Experimental Investigation of Hydrocarbon Gas Huff-N-Puff Injection into the Live-Oil Window of Eagle Ford

J. Tsau, Qinwen Fu, R. Barati, J. Zaghloul, A. Baldwin, K. Bradford, B. Nicoud, J. D. Mohrbacher
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引用次数: 1

Abstract

The hydrocarbon gas huff and puff (HnP) technique has been used to improve oil production in unconventional oil reservoirs where excess capacity of produced gas is available and hydrocarbon prices are in a range to result in an economically viable case. Eagle Ford (EF) is one of the largest unconventional oil plays in the United State where HnP has been applied for enhanced oil recovery (EOR) at reservoirs within various oil windows. Our previously published Huff-n-puff results on dead oil with produced gas from Eagle Ford (EF) showed the recovery factor of hydrocarbon varying from 40 to 58%. The objective of this paper is to extend the experiments to live oil with EF core plugs to investigate the mechanisms of HnP which are affected by the composition of injected gas and resident oil, injection and soaking time as well as injection/depletion pressure gradient. Eagle Ford live oil and natural gas produced from the target area were used for HnP tests. Four representative core plugs were used with the tests conducted at reservoir conditions (125 °C and 3,500 psi). The live oil experiments with four reservoir core plugs showed an improvement in oil recovery with recovery factor (RF) varying from 19.5 to 33 % in six cycles of HnP, whereas the primary depletion on the same core plug showed RF below 11 %. A lower recovery factor of HnP from live oil saturated core in this study was observed as compared to dead oil saturated core reported in a previous publication. It is attributed to a lesser diffusion effect on mass transfer between injected gas and resident oil when the core is saturated with live oil. This behavior is displayed by the pressure decline curve during the first soaking period. A sharper diffusion pressure decline occurred in the dead oil saturated core plug where a higher concentration gradient between injected gas and resident oil drives a faster gas transport into the oil due to the molecular diffusion during the soaking period.
Eagle Ford油田活油窗烃类气吞吐注气实验研究
烃类气吞吐(HnP)技术已被用于提高非常规油藏的产量,这些油藏的产出气产能过剩,且烃类价格在经济上可行的范围内。Eagle Ford (EF)是美国最大的非常规油区之一,HnP已应用于不同油窗的储层提高采收率(EOR)。我们之前发表的针对Eagle Ford (EF)采出气的死油的huffn -puff结果显示,油气的采收率从40%到58%不等。本文的目的是将实验扩展到使用EF岩心塞的活油,以研究注入气和常住油的组成、注入和浸泡时间以及注入/耗尽压力梯度对HnP的影响机制。从目标区域产出的Eagle Ford活油和天然气用于HnP测试。在油藏条件下(125°C和3500 psi),使用了四个具有代表性的岩心桥塞进行了测试。4个储层岩心桥塞的油井实验表明,在6个HnP循环中,采收率提高,采收率系数(RF)从19.5%到33%不等,而同一岩心桥塞的初始枯竭显示RF低于11%。与之前发表的报告相比,本研究中从活油饱和岩心中提取的HnP采收率较低。这是由于当岩心被活油饱和时,注入气体和驻留油之间的传质扩散效应较小。这一特性在第一次浸泡期间的压力下降曲线中得到了体现。在死油饱和岩心塞中,由于浸渍期分子扩散作用,注入气和滞留油之间的浓度梯度较高,导致气体运移到油中速度更快,扩散压力下降幅度更大。
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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