DS200GGXCG1A - AC2000 Regen Distribution Board

DS200GGXCG1A - AC2000 Regen Distribution Board DS200GGXCG1A - AC2000 Regen Distribution Board

World Of Controls understands the criticality of your requirement and works towards reducing the lead time as much as possible.

DS200GGXCG1A - AC2000 Regen Distribution Board is available in stock which ships the same day.

DS200GGXCG1A - AC2000 Regen Distribution Board comes in UNUSED as well as REBUILT condition.

To avail our best deals for DS200GGXCG1A - AC2000 Regen Distribution Board, contact us and we will get back to you within 24 hours.

SPECIFICATIONS:

Part Number: DS200GGXCG1A
Manufacturer: General Electric
Series: Drive Control
Product Type: AC2000 Regen Distribution Board
Number of relay channels: 12
Power supply voltage: 28 V dc
Mounting: DIN-rail mounting
Interface ports: 4
Operating temperature: -30 to +65°C
Size: 15.9 cm high x 17.8 cm
Repair: 3-7 Day
Availability: In Stock
Country of Origin: United States
Manual: GEH-5980E

FUNCTIONAL DESCRIPTION:

DS200GGXCG1A is an AC2000 Regen Distribution Board manufactured and designed by General Electric as part of the Mark V Series used in GE Drive Control Systems. The Regen Distribution Board is commonly utilized in industrial and commercial environments where there is a significant presence of electrical loads that operate at variable speeds. These loads may include conveyor belts, cranes, elevators, or other machinery and equipment that require variable speed control. The primary purpose of the board is to make the electrical loads connected to it more energy-efficient. Regenerative technology allows the board to capture and redirect the energy generated during the deceleration or braking of the loads back into the power supply system. This regenerative process helps to reduce energy waste and improve the overall energy efficiency of the system.

FEATURES:

Installation Proximity to Electrical Loads: Installed near the electrical loads it serves. This proximity ensures efficient power distribution and minimizes power losses over long distances. By being installed nearby, the distribution board can effectively manage and control the energy flow to the connected electrical loads.

Connection to Power Supply System: Connected to a power supply system, such as a grid or generator. It acts as an intermediary between the power supply system and the electrical loads, regulating and distributing the electrical power as needed. This connection enables the board to effectively manage the energy flow and optimize the operation of the connected loads.

Monitoring and Control Capabilities: Equipped with monitoring and control systems that provide real-time monitoring of energy usage and performance. These systems allow operators or facility managers to monitor the energy consumption of the connected loads, analyze energy usage patterns, and make informed decisions for optimizing energy efficiency.

Prohibition of Manual Duplex Mode Configuration: The IEEE 802.3 specification strictly prohibits manual configuration of a port's duplex mode. This means that the duplex mode of an Ethernet Interface port should not be manually set using advanced user parameters or any other means. The specification emphasizes relying on the auto-negotiation function of the port to determine the appropriate duplex mode based on the capabilities of the link partner.

Understanding Link Partner Characteristics: When manually selecting the duplex mode for an Ethernet Interface port using advanced user parameters, it is crucial to have a clear understanding of the characteristics of the link partner. The link partner refers to the device or component on the other end of the Ethernet connection. Manually adjusting the duplex mode without considering the capabilities of the link partner can result in compatibility issues and improper duplex mode configurations.

Disabling Auto-Negotiation: When both the speed and duplex advanced user parameters are set on an IC698 Ethernet Interface port, the auto-negotiation function of the port is disabled. Auto-negotiation is a process in which connected devices exchange information about their capabilities to determine the best configuration for the link. Disabling auto-negotiation through manual configuration means that the port will not dynamically adjust its settings based on the link partner's capabilities.

Implications of Improper Duplex Mode: If the link partner is not similarly adjusted with manual configurations, there can be consequences in terms of improper duplex mode settings. For example, linking a full-duplex device (DTE or MAU) to a half-duplex MAU or a full-duplex DTE to a repeater can lead to compatibility issues and degraded performance. In such cases, the link partners may not be able to effectively transmit and receive data, leading to communication problems and potential data loss.

CHARACTERISTICS:

Connectors: The board features seven header connectors, which are used for connecting various external devices or modules to the board. These connectors serve as the interface for input/output connections. Additionally, there are nine stab-on connectors for wire jumpers, facilitating convenient wiring configurations. A vertical pin cable connector allows for the connection of cables, ensuring seamless integration with other components or systems. Lastly, the board is equipped with four fiber-optic signal interface ports, providing high-speed communication capabilities using fiber-optic technology.

Components: The board incorporates various components that enable its operation and functionality. It includes three transformer components, which play a role in voltage regulation or isolation. A heat sink is integrated into the board to dissipate heat generated by power components, ensuring optimal temperature levels. Integrated circuits (ICs) are employed for signal processing, logic control, or data storage functions. Additionally, the board contains three transistors, which are semiconductor devices used for amplification or switching purposes. Furthermore, it includes diodes, capacitors, and resistors, which are passive electronic components used for rectification, energy storage, and signal conditioning.

Jumper Switches: The board features twelve jumper switches that allow for customization and configuration options. These switches can be set or adjusted to specific positions to modify the behavior or settings of the board, adapting it to different operating conditions or requirements. Jumper switches are commonly used for selecting operating modes, enabling or disabling features, or adjusting parameter values.

Mounting Holes: The board includes factory-made mounting holes positioned at each corner. These holes facilitate secure and reliable mounting of the board onto a suitable surface or within an enclosure. Proper mounting ensures stability and prevents unintended movement or damage to the board during operation.

Printed Information: Important usage information is printed directly on the surface of the board in the form of two charts. These charts provide valuable guidance, instructions, or reference data related to the board's functionality, connection schemes, or configuration options. They serve as a quick reference for users, technicians, or installers to ensure proper installation, operation, and troubleshooting.

WOC has the largest stock of GE Drive Control System Replacement Parts. We can also repair your faulty boards. WORLD OF CONTROLS can also supply unused and rebuilt backed-up with a warranty. Our team of experts is available round the clock to support your OEM needs. Our team of experts at WOC is happy to assist you with any of your automation requirements. For pricing and availability on any parts and repairs, kindly get in touch with our team by phone or email.

FREQUENTLY ASKED QUESTIONS:

What are some of the features of the board?

The board has seven header connectors, nine stab-on connectors for wire jumpers, a vertical pin cable connector, and four fiber-optic signal interface ports. The board also has twelve jumper switches for customization, and important usage information is printed on the board's surface.

How does regenerative technology work?

Regenerative technology is achieved through the use of special circuits that can convert the kinetic energy of moving loads into electrical energy that can be stored or reused.

What is the purpose of the monitoring and control systems that can be equipped with the board?

Monitoring and control systems allow for real-time monitoring of energy usage and performance of the board and the electrical loads it serves.