Effect of Steam Hammer Pressure Wave Steepening on Pipe Supports

Volume 3B: Design and Analysis Pub Date : 2018-07-15 DOI:10.1115/PVP2018-84775

A. Mayes, Kshitij P. Gawande

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引用次数: 1

Abstract

Safety valve closure is employed within power plant piping systems to protect sensitive components from damage due to irregular events causing abrupt pressure variations of the thermal fluid flow. The valve closure creates a sudden obstruction to the flow, generating a pressure wave within the fluid which travels upstream and impacts at the pipe elbows. Such an event is known as steam hammer. This steam hammer pressure wave is capable of producing significant loads and stresses which can disrupt the piping supports as the wave travels throughout the pipe system. Previous studies have shown that the magnitude of these transient loads depend upon the characteristics of the flow, valve closure time, elbow-to-elbow pipe section lengths, the piping system flexibility, and the ‘steepness’ of the pressure transient. The latter effect has been ignored in most steam hammer studies; however, wave steepening has been shown to have a significant effect in cases where the pressure wave travels long distances from the safety valve. This study focuses on Computational Fluid Dynamics (CFD) modeling of rapid valve closure to produce this wave steepening effect and to investigate the significance in terms of transient pipe support loads.

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蒸汽锤压力波增陡对管道支架的影响

安全阀关闭用于发电厂管道系统中，以保护敏感部件免受因热流体流动压力突然变化引起的不规则事件的损坏。阀门关闭会对流体产生突然的阻塞，在流体中产生压力波，该压力波向上游流动并冲击管道弯头。这样的事件被称为蒸汽锤。这种蒸汽锤压力波能够产生巨大的载荷和应力，当波在管道系统中传播时，可能会破坏管道支架。先前的研究表明，这些瞬态载荷的大小取决于流量特性、阀门关闭时间、弯头到弯头的管道段长度、管道系统的灵活性以及压力瞬态的“陡峭度”。后一种效应在大多数蒸汽锤研究中被忽略;然而，在压力波从安全阀传播很远的情况下，波浪陡增已被证明有显著的效果。本研究的重点是通过计算流体动力学(CFD)对快速阀门关闭进行建模，以产生这种波浪陡坡效应，并从瞬态管道支撑载荷的角度研究其意义。

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 3B: Design and Analysis

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