Manifestations of surfactant-polymer flooding for successful field applications in carbonates under harsh conditions: A comprehensive review

2区 工程技术 Q1 Earth and Planetary Sciences
Anas M. Hassan , Emad W. Al-Shalabi , Waleed Alameri , Muhammad Shahzad Kamal , Shirish Patil , Syed Muhammad Shakil Hussain
{"title":"Manifestations of surfactant-polymer flooding for successful field applications in carbonates under harsh conditions: A comprehensive review","authors":"Anas M. Hassan ,&nbsp;Emad W. Al-Shalabi ,&nbsp;Waleed Alameri ,&nbsp;Muhammad Shahzad Kamal ,&nbsp;Shirish Patil ,&nbsp;Syed Muhammad Shakil Hussain","doi":"10.1016/j.petrol.2022.111243","DOIUrl":null,"url":null,"abstract":"<div><p><span>Most oil fields today are mature, and the majority of the reservoirs in the Middle East are carbonate rocks<span> characterized by high temperature high salinity<span> (HTHS), heterogeneous mineral composition, and natural fractures<span>. Enhanced oil recovery (EOR) methods are used for boosting oil recovery from the aged reservoirs beyond primary and secondary recovery stages. Nevertheless, it can be a challenging task to employ EOR techniques in these aged </span></span></span></span>carbonate reservoirs<span>. This is because carbonate reservoirs have mixed-to-oil-wet wettability<span> with temperatures exceeding 85 °C and salinity of over 100,000 ppm, which renders secondary EOR-methods such as waterflooding ineffective. Therefore, even though carbonate reservoirs contain 60–65% of world's remaining oil, with immense intrinsic economic prospects, the oil recovery process from carbonate reservoirs remains a considerable challenge. Chemical-EOR (cEOR) techniques, like SP based cEOR, have shown marked promise in improved oil recovery, mainly from clastic reservoirs with medium temperature and salinity, unlike carbonate reservoirs. During SP-floodings, the surfactants get adsorbed due to the mineral composition of the carbonate rocks, and polymer degradation<span> occurs due to HTHS conditions. Consequently, new surfactants and polymers have been structurally conformed and tested to improve their robustness and related recovery efficacy. For instance, Guerbet alkoxy-carboxylate surfactants demonstrated good stability at temperatures over 100 °C and salinities up-to 275,000 ppm, yielding tertiary recovery of 94.5% and low adsorption of 0.086 mg/g of rock. The cationic Gemini surfactants, zwitterionic or amphoteric class of surfactants are also suitable for HTHS carbonates. Besides, effective biosurfactants sourced from plant such as, soy, corn, etc., are non-toxic and readily biodegradable. The hydrophobically associating polyacrylamide (HAPAM) and its modified nanocomposite<span> derivative can act as replacement surfactants, due to their wettability altering and robust characteristics. Novel polymers viz., NVP-based, novel smart thermoviscosifying polymers (TVP), soft microgel<span><span>, and sulfonated polymers, are also relevant to HTHS carbonate applications. Xanthan gum, scleroglucan, and schizophyllan </span>biopolymers have been noted to resist HTHS and low permeability conditions, requiring lower concentration and having low adsorption. Recent surfactant-polymer (SP) formulations also can be applicable for HTHS carbonates with excellent ternary recoveries (93.6%) and minimal retention (0.083 μg/g of rock). Such low retention values suggest low surfactants cost with minimal environmental impact. Moreover, several successful field applications in carbonates were conducted in preceding years; however, the performance of some novel surfactants under HTHS carbonates is yet to be fully understood. Hence, this comprehensive review aims to provide renewed perspectives on surfactant and polymer optimizations for field applications in HTHS carbonates. A list of recommendations is presented as guidelines for efficient SP-flooding designs. This critical literature appraisal furnishes an array of potential manifestations for successful field application of SP-flooding in HTHS carbonates, which holds both economic and environmental feasibility.</span></span></span></span></span></p></div>","PeriodicalId":16717,"journal":{"name":"Journal of Petroleum Science and Engineering","volume":"220 ","pages":"Article 111243"},"PeriodicalIF":0.0000,"publicationDate":"2023-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"14","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Journal of Petroleum Science and Engineering","FirstCategoryId":"5","ListUrlMain":"https://www.sciencedirect.com/science/article/pii/S0920410522010956","RegionNum":2,"RegionCategory":"工程技术","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"Earth and Planetary Sciences","Score":null,"Total":0}
引用次数: 14

