Abstract
In the process of development and utilization of mine resources, the damp-heat environment has always been a difficult problem for mining. An enormous amount of research effort has gone into analyzing the underground operating environment. By summarizing the existing research theories on the damp-heat environment in the mine, this paper analyzed the influence of the wall rock, wind flow parameters, groundwater seepage, and other factors on the damp-heat environment and summarizes the determination of heat transfer coefficient (h) and mass transfer coefficient (m), which provided the theoretical basis for the improved technology of the damp-heat environment of mines. The field synergy theory (FST) reveals the essence of enhancing heat transfer performance and mass transfer performance and has been widely applied in engineering practice; based on the commonality between the research model of the FST and the damp-heat environment of the mine, we put forward a novel approach by using the FST to study the mine’s damp-heat problem and gave the research models based on the FST under the form of bifurcation and turning wall rock, which can be used to guide the design and layout of the mine wind flow deflector. Finally, considering the actual economic benefits of mine engineering, the FST and ventilation system power consumption are used as comprehensive evaluation indicators to guide the design of ventilation systems, which provided fresh concepts and approaches for improving the subterranean damp-heat environment.
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Acknowledgements
This work was supported by the National Science Foundation of China [52374209]; Shandong Natural Science Foundation [ZR2023ME012, ZR2023QE080]; and Outstanding youth innovation team project in Shandong colleges and Universities [2019KJH008].
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All authors contributed to the study conception and design. Min Qu contributed to writing-original draft preparation. Wentao Fan contributed to conceptualization ideas. Xiangnan chen contributed to methodology. Hongwei Mu contributed to investigation. Qinnglei Tan contributed to writing-reviewing and editing. Bing Shao contributed to software. Yongliang Zhang contributed to visualization.
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Qu, M., Fan, W., Chen, X. et al. Law of the damp heat in mines and its application exploration based on FST. J Therm Anal Calorim (2024). https://doi.org/10.1007/s10973-024-13069-9
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DOI: https://doi.org/10.1007/s10973-024-13069-9