王博

发布者:阮勤超发布时间:2017-08-17浏览次数:8891

姓名:王博

职称:副教授

所属学院:材料工程学院

研究方向

1.金属基复合材料方向

2.高能束表面性能改善

通讯地址:上海市松江区龙腾路333号行政楼1619

邮编201620

联系电话67791203

电子邮箱wangbo@sues.edu.cn; power_xx@126.com

教育背景:

2005.09~2009.07  哈尔滨工业大学  bat365官网登录入口   材料科学与工程   学士

2009.09~2011.07  哈尔滨工业大学  bat365官网登录入口      材料学        硕士

2011.07~2015.07  哈尔滨工业大学  bat365官网登录入口      材料学        博士  

科研项目:

  1. 国家自然科学基金《网状结构TiBw/Ti60复合材料高温变形组织重构及演变机制研究》,2018.1-2020.12, 主持

  2. 上海市高校青年教师培养资助计划《网状结构钛基复合材料电子束表面改性研究》

2016.1-2017.12, 主持

  1. 第九批(2019 年)“上海高校教师产学研计划”, 践习单位:上海市上海构捷三维科技有限公司, 2019.7-2020.7, 主持;  

  2. 上海工程技术大学展翅计划, 2018.1-2020.12, 主持

  3. 上海工程技术大学校启动项目《网状结构钛基复合材料超塑性成型研究》, 2016.1-2017.12, 主持

  4. 横向《镁合金高温塑性变形行为研究》, 扬州大学, 2016.4-2017.4, 主持

  5. 横向《铸态高温合金力学性能研究》, 上海交通大学, 2017.4-2018.4, 主持

  6. 横向《IN939 高温合金熔铸实验与高温力学性能研究》, 上海交通大学, 2017.9-2018.9, 主持

  7. 横向《TA1 TA7 钛合金热变形行为研究》, 内蒙古工业大学, 2018.12-2019.12, 主持

  8. 横向《焊接热循环过程应力应变模拟测试》, 上海交通大学, 2019.10-2020.10, 主持

  9. 国家自然科学基金《压凝固 Al-Cu 合金组织演变及力学性能研究》, 2017.1-2019.12, 第二参与人

  10. 国家自然科学基金《LiTiO3压电陶瓷结构缺陷的多角度调控机制及压电性能研究》, 2017.1-2019.12, 第二参与人

  11. 国家自然科学基金《Mg-RE合金热锻中第二相诱发空洞演化致其损伤断裂机制及多尺度模拟》, 2019.1-2021.12, 第三参与人

  12. 国家自然科学基金《增强体准连续网状分布TiB/TC4复合材料设计与制备基础研究》, 2011.1-2013.12, 第三参与人

  13. 国家自然科学基金《网状结构TiB/Ti60复合材料高温塑性变形与强化和氧化机理研究》, 2012.1-2014.12, 第三参与人

  14. 横向《中重型汽车转向节组织控制和性能提升研究》, 上海嘉仕久精密铸造有限公司, 2018.12-2019.12, 第二参与人

  15. 横向《新型电缆屏蔽用铝合金带材研究与开发》, 温州信德, 2019.8-2020.8, 第二参与人

  16. 横向《焊接热模拟技术》, 上海电气核电设备有限公司, 2019.5-2020.5, 第三参与人

主要论文:

  1. H. B. Zhang, B. Wang, Y. T. Zhang, Y. Li, J. L. He, Y. F. Zhang. Microstructure evolution and deformation mechanisms of β phase in TiBw/Ti60 composites studied by reconstructing grain during the hot deformation. Journal of Alloys and compounds. Available online 20 January 2020. (SCI 二区IF: 4.12)

  2. H. B. Zhang, B. Wang, Y. T. Zhang, Y. Li, J. L. He, Y. F. Zhang. Influence of aging treatment on the microstructure and mechanical properties of CNTs/7075 Al composites. Journal of Alloys and compounds. 2020, 814. (SCI 二区IF: 4.12)

  3. B. Wang. H.B. Zhang, L.J. Huang, J.L. He, Y.F. Zhang. Evolution of microstructure and high temperature tensile properties of as-extruded TiBw reinforced near-α titanium matrix composite subjected to heat treatments. SCIENCE CHINA Technological Sciences. 2018, 61:1340-1345.(SCI 二区IF: 2.25)

  4. B. Wang, L.J. Huang, L. Geng. Modification of microstructure and tensile property of TiBw/near-alpha Ti composites by tailoring TiBw distribution and heat treatment. Journal of Alloys and compounds. 2017, 690:424-430. (SCI 二区IF: 4.12)

  5. B. Wang, L.J. Huang, L. Geng. Effects of deformation conditions on the microstructure and substructure evolution of network structured TiBw/Ti60 composites. Materials Science and Engineering A. 2015, 627: 316-325. (SCI 二区IF: 4.62)

