IS210MACCH1ACB I/O excitation redundant module GE

IS210MACCH1ACB I/O excitation redundant module GE

Brand: GE

model: IS210MACCH1ACB
System: Gas turbine system
Origin: United States

The GE IS210MACCH1ACB turbine control module is used for various applications, including:

Electric power generation

Oil and Gas

EADS

ship

Get a Quote
Categories: , , , , Tags: Brand:
  • Email:sauldcsplc@outlook.com
  • Phone:+86 18350224834
  • WhatsApp:+8618350224834

Description

IS210MACCH1ACB Product Introduction

GE IS210MACCH1ACB Embedded Controller Module
 
GE IS210MACCH1ACB Embedded Controller Module Product Details:
 
GE IS210MACCH1ACB is an embedded controller module developed by General Electric (GE) for industrial automation and control systems.
The specific application scope of the product
will depend on the needs of system integration and industrial application, but generally speaking, this type of embedded controller module can be applied to the following categories:
 
Industrial automation: used to master and monitor various automation processes in the factory, such as production lines, machine installation,
manufacturing processes, etc.
Power industry: used for mastering and monitoring tasks in power plants and power distribution systems.
Chemical and process industries: used to monitor and grasp the production process in chemical plants, refineries, and other process industries.
Manufacturing industry: can be used to master and optimize the production process, ensuring the effectiveness of labor and product quality.
Transportation: The application in the traffic signal system, railway system, or other traffic control systems.
Construction automation: used for automation systems in construction, such as building management systems, intelligent construction control systems, etc.
Fire disposal punishment and situation control: application in the pollution fire disposal punishment plant, fire disposal punishment measures, and situation
monitoring and control system.
These are just some potential application areas, in fact, there can be more application scenarios, depending on the effectiveness and personality
of the controller module, as well as the specific needs of the customer.
 
 
General Electric has designed the processor/controller for the IS210MACCH1ACB Mark VIe system. The Mark VI platform is General Electric”s Speedtronic range,
designed to manage gas or steam turbines.
It has a CIMPLICITY graphical interface and an HMI with software suitable for running heavy-duty turbines.
 
 
This IS210MACCH1ACB is a single box assembly with a front panel for communication connections, two screws installed on the rear edge, and three grille holes for ventilation. The controller is designed to
be installed at the bottom of the cabinet. For a small setup that is easy to serve a triple redundant system, up to three components can be installed side by side.
 
IS210MACCH1ACB uses the QNX operating system. It has a 667MHz Freescale 8349 processor. This board is powered by a 12 watt, 18-36 V DC power supply. Even at its maximum rated temperature, t
he board can operate within a temperature range of 0 to 65 degrees Celsius without the need for a fan for cooling. NFPA Class 1. This board can be used for two applications.
Contact Us
 
Mobile phone: 18350224834
 
E-mail: sauldcsplc@outlook.com
 
WhatsApp:+86 18350224834

Shandong”s policies are more specific. In addition to financial incentives, land supply, tax incentives, etc., it also mentions improving the first (set) of major technical equipment research and development and market promotion support policies, and accelerating independent innovation and industrialization of high-end products. Encourage provincial equity investment guidance funds to tilt towards the high-end equipment field, give full play to the leverage and amplification effect of fiscal funds, and attract and leverage social capital to increase investment.How can local governments effectively support high-end manufacturing?Analysts believe that when formulating development plans for high-end manufacturing, local governments must first conduct thorough research and research on the industry, find a development path that suits them, and formulate policies that suit the laws of industrial development. For example, Chongqing has a developed automobile industry, Shanghai has a strong industrial foundation in large aircraft, chips and robot manufacturing, and Shandong has a certain technical foundation in marine engineering equipment and rail transit equipment. We should leverage our strengths and avoid weaknesses and formulate policies based on local conditions.Second, local policies should not pursue automation and intelligence one-sidedly and support a number of face-saving projects that are blooming everywhere. For example, in the past two years, my country”s robot industrial parks have blossomed all over the country, and local governments have used subsidies and tax incentives to support a number of low-end, small and weak “intelligent manufacturing” robot industries.Third, local governments’ understanding of high-end manufacturing needs to be further deepened, and automation cannot simply be equated with high-end manufacturing. Local governments use subsidies to guide companies to purchase high-end automation equipment, but companies must also use good technology instead of expensive technology based on actual conditions. The case of Tesla’s over-reliance on automation causing a production capacity crisis should be taken seriously.Fourth, neither local governments nor enterprises can rely solely on buying and selling to promote high-end manufacturing. The government should guide and encourage technological innovation and seek long-term development.Generally speaking, enterprises should be closer to the market in terms of their own development and industry needs, and the government should create a policy environment more conducive to enterprise innovation, such as tax cuts, streamlining administration and delegating powers, etc., to help enterprises reduce costs as much as possible and give them the greatest benefits. Expansion capacity.

