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A technical approach based on microbial technology is proposed to help resolve the problems caused by explosive gases in coal mines. The proposed technique uses methanotrophic bacteria to oxidize methane. In laboratory experiments, the oxidation effect of hanging nets impregnated with liquid containing methanotrophic bacteria was investigated at different air flow-rates. The experimental results showed that the volume of gas degraded and the gradient of degradation both increased as the gas concentration increased at constant air flow-rates. At fixed gas concentrations, the volume of degraded gas increased with increasing flow-rates of air at low flow-rates. However, the volume of degraded gas slightly decreased with increasing flow-rates of air at high flow-rates. These experimental results provide a theoretical basis for the treatment of explosive gases during exploration for natural gas and to treat potentially dangerous concentrations of gas in gobs, caves and upper corners of mineshafts. They will also be of great practical significance in coal mining.
Czasopismo
Rocznik
Tom
Strony
112--118
Opis fizyczny
Bibliogr. 13 poz., rys., tab., wykr.
Twórcy
autor
- School of Resource and Safety Engineering, Central South University, Changsha 410083, China
- School of Safety Engineering, Henan Institute of Engineering, Zhengzhou 451191, China
- The Cultivation Base of College and University Key Laboratory of Henan Province, China
- Key Laboratory of Safe Mining Techniques of Coal Mines, School of Energy and Safety Engineering, Hunan University of Science and Technology, Xiangtan 411201, China
autor
- Key Laboratory of Safe Mining Techniques of Coal Mines, School of Energy and Safety Engineering, Hunan University of Science and Technology, Xiangtan 411201, China
autor
- School of Safety Engineering, Henan Institute of Engineering, Zhengzhou 451191, China
- The Cultivation Base of College and University Key Laboratory of Henan Province, China
autor
- University of Kentucky, Lexington, KY 40506–0046, U.S.A
Bibliografia
- [1] M. Marschalko, M. Bednárik, I. Yilmaz, T. Bouchal, K. Kubečka, Evaluation of subsidence due to underground coal mining: an example from the czech republic, Bulletin of engineering geology and the environment 71 (1) (2012) 105–111.
- [2] C. Ö. Karacan, F. A. Ruiz, M. Cotè, S. Phipps, Coal mine methane: a review of capture and utilization practices with benefits to mining safety and to greenhouse gas reduction, International Journal of Coal Geology 86 (2) (2011) 121–156.
- [3] A. Y. Kallistova, M. Kevbrina, V. Nekrasova, M. Glagolev, M. Serebryanaya, A. Nozhevnikova, Methane oxidation in landfill cover soil, Microbiology 74 (5) (2005) 608–614.
- [4] G. Sakantsev, M. Sakantsev, V. Cheskidov, V. Norri, Improvement of deep-level mining systems based on optimization of accessing and open pit mine parameters, Journal of Mining Science 50 (4) (2014) 714–718.
- [5] S. Kotelnikova, Microbial production and oxidation of methane in deep subsurface, Earth-Science Reviews 58 (3) (2002) 367–395.
- [6] K. Win, R. Nonaka, A. Win, Y. Sasada, K. Toyota, T. Motobayashi, M. Hosomi, Comparison of methanotrophic bacteria, methane oxidation activity, and methane emission in rice fields fertilized with anaerobically digested slurry between a fodder rice and a normal rice variety, Paddy and Water Environment 10 (4) (2012) 281–289.
- [7] S. R. Mohanty, B. Kollah, V. K. Sharma, A. B. Singh, M. Singh, A. S. Rao, Methane oxidation and methane driven redox process during sequential reduction of a flooded soil ecosystem, Annals of Microbiology 64 (1) (2014) 65–74.
- [8] I. Karakurt, G. Aydin, K. Aydiner, Mine ventilation air methane as a sustainable energy source, Renewable and Sustainable Energy Reviews 15 (2) (2011) 1042–1049.
- [9] Y.-P. CHENG, H.-Y. LIU, P.-K. GUO, R.-K. PAN, L. WANG, A theoretical model and evolution characteristic of mining-enhanced permeability in deeper gassy coal seam, Journal of China Coal Society 39 (8) (2014) 1650–1658.
- [10] L. Wang, J. LIU, C. Longzhe, Dongke, Research prospect of applying microorganism in controlling coal gas, China Safety Science Journal 15 (10) (2005) 97–99.
- [11] X. DING, X. PENG, H. MIN, W. YANG, L. ZHANG, Y. JIN, Q. CHEN, Y. FANG, Z. WANG, J. GUAN, et al., Molecular mechanism of stress resistance in methanothermobacter thermoautotrophicus, Chinese Journal of Applied & Environmental Biology 3 (2011) 004.
- [12] Z. Ruilin, C. Chaunhui, W. Zhenjiang, The preliminary experiment research on gas degradation by microorganism under highpressure and poor-oxygen conditions, China Mining Magazine 23 (11) (2014) 132–135.
- [13] P. Jose Marjalizo-Cerrato, J. Tejero-Manzanares, F. Mata-Cabrera, F. Montes-Tubio, Intervention, search and rescue equipment within confined spaces, DYNA 88 (2) (2013) 216–225.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-752e55cd-af0c-498c-83fe-3a620ff124d5