川南深层页岩气压裂技术发展

Haitao Wang, S. Zhang, X. Bian, Shuangming Li, Yulin Tu, Xiong Zhang, Zhifa Wang
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摘要

在高环境温度和高围压条件下,深层页岩的物理力学性质和地应力状态会发生明显变化。通常情况下,深层页岩地层具有高水平应力差(约11 ~ 21 MPa, 1595 ~ 3045 psi)、高裂缝闭合压力梯度(约0.023 ~ 0.025 MPa/m, 1.017 ~ 1.105 psi/ft)、高破裂压力梯度(大于0.03 MPa/m, 1.327 psi/ft)、低机械脆性(约42% ~ 55%)、低垂直和水平应力差(约3 ~ 5MPa, 435 ~ 725 psi)。深层页岩复杂的地质特征增加了压裂难度:1)高围压下脆性/韧性转变的影响;2)多簇裂缝扩展不均匀性更为突出;3)在狭窄的裂缝网络中,支撑剂运移困难;4)高摩擦、高泵送压力;5)对压裂工具的要求更严格;6)对压裂规模、效率、经济性要求高。为了应对上述挑战,本文全面概述了深层页岩压裂(3500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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Development of Fracturing Technology for Deep Shale Gas in South Sichuan, China
Under the condition of high ambient temperature and high confining pressure,the physical & mechanical properties and in-situ stress state of deep shale will change noticeably. Normally, the deep-shale formation has high horizontal stress difference (about 11∼21 MPa, 1595∼3045 psi), high fracture-closure pressure gradient (about 0.023∼0.025 MPa/m, 1.017∼1.105 psi/ft), high breakdown pressure gradient (larger than 0.03 MPa/m, 1.327 psi/ft), low mechanical brittleness (about 42%∼55%), low difference between the vertical and the horizontal stresses (about 3∼5MPa, 435∼725 psi). The complex geological characteristics of deep shale increase the difficulity of fracturing: 1) effect of brittle/ductile transition under high confining pressure; 2) non-uniform propagation of multi-cluster fractures is more prominent; 3) the migration of proppant is difficult in narrow fracture network; 4) high friction and high pumping pressure; 5) more stringent requirements for fracturing tools; 6) high requirements for fracturing scale, efficiency and economy. To address above challenges, this paper presents a comprehensive overview of latest researching and applicable techniques about deep-shale fracturing (3500
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