姓名:

张宏

性别:

出生年月:

1982-06

学位:

博士

职称:

副研究员/博士生导师

联系电话:

028-64698160

电子邮箱:

zzhanghong@scu.edu.cn

通讯地址:

成都市一环路南一段24号新葡萄8883官网AMG建环学院力学系

邮编:

610065



【个人描述】

主要从事材料力学性能与微观演化跨尺度评价及寿命可靠性一体化研究,针对力学性能与微观结构定量映射与失效机制问题,及材料或结构服役寿命与可靠性一体化评估现状,提出材料加工-材料服役-寿命评估一体化解决方案,发展光滑算法与局部-全局映射关联技术,研究考虑材料加工工艺对复杂载荷和服役环境下材料力学行为与微观演化机制的影响,解决考虑材料加工工艺影响的材料服役性能与寿命评估问题,实现准确且高效地细观与宏观多尺度材料力学性能与寿命可靠性评估,揭示复杂载荷和环境下材料力学性能与微观演化之间映射关系和作用机制,阐明材料损伤机制与失效机理,为工程服役损伤评估与材料性能设计提供理论依据和技术指导。目前已构建了多种疲劳寿命预测模型并已在企业产品设计和使用端验证应用。近年来主持国家及省部级科研课题40余项,发表学术论文50余篇,其中SCI论文40篇,申请发明专利40项,其中已授权中国发明18项(已成功转让一项)、美国发明专利2项,实用新型专利2项、软件著作权8项。

欢迎具有材料学/材料加工、力学、机械、计算机等专业背景的学者/学生咨询,熟悉微观表征、有限元及编程者优先。


【学习及工作经历】

2021/08-至今,新葡萄8883官网AMG,新葡萄8883官网AMG,副研究员

2019/08, 德国克劳斯塔尔工业大学(Technische Universität Clausthal),访学

2018/10-2021/10,新葡萄8883官网AMG,新葡萄8883官网AMG,固体力学博士后

2015/09-2018/09,新葡萄8883官网AMG,新葡萄8883官网AMG,固体力学,博士

2012/06-2015/05,中国第二重型机械集团大型铸锻件数值模拟国家工程实验室,主任工程师

2007/07-2012/05,法国ESI 集团,技术部,产品经理

2004/09-2007/06,西南交通大学,材料加工工程,硕士

2000/09-2004/06,兰州理工大学,材料成型及控制工程,学士


【主要研究领域】

1.材料力学行为、损伤机制及寿命可靠性评估

2.材料改性、微观表征及本构关系与结构拓扑优化

3.材料加工工艺与力学性能集成计算及数据分析


【承担的主要课程】

本科:理论力学,结构力学,材料工艺力学与数值模拟方法(跨学科交叉课程)

研究生:材料疲劳与结构耐久性,材料科学与工程前沿,非线性有限元法


【主持的科研及教改项目】

1.国家自然科学面上基金,12272245,热-机载荷下叶片材料塑性损伤机理与蠕变-疲劳寿命预测研究

2.四川省应用基础研究项目(需求引导型),2022NSFSC0324,增材制造钛铝合金温度相关力学性能、微观演化及寿命评估技术研究

3.国家博士后面上基金,2019M653396,增材制造镍基材料疲劳失效与微观组织演化影响研究

4.中央高校基本科研项目,疲劳载荷下高温转子耐热钢循环软化与损伤机理研究

5.新葡萄8883官网AMG博士后基金,2019SCU12056,基于试验与晶体塑性计算研究疲劳裂纹萌生机理和微观短裂纹扩展行为

6.新葡萄8883官网AMG-自贡市政府战略合作项目,2019-CDZG-4,增材制造零部件工艺设计与服役性能评估技术研究

7.新葡萄8883官网AMG-宜宾市政府战略合作项目,2019-CDYB-24,汽车超高强钢冲压回弹工艺模拟应用研究

8.国家重点实验室项目,HG2020057,定向晶材料热等静压及热处理技术开发研究

9.国家重点实验室项目,HG2020070,压缩机技术研究及开发(离心式)-超高周疲劳性能研究

10.国家重点实验室项目,HG2019027,630℃高温转子耐热钢微观性能与疲劳寿命评估研究

11.国家重点实验室项目,HG2019010,模拟件寿命评估相关疲劳和断裂试验研究

12.企业横向,21H0107,增材制造工艺过程数值仿真与疲劳失效机理研究

13.企业横向,HG2020070,基于GROD/KAM技术的镍基高温合金部件服役损伤形式评估技术研究

14.企业横向,HG2023130,弹簧疲劳性能试验与寿命评估仿真硏究

15.其他项目等45项。

参与科研项目:

