Research on the transport behavior of microparticle proppants inside natural fractures

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS

ACS Applied Bio Materials Pub Date : 2024-06-13 DOI:10.3389/feart.2024.1418783

Huifeng Liu, Xiaohan Wang, Ning Xu, Zhangxin Chen, Yan Peng

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引用次数: 0

Abstract

As a crucial exploration technique for unconventional reservoirs, hydraulic fracturing enables the formation of complex fracture networks, thereby facilitating the flow of oil and gas. The closure of natural fractures decreases stimulation performance. Microparticle proppants are used to fill natural fractures and effectively increase the stimulation area. The 100-mesh proppant conventionally used in field operations may be insufficiently small to effectively access natural fractures. In order to effectively overcome natural fractures closure, microparticle proppants (i.e., proppants with a diameter of 75 μm (200-mesh) or less) are required. The particle size threshold test of microparticle proppants placement is conducted to determine the size threshold of proppants flowing into natural fractures. The microparticle proppants placement experiment in multi-branch fractures is conducted to investigate the volume difference of proppants in different fractures. Numerical simulations are performed to model proppant transport within fractures of actual dimensions to facilitating the optimization of stimulation parameters. The main conclusions are as follows: (1) Effective inflow of microparticle proppants requires a size threshold of proppants. For the 200-mesh proppants, the size should be less than half of natural fractures width when microparticle proppants effectively flow into natural fractures. (2) Sand concentration affects the size threshold of microparticle proppants. The size threshold should appropriately increase to ensure the inflow of proppant. (3) Difference of multi-branch fracture width has a significant effect on volume of microparticle proppants inside fractures. When the width ratio of multi-branch fractures exceeds 2, this effect becomes obvious. (4) Particle size has an effect on proppant placement. 200-mesh proppants can obtain uniform distribution of proppants among natural fractures. 140-mesh proppants can obtain maximum proppant volume among natural fractures. Sand concentration significantly affects proppant placement performance. The optimal sand concentration is 60kg/m3. The pumping rate for a single cluster fracture should not be excessively low. The pumping rate should be larger than 0.5m3/min and the optimal pumping rate 2m3/min. In this paper, the particle size and concentration of particulate proppant are optimized and the geometric characteristics of fractures are considered. These conclusions provide important practical guidance and scientific basis for the optimization and application of hydraulic fracturing technology.

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微粒支撑剂在天然裂缝内的迁移行为研究

作为非常规储层的一项重要勘探技术，水力压裂法能够形成复杂的裂缝网络，从而促进石油和天然气的流动。天然裂缝的闭合会降低水力压裂的效果。微粒子支撑剂可用于填充天然裂缝，并有效增加增产面积。油田作业中常规使用的 100 目支撑剂可能不够细小，无法有效进入天然裂缝。为了有效克服天然裂缝的闭合，需要使用微颗粒支撑剂（即直径为 75 微米（200 目）或更小的支撑剂）。微粒支撑剂投放的粒度阈值测试是为了确定支撑剂流入天然裂缝的粒度阈值。在多分支裂缝中进行微颗粒支撑剂投放试验，以研究支撑剂在不同裂缝中的体积差异。进行了数值模拟，以模拟支撑剂在实际尺寸裂缝中的运移，从而帮助优化激励参数。主要结论如下(1）微颗粒支撑剂的有效流入需要一个支撑剂尺寸阈值。对于 200 目支撑剂，当微粒支撑剂有效流入天然裂缝时，其尺寸应小于天然裂缝宽度的一半。(2）砂浓度会影响微粒支撑剂的粒度临界值。应适当提高尺寸阈值，以确保支撑剂的流入。(3）多分支裂缝宽度的差异对裂缝内微粒支撑剂的体积有显著影响。当多分支裂缝的宽度比超过 2 时，这种影响会变得非常明显。(4) 颗粒大小对支撑剂的放置有影响。200 目支撑剂可以使支撑剂在天然裂缝中均匀分布。140 目支撑剂可在天然裂缝中获得最大的支撑剂用量。砂浓度对支撑剂的铺放效果有很大影响。最佳砂浓度为 60kg/m3。单个集束裂缝的抽速不宜过低。泵送速率应大于 0.5m3/min，最佳泵送速率为 2m3/min。本文对颗粒支撑剂的粒径和浓度进行了优化，并考虑了裂缝的几何特征。这些结论为水力压裂技术的优化和应用提供了重要的实践指导和科学依据。

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

ACS Applied Bio Materials Chemistry-Chemistry (all)

CiteScore

9.40

自引率

2.10%

发文量

464

期刊介绍： ACS Applied Bio Materials is an interdisciplinary journal publishing original research covering all aspects of biomaterials and biointerfaces including and beyond the traditional biosensing, biomedical and therapeutic applications. The journal is devoted to reports of new and original experimental and theoretical research of an applied nature that integrates knowledge in the areas of materials, engineering, physics, bioscience, and chemistry into important bio applications. The journal is specifically interested in work that addresses the relationship between structure and function and assesses the stability and degradation of materials under relevant environmental and biological conditions.