Determining the Layout Parameters of the Gas Drainage Roadway: A Study for Sima Coalmine China

To determine the layout parameters of the gas drainage roadway (GDR) serving for the working face, an analytical calculation method of fracture zone and the modelling experiment were adopted, and the overburden fissure induced by mining and the height of fracture zone were analyzed. For the research on the distribution of fracture zone by analytical calculation method, the multiple factors influencing the failure mode of strata and the height of fracture zone were considered. The #1207 working face in Sima mine was taken as an engineering background, and the layout parameters of GDR were given by analyzing the height of fracture zone. Combining the results obtained by analytical calculation and scale modelling experiment, the suggested height of GDR was 10.7–32.8 m away from the coal seam roof, and the projection distance of GDR in the horizontal was within the range of 0–35 m from the airway. By monitoring the gas drainage effects in different heights away from coal seam roof in #1207 working face and in different horizontal distances away from the ventilation roadway in the #1211 working face, the results showed that the optimal height was 17.5–22 m away from coal roof, and the optimal horizontal distance was 17–21 m away from airway for GDR. The gas drainage effect of GDR indicated that the proposed parameters are scientific and reasonable.

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Computational fluid dynamics optimization of gas drainage technology in gas-mining areas

Energy Exploration & Exploitation ◽

10.1177/01445987211063586 ◽

2021 ◽

pp. 014459872110635

Author(s):

Wei Zhao ◽

Wei Qin

Keyword(s):

Fluid Dynamics ◽

Computational Fluid Dynamics ◽

Coal Seam ◽

Field Tests ◽

Mining Area ◽

Engineering Practice ◽

Horizontal Distance ◽

Gas Drainage ◽

Working Face ◽

Gas Seepage

Coal mining results in strata movement and surrounding rock failure. Eventually, manual mining space will be occupied by the destructed coal rock, making it difficult to conduct field tests of the coal seam to explore gas seepage and transport patterns. Therefore, computational fluid dynamics (CFD) numerical computation is an important tool for such studies. From the aspect of gas pre-drainage, for layer-through boreholes in the floor roadway of the 8,406 working face in Yangquan Mine 5 in China, reasonable layout parameters were obtained by CFD optimization. For effectively controlling the scope of boreholes along coal seam 9 in the Kaiyuan Mine, CFD computation was performed. The results revealed that the horizontal spacing between boreholes should be ≤2 m when a tri-quincuncial borehole layout is used. Optimization of the surface well position layout for the fault structure zone in the Xinjing Mine of the Yangquan mining area indicated that the horizontal distance between the surface well and the fault plane should be <150 m. From the aspect of gas drainage with mining-induced pressure relief, CFD computation was performed for pressure-relieved gas transport in the K8205 working face of Yangquan Mine 3. The results showed that forced roof caving should be used before the overhang length of hard roof reaches 25 m in the K8205 working face to avoid gas overrun. From the aspect of gas drainage from the abandoned gob, surface well control scopes at different surface well positions were computed, and an O-ring fissure zone is proposed as a reasonable scope for the surface well layout. CFD computation has been widely applied to coal and gas co-extraction in the Yangquan mining area and has played a significant role in guiding related gas drainage engineering practice.

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Improvement and application of hole-sealing technology across seams in Song Zao coal mine

E3S Web of Conferences ◽

10.1051/e3sconf/20185302003 ◽

2018 ◽

Vol 53 ◽

pp. 02003

Author(s):

Rili Yang ◽

Xiaoxia Zhao ◽

Lan Yu

Keyword(s):

Coal Seam ◽

Coal Mine ◽

Field Conditions ◽

Test Results ◽

Pressure Relief ◽

Gas Drainage ◽

Working Face ◽

Sealing Material ◽

Drainage Effect ◽

The Cost

Through the analysis on the drilling hole gas drainage effect(2225 working face crossing seam drainage, K2air way drilling field layout, crossing seam drainage gas in K3b coal seam),it is found that hole sealing technology directly affects gas drainage. Based on the original hole sealing technology and combining with field conditions, an improved drilling scheme for transportation roadway was proposed, considering the drilling layout, sealing material and depth, grouting time, pre-plunging depth. Test results of the scheme showed that, with a rise in the cost and drilling pressure relief time, the pressuring-relief gas drainage amount was greatly increased, the drilling field pre-pumping concentration was enhanced to 4.4times, the drainage efficiency was improved.

