锻压技术

GH4169合金压缩热变形行为及临界损伤值

英文标题：Compression hot deformation behavior and critical damage value for alloy GH4169

作者：刘光辉1 孙红星1 2 郑晓磊3 王龙飞3 蔡宗超3 康根发4 秦单单4 刘华1

单位：1.中国机械总院集团郑州机械研究所有限公司 2.西安交通大学机械工程学院 3.河南平高电气股份有限公司 4.河南航天精工制造有限公司

关键词：GH4169合金热变形行为热加工图临界损伤值 Arrhenius本构方程

分类号：TG316.3

出版年,卷(期):页码：2025,50(2):227-234

摘要：

针对GH4169合金在锻造过程中存在的变形抗力大、锻造温度区间窄、易出现锻造裂纹等问题，对其热变形行为和临界损伤值进行研究。通过单道次热压缩实验得到GH4169合金在不同变形条件下的真应力-真应变曲线，经线性拟合后得到Arrhenius本构方程。基于实验数据进行了GH4169合金压缩热变形模拟，根据模拟结果分析了热变形过程中的最大损伤值，进而求得临界损伤值。研究结果表明：当变形温度一定时，GH4169合金的真应力与应变速率呈正相关；当应变速率一定时，GH4169合金的真应力与变形温度呈负相关。GH4169合金压缩热变形过程中的临界损伤值在不同变形条件下在一定范围内波动，且其对应变速率较敏感，当变形温度不变时，随着应变速率的增大，临界损伤值逐渐增大。研究结果对于GH4169合金的锻造工艺制定及其裂纹预测具有一定的指导意义。

For the problems of high deformation resistance, narrow forging temperature range and easy occurrence of forging cracks during the forging process of alloy GH4169, the hot deformation behavior and critical damage value were studied. Through a single pass hot compression experiment,the true stress-true strain curves of alloy GH4169 under different deformation conditions were obtained,and the Arrhenius constitutive equation was obtained by linear fitting. Based on the experimental data, the compression hot deformation of alloy GH4169 was simulated, and according to the simulation results, the maximum damage value during the hot deformation process of alloy GH4169 was analyzed to obtain the critical damage value. The research results indicate that when the deformation temperature is constant, the true stress of alloy GH4169 is positively correlated with the strain rate, and when the strain rate is constant, the true stress of alloy GH4169 is negatively correlated with the deformation temperature. The critical damage value of alloy GH4169 during the compression hot deformation process fluctuates within a certain range under different deformation conditions, and the critical damage value is sensitive to the strain rate. When the deformation temperature remains constant, the critical damage value gradually increases with the increasing of strain rate. The research results have certain guiding significance for the forging process formulation and crack prediction of alloy GH4169.

基金项目：

科研院所双创基金项目（203SC2023001-07）；河南省重点研发专项基金项目（231111221800）

作者简介：刘光辉(1989-)，男，硕士，高级工程师,E-mail：liu0406gh@163.com;通信作者：孙红星（1975-），男，博士，研究员,E-mail：sunhx@zrime.com.cn

参考文献：

[1]赵海生,房立家,刘欢,等.热等静压对激光选区熔化成形GH4169合金组织与高温性能的影响[J].航空材料学报, 2024, 44(1):84-92.

Zhao H S, Fang L J, Liu H, et al. Effect of hot isostatic pressing on microstructure and high temperature properties of GH4169 alloy formed by selective laser melting [J]. Journal of Aeronautical Materials, 2024, 44 (1): 84-92.

[2]石照夏,胥国华,刘宁,等.C含量对GH4169合金显微组织及力学性能的影响[J].稀有金属材料与工程, 2023, 52(8):2926-2934.

Shi Z X, Xu G H, Liu N, et al. Effect of C content on microstructure and mechanical properties of GH4169 alloy [J]. Rare Metal Materials and Engineering, 2023, 52 (8): 2926-2934.

[3]李俊玲,李征,王宝雨,等.GH4169合金叶片楔横轧预制坯成形质量研究[J].机械工程学报, 2023,59(24):72-82.

Li J L, Li Z, Wang B Y, et al. Study on the forming quality of GH4169 alloy blade preformed by cross wedge rolling [J]. Journal of Mechanical Engineering, 2023, 59 (24): 72-82.

