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摘要: 针对松软煤层顺层钻进长钻孔成功率低、煤层机械强度低的难题,提出将机械发泡式泡沫水泥浆通过高压旋喷的方式注入松软煤层进行随钻加固的技术思路。室内试验中,通过改变松软煤岩与泡沫水泥浆的比例,模拟注浆后形成不同固结效果的松软煤岩-泡沫水泥固结体。以抗压强度和气体渗透率作为主要评价指标,研究了松软含煤量对固结体性能的影响规律。结果表明:(1)与纯泡沫水泥浆的固结体相比,当松软煤岩含量(以下简称“含煤量”)为5%时,固结体的气体渗透率略有降低,气体渗透率随养护时间增加而降低;(2)含煤量≥10%,固结体气体渗透率随含煤量增大而升高;(3)固结体的早期抗压强度(养护1 d)随含煤量的升高先升高后降低。养护时间增加至7 d后,固结体强度随含煤量升高而降低;(4)含煤量在20%~25%之间的固结体养护7 d后,抗压强度在8.65~9.94 MPa,气体渗透率在9.08~36.52 mD之间。研究成果可以为松软煤层的随钻护壁与瓦斯抽采提供有益借鉴。Abstract: In view of the problems of low success rate and low mechanical strength of long drilling holes along the soft coal bedding, the technical idea of injecting mechanical foamed cement slurry into the soft coal seam by the way of high-pressure rotary spraying while drilling to inforce the fomation is proposed. In the laboratory test, the proportion of soft coal rock and foamed cement slurry was changed to simulate the soft coal rock and foamed cement consolidation body which has different consolidation effects after grouting. In addition, taking compressive strength and gas permeability as the main evaluation indicators, the influence of soft coal content on the performance of the consolidated body was studied. The results show that: (1) Compared with the consolidated body of pure foamed cement slurry, when the content of soft coal rock (hereinafter referred to as “coal content”) was 5%, the gas permeability of the consolidated body decreases slightly, and the gas permeability decreased with the increase of curing time; (2) When the coal content was greater than or equal to 10%, the gas permeability of the consolidated body increased with the increase of coal content; (3) The early compressive strength (cured for 1d) of the consolidated body increases first and then decreases with the increase of coal content. After 7 d of curing time, the strength of the consolidated body decreased with the increase of coal content; (4) After the coal content was between 20%~25% and the consolidation body was cured for 7 d, the compressive strength was 8.65~9.94 MPa, and the gas permeability was 9.08~36.52 mD. The research results can provide useful reference for the wall protection while drilling and gas extraction in soft coal seam.
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Key words:
- foamed cement /
- soft coal seam /
- consolidated body /
- gas permeability /
- compressive strength
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[1] 吕清刚,柴祯.“双碳”目标下的化石能源高效清洁利用[J].中国科学院院刊,2022,37(04):541-548.
Qinggang LÜ, CHAI Zhen. Highly efficient and clean utilization of fossil energy under carbon peak and neutrality targets[J]. Bulletin of Chinese Academy of Sciences, 2022,37(4):541-548.
[2] [2] 姚宁平,姚亚峰,张杰,等.煤矿井下梳状定向孔钻进技术与装备[J].煤炭科学技术,2012,40(10):12-16,21.
YAO Ningping, YAO Yafeng, ZHANG Jie, et al. Technology and equipment of pectination directional drilling in underground mine[J]. Coal Science and Technology, 2012,40(10):12-16,21.
[3] [3] 袁亮,王伟,王汉鹏,等.巷道掘进揭煤诱导煤与瓦斯突出模拟试验系统[J].中国矿业大学学报,2020,49(2):205-214.
YUAN Liang, WANG Wei, WANG Hanpeng, et al. A simulation system for coal and gas outburst induced by coal uncovering in roadway excavation[J]. Journal of China University of Mining & Technology, 2020,49(2):205-214.
[4] [4] Black D J. Review of coal and gas outburst in Australian underground coal mines[J]. International Journal of Mining Science and Technology, 2019,29(6):815-824.
[5] [5] Karacan C O, Ruiz F A, Cote M, et al. Coal mine methane: A review of capture and utilization practices with benefits to mining safety and to greenhouse gas reduction[J]. International Journal of Coal Geology, 2011,86(2-3):121-156.
[6] [6] 张超林,王奕博,王恩元,等.煤与瓦斯突出煤粉在巷道内运移分布规律试验研究[J].煤田地质与勘探,2022,50(06):11-19.
ZHANG Chaolin, WANG Yibo, WANG Enyuan, et al. Experimental study on the migration and distribution law of pulverized coal in roadway during coal and gas outburst[J]. Coal Geology & Exploration, 2022,50(6):11-19.
[7] [7] Flores R M, Wang G Q, Qin D F, et al. Advancing CMM drainage, quality, and utilization with horizontal directional-drilled boreholes in Duanshi Coal Mine, southern Qinshui Basin, China[J]. International Journal of Coal Geology, 2019,209:1-13.
