Elevated Temperature Fatigue of Continuous Fiber Reinforced Ti-alloy Matrix Composites SCS-6/SP700(Composite 1)
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概要
- 論文の詳細を見る
Continuous fiber reinforced metal matrix composites (MMCs) have been researched and developed because of both high specific strength and high temperature capability and various trial high temperature structural components have been successfully fabricated in the field of aeronautics, aerospace and power generation industries. However, there is the limited number of research for long-term durability performance at practical use temperature ranges in comparison with the static strength characteristics. The final goal of this research is to establish the fatigue damage tolerance design concepts for continuous fiber partially reinforced Ti-alloy matrix composite (TMCs) rotating parts in aircraft engines. This paper summarizes the elevated temperature low cycle fatigue behavior for Ti-alloy matrix composites.
- 一般社団法人日本機械学会の論文
- 2001-10-20
著者
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Noda Minoru
R&d Institute Of Metals And Composites For Future Industries
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Hirano Kazumi
National Institute Of Advanced Industrial Science And Technology Meti.
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Hirano Kazumi
National Institute Of Advanced Industrial Science And Technology (aist)
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NAKAYAMA Hirotoshi
Japan Ultra-high Temperature Materials Research Institute
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YAMADA Takeshi
Mitsubishi Heavy Industries, Ltd.
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HIRA Hirohito
Kawasaki Heavy Industries, Ltd.
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NODA Minoru
R&D Institute of Metals and Composites for Future Industries
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Hira Hirohito
Kawasaki Heavy Industries Ltd.
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Yamada Takeshi
Mitsubishi Heavy Industries Ltd.
関連論文
- Moisture Absorption Effects on Open-Hole Fully-Reversed Tension-Compression Fatigue Damage Tolerance of High Temperature Polymer Matrix Composites
- Comparisons of Open-Hole Fatigue Strength Characteristics between Candidate High Temperature Polymer Matrix Composites for the Next Generation Aircraft(Composite 1)
- Elevated Temperature Fatigue of Continuous Fiber Reinforced Ti-alloy Matrix Composites SCS-6/SP700(Composite 1)
- SB-04-3(103) High Temperature Fatigue and Creep Behavior of TiB_2 Particulate Reinforced Titanium Aluminide Intermetallic Matrix Composites(Intermetallics and Its Composites)