ATBS聚合物在Mangala聚合物驱中的应用评价

IF 2.1 4区 工程技术 Q3 ENERGY & FUELS
Vivek Shankar, Robert Zagitov, S. Shekhar, A. Gupta, M. Kumar, Ritesh Kumar, Santhosh Veerbhadrappa, P. Nakutnyy
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引用次数: 0

摘要

Mangala油田自2015年以来一直处于聚合物驱阶段。与注水相比,聚合物驱在加速采收率方面取得了更大的成功。随着注水的成熟,现场表现表明,部分注入的聚合物在储层中降解。实验室研究和从储层收集的聚合物样品表明,降解最可能的原因是热老化导致水解增加。这种降解迫使更高剂量的聚合物来弥补损失的粘度,并增加了操作成本。聚合物在储层中的沉淀也可能导致储层渗透率的降低。文献调查和初步实验室研究表明,具有丙烯酰胺-叔丁基磺酸单体单元的聚合物(称为ATBS聚合物)可能是Mangala的合适选择。为了评估这一假设,研究小组进行了一系列的实验室和岩心研究。这些研究包括加速热老化、流变性、动态吸附、注入性、新鲜和降解样品的水驱以及与上层化学品的相容性研究。对两种不同水解度的聚丙烯酰胺(HPAM)聚合物和两种ATBS聚合物进行了评价。然后测试选定的ATBS聚合物与表层化学物质的相容性。研究表明,经典的20 ~ 25% DOH HPAM在Mangala油藏条件下会发生粘度降解和可能的沉淀。ATBS聚合物和DOH较低的HPAM提供了优于现有HPAM的效果,丙烯酰胺(AM) (86)-ATBS(14)共聚物提供了最佳效果。ATBS聚合物尤其耐云点降低,在剪切降解方面具有一定的优势。在测试期间,ATBS单体具有抗水解性。与已发表的文献相反,ATBS聚合物表现出更高的吸附性,并且它们在岩心中的传播需要更高的压降。ATBS聚合物似乎堵塞了岩心堆的低渗透部分。所有聚合物的粘度在水解30 ~ 40%时达到峰值,水解40%后急剧下降,但在加速老化过程中测量的粘度和浊点可能是保守的。目前正在曼加拉进行大规模注射ATBS试验,以验证实验室测试结果。ATBS聚合物具有较高的停留时间和渗透性,可以作为一种适用于某些层的聚合物。这一选择是由ATBS的增量成本经济驱动的,因为它提供了好处。在一些井间间距较短的砂岩中,较低的DOH HPAM可能是更具成本效益的解决方案。本文的研究结果为作业者了解现有聚合物驱的油藏动态以及规划未来的聚合物驱提供了见解。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Evaluation of ATBS Polymers for Mangala Polymer Flood
Mangala field has been under polymer flood since 2015. The polymer flood has been more successful in accelerating recovery compared to waterflood. As the flood matured, field performance indicated that part of the injected polymer was degrading in the reservoir. Laboratory studies and polymer samples collected from the reservoir suggest that the most likely reason for the degradation is increased hydrolysis due to thermal aging. This degradation compels higher dosing of polymer to make up for the lost viscosity and increases operating costs. Polymer precipitation in the reservoir may also lead to loss of reservoir permeability. Literature surveys and preliminary laboratory studies showed that polymers with acrylamide-tertiary-butyl-sulfonic acid monomer units (referred to as ATBS polymers) could be a suitable option for Mangala. To evaluate the hypothesis, the team did a series of laboratory and coreflood studies. The studies include accelerated thermal ageing, rheology, dynamic adsorption, injectivity, waterflood with fresh and degraded samples, and compatibility studies with topside chemicals. Two hydrolyzed polyacrylamide (HPAM) polymers with different degrees of hydrolysis (DOH) and two ATBS polymers were evaluated. The selected ATBS polymer was then tested for compatibility with surface topside chemicals. The studies show that the classic 20 to 25% DOH HPAM suffers viscosity degradation and possible precipitation in Mangala reservoir conditions. ATBS polymers and a lower DOH HPAM provide superior results to the incumbent HPAM with an acrylamide (AM) (86)-ATBS (14) copolymer providing the best results. ATBS polymers were especially resistant to cloudpoint lowering and provide some superiority in shear degradation. The ATBS monomer was resistant to hydrolysis during the period of testing. Contrary to the published literature, ATBS polymers showed higher adsorption and their propagation through cores required a higher pressure drop. ATBS polymer seemed to plug a low-permeability section of the core stack. All polymers reach their peak viscosity at 30 to 40% hydrolysis and decline sharply after 40%, but viscosity and cloudpoints measured during accelerated aging are possibly conservative. A large-scale pilot of ATBS injection in Mangala is under way to validate the laboratory test results. ATBS polymer can be a suitable polymer for some layers of Mangala with a high residence time and permeability. The choice is driven by the economics of the incremental cost of ATBS for the benefits it offers. In some sands with shorter interwell spacing, a lower DOH HPAM may be a more cost-effective solution. The study results in this paper provide insights to operators to understand the reservoir performance of existing polymer floods and plan for future polymer floods.
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来源期刊
CiteScore
5.30
自引率
0.00%
发文量
68
审稿时长
12 months
期刊介绍: Covers the application of a wide range of topics, including reservoir characterization, geology and geophysics, core analysis, well logging, well testing, reservoir management, enhanced oil recovery, fluid mechanics, performance prediction, reservoir simulation, digital energy, uncertainty/risk assessment, information management, resource and reserve evaluation, portfolio/asset management, project valuation, and petroleum economics.
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