中国有色金属学报(英文版)
中國有色金屬學報(英文版)
중국유색금속학보(영문판)
TRANSACTIONS OF NONFERROUS METALS SOCIETY OF CHINA
2011年
z2期
483-488
,共6页
刘燕%于思荣%刘金丹%韩志武%苑东生
劉燕%于思榮%劉金丹%韓誌武%苑東生
류연%우사영%류금단%한지무%원동생
镁合金%纳米复合镀层%显微结构%耐磨性
鎂閤金%納米複閤鍍層%顯微結構%耐磨性
미합금%납미복합도층%현미결구%내마성
magnesium alloy%nano-composite coatings%microstructure%wear resistance
以AZ91HP镁合金为研究对象,以纳米氧化硅为第二相粒子,通过纳米复合电沉积法制备AZ91HP镁合金Ni-SiO2纳米复合镀层.利用扫描电镜观察纳米复合镀层的显微形貌与微观结构,利用显微硬度计测定纳米复合镀层显微硬度,利用M-200摩擦磨损试验机测试纳米复合镀层的耐磨性能.结果表明:在AZ91HP镁合金表面获得了结晶均匀、结构致密的Ni-SiO2纳米复合镀层;纳米复合镀层剖面形貌显示纳米复合镀层与镁合金基体结合良好;镀液中纳米颗粒含量为10 g/L时,AZ91HP镁合金表面电沉积Ni-SiO2纳米复合镀层的显微硬度最高,最高达HV367;摩擦磨损试验表明纳米复合镀层与镀镍层、镁合金基体相比,耐磨性明显提高,这是由于纳米颗粒的细晶强化和弥散强化所致;纳米复合镀层的磨损机制主要是磨粒磨损,镁合金基体磨损机制为粘着磨损,镀镍层磨损机制为剥层磨损.
以AZ91HP鎂閤金為研究對象,以納米氧化硅為第二相粒子,通過納米複閤電沉積法製備AZ91HP鎂閤金Ni-SiO2納米複閤鍍層.利用掃描電鏡觀察納米複閤鍍層的顯微形貌與微觀結構,利用顯微硬度計測定納米複閤鍍層顯微硬度,利用M-200摩抆磨損試驗機測試納米複閤鍍層的耐磨性能.結果錶明:在AZ91HP鎂閤金錶麵穫得瞭結晶均勻、結構緻密的Ni-SiO2納米複閤鍍層;納米複閤鍍層剖麵形貌顯示納米複閤鍍層與鎂閤金基體結閤良好;鍍液中納米顆粒含量為10 g/L時,AZ91HP鎂閤金錶麵電沉積Ni-SiO2納米複閤鍍層的顯微硬度最高,最高達HV367;摩抆磨損試驗錶明納米複閤鍍層與鍍鎳層、鎂閤金基體相比,耐磨性明顯提高,這是由于納米顆粒的細晶彊化和瀰散彊化所緻;納米複閤鍍層的磨損機製主要是磨粒磨損,鎂閤金基體磨損機製為粘著磨損,鍍鎳層磨損機製為剝層磨損.
이AZ91HP미합금위연구대상,이납미양화규위제이상입자,통과납미복합전침적법제비AZ91HP미합금Ni-SiO2납미복합도층.이용소묘전경관찰납미복합도층적현미형모여미관결구,이용현미경도계측정납미복합도층현미경도,이용M-200마찰마손시험궤측시납미복합도층적내마성능.결과표명:재AZ91HP미합금표면획득료결정균균、결구치밀적Ni-SiO2납미복합도층;납미복합도층부면형모현시납미복합도층여미합금기체결합량호;도액중납미과립함량위10 g/L시,AZ91HP미합금표면전침적Ni-SiO2납미복합도층적현미경도최고,최고체HV367;마찰마손시험표명납미복합도층여도얼층、미합금기체상비,내마성명현제고,저시유우납미과립적세정강화화미산강화소치;납미복합도층적마손궤제주요시마립마손,미합금기체마손궤제위점착마손,도얼층마손궤제위박층마손.
The Ni-SiO2 nano-composite coatings were fabricated by electrodeposition on the AZ91HP magnesium alloy surface,in which nano-SiO2 was chosen as the second-phase particulates.The microstructure was observed by SEM,the microhardness was measured by micro-density tester and the wear resistance was estimated by M-200 type block-on-wheel dry sliding frication and wear tester.The results indicate that the Ni-SiO2 nano-composite coatings with uniform crystalline,dense structure can be obtained on AZ91HP magnesium alloy.The interface morphology shows that the combination between the nano-composite coatings and magnesium alloy is fine.The maximum value of microhardness reaches HV367 when the content of nanoparticles is 10 g/L,however,the microhardness of the pure nickel coatings is HV274 and the hardness of magnesium alloy only is HV82.7.The frication and wear experiments reveal that the wear resistance of nano-composite coatings are improved obviously compared to magnesium alloys and pure nickel coatings,which are induced by dispersive strengthening effect and grain refining effect.The main wear mechanism of nano-composite coating is abrasive wear,the wear mechanism of magnesium alloys is adhesion wear,and that of pure nickel coating is exfoliation wear,respectively.
