Research on Fractal Evolution Characteristics and Safe Mining Technology of Overburden Fissures under Gully Water Body
Abstract
:1. Introduction
2. Engineering Background
3. Analysis of DHWF
3.1. Overview of the Equation for Predicting DHWF
3.2. Applicability Analysis
3.3. Optimization of Mining Parameters
4. Experimental Study on Fracture Evolution with Different Mining Heights
4.1. Scale Models
4.2. Fractal Calculation Method and Results of Mining Fracture Network
4.3. Fractal Characteristics of Overlying Fracture Network Evolution during Height Reduction Mining
5. Safe Mining Technology
6. Discussion
- (1)
- The study site presents the mining conditions of a shallow coal seam, which is different from the fractal characteristics of overlying fissures in many deep coal seams mining [18,20]. The fractal dimension of the overlying fissures in shallow coal seams has more significant fluctuation characteristics. The reason for this difference deserves further study.
- (2)
- Under the condition of reduced mining height, the fractal dimension of similar simulations begins to fluctuate about 40 m ahead of full-thickness mining. The difference in excavation speed and the amount of mining space are possible influencing factors. According to the fractal dimension curve, the fluctuation characteristics show that there are also differences in the amplitude of the fractal dimension of the two times. The small-amplitude change of the mining thickness may cause the butterfly effect on the overburden fracture [29]. It is speculated that the mining overburden fracture may be a chaotic system.
- (3)
- Dynamic processing of the separation space is of great significance to the control of WF. Chinese scholars have proposed and practiced the grouting and filling technology in the separation space [30]. However, the positioning of the abscission space and the coordinating time and space of grouting and mining have not yet been solved well. Similar simulations are the most feasible among existing methods when studying separation filling technology, but the cost is prohibitive. Numerical simulation has a good advantage in repeating experiments, but it is difficult to characterize the separation space with finite element analysis, and it is difficult to express the grouting and filling effect in block discrete element software. Therefore, the modeling and quantitative analysis of the evolution and control of the separation space by numerical simulation is an important exploration direction.
7. Conclusions
- (1)
- Reducing mining height is an important technical means for safe mining under gullies, and the fractal dimension can describe the confusion of overlying fissures caused by different mining heights. The evolution process of overlying fissures in shallow coal seams can be divided into three stages according to the change law of fractal dimension: rising dimension, fluctuation, and stable stage.
- (2)
- Reviewing the prediction equation for the DHWF shows that the prediction equation for the height of the WF in the western mining area needs to be classified and regressed in combination with the specific overlying rock type, mining thickness, mining intensity, and other parameters to ensure the accuracy of the prediction.
- (3)
- The control of the separation space in the overlying rock is the key to avoiding the sudden increase of the WF height. The fluctuation process of the fractal dimension is consistent with the occurrence and disappearance of the separation space of the overlying rock.
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
Glossary
Hli | development height of the water-conducting fracture, m |
M | mining height, m |
ci | the coefficient that depends on strata lithology |
k | the coefficient in Equation (4) |
L | the working face inclination length, m |
b | the hard rock proportion coefficient |
