中深层稠油油藏注超临界CO2吞吐开发室内实验研究

摘要/Abstract

摘要： 随着中国油气资源的勘探开发,稠油油藏在中国油藏开发中占比超20%,稠油资源的高效开发对中国能源安全具有重要意义。注CO₂开发技术是被证实了的有效提高稠油采收率的效益开发措施。研究区块中深层稠油油藏面临储层强水敏、规模注水开发难度大的难题,亟须转变现有注水开发模式。针对研究区块注CO₂作用机理尚不明确、吞吐开发参数尚待优化、缺少实验研究成果支撑的问题,以新疆油田北10井区中深层稠油油藏为研究对象,开展CO₂在原油中的扩散、稠油超临界CO₂萃取和高温高压长岩心吞吐实验研究,探究稠油油藏注CO₂作用机理以及高效CO₂吞吐开发机制。实验结果表明：①CO₂在稠油中的扩散系数与注气温度、压力呈正相关关系且压力对于扩散系数的影响大于温度;②随萃取次数的增加,中-轻质组分C₆—C₁₂质量分数大幅降低,中-重质组分C₁₄₊质量分数逐渐上升,尤其在前三轮萃取尤为显著;③针对稠油油藏,衰竭方式开发采收率仅有7.01%,CO₂吞吐开发方式是有效的提高稠油采收率的方式,使累计采收率达到36.94%,换油率达到0.59 t/t（每注入1t CO₂获得的产油量）;④通过吞吐实验研究,优选焖井时间为1.0~2.0 h,优选压降速度为50 kPa/min。研究成果有助于明确中深层稠油注CO₂提高采收率机理,同时指导北10井区现场注CO₂开发注采参数设计,为后续CO₂吞吐规模化推广应用提供了参考依据,也为同类型油藏注CO₂开发提供了借鉴。

关键词: 中深层稠油油藏, CO₂吞吐, 扩散, 萃取, 注采参数优化

Abstract: With the exploration and development of oil and gas resources in China, heavy oil reservoirs account for more than 20% of the total reservoir development. The efficient exploitation of heavy oil resources is of significant importance to China's energy security. CO₂ injection technology has been proven as an effective method to enhance the recovery efficiency of heavy oil. Because of the extremely strong water sensitivity of the reservoir, large-scale water flooding of mid-deep heavy oil reservoirs is challenging, necessitating a shift in the development approach. The mechanism of CO₂ injection for mid-deep heavy oil reservoirs remains unclear, the injection/production parameters are not clearly determined, and there is a lack of experimental research to support these findings.. In this study, the mid-deep heavy oil reservoir in the Bei 10 well area of Xinjiang Oilfield was selected as the research object. The diffusion coefficient of CO₂ in the crude oil, the extraction mechanism by supercritical CO₂, and the high-temperature high-pressure long core huff-n-puff experiments were implemented to investigate the mechanisms of CO₂ injection in heavy oil reservoirs and the efficient CO₂ huff-and-puff development mechanisms.. The experimental results indicate that：1) The diffusion coefficient of CO₂ in heavy oil increases with temperature and pressure, with pressure having a greater influence on the diffusion coefficient than temperature. 2) With the increase of the number of extractions, especially in the first three rounds of extraction, the content of light components (C₆ to C₁₂) decreases significantly,while the content of heavy middle-components (C₁₄₊) gradually increases. It was also observed that CO₂ has a greater impact on the extraction of saturated heavy oil than the dead oil. 3) For heavy oil reservoirs, the recovery factor under depletion development is only 7.01%, whereas CO₂ huff-and-puff development significantly enhances the recovery factor, achieving a cumulative recovery factor of 36.94% and an oil exchange rate of 0.59 t/t（Oil production per ton of CO₂ injected）. 4) Via comprehensive comparative analysis, the optimal soak time is found to be 1-2 hours, and the optimal pressure depletion rate is 50 kPa/min. The findings of this study contribute to clarifying the mechanism of CO₂ injection for mid-deep heavy oil recovery, while providing guidance for the optimization of on-site CO₂ soak time and depletion development pressure drop rate in the Bei 10 block. This study also serves as a reference for the subsequent large-scale application of CO₂ huff-n-puff process, as well as insights for CO₂ injection development in similar reservoirs.

Key words: Mid-deep heavy oil reservoir, CO₂ huff-n-puff, CO₂ diffusion, CO₂ extraction, Operation parameters

中图分类号:

TE345

四郎洛加,周翔,孙新革, 等. 中深层稠油油藏注超临界CO₂吞吐开发室内实验研究[J]. 油气藏评价与开发, 0, (): 0-.

SI Langluojia,ZHOU Xiang,SUN Xinge, et al. Experimental Study on Supercritical CO₂ Huff-n-Puff Process Applied in Mid-deep Heavy Oil Reservoirs[J]. Petroleum Reservoir Evaluation and Development, 0, (): 0-.

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中深层稠油油藏注超临界CO₂吞吐开发室内实验研究

Experimental Study on Supercritical CO₂ Huff-n-Puff Process Applied in Mid-deep Heavy Oil Reservoirs

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