教授
| 姓名:刘 奎 | 性别:男 | 职务: |
职称:教 授 | 博导/硕导:博导 | 办公室:15-357 | |
研究领域:超精密切削加工(Ultra-Precision Machining),微纳加工(Micro/Nano Machining),多能场制造(Hybrid Manufacturing),智能制造(Intelligent Manufacturing) | |||
电话: | Email:liukui@nuaa.edu.cn | ||
个人简介:
刘奎博士,bv1946伟德官网教授,入选国家级重大人才工程,1989年和1996年毕业于bv1946伟德官网分别获学士、硕士学位,2002年毕业于新加坡国立大学获博士学位。在回国之前,任新加坡科技研究局(A*STAR)制造技术研究院首席科学家、新加坡国立大学机械工程系副教授、博士生导师,先后担任新加坡制造技术研究院—新加坡国立大学“大尺寸精密加工联合实验室”主任、新加坡制造技术研究院—南洋理工大学“超精密加工联合实验室”主任、新加坡制造技术研究院加工技术研究室主任等职务,长期从事超精密加工与智能制造技术的基础理论和工业应用研究,曾主持政府资助的研究课题及工业项目67项,合作企业包括Applied Materials、Royce-Rolls、Schlumberger、TechnipFMC等国际知名公司,累计研究经费达4700万新元,多项研究成果已被多家企业实现产业化应用。受邀担任国际磨料技术委员会和亚洲精密工程及纳米技术学会理事,SCI期刊IJEM、NMME、Machines等编委。
工作经历:
2025.09 —至今 bv1946伟德官网教授
2005.01 —至今 新加坡国立大学助理教授、副教授
2023.04 —2025.09 新加坡制造技术研究院首席科学家
2015.04—2023.03 新加坡制造技术研究院高级科学家、室主任
2004.03 —2013.03 新加坡制造技术研究院工程师、高级工程师、副科学家、科学家、学科带头人
2002.02 —2004.02 新加坡国立大学博士后
1989.07 —1998.11 bv1946伟德官网助教、讲师
教育背景:
1993.09—1996.03 硕 士 bv1946伟德官网
1985.09—1989.07 学 士 bv1946伟德官网
学术成果: (详见)
出版英文专著2部,英文论文集1部,受邀参编6部英文科技手册,发表学术论文200余篇,论文被引5500余次,谷歌学术H指数41,拥有授权专利6项,专有技术26项,受邀在国际会议做主题报告和特邀报告40余次,担任国际学术会议大会主席、组委会主席、学术委员和分会主席30余次。主要代表作如下:
[1]L.Q. Chen, C.L. Tan, J.L. Su, N.P.H Ng, Y.X. Chew, K. Liu and S.K. Moon, Multisensor fusion-based digital twin for localized quality prediction in robotic laser-directed energy deposition, Robotics and Computer-Integrated Manufacturing, Vol. 84, pp. 102581, 2023 (IF 11.4)
[2]N.Y.J. Tan, K. Liu and A.S. Kumar, Multiple axis ultra-precision freeform deviation control using encoder data analysis, Journal of Manufacturing Processes, Vol. 90, pp. 242-256, 2023 (IF 6.8)
[3]X.Q. Zhang, R. Huang, Y. Wang, K. Liu, H. Deng and D.W.K. Neo, Suppression of diamond tool wear with sub-millisecond oxidation in ultrasonic vibration cutting of steel, Journal of Materials Processing Technology, Vol. 299, pp. 117320, 2022 (IF 7.5)
[4]P. Xu, X.L. Yao, L.Q. Chen, C.Y. Zhao, K. Liu, S.K. Moon and G.J. Bi, In-process adaptive dimension correction strategy for laser aided additive manufacturing using laser line scanning, Journal of Materials Processing Technology, Vol. 303, pp. 117544, 2022 (IF 7.5)
[5]N.Y.J. Tan, X.Q. Zhang, D.W.K. Neo, R. Huang, K. Liu and A.S. Kumar, A review of recent advances in fabrication of optical Fresnel lenses, Journal of Manufacturing Processes, Vol. 71, pp. 113-133, 2021 (IF 6.8)
[6]D.W.K. Neo, K. Liu and A.S. Kumar, High throughput deep-hole drilling of Inconel 718 using PCBN gun drill, Journal of Manufacturing Processes, Vol. 57, pp. 302-311, 2020 (IF 6.8)
[7]J. Guo, K.H. Au, C.N. Sun, M.H. Goh, C.W. Kum, K. Liu, J. Wei, H. Suzuki and R. Kang, Novel rotating-vibrating magnetic abrasive polishing method for double-layered internal surface finishing, Journal of Materials Processing Technology, Vol. 264, pp. 422-437, 2019 (IF 7.5)
[8]F.Z. Fang, N. Zhang, D.M. Guo, K. Yamamura, B. Cheung, K. Liu and K. Ehmann, Towards atomic and close-to-atomic scale manufacturing, International Journal of Extreme Manufacturing, Vol. 1, pp. 1-33, 2019 (IF 21.3)
