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INDUSTRY SAFETY AND LABOUR PROTECTION
Название Forms of connection of methane with coal matrix and gas drainage efficiency
DOI 10.17580/gzh.2016.10.17
Автор Vasyuchkov Yu. V.
Информация об авторе

College of Mining, National University of Science and Technology – MISIS, Moscow, Russia:

Yu. V. Vasyuchkov, Professor, Doctor of Engineering Sciences, vas-yury@yandex.ru

Реферат

Gas-bearing coal mining is associated with sealed-off draining of mixture of methane and air to bypass mine workings. The second half of the 20th century featured creation and introduction of methods to predict methane release in underground excavations, as well as technologies and techniques of coalbed methane drainage, including drilling, vacuum degassing and sealed-off drainage of air and methane mixture to ground surface. Heading with heavy-duty mining machinery required new approaches and means to intensify gas drainage in order to ensure standard safety and high outputs per development and production faces. However, methane releases in roadways yet remain a serious threat to health and life of miners. This article considers discovered forms of connection of methane with coal matrix, which confirms the existence of strong intermolecular association between methane and its organic microstructure. As regards the forms of connection, there can be nonassociated gas obeying the laws of viscous transfer in fractured-and-porous structure of coal, occluded methane, fixed gas concentrated on inner surface of micropores in coal, methane in the form of solid coal-and-gas solution (absorbed gas) and gas-crystal methane included in crystals of the organic structure of coal. The latter three forms make molecular coalbed methane obeying the laws of diffusion under transfer in coal. For each form of gaseousness, the author quantitatively estimates activation energy required for methane molecules to transfer from bound state to free state. The described gas drainage methods enable reaching the wanted efficiency of coal degassing. Parameters of the existing techniques of coal drainage stimulation are presented. The scope of the analysis embraces the extensive domestic experience gained in hydraulic fracturing and physicochemical treatment of gas-bearing coal beds based on high-pressure injection of power fluids to create extensive permeable fracturing patterns for deep coal-mine drainage.

Ключевые слова Mineral coal, coal bed, methane content, coal-and-methane connection, free methane, absorbed gas, occluded methane
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