压铸模具钢大模块真空高压气淬冷却过程的数值模拟

doi:10.13251/j.issn.0254-6051.2023.04.034

金属热处理 ›› 2023, Vol. 48 ›› Issue (4): 211-220.DOI: 10.13251/j.issn.0254-6051.2023.04.034

压铸模具钢大模块真空高压气淬冷却过程的数值模拟

蒋志鹏, 陈浩, 吴晓春

上海大学材料科学与工程学院省部共建高品质特殊钢冶金与制备国家重点实验室, 上海 200072

收稿日期:2022-10-08 修回日期:2023-01-05 发布日期:2023-05-27
通讯作者: 吴晓春,教授,博士生导师,E-mail:wuxiaochun@shu.edu.cn
作者简介:蒋志鹏(1997—),男,硕士研究生,主要研究方向为模具钢材料的热处理,E-mail:jzp971104@163.com。
基金资助:
广东省重点领域研发计划(2020B010184002);省部共建高品质特殊钢冶金与制备国家重点实验室自主课题项目(SKLASS2020—Z08)

Numerical simulation of vacuum high-pressure gas quenching cooling process for large die-casting die steel modules

Jiang Zhipeng, Chen Hao, Wu Xiaochun

State Key Laboratory of Advanced Special Steel, School of Materials Science and Engineering, Shanghai University, Shanghai 200072, China

Received:2022-10-08 Revised:2023-01-05 Published:2023-05-27

摘要/Abstract

摘要： 以尺寸为500 mm×500 mm×500 mm的SDDVA模具钢大模块为研究对象,采用DEFORM建立模块真空气淬冷却过程的数值模型,结合试验研究了大模块在真空气淬炉中不同淬火压力条件下的冷却行为、组织演变及应力演变规律,并从理论角度预测了模块可生产的最大规格。结果表明,大模块心部在0.4、0.6和0.9 MPa压力条件下气淬,均观察到先共析碳化物沿晶析出。为了避免碳化物沿晶析出,从800 ℃冷却到500 ℃的冷速应不小于0.25 ℃/s。0.4 MPa压力条件下气淬过程中,模块最大心表温差最小,约为120 ℃;大模块心部在0.9 MPa压力条件下淬火所得马氏体含量高于0.4、0.6 MPa压力下淬火,同时,贝氏体含量也更少;模块表面和心部主要表现为热应力和组织应力。SDDVA钢模块在0.4、0.6和0.9 MPa压力条件下真空高压气淬可生产的理论最大厚度分别为280、320和380 mm。

关键词: 数值模拟, 大模块, 气淬, 组织演变, 压铸模具钢

Abstract: A numerical model of vacuum gas quenching cooling process of a 500 mm×500 mm×500 mm SDDVA die steel module was investigated by using DEFORM to investigate the cooling behaviour, microstructure evolution and stress evolution of the large module under different quenching pressure conditions in a vacuum air quenching furnace, and to predict the maximum size of the module that can be produced from a theoretical point of view. The results show that the proeutectoid carbide precipitation along the crystal is unavoidable in large module cores when quenched under 0.4, 0.6 and 0.9 MPa. And in order to avoid carbide precipitation, the cooling rate from 800 ℃ to 500 ℃ should be at least greater than 0.25 ℃/s. When gas quenched under pressure of 0.4 MPa, the maximum temperature difference between the core and the surface of the module is the smallest, about 120 ℃. The martensite content obtained in the core of large modules quenched under 0.9 MPa is higher than that obtained by quenching under 0.4 and 0.6 MPa, and the bainite content is also lower. The surface and core of the module mainly exhibit thermal and phase transformation stresses. The theoretical maximum thickness of SDDVA modules quenched by vacuum and high pressure gas under 0.4, 0.6 and 0.9 MPa is 280, 320 and 380 mm, respectively.

Key words: numerical simulation, large module, gas quenching, microstructure evolution, die-casting die steel

中图分类号:

TG161

蒋志鹏, 陈浩, 吴晓春. 压铸模具钢大模块真空高压气淬冷却过程的数值模拟[J]. 金属热处理, 2023, 48(4): 211-220.

Jiang Zhipeng, Chen Hao, Wu Xiaochun. Numerical simulation of vacuum high-pressure gas quenching cooling process for large die-casting die steel modules[J]. Heat Treatment of Metals, 2023, 48(4): 211-220.

