1. Deformed high-temperature alloy

Deformed high-temperature alloy means that it can be processed by hot and cold deformation. The working temperature range is -253~1320℃, and it has good mechanical properties and comprehensive strength. , toughness index, a type of alloy with high anti-oxidation and anti-corrosion properties. According to its heat treatment process, it can be divided into solid solution strengthened alloy and age strengthened alloy.

1. Solid solution strengthened alloy

The service temperature range is 900~1300℃, and the maximum anti-oxidation temperature reaches 1320℃. For example, GH128 alloy has a room temperature tensile strength of 850MPa and a yield strength of 350MPa; a tensile strength of 140MPa and an elongation of 85% at 1000°C. The endurance life at 1000°C and 30MPa stress is 200 hours and the elongation is 40%. Solid solution alloys are generally used to make aviation and aerospace engine combustion chambers, casings and other components.

2. Age-strengthened alloy

The operating temperature is -253~950℃, and it is generally used to make structural parts such as turbine disks and blades of aviation and aerospace engines. The alloy used to make turbine disks has a working temperature of -253~700°C and is required to have good high and low temperature strength and fatigue resistance. For example: GH4169 alloy has a maximum yield strength of 1000MPa at 650°C; the alloy temperature for making blades can reach 950°C. For example: GH220 alloy has a tensile strength of 490MPa at 950°C and a durable life of more than 40 hours at 940°C and 200MPa.

Deformed high-temperature alloys mainly provide structural forgings, cakes, rings, bars, plates, pipes, strips and wires for the aerospace, aviation, nuclear energy, and petroleum civil industries.

2. Cast high-temperature alloys

Casted high-temperature alloys refer to a type of high-temperature alloys that can or can only be formed by casting methods. Its main features are:

1. It has a wider composition range. Since there is no need to take into account its deformation processing performance, the design of the alloy can focus on optimizing its performance. For example, for nickel-based high-temperature alloys, the composition can be adjusted so that the γ' content reaches 60% or higher, so that the alloy can still maintain excellent properties at temperatures up to 85% of the melting point of the alloy.

2. It has a wider application field. Due to the special advantages of the casting method, high-temperature alloys with nearly net shape or no margin can be designed and manufactured with any complex structure and shape according to the needs of the parts. casting.

According to the service temperature of casting alloys, they can be divided into the following three categories:

The first category: equiaxed crystal casting high-temperature alloys used at -253~650℃. It has good comprehensive properties within a wide range of temperatures, especially at low temperatures, where both strength and plasticity are maintained without deterioration. For example, K4169 alloy, which is used in large quantities in aviation and aerospace engines, has a tensile strength of 1000MPa at 650°C, a yield strength of 850MPa, and a tensile plasticity of 15%; the endurance life under 620MPa stress at 650°C is 200 hours. It has been used to make diffuser casings in aerospace engines and complex structural parts for various pumps in aerospace engines.

The second category: equiaxed crystal cast high-temperature alloys used at 650 to 950 ℃. This type of alloy has high mechanical properties and hot corrosion resistance at high temperatures. For example, K419 alloy has a tensile strength greater than 700MPa and a tensile plasticity greater than 6% at 950°C; at 950°C, the ultimate strength limit for 200 hours is greater than 230MPa. This type of alloy is suitable for use in aero-engine turbine blades, guide vanes and integrally cast turbines.

The third category: directionally solidified columnar crystal and single crystal high-temperature alloys used at 950 to 1100°C. This type of alloy has excellent comprehensive properties and oxidation resistance and hot corrosion resistance in this temperature range. For example, DD402 single crystal alloy has a durable life of more than 100 hours under a stress of 1100°C and 130MPa. This is the hottest turbine blade material used in China and is suitable for making first-stage turbine blades for new high-performance engines.

With the continuous improvement of precision casting technology, new special processes are also emerging. Fine-grain casting technology, directional solidification technology, and CA technology for complex thin-walled structural parts have greatly improved the level of casting high-temperature alloys, and their application scope has continued to increase.

3. Powder metallurgy high-temperature alloys

Using atomized high-temperature alloy powder, hot isostatic pressing or hot isostatic pressing and then forging to produce high-temperature alloys Powder product. Using the powder metallurgy process, due to the small powder particles and fast cooling speed, the composition is uniform, no macrosegregation, and the grains are small, the hot processing performance is good, the metal utilization rate is high, and the cost is low, especially the yield strength and fatigue properties of the alloy are improved. Big improvement.

FGH95 powder metallurgy superalloy has a tensile strength of 1500MPa at 650°C and a durable life of more than 50 hours under 1034MPa stress. It is currently the highest strength plate powder metallurgy superalloy under 650°C working conditions. Powder metallurgy high-temperature alloys can meet the requirements of engines with higher stress levels and are the materials of choice for high-temperature components such as turbine disks, compressor disks and turbine baffles in engines with high thrust-to-weight ratios.

4. Oxide Dispersion Strengthened (ODS) Alloy

It adopts a unique mechanical alloying (MA) process. Ultra-fine (less than 50nm) has ultra-stable properties at high temperatures. The oxide dispersion strengthening phase is evenly dispersed in the alloy matrix to form a special high-temperature alloy. Its alloy strength can still be maintained under conditions close to the melting point of the alloy itself, and has excellent high-temperature creep properties, superior high-temperature oxidation resistance, carbon and sulfur corrosion resistance.

There are currently three main types of ODS alloys that have been commercially produced:

MA956 alloy can be used at temperatures up to 1350°C in an oxidizing atmosphere, ranking among the highest temperature alloys in terms of resistance to oxidation, carbon, and sulfur. First place in corrosion. Can be used for lining the combustion chamber of aircraft engines.

MA754 alloy can be used at temperatures up to 1250°C in an oxidizing atmosphere and maintains very high high-temperature strength and resistance to medium-alkali glass corrosion. It is now used to make aero-engine guide rings and guide blades.

MA6000 alloy has a tensile strength of 222MPa and a yield strength of 192MPa at 1100°C; at 1100°C, the 1000-hour endurance strength is 127MPa, ranking first among high-temperature alloys and can be used for aircraft engine blades.

5. Intermetallic compound high-temperature materials

Intermetallic compound high-temperature materials are a type of light-specific high-temperature materials that have been recently researched and developed and have important application prospects. Over the past decade, basic research on intermetallic compounds, alloy design, process development and application research have matured, especially in the preparation and processing technology, toughening and strengthening of Ti-Al, Ni-Al and Fe-Al series materials. , mechanical properties and application research have made remarkable achievements.

Ti3Al-based alloy (TAC-1), TiAl-based alloy (TAC-2) and Ti2AlNb-based alloy have low density (3.8~5.8g/cm3), high temperature and high strength, high steel and excellent resistance. The advantages of oxidation and creep resistance can reduce the weight of structural parts by 35 to 50%. Ni3Al-based alloy, MX-246 has good corrosion resistance, wear resistance and cavitation resistance, showing excellent application prospects. Fe3Al-based alloy has good oxidation and wear resistance, high strength at medium temperatures (less than 600°C), and low cost. It is a new material that can partially replace stainless steel.