Description
IS420UCSBH4A 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.
Practical application of ABB industrial information control system 800xA in main shaft hoist controlintroductionThe mine hoist is an important transportation equipment for mining enterprises. Its main function is to transport the ore, personnel or equipment that need to be transported to the destination by the lifting container. Therefore, it plays a very important role in the mining production process. Usually the mine hoist control system consists of a driving part and a control part. The working mechanism of the driving part is: the motor unit drives the mechanical hoisting device, and the frequency converter or other types of hoisting control systems drive the motor unit: the working mechanism of the control part is: Each component of the hoist is coordinated and controlled by the Distributed Control System (DCS). In addition to completing basic process control, it can also integrate intelligent instruments, intelligent transmission and motor control, and even production management and safety systems into one operation and engineering environment. middle. Therefore, the mine hoist requires a control system with high performance, high reliability, and high integration.1ABB800xA system and AC800M controller introduction1.1ABB800xA system introductionThe 800xA system is an industrial information control system launched by ABB. The core of its architecture is object-oriented (ObjectOriented) technology. Due to the adoption of ABB”s unique Aspect0object concept, enterprise-level information access, object navigation and access can become standardized and simple.In order to provide a unified information platform for enterprise managers and technical personnel, the 800xA system provides a base platform (BasePlatform), which relatively separates the process control part and production control management and organically combines them together. As shown in Figure 1, the middle part is the basic platform, the upper part is the production control management part, and the lower part is the process control part. The basic platform provides standard interfaces for these two parts for data exchange.1.2 Introduction to ABBAC800M controller and its programming configuration toolsAC800M controller is ABB”s latest controller series, which includes a series of processors from PM851 to PM865. The AC800M controller itself has a pair of redundant TCP/IP interfaces. It can use the MMs protocol to communicate with other control devices and 800xA operator stations through Ethernet. It can also use the Modbus protocol and Point-Point protocol through 2 serial ports. communication. The programming and configuration tool of AC800M is ControlBuilderM, referred to as CBM. It supports standard ladder diagram, function block language, text description language and assembly language to write control logic.2. Improve the design and implementation of control system functions2.1 Implementation of elevator operating speed curveOne of the main tasks of the lifting control system is to control the lifting motor to operate according to the speed-position curve given by the design, so that the lifting container passes through the acceleration section, the uniform speed section and the deceleration section successively, and stops accurately after completing the specified lifting distance. somewhere in the wellbore. In order to realize the function of precise position calculation, the designed elevator control system must be able to perform high-precision position calculation based on the photoelectric encoder connected to the main shaft of the elevator drum. The calculation formula is as follows:In the formula, s is the actual position value of the elevator: sp is the distance corresponding to two consecutive encoder pulses: AN is the difference between the encoder count value at the reference position and the current position (signed variable): s0 is the reference position value.The encoder counts are distributed according to the circumference of the drum. After the number of pulses Np generated by the encoder rotation is known, the diameter of the circumference of the centerline of the wire rope wrapped around the drum must be accurately known, so that it can be calculated according to formula (2) The distance sp corresponding to the two encoder pulses:In the formula, D is the circumferential diameter of the centerline of the wire rope: Np is the number of pulses for one revolution of the known encoder.But in formula (2), there is a value D that keeps getting smaller as the system runs. This is because the wire rope used in the elevator is wrapped around the drum, and there is a lining between the wire rope and the drum that increases friction. This liner will