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Coal Geology & Exploration

Abstract

In order to make up for the deficiency of the regional monitoring of the traditional gas drainage monitoring system, this paper proposes to build a borehole gas drainage monitoring system with borehole as the monitoring unit, which can dynamically grasp the drainage effect of each borehole in the process of gas drainage in real time, change the large area regional measurement into the measurement of each borehole in the region, and realize the fine monitoring of gas drainage. According to the requirements of borehole gas drainage monitoring system, combined with the characteristics of gas drainage parameters at the borehole orifice, a multi parameter monitoring device for mine gas drainage borehole is developed. The device has the functions of real-time data acquisition of ultrasonic gas flow measurement, non dispersive infrared gas concentration measurement, piezoelectric ceramic gas pressure measurement and platinum resistance gas temperature measurement. It is equipped with the functional human-computer interaction modules such as data display, data storage, data remote transmission and data Wi-Fi transmission, and develops two supporting software, namely, gas drainage analysis software and mobile data acquisition station. According to the actual application requirements, combined with the corresponding measurement standards of the industry, the device has been tested in the inspection unit with the national metrological verification qualification, and the underground industrial test has been carried out in No.2 Coal Mine of Huangling Mining Company to verify the actual application effect of the device. The test results show that the four measurement parameters of the multi parameter monitoring device for mine gas drainage boreholes meet the measurement requirements of the corresponding industry standards, and can realize the accurate measurement of various parameters. Moreover, the device has good working reliability and stability in the actual underground application, which achieves the purpose of gas drainage monitoring with borehole as the monitoring unit, and can be used for gas drainage evaluation, providing strong data support to ensure efficient and safe development of coal and gas resources.

Keywords

borehole gas drainage monitoring system, multi parameter monitoring, ultrasonic gas flow measurement, human-computer interaction module, gas drainage analysis software, mobile data collection station

DOI

10.3969/j.issn.1001-1986.2020.06.023

Reference

[1] 吕玉广,李宏杰,夏宇君,等. 基于多类型四双法的煤层顶板突水预测评价研究[J]. 煤炭科学技术,2019,47(9):219-228. LYU Yuguang,LI Hognjie,XIA Yujun,et al. Prediction and evaluation study on coal seam roof water inrush based on multi-type four-double method[J]. Coal Science and Technology,2019,47(9):219-228.

[2] 王大纯,张人权,史毅虹,等.水文地质学基础[M].北京:地质出版社,1995:106-107. WANG Dachun,ZHANG Renquan,SHI Yihong,et al. General Hydrogeology[M].Beijing:Geological Publishing House,1995:106-107.

[3] 王洋,武强,丁湘,等. 深埋侏罗系煤层顶板水害源头防控关键技术[J]. 煤炭学报,2019,44(8):2449-2459. WANG Yang,WU Qiang,DING Xiang,et al. Key technologies for prevention and control of roof water disaster at sources in deep Jurassic seams[J]. Journal of China Coal Society,2019,44(8):2449-2459.

[4] 赵宝峰. 基于含水层沉积和构造特征的富水性分区[J]. 中国煤炭地质,2015,27(4):30-34. ZHAO Baofeng. Water yield property zoning based on aquifer sedimentary and structural features[J]. Coal Geology of China,2015,27(4):30-34.

[5] 郭小铭,董书宁. 深埋煤层开采顶板基岩含水层渗流规律及保水技术[J]. 煤炭学报,2019,44(3):805-812. GUO Xiaoming,DONG Shuning. Seepage law of bedrock aquifer and water-preserved mining technology in deep coal seam mining[J]. Journal of China Coal Society,2019,44(3):805-812.

[6] 张东升,李文平,来兴平,等. 我国西北煤炭开采中的水资源保护基础理论研究进展[J]. 煤炭学报,2017,42(1):36-43. ZHANG Dongsheng,LI Wenping,LAI Xingping,et al. Development on basic theory of water protection during coal mining in northwest of China[J]. Journal of China Coal Society,2017,42(1):36-43.

[7] 王海军,马良. 陕北侏罗纪煤田三角洲平原沉积环境及其岩石力学特征[J]. 煤田地质与勘探,2019,47(3):61-69. WANG Haijun,MA Liang. Study on sediment environment and rock mechanics characteristics of the delta plain of Jurassic coalfield in northern Shaanxi[J]. Coal Geology & Exploration,2019,47(3):61-69.

[8] 李东,刘生优,张光德,等. 鄂尔多斯盆地北部典型顶板水害特征及其防治技术[J]. 煤炭学报,2017,42(12):3249-3254. LI Dong,LIU Shengyou,ZHANG Guangde,et al. Typical roof water disasters and its prevention & control technology in the north of Ordos basin[J]. Journal of China Coal Society,2017,42(12):3249-3254.

