 | 姓 名: | 韦超 |
| 所在单位: | 中国科学院宁波材料技术与工程研究所 | |
| 职 称: | 正高级工程师 | |
| 邮寄地址: | 浙江省宁波市镇海区中官西路1219号 | |
| 办公电话: |
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| 电子邮件: | weichao@nimte.ac.cn | |
| 办公地点: | 中国科学院大学宁波材料工程学院遍观楼602室 | |
| 教育背景 | ||
| 2002.9-2006.6,南京航空航天大学,飞行器制造工程,本科 2014.9-2015.11,英国曼彻斯特大学,先进制造技术及系统管理,硕士 2016.4-2019.4,英国曼彻斯特大学,机械工程,博士 | ||
| 工作履历 | ||
| 2006.8-2016.4,中国航天科技集团公司,上海航天精密研究所,副主任设计师,高级工程师 2019.4-2022.4,英国曼彻斯特大学,激光加工研究中心,博士后 2022.5-至今,中国科学院宁波材料技术与工程研究所,激光极端制造研究中心,正高级工程师 | ||
| 教 学 | ||
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| 学术兼职 | ||
| 中国机械工程学会极端制造分会委员 英国机械工程师学会特许工程师 英国机械工程师学会会员 英国激光用户协会青年委员会委员 | ||
| 研究领域 | ||
| 多材料增材制造 | ||
| 研究概况 | ||
| 韦超博士,现任激光极端制造研究团队副组长。本科毕业于南京航空航天大学,硕士、博士毕业于英国曼彻斯特大学。曾长期在上海航天八院从事航天产品研制工作。于2014年赴英,跟随李琳教授(英国皇家工程院院士)开展前沿激光加工研究。2022年回国至今,已获中科院引才计划、浙江省创新青年人才、宁波市甬江人才等人才项目支持。已获得各类科研项目合同经费>2900万。因承担国家重大任务,已被纳入中科院特聘研究岗位(第二批)。 韦超博士专注于面向航空航天应用的多材料增材制造研究和激光复合加工研究。前沿研究领域成果包括:(1)针对航天产品“材料结构性能”一体化趋势,牵头研发了多材料铺粉增材制造工艺及装备,在国际上较早实现了三维功能梯度结构制造,技术方案被德国SLM Solutions公司、德国Fraunhofer研究所采用,已研制出工程样机;(2)与英国宇航公司(BAE Systems)合作,研发了针对碳纤维复合材料(CFRP)的激光复合加工工艺及装备。实现了高效率、低热损伤CFRP蒙皮切割;(3)与英国先进制造研究中心(AMRC,UK)合作,研发了针对航空陶瓷增强铝基复材(MMC)的激光辅助车削工艺及装备,实现了低切削力、高切削速度MMC加工。 截止目前,韦超博士已发表SCI论文24篇(含中科院一区论文15篇),10篇发表于学术期刊Additive Manufacturing;撰写著作章节3篇(一作)和行业标准1项(一作);申请国际专利2项、授权中国专利29项(含第一发明人17项)。任中国机械工程学会极端制造分会委员、英国机械工程师学会特许工程师/会员、英国激光用户协会青年委员会委员。 | ||
| 学术成果 | ||
| 出版著作: | ||
| [1] C. Wei, L. Li, Ultrasonic/Acoustic methods for process monitoring, in: Handb. Laser Micro- Nano-Engineering, Springer Nature, 2020: p. 34. [2] C. Wei, L. Li, Thermometry in laser micro/nanofabrication, in: Handb. Laser Micro- Nano-Engineering, Springer Nature, 2020: p. 41. | ||
| 发表文章: | ||
| 2022 [1] C. Wei, L. Liu, H. Cao, X. Zhong, X. Xu, Y. Gu, D. Cheng, Y. Huang, Z. Li, W. Guo, Z. Liu, L. Li, Cu10Sn to Ti6Al4V bonding mechanisms in laser-based powder bed fusion multiple material additive manufacturing with different build strategies, Addit Manuf. 51 (2022) 102588. [2] C. Wei, L. Liu, Y. Gu, Y. Huang, Q. Chen, Z. Li, L. Li, Multi-material additive-manufacturing of tungsten - copper alloy bimetallic structure with a stainless-steel interlayer and associated bonding mechanisms, Addit Manuf. 50 (2022) 102574. [3] C. Wei, H. Gu, Y. Gu, L. Liu, Y. Huang, D. Cheng, Z. Li, L. Li, Abnormal interfacial bonding mechanisms of multi-material additive-manufactured tungsten–stainless steel sandwich structure, International Journal of Extreme Manufacturing. 4 (2022) 025002. [4] M. Zhu, C. Wei, W. Guo, Z. Zhang, J. Ouyang, P. Mativenga, L. Li, Significant Reduction in Energy Consumption and Carbon Emission While Improving Productivity in Laser Drilling of CFRP Sheets with a Novel Stepped Process Parameter Parallel Ring Method, Journal of Manufacturing and Materials Processing. 6 (2022). 2021 [5] C. Wei, L. Li, Recent progress and scientific challenges in multi-material additive manufacturing via laser-based powder bed fusion, Virtual Phys. Prototyp. (2021) 1–25. [6] C. Wei, W. Guo, B. Gao, Y. Wang, Z. Sun, L. Li, Understanding the behaviour of workpieces’ bulk temperature during laser-assisted turning of Ti6Al4V alloy and heating of Al-SiC metal-matrix composite rods, Opt. Laser Technol. 139 (2021) 106951. [7] C. Wei, Z. Zhang, D. Cheng, Z. Sun, M. Zhu, L. Li, An overview of laser-based multiple metallic material additive manufacturing: From macro: From micro-scales, Int. J. Extrem. Manuf. 3 (2021). [8] D. Cheng, C. Wei, Y. Huang, Z. Zhang, D. Wang, Z. Liu, M. Newman, T. Ma, Y.