WOODWARD 8237-2596 Digital Speed ​​Regulating Turbocharger

Woodward 8237 - 2596 digital speed control turbocharger is an advanced device for turbine engines launched by Woodward. The following is its related introduction:

Functional features

Digital speed control function: It adopts an advanced digital control system to accurately adjust the speed of the turbocharger. By real-time monitoring and analysis of the signals input by various sensors, the required speed adjustment amount is accurately calculated, and the operating speed of the turbocharger is quickly and accurately controlled to meet the needs of the engine under different working conditions.

Efficient supercharging: The exhaust gas energy discharged by the engine is used to drive the turbine to rotate, and then drive the compressor impeller to compress the air and send it into the engine intake manifold. By optimizing the design of the turbine and compressor, the supercharging efficiency is improved, and sufficient supercharged air can be provided to the engine at different engine speeds and loads, thereby increasing the engine's power and torque output.

Quick response: The digital control system has a fast response capability and can quickly adjust the speed of the turbocharger when the engine working conditions change. The common turbo hysteresis phenomenon of traditional turbochargers is reduced, so that the engine can respond to the driver's operation more quickly during dynamic processes such as acceleration and deceleration, and provide smoother power output.

Reliability and durability: The use of high-quality materials and advanced manufacturing processes ensures that the turbocharger has good reliability and durability under harsh working conditions such as high temperature, high pressure and high speed. At the same time, the digital control system also has fault diagnosis and protection functions, which can monitor the operating status of the system in real time. When an abnormal situation is detected, corresponding protection measures will be taken, such as limiting the speed and issuing an alarm signal, to prevent equipment damage.

Application scenarios

Aviation field: Applicable to various aviation turbine engines, including jet engines and turboprop engines. Provide reliable power support for aircraft to meet the requirements of aircraft engine performance in different flight stages such as take-off, cruising, and landing.

Industrial field: It can be applied to industrial gas turbines to provide efficient power for power generation, heating, and driving large mechanical equipment in industrial production. In addition, it can also play an important role in some industrial applications with high requirements for power performance and reliability, such as petrochemicals, metallurgy and other industries.

Shipbuilding: Turbine engines used in ships provide propulsion power for ships. They can adapt to the needs of ships under different sailing conditions, such as full load, no load, different speeds, etc., to ensure stable engine performance and improve the sailing efficiency and economy of ships.