水力压裂起裂与扩展分析

摘要
图/表
参考文献
相关文章 (15)

全文: PDF (0 KB) HTML (1 KB)
输出: BibTeX | EndNote (RIS)

摘要水力压裂起裂与扩展压力的确定是压裂设计最为重要的参数之一，与水平孔或垂直孔水力压裂相比，任意方向钻孔水力压裂的起裂与扩展更加复杂。根据最大拉应力准则，分析任意方向钻孔裂缝起裂压力及起裂方向，得出量纲一起裂压力(pb/?v)随钻孔方位角和钻孔倾斜角的变化规律；并以王台铺煤矿顶板岩层水力压裂为例，进行起裂压力与起裂位置计算，通过有限元计算分析扩展压力较大的原因。研究结果如下：(1) 当水平主应力相等时，钻孔从垂直方向逐渐旋转至水平方向过程中，所需起裂压力不断减小，水平孔由?h方向逐渐旋转至?H方向过程中，裂缝起裂压力保持不变；(2) 随着?H/?h或?H/?v的增大，裂缝起裂压力的变化规律与地应力场类型密切相关；(3) 钻孔由垂直方向转向水平方向过程中，对于3种类型的应力场(正断层型、平滑断层型、逆断层型)，裂缝起裂压力有着各自独特的变化规律；(4) 水平孔由?h方向逐渐旋转至?H方向过程中，对于不同类型的应力场，合理布置钻孔方向可使起裂压力最小；(5) 当岩石抗拉强度与地应力大小相近时，增大抗拉强度使裂缝起裂所需的压力明显增大；(6) 有限元计算结果表明，裂缝起裂后旋转扩展会导致较高的扩展压力；(7) 在进行水力压裂作业时，地应力的大小、方向和类型是进行钻孔参数设计的基础。

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章

关键词 ：岩石力学, 任意倾斜钻孔, 水力压裂, 裂缝起裂与扩展, 钻孔倾角, 钻孔方位角, 地应力类型

Abstract：The initiation pressure and propagation pressure are essential to hydraulic fracturing operation. The initiation and propagation of an arbitrarily inclined borehole is considered more complicated compared with a horizontal or vertical borehole. By means of maximum tensile stress criterion，initiation pressure and orientation are analyzed and dimensionless initiation pressure(pb/?v) varying with borehole azimuth and inclination is obtained. With regard to hydraulic fracturing treatment carried out in the roof of Wangtaipu coal mine，initiation pressure and corresponding location are calculated. Finite element method is employed to explain the excessive propagation pressure during the fracturing process. The results are that：(1) When ?h = ?H，initiation pressure keeps ever-reduced as borehole rotates gradually from vertical direction to horizontal direction and maintains constant as borehole rotates from ?h direction to ?H direction. (2) Change rule of initiation pressure is closely related to in-situ stress regime with increase of ?H/?h or ?H/?v. (3) During the process of borehole rotating from vertical to horizon，initiation pressure performs uniquely subjected to normal faulting stress regime，striking slip faulting regime and reversing faulting stress regime，respectively. (4) The horizontal borehole direction requiring minimum initiation pressure exists for corresponding in-situ stress regime as it rotates from ?h direction to ?H direction. (5) Initiation pressure increases dramatically with the growth of rock tensile strength as it is close to the magnitude of in-situ stress. (6) The fracture turning during propagation would generate high pressure. (7) The magnitude，direction and type of in-situ stress are the groundwork for borehole design of hydraulic fracturing operation.

Key words： rock mechanics arbitrarily inclined borehole hydraulic fracturing fracture initiation and propagation borehole inclination borehole azimuth in-situ stress type

收稿日期: 2012-09-10

引用本文:

冯彦军1，2，3，康红普1，2. 水力压裂起裂与扩展分析[J]. 岩石力学与工程学报, 2013, 32(s2): 3169-3179.
FENG Yanjun1，2，3，KANG Hongpu1，2. HYDRAULIC FRACTURING INITIATION AND PROPAGATION. , 2013, 32(s2): 3169-3179.

链接本文:

