中国有色金属学报
中國有色金屬學報
중국유색금속학보
THE CHINESE JOURNAL OF NONFERROUS METALS
2014年
2期
387-394
,共8页
王新迎%于化顺%王雷%万海云%颜鲁滨
王新迎%于化順%王雷%萬海雲%顏魯濱
왕신영%우화순%왕뢰%만해운%안로빈
铝基复合材料%原位反应%力学性能
鋁基複閤材料%原位反應%力學性能
려기복합재료%원위반응%역학성능
aluminum matrix composite%in-situ reaction%mechanical property
采用SEM、EDS、XRD、TEM和拉伸强度测试等研究Al2O3粒子增强的ZL109铝基复合材料。结果表明:多元氧化物和铝原位反应生成的Al2O3粒子尺寸细小,粒径约为0.1μm,在基体中弥散分布,与基体存在共格关系,(001)α(Al)//(010)α-Al2O3,[110]α(Al)//[001]α-Al2O3。原位反应中生成的金属间化合物经T6处理后,以Al5FeSi、FeCr、Mg2Si、Al3Ni、Al2Cu和Al7Cu4Ni相的形式存在于基体中,使得复合材料在300℃的拉伸强度达到163.4 MPa,较基体的提高7.9%。随Al2O3粒子含量的增加,25℃时,复合材料断口断裂方式由韧性断裂转变为解理断裂,再到穿晶断裂;而300℃时,断口断裂转变方式为脆性断裂到延性断裂。
採用SEM、EDS、XRD、TEM和拉伸彊度測試等研究Al2O3粒子增彊的ZL109鋁基複閤材料。結果錶明:多元氧化物和鋁原位反應生成的Al2O3粒子呎吋細小,粒徑約為0.1μm,在基體中瀰散分佈,與基體存在共格關繫,(001)α(Al)//(010)α-Al2O3,[110]α(Al)//[001]α-Al2O3。原位反應中生成的金屬間化閤物經T6處理後,以Al5FeSi、FeCr、Mg2Si、Al3Ni、Al2Cu和Al7Cu4Ni相的形式存在于基體中,使得複閤材料在300℃的拉伸彊度達到163.4 MPa,較基體的提高7.9%。隨Al2O3粒子含量的增加,25℃時,複閤材料斷口斷裂方式由韌性斷裂轉變為解理斷裂,再到穿晶斷裂;而300℃時,斷口斷裂轉變方式為脆性斷裂到延性斷裂。
채용SEM、EDS、XRD、TEM화랍신강도측시등연구Al2O3입자증강적ZL109려기복합재료。결과표명:다원양화물화려원위반응생성적Al2O3입자척촌세소,립경약위0.1μm,재기체중미산분포,여기체존재공격관계,(001)α(Al)//(010)α-Al2O3,[110]α(Al)//[001]α-Al2O3。원위반응중생성적금속간화합물경T6처리후,이Al5FeSi、FeCr、Mg2Si、Al3Ni、Al2Cu화Al7Cu4Ni상적형식존재우기체중,사득복합재료재300℃적랍신강도체도163.4 MPa,교기체적제고7.9%。수Al2O3입자함량적증가,25℃시,복합재료단구단렬방식유인성단렬전변위해리단렬,재도천정단렬;이300℃시,단구단렬전변방식위취성단렬도연성단렬。
Al2O3 particles reinforced ZL109 aluminum matrix composites were investigated by scanning electron microscopy (SEM), energy dispersive spectroscopy (EDS), X-ray diffractometry (XRD), transmission electron microscopy (TEM) and tensile strength test. The results indicate that small size (about 0.1μm) Al2O3 particles formed by in-situ reaction between multi-oxide and aluminum distribute uniformly in the matrix, and the orientation relation between Al2O3 and matrix is (001)α(Al)//(010)α-Al2O3 and [110]α(Al)//[001]α-Al2O3. After T6 heat treatment, the intermetallic compounds accompany with in-situ reaction uniformly disperse in the matrix and exist in the form of Al5FeSi, FeCr, Mg2Si, Al3Ni, Al2Cu and Al7Cu4Ni phase. Composite tensile strength can reach 163.4 MPa, improves by 7.9%than that of the matrix. With the increase of Al2O3 particles, the fracture mechanism of the composites at 25 ℃ changes from ductile fracture to cleavage fracture, and then to transgranular fracture, while at 300℃, the brittle fracture changes to ductile fracture.
