Description
IS200AEPCH1CCB Product Introduction
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:
manufacturing processes, etc.
monitoring and control system.
of the controller module, as well as the specific needs of the customer.
designed to manage gas or steam turbines.
It has a CIMPLICITY graphical interface and an HMI with software suitable for running heavy-duty turbines.
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.
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.
Why is the industrial Internet inseparable from industrial control? ABB Global CEO Ulrich Spiesshofer recently accepted an exclusive interview with a reporter from Caijing in New York. He believes that the global manufacturing industry is undergoing drastic changes. The era of labor arbitrage is over. Labor costs are no longer the focus of competition. The future of manufacturing lies in In factories that are smaller, closer to consumers, and more agile. Artificial intelligence ( AI ) is the most important technology shaping the future of manufacturing. Currently, AI technology is mainly used in the consumer field, but its large-scale application in the industrial field and among enterprises is more critical. Digital transformation has been a keyword for global manufacturing giants in the past two years, and the industrial Internet is the implementation form of digital transformation. General Electric (GE), Siemens and ABB are all leaders in this regard . Spiesshofer believes that GE”s industrial Internet only collects data and analyzes but cannot control it. As the world”s two largest industrial automation suppliers, ABB and Siemens have the ability to control equipment, which is a significant difference from GE. ABB is headquartered in Zurich, Switzerland. Its history can be traced back to the 1880s. It started from the original electrical manufacturing business and has developed into an international manufacturing giant including electrical products, robotics and motion control, industrial automation and power grid. In 2017, ABB”s revenue was US$34.3 billion, ranking 341st among the Fortune 500 companies. Spiesshofer has served as CEO for nearly five years since taking office in September 2013. Below are the details of the interview. The era of labor arbitrage is over Caijing: Is 2018 a good year for the manufacturing industry? Spiesshofer: From a global perspective, GDP is growing and consumption is also growing. Overall positive. Caijing: What crucial changes are taking place in the manufacturing industry? Spiesshofer: The jobs of the future will be different from the jobs of the past. In the Middle Ages, craftsmen moved between villages, taking their tools with them to work where there was demand; later we invented factories, integrated supply and demand, and invented logistics; later people realized that there was labor arbitrage (Labor Arbitrage, Refers to the existence of moving industries that have lost technological advantages and technical barriers to areas with low labor prices to increase profits by reducing labor costs), so we place factories in emerging countries to benefit from labor arbitrage. Now, with the development of modern automation and robotics, we can break this picture and bring value addition closer to demand. I think the future of manufacturing is in factories that are smaller, closer to consumers, and more agile. I believe that the global logistics chain will also be reduced in the future because we will produce products closer to consumers. The era of labor arbitrage shaping the global manufacturing landscape will be over because we can offset this arbitrage. Recently we opened a new factory in Germany. Due to the adoption of intelligent automation technology, its unit cost is exactly the same as that of the best factories in China. So I think the local market will be repositioned in the future, and the positioning of competitiveness will also change from just considering costs to focusing more on technology and value. Caijing: Many people are complaining that automation has caused people to lose their jobs, and artificial intelligence technology has made the complaints louder. But these new technologies are also creating new jobs. How do you see the relationship between the two? Spiesshofer: In 1990, one-third of the world”s population lived below the extreme poverty line. Today, only 8% rely on technology. In fact, countries with the highest robot densities, such as Germany, South Korea, Singapore, and Japan, also have the lowest unemployment rates. Robots combined with educated people can create prosperity, produce more affordable goods, and lead to economic growth. Government, education and business need to work together to keep up with the changing world. Clearly, millions of jobs are disappearing, but millions of new ones are being created. Taking our own business as an example, we used to have many employees doing metal casting and forging work, but now these tasks are automated. But now we have more employees working in the service industry, developing apps, and working with customers. So I think we should not be afraid of change, but should lead our employees to manage change and promote change. If we succeed, global employment will eventually grow.
