TY - GEN
T1 - Ex Situ UCG model experiments with oxygen enriched air in an artificial coal seam
AU - Su, Fa Qiang
AU - Itakura, Kenichi
AU - Hamanaka, Akihiro
AU - Deguchi, Gota
AU - Sato, Kohki
AU - Kodama, Jun Ichi
N1 - Publisher Copyright:
© 2017 Trans Tech Publications, Switzerland.
Copyright:
Copyright 2020 Elsevier B.V., All rights reserved.
PY - 2017
Y1 - 2017
N2 - Underground Coal Gasification (UCG) demands precise evaluation of the combustion area in the coal seam. Especially, the monitoring of fracture activity in the coal seam and around rock is important not only for efficient gas production but also for estimation of subsidence and gas leakage to the surface. For this objective, laboratory experiments were conducted using the simulated UCG models. This paper also investigated gas energy for coal consumption, the production gas quantity and heat value, the application of oxygen element balance in the gasification reaction process, and the gas composition obtained in this study. During burning of the coal, temperatures inside the coal, contents of product gases and acoustic emission (AE) activities were monitored successively under the control of feeding gas (air/oxygen and steam) flow rate. Comparison of the temperature variation and accumulated AE event curves revealed a close correlation between them. The local change of temperature inside the coal induced fractures with AE. The AE activity was related closely to the local changes of temperature inside the model. The evaluation of gas energy recovery calculated from the obtained product gas provided a fair evaluation for the coal consumed, and the quantity of gas product and calorific value obtained from the UCG process.
AB - Underground Coal Gasification (UCG) demands precise evaluation of the combustion area in the coal seam. Especially, the monitoring of fracture activity in the coal seam and around rock is important not only for efficient gas production but also for estimation of subsidence and gas leakage to the surface. For this objective, laboratory experiments were conducted using the simulated UCG models. This paper also investigated gas energy for coal consumption, the production gas quantity and heat value, the application of oxygen element balance in the gasification reaction process, and the gas composition obtained in this study. During burning of the coal, temperatures inside the coal, contents of product gases and acoustic emission (AE) activities were monitored successively under the control of feeding gas (air/oxygen and steam) flow rate. Comparison of the temperature variation and accumulated AE event curves revealed a close correlation between them. The local change of temperature inside the coal induced fractures with AE. The AE activity was related closely to the local changes of temperature inside the model. The evaluation of gas energy recovery calculated from the obtained product gas provided a fair evaluation for the coal consumed, and the quantity of gas product and calorific value obtained from the UCG process.
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U2 - 10.4028/www.scientific.net/KEM.737.379
DO - 10.4028/www.scientific.net/KEM.737.379
M3 - Conference contribution
AN - SCOPUS:85027010559
SN - 9783035710335
T3 - Key Engineering Materials
SP - 379
EP - 384
BT - Engineering Materials and Technology - ICMSET 2016
A2 - Jung, Jong Won
PB - Trans Tech Publications Ltd
T2 - International Conference on Material Science and Engineering Technology, ICMSET 2016
Y2 - 14 October 2016 through 16 October 2016
ER -