H | the burial depth, m |
Σh | the cumulative total thickness of the hard rock in the overlying rock, m |
V | the daily mining speed, m |
KJ | the water-resistance coefficient of the bedrock |
HJ | the thickness of water-resistance bedrock, m |
Cl | the geometric similarity ratio |
Cγ | the bulk density similarity constant |
Cσ | the stress similarity constant |
Ct | the time similarity constant |
WF | water-conducting fracture |
DHWF | development height of the water-conducting fracture |
CIAS | Crack Information Analysis System |
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Lithology of Direct Roof | c1 | c2 | c3 | c4 | c5 |
---|---|---|---|---|---|
Hard | 1.2 | 2.0 | 8.9 | 30 | 10 |
Medium hard | 1.6 | 3.6 | 5.6 | 20 | 10 |
Soft and weak | 3.1 | 5.0 | 4.0 | 10 | 5 |
Extremely weak | 5.0 | 8.0 | 3.0 | - | - |
Equation | (1) | (2) | (3) | (4) | (7) * |
---|---|---|---|---|---|
DHWF/m | 26.8 | 25.0 | 52.1 | 84~120 | 86.6 |
Model Layer * | Lithology | Layer Height/cm | Sand/kg | CaCO3/kg | Gypsum/kg | Water/kg | n * |
---|---|---|---|---|---|---|---|
F2 | medium-grained sandstone | 10 | 217.2 | 21.7 | 50.7 | 32.2 | 1 |
F1 | sandy mudstone | 3 | 64.1 | 5.3 | 5.3 | 8.3 | 1 |
C | 2-2 coal seam | 4 | 86.1 | 12.1 | 5.2 | 11.5 | 1 |
R1 | mudstone | 0.6 | 12.7 | 1.3 | 0.5 | 1.6 | 1 |
R2(H) | medium and fine-grained sandstone | 3 | 64.1 | 7.5 | 3.2 | 8.3 | 2 |
R3 | sandy mudstone | 14.4 | 312.0 | 23.4 | 54.6 | 43.3 | 8 |
R4(H) | coarse sandstone | 8.5 | 183.6 | 12.2 | 28.6 | 24.9 | 4 |
R5 | sandy mudstone | 5 | 108.3 | 13.5 | 13.5 | 15.0 | 3 |
R6 | mudstone | 5 | 107.6 | 15.1 | 6.5 | 14.4 | 3 |
R7(H) | coarse sandstone | 8.5 | 183.6 | 12.2 | 28.6 | 24.9 | 4 |
R8 | sandy mudstone | 8 | 172.8 | 19.2 | 19.2 | 23.5 | 4 |
R9(H) | siltstone | 6 | 130.0 | 9.7 | 22.7 | 18.1 | 3 |
R10 | mudstone | 6 | 128.3 | 15.0 | 6.4 | 16.6 | 3 |
R11(H) | siltstone | 8 | 172.8 | 11.5 | 26.9 | 23.5 | 4 |
R12 | sandy mudstone | 9 | 194.4 | 21.6 | 21.6 | 26.4 | 4 |
R13(H) | siltstone | 8 | 172.8 | 11.5 | 26.9 | 23.5 | 4 |
R14 | sandy mudstone | 6 | 129.6 | 14.4 | 14.4 | 17.6 | 3 |
R15(H) | siltstone | 8 | 172.8 | 11.5 | 26.9 | 23.5 | 4 |
R16 | mudstone | 6 | 128.3 | 15.0 | 6.4 | 16.6 | 3 |
R17 | conglomerate | 10 | 211.1 | 18.5 | 7.9 | 26.4 | 4 |
R18(H) | coarse sandstone | 8 | 150.9 | 7.5 | 17.6 | 19.6 | 3 |
R19 | sandy mudstone | 12 | 212.7 | 21.3 | 21.3 | 28.4 | 5 |
R20 | fine sandstone | 10 | 158.2 | 15.8 | 6.8 | 20.1 | 3 |
R21 | sand, gravel | 8.2 | 118.2 | 6.6 | 6.6 | 14.6 | 2 |
s */m | Model 1: Mining Height 3.2 m | Model 2: Mining Height 4.0 m |
---|---|---|
40 | ||
80 | ||
120 | ||
160 | ||
200 |
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Miao, K.; Tu, S.; Tu, H.; Liu, X.; Li, W.; Zhao, H.; Tang, L.; Ma, J.; Li, Y. Research on Fractal Evolution Characteristics and Safe Mining Technology of Overburden Fissures under Gully Water Body. Fractal Fract. 2022, 6, 486. https://doi.org/10.3390/fractalfract6090486
Miao K, Tu S, Tu H, Liu X, Li W, Zhao H, Tang L, Ma J, Li Y. Research on Fractal Evolution Characteristics and Safe Mining Technology of Overburden Fissures under Gully Water Body. Fractal and Fractional. 2022; 6(9):486. https://doi.org/10.3390/fractalfract6090486
Chicago/Turabian StyleMiao, Kaijun, Shihao Tu, Hongsheng Tu, Xun Liu, Wenlong Li, Hongbin Zhao, Long Tang, Jieyang Ma, and Yan Li. 2022. "Research on Fractal Evolution Characteristics and Safe Mining Technology of Overburden Fissures under Gully Water Body" Fractal and Fractional 6, no. 9: 486. https://doi.org/10.3390/fractalfract6090486
APA StyleMiao, K., Tu, S., Tu, H., Liu, X., Li, W., Zhao, H., Tang, L., Ma, J., & Li, Y. (2022). Research on Fractal Evolution Characteristics and Safe Mining Technology of Overburden Fissures under Gully Water Body. Fractal and Fractional, 6(9), 486. https://doi.org/10.3390/fractalfract6090486