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
4期
848-854
,共7页
Mg-Li合金%弹性模量%力学性能%阻尼性能
Mg-Li閤金%彈性模量%力學性能%阻尼性能
Mg-Li합금%탄성모량%역학성능%조니성능
Mg-Li alloys%elastic modulus%mechanical property%damping capacity
在氩气保护下采用电磁感应真空熔炼制备出单一α-Mg 相、单一β-Li 相及两相共存的3种不同相态的Mg-Li二元合金,并运用光学显微镜、XRD、阻尼测试及力学测试方法对合金的组织结构、力学性能及阻尼性能进行分析和讨论。结果表明:Li含量的增加使合金的相态发生改变,同时对合金起到晶粒细化的作用,且能有效地提高合金的屈服强度。体心立方结构的β-Li 相会增大合金的临界应变振幅以及阻尼性能,但两相共存状态的Mg-Li合金具有最好的抗拉强度及伸长率。Mg-Li二元合金的新阻尼机制是由低温区域位错滑移、高温区域的晶界滑移以及合金中的晶格畸变这3种阻尼机制叠加而成。
在氬氣保護下採用電磁感應真空鎔煉製備齣單一α-Mg 相、單一β-Li 相及兩相共存的3種不同相態的Mg-Li二元閤金,併運用光學顯微鏡、XRD、阻尼測試及力學測試方法對閤金的組織結構、力學性能及阻尼性能進行分析和討論。結果錶明:Li含量的增加使閤金的相態髮生改變,同時對閤金起到晶粒細化的作用,且能有效地提高閤金的屈服彊度。體心立方結構的β-Li 相會增大閤金的臨界應變振幅以及阻尼性能,但兩相共存狀態的Mg-Li閤金具有最好的抗拉彊度及伸長率。Mg-Li二元閤金的新阻尼機製是由低溫區域位錯滑移、高溫區域的晶界滑移以及閤金中的晶格畸變這3種阻尼機製疊加而成。
재아기보호하채용전자감응진공용련제비출단일α-Mg 상、단일β-Li 상급량상공존적3충불동상태적Mg-Li이원합금,병운용광학현미경、XRD、조니측시급역학측시방법대합금적조직결구、역학성능급조니성능진행분석화토론。결과표명:Li함량적증가사합금적상태발생개변,동시대합금기도정립세화적작용,차능유효지제고합금적굴복강도。체심립방결구적β-Li 상회증대합금적림계응변진폭이급조니성능,단량상공존상태적Mg-Li합금구유최호적항랍강도급신장솔。Mg-Li이원합금적신조니궤제시유저온구역위착활이、고온구역적정계활이이급합금중적정격기변저3충조니궤제첩가이성。
The vacuum induction melting furnace was used to melt the Mg-Li alloys under the protection of argon atmosphere. Three kinds of Mg-Li binary alloys, singleα-Mg phase alloy, singleβ-Li phase alloy and the dual-phase alloy are obtained. The optical microscope (OM), X-ray diffractometer (XRD), scanning electron microscope (SEM), tensile properties test, amplitude-damping test and temperature-damping test were used to analyze the mechanical properties and the damping capacity of Mg-Li alloys with different phases were studied. The results show that the increase of Li content changes the phases of the alloy, and also plays an important role in the grain refinement which can effectively improve the yield strength. The BCC-structuredβ-Li phase improves the critical stain amplitude and the damping capacity of Mg-Li alloys, and the dual-phase Mg-Li alloy has the best tensile strength and elongation. The new damping mechanism of Mg-Li alloy is superposed by the dislocation gliding at low temperature, grain boundary sliding at high temperature and the lattice distortion.