Abstract

Most oil fields today are mature, and the majority of the reservoirs in the Middle East are carbonate rocks characterized by high temperature high salinity (HTHS), heterogeneous mineral composition, and natural fractures. Enhanced oil recovery (EOR) methods are used for boosting oil recovery from the aged reservoirs beyond primary and secondary recovery stages. Nevertheless, it can be a challenging task to employ EOR techniques in these aged carbonate reservoirs. This is because carbonate reservoirs have mixed-to-oil-wet wettability with temperatures exceeding 85 °C and salinity of over 100,000 ppm, which renders secondary EOR-methods such as waterflooding ineffective. Therefore, even though carbonate reservoirs contain 60–65% of world's remaining oil, with immense intrinsic economic prospects, the oil recovery process from carbonate reservoirs remains a considerable challenge. Chemical-EOR (cEOR) techniques, like SP based cEOR, have shown marked promise in improved oil recovery, mainly from clastic reservoirs with medium temperature and salinity, unlike carbonate reservoirs. During SP-floodings, the surfactants get adsorbed due to the mineral composition of the carbonate rocks, and polymer degradation occurs due to HTHS conditions. Consequently, new surfactants and polymers have been structurally conformed and tested to improve their robustness and related recovery efficacy. For instance, Guerbet alkoxy-carboxylate surfactants demonstrated good stability at temperatures over 100 °C and salinities up-to 275,000 ppm, yielding tertiary recovery of 94.5% and low adsorption of 0.086 mg/g of rock. The cationic Gemini surfactants, zwitterionic or amphoteric class of surfactants are also suitable for HTHS carbonates. Besides, effective biosurfactants sourced from plant such as, soy, corn, etc., are non-toxic and readily biodegradable. The hydrophobically associating polyacrylamide (HAPAM) and its modified nanocomposite derivative can act as replacement surfactants, due to their wettability altering and robust characteristics. Novel polymers viz., NVP-based, novel smart thermoviscosifying polymers (TVP), soft microgel, and sulfonated polymers, are also relevant to HTHS carbonate applications. Xanthan gum, scleroglucan, and schizophyllan biopolymers have been noted to resist HTHS and low permeability conditions, requiring lower concentration and having low adsorption. Recent surfactant-polymer (SP) formulations also can be applicable for HTHS carbonates with excellent ternary recoveries (93.6%) and minimal retention (0.083 μg/g of rock). Such low retention values suggest low surfactants cost with minimal environmental impact. Moreover, several successful field applications in carbonates were conducted in preceding years; however, the performance of some novel surfactants under HTHS carbonates is yet to be fully understood. Hence, this comprehensive review aims to provide renewed perspectives on surfactant and polymer optimizations for field applications in HTHS carbonates. A list of recommendations is presented as guidelines for efficient SP-flooding designs. This critical literature appraisal furnishes an array of potential manifestations for successful field application of SP-flooding in HTHS carbonates, which holds both economic and environmental feasibility.

