哈尔滨工业大学航天学院力学研究所导师王长国介绍如下：

My Curriculum Vitae

Prof. Dr. Changguo Wang

Ph.D Supervisor in Engineering Mechanics

Deputy Director of Center for Composite Materials

National Key Laboratory of Science and Technology on Advanced Composites in Special Environments

School of Astronautics

Harbin Institute of Technology

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王长国，1979年11月，辽宁大连人。

教授，博士生导师。

复合材料与结构研究所 副所长

哈工大 航天学院

作为项目负责人主持承担国家自然科学基金、高分国家重大科技专项、科工局民用航天预研、国防863等项目。 获得国防技术发明二等奖1项、军队科技进步二等奖3项、教育部技术发明二等奖1项，省高校科技奖一等奖1项，全国百篇优秀博士学位论文提名奖，入选教育部新世纪优秀人才支持计划，国家万人计划青年拔尖人才。

联系方式

电话 0451-86402368

邮箱 wangcg@hit.edu.cn

地址  哈市南岗区一匡街2号哈工大科学园A栋416室,150080

Overview

Changguo Wang is a tenured professor in Center for Composite Materials, National Key Laboratory of Science and Technology on Advanced Composites in Special Environments, School of Astronautics at Harbin Institute of Technology (HIT), China.

Professor Wang was born in Dalian, Liaoning Province, China, in 1979. He received the B.S. degree in Engineering Management from Shenyang Jianzhu University, China in 2002; the M.E. and Ph.D degrees in Engineering Mechanics from Harbin Institute of Technology, China in 2004 and 2007, respectively. Wang was a visiting scholar in Institute of Lightweight Structures, Technische Universit？t München in Munich in 2009.

His current research interests include Mechanics of Flexible Structures, Flexible Composite Materials and Structures, Structural Lightweight and Optimization, Structural Buckling/Wrinkling and Vibration, Delamination of Composite Structures, Membrane Crease, Nanoscale Wrinkling Mechanics.

Professor Wang currently serves as a member of council in Society of Composite of Heilongjiang Province.

He is the senior member of CSTAM and CSFCM, a member of AIAA, IASS, and ShellBuckling.

He is the Editoral board of JACM, Front.Mech.Mater., Material Science: Adv. Compo. Struct. etc..

He has served as an organizing committee member, technical program committee member, or scientific committee member for several international conferences, such as MECHCOMP3, M2D2017, MDCE 2016, MEME2016, MSCE2016, and CAC2014, etc..

He was the keynote/session speakers for several international conferences, such as MME2016, MSCE2016, IAC2014, and TCIS2013, etc..

He is the author of over 80 papers in top academic journals such as JMPS, IJSS, Carbon, Proceedings A, IJES, APL, AIAA J., Nanoscale, IJMS, Compo Struct, Soft matter, TWS, Smart mater struct, APL, etc, with more than 800 SCI citations.

He is a referee for ~30 international journals, such as IJSS, IJMS, NC, Strain, JAE, MAMS, Carbon, NS, AIAA J., IJNME, AMS, etc.

Honors(荣誉和奖励)

2007.09, the second prize of military scientific and technological progress award

         总装备部军队科技进步二等奖；

2008.09, 哈工大第十届优秀博士学位论文；

2009.09, the nomination award of top 100 outstanding doctoraldissertations in China

         全国百篇优秀博士学位论文提名；

2009.11, 哈工大第三届青年教师教学基本功竞赛一等奖；

2011.01, 航院2010年度何鸿燊奖教金(SHAFT)；

2011.11, the Program for New Century Excellent Talents in University

         教育部“新世纪优秀人才支持计划”；

2012.07, 哈工大基础研究杰出人才培育计划III类；

2012.11, the third prize of military scientific and technological progress award

         总装备部军队科技进步三等奖；

2012.12, 校优秀专兼职工作者；

2013.09, 哈尔滨工业大学教学新秀奖；

2013.11, the second prize of National Defense Technology Invention Award

         国防技术发明二等奖；

2013.12, the outstanding youth talent plan of HIT

         哈工大“青年拔尖人才选聘计划”；

2014.10, the second prize of military scientific and technological progress award

