有底水稠油油藏足跟注气过程的现场性能及数值模拟研究

2区 工程技术 Q1 Earth and Planetary Sciences Journal of Petroleum Science and Engineering Pub Date : 2023-01-01 DOI:10.1016/j.petrol.2022.111202
Hossein Anbari , John P. Robinson , Malcolm Greaves , Sean P. Rigby
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引用次数: 4

摘要

超稠油和沥青(EHOB)占地球上剩余可开采化石燃料资源的30%。这意味着到2050年,EHOB可以在向净零排放(NZE)的安全过渡中发挥重要作用。技术发展,如足跟空气喷射(THAI),已被证明可以有效地回收重油,并减少环境足迹。Kerrobert项目是第一个在水库存在底层水(BW)的情况下使用THAI技术的项目。与BW情况下的传统ISC操作相比,该项目表现出良好的性能(平均每口井的石油流量为10 m3/天)。从Kerrobert操作经验中吸取的经验教训可以明确地帮助即将在BW存在的情况下进行的THAI操作。本工作分析了性能最好的THAI先导井对之一(K2)的动态现场数据。已经发现K2导频一定经历了来自K5的干扰,K5是与K2最近的相邻THAI井对。先前开发的THAI模型尚未根据实际现场数据进行验证。在BW存在的情况下,构建了一个新的现场规模THAI模型,并首次根据Kerrobert项目的现场数据进行了验证。此外,还研究了用于K2先导的准交错线驱动井布置。对日产油率和累计产油率进行了很好的预测(与现场数据的最终一致性在3%以内)。然后使用历史匹配模型研究了在BW存在的情况下,空气喷射速率的变化对THAI性能的影响。对燃烧前沿传播过程中的主要发展区进行了数值研究。研究表明,从相邻THAI井对进入的额外空气导致整个过程中氧气利用率降低。结果,模拟温度曲线随着燃烧时间的增加而下降。采用新的历史拟合模型对水平生产井周围的氧气剖面进行了研究。在焦炭浓度和HP井周围的氧气分布之间检测到反比关系。研究发现,燃烧前沿之前的蒸汽区的大小随着空气喷射率的变化而不同。据观察,一些调动的石油沉入BW,留下大量石油滞留在储层中。为了防止此类事件发生,HP井的位置被更改为优化THAI效率的潜在策略。因此,氧气利用率提高了13%,与历史匹配模型相比,累计石油产量提高了73%。
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Field performance and numerical simulation study on the toe to heel air injection (THAI) process in a heavy oil reservoir with bottom water

Extra-heavy oil and bitumen (EHOB) comprise 30 percent of the remaining recoverable fossil fuel resources on Earth. This means EHOB could play an important role in a secure transition towards net zero emissions (NZE) by 2050. Technological developments, such as toe to heel air injection (THAI), have been shown to efficiently recover heavy oil with reduced environmental footprint. The Kerrobert project was the first to utilise the THAI technology in presence of bottom water (BW) in the reservoir. The project demonstrated a good performance (with average oil rate of 10 m3/day per well) compared to the conventional ISC operations in a BW situation. Lessons taken from the Kerrobert operational experience can assist the forthcoming THAI operations explicitly in the presence of BW. Dynamic field data for one of the best performing THAI pilot well pairs (K2), were analysed in this work. It was found that the K2 pilot must have experienced interference from K5, which is the closest neighbouring THAI well pair to the K2. Previously developed THAI models have not been validated against actual field data. A new field-scale THAI model in the presence of BW was constructed and, for the first time, validated against the field data from the Kerrobert project in this work. In addition, the quasi-staggered line drive well arrangement, as used for the K2 pilot, was studied. The daily and cumulative oil production rates were predicted well (the final agreement with field data was within 3 percent). The history matched model was then used to investigate the effect of the variation in air injection rates on THAI performance in presence of BW. Major developed zones during the propagation of the combustion front were numerically examined. It was demonstrated that extra air ingress from the neighbouring THAI well pair has caused a reduction in oxygen utilisation throughout the process. As a result, the simulated temperature profile declined with the increasing combustion time. The oxygen profile around the horizontal producer (HP) well was studied via the new history-matched model. An inversely proportional relationship was detected between the coke concentration and the oxygen profile around the HP well. It was found that the size of the steam zone, ahead of the combustion front, differs with variation in air injection rates. It was observed that some of the mobilised oil sank into the BW, leaving a significant amount of oil trapped in the reservoir. To prevent such an event, the location of the HP well was altered as a potential strategy to optimise the THAI efficiency. Consequently, the oxygen utilisation was improved by 13%, resulting in 73% higher cumulative oil production in comparison with the history-matched model.

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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.
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Predictive Analytical Model for Hydrate Growth Initiation Point in Multiphase Pipeline System Optimization of the Oxidative Desulphurization of Residual Oil Using Hydrogen Peroxide Terpane Characterization of Crude Oils from Niger Delta, Nigeria: A Geochemical Appraisal Editorial Board Editorial Board
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