Turbine blades are important components of the turbine section of gas turbine engines, responsible for sucking high-temperature and high-pressure airflow into the burner to maintain the operation of the engine. Rough turbine blades are important components of the turbine section of gas turbine engines, responsible for sucking high-temperature and high-pressure airflow into the burner to maintain the operation of the engine.
Rough forging process is usually faster than precision forging process, and a large number of blades can be produced more quickly, which is suitable for large-scale production.
Due to the high production efficiency of rough forging process, it usually has a lower production cost, which helps to reduce product costs.
Rough forging process is suitable for the production of large parts, so it is suitable for the manufacture of large-size turbine blades.
Rough forging process can usually obtain a more uniform internal structure of the material, which improves the mechanical properties and fatigue resistance of the blade.
Rough forging process can produce blades made of high-temperature alloy materials, which are suitable for working conditions in high temperature environment.
Rough forging process is usually suitable for mass production, suitable for large-scale production needs, and helps to improve production efficiency and reduce costs.
High temperature and high pressure environment: Turbine blades are often used in high temperature and high pressure working environments, such as aircraft engines, industrial gas turbines, etc.
High speed rotation environment: Turbine blades usually have to withstand high speed rotation environment, so they need to have high mechanical strength and dynamic balance.
High pressure airflow environment: Turbine blades work in high pressure airflow and need to have good aerodynamic performance and fluid dynamic characteristics.
Corrosion and wear environment: In some application scenarios, turbine blades may be exposed to corrosive media or high-speed flowing particles, so they need to have good corrosion resistance and wear resistance.
Complex flow environment: Turbine blades are in a complex fluid dynamics environment and need to be able to accurately control the airflow and meet the design requirements of flow, pressure and other parameters.
Aircraft engine:
Turbine blades are one of the most critical components in aircraft engines, used to convert gas kinetic energy into mechanical kinetic energy to propel aircraft flight.
Turbine blades are used in various types of aircraft engines such as jet engines, turboprop engines and turbojet engines.
Industrial gas turbine:
Industrial gas turbines are one of the main power equipment used in power plants, chemical plants and industrial production. Turbine blades are used to convert gas kinetic energy into mechanical kinetic energy to drive generators or other equipment.
Steam turbine:
A steam turbine is a device that converts steam kinetic energy into mechanical energy, and turbine blades are used in the rotor part of a steam turbine.
Steam turbines are usually used in steam turbine generator sets in power plants to convert steam kinetic energy into electrical energy.
Ship propulsion system:
Turbine blades are also used in ship propulsion systems, such as turboprops, to convert the power generated by the engine into kinetic energy of water to propel the ship forward.
Advantages: high specific strength, low density, excellent corrosion resistance and good high temperature performance.
Applications: aircraft engine turbine impellers, marine engineering and other applications that require high strength and light weight.
Advantages: excellent strength and creep resistance at high temperatures, good oxidation resistance and corrosion resistance.
Applications: gas turbine impellers, equipment in high temperature corrosive environments.
Advantages: high strength and hardness can be achieved through aging treatment, with good toughness and processing performance.
Applications: aircraft engine parts
Advantages: excellent corrosion resistance, high strength, good wear resistance
Applications: marine engineering equipment, chemical and petroleum equipment, equipment in high temperature corrosive environments
High strength and durability
Excellent fatigue performance
Complex shape manufacturing capability
Material diversity