王林，男，1990年12月生，山东肥城人，中共党员，工学博士，副教授。主要研究领域为焊接过程检测/控制及数值模拟，如高速电弧焊接、等离子弧焊接、异种材料焊接与连接，电弧增材制造/3D打印等方面的工艺优化及改型、视觉检测、数值分析等。
教育/工作经历：
2021.12-至今，中国矿业大学，材料与物理学院，副教授
2018.10-2021.12，山东大学，材料科学与工程学院，博士后
2013.09-2018.07，山东大学，材料科学与工程专业，博士
2009.09-2013.07，山东大学，材料成型及控制工程专业，本科
主持及参与的科研项目：
1)  国家自然科学基金青年项目，铝合金/镀锌钢磁控脉冲MIG熔钎焊热源及熔池行为调控机理的研究，主持。
2)  中国博士后科学基金面上项目，外加磁场辅助铝合金/镀锌钢脉冲MIG熔钎焊工艺研究，主持。
3)  国家自然科学基金面上项目，高速GMAW熔池流态的复合磁场调控及焊缝成形缺陷抑制机理的研究，参与。
4)  国家自然科学基金面上项目，高速GMAW熔池流态调控与驼峰焊道抑制机理的研究，参与。
5)  国家自然科学基金面上项目，超声复合等离子弧的热-力特性及其对熔池穿孔行为的影响机制，参与。
6)   山东省自然科学基金重大基础研究资助项目，基于熔池三维形态测控的GMAW高速焊接成形新工艺关键问题研究，参与。
代表性论文：
[1] Wang L, Chen J, Wu C S. Auxiliary energy-assisted arc welding processes and their modelling, sensing and control. Science and Technology of Welding and Joining, 2021, 26(5): 389-411. (SCI)
[2] Wang L, Chen J, Zhang S, Wu C S. Numerical simulation of coupled arc-droplet-weld pool behaviors during compound magnetic field assisted gas metal arc welding. AIP Advances, 2021, 11(6):65221. (SCI)
[3] Wang L, Chen J, Wu C S, et al. Numerical analysis of arc and droplet behaviors in gas metal arc welding with external compound magnetic field. Journal of Materials Processing Technology, 2020, 282:116638. (SCI)
[4] Wang L, Wu C, Chen J, et al. Experimental measurement of fluid flow in high-speed GMAW assisted by transverse magnetic field. Journal of Manufacturing Processes, 2020, 56: 1193-1200. (SCI)
[5] Wang L, Chen J, Wu C S. Numerical investigation on the effect of process parameters on arc and metal transfer in magnetically controlled gas metal arc welding. Vacuum, 2020, 177:109391. (SCI)
[6]  Wang L, Zhang, C. Wu C S. Experimental study on controlled pulse keyholing plasma arc welding assisted by ultrasonic vibration. The International Journal of Advanced Manufacturing Technology, 2020, 107: 4995–5009. (SCI)
[7] Wang L, Chen J, Jiang C L, et al. Numerical simulations of arc plasma under external magnetic field-assisted gas metal arc welding. AIP Advances, 2020, 10(6): 065030. (SCI)
[8] Wang L, Chen J, Fan X H, Wu C S. Influence of fluid flow on humping bead during high-speed GMAW. Welding Journal, 2019, 98 (11)315s-327s. (SCI)
[9] Wang L, Wu C S, Chen J, Gao J Q. Influence of the external magnetic field on fluid flow, temperature profile and humping bead in high speed gas metal arc welding. International Journal of Heat and Mass Transfer, 2018, 116: 1282-1291. (SCI)
[10] Wang L, Chen J, Wu C S, Gao J Q. Backward flowing molten metal in weld pool and its influence on humping bead in high-speed GMAW.Journal of Materials Processing Technology, 2016, 237: 342-350. (SCI)
[11] Wang L, Wu C S, Gao J Q. Suppression of humping bead in high speed GMAW with external magnetic field. Science and Technology of Welding and Joining, 2016, 21(2): 131-139. (SCI)
[12] 王林, 武传松, 杨丰兆, 高进强. 外加磁场对高速 GMAW 电弧和熔池行为的主动调控效应. 机械工程学报, 2016, 52(2): 1-6. (EI)
[13] 王林, 高进强, 李琰. 抑制高速 GMAW 驼峰焊道的外加磁场数值分析. 焊接学报, 2016 (11): 109-112. (EI)
[14] Wu C S, Wang L, Ren W J, et al. Plasma arc welding: process, sensing, control and modeling. Journal of Manufacturing Processes, 2014, 16(1): 74-85. (SCI)
[15] Tian S, Wang L, Wu CS, et al. Influence of ultrasonic vibration on keyholing penetrating capability in plasma arc welding with controlled pulse waveform. Welding in the world, 2021. (SCI)
[16] Chen J, Han Z, Wang L, Wu C S. Influence of arc interactions on heat and mass transfer during a two-arc hybrid welding. International Journal of Heat and Mass Transfer, 2019, 148:119058. (SCI)