山东冶金
山東冶金
산동야금
SHANDONG METALLURY
2014年
3期
36-38,40
,共4页
核电站用钢%SA738Gr.B钢%热处理%显微组织%力学性能
覈電站用鋼%SA738Gr.B鋼%熱處理%顯微組織%力學性能
핵전참용강%SA738Gr.B강%열처리%현미조직%역학성능
steel for nuclear power plant%SA738Gr.B steel%heat treatment%microstructure%mechanical property
为满足SA738Gr.B核电站用钢较高的性能要求,在实验室试验的基础上,研究了工业化生产热处理工艺参数对钢显微组织和力学性能的影响。结果表明,钢板淬火时冷却速度>5℃/s时,能够避免先共析铁素体的析出;淬火温度较高时,钢板具有更细小和均匀的板条贝氏体;随着淬火加热的保温时间延长,晶粒组织粗化且铁素体含量减少;随着回火温度的升高,晶粒粗化,同时贝氏体含量减少,铁素体含量增多;在工业化生产中,较大淬火水量下钢板的拉伸性能更优;随着回火时间的延长,钢板强度下降而冲击韧性提高。以920℃×2.0 min/mm加热、较高水量的Q2工艺淬火,并采用650℃×1.5 min/mm的工艺回火,可使钢板的强韧性达到最佳匹配。
為滿足SA738Gr.B覈電站用鋼較高的性能要求,在實驗室試驗的基礎上,研究瞭工業化生產熱處理工藝參數對鋼顯微組織和力學性能的影響。結果錶明,鋼闆淬火時冷卻速度>5℃/s時,能夠避免先共析鐵素體的析齣;淬火溫度較高時,鋼闆具有更細小和均勻的闆條貝氏體;隨著淬火加熱的保溫時間延長,晶粒組織粗化且鐵素體含量減少;隨著迴火溫度的升高,晶粒粗化,同時貝氏體含量減少,鐵素體含量增多;在工業化生產中,較大淬火水量下鋼闆的拉伸性能更優;隨著迴火時間的延長,鋼闆彊度下降而遲擊韌性提高。以920℃×2.0 min/mm加熱、較高水量的Q2工藝淬火,併採用650℃×1.5 min/mm的工藝迴火,可使鋼闆的彊韌性達到最佳匹配。
위만족SA738Gr.B핵전참용강교고적성능요구,재실험실시험적기출상,연구료공업화생산열처리공예삼수대강현미조직화역학성능적영향。결과표명,강판쉬화시냉각속도>5℃/s시,능구피면선공석철소체적석출;쉬화온도교고시,강판구유경세소화균균적판조패씨체;수착쉬화가열적보온시간연장,정립조직조화차철소체함량감소;수착회화온도적승고,정립조화,동시패씨체함량감소,철소체함량증다;재공업화생산중,교대쉬화수량하강판적랍신성능경우;수착회화시간적연장,강판강도하강이충격인성제고。이920℃×2.0 min/mm가열、교고수량적Q2공예쉬화,병채용650℃×1.5 min/mm적공예회화,가사강판적강인성체도최가필배。
In order to meet the high performance requirements of SA738Gr.B steel plate for nuclear power plant, on the basis of lab tests, heat treatment process parameters in industrial production are studied. The results showed that Pro-eutectoid ferrite precipitation can be avoided when quenching cooling rate greater than 5℃/s;The steel plates have smaller and more uniform lath bainite when quenching temperature is higher;With the extension of heating holding time in quenching, the grains are coarser and ferrite content reduces;With the increase of the tempering temperature, grains coarsen, and the content of bainite reduces, ferrite content increases; In industrial production, tensile properties is superior when water quantity of quenching is higher; With the increase of the tempering time, the steel strength decreases and the impact toughness increases. When the steel plate was heated in 920℃×2.0 min/mm, and subsequently quenched in Q2 program with higher water flow, then tempered in 650℃×1.5 min/mm, the best match of the strength and toughness can be achieved.