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Determination of Long Horizontal Borehole Height in Roofs and its Application to Gas Drainage

Energies ◽

10.3390/en11102647 ◽

2018 ◽

Vol 11 (10) ◽

pp. 2647

Author(s):

Gang Wang ◽

Cheng Fan ◽

Hao Xu ◽

Xuelin Liu ◽

Rui Wang

Keyword(s):

Numerical Simulation ◽

Theoretical Model ◽

Fracture Zone ◽

Coalbed Methane ◽

High Efficiency ◽

Gas Drainage ◽

Methane Drainage ◽

Working Face ◽

Variation Characteristics

Accurately determining the height of the gas-guiding fracture zone in the overlying strata of the goaf is the key to find the height of the long horizontal borehole in the roof. In order to determine the height, in this study we chose the 6306 working face of Tangkou Coal Mine in China as a research example and used both the theoretical model and discrete element method (DEM) numerical simulation to find the height of the gas-guiding fracture zone and applied the height to drill a long horizontal borehole in the roof of the 6303 working face. Furthermore, the borehole was utilized to deep into the roof for coalbed methane drainage and the results were compared with conventional gas drainage measures from other aspects. The height of the gas-guiding fracture zone was found to be 48.57 m in theoretical model based on the bulk coefficient and the void ratio and to be 51.19 m in the DEM numerical simulation according to the temporal and spatial variation characteristics of porosity. Taking both the results of theoretical analysis and numerical simulation into consideration, we determined that gas-guiding fracture zone is 49.88 m high and applied it to drill a long horizontal borehole deep into the roof in the 6303 working face field. Compared with conventional gas drainage measures, we found that the long horizontal borehole has the high stability, high efficiency and strong adaptability for methane drainage.

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Study on the Development Height of Overburden Water-Flowing Fracture Zone of the Working Face

Geofluids ◽

10.1155/2021/5570884 ◽

2021 ◽

Vol 2021 ◽

pp. 1-10

Author(s):

Ke Ding ◽

Lianguo Wang ◽

Wenmiao Wang ◽

Kai Wang ◽

Bo Ren ◽

...

Keyword(s):

Coal Seam ◽

Fracture Zone ◽

Tensile Deformation ◽

Drainage Water ◽

Future Research ◽

Overburden Rock ◽

Material Transfer ◽

Rock Stratum ◽

Working Face ◽

Sandstone Rock

Mining-induced fractures in underground coal mining face affect the stability of overburdens and provide preferential channels for water and material transfer in the underground environment. Therefore, to study the development of water-flowing fracture zones in overburdens of working face and goaf is of great significance for roof control, gas drainage, water resistance, disaster reduction, and efficient mining from the mining. In this study, a new method for predicting the development of overburden water-flowing fracture zone height (DHOWFFZ) was proposed based on the characteristics of overburden rock in No. 3 coal seam of Xin’an Coal Mine. First, the stope of No. 3 coal seam exhibits a rock stratum structure of mudstone and sandstone overlapping. Considering this characteristic, the overburden strata of No. 3 coal seam are divided into several “mudstone-sandstone” rock stratum groups. Furthermore, the ultimate tensile deformation of soft rock is greater than that of hard rock. It is proposed to judge the development degree of penetrating fracture in each rock stratum by adopting the elongation rate of mudstone intermediate layer. Meanwhile, the DHOWFFZ of “mudstone sandstone” composite rock stratum structure in the 3402 working face of No. 3 coal seam is calculated to be smaller than 43.1 m according to the actual situation. Finally, the DHOWFFZ in the 3402 working face was measured in the field, which verifies the rationality of the new DHOWFFZ prediction method. The research results provide new ideas for the prediction of DHOWFFZ and are helpful for future research in related fields.

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Reasonable Scope of Kilometer Drilling in Lower Layer of Extrathick Coal Seam: A Case Study of Tingnan Coal Mine, China

Advances in Civil Engineering ◽

10.1155/2021/2044717 ◽

2021 ◽

Vol 2021 ◽

pp. 1-17

Author(s):

Delong Zou ◽

Xiang Zhang

Keyword(s):

