上海交通大学学报

上海交通大学学报 >

2022 , Vol. 56 >Issue 6: 730 - 738

DOI: https://doi.org/10.16183/j.cnki.jsjtu.2021.152

船舶海洋与建筑工程

一种分析膜面在积水荷载作用下响应的数值模型

展开
  • 上海交通大学 船舶海洋与建筑工程学院,上海 200240
王沙沙(1995-),女,河南省周口市人,硕士生,主要从事膜结构分析研究.

收稿日期: 2021-05-08

  网络出版日期: 2022-07-04

基金资助

国家自然科学基金(51978395)

收起

A Numerical Model for Analysing Response of Membrane Surface Under Ponding Load

Expand
  • School of Naval Architecture, Ocean and Civil Engineering, Shanghai Jiao Tong University, Shanghai 200240, China

Received date: 2021-05-08

  Online published: 2022-07-04

Fold

摘要

结合光滑粒子流体动力学(SPH)方法和膜材非线性本构,提出了一种分析膜面在积水荷载作用下响应的数值模型.通过不同应力比的双轴拉伸试验得到膜材的应力-应变响应面,建立膜材的非线性本构模型,并使用SPH粒子模拟水,建立膜面与水的流固耦合数值模型.通过网格收敛性分析确定了文中采用的网格尺寸,分析了加载时长对计算结果的影响.同时分析了膜面的应力和应变的分布规律.结果表明,加载过程随加载时长的增加越来越稳定,且100 s能满足分析需求.将数值模拟结果与平膜积水试验结果进行比较,膜面的最大竖向变形吻合较好,验证了所提方法的可靠性.

关键词: ; 积水; 光滑粒子流体动力学; 非线性本构; 数值模型

本文引用格式

王沙沙, 张翔宇, 邱国志, 龚景海 . 一种分析膜面在积水荷载作用下响应的数值模型[J]. 上海交通大学学报, 2022 , 56(6) : 730 -738 . DOI: 10.16183/j.cnki.jsjtu.2021.152

Abstract

A numerical model to analyze the response of the membrane surface under ponding load is propesed which combines the smoothed particle hydrodynamics (SPH) method and the non-linear constitutive model of the membrane material. According to the stress-strain response surface of the membrane material based on the biaxial tensile test with different stress ratios, a nonlinear constitutive model is established. SPH particles are used to simulate water, and a numerical model of the fluid-solid coupling between the membrane surface and ponding load is established. The mesh size adopted in this paper is determined by verifying the mesh convergence, and the influence of the loading time on the calculation results is analyzed. At the same time, the distribution law of stress and strain of the membrane surface are analyzed. The results show that the loading process becomes increasingly stable with the increase of the loading time, and 100 s can meet the analysis requirements.The numerical simulation results are compared with those of the flat membrane ponding test. It is found that the maximum vertical deformation of the membrane surface is in good agreement, which verifies the reliability of the method proposed in this paper.

Key words: membrane; ponding water; smoothed particle hydrodynamics (SPH); nonlinear constitutive; numerical model

