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王青山


基本资料
职称: 副教授、硕士生导师
电子邮件: wangqingshanxlz@hotmail.comqingshanwang@csu.edu.cn
联系电话:17375815030
QQ309746131
联系地址:湖南省长沙市岳麓区中南大学新校区机电楼A219B

教育背景
2012.09-2016.12哈尔滨工程大学机械工程专业,博士
2008.09-2012.06哈尔滨工程大学机械设计制造及其自动化专业,学士

工作经历
2017.10-至今:中南大学,机电工程学院,副教授 (破格)
2017.3-2017.9:中南大学,机电工程学院,讲师

科学研究方向
1. 结构动力学研究:主要针对工程上具有一般通用性的基础构件,例如梁、板、壳等结构,开展其内在的动力学机理研究,为其工程应用提供优化方案
2. 振动噪声评估研究:主要基于有限元、边界元以及统计能量法等方法对舰船、海洋平台等实际工程结构进行振动噪声分析,并进一步提供相对应的减振降噪措施
3. 计算力学方法研究:主要是基于傅立叶级数、雅克比级数、变分原理等基础数学原理,开展适应于复杂边界条件下的结构动力学分析新方法研究

主持科研项目
1. 国家自然科学基金青年基金项目:回转类复合材料板壳结构与声腔耦合系统理论建模及声振机理研究,2018.01—2020.12
2. 湖南省自然科学基金青年基金项目:复合材料板壳结构与声腔耦合系统理论建模及声振机理研究,2018.01—2020.12
3. 中央高校基本科研业务费:复合材料板壳结构声振机理研究,2017.06—2019.12
4. 国防预研子课题:基于动态能量法的JXZS评估方法研究,2018.03—2019.12
5. 横向课题:船舶舱段结构损耗特性试验,2017.04—2017.11
6. 横向课题:深水半潜支持平台典型结构损耗特性测试及平台结构动力吸振防护设计验证试验,2017.08—2018.11
7. 横向课题:多艘海洋平台噪声环境评估研究,2018.03—2018.12

