Evaluation of the gas recycling duration on the hydrocarbon recovery from gas condensate fields

Q3 Materials Science

Archives of materials science and engineering Pub Date : 2022-10-01 DOI:10.5604/01.3001.0016.1776

S. Matkivskyi, O. Burachok, L. Matiishyn

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Abstract

Optimization of formation pressure maintenance technologies in the development of gas condensate fields with a high initial content of condensate in the reservoir gas using numerical modelling. A study on the efficiency of dry gas injection for pressure maintenance in gas condensate fields was performed with the help of numerical 3D models. Key technological indicators of the reservoir development were calculated for the dry gas injection period of 12, 24, 36, 48, and 60 months. The results are presented as plots for the parameters in a study. Based on the results of the studies, it was found that the introduction of dry gas injection technology ensures that reservoir pressure is maintained at the highest level compared to the development of gas condensate reservoirs on primary depletion. Due to this, further condensate drop-out in the reservoir is slowed down, and the production of partly already condensed hydrocarbons is ensured by their evaporation into the dry gas injected from the surface. The simulation results indicate that increase in the injection duration period leads to an increase of the cumulative condensate production and hence the final hydrocarbon recovery factor. The heterogeneity of oil and gas deposits, both in terms of area and thickness, significantly affects the efficiency of the developed hydrocarbon enhancement technologies. In order to minimize the negative impact of heterogeneity, it is necessary to conduct additional studies on the conditions of specific reservoirs or fields. The reservoir pressure maintenance technology implementation according to various technological schemes, as well as using various types of injection agents, will significantly intensify the development of depleted gas condensate fields with a high condensate yield. Statistical analysis of the simulation results identified the optimum value of the dry gas injection period into the gas condensate reservoir, which is 34.3 months for the conditions of a given reservoir in the study.

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凝析气田油气开采中气循环周期的评价

基于数值模拟的高凝析气初始含量凝析气田开发中地层压力维持技术优化利用三维数值模型对凝析气田干注保压效率进行了研究。计算了干气注入周期为12、24、36、48、60个月的储层开发关键技术指标。结果以图的形式表示研究中的参数。研究结果表明，相对于凝析气藏一次衰竭开发，干注气技术的引入确保了储层压力保持在最高水平。因此，油藏中的凝析液进一步下降的速度会减慢，并且已经部分冷凝的碳氢化合物的生产通过将其蒸发到从地面注入的干气中来保证。模拟结果表明，注入时间的增加导致累积凝析油产量的增加，从而提高最终的油气采收率。油气沉积面积和厚度的非均质性对已开发的油气强化技术的效果有显著影响。为了尽量减少非均质性的负面影响，有必要对特定油藏或油田的条件进行额外的研究。根据各种技术方案实施储层保压技术，使用各种类型的注入剂，将大大加强高凝析油枯竭凝析气田的开发。通过对模拟结果的统计分析，确定了在给定储层条件下凝析气藏干气注入周期的最佳值为34.3个月。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Archives of materials science and engineering Materials Science-Materials Science (all)

CiteScore

2.90

自引率

0.00%

发文量