Coal Geology & Exploration
Abstract
In order to study the characteristics of coalbed methane accumulation and production controlling factors in the northeastern Qinshui Basin, based on the data of coalbed methane drilling and drainage in the Sijiazhuang area, the geological structure, coal seam thickness and buried depth, maceral of the Sijiazhuang coals are analyzed. The geological control mechanism of gas-bearing coal reservoirs is studied, combined with the fracturing and drainage technology of coal-bed methane wells, the production characteristics of coal-bed methane and its influencing factors are discussed. The results show that: (1) The gas-bearing properties of coal reservoirs in the study area are greatly affected by geological structure. In the fold axis and lateral structural compression zone, the gas content is often high, especially in the syncline axis. Under the superimposed action of the collapse column and hydrogeological conditions, the gas content of the No.15 coal seam is lower than that of the No.8 and No.9 coal seams, and the gas saturation of the No.8 and No.9 coal seams is also higher than that of the No.15 coal seam. (2) The gas content of the No.8 , No.9 and No.15 coal seams in the study area all show a trend of increasing with the increase of the coal seam depth, but with the increase of the coal seam depth, the effects of tectonic stress and geothermal field gradually increase, and there is “critical depth” that varies with buried depth(approximately about 700 m). The gas content of coal seams also shows a trend of increasing with the increase of coal seam thickness. The simpler the coal seam structure, the better the coal seam gas content. (3) The area where the NNE-NE trending fold and the EW trending structure are superimposed in the middle of the study area has become a high production area of coalbed methane due to its larger structural curvature and relatively relaxed regional in-situ stress, which has good permeability conditions and gas-bearing properties. (4) Adopting partial pressure combined mining technology in areas with multiple coal seams can effectively increase gas production. Multiple coal seams can provide sufficient gas sources for high productivity of coalbed methane wells, and simultaneous drainage and pressure reduction of multiple layers can produce gas from different coal reservoirs. Production capacity superposition, realize long-term stable production, and long-term sustained high-yield wells can appear in areas where gas-bearing properties are good and free gas may exist.
Funding Information
10.12363/issn.1001-1986.21.12.0756
Keywords
gas content of coal seam, productivity controlling factors, geological structure, collapse column, hydrogeological condition, Qinshui Basin, Sijiazhuang area
Recommended Citation
LI Guofu, ZHANG Wei, LI Meng,
et al.
(2022)
"Gas content and productivity controlling factors of coal reservoir in Sijiazhuang area, Qinshui Basin,"
Coal Geology & Exploration: Vol. 50:
Iss.
3, Article 16.
Available at:
https://cge.researchcommons.org/journal/vol50/iss3/16
Reference
[1] 张遂安,张典坤,彭川,等. 中国煤层气产业发展障碍及其对策[J]. 天然气工业,2019,39(4):118−124. ZHANG Sui’an,ZHANG Diankun,PENG Chuan,et al. Obstacles to the development of CBM industry and countermeasures in China[J]. Natural Gas Industry,2019,39(4):118−124.
[2] 孙钦平,赵群,姜馨淳,等. 新形势下中国煤层气勘探开发前景与对策思考[J]. 煤炭学报,2021,46(1):65−76. SUN Qinping,ZHAO Qun,JIANG Xinchun,et al. Prospects and strategies of CBM exploration and development in China under the new situation[J]. Journal of China Coal Society,2021,46(1):65−76.
[3] 孙粉锦,王勃,李梦溪,等. 沁水盆地南部煤层气富集高产主控地质因素[J]. 石油学报,2014,35(6):1070−1079. SUN Fenjin,WANG Bo,LI Mengxi,et al. Major geological factors controlling the enrichment and high yield of coalbed methane in the southern Qinshui Basin[J]. Acta Petrolei Sinica,2014,35(6):1070−1079.
[4] 徐凤银,闫霞,林振盘,等. 我国煤层气高效开发关键技术研究进展与发展方向[J/OL]. 煤田地质与勘探,2022:1–15[2021–12–22]. http://kns.cnki.net/kcms/detail/61.1155.p.20211220.1747.006.html.
XU Fengyin,YAN Xia,LIN Zhenpan,et al. Research progress and development direction of key technologies for efficient development of coalbed methane in China[J]. Coal Geology & Exploration,2022:1−15[2021−12−22]. http://kns.cnki.net/kcms/detail/61.1155.p.20211220.1747.006.html.
[5] 陈召英,王保玉,郝海金,等. 寺河区块煤层气井排采特征及抽采效果分析[J]. 煤炭科学技术,2017,45(7):100−105. CHEN Zhaoying,WANG Baoyu,HAO Haijin,et al. Analysis on drainage features and drainage effect of coalbed methane well in Sihe block[J]. Coal Science and Technology,2017,45(7):100−105.
