GE DS3800HSPC Speed Position Input Board

GE DS3800HSPC Speed Position Input Board

Part Number DS3800HSPC Manufacturer General Electric Country of Manufacture As Per GE Manufacturing Policy Series Mark VI/VIe Function Module Availability In StockDS3800HSPC is a Speed Position Input Board manufactured and designed by General Electric as part of the Mark IV Series used in GE Speedtronic Gas Turbine Control Systems. A Speed Position Input (SPI) board is a critical component in turbine control systems. 

It is responsible for providing accurate and reliable speed and position information to the control system, which is used to regulate the operation of the turbine. The SPI board typically consists of sensors that measure the rotational speed and position of the turbine shaft, as well as signal conditioning and amplification circuits that process the sensor signals and output the information in a form that can be used by the control system. The board may also include microprocessors or other processing units to further refine the signals and perform diagnostics. The accuracy and reliability of the SPI board are essential for the safe and efficient operation of the turbine. Any errors or malfunctions in the SPI board can lead to incorrect speed or position measurements, which can result in unstable or unsafe turbine operation. Therefore, SPI boards are typically designed with redundant sensors and fault-tolerant circuits to ensure that they continue to function correctly even in the event of a failure. 

 FEATURES: The Speed Position Input (SPI) board in turbine control systems typically includes the following features: Speed and Position Sensors: The SPI board typically includes sensors that measure the rotational speed and position of the turbine shaft. These sensors may be based on different technologies, such as magnetic or optical encoders, and are designed to provide accurate and reliable speed and position measurements. Signal Conditioning and Amplification Circuits: The signals from the sensors are typically weak and require amplification and conditioning before they can be processed by the control system. The SPI board includes circuits that perform this function, ensuring that the signals are of sufficient strength and quality to be used by the control system. Redundant Sensors: To ensure high reliability, the SPI board often includes redundant sensors. 

This means that multiple sensors are measuring the speed and position of the turbine shaft, and the signals from these sensors are compared to ensure that they are consistent. If there is a discrepancy between the signals, the control system can use a voting algorithm to determine the correct value. Fault-Tolerant Circuits: The SPI board is typically designed with fault-tolerant circuits that can detect and respond to errors or malfunctions in the system. For example, if one of the sensors fails, the control system can automatically switch to a backup sensor, ensuring that the speed and position measurements remain accurate and reliable. Diagnostic Features: The SPI board may include diagnostic features that allow the control system to monitor the health of the board and detect any faults or malfunctions. This can include built-in self-tests or diagnostic algorithms that analyze the sensor signals and alert the control system if there are any issues.

SPECIFICATIONS:

Part Number: DS3800HSPC
Manufacturer: General Electric
Series: Mark IV
Product Type: Speed Position Input Board
Operating temperature: -33 to 56 °C
Size: 8.25 cm high x 4.25 cm
Repair: 3-7 Day
Availability: In Stock
Weight: 2 lbs
Country of Origin: United States

Main Functions

Power system monitoring and control:

The power interface board can be used for power system monitoring and control equipment to ensure the safe, stable and reliable operation of the power system.

Power plant automation:

In the power plant, it can be used to connect and manage the power supply of the mastering system and monitoring equipment to improve the automation level of the power plant.

Power transformer and distribution:

Applicable to substations and distribution stations, it is used to govern the power supply of transformers, circuit breakers and other equipments to ensure the high efficiency of power transmission and distribution.

Industrial Process Mastering:

In manufacturing and chemical workshops, this power interface board can be used for power management of automation systems, inner and control equipment to enhance productivity and safety.

Building Automation:

It can be used in building automation system, power supply to lighting, air conditioning, security equipment, etc., to achieve intelligent management of building equipment.

Railway flag signal system:

In the railway system, it is used in the power management of railway flag signal equipment and control system to ensure the stable operation of railway signal system.

Smart Grid:

In the smart grid, the power interface board can be used to connect and manage the digital power equipment and promote the intelligent development of the power grid.

Traffic Flag Signal System:

In the traffic flag signal system of routes and intersections, it is used to supply power to the flag master and equipment to ensure the normal display of traffic signals.

Aerospace:

In aviation and aerospace, the power interface board can be used in the control system of aircraft and spacecraft to provide stable and reliable power support.

It is suitable for land initiatives, oilfield equipment and other categories, providing power support for various land engineering equipment.