Lin Wang

Personal Information

Personal Information

  • Date of Employment:

    2021-12-28
  • School/Department:

    材料与物理学院
  • Education Level:

    With Certificate of Graduation for Doctorate Study
  • Business Address:

    中国矿业大学南湖校区,材料与物理学院A506
  • Gender:

    Male
  • Degree:

    Doctoral Degree in Engineering
  • Professional Title:

    Associate professor
  • Status:

    在岗
  • Alma Mater:

    山东大学
  • Supervisor of Master's Candidates
  • Teacher College:

    材料与物理学院

Other Contact Information

    PostalAddress:

    Telephone:

    Email:

Profile

王林,男,199012月生,山东肥城人,中共党员,山东大学工学博士,现为中国矿业大学材料与物理学院副教授,硕导。

主要研究领域为增材制造激光熔覆高效电弧焊接方面的实验及数值模拟仿真,如电弧熔丝增材制造(WAAM)、高熵合金激光熔覆、高速电弧焊接及异种材料焊接与连接等方面的工艺优化及改型过程视觉检测及机器学习多尺度多物理场耦合数值模拟分析等。

作为项目负责人主持国家自然科学基金项目,中国博士后科学基金面上项目,国家重点实验室开放课题及企业委托项目多项。作为主要人员参与国家自然科学基金、省级自然科学基金重大基础研究资助项目等多项。目前已发表SCI/EI学术论文20余篇。

 

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]      西北工业大学凝固技术国家重点实验室开放课题,主持。

[2]      国家自然科学基金青年项目(项目批准号:52005296),主持。

[3]      中国博士后科学基金面上项目(项目批准号:2019M662351),主持。

[4]      横向课题(委托单位:中国航空制造技术研究院),2020.4-2021.06, 15万,主持,结题。

[5]      横向课题(委托单位:核工业理化工程研究院),2019.09-2020.05, 25万,主持,结题。

[6]      国家自然科学基金面上项目(项目批准号:51775313),主要参与人。

 

代表性论文:

[1]     Yue K, Wang L*, Xu Z, Cheng C, et al. Effect of WC content on the microstructure and wear resistance of laser cladding AlCoCrFeNiTi0.5 high-entropy alloy coatings, Ceramics International, 2024.

[2]     Wang L, Ma Y, Xu J*. Numerical simulation of arc-droplet-weld pool behaviors during the external magnetic field-assisted MIG welding-brazing of aluminum to steel. International Journal of Thermal Sciences, 2023, 194: 108530.

[3]     耿汝伟, 王林, 魏正英, 麻宁绪. 铝合金熔滴复合电弧增材组织演化及外延生长特性研究[J]. 金属学报, 10.11900/0412.1961.2023.00331.

[4]     Wang L*, Ma Y, Xu J, et al. Improving spreadability of molten metal in MIG welding-brazing of aluminum to steel by external magnetic field. Journal of Manufacturing Processes, 2022, 81: 35-47.

[5]     Xu J, Ma Y, Wang L*. et al. Numerical simulation of arc and metal transfer behaviors in double-wire gas metal arc welding. Welding in the World 66, 2022, 66: 2521–2531.

[6]     Xu J, Ma Y, Wang L*, et al. Numerical investigation on the influence of current waveform on droplet transfer in pulsed gas metal arc welding. Vacuum, 2022, 203: 111230.

[7]     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.

[8]     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.

[9]     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.

[10]  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.

[11]  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.

[12]  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.

[13]  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.

[14]  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.

[15]  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.

[16]  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.

[17]  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.

[18]  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.

[19]  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.

[20]  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.

[21]  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.

[22]  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.

 


Educational Experience

  • 2009.9 to 2013.6

    山东大学 | 材料成型及控制工程 | Bachelor's Degree in Engineering | 本科毕业

  • 2013.9 to 2018.6

    山东大学 | 材料科学与工程 | Doctoral Degree in Engineering | With Certificate of Graduation for Doctorate Study

Work Experience

  • 2021.12 to Now

    中国矿业大学 | 材料与物理学院 | 副教授

  • 2018.10 to 2021.12

    山东大学 | 材料科学与工程学院 | 博士后

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