Numerical simulation of vibration response of pipe conveying fluid based on a generalized finite difference method

被引：0

作者：

Zhang T. ^{[1
]}

Lin Z. ^{[1
]}

Guo X. ^{[1
]}

Zhang H. ^{[1
]}

Fan J. ^{[2
]}

机构：

[1] College of Civil Engineering, Fuzhou University, Fuzhou

[2] Department of Harbor and River Engineering, Taiwan Ocean University, Keelung

来源：

Zhendong yu Chongji/Journal of Vibration and Shock | 2019年 / 38卷 / 24期

关键词：

Generalized finite difference method(GFDM); Houbolt method; Meshless method; Transverse vibration; Words: pipe conveying fluid;

D O I：

10.13465/j.cnki.jvs.2019.24.023

中图分类号：

学科分类号：

摘要：

In this study, a high-order accuracy numerical model of the meshless method, called generalized finite difference method (GFDM), was generalized to analyze the transverse vibration problem of pipe conveying fluid. Based on the differential equation of transverse vibration, the GFDM and the Houbolt methods were adopted to discretize the partial differential items in space and time, respectively. The consistent with good results of natural frequency and the amplitude time range was compared with the theoretical solution and other numerical results reported in literature. Meanwhile, the numerical model proposed in this paper has good stability and robustness in solving the vibration response of pipe conveying fluid by comparing with the vibration amplitude at the midpoint with different total number of points N, time step Δt and sub-region selection points ns, respectively. Furthermore, detailed analysis of the vibration response characteristics with several typical boundary conditions indicates that the vibration amplitude at the midpoint of the pined-pined pipe is much large than that of two other boundary conditions, and the vibration frequency of the clamped-clamped pipe is more fast than that of others. Besides, the position of the maximum amplitude of the vibration is shifted to the weak constraint when the end of restrictive condition is asymmetric. © 2019, Editorial Office of Journal of Vibration and Shock. All right reserved.

引用

页码：165 / 171

页数：6

共 23 条

[1] Zhang T., Tan Z., Zhang H., Et al., Axial coupled response characteristics of a fluid-conveying pipeline based on split-coefficient matrix finite difference method, Journal of Vibration and Shock, 37, 5, pp. 148-154, (2018)
[2] Paidoussis M.P., Fluid-Structure Interactions: Slender Struc- Tures and Axial Flow, (1998)
[3] Jin J., Song Z., Yang X., Stability and parametric resonances of a clamped-clamped pipe conveying fluid, Journal of Vibration Engineering, 17, 2, pp. 190-195, (2004)
[4] Bao R., Jin Z., Wen B., Bifurcation and chaotic response of restrained cantilever pipe with conveyed fluid, Journal of Vibration and Shock, 27, 5, pp. 36-39, (2008)
[5] Ni Q., Zhang Z.L., Wang L., Application of the differential transformation method to vibration analysis of pipes conveying fluid, Applied Mathematics & Computation, 217, 16, pp. 7028-7038, (2011)
[6] Wang C.C., Yau H.T., Application of the differential transformation method to bifurcation and chaotic analysis of an AFM probe tip, Computers & Mathematics with Applications, 61, 8, pp. 1957-1962, (2011)
[7] Ni Q., Huang Y., Chen Y., Differential guadrature method for analyzing critical flow velocity of the pipe conveying fluid with spring support, Chinese Journal of Computational Mechanics, 18, 2, pp. 146-149, (2001)
[8] Wang L., Ni Q., The nonlinear dynamic vibrations of a restrained pipe conveying fluid by differential quadrature method, Journal of Dynamics and Control, 2, 4, pp. 56-61, (2004)
[9] Zhong W.X., On precise integration method, Journal of Computational and Applied Mathematics, 163, 1, pp. 59-78, (2004)
[10] Long L., Xuan F.Z., Flow-induced vibration analysis of supported pipes conveying pulsating fluid using precise integration method, Mathematical Problems in Engineering, 12, pp. 1-15, (2010)

← 1 2 3 →