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Coal seam water infusion for dust control: a technical review

  • Kaixuan Zhang
  • Jian ZhangEmail author
  • Jianping Wei
  • Ting Ren
  • Xiangyu Xu
Review Article
  • 44 Downloads

Abstract

Coal mine dust continues to be a health and safety issue in underground coal mines. Coal seam water infusion was developed and widely applied in European coal mines for dust control, and was also a common practice in most Chinese coal mines. This method typically involves the infusion of water into the coal seam to increase its moisture content, and therefore reduce dust generation during mining operations. With the availability of other dust control methods such as water spraying systems, the water infusion method has not been considered as a viable means for dust mitigation in modern mines. However, the increase in production output and the deployment of more powerful equipment for coal cutting and transport and intensive gas drainage practices mean that workers could be exposed to more dust contaminations. Whilst the mine operators are committed to suppress and dilute airborne dust particles using these passive measures, there is a need to critically examine and subsequently develop this proactive dust control technology for practical applications in Chinese coal mines. The paper provides a critical review of the water infusion technologies in view of its technological advances and practical application limitations. The methods of water infusion, mechanism of water flow in coal, the role of surfactants and the key parameters influencing the effect of water infusion on dust control are identified and discussed. Existing problems and prospects for water infusion are analysed.

Keywords

Water infusion Dust control Underground coal mine Coal seam Surfactant 

Notes

Funding information

State Key Laboratory Cultivation Base for Gas Geology and Gas Control (Henan Polytechnic University) Open Funding (WS2017A01) is acknowledged. The study is also supported by Key Projects of Science and Technology Research of The Ministry of Education (Grant No. 213022A) and PhD Funding of Henan Polytechnic University (Grant No. B2018-57). The authors also acknowledge the support by National Nature Science Foundation of China (Grant No. 51804101, 51574112) and Youth Funding of Henan Polytechnic University (Grant No. Q2017-01).

