High Temperature Nickel-Based Superalloys for Turbine Discs: Part One

요약:

Nickel-Based superalloys are an unusual class of metallic materials with an exceptional combination of high temperature strength, toughness, and resistance to degradation in corrosive or oxidizing environments.
The operating temperatures for the rim sections (near the gas flow path) of high-pressure turbine discs have continued to challenge materials and design engineers as temperatures now approach 760°C and even as high as 815°C for some specialized military applications.

Nickel-Based superalloys are an unusual class of metallic materials with an exceptional combination of high temperature strength, toughness, and resistance to degradation in corrosive or oxidizing environments. These materials are widely used in aircraft and power-generation turbines, rocket engines, and other challenging environments, including nuclear power and chemical processing plants.

Intensive alloy and process development activities during the past few decades have resulted in alloys that can tolerate average temperatures of 1050°C with occasional excursions (or local hot spots near airfoil tips) to temperatures as high as 1200°C, which is approximately 90% of the melting point of the material. The underlying aspects of microstructure and composition that result in these exceptional properties are briefly reviewed here. Major classes of superalloys that are utilized in gas-turbine engines and the corresponding processes for their production are outlined along with their characteristic mechanical and physical properties.

As mentioned above, one of the main applications for nickel-based superalloys is gas-turbine-engine disc components for land-based power generation and aircraft propulsion. Turbine engines create harsh environments for materials due to the high operating temperatures and stress levels. Hence, as described in this article, many alloys used in the high-temperature turbine sections of these engines are very complex and highly optimized.

Gas turbines are complex machines, being employed in both aircraft engines or land-based power-generation applications. Small, intermediate, and large gas turbines are being developed rapidly for mobile land-based power units and large commercial aircraft applications.

The various parts within this type of power-generation system have specific and unique requirements. For example, the material used for the high-pressure turbine area of an engine reach the highest temperatures and is therefore one of the highest stressed parts of the engine, requiring very specialized nickel-based superalloy materials. The operating temperatures for the rim sections (near the gas flow path) of high-pressure turbine discs have continued to challenge materials and design engineers as temperatures now approach 760°C and even as high as 815°C for some specialized military applications. Turbine blades are attached to a disc which in turn is connected to the turbine shaft. The properties required for an aeroengine disc (Figure1) are different from that of a turbine, because the metal is subjected to a lower temperature. The discs must resist fracture by fatigue. Discs are usually cast and then forged into shapeand are typically polycrystalline.



Figure 1: Powder metallurgical aeroengine disc

One difficulty is that cast alloys have a large columnar grain structure and contain significant chemical segregation; the latter is not completely eliminated in the final product. This can lead to scatter in mechanical properties. One way to overcome this is to begin with fine, clean powder which is then consolidated.

The powder is made by atomisation in an inert gas; the extent of chemical segregation cannot exceed the size of the powder. After atomisation, Some discs are made from powder which is hot-isostatically pressed, extruded and then forged into the required shape.

The process is difficult because of the need to avoid undesired particles being introduced, for example, from the refractories used in the atomisation process, or impurities picked up during solidification. Such particles initiate fatigue and of courser, the failure of an aeroengine turbine disc can be catastrophic.

Table 1: The chemical compositions of Several Superalloys (wt.%)

In addition to the high temperature concerns, materials for modern turbine applications are driven by ever-growing commercial pressures. These pressures can be seen as demands rise for lower component costs, life-cycle costs, and maintenance costs. For lower acquisition costs, avenues such as alloys with reduced cobalt and alloys that result in higher processing yields are being pursued.

For lower life-cycle costs, alloys are being designed with longer service lives. Alloys with good stability and very low crack-growth rates that are easily inspected and monitored by nondestructive means are desired. Fuel efficiency and emissions are also key commercial and environmental drivers impacting turbine-engine materials. To meet these demands, modern nickel-based alloys offer an efficient compromise between performance and economics. The chemistries of several common and advanced nickel-based superalloys are listed in Table 1.

기술 자료 검색

검색할 어구를 입력하십시오:

검색 범위

본문
키워드

머릿글
요약

이 문서는 전체 문서 중 일부분입니다. 이 주제에 대해 더 읽고 싶으시면 아래 링크를 클릭하시면 됩니다.

Total Materia는 다양한 나라와 규격에 따른 수천개의 니켈 재질에 대한 정보를 포함하고 있습니다.

재질의 화학적 조성, 기계적 특성, 물리적 특성, 고급 물성 데이터 등의 전체적인 특성 정보들을 어디서든 검토하실 수 있습니다.

고급 검색을 이용하여, 검색 조건의 재질 리스트에서 '니켈'을 선택합니다. 검색 범위 좀 더 줄이기를 원하신다면 국가/규격과 같은 다른 조건을 지정할 수 있습니다.

검색 버튼을 클릭합니다.


선택된 정보에 부합하는 일련의 재질이 검색됩니다.


결과 리스트에서 재질을 선택하시면, 일련의 규격 사양 소그룹이 나타납니다.

여기에서 선택한 재질의 특정 특성 데이터를 검토하실 수도 있고, 강력한 상호 참조 표를 이용하여 유사 재질이나 등가 재질을 검토하는 것 또한 가능합니다.


자세한 특성 데이터를 보시려면 특성 데이터 링크를 클릭하세요.


Total Materia 데이터베이스를 사용해 보실 수 있는 기회가 있습니다. 저희는 Total Materia 무료 체험을 통해 150,000명 이상의 사용자가 이용하고 있는 커뮤니티로 귀하를 초대합니다.