[9]S. Kannan and K. Liu, Experimental investigation of surface integrity during abrasive edge profiling of nickel-based alloy, Journal of Manufacturing Processes, Vol. 39, pp. 40-51, 2019 (IF 6.8)
[10]C.W. Kum, T. Sato, J. Guo, K. Liu and D.L. Butler, A novel media properties-based material removal rate model for magnetic field-assisted finishing, International Journal of Mechanical Sciences, Vol. 141, pp. 189-197, 2018 (IF 9.4)
[11]X.Q. Zhang, G.L. Tnay, K. Liu and A.S. Kumar, Effect of apex offset inconsistency on hole straightness deviation in deep hole gun drilling of Inconel 718, International Journal of Machine Tools and Manufacture, Vol. 125, pp. 123-132, 2018 (IF 18.8)
[12]J. Guo, J.M. Bai, K. Liu and J. Wei, Surface quality improvement of selective laser sintered polyamide 12 by precision grinding and magnetic field-assisted finishing, Materials and Design, Vol. 138, pp. 39-45, 2018 (IF 7.9)
[13]J. Guo, K. Liu, Z.F. Wang and G.L. Tnay, Magnetic field-assisted finishing of a mold insert with curved microstructures for injection molding of microfluidic chips, Tribology International, Vol. 114, pp. 306-314, 2017 (IF 6.9)
[14]S.B. Wang. L. Geng, Y.F. Zhang, K. Liu and T.E. Ng, Cutting force prediction for five-axis ball-end milling considering cutter vibrations and run-out, International Journal of Mechanical Sciences, Vol. 96-97, pp. 206-215, 2015 (IF 9.4)
[15]X.Q. Zhang, K. Liu, V. Sunappan and X.C. Shan, Diamond micro engraving of gravure roller mould for roll-to-roll printing of fine line electronics, Journal of Materials Processing Technology, Vol. 225, pp. 337-346, 2015 (IF 7.5)
[16]X.Q. Zhang, K. Liu, A.S. Kumar and M. Rahman, A study of the diamond tool wear suppression mechanism in vibration-assisted machining of steel, Journal of Materials Processing Technology, Vol. 214, No. 2, pp. 496-506, 2014 (IF 7.5)
[17]X.Q. Zhang, K. Liu, X.C. Shan and Y.C. Liu, Roll-to-Roll embossing of optical linear Fresnel lens polymer film for solar concentration, Optics Express, Vol. 22, S7, pp. A1835-A1842, 2014 (IF 3.3)
[18]X.Q. Zhang, M. Arif, K. Liu, A.S. Kumar and M. Rahman, A model to predict the critical undeformed chip thickness in vibration-assisted machining of brittle materials, International Journal of Machine Tools & Manufacture, Vol. 69, pp. 57-66, 2013 (IF 18.8)
[19]K.S. Woon, M. Rahman, K.S. Neo and K. Liu, The effect of tool edge radius on the contact phenomenon of tool-based micromachining, International Journal of Machine Tools & Manufacture, Vol. 48, pp. 1395-1407, 2008 (IF 18.8)
[20]K. Liu, X.P. Li and M. Rahman, Characteristics of ultrasonic vibration assisted ductile cutting of tungsten carbide, International Journal of Advanced Manufacturing Technology, Vol. 35, No. 7-8, pp. 833-841, 2008 (IF 3.1)
[21]K.S. Woon, M. Rahman, F.Z. Fang, K.S. Neo and K. Liu, Investigation of tool edge radius effect in micromachining: a FEM simulation approach, Journal of Materials Processing Technology, Vol. 195, No. 1-3, pp. 204-211, 2008 (IF 7.5)
