鄂尔多斯盆地深层煤岩气储层改造增产关键技术与应用

doi:10.3969/j.issn.1672-7703.2025.04.011

摘要/Abstract

摘要： 鄂尔多斯盆地深层本溪组8号煤岩资源丰富，是我国非常规天然气增储上产的现实接替。与浅层煤层气相比，深层煤岩气具有“基质致密、孤立孔占比高、割理裂隙发育、游离气—吸附气共存”的特征，大规模压裂改造是降低深层煤岩游离气渗流阻力、促进吸附气解吸的有效手段。通过三轴力学压缩、地应力测试、大物理模拟裂缝扩展等实验，明确8号煤岩割理发育、低杨氏模量、高泊松比、纵向应力差大的力学性质，以及高排低黏和低排高黏模式下的裂缝扩展特征。通过多参数地质工程甜点识别方法与差异化精细分段分簇布缝技术，形成以“多段少簇、交替注入、组合加砂”为核心的经济规模压裂技术，其要点为（1）段内少簇聚能量，实现缝口聚能，开启割理裂隙；（2）交替注入扩带宽，高低黏液体交替注入，提高裂缝的复杂程度；（3）组合加砂提导流，实现多尺度裂缝有效支撑。该技术在矿场累计应用完试19口井，初期日产4.9×10⁴m³，具有较好的试气效果，为深层煤岩气的效益开发提供了重要的技术支撑。

关键词: 鄂尔多斯盆地, 深层煤岩气, 本溪组, 压裂改造技术, 应用成效

Abstract: There are abundant coal rock resources in Benxi Formation coal seam No.8 in Ordos Basin, which is a realistic replacement field for increasing unconventional gas reserves and production in China. Compared with shallow coalbed methane, deep coal rock gas has the characteristics of “tight matrix, high proportion of isolated pores, well developed cleavages and fissures, coexistence of free gas and adsorbed gas”. Therefore, the large-scale fracturing is an effective means to reduce free gas flow resistance and promote the desorption of adsorbed gas in deep coal rocks. The experiments such as triaxial mechanical compression, in-situ stress test and large physical simulation on fracture propagation have been conducted, which have identified the well-developed cleavages, mechanical properties of low Young’s modulus, high Poisson’s ratio, large longitudinal stress difference of coal rock No.8, and fracture propagation characteristics given the fracturing modes of high displacement low viscosity and low displacement high viscosity. By applying multi-parameter geology–engineering sweet spot identification method and multi-stage and multi-cluster differentiated fine fracture layout technology, the economic and large-scale fracturing technology has been formed with the core of “multi-stage and few clusters, alternating fluid injection, and combined sand addition”. The key points of the technology include: (1) Few clusters in one stage to concentrate energy at the fracture opening and initiate cleavages and fissures; (2) Alternating injection of high and low viscosity fluids to expand fracture propagation zone and increase the fracture complexity; (3) Combined sand addition to increase flow capacity, so as to achieve the effective support of multi-scale fractures. The technology has been applied to 19 wells, with an initial daily gas rate of 4.9×10⁴ m³/d, showing good gas production test results, which has provided important technical support for beneficial development of deep coal rock gas.

Key words: Ordos basin, deep coal gas, Benxi Formation, fracturing stimulation technology, application results

中图分类号:

TE357

张燕明, 蔺小博, 周长静, 马占国, 肖元相, 古永红, 王历历, 惠波, 刘欣佳, 刘晓瑞. 鄂尔多斯盆地深层煤岩气储层改造增产关键技术与应用[J]. 中国石油勘探, 2025, 30(4): 158-168.

Zhang Yanming, Lin Xiaobo, Zhou Changjing, Ma Zhanguo, Xiao Yuanxiang, Gu Yonghong, Wang Lili, Hui Bo, Liu Xinjia, Liu Xiaorui. Key reservoir stimulation technologies and application for deep coal rock gas in Ordos Basin[J]. China Petroleum Exploration, 2025, 30(4): 158-168.

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