TY - JOUR A1 - Kurnia, J.C. A1 - Xu, P. A1 - Sasmito, A.P. JF - Journal of Natural Gas Science and Engineering UR - https://www.scopus.com/inward/record.uri?eid=2-s2.0-84987968050&doi=10.1016%2fj.jngse.2016.09.013&partnerID=40&md5=cc99bd10d0dea79e921fa89310f4d00f VL - 35 Y1 - 2016/// N2 - Large amount of methane are released in the mining face area during active mining operation. To maintain safe working condition in the mining face and to maximize the potential usage of methane released from the mining face, an effective methane enhanced gas recovery strategy is essential. This study addresses the air flow and methane dispersion in the mining face and strategies to mitigate and enhance methane gas recovery for energy sources by using ventilation system. The investigated strategies involve installation of a suction duct and combination of brattice and suction duct. The aim is to collect methane-rich ventilation air via additional exhaust (suction) duct rather than disperse it and collect it later from the main exhaust shaft. Computational fluid dynamics (CFD) approach is utilized to investigate and examine the effectiveness of these strategies which will be evaluated in term of methane concentration in the mining face and at the outlet of suction duct. The effect of suction duct height, setback distance and suction velocity on the methane mitigation and recovery are also evaluated. The result indicates that suction-brattice configuration results in better methane control but yields lower methane concentration collected at the suction duct outlet. Among the studied parameters, suction velocity has significant influence while suction duct height and setback distance have marginal effect. The proposed strategies are potential to be applied in underground coal mine for methane mitigation and recovery. © 2016 Elsevier B.V. ID - scholars6843 KW - Coal mines; Computational fluid dynamics; Ducts; Metal recovery; Methanation; Mine ventilation; Recovery; Ventilation; Ventilation exhausts KW - Computational investigation; Enhanced gas recoveries; Methane concentrations; Methane controls; Methane extraction; Underground coal mine; Ventilation air methane; Ventilation systems KW - Methane EP - 672 PB - Elsevier B.V. SN - 18755100 N1 - cited By 22 TI - A novel concept of enhanced gas recovery strategy from ventilation air methane in underground coal mines â?? A computational investigation SP - 661 AV - none ER -