确定候选压裂井及提高水力压裂系统复杂性的策略

B. Jamaloei
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引用次数: 2

摘要

非常规(页岩/致密/煤层气)储层水力压裂工艺优化的考虑因素之一是通过降低或消除或中和地应力各向异性(差应力)来增加裂缝复杂性,从而通过激活薄弱面(天然裂缝、裂缝、断层、裂缝、裂缝、裂缝)来提高水力裂缝的导流性和连通性。等),以形成次生裂缝或分支裂缝(诱导应力消除裂缝),并将它们连接到主双翼水力裂缝。然而,实际的现场经验表明,在某些处理设计下,由于过度的诱导应力或应力阴影,一些油藏表现出过度的裂缝复杂性,可能导致压出或筛出,从而导致完井和产能表现不佳。因此,确定适合提高裂缝复杂性的候选储层和处理策略至关重要,以避免压裂处理方案对油井产能产生不利影响。在这项工作中,三维水力裂缝扩展模拟器与油藏生产模拟器相结合,以筛选候选油藏和压裂处理方案,从而提高裂缝的复杂性、导流性、连通性和良好的油井生产性能。此外,还确定了过度裂缝复杂性(由于过度诱导应力或应力阴影)导致完井性能不佳的情况。结果表明,在以下处理方案下,可以提高裂缝复杂性:(1)高处理率下支撑剂尺寸较小的低粘度滑溜水;(2)混合压裂处理(低粘度滑溜水含较小的支撑剂和较低的支撑剂浓度,处理率高,然后是含较大支撑剂和较高支撑剂浓度的粘性处理液);(3)小间距多段同时压裂;(4)无序精确压裂(压裂阶段1和阶段3,然后将阶段2置于先前压裂阶段1和阶段3之间)。研究还表明,上述每种处理方案的成功对岩石脆性(杨氏模量和泊松比的组合)、应力各向异性大小、基质渗透率、过程带应力/净延伸压力、裂缝梯度、处理液粘度和速率非常敏感。此外,由于压出和筛出,过度的裂缝复杂性会阻碍裂缝的生长,可以通过降低处理率和压力、增加处理液粘度和使用小颗粒(如100目支撑剂)来缓解。这项工作是首次尝试在各种可行的处理方案下对裂缝复杂性的影响进行比较评估,这些方案适用于广泛的储层和岩石地质力学性质。这表明,具有杨氏模量、泊松比、应力各向异性和裂缝梯度的特定组合的井不适合在水力裂缝系统中制造复杂性。
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Identifying Well Treatment Candidates and Strategies for Enhancing Hydraulic Fractures System Complexity
One of the considerations in hydraulic fracturing treatment optimization in unconventional (shale/tight/CBM) reservoirs is creating fracture complexity through reducing or possibly eliminating or neutralizing the in-situ stress anisotropy (differential stress) to enhance hydraulic fracture conductivity and connectivity by activating planes of weakness (natural fractures, fissures, faults, cleats, etc.) within the formation in order to create secondary or branch fractures (induced stress-relief fractures) and connect them to the main bi-wing hydraulic fractures. However, actual field experience has shown that some reservoirs under certain treatment designs exhibit excessive fracture complexity due to excessive induced stresses or stress shadowing that can result in pressureout or screenout, and thus, poor well completion and productivity performance. Therefore, it is crucial to identify the reservoir candidates and treatment strategies that are suitable for enhancing fracture complexity to avoid fracturing treatment scenarios that will have an adverse effect on the well productivity. In this work, a three-dimensional hydraulic fracture extension simulator is coupled with a reservoir production simulator to screen for the reservoir candidates and fracturing treatment scenarios that can lead to enhancing fracture complexity, conductivity, and connectivity and positive well production performance. Furthermore, scenarios are identified under which excessive fracture complexity (due to excessive induced stresses or stress shadowing) results in poor well completion performance. The results indicate that fracture complexity can be enhanced under the following treatment scenarios: (1) low-viscosity slickwater with smaller proppant sizes under high treatment rates, (2) hybrid fracture treatment (low-viscosity slickwater containing smaller proppants and low proppant concentrations with high treatment rates followed by viscous treatment fluids containing larger proppants and higher proppant concentrations), (3) simultaneous fracturing of multiple intervals at close spacing, and, (4) out-of-sequence pinpoint fracturing (fracturing Stage 1 and then Stage 3 followed by placing Stage 2 between the previously fractured Stages 1 and 3). It is also revealed that the success of each of the above treatment scenarios is very sensitive to rock brittleness (combination of Young's modulus and Poisson's ratio), magnitude of stress anisotropy, matrix permeability, process zone stress/net extension pressure, fracture gradients, and treatment fluid viscosity and rate. Additionally, excessive fracture complexity, which impedes fracture growth due to pressure out and screenout, can be mitigated by reducing treatment rate and pressure, increasing treatment fluid viscosity, and using small particulates, such as 100-mesh proppant. This work is the first attempt in comparative evaluation of the impact of creating fracture complexity under a variety of operationally-feasible treatment scenarios applied to a wide range of reservoir and rock geomechanical properties. It shows that wells with certain combinations of Young's modulus, Poisson's ratio, stress anisotropy, and fracture gradients are not suitable candidates for creating complexity in the hydraulic fractures system.
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