         总装备部军队科技进步二等奖；

2017.02, 黑龙江省高校科技奖一等奖；

2017.05, 全国创新争先奖牌(团队核心成员）；

2017.12,国防科技创新团队奖（团队核心成员）；

2018.01, 教育部高等学校科学研究优秀成果奖技术发明奖二等奖；

2019，第四批国家“万人计划”青年拔尖人才；

Work(工作经历)

2007.11-至今 
CCMS, School of Astronautics, HIT
哈工大航院复合材料与结构研究所

2007.6-2011.3 
Post-doctorial Stations, School of Materials, HIT
哈工大材料学院博士后流动站

2009 
Institute of Lightweight Structures, Technische Universit？t München, Munich, Germany (TUM-LLB)
德国慕尼黑工业大学轻型结构实验室（TUM-LLB）

Education(教育经历)

2004.4-2007.4, Engineering Mechanics, HIT, Ph.D

哈尔滨工业大学,博士

2002.9-2004.4, Engineering Mechanics, HIT, M.E.

哈尔滨工业大学,硕士

1998.9-2002.7, Engineering Management, SJU, B.S.

沈阳建筑大学,本科

Research interests(研究方向)

Prof. Wang's major research direction is focused on the membrane materials and structural mechanics of aircrafts. His research interests include Membrane buckling/wrinkling and vibration; Load-carrying ability of inflated membrane structures; Mechanics of flexible composite materials and structures; Mechanics of membrane folding and unfolding; Space rigidization of membrane materials; Structural design theory and its application of space large-scale deployable antenna reflector; Tension-based shape stability of large-scale flexible structures; Light-weighted optimization and fine design of near-space airship structures; Thermal insulation and drag-reducing of envelope material of airship; Structural technology of mixed reinforced super-pressure envelope of light-than-air structures; Non-contact test technologies of static/dynamic perforcement of membrane structures; of Mechanics of graphene pseudo-membrane; Krigami/Origami mechanics of membrane materials and structures;

我所关心的是：柔性复合材料力学、软物质力学和纳米力学中的稳定性问题；

主要研究方向：航天柔性材料与结构、薄膜飞行器结构技术、结构稳定性与控制

学术与科研相关方面（涉及但不局限）：

A 薄膜屈曲/褶皱与振动

B 充气膜的承载失效行为

C 柔性复合材料与结构力学

D 膜结构折叠/展开力学

E 薄膜材料的空间刚化

F 空间展开天线反射器结构设计理论与应用

G 大型柔性结构的张力控型

H 临近空间浮空器结构的轻量化与精细化设计

I 平流层飞艇蒙皮材料隔热与减阻

J 复合增强超压囊体结构技术

K 薄膜结构的非接触静动力性能测试技术

L 石墨烯拟膜结构的力学行为

M 薄膜材料与结构的Kirigami/Origami设计与分析

Projects(科研项目)

作为项目负责人承担过高分国家重大科技专项、国防科工局民用航天预研、国防863、总装武器预研基金、国家自然科学基金、航空科学基金等项目20余项。

2019-2022，弹塑性层合膜结构的屈诱多态失稳力学行为研究，11872160，国家自然科学基金面上，主持；

2016-2019，柔性网增强充气梁的弯皱耦联行为研究，11572099，国家自然科学基金面上，主持；

2012-2015，充气膜承力结构整体屈曲与局部皱曲行为研究，11172079，国家自然科学基金面上，主持；

2010-2012，薄膜褶皱及二次皱曲行为数值分析和模拟研究，10902027，国家自然科学基金青年，主持；

Courses(讲授课程)

Undergraduate courses

Mechanic sof Deformable Solid (Elastic and Plastic Mechanics) (Autumn course).

Mechanics of Composite Materials (Spring course).

Flexible Materials and Structures (Autumn course).