[6] 郭盛强. 成庄区块煤层气井产气特征及控制因素研究[J]. 煤炭科学技术,2013,41(12):100−104. GUO Shengqiang. Study on coalbed methane well production characteristics and control factors in Chengzhuang block[J]. Coal Science and Technology,2013,41(12):100−104.
[7] 于振锋,郝春生,杨昌永,等. 阳泉矿区寺家庄井田太原组煤层气地球化学特征及成因[J]. 煤田地质与勘探,2019,47(3):91−96. YU Zhenfeng,HAO Chunsheng,YANG Changyong,et al. Genesis and geochemical characteristics of coalbed methane from Taiyuan Formation in Sijiazhuang mine field of Yangquan mining area[J]. Coal Geology & Exploration,2019,47(3):91−96.
[8] 于振锋,郝春生,李子健,等. 寺家庄井田含煤地层煤层气赋存层位研究[J]. 煤炭技术,2019,38(3):51−53. YU Zhenfeng,HAO Chunsheng,LI Zijian,et al. Study on occurrence layer of CBM in coal bearing strata of Sijiazhuang minefield[J]. Coal Technology,2019,38(3):51−53.
[9] 杨昌永,郝春生,田庆玲,等. 沁水煤田东北部15号煤储层物性及特征研究[J]. 煤炭工程,2019,51(6):11−17. YANG Changyong,HAO Chunsheng,TIAN Qingling,et al. Research on physical properties and characteristics of No.15 coal reservoir in the northeast of Qinshui coal field[J]. Coal Engineering,2019,51(6):11−17.
[10] 杨昌永,郝春生,李瑾,等. 寺家庄井田地温负异常及其主控因素[J]. 煤田地质与勘探,2018,46(6):74−80. YANG Changyong,HAO Chunsheng,LI Jin,et al. Negative geothermal anomaly and its main geological controlling factors in Sijiazhuang minefield[J]. Coal Geology & Exploration,2018,46(6):74−80.
[11] 田庆玲. 阳泉区块寺家庄井田分压合层排采适应性探讨[J]. 山西焦煤科技,2016,40(1):46−48. TIAN Qingling. Research on the adaptability of layered fracture and multi–layer drainage in Sijiazhuang mine field of Yangquan block[J]. Shanxi Coking Coal Science & Technology,2016,40(1):46−48.
[12] 秦勇,叶建平,林大扬,等. 煤储层厚度与其渗透性及含气性关系初步探讨[J]. 煤田地质与勘探,2000,28(1):24−27. QIN Yong,YE Jianping,LIN Dayang,et al. Relationship of coal reservoir thickness and its permeability and gas−bearing property[J]. Coal Geology & Exploration,2000,28(1):24−27.
[13] 张永平,杨艳磊,邵国良,等. 沁水盆地煤层结构及煤岩储层特征研究[J]. 煤炭科学技术,2017,45(4):131−136. ZHANG Yongping,YANG Yanlei,SHAO Guoliang,et al. Study on coal seam structure and properties of coal reservoirs in Qinshui Basin[J]. Coal Science and Technology,2017,45(4):131−136.
[14] 王国玲,秦勇. 煤储层含气性特征及其地质动力学控制因素[J]. 中国煤炭地质,2009,21(2):18−23. WANG Guoling,QIN Yong. Gas–bearing characteristics of coal reservoirs and their geological dynamic controlling factors[J]. Coal Geology of China,2009,21(2):18−23.
[15] 张松航,汤达祯,唐书恒,等. 鄂尔多斯盆地东缘煤层气储集与产出条件[J]. 煤炭学报,2009,34(10):1297−1304. ZHANG Songhang,TANG Dazhen,TANG Shuheng,et al. Preservation and deliverability characteristics of coalbed methane in east margin of Ordos Basin[J]. Journal of China Coal Society,2009,34(10):1297−1304.
[16] 王剑英. 寺家庄井田8号煤层气储层物性特征研究[J]. 煤,2019,28(11):5−8. WANG Jianying. Physical properties characteristics of the No.8 coalbed methane reservoirs in Sijiazhuang minefield[J]. Coal,2019,28(11):5−8.
[17] 秦勇,申建. 论深部煤层气基本地质问题[J]. 石油学报,2016,37(1):125−136. QIN Yong,SHEN Jian. On the fundamental issues of deep coalbed methane geology[J]. Acta Petrolei Sinina,2016,37(1):125−136.
[18] 谢和平,高峰,鞠杨,等. 深部开采的定量界定与分析[J]. 煤炭学报,2015,40(1):1−10. XIE Heping,GAO Feng,JU Yang,et al. Quantitative definition and investigation of deep mining[J]. Journal of China Coal Society,2015,40(1):1−10.
