采用有限质点法的薄壳动力非线性行为分析

doi:10.3785/j.issn.1008-973X.2019.06.001

浙江大学学报(工学版)

2019, Vol. 53

Issue (6): 1019-1030 DOI: 10.3785/j.issn.1008-973X.2019.06.001

土木与建筑工程

采用有限质点法的薄壳动力非线性行为分析

杨超1,2(

),罗尧治1,*(

),郑延丰1

1. 浙江大学空间结构研究中心，浙江杭州 310058
2. 广东省高等学校结构与风洞重点实验室，广东汕头 515063

Nonlinear dynamic analysis of shells using finite particle method

Chao YANG1,2(

),Yao-zhi LUO1,*(

),Yan-feng ZHENG1

1. Space Structure Research Center of Zhejiang University, Hangzhou 310058, China
2. Key Laboratory of Structure and Wind Tunnel of Guangdong Higher Education Institutes, Shantou 515063, China

全文: PDF(3139 KB) HTML

摘要：

基于有限质点法原理和K-L经典薄壳理论，构造具有大位移大转动分析能力的薄壳离散质点模型，推导表述基本控制方程与公式. 对于质点位移以及壳元的变形和内力，均按照面内拉压和面外弯扭两部分进行拆分与叠加，并通过物理方式的虚拟运动依次分离出与薄膜刚度和弯曲刚度相关的纯变形，进而在局部变形坐标系下求解面外变形相对应的质点内力和内力矩，建立质点切平面外转角的变步长显式时间积分式，并对质点质量、时间步长、阻尼等关键参数取值给出建议. 在此基础上引入材料非线性应力修正算法，实现对薄壳弹塑性大应变动力非线性行为的模拟，并通过典型算例验证方法及程序的有效性和正确性.

关键词： 薄壳结构; 有限质点法; 非线性; 动力; 结构复杂行为

Abstract:

A discrete particle model of thin shells with large displacement and large rotation analysis capability was constructed based on the principle of finite particle method and K-L classical thin shell theory, and the fundamental governing equations and formulas were derived. For the particle displacement and the deformation and internal force of the shell element, the two parts corresponding to the in-plane tension and the out-of-plane bending and twisting were split and superimposed, respectively. The pure deformation related with the membrane rigidity and bending rigidity was sequentially separated by using a physical modeling procedure involving fictitious motions. Then in the local deformation coordinate system, the internal forces and moments were solved, and the explicit time integral formula with variable step sizes for calculation of the out-of-plane rotation was established. The determinations of several key parameters were also given, including particle mass, time step and damping. Moreover, an stress correction algorithm for solving material nonlinearity was introduced to simulate the dynamic nonlinear behavior of a thin shell with large elastic-plastic strain. The efficiency and validity of the presented method and the self-developed program are verified by several benchmark examples of nonlinear shell dynamics.

Key words: shell structures finite particle method nonlinearity dynamic complicated behaviors of structures

收稿日期: 2018-05-23 出版日期: 2019-05-22

CLC:

TU 33

通讯作者: 罗尧治 E-mail: 04tmgcyc@zju.edu.cn;luoyz@zju.edu.cn

作者简介: 杨超(1986—)，男，博士后，从事大跨度空间结构研究. orcid.org/0000-0003-1405-2592. E-mail: 04tmgcyc@zju.edu.cn

	服务
	把本文推荐给朋友
	加入引用管理器
	E-mail Alert
	作者相关文章
	杨超
	罗尧治
	郑延丰

引用本文:

杨超,罗尧治,郑延丰. 采用有限质点法的薄壳动力非线性行为分析[J]. 浙江大学学报(工学版), 2019, 53(6): 1019-1030.

Chao YANG,Yao-zhi LUO,Yan-feng ZHENG. Nonlinear dynamic analysis of shells using finite particle method. Journal of ZheJiang University (Engineering Science), 2019, 53(6): 1019-1030.

链接本文:

http://www.zjujournals.com/eng/CN/10.3785/j.issn.1008-973X.2019.06.001 或 http://www.zjujournals.com/eng/CN/Y2019/V53/I6/1019