[8] [8] Gentzis T, Deisman N, Chalaturnyk R J. Effect of drilling fluids on coal permeability: Impact on horizontal wellbore stability[J]. International Journal of Coal Geology, 2009,78(3):177-191.
[9] [9] Hungerford F, Ren T, Aziz N. Evolution and application of in-seam drilling for gas drainage[J]. International Journal of Mining Science and Technology, 2013,23(4):534-544.
[10] [10] 张杰,王毅,黄寒静.软煤气动螺杆钻具定向钻进技术与装备 [J].煤田地质与勘探,2020,48(2):36-41.
ZHANG Jie, Wang Yi, HUANG Hanjing. Directional drilling technology and equipment of pneumatic screw motor in soft seam[J]. Coal Geology & Exploration, 2020,48(2):36-41.
[11] [11] 韩颖,张飞燕,杨志龙.煤层钻孔孔壁稳定性分析[J].中国安全科学学报,2014,24(6):80-85.
HAN Ying, ZHANG Feiyan, YANG Zhilong. Analysis of stability of coalbed borehole wall[J]. China Safety Science Journal, 2014,24(6):80-85.
[12] [12] 刘建林,刘飞,李泉新,等.碎软煤层瓦斯抽采钻孔孔壁稳定性分析[J].煤矿安全,2018,49(8):189-193.
LIU Jianlin, LIU Fei, LI Quanxin, et al. Stability analysis of borehole wall for gas drainage boreholes in broken soft coal seam[J]. Safety in Coal Mines, 2018,49(8):189-193.
[13] [13] 方俊,刘飞,李泉新,等.煤矿井下碎软煤层空气复合定向钻进技术与装备[J].煤炭科学技术,2019,47(2):224-229.
FANG Jun, LIU Fei, LI Quanxin, et al. Air compound directional technology and equipment for soft-fragmentized seam underground coal mine[J]. Coal Science and Technology, 2019,47(2):224-229.
[14] [14] 张群,葛春贵,李伟,等.碎软低渗煤层顶板水平井分段压裂煤层气高效抽采模式[J].煤炭学报,2018,43(1):150-159.
ZHANG Qun, GE Chungui, LI Wei, et al. A new model and application of coalbed methane high efficiency production from broken soft and low permeable coal seam by roof strata-in horizontal well and staged hydraulic fracture[J]. Journal of China Coal Society, 2018,43(1):150-159.
[15] [15] 聂超,王毅,姚亚峰,等.碎软煤层气动双管定向钻进排粉特性分析及应用[J].煤田地质与勘探,2022,50(0):159-166.
NIE Chao, WANG Yi, YAO Yafeng, et al. Powder discharge characteristics of pneumatic double pipe directional drilling in broken soft coal seams and its application[J]. Coal Geology & Exploration, 2022,50(5):159-166.
[16] [16] 凌标灿,戴世鑫,曹承平,等.三棱钻杆在中软煤层顺层瓦斯抽排钻孔的应用[J].煤炭科学技术,2009,37(10):44-46,111.
LING Biaocan, DAI Shixin, CAO Chengping, et al. Application of triangular drilling road to gas drainage borehole drilling in medium soft seam[J]. Coal Science and Technology, 2009,37(10):44-46,111.
[17] [17] 路桂英.井下煤层气抽采钻井松散段随钻注浆护壁关键技术研究[D].武汉:中国地质大学,2014.LU Guiying. Study of Grouting while Drilling in lose undergroundcoal bed methane extraction[D]. Wuhan: China University of Geosciences, 2014.
[18] [18] 胡艳丽,郝晋高,赵向敏,等.泡沫轻质混凝土性能与孔结构关系研究[J].南京理工大学学报,2019,43(3):363-366.
HU Yanli, HAO Jingao, ZHAO Xiangmin, et al. Relationship between properties andpore structure of foamed lightweight concrete[J]. Journal of Nanjing University of Science and Technology, 2019,43(3):363-366.
[19] [19] 岳文萍,凌伟,刘超.不同发泡剂对抽采钻孔护孔泡沫混凝土性能的影响研究[J].煤矿安全,2020,51(2):25-28,33.
YUE Wenping, LING Wei, LIU Chao. Study on influence of different foaming agents on properties of foamed concrete for extraction drilling[J]. Safety in Coal Mines, 2020,51(2):25-28,33.
[20] [20] 许文韬.高瓦斯低透气性煤层瓦斯抽采钻孔群孔优化布置研究[D].合肥:安徽建筑大学,2022.XU Wentao. Study on optimal arrangement of gas drainage boreholes in high gas and low permeability coal seams[D]. Hefei: Anhui Jianzhu University, 2022.
[21] [21] 顾军,尹会存,高德利,等.泡沫水泥稳定性研究[J].油田化学,2004(4):307-309.
GU Jun, YIN Huicun, GAO Deli, et al. A study on foamed-admixtured oil well cement[J]. Oilfield Chemistry, 2004(4):307-309.
[22] [22] Li K, Stroeven P, Stroeven M, et al. A numerical investigation into the influence of the interfacial transition zone on the permeability of partially saturated cement paste between aggregate surfaces[J]. Cement and Concrete Research, 2017,102:99-108.
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