DEVELOPMENT OF A DETECTION SYSTEM AND DETERMINATION OF THE DIFFUSION COEFICIENT OF METHANE GAS FLOW THROUGH ROCK FRACTURES AND POROUS ROCKS IN COAL MINES AT A LABORATORY SCALE
The emission of methane gas in coal mines has significant negative impacts, such as contributing to the greenhouse effect, which leads to global warming, and the potential to cause methane gas explosions and produce toxic carbon monoxide gas. This highlights the severe dangers of methane emission...
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| Format: | Theses |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/86094 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | The emission of methane gas in coal mines has significant negative impacts, such
as contributing to the greenhouse effect, which leads to global warming, and the
potential to cause methane gas explosions and produce toxic carbon monoxide gas.
This highlights the severe dangers of methane emissions during mining and postmining activities. Therefore, monitoring methane leakage is essential for the early
detection of potential gas leaks.
The Automatic and Continuous Monitoring System — CO? (ACMS-COp) is a system
designed to monitor CO? emissions from the ground. However, previous studies of
this tool, which utilized soil CO: flux variables, revealed limited flexibility. Thus,
further development of the ACMS-COj is necessary to effectively monitor methane
Slow in coal mines. This research focuses on the development of the ACMS-CO) into
an Automatic and Continuous Monitoring System — CH4 (ACMS-CH4), which can
directly measure methane concentrations in the field with greater flexibility.
The methane concentration data obtained will then be processed to determine the
diffusion and permeability of methane gas, both through rock fractures and porous
rock. Numerical modeling will also be conducted to simulate methane gas diffusion
through rock fractures and porous rock using the explicit forward Euler method,
leveraging Microsoft Excel software.
The findings of this study indicate that the diffusion coefficient of methane gas in
rock fractures is influenced by the type of fracture, with simple rock fractures
diffusing methane gas more guickly than complex fractures. The diffusion
coefficient values in rock fractures are higher than in porous rock. Among porous
rocks, sandstone has a higher diffusion coefficient compared to siltstone. Numerical
modeling shows that the closer an area is to the methane gas source, the higher the
methane flow concentration and the type of rock also affects the concentration of
methane flow. In this study, siltstone was identified as the rock type with the lowest
capacity to transmit methane.
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