Coal Seam ◽

Coal Mine ◽

Lower Layer ◽

Maximum Depth ◽

Support Pressure ◽

Directional Drilling ◽

Pressure Relief ◽

Gas Drainage ◽

Working Face ◽

Fracture Development

When stratified mining is adopted in high-gas and extrathick coal seam, a large amount of pressure-relief gas of the lower layer flows into the upper layer goaf along the cracks in the layer, resulting in upper layer working face to frequently exceed the gas limit. And ordinary drilling can no longer meet the requirements of the pressure-relief gas drainage of the lower layer. The 205 working face of Tingnan Coal Mine is taken as the test background in this paper, and based on the “pressure-relief and flow-increase” effect of the lower layer under the action of mining stress during the upper layer mining, the gas drainage of kilometer directional drilling in lower layer is studied. According to the distribution characteristics of support pressure before and after the working face, the pressure-relief principle, fracture development characteristics, and gas migration law of the lower layered coal body are analyzed in the process of advancing the upper layered working face in the extrathick coal seam with high gas. The maximum depth of goaf damage is calculated theoretically, and the Flac3D numerical simulation of the failure deformation of the 205 working face floor is carried out. It is found that the maximum depth of plastic failure of the lower layer is about 13 m. According to the plastic deformation of the lower layer under different vertical depths and the movement of coal and rock mass, it is determined that the reasonable range of kilometer directional drilling in the lower layer is 6–9 m below the floor vertical depth. From 15 m to 45 m in the two parallel grooves, there is no fracture failure with a sharp increase or decrease in the displacement in the local range. Meanwhile, in this part, the roof falling behind is not easy to compaction, and the displacement of the floor is large, which does not cause plastic damage. The degree of pressure relief is more sufficient, and the permeability of the lower layer is good. Therefore, drilling should be arranged as much as possible along the working face in this tendency range. The determination of reasonable arrangement range of kilometer directional drilling in extrathick coal seam provides reference index and theoretical guidance for industrial test of working face and also provides new ideas for gas control of stratified mining face in high-gas and extrathick coal seam.

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Influence of Long Boreholes Layout and Drilling Length on Gas Drainage Based on Multifield Coupling Model of Gas-Bearing Coal

Advances in Civil Engineering ◽

10.1155/2021/1473769 ◽

2021 ◽

Vol 2021 ◽

pp. 1-16

Author(s):

Renjun Feng

Keyword(s):

Coupling Model ◽

Specific Reference ◽

Gas Migration ◽

Quantitative Characterization ◽

Gas Drainage ◽

Drainage Time ◽

Working Face ◽

Drainage Effect ◽

Gas Bearing

Gas drainage through long seam boreholes is an effective method to prevent gas disasters in coal mines. In this paper, a multifield coupling model of gas migration in gas-bearing coal was first established. Then, a quantitative characterization method of gas drainage effect was put forward. Finally, the extraction effect of long boreholes was obtained under different layouts and drilling lengths. The research results show that, under the arrangement of long boreholes along the seam, the gas pressure around the borehole decreases significantly with the extraction time. There is no extraction blank in the middle of the working face. However, it is easy to cause uneven gas drainage in the combined arrangement of the long boreholes along the seam and the penetrating boreholes. Furthermore, it is found that the drainage volume of the long boreholes along the seam is similar to that of the joint layout under the same drainage time. As the length of the borehole increases, the influencing range of gas drainage increases. When the borehole lengths are 150 m and 240 m, the drainage volumes are about 1.31 and 2.50 times that of the 90 m boreholes, respectively. The research achievements could provide a specific reference for the layout of long boreholes along the bedding and the determination of reasonable parameters for gas drainage on site.

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The Application of Gas Drainage Technology in the Workface of "Three Soft" Specially Thick Coal Seam

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.204-208.3469 ◽

2012 ◽

Vol 204-208 ◽

pp. 3469-3475

Author(s):

Guo Liang Lu ◽

Chen Wang ◽

Yao Dong Jiang ◽

Hong Wei Wang

Keyword(s):

Coal Seam ◽

Production Process ◽

Low Permeability ◽

Gas Drainage ◽

Thick Coal Seam ◽

Mine Area ◽

Soft Coal ◽

Drainage Effect ◽

Soft Coal Seam

In order to improve the gas drainage effect of "three soft" coal seam with low-permeability and eliminate the gas overrun in the upper corner and return air during the production process, this paper did an exploration on the comprehensive gas management on the fully mechanized caving face of gassy mines in Xuangang mine area and its application achieved a good result.