[22]M. Sharif Uddin, K.H.W. Seah, M. Rahman, X.P. Li and K. Liu, Performance of single crystal diamond tools in ductile mode cutting of silicon, Journal of Materials Processing Technology, Vol. 185, No. 1-3, pp. 24-30, 2007 (IF 7.5)
[23]K. Liu, X.P. Li, S.Y. Liang and X.D. Liu, Nanometer scale ductile mode cutting of soda-lime glass, Journal of Manufacturing Processes, Vol. 7, pp. 95-101, 2005 (IF 6.8)
[24]M. Sharif Uddin, K.H.W. Seah, X.P. Li, M. Rahman and K. Liu, Effects of crystalline orientation on wear of diamond tools for nano-scale ductile cutting of silicon, Wear, Vol. 257, pp. 751-759, 2004 (IF 6.1)
[25]K. Liu, X.P. Li and S.Y. Liang, Nanometer scale ductile cutting of tungsten carbide, Journal of Manufacturing Processes, Vol. 6, No. 2, pp. 187-195, 2004 (IF 6.8)
[26]K. Liu, X.P. Li, M. Rahman and X.D. Liu, CBN tool wear in ductile cutting of tungsten carbide, Wear, Vol. 255, pp. 1344-1351, 2003 (IF 6.1)
[27]K. Liu, X.P. Li and M. Rahman, Characteristics of high-speed micro cutting of tungsten carbide, Journal of Materials Processing Technology, Vol. 140, pp. 352-357, 2003 (IF 7.5)
[28]X.P. Li, M. Rahman, K. Liu, K.S. Neo and C.C. Chan, Nano-precision measurement of diamond tool edge radius for wafer fabrication, Journal of Materials Processing Technology, Vol. 140, pp. 358-362, 2003 (IF 7.5)
[29]K. Liu and X.P. Li, Ductile cutting of tungsten carbide, Journal of Materials Processing Technology, Vol. 113, pp. 348-354, 2001 (IF 7.5)
[30]H.Z. Li, K. Liu, and X.P. Li, A new method for determining the undeformed chip thickness in milling, Journal of Materials Processing Technology, Vol. 113, pp. 378-384, 2001 (IF 7.5)
著书:
[1]A.S. Kumar and K. Liu, e-Proceedings of 9th International Conference of Nanomanufacturing (nanoMan2024), December 1-4, 2024, Singapore, http://rpsonline.com.sg/proceedings/nanoman2024/html/toc.html
[2]K. Liu, H. Wang and X.Q. Zhang, Ductile Mode Cutting of Brittle Materials. 291 pages, ISBN: 978-981-329-835-4, Springer Nature, Singapore, DOI: 10.1007/978-981-32-9836-1, 2020
[3]K. Liu, Tungsten Carbide: Processing and Applications. 148 pages, ISBN: 978-953-51-0902-0, IntechOpen, London, UK, DOI: 10.5772/3148, 2012
[4]W.K. Neo, A. Chaudhari, M.T. Lew, S. Malarvizhi, A.S. Kumar and K. Liu, Gun Drilling of Difficult-to-machine Materials. In: Gupta K. and Pramanik A. (eds) Advanced Machining and Finishing, pp. 77-141, ISBN: 978-0-128-17452-4, Elsevier, 2021
[5]R. Huang, X.Q. Zhang and K. Liu, Micromachining of Roller Mold for Roll-to-Roll Manufacturing. In: Yan J.W. (ed) Micro and Nano Fabrication Technology, pp. 183-213, ISBN: 978-981-13-0097-4, Springer, 2018
[6]H.Y. Zheng, Y.C. Guan, K. Liu, Z.K. Wang and S.M. Yuan, Other Methods of Polymer Surface Modifications. In: Izdebska J. and Thomas S. (eds) Printing on Polymers: Fundamentals and Applications, pp. 161-178, ISBN: 978-0-323-37468-2, Elsevier, Oxford, 2016
