Slug Flow Root Cause Analysis: A Data-Driven Approach

Day 1 Tue, October 29, 2019 Pub Date : 2019-10-28 DOI:10.4043/29925-ms

Anders T. Sandnes, Vidar Thune Uglane, B. Grimstad

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Abstract

We present a data-driven root cause analysis of slug flow in a subsea field. The asset experienced severe slugging in a riser, which limited production throughput. The results were used in combination with simulator studies and engineering experience to create a better understanding of the underlying root cause for slugging. A selection of signals was investigated as possible drivers behind slug severity. Focus was put on well-specific signals such as pressures, temperatures and flow rates, in addition to total flow rates, pipeline pressures and temperatures, and settings on the topside facility. Total liquid rate, especially the water component, is isolated as an important driver for slugging, while ruling out other signals believed to be important before the analysis, such as production from individual wells. The results were aligned with the field engineers’ experience. Actions were implemented to reduce water production, and this led to reduced slugging. Close collaboration between data scientists and field engineers was essential to guide the search towards actionable evidence. The novelty of this approach lies in utilizing machine learning techniques to model and analyze historical production data in order to find drivers behind events such as slug flow. This makes it easier for field engineers to leverage all available information to optimize production.

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段塞流的根本原因分析:数据驱动的方法

我们提出了一个数据驱动的水下油田段塞流根本原因分析。该资产的隔水管出现了严重的段塞流，限制了生产能力。该结果与模拟器研究和工程经验相结合，以更好地了解段塞流的根本原因。研究人员选择了一些信号作为段塞严重程度的可能驱动因素。除了总流量、管道压力和温度以及上层设施的设置外，还将重点放在特定井的信号上，如压力、温度和流量。总液率，特别是水成分，被认为是段塞流的重要驱动因素，同时排除了分析前认为重要的其他信号，如单井的产量。结果与现场工程师的经验一致。采取措施减少产水，减少了段塞流。数据科学家和现场工程师之间的密切合作对于指导寻找可操作的证据至关重要。该方法的新颖之处在于利用机器学习技术对历史生产数据进行建模和分析，以找到段塞流等事件背后的驱动因素。这使得现场工程师更容易利用所有可用信息来优化生产。

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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Day 1 Tue, October 29, 2019

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