Abstract Image

表面活性剂聚合物驱在恶劣条件下成功应用于碳酸盐岩的表现:综述
今天的大多数油田都已成熟,中东的大多数储层都是碳酸盐岩,其特征是高温高盐度(HTHS)、不均匀矿物成分和天然裂缝。提高石油采收率(EOR)方法用于提高老化储层的石油采收率,使其超过初级和次级采收阶段。然而,在这些老化的碳酸盐岩储层中采用EOR技术可能是一项具有挑战性的任务。这是因为碳酸盐岩储层在温度超过85°C和盐度超过100000 ppm的情况下混合到了油湿润湿性,这使得二次提高采收率方法(如注水)无效。因此,尽管碳酸盐岩油藏含有世界剩余石油的60-65%,具有巨大的内在经济前景,但碳酸盐岩油藏的采油过程仍然是一个相当大的挑战。化学EOR(cEOR)技术,如基于SP的cEOR,在提高石油采收率方面显示出显著的前景,主要来自中等温度和盐度的碎屑岩储层,而不是碳酸盐岩储层。在SP驱油过程中,表面活性剂由于碳酸盐岩的矿物成分而被吸附,聚合物由于HTHS条件而发生降解。因此,新的表面活性剂和聚合物已经在结构上进行了鉴定和测试,以提高它们的稳健性和相关的回收效率。例如,Guerbet烷氧基羧酸盐表面活性剂在超过100°C的温度和高达275000 ppm的盐度下表现出良好的稳定性,产生94.5%的三次回收率和0.086 mg/g岩石的低吸附率。阳离子Gemini表面活性剂、两性或两性表面活性剂也适用于HTHS碳酸盐。此外,有效的生物表面活性剂来源于植物,如大豆、玉米等,无毒且易于生物降解。疏水缔合聚丙烯酰胺(HAPAM)及其改性的纳米复合衍生物由于其润湿性的改变和坚固的特性,可以作为替代表面活性剂。新型聚合物,即基于NVP的新型智能热增粘聚合物(TVP)、软微凝胶和磺化聚合物,也与HTHS碳酸盐应用有关。黄原胶、硬葡聚糖和裂叶兰生物聚合物已被注意到能够抵抗HTHS和低渗透性条件,需要较低的浓度和较低的吸附性。最近的表面活性剂聚合物(SP)配方也适用于HTHS碳酸盐,具有优异的三元回收率(93.6%)和最小的保留率(0.083μg/g岩石)。这种低保留值表明表面活性剂成本低,对环境的影响最小。此外,在过去几年中,在碳酸盐岩中进行了几次成功的现场应用;然而,一些新型表面活性剂在HTHS碳酸盐下的性能尚待充分了解。因此,这篇全面的综述旨在为表面活性剂和聚合物优化在HTHS碳酸盐领域的应用提供新的视角。建议清单作为高效SP注水设计的指南。这一关键文献评估为高温高压碳酸盐岩SP驱的成功现场应用提供了一系列潜在的表现形式,具有经济和环境可行性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
求助全文
约1分钟内获得全文 求助全文
来源期刊
Journal of Petroleum Science and Engineering
Journal of Petroleum Science and Engineering 工程技术-地球科学综合
CiteScore
11.30
自引率
0.00%
发文量
1511
审稿时长
13.5 months
期刊介绍: The objective of the Journal of Petroleum Science and Engineering is to bridge the gap between the engineering, the geology and the science of petroleum and natural gas by publishing explicitly written articles intelligible to scientists and engineers working in any field of petroleum engineering, natural gas engineering and petroleum (natural gas) geology. An attempt is made in all issues to balance the subject matter and to appeal to a broad readership. The Journal of Petroleum Science and Engineering covers the fields of petroleum (and natural gas) exploration, production and flow in its broadest possible sense. Topics include: origin and accumulation of petroleum and natural gas; petroleum geochemistry; reservoir engineering; reservoir simulation; rock mechanics; petrophysics; pore-level phenomena; well logging, testing and evaluation; mathematical modelling; enhanced oil and gas recovery; petroleum geology; compaction/diagenesis; petroleum economics; drilling and drilling fluids; thermodynamics and phase behavior; fluid mechanics; multi-phase flow in porous media; production engineering; formation evaluation; exploration methods; CO2 Sequestration in geological formations/sub-surface; management and development of unconventional resources such as heavy oil and bitumen, tight oil and liquid rich shales.
×
引用
GB/T 7714-2015
复制
MLA
复制
APA
复制
导出至
BibTeX EndNote RefMan NoteFirst NoteExpress
×
提示
您的信息不完整,为了账户安全,请先补充。
现在去补充
×
提示
您因"违规操作"
具体请查看互助需知
我知道了
×
提示
确定
请完成安全验证×
copy
已复制链接
快去分享给好友吧!
我知道了
右上角分享
点击右上角分享
0
联系我们:info@booksci.cn Book学术提供免费学术资源搜索服务,方便国内外学者检索中英文文献。致力于提供最便捷和优质的服务体验。 Copyright © 2023 布克学术 All rights reserved.
京ICP备2023020795号-1
ghs 京公网安备 11010802042870号
Book学术文献互助
Book学术文献互助群
群 号:481959085
Book学术官方微信