References

  1. Aguado MBD, Nicieza CG (2007) Control and prevention of gas outbursts in coal mines, Riosa–Olloniego coalfield, Spain. Int J Coal Geol 69(4):253–266Google Scholar
  2. Barenblatt GI, Zheltov IP, Kochina IN (1960) Basic concepts in the theory of seepage of homogeneous liquids in fissured rocks. J Appl Math Mech 24(5):1286–1303Google Scholar
  3. Cervik J, Sainato A, Deul M (1977) Water infusion of coalbeds for methane and dust control. Contraception 73(3):253–256Google Scholar
  4. Cervik J, Sainato A, Baker E (1983) Water infusion-an effective and economical longwall dust control. Aust N Z J Psychiatry 47(9):883–884Google Scholar
  5. Cetinbas A, Vinson RP, Cervik J, Zabetakis MG (1972) Methane and dust control by water infusion, Pittsburgh coalbedGoogle Scholar
  6. Chen H (2008) Analysis on technics of water infusion of “three soft” coal seam. Coal Technol 27(8):158–159Google Scholar
  7. Chen X, Huo G (1999) Discussion on dustproof and sealing methods of water infusion in “three soft” coal seams. Coal Sci Technol 27(3):1–3Google Scholar
  8. Cheng WM, Nie W, Zhou G, Yu Y, Ma Y, Xue J (2012) Research and practice on fluctuation water injection technology at low permeability coal seam. Saf Sci 50(4):851–856Google Scholar
  9. Crawford RJ, Mainwaring DE (2001) The influence of surfactant adsorption on the surface characterisation of Australian coals. Fuel 80(3):313–320Google Scholar
  10. Cybulski K, Malich B, Wieczorek A (2015) Evaluation of the effectiveness of coal and mine dust wetting. J Sustain Min 14(2):83–92Google Scholar
  11. Frid V (2000) Electromagnetic radiation method water-infusion control in rockburst-prone strata. J Appl Geophys 43(1):5–13Google Scholar
  12. Fu H, Chen G (2003) Test of coal seam water injection by gas drainage drilling. Jiangxi Coal Sci Technol 3:52–53Google Scholar
  13. Gao H (2007a) The study of deep hole coal seam water injection in coal mining faces., Anhui University of Science and Technology, Hefei, Master thesisGoogle Scholar
  14. Gao J (2007b) Experimental study on shallow hole irrigating to coal seams in high gas synthesis mines working face. Anhui University of Science and Technology, Hefei, Master thesisGoogle Scholar
  15. Gao S, Liu H (2010) Capillary mechanics. Science Press, BeijingGoogle Scholar
  16. Glanville JO, Haley LH (1982) Studies of coal dust wetting by surfactant solutions. Colloids Surf 4(3):209–212Google Scholar
  17. Gosiewska A, Drelich J, Laskowski JS, Pawlik M (2002) Mineral matter distribution on coal surface and its effect on coal wettability. J Colloid Interface Sci 247(1):107–116Google Scholar
  18. Guo H, Wang H, Zhou J (2017) Study on coal seam water injection technology in fully mechanized mining face of Qipanjing mine. Min Saf Environ Prot 44(5):14–17Google Scholar
  19. Han J, Wang Y, Zhao S, Guan M (2010) Research status and influence factors of coal seam water injection. Sci Technol Innov Herald 3:73–74Google Scholar
  20. Hu G, Xu J, Ren T et al (2015) Field investigation of using water injection through inseam gas drainage boreholes to control coal dust from the longwall face during the influence of abutment pressure. Int J Surf Min Reclam Environ 30(1):48–63Google Scholar
  21. Imachi M (1998) Evaluation of Young’s equation and analysis of wetting. J High Temp Soc 24(4):318–321Google Scholar
  22. Jia Z (2012) Research on the dust control technology with dynamic pressure water injectionon fully mechanized caving face., Taiyuan University of Technology, Master thesisGoogle Scholar
  23. Jia Z, Rong L, Zhou J, Wang F (2012) Dust control effect with water infusion on 23520 working face in Baijiazhuang mine. Shanxi Coal 32(11):59–60Google Scholar
  24. Jiang J, Cheng Y, Mou J et al (2015) Effect of water invasion on outburst predictive index of low rank coals in Dalong mine. PLoS One 10(7):e132355Google Scholar
  25. Jin L (1994) Development trend of water injection and dust prevention in coal seam in Germany. Min Saf Environ Prot 5:46–48Google Scholar
  26. Jin L (1997) Study and experiment on approach of dust suppression by sticking. J China Coal Soc 4:410–414Google Scholar
  27. Jin L, Li J, Sun Y (2010) Theory of mine dust control. Science Press, BeijingGoogle Scholar
  28. Joseph DD (1966) Nonlinear stability of the Boussinesq equations by the method of energy. Arch Ration Mech Anal 22(3):163–184Google Scholar
  29. Keller (1988) The contact angle of water on coal. Colloids Surf 22(1):21–35Google Scholar