http://www.rockmech.org/CN/Y2013/V32/Is2/3169

[3]	蔺海晓，杜春志. 煤岩拟三轴水力压裂实验研究[J]. 煤炭学报. 2011，36(11)：1 801-1 805.(LIN Haixiao，DU Chunzhi. Experimental research on the quasi three-axis hydraulic fracturing of coal[J]. Journal of China Coal Society，2011，36(11)：1 801-1 805.(in Chinese)) " target="_blank">
[4]	闫少宏，宁宇，康立军，等. 用水力压裂处理坚硬顶板的机制及实验研究[J]. 煤炭学报，2000，25(1)：32-35.(YAN Shaohong，NING Yu，KANG Lijun，et al. The mechanism of hydrobreakage to control hard roof and its test study[J]. Journal of China Coal Society，2000，25(1)：32-35.(in Chinese)) " target="_blank">
[7]	富向. 井下点式水力压裂增透技术研究[J]. 煤炭学报，2011，36(8)：1 318-1 321.(FU Xiang. Study of underground point hydraulic fracturing increased permeability technology[J]. Journal of China Coal Society，2011，36(8)：1 318-1 321.(in Chinese)) " target="_blank">
[8]	翟成，李贤忠，李全贵. 煤层脉动水力压裂卸压增透技术研究与应用[J]. 煤炭学报，2011，36(12)：1 996-2 001.(ZHAI Cheng，LI Xianzhong，LI Quangui. Research and application of coal seam pulse hydraulic fracturing technology[J]. Journal of China Coal Society，2011，36(12)：1 996-2 001.(in Chinese)) " target="_blank">
[10]	盛金昌，赵坚，速宝玉. 高水头作用下水工压力隧洞的水力劈裂分析[J]. 岩石力学与工程学报，2005，24(7)：1 226-1 230.(SHENG Jinchang，ZHAO Jian，SU Baoyu. Analysis of hydraulic fracturing in hydraulic tunnels under high water pressure[J]. Chinese Journal of Rock Mechanics and Engineering，2005，24(7)：1 226-1 230.(in Chinese)) " target="_blank">
[13]	徐芝纶. 弹性力学(上册)[M]. 4版. 北京：高等教育出版社，2006：63-77.(XU Zhilun. Elasticity(volume I)[M]. 4th ed. Beijing：Higher Education Press，2006：63-77.(in Chinese)) " target="_blank">
[14]	HASHIN Z，ROSEN B W. The elastic moduli of fiber-reinforced materials[J]. Journal of Applied Mechanics，1964，31(2)：223-232. " target="_blank">
[17]	HAIMSON B，FAIRHURST C. Hydraulic fracturing in porous- permeable materials[J]. Journal of Petroleum Technology，1969，21(7)：811-817. " target="_blank">
[19]	HUANG J，GRIFFITHS D V，WONG S. Initiation pressure，location and orientation of hydraulic fracture[J]. International Journal of Rock Mechanics and Mining Sciences，2012，49(1)：59-67. " target="_blank">
[20]	冯彦军，康红普. 定向水力压裂控制煤矿坚硬难垮顶板试验[J]. 岩石力学与工程学报，2012，31(6)：1 148-1 155.(FENG Yanjun，KANG Hongpu. Test on hard and stable roof control by means of direction hydraulic fracturing in coal mine[J]. Chinese Journal of Rock Mechanics and Engineering，2012，31(6)：1 148-1 155.(in Chinese)) " target="_blank">
[22]	RAHMAN M K，SUAREZ Y A，CHEN Z，et al. Unsuccessful hydraulic fracturing cases in Australia：investigation into causes of failures and their remedies[J]. Journal of Petroleum Science and Engineering，2007，57(1/2)：70-81. " target="_blank">
[1]	ANDREWS A. Unconventional gas shales：development，technology，and policy issues[M]. [S. l.]：Diane Publishing，2010：2-25. " target="_blank">
[2]	STEVENS P. The shale gas revolution：hype and reality[R]. London：Chatham House，2010. " target="_blank">
[5]	黄炳香，程庆春，刘长友，等. 煤岩体水力致裂理论及其工艺技术框架[J]. 采矿与安全工程学报，2011，28(2)：167-173.(HUANG Bingxiang，CHENG Qingchun，LIU Changyou，et al. Hydraulic fracturing theory of coal-rock mass and its technical framework[J]. Journal of Mining and Safety Engineering，2011，28(2)：167-173.(in Chinese)) " target="_blank">
[6]	林柏泉，李子文，翟成，等. 高压脉动水力压裂卸压增透技术及应用[J]. 采矿与安全工程学报，2011，(3)：452-455.(LIN Baiquan，LI Ziwen，ZHAI Cheng，et al. Pressure relief and permeability- increasing technology based on high pressure pulsating hydraulic fracturing and its application[J]. Journal of Mining and Safety Engineering，2011，(3)：452-455.(in Chinese)) " target="_blank">
[11]	YEW C H. Mechanics of hydraulic fracturing[M]. [S. l.]：Gulf Professional Publishing，1997：1-15. " target="_blank">
[15]	HOSSAIN M M，RAHMAN M K，RAHMAN S S. Hydraulic fracture initiation and propagation：roles of wellbore trajectory，perforation and stress regimes[J]. Journal of Petroleum Science and Engineering，2000，27(3/4)：129-149. " target="_blank">
[9]	邓广哲，黄炳香，王广地，等. 圆孔孔壁裂缝水压扩张的压力参数理论分析[J]. 西安科技学院学报，2003，23(4)：361-364.(DENG Guangzhe，HUANG Bingxiang，WANG Guangdi，et al. Theoretical analysis of crack expanding under pore hydraulic pressure[J]. Journal of Xi?an University of Science and Technology，2003，23(4)：361-364.(in Chinese)) " target="_blank">
[12]	RAHMAN M M，HOSSAIN M M，CROSBY D G，et al. Analytical，numerical and experimental investigations of transverse fracture propagation from horizontal wells[J]. Journal of Petroleum Science and Engineering，2002，35(3/4)：127-150. " target="_blank">
[16]	HUBBERT M K，WILLIS D G. Mechanics of hydraulic fracturing[J]. Transactions of Society of Petroleum Engineers of AIME，1957，210：153-168. " target="_blank">
[18]	SCHMIDT D R，ZOBACK M D. Poroelasticity effects in the determination of minimum horizontal principal stress in hydraulic fracturing test—a proposed breakdown equation employing a modified effective stress relation for tensile failure[J]. International Journal of Rock Mechanics and Mining Science and Geomechanics Abstracts，1989，26(6)：499-506. " target="_blank">
[21]	ZHANG X，JEFFREY R G，BUNGER A P，et al. Initiation and growth of a hydraulic fracture from a circular wellbore[J]. International Journal of Rock Mechanics and Mining Sciences，2011，48(6)：984-995.