Numerical simulation of respirable dust transport law in fully mechanized excavation face
Due to its small particle size, respirable dust is more likely to enter the deep respiratory tract, and it is difficult to settle in the roadway for a long suspension time. In order to improve the problem of serious respirable dust pollution on the excavation surface, we conducted a study on the dri...
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Editorial Office of Safety in Coal Mines
2025-06-01
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| Series: | Meikuang Anquan |
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| Online Access: | https://www.mkaqzz.com/cn/article/doi/10.13347/j.cnki.mkaq.20240161 |
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| author | Jianguo WANG Bolan WANG Min HAN |
| author_facet | Jianguo WANG Bolan WANG Min HAN |
| author_sort | Jianguo WANG |
| collection | DOAJ |
| description | Due to its small particle size, respirable dust is more likely to enter the deep respiratory tract, and it is difficult to settle in the roadway for a long suspension time. In order to improve the problem of serious respirable dust pollution on the excavation surface, we conducted a study on the driving face of 42207 auxiliary transport roadway in Liangshuijing Mine. Based on the theory of gas-solid two-phase flow, the air flow condition and the migration and distribution characteristics of respirable dust in the tunnel under press-in ventilation were studied by numerical simulation. The simulation results showed that air flow plays a major role in dust migration within the roadway and can be divided into three regions: vortex region, jet region and reflux region. Under single air flow action, dense distribution of dust varies across different regions. At the driving face, high-speed jets carry large amounts of respirable dust which gather between working faces and driving machines resulting in an average concentration of about 2 300 mg/m3 at the driving face. In the vicinity of the TBM, that is, within the first 15 m of the tunnel, most of the dust particles are affected by the eddy currents above and behind the TBM, causing most of the particles to accumulate at the eddy currents, while the rest settle at the bottom of the tunnel, and the other part continues to move backward along the left side wall of the tunnel under the action of wind currents. The average mass concentration of the dust on the left side of the tunnel reaches more than 1 000 mg/m3. When the air flow field is far away from the tunneling surface and without the obstruction of the tunneling machine, the airflow field diffuses and the wind speed decreases, but a large number of particles still float in the roadway for a long time and are difficult to settle due to the small particle size of the exhaled dust. |
| format | Article |
| id | doaj-art-ffb50825459a4b8c9a475b1ef7d5d04e |
| institution | OA Journals |
| issn | 1003-496X |
| language | zho |
| publishDate | 2025-06-01 |
| publisher | Editorial Office of Safety in Coal Mines |
| record_format | Article |
| series | Meikuang Anquan |
| spelling | doaj-art-ffb50825459a4b8c9a475b1ef7d5d04e2025-08-20T02:06:44ZzhoEditorial Office of Safety in Coal MinesMeikuang Anquan1003-496X2025-06-01566717810.13347/j.cnki.mkaq.20240161lyMKAQ20240161Numerical simulation of respirable dust transport law in fully mechanized excavation faceJianguo WANG0Bolan WANG1Min HAN2College of Safety Science and Engineering, Xi’an University of Science and Technology, Xi’an 710054, ChinaCollege of Safety Science and Engineering, Xi’an University of Science and Technology, Xi’an 710054, ChinaCollege of Safety Science and Engineering, Xi’an University of Science and Technology, Xi’an 710054, ChinaDue to its small particle size, respirable dust is more likely to enter the deep respiratory tract, and it is difficult to settle in the roadway for a long suspension time. In order to improve the problem of serious respirable dust pollution on the excavation surface, we conducted a study on the driving face of 42207 auxiliary transport roadway in Liangshuijing Mine. Based on the theory of gas-solid two-phase flow, the air flow condition and the migration and distribution characteristics of respirable dust in the tunnel under press-in ventilation were studied by numerical simulation. The simulation results showed that air flow plays a major role in dust migration within the roadway and can be divided into three regions: vortex region, jet region and reflux region. Under single air flow action, dense distribution of dust varies across different regions. At the driving face, high-speed jets carry large amounts of respirable dust which gather between working faces and driving machines resulting in an average concentration of about 2 300 mg/m3 at the driving face. In the vicinity of the TBM, that is, within the first 15 m of the tunnel, most of the dust particles are affected by the eddy currents above and behind the TBM, causing most of the particles to accumulate at the eddy currents, while the rest settle at the bottom of the tunnel, and the other part continues to move backward along the left side wall of the tunnel under the action of wind currents. The average mass concentration of the dust on the left side of the tunnel reaches more than 1 000 mg/m3. When the air flow field is far away from the tunneling surface and without the obstruction of the tunneling machine, the airflow field diffuses and the wind speed decreases, but a large number of particles still float in the roadway for a long time and are difficult to settle due to the small particle size of the exhaled dust.https://www.mkaqzz.com/cn/article/doi/10.13347/j.cnki.mkaq.20240161fully mechanized excavation facepress-in ventilationrespirable dustair flow characteristicmigration law |
| spellingShingle | Jianguo WANG Bolan WANG Min HAN Numerical simulation of respirable dust transport law in fully mechanized excavation face Meikuang Anquan fully mechanized excavation face press-in ventilation respirable dust air flow characteristic migration law |
| title | Numerical simulation of respirable dust transport law in fully mechanized excavation face |
| title_full | Numerical simulation of respirable dust transport law in fully mechanized excavation face |
| title_fullStr | Numerical simulation of respirable dust transport law in fully mechanized excavation face |
| title_full_unstemmed | Numerical simulation of respirable dust transport law in fully mechanized excavation face |
| title_short | Numerical simulation of respirable dust transport law in fully mechanized excavation face |
| title_sort | numerical simulation of respirable dust transport law in fully mechanized excavation face |
| topic | fully mechanized excavation face press-in ventilation respirable dust air flow characteristic migration law |
| url | https://www.mkaqzz.com/cn/article/doi/10.13347/j.cnki.mkaq.20240161 |
| work_keys_str_mv | AT jianguowang numericalsimulationofrespirabledusttransportlawinfullymechanizedexcavationface AT bolanwang numericalsimulationofrespirabledusttransportlawinfullymechanizedexcavationface AT minhan numericalsimulationofrespirabledusttransportlawinfullymechanizedexcavationface |