN Smart Temperature Monitoring Relay is designed to meet different customer needs with one device.

Its LCD display provides intuitive status updates, and through Near Field Communication (NFC) you can adjust settings simply from your smartphone, making installation quicker and more intuitive.

With a measuring range of -200…+850 °C, the device is compatible with a wide range of sensor types and offers storage for predefined and user-defined configurations for common motor or transformer monitoring applications.

Wireless configuration and status checking is possible using ABB’s EPiC application.

Using the app, parameters can be quickly set and stored in the app or copied to other www.ge-drive.com CM-TCN devices, even in the absence of power.

In addition, parameters can be uploaded to the cloud or shared via email within seconds.

Temperature monitoring relays are typically used in the following applications:

Motor and system protection

Control cabinet internal temperature monitoring

Motor monitoring

Transformer monitoring

Ambient temperature monitoring

Process variable temperature limits

Bearing temperature monitoring

Coolant Temperature Monitoring

Packaging Industry

Air conditioning systems

Ventilation systems

Heat pumps

Hot water supply

LCD display and symbol-based menu structure

Unit with LCD display.

Display:

– Ensures intuitive and quick setup with the help of a symbol-based menu structure. Configuration files for various applications are also available. Each parameter can also be modified individually and stored as a user profile for future re-use.

– Permanent display of the device status and all currently measured temperatures. Detailed diagnostic information helps to quickly identify problems.

-Provides a wide range of operating parameter calculations, helping to reduce maintenance costs.

Uses symbols rather than text throughout the menu structure.

Near Field Communication (NFC)

Each device in the Smart Monitoring Relay series has a built-in NFC antenna, which makes it possible to use the

ABB’s EPiC mobile smartphone app allows the device to be parameterized via NFC.

To read or write data, the smartphone needs to touch the surface of the CM-TCN. The connection is only active when data is being transferred. In contrast to Bluetooth, there is no continuous communication between NFC and the device.

ABB EPiC Smartphone App

EpiC, or “Electrification Product Intuitive Configurator”, is a mobile application that allows configuration and checking the status of ABB low voltage products. The app is free and can be downloaded on Android and iOS. Registration is required to use it.

Device description

LED status indication

Motorola 3496B01A MVME712M/M P2 Adapter Board

Features:

4 25-pin multi-protocol EIA-232-D serial ports

The MVME712M is an I/O converter module for Motorola MPU VME Modules, VME Processor Modules, Embedded Controllers, and Single Board Computer (SBC) series processor modules.

The MVME712M is compatible with the MVME147. MVME1600. MVME162. MVME2600. MVME167. MVME2700. MVME177. MVME3600. MVME4600.

The MVME712M is used as an interface between the processor module and its peripherals. The purpose of this module is to provide rear panel industry standard connectors to simplify external customer cable requirements.

The P2 adapter assembly routes I/O signals and ground from the P2 connector on the chassis backplane (at the VMEmodule MPU connection) to the MVME712M.

The MVME712M routes signals to four serial ports that have four industry-standard DB-25 connectors on the front panel.

The serial ports can be configured as EIA-232-D DTE or DCE via a www.ge-drive.com patch cable arrangement on the MVME 712M.

The MVME712M also has an Ethernet port, a SCSI port, and a printer port on the front panel.

In addition, the MVME712M routes EIA-232-D Port 2 signals to the internal modem.

The MVME712M requires the use of the P2 adapter board, which is not included.

The features of the P2 adapter board include:

-Connectors that allow SCSI cables to be connected to other SCSI devices and/or to the MVME712M via a flat ribbon cable.

-SCSI termination resistors mounted in sockets for cable ends or in the middle of the cable configuration.

-Terminator power developed from +5 Vdc on connector P2 on P2 adapter, and fuses (2 A) on P1 adapter

-Connects EIA-232-D port, printer port, SCSI and Ethernet signals to MVME712M connectors

Motorola PPMC750-1141 Processor PCI Mezzanine Card

PPMC750-2xxx Description

The PPMC750-2xxx is an extended form factor version of the PPMC750 Processor PCI Mezzanine Card (PPMC) board (see the Processor PMC Standard for VITA-32-199x Processor PCI Mezzanine Cards for more information).

