Response of pores in coal to repeated strong impulse waves

Repeated-strong-impulse-wave (RSIW) is a new development technique to enhance coalbed methane recovery. The objective of this paper is to investigate the response of pores to impacts using this device. Bituminous coals and anthracites were impacted, and their pores were analysed by mercury porosimet...

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Bibliographic Details
Published in:Journal of natural gas science and engineering 2016-08, Vol.34, p.298-304
Main Authors: Shi, Qingmin, Qin, Yong, Li, Hengle, Qiu, Aici, Zhang, Yongmin, Zhou, Xiaoting, Zheng, Shujie
Format: Article
Language:English
Subjects:
Coal
Crack
Fracture
Impact
Impulse wave
Pore
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Summary:Repeated-strong-impulse-wave (RSIW) is a new development technique to enhance coalbed methane recovery. The objective of this paper is to investigate the response of pores to impacts using this device. Bituminous coals and anthracites were impacted, and their pores were analysed by mercury porosimetry, a scanning electron microscope and an optical microscope. The results show that pores of anthracite have limited sensitivity to impacts, and their evolution trend is inconspicuous with increasing the number of impacts. Pores of bituminous coal are remarkably sensitive to impacts. The pore evolution of bituminous coal presents two stages during impacts, sharply increasing and then decreasing slowly. Impacts at higher energy levels shorten the process of pore evolution. The distribution of pores seems to be a reason that smaller pores in size are more sensitive to impacts than the larger ones. The mechanical property results in the differences in responses to impacts between bituminous coal and anthracite. Therefore, it is determined that pre-existing crack propagation is the primary fracturing mode of anthracite. Pore initiation and propagation contribute markedly to the fracture of bituminous coal during impacts. However, their contribution is gradually weakened in the second stage of impact evolution. •Repeated-strong-impulse-wave (RSIW) is a new technique to enhance CBM recovery.•Pre-existing crack propagation is the main fracturing mode of anthracite on RSIW impact.•Pore initiation and propagation contribute to the fracture of bituminous coal markedly.•Pore response to impact for bituminous coal is intensive, but not for anthracite.•The pore evolution of bituminous coal presents two stages during impact.
ISSN:1875-5100
DOI:10.1016/j.jngse.2016.06.067