具有热解碳界面的SiCf/SiC陶瓷基复合材料在空气中的高温循环疲劳

IF 1.1 4区工程技术 Q4 Engineering

High Temperatures-high Pressures Pub Date : 2021-01-01 DOI:10.32908/HTHP.V50.1079

K. Kim, Kyoon Choi, Yoonsoo Han, S. Nahm, Sung-Min Lee

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引用次数: 1

摘要

对SiCf/SiC陶瓷基复合材料在1400℃下进行了循环疲劳试验，并与单调拉伸试验进行了对比。试样采用热解碳界面层制备，通过化学蒸汽渗透致密化。在1400℃的单调拉伸试验中，试样在0.35%的应变下断裂，比例极限应力为175 MPa，表现为典型的纤维拉拔。然而，经过长时间的循环试验，将应力从65 MPa增加到95 MPa，试样脆性断裂，几乎没有纤维拔出。断口微观组织分析表明，随断口位置不同，裂纹氧化程度不同，表明裂纹在循环疲劳试验中扩展。透射电镜分析表明，在循环试验后期，热解碳界面层被氧化去除，纤维与基体两侧形成氧化层，导致纤维与基体界面较强，在1400℃循环试验时发生脆性断裂。

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High-temperature cyclic fatigue in air of SiCf/SiC ceramic matrix composite with a pyrolytic carbon interface

A cyclic fatigue test of SiCf/SiC ceramic matrix composites was conducted at 1400°C and compared to the monotonic tensile test. The specimens were prepared with an interface layer of pyrolytic carbon and densified through chemical vapor infiltration. In the monotonic tensile test, at 1400°C, the specimen fractured at a strain of 0.35% with a proportional limit stress of 175 MPa, showing a typical fiber pull-out. However, after a prolonged cyclic test with increasing stresses from 65 to 95 MPa, the specimen fractured brittlely with almost no fiber pull-out. The microstructure analysis of the fracture surface showed different oxidation levels with respect to fracture locations, indicating that the crack propagated during the cyclic fatigue test. Transmission electron microscopy analysis revealed that the interface layer of pyrolytic carbon was removed by oxidation and oxide layers were formed on both sides of the fiber and matrix at the later stage of the cyclic test, resulting in a strong interface between the fibers and matrix and brittle fracture during the cyclic test at 1400°C.

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来源期刊

High Temperatures-high Pressures THERMODYNAMICS-MECHANICS

CiteScore

1.00

自引率

9.10%

发文量

期刊介绍： High Temperatures – High Pressures (HTHP) is an international journal publishing original peer-reviewed papers devoted to experimental and theoretical studies on thermophysical properties of matter, as well as experimental and modelling solutions for applications where control of thermophysical properties is critical, e.g. additive manufacturing. These studies deal with thermodynamic, thermal, and mechanical behaviour of materials, including transport and radiative properties. The journal provides a platform for disseminating knowledge of thermophysical properties, their measurement, their applications, equipment and techniques. HTHP covers the thermophysical properties of gases, liquids, and solids at all temperatures and under all physical conditions, with special emphasis on matter and applications under extreme conditions, e.g. high temperatures and high pressures. Additionally, HTHP publishes authoritative reviews of advances in thermophysics research, critical compilations of existing data, new technology, and industrial applications, plus book reviews.