粉末冶金技术
粉末冶金技術
분말야금기술
POWDER METALLURGY TECHNOLOGY
2010年
1期
26-30
,共5页
王庆相%梁淑华%杨怡%范志康
王慶相%樑淑華%楊怡%範誌康
왕경상%량숙화%양이%범지강
Ti-20%W合金%固溶体%显微组织%抗压强度
Ti-20%W閤金%固溶體%顯微組織%抗壓彊度
Ti-20%W합금%고용체%현미조직%항압강도
Ti-20wt%W alloy%solid solution%microstructure%compression strength
以TiH_2粉和不同粒径的W粉为原料,通过粉末冶金法制备了Ti-20%W合金,利用金相显微镜、X射线衍射仪、扫描电子显微镜和能谱分析仪对合金的微观组织和成分进行分析,并测定了其显微硬度和抗压强度.结果表明:选用细W粉时,W颗粒与Ti固溶量大,显微硬度值均匀且抗压强度高,强化机理为固溶强化,断口分析表明采用纳米W粉时Ti-20%W合金发生了韧性断裂;而采用粗W粉时,W颗粒与Ti固溶量较少,显微硬度值从W颗粒中心到Ti基体呈现先升高后降低的趋势,抗压强度较差.这说明采用W增强Ti基体时固溶强化比第二相即颗粒强化的效果更明显.
以TiH_2粉和不同粒徑的W粉為原料,通過粉末冶金法製備瞭Ti-20%W閤金,利用金相顯微鏡、X射線衍射儀、掃描電子顯微鏡和能譜分析儀對閤金的微觀組織和成分進行分析,併測定瞭其顯微硬度和抗壓彊度.結果錶明:選用細W粉時,W顆粒與Ti固溶量大,顯微硬度值均勻且抗壓彊度高,彊化機理為固溶彊化,斷口分析錶明採用納米W粉時Ti-20%W閤金髮生瞭韌性斷裂;而採用粗W粉時,W顆粒與Ti固溶量較少,顯微硬度值從W顆粒中心到Ti基體呈現先升高後降低的趨勢,抗壓彊度較差.這說明採用W增彊Ti基體時固溶彊化比第二相即顆粒彊化的效果更明顯.
이TiH_2분화불동립경적W분위원료,통과분말야금법제비료Ti-20%W합금,이용금상현미경、X사선연사의、소묘전자현미경화능보분석의대합금적미관조직화성분진행분석,병측정료기현미경도화항압강도.결과표명:선용세W분시,W과립여Ti고용량대,현미경도치균균차항압강도고,강화궤리위고용강화,단구분석표명채용납미W분시Ti-20%W합금발생료인성단렬;이채용조W분시,W과립여Ti고용량교소,현미경도치종W과립중심도Ti기체정현선승고후강저적추세,항압강도교차.저설명채용W증강Ti기체시고용강화비제이상즉과립강화적효과경명현.
Blends of TiH_2 and W powders were consolidated by powder metallurgy, using an initial W powder size that was very fine (50~70nm and 6~8μm) or very coarse (<30~35μm). Microstructure and component were analyzed by optical micrographs (OM), X-ray diffraction (XRD), scanning electron microscopy (SEM) and energy-dispersive spectroscopy (EDS).The microhardness and compression strength were also measured. The results show that dissolution of W powders in the Ti matrix during consolidation is almost complete for the fine powders, which exhibit much higher strength of compression and the distribution of microhardness value is uniform. The strengthening mechanism for those alloys is the solid-solution strengthening. The fracture analysis indicates that Ti-20wt% W alloy prepared by nano W powders displays tough fracture. When using coarse W powder, dissolution of W powders in the Ti matrix is limited and the microhardness presents a trend of first increase then decrease from the center of W powder to Ti matrix whose strength of compression is lower. This indicates that tungsten strengthened titanium is due to solid-solution strengthening rather than second phase strengthening.