•  
  •  
 

Coal Geology & Exploration

Authors

XU Hao, School of Energy Resources, China University of Geosciences (Beijing), Beijing 100083, Chin; Coal Reservoir Laboratory of National Engineering Research Center of CBM Development & Utilization, China University of Geosciences, Beijing 100083, ChinaFollow
TANG Dazhen, School of Energy Resources, China University of Geosciences (Beijing), Beijing 100083, Chin; Coal Reservoir Laboratory of National Engineering Research Center of CBM Development & Utilization, China University of Geosciences, Beijing 100083, China
TAO Shu, School of Energy Resources, China University of Geosciences (Beijing), Beijing 100083, Chin; Coal Reservoir Laboratory of National Engineering Research Center of CBM Development & Utilization, China University of Geosciences, Beijing 100083, China
LI Song, School of Energy Resources, China University of Geosciences (Beijing), Beijing 100083, Chin; Coal Reservoir Laboratory of National Engineering Research Center of CBM Development & Utilization, China University of Geosciences, Beijing 100083, China
TANG Shuling, School of Energy Resources, China University of Geosciences (Beijing), Beijing 100083, Chin; Coal Reservoir Laboratory of National Engineering Research Center of CBM Development & Utilization, China University of Geosciences, Beijing 100083, China
CHEN Shida, School of Energy Resources, China University of Geosciences (Beijing), Beijing 100083, Chin; Coal Reservoir Laboratory of National Engineering Research Center of CBM Development & Utilization, China University of Geosciences, Beijing 100083, China
ZONG Peng, School of Energy Resources, China University of Geosciences (Beijing), Beijing 100083, China
DONG Yu, School of Energy Resources, China University of Geosciences (Beijing), Beijing 100083, China

Abstract

Deep coalbed methane (CBM) boasts abundant resources and great potential for exploitation. However, there is a lack of in-depth studies on the internal connections between deep and shallow CBM. This study investigated the Upper Paleozoic coalbed in the Ordos Basin. From the perspective of coalbed formation and evolution, it obtained three burial depth evolution modes of coalbed through summaries: both the maximum and present burial depths exceeding 2000 m, the maximum burial depth over 2000 m while the present burial depth less than 2000 m, and both the maximum and present burial depths less than 2000 m. This study systematically analyzed the differences in the temperature and pressure conditions, gas content, in-situ stress, reservoir permeability, metamorphic grade, and water content of deep and shallow coal seams, as well as their formation mechanisms. The results indicate that, due to the influence of burial depth and evolutionary process, deep and shallow coal reservoirs show maximum temperature and pressure differences of up to 100°C and about 40 MPa, respectively. As a result, from deep to shallow, the CMB occurrence state transitions from the predominance of adsorbed gas to the coexistence of adsorbed state and free gas, the in-situ stress field shifts from the predominance of horizontal stress to that of vertical stress, and coal reservoirs’ porosity, permeability, and water content gradually decreased. Accordingly, this study ascertained the typical characteristics of deep CBM. Specifically, under high-temperature and high-pressure conditions, deep CBM occurs as coexisting adsorbed and free gas in coal reservoirs below a certain depth. Under the action of predominant vertical stress, the coal reservoirs of deep CBM feature extremely compressed pore and fissure spaces, an extremely low water content, and an extremely high degree of mineralization, with microfissures acting as major seepage channels. Based on the differences in the critical depth for gas-bearing property and the transformation depth of in-situ stress field between deep and shallow coal reservoirs, this study proposed that there exist transitional zones between shallow and deep coal seams, exhibiting the characteristics of atypical deep CBM or the coexistence of geological conditions for deep and shallow CBM. During exploration and exploitation, it is necessary to figure out a tailored scheme based on specific analysis to achieve efficient and coordinated development of shallow and deep CBM.

Keywords

deep CBM, shallow CBM, geological condition, formation mechanism, critical depth, transformation depth

DOI

10.12363/issn.1001-1986.23.10.0693

Reference

[1] 徐凤银,闫霞,李曙光,等. 鄂尔多斯盆地东缘深部(层)煤层气勘探开发理论技术难点与对策[J]. 煤田地质与勘探,2023,51(1):115−130.

