• Chinese Core Periodicals
  • Chinese Core Journals of Science and Technology
  • RCCSE Chinese Authoritative Academic Journals
Email Alert RSS
Advanced Search
LAN Sheng, YIN Yanchun. Research on Influence of Lateral Pressure Coefficient on Hydraulic Fracturing Propagation Law in Coal Body[J]. Safety in Coal Mines, 2020, 51(11): 210-215.
Citation: LAN Sheng, YIN Yanchun. Research on Influence of Lateral Pressure Coefficient on Hydraulic Fracturing Propagation Law in Coal Body[J]. Safety in Coal Mines, 2020, 51(11): 210-215.
shu

Research on Influence of Lateral Pressure Coefficient on Hydraulic Fracturing Propagation Law in Coal Body

More Information
  • Published Date: November 19, 2020
    Graphical Abstract
    • Abstract
  • In order to study the crack initiation characteristics of coal body under different lateral pressure coefficients during hydraulic fracturing, a fluid-solid coupling model of coal body is established by using particle flow software PFC2D. The law of crack propagation and the influence of lateral pressure coefficient on fracture propagation and kinetic energy evolution were analyzed. The results show that: hydraulic fracturing failure form of coal body is tensile shear failure. The cracks near to the injection hole are mainly caused by tensile failure. And the cracks farther from the injection hole produce more shear failure. When lateral pressure coefficient is in the range of 1.6 to 3.4, the crack initiation pressure decreases as the lateral pressure coefficient increases. Tthe hydraulic crack extension distance increases with the increase of the lateral pressure coefficient in the same time. When λ≥2.8,the fracture extends along the diagonal of the coal sample after turning. Its expansion rate shows a change from fast to slow. When the lateral pressure coefficient is increased, it not only promotes the development of hydraulic fractures, but also increases the expansion rates. However, with the increase of the lateral pressure coefficient, its influence on the fracture propagation rate gradually decreases.
    • FullText(HTML)
    • References (15)
  • [1]
    郭印同,杨春和,贾长贵,等.页岩水力压裂物理模拟与裂缝表征方法研究[J].岩石力学与工程学报,2014,33(1):52-59.
    [2]
    衡帅,杨春和,曾义金,等.页岩水力压裂裂缝形态的试验研究[J].岩土工程学报,2014,36(7):1243.
    [3]
    王磊,杨春和,郭印同,等.基于室内水力压裂试验的水平井起裂模式研究[J].岩石力学与工程学报,2015, 34(S2):3624-3632.
    [4]
    侯振坤,杨春和,王磊,等.大尺寸真三轴页岩水平井水力压裂物理模拟试验与裂缝延伸规律分析[J].岩土力学,2016,37(2):407-414.
    [5]
    张旭,蒋廷学,贾长贵,等.页岩气储层水力压裂物理模拟试验研究[J].石油钻探技术,2013,41(2):70.
    [6]
    姜福兴,王博,翟明华,等.煤层超高压定点水力压裂防冲试验研究[J].岩土工程学报,2015,37(3):526.
    [7]
    武鹏飞.煤岩复合体水压致裂裂纹扩展规律试验研究[D].太原:太原理工大学,2017.
    [8]
    王维德.煤体水力压裂声发射监测及失稳破裂特征实验研究[D].淮南:安徽理工大学,2016.
    [9]
    严成增,郑宏,孙冠华,等.基于FDEM-Flow研究地应力对水力压裂的影响[J].岩土力学,2016,37(1):237-246.
    [10]
    门晓溪.岩体渗流-损伤耦合及其水力压裂机理数值试验研究[D].沈阳:东北大学,2015.
    [11]
    师访.岩石破裂过程的扩展有限元法研究[D].徐州:中国矿业大学,2015.
    [12]
    吕天奇.基于颗粒流的花岗岩水力压裂数值模拟及试验研究[D].长春:吉林大学,2018.
    [13]
    赵同彬,尹延春,谭云亮,等.锚杆界面力学试验及剪应力传递规律细观模拟分析[J].采矿与安全工程学报,2011,28(2):220-224.
    [14]
    赵同彬,尹延春,谭云亮,等.基于颗粒流理论的煤岩冲击倾向性细观模拟试验研究[J].煤炭学报,2014, 39(2):280-285.
    [15]
    Yanchun Y, Yunliang T, Yanwei L, et al. Numerical Research on Energy Evolution and Burst Behavior of Unloading Coal Rock Composite Structures[J]. Geotechnical and Geological Engineering, 2018(6): 295-303
    • Related Articles