[7]X.Q. Zhang, K. Liu and X.D. Liu, Ultraprecision Machining of Stainless Steel and its Applications. In: Pramanik A. and Basak A.K. (eds) Stainless Steel: Microstructure, Mechanical Properties and Methods of Application, pp. 183-206, ISBN: 978-1-63482-080-6, Nova Science Publishers, New York, 2015
[8]H.Y. Zheng and K. Liu, Machinability of Engineering Materials. In: Nee A.Y.C. (ed) Handbook of Manufacturing Engineering and Technology, pp. 899-939, ISBN: 978-1-4471-4669-8, Springer, London, 2015
[9]F.Z. Fang, K. Liu, T.R. Kurfess and G.C. Lim, Tool-based Micro Machining and Applications in MEMS. In: Leondes C.T. (ed) MEMS/NEMS Handbook: Techniques and Applications, Vol. 3, pp. 63-125, ISBN: 978-0-387-24520-1, Springer, Boston, MA, 2006
发明专利:
[1]X.C. Wang, Y.C. Wan, K. Liu and H. Wu, Surface texturing process chamber components, 19/311,957 US, 27 August 2025
[2]X.C. Wang, Y.C. Wan, K. Liu and H. Wu, Surface texturing process chamber components (A*STAR Ref: IP2024-540-01), 44026314US01 TW, 27 August 2025
[3]S.M. Saw, C. Lam, C.H. To, K. Liu, I. Wong and L. Lim, Optical lens for slowing myopia progression, China Patent Application No. 2012800428526, 2012
[4]J.H. Zhao, X. Li, G. Chen, J.E. Low and K. Liu, Method and apparatus forming a porous biodegradable medical implant device, US 13/187,414, 2012
[5]S.M. Saw, C. Lam, C.H. To, K. Liu, I. Wong and L. Lim, A novel soft contact lens designed to retard the progression of myopia, US 61/512,255, 2011
[6]J.H. Zhao, X. Li, G. Chen, J.E. Low and K. Liu, Method and apparatus for making porous medical devices with channels. SG Provi_20100603, 2010
获奖情况:
2021 SCI期刊优秀编辑奖,Nanomanufacturing and Metrology,Springer
2018 最佳科研成就奖(唯一项目),Machining of high-precision roller moulds for roll-to-roll embossing and gravure printing,新加坡制造技术研究院,排名第2
2016 航空成就奖,Process modelling of magneto-rheological finishing,新加坡科技研究局,排名第1
2012 最佳工业成果奖(唯一项目),Robotized precision finishing,新加坡制造技术研究院,排名第11
2010 总统科技奖(研究院唯一提名),Direct machining of steel to mirror surface finish using single point diamond tools,新加坡国家研究基金会,排名第4
2008 最佳工业成果奖(唯一项目),Mechanized edge profiling,新加坡制造技术研究院,排名第1
1998 新加坡国家研究学者奖学金赴新加坡国立大学攻读博士学位
讲授课程:
在新加坡国立大学讲授《Modelling of Machining Processes》,《Manufacturing Technology》
承担项目:
[1] 新加坡RIE2025国家基金(M22K5a0045),Manufacturing of multi-material net-shape parts with heterogeneous properties,1336万新元,2023年-2026年,子项目负责人;
[2] 新加坡RIE2020国家基金(H2107d3023),Expenditure on manpower funding for A*STAR Stronghold Diagnostics Lab (SDL),38.1万新元,2021年-2022年,负责人;
[3] 新加坡RIE2020国家基金(A1893a0031),Integrated large format hybrid manufacturing using wire-fed and powder-blown technology for LAAM process,600万新元,2018年-2021年,子项目负责人;
[4]新加坡-德国学术与企业2+2国际合作基金(A1890b0048),Enhanced ultra-precision machining of discontinuous microstructures on monolithic surface,30.8万新元,2018年-2020年,负责人;
[5] 新加坡国家基金(1426400038),Large format machining and drilling of high aspect holes,273.1万新元,2015年-2018年,负责人;
[6] 新加坡科技研究研究局基金(RE2014-058),SIMTech-NUS Joint Laboratory on Large Format Machining,218.2万新元,2015年-2019年,负责人。
指导研究生情况:
在新加坡制造技术研究院指导博士研究生9名(毕业9名),硕士研究生7名(毕业7名)。
