低矿化度水驱在海上的应用及其潜在机遇

Quan Chen, S. Ayirala, A. Yousef
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引用次数: 5

摘要

低矿化度水驱(LSWF)是一种新兴的提高石油采收率(EOR)技术,具有巨大的海上应用潜力。为了评估LSWF的EOR效益,了解潜在的采收率机制,已经进行了大量的实验室实验和现场试验。本研究的目的是对LSWF海上油田的应用进行评述,并总结吸取的关键经验教训。还对海上油田现有的用于海水注入的硫酸盐去除装置的能力进行了审查。此外,针对海上油田进行脱硫海水注入的潜力,无论是正在进行的还是计划中的,都已被研究作为转向LSWF EOR的主要候选。对于LSWF现场试验,如果基于关键的实验室筛选测试(如油藏条件下的岩心注水),则成功的几率可以显著提高。LSWF海上油田试验采用的方法主要包括单井化学示踪测试(SWCTT)和井间油田试验。然而,到目前为止,进行的井间试验仅限于无限制的试验,这使得生产和注入分配更加困难。因此,在将来进行LSWF现场试验时,建议采用密闭先导装置,以更好地估计波及体积并提高驱油效率。在全球范围内,目前有80多个硫酸盐去除装置正在运行,用于北海、墨西哥湾、西非和巴西的海上海水驱,累计脱硫海水注入(DSSW)能力约为1000万BWPD。所有这些正在或计划注入DSSW的油田都可能成为转向LSWF EOR的潜在候选油田,原因如下:(1)从海水中去除硫酸盐的主要目的是防止由于地层水中通常含有高浓度的二价阳离子和海水中高浓度的硫酸盐而结垢。二价阳离子可以在带负电荷的岩石表面和带负电荷的极性油组分之间起桥梁作用,增加油湿倾向。为了提高采收率,低盐度水中的非络合阳离子取代了这些桥接物。(2)如果这些水库符合筛选标准,且LSWF评价结果积极,则可以通过反渗透膜取代现有的硫酸盐去除设施纳滤膜,并对设施进行升级,以增加水处理能力并产生所需的低盐度水,从而轻松地将脱硫酸盐海水注入工艺转换为LSWF。这种对海上平台海水处理设施的改造可以以最小的额外投资带来显著的收益,提高石油采收率。该研究的新颖之处在于,它为储层筛选和海上油田实施LSWF提供了一些有用的实用指南。此外,已经确定了利用现有的脱硫海水注入来评估海上油田转向LSWF的新潜力。这些发现将对提高LSWF在不同海上油田提高采收率的前景和机会产生潜在影响。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A Critical Review of Low Salinity Water Flooding for Offshore Applications and Potential Opportunities
Low salinity water flooding (LSWF) is an emerging enhanced oil recovery (EOR) technology with enormous potential for offshore applications. Numerous laboratory experiments and field trials of LSWF have been conducted to evaluate the EOR benefits and understand the underlying recovery mechanisms. The objective of this study is to provide a critical review on LSWF offshore field applications and summarize the key lessons learned. A review was also conducted on the capabilities of existing sulfate removal units for seawater injection in offshore fields. Furthermore, the potential of targeting offshore oil fields with de-sulfated seawater injection, either ongoing or planned, as primary candidates to switch over to LSWF EOR has been investigated. For LSWF field trials, the chance of success can be significantly improved when it is based on key laboratory screening tests such as corefloods at reservoir conditions. The methodologies implemented for LSWF offshore field trials mainly involved Single Well Chemical Tracer Test (SWCTT) and inter-well field trials. However, the inter-well field trials implemented so far are restricted to unconfined pilots, which makes the production and injection allocation more difficult. Therefore, confined pilots are recommended for future consideration of LSWF field trials to provide better estimations on swept volume and improvements in the oil displacement efficiency. Globally, there are more than 80 sulfate removal units currently in operation for offshore seawater flooding with approximately 10 million BWPD of cumulative de-sulfated seawater injection (DSSW) capacity for offshore water floods in the North Sea, the Gulf of Mexico, West Africa, and Brazil. All these fields with DSSW injection either ongoing or planned can become potential candidates to switch to LSWF EOR for the following two reasons: (1) The primary purpose for sulfate removal from sea water is to prevent scaling due to often high concentration of divalent cations in formation water and high sulfate concentration in seawater. The divalent cations can act as bridges between negatively charged rock surfaces and negatively charged polar oil components to increase the oil-wet tendency. These bridges become primary targets to be replaced by un-complexed cations in low salinity water for EOR. (2) The de-sulfated sea water injection process can easily be switched to LSWF by replacing the existing nanofiltration membranes in the sulfate removal facilities with reverse osmosis membranes and upgrading the facilities to increase the water treatment capacity and generate the desired low salinity water if these reservoirs fit the screening criteria and have a positive outcome of LSWF evaluation. Such retrofitting to the seawater treatment facilities on offshore platforms can bring significant gains to increase oil recovery with minimal additional investment. The novelty of this study is that it provides some useful practical guidelines for reservoir screening and offshore field implementation of LSWF. Also, the new potential of evaluating the offshore oil fields with existing de-sulfated seawater injection for switching over to LSWF has been identified. These findings will have a potential impact on increasing the prospects and opportunities of LSWF for EOR in different offshore fields.
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