DS200TCPDG1BEC Processor/Controller Mark VI System
IS220PAOCH1BD Gas turbine system Mark VI
IS210BPPBH2BMD High performance processor module GE
IS420PVIBH1B High performance processor module GE
IS200ISBBG1AAB Processor/Controller Mark VI System
IS200DAMDG2A GE power control board
IS215VPROH2B Processor/Controller Mark VI System
8201-HI-IS Gas turbine system Mark VI
DS200TBQDG1AFF High performance processor module GE
IS420ESWAH2A I/O excitation redundant module GE
IS220PDOAH1A From General Electric in the United States
IS200TVBAH2ACC High performance processor module GE
IS220PDIOH1A Processor/Controller Mark VI System
IS210DSVOH1A Processor/Controller Mark VI System
DS200SLCCG3AGH High performance processor module GE
IS200ERGTH1AAA I/O excitation redundant module GE
IS200JPDFG1A Gas turbine system Mark VI
DS200GDPAG1AHE Gas turbine system Mark VI
IS220PRTDH1A High performance processor module GE
DS200TCCAG1BAA Gas turbine system Mark VI
DS200RTBAG2AHC From General Electric in the United States
IS200STAIH1ABB From General Electric in the United States
IS200TSVCH1AJE GE power control board
DS200LDCCH1APA GE power control board
DS200SHCBG1ABC GE power control board
IS210AEBIH1BAA Gas turbine system Mark VI
IS220PDIAH1B Gas turbine system Mark VI
IS400WROFH1A I/O excitation redundant module GE
IS200TSVOH1BCC From General Electric in the United States
IS210MVRCH1A GE power control board
IS420UCSBH1A High performance processor module GE
DS215TCQFG1AZZ01A Processor/Controller Mark VI System
IS420ESWBH3A I/O excitation redundant module GE
IS200TRLYH1F I/O excitation redundant module GE
DS200SIOBH1ABA I/O excitation redundant module GE
IS200ISBBG1A I/O excitation redundant module GE
IS215UCVEM01A Gas turbine system Mark VI
IS210MACCH1ACC GE power control board
IS200DAMEG1A From General Electric in the United States
IS200DSPXH1DBD Processor/Controller Mark VI System
DS2020FECNRX010A GE power control board
IS230SNAOH2A GE power control board
IS215UCCAM03A High performance processor module GE
DS200TCPDG2B From General Electric in the United States
IS210BAPAH1A From General Electric in the United States
IS210BPPCH1AD I/O excitation redundant module GE
IS200JPDFG1A I/O excitation redundant module GE
IS210AEBIH3BBC Gas turbine system Mark VI
IS420UCECH1B Gas turbine system Mark VI
IS200VPROH1B GE power control board
IS200EISBH1AAA I/O excitation redundant module GE
DS200RCTBG1AAA I/O excitation redundant module GE
IS220PPDAH1B From General Electric in the United States
IS200JPDBG1A From General Electric in the United States
IS420UCSBH4A Gas turbine system Mark VI
IS200IGDMH1AAA Gas turbine system Mark VI
IS200ERSCG2A Gas turbine system Mark VI
DS200SSRAG1A High performance processor module GE
IS220PPROH1A High performance processor module GE
DS2020FECNRX010A Gas turbine system Mark VI
IS200TRPGH1BDE From General Electric in the United States
DS200TCCBG3BDC Gas turbine system Mark VI
IS220PRTDH1A Gas turbine system Mark VI
DS200RCTBG1AAA GE power control board
IS200TVBAH2A Gas turbine system Mark VI
DS200SDCCG1A I/O excitation redundant module GE
IS420PPNGH1A High performance processor module GE
IS200ICBDH1B High performance processor module GE
IS200IHG1A From General Electric in the United States
IS200TBAIH1C I/O excitation redundant module GE
IS200RCSAG1A Gas turbine system Mark VI
IS230TVBAH4A Gas turbine system Mark VI
IS420UCSBH4A High performance processor module GE
IS200JPDFG2AED Gas turbine system Mark VI
DS200TCQCG1B GE power control board

Related products