个人简历

1982年毕业于华中理工大学，并留校任教；1994年获英国帝国理工学院博士学位；先后在英国剑桥大学、帝国理工学院、香港理工大学从事研究工作；2003年至今就职于哈尔滨工业大学深圳研究生院。
教育经历
03/1991-12/1994 英国帝国理工学院，航空系，计算流体动力学，博士
09/1985-12/1987 华中理工大学，计算流体动力学，硕士
03/1978-01/1982 华中理工大学，流体力学，学士
研究与工作经历
2010- 至今 哈尔滨工业大学深圳研究生院，副院长、院教授会委员
09/2005- 至今 哈尔滨工业大学深圳研究生院，教授、博导
02/2003-09/2005 哈尔滨工业大学深圳研究生院，副教授
03/1997-03/1999 香港理工大学，机械系，博士后/研究员
03/1991-10/1994 英国帝国理工学院，航空系，研究助理
03/1989-03/1989 英国剑桥大学，工程系，访问学者
01/1982-05/1989 华中理工大学，力学系，助教/讲师
科研项目
2017.05-2019.05 深圳基础研究自由探索项目，高超声速飞行器等离子体减阻机理及流动控制研究，50万元
2017.01-2020.12 自然科学基金联合基金项目，U1613227，大中型仿生飞鸟机器人建模理论、设计与控制关键技术，40/260万元。
2015.10-2017.10 深圳市科技计划基础研究项目，JCYJ20150625142543449，扑翼式飞行器气动特性及控制方法研究，30万元。
2015.07-2016.06 国防863，2015AA7046202，面向XXXXX的大型仿生飞行机器人关键技术研究，15/30万元。
2015.09-2016.03 横向课题，一种多轴旋翼无人样机的研制，20万元。
2014.11-2016-11 深圳市创新环境建设计划重点实验室提升项目，ZDSYS20140508161547829，仿生扑翼无人机的研制，150万元。
2014.12-2015.12 深圳市南山区软科学研究项目资助分项资金---软科学研究资助项目，KC2014RKRK0025A ，微小型无人机技术发展趋势研究与市场需求分析，10万元。
2013.09-2016.09 深圳市南山区技术研发和创意设计项目分项资金，KC2013JSCX0070A，可悬停微型仿生扑翼飞行器的研制，20万元。
2013.03-2014.12 横向课题， 大型高科技游乐设备结构设计与优化分析，38万元
2011.04-2012.12 深圳市基础研究计划项目，JC201005260149A，垂直轴风力机气动设计及数值模拟研究，10万元。
2011.01-2012.12 哈尔滨工业大学科研创新基金，大型双层H型垂直轴风力机气动性能分析，5万元。
2009.01-2010.12 深圳市产学研和公共科技项目，SY200806260041A，新型仿生扑翼研究，15万元。
2008.12-2009.12 横向课题，扑翼微型飞行器研制，20万元。
2008.01-2011.12 国家自然科学基金委，登陆台风风场及其工程致灾特性研究，20/200万元。
发明专利
一种单自由度可实现二维运动的扑翼机构（专利号:201220113581.6）
“8”字轨迹扑翼机构及微型扑翼飞行器（专利号:201220239562.8）
一种微型扑翼飞行器的扑翼机构及微型扑翼飞行器（专利号：CN201220239322.8）
垂直轴风力机（专利号：CN201230439542.0）
一种扑翼飞行器的三维扑翼机构及微型扑翼飞行器（专利号：CN201420266922.2）
一种新型十字扑翼飞行器（专利号：CN201520216209.1 ）
一种应变式小量程三维力传感器（专利号：CN201520541943.5）
任教和任导师经历
开设课程 全日制研究生课程：数值分析、高等计算流体力学；
非全日制研究生课程：专业英语、高等工程数学；
讲座课程：科普类专业课讲座、英文论文撰写规范讲座。
硕士培养 指导全日制硕士研究生94人，80人已毕业(其中省级优秀毕业生1人、校级优秀毕业生5人、院级优秀毕业生14人)，14人在读；
指导非全日制硕士研究生12人，9人毕业，3人在读。
博士培养 指导博士研究生8人(其中留学生2人)，7人毕业，1人在读。

研究领域

从事计算流体力学相关问题的研究，主要研究方向包括：
1.流动诱发振动、流固相互作用、流动减阻和控制；
2.高超声速飞行器减阻、减振及热防护；
3.仿生扑翼气动力特征研究及微型仿生扑翼飞行器研制；
4.风力机气动设计及优化。""