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Analysis of Overlying Strata Movement and Disaster-Causing Effects of Coal Mining Face under the Action of Hard Thick Magmatic Rock

Processes ◽

10.3390/pr6090150 ◽

2018 ◽

Vol 6 (9) ◽

pp. 150 ◽

Cited By ~ 8

Author(s):

Quanlin Wu ◽

Quansen Wu ◽

Yanchao Xue ◽

Peng Kong ◽

Bin Gong

Keyword(s):

Coal Seam ◽

Fracture Zone ◽

Magmatic Rock ◽

Ratio Test ◽

Large Area ◽

Deformation And Failure ◽

Key Strata ◽

Magmatic Rocks ◽

Working Face ◽

Bed Separation

When the hard and thick key strata are located above the working face, the bed separation structure is easy to be formed after mining because of the high strength and integrity of the hard and thick key strata and the initial breaking step is large. After the hard, thick strata are broken, the overburden will be largely collapsed and unstable in a large area and the dynamic disaster is easily induced. In this study, considering the fundamental deformation and failure effect of coal seam, the development law of the bed separation and the fractures under hard and thick magmatic rocks and the mechanism of breaking induced disaster of hard and thick magmatic rocks are studied by similar simulation tests. The results of the study are as follows: (1) The similar material ratio of coal seam is obtained by low-strength orthogonal ratio test of similar materials of coal seam, that is, cement:sand:water:activated carbon:coal = 6:6:7:1.1:79.9. (2) The magmatic rocks play a role in shielding the development of the bed separation, which makes the bed separation beneath the magmatic rock in an unclosed state for a long time, providing space for the accumulation of gas and water. (3) The distribution pattern of the fracture zone shows different shapes as the advancing of working face and the fracture zone width of the rear of working face coal wall is larger than that of the front of the open-off. (4) The breaking of magmatic rocks will press the gas and water accumulated in the bed separation space below to rush towards the working face along the fracture zone at both ends of the goaf. The above results are verified through the drainage borehole gas jet accident in the Yangliu coal mine. The research results are of great significance for revealing the occurrence process of dynamic disasters and adopting scientific and reasonable preventive measures.

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The Research on Abutment Stress Distribution and Fracture Characteristics of Coal Seam in Longwall Face

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.361-363.103 ◽

2011 ◽

Vol 361-363 ◽

pp. 103-107

Author(s):

Chuan Ming Li

Keyword(s):

Stress Distribution ◽

Coal Seam ◽

Surrounding Rock ◽

Geometrical Shape ◽

Horizontal Distance ◽

Site Testing ◽

Fracture Characteristics ◽

Working Face ◽

Coal Wall ◽

Overlying Strata

The abutment stress results from the load coming from overlying strata above the influence range of abutment stress and the load which coming from overlying strata above the stress shell passed by the shell. Through the mechanical calculation,this paper analyzed abutment stress distribution and fracture characteristics of coal seam resulted from the load of overlying strata passed by stress shell which exists in surrounding rock of working face, and obtained the laws of abutment stress distribution and fracture in coal seam in combination with numerical simulation and site testing. The characteristics of abutment stress distribution and fracture are related to the geometrical shape of the stress shell, such as height of the stress shell, horizontal distance between top of stress shell and coal wall,and width of stress shell skewback.

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Study on Permeability Improvement Technology by Injecting Air into the Gas Drainage Borehole in Low-Permeability Coal Seam

Advances in Civil Engineering ◽

10.1155/2018/1912383 ◽

2018 ◽

Vol 2018 ◽

pp. 1-7

Author(s):

Li Hui ◽

Guo Chengwei ◽

Sun Yuanfang ◽

Guo Shaoshuai

Keyword(s):

Coal Seam ◽

Gas Injection ◽

Vertical Direction ◽

Injection Pressure ◽

Gas Content ◽

Low Permeability ◽

Gas Drainage ◽

Working Face ◽

Injection Technology ◽

Time Required

Gas extraction cycle is too long in low-permeability coal seam. In order to solve the problem, the basic principle about gas drainage drilling for gas injection technology is studied to increase permeability. And the mathematical model is established. Gas is injected into the low-permeability coal seam by numerical simulation. The results indicate that the best condition is a negative pressure drainage at 26 kPa and a gas injection pressure at 0.6 MPa in the vertical direction and in the horizontal direction of the injection hole. In Shanxi Daping Coal Mine 3113 working face, the field test is implemented. As a result, the test is successful. During the 14 d gas injection constantly, gas content of coal seam is reduced from 12.33 m3/t to 7.12 m3/t, greatly reducing the risk of coal and gas outburst elimination time required.

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