首页|期刊导航|无机材料学报|化学气相渗透2D SiC/SiC窄带随机振动疲劳损伤与性能退化

化学气相渗透2D SiC/SiC窄带随机振动疲劳损伤与性能退化OA

2D SiC/SiC Manufactured by Chemical Vapor Infiltration:Narrow Band Random Vibration Fatigue Damage and Performance Degradation

中文摘要英文摘要

随着航空发动机热端部件对高温性能与轻量化的要求日益严苛,SiC/SiC复合材料凭借其优异的耐高温性、低密度和耐腐蚀性,成为极具应用潜力的替代材料.然而,其服役过程中不可避免地承受复杂振动载荷,振动引发的疲劳损伤已成为限制其工程应用的关键问题.本工作采用化学气相渗透法制备了 2D SiC/SiC板材,并加工成两侧具有圆弧状缺口的试样,在一阶振型下开展了窄带随机振动疲劳试验,系统揭示其损伤演化过程及拉伸性能退化规律.研究结果表明,随着等效应力增大,2D SiC/SiC板结构的归一化全时域曲线整体向下偏移,低应力区的响应表现出显著的分散性.基于微结构图像分析,2D SiC/SiC板结构的损伤演化可分为基体损伤、界面损伤和纤维损伤三个阶段,损伤速率呈现快-慢-快的变化趋势.残余拉伸性能结果表明,2D SiC/SiC板结构的拉伸性能呈指数型下降趋势,当共振频率降幅为 31.9%时,其拉伸强度、比例极限应力、弹性模量和回弹模量分别下降至 270.0 MPa、64.1 MPa、106.3 GPa和 0.020 MJ/m3,均不足制备态性能的 70%.拉伸断口形貌分析表明,基体裂纹和纤维磨损是导致拉伸性能退化的关键因素.本研究为评估 2D SiC/SiC板结构在振动环境下的服役可靠性提供了重要依据和实验支撑.

Under demanding service conditions,the operational requirements,namely high-temperature performance and structural weight reduction,in aero-engine hot section components continue to intensify.Silicon carbide fiber reinforced silicon carbide matrix(SiC/SiC)composites are widely recognized as exceptionally promising alternative materials owing to their outstanding high-temperature stability,substantially reduced density and superior corrosion resistance.However,in actual service environments,these composites inevitably experience complex vibrational loading spectra,which induce fatigue damage accumulation emerging as a critical limiting factor in their practical engineering implementation.In this study,2D SiC/SiC plates were fabricated by chemical vapor infiltration.Specimens featuring bilateral arc-shaped notches were machined from the plates and subsequently subjected to narrow band random vibration fatigue tests under the first-order vibration mode.This experimental approach was undertaken specifically to investigate the progressive damage evolution process and the accompanying degradation patterns in tensile properties under vibrational fatigue loading.The experimental findings reveal that the normalized full time-domain characteristic curves of the 2D SiC/SiC plate structures exhibit progressive downward displacement while the applied equivalent stress amplitude increases.These curves concurrently manifest pronounced statistical dispersion throughout low-stress loading regime.Based on microstructural analyses,the damage evolution within the 2D SiC/SiC plate structure can be classified into three distinct and sequential stages:the initial matrix damage stage,the subsequent interface damage stage,and the final fiber damage stage.Quantitatively,the damage progression rate follows a distinct correlated three stage evolution—commencing with rapid progression,then transitioning to reduced propagation velocity,and lastly culminating in accelerated damage advancement.Residual tensile properties demonstrate that the tensile characteristics of the 2D SiC/SiC plate structure follow an exponential decline trend.At a resonance frequency reduction of 31.9%,the tensile strength,proportional limit stress,elastic modulus,and resilience modulus have degraded to 270.0 MPa,64.1 MPa,106.3 GPa,and 0.020 MJ/m3,respectively,all falling below 70%of the corresponding values in the as-fabricated pristine state.Subsequent analyses of the tensile fracture surface reveal matrix cracking and pronounced fiber wear as the dominant damage mechanisms responsible for the significant degradation observed in the tensile properties of the vibration fatigued composite structure.These findings provide a critical experimental basis for assessing the service reliability of 2D SiC/SiC plate structures under vibrational service conditions.

刘明扬;王纯;程鹏飞;马雪寒;高祥云;由博杰;赵录峰;成来飞;张毅

西北工业大学 超高温结构复合材料重点实验室,西安 710072中国飞机强度研究所,西安 710065中国飞机强度研究所,西安 710065西北工业大学 超高温结构复合材料重点实验室,西安 710072西安航空制动科技有限公司,西安 713106西北工业大学 超高温结构复合材料重点实验室,西安 710072西安鑫垚陶瓷复合材料股份有限公司,西安 710051西北工业大学 超高温结构复合材料重点实验室,西安 710072||西安鑫垚陶瓷复合材料股份有限公司,西安 710051西北工业大学 超高温结构复合材料重点实验室,西安 710072

通用工业技术

2D SiC/SiC随机振动疲劳损伤等效应力拉伸性能

2D SiC/SiCrandom vibrationfatigue damageequivalent stresstensile property

《无机材料学报》 2026 (3)

349-358,中插6,11

10.15541/jim20250184

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