Volume 48 Issue 5
Oct.  2020
Turn off MathJax
Article Contents
Abstract
References
WU Boqiang, WANG Xiaodong, ZHU Shibin. Expansion mechanism and control measures of high concentration slurry filling in cavity goaf of coal mine[J]. COAL GEOLOGY & EXPLORATION, 2020, 48(5): 123-129. DOI: 10.3969/j.issn.1001-1986.2020.05.015
Citation: WU Boqiang, WANG Xiaodong, ZHU Shibin. Expansion mechanism and control measures of high concentration slurry filling in cavity goaf of coal mine[J]. COAL GEOLOGY & EXPLORATION, 2020, 48(5): 123-129. DOI: 10.3969/j.issn.1001-1986.2020.05.015
shu

Expansion mechanism and control measures of high concentration slurry filling in cavity goaf of coal mine

  • Xi'an Research Institute Co. Ltd., China Coal Technology and Engineering Group Corp., Xi'an 710077, China

Funds: 

Science and Technology Innovation Fund of Xi'an Research Institute of CCTEG(2019XAYZD05)

More Information
  • Received Date: January 14, 2020
  • Revised Date: September 13, 2020
  • Published Date: October 24, 2020
    Graphical Abstract
    • Abstract
  • The filling expansion mechanism and control measures of high concentration slurry in goaf is one of the difficult problems to be solved in the filling treatment of cavity goaf. Based on this, combined with the high concentration slurry transportation and rheological theory, a high concentration slurry filling process model was constructed to reveal its expansion mechanism, the dynamic and resistance calculation methods of filling expansion process were studied, the main influencing factors and control methods of filling accumulation body morphology were determined, and the theoretical results were verified by outdoor filling test.The results show that the the relative error between the calculated value and the experimental value of high concentration slurry filling resistance is about 5%; the rheological parameters yield stress and viscosity of slurry are directly proportional to the pipeline transportation resistance; the strength growth trend of slurry accumulation body is affected by the setting characteristics, and the resistance of slurry flowing between the accumulation body and the roof increases during the condensation process; when the filling material and flow rate remain unchanged, the resistance along the pipeline transportation is mainly affected by The results show that the local resistance is related to the pipe diameter, elbow, diameter change form and quantity, and the more the number, the greater the local resistance; the slurry property, filling path and grouting technology are the main factors affecting the shape of filling accumulation body. Shortening the filling distance, reducing the number of pipe diameter and elbow, reducing the yield stress and viscosity of slurry, and increasing the grouting flow and pressure are helpful The results provide a basis for the controlled filling of high concentration slurry in cavity goaf.
    • FullText(HTML)
    • References (22)
  • [1]
    李树志. 我国采煤沉陷区治理实践与对策分析[J]. 煤炭科学技术,2019,47(1):36-43.

    LI Shuzhi. Control practices and countermeasure analysis on coal mining subsidence area in China[J]. Coal Science and Technology,2019,47(1):36-43.
    [2]
    李佳洺,余建辉,张文忠. 中国采煤沉陷区空间格局与治理模式[J]. 自然资源学报,2019,34(4):867-880.

    LI Jiaming,YU Jianhui,ZHANG Wenzhong. Spatial distribution and governance of coal-mine subsidence in China[J]. Journal of Natural Resources,2019,34(4):867-880.
    [3]
    谭新平,徐张建,王小秋,等. 厚黄土与煤炭采空区地质灾害易发性评价[J]. 煤田地质与勘探,2017,45(5):112-120.

    TAN Xinping,XU Zhangjian,WANG Xiaoqiu,et al. Geological hazard susceptibility assessment in thick loess and gob[J]. Coal Geology & Exploration,2017,45(5):112-120.
    [4]
    朱世彬. 高浓度胶结材料在空洞型采空区中的堆积扩散规律试验研究[J]. 能源与环保,2018,40(8):73-77.

    ZHU Shibin. Experimental study on accumulation and diffusion laws of high concentration cementitious materials in gobs of large caverns[J]. China Energy and Environmental Protection,2018,40(8):73-77.
    [5]
    王晓宇,乔登攀. 废石-全尾砂高浓度充填料浆管输阻力影响因素分析[J]. 有色金属(矿山部分),2010,62(4):61-65.

    WANG Xiaoyu,QIAO Dengpan. Analysis of the influence of waste rock-full tailings high concentration filling on the resistance of slurry pipeline transport[J]. Non Ferrous Metals(Mine Part),2010,62(4):61-65.
    [6]
    孙凯年,寿国华. 管径对宾汉体砂浆输送阻力影响的研究[J]. 黄金,1988,9(5):1-4.

    SUN Kainian,SHOU Guohua. Effects of diameter of pipeline on transport resistance to Bingham tailing slurries[J]. Gold,1988,9(5):1-4.
    [7]
    吴爱祥,杨莹,程海勇,等. 中国膏体技术发展现状与趋势[J].工程科学学报,2018,40(5):517-525.

    WU Aixiang,YANG Ying,CHENG Haiyong,et al. Status and prospects of paste technology in China[J]. Chinese Journal of Engineering,2018,40(5):517-525.
    [8]
    岩土注浆理论与工程实践协作组. 岩土注浆理论与工程实践[M]. 北京:科学出版社,2001.