近期论文

[1] Wang C, Zhou C, et al. Numerical Investigation On Aerodynamic Performance of a 2-D Inclined Hovering Wing in Asymmetric Strokes[J]. Journal of Mechanical Science and Technology, 2016, 30(1): 199-210.
[2] Wang C, Zhou C, et al. Numerical Investigation Into the Effects of Stroke Trajectory On the Aerodynamic Performance of Insect Hovering Flight[J]. Journal of Mechanical Science and Technology, 2016, 30(4): 1659-1669.
[3] Li L, Kareem A, et al. Turbulence Spectra for Boundary-Layer Winds in Tropical Cyclones: A Conceptual Framework and Field Measurements at Coastlines[J]. Boundary-Layer Meteorology, 2015, 154(2): 243-263.
[4] Zhu J, Zhou C. The Aerodynamic Performance of Flexible Wing in Plunge[J]. Journal of Mechanical Science and Technology, 2014, 28(7): 2687-2695.
[5] Zhu J, Zhou C, et al. Effect of Flexibility On Flapping Wing Characteristics Under Forward Flight[J]. Fluid Dynamics Research, 2014, 46(0555155).
[6] Zhu J Y, Zhou C Y. Aerodynamic Performance of a Two-Dimensional Flapping Wing in Asymmetric Stroke[J]. Proceedings of the Institution of Mechanical Engineers Part G-Journal of Aerospace Engineering, 2014, 228(5): 641-651.
[7] Zhou C, Ji W. A Three-Dimensional Numerical Investigation On Drag Reduction of a Supersonic Spherical Body with an Opposing Jet[J]. Proceedings of the Institution of Mechanical Engineers Part G-Journal of Aerospace Engineering, 2014, 228(2): 163-177.
[8] Zhou C, Zhu J. The Aerodynamic Performance of a 2D Lumped Flexible Airfoil in Forward Flight[J]. Proceedings of the Institution of Mechanical Engineers, Part G: Journal of Aerospace Engineering, 2014, 228(8): 1363-1374.
[9] Xie P, Zhou C Y. Numerical Investigation On Effects of Rivulet and Cable Oscillation of a Stayed Cable in Rain-Wind-Induced Vibration[J]. Journal of Mechanical Science and Technology, 2013, 27(3): 685-701.
[10]Zhou C, Zhu J, et al. Effect of the Flexibility of Flapping Wings On their Aerodynamic Characteristics[J]. Information Technology Journal, 2012, 11(12): 1758-1763.
[11]张兴伟，周超英，等. 扑翼柔性变形对悬停气动特性影响的数值研究[J]. 哈尔滨工业大学学报. 2012(1): 115-119.
[12]Xie P, Zhou C Y, et al. Effects of Upper Rivulet During Rain-Wind Induced Vibration[J]. Information Technology Journal, 2012, 11(2): 181-190.
[13]Islam S U, Zhou C Y, et al. Numerical Simulation of Flow Past Rectangular Cylinders with Different Aspect Ratios Using the Incompressible Lattice Boltzmann Method[J]. Journal of Mechanical Science and Technology, 2012, 26(4): 1027-1041.
[14]Zhang X W, Zhou C Y. Computational Study On the Hovering Mechanisms of a Chordwise Flexible Wing[J]. Proceedings of the Institution of Mechanical Engineers, Part G: Journal of Aerospace Engineering, 2012, 226(1): 3-14.
[15]Zhang T, Zhou C, et al. Design, Analysis, Optimization and Fabrication of a Flapping Wing MAV[C]. 2011 International Conference on Mechatronic Science, Electric Engineering and Computer, MEC 2011, August 19, 2011 - August 22, 2011. Jilin, China: IEEE Computer Society, 2011.
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[17]Zhang X W, Zhou C Y. Numerical Investigation On the Aerodynamic Characteristics of a Forward Flight Flapping Airfoil with Nonsymmetrical Plunging Motion[J]. Information Technology Journal, 2011, 10(4): 748-758.
[18]Xie P, Zhou C Y, et al. Forces and Pressure Investigation of Steady and Oscillating Cables with Rivulets via Numerical Method[J]. Energy Procedia, 2011, 13: 7557-7564.
[19]Wang C, Zhou C, et al. An Optimization On Single-Crank-Double-Rocker Flapping Wing Mechanism[C]. 4th International Conference on Genetic and Evolutionary Computing, ICGEC 2010, December 13, 2010 - December 15, 2010. Shenzhen, China: IEEE Computer Society, 2010.
[20]Zhang X, Zhou C. Numerical Study On the Effect of Trajectory Pattern On Hovering Flight[C]. 2010 International Conference on Computer Design and Applications, ICCDA 2010, June 25, 2010 - June 27, 2010. Qinhuangdao, Hebei, China: IEEE Computer Society, 2010.
[21]Zhang X, Zhou C. The Flow Field Characters of a Two-Dimensional Deformable Wing Heaving in a Viscous Flow[C]. 2010 International Conference on Computer Design and Applications, ICCDA 2010, June 25, 2010 - June 27, 2010. Qinhuangdao, Hebei, China: IEEE Computer Society, 2010.