参考文献

[1] 董石麟, 邢栋, 赵阳. 现代大跨空间结构在中国的应用与发展[J]. 空间结构, 2012, 18(1): 3-16.
[1] DONG Shilin, XING Dong, ZHAO Yang. Application and development of modern long-span space structures in China[J]. Spatial Structures, 2012, 18(1): 3-16.
[2] 吴明儿, 王暄. ETFE薄膜结构积水试验与数值分析[J]. 建筑钢结构进展, 2012, 14(4): 18-21.
[2] WU Minger, WANG Xuan. Experimental and numerical studies on the ponding of ETFE foil structures[J]. Progress in Steel Building Structures, 2012, 14(4): 18-21.
[3] 罗永赤. 膜结构积水的事故与控制[J]. 建筑结构, 2008, 38(2): 101-102.
[3] LUO Yongchi. Water-collection analysis of membrane structure[J]. Building Structure, 2008, 38(2): 101-102.
[4] 宋小兵, 李中立, 龚景海. 大跨度充气膜结构的研究与应用[C]∥第十九届全国现代结构工程学术研讨会论文集. 北京: 工业建筑, 2019: 140-147.
[4] SONG Xiaobing, LI Zhongli, GONG Jinghai. Research and application of large-span inflatable membrane structure[C]∥The 19th National Symposium on Modern Structural Engineering. Beijing: Industrial Construction, 2019: 140-147.
[5] American Society of Civil Engineers. Tensile membrane structures: ASCE/SEI 55-10[S]. Reston, Virginia: American Society of Civil Engineers, 2010.
[6] 中国工程建设标准化协会. 膜结构技术规程: CECS 158—2015[S]. 北京: 中国工程建设标准化协会, 2015.
[6] China Association for Engineering Construction Standardization. Technical specification for membrane structures: CECS 158—2015[S]. Beijing: China Association for Engineering Construction Standardization, 2015.
[7] Membrane Structures Association of Japan. Testing method for elastic constants of membrane materials: MSAJ/M-02-1995[S]. Tokyo: Membrane Structures Association of Japan, 1995.
[8] GAO C J, CHEN W J, SHI T B, et al. Response surface characterization for biaxial tensile properties of envelope fabrics under multiple stress ratios[J]. Composite Structures, 2019, 230: 111482.
[9] SHI T B, HU J H, CHEN W J, et al. A refined numerical model for determining inflation-burst behavior of composite membrane structures[J]. Polymer Testing, 2020, 81: 106123.
[10] 李意, 陈务军, 高成军, 等. 考虑裁切效应飞艇囊体模型充气数值模拟与试验[J]. 上海交通大学学报, 2020, 54(3): 277-284.
[10] LI Yi, CHEN Wujun, GAO Chengjun, et al. Numerical simulation and tests on inflation of an airship envelope model with cutting pattern effects[J]. Journal of Shanghai Jiao Tong University, 2020, 54(3): 277-284.
[11] 张影, 袁行飞, 徐晓红. 强降雨作用下具有初始凹陷的充气膜结构袋状效应研究[J]. 空间结构, 2018, 24(4): 49-55.
[11] ZHANG Ying, YUAN Xingfei, XU Xiaohong. Analysis of bagging effect in air-supported membrane structures with initial imperfections under intensive rainfall[J]. Spatial Structures, 2018, 24(4): 49-55.
[12] NARAYANAN N K, WÜCHNER R, DEGROOTE J. Monolithic and partitioned approaches to determine static deformation of membrane structures due to ponding[J]. Computers & Structures, 2021, 244: 106419.
[13] SIMULIA D. Abaqus 6.11 analysis user’s manual[DB/OL]. (2011-02-15)[2021-05-08] https:∥www.researchgate.net/publication/310842372_Abaqus_611_analysis_user’s_manual.
[14] 孟翔, 高路恒, 吴浩, 等. 基于SPH无网格法的纺锤形桩靴连续贯入过程模拟[J]. 水利水运工程学报, 2020(4): 111-118.
[14] MENG Xiang, GAO Luheng, WU Hao, et al. Numerical simulation of continuous penetration of spudcan based on SPH mesh-free method[J]. Hydro-Science and Engineering, 2020(4): 111-118.
[15] 李文盛, 赵友清, 贾善坡, 等. 储液容器内液体晃荡的非线性动力学分析[J]. 爆炸与冲击, 2014, 34(1): 87-92.
[15] LI Wensheng, ZHAO Youqing, JIA Shanpo, et al. Numerical analysis on liquid sloshing in storage container by nonlinear dynamics method[J]. Explosion and Shock Waves, 2014, 34(1): 87-92.
[16] 周杰, 徐胜利. 弹丸入水特性的SPH计算模拟[J]. 爆炸与冲击, 2016, 36(3): 326-332.
[16] ZHOU Jie, XU Shengli. SPH simulation on the behaviors of projectile water entry[J]. Explosion and Shock Waves, 2016, 36(3): 326-332.
Options
文章导航

/