CO2 Injection In Low Pressure Depleted Reservoirs

Fifth CO2 Geological Storage Workshop Pub Date : 2018-11-21 DOI:10.3997/2214-4609.201802976

A. Twerda, S. Belfroid, F. Neele

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引用次数: 2

Abstract

Re-using depleted fields (and platforms and wells) offers advantages over developing storage projects in saline formations. However, with reservoir pressures after production sometimes below 20 bar, there can be a large pressure difference between the reservoir and the transport pipeline at the surface, which will be typically at pressures in the range of 80 - 120 bar. This pressure difference must be carefully managed to ensure that the temperature of the CO2, the surface installations and the well, remain within materials specifications and within proper operating boundaries. Pressure drops of the CO2 result in potentially large decrease in temperature, due to its high Joule-Thomson coefficient; in addition, the temperatures and pressures that occur in a typical CO2 transport and storage system are such that two-phase flow is likely to occur. Pipeline pressure and temperature management can easily be done in a single source- single sink scenario as the pipeline pressure is a free parameter. However, if the pipeline must act as a backbone for multiple wells at different reservoir pressure, pressure and flow management must be balanced carefully. In this paper, the differences between a pipeline as transport and a pipeline as backbone will be discussed in detail.

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低压衰竭油藏的CO2注入

重复利用枯竭油田(以及平台和井)比开发含盐地层的存储项目更具优势。然而，由于生产后的储层压力有时低于20bar，因此地面储层和输送管道之间的压力差可能很大，通常在80 - 120bar之间。必须仔细管理这种压力差，以确保CO2、地面设施和井的温度保持在材料规格和适当的操作范围内。由于CO2具有很高的焦耳-汤姆逊系数，因此CO2的压降可能导致温度的大幅度下降;此外，在典型的二氧化碳运输和储存系统中，温度和压力很可能导致两相流的发生。由于管道压力是一个自由参数，因此可以很容易地在单源-单汇方案中完成管道压力和温度管理。然而，如果管道必须作为不同油藏压力下多口井的主干，则必须仔细平衡压力和流量管理。本文将详细讨论管道作为传输和管道作为主干的区别。

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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Fifth CO2 Geological Storage Workshop

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