Boundaries Definition for Modeling Transients in Oil Terminals

Wilfredo Vargas Molina
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Abstract

Terminals are an integral part of transmission pipelines that can operate in different modes. The two most common modes are single injection and single delivery. Because pressure waves generated after accidental valve closures, pump trips, or others can travel many miles in a few seconds, it is a current practice to simulate the whole mainline to the next pump station, upstream or downstream, due to the lack of a standard method to identify boundaries. This paper proposes a method to define the minimum modeling boundary. This boundary is especially useful when the available data is limited, when multiple suppliers / pipeline owners are connected to a terminal, when advanced simulation software or powerful computers are not available, or when the goal is to avoid unnecessary, complex labor-intensive simulations. The technique consists of identifying a boundary located far enough in the mainline so that pressure waves do not interfere with the development of pressure surges after transient events in the facility piping or in a segment of a pipeline that has the weakest pipe. This straightforward method is supported by concepts published by well-known authorities in the transient hydraulics field and tested with available pipeline simulation software. After reading this paper, the reader will be able to answer these questions: • How much data do I need? • How many permutations? • What info is critical for this method? • Where is the boundary? • What causes a wrong selection? In summary, the hydraulic engineer will be able to shorten the current boundary to small fractions: up to 1/25 in the case of injection facilities and up to 2/25 in the case of delivery facilities. As well, readers will confirm that the hydraulic conditions in the mainlines beyond these boundaries don’t have any effect on the facilities’ piping due to transient events such as accidental valve closures or pumps trips, the most common initiators of large pressure surges.
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油站瞬态建模的边界定义
终端是输送管道的一个组成部分,可以在不同的模式下运行。两种最常见的方式是单次注射和单次输送。由于意外关闭阀门、泵跳闸或其他原因产生的压力波可以在几秒钟内传播数英里,由于缺乏确定边界的标准方法,目前的做法是模拟整个主线到下一个泵站(上游或下游)。本文提出了一种定义最小建模边界的方法。当可用数据有限时,当多个供应商/管道所有者连接到一个终端时,当先进的模拟软件或功能强大的计算机不可用时,或者当目标是避免不必要的,复杂的劳动密集型模拟时,这个边界特别有用。该技术包括确定位于主干线足够远的边界,以便在设施管道或管道最薄弱的管道段发生瞬态事件后,压力波不会干扰压力浪涌的发展。这种简单的方法得到了瞬变水力学领域知名权威机构发表的概念的支持,并通过现有的管道仿真软件进行了测试。在阅读完这篇论文后,读者将能够回答这些问题:•我需要多少数据?•有多少种排列?•该方法的关键信息是什么?•边界在哪里?•是什么导致了错误的选择?总而言之,液压工程师将能够将当前边界缩短到很小的部分:在注射设施的情况下可达1/25,在输送设施的情况下可达2/25。此外,读者将确认,由于阀意外关闭或泵跳闸等瞬态事件(大压力波动最常见的触发因素),超过这些边界的干线水力条件不会对设施的管道产生任何影响。
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