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氧化铝纤维增强二氧化硅复合材料力学性能失效研究OA

Mechanical Property Failure of Alumina Fiber Reinforced Silica Composite

中文摘要英文摘要

连续氧化铝纤维增强二氧化硅陶瓷基复合材料具有优异的高温抗氧化性、高强度、高韧性等特性,作为一种军民两用材料,广泛应用于航空、航天、能源等领域.但国内相关研究尚处于起步阶段,对其力学性能失效机制认识不足.本研究综合溶胶-凝胶法和浆料浸渍法的工艺特点,采用改进的液相浸渍法,成功制备了孔隙率可调控的连续氧化铝纤维增强二氧化硅复合材料.通过多种技术手段全面表征了典型复合材料的微观形貌和成分组成,并测试分析了不同致密程度复合材料的力学性能.结合计算机断层扫描(CT)测试获得的复合材料孔隙率,通过模拟仿真计算,建立了连续氧化铝纤维增强二氧化硅复合材料力学性能失效与孔隙率及孔隙尺寸的关系模型.研究结果表明,采用改进的液相浸渍法制备的复合材料因孔隙缺陷和弱界面结合的影响,其力学性能显著提升.同时,随着复合材料孔隙率由 2.2%增大到 15.2%,其拉伸强度由 24.5 MPa降低至 17.8 MPa.进一步建模仿真分析显示,当孔隙缺陷半径为250 μm时,孔隙率由4.5%增大至13.5%,拉伸强度从27.2 MPa降低至20.6 MPa,这验证了仿真模型的合理性,揭示了拉伸强度的n次方与孔隙率呈负线性关系,拉伸强度指数因子n与缺陷半径r呈负线性关系.本研究为连续氧化铝纤维增强二氧化硅复合材料的性能优化和实际应用提供了研究基础.

Continuous alumina fiber-reinforced silica ceramic matrix composites exhibit excellent properties,such as high-temperature oxidation resistance,high strength and high toughness.As a dual-use material for both military and civilian applications,they hold broad prospects in numerous fields,including aviation,aerospace and energy.However,domestic research currently still remains on its initial stage and is characterized by a primarily qualitative understanding of their mechanical property failure mechanisms.In this study,an improved liquid-phase impregnation method,which integrated the process characteristics of the Sol-Gel method and slurry impregnation method,was adopted to prepare continuous alumina fiber-reinforced silica composites with tunable porosity.Microstructure and composition of the typical composite were comprehensively characterized using different techniques.Mechanical properties of these composites with different densification degrees were tested and analyzed.By integrating porosity data obtained from computed tomography(CT)test with simulation calculation,a relationship model linking mechanical property failure of the composites to porosity and pore size parameters was established.The results indicated that composites prepared via the improved liquid-phase impregnation method had significantly enhanced mechanical properties due to the presence of pore defects and weak interfacial bonding.Notably,as the composite porosity increased from 2.2%to 15.2%,the tensile strength decreased from 24.5 MPa to 17.8 MPa.Further modeling and simulation analysis revealed that,at a pore defect radius of 250 μm,an increase in porosity from 4.5%to 13.5%led to a corresponding reduction in tensile strength from 27.2 MPa to 20.6 MPa,thereby validating rationality of the simulation model.The law that the n-th power of tensile strength shows a negative linear correlation with porosity,and the tensile strength exponent factor n is negatively linearly correlated with the pore defect radius r.These findings provide a research basis for the performance optimization and practical application of continuous alumina fiber-reinforced silica composites.

郑晨;王湘宁;苑贺楠;杨嘉伟;李传建;王华栋

航天特种材料及工艺技术研究所,北京 100074某部驻北京地区某代表室,北京 100074航天特种材料及工艺技术研究所,北京 100074航天特种材料及工艺技术研究所,北京 100074北京化工大学数理学院,北京 100029航天特种材料及工艺技术研究所,北京 100074

通用工业技术

氧化铝纤维二氧化硅复合材料力学性能孔隙率孔隙缺陷尺寸性能失效

alumina fibersilica compositemechanical propertyporositypore defect sizefailure

《无机材料学报》 2026 (3)

331-339,9

10.15541/jim20250258

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