  • Related Articles

    [1]LIU Maoqi, LIU Ping, ZHU Hengzhong, WANG Chen, WANG Chunhua. Study on stability of mining landslide in shallow coal seam based on numerical analysis[J]. Safety in Coal Mines, 2021, 52(2): 225-230.
    [2]KONG Dezhong, ZHENG Shangshang, HAN Chenghong, LOU Yahui, PU Shijiang. Stability Analysis of End Face in Close Coal Seam Group Under Repeated Mining[J]. Safety in Coal Mines, 2019, 50(11): 220-223.
    [3]XIE Fuxing, DONG Shizhuo, LIU Yang, LIANG Zhipeng, GUO Peng. Numerical Simulation on Surrounding Rock Stability of Gob-side Entry in Large Height Mining Face[J]. Safety in Coal Mines, 2018, 49(11): 215-219,223.
    [4]ZHAO Jian, ZHENG Zhiyang, LIU Leibin. Study on Stress and Stability of Coal Wall in Fully-mechanized Working Face with Large Mining Height[J]. Safety in Coal Mines, 2018, 49(1): 164-167.
    [5]SONG Xuefeng, MA Wenqiang, WANG Tongxu, JIANG Zilong, ZHANG Heng. Numerical Simulation of Failure Mechanism of Weakly Bonded Rock Beam in Regeneration Roof[J]. Safety in Coal Mines, 2017, 48(10): 182-185,190.
    [6]ZHANG Baodong. Research on Roof Rock Pressure Laws During Anshun Mine 9103 Fully Mechanized Face Passing Through Fault[J]. Safety in Coal Mines, 2017, 48(3): 137-139.
    [7]HU Tao, ZHAO Deshen. Similarity Simulation of Water-inrush from Reverse Fault Roof Under Mining Effect[J]. Safety in Coal Mines, 2017, 48(2): 52-55.
    [8]ZHANG Shoubao, WANG Zhiliu, XUE Shanbin, ZHANG Yupeng, YANG Guangtong. Influence of Top Coal Thickness on End-face Stability of Fully Mechanized Mining Face with Large Mining Height[J]. Safety in Coal Mines, 2015, 46(3): 197-2000.
    [9]ZHANG Xiaoqiang, WANG An, GONG Peilin, WANG Kai. Structure and Stability Analysis of Surrounding Rock During Working Face Crossing Old Mining Area[J]. Safety in Coal Mines, 2014, 45(11): 180-182,186.
    [10]ZHENG Wenxiang. Study on Stability and Dynamic Characteristics of Roof in Mining Face Crossing Abandoned Roadways[J]. Safety in Coal Mines, 2014, 45(4): 51-53,57.

Catalog

    Get Citation
    XML
    Article views (13) PDF downloads (0) Cited by()
    Turn off MathJax
    Article Contents
    Abstract
    References
    Related Articles
    Links

    辽公网安备 21049802000106号 辽ICP备11020636号-9

    Website Copyright © CCTEG Shenyang Research Institute

    Address:No. 11 Binhe Road, Fushun Economic Development Zone, Liaoning Postal Code:113122

    Tel:024-56616988/56616881 Email:mkaq@163.com

    Supported by: Beijing Renhe Information Technology Co., Ltd. Baidu Analytics

    /

    DownLoad:  Full-Size Img  PowerPoint
    Return
    Return