轧制下线温度对15CrNiMo硬度及析氢行为的影响
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摘要
为了优化牙轮钻头用15CrNiMo圆钢轧制工艺,降低圆钢氢含量及硬度,减少白点缺陷以及应力开裂的质量风险,对比了不同轧制下线温度对圆钢宏观硬度、显微硬度以及显微组织的影响,并采用升温脱氢分析方法(thermal desorption spectroscopy,简称TDS)对圆钢析氢曲线、氢含量等进行了对比分析。结果显示,升高轧制下线温度可以有效提高钢材铁素体组织比例,从而使钢材整体硬度降低,另外也有助于减少钢中的氢含量。
In order to optimize the rolling process of 15 CrNiMo round steel for cone bit,reduce the hydrogen content and hardness of round steel,and reduce the risk of flake defect and stress cracking,the effect of different pit temperature after rolling on the macro-hardness,micro-hardness and microstructure of 15 CrNiMo round steel was compared and analyzed.The hydrogen desorption curves and hydrogen contents of round steel were analyzed by thermal desorption spectroscopy(TDS).The results showed that increasing the pit temperature could effectively increase the ferrite structure ratio of steel,thus reducing the overall hardness of steel,and also help to reduce the hydrogen content in steel.
In order to optimize the rolling process of 15 CrNiMo round steel for cone bit,reduce the hydrogen content and hardness of round steel,and reduce the risk of flake defect and stress cracking,the effect of different pit temperature after rolling on the macro-hardness,micro-hardness and microstructure of 15 CrNiMo round steel was compared and analyzed.The hydrogen desorption curves and hydrogen contents of round steel were analyzed by thermal desorption spectroscopy(TDS).The results showed that increasing the pit temperature could effectively increase the ferrite structure ratio of steel,thus reducing the overall hardness of steel,and also help to reduce the hydrogen content in steel.
引文
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[2]Nagumo,Michihiko.Fundamentals of Hydrogen Embrittlement[M].Singapore:Springer Singapore,2016.
[3]Bergers K.Determination of hydrogen in steel by thermal desorption mass spectrometry[J].Steel Research International,2010,81(7):499.
[4]Choo W,Lee J.Thermal analysis of trapped hydrogen in pure iron[J].Metallurgical and Materials Transactions:A,1982,13(1):135.
[5]Depover T,Verbeken K.The effect of TiC on the hydrogen induced ductility loss and trapping behavior of Fe-C-Ti alloys[J].Corrosion Science,2016,112:308.
[6]康大韬,叶国斌.大型锻件材料及热处理[M].上海:龙门书局,1998.
[7]George E.Totten Steel Heat Treatment Handbook Second Edition[M].Boca Raton:CRC Press,2006.
[8]郭昀静,王春芳,李建锡,等.利用TDS研究二次硬化钢中氢的扩散行为[J].航空材料学报,2012,32(3):5.
[9]惠卫军,翁宇庆,董瀚.高强度紧固件用钢[M].北京:冶金工业出版社,2009.
[10]谌康,徐乐,王毛球.利用升温脱氢分析方法表征钢中的可扩散氢[J].物理测试,2017,35(6):20.
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