[22]周超英，葛家，等. 平板间方柱绕流的格子Boltzmann方法模拟[J]. 哈尔滨工业大学学报. 2010(11): 1753-1757.
[23]Zhang X, Zhou C. Numerical Calculation On Vortex-Induced Vibration of the Circular Cylinder Using Low Reynolds Model in Hybrid Method[C]. ASME 2009 International Mechanical Engineering Congress and Exposition, IMECE2009, November 13, 2009 - November 19, 2009. Lake Buena Vista, FL, United states: American Society of Mechanical Engineers, 2010.
[24]Kuhtz S, Zhou C, et al. Energy Use in Two Italian and Chinese Tile Manufacturers: A Comparison Using an Enterprise Input-Output Model[J]. Energy, 2009, 35(1): 364-374.
[25]Islam S, Shah A, et al. Homotopy Perturbation Analysis of Slider Bearing with Powell-Eyring Fluid[J]. Zeitschrift Fur Angewandte Mathematik Und Physik, 2009, 60(6): 1178-1193.
[26]Zhang X M, Zhou C Y, et al. Multiparameter Identification of Fluid-Saturated Porous Medium with the Wavelet Multiscale Method[J]. Journal of Porous Media, 2009, 12(3): 255-264.
[27]Islam S, Zhou C Y, et al. More Exact Solutions for Incompressible Couple Stressed MHD Aligned Fluid Flows in a Porous Medium Channel[J]. Journal of Porous Media, 2009, 12(8): 801-809.
[28]Islam S U, Zhou C Y, et al. Numerical Simulations of Cross-Flow Around Four Square Cylinders in an In-Line Rectangular Configuration[J]. World Academy of Science, Engineering and Technology, 2009, 33: 824-833.
[29]张新明，周超英，等. 流体饱和多孔隙介质多参数反演的小波多尺度-正则化高斯牛顿法[J]. 应用基础与工程科学学报. 2009(1).
[30]张新明，周超英，等. 用格子Boltzmann方法数值模拟三维空化现象[J]. 物理学报. 2009(12): 8406-8414.
[31]Chen W, Zhou C Y. Application of Numercal Simulation to Obtain the Optimization Pitch Angle for VAWT[C]. 1st World Non-Grid-Connected Wind Power and Energy Conference, WNWEC 2009, September 24, 2009 - September 26, 2009. Nanjing, China: IEEE Computer Society, 2009.
[32]Ul-Islam S, Zhou C Y. Characteristics of Flow Past a Square Cylinder Using the Lattice Boltzmann Method[J]. Information Technology Journal, 2009, 8(8): 1094-1114.
[33]Islam S U, Zhou C Y. Numerical Simulation of Flow Around a Row of Circular Cylinders Using the Lattice Boltzmann Method[J]. Information Technology Journal, 2009, 8(4): 513-520.
[34]Zhou C Y, Wang C, et al. Numerical Study of Fluid Force Reduction On a Square Cylinder Using a Control Plate[C]. 19th (2009) International OFFSHORE AND POLAR ENGINEERING CONFERENCE, June 21, 2009 - June 26, 2009. Osaka, Japan: International Society of Offshore and Polar Engineers, 2009.
[35]Islam S, Zhou C Y, et al. Exact Solutions for Different Vorticity Functions of Couple Stress Fluids[J]. Journal of Zhejiang University-Science a, 2008, 9(5): 672-680.
[36]Islam S, Mohyuddin M R, et al. Few Exact Solutions of non-Newtonian Fluid in Porous Medium with Hall Effect[J]. Journal of Porous Media, 2008, 11(7): 669-680.
[37]周超英，林玉峰. 前后双翼差相位扑动对升力的影响[J]. 哈尔滨工业大学学报. 2007(4): 642-646.
[38]Islam S, Zhou C Y. Exact Solutions for Two Dimensional Flows of Couple Stress Fluids[J]. Zeitschrift Fur Angewandte Mathematik Und Physik, 2007, 58(6): 1035-1048.
[39]Zhou C Y, Wang L, et al. Numerical Study of Fluid Force Reduction On a Circular Cylinder Using Tripping Rods[J]. Journal of Mechanical Science and Technology, 2007, 21(9SI): 1425-1434.
[40]Islam S, Zhou C Y. Certain Inverse Solutions of a Second-Grade Magnetohydrodynamic Aligned Fluid Flow in a Porous Medium[J]. Journal of Porous Media, 2007, 10(4): 401-408.
[41]周超英，林玉峰. 扑翼气动力特性的数值研究[J]. 哈尔滨工业大学学报. 2006(9): 1403-1405.
[42]Islam S, Zhou C Y. Exact Solutions of a Second Grade Fluid in a Porous Medium[J]. Proc. NSC, Beijing, 2006: 247-258.
[43]Zhou C Y, So R M C, et al. Fluid Damping of an Elastic Cylinder in a Cross-Flow[J]. Journal of Fluids and Structures, 2000, 14(3): 303-322.
[44]Zhou C Y, Graham J M R. A Numerical Study of Cylinders in Waves and Currents[J]. Journal of Fluids and Structures, 2000, 14(3): 403-428.
[45]Downie M J, Graham J M R, et al. Viscous Damping of a Submerged Pontoon Undergoing Forced Combined Motions in the Presence of a Weak Current[J]. International Journal of Offshore and Polar Engineering, 1995, 5(4): 241-250.
[46]Graham J M R, Zhao Y D, et al. Effects of Combination Motions On Hydrodynamic Forces Induced On Bodies in the Sea[C]. Proceedings of the International Conference on Hydroelasticity in Marine Technology. Trondheim, Norway: A.A. Balkema, 1994.