粉末冶金材料科学与工程
粉末冶金材料科學與工程
분말야금재료과학여공정
POWDER METALLURGY MATERIALS SCIENCE AND ENGINEERING
2014年
1期
95-100
,共6页
张鹏%张哲维%李宇力%王文先%王保东
張鵬%張哲維%李宇力%王文先%王保東
장붕%장철유%리우력%왕문선%왕보동
B4C/Al 复合材料%真空热压%界面%力学性能%增强机制
B4C/Al 複閤材料%真空熱壓%界麵%力學性能%增彊機製
B4C/Al 복합재료%진공열압%계면%역학성능%증강궤제
B4C/Al composite%vacuum hot-pressing%interface%mechanical properties%strengthening mechanisms
采用低温真空热压法制备B4C质量分数为30%、平均粒度为23μm的B4C/Al基复合材料,热压温度控制在基体6061Al合金的固液相线之间。对B4C/Al复合材料进行显微结构分析和力学性能检测,结果表明:B4C/Al复合材料内无大尺寸的显微缺陷,组织分布较均匀、致密,界面结合较好;B4C/Al基复合材料的硬度比基体6061铝合金提高34.9%,断裂韧性是B4C增强颗粒断裂韧性的5.16倍,屈服强度比基体提高198.3%。利用Ramakrishnan提出的金属基复合材料屈服强度的分析模型,对30%B4C/Al复合材料的屈服强度进行计算,计算结果与实验结果基本符合。分析表明微米级B4C颗粒对6061Al合金的增强机制主要为载荷增强和位错增强。
採用低溫真空熱壓法製備B4C質量分數為30%、平均粒度為23μm的B4C/Al基複閤材料,熱壓溫度控製在基體6061Al閤金的固液相線之間。對B4C/Al複閤材料進行顯微結構分析和力學性能檢測,結果錶明:B4C/Al複閤材料內無大呎吋的顯微缺陷,組織分佈較均勻、緻密,界麵結閤較好;B4C/Al基複閤材料的硬度比基體6061鋁閤金提高34.9%,斷裂韌性是B4C增彊顆粒斷裂韌性的5.16倍,屈服彊度比基體提高198.3%。利用Ramakrishnan提齣的金屬基複閤材料屈服彊度的分析模型,對30%B4C/Al複閤材料的屈服彊度進行計算,計算結果與實驗結果基本符閤。分析錶明微米級B4C顆粒對6061Al閤金的增彊機製主要為載荷增彊和位錯增彊。
채용저온진공열압법제비B4C질량분수위30%、평균립도위23μm적B4C/Al기복합재료,열압온도공제재기체6061Al합금적고액상선지간。대B4C/Al복합재료진행현미결구분석화역학성능검측,결과표명:B4C/Al복합재료내무대척촌적현미결함,조직분포교균균、치밀,계면결합교호;B4C/Al기복합재료적경도비기체6061려합금제고34.9%,단렬인성시B4C증강과립단렬인성적5.16배,굴복강도비기체제고198.3%。이용Ramakrishnan제출적금속기복합재료굴복강도적분석모형,대30%B4C/Al복합재료적굴복강도진행계산,계산결과여실험결과기본부합。분석표명미미급B4C과립대6061Al합금적증강궤제주요위재하증강화위착증강。
30%B4C (mass fraction) particle-reinforcing Al matrix composite with the average particle size 23μm of was prepared by low temperature vacuum hot-pressing technique. The preparation temperature was between the solid and liquid phase line of the 6061Al matrix. The microstructure and mechanical property were analyzed. The results show that the particles are uniformly distributed in the B4C/Al composite without agglomeration and there is mutual diffusion between the particles and matrix. The interface bonds between matrix and reinforcer well. The hardness of B4C/Al composite is 34.9%higher than that of 6061 aluminum alloy. The fracture toughness of B4C/Al composite is 5.16 times larger than that of the B4C material and the yield strength increases 198.3%than that of the matrix. An analytical model for the strength of metal matrix composites presented by Ramakrishnan was selected to calculate the yield strength of the 30%B4C/Al composite. The results of theoretical calculations agree well with the experimental data. The strengthening mechanisms of B4C particle-reinforcing Al matrix composite with micron particle size are mainly loading strengthening and dislocation strengthening.