提高低渗透碳酸盐岩油藏采收率的聚合物驱新技术——从实验室研究到先导试验——阿曼案例研究

Xingcai Wu, Yongli Wang, A. Naabi, Hanbing Xu, Ibrahim S. Al Sinani, K. Busaidi, S. A. Jabri, S. Dhahab, Jianli Zhang, C. Xiong, Ye Yinzhu, X. Tian, Xu Jia, Jing Lv
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引用次数: 2

摘要

该油田位于阿曼北部,大部分油田都有致密的碳酸盐岩油藏。最初,该油田在自然枯竭状态下生产了近15年,直到2005年,水平井线驱水驱开发开始,并在整个油田进行了部署。经过10多年的注水,主要生产区块的含水率平均达到75%。储层为粘度为0.8 mPa的轻质油。s,井下温度为87℃,平均渗透率为10 mD。地层水中钙镁浓度高,约为4000 mg/L。致密碳酸盐岩储层的非均质性导致水驱波及效果不均匀,导致大量的漏失油。由于储层渗透率低,注入能力面临挑战,在研究现场筛选的最初EOR方法不推荐使用常规聚合物驱。然而,最近市场上开发了一种独特的纳米聚合物,有望成为这种致密储层的提高采收率方法。利用所研究油藏的岩心和流体样品进行的大量实验室实验以及随后的数值模拟建模工作证明了这种新聚合物在技术上的可行性。随后在一个成熟的注水区进行了现场试验,目前正在监测其性能。这种新型聚合物是颗粒型的,具有不同的纳米-微米尺寸。该聚合物的表观粘度较低,为1 ~ 4 mPa,与注入水中混合后,颗粒分散在水中,形成的混合物粘度较低,易于注入。此外,这种纳米聚合物对温度和盐度都有很高的耐受性。当颗粒进入地层时,它们会暂时堵塞现有的优先水通道,并将注入的水转移到相对较小的孔隙/喉道中,并取代剩余的旁路油。聚合物颗粒具有很高的变形能力,因此它可以在一定的压力下变形并通过喉部,堵塞地层的更深部分。这个过程是连续重复的,这样可以抑制出水,提高产油量。在实验室实验中,从伴生油藏中采集了12个岩心桥塞,在此基础上进行了岩心薄片分析、纳米聚合物注入能力测试以及单桥塞和平行双桥塞岩心驱油实验。随后,利用实验室结果进行数值模拟,然后进行经济评估。在实验室测试结果的基础上,研究人员建立了一个概念模拟模型,用于估算不同孔隙体积(PV)注入下的产油量增量。从0.05PV到0.5 PV,测量了不同SMG PV注入时的产油量增量。结果表明,最佳的经济情景为光伏注入0.3,可在~4年的时间内实现。然而,为了加快现场试验阶段并降低成本,我们选择了最低的PV注入,即在0.05 PV的情况下,仅在两个注水井中注入一年。到目前为止,现场试验已经成功地完成了纳米聚合物总计划体积(0.05 PV)的注入阶段。连续注入一年,没有出现注入能力问题,目前正在监测生产情况。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A New Polymer Flooding Technology for Improving Low Permeability Carbonate Reservoir Recovery--From Lab Study to Pilot Test--Case Study from Oman
The field under study is located in the northern part of Oman where most of the fields have a tight carbonate oil reservoirs. Initially the field was produced under natural depletion for almost 15 years until 2005 when a line drive water flood development with horizontal wells took place and was deployed in the whole field. After more than 10 years of water injection, the water cut reached an average of 75% in the major producing blocks. The reservoir has a light oil with viscosity of 0.8 mPa.s, a downhole temperature of 87°C and average permeability of 10 mD. The calcium and magnesium concentration in formation water is high, about 4000 mg/L. Reservoir heterogeneity in tight carbonate reservoirs causes uneven water flood sweep efficiency and hence resulted in a lot of bypassed oil. The initial EOR methods screening in the field under study didn't recommend to use the conventional polymer flooding due to low reservoir permeability and hence injectivity challenge. However, a new unique nano-ploymer was recently developed in the market to be a potential EOR method for such tight formation reservoirs. Extensive laboratory experiments using the core and fluid samples from the studied reservoir followed by numerical simulation modeling work proved the technical feasibility for this new polymer. This was then followed by field testing pilot in one of the matured water flood sector and the performance is currently under monitoring. The new polymer is a particle-type and comes with various nanometer-micrometer sizes. This polymer has a low apparent viscosity of 1-4 mPa and when it is mixed with the injection water, the particles disperse in the water and the resultant mixture has a low viscosity making it easily to be injected. In addition, this nano-polymer has a high tolerance for both temperature and salinity. While the particles move into formation, they temporarily plug the preferential existing water paths and divert the injection water into the relatively small pores/throats and displace the remaining bypassed oil. The polymer particle has high deformation capacity, so it can deform and pass through the throat under certain pressure to plug even deeper parts of the formation. The process is repeated continuously so that it can inhibit water production and enhance oil production. For the lab experiments, 12 core plugs from the associated reservoir were collected, based on which, a series of experiments were conducted including: core thin section analysis, injectivity test for the nano-polymer and core flooding experiments on single plug and parallel double plugs. Subsequently, the lab results were utilized for numerical simulation and that was followed by economic evaluation. Based on the lab test results, a conceptual simulation model for the studiedfield's sector was used to estimate the incremental oil gain at different pore volume (PV) injection. The incremental oil gain was determined at different SMG PV injection starting from 0.05PV to 0.5 PV. The results showed that the best economic scenario is to go for PV injection of 0.3 which can be achieved in ~4 years'time. However, in order to expedite the field trail stage and reduce its cost, the lowest PV injection was selected which involves injection in two water injectors for one year only at 0.05 PV. The field pilot thus far has successfully completed the injection phase of the total planned volume (0.05 PV) of nano-ploymer. The injection was continuous for one year with no injectivity issue and the production performance is currently under monitoring.
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