  6. B. Wang, L.J. Huang, L. Geng. Compressive behaviors and mechanisms of TiB whiskers reinforced high temperature Ti60 alloy matrix composites. Materials Science and Engineering A. 2015, 648: 443-451. (SCI 二区IF: 4.62)

  7. B. Wang, L.J. Huang, L. Geng. Effects of heat treatments on microstructure and tensile properties of as-extruded TiBw/near-α Ti composites. Materials & Design. 2015, 85:679-686. (SCI 二区IF: 6.25)

  8. B. Wang, L.J. Huang, L. Geng, B.X. Liu. Superior tensile strength and microstructure evolution of TiB whisker reinforced Ti60 composites with network architecture after beta extrusion. Materials Characterization. 2015, 103:140-149. IF=2.714 (SCI 三区IF: 3.62)

  9. B. Wang, L.J. Huang, L. Geng. Effects of heat treatments on the microstructure and mechanical properties of as-extruded TiBw/Ti6Al4V composites. Materials Science and Engineering A. 2012, 558: 663-667. (SCI 二区IF: 4.62)

  10. B. Wang, L.J. Huang, L. Geng Effects of heat treatment and sintering temperature on the microstructure of TiBw/Ti60 composites with a novel network microstructure. ECCM16 - 16TH EUROPEAN CONFERENCE ON COMPOSITE MATERIALS, Seville, Spain, 22-26 June 2014

  11. Jianli He, Fei Chen, Bo Wang, Luo Bei Zhu. A modified Johnson-Cook model for 10%Cr steel at elevated temperatures and a wide range of strain rates. Materials Science and Engineering A. 2018, 715: 1-9. (SCI 二区IF: 4.62)

  12. Huang, LJ; Geng, L; Wang, B; Xu, H. Y; Kaveendran. B. Effects of extrusion and heat treatment on the microstructure and tensile properties of in situ TiBw/Ti6Al4V composite with a network architecture. COMPOSITES PART A. 2012, 43:486-491. IF4.075

  13. L.J. Huang, H.Y. Xu, B. Wang, Y.Z. Zhang, L. Geng. Effects of heat treatment parameters on the microstructure and mechanical properties of in situ TiBw/Ti6Al4V composite with a network architecture. Materials & Design, 2012, 36, 694-698. (SCI 二区IF: 6.25)

  14. L.J. Huang, L. Geng, B. Wang, L.Z. Wu. Effects of volume fraction on the microstructure and tensile properties of in situ TiBw/Ti6Al4V composites with novel network microstructure. Materials & Design, 2013, 45, 532-538. (SCI 二区IF: 6.25)

  15. B.X. Liu, L.J. Huang, L. Geng, B. Wang, X.P. Cui, C. Liu, G.S. Wang. Microstructure and tensile behavior of   novel laminated Ti-TiBw/Ti composites by reaction hot pressing. Materials Science and Engineering A. 2013, 583: 182-187. (SCI 二区IF: 4.62)

  16. B.X. Liu, L.J. Huang, L. Geng, B. Kaveendran, B. Wang, X.Q. Song, X.P. Cui. Gradient grain distribution and enhanced properties of novel laminated Ti-TiBw/Ti composites by reaction hot-pressing. Materials Science and Engineering A. 2014, 595: 257-266. (SCI 二区IF: 4.62).

  17. B.X. Liu, L.J. Huang, L. Geng, B. Wang, C. Liu, W.C. Zhang. Fabrication and superior ductility of laminated Ti-TiBw/Ti composites by diffusion welding. Journal of Alloys and compounds. 2014, 602: 187-192. (SCI 二区IF: 4.12)

  18. H.T. Hu, L.J. Huang, L. Geng, B.X. Liu, B. Wang. Oxidation behavior of TiB-whisker-reinforced Ti60 alloy composites with three-dimensional network architecture. Corrosion Science. 2014, 85:7-14. (SCI 一区IF: 6.76)

专利

  1. 王博, 李东, 赵建.一种TiBw/TC4复合材料表面纳米重熔层及其制备方法.(发明专利, 201810189552.X)

  2. 黄陆军, 王博, 耿林, 荣旭东, 崔西平, 刘宝玺.一种耐磨高韧的壳芯结构钛基棒材及其制备方法.(发明专利, ZL 2014 1 0624751.0)

  3. 赵健, 王付鑫, 李东, 王博, 于治水. 基于双电子束的TC4钛合金增材制造构件应力缓释方法. (发明专利, ZL.2016 1 0312445.2)

获奖情况

黑龙江省科学技术一等奖 轻质耐热钛基复合材料组织设计与应用基础