一种第四代镍基单晶高温合金的同相位热机械疲劳行为及损伤机制

doi:10.11900/0412.1961.2022.00309

金属学报

2024, Vol. 60

Issue (2): 154-166 DOI: 10.11900/0412.1961.2022.00309

研究论文

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一种第四代镍基单晶高温合金的同相位热机械疲劳行为及损伤机制

谭子昊¹^,², 李永梅¹^,², 王新广¹(

), 赵浩川³, 谭海兵³, 王标³, 李金国¹, 周亦胄¹, 孙晓峰¹(

)

1 中国科学院金属研究所师昌绪先进材料创新中心沈阳 110016
2 中国科学技术大学材料科学与工程学院沈阳 110016
3 中国航发四川燃气涡轮研究院成都 610500

In-Phase Thermal-Mechanical Fatigue Behavior and Damage Mechanism of a Fourth-Generation Ni-Based Single-Crystal Superalloy

TAN Zihao¹^,², LI Yongmei¹^,², WANG Xinguang¹(

), ZHAO Haochuan³, TAN Haibing³, WANG Biao³, LI Jinguo¹, ZHOU Yizhou¹, SUN Xiaofeng¹(

)

1 Shi -changxu Innovation Center for Advanced Materials, Institute of Metal Research, Chinese Academy of Sciences, Shenyang 110016, China
2 School of Materials Science and Engineering, University of Science and Technology of China, Shenyang 110016, China
3 Institute of Sichuan Gas Turbine Research, Aero Engine Corporation of China, Chengdu 610500, China

引用本文:

谭子昊, 李永梅, 王新广, 赵浩川, 谭海兵, 王标, 李金国, 周亦胄, 孙晓峰. 一种第四代镍基单晶高温合金的同相位热机械疲劳行为及损伤机制[J]. 金属学报, 2024, 60(2): 154-166.
Zihao TAN, Yongmei LI, Xinguang WANG, Haochuan ZHAO, Haibing TAN, Biao WANG, Jinguo LI, Yizhou ZHOU, Xiaofeng SUN. In-Phase Thermal-Mechanical Fatigue Behavior and Damage Mechanism of a Fourth-Generation Ni-Based Single-Crystal Superalloy[J]. Acta Metall Sin, 2024, 60(2): 154-166.

全文: PDF(5938 KB) HTML

摘要:

热机械疲劳是单晶高温合金在实际服役过程中的一种重要损伤模式，澄清合金的热机械疲劳行为及损伤机制对于提升单晶高温合金的服役可靠性具有重要意义。本工作以先进航空发动机高压涡轮叶片用第四代单晶高温合金DD91为对象，采用SEM、EBSD、TEM等手段研究了合金在600~1000℃下的同相位热机械疲劳断裂特征及损伤机理。结果表明，随应变幅的升高，合金的疲劳寿命大幅下降，迟滞曲线明显张开，且应力响应行为由高温半周循环软化和低温半周循环硬化转变为以循环稳定为主导的特征。在不同应变幅下疲劳断裂后，合金断口呈韧性断裂特征，随应变幅的升高，韧窝区面积分数不断下降。在低应变幅下，合金主要承受氧化损伤，并伴随一定程度的蠕变损伤，合金的主要变形机制为位错在γ基体中滑移，并以Orowan机制绕过γ'强化相；而在高应变幅下，合金承受严重的塑性变形损伤而氧化损伤程度减轻，此时界面位错能够以生成层错或反相畴界的形式切割γ'相。另外，合金在不同应变幅下循环至断裂后，均未出现再结晶晶粒和变形孪晶。

关键词 ：第四代单晶高温合金, 热机械疲劳, 断裂特征, 氧化行为, 损伤机制

Abstract：

During the service, the turbine blades of aero-engines are subjected to a complex and ever-changing combination of temperature and stress, resulting in severe cyclic temperature/strain damages and thermal-mechanical fatigue (TMF) failures of the alloy. In this work, in-phase (IP) TMF tests under 600-1000^oC were conducted on a newly developed fourth-generation single-crystal superalloy. The alloy's fracture characteristics and comprehensive damage mechanisms were examined via SEM, EBSD, and TEM. The results showed that when the strain range increased, the fatigue life of the experimental alloy noticeably decreased, and the hysteresis loop clearly opened. Stress response behaviors shifted from cyclic softening at high temperatures and cyclic hardening at low temperatures into a dominant characteristic of cyclic stabilizing. The fracture surfaces of alloys displayed ductile features after fatigue fracture under various circumstances, and the area fraction of dimples reduced with increasing strain amplitude. When the strain amplitude was low, the alloy was mainly subjected to oxidation damage, accompanied with a certain degree of creep damage. In contrast, the dominant deformation mechanism of the alloy was dislocation slipping in γ matrix and Orowan by-passing through γ' particles. As the strain amplitude increased to higher levels, the alloy was subjected to severe plastic deformation damage, while the degree of oxidation damage had been alleviated. Under this condition, the interfacial dislocations could shear into the γ' phase with the generated stacking fault or anti-phase boundary. Notably, no recrystallization grains or deformation twins were formed in the DD91 alloy during the IP-TMF experiments at different mechanical strain amplitudes.

Key words： fourth-generation single-crystal superalloy thermal-mechanical fatigue fracture characteristic oxidation behavior damage mechanism

收稿日期: 2022-06-22

ZTFLH:

TG132.32

基金资助:国家科技重大专项项目(2017-VI-0002-0072);国家重点研发计划项目(2017YFA0700704);中国科学院青年创新促进会项目

通讯作者: 王新广，xgwang11b@imr.ac.cn，主要从事单晶高温合金设计与应用研究;
孙晓峰，xfsun@imr.ac.cn，主要从事铸造高温合金研发与工程化应用研究

Corresponding author: WANG Xinguang, professor, Tel: (024)23971887, E-mail: xgwang11b@imr.ac.cn;
SUN Xiaofeng, professor, Tel: (024)23971807, E-mail: xfsun@imr.ac.cn

作者简介: 谭子昊，男，1994年生，博士生

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	谭子昊
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	孙晓峰
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链接本文:

https://www.ams.org.cn/CN/10.11900/0412.1961.2022.00309 或 https://www.ams.org.cn/CN/Y2024/V60/I2/154

图1 DD91合金标准热处理流程图

图2 热机械疲劳试样尺寸示意图

图3 DD91合金标准热处理后的γ /γ'两相组织

图4 DD91合金在不同应变幅下的同相位热机械疲劳(IP-TMF)循环应力响应曲线

图5 DD91合金在不同应变幅IP-TMF过程第1 cyc及循环稳定时的迟滞回线

图6 DD91合金在不同应变幅IP-TMF断裂后纵截面((011)面)的SEM像

图7 DD91合金在不同应变幅下IP-TMF失效断裂后的表面裂纹形貌及对应的反极图(IPF)、局部取向差(KAM)和晶内参考取向差(GROD)图

图8 DD91合金在不同应变幅下IP-TMF失效断裂后的断口形貌

图9 DD91合金IP-TMF断口外表面形貌及表面氧化产物分布特征

图10 DD91合金在0.5%和0.8%应变幅IP-TMF疲劳断裂后表面EDS分析

图11 DD91合金在不同应变幅下IP-TMF断裂后的特征位错组态

表1 DD91合金在不同应变幅下IP-TMF断裂后的外表面最长裂纹尺寸及内部裂纹数量

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