  30. Kirwin RC (1986) Method for the control of dust using methacrylate containing emulsions and compositions.USGoogle Scholar
  31. Kissell FN (2003) Handbook for dust control in mining. Niosh Inf Circ 54(9):969–976Google Scholar
  32. Kittle PA (1985) Method for suppressing coal dust.USGoogle Scholar
  33. Kobashi M, Adachi A (1992) Effect of hepatic portal infusion of water on water intake by water-deprived rats. Physiol Behav 52(5):885–888Google Scholar
  34. Li L (2006) Application of coal seam water injection in production of “three soft” unstable thick seam. Zhongzhou Coal 4:52–53Google Scholar
  35. Li J (2016) Situation analysis and the coal industry pneumoconiosis prevention countermeasures. Chem Eng Des Commun 46:11Google Scholar
  36. Li Y, Shao G (2004) Practice of water injection and precipitation by gas drainage borehole. Heilongjiang Sci Technol Inf 7:140Google Scholar
  37. Li Z, Qin SY, Sun GY (2003) Parameter reverse-solving of infiltrating character during water injection into coal seams. J Liaoning Tech Univ 22(6):728–731Google Scholar
  38. Li Q, Lin B, Zhao S, Dai H (2013) Surface physical properties and its effects on the wetting behaviors of respirable coal mine dust. Powder Technol 233(2):137–145Google Scholar
  39. Li J, Zhou F, Liu H (2015) The selection and application of a compound wetting agent to the coal seam water infusion for dust control. Coal Prep 36(4):192–206Google Scholar
  40. Lin Q (2013) Test on a new dust-removal additive and analysis on its application effect. Min Saf Environ Prot 3:62–64Google Scholar
  41. Liu J (2004) Test effect analysis of water injection technology with infiltration stick in Taoyuan coal mine. Saf Coal Mines 35(8):40–41Google Scholar
  42. Liu Z (2010) The research on water infusion parameters and construction technology for longwall top coal caving face used for Tang’an no.3 coal, Taiyuan University of Technology, Master thesisGoogle Scholar
  43. Liu X (2014) Research of hole sealing technology for coal seam of mining face with high ground press. Energy Energy Conserv 5:190–192Google Scholar
  44. Liu X, Li Z, Zhang X, Yu H, Wang P (2011) Application of affusion in coal for dust control. Procedia Eng 26:902–908Google Scholar
  45. Mcclelland JJ, Organiscak JA, Jankowski RA, Pothini BR (1987) Water infusion for coal-mine dust control: three case studies. RI 9096Google Scholar
  46. Mo J, Wang L, Au W, Su M (2014) Prevalence of coal workers' pneumoconiosis in China: a systematic analysis of 2001-2011 studies. Int J Hyg Environ Health 217(1):46–51Google Scholar
  47. Murata, Zheng YX (1984) Influence of coal particle size on flotation—a study of coal flotation. Coal Prep Technol 5:49–54Google Scholar
  48. Oda M, Takemura T, Aoki T (2002) Damage growth and permeability change in triaxial compression tests of Inada granite. Mech Mater 34(6):313–331Google Scholar
  49. Qin Y, Fu G (2000) Study on fractal characteristic of pore in coal and moisture absorbing property of coal. J China Coal Soc 25(1):55–59Google Scholar
  50. Qin S, Hai G (1992) Orthogonal experiment optimization method for injection parameters of coal seam. Min Saf Environ Prot 3:24–27Google Scholar
  51. Qin S, Qin W (2003) Engineering experiment research of the quantity theoretical orthogonal design optimal method for the coal-seam injection parameters. Eng Sci 5(10):38–52Google Scholar
  52. Radaelli F, Paggi S, Amato A, Terruzzi V (2010) Warm water infusion versus air insufflation for unsedated colonoscopy: a randomized, controlled trial. Gastrointest Endosc 72(4):701–709Google Scholar
  53. Ren TX, Plush B, Aziz N (2011) Dust controls and monitoring practices on Australian longwalls. First Int Symp Mine Saf Sci Eng 26:1417–1429Google Scholar
  54. Roach SA (1968) The prevention and suppression of dust in mining, tunnelling and quarrying. Occupational & Environmental Medicine 25 (4): 332-bGoogle Scholar
  55. Santhanam CJ, Lunt RR, Johnson SL et al (1979) Health and environmental impacts of increased generation of coal ash and FGD Sludges: report to the committee on health and ecological effects of increased coal utilization. Environ Health Perspect 33:131–157Google Scholar
  56. Seidle JP, Jeansonne MW, Erickson DJ (1992) Application of matchstick geometry to stress dependent permeability in coals. Spe Rocky Mountain Regional MeetingGoogle Scholar