1.国家自然科学重点基金项目,12332012,复杂条件下增材制造材料超长寿命服役损伤表征与性能调控


获奖荣誉

1.复杂环境载荷下超长寿命疲劳加速测试关键技术与装备研发教育部高等学校技术发明奖排名第三)

2.复杂条件下高频振动疲劳试验技术与应用,中国发明协会 一等奖(排名第三

3.中国产学研合作创新与促进奖产学研合作创新成果奖 二等奖(排名第六)

4.全国高等学校力学类专业优秀本科毕业设计论文 指导老师

5.新葡萄8883官网AMG生力学竞赛暨第八届孙训方大学生力学竞赛 优秀指导教师

6.新葡萄8883官网AMG本科优秀毕业论文 指导老师


【代表性论著】

1.Y. Yang, B. Zhang, H. Wu, Y. Zhang, Hong. Zhang*, Y. Liu, Q. Wang, A deep learning approach for low-cycle fatigue life prediction under thermal–mechanical loading based on a novel neural network model, Engineering Fracture Mechanics 306 (2024).

2.T. Zou, M. Liu, Q. Wang, Y. Jiang, H. Wu, Hong. Zhang*, Y. Pei, Y. Liu, Q. Wang, New approach to low-cycle fatigue lifetime prediction for deep-rectangular notched components with finite residual thickness: Experiment and simulation, International Journal of Fatigue (2024) 108380.

3.Y. Jiang, T. Zou, M. Liu, Q. Wang, Y. Pei, Hong. Zhang*, Y. Liu, Q. Wang, Tensile Deformation Behaviors and Microstructure Evolution Under Various Temperatures for MAR‐M247 Nickel‐Based Superalloy, Adv Eng Mater (2024) 2302056.

4.Hong. Zhang, Y. Jiang*, M. Liu, T. Zou, Q. Wang, H. Wu, Y. Pei, Y. Liu, Q. Wang, The Effect of Laser Shock Peening with Different Power Density on the Microstructure Evolution and Mechanical Properties of MAR-M247 Nickel-base alloy, Journal of Materials Research and Technology  (2024).

5.T. Zou, M. Liu, Q. Wang, Y. Jiang, H. Wu, Z. Gao, Y. Pei, Hong. Zhang*, Y. Liu, Q. Wang, Evolutionary mechanisms in the plastic deformation of γ'-Ni3(Al, Ti)-strengthened additively manufactured nickel-based 939 superalloys at intermediate temperatures, Materials & Design  (2024) 112795.

6.M. Liu, T. Zou, Q. Wang, Y. Jiang, H. Wu, Y. Pei, Hong. Zhang*, Y. Liu, Q. Wang, Microstructure evolution, failure mechanism and life prediction of additively manufactured Inconel 625 superalloy with comparable low cycle fatigue performance, International Journal of Fatigue 181 (2024) 108142.

7.Y. Jiang, M. Liu, T. Zou, Q. Wang, H. Wu, Y. Pei, Hong. Zhang*, Y. Liu, Q. Wang, Numerical simulation and high cycle fatigue behaviour study on shot peening of MAR-M247 Nickel-based alloy, International Journal of Fatigue  (2024) 108161.

8.Q. Wang, M. Liu, T. Zou, Y. Jiang, Z. Gao, Y. Pei, Hong. Zhang*, Y. Liu, Q. Wang, The cyclic deformation behavior and microstructural evolution of 304L steel manufactured by selective laser melting under various temperatures, Materials Science and Engineering: A  (2023) 145949.

9.T. Zou, Q. Wang, Y. Pei, T. Mei, Hong. Zhang*, Mechanisms of Serrated Flow and Microstructural Evolution in MarBN Steel, Materials 16(19) (2023) 6411.

10.Q. Wang, Y. Cai, M. Liu, Q. Li, Y. Pei, Hong. Zhang*, Y. Liu, Q. Wang, The cyclic response behavior, failure mechanism, and life prediction model of 9% Cr‐based steel under different strain ratios in the low cyclic fatigue regime at 430°C, Fatigue & Fracture of Engineering Materials & Structures (2023).

