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
12期
3042-3050
,共9页
白嘉伟%詹倩%迟成宇%谢锡善
白嘉偉%詹倩%遲成宇%謝錫善
백가위%첨천%지성우%사석선
Spuer304H%富Cu相%析出相%共格强化
Spuer304H%富Cu相%析齣相%共格彊化
Spuer304H%부Cu상%석출상%공격강화
Super304H%Cu-rich phase%precipitate phase%coherent strengthening
利用透射电子显微镜(TEM)研究Super304H奥氏体热强钢在650℃下不同时间(10~10000 h)时效过程中3种析出相的析出行为,并对其强化机理进行分析;同时,利用三维原子探针(3DAP)研究Super304H不锈钢在650℃时效1 h后富Cu相的早期析出行为。并详细分析富Cu相共格应变的强化机制。结果表明:细小弥散的富Cu相均匀且高度稳定地分布在奥氏体基体上,当650℃时效时间达到10000 h,球形的富Cu相依然保持在纳米级别,直径约为32 nm。在时效过程中,富Cu相与奥氏体基体始终保持完全共格的关系。Super304H不锈钢显微硬度的显著提高是由于细小弥散的富Cu相起到共格应变强化的作用,晶内较大尺寸的MX相也能够通过钉扎位错起到一定的强化作用;晶界上呈链状分布的M 23 C 6相亦具有辅助强化作用。
利用透射電子顯微鏡(TEM)研究Super304H奧氏體熱彊鋼在650℃下不同時間(10~10000 h)時效過程中3種析齣相的析齣行為,併對其彊化機理進行分析;同時,利用三維原子探針(3DAP)研究Super304H不鏽鋼在650℃時效1 h後富Cu相的早期析齣行為。併詳細分析富Cu相共格應變的彊化機製。結果錶明:細小瀰散的富Cu相均勻且高度穩定地分佈在奧氏體基體上,噹650℃時效時間達到10000 h,毬形的富Cu相依然保持在納米級彆,直徑約為32 nm。在時效過程中,富Cu相與奧氏體基體始終保持完全共格的關繫。Super304H不鏽鋼顯微硬度的顯著提高是由于細小瀰散的富Cu相起到共格應變彊化的作用,晶內較大呎吋的MX相也能夠通過釘扎位錯起到一定的彊化作用;晶界上呈鏈狀分佈的M 23 C 6相亦具有輔助彊化作用。
이용투사전자현미경(TEM)연구Super304H오씨체열강강재650℃하불동시간(10~10000 h)시효과정중3충석출상적석출행위,병대기강화궤리진행분석;동시,이용삼유원자탐침(3DAP)연구Super304H불수강재650℃시효1 h후부Cu상적조기석출행위。병상세분석부Cu상공격응변적강화궤제。결과표명:세소미산적부Cu상균균차고도은정지분포재오씨체기체상,당650℃시효시간체도10000 h,구형적부Cu상의연보지재납미급별,직경약위32 nm。재시효과정중,부Cu상여오씨체기체시종보지완전공격적관계。Super304H불수강현미경도적현저제고시유우세소미산적부Cu상기도공격응변강화적작용,정내교대척촌적MX상야능구통과정찰위착기도일정적강화작용;정계상정련상분포적M 23 C 6상역구유보조강화작용。
The precipitation behavior of three precipitate phases in Super304H austenitic heat-resistant steel during long time aging (10?10000 h) at 650 ℃ was investigated by transmission electron microscopy (TEM), and the relevant strengthening mechanism was analyzed. Three dimensional atom probe (3DAP) was used to study the early stage of precipitation behavior of Cu-rich phase of Super304H aged at 650 ℃ for 1 h after solution treatment at high temperature. The coherency strain strengthening mechanism of Cu-rich phase has been investigated in detail. The results show that the dispersed fine Cu-rich precipitates exhibit spherical morphology and keep highly stable in austenite matrix, which have the size of about 32 nm in diameter, even after aging at 650 ℃ for 10000 h. The coherent relationship between Cu-rich phase and matrix is preserved during the whole aging process. Due to the coherency strain strengthening effect of Cu-rich phase, the microhardness of Super304H steel increases significantly; simultaneously, the MX phase can also pin the dislocations to induce the additional strengthening effect. Moreover, the chain-like M 23 C 6 phase precipitated at grain boundaries can also contribute to the strengthening effect for Super304H steel.