Graduate courses

Mechanics of Composite Materials and structures (Master)

Advanced Composite Structures (Doctor)

High Temperature Solid Mechnics (Doctor)

复合材料与工程专业本科生课程《柔性复合材料与结构》

复合材料与工程专业本科生课程《变形体力学I》（航天学院重点建设的优秀课程）

复合材料与工程专业、工程力学专业本科生课程《复合材料及其结构力学》（航天学院重点建设的优秀课程）

2010工程力学硕士研究生课程《复合材料结构及其力学》

《先进复合材料与结构》，博士研究生课程

《高温固体力学》，博士研究生课程

Projects(教改项目)

《复合材料专业校内外实习基地建设的研究与实践》. 省科技厅“黑龙江省高等教育教学改革项目”. (JG2012010177). 李金平, 韩杰才, 孟松鹤,张宇民, 王长国. 2012-2014.

《研究生实践教学的研究》. 校“研究生教学改革项目”. 王荣国, 李金平, 孙跃, 王长国, 梁媛媛. 2010-2012.

发表的主要研究论文

The selected papers.

Y.P.Liu, K.Guo, C.G.Wang*, H.J.Gao*. Wrinkling and ratcheting of a thin film on cyclically deforming plastic substrate: mechanical instability of the solid-electrolyte interphase in Li-ion batteries. J. Mech. Phys. Solids. ,2019,123:103-118. https://doi.org/10.1016/j.jmps.2018.08.006

M. X. Liu, C. G. Wang, X. D. Li, Rigid-flexible contact analysis of an inflated balloon with various contact conditions. Int. J. Solids Struct., 2018, 144-145: 218-229. https://doi.org/10.1016/j.ijsolstr.2018.05.004

Z. M. Xia, C. G. Wang, H. F. Tan, Elastoplastic folding behavior of membrane ribbon based on plane strain beam theory. Int. J. Solids Struct., 2018,143:167-174. https://doi.org/10.1016/j.ijsolstr.2018.03.004

C. G. Wang, Y. P. Liu, H. F. Tan, Global and local interactive buckling behavior of a stiff film/compliant substrate system. Int. J. Solids Struct., 2016, 102-103: 176-185. doi: 10.1016/j.ijsolstr.2016.10.006

C. G. Wang, L. Lan, Y. P. Liu, H. F. Tan.Vibration characteristics of wrinkled single-layered graphene sheets. Int. J. Solids Struct., 2013, 50(10):1812-1823.

C. G. Wang, X. W. Du, H. F. Tan, X. D. He, A New Computational Method for Wrinkling Analysis of Gossamer Space Structures, Int. J. Solids Struct., 2009, 46(6):1516-1526.

C. G. Wang, H. F. Tan, X. W. Du and Z. M. Wan. Wrinkling Prediction of Rectangular Shell-Membrane under Transverse In-Plane Displacement. Int. J. Solids Struct., 2007, 44(20): 6507-6516.

Y.P. Liu, C.G. Wang, H. F. Tan. The interactive bending wrinkling behaviour of inflated beams. Proc. R. Soc. A. 2016, 472: 20160504.

C.G.Wang,Y.P.Liu,L.Lan and H.F.Tan.Free transverse vibration of a wrinkled annular thin film by using finite difference method. J. Sound Vib. 2016,363:272-284.

C.G.Wang, J.T.Kang, Z.M.Xue, H.F.Tan, Buckling induced delamination and microflow analysis of film/substrate system. Composite Structures. 2017,161:8-14.

Y. P. Liu, C.G.Wang, H .F. Tan. Growth from buckling to buckling-driven delamination in a film/substrate system with finite thickness. Composite Structures. 2017,174:292-300.

C.G.Wang,H.FMode jumping analysis of thin film secondary wrinkling. Int.J.Mech.Sci.2015,104:138-146.

C. G. Wang, L. Lan, H. F. Tan. Secondary Wrinkling Analysis of Rectangular Membrane under Shearing. Int. J. Mech. Sci., 2013,75:299-304.

C. G. Wang, Y. P. Liu, L. Lan, L. Li. H. F. Tan, Post-wrinkling analysis of a torsionally sheared annular thin film by using a compound series method. Int. J. Mech. Sci.,2016,110:22-33.

C.G.Wang, M. X. Liu, H. F. Tan. Bending wrinkling and kink behaviors of inflated beam under local uniform loadings. Int. J. Mech. Sci., 2017,120:136-148.

Q.X.Ji, C.G.Wang, H.F. Tan. Multi-scale wrinkling analysis of the inflated beam. Int. J. Mech. Sci., 2017(126):1-11.

