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王丙旭
部门: 日期:2019-05-07 18:36:06 浏览量:

基本资料


王丙旭,特聘副教授,博士研究生,硕导,2018年12月毕业于奥克兰大学,2019年入职浙江理工大学;浙江省新材料产业智库专家,美国润滑工程师协会(STLE)会员,美国汽车工程师协会(SAE)会员;主持科研项目20余项,教改项目3项;以第一/通讯作者发表SCI期刊论文40余篇;授权发明专利10余件;担任《Chinese Journal of Mechanical Engineering》、《热加工工艺》和《电焊机》期刊青年编委,JMR&T, Wear, Materials, Advanced Materials Research, Tribology Transactions, International of Metalcasting等期刊审稿人。


主要研究方向


● 金属材料组织调控及强韧化

● 耐磨/耐蚀钢铁材料

● 金属热处理

● 材料成型数值模拟

● 纳米润滑油/脂


获奖情况


1. 2023年度浙江省青年科技工作者优秀论文

2. 2022年浙江机械工业科学技术奖-二等奖, 2/9, 2022

3. “纺织之光”2021年度中国纺织工业联合会纺织高等教育教学成果奖, 3/8, 2021

4. 美国汽车工业协会-合作研究奖(Research Partner Award), 1/5, 2018


科研项目


1.国家自然科学基金青年项目,纳米颗粒对含碳化物等温淬火球墨铸铁组织性能协同调控机理研究,2025/1-2027/12,主持,在研

2.国家教育部合作科研项目,含碳化物等温淬火球墨铸铁(CADI)的纳米颗粒强韧化技术基础研究,2023/5-2025/4,主持,在研

3.浙江省自然科学基金探索项目,纳米颗粒对球墨铸铁液固相变和服役性能的协同调控规律及作用机理,2021/1-2023/12,主持,已结题

4.浙江理工大学嵊州创新研究院成果培育博士入企项目,纳米贝氏体轴承钢组织性能调控技术研究,2024/7-2025/7,主持,在研

5.浙江理工大学嵊州创新研究院成果培育博士入企项目,安全气囊用高强韧无缝钢管生产工艺研发,2023/5-2024/4,主持,已结题

6.浙江省教育厅科研项目,双相纳米颗粒增强蠕墨铸铁的组织构型设计和强韧化机制,2020/10-2022/10,主持,已结题

7.省重点建设高校优势特色学科-重大/重点成果培育计划项目,颗粒增强铸铁的组织构型演化及强韧化机制,2020/6-2021/12,主持,已结题

8.省重点建设高校优势特色学科-高水平科研平台条件建设计划项目,多功能摩擦学实验平台建设,2019/6-2020/12,主持,已结题

9.浙江省自然科学基金国际合作项目,基于多层摩擦堆焊的铝/钢板材对接焊接技术研究,2021/1-2023/12,参与(2/8),已结题

10.企业横向项目,Cr-Mo-V热作模具钢组织性能一体化调控技术开发,主持,在研

11.企业横向项目,摘果机刀具表面氮化物耐磨涂层开发,主持,在研

12.企业横向项目,锤锻模具用高性能合金钢强韧化技术开发,主持,在研

13.企业横向项目,新型镁铝合金材料开发,主持,在研

14.企业横向项目,手持式液压工具用高性能铝合金缸体关键技术研发,主持,在研

15.企业横向项目,热交换器用高性能无缝钢管关键技术研发,主持,在研

16.企业横向项目,星用功能薄膜环境处理后电学性能分析与评估,主持,在研

17.企业横向项目,基于Simufact Welding的电加热管折弯成型过程仿真模拟分析,主持,在研

18.企业横向项目,接触面动静摩擦系数智能测量装置设计,主持,在研

19.企业横向项目,机笼散热器热仿真分析及结构优化,主持,在研

20.企业横向项目,纳米润滑油减摩抗磨分子动力学模拟与试验研究,主持,已结题

21.专利成果转化,一种基于齿轮单向回转运动的开合机构,主持

22.专利成果转化,利用铝基中间合金制备纳米颗粒增强球墨铸铁的方法,主持

23.专利成果转化,一种兼备高强韧性高耐磨性的新型等温淬火蠕墨铸铁制备方法,主持


发表论文


1. D. Zhang, H. Li, J. Jiang, Bingxu Wang*. Effect of Biomimetic Unit Structure on Microstructure and Properties of In-Situ TiC-TiB2Enhanced Nodular Cast Iron. Surfaces and Interfaces. 2025, 72: 107151.

2. Q. Chen, Bingxu Wang*, Y. Xu, et al. Microstructure and Mechanical Properties of Austenitic Stainless Steels Manipulated by Trace TiC-TiB2Nanoparticles. Journal of Materials Research and Technology. 2024, 33: 7977-7989.

3. Y. Xu, Q. Chen, Bingxu Wang*, et al. Dissimilar Joining of Aluminum Alloy and Low-Alloy Carbon Steel by Resistance Spot Welding. Journal of Materials Research and Technology. 2024, 33: 919-928.

4. Bingxu Wang, Y. Xu, L. Chen, et al. A Novel Design to Enhance the Tribological Properties of HHD Steel via Trace TiC Ceramic Nanoparticles. Steel Research International. 2024, 95(9): 2400305.