参考文献

[1]杜行. 新型材料和工艺在汽车轻量化中的应用[J]. 科技创新与应用, 2019(5): 148-150.
[2]Schruff I. Special hot-work tool steels for die cast structural components of passenger cars [C]//Developing the World of Tooling, 9th International Tooling Confe-rence. Leoben, 2012.
[3]王斌. 热作模具钢发展现状[J]. 模具制造, 2017, 17(2): 79-82.
Wang Bin. Development status of hot work die steel [J]. Die and Mould Manufacture, 2017, 17(2): 79-82.
[4]夏书文, 左鹏鹏, 吴晓春. 国内外压铸模具钢发展概述[J]. 模具制造, 2017, 17(7): 93-99.
Xia Shuwen, Zuo Pengpeng, Wu Xiaochun. Development of die-casting die steels at home and abroad [J]. Die and Mould Manufacture, 2017, 17(7): 93-99.
[5]Yeh Shu-Hung, Chiu L H, Pan Y T, et al. Relative dimensional change evaluation of vacuum heat-treated JIS SKD61 hot-work tool steels [J]. Journal of Materials Engineering and Performance, 2014, 23(6): 2075-2082.
[6]左鹏鹏, 黎军顽, 蒋波, 等. 压铸模具钢大模块固溶冷却过程的多物理场耦合数值研究[J]. 材料导报, 2017, 31(S2): 458-464.
Zuo Pengpeng, Li Junwan, Jiang Bo, et al. Multi-physics coupling numerical study on cooling after solution heat treatment for a large die casting steel bloom [J]. Materials Review, 2017, 31(S2): 458-464.
[7]Heilmann P. Vacuum heat treatment-vacuum carburizing with high-pressure gas quenching [J]. Bergsmannen med Jernkontorets Annaler, 1997(3): 116, 119.
[8]贺连芳, 李辉平, 赵国群. 淬火过程中温度、组织及应力/应变的有限元模拟[J]. 材料热处理学报, 2011, 32(1): 128-133.
He Lianfang, Li Huiping, Zhao Guoqun. FEM simulation of temperature, phase-transformation and stress/strain in quenching process [J]. Transactions of Materials and Heat Treatment, 2011, 32(1): 128-133.
[9]宿德军, 陈军. 热处理过程数值模拟的研究现状和发展趋势[J]. 模具技术, 2004(6): 54-57.
Su Dejun, Chen Jun. Present research status and trend in development of numerical simulation on heat treatment [J]. Die and Mould Technology, 2004(6): 54-57.
[10]Sugimoto T, Taniguchi K, Yamada S. Research for utility of combination calculation method between heat treatment simulation and computer fluid dynamics [J]. Materials Performance and Characterization, 2019, 8(2): 37-39.
[11]顾剑锋, 潘健生, 胡明娟, 等. 9Cr2Mo冷轧辊加热过程的数值模拟[J]. 金属学报, 1999, 35(12): 1266-1270.
Gu Jianfeng, Pan Jiansheng, Hu Mingjuan, et al. Numerical simulation on heating process of 9Cr2Mo cold roller [J]. Acta Metallurgica Sinica, 1999, 35(12): 1266-1270.
[12]陈旭阳, 陆文林, 杜春辉, 等. 大长径比零件高压气淬温度场数值模拟[J]. 金属热处理, 2021, 46(10): 242-247.
Chen Xuyang, Lu Wenlin, Du Chunhui, et al. Numerical simulation of temperature field of parts with large aspect ratio during high pressure gas quenching process [J]. Heat Treatment of Metals, 2021, 46(10): 242-247.
[13]汤磊磊, 黎军顽, 吴晓春. SDC99钢淬火过程中应力和组织演变的有限元模拟[J]. 材料科学与工艺, 2014, 22(2): 75-80.
Tang Leilei, Li Junwan, Wu Xiaochun. FEM simulation of the stress changing and phase transformation of the quenching process of SDC99 steel [J]. Materials Science and Technology, 2014, 22(2): 75-80.
[14]翁中杰. 传热学[M]. 上海: 上海交通大学出版社, 1987.
[15]Jung M, Kang M, Lee Y K. Finite-element simulation of quenching incorporating improved transformation kinetics in a plain medium-carbon steel [J]. Acta Materialia, 2012, 60(2): 525-536.
[16]苏兴武, 顾敏. 淬火冷却过程数值模拟的研究现状及展望[J]. 金属热处理, 2008, 33(6): 1-7.
Su Xingwu, Gu Ming. Research status and prospects of the numerical simulation of quenching process [J]. Heat Treatment of Metals, 2008, 33(6): 1-7.
[17]Johnson A W, Mehl R F. Reactions of kinetics in processes of nucleation and growth [J]. Trans AIME, 1939, 13(5): 416.
[18]Inoue T, Funatani K, Totten G E. Process modeling for heat treatment: Current status and future developments [J]. Journal of Shanghai Jiaotong University, 2000, 5(1): 14-25.
[19]Li H, Zhao G, He L. Finite element method based simulation of stress strain field in the quenching process [J]. Materials Science and Engineering A, 2008, 478(1/2): 276-290.
[20]蒋波, 左鹏鹏, 黎军顽, 等. 大截面DIEVAR钢模块固溶冷却行为的数值研究[J]. 上海金属, 2018, 40(2): 38-43.
Jiang Bo, Zuo Pengpeng, Li Junwan, et al. Numerical study on solid solution cooling behavior of DIEVAR steel block with large section [J]. Shanghai Metals, 2018, 40(2): 38-43.

压铸模具钢大模块真空高压气淬冷却过程的数值模拟

Numerical simulation of vacuum high-pressure gas quenching cooling process for large die-casting die steel modules

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