H.F.Tan,J.T.Kang,and C.G.Wang.Study on grooved wall flow under rarefied condition using Lattice Boltzmann Method.Int.J.Mech.Sci.2015,90:1-5.

C. G. Wang, Z. M. Xia, H. F. Tan. An improved molecular structure mechanics method and its application for graphene wrinkling. Int. J. Eng. Sci., 2016, 106:168-178.

C.G.Wang,Y. P. Liu, J. Al-Ghalith, T. Dumitric？, M. K. Wadee, H .F. Tan. Buckling behavior of carbon nanotubes under bending: from ripple to kink, Carbon, 2016,102:224-235.

C. G. Wang, Y. P. Liu. L. Lan, H. F. Tan. Graphene wrinkling: formation, evolution and collapse. Nanoscale, 2013, 5:4454-4461.

C. G. Wang, Y. P. Liu. L. Li, H. F. Tan. Anisotropic thermal conductivity of graphene wrinkles. Nanoscale, 2014, 6:5703-5707.

C. G. Wang, Z. M. Xia, and H. F. Tan. InitialShape Design and Stability Analysis of Rib for Inflatable Deployable Reflector. AIAA J., 2015,53(2):486-492.

J.T.Kang, C.G. Wang, Z.M.Xue, M.X.Liu, H.F.Tan, Buckling Delamination Induced Microchannel: Flow Regulation in Microfluidic Devices. Appl. Phys. Lett., 2016,109:103503.

J.T. Kang, C.G. Wang*, H.F. Tan, Cavitation in inhomogeneous soft solids. Soft Matter, 2018. http://dx.doi.org/10.1039/C8SM01464G.

J.T.Kang, C.G.Wang, S.Q.Cai. Cavitation to Fracture Transition in a Soft Solid. Soft Matter. 2017,13：6372-6376.

C. G. Wang, J. Xie, H. F. Tan.The Modal Analysis and Modal Behavior Investigations on the Wrinkled Membrane Inflated Beam. ACTA Astronaut., 2012,81:660-666.

Q. Tao, C. G. Wang, Z. M. Xue, Z. M. Xie, H. F. Tan. Wrinkling and collapse of mesh reinforced membrane inflated beam under bending. Acta Astronautica. 2016,128: 551-559.

C.G.Wang, J.Xie and H.F.Tan.Vibration Simulations of Wrinkled Membrane Inflated Arch. J. Aerospace Eng. 2014,27(2):414-422.

C. G. Wang, H. F. Tan, X. W. Du. Wrinkling Analysis Method Based on Singular Displacement Component Modification for Membrane Structure. AIAA J. Spacecraft Rockets., 2010,47(1):210-213.

C. G. Wang, X. W. Du and L. M. Zhang. Evaluation of Characteristic and Degree of Wrinkles in Space Membrane Structures. AIAA J. Spacecraft Rockets., 2007,44(1):284-286.

C. G. Wang, X. W. Du and Z. M. Wan. Numerical Simulation of Wrinkles in Space Inflatable Membrane Structures. AIAA J. Spacecraft Rockets., 2006,43(5):1146-1149.

C. G. Wang, X. W. Du and Z. M. Wan. An Experimental Study on Wrinkling Behaviours and Characteristics of Gossamer Space Structures. Strain, 2007,43(4):332-339.

C. G. Wang and H. F .Tan. Experiment and numerical studies on wrinkling control of inflated beam using SMA wires. Smart Mater. Struct., 2010, 19(10):105019(9pages).

C.G.Wang, Y.F.Wang, The mechanical design of a hybrid intellegent hinge with shape memory polymer and spring sheet. Compos. Part.B: Engineering. 2018,134:1-8.

C. G. Wang, L. Lan, H. F. Tan. The physis of wrinkling in graphene membrane under local tension. Phys. Chem. Chem. Phys., 2013, 15(8):2764-2773.

J.T.Kang,C.G.Wang and H.F.Tan.Nanoscale crosslinking in thermoset polymers:A molecular dynamics study. Phys. Chem. Chem. Phys.,2015,17,16519 -16524.

