ZHAO Jizhan, ZHANG Qun, ZHANG Peihe. C Coalbed methane reservoir model under mining conditions and its application[J]. COAL GEOLOGY & EXPLORATION, 2017, 45(6): 34-39. DOI: 10.3969/j.issn.1001-1986.2017.06.006
Citation: ZHAO Jizhan, ZHANG Qun, ZHANG Peihe. C Coalbed methane reservoir model under mining conditions and its application[J]. COAL GEOLOGY & EXPLORATION, 2017, 45(6): 34-39. DOI: 10.3969/j.issn.1001-1986.2017.06.006

C Coalbed methane reservoir model under mining conditions and its application

Funds: 

National Science and Technology Major Project(2011ZX05040-002)

More Information
  • Received Date: April 12, 2016
  • Published Date: December 24, 2017
  • In order to realize the numerical simulation of coalbed methane reservoir under mining conditions, the geological model of coalbed methane development under mining conditions is generalized, the mathematical model of coalbed methane reservoir under mining condition is constructed, through the secondary exploration of CBM-SIM software, the numerical simulation of coalbed methane reservoir under mining conditions is realized. In the process, the formula of reservoir permeability change curve under mining condition is established based on the formula of variation curve of strata separation, the variation formula of water loss in reservoir is established based on the variation law of water level. By the time card mechanism, the dynamic solution of permeability and leakage water quantity of coal reservoir is made, and the call assignment of coefficients and boundary conditions in the iteration process is solved. The coupling calculation of the dynamic change of permeability with mining influence, the reservoir water leakage and reservoir gas production is realized. By using the software development, the production data of coalbed methane extraction well under mining conditions in Huainan mining area are simulated by historical and yield prediction. The production curve is consistent in shape, and the coefficient of judgment is 0.92. Good simulation results have been achieved.
  • [1]
    BUMB A C,MCKEE C R. Gas-well testing in the presence of desorption for coalbed methane and Devonian shale[J]. SPEFE, 1988,3(1):179-185.
    [2]
    SMITH D M,WILLIAMS F L. Diffusional effects in the recovery of methane from coalbeds[J]. Society of Petroleum Engineers Journal,1984,24(10):529-535.
    [3]
    RUCKENSTEIN E,VAIDYANATHAN A S,YOUNGQUIST G R. Sorption by solid withbidisperse pore structures[J]. Chemical Engineering Science,1971,26(9):1305-1318.
    [4]
    PAUL G W,SAWYER W K,DEAN R H. Validation of 3D coalbed simulators[C]//SPE Annual Technical Conference and Exhibition,SPE 20733-MS. New Orleans,Louisiana:Society of Petroleum Engineers,1990.
    [5]
    Advanced Resources International,Inc. COMET2 version 2.1 user's guide[M]. Washington,DC,USA:Advanced Resources International,Inc.,2000.
    [6]
    杨天鸿,徐涛,刘建新,等. 应力-损伤-渗流耦合模型及在深部煤层瓦斯卸压实践中的应用[J]. 岩石力学与工程学报, 2005,24(16):2900-2905.

    YANG Tianhong,XU Tao,LIU Jianxin,et al. Coupling model of stress-damage-flow and its application to the investigation of instantaneous seepage mechanism for gas during unloading in coal seam with depth[J]. Chinese Journal of Rock Mechanics and Engineering,2005,24(16):2900-2905.
    [7]
    李树刚. 综放开采围岩活动影响下瓦斯运移规律及其控制[J]. 岩石力学与工程学报,2000,19(6):809-810.

    LI Shugang. Gas delivery feature and its control influenced by movement of the surrounding rock in fully-mechanized top coal caving[J]. Chinese Journal of Rock Mechanics and Engineering, 2000,19(6):809-810.
    [8]
    涂敏,付宝杰. 低渗透性煤层卸压瓦斯抽采机理研究[J]. 采矿与安全工程学报,2009,26(4):433-436.

    TU Min,FU Baojie. Extraction mechanism of relieved gas from low permeability seam[J]. Journal of Mining & Safety Engineering,2009,26(4):433-436.
    [9]
    尹光志,李铭辉,李生舟,等. 基于含瓦斯煤岩固气耦合模型的钻孔抽采瓦斯三维数值模拟[J]. 煤炭学报,2013,38(4):535-541.

    YIN Guangzhi,LI Minghui,LI Shengzhou,et al. 3D numerical simulation of gas drainage from boreholes based on solid-gas coupling model of coal containing gas[J]. Journal of Chinese Coal Society,2013,38(4):535-541.
    [10]
    谢和平,高峰,周宏伟,等. 煤与瓦斯共采中煤层增透率理论与模型研究[J]. 煤炭学报,2013,38(7):1101-1108.

    XIE Heping,GAO Feng,ZHOU Hongwei,et al. On theoretical and modeling approach to mining enhanced permeability for simultaneous exploitation of coal and gas[J]. Journal of China Coal Society,2013,38(7):1101-1108.
    [11]
    孙海涛,郑颖人,胡千庭,等. 地面钻井套管耦合变形作用机理[J]. 煤炭学报,2011,36(5):823-829.

    SUN Haitao,ZHENG Yingren,HU Qianting,et al. Surface borehole casing coupling deformation mechanism[J]. Journal of Chinese Coal Society,2011,36(5):823-829.
    [12]
    李日富,梁运培,张军. 地面钻孔抽采采空区瓦斯效率影响因素[J]. 煤炭学报,2009,34(7):942-946.