11.Y. Zhang, Hong. Zhang*, T. Zou, M. Liu, Q. Wang, Y. Pei, Y. Liu, Q. Wang, Microstructure-Based Multiscale Modeling of Deformation in MarBN Steel under Uniaxial Tension: Experiments and Finite Element Simulations, Materials 16(14) (2023).

12.M. Liu, Y. Cai, Q. Wang, Y. Jiang, T. Zou, Y. Wang, Q. Li, Y. Pei, Hong. Zhang*, Y. Liu, Q. Wang, The low cycle fatigue property, damage mechanism, and life prediction of additively manufactured Inconel 625: Influence of temperature, Fatigue & Fracture of Engineering Materials & Structures  (2023).

13.Q. Wang, F. Yang, T. Zou, M. Liu, Y. Jiang, Y. Pei, Hong. Zhang*, Y. Liu, Q. Wang, Effect of microstructure on the fatigue crack growth behavior of 9%Cr martensitic steel at different stress ratios under 630 ℃, International Journal of Fatigue 175 (2023) 107796.

14.T. Zou, M. Liu, Y. Cai, Q. Wang, Y. Jiang, Y. Wang, Z. Gao, Y. Pei, Hong. Zhang*, Y. Liu, Q. Wang, Effect of temperature on tensile behavior, fracture morphology, and deformation mechanisms of Nickel-based additive manufacturing 939 superalloy, Journal of Alloys and Compounds (2023) 170559.

15.T. Zou, M. Liu, Y. Cai, Q. Wang, Y. Jiang, Y. Wang, Y. Pei, Hong. Zhang*, Y. Liu, Q. Wang, Analysis of the Tensile Deformation Behaviors and Microstructure Characterization under Various Temperatures of MarBN Steel by EBSD, Materials, 2023.

16.Y. Jiang, T. Zou, M. Liu, Y. Cai, Q. Wang, Y. Wang, Y. Pei, Hong. Zhang*, Y. Liu, Q. Wang, Temperature and Strain Rate Dependence on the Tensile Mechanical Properties, Constitutive Equations, and Fracture Mechanisms of MarBN Steel, Materials, 2023.

17.Q. Wang, M. Liu, Y. Cai, T. Wang, Y. Pei, Hong. Zhang*, Y. Liu, Q. Wang, The high cycle fatigue behavior, failure characteristics, and fatigue life empirical relationship of 9% Cr steel under different stress ratios at 630 °C, International Journal of Fatigue 170 (2023).

18.Hong Zhang, D. Lu, Y. Pei, T. Chen, T. Zou, T. Wang, X. Wang, Y. Liu, Q. Wang, Tensile behavior, microstructural evolution, and deformation mechanisms of a high Nb-TiAl alloy additively manufactured by electron beam melting, Materials & Design 225 (2023).

19.Y. Cai, Q. Wang, M. Liu, Y. Jiang, T. Zou, Y. Wang, Q. Li, Y. Pei, Hong Zhang*, Y. Liu, Q. Wang, Tensile Behavior, Constitutive Model, and Deformation Mechanisms of MarBN Steel at Various Temperatures and Strain Rates, Materials 15(24) (2022) 8745.

20.Hong Zhang, Yubing. Pei, Xiufang Gong, Xiaohui Chen, Wei Zhang, Peng Zhang, Lang Li, Yongjie Liu, Qingyuan Wang, Deformation nanotwins in a single-crystal Ni-based superalloy at room temperature and low strain rate, Mater Charact 187 (2022) 111865.

21.Tianjian Wang, Hong Zhang*, Chunhua Liu, Xiufang Gong, Yubing Pei, Yu Zou, Yongjie Liu, Qingyuan Wang, Effect of temperature on tensile behavior, fracture morphology and deformation mechanisms of Nickel-based single crystal CMSX-4, Journal of Alloys and Compounds (2022) 165175.

22.Ma Yaxin, Zhang Hong*, Gao Yifei, Men Zhengxing, He Ling, Cao Jianguo, Failure analysis of a natural gas transmission X60 steel pipeline, Anti-Corrosion Methods and Materials 2022.

23.Hong Zhang, Quanyi Wang, Xiufang Gong, Tianjian Wang, Yubing Pei, Wei Zhang, Yongjie Liu, Chong Wang, Qingyuan Wang, Comparisons of low cycle fatigue response, damage mechanism, and life prediction of MarBN steel under stress and strain-controlled modes, International Journal of Fatigue 149 (2021).