近三年主要期刊论文(第一作者/通信作者)
ESI高被引论文
1. Dongyan Shi, Qingshan Wang*. A series solution for the in-plane vibration analysis of orthotropic rectangular plates with non-uniform elastic boundary constraints and internal line supports, Arch. Appl. Mech., 85 (2015) 51-73.
2. X. Shi, D. Shi, W.L. Li, Qingshan Wang. A unified method for free vibration analysis of circular, annular and sector plates with arbitrary boundary conditions, J. Vibrat. Control, 22 (2016) 442-456.
3. Qingshan Wang* D. Shi, Q. Liang, F.E. Ahad, A unified solution for free in-plane vibration of orthotropic circular, annular and sector plates with general boundary conditions, Appl. Math. Model., 40 (2016) 9228-9253.
4. D. Shao, S. Hu Qingshan Wang*, An enhanced reverberation-ray matrix approach for transient response analysis of composite laminated shallow shells with general boundary conditions, Composite Structures, 162 (2017) 133-155.
5. D. Shao, S. Hu Qingshan Wang*, Free vibration of refined higher-order shear deformation composite laminated beams with general boundary conditions, Composites Part B-Engineering, 108 (2017) 75-90.
6. Qingshan Wang*, D. Shi, Q. Liang, F. Pang, Free vibrations of composite laminated doubly-curved shells and panels of revolution with general elastic restraints, Appl. Math. Model., 46 (2017) 227-262.
7. Qingshan Wang*, D. Shi, Q. Liang, F. Pang, Free vibration of four-parameter functionally graded moderately thick doubly-curved panels and shells of revolution with general boundary conditions, Appl. Math. Model., 42 (2017) 705-734.
8. Qingshan Wang*. Shi, F. Pang, F.e. Ahad, Benchmark solution for free vibration of thick open cylindrical shells on Pasternak foundation with general boundary conditions, Meccanica, 52 (2017) 457-482.
9. H. Zhang, D. Shi, Qingshan Wang*, Benchmark solution for free vibration of thick open cylindrical shells on Pasternak foundation with general boundary conditions, International Journal of Mechanical Sciences, 121 (2017) 1-20.
10. Qingshan Wang*. Shi, F. Pang, F.e. Ahad, A unified solution for vibration analysis of functionally graded circular, annular and sector plates with general boundary conditions, Composites Part B-Engineering, 88 (2016) 264-294.
2018年度论文
1. Qingshan Wang*, D. Shao, B. Qin, A simple first-order shear deformation shell theory for vibration analysis of composite laminated open cylindrical shells with general boundary conditions, Composite Structures, 184 (2018) 211-232.
2. Qingshan Wang*, K. Choe, D. Shi, K. Sin, Vibration analysis of the coupled doubly-curved revolution shell structures by using Jacobi-Ritz method, International Journal of Mechanical Sciences, 135 (2018) 517-531.
3. Q. Guo, D. Shi, Qingshan Wang*, A domain decomposition approach for static and dynamic analysis of composite laminated curved beam with general elastic restrains, Mechanics of Advanced Materials and Structures, DOI:10.1080/15376494.2018.1432810.
4. Q. Guo, D. Shi, Qingshan Wang*, Dynamic analysis of laminated doubly-curved shells with general boundary conditions by means of a domain decomposition method, International Journal of Mechanical Sciences, 138 (2018) 159-186.
5. H. Zhang, D. Shi, Qingshan Wang*, Vibro-acoustic analysis of the thin laminated rectangular plate-cavity coupling system, Composite Structures 189 (2018): 570-585.
6. Chen zhang, Qingshan Wang*, Free vibration analysis of elastically restrained functionally graded curved beams based on Mori–Tanaka scheme, Mechanics of Advanced Materials and Structures, DOI: 10.1080/15376494.2018.1452318.
7. Guan, Xianlei, Jinyuan Tang, Qingshan Wang*, Cijun shuai. Application of the differential quadrature finite element method to free vibration of elastically restrained plate with irregular geometries, Engineering Analysis with Boundary Elements 90 (2018): 1-16.
8. Zhong, Rui, Qingshan Wang*, et al. Vibration characteristics of functionally graded carbon nanotube reinforced composite rectangular plates on Pasternak foundation with arbitrary boundary conditions and internal line supports, Curved and Layered Structures 5.1 (2018): 10-34.
9. Guan, Xianlei, Jinyuan Tang, Qingshan Wang*, et al. A semi-analytical method for transverse vibration of sector-like thin plate with simply supported radial edges. Applied Mathematical Modelling, 2018, 60: 48-63.
10. Choe K, Qingshan Wang *.  Vibration analysis for coupled composite laminated axis-symmetric doubly-curved revolution shell structures by unified Jacobi-Ritz Method, Composite Structures, 194 (2018) 136-157.
11. Rui zhong, Qingshan Wang *. Vibration analysis for coupled composite laminated axis-symmetric doubly-curved revolution shell structures by unified Jacobi-Ritz Method, Composite Structures, 194 (2018) 49-67.
12. Fei Xie, Qingshan Wang*, et al. Free vibration of functionally graded carbon nanotube reinforced composite cylindrical panels with general elastic supports, Curved and Layered Structures 5 (2018): 95-115.

13. Hong Zhang, D. Shi, Qingshan Wang *. Parameterization study on the moderately thick laminated rectangular plate-cavity coupling system with uniform or non-uniform boundary conditions, Composite Structures, 2018 (In Press).
14. Choe K, Qingshan Wang *. Free vibration analysis of coupled functionally graded (FG) doubly-curved revolution shell structures with general boundary conditions, Composite Structures, 2018 (In Press).