    LI Rifu,LIANG Yunpei,ZHANG Jun. Influencing factors to extraction efficiency of surface goaf hole[J]. Journal of Chinese Coal Society,2009,34(7):942-946.
    [13]
    胡千庭,梁运培,林府进. 采空区瓦斯地面钻孔抽采技术试验研究[J]. 中国煤层气,2006,3(2):3-6.

    HU Qianting,LIANG Yunpei,LIN Fujin. Test of drawing technology on surface borehole in coal mine goal[J]. China Coalbed Methane,2006,3(2):3-6.
    [14]
    张群. 煤层气储层数值模拟模型及应用的研究[D]. 西安:煤炭科学研究总院西安分院,2003.
    [15]
    钱鸣高,缪协兴. 采场上覆岩结构形态与受力分析[J]. 岩石力学与工程学报,1995,14(2):97-106.

    QIAN Minggao,MIAO Xiexing. Theoretical analysis on the structural form and stability of overlying strata in longwall mining[J]. Chinese Journal of Rock Mechanics and Engineering, 1995,14(2):97-106.
    [16]
    袁亮. 低透高瓦斯煤层群安全开采关键技术研究[J]. 岩石力学与工程学报,2008,27(7):1370-1379.

    YUAN Liang. Key technique of safe mining in low permeability and methane-rich seam group[J]. Chinese Journal of Rock Mechanics and Engineering,2008,27(7):1370-1379.
    [17]
    钱鸣高,缪协兴,许家林. 岩层控制中的关键层理论研究[J]. 煤炭学报,1996,21(3):225-230.

    QIAN Minggao,MIAO Xiexing,XU Jialin. Theoretical study of key stratum in ground control[J]. Journal of Chinese Coal Society,1996,21(3):225-230.
    [18]
    缪协兴,茅献彪,胡光伟,等. 岩石(煤)的碎胀与压实特性研究[J]. 实验力学,1997,12(3):394-399.

    MIAO Xiexing,MAO Xianbiao,HU Guangwei,et al. Research on broken expand and press solid characteristics of rocks and coals[J]. Journal of Experimental Mechanics,1997,12(3):394-399.
  • Cited by

    Periodical cited type(14)

    1. 王大兴,胡海燕,邹佳群,王涛,朱根根,陈笑宇,梁烁. 准噶尔盆地东道海子凹陷二叠系下乌尔禾组陆相页岩气形成富集条件及主控因素. 地质科技通报. 2024(04): 98-112 .
    2. 任诺,宋怀雷,杨超,王文涛. 页岩在水压致裂过程中破裂规律的数值模拟研究. 水利规划与设计. 2023(01): 101-107 .
    3. 邱凯旋,李恒,郝世彦,张丽霞,唐永槐,马玉珊. 含砂岩薄互层陆相页岩气藏生产预测模型研究. 非常规油气. 2023(01): 111-121 .
    4. 李泽帆,陈相霖,李树刚,郭睿良,李泳,刘鹏. 高—过成熟页岩CH_4/N_2/CO_2混合气体竞争吸附特征与地质意义. 天然气地球科学. 2023(01): 169-180 .
    5. 魏若飞,信凯. 鄂尔多斯盆地东缘石西区块煤层气及致密砂岩气资源潜力评价. 中国煤炭地质. 2022(07): 7-11+38 .
    6. 李海,赵昌杰,王文涛. 不同层理倾角与石英含量下页岩破裂过程数值试验研究. 水利规划与设计. 2022(11): 108-113+167 .
    7. 李浩. 延长探区南部盒8段稀土元素地球化学示踪. 云南化工. 2021(06): 129-132 .
    8. 陆雨诗,胡勇,侯云东,孙继峰,何文祥,高小洋,司锦,宋雯馨. 鄂尔多斯盆地西缘羊虎沟组微量元素地球化学特征及沉积环境指示意义. 科学技术与工程. 2021(28): 11999-12009 .
    9. 客昆,秦建华,牟必鑫,余谦,魏洪刚,郝学峰,陈杨,客达,周家云,龚大兴. 楚雄盆地上三叠统舍资组泥页岩储层特征分析——以滇禄地3井为例. 科学技术与工程. 2021(28): 12020-12030 .
    10. 娄义黎,邬忠虎,王安礼,左宇军,刘镐,孙文吉斌. 流固耦合作用下页岩破裂过程的数值模拟. 煤田地质与勘探. 2020(01): 105-112 . 本站查看
    11. 王羽,汪丽华,王建强,王彦飞. 利用微米X射线显微镜研究陆相延长组页岩孔隙结构特征. 岩矿测试. 2020(04): 566-577 .
    12. 和钰凯,李贤庆,魏强,张学庆,邹晓艳,张亚超,李阳阳. 淮南潘谢矿区石盒子组煤系页岩气储层孔隙结构特征及影响因素. 科学技术与工程. 2020(33): 13618-13627 .
    13. 孙细宁,陈奕奕,王桂成,姜呈馥,许小强. 延长探区陆相页岩气产能影响因素分析. 复杂油气藏. 2019(04): 8-14 .
    14. 景丰. 陆相页岩气水平井中增韧防气窜固井水泥浆体系的研究. 石油化工应用. 2018(07): 5-10 .

    Other cited types(5)

Catalog

    Article Metrics

    Article views (78) PDF downloads (9) Cited by(19)
    Related

    /

    DownLoad:  Full-Size Img  PowerPoint
    Return
    Return