[19] 秦勇,宋全友,傅雪海. 煤层气与常规油气共采可行性探讨:深部煤储层平衡水条件下的吸附效应[J]. 天然气地球科学,2005,16(4):492−498. QIN Yong,SONG Quanyou,FU Xuehai. Discussion on reliability for co–mining the coalbed gas and normal petroleum and natural gas–absorptive effect of deep coal reservoir under condition of balanced water[J]. Natural Gas Geoscience,2005,16(4):492−498.
[20] 徐占杰,刘钦甫,宋璞,等. 寺家庄井田陷落柱对煤层气井产出水地球化学特征的影响[J]. 煤田地质与勘探,2017,45(2):50−54. XU Zhanjie,LIU Qinfu,SONG Pu,et al. Effect of karstic collapse column on hydrogeochemistry of produced water from coalbed methane wells in Sijiazhuang mine field[J]. Coal Geology & Exploration,2017,45(2):50−54.
[21] 侯晓伟. 沁水盆地深部煤系气储层控气机理及共生成藏效应[D]. 徐州:中国矿业大学,2020.
HOU Xiaowei. Study on gas controlling mechanism and coupled accumulation of deep coal measure gases in Qinshui Basin[D]. Xuzhou:China University of Mining and Technology,2020.
[22] 赵庆波. 煤层气地质与勘探技术[M]. 北京:石油工业出版社,1999.
[23] 秦勇. 中国煤层气地质研究进展与述评[J]. 高校地质学报,2003,9(3):339−358. QIN Yong. Advances and reviews on research of coalbed gas geology in China[J]. Geological Journal of China Universities,2003,9(3):339−358.
[24] 闫霞,徐凤银,聂志宏,等. 深部微构造特征及其对煤层气高产“甜点区”的控制:以鄂尔多斯盆地东缘大吉地区为例[J]. 煤炭学报,2021,46(8):2426−2439. YAN Xia,XU Fengyin,NIE Zhihong,et al. Microstructure characteristics of Daji area in east Ordos Basin and its control over the high yield dessert of CBM[J]. Journal of China Coal Society,2021,46(8):2426−2439.
[25] 秦勇,姜波,王继尧,等. 沁水盆地煤层气构造动力条件耦合控藏效应[J]. 地质学报,2008,82(10):1355−1362. QIN Yong,JIANG Bo,WANG Jiyao,et al. Coupling control of tectonic dynamical conditions of coalbed methane reservoir formation in the Qinshui Basin,Shanxi,China[J]. Acta Geologica Sinica,2008,82(10):1355−1362.
[26] 张小东,杜志刚,李朋朋. 不同煤体结构的高阶煤储层物性特征及煤层气产出机理[J]. 中国科学:地球科学,2017,47(1):72−81. ZHANG Xiaodong,DU Zhigang,LI Pengpeng. Physical characteristics of high–rank coal reservoirs in different coal–body structures and the mechanism of coalbed methane production[J]. Scientia Sinica (Terrae),2017,47(1):72−81.
[27] 乔茂坡,胡秋嘉,窦武,等. 煤体结构分布规律及其对产量的控制作用:以沁水盆地南部长治WY井区为例[C]// 2015年全国天然气学术年会. 武汉,2015.
[28] 郭涛,高小康,孟贵希,等. 织金区块煤层气合采生产特征及开发策略[J]. 煤田地质与勘探,2019,47(6):14−19. GUO Tao,GAO Xiaokang,MENG Guixi,et al. Combined CBM production behavior and development strategy of multiple coal seams in Zhijin block[J]. Coal Geology & Exploration,2019,47(6):14−19.
[29] 刘江,桑树勋,周效志,等. 六盘水地区煤层气井合层排采实践与认识[J]. 煤田地质与勘探,2020,48(3):93−99. LIU Jiang,SANG Shuxun,ZHOU Xiaozhi,et al. Practice and understanding of multi−layer drainage of CBM wells in Liupanshui area[J]. Coal Geology & Exploration,2020,48(3):93−99.
[30] 许耀波. 煤层气井合层开发层间干扰分析与合采方法探讨:以平顶山首山一矿为例[J]. 煤田地质与勘探,2021,49(3):112−117. XU Yaobo. Analysis of interlayer interference in combined development of coalbed methane wells and discussion on combined production methods:A case study of Shoushan No.1 Coal Mine in Pingdingshan[J]. Coal Geology & Exploration,2021,49(3):112−117.
[31] 李忠城,唐书恒,王晓锋,等. 沁水盆地煤层气井产出水化学特征与产能关系研究[J]. 中国矿业大学学报,2011,40(3):424−429. LI Zhongcheng,TANG Shuheng,WANG Xiaofeng,et al. Relationship between water chemical composition and production of coalbed methane wells,Qinshui Basin[J]. Journal of China University of Mining & Technology,2011,40(3):424−429.
Included in
Earth Sciences Commons, Mining Engineering Commons, Oil, Gas, and Energy Commons, Sustainability Commons