IS220PPROH1A Product datasheet
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Model number: |
IS220PPROH1A |
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Module Type: |
Backup Turbine Protection Module |
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Manufacture: |
GE |
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Condition: |
Brand New |
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Range of Product: |
EX2100 |
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Lead time: |
In Stock |
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Weight: |
0.36 kg |
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HS CODE: |
8537101190 |
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Dimension: |
13x8.2x6cm |
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MOQ: |
1 |
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Product Origin: |
USA |
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System: |
DCS |
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Discontinued on: |
Active |
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Communication Service: |
Ethernet router |
IS220PPROH1A Functional Description
The IS220PPROH1A part of General Electric's Mark VI Turbine Control System, stands out as a specialized modular assembly rather than a conventional printed circuit board. Unlike its predecessors, the IS220PPROH1A is integral to the control and management systems for gas, steam, and wind turbines, marking an important shift from the Mark V Series, which was limited to gas and steam turbines. The Mark VI Series, including the IS220PPROH1A, benefits from GE's patented Speedtronic control system, a key reason for its prominence in the industrial automation market.
The IS220PPROH1A is a turbine-specific I/O module designed to interface directly with turbine field devices, reducing the need for extensive instrumentation and improving reliability while decreasing long-term maintenance. It typically works with the TREAH_A terminal board and is used in emergency trip applications for aeroderivative turbines. This module connects to both barrier and box-type terminal blocks and has wiring limitations for voltage sensing, with a maximum cable length of 1,000 feet using 18 AWG wire.
Equipped with three speed signal inputs—deceleration, acceleration, and overspeed—the IS220PPROH1A Backup Turbine Protection Module also features hardware-implemented overspeed protection. Its front faceplate includes several LED indicators for status monitoring, such as PWR/ATTN, LINK/TxRx, and ENET ports. The module operates with a high-speed processor, dual 10/100 Ethernet ports, and has internal temperature monitoring. Notably, the IS220PPROH1A does not support auto-reconfiguration when swapping P-Pack types and is distinguished by its A-rated functional revision.
The General Electric IS220PPROH1A ’s unique design and features make it an essential component within the Mark VI Series, ensuring high-performance turbine control with enhanced durability and fewer maintenance requirements.
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GE Gas Turbine Control System
The GE Mark VI system is a comprehensive control solution used primarily in power generation and other industrial applications. It controls, protects, and monitors gas and steam turbines, generators, and auxiliary systems.
The SPEEDTRONIC™ Mark VI turbine control is the current state-of-the-art control for GE turbines that have a heritage of more than 30 years of successful operation. It is designed as a complete integrated control, protection, and monitoring system for generator and mechanical drive applications of gas and steam turbines. It is also an ideal platform for integrating all power island and balance-of-plant controls. Hardware and software are designed with close coordination between GE’s turbine design engineering and controls engineering to insure that your control system provides the optimum turbine performance and you receive a true “system” solution. With Mark VI, you receive the benefits of GE’s unmatched experience with an advanced turbine control platform.
The heart of the control system is the Control Module, which is available in either a 13- or 21- slot standard VME card rack. Inputs are received by the Control Module through termination boards with either barrier or box-type terminal blocks and passive signal conditioning. Each I/O card contains a TMS320C32 DSP processor to digitally filter the data before conversion to 32 bit IEEE-854 floating point format. The data is then placed in dual port memory that is accessible by the on-board C32 DSP on one side and the VME bus on the other. In addition to the I/O cards, the Control Module contains an “internal” communication card, a main processor card, and sometimes a flash disk card. Each card takes one slot except for the main processor that takes two slots. Cards are manufactured with surface-mounted technology and conformal coated per IPC-CC830. I/O data is transmitted on the VME backplane between the I/O cards and the VCMI card located in slot 1. The VCMI is used for “internal” communications between:
■ I/O cards that are contained within its card rack
■ I/O cards that may be contained in expansion I/O racks called Interface Modules
■ I/O in backup <P> Protection Modules
■ I/O in other Control Modules used in triple redundant control configurations
■ The main processor card
Triple Redundancy
Mark VI control systems are available in Simplex and Triple Redundant forms for small applications and large integrated systems with control ranging from a single module to many distributed modules. The name Triple Module Redundant (TMR) is derived from the basic architecture with three completely separate and independent Control Modules, power supplies, and IONets. Mark VI is the third generation of triple redundant control systems that were pioneered by GE in 1983. System throughput enables operation of up to nine, 21-slot VME racks of I/O cards at 40 ms including voting the data. Inputs are voted in software in a scheme called Software Implemented Fault Tolerance (SIFT). The VCMI card in each Control Module receives inputs from the Control Module back-plane and other modules via “its own” IONet. Data from the VCMI cards in each of the three Control Modules is then exchanged and voted prior to transmitting the data to the main processor cards for execution of the application software. Output voting is extended to the turbine with three coil servos for control valves and 2 out of 3 relays for critical outputs such as hydraulic trip solenoids. Other forms of output voting are available, including a median select of 4-20ma outputs for process control and 0- 200ma outputs for positioners. Sensor interface for TMR controls can be either single, dual, triple redundant, or combinations of redundancy levels. The TMR architecture supports riding through a single point failure in the electronics and repair of the defective card or module while the process is running. Adding sensor redundancy increases the fault tolerance of the overall “system.” Another TMR feature is the ability to distinguish between field sensor faults and internal electronics faults. Diagnostics continuously monitor the 3 sets of input electronics and alarms any discrepancies between them as an internal fault versus a sensor fault. In addition, all three main processors
continue to execute the correct “voted” input data,More info pls check GEH-6005 datasheet
