波浪冲击下近井底区的渗透率预测

IF 2.4 Q2 MINING & MINERAL PROCESSING Journal of Mining Institute Pub Date : 2022-12-30 DOI:10.31897/pmi.2022.59
Qin Chengzhi, M. Guzev, V. Poplygin, A. Kunitskikh
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引用次数: 2

摘要

研究表明,在选择提高采收率的方法时,必须考虑流体在地层中的流动流变特征、毛管力的影响以及生产地层在厚度上和顺层上储层物性的非均质性。考虑了利用低频波冲击提高油田产量的方法。在低频冲击下,岩石中出现新的裂缝,现有裂缝的尺寸增大。岩石孔隙度和渗透率的最大增加发生在撞击频率达到10hz时。本文研究了波在饱和多孔介质中运动时振幅的动力学特性:振幅的基本衰减发生在距井轴线1 m处。从1 Hz到10 Hz,振幅衰减强度随频率的增加而减小。该技术在俄罗斯彼尔姆地区的一口井中进行了测试。实际渗透率比预测值高50%。水动力研究处理结果表明,井筒附近的渗透率增加幅度最大,而远离井筒轴线的渗透率基本保持不变。为了完善波浪对岩石渗透性影响预测的数学模型,需要考虑孔隙空间结构的互联性、附着层的变化以及振动过程中颗粒的转移研究。
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Predicting the permeability of the near-bottomhole zone during wave impact
The research reveals that during selection of a method to increase oil recovery it is necessary to take into account rheological features of fluid movement through the formation, effect of capillary forces and heterogeneity of reservoir properties of the productive formation in thickness and along the bedding. Low-frequency wave impact, which is used to increase production in oil fields, is considered. At low-frequency impact new fractures appear and existing fractures in rocks increase in size. The greatest increase in porosity and permeability of rocks occurs at an impact frequency up to 10 Hz. Dynamics of oscillation amplitude during wave's movement in saturated porous medium is studied in the paper: essential attenuation of amplitude occurs at distance up to 1 m from borehole axis. With increase of frequency from 1 to 10 Hz the intensity of amplitude's attenuation decreases. The technology was tested on a well in Perm region (Russia). The actual permeability value was 50 % higher than the predicted value. According to the results of hydrodynamic investigations processing, it was noted that the greatest increase of permeability took place near the wellbore, while away from the wellbore axis permeability remained almost unchanged. In order to refine the mathematical model for prediction of wave impact on rock permeability it is necessary to take into account interconnection of pore space structure, change of adhesion layer, as well as to study transfer of particles during vibration.
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来源期刊
Journal of Mining Institute
Journal of Mining Institute MINING & MINERAL PROCESSING-
CiteScore
7.50
自引率
25.00%
发文量
62
审稿时长
8 weeks
期刊最新文献
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