Development and Turbine Engine Performance of Three Advanced Rhenium Containing Superalloys for Single Crystal and Directionally Solidified Blades and Vanes
Author:
Broomfield R. W.1, Ford D. A.1, Bhangu J. K.1, Thomas M. C.2, Frasier D. J.2, Burkholder P. S.2, Harris K.3, Erickson G. L.3, Wahl J. B.3
Affiliation:
1. Rolls-Royce plc, Elton Road Materials Center, P. O. Box 31, Derby and Bristol, U. K 2. Allison Engine Company (Rolls-Royce plc), Indianapolis, IN 3. Cannon-Muskegon Corporation, SPS Technologies, Inc., Muskegon, MI
Abstract
Turbine inlet temperatures over the next few years will approach 1650°C (3000°F) at maximum power for the latest large commercial turbofan engines, resulting in high fuel efficiency and thrust levels approaching 445 KN (100,000 lbs.). High reliability and durability must be intrinsically designed into these turbine engines to meet operating economic targets and ETOPS certification requirements. This level of performance has been brought about by a combination of advances in air cooling for turbine blades and vanes, design technology for stresses and airflow, single crystal and directionally solidified casting process improvements, and the development and use of rhenium (Re) containing high γ′ volume fraction nickel-base superalloys with advanced coatings, including full-airfoil ceramic thermal barrier coatings. Re additions to cast airfoil superalloys not only improves creep and thermo-mechanical fatigue strength, but also environmental properties including coating performance. Re dramatically slows down diffusion in these alloys at high operating temperatures. A team approach has been used to develop a family of two nickel-base single crystal alloys (CMSX-4® containing 3 percent Re and CMSX®-10 containing 6 percent Re) and a directionally solidified, columnar grain nickel-base alloy (CM 186 LC® containing 3 percent Re) for a variety of turbine engine applications. A range of critical properties of these alloys is reviewed in relation to turbine component engineering performance through engine certification testing and service experience. Industrial turbines are now commencing to use this aero developed turbine technology in both small and large frame units in addition to aero-derivative industrial engines. These applications are demanding, with high reliability required for turbine airfoils out to 25,000 hours, with perhaps greater than 50 percent of the time spent at maximum power. Combined cycle efficiencies of large frame industrial engines are scheduled to reach 60 percent in the U. S. ATS programme. Application experience to a total 1.3 million engine hours and 28,000 hours individual blade set service for CMSX-4 first stage turbine blades is reviewed for a small frame industrial engine.
Publisher
ASME International
Subject
Mechanical Engineering,Energy Engineering and Power Technology,Aerospace Engineering,Fuel Technology,Nuclear Energy and Engineering
Reference45 articles.
1. Bachelet, E., and Lamanthe, G., 1986, National Symposium—Single Crystal Superalloys, Viallard-de-Lans, France. 2. Blavette, D., Caron, P., and Khan, T., Scripta Met, Vol. 20, No. 10. 3. Blavette, D., Caron, P., and Khan, T., “An Atom-Probe Study of Some Fine Scale Microstructural Features in Ni-Base Single Crystal Superalloy,” 6th International Symposium, TMS, Warrendale, PA, pp. 305–314. 4. Brentnall, W. D., Aurrecoechea, J. M., Rimlinger, C. M., Harris, K., Erickson, G. L., Wahl, J. B., 1997, “Extensive Industrial Gas Turbine Experience With Second Generation Single Crystal Alloy Turbine Blades,” ASME (IGTI) Turbo Expo ’97, ASME, NY. 5. Burkholder, P. S., Thomas, M. C., Frasier, D. J., Whetstone, J. R., Harris, K., Erickson, G. L., Sikkenga, S. L., and Eridon, J. M., 1995, “Allison Engine Testing CMSX-4 Single Crystal Turbine Blades and Vanes,” IOM 3rd International Charles Parsons Turb. Conf. Proc.,
Cited by
27 articles.
订阅此论文施引文献
订阅此论文施引文献,注册后可以免费订阅5篇论文的施引文献,订阅后可以查看论文全部施引文献
|
|