鄂尔多斯盆地深层煤岩气地质认识进展与关键工程技术

doi:10.3969/j.issn.1672-7703.2025.04.005

摘要/Abstract

摘要： 鄂尔多斯盆地石炭系—二叠系煤系地层广泛分布，深层煤岩气资源基础雄厚，具备大规模建产的物质条件。为系统认识深层煤岩气的地质特征与勘探规律，本文在梳理勘探历程的基础上，综合钻井、录井及分析测试等资料，从盆地尺度出发，研究了上古生界煤系地层的聚煤环境、煤质特征、储层物性与成藏条件，结合近年来典型井的地质与工程实践成果，总结了资源潜力、富集规律及关键开发技术，明确了下一步勘探方向。研究表明：（1）本溪组8号煤层与山西组5号煤层是深层煤岩气的主力勘探层系，煤层厚度大、分布稳定，热演化程度较高，镜质组含量高，具备良好的生气能力；（2）煤岩储层以原生结构煤为主，孔隙结构呈双峰分布，微孔与割理裂缝体系共同发育，游离气占比较高；（3）生烃滞留率普遍较高，盆地中部约为40%，东部可达50%以上，为气体富集提供了物质基础；（4）煤岩与上覆不同岩性形成了煤泥、煤灰和煤砂3 种储盖组合，控制着游离气富集分布，形成了“持续生烃—源储一体—箱式封存”的有利成藏模式；（5）结合开发实践，形成了适用于深层煤岩气开发的差异化地质导向、二开井身结构优化、高排量压裂与控压排采等关键工程技术体系，显著提升了钻遇率、改造效率与单井产能。研究成果支撑了深部煤岩气“看得准、打得成、产得稳”的开发目标，体现了地质—工程一体化发展推动下盆地资源规模化建产的可行性和实践价值。

关键词: 鄂尔多斯盆地, 本溪组, 煤岩气, 地质特征, 富集模式, 工程技术

Abstract: The Carboniferous–Permian coal measure strata are widely distributed in Ordos Basin. There are abundant deep coal rock gas resources, showing a solid material basis for large-scale capacity construction, so it is crucial to systematically understand the geological characteristics and exploration methods of deep coal rock gas. Based on review of exploration history, and combined with well drilling,logging, and laboratory test data, the coal accumulation environment, coal quality, reservoir physical properties, and gas accumulation conditions of the Upper Paleozoic coal measure strata at the basin scale have been analyzed. By integrating with geological and engineering data from typical wells in recent years, the resource potential, enrichment patterns, and key development technologies have been summarized,and future exploration orientations have been determined. The study results show that: (1) No.8 coal seam in Benxi Formation and No.5 coal seam in Shanxi Formation are the main target layers for deep coal rock gas exploration, which are featured by thick coal seams, consistent distribution, relatively high maturity, high vitrinite content, and high gas generation capacity; (2) The coal rock reservoirs are dominated by primary structure coal, with bimodal pattern of pore structure, well-developed micropores and cleat–fracture system, and high proportion of free gas; (3) Hydrocarbon retention rate is generally high, which is about 40% in the central basin and exceeding 50% in the eastern basin,providing a material basis for gas accumulation; (4) Three types of reservoir and cap rock combinations were formed by coal rocks and the overlying strata, including coal–mudstone, coal–limestone, and coal–sandstone, which effectively controlled the distribution of free gas and formed a favorable hydrocarbon accumulation pattern of “continuous hydrocarbon generation, integration of source rock and reservoir, and box-type sealing”; (5) Based on field practice, a series of key engineering technologies applicable for deep coal rock gas have been developed, including differentiated geosteering, two-section wellbore structure optimization, high-displacement fracturing, and pressure-controlled production, significantly improving the drilling encounter rates, reservoir reconstruction efficiency, and single-well production capacity. The research results support the goal of deep coal rock gas development with “accurate identification, successful drilling, and steady production”, and demonstrate the feasibility and practical value of large-scale capacity construction promoted by integration of geology and engineering.

Key words: Ordos Basin, Benxi Formation, coal rock gas, geological characteristics, enrichment mode, engineering technology

中图分类号:

TE122.1

喻健, 史云鹤, 张涛, 戴贤铎, 梁晨, 焦鹏帅, 杜小伟, 高星, 庄一鹏, 张辉, 陈宇航. 鄂尔多斯盆地深层煤岩气地质认识进展与关键工程技术[J]. 中国石油勘探, 2025, 30(4): 58-76.

Yu Jian, Shi Yunhe, Zhang Tao, Dai Xianduo, Liang Chen, Jiao Pengshuai, Du Xiaowei, Gao Xing, Zhuang Yipeng, Zhang Hui, Chen Yuhang. New geological understanding and key engineering technologies for deep coal rock gas in Ordos Basin[J]. China Petroleum Exploration, 2025, 30(4): 58-76.

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