C. G. Wang, Z. Y. Du and H. F. Tan. Initial wrinkling and its evolution of membrane inflated cone in bending. Thin wall. struct., 2012,59:97-102.

Z.M.Xue, C.G.Wang, J.T.Kang, H.F.Tan. Buckling and wrinkling analysis of inflated arch based on Pseudo Curved Beam model. Thin-walled structures. 2018,131: 336-346.

L.Lan,C.G.Wang,and H.F.Tan.Experiment and evaluation of wrinkling strain in a corner tensioned square membrane. Acta Mech.Sinica. 2014,30(3):430-436.

C.G. Wang, M.X. Liu, H.F. Tan. Interactive buckling of inflated envelope under mechanical and thermal loads. Acta Mech. Sinica.. 2016. doi:10.1007/s10409-016-0615-x

C. G. Wang, H. F. Tan and X. D. He. Wrinkle-Crease Interaction Behavior Simulation of A Rectangular Membrane under Shearing. Acta Mech. Sinica., 2011,27(4): 550-558.

C. G. Wang, H. F. Tan and X. W. Du. Pseudo-Beam Method for Compressive Buckling Characteristics Analysis of Space Inflatable Load-Carrying Structures. Acta Mech. Sinica., 2009, 25(5):659-668.

C. G. Wang, H. F. Tan, X. W. Du and X. D. He. A New Model for Wrinkling and Collapse Analysis of Membrane Inflated Beam. Acta Mech. Sinica., 2010,26(4):617-623.

C.G. Wang, M.X. Liu, H.F. Tan. Interactive buckling of an inflated envelope under mechanical and thermal loads. Acta Mech. Sinica., 2017, 33(1): 159-172.

C.G.Wang,J.Xie,H.F.Tan.Vibration evaluation of wrinkled membrance inflated beam.Mech.Adv.Mater.Struc.2015,22(5):376-382.

C. G. Wang, L. N. Mao, X. W. Du, X. D. He. Influence Parameter Analysis and Wrinkling Control of Space Membrane Structures, Mech.Adv. Mater. Struct., 2010, 17(1):49-59.

C. G. Wang, H. F. Tan and X. W. Du. Wrinkling Behaviors of Gossamer Structure with Stretched Annulus-Shape under In-Plane Torsion. Mech.Adv. Mater. Struct., 2008, 15(2):157-164.

C. G. Wang, Z. Y. Du, H. F. Tan. An extremum method for bending-wrinkling predictions of inflated conical cantilever beam. Struct. Eng. Mech., 2013, 46(1): 39-51.

J.T.Kang, H.F.Tan, C.G.Wang, S.Q.Cai. Mechanics modeling of fern cavitation catapult. J. Appl. Phys. 2017,122: 225105.

Y. F. Wang，C. G. Wang, Y . C .Zhang, J .M . Guo, H . F . Tan. Dimensional variation of reconfigurable serpentine graphene nanoribbon under tension. J. Appl. Phys. 2018,125(8),082509.https://doi.org/10.1063/1.5050458

C. G. Wang, L. Lan, Y. P. Liu, H. F. Tan. Functional group-guided variable frequency characteristics of graphene resonator. RSC Adv., 2013,3(36):16095-16101.

C. G. Wang, Y. P. Liu, L. Li, L. Lan, and H. F. Tan. Abnormal Frequency Characteristics of Wrinkled Graphene. RSC Adv., 2014,4:9395-9400.

C. G. Wang, L. Lan; Y. P. Liu; H. F. Tan, Defect-guided wrinkling in graphene. Comp. Mater. Sci., 2013, 77:250-253.

Xia Z M, Wang C G, Tan H F. Strain-dependent elastic properties of graphene oxide and its composite. Comp. Mater. Sci., 2018, 150C:252-258.

Y. F. Wang , C. G. Wang , Y . C .Zhang, H . F . Tan. Graphene kirigami as reinforcement and interfacial bonding effect for toughness and strength of silicon-based nanocomposites. Comp. Mater. Sci., 2019, 159: 306-315.https://doi.org/10.1016/j.commatsci.2018.12.034

C. G. Wang, L. Lan, Y. P. Liu and H. F. Tan. Multiple component correlation model for elastic modulus of single layer graphene sheets. Physica E. 2014,56:372-376.

