孔挤压对于高温合金GH4169孔结构高温疲劳性能的影响

王欣; 胡仁高; 胡博; 赵振业; 罗学昆; 古远兴; 宋颖刚

doi:10.13224/j.cnki.jasp.2017.01.013

孔挤压对于高温合金GH4169孔结构高温疲劳性能的影响

doi: 10.13224/j.cnki.jasp.2017.01.013

1.
中国航空发动机集团有限公司北京航空材料研究院表面工程研究所，北京 100095
2.
中国航空发动机集团有限公司四川燃气涡轮研究院强度技术研究室，成都 610500

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出版历程
- 收稿日期: 2015-08-12
- 刊出日期: 2017-01-28

Effect of holeexpansion on hightemperature fatigue property of GH4169 superalloy hole structure

摘要

摘要: 根据高压压气机盘螺栓孔结构，设计中心孔板材疲劳试样.表征了孔挤压强化后的表面轮廓，分析了在多种交变载荷条件下孔挤压前后试样的疲劳寿命，并进行了断口观察和疲劳过程中孔挤压残余应力的演化分析.结果表明:孔挤压强化减小了孔壁表面粗糙度，并使孔结构在多种高温大应力条件下（825MPa/600℃、825MPa/400℃和663MPa/600℃）的高温疲劳性能提高1～3倍，但疲劳数据分散度略有增大.孔挤压残余应力在最大拉应力为663MPa，温度为600℃，应力比为01条件下20000次疲劳试验中松弛到60%.原始试样的多源疲劳断口主要起源于孔边的加工刀痕，而挤压强化试样断口起源于孔挤压在倒角区域流动金属堆积处，为单源疲劳断口.
- 高温合金 /
- 螺栓孔 /
- 孔挤压（HE） /
- 应力集中 /
- 残余应力 /
- 高温疲劳性能
Abstract: Fatigue specimen with central hole was designed based on the bolthole of a high pressure compressor disk. Of the asreceived (AR) specimens and after holeexpansion (HE), the surface profile and fatigue property in multiple alternating loads were characterized; moreover, failure analysis and the evolution of HE residual stress profile during fatigue cycle were investigated. Results showed that, after HE, the roughness of hole wall decreased, besides, the high temperature fatigue performances improved 1-3 times under multiple large load condition with the slight rise of fatigue data dispersion. The HE residual stress released to 60% during 20000 cycles at the maximum tensile stress of 663MPa,temperature of 600℃ and stress ratio of 01. Compared with the untreated specimens nucleating at machining marks, the HE crack initiated at metal accumulation by HE in the chamfer, presenting single source crack initiations.
- superalloy /
- bolthole /
- holeexpansion (HE) /
- stress concentration /
- residual stress /
- hightemperature fatigue property

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