  57. Shi J (2012) Working face short hole infusion of practical technology research. J North China Inst Sci Technol 9(3):43–46Google Scholar
  58. Singh BP (1999) The role of surfactant adsorption in the improved dewatering of fine coal. Fuel 78(4):501–506Google Scholar
  59. Sun Q, Cao X, Guo J (1993) Soft coal seam water injection dust reduction. Min Saf Environ Prot 4:25–35Google Scholar
  60. Sun Z, Wang Y, Li X (2014) Comprehensive dust control technology in mining thin coal seam. J Shandong Univ Sci Technol Nat Sci 33(2):67–74Google Scholar
  61. Thakur (1992) Study on the wettability of coal and its application. China Coal Industry Publishing House, BeijingGoogle Scholar
  62. Tomb TF, Raymond LD (1975) Fifth International Labor Organization report on the prevention and suppression of dust in mining, tunneling, and quarrying in the United StatesGoogle Scholar
  63. Vadlamudi R (1964) Darcy’s law. Encyclopedia Soils Environ 24(6):363–369Google Scholar
  64. Walker PL, Petersen EE, Wright CC (1952) Surface active agent phenomena in dust abatement. Ind Eng Chem 44(10):2389–2393Google Scholar
  65. Wang WH (2011a) Appliation present status and outlook of seam water injection dust control technology. Coal Sci Technol 39:57–60Google Scholar
  66. Wang Z (2011b) The research on seepage charaeteristie of water infusion for coal seam and Numerieal simulation analysis., Anhui University of Science & Technology, Hefei, Master thesisGoogle Scholar
  67. Wang L (2012) Study of Qi’nan mine 10114 working face coal seam water injection effect. Jiangxi Coal Sci Technol 4:67–69Google Scholar
  68. Wang J, Yuan G (2013) Study on using gas drainage hole water injection dust suppression technology. Sci Technol Eng 27(13):8111–8114Google Scholar
  69. Wang Q, Jin L, Sun J (2004) A research on coal seam water infusion course and coal body wetness mechanis. J Saf Environ 4(1):70–73Google Scholar
  70. Wang K, Zang J, Wang G, Zhou A (2014) Anisotropic permeability evolution of coal with effective stress variation and gas sorption: model development and analysis. Int J Coal Geol 130(4):53–65Google Scholar
  71. Wang K, Ma X, Jiang S, Wu Z, Shao H, Pei X (2016) Application study on complex wetting agent for dust-proof after gas drainage by outburst seams in coal mines. Int J Min Sci Technol 26(4):669–675Google Scholar
  72. Wang Q, Wang D, Wang H, Shen Y, Zhu X (2018) Experimental investigations of a new surfactant adding device used for mine dust control. Powder Technol 327:303–309Google Scholar
  73. Wu C (2003) Chemical dust suppression. The Central South University Press, ChangshaGoogle Scholar
  74. Wu C, Zuo Z, Ou J et al (2005) Different experimental devices for the determination of dust wetting agent. Chin J Nonferrous Metals 15(10):1612–1617Google Scholar
  75. Wu J, Guo J, Li S (2013) Study on boreholes layout and effect of dustproof with water injection in complicated coal seam. Coal Sci Technol 41(8):65–67Google Scholar
  76. Xie H, Wang K (2015) Research on status and development about technology of dust control by injecting water in coal seam. J North China Inst Sci Technol 12(6):10–13Google Scholar
  77. Xing S, Li Y, Yang D (2012) Application and exploration of short wall water injection in thin coal seam in tian Zhuang coal mine. Shandong Coal Sci Technol 4:159Google Scholar
  78. Xu S, Xu P, Lv Y (1984a) Experimental research on long drilling hole injection in thin coal seam. Jiangsu Coal Sci Technol 4:19–26Google Scholar
  79. Xu S, Xu Y, Lv Y (1984b) Test of adding wetting agent in coal seam water injection. Coal Sci Technol 8:23–27Google Scholar
  80. Yang J, Xiu K, Jian G et al (2010) Surface characteristics and wetting mechanism of respirable coal dust. Int J Min Sci Technol 20(3):365–371Google Scholar
  81. Yang SB, Nie W, Liu ZQ et al (2019) Effects of spraying pressure and installation angle of nozzle on atomization characteristics of external spraying system at a fully-mechanized mining face. Powder Technol 343:754–764Google Scholar
  82. Yao Q, Xu C, Zhang Y, Zhou G, Zhang S, Wang D (2017) Micromechanism of coal dust wettability and its effect on the selection and development of dust suppressants. Process Saf Environ Prot 111:726–732Google Scholar
  83. Yin SH, Xun C, Jiang LC (2015) Effect of ore particle size on solution capillary seepage in ore heaps. Chin J Eng 37(5):561–567Google Scholar
  84. Yin L, Ren T, Wynne et al (2016) A comparative study of dust control practices in Chinese and Australian longwall coal mines. Int J Min Sci Technol 26(2):199–208Google Scholar