24.Hong Zhang, Quanyi Wang, Xiufang Gong, Tianjian Wang, Wei Zhang, Ke Chen, Chong Wang, Yongjie Liu*, Qingyuan Wang, Dependence on temperature of compression behavior and deformation mechanisms of Nickel-based single crystal CMSX-4[J]. Journal of Alloys and Compounds, (2021) 158878.

25.Xiufang Gong, Tianjian Wang, Qingsong Li, Yongjie Liu, Hong Zhang*, Wei Zhang, Quanyi Wang, Qingyuan Wang, Cyclic responses and microstructure sensitivity of Cr-based turbine steel under different strain ratios in low cycle fatigue regime, Materials & Design (2021) 109529.

26.X. Zhang, T. Wang, X. Gong, Q. Li, Y. Liu, Q. Wang, Hong Zhang*, Q. Wang, Low cycle fatigue properties, damage mechanism, life prediction and microstructure of MarBN steel: Influence of temperature[J]. International Journal of Fatigue, 2021, 144:106070.

27.Liu, Meng, Quanyi Wang, Yifan Cai, Dong Lu, Tianjian Wang, Yubing Pei, Hong Zhang*, Yongjie Liu, and Qingyuan Wang, Comparison in Deformation Behavior, Microstructure, and Failure Mechanism of Nickel Base Alloy 625 under Two Strain Rates, Materials. 2021; 14(10):2652.

28.Hong Zhang, Peidong Li, Xiufang Gong, Tianjian Wang, Lang Li, Yongjie Liu, Qingyuan Wang, Tensile properties, strain rate sensitivity and failure mechanism of single crystal superalloys CMSX-4, Materials Science and Engineering: A (2020) 782(24).

29.Q. Wang, Q. Wang, X. Gong, T. Wang, W. Zhang, L. Li, Y. Liu, C. He, C. Wang, Hong Zhang*, A comparative study of low cycle fatigue behavior and microstructure of Cr-based steel at room and high temperatures, Materials & Design 195 (2020) 109000.

30.Q. Wang, Y. Chen, Y. Liu, C. Wang, L. Li, C. He, X. Gong, T. Wang, W. Zhang, Q. Wang, Hong Zhang*, The Effect of Stress Ratios on the Very High Cycle Fatigue Behavior of 9%Cr Turbine Steel at 630 °C, Materials 13(216) (2020) 3444.

31.Hong Zhang, P. Li, Q. Wang*, Z. Guan, Y. Liu, X. Gong, Electron Beam Welding of Nimonic 80A Superalloy: Microstructure Evolution and EBSD Study After Aging Heat Treatment, Journal of Materials Engineering and Performance 28(2) (2019) 741-752.

32.Hong Zhang, P. Li, Q. Wang*, Y. Liu, Fatigue Crack Propagation of Nickel-Based Superalloy: Experiments and Simulations with Extended Finite Element Method, Journal of Materials Engineering and Performance 28(2) (2019) 967-972.

33.Hong Zhang, J.K. Li, Z.W. Guan, Y.J. Liu, D.K. Qi, Q.Y. Wang*, Electron beam welding of Nimonic 80A: Integrity and microstructure evaluation, Vacuum 151 (2018) 266-274.

34.Hong Zhang, M. Zhengxing, L. Jiukai, L. Yongjie, W. Qingyuan*, Numerical Simulation of the Electron Beam Welding and Post Welding Heat Treatment Coupling Process, High Temperature Materials and Processes 37(9-10) (2018) 793-800.

35.Hong Zhang, Huang C, Guan Z, Li J, Liu Y, Chen R, Wang Q*. Effects of the Electron Beam Welding Process on the Microstructure, Tensile, Fatigue and Fracture Properties of Nickel Alloy Nimonic 80A[J]. Journal of Materials Engineering and Performance, 2017,27:(1): 89-98.

36.Hong Zhang, Z.W. Guan, Q.Y. Wang, Y.J. Liu, J.K. Li, Effects of Stress Ratio and Microstructure on Fatigue Failure Behavior of Polycrystalline Nickel Superalloy, Journal of Materials Engineering and Performance 27(5) (2018) 2534-2544.

