何博

发布者:阮勤超发布时间:2023-12-18浏览次数:10

何博   教授


业单位:上海交通大学                      

办公电话:021-67796017                      

联系地址:上海市松江区龙腾路333号实训楼5416

邮        编:201620                                                

电子邮件:hebo@sues.edu.cn



个人简介


        上海交通大学材料加工专业博士。2010-2016年在上海交通大学38238威尼斯欢迎你任教,   2016年末入职38238威尼斯欢迎你,参与创建校级实验室高温合金精密成型研究中心,研究兴趣为增材制造和精密铸造。近五年来主要围绕航空航天及医疗领域进行金属材料的液态成型及高能束控性与控形研究,承担了工信部绿色系统集成、上海市重大基础研究等多项国家及省部级科研项目,以第一作者或通讯作者身份发表了10余篇SCI论文,授权了8项国内外发明专利。发明的“基于激光的增减材复合制造方法与装备”已获得中、美、澳三国专利授权,尤为适合航空、航天、医疗等行业的复杂精细件的增材制造。


开设课程


  1. 压铸模设计  本科生课程  32学时(4学时/周)

  2. 材料先进加工技术   研究生课程  32学时(2学时/周)

  3. 材料组织结构表征   研究生课程  32学时(2学时/周)

 

代表性论著


  

  1. He Bo* ,Wan Jianfeng*,   Rong Yonghua; Evolution and formation mechanism of surface nanorelief   associated with martensite twin colony (MTC) in Mn-based alloy,   Materials and Design, 2020, 193: 108800.

  2. Li Zan; He Bo*;    Guo Qiang*; Strengthening and hardening mechanisms of additively    manufactured stainless steels: The role of cell sizes , Scripta    Materialia, 2020, 177: 17-21.

  3. Jin Xinyuan; Lan Liang*; Gao Shuang; He Bo*;   Rong Yonghua; Effects of laser shock peening on microstructure and   fatigue behavior of Ti–6Al–4V alloy fabricated via electron beam   melting, Materials Science and Engineering A-Structural Materials   Properties Microstructure and Processing, 2020, 780: 139199-139207.

  4. Lan Liang; Jin Xinyuan; Gao Shuang; He Bo*;   Rong Yonghua; Microstructural evolution and stress state related to   mechanical properties of electron beam melted Ti-6Al-4V alloy modified   by laser shock peening , Journal of Materials Science & Technology,   2020, 50: 153-161.

  5. Tian, Yuncan; Yang Dongye; Jiang Mengqi; He Bo*.    Accurate Simulation of Complex Temperature Field in Counter-Pressure    Casting Process Using A356 Aluminum Alloy. International Journal of    Metalcasting, 2020(9).

  6. Yao Dingye, Zhang Weixing, Ma Yuli, He Bo*.Numerical   Prediction and Experimental Analysis of the Anisotropy of Laser Powder   Bed Fusion Produced Ti-6Al-4V Body-Centered Cubic Lattice Structure.   Journal of Materials Engineering and Performance 32.7(2022):2963-2972.

  7. Wang Zhiqiang,He Bo*,  Song  Zhenfeng et al.Optimization of the Process Parameters of Laser  Beam  Powder Bed Fusion GTD222 Nickel-Based Superalloy Based on Two Laser Energy Densities. Metals 2022, 12(7), 1154.

  8. Fan Shijing, He Bo*, Liu Meishuai. Effect of Pulse Current Density on Microstructure of Ti-6Al-4V Alloy by Laser Powder Bed Fusion. Metals  2022, 12(8), 1327.

  9. Wang Zhiqiang, He Bo*, Song Zhenfeng et al.Research Progress of Laser Additive Manufacturing Nickel-Based Alloy Metal Matrix Composites. Metals  2023, 13(1), 129.

  10. Huo Junmei,  He Bo*, Lan. Liang. Effects of Boron on Microstructure  and Mechanical Properties of High-Nb TiAl Alloy Fabricated via Laser  Melting Deposition. Journal of Materials Engineering and Performance : 1-11.

  11. He Bo*, Lei Yiyu, Jiang Mengqi, et al.Optimal Design of the Gating and Riser System for Complex Casting Using an Evolutionary Algorithm. Materis  2022, 15(21), 7490.

  12. Song Zhenfeng, Wang Zhiqiang, He Bo*, et al. Effects   of non-equilibrium microstructures on microstructure evolution and   mechanical properties of laser powder bed fusion IN625 Ni-based   superalloy during long-term thermal exposure at 700℃ and 750℃. Materials Science and Engineering: A  2022, 20(856), 143883.

  13. Xiao Yusen, Lan Liang, He Bo*, et al. Mechanism of ultrahigh ductility obtained by globularization of alpha GB for additive manufacturing Ti-6Al-4V. Materials Science and Engineering: A  2022, 14(858), 144174.

  14. Gao S, Tan Z, He Bo*,   et al. Experimental Investigation and Numerical Simulation of Residual   Stress and Distortion of Ti6Al4V Components Manufactured Using  Selective  Laser Melting. Journal of Materials Engineering and  Performance, 2022,  31(10):8113-8123.

  15. Xin R , Lan L ,He Bo*,et   al. Fatigue properties of selective laser melted Ti-6Al-4V alloy   subjected to laser shock processing. Journal of Materials Science,  2022,  57(21):9619-9630.

  16. Bai C , Lan L , He Bo*,et al. Microstructure   evolution and cyclic deformation behavior of Ti-6Al-4V alloy via   electron beam melting during low cycle fatigue. International Journal  of  Fatigue, 2022(159-):159.

      


  

授权专利




序号

专利名称

专利类别

授权时间

角色

1

一种基于增材制造技术制备梯度结构金属件的方法,ZL109967739

中国发明专利

2021-07

第一发明人

2

一种界面换热系数及材料热导率的测量装置及测量方法,ZL 110018193

中国发明专利

2022-02

第一发明人

3

界面换热系数及材料热导率的激光加热测量装置及方法,ZL 109991266

中国发明专利

2022-07

第一发明人

4

一种基于激光熔化沉积的室温塑性优异的高铌钛铝合金制备方法,ZL 113600834

中国发明专利

2022-08

第一发明人

5

一种钛镍基合金材料及其制备方法与应用,CN202210632109.1

中国发明专利

2022-06

第一发明人

6

COMPOSITE   DEVICE FOR HIGH_PRECISION LASER ADDITIVESUBTRACTIVE MANUFACTURING17235701

美国发明专利

2021-04

第一发明人

7

METAL   ADDITIVE MANUFACTURING METHOD BASED ON DOUBLE HIGH-ENERGY BEAMS TECHNIQUE2021101664

澳大利亚革新专利

2021-06

第一发明人

8

POLISHING   METHOD FOR INNER AND OUTER SURFACES OF COMPLEX CAVITY ADDITIVE MANUFACTURING   PARTS2021102055

澳大利亚革新专利

2021-05

第一发明人




科研成果


  1. 上海市重大基础研究项目子课题,“面向复杂精细结构的金属增材制造”课题三——系统误差形成机理及控制,2017.6-2020.6,结题,主持。

  2. 中华人民共和国工业和信息化部绿色制造系统集成项目,先进涡轮发动机热端部件绿色关键工艺系统集成-子课题:1. 多尺度集成计算;2.  高温合金的增材制造,2017.12-2020.12结题,主持。

  3. 上海市经信委项目,航空射流管电液伺服阀关键部件激光增减材复合制造技术研发,2019.7-2023.3,结题,主持。