-H. Chueh, X. Zhang, Z. Liu, L. Li, Additive manufacturing of lithium aluminosilicate glass-ceramic/metal 3D electronic components via multiple material laser powder bed fusion, Addit Manuf. (2021) 102481. [9] H. Gu, C. Wei, L. Li, M. Ryan, R. Setchi, Q. Han, L. Qian, Numerical and experimental study of molten pool behaviour and defect formation in multi-material and functionally graded materials laser powder bed fusion, Adv. Powder Technol. (2021). 2020 [10] C. Wei, H. Gu, Q. Li, Z. Sun, Y. Chueh, Z. Liu, L. Li, Understanding of process and material behaviours in additive manufacturing of Invar36/Cu10Sn multiple material components via laser-based powder bed fusion, Addit. Manuf. (2020) 101683. [11] C. Wei, H. Gu, X. Zhang, Y. Chueh, L. Li, Hybrid ultrasonic and mini-motor vibration-induced irregularly shaped powder delivery for multiple materials additive manufacturing, Addit. Manuf. 33 (2020) 101138. [12] C. Wei, W. Guo, E.S. Pratomo, Q. Li, D. Wang, D. Whitehead, L. Li, High speed, high power density laser-assisted machining of Al-SiC metal matrix composite with significant increase in productivity and surface quality, J. Mater. Process. Technol. 285 (2020) 116784. [13] X. Zhang, Y. Chueh, C. Wei, Z. Sun, J. Yan, L. Li, Additive manufacturing of three-dimensional metal-glass functionally gradient material components by laser powder bed fusion with in situ powder mixing, Addit. Manuf. 33 (2020) 101113. [14] Y.-H. Chueh, X. Zhang, C. Wei, Z. Sun, L. Li, Additive Manufacturing of Polymer-Metal/Ceramic Functionally Graded Composite Components via Multiple Material Laser Powder Bed Fusion, J. Manuf. Sci. Eng. 142 (2020). [15] H. Gu, C. Wei, L. Li, Q. Han, R. Setchi, M. Ryan, Q. Li, Multi-physics modelling of molten pool development and track formation in multi-track, multi-layer and multi-material selective laser melting, Int. J. Heat Mass Transf. 151 (2020) 119458. [16] Y.-H. Chueh, C. Wei, X. Zhang, L. Li, Integrated laser-based powder bed fusion and fused filament fabrication for three-dimensional printing of hybrid metal/polymer objects, Addit. Manuf. 31 (2020) 100928. [17] Y. Chueh, X. Zhang, J.C.-R. Ke, Q. Li, C. Wei, L. Li, Additive manufacturing of hybrid metal/polymer objects via multiple-material laser powder bed fusion, Addit. Manuf. 101465 (2020). 2019 [18] C. Wei, Z. Sun, Q. Chen, Z. Liu, L. Li, Additive Manufacturing of Horizontal and 3D Functionally Graded 316L/Cu10Sn Components via Multiple Material Selective Laser Melting, J. Manuf. Sci. Eng. 141 (2019). [19] C. Wei, Y.-H. Chueh, X. Zhang, Y. Huang, Q. Chen, L. Li, Easy-To-Remove Composite Support Material and Procedure in Additive Manufacturing of Metallic Components Using Multiple Material Laser-Based Powder Bed Fusion, J. Manuf. Sci. Eng. 141 (2019). [20] C. Wei, H. Gu, Z. Sun, D. Cheng, Y.-H. Chueh, X. Zhang, Y. Huang, L. Li, Ultrasonic material dispensing-based selective laser melting for 3D printing of metallic components and the effect of powder compression, Addit. Manuf. 29 (2019) 100818. 2018 [21] C. Wei, Z. Sun, Y. Huang, L. Li, Embedding anti-counterfeiting features in metallic components via multiple material additive manufacturing, Addit. Manuf. 24 (2018) 1–12. [22] C. Wei, L. Li, X. Zhang, Y.-H. Chueh, 3D printing of multiple metallic materials via modified selective laser melting, CIRP Ann. 67 (2018) 245–248. [23] X. Zhang, C. Wei, Y.-H. Chueh, L. Li, An Integrated Dual Ultrasonic Selective Powder Dispensing Platform for Three-Dimensional Printing of Multiple Material Metal/Glass Objects in Selective Laser Melting, J. Manuf. Sci. Eng. 141 (2018). | ||
| 申请专利: | ||
| [1] Lin Li, Chao Wei, Xiaoji Zhang, “Additive manufacturing apparatus and method”, WO2018197876A1, 2018. [2] Lin Li, Chao Wei, Xiaoji Zhang, “Powder Deposition”, WO2020002951A1, 2021. | ||
韦超
