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Research Article

Laboratory Investigation of Underground Fire Hazard Control in Coal Mines by Use of the Pyrotechnic Aerosol

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Pages 232-246 | Received 13 Oct 2020, Accepted 20 Jun 2021, Published online: 12 Jul 2021

References

  • Beamish, B. B., and J. Theiler. 2019. Coal spontaneous combustion: Examples of the self-heating incubation process. Int. J. Coal Geol. 215:103297.
  • Korobeinichev, O. P., A. G. Shmakov, V. M. Shvartsberg, A. A. Chernov, S. A. Yakimov, K. P. Koutsenogii, and V. I. Makarov. 2012. Fire suppression by low-volatile chemically active fire suppressants using aerosol technology. Fire Saf. J. 51:102–09.
  • Kwon, K., and Y. Kim. 2013. Extinction effectiveness of pyrogenic condensed-aerosols extinguishing system. Korean J. Chem. Eng. 30:2254–58.
  • Li, J., Z. Li, Y. Yang, and X. Zhang. 2019. Study on the generation of active sites during low-temperature pyrolysis of coal and its influence on coal spontaneous combustion. Fuel 241:283–96.
  • Lu, Y., Y. Liu, S. Shi, G. G. X. Wang, H. Li, and T. Wang. 2020a. Micro-particles stabilized aqueous foam for coal spontaneous combustion control and its flow characteristics. Process Saf. Environ. Prot. 139:262–72.
  • Lu, Y., and B. T. Qin. 2015. Identification and control of spontaneous combustion of coal pillars: A case study in the Qianyingzi Mine, China. Nat. Hazard. 75:2683–97.
  • Lu, Y., Z. H. Yan, S. L. Shi, G. Wang, H. Li, H. Y. Niu, Z. G. Guo, and P. Wang. 2020b. Delineation and prevention of the spontaneous combustion dangerous area of coal in a regenerated roof: A case study in the Zhoujing coal mine, China. Energy Fuels 34:6401–13.
  • Ma, L., R. Guo, M. Wu, W. Wang, L. Ren, and G. Wei. 2020. Determination on the hazard zone of spontaneous coal combustion in the adjacent gob of different mining stages. Process Saf. Environ. Prot. 142:370–79.
  • Ma, L., D. Wang, Y. Wang, G. Dou, and H. Xin. 2017. Synchronous thermal analyses and kinetic studies on a caged-wrapping and sustained-release type of composite inhibitor retarding the spontaneous combustion of low-rank coal. Fuel Process. Technol. 157:65–75.
  • Qin, B., L. Li, D. Ma, Y. Lu, X. Zhong, and Y. Jia. 2016. Control technology for the avoidance of the simultaneous occurrence of a methane explosion and spontaneous coal combustion in a coal mine: A case study. Process Saf. Environ. Prot. 103:203–11.
  • Ren, X., X. Hu, D. Xue, Y. Li, Z. Shao, H. Dong, W. Cheng, Y. Zhao, L. Xin, and W. Lu. 2019. Novel sodium silicate/polymer composite gels for the prevention of spontaneous combustion of coal. J. Hazard. Mater. 371:643–54.
  • Shi, Q., and B. Qin. 2019. Experimental research on gel-stabilized foam designed to prevent and control spontaneous combustion of coal. Fuel 254:115558.
  • Song, Z., and C. Kuenzer. 2014. Coal fires in China over the last decade: A comprehensive review. Int. J. Coal Geol. 133:72–99.
  • Tang, Y. 2016. Inhibition of low-temperature oxidation of bituminous coal using a novel phase-transition aerosol. Energy Fuels 30:9303–09.
  • Tang, Y., S. Hu, and H. Wang. 2020. Using P–Cl inorganic ultrafine aerosol particles to prevent spontaneous combustion of low-rank coal in an underground coal mine. Fire Saf. J. 115:103140.
  • Tang, Y., and S. Xue. 2015. Laboratory study on the spontaneous combustion propensity of lignite undergone heating treatment at low temperature in inert and low-oxygen environments. Energy Fuels 29:4683–89.
  • Tang, Y. B., and H. E. Wang. 2018. Development of a novel bentonite-acrylamide superabsorbent hydrogel for extinguishing gangue fire hazard. Powder Technol. 323:486–94.
  • Taraba, B., and Z. Pavelek. 2014. Investigation of the spontaneous combustion susceptibility of coal using the pulse flow calorimetric method: 25 years of experience. Fuel 125:101–05.
  • Taraba, B., and Z. Pavelek. 2016. Study of coal oxidation behaviour in re-opened sealed heating. J. Loss Prev. Process Ind. 40:433–36.
  • Xue, D., X. M. Hu, W. M. Cheng, J. F. Wei, Y. Y. Zhao, and L. Shen. 2020. Fire prevention and control using gel-stabilization foam to inhibit spontaneous combustion of coal: Characteristics and engineering applications. Fuel 264, 116903.
  • Yang, Y. L., Z. H. Li, L. L. Si, S. S. Hou, Y. B. Zhou, and Q. Q. Qi. 2017. Consolidation grouting technology for fire prevention in mined-out areas of working face with large inclined angle and its application. Fire Mater. 41:700–15.
  • Ye, Y., Z. Han, Z. Du, L. Zhao, and X. Cong. 2017. New type pyrotechnically generated aerosol extinguishing agents containing phosphorus. J. Clean. Prod. 154:151–58.
  • Zhai, X., H. Ge, C.-M. Shu, D. Obracaj, K. Wang, and B. Laiwang. 2020. Effect of the heating rate on the spontaneous combustion characteristics and exothermic phenomena of weakly caking coal at the low-temperature oxidation stage. Fuel 268:117327.
  • Zhang, J., H. Zhang, T. Ren, J. Wei, and Y. Liang. 2019a. Proactive inertisation in longwall goaf for coal spontaneous combustion control-A CFD approach. Saf. Sci. 113:445–60.
  • Zhang, L., and B. Qin. 2016. Rheological characteristics of foamed gel for mine fire control. Fire Mater. 40:246–60.
  • Zhang, X., M. H. S. Ismail, F. R. B. Ahmadun, N. B. H. Abdullah, C. Hee, X. Zhang, M. H. S. Ismail, F. R. B. Ahmadun, N. B. H. Abdullah, and C. Hee. 2015. Hot aerosol fire extinguishing agents and the associated technologies: A review. Braz. J. Chem. Eng. 32:707–24.
  • Zhang, Y., C. Yang, Y. Li, Y. Huang, J. Zhang, Y. Zhang, and Q. Li. 2019b. Ultrasonic extraction and oxidation characteristics of functional groups during coal spontaneous combustion. Fuel 242:287–94.
  • Zhang, Y., Y. Zhang, Y. Li, Q. Li, J. Zhang, and C. Yang. 2020. Study on the characteristics of coal spontaneous combustion during the development and decaying processes. Process Saf. Environ. Prot. 138:9–17.
  • Zhou, C. S., Y. L. Zhang, J. F. Wang, S. Xue, J. M. Wu, and L. P. Chang. 2017. Study on the relationship between microscopic functional group and coal mass changes during low-temperature oxidation of coal. Int. J. Coal Geol. 171:212–22.
  • Zhou, F. B., B. B. Shi, J. W. Cheng, and L. J. Ma. 2015. A new approach to control a serious mine fire with using liquid nitrogen as extinguishing media. Fire Technol. 51:325–34.
  • Zhu, C. G., J. Wang, W. X. Xie, T. T. Zheng, and C. Lv. 2015. Improving strontium nitrate-based extinguishing aerosol by magnesium powder. Fire Technol. 51:97–107.

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