37.P. Zhang, Y. Yuan, J. Li, J.B. Yan, Hong Zhang, X.B. Zhao, X.B. Shi, Y.F. Gu, Deformation Modes in the Single-Crystal Nickel-Based Superalloy CMSX-4 During Compressive Deformation at 1000 °C, Metall and Mat Trans A 53(2) (2022) 388-393.

38.Y. Liu, Y. Chen, C. He, F. Liu, K. Yang, L. Li, Hong Zhang, C. Wang, Q. Wang, Vacuum retarding and air accelerating effect on the high-cycle and very-high-cycle fatigue behavior of a ZK60 magnesium alloy, Materials & Design, (2020) 109310.

39.P. Li, Y. Liu, Hong Zhang, Q. Wang*, Indentation on a half-infinite one-dimensional hexagonal quasi-crystal space by a rigid flat-ended cylindrical indenter with uniform heat flux or temperature, Mechanics of Materials 131 (2019) 33-46.

40.P. Li, Hong Zhang, Q. Wang, B. Shao, H. Fan, Effect of temperature on the performance of laterally constrained dielectric elastomer actuators with failure modes, Journal of Applied Polymer Science, 137 (2020).

41.Y. Chen, C. He, K. Yang, Hong Zhang, C. Wang, Q. Wang, Y. Liu, Effects of microstructural inhomogeneities and micro-defects on tensile and very high cycle fatigue behaviors of the friction stir welded ZK60 magnesium alloy joint, International Journal of Fatigue 122 (2019) 218-227.

42.Y. Liu, Y. Chen, C. He, F. Liu, K. Yang, L. Li, Hong Zhang, C. Wang, Q. Wang, Vacuum retarding and air accelerating effect on the high-cycle and very-high-cycle fatigue behavior of a ZK60 magnesium alloy, Materials & Design (2020) 109310.

43.F. Liu, Hong Zhang, H. Liu, Y. Chen, K. Muhammad Kashif, Q. Wang, Y. Liu, Influence of Welded Pores on Very Long-Life Fatigue Failure of the Electron Beam Welding Joint of TC17 Titanium Alloy, Materials 12(11) (2019) 1825.

44.门正兴, 郑金辉, 王昌飞, 张宏, 刘建超, 马亚鑫, 岳太文, 激光选区熔化成形Ti6Al4V钛合金叶片的超高周疲劳行为, 锻压技术, 45 (2020) 89-93+125.

45.张宏, 李久楷, 刘永杰, 王清远*, GH80A镍合金电子束焊接接头旋转弯曲高周疲劳行为研究, 工程科学与技术 49(04) (2017) 188-195.

46.李久楷, 刘永杰, 张宏, 杨昆, 王清远*, Ti-6Al-4V在模拟体液中的超高周疲劳裂纹萌生与扩展, 实验力学 31(06) (2016).

47.孙德润,张宏,门正兴,冷却速度对铸件二次枝晶臂间距影响的模拟研究,大型铸锻件,2014(04):1-3+10

48.瞿贵峰,门正兴,李英,张宏,有色金属轧机工作辊感应淬火过程数值模拟分析,大型铸锻件, 2014(05):11-13

49.王秋林, 李明富, 门正兴, 李勇, 张宏*, 激光熔化沉积制造翅片热管管壳, 热加工工艺 1-5.

50.曾小平, 王秋林, 马亚鑫, 张宏*, 7075铝合金激光熔覆Al-Cr复合涂层, 粉末冶金工业 1-7.

51.门正兴, 郑金辉, 王昌飞, 张宏*, 激光选区熔化成形Ti6Al4V钛合金叶片的超高周疲劳行为, 锻压技术 45(11) (2020) 89-93+125.


教改文章

张宏,刘迪,何超,李浪,王宠,刘永杰,王清远,“新工科”背景下面向智能制造的力学专业教改探究,中国多媒体与网络教学学报,2023


【学术兼职】

清洁高效透平动力装备全国重点实验室技术顾问

机械工业高温、高压材料与焊接重点实验室学术委员

中国材料研究学会疲劳分会理事

四川省振动力学学会理事

中国力学学会会员

四川省力学学会会员

International Journal of Fatigue /Journal of Materials Engineering and Performance/ Vacuum/Science reports/Material letters等期刊审稿人


