结构入水砰击是一个很复杂的水弹性力学问题,在船舶与海洋工程领域,人们对其十分关注。本文借助模型试验和商用软件平台Ansys技术,对结构入水砰击过程展开研究。首先,自主设计入水结构模型、试验装置,通过布置在楔形体结构内的传感器,全程实时监测楔形体结构下落的压力变化。然后,基于试验结果,数值模拟了三维弹性楔形体的入水砰击过程。得到了砰击压力云图、等效应力云图以及流体的速度云图,对比分析了弹性体测点与试验中测点的砰击压力,验证了该数值模拟方法的可行性与有效性。
Water entry slamming is a complicated hydroelastic problem, which is paid more and more attention in the field of naval architecture and ocean engineering. A systematic study on the process of water entry slamming is performed with the aid of model test and Ansys numerical simulation software technology. Firstly, a reduced scale structure model and test device are designed. The slamming pressure during the structure water entry is measured in real time through the sensors arranged on the wedge structure. The effective and feasibility of the numerical simulation method is validated by model test. Finally, based on the result of the test, numerical simulations of water entry for 3D flexible wedge is conducted. We can obtain both the contours of pressure and von mises stress of the wedge and the contours of velocity of the fluid. The points of flexible wedge and test are compared and analyzed, which proves the feasibility and validity of the numerical simulation method.
2018,40(3): 19-25 收稿日期:2016-10-27
DOI:10.3404/j.issn.1672-7649.2018.03.004
分类号:U661.3
作者简介:王玲(1990-),女,硕士研究生,研究方向为流体力学
参考文献:
[1] OCHI M K, MOTTER L E. Prediction of slamming characteristics and hull responses for ship design[J]. Transactions SNAME, 1973, Vol. 81, 144-177.
[2] PUKHNACHOV V V. Linear approximation in the problem on a blunt body entry in water[J]. Din. Sploshnoi Sredy. 1979, 38:143-150.
[3] TAKAGI K, 1994, Influence of e1asticity on hydrodynamic impact problem[J], J. Kansai Soc. N. A., Japan, Sep. 1994, No. 222, pp. 97-106.
[4] A. EL MALKI ALAOUI, A. NÊME, A. TASSIN, et al. Experimental study of coefficients during vertical water entry of axisymmetric rigid shapes at constant speeds[J]. Applied Ocean Research. 2012, 37:183-197.
[5] SUN S Y, SUN S L, WU G X. Oblique water entry of a wedge into waves with gravity effect[J]. Jounal of Fluids and structures, 2015, 52:49-64(IF, 2.021).
[6] 张伟, 郭子涛, 肖新科, 等. 弹体高速入水特性实验研究[J]. 爆炸与冲击. 2011, 31(6):579-584.
[7] 何春涛, 王聪, 魏英杰, 等. 圆柱体垂直入水空泡形态试验[J]. 北京航空航天大学学报, 2012(11):1542-1546.
[8] 杨衡, 张阿漫, 龚小超, 等. 不同头型弹体低速入水空泡试验研究[J]. 哈尔滨工程大学学报, 2014, 09:1060-1066.
[9] 张岳青, 徐绯, 金思雅, 等. 楔形体入水冲击响应的试验研究及应用[J]. 机械强度, 2015, 37(2):226-231.
[10] 杨衡, 孙龙泉, 龚小超, 等. 弹性结构入水砰击载荷特性三维数值模拟研究[J]. 振动与冲击, 2014, 33(19):28-33.
[11] 张伟伟, 金先龙, 刘涛. 正交异性复合材料储液容器入水过程数值分析[J]. 计算力学学报, 2015, 32(15):633-638, 698.
[12] SUN P, MING F, ZHANG A. Numerical simulation of interactions between free surface and rigid body using a robust SPH method[J]. Ocean Engineering, 2015, 98:32-49.
[13] 张智. 基于CFD技术的三维楔形体入水砰击试验和数值预报研究[D]. 天津:天津大学. 2013.