XU Fengyin,YAN Xia,LI Shuguang,et al. Theoretical and technological difficulties and countermeasures of deep CBM exploration and development in the eastern edge of Ordos Basin[J]. Coal Geology & Exploration,2023,51(1):115−130.

[2] 姚红生,陈贞龙,何希鹏,等. 深部煤层气“有效支撑”理念及创新实践:以鄂尔多斯盆地延川南煤层气田为例[J]. 天然气工业,2022,42(6):97−106.

YAO Hongsheng,CHEN Zhenlong,HE Xipeng,et al. “Effective support”concept and innovative practice of deep CBM in south Yanchuan gas field of the Ordos Basin[J]. Natural Gas Industry,2022,42(6):97−106.

[3] 邹才能,杨智,黄士鹏,等. 煤系天然气的资源类型、形成分布与发展前景[J]. 石油勘探与开发,2019,46(3):433−442.

ZOU Caineng,YANG Zhi,HUANG Shipeng,et al. Resource types,formation,distribution and prospects of coal–measure gas[J]. Petroleum Exploration and Development,2019,46(3):433−442.

[4] 李瑞明,周梓欣. 新疆煤层气产业发展现状与思考[J]. 煤田地质与勘探,2022,50(3):23−29.

LI Ruiming,ZHOU Zixin. Development status and thoughts on coalbed methane industry in Xinjiang[J]. Coal Geology & Exploration,2022,50(3):23−29.

[5] 郭绪杰,支东明,毛新军,等. 准噶尔盆地煤岩气的勘探发现及意义[J]. 中国石油勘探,2021,26(6):38−49.

GUO Xujie,ZHI Dongming,MAO Xinjun,et al. Discovery and significance of coal measure gas in Junggar Basin[J]. China Petroleum Exploration,2021,26(6):38−49.

[6] 张君峰,毕彩芹,汤达祯,等. 中国煤层气勘探开发探索与实践[M]. 北京:地质出版社,2020.

[7] 李松,汤达祯,许浩,等. 应力条件制约下不同埋深煤储层物性差异演化[J]. 石油学报,2015,36(增刊1):68−75.

LI Song,TANG Dazhen,XU Hao,et al. Evolution of physical differences in various buried depth of coal reservoirs under constraint of stress[J]. Acta Petrolei Sinica,2015,36(Sup.1):68−75.

[8] 赵丽娟,秦勇. 国内深部煤层气研究现状[J]. 中国煤层气,2010,7(2):38−40.

ZHAO Lijuan,QIN Yong. Current status on deep coalbed methane in China[J]. China Coalbed Methane,2010,7(2):38−40.

[9] TONNSEN R R,MISKIMINS J L. Simulation of deep coalbed methane permeability and production assuming variable pore volume compressibility[C]//Proceedings of Canadian Unconventional Resources and International Petroleum Conference. Calgary:Society of Petroleum Engineers,2010.

[10] 谢和平. “深部岩体力学与开采理论”研究构想与预期成果展望[J]. 工程科学与技术,2017,49(2):1−16.

XIE Heping. Research framework and anticipated results of deep rock mechanics and mining theory[J]. Advanced Engineering Sciences,2017,49(2):1−16.

[11] 申建,秦勇,傅雪海,等. 深部煤层气成藏条件特殊性及其临界深度探讨[J]. 天然气地球科学,2014,25(9):1470−1476.

SHEN Jian,QIN Yong,FU Xuehai,et al. Properties of deep coalbed methane reservoir–forming conditions and critical depth discussion[J]. Natural Gas Geoscience,2014,25(9):1470−1476.

[12] CHEN Shida,TANG Dazhen,TAO Shu,et al. Characteristics of in–situ stress distribution and its significance on the coalbed methane (CBM) development in Fanzhuang–Zhengzhuang Block,southern Qinshui Basin,China[J]. Journal of Petroleum Science and Engineering,2018,161:108−120.

