DS3828BH5AR | General Electric Cell Stack Assembly GE Heat Sink

DS3828BH5AR | General Electric Cell Stack Assembly GE Heat Sink

Product Description P/N: DS3828BH5AR DESCRIPTION / SPECIFICATIONS Description The DS3828BH5AR is a Cell Stack Assembly with an attached heat sink, manufactured by General Electric. This component is intended for use within the Mark IV control system, which is an industrial gas/steam turbine control structure utilizing triple-modular-redundant controller units to minimize system downtime. The DS3828BH5AR functions as a Cell Stack assembly. 

The attached heat sink is designed to enhance heat transfer and dissipation from the cell stack by increasing surface area, thereby maintaining appropriate operating temperatures. Technical Specifications Part Number DS3828BH5AR Category Cell Stack Assembly with Heat Sink Manufacturer General Electric System Compatibility Designed for use within the Mark IV control system System Description GE industrial gas/steam turbine control structure utilizing triple-modular-redundant controller units Function Cell Stack assembly with an attached heat sink Information About DS3828BH5AR The DS3828BH5AR is a specialized cell stack assembly with an integrated heat sink, designed and manufactured by General Electric. 

This component is engineered for use within the Mark IV control system, a sophisticated industrial control structure developed by GE for managing gas and steam turbine operations. The Mark IV system is known for its reliability and efficiency in controlling complex turbine processes, utilizing a triple-modular-redundant (TMR) architecture to ensure fault tolerance and operational stability. The DS3828BH5AR plays a critical role in this system, contributing to both the thermal management and the overall performance of the control modules. As part of the Mark IV control system, the DS3828BH5AR is specifically designed to fit within the system's framework, ensuring seamless integration and optimal performance. 

The Mark IV system is deployed in various industrial applications, particularly in the energy sector, where it manages the operation of gas and steam turbines. The system's TMR design is key to its reliability, as it allows for continuous operation even in the presence of faults, thereby minimizing downtime and ensuring uninterrupted power generation. The primary function of the DS3828BH5AR is to serve as a cell stack assembly, a critical component that contributes to the regulation and control of electrical signals within the system. The cell stack assembly is responsible for ensuring that the correct voltages and currents are maintained throughout the control modules, which is essential for the accurate operation of the turbine control system. 

The assembly's design and materials are selected to provide high reliability and durability, capable of withstanding the demanding conditions typically encountered in industrial environments. One of the key features of the DS3828BH5AR is its integrated heat sink. The heat sink is designed to dissipate the heat generated by the cell stack during operation, which is crucial for maintaining the optimal temperature of the control system components. Effective thermal management is essential in high-performance industrial systems like the Mark IV, where excessive heat can lead to component degradation or failure. 

The heat sink ensures that the cell stack operates within its specified temperature range, thereby enhancing the longevity and reliability of the system. The DS3828BH5AR is constructed to meet the rigorous standards required for industrial control systems. Its materials and design are chosen to provide robust performance, even in harsh operating environments. This includes resistance to thermal cycling, mechanical vibrations, and electrical stress, all of which are common in turbine control applications. The assembly's design also facilitates easy installation and maintenance within the Mark IV system, allowing for quick replacement or servicing if necessary. In terms of system compatibility, the DS3828BH5AR is tailored specifically for the Mark IV control system. 

This ensures that it functions optimally within the system's architecture, contributing to the overall efficiency and reliability of turbine operations. The Mark IV system's reliance on components like the DS3828BH5AR underscores the importance of using high-quality, compatible parts to maintain system integrity and performance. In summary, the General Electric DS3828BH5AR is a crucial component within the Mark IV turbine control system, serving as a cell stack assembly with an integrated heat sink. Its design and functionality are tailored to meet the specific needs of this advanced control system, providing reliable signal regulation and effective thermal management. The DS3828BH5AR's compatibility with the Mark IV system, combined with its robust construction, makes it an essential part of maintaining the efficiency and reliability of gas and steam turbine operations. 

Whether used in new installations or as part of maintenance and upgrades, this component ensures that the Mark IV system continues to deliver the high performance and fault tolerance required in industrial energy applications. Manufacturer information General Electric (GE) is a multinational conglomerate founded in 1892, based in the United States. It operates in various industries, including aviation, healthcare, renewable energy, and power. GE is known for its innovations in technology, manufacturing, and infrastructure solutions. IQElectro is not an authorized distributor. QElectro LLC (IQElectro) is NOT an Authorized Distributor or in any way affiliated with Rockwell Automation, Siemens, or any other Manufacturers. 

IQElectro is NOT an Authorized Dealer of this product. The product may be of older version, date codes, or design than that available from authorized dealers. As IQElectro is not an authorized dealer of this product, the Original Manufacturer's Warranty and Support DO NOT apply.IQElectro sells SURPLUS onlyand DOES NOT SELL SOFTWARE or FIRMWARE licenses For more detailed information, please refer to the full version of our disclaimer policy Disclaimer Policy.