5. Bingxu Wang, Y. Xu, L. Chen, et al. Insights into the Microstructure Evolution and Wear Resistance of Nano-TiC Particles Reinforced High-Cr Hot Work Die Steel. Journal of Materials Research and Technology. 2024, 30: 8371-8381.

6. Y. Zhang, Bingxu Wang*, F. Qiu, et al. Dry Sliding Wear Properties of Annealed Carbon Steels Matrix Composites by Nano-Sized TiC-TiB2Particles. Advanced Engineering Materials. 2023, 25(20): 202300588.

7. Y. Zhang, Bingxu Wang*, B. Dong, et al. Microstructure and Wear Resistance of Gray Cast Iron Synergistically Manipulated by Nano-Sized TiC-TiB2Ceramic Particles. Tribology Letters. 2023, 71(3): 84.

8. Y. Zhang, Bingxu Wang*, F. Qiu, et al. Superior Wear Resistance of Dual-Phased TiC-TiB2Ceramic Nanoparticles Reinforced Carbon Steels. Journal of Materials Research and Technology. 2023, 24: 653-662.

9. W. Cui, Bingxu Wang*, F. Qiu*, et al. Microstructural Configuration and Impact Toughness of Graphite Ductile Iron Reinforced by Trace Amount of TiC-TiB2Nanoparticles. Journal of Materials Engineering and Performance. 2022, 31; 4575-4582.

10. Bingxu Wang, Y. Zhang, F. Qiu*, et al. Synergistic Optimization in Microstructure and Mechanical Properties of Low Carbon Steel via Trace Amount of Nano-Sized TiC-TiB2. Materials Characterization. 2022, 190; 112060.

11. Bingxu Wang, F. Qiu*, L. Chen, et al. Microstructure and Shearing Strength of Stainless Steel/Low Carbon Steel Joints Produced by Resistance Spot Welding. Journal of Materials Research and Technology. 2022, 20; 2668-2679.

12. Bingxu Wang, F. Qiu*, Gary C. Barber, et al. Role of Nano-sized Materials as Lubricant Additives in Friction and Wear Reduction: A Review. Wear. 2022. 490-491(11); 204206.

13. L. Chen, Y. Zhang, X. Xue, Bingxu Wang*, et al. Investigation on Shearing Strength of Resistance Spot-Welded Joints of Dissimilar Steel Plates with Varying Welding Current and Time. Journal of Materials Research and Technology. 2022, 16; 1021-1028.

14. Bingxu Wang, Y. Zhang, F. Qiu*, et al. Microstructure Refinement and Strengthening-Toughening Mechanisms of Gray Cast Irons Reinforced by In-Situ Nano-Sized TiB2-TiC/Al Master Alloy. Advanced Engineering Materials. 2021; 202100731.

15. Bingxu Wang*, F. Qiu, W. Cui, et al. Microstructure and Tensile Properties of Graphite Ductile Iron Improved by Minor Amount of Dual-Phased TiC-TiB2Nanoparticles. Advanced Engineering Materials. 2021; 2100246.

16. Bingxu Wang*, Y. Zhang, F. Qiu, et al. Simultaneously Enhanced Hardness and Toughness of Normalized Graphite Ductile Irons by TiC-TiB2 Nanoparticles. Materials Letters. 2021, 291: 129597.

17. W. Cui, Bingxu Wang*, G. C. Barber, et al. Experimental Evaluations on Tribological Performance of Oil-Based WS2Nanofluid Applied on Steel/Brass Friction Pairs. Applied Physics A. 2021, 127: 222.

18. Bingxu Wang*, Y. Pan, Y. Liu, et al. Effects of Quench-Tempering and Laser Hardening Treatment on Wear Resistance of Gray Cast Iron. Journal of Materials Research and Technology. 2020, 9(4): 8163-8171.

19. Y. Pan, Bingxu Wang*, G. C. Barber. Investigation on Tensile Properties of Austempered SAE52100 Steel. Metallurgical and Materials Transactions A. 2020, 51; 1593-1601.

20. Bingxu Wang*, G. C. Barber, C. Tao, et al. Tribological Performance of Austempered and Tempered Ductile Iron. Metallurgical and Materials Transactions B. 2018, 49; 2261-2269.

21. Bingxu Wang*, M. He, G. C. Barber, et al. Rolling Contact Fatigue Resistance of Austempered Ductile Iron Processed at Various Austempering Holding Times. Wear. 2017, 398-399; 41-46.


专利情况


1. 一种兼备高强韧性高耐磨性的新型等温淬火蠕墨铸铁制备方法专利号:202310885551.X

2. 一种基于齿轮单向回转运动的开合机构的开合方法专利号:202110756578.X

3. 利用铝基中间合金制备纳米颗粒增强球墨铸铁的方法专利号:202110346068.5

4. 一种高接触疲劳抗性奥贝球铁的制备方法、应用专利号:202110744831.X

5. 一种智能化辅助阅读装置专利号:201922249551.2

6. 一种便于阅读的书籍加持机构专利号:201922248206.7

7. 一种座椅式助洗装置专利号:202021816149.4

8. 一种可同时夹持矩形和圆形试件的摩擦磨损试验夹具专利号:202121006518.8

9. 一种基于齿轮单向回转运动的开合机构专利号:202121512032.1

10. 一种连杆式拉伸试验机夹具专利号:202121526008.3


联系方式


● 通讯地址:浙江理工大学(下沙校区)15号楼509室

● Email: bingxuwang@zstu.edu.cn

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