深层煤岩气直丛井高效开发技术对策与实践——以大宁—吉县区块宜川井区为例

doi:10.3969/j.issn.1672-7703.2025.04.009

摘要/Abstract

摘要： 深层煤岩气直丛井开发过程中存在产能主控因素不明确、单井产量差异大等问题，制约了多套薄煤岩发育区煤岩气资源的高效动用。为提升单井产量，以大宁—吉县区块105口直丛井为研究对象，系统开展产能主控因素识别。通过单因素分析明确了11项地质与工程因素的产能控制规律，其中资源丰度与储层可改造潜力构成气井高产的地质基础。进一步结合多元线性回归分析与决策树模型，从工程因素中识别出施工总砂量、施工压力、关井时长与压裂后辅助排液量4项工程主控因素。在此基础上，构建了“优部署—强改造—控伤害—提能效”的高产井培育路径，形成了以地质—工程甜点区协同优选、大规模体积压裂改造、压裂后快速返排控滤失、多源能量耦合助排降压为核心的高效开发技术体系，并配套提出人工举升工艺前移、地面工程分段实施、多工序协同推进等工程组织策略，建立了覆盖直丛井全生命周期的高效开发模式。该技术体系在宜川井区现场应用效果显著，平均单井日产气量由0.8×10⁴m³提升至1.8×10⁴m³，EUR达到2000×10⁴m³，储层降压效率显著提升，稳产能力持续增强。研究成果不仅支撑了宜川井区深层煤岩气资源的高效开发，也为该技术体系在同类区块的规模化推广应用提供了路径参考与实践支撑。

关键词: 深层煤岩气, 直丛井, 高产主控因素, 高产培育路径, 高效开发技术体系, 工程组织策略

Abstract: The development of deep coalbed methane using clustered vertical–deviated wells faces several challenges, including unclear productivity-controlling factors and significant variation in single-well production, which constrain the efficient utilization of deep coalbed methane resources in areas with multiple thin coal seams. To enhance single-well production, this study investigated 105 clustered vertical–deviated wells in the Daning–Jixian Block and systematically identified the key factors controlling productivity. Through single-factor analysis,11 geological and engineering parameters influencing productivity were clarified, among which resource abundance and reservoir fracability served as the geological foundation for high productivity. Multiple linear regression and a decision tree model were subsequently applied to identify four engineering-dominant factors: total proppant volume, fracturing pressure, shut-in duration, and post-fracturing assisted fluid flowback volume. Based on this, a high-productivity development pathway was established following the strategy of “deploy optimally–stimulate effectively –mitigate damage – boost efficiency.” An efficient development technology system was developed, centered on integratedgeological–engineering sweet spot identification, large-scale volume fracturing, rapid post-fracturing flowback, and multi-source energy synergy for enhanced drainage and pressure drawdown. This was supported by engineering organization strategies such as early-stage artificial lift deployment, staged surface facility construction, and multi-process coordinated execution, forming a full-lifecycle development model for clustered vertical–deviated wells. Field tests conducted on 9 wells in the Yichuan area demonstrated the effectiveness of this technology system, with average daily gas production per well increasing from 0.8×10⁴ m³ to 1.8×10⁴ m³, and EUR reaching 2000×10⁴ m³. Reservoir pressure drawdown efficiency was improved significantly, and stable production capacity was notably enhanced. The results provide systematic technical support for efficient development of deep CBM in Yichuan and offer a reference path and practical basis for large-scale application of the technology in similar blocks.

Key words: deep coalbed methane, clustered vertical–deviated wells, productivity-controlling factors, high-productivity development pathway, efficient development technology system, engineering organization strategy

中图分类号:

TE313

聂志宏, 王得志, 熊先钺, 季亮, 周昌辉, 邓永洪, 王伟, 宋一男, 黄扬扬, 高锡成, 许成超, 邢雪杰. 深层煤岩气直丛井高效开发技术对策与实践——以大宁—吉县区块宜川井区为例[J]. 中国石油勘探, 2025, 30(4): 118-138.

Nie Zhihong, Wang Dezhi, Xiong Xianyue, Ji Liang, Zhou Changhui, Deng Yonghong, Wang Wei, Song Yinan, Huang Yangyang, Gao Xicheng, Xu Chengchao, Xing Xuejie. Efficient Development Strategies and Engineering Practices for Deep Coalbed Methane Clustered Vertical–Deviated Wells: A Case Study of the Yichuan Well Area in the Daning–Jixian Block[J]. China Petroleum Exploration, 2025, 30(4): 118-138.

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