[13] WU Shuang,TANG Dazhen,LI Song,et al. Coalbed methane adsorption behavior and its energy variation features under supercritical pressure and temperature conditions[J]. Journal of Petroleum Science and Engineering,2016,146:726−734.

[14] 杨起. 煤地质学进展[M]. 北京:科学出版社,1987.

[15] PASHIN J C. Stratigraphy and structure of coalbed methane reservoirs in the United States:An overview[J]. International Journal of Coal Geology,1998,35(1-4):209−240.

[16] 李增学,魏久传,刘莹. 煤地质学[M]. 北京:地质出版社,2005.

[17] 王双明. 鄂尔多斯盆地叠合演化及构造对成煤作用的控制[J]. 地学前缘,2017,24(2):54−63.

WANG Shuangming. Ordos Basin superposed evolution and structural controls of coal forming activities[J]. Earth Science Frontiers,2017,24(2):54−63.

[18] 孟艳军,汤达祯,许浩,等. 煤层气解吸阶段划分方法及其意义[J]. 石油勘探与开发,2014,41(5):612−617.

MENG Yanjun,TANG Dazhen,XU Hao,et al. Division of coalbed methane desorption stages and its significance[J]. Petroleum Exploration and Development,2014,41(5):612−617.

[19] 秦勇,申建,王宝文,等. 深部煤层气成藏效应及其耦合关系[J]. 石油学报,2012,33(1):48−54.

QIN Yong,SHEN Jian,WANG Baowen,et al. Accumulation effects and coupling relationship of deep coalbed methane[J]. Acta Petrolei Sinica,2012,33(1):48−54.

[20] 李松,汤达祯,许浩,等. 深部煤层气储层地质研究进展[J]. 地学前缘,2016,23(3):10−16.

LI Song,TANG Dazhen,XU Hao,et al. Progress in geological researches on the deep coalbed methane reservoirs[J]. Earth Science Frontiers,2016,23(3):10−16.

[21] LI Song,QIN Yong,TANG Dazhen,et al. A comprehensive review of deep coalbed methane and recent developments in China[J]. International Journal of Coal Geology,2023,279:104369.

[22] ANDERSON E M. The dynamics of faulting and dike formation with application to Britain[M]. Edinburgh:Oliver and Boyd,1951.

[23] 陈世达,汤达祯,陶树,等. 煤层气储层地应力场宏观分布规律统计分析[J]. 煤炭科学技术,2018,46(6):57−63.

CHEN Shida,TANG Dazhen,TAO Shu,et al. Statistic analysis on macro distribution law of geostress field in coalbed methane reservoir[J]. Coal Science and Technology,2018,46(6):57−63.

[24] WANG Jingping,MA Haichun,FENG Peichao,et al. An experimental study on seepage within shale fractures due to confining pressure and temperature[J]. KSCE Journal of Civil Engineering,2021,25(9):3596−3604.

[25] 任战利,祁凯,李进步,等. 鄂尔多斯盆地热动力演化史及其对油气成藏与富集的控制作用[J]. 石油与天然气地质,2021,42(5):1030−1042.

REN Zhanli,QI Kai,LI Jinbu,et al. Thermodynamic evolution and hydrocarbon accumulation in the Ordos Basin[J]. Oil & Gas Geology,2021,42(5):1030−1042.

[26] XU Hao,TANG Dazhen,TANG Shuheng,et al. Geologic and hydrological controls on coal reservoir water production in marine coal–bearing strata:A case study of the Carboniferous Taiyuan Formation in the Liulin area,eastern Ordos Basin,China[J]. Marine and Petroleum Geology,2015,59:517−526.

Share

COinS
 
 

To view the content in your browser, please download Adobe Reader or, alternately,
you may Download the file to your hard drive.

NOTE: The latest versions of Adobe Reader do not support viewing PDF files within Firefox on Mac OS and if you are using a modern (Intel) Mac, there is no official plugin for viewing PDF files within the browser window.