Effects of Drilling Number and Distribution on Fracture Using the Pulse Plasma on Tight Sand Reservoir

SPE Journal Pub Date : 2024-01-01 DOI:10.2118/218413-pa
Zhaoxuan Li, Shuo Wang, Yi Pan, Rongqi Zhang, Jiajun Chen
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Abstract

The permeability of unconventional reservoirs is extremely low, resulting in their drainage area being limited to tens of feet. Therefore, researchers have developed an effective stimulation technology that can be used in combination with conventional hydraulic fracturing, namely, pulsed plasma fracturing technology. Pulsed plasma fracturing technology is an efficient and environmentally friendly auxiliary hydraulic fracturing stimulation technology. However, most existing studies have focused only on the effect of pulsed plasma fracturing on single wells, ignoring the effect of the number and distribution of wells drilled on pulsed plasma fracturing. In this paper, pulsed plasma fracturing is studied by a self-built pulsed plasma experimental platform and nonlinear finite element software. First, the generation and propagation mechanism of shock wave, fracture type, and stress field analysis of rock mass in pulsed plasma fracturing technology are discussed. The double-well experiment was carried out by using the experimental platform, and the fracture law of fractures under different wellhead distribution conditions was obtained. In addition, a multiwell mathematical model is established by using the combination of the Euler method and Lagrange method to simulate the interaction between fluid and solid, that is, arbitrary Lagrangian Eulerian (ALE) multimaterial fluid-solid coupling method and the influence of drilling times and wellhead distribution on pulsed plasma fracturing is discussed. Stress analysis shows that the rock is mainly affected by ground stress, liquid column pressure, and shock wave pressure. The experimental results show that the discharge voltage is positively correlated with the shock wave pressure on the rock. The distribution of different wellheads affects the distribution and length of fractures. The double-well experiment makes the fractures easier to fracture. The simulation results show that the fracture length in the connection direction of the two wells is longer, and the fracture length in the vertical direction is shorter. This shows that the number and distribution of drilling affect the initiation and propagation of fractures.
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在致密砂岩储层中使用脉冲等离子体的钻井数量和分布对压裂的影响
非常规储层的渗透率极低,导致其排水面积仅限于数十英尺。因此,研究人员开发了一种可与常规水力压裂技术结合使用的有效激励技术,即脉冲等离子体压裂技术。脉冲等离子体压裂技术是一种高效、环保的辅助水力压裂增产技术。然而,现有研究大多只关注脉冲等离子体压裂对单井的影响,忽视了钻井数量和分布对脉冲等离子体压裂的影响。本文利用自建的脉冲等离子体实验平台和非线性有限元软件对脉冲等离子体压裂进行了研究。首先,讨论了脉冲等离子体压裂技术中冲击波的产生和传播机理、裂缝类型以及岩体应力场分析。利用实验平台进行了双井实验,得到了不同井口分布条件下裂缝的断裂规律。此外,利用欧拉法和拉格朗日法相结合的方法建立了多井数学模型,模拟流体和固体之间的相互作用,即任意拉格朗日欧拉(ALE)多材料流固耦合方法,并讨论了钻井时间和井口分布对脉冲等离子体压裂的影响。应力分析表明,岩石主要受地应力、液柱压力和冲击波压力的影响。实验结果表明,放电电压与岩石上的冲击波压力呈正相关。不同井口的分布会影响裂缝的分布和长度。双井实验使裂缝更容易压裂。模拟结果表明,双井连接方向的裂缝长度较长,垂直方向的裂缝长度较短。这表明钻井的数量和分布会影响裂缝的起始和扩展。
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