The PPMC750-2xxx is 1.5 times wider than normal at 111 mm. It is based on the PowerPC MPC750 processor and the Hawk PCI host bridge/system memory controller.

Standard features of the PPMC750 include 1MB of L2 cache, an on-board bank of SDRAM (32MB to 128MB), 8MB of FLASH, and optional SDRAM memory expansion.

In addition to the standard features of the PPMC750. the PPMC750-2xxx features 1MB of socketed FLASH, a 10/100TX Ethernet channel, a 190-pin Mictor debug connector, and a serial port debug connector.

Four 64-pin PMC connectors on the PPMC750-2xxx are used to connect the PPMC750-2xxx to the motherboard.

A 10-pin right-angle connector located on the side of the motherboard provides the interface to the asynchronous serial port. A 16-pin header provides the interface to the processor’s JTAG/COP port.

A 190-pin Mictor connector on the secondary side of the board provides debug www.ge-drive.com access to the processor bus.

The serial port and JTAG/COP interfaces and ABORT_L signals are also routed to the PMC P14 connector for access to the carrier board.

The PPMC750-2xxx includes a 140-pin AMP connector mounted on the auxiliary side of the board to provide sockets for memory expansion functions.

The presence of this connector increases the height measurement of the components on both sides beyond the standard PMC height.

Monarch and Non-Monarch PPMC

The traditional concepts of host/master and slave/target processors changed with the creation of the PPMC because the arbiter or clock source traditionally located on the host board was not on the PPMC7502xxx.

The VITA 32 specification defines the terms Monarch and Nonmonarch to refer to the two modes of PPMC operation.

Monarch PPMC is defined as the master PCI bus PPMC (or CPU) that performs PCI bus enumeration at power-up or reset and acts as a PCI interrupt handler.

A non-Monarch type is a slave/target processor that does not perform bus enumeration and does not handle PCI interrupts, but may issue PCI interrupts to the host processor.

A system may have a Monarch PPMC750-2xxx and/or one or more non-Monarch PPMC750-2xxx, resulting in a loosely coupled multiprocessing system.

A PPMC750-2xxx operating as a Monarch system may be connected to a carrier board with slave processors, PCI and other I/O devices.

The PPMC750-2xxx operating as a non-monarch system can be mounted on a carrier board with a master processor and other PCI devices such as MVME2400 or MCPN750 boards.

PPMC750-2xxx boards running in non-monarch mode may require a different version of PPCBUG or other operating system than PPMC750-2xxx boards running in monarch mode.

The PPMC750-2xxx software is configured for Monarch or Non-Monarch mode by reading the status of the MONARCH# pin on the PPMC750-2xxx.

This pin is grounded or open on the carrier board to enable the desired mode of operation. Refer to the MONARCH# signal description on page 3-14 of this manual for details.

Carrier Board Requirements The carrier board must provide standard PCI interfaces including 3.3V and 5V power, PCI address/control, PCI clock, and PCI arbiter REQ/GNT pairs.

Refer to the VITA-32-199x specification. The carrier board must also have the MONARCH# pin grounded to enable Monarch operation mode.

Turning the MONARCH# pin on will enable non-Monarch mode.

System Enclosure

System enclosure requirements depend on the configuration and architecture of the baseboard (VME, CompactPCI, or custom), and two slots are required for both the baseboard and the attached PPMC7502xxx (in a VME or CompactPCI chassis).

Motorola MVME162FX Embedded Controller

The MVME162FX is based on the MC68040 or MC68LC040 microprocessor.

Different versions of the MVME162FX are available with 4MB, 8MB or 16MB of unprotected DRAM, 8KB SRAM (with battery backup), daily clock (with battery backup),

Ethernet transceiver interface, two serial ports with EIA-232-D or EIA-530 or EIA-485/422 interfaces, six timers, watchdog timer, one PROM socket,

1MB of Flash memory (one Flash device), four IndustryPack (IP) interfaces with DMA, SCSI bus interface with DMA, VMEbus controller, and 512KB of SRAM with battery backup. a “no VMEbus” option is also available.

The I/O on the MVME162FX is connected to the VMEbus P2 connector. The main board is connected via a P2 transition board and a cable connecting the transition board.

