Numerical Simulation of Proppant Transport in Hydraulically Fractured Reservoirs

Day 1 Tue, October 26, 2021 Pub Date : 2021-10-19 DOI:10.2118/203927-ms

S. E. Gorucu, V. Shrivastava, L. Nghiem

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引用次数: 1

Abstract

An existing equation-of-state compositional simulator is extended to include proppant transport. The simulator determines the final location of the proppant after fracture closure, which allows the computation of the permeability along the hydraulic fracture. The simulation then continues until the end of the production. During hydraulic fracturing, proppant is injected in the reservoir along with water and additives like polymers. Hydraulic fracture gets created due to change in stress caused by the high injection pressure. Once the fracture opens, the bulk slurry moves along the hydraulic fracture. Proppant moves at a different speed than the bulk slurry and sinks down by gravity. While the proppant flows along the fracture, some of the slurry leaks off into the matrix. As the fracture closes after injection stops, the proppant becomes immobile. The immobilized proppant prevents the fracture from closing and thus keeps the permeability of the fracture high. All the above phenomena are modelled effectively in this new implementation. Coupled geomechanics simulation is used to model opening and closure of the fracture following geomechanics criteria. Proppant retardation, gravitational settling and fluid leak-off are modeled with the appropriate equations. The propped fracture permeability is a function of the concentration of immobilized proppant. The developed proppant simulation feature is computationally stable and efficient. The time step size during the settling adapts to the settling velocity of the proppants. It is found that the final location of the proppants is highly dependent on its volumetric concentration and slurry viscosity due to retardation and settling effects. As the location and the concentration of the proppants determine the final fracture permeability, the additional feature is expected to correctly identify the stimulated region. In this paper, the theory and the model formulation are presented along with a few key examples. The simulation can be used to design and optimize the amount of proppant and additives, injection timing, pressure, and well parameters required for successful hydraulic fracturing.

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水力裂缝性储层支撑剂运移数值模拟

将现有的状态方程组成模拟器扩展到包括支撑剂输运。该模拟器确定裂缝闭合后支撑剂的最终位置，从而可以计算水力裂缝沿线的渗透率。然后，模拟将继续进行，直到生产结束。在水力压裂过程中，支撑剂与水和聚合物等添加剂一起注入储层。水力压裂是由于高注入压力引起的应力变化造成的。一旦裂缝打开，大量泥浆沿着水力裂缝移动。支撑剂的移动速度与散装泥浆不同，并在重力作用下下沉。当支撑剂沿着裂缝流动时，一些泥浆会泄漏到基质中。随着注入停止后裂缝闭合，支撑剂变得不能动。固定化支撑剂可以防止裂缝闭合，从而保持裂缝的高渗透率。在这个新的实现中，上述所有现象都得到了有效的模拟。采用耦合地质力学模拟方法，按照地质力学准则模拟裂缝的开闭过程。用适当的方程对支撑剂缓凝、重力沉降和流体泄漏进行了建模。支撑裂缝渗透率是固定支撑剂浓度的函数。所开发的支撑剂模拟功能在计算上稳定且高效。沉降过程中的时间步长与支撑剂的沉降速度相适应。研究发现，由于缓凝和沉降作用，支撑剂的最终位置高度依赖于其体积浓度和浆液粘度。由于支撑剂的位置和浓度决定了最终的裂缝渗透率，因此该附加特征有望正确识别压裂区域。本文介绍了理论和模型的建立，并给出了几个关键的例子。该模拟可用于设计和优化支撑剂和添加剂的用量、注入时间、压力和成功水力压裂所需的井参数。

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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Day 1 Tue, October 26, 2021

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