Article: Numerical studies on the effects of water presence in the coal matrix and coal shrinkage and swelling phenomena on CO2-enhanced coalbed methane recovery process Journal: International Journal of Oil, Gas and Coal Technology (IJOGCT) 2012 Vol.5 No.1 pp.47 - 65 Abstract: Conventional coalbed methane (CBM) models are developed using dual-porosity, single-permeability domain characteristics, which ignore the effects of water presence in the coal matrix. Neglecting these effects typically over-predicts gas production. Another phenomenon often disregarded in most CBM models is the coal shrinkage and swelling effects, which cause changes in coal permeability. This study illustrates how the water presence in the coal matrix and coal shrinkage and swelling phenomena affect the CO2-enhanced CBM recovery process. An in-house two-phase, fully-implicit, compositional, dual-porosity, dual-permeability CBM simulator accounting for the effects of water presence in the coal matrix and coal shrinkage and swelling, is used in this analysis. Results demonstrate the water presence in the coal matrix caused an early CO2 breakthrough. A decrease in fracture permeability caused by the dominating effects of coal swelling delays the CO2 breakthrough. Ignoring these effects could provide significant errors of production predictions of enhanced CBM recovery process. [Received: May 10, 2011; Accepted: July 28, 2011] Inderscience Publishers - linking academia, business and industry through research

Title: Numerical studies on the effects of water presence in the coal matrix and coal shrinkage and swelling phenomena on CO₂-enhanced coalbed methane recovery process

Authors: Prob Thararoop; Zuleima T. Karpyn; Turgay Ertekin

Addresses: Petroleum and Natural Gas Engineering, The Pennsylvania State University, 128 Hosler Building, University Park, PA 16802, USA; Chevron Energy Technology Company, Houston, Texas, USA. ' Petroleum and Natural Gas Engineering, The Pennsylvania State University, 151 Hosler Building, University Park, PA 16802, USA. ' Petroleum and Natural Gas Engineering, The Pennsylvania State University, 151 Hosler Building, University Park, PA 16802, USA

Abstract: Conventional coalbed methane (CBM) models are developed using dual-porosity, single-permeability domain characteristics, which ignore the effects of water presence in the coal matrix. Neglecting these effects typically over-predicts gas production. Another phenomenon often disregarded in most CBM models is the coal shrinkage and swelling effects, which cause changes in coal permeability. This study illustrates how the water presence in the coal matrix and coal shrinkage and swelling phenomena affect the CO₂-enhanced CBM recovery process. An in-house two-phase, fully-implicit, compositional, dual-porosity, dual-permeability CBM simulator accounting for the effects of water presence in the coal matrix and coal shrinkage and swelling, is used in this analysis. Results demonstrate the water presence in the coal matrix caused an early CO₂ breakthrough. A decrease in fracture permeability caused by the dominating effects of coal swelling delays the CO₂ breakthrough. Ignoring these effects could provide significant errors of production predictions of enhanced CBM recovery process. [Received: May 10, 2011; Accepted: July 28, 2011]

Keywords: coalbed methane reservoirs; coal shrinkage; coal swelling; enhanced coalbed methane recovery; CO2 injection; carbon dioxide; coal seams; water presence; coal permeability; modelling.

DOI: 10.1504/IJOGCT.2012.044177

International Journal of Oil, Gas and Coal Technology, 2012 Vol.5 No.1, pp.47 - 65

Published online: 23 Oct 2014 *

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Title: Numerical studies on the effects of water presence in the coal matrix and coal shrinkage and swelling phenomena on CO2-enhanced coalbed methane recovery process

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Title: Numerical studies on the effects of water presence in the coal matrix and coal shrinkage and swelling phenomena on CO₂-enhanced coalbed methane recovery process