特种铸造及有色合金
特種鑄造及有色閤金
특충주조급유색합금
SPECIAL CASTING & NONFERROUS ALLOYS
2010年
1期
49-53
,共5页
触变注射成形%AZ91D合金%固相%力学性能
觸變註射成形%AZ91D閤金%固相%力學性能
촉변주사성형%AZ91D합금%고상%역학성능
Thixo-molded%AZ91D Magnesium Alloy%Solid Phase%Properties
通过不同工艺制备的合金的组织特点和性能变化,研究了触变注射成形AZ91D合金的拉伸断裂行为.结果表明,典型触变注射成形AZ91D合金的室温组织主要由未熔固相α-Mg和液相急冷组织构成.未熔固相有类球状、不规则状、包裹液相和内部小液池等4种形态.液相急冷组织包含初生α-Mg固相和共晶相,初生固相较规则,尺寸较小,主要受液相的过冷度影响.当组织变化不大时,孔隙率对合金性能的影响最大,而当孔隙率变化不大时,组织的变化对性能的影响较大,固相率较低和初生固相较细小的试样的力学性能较好.试样拉伸时裂纹主要沿着未熔固相与液相的界面或初生固相与共晶的界面扩展.当固相率较高时,裂纹大部分沿着未熔固相与液相的界面扩展,试样的性能较低;而当固相率较低时,裂纹大部分沿着初生固相与共晶相的界面扩展,并通过β相的桥接进行拓展,性能较好.
通過不同工藝製備的閤金的組織特點和性能變化,研究瞭觸變註射成形AZ91D閤金的拉伸斷裂行為.結果錶明,典型觸變註射成形AZ91D閤金的室溫組織主要由未鎔固相α-Mg和液相急冷組織構成.未鎔固相有類毬狀、不規則狀、包裹液相和內部小液池等4種形態.液相急冷組織包含初生α-Mg固相和共晶相,初生固相較規則,呎吋較小,主要受液相的過冷度影響.噹組織變化不大時,孔隙率對閤金性能的影響最大,而噹孔隙率變化不大時,組織的變化對性能的影響較大,固相率較低和初生固相較細小的試樣的力學性能較好.試樣拉伸時裂紋主要沿著未鎔固相與液相的界麵或初生固相與共晶的界麵擴展.噹固相率較高時,裂紋大部分沿著未鎔固相與液相的界麵擴展,試樣的性能較低;而噹固相率較低時,裂紋大部分沿著初生固相與共晶相的界麵擴展,併通過β相的橋接進行拓展,性能較好.
통과불동공예제비적합금적조직특점화성능변화,연구료촉변주사성형AZ91D합금적랍신단렬행위.결과표명,전형촉변주사성형AZ91D합금적실온조직주요유미용고상α-Mg화액상급랭조직구성.미용고상유류구상、불규칙상、포과액상화내부소액지등4충형태.액상급랭조직포함초생α-Mg고상화공정상,초생고상교규칙,척촌교소,주요수액상적과랭도영향.당조직변화불대시,공극솔대합금성능적영향최대,이당공극솔변화불대시,조직적변화대성능적영향교대,고상솔교저화초생고상교세소적시양적역학성능교호.시양랍신시렬문주요연착미용고상여액상적계면혹초생고상여공정적계면확전.당고상솔교고시,렬문대부분연착미용고상여액상적계면확전,시양적성능교저;이당고상솔교저시,렬문대부분연착초생고상여공정상적계면확전,병통과β상적교접진행탁전,성능교호.
By understanding microstructure and properties of thixo-molded AZ91D fabricated at different processing parameters, the fracture behavior was investigated. The results show that ambient microstructure of typical thixo-molded AZ91D alloy is mainly composed of un-melted α-Mg and solidified phase. The un-melted solid phase can be divided into four types, such as spherical solid particles, irregular solid particle, solid particle with liquid pool inside and solid particle with liquid alloy inside. Solidified phase includes primary α-Mg phase and eutectic phase, in which primary phase exhibits regular structure with fine grain, controlling by under-cooling rate of liquid alloy. Porosity rate is the main factor influencing the mechanical properties of the alloy with similar microstructure, while effects of microstructure on the mechanical properties of the alloy with similar porosity rate is dominant. The samples with a lower solid fraction and a finer primary solid phase exhibits acceptable properties. Crack in the sample during tensile testing is propagated along interface of un-melted solid phase and liquid phase or along primary solid phase and eu-tectic phase. With a higher solid fraction, crack is mainly propagated along interface of un-melted solid phase and liquid phase, resulting in the deterioration of mechanical properties, while with a lower solid fraction, crack is mainly propagated along interface of primary solid phase and eutectic phase, leading to the improvement of mechanical properties as a result of bridging effects though β phase.