Abstract
The pore-fractures network plays a key role in coalbed methane (CBM) accumulation and production, while the impacts of coal facies on the pore-fractures network performance are still poorly understood. In this work, the research on the pore-fracture occurrence of 38 collected coals from Sangjiang-Muling coal-bearing basins with multiple techniques, including mercury intrusion porosimetry (MIP), micro-organic quantitative analysis, and optic microscopy, and its variation controlling of coal face were studied. The MIP curves of 38 selected coals, indicating pore structures, were subdivided into three typical types, including type I of predominant micropores, type Ⅱ of predominant micropores and macropores with good connectivity, and type Ⅲ of predominant micropores and macropores with poor connectivity. For coal facies, three various coal facies were distinguished, including lake shore coastal wet forest swamp, the upper delta plain wet forest swamp, tidal flat wet forest swamp using Q-cluster analysis and tissue preservation index–gelification index (TPI-GI), and wood index–groundwater influence index (WI-GWI). The results show a positive relationship between tissue preservation index (TPI), wood index (WI), and mesopores (102 nm–103 nm), and a negative relationship between TPI, WI, and macropores/fractures. In addition, groundwater level fluctuations can control the development of type C and D fractures, and the frequency of type C and D fractures show an ascending trend with increasing groundwater index (GWI), which may be caused by the mineral hydration of the coal. Finally, from the perspective of the pore-fractures occurrence in CBM reservoirs, the wet forest swamp of upper delta plain is considered to be the optimization areas for Sangjiang-Muling coal-bearing basins by a comparative study of various coal facies.
Highlights
Coal is the source rock and reservoir for coalbed methane (CBM) [1]
The fracture is made up of micro-fracture and macro-fracture, the former is the bridge of pores and macro-fractures; macro-fracture is the pathway for CBM flow from coal reservoirs to Energies 2020, 13, 1196; doi:10.3390/en13051196
Compared withexperiment the gas adsorption method, a more comprehensive analyzing the pore characteristics of the porous medium, including porosity, pore structure, range of pore sizes could be measured with Mercury intrusion porosimetry (MIP), including pore characteristics of mesopore and pore connectivity, and pore compression coefficient
Summary
Coal is the source rock and reservoir for coalbed methane (CBM) [1]. High costs and low production rates are two key factors influencing CBM commercial development [7]. The dual pore-fracture system of CBM reservoir can provide CBM enrichment space and the channel for the gas adsorption, diffusion, and seepage. The fracture is made up of micro-fracture and macro-fracture, the former is the bridge of pores and macro-fractures; macro-fracture is the pathway for CBM flow from coal reservoirs to Energies 2020, 13, 1196; doi:10.3390/en13051196 www.mdpi.com/journal/energies. Evaluating pore-fracture is important to acquire a high abundance CBM reservoir and a high productivity reservoir
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