图 1 薄壳离散质点群模型及任一质点的运动情况

图 2 质点转动计算的局部切平面坐标系

图 3 三节点薄壳元的空间运动描述

图 4 质点的质量截面转动惯量

图 5 扁球壳模型：几何、边界及材料性质

图 6 扁球壳的有限质点离散模型

图 7 扁球壳受突加均布荷载作用下的顶点竖向位移时程

表 1 扁球壳中心顶点处的竖向位移比较

图 8 受冲击作用柱面曲壳：几何、材料与载荷作用

图 9 受冲击后不同时刻的柱面壳形态

图 10 柱面曲壳的最终剖面形状与试验结果比较（t=1.0 ms）

图 11 柱面曲壳纵轴线上位于y=15.95 cm和y=23.93 cm两点的竖向位移时程曲线

图 12 薄壁方管受刚块撞击：几何尺寸、材料与约束条件

图 13 受撞击后薄壁方管的动力响应

图 14 受撞击后不同时刻的方管形态

图 15 t=13.4 ms时方管壁表面的等效塑性应变分布

1	TIMOSHENKO S, WOINOWSKY-KRIEGER S. Theory of Plates and Shells[M]. 2nd ed. Singapore: Mcgraw-Hill, 1959: 107−145.
2	DOYLE J F. Nonlinear Analysis of Thin-Walled Structures: Statics, Dynamics, and Stability [M]. Berlin: Springer, 2001.
3	RAMM E, WALL W A. Shells in advanced computational environment[C] // Proceedings of the 5th World Congress on Computational Mechanics. Barcelona: IACM, 2002: 1–22.
4	BELYTSCHKO T, LIU W K, MORAN B, et al. Nonlinear Finite Elements for Continua and Structures [M]. 2nd ed. New York: John Wiley & Son, 2014.
5	BATOZ J L, BATHE K J, HO L W A Study of three-node triangular bending elements[J]. International Journal for Numerical Methods in Engineering, 1980, 15 (12): 1771- 1812
6	BELYTSCHKO T, WONG B L, CHIANG H Y Advances in one-point quadrature shell elements[J]. Computer Methods in Applied Mechanics and Engineering, 1992, 96 (1): 93- 107 doi: 10.1016/0045-7825(92)90100-X
7	O?ATE E, CENDOYA P, MIQUEL J Non-linear explicit dynamic analysis of shells using the BST rotation-free triangle[J]. Engineering Computations, 2002, 19 (6): 662- 706 doi: 10.1108/02644400210439119
8	LIU C, TIAN Q, YAN D, et al Dynamic analysis of membrane systems undergoing overall motions, large deformations and wrinkles via thin shell elements of ANCF[J]. Computer Methods in Applied Mechanics and Engineering, 2013, 258 (258): 81- 95
9	HOSSEINI S, REMMERS J J C, VERHOOSEL C V, et al An isogeometric solid-like shell element for nonlinear analysis[J]. International Journal for Numerical Methods in Engineering, 2013, 95 (3): 238- 256 doi: 10.1002/nme.v95.3
10	DVORKIN E N, BATHE K J A continuum mechanics based four-node shell element for general non-linear analysis[J]. Engineering Computations, 1984, 1 (1): 77- 88 doi: 10.1108/eb023562
11	HUGHES T J R, LIU W K Nonlinear finite element analysis of shells: Part I. three-dimensional shells[J]. Computer Methods in Applied Mechanics and Engineering, 1981, 26 (3): 331- 362 doi: 10.1016/0045-7825(81)90121-3
12	LUIZ B M, KLAUS JüEN B Higher-order MITC general shell elements[J]. International Journal for Numerical Methods in Engineering, 2010, 36 (21): 3729- 3754
13	喻莹. 基于有限质点法的空间钢结构连续倒塌破坏研究[D]. 杭州: 浙江大学, 2010. YU Ying. Progressive collapse of space steel structures based on the finite particle method[D]. Hangzhou: Zhejiang University, 2010.
14	罗尧治, 郑延丰, 杨超, 等结构复杂行为分析的有限质点法研究综述[J]. 工程力学, 2014, 31 (8): 1- 7, 23 LUO Yao-zhi, ZHENG Yan-feng, YANG Chao, et al Review of the finite particle method for complex behaviors of structures[J]. Engineering Mechanics, 2014, 31 (8): 1- 7, 23
15	郑延丰, 罗尧治基于有限质点法的多尺度精细化分析[J]. 工程力学, 2016, 33 (9): 21- 29 ZHENG Yan-feng, LUO Yao-zhi Multi-scale fine analysis based on the finite particle method[J]. Engineering Mechanics, 2016, 33 (9): 21- 29
16	TING E C, WANG C Y, WU T Y, et al. Motion analysis and vector form intrinsic finite element [R]. Taiwan: V-5 Research Group,National Central University, 2006.
17	赵阳, 王震, 胡可考虑Cowper-Symonds黏塑性材料本构的向量式有限元三角形薄壳单元研究[J]. 建筑结构学报, 2014, 35 (4): 71- 77 ZHAO Yang, WANG Zhen, HU Ke Study on triangular thin-shell element of vector form intrinsic finite element considering Cowper-Symonds viscoplastic constitutive model[J]. Journal of Building Structures, 2014, 35 (4): 71- 77
18	王震, 赵阳, 杨学林薄壳结构碰撞、断裂和穿透行为的向量式有限元分析[J]. 建筑结构学报, 2016, (6): 53- 59 WANG Zhen, ZHAO Yang, YANG Xue-lin Collision-contact, crack-fracture and penetration behavior analysis of thin-shell structures based on vector form intrinsic finite element[J]. Journal of Building Structures, 2016, (6): 53- 59
19	YANG C, SHEN Y, LUO Y An efficient numerical shape analysis for light weight membrane structures[J]. Journal of Zhejiang University: SCIENCE A, 2014, 15 (4): 255- 271 doi: 10.1631/jzus.A1300245
20	BAZELEY G P, CHEUNG Y K, IRONS B M, et al. Triangular elements in plate bending, conforming and non-conforming solutions [C] // Proceedings of the 1st Conference on Matrix Methods in Structural Mechanics. Dayton: Wright-Patterson Air Force Base, 1965: 547–576.
21	HALL J F Problems encountered from the use (or misuse) of Rayleigh damping[J]. Earthquake Engineering and Structural Dynamics, 2006, 35 (5): 525- 545 doi: 10.1002/(ISSN)1096-9845
22	SIMO J C, HUGHES T J R. Computational Inelasticity[M]. New York: Springer-Verlag, 1998: 120−138.
23	BATHE K, RAMM E, WILSON E L Finite element formulations for large deformation dynamic analysis[J]. International Journal for Numerical Methods in Engineering, 1975, 9 (2): 353- 386 doi: 10.1002/(ISSN)1097-0207
24	O?ATE E, FLORES F G Advances in the formulation of the rotation-free basic shell triangle[J]. Computer Methods in Applied Mechanics and Engineering, 2005, 194 (21-24): 2406- 2443 doi: 10.1016/j.cma.2004.07.039
25	ARGYRIS J, PAPADRAKAKIS M, MOUROUTIS Z S Nonlinear dynamic analysis of shells with the triangular element TRIC[J]. Computer Methods in Applied Mechanics and Engineering, 2003, 192 (26/27): 3005- 3038
26	WITMER E A, CLARK E N, BALMER H A Experimental and theoretical studies of explosive-induced large dynamic and permanent deformations of simple structures[J]. Experimental Mechanics, 1967, 7 (2): 56- 66 doi: 10.1007/BF02326708
27	STOLARSKI H, BELYTSCHKO T, CARPENTER N, et al A simple triangular curved shell element[J]. Engineering computations, 1984, 1 (3): 210- 218 doi: 10.1108/eb023574
28	MACNAY G H. Numerical modelling of tube crush with experimental comparison [C] // Proceedings of the 7th International Conference on Vehicle Structural Mechanics. Warrendale: American Society of Automotive Engineers, 1988: 123–134.

