Description
DS200TCPDG1B 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.
When German Chancellor Mucker inserted an index finger into the mechanical tongs at the Hannover Messe and insisted on personally testing the intelligence of the robot “Corn”, almost all the audience present held their breath and sweated in their hearts. But his pliers immediately stayed in place, and everyone breathed a sigh of relief.Since the establishment of ABB China Research Institute in 2005, ABB China R&D personnel have developed the world”s fastest and most accurate six-axis robot – the “Dragon” IRB 120, and officially launched the world”s first true robot to the market at the Hannover Industrial Fair in Germany. YuMi (“Corn”), a dual-arm industrial robot that realizes human-machine collaboration.On the occasion of the tenth anniversary of the establishment of ABB China Research Institute, Mr. Claes Rytoft, the group”s global chief technology officer, was interviewed by reporters on ABB”s robotics business development and other issues.Reporter: Is the development of the robot “Corn” targeted at the application needs of specific industries?Claes Rytoft: Before talking about “corn”, let”s first look at other robots that have been used in industry before. They are basically industrial arms that do some complex repetitive work. But these robot arms are not safe. They must be placed in a cage and separated from people at a distance because they are not safe enough.So let”s look back at “Corn”, he can collaborate with others, he can stand next to you and participate in the work together. In the process of your human-machine collaboration, if you accidentally touch it with your arm, it will immediately slow down or even stop. This collaborative robot is an innovation in the entire field of robotics.Let me tell you a tidbit. At the Hannover Industrial Fair in Germany last week, ABB”s robot “Corn” became the focus, and it was almost one of the most attractive booths at the expo. At that time, German Chancellor Mucker insisted on personally testing the safety and intelligence of “Corn”, so he inserted his index finger into the mechanical tongs on “Corn””s arm. At that time, almost all the spectators present held their breath and were sweating in their hearts, fearing that something would go wrong and Mucker would be injured. But as soon as Mukeer put his fingers in, his pliers immediately stopped in place, and everyone breathed a sigh of relief.This example also shows that “Corn” is a true human-machine collaborative robot, and the users it targets are users who need human-machine collaborative work.”Corn” can be used in many assembly and manufacturing industries. In terms of human-machine collaboration, there is no compromise in the accuracy of its operation, and it can accurately reach an accuracy of 0.02 mm, which is equivalent to the smallest gap that can be felt by the human hand. To put it figuratively, you can use “corn” to “thread the needle”.Reporter: What is the development direction of ABB Robotics in China? What is the driving force for development?Claes Rytoft: ABB”s robot business first started in the automotive industry. In the era of mass production in the 1950s and 1960s, robots were used to perform complex and dangerous operations, such as spraying and welding.Take welding as an example. To ensure that welding meets standards, it must be operated by very skilled technical workers, and robots can also meet standards after being programmed. This is why the first robot was born at ABB”s Swedish research institute and was quickly promoted to worldwide.There is always room for development in this industry, and saturation is relative. China has now become a production base for electronic consumer products, and most of the production factories still rely on manual labor. Therefore, when ABB established a robot R&D and manufacturing base in Shanghai in 2005, it began to study which manufacturing industries robots should serve, and finally believed that it could replace Labor in these factories is also a new development direction. This depends more on the Chinese team.In 2009, Dr. Gu Chunyuan, chairman and president of ABB (China) Co., Ltd., led a local team to successfully develop the IRB 120 robot, which is specifically designed for small parts assembly in the automotive industry.As for the driving force of development, it is cost. In 2005, Dr. Gu Chunyuan went to a labor-intensive equipment company in China for research. At that time, he imagined that if the robot designed by ABB could complete all the operations of human hands on this production line, it would be able to relieve these young people from these heavy and intensive tasks. Freed from extremely boring and highly repetitive labor to do other things. This is why ABB Robotics has determined such a development direction in China.
IS200VSVOH1B From General Electric in the United States
IS230TVBAH4A High performance processor module GE
IS210AEBIH1BAA GE power control board
IS200VRTDH1DAC From General Electric in the United States
IS200TSVCH2ADC Gas turbine system Mark VI
DS200LRPAG1AAA Gas turbine system Mark VI
DS215TCQAG1BZZ01A I/O excitation redundant module GE
DS200DCFBG1BLC I/O excitation redundant module GE
IS210BPPCH1AC Processor/Controller Mark VI System
IS210AEBIH1BED From General Electric in the United States
IS200ISBEH2ABB GE power control board
IS200VPWRH1AF GE power control board
IS200ERRRH1A Gas turbine system Mark VI
IS200VTCCH1CBB High performance processor module GE
IS200TBACIH1B Gas turbine system Mark VI
IS200VTCCH1CBB GE power control board
IS200RCSBG1BAA From General Electric in the United States
IS200ICIAH1ABB From General Electric in the United States
IS200TREGH1B GE power control board
IS215UCVEH2A Processor/Controller Mark VI System
IS200ISBBG2AAB Processor/Controller Mark VI System
IS200TREGH1BDB Gas turbine system Mark VI
IS220PVIBH1A I/O excitation redundant module GE
DS200CTBAG1ACC From General Electric in the United States
IS200BPIAG1AEB From General Electric in the United States
IS200ERRBG1A High performance processor module GE
IS200VSVOH1BDC I/O excitation redundant module GE
DS200TCCAG1BAA GE power control board
DS200TCTGG1AFF GE power control board
IS200EXHSG3AEC High performance processor module GE
IS200TPROS1CBB High performance processor module GE
IS200EXAMG1A Gas turbine system Mark VI
IS220PDOAH1B I/O excitation redundant module GE
IS200WETBH1BAA GE power control board
IS200VCMIH1BCC Processor/Controller Mark VI System
DS200UCPBG6AFB Processor/Controller Mark VI System
IS200TRLYH2C I/O excitation redundant module GE
DS200TCQAG1BEC Processor/Controller Mark VI System
IS215SUCVEH2AE Gas turbine system Mark VI
IS230TBAIH2C High performance processor module GE
IS200ECTBG1ADE I/O excitation redundant module GE
IS200JPDPG1A GE power control board
IS200TBCIH1BBC High performance processor module GE
IS200TREGH1BDC I/O excitation redundant module GE
IS215UCVEM09A Gas turbine system Mark VI
IS200BICIH1ADB Processor/Controller Mark VI System
IS215ACLEH1A High performance processor module GE
IS200SAMBH1A Gas turbine system Mark VI
IS200TREGH1B I/O excitation redundant module GE
IS220PTCCHIA Processor/Controller Mark VI System
IS215PCMIH1AC Gas turbine system Mark VI
IS220PTURH1A GE power control board