2017年度论文
1. Y. Zhou, Qingshan Wang *, D. Shi, Q. Liang, Z. Zhang, Exact solutions for the free in-plane vibrations of rectangular plates with arbitrary boundary conditions, International Journal of Mechanical Sciences, 130 (2017) 1-10.
2. K. Zhang, D. Shi, W. Qingshan Wang *. Wang, Mechanical characterization of hybrid lattice-to-steel joint with pyramidal CFRP truss for marine application, Composite Structures, 160 (2017) 1198-1204.
3. H. Zhang, D. Shi, Qingshan Wang *, B. Qin, Free vibration of functionally graded parabolic and circular panels with general boundary conditions, Curved and Layered Structures, 4 (2017) 52-84.
4. H. Zhang, D. Shi, Qingshan Wang *, An improved Fourier series solution for free vibration analysis of the moderately thick laminated composite rectangular plate with non-uniform boundary conditions, International Journal of Mechanical Sciences, 121 (2017) 1-20.
5. Qingshan Wang *, D. Shi, F. Pang, F. e Ahad, Benchmark solution for free vibration of thick open cylindrical shells on Pasternak foundation with general boundary conditions, Meccanica, 52 (2017) 457-482.
6. Qingshan Wang *, D. Shi, Q. Liang, F. Pang, Free vibration of four-parameter functionally graded moderately thick doubly-curved panels and shells of revolution with general boundary conditions, Appl. Math. Model., 42 (2017) 705-734.
7. Qingshan Wang *, D. Shi, Q. Liang, F. Pang, Free vibrations of composite laminated doubly-curved shells and panels of revolution with general elastic restraints, Appl. Math. Model., 46 (2017) 227-262.
8. Qingshan Wang *, D. Shi, Q. Liang, F. Pang, A unified solution for vibration analysis of moderately thick functionally graded rectangular plates with general boundary restraints and internal line supports, Mechanics of Advanced Materials and Structures, 24 (2017) 943-961.
9. Qingshan Wang *, B. Qin, D. Shi, Q. Liang, A semi-analytical method for vibration analysis of functionally graded carbon nanotube reinforced composite doubly-curved panels and shells of revolution, Composite Structures, 174 (2017) 87-109.
10. Qingshan Wang *, F. Pang, B. Qin, Q. Liang, A unified formulation for free vibration of functionally graded carbon nanotube reinforced composite spherical panels and shells of revolution with general elastic restraints by means of the Rayleigh–Ritz method, Polymer Composites, (2017) n/a-n/a.
11. Qingshan Wang *, X. Cui, B. Qin, Q. Liang, J. Tang, A semi-analytical method for vibration analysis of functionally graded (FG) sandwich doubly-curved panels and shells of revolution, International Journal of Mechanical Sciences, 134 (2017) 479-499.
12. Qingshan Wang *, X. Cui, B. Qin, Q. Liang, Vibration analysis of the functionally graded carbon nanotube reinforced composite shallow shells with arbitrary boundary conditions, Composite Structures, 182 (2017) 364-379.
13. D. Shao, S. Hu, Qingshan Wang *, F. Pang, An enhanced reverberation-ray matrix approach for transient response analysis of composite laminated shallow shells with general boundary conditions, Composite Structures, 162 (2017) 133-155.
14. D. Shao, S. Hu, Qingshan Wang *, F. Pang, Free vibration of refined higher-order shear deformation composite laminated beams with general boundary conditions, Compos Part B-Eng, 108 (2017) 75-90.
2016年度论文
1. Qingshan Wang *, D. Shi, X. Shi, A modified solution for the free vibration analysis of moderately thick orthotropic rectangular plates with general boundary conditions, internal line supports and resting on elastic foundation, Meccanica, 51 (2016) 1985-2017.
2. Qingshan Wang *, D. Shi, F. Pang, Q. Liang, Vibrations of Composite Laminated Circular Panels and Shells of Revolution with General Elastic Boundary Conditions via Fourier-Ritz Method, Curved and Layered Structures, 3 (2016) 105-136.
3. Qingshan Wang *, D. Shi, Q. Liang, X. Shi, A unified solution for vibration analysis of functionally graded circular, annular and sector plates with general boundary conditions, Compos Part B-Eng, 88 (2016) 264-294.
4. Qingshan Wang *, D. Shi, Q. Liang, F. e Ahad, A unified solution for free in-plane vibration of orthotropic circular, annular and sector plates with general boundary conditions, Appl. Math. Model., 40 (2016) 9228-9253.
5. Qingshan Wang *, D. Shi, Q. Liang, F. Ahad, An improved Fourier series solution for the dynamic analysis of laminated composite annular, circular, and sector plate with general boundary conditions, Journal of Composite Materials, 50 (2016) 4199-4233.
6. Qingshan Wang *, D. Shi, Q. Liang, Free vibration analysis of axially loaded laminated composite beams with general boundary conditions by using a modified Fourier–Ritz approach, Journal of Composite Materials, 50 (2016) 2111-2135.
7. X. Shi, D. Shi, W.L. Li, Qingshan Wang *, A unified method for free vibration analysis of circular, annular and sector plates with arbitrary boundary conditions, J. Vibrat. Control, 22 (2016) 442-456.
8. D. Shi, Y. Zhao, Qingshan Wang *, X. Teng, F. Pang, A unified spectro-geometric-Ritz method for vibration analysis of open and closed shells with arbitrary boundary conditions, Shock Vibrat., 2016 (2016).
9. D. Shi, X. Lv, Qingshan Wang *, Q. Liang, A unified solution for free vibration of orthotropic annular sector thin plates with general boundary conditions, internal radial line and circumferential arc supports, Journal of Vibroengineering, 18 (2016) 361-377.
10. D. Shi, Q. Liang, Qingshan Wang *, X. Teng, A unified solution for free vibration of orthotropic circular, annular and sector plates with general boundary conditions, Journal of Vibroengineering, 18 (2016) 3138-3152.
11. D. Shao, S. Hu, Qingshan Wang *, F. Pang, A unified analysis for the transient response of composite laminated curved beam with arbitrary lamination schemes and general boundary restraints, Composite Structures, 154 (2016) 507-526.
12. D. Shao, F. Hu, Qingshan Wang *, F. Pang, S. Hu, Transient response analysis of cross-ply composite laminated rectangular plates with general boundary restraints by the method of reverberation ray matrix, Composite Structures, 152 (2016) 168-182.
13. X. Lv, D. Shi, Qingshan Wang *, Q. Liang, A unified solution for the in-plane vibration analysis of multi-span curved Timoshenko beams with general elastic boundary and coupling conditions, Journal of Vibroengineering, 18 (2016) 1071-1087.
14. D. Shi, Qingshan Wang *, X. Shi, F. Pang, An accurate solution method for the vibration analysis of Timoshenko beams with general elastic supports, Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science, 229 (2015) 2327-2340.
15. D. Shi, Qingshan Wang *, X. Shi, F. Pang, A series solution for the in-plane vibration analysis of orthotropic rectangular plates with non-uniform elastic boundary constraints and internal line supports, Arch. Appl. Mech., 85 (2015) 51-73.

