Thermal Strain Fatigue Modeling of a Matrix Alloy for a Metal Matrix Composite

G. Halford, B. Lerch, V. K. Arya
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引用次数: 3

Abstract

The Total Strain Version of the method of Strainrange Partitioning was used as the basis for modeling the thermomechanical fatigue resistance of the matrix material of the metal matrix composite, SCS-6/Ti-15-3. As prescribed by the model, the resistance was assessed through the use of bithermal creep-fatigue experiments. Bithermal temperatures of 205 and 427°C were imposed. A minimal number of strain limit-controlled, in-phase PP (pure fatigue, no creep) and CP (tensile creep) as well as out-of-phase PP (pure fatigue, no creep) and PC (compressive creep) experiments were conducted on conventional, axially-loaded, cylindrical-bar specimens. Inelastic strain range versus cyclic life curves for each of the Strainrange Partitioning bithermal cycles were evaluated and found to be nominally coincident. Cyclic elastic strain range versus inelastic strain range curves as well as elastic strain range versus life curves were documented for pure-fatigue and creep-fatigue conditions. The time-dependencies of these relationships were calibrated with the available data. These results enable the construction of total strain range versus fatigue life curves for thermomechanical fatigue for in- and out-of-phasing and for any arbitrary creep-time per cycle. Results are applicable to the cyclic life prediction of metal matrix composites using the Ti-15-3 matrix material.
金属基复合材料基体合金的热应变疲劳建模
采用应变范围划分法的总应变版本作为模拟金属基复合材料SCS-6/Ti-15-3基体材料的热疲劳抗力的基础。根据模型的规定,通过热蠕变疲劳试验来评估其阻力。施加205°C和427°C的双温温度。在常规轴向加载的圆柱杆试件上进行了应变极限控制的同相PP(纯疲劳、无蠕变)、CP(拉伸蠕变)、非相PP(纯疲劳、无蠕变)和PC(压缩蠕变)试验。评估了每个应变范围分配双热循环的非弹性应变范围与循环寿命曲线,发现它们在名义上是一致的。在纯疲劳和蠕变疲劳条件下,记录了循环弹性应变范围与非弹性应变范围曲线以及弹性应变范围与寿命曲线。这些关系的时间依赖性是用现有数据校准的。这些结果使得构建总应变范围与疲劳寿命曲线的热机械疲劳在同相和非同相和任何任意蠕变时间每周期。研究结果适用于Ti-15-3基复合材料的循环寿命预测。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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