[1]	张铁,胡亮亮,邹焱飚. 基于混合遗传算法的机器人改进摩擦模型辨识[J]. 浙江大学学报(工学版), 2021, 55(5): 801-809.
[2]	刘桓龙,谢迟新,李大法,王家为. 齿轮箱飞溅润滑流场分布和搅油力矩损失[J]. 浙江大学学报(工学版), 2021, 55(5): 875-886.
[3]	黄方平,龚国芳,杨灿军,杨华勇. S型桨叶捕能消波浮式防波堤仿真及试验研究[J]. 浙江大学学报(工学版), 2021, 55(5): 866-874.
[4]	詹志文,张凌新,邓见,邵雪明. DTMB 4119螺旋桨噪声特性的数值模拟[J]. 浙江大学学报(工学版), 2021, 55(4): 767-774.
[5]	张玙,刘益才. 小型制冷系统两相流致噪声研究进展[J]. 浙江大学学报(工学版), 2021, 55(4): 775-792.
[6]	张孝良,耿灿,聂佳梅,高乔. 液力忆惯容器装置建模与特性试验[J]. 浙江大学学报(工学版), 2021, 55(3): 430-440.
[7]	于梦婷,汪怡平,苏楚奇,陶琦,史建鹏. 尾随半挂车队列行进的轿车燃油经济性研究[J]. 浙江大学学报(工学版), 2021, 55(3): 455-461.
[8]	李伟达,李娟,李想,张虹淼,顾洪,史逸鹏,张浩杰,孙立宁. 欠驱动异构式下肢康复机器人动力学分析及参数优化[J]. 浙江大学学报(工学版), 2021, 55(2): 222-228.
[9]	李静,王晨,张家旭. 基于自适应快速终端滑模的车轮滑移率跟踪控制[J]. 浙江大学学报(工学版), 2021, 55(1): 169-176.
[10]	朱凯,王云鹤,秦雪薇,黄亚东,王强,吴珂. 升温速率对沥青燃烧和气态产物释放特性的影响[J]. 浙江大学学报(工学版), 2020, 54(9): 1805-1811.
[11]	王泽胜,李研彪,罗怡沁,孙鹏,陈波,郑航. 七自由度冗余混联机械臂的动力学分析[J]. 浙江大学学报(工学版), 2020, 54(8): 1505-1515.
[12]	江冬冬,李道飞,俞小莉. 基于驾驶员需求转矩预测的模型预测控制能量管理[J]. 浙江大学学报(工学版), 2020, 54(7): 1325-1334.
[13]	胡凯明,李华. 轴向受压梁非线性随机最优电压有界控制[J]. 浙江大学学报(工学版), 2020, 54(5): 940-946.
[14]	吕福在,胡宇天,伍建军,王林翔. 双程形状记忆效应的唯象动力学模型[J]. 浙江大学学报(工学版), 2020, 54(4): 642-649.
[15]	吴君涛,王奎华,刘鑫,孙梵. 基于既有桩基振动理论反演的桩周土动态响应解[J]. 浙江大学学报(工学版), 2020, 54(3): 521-528.

Viewed

Full text

Abstract

Cited

Shared

Discussed