become thinner and thinner as the system continues to wear and tear, causing the diameter of the circle formed by the center line of the steel wire rope to gradually become smaller. When the pad wears to a certain extent, it will cause a large position calculation error. In order to solve the above problems, the two parking position switches in the shaft are used to correct the drum diameter, because the distance between the two parking positions can be obtained through actual measurement with high accuracy. During the actual operation, record the encoder count values at the two parking positions respectively. According to formula (3), the actual correction value of sp can be calculated:In the formula, sd is the distance between two parking positions: Abs is the absolute value operation: N is the encoder count value when there are two parking positions.In this way, the initial sp value is first set according to the given design parameter value, and then the value is corrected according to the actual operating conditions, which can effectively ensure the accuracy of position calculation. At the same time, sp” can also be substituted into formula (2), and the D value can be obtained in turn, which can be used as a basis for judging whether the liner is seriously worn.After obtaining the elevator position value, the speed control curve can be calculated according to formula (4):
IS420UCSCS2A-B From General Electric in the United States
IS200TVBAH2ACC I/O excitation redundant module GE
IS200JPDSG1ACBGE From General Electric in the United States
IS220PDIIH1B GE power control board
DS200LDCCH1AGA GE power control board
IS200BLIGH1A Gas turbine system Mark VI
IS200ERRBG1A From General Electric in the United States
IS200DSPXH1D I/O excitation redundant module GE
IS200ERIOH1ACB From General Electric in the United States
IS200TBTCH1CBB High performance processor module GE
IS200DAMAG1B From General Electric in the United States
IS200VAICH1DAA From General Electric in the United States
IS200HFPAG2A I/O excitation redundant module GE
IS200RCSAG1ABB GE power control board
IS200TREGH1BDC Processor/Controller Mark VI System
IS210DTAIH1A Processor/Controller Mark VI System
IS230TNTRH1C Gas turbine system Mark VI
DS200TCEAG1BNE I/O excitation redundant module GE
IS200JPDDG1A Processor/Controller Mark VI System
IS200TRLYH1BGF GE power control board
DS200TCEAG1BTF High performance processor module GE
IS200TRLYH1C High performance processor module GE
IS210AEBIH1ADC From General Electric in the United States
IS200ESYSH3ABB Gas turbine system Mark VI
IS200HFPAG2ADC GE power control board
IS200BICRH1A GE power control board
IS220PRTDH1B Processor/Controller Mark VI System
DS200ACNAG1ADD High performance processor module GE
DS200TCRAG1ABB GE power control board
DS200SDCCG4AFD High performance processor module GE
DS200GDPAG1AKF High performance processor module GE
DS200TCCAG1BAA I/O excitation redundant module GE
DS215TCDAG1BZZ01A From General Electric in the United States
GDS1168-PFF-PA-NF Processor/Controller Mark VI System
IS210MACCH2AEG High performance processor module GE
IS200EGPAG1B Gas turbine system Mark VI
IS200SPROH1AAB Processor/Controller Mark VI System
DS200UPSAG1A Processor/Controller Mark VI System
DS200TBQCG1AAA High performance processor module GE
DS200SPCBG1ADC I/O excitation redundant module GE
DS200IIBDG1A High performance processor module GE
IS200TRLYS1BGG High performance processor module GE
IS215UCVFH2AB High performance processor module GE
DS200SDCCG5A GE power control board
IS210AEBIH3B Gas turbine system Mark VI
IS200DAMDG2A Processor/Controller Mark VI System
DS3820LT4AICIA From General Electric in the United States
IS400JPDHG1ABB Gas turbine system Mark VI
IS200VTCCH1CBC GE power control board
DS200TCDAH1B Processor/Controller Mark VI System
IS210AEACH1A I/O excitation redundant module GE
DS200LDCCH1AGA Processor/Controller Mark VI System
IS410TRLYS1F High performance processor module GE
IS220PRTDH1B High performance processor module GE
IS215SECAH1A I/O excitation redundant module GE
IS200TBTCH1C I/O excitation redundant module GE
DS200TCQCG1BKG Gas turbine system Mark VI
IS200BPVCG1B I/O excitation redundant module GE
IS210BPPBH2B From General Electric in the United States
IS200EPDMG1ABA I/O excitation redundant module GE
IS200STCIH6ADD Gas turbine system Mark VI
IS200VCRCH1BBB GE power control board
IS200BPIIH1AAA High performance processor module GE
IS420YDOAS1B Processor/Controller Mark VI System
IS210AEAAH1B GE power control board
DS200TCDAG1PR5A Processor/Controller Mark VI System
IS200DAMDG2AAA Processor/Controller Mark VI System
DS200SDCCG4AFD From General Electric in the United States
IS200ICBDH1ABB From General Electric in the United States
DS200ACNAG1ADD Processor/Controller Mark VI System
