高压大流量液压动力系统回路流固耦合分析

IF 0.6 4区工程技术 Q4 MECHANICS

Progress in Computational Fluid Dynamics Pub Date : 2021-01-06 DOI:10.1504/pcfd.2021.10034687

Y. Sang, Pengkun Liu, W. Xudong, Weiqi Sun, Jianlong Zhao

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引用次数: 3

摘要

本文旨在研究高压大流量液压动力系统中回流管路的动态特性。首先，建立了管道的几何模型，介绍了一种单向耦合流体结构方法。对空管道和填充管道进行了模态分析，并进行了比较。然后，对管道谐振现象进行了研究，并通过快速傅立叶变换（FFT）分析获得了响应频率，结果与实验不一致。此外，还对管道的动态响应进行了仿真。采用动态网格和用户定义函数（UDF），观察管道振动和水锤现象。最后，研究了不同流体速度和壁厚下管道的动态特性。结果表明，管道阀门引起的振动不能通过降低流体入口速度来减轻，但可以通过增加壁厚来显著减轻。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Fluid-structure interaction analysis of the return pipeline in the high-pressure and large-flow-rate hydraulic power system

This paper aims to investigate the dynamic characteristic of the return pipeline in the high-pressure and large-flow-rate hydraulic power system. First, the geometry model of the pipeline is established, and a one-way coupling fluid structure method is introduced. The modal analyses with empty and filled pipelines are performed and compared. Then, the pipeline resonance phenomenon is investigated, and the response frequency is achieved by the fast Fourier transformation (FFT) analysis, the results are inconsistent with the experiments. Besides, the dynamic response of the pipeline is simulated. Dynamic mesh and user define function (UDF) are adopted, and the pipeline vibration and water hammer phenomenon are observed. Finally, the dynamic characteristics of the pipeline under different fluid velocities and wall thickness are investigated. The results show that the pipeline valve-induced vibration cannot be lightened by reducing the fluid inlet velocity but can be significantly mitigated by increasing the wall thickness.

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来源期刊

Progress in Computational Fluid Dynamics 物理-力学

CiteScore

1.50

自引率

14.30%

发文量

审稿时长

7.5 months

期刊介绍： CFD is now considered an indispensable analysis/design tool in an ever-increasing range of industrial applications. Practical flow problems are often so complex that a high level of ingenuity is required. Thus, besides the development work in CFD, innovative CFD applications are also encouraged. PCFD''s ultimate goal is to provide a common platform for model/software developers and users by balanced international/interdisciplinary contributions, disseminating information relating to development/refinement of mathematical and numerical models, software tools and their innovative applications in CFD. Topics covered include: -Turbulence- Two-phase flows- Heat transfer- Chemical reactions and combustion- Acoustics- Unsteady flows- Free-surfaces- Fluid-solid interaction- Navier-Stokes solution techniques for incompressible and compressible flows- Discretisation methods and schemes- Convergence acceleration procedures- Grid generation and adaptation techniques- Mesh-free methods- Distributed computing- Other relevant topics