西西伯利亚成熟油田多作用水驱优化技术

S. Matveev, A. Gazizov, E. Shastina, S. Ishkinov, M. Kuznetsov
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摘要

在采用水驱技术开发的成熟油田中,由于储层渗透率不均匀和驱替前缘推进不均匀,油公司一直在努力防止生产井过早进水。压力梯度和流量的变化,以及吸附、渗透和毛细力的增加,导致低渗透层段的油渗透率显著降低,产量降低。化学技术的发展是为了将选择性堵水和岩石性质从水湿变为油湿或相反的变化结合起来,在岩石表面形成一个新的相,产生大量的多余能量,用于回收剩余油。通过研究所使用的药剂与储层流体的相容性,以及在三种非均质储层模型上进行的流动试验,在储层建模实验室验证了该技术的有效性。测试表明,该技术中使用的药剂在高达120°C的高温和地层水盐度为10-127 g/l的条件下仍能保持其功能,对油品没有不利影响。在实验室研究了储层条件下将油水界面张力降低至0.005 mN/m的超细试剂。地质和生产数据表明,试验区的主要问题是,由于注入水的突破,生产井早期被注入水侵蚀,随后有害的流动穿过最渗透性和衰竭层。在注入井中进行的示踪剂研究中,示踪剂通过冲洗通道进入高产量和高含水率的井,确定了无效注入区域。在油田的4个试验区采用多作用技术进行的处理产生了以下效果:通过增加高渗透层的剩余阻力系数,重新分配注入水流,并将水流重新定向到以前不活跃的储层。在10个月内,四个地区的石油产量增加了2745吨,并产生了持久的影响。多作用技术的新颖之处在于,通过选择性隔离水侵层,对油藏进行针对性处理,并驱替剩余油。在相界面产生的能量用于分离膜结合油,使球形油通过孔喉,提高储层的油流量和油渗透率,而不考虑其地质和矿物学特征或地层流体性质。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Waterflooding Optimisation Using a Multi-Action Technology in the Mature West Siberian Oil Field
In mature fields developed by water flooding, oil companies keep trying to fight premature water encroachment in producing wells caused by heterogeneous reservoir permeability and non-uniform displacement front advance. Changes in pressure gradients and flow rates and increased effects of adsorptive, osmotic and capillary forces result in significantly reduced oil permeability and low production from low-permeability intervals. The chemical technology has been developed for the combined effect of selective water shut-off and change of rock properties from water wet to oil wet or visa versa to form a new phase on the rock surface, which produces significant excess energy used to recover residual oil. The effectiveness of this technology has been tested in a reservoir modelling laboratory by studying the compatibility between the agents employed and reservoir fluids and flow tests conducted on three areal heterogeneous reservoir models. Tests have shown that the agents used in the technology retain their functionality at high temperatures of up to 120°C and a formation water salinity of 10–127 g/l with no adverse effect on oil quality. The ultra-fine reagent reducing interfacial tension at the oil-water interface under reservoir conditions to 0.005 mN/m was studied in the laboratory. Geological and production data show that the main problem of the pilot areas is early encroachment of production wells by injected water because of its breakthrough and subsequent unwanted flow through the most permeable and depleted layers. Tracer studies, conducted in injection wells using tracers that moved through flushed channels towards wells with high production rates and high-water cuts, identified zones of ineffective injection. Treatments using multi-action technology in four pilot areas of the field produced the following effects: Redistribution of injected water flows by increasing the residual resistance factor in high-permeability zones and redirection of flows into previously inactive reservoir zones.Incremental oil production from four areas over 10 months was 2745 tonnes with a lasting effect. The novelty of the multi-action technology consists in targeted treatment of oil reservoirs and displacement of residual oil through selective isolation of water-encroached zones. The energy produced at the phase interface is used to separate film-bound oil, move globular oil through pore throats and increase oil flow rate and oil permeability in the reservoir irrespective of its geological and mineralogical characteristics or formation fluid properties.
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