高瓦斯低透气性煤层深钻孔高压水力割缝增透技术
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摘要
为提高新田煤矿M9煤层瓦斯抽采效果,解决低透气性突出煤层抽采效率低及应力主导型煤层卸压效果差的难题,以新田煤矿1901工作面为研究背景,分析了深钻孔超高压水力割缝卸压增透机理,采用深钻孔与高压水力割缝相结合增透技术,加快了1901掘进工作面抽采效率,减少了抽采达标时间,实现了1901掘进工作面"安全、科学、精准、经济、高效"的瓦斯灾害防治,有利于煤矿安全高效生产和可持续健康发展。
In order to improve the gas drainage effect of M9 coal seam in Xintian Coal Mine and solve the problem of low extraction efficiency of low permeability and outburst coal seam and poor pressure relief effect of stress-oriented coal seam,the pressure-relief and permeability-increasing mechanism was analyzed for deep hole supper-high pressure hydraulic cutting with the 1901 working face of Xintian Coal Mine as the research background. Combined with deep drilling and high-pressure hydraulic cutting,the permeability-increasing speeds up the extraction efficiency of 1901 heading face,reduces the time of gas extraction,safe,scientific,precise,economical and efficient gas disaster prevention and control of the 1901 heading face is achieved,which is conducive to safe and efficient production and sustainable and healthy development of coal mines.
In order to improve the gas drainage effect of M9 coal seam in Xintian Coal Mine and solve the problem of low extraction efficiency of low permeability and outburst coal seam and poor pressure relief effect of stress-oriented coal seam,the pressure-relief and permeability-increasing mechanism was analyzed for deep hole supper-high pressure hydraulic cutting with the 1901 working face of Xintian Coal Mine as the research background. Combined with deep drilling and high-pressure hydraulic cutting,the permeability-increasing speeds up the extraction efficiency of 1901 heading face,reduces the time of gas extraction,safe,scientific,precise,economical and efficient gas disaster prevention and control of the 1901 heading face is achieved,which is conducive to safe and efficient production and sustainable and healthy development of coal mines.
引文
[1]瞿涛宝,赵新根.高压水力割缝的参数确定和效果分析[J].煤矿安全,1982(7):1-10.
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[3]于洪,陈庭侃.高压水射流割缝提高瓦斯抽放效率的研究[J].煤炭科学技术,2009(3):44-46.
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[5]冯增朝.低渗透煤层强化抽采理论及应用[J].北京:科学出版社,2008.
[6]段康廉,冯增朝,赵阳升,等.低渗透煤层钻孔与水力割缝瓦斯排放的试验研究[J].煤炭学报,2002(1):50-53.
[7]唐巨鹏,李成全,潘一山.水力割缝开采低渗煤层气应力场数值分析[J].天然气工业,2004(10):93-98.
[8]吴海进,林柏泉,杨威,等.初始应力对缝槽卸压效果影响的数值分析[J].采矿与安全工程学报,2009(2):194-197.
[9]谢正红.高压水力割缝增透技术及其应用[J].能源技术与管理,2014,39(4):45-47.
[10]王迪.高压水力割缝在孟津煤矿的应用[J].硅谷,2012(22):101,133.
[2]张国平.低透气性煤层高压水力增透预抽煤层瓦斯技术的应用[J].科技与企业,2012(16):157-158.
[3]于洪,陈庭侃.高压水射流割缝提高瓦斯抽放效率的研究[J].煤炭科学技术,2009(3):44-46.
[4]冯增朝,赵阳升,吕兆兴,等.切割煤层的高压水力割缝机:中国,ZL201010503187. 9[P]. 2010-09-30.
[5]冯增朝.低渗透煤层强化抽采理论及应用[J].北京:科学出版社,2008.
[6]段康廉,冯增朝,赵阳升,等.低渗透煤层钻孔与水力割缝瓦斯排放的试验研究[J].煤炭学报,2002(1):50-53.
[7]唐巨鹏,李成全,潘一山.水力割缝开采低渗煤层气应力场数值分析[J].天然气工业,2004(10):93-98.
[8]吴海进,林柏泉,杨威,等.初始应力对缝槽卸压效果影响的数值分析[J].采矿与安全工程学报,2009(2):194-197.
[9]谢正红.高压水力割缝增透技术及其应用[J].能源技术与管理,2014,39(4):45-47.
[10]王迪.高压水力割缝在孟津煤矿的应用[J].硅谷,2012(22):101,133.
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