The MVME162FX supports the transition boards MVME712-12. MVME712-13. MVME712M, MVME712A, MVME712AM, and MVME712B (referred to in this manual as MVME712x unless otherwise noted).

The MVME712x transition board provides configuration headers and industry standard connectors for I/O devices.

I/O connections to the serial ports on the MVME162FX are also made via two DB-25 front panel I/O connectors.

The MVME712 series transition boards are designed to support the MVME167 www.ge-drive.com boards, but can be used on the MVME162FX if some special precautions are taken.

(For more information, see the Serial Communications Interfaces section of the MVME162FX Embedded Controller Installation and Use Manual).

These transition boards These transition boards provide configuration headers, serial port drivers, and industry-standard connectors for I/O devices.

These transition boards provide configuration headers, serial port drivers, and industry standard connectors for I/O devices.

Benefits

The MVME162FX series provides an ideal platform for embedded monitoring applications for OEMs and solution developers.

It enables OEMs to minimize engineering costs while integrating value-added hardware and software applications into off-the-shelf products.

To provide a wide range of solutions, the MVME162FX allows the use of a variety of MPUs, memory and interface options such as floating point, Ethernet, SCSI and VME.

As a result, the MVME162FX variants best fit the application requirements.

Functional Features

– Optional Processor:

– 32 MHz MC68040 Enhanced 32-bit Microprocessor with 8KB Cache and MMU and FPU

– 25 MHz MC68LC040 Enhanced 32-bit Microprocessor with 8KB Cache and MMU

– A32/D64 VMEbus Master/Slave Interface with System Controller Function

– High performance DMA support for VMEbus D64 and local bus memory burst cycles

– 4. 8 or 16MB of shared DRAM

– 512KB SRAM with battery backup

– 1MB Flash for on-board monitor/debugger or user-installed firmware

– 8K x 8 NVRAM and time clock with battery backup

– Two serial communication ports, console port is EIA-232-D DCE, second port is user configurable to EIA-232-D/EIA-422 (V.36) DTE/DCE

– Four 16-bit or two 32-bit IndustryPack® ports, one DMA channel per port

– Six 32-bit timers (four without VMEbus) and watchdog timer

– Optional SCSI bus interface with 32-bit local bus burst DMA

– Optional Ethernet transceiver interface with 32-bit local bus DMA

– One 32-pin PLCC EPROM socket

– Four-stage requester, seven-stage interruptor, and seven-stage interrupt handler for VMEbus

– Remote reset/pause/status control functions

– On-board debugger and diagnostic firmware

Motorola Commitment

Motorola Computer Group is committed to delivering best-in-class embedded computing solutions.

The MVME162FX family reinforces this commitment by providing superior hardware at a low price.

The MVME162FX family reinforces this commitment by providing superior hardware, affordable performance, and staying true to the principles of open computing:

modularity, scalability, portability and interoperability.

Motorola Computer Group is ISO9001 certified and offers world-class quality in manufacturing, engineering sales and marketing.

ABB SPHSS13 Hydraulic Servo Module

General Information

Product Code: SPHSS13

ABB Model: SPHSS13

Catalog Description: Hydraulic Servo Module

Long Description.

Hydraulic servo module for Harmony Rack, redundant servo coils, redundant AC or DC LVDT, PI and P-only control.

Additional Information

Medium Description.

Hydraulic Servo Module for Harmony Rack, redundant servo coils, redundant AC or www.ge-drive.com DC LVDT, PI and P control only

Product Type: I-O_Module

Product Type: I-O_Module

Country of Origin: India (IN) Malta (MT)

Customs Tariff No.: 8538908180

Product Dimensions

Net Depth/Length: 297.18 mm

Net Height: 35.56 mm

Net Product Width: 175.26 mm

Product Net Weight: 0.272kg

Environmental Protection:

WEEE Category: 5. Small devices (external dimensions up to 50 cm)

Number of batteries: 0

Category.

Control system products → Rotating machines → S+ HR series → HR turbines → HR turbine modules → Hydraulic servo modules

Control Systems → Symphony Plus → Turbine Control → HR Series Turbine Modules → SPHSS13

Hitachi Energy New Generation Digital Substation

The term “digital substation” currently applies to substations using process bus technology. Process buses replace hard-wired connections with Ethernet communication.