  85. Yuan ZG, Wang HT, Hu GZ et al (2011) Fisher discriminant analysis model and application of classifying difficulty degree of water infusion for coal seam. J China Coal Soc 36(4):638–642Google Scholar
  86. Zhang Y (1994) The study of adding wetting agent to coal water injection. J Saf Sci Technol 1:47–53Google Scholar
  87. Zhang Y (1995) Study on mechanism of wetting agent to improve water injection effect in coal seam. Mech Eng 17(3):54–57Google Scholar
  88. Zhang Y (2001a) Coal seam water injection technology. China Coal Industry Publishing House, BeijingGoogle Scholar
  89. Zhang Y (2001b) Research on fully-mechanized caving coal seam affusion technology. Coal Sci Technol 29(1):33–35Google Scholar
  90. Zhang M (2008) Application of shallow hole dynamic pressure water injection and dust prevention technology in mining face of three soft coal seams. Coal Eng 6:54–55Google Scholar
  91. Zhang W (2015) Experimental study on compound wetting agent of dust prevention and water injection for coal seam. Anhui University Of Science and Technology, Hefei, Master thesisGoogle Scholar
  92. Zhang Z, Chen X (2000) Study on technology for water injection by long bore hole in three soft seam. China Saf Sci J 10(3):54Google Scholar
  93. Zhang D, Liu B (2017) Statistics and prospect of occupational diseases of mine in China. China Energy Environ Prot 39(9):173–178Google Scholar
  94. Zhang X, Song W (2006) Theoretical study on the seepage of water flooding in dual media of coal rock. J China Coal Soc 31(2):187–190Google Scholar
  95. Zhang YK, Wang WY, Zhou JJ (2010) The influence of water injection pressure on percolation of low permeability reservoirs. Lithologic Reservoirs 22(2):120–124Google Scholar
  96. Zhang S, Yu SJ, Song L, Shi X (2017) Reliability analysis of coal seam water injection system based on multilevel flow models. Saf Coal Mines 48(4):172–175Google Scholar
  97. Zhang HH, Nie W, Wang HK, Bao Q, Jin H, Liu Y (2018) Preparation and experimental dust suppression performance characterization of a novel guar gum-modification-based environmentally-friendly degradable dust suppressant. Powder Technol 339:314–325Google Scholar
  98. Zhao ZB (2008) Study of technology of variable-frequency pulse water infusion into coal seam. J Min Saf Eng 25(4):486–789Google Scholar
  99. Zhao H (2016) Application technology of coal seam water injection in three soft coal seams. Mech Eng 3:206–207Google Scholar
  100. Zhao Y, Hu Y, Duan K (1990). Consolidation mathematical model and numerical method for seepage of coal and rock strata. The National Symposium on numerical computation and model experiments of rock mechanicsGoogle Scholar
  101. Zheng L, Wang X (2015) Fault tree analysis of coal dust explosion. China Mine Eng 44:69–72Google Scholar
  102. Zheng B, Jin X, Wei C (2014) Analysis of effect of water injection test on thin seam face and summary of dust proofing. Manag Technol SME 3:137–139Google Scholar
  103. Zhou G, Ma Y, Fan T, Wang G (2018) Preparation and characteristics of a multifunctional dust suppressant with agglomeration and wettability performance used in coal mine. Chem Eng Res Des 132:729–742Google Scholar
  104. Zhu R, Jin D (2004) Reasonable choice of infusion parameter in coal seam and the analysis of dust-proof effect. J Huainan Vocat Tech Coll 4(4):93–95Google Scholar
  105. Zhu J, Liu H (2009) Analysis on the dustproof effect of water injection in coal Seam305 working face. Coal mine modernization (z1): 39–40Google Scholar
  106. Zhu X, Lu Z (2017) Analysis on the characteristics of pneumoconiosis in coal mines in China and its control countermeasures. J Sci Eng Res 4(10):477–482Google Scholar

Copyright information

© Springer-Verlag GmbH Germany, part of Springer Nature 2019

Authors and Affiliations

  • Kaixuan Zhang
    • 1
    • 2
  • Jian Zhang
    • 1
    • 2
    Email author
  • Jianping Wei
    • 2
    • 3
  • Ting Ren
    • 4
  • Xiangyu Xu
    • 1
    • 2
  1. 1.State Key Laboratory Cultivation Base for Gas Geology and Gas ControlHenan Polytechnic UniversityJiaozuoChina
  2. 2.College of Safety Science and EngineeringHenan Polytechnic UniversityJiaozuoChina
  3. 3.The Collaborative Innovation Center of Coal Safety Production of Henan ProvinceJiaozuoChina
  4. 4.School of Civil, Mining & Environmental EngineeringUniversity of WollongongWollongongAustralia

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