学术奖励
1.    国家博士研究生奖学金,2015年度
2.    国家博士研究生奖学金,2016年度
3.    工信部创新创业一等奖学,2016年度
4.    中国船级社最佳论文奖学金,2015年度
5.    黑龙江省三好学生,2015年度
6.    提名上银优秀机械博士论文奖,2017年度

学术和社会兼职
1. 国际期刊Applied Mathematical Modelling (ISSN: 0307-904X)审稿人
2. 国际期刊Meccanica (ISSN: 0025-6455)审稿人
3. 国际期刊Thin-Walled Structures (ISSN: 0263-8231)审稿人
4. 国际期刊Frontiers of Aerospace Engineering (ISSN: 2325-6796)审稿人
5. 国际期刊International Journal of Structural Stability and Dynamics (ISSN: 0219-4554)审稿人
6. 国际期刊Composite Structures (ISSN: 0263-8223)审稿人
7. 国际期刊Aerospace Science and Technology (ISSN: 1270-9638)审稿人
8. 国际期刊International Journal of Mechanical Science (ISSN: 0020-7403)审稿人
9. 国际期刊Journal of Sandwich Structures and Materials(ISSN: 1099-6362)审稿人
10. 国际期刊Mechanics of Advanced Materials and Structures (ISSN: 1537-6494)审稿人
11. 国际期刊Journal of Composite Materials (ISSN: 0021-9983)审稿人
12. 国际期刊Noise Control Engineering Journal (ISSN: 0736-2501)审稿人
13. 国际期刊Scientia Iranica (ISSN: 1026-3098)审稿人
14. 国际期刊Journal of Sound and Vibration (ISSN: 0022-460X)审稿人
15. 国际期刊Engineering Science and Technology, an International Journal (ISSN: 2215-0986)审稿人
16. 国际期刊Journal of the Brazilian Society of Mechanical Sciences and Engineering (ISSN: 1678-5878)审稿人
17. ITA2017, EIA2017, CTCE2017等多个国际学术会议技术程序委员会成员