[9] 齐跃明,李民族,许进鹏. 复杂地质条件下的突水疏放试验及水文地质意义[J]. 采矿与安全工程学报,2016,33(1):140-145. QI Yueming,LI Minzu,XU Jinpeng. Draining test of mine water inrush under complex geological conditions and its hydrogeological significance[J]. Journal of Mining & Safety Engineering,2016,33(1):140-145.

[10] 王双明,吕道生,佟英梅,等. 鄂尔多斯盆地聚煤规律及煤炭资源评价[M]. 北京:煤炭工业出版社,1996. WANG Shuangming,LYU Daosheng,TONG Yingmei,et al. Coal accumulation and coal resource evaluation of Ordos basin[M]. Beijing:China Coal Industry Publishing House,1996.

[11] 吕玉广,齐东合. 顶板突(涌)水危险性"双图"评价技术与应用:以鄂尔多斯盆地西缘新上海一号煤矿为例[J]. 煤田地质与勘探,2016,44(5):108-112. LYU Yuguang,QI Donghe. Technique based on "double maps" for assessment of water inrush from roof aquifer and its application:With New Shanghai No.1 coal mine at western edge of Ordos basin as example[J]. Coal Geology & Exploration,2016,44(5):108-112.

[12] 刘晓东. 陕北侏罗纪煤田煤炭资源勘查利用现状分析[J]. 地下水,2017,39(5):126-128. LIU Xiaodong. Analysis on the present situation of exploration and utilization of the Jurassic coal field in northern Shaanxi[J]. Groundwater,2017,39(5):126-128.

[13] 吕玉广,齐东合. 内蒙古鄂托克前旗新上海一号煤矿111084工作面突水原因与机理[J]. 中国煤炭地质,2016,28(9):53-57. LYU Yuguang,QI Donghe. No.111084 working face water bursting causation and mechanism in Xinshanghai No.1 coalmine,Otog Front Banner,Inner Mongolia[J]. Cola Geology of China,2016,28(9):53-57.

[14] 田增林,黄选明,曹海东,等. 基于Aquifer Test的底板放水试验参数计算与评价研究[J]. 煤炭工程,2018,50(9):96-100. TIAN Zenglin,HUANG Xuanming,CAO Haidong,et al. Parameter calculation and evaluation in coalbed floor dewatering test based on aquifer test[J]. Coal Engineering,2018,50(9):96-100.

[15] 武强,许珂,张维. 再论煤层顶板涌(突)水危险性预测评价的"三图-双预测法"[J]. 煤炭学报,2016,41(6):1341-1347. WU Qiang,XU Ke,ZHANG Wei. Further research on "three maps-two predictions" method for prediction on coal seam roof water bursting risk[J]. Journal of China Coal Society,2016,41(6):1341-1347.

[16] 武强,樊振丽,刘守强,等. 基于GIS的信息融合型含水层富水性评价方法:富水性指数法[J]. 煤炭学报,2011,36(7):1124-1128. WU Qiang,FAN Zhenli,LIU Shouqiang,et al. Water-richness evaluation method of water-filled aquifer based on the principle of information fusion with GIS:Water-richness index method[J]. Journal of China Coal Society,2011,36(7):1124-1128.

[17] 吕玉广,肖庆华,程久龙. 弱富水软岩水-沙混合型突水机制与防治技术研究:以上海庙矿区为例[J]. 煤炭学报,2019,44(10):3154-3163. LYU Yuguang,XIAO Qinghua,CHENG Jiulong. Mechanism and prevention of water-sand inrush in soft rock with weakly abundant water:A case study in Shanghai temple mining area[J]. Journal of China Coal Society,2019,44(10):3154-3163.

[18] 武强,徐华,赵颖旺,等. 基于"三图法"煤层顶板突水动态可视化预测[J]. 煤炭学报,2016,41(12):2968-2974. WU Qiang,XU Hua,ZHAO Yingwang,et al. Dynamic visualization and prediction for water bursting on coal roof based on "three maps method"[J]. Journal of China Coal Society,2016,41(12):2968-2974.

[19] 牛宏,梁杏,张人权. 通量上边界与水头上边界方法的地下水流系统模拟对比[J]. 吉林大学学报(地球科学版),2014,44(3):977-985. NIU Hong,LIANG Xing,ZHANG Renquan. Comparison of flux upper boundary and given head upper boundary in simulation of groundwater flow systems[J]. Journal of Jilin University(Earth Science Edition),2014,44(3):977-985.

[20] 陈晋栋,王武祥,张磊蕾,等. 透水混凝土透水系数试验方法的影响因素[J]. 科学技术与工程,2018,18(16):251-255. CHEN Jindong,WANG Wuxiang,ZHANG Leilei,et al. Influencing factors of permeability test methods of pervious concrete[J]. Science Technology and Engineering,2018,18(16):251-255.

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