[4]刘明哲,乔桂英,刘猛, 等. 资源节约型 GH4169 合金热变形行为及热加工图[J].材料热处理学报,2021,42(11):131-139.

Liu M Z, Qiao G Y, Liu M, et al. Hot deformation behavior and hot processing map of resource-saving GH4169 superalloy [J]. Transactions of Materials and Heat Treatment, 2021, 42 (11): 131-139.

[5]任永海,程治,王龙祥,等.锻态GH4169合金热变形本构方程及热加工图[J].精密成形工程, 2023, 15(5):148-155.

Ren Y H, Cheng Z, Wang L X, et al. Constitutive equation for hot deformation and hot processing map of wrought GH4169 superalloy [J]. Journal of Netshape Forming Engineering, 2023, 15 (5): 148-155.

[6]丁奔,蔡军,张兵,等.GH4169稀土强化镍基高温合金热变形行为[J].塑性工程学报, 2023, 30(9):131-141.

Ding B, Cai J, Zhang B, et al. Hot deformation behavior of GH4169 rare earth reinforced Ni-base superalloy [J]. Journal of Plasticity Engineering, 2023, 30 (9): 131-141.

[7]张兵,岳磊,陈韩锋,等.铸态GH4169合金热变形行为及三种本构模型对比[J].稀有金属材料与工程, 2021,50(1):212-222.

Zhang B, Yue L, Chen H F, et al. Hot deformation behavior of as-cast GH4169 alloy and comparison of three constitutive models [J]. Rare Metal Materials and Engineering, 2021,50 (1): 212-222.

[8]郭昊函,杨杰,刘芳,等. GH4169合金拘束相关的疲劳裂纹萌生寿命[J].金属学报, 2022,58 (12): 1634-1644.

Guo H Ｈ, Yang J, Liu F, et al. Constraint related fatigue crack initiation life of GH4169 superalloy [J]. Acta Metallurgica Sinica, 2022, 58 (12): 1634-1644.

[9]GB/T 7314—2017,金属材料室温压缩试验方法[S].

GB/T 7314—2017, Metallic materials—Compression test method at room temperature[S].

[10]罗登,胡斌,王振,等.近β钛合金Ti-55511热塑性变形的流变应力分析与Arrhenius本构方程研究[J].粉末冶金材料科学与工程, 2023, 28(3):212-222.

Luo D, Hu B, Wang Z, et al. Flow stress analysis and Arrhenius constitutive equation of near β titanium alloy Ti-55511 during thermoplastic deformation [J]. Materials Science and Engineering of Powder Metallurgy, 2023, 28 (3): 212-222.

[11]张义俊,冯亚磊,郭晓光,等.2195铝锂合金的热变形行为及本构方程研究[J].锻压技术, 2023, 48(9):239-247.

Zhang Y J, Feng Y L, Guo X G, et al. Study on thermal deformation behavior and constitutive equation of 2195 Al-Li alloy [J]. Forging & Stamping Technology, 2023, 48 (9): 239-247.

[12]段继平,唐湘林,盛俊英,等.热挤压态FGH95合金热变形特性[J].粉末冶金技术, 2024, 42(1):36-44.

Duan J P, Tang X L, Sheng J Y, et al. Hot deformation characteristics of hot extruded FGH95 superalloys [J]. Powder Metallurgy Technology, 2024, 42 (1): 36-44.

[13]Chen D, Yang Q R, Yang N C, et al. Hot compressive deformation and microstructural evolution of 60NiTi alloy[J].Transactions of Nonferrous Metals Society of China, 2023 (1): 189-200.

[14]郁天其,闫宏,陈荣石.EV31镁合金热压缩变形行为及热加工图[J].材料热处理学报, 2023,44(4):59-68.

Yu T Q, Yan H, Chen R S. Hot compression deformation behavior and hot processing map of EV31 magnesium alloy [J]. Transactions of Materials and Heat Treatment, 2023,44 (4): 59-68.

[15]田继红,陈彦龙,袁海伦,等.12%Cr超超临界转子钢锻造裂纹机理分析及损伤模型建立[J].塑性工程学报, 2022, 29(10):135-142.

Tian J H, Chen Y L, Yuan H L, et al. Forging crack mechanism analysis and damage model establishment of 12%Cr ultra-supercritical rotor steel [J]. Journal of Plasticity Engineering, 2022, 29 (10): 135-142.

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