Distributed intelligent electronic devices (IEDs) interconnected via a communication network based on IEC 61850 perform operation and control.

IEDs can measure and communicate variables such as current or voltage, or switching devices such as relays.

However, IEDs communicate digitally over serial or Ethernet networks for protection, measurement, metering, or monitoring.

Digital substations can use other communication methods, but IEC-61850 is the modern global communication protocol.

IEC 61850 is more than just a protocol, or even a set of protocols, it is a comprehensive standard that

It is a comprehensive standard that was designed from the ground up to operate on modern network technologies. It provides functionality not found in traditional communication protocols.

It provides interfaces to communication services and supports Generic Object Oriented Substation Events (GOOSE), Sampled Measured Values (SMV), logging and other services.

These unique features of IEC 61850 help to significantly reduce the costs associated with power system design, installation, commissioning and operation.

Asset Performance Management (APM) Solution Collects Data from Digital Substations

The Asset Performance Management (APM) solution collects data from digital substations and www.ge-drive.com combines data collection, integration, visualization, and analytics to

APM encompasses concepts such as condition monitoring, predictive forecasting, and reliability-centered maintenance (RCM).

Digital Substation APM collects data from the substation’s IED and combines this data with other relevant asset data.

Combining data collection with a deeper understanding of an asset’s operating characteristics can provide significant value to operations and maintenance personnel by supporting predictive methods.

Managing Grid Assets in the Digital Substation

So how can you control the grid in a way that improves reliability and keeps the cost of power low? With limited capital budgets, the

utilities must make choices related to long-term expenditures.

These choices include

 Considering all relevant factors, determining which projects minimize risk

 Determining which aging equipment assets can more cost-effectively reduce risk

 determining whether additional capital expenditures can be justified to regulators or other stakeholders.

Regulators or other stakeholders

 Determine the most efficient way to deploy resources during an outage

Process bus digital communication standards support interoperability between IEDs from different vendors and “digitize” modern substations.

When process bus devices are properly configured according to the IEC 61850 standard, they provide fast, reliable and secure communications that

to support device protection, remote monitoring and remote control. Process buses can also provide control centers with situational awareness based on accurate and timely measurement data from all corners of the grid.

control center situational awareness based on accurate and timely measurement data from all corners of the grid. By connecting the data to the APM application, the data enables coordination between transmission sections and between transmission and distribution operators.

Hitachi ABB Power Grid APM

New asset performance management capabilities that connect directly to digital substations are expected to support all three priorities for the grid: high reliability, low cost and compliance.

However, developing a viable APM solution for the grid requires both significant domain expertise for these types of assets, as well as an understanding of these assets as a system.

It also requires a thorough understanding of how these assets work together as a system. Mathematical models based on first principles.

Simulating asset behavior in conjunction with operational statistics is a key approach to creating digital twins. A digital twin refers to a dynamic digital replica of the actual physical asset

and how it interacts with the larger grid and operators.

A digital twin refers to a dynamic digital replica of an actual physical asset and how it interacts with the larger grid and the humans who operate and maintain it.

The digital twin can include the spatial geometry of the asset and its location in the grid, as well as thermodynamic and electrical behavior.

APM, when applied effectively, can reduce OPEX and CAPEX based on predictive and prescriptive analytics, resulting in operational cost savings and/or deferring capital investment requirements.

APM can also help utilities achieve compliance as outages are reduced.

As ARC learned, Hitachi ABB Power Grid’s APM solution is designed to provide asset health and performance insights that

to help prevent critical failures while optimizing asset lifecycle costs. The solution utilizes digital twin technology, integrating online data with existing historical data.

It can also connect from the substation to the cloud using state-of-the-art IIoT (Industrial Internet of Things) connectivity technology, enabling utilities to leverage their online and offline data to

Drive a smarter, condition- and risk-based approach to asset management. By combining data collection, integration, visualization and analytics capabilities, the

utilities can gain new insights through a predictive, prescriptive and predictive view of their systems.

The solution complies with key industry standards such as ISO 55000 and PAS 55.

