Si-Mn-Mo-V钢在淬火和低温回火状态下的脆化与韧化
Toughening and Embrittlening of Si-Mn-Mo-V Steels in Quenched and lowTemperature Tempered Condition
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摘要: 本文利用冲击韧性试验、扫描电镜、离子探针及俄歇谱议等手段研究讨论了合金元素Si和Mn对Si-Mn-Mo-V钢在淬火和低温回火状态下韧性的影响规律。研究结果表明:当钢中不含Si或含有少量Si面单独加入Mn,则由于Mn-P在晶界共偏析的原因,使P在晶界的浓度大为增加,导致了钢在淬火和低温回火状态下沿晶断裂的发生,从而降低了钢的韧性水平。在高Mn(2%Mn)钢中加入Si,由于Si在晶界的富集及Si-P的相互排斥作用,使P在晶界的偏析浓度下降。从而在一定程度上抑制了晶界脆性的发展和晶界断裂的发生,使钢的韧性水平显著提高。
本文还研究了Si和Mn对Si-Mn-Mo-V钢低温回火脆性(350℃脆性)的影响。实验结果表明:低温回火脆性既与杂质元素的晶界偏析有关,又与ε碳化物向渗碳体转化及渗碳体沿原奥氏体晶界成薄片状析出有关,由于Si和Mn既能影响杂质元素,特别是P在晶界的偏聚,又能影响ε碳化物向渗碳体转化,故Si和Mn对Si-Mn-Mo-V钢低温回火脆性发生的温度和强烈程度均有显著的影响。Abstract: The influence of Si and Mn on the toughening and embrittlening of Si-Mn-Mo-V steels in the quenched and low temperature tempered condition has been studied in this paper. Experimental results indicate that the segregation of P at austenite grain boundaries is seriously promoted by the Mn addition in-the steel without Si. The segregation of P may be occured during the austeni tizing and subsequent cooling by the co-segregation of Mn and P.The steel at quenched and low temperature tempered condition is offen failed by intergran ular fracture, with low impact toughness because of P segregation.The segregation of P and Mn at the austenite grain boundaries is significantly decreased by the addition of Si in the steel which has been embrittled by Mn (about 2%).Auger Spectromicroscope analyses show there is an obvious segregation of Si at the austenite grain boundaries of the Si bearing steels.It is well known that Si and P have a nagative interaction coefficient,sip<0.For this reason,P was repelled away from the austenite grain boundaries where si has been alread segregated and then the concentration of P at the grain boundaries is decreased.For reasons given above,the grain boundar ombrittlernent and in-tsrgranular fracture are suppressed and then the impact touphnese is markedly increased.
The effects of si and Mn on low temperature tempered embrittlement(LT-TE), or 350℃-embrittlement as it called, of Si-Mn-Mo-V steels have been a-Iso studied in this work. Experimental results indicate that the LTTE is associated both with the impurities segregation at grain boundaries and with the transition of epsilon carbide to cementite which usually precipitated as thin film at the austenite grain boundaries. The segregation of impurities, especially P and the carnbide transition are both significantly influenced by si and Mn. Therefore, the temperature and the intensity of LTTE occured in these steels are also strongly influenced by si and Mn.