Diagnosis, Modelling and Assessment of Transient Pressure Events Based on Observed In-Field Evidence

T. J. Prewitt, M. Bednorz
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Abstract

Intermittent pipe movement due to transient pressure events including vapor column collapse or water hammer events can impart large strains into the pipe, cause damage to the support structure, damage coatings, and cause damage or failure of the pipe. This paper will present a method that has been used with success for determining the pipe stresses and strains and possible cause associated with a transient pressure event based on coating damage evidence gathered from in-field assessments. After constructing a hydraulic model of the piping system, various transient events were modelled to obtain resulting pressure over the transient event’s period at key points along the piping system, such as valves and elbows. A second, more refined finite element model was created to incorporate the pressure values to determine the resulting displacements and stresses to relate to the in-field measurements of the region in question. By comparing the displacements in the model to the field evidence, the models were calibrated, and evaluation of the likely cause of coating damage found in the field was able to be performed. Moreover, the stresses in the pipe during the event are able to be assessed which allows for damage assessments to be conducted and allows for corrective actions to take place. Transient events assessed ranged from valve openings and closures, pump start up, and vapor column collapse.
基于现场观测证据的瞬态压力事件诊断、建模和评估
由于瞬态压力事件(包括汽柱坍塌或水锤事件)引起的间歇性管道运动可能会给管道带来巨大的应变,导致支撑结构损坏,涂层损坏,并导致管道损坏或失效。本文将介绍一种基于现场评估收集的涂层损伤证据,成功地用于确定管道应力和应变以及与瞬态压力事件相关的可能原因的方法。在建立管道系统的水力模型后,对各种瞬态事件进行建模,以获得沿管道系统关键点(如阀门和弯头)在瞬态事件期间的最终压力。第二种是更精细的有限元模型,将压力值纳入其中,以确定与相关区域的现场测量相关的位移和应力。通过将模型中的位移与现场证据进行比较,对模型进行了校准,并能够对现场发现的涂层损坏的可能原因进行评估。此外,该系统还可以评估管柱在作业过程中的应力,从而进行损伤评估,并采取纠正措施。评估的瞬时事件包括阀门开启和关闭、泵启动和汽柱坍塌。
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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