    Cooperation Group of Geotechnical Grouting Theory and Engineering Practice. Geotechnical grouting theory and engineering practice[M]. Beijing:Science Press,2001.
    [9]
    徐斌,董书宁,徐路路,等. 水泥基注浆材料浆液稳定性及其析水规律试验[J]. 煤田地质与勘探,2019,47(5):24-31.

    XU Bin,DONG Shuning,XU Lulu,et al. Stability of cement-based grouting slurry and test of its bleeding law[J]. Coal Geology & Exploration,2019,47(5):24-31.
    [10]
    周振方,曹海东,朱明诚,等. 水泥-水玻璃双液浆在工作面顶板突水溃砂治理中的应用[J]. 煤田地质与勘探,2018,46(6):121-127.

    ZHOU Zhenfang,CAO Haidong,ZHU Mingcheng,et al. Application of cement-sodium silicate mixed grout in control of water and sand bursting from roof of the working face[J]. Coal Geology & Exploration,2018,46(6):121-127.
    [11]
    阮文军. 注浆扩散与浆液若干基本性能研究[J]. 岩土工程学报,2005,27(1):69-73.

    RUAN Wenjun. Research on diffusion of grouting and basic properties of grouts[J]. Chinese Journal of Geotechnical Engineering,2005,27(1):69-73.
    [12]
    张良辉. 岩土注浆渗流机理及渗流力学[D]. 北京:北京交通大学,1996.

    ZHANG Lianghui. Geotechnical grouting percolation mechanism and percolation mechanics[D]. Beijing:Northern Jiaotong University,1996.
    [13]
    李术才,张伟杰,张庆松,等. 富水断裂带优势劈裂注浆机制及注浆控制方法研究[J]. 岩土力学,2014,35(3):744-752.

    LI Shucai,ZHANG Weijie,ZHANG Qingsong,et al. Research on advantage-fracture grouting mechanism and controlled grouting method in water-rich fault zone[J]. Rock and Soil Mechanics,2014,35(3):744-752.
    [14]
    白仲荣. 采空区内浆料堆积规律试验研究[D]. 北京:煤炭科学研究总院,2016.

    BAI Zhongrong. Experimental study on the law of slurry packing in goaf[D]. Beijing:China Coal Research Institute,2016.
    [15]
    王义杰. 空洞型采空区高触变性充填浆液试验研究[D]. 北京:煤炭科学研究总院,2019.

    WANG Yijie. Experimental study on high thixotropy filling slurry cavitary gob area[D]. Beijing:China Coal Research Institute,2019.
    [16]
    刘晓辉,吴爱祥,姚建,等. 膏体尾矿管内滑移流动阻力特性及其近似计算方法[J]. 中国有色金属学报,2019,29(10):2403-2410.

    LIU Xiaohui,WU Aixiang,YAO Jian,et al. Resistance characteristic and approximate calculation of paste tailings slip flow inside pipe[J]. The Chinese Journal of Non ferrous Metals,2019,29(10):2403-2410.
    [17]
    侯晖昌. 管道矿浆高浓度输送若干问题分析[J]. 泥沙研究,1981(4):50-61.

    HOU Huichang. Analysis of some problems in high concentration transportation of pipeline slurry[J]. Journal of Sediment Research,1981(4):50-61.
    [18]
    刘晓辉. 膏体流变行为及其管流阻力特性研究[D]. 北京:北京科技大学,2015.

    LIU Xiaohui. Study on rheological behavior and pipe flow resistance of paste backfill[D]. Beijing:University of Science and Technology Beijing,2015.
    [19]
    甘德清,薛娜,刘志义,等. 全尾砂充填料浆管道阻力损失探究及优化[J]. 金属矿山,2019,48(7):32-40.

    GAN Deqing,XUE Na,LIU Zhiyi,et al. Investigation and optimization of pipeline resistance loss of full tailings slurry[J]. Metal Mine,2019,48(7):32-40.
    [20]
    何哲祥. 高浓度充填料浆管道挤压输送理论与应用研究[D]. 长沙:中南大学,2008. HE Zhexiang. Study on squeezed-transport theory and application of pipeline hydraulic flilling at high-density[D]. Changsha:Central South University,2008.
    [21]
    王枭,饶杰,王弼. 管道阻力计算[J]. 压缩机技术,2018(6):26-29.

    WANG Xiao,RAO Jie,WANG Bi. Calculation of the drag in pipes[J]. Compressor Technology,2018(6):26-29.
    [22]
    王劼,杨超,张军,等. 膏体充填管道输送阻力损失计算方法[J]. 金属矿山,2010,39(12):33-36.

    WANG Jie,YANG Chao,ZHANG Jun,et al. Calculation method of the resistance loss in pipeline transportation of paste filling slurry[J]. Metal Mine,2010,39(12):33-36.
    • Related Articles

Catalog

    Get Citation
    PDF
    XML

    Article Metrics

    Article views (172) PDF downloads (29) Cited by()
    Related

    Copyright of website design © Editorial Office of Coal Geology & Exploration 陕ICP备05001372号-6 陕公网安备 61019002002193号

    Address: Editorial Office of Coal Geology & Exploration, No.82 Jinye 1st Rd, High-Tech Zone, Xi'an City, Shaanxi, China

    Tel: 029-81778075 E-mail: ccrimtdzykt@vip.163.com

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

    /

    DownLoad:  Full-Size Img  PowerPoint
    Return
    Return