Vibration Analysis in Multiple Close Proximity Flow Restrictions

Volume 10: Fluids Engineering Pub Date : 2020-11-16 DOI:10.1115/IMECE2020-23804

R. Verma, George Horiates, Nicholas Kanellis

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Abstract

In this study, a segment of water conveyance system at a chemical manufacturing facility is under investigation. The pipe segment under investigation conveys a daily average flow of five million gallons of water per day (MGD) from the river to a water treatment plant. The exact age of the pipe system is unknown as limited construction or maintenance information exists. The study area is a pipe segment near the treatment plant where three flow restrictions exist within a 30-foot distance bounded by a T-junction and a water filtration plant. These restrictions include two self-actuated butterfly valves and an orifice plate on a 16-inch diameter steel pipe, buried approximately three feet below ground surface. When standing in the study area, heavy vibrations are felt at the ground surface. The valves and orifice plate are to control flowrate and reduce pressure from 80 PSI to 45PSI as the flow enters the water treatment plant. Flow restrictions in close proximity can cause cavitation, water hammer and other flow phenomena within a pipe system. This can result in excessive wear of the pipe’s inner walls and valves which may compromise the structural integrity and/or function of the system. Computational fluid dynamics (CFD) software is a useful tool for determining if the conditions for the various flow phenomena are present in a system. The flow characteristics were numerically calculated in MATLAB then computationally modeled in AFT Fathom. The purpose of the numerical analysis was to describe the stability of the fluid flow at discrete points in the pipe network and identify the network segments with significantly unstable flow profiles. The purpose of the AFT Fathom CFD model purpose was to provide a continuous simulation of the flow stability in the pipe segment and provide a more robust description of the flow profiles in the network. While Fathom cannot explicitly predict cavitation or water hammer, the kinematic parameters produced by the Fathom model and the physical conditions observed in the study indicate that water hammer is likely occurring.

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多近距离流动约束下的振动分析

在这项研究中，正在调查一个化学制造设施的输水系统的一部分。被调查的管道段每天平均从河流向水处理厂输送500万加仑的水。由于有限的施工或维护信息存在，管道系统的确切年龄是未知的。研究区域是处理厂附近的一个管道段，在30英尺的距离内存在三个流量限制，由一个t形路口和一个水过滤厂边界。这些限制包括两个自动蝶阀和直径16英寸的钢管上的孔板，埋在地表以下约3英尺处。当站在研究区域时，地面会感受到强烈的振动。阀门和孔板用于控制流量，并在水流进入水处理厂时将压力从80psi降低到45PSI。近距离的流动限制会导致管道系统内的空化、水锤和其他流动现象。这可能会导致管道内壁和阀门的过度磨损，从而损害系统的结构完整性和/或功能。计算流体动力学(CFD)软件是确定系统中是否存在各种流动现象的条件的有用工具。在MATLAB中对其流动特性进行了数值计算，并在AFT Fathom中进行了计算建模。数值分析的目的是描述管网中离散点处流体流动的稳定性，并识别出流动曲线明显不稳定的网段。AFT Fathom CFD模型的目的是提供管段流动稳定性的连续模拟，并提供更可靠的网络流动剖面描述。虽然Fathom无法明确预测空化或水锤，但Fathom模型产生的运动学参数和研究中观察到的物理条件表明，水锤可能会发生。

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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Volume 10: Fluids Engineering

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