基于实验结果和二尺度连续体模拟的新尺度虫洞模型

M. Schwalbert, A. Hill, D. Zhu
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引用次数: 9

摘要

碳酸盐岩储层基质酸化处理的优化设计需要对虫孔扩展进行精确建模。虽然有几种虫孔相关模型可用,但大多数都是基于小型岩心规模实验开发的,当扩大到现场处理设计时,结果会产生显著偏差。也存在模拟模型(如双尺度连续体或孔隙网络模型)。这些模型不适合现场设计,因为涉及大量的计算工作。在使用不同岩心尺寸和几何形状(径向流动与线性流动)的实验室实验中,观察到虫孔行为的巨大变化。在以前的模型中没有捕捉到这种变化。本文提出了一种新的多尺度虫孔模型,该模型代表了岩心和现场尺度碳酸盐基质酸化过程中虫孔行为的物理特性。给出了新的半经验模型的推导公式,以表示不同岩心尺寸和流动几何形状的实验数据以及现场结果。在不同岩心尺寸的岩心驱油实验中,不同岩心尺寸获得的可突破孔隙体积和最佳注入速度不同。在采用双尺度连续体模型的数值模拟中也观察到相同的行为。该模型能够正确地计算出虫洞区域尺度和几何形状对相关参数依赖的函数的维度。升级程序线性,径向,椭圆,球形和椭球几何提出。通过双尺度连续体的线性流和径向流数值模拟,以及不同芯型尺寸和几何形状(线性流和径向流)的实验结果验证了模型的结果。在此基础上进一步发展了该模型,并对模型的使用过程进行了说明。不同的流体几何形状可以预测常见完井的酸化行为,如裸眼、套管井和射孔井以及有限进井。该模型的预测结果与现场实例的结果非常吻合。新模型再现了在最佳注入速率以上优势虫孔生长的分形行为,并预测了实验测量的注入压力随时间的依赖关系。该模型正确地描述了虫洞传播现象的物理性质。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A New Up-Scaled Wormhole Model Grounded on Experimental Results and in 2-Scale Continuum Simulations
The optimum design of matrix acidizing treatments in carbonate reservoirs requires accurate modeling of wormhole propagation. While there are several wormhole correlation models available, most are developed based on small core scale experiments, and result in significant deviation when upscaled to field treatment design. There also exists simulation models (e.g. Two-Scale Continuum or Pore Network models). These models are not practical for field design because of the extensive computation effort involved. Large variations in the wormholing behavior are observed in laboratory experiments using different core sizes and geometries (radial flow versus linear flow). This variation is not captured in the previous models. This work proposes a new multiscale wormhole model that represents the physics of wormholing behavior in matrix acidizing of carbonates both at core and field scales. The derivation of the new semi-empirical model is formulated to represent the experimental data for different core dimensions and flow geometries, as well as field results. In core flooding experiments with different core sizes, the obtained pore volumes to breakthrough and optimal injection velocity are different for each core size. The same behavior is observed in numerical simulations using the Two-Scale Continuum model. That behavior is correctly calculated with the proposed model, which accounts for the dimensions in a function with dependence of the correlation parameters on the wormholed region scale and geometry. Upscaling procedures to linear, radial, elliptical, spherical, and ellipsoidal geometries are presented. The model's results are validated by the Two-Scale Continuum numerical simulations for both linear and radial flow and verified with experimental results with different core sizes and geometries (both linear and radial flow). We further developed the model for field application, and procedure of using the model is illustrated in the paper. The different flow geometries allow predicting the acidizing behavior in common completions, such as openhole, cased and perforated, and limited entry. The model prediction compares very well to the outcome of field cases. The new model reproduces the fractal behavior of the dominant wormhole growth above optimal injection rate, and predicts the injection pressure dependence on time as measured experimentally. The model correctly captured the physics of wormhole propagation phenomenon.
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