Hitachi ABB Power Grid APM helps utilities understand when faults are likely to occur and the consequences of those faults.

With this information, utilities are better able to achieve key objectives, including

 Cost-effectively manage asset health

 Effectively address identified risks

 Prioritizing repair and replacement decisions

 Implementing “what-if” analysis and contingency planning programs

Hitachi ABB Power Grid

Founded in 2020. Hitachi ABB Power Grid is a global technology leader with a history spanning nearly 250 years.

Headquartered in Switzerland, the company serves utility, industrial and infrastructure customers across the entire value chain.

With expertise in emerging areas such as renewable energy integration, energy storage, electrified mobility and smart cities, Hitachi ABB Power Grid is well-positioned to help companies around the world transition to a smart and distributed energy future.

Hitachi Energy Shielded Detachable Connectors

Connecting Cable Networks Safely and Reliably

Hitachi Energy is committed to building reliable and secure power transmission and distribution networks. To fulfill this commitment, we offer a wide range of cable accessories to customers in the power generation and transmission utility, renewable energy, and industrial sectors.

Shielded Separable Connectors

Applications

Separable cable connectors with shield are used for 12-24 kV XLPE-insulated single- or three-core cables with aluminum or copper conductors. They are suitable for use in standardized bushings with an A-type outer cone according to EN 50181.

Standards

– GB/T12706.4

– IEC 60502.4

Features

– Elbow cable connectors CSEB and straight cable connectors CSS-B are made of EPDM rubber with three layers: conductive inner layer, insulating layer and conductive outer layer.

The three layers of rubber are vulcanized to make the interface between the layers as perfect as possible. It has good UV, ozone and tracking resistance and is suitable for outdoor use.

The capacitance test points of the connectors are covered by conductive rubber caps to ensure complete shielding.

– Supplied in a three-phase kit including crimped cable lugs, terminal block, installation tool and ground wire, www.ge-drive.com designed to ensure reliable installation

– Single- or three-conductor cable grounding kit must be used (can be ordered separately)

Pre-assembled shielded detachable connectors

Applications

Preformed shielded breakaway connectors for 12kV XLPE insulated single or three core cables with aluminum or copper conductors. Suitable for EN 50181 Type C interface

Standard

– GB/T12706.4

– IEC 60502.4

Features

– Pre-molded shielded separable connectors are made of EPDM rubber with three layers: conductive inner layer, insulating layer and conductive outer layer.

The three layers of rubber are vulcanized to make the interface between the layers as perfect as possible. It has good resistance to UV, ozone and tracking.

– Supplied in three-phase kits with crimped cable lugs, stress-graded adapters designed to ensure reliable installation

– Single- or three-pole cable grounding kit must be used (can be ordered separately)

Preformed shielded detachable connectors

Applications

Preformed shielded breakaway connectors for 12kV XLPE insulated single or three core cables with aluminum or copper conductors. Suitable for EN 50181 Type C interface

Standard

– GB/T12706.4

– IEC 60502.4

Features

– Pre-molded shielded separable connectors are made of EPDM rubber with three layers: conductive inner layer, insulating layer and conductive outer layer.

The three layers of rubber are vulcanized to make the interface between the layers as perfect as possible. It has good resistance to UV, ozone and tracking.

– Supplied in three-phase kits with crimped cable lugs, stress-graded adapters designed to ensure reliable installation

– Single or three core cable grounding kit must be used (can be ordered separately)

Quality Assurance

We are committed to providing the best possible products and services. Our products meet or exceed the latest international standards.

In addition to type testing in independent laboratories, our certified design and manufacturing processes provide assurance of the highest quality. We are ISO 9001:2015 certified.

Sustainability

For Hitachi Energy, sustainability is about striking a balance between economic success, environmental stewardship and social progress that benefits all of our stakeholders.

Sustainability considerations include how we design and manufacture our products, what we offer our customers, how we work with our suppliers, the

how we assess risks and opportunities, and how we behave and relate to each other in the communities where we operate.

We also work to ensure the health, safety and security of our employees, contractors and others affected by our activities.

We are certified to ISO 14001:2015. ISO 45001:2018 and ISO 50001:2018.

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