【发明专利

1.张宏,杨洋,张博,胡正玮,刘永杰,王清远,一种基于深度学习的低周疲劳寿命预测方法,2024-03-22,中国,ZL 202410180390.9

2.张宏,张博,张博,杨洋,胡正玮,刘永杰,王清远,一种金属材料温度与应变速率相关塑性硬化模型计算方法,2024-03-22,中国,ZL 202410044916.0

3.张宏,张意达,彭堃恩,张博,杨洋,胡正纬,基于人工神经网络的电子束增材制造本构关系计算方法,2023-10-27,中国,ZL202310988095.1

4.张宏,邱近贻,牛池,彭堃恩,梅瑞东,李艳,刘永杰,王宠,何超,李浪,王清远.一种用于激光增材制造工艺的热源数值模拟方法,2022-09-27, 中国,ZL202110474227.X

5.张宏,刘佳,何杨,李艳,刘永杰,王宠,何超,李浪,王清远.基于材料本构优化模型的汽车高强度钢冲压回弹优化方法,2022-09-27, 中国,ZL202110474304.1

6.张宏,张玮,王林森,王清远,刘永杰,王宠,何超,李浪.一种低周疲劳测试数据处理与内应力评估方法,2021-11-22, 中国,ZL202010588246.0

7.张宏,张玮,王林森,王清远,刘永杰,王宠,何超,李浪. 基于晶体塑性的疲劳裂纹萌生与扩展的损伤寿命评估方法,2021-06-30, 中国,ZL202010586845.9

8.张宏,张玮,王林森,王清远,刘永杰,王宠,何超,李浪.一种基于机器学习的材料抗疲劳优化设计方法,2021-06-01, 中国,ZL202010321360.7

9.张宏,王清远,刘永杰,王宠,何超,李浪. 针对单晶材料热-机疲劳本构模型的损伤计算方法,2021-02-23, 中国,ZL202010321378.7

10.张宏,王清远,刘永杰,王宠,李浪. 基于Abaqus平台疲劳损伤与寿命评估计算方法,2019-06-12, 中国,ZL201910507043.1

11.张宏,王清远,刘永杰,王宠,李浪. 基于晶体塑性焊接工艺模型的损伤与疲劳寿命评估方法,2019-06-12,中国,ZL201910507813.2

12.张宏,王清远,刘永杰,王宠,李浪. 微观-宏观尺度钣金成形工艺模型的损伤与疲劳寿命评估方法,2019-06-12,中国,ZL201910507041.2

13.王清远,张宏,李久楷,刘永杰. 材料热加工全流程热力流微观组织多物理场数值计算方法,2016-07-25,中国,ZL 201610585461.9

14.王清远,张宏,李久楷,刘永杰. 摩擦焊工艺热力流微观组织多物理场数值计算方法,2016-07-25,中国,ZL201610586477.1

15.刘永杰,张宏,王清远,王宠,李浪. 面心立方材料疲劳过程晶体塑性本构模型建立方法,2019-06-12,中国,ZL201910507805.8

16.刘迪,李胤熙,陈腾,张宏,一种用于材料拉伸本构参数拟合的高通量计算方法,2022-05-11, 中国,ZL202210515162.3

17.ZHANGHONG et al. METHOD FOR ASSESSING FATIGUE DAMAGE AND A FATIGUE LIFE BASED ON A CRYSTAL PLASTIC WELDING PROCESS MODEL, US Patent, GBCD044-PKG.

18.ZHANGHONG et al. METHOD FOR ASSESSING FATIGUE DAMAGE AND FATIGUE LIFE BASED ON ABAQUS, US Patent, GBCD043-PKG.


【实用新型专利】

1.一种结构单元类零件高周疲劳专用夹具,2020-04-08,中国,ZL201921840339.7

2.一种缺陷条带微型弹簧类零件高周疲劳专用夹具,2020-04-08,中国,ZL201921853444.4


【软件著作权】

1.疲劳损伤与寿命评估计算软件V1.0,2020SR0933313

2.疲劳寿命与可靠性评估数据库系统V1.0,2020SR0927272

3.材料拉伸本构参数拟合高通量计算软件V1.0,2022SR0674625

4.基于温度和应变速率本构模型的冲压成型计算软件V1.0,2022SR0674624

5.焊接工艺专家库系统V1.0,2023SR0242642

6.增材制造工艺数据库专家系统V1.0,2023SR0246137

7.材料性能数据库系统V1.0,2023SR0246160

8.增材制造工艺分析插件软件V1.0,2023SR1355080



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