IS215UCVFH2AB Processor/Controller Mark VI System
DS200FCSAG1ACB Processor/Controller Mark VI System
IS200EXCSG1A GE power control board
IS200TDBSH2A I/O excitation redundant module GE
IS420YVIBS1B Processor/Controller Mark VI System
IS200HSLAH2A Processor/Controller Mark VI System
IS215UCVFH2AB Gas turbine system Mark VI
IS210AEPSG1B GE power control board
DS200SPCBG1ADC High performance processor module GE
IS210DRTDH1AA Gas turbine system Mark VI
IS420ESWBH3AX GE power control board
IS230SNAIH4A I/O excitation redundant module GE
IS200VTURH1BAC From General Electric in the United States
IS420ESWBH3A From General Electric in the United States
DS2020FEXAG4 I/O excitation redundant module GE
IS200ACLEH1ABA GE power control board
IS200BICIH1ADB Gas turbine system Mark VI
IS200PMCIH1AAA6BA00 GE power control board
IS200IGPAG2A I/O excitation redundant module GE
DS200RTBAG1AHC Processor/Controller Mark VI System
DS200PCCAG9ACB From General Electric in the United States
DS200RCIAG1AAA GE power control board
IS200TBCIH2C GE power control board
DS3800XPEX1B1A I/O excitation redundant module GE
IS215UCCAM03A GE power control board
DS200PCCAG6A Gas turbine system Mark VI
IS410JPDDG2A From General Electric in the United States
IS220PDIOH1A Gas turbine system Mark VI
DS200ADMAH1AAC Gas turbine system Mark VI
IS200EHPAG1B From General Electric in the United States
IS200AEBMG1AFB GE power control board
DS200VPBLG1AEE From General Electric in the United States
IS200JPDDG1AAA I/O excitation redundant module GE
IS200EXHSG4A Gas turbine system Mark VI
DS200DMCAG1AJD I/O excitation redundant module GE
DS200PCCAG6A Processor/Controller Mark VI System
IS420PSCAH1B Gas turbine system Mark VI
IS200DTAOH1ABA Gas turbine system Mark VI
IS200BPVCG1B Gas turbine system Mark VI
IS200EDCFG1A I/O excitation redundant module GE
DS200DTBAG1AAA Gas turbine system Mark VI
DS215TCQAG1BZZ01A Gas turbine system Mark VI
DS200SHCAG1B From General Electric in the United States
IS420ESWAH5A From General Electric in the United States
IS200TREGH1BDB I/O excitation redundant module GE
IS200ERRRH1A Processor/Controller Mark VI System
IS200VSCAH2A From General Electric in the United States
IS200TBAIH1B Processor/Controller Mark VI System
IS200IHG1A Gas turbine system Mark VI
IS200ADIIH1AAA Gas turbine system Mark VI
DS200TCQCG1BLG I/O excitation redundant module GE
IS215VCMIH2CA Gas turbine system Mark VI
IS200IGDMH1B Gas turbine system Mark VI
DS200DTBDG1ABB I/O excitation redundant module GE
IS200TTPWH1A Gas turbine system Mark VI
IS200TBAIH1C From General Electric in the United States
IS200VPROH2B I/O excitation redundant module GE
IS220PAISAH1A Processor/Controller Mark VI System
IS220PDIIH1B From General Electric in the United States
IS220PPDAH1A Gas turbine system Mark VI
IS200JGNDG1A High performance processor module GE
IS200VAICH1DAB I/O excitation redundant module GE
DS200GGXCG1A I/O excitation redundant module GE
IS200TBTCH1CBB I/O excitation redundant module GE
IS220PTURH1A I/O excitation redundant module GE
IS230STTCH2A I/O excitation redundant module GE
DS200DTBDG1 Gas turbine system Mark VI
IS200PTURH1B Gas turbine system Mark VI
IS215VCMIH2B High performance processor module GE
DS3820LT4AICIA Gas turbine system Mark VI
IS215PMVPH1A Processor/Controller Mark VI System
IS200DSPXH2DBD From General Electric in the United States
DS200SLCCG3ACC From General Electric in the United States
IS200PTURH1B High performance processor module GE
GE DS200EXPSG1A Processor/Controller Mark VI System
IS200ERDDH1 High performance processor module GE
IS200TVIBH2BBB GE power control board
DS200TCQAG1A GE power control board
IS210BPPBH2BMD Gas turbine system Mark VI
IS200TDBTH6A Processor/Controller Mark VI System
IS200EPBPG1ACD Processor/Controller Mark VI System
DS200DSFBG1A From General Electric in the United States
DS200PCCAG10A Gas turbine system Mark VI
DS200FSAAG2ABA I/O excitation redundant module GE
IS210AEBIH1ADC Gas turbine system Mark VI
IS220PSVOH1A From General Electric in the United States
DS200ADPBG1A From General Electric in the United States
DS200TCPDG1BEC I/O excitation redundant module GE
DS200TCDAH1B Gas turbine system Mark VI
IS200WNPSH1ABA Gas turbine system Mark VI
IS420UCSBS1A Gas turbine system Mark VI
IS420ESWBH2A From General Electric in the United States
IS200ERSCG1A I/O excitation redundant module GE
IS200ESELH1A GE power control board
DS200TCRAG1A GE power control board