Xia Z M, Wang C G, Tan H F. Elastic properties of graphene: A pseudo-beam model with modified internal bending moment and its application. Physica E., 2018, 98C:45-52.

Y. P. Liu, C. G. Wang, L. M. Zhang, H. F. Tan. An evaluation method for nanoscale wrinkle. Physica E. 2016,80:191-194.

C. G. Wang, Y. L. Li, X. W. Du and X. D. He. Simulation Analysis of the Vibration Characteristics of Wrinkled Membrane Space Structure. Int. J. Space Struct., 2007,22(4):239-246.

王长国, 杜星文, 赫晓东. 空间充气薄膜结构的褶皱分析. 力学学报. 2008.(40)3:331-338.

王长国, 杜星文, 万志敏. 空间薄膜结构褶皱的数值模拟最新研究进展. 力学进展. 2007,37(3): 389-397.

杜星文, 王长国, 万志敏. 空间薄膜结构的褶皱研究进展. 力学进展. 2006,36(2):187-199.

王长国, 杜星文, 万志敏. 薄膜褶皱的非线性屈曲有限元分析. 计算力学学报. 2007,24(3):269-274.

C. G. Wang, Y. P. Liu, et al., A Novel Lattice-Based Design and Analysis of Inflatable Wing. 54th AIAA/ASME/ASCE/AHS/ASC Structures,Structural Dynamics & Materials Conference, Boston,Massachusetts, 8–11 April 2013. AIAA 2013-1882.

C. C. Wang, et al., A Numerical Algorithm for Eliminating the Singular Stiffness Matrix of Membrane Wrinkling. 54th AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics & Materials Conference,Boston, Massachusetts, 8–11 April 2013. AIAA 2013-1930.

C. G. Wang, H. F. Tan and X. D. He. Wrinkle-Crease Interaction Simulation Using Combined MT Model and DP Technique. 51st AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics & Materials Conference, Orlando, Florida, 12–15 April 2010. AIAA 2010-2506.

C. G. Wang, H. F. Tan and X. W. Du. Modified Displacement Component Approach for Wrinkling Analysis of Gossamer Space Structures. 48th AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics & Materials Conference, Sheraton, Waikiki, Hawaii, 23-26 April, AIAA 2007-1822.

C. G. Wang, X. W. Du and Z. M. Wan. Numerical Analysis of Wrinkles in Space Inflatable Membrane Structures. 47th AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics & Materials Conference, Hyatt Regency Newport, Rhode Island, 1-4 May, AIAA 2006-1797.

C. G. Wang, Z. M. Xia, H. F. Tan. Buckling and wrinkling of inflatable support structure of deployable antenna. 65th International Astronautical Congress (IAC2014), Sep.29-Oct.3,2014.

C. G. Wang, Y. P. Liu, H. F. Tan. Torsional wrinkling behaviour of annular thin elastic sheets. 24th International Congress of Theoretical and Applied Mechanics-ICTAM 2016, Montréal, Canada from August 21-26, 2016.

C. G. Wang, Q. Tao, H. F. Tan. Bending capacity of inflated mesh-reinforced-membrane beam. 24th International Congress of Theoretical and Applied Mechanics-ICTAM 2016, Montréal, Canada from August 21-26, 2016.

 

Authorized invention patents
Patent list

授权发明专利列表

 

ZL201010235077.9, 通过修正奇异位移分量消除褶皱计算时刚度矩阵奇异性的方法, 排名第1. 2012

ZL201310572194.8,薄膜拉剪耦合实验测试装置，排名第1. 2016

ZL201210257425.1,高精度充气膜结构设计方法，排名第1.2014

ZL201210220314.3,一种用于控制充气结构构型混编预张力索网的方法，排名第1.2013

ZL201210187102.X,一种用于超薄柔性膜材拉伸性能测试用的夹具, 排名第1. 2013

ZL200810064518.6,一种可刚化充气展开径向肋支撑式偏馈抛物面天线，排名第1. 2012

ZL201310667740.6, 一种带膜径向肋，排名第1. 2016

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