Since 1963
ARTICLE
Mechanisms of mining induced inrush of pressurized water in the floor containing faults
1
School of Architecture and Engineering, Liaocheng University, Liaocheng, China
2
The Commonwealth Scientific and Industrial Research Organisation, Queensland, Australia
3
Water-Sediment Regulation and Sand Effective Utilization Special Laboratory of Shandong Provincial Education
Department, Liaocheng University, Liaocheng, China
Submission date: 2023-10-10
Acceptance date: 2024-01-22
Online publication date: 2024-07-31
Publication date: 2024-07-31
Journal of Theoretical and Applied Mechanics 2024;62(3):573-585
KEYWORDS
floor concealed faultwater inrush mechanismmining-water pressure actioncrack propagationseepage path
TOPICS
ABSTRACT
Investigating the propagation of the seepage path of confined water in the floor is an impor-
tant means to determine the conditions of water inrush from the mine floor for deep mines
with high water pressure. In order to better understand the mechanisms of water inrush due
to the hidden fault floor above a confined water body, an integrated study including analyt-
ical analysis, and similarity simulation experiments were conducted. The study focuses on
the distribution of mining induced stress in the floor, the propagation of hidden faults, and
the evolution process of water inrush channels during longwall coal seam extraction.
REFERENCES (25)
1.
Aguilera M.A., Arias R.M., Manzur T., 2019, Mapping microhabitat thermal patterns in artificial breakwaters: Alteration of intertidal biodiversity by higher rock temperature, Ecology and Evolution, 9, 22, 12915-12927.
2.
Bhuiyan M.Y., Lin B., Giurgiutiu V., 2018, Acoustic emission sensor effect and waveform evolution during fatigue crack growth in thin metallic plate, Journal of Intelligent Material Systems and Structures, 29, 7, 1275-1284.
3.
Cao K.W., Ma L.Q., Wu Y., Khan N.M., Spearing A.J.S., Hussain S., Yang J., 2021, Cyclic fatigue characteristics of rock failure using infrared radiation as precursor to violent failure: Experimental insights from loading and unloading response, Fatigue and Fracture of Engineering Materials and Structures, 44, 2, 584-594.
4.
Guerin A., Jaboyedoff M., Collins B. D., Stock G. M., Derron M. H., Abellan A., Matasci B., 2021, Remote thermal detection of exfoliation sheet deformation, Landslides, 18, 3, 865-879.
5.
Li G., Zhu C., He M.C., Zuo Y.J., Gong F.Q., Xue Y.G., Feng G.L., 2023, Intelligent method for parameters optimization of cable in soft rock tunnel base on longitudinal wave velocity, Tunnelling and Underground Space Technology incorporating Trenchless Technology Research, 133, 104905.
6.
Lin Q.B., Cao P., Liu Y.Z., Cao R.H., Li J.T., 2021, Mechanical behaviour of a jointed rock mass with a circular hole under compression-shear loading: Experimental and numerical studies, Theoretical and Applied Fracture Mechanics, 114, 102998.
7.
Mezza S., Vazquez P., Ben M'barek Jemai M., Fronteau G., 2022, Infrared thermography for the investigation of physical-chemical properties and thermal durability of Tunisian limestone rocks, Construction and Building Materials, 339, 127470.
8.
Mineo S., Pappalardo G., 2019, InfraRed Thermography presented as an innovative and non-destructive solution to quantify rock porosity in laboratory, International Journal of Rock Mechanics and Mining Sciences, 115, 99-110.
9.
Pappalardo G., Mineo S., Imposa S., Grassi S., Leotta A., Rosa F.L., Salerno D., 2020, A quick combined approach for the characterization of a cliff during a post-rockfall emergency, Landslides, 17, 5, 1063-1081.
10.
Ren F.Q., Zhu C., He M.C., Shang J.L., Feng G.L., Bai J.W., 2022, Characteristics and precursor of static and dynamic triggered rockburst: Insight from multifractal, Rock Mechanics and Rock Engineering, 56, 3, 1945-1967.
11.
Tu W.F., Li L.P., Zhou Z.Q., Shang C.S., 2022, Thickness calculation of accumulative damaged zone by rock mass blasting based on Hoek-Brown failure criterion, International Journal of Geomechanics, 22, 2, 04021273.
12.
Wang Q., Xu S., Xin Z.X., He M.C., Wei H.Y., Jiang B., 2022, Mechanical properties and field application of constant resistance energy-absorbing anchor cable, Tunnelling and Underground Space Technology incorporating Trenchless Technology Research, 125, 104526.
13.
Xiong F., Zhu C., Feng G., Zheng J., Sun H., 2023, A three-dimensional coupled thermo-hydro model for geothermal development in discrete fracture networks of hot dry rock reservoirs, Gondwana Research, 122, 331-347.
14.
Yin Q., Wu J.Y., Jiang Z., Zhu C., Su H.J., Jing H.W., Gu X.W., 2022, Investigating the effect of water quenching cycles on mechanical behaviors for granites after conventional triaxial compression, Geomechanics and Geophysics for Geo-Energy and Geo-Resources, 8, 2, 77.
15.
Yin Q., Wu J.Y., Zhu C., He M.C., Meng Q.X., Jing H.W., 2021, Shear mechanical responses of sandstone exposed to high temperature under constant normal stiffness boundary conditions, Geomechanics and Geophysics for Geo-Energy and Geo-Resources, 7, 2, 1-17.
16.
Zhang C.Q., Cui G.J., Deng L., Zhou H., Lu J.J., Dai F., 2020a, Laboratory investigation on shear behaviors of bolt-grout interface subjected to constant normal stiffness, Rock Mechanics and Rock Engineering, 53, 3, 1333-1347.
17.
Zhang C.W., Jin Z.X., Feng G.R., Song X.M., Gao R., Zhang Y.J., 2020b, Double peaked stress-strain behavior and progressive failure mechanism of encased coal pillars under uniaxial compression, Rock Mechanics and Rock Engineering, 53, 7, 3253-3266.
18.
Zhang X.P., Lv G.G., Liu Q.S., Wu S.C., Zhang Q., Ji P.Q., Tang X.H., 2020c, Identifying accurate crack initiation and propagation thresholds in siliceous siltstone and limestone, Rock Mechanics and Rock Engineering, 54, 2, 973-980.
19.
Zhang W., Guo W.Y., Wang Z.Q., 2022a, Influence of lateral pressure on mechanical behavior of different rock types under biaxial compression, Journal of Central South University, 29, 11, 3695-3705.
20.
Zhang W., Xing M.L., Guo W.Y., 2023a, Study on fracture characteristics of anchored sandstone with precast crack based on double K criterion, International Journal of Solids and Structures, 275, 112296.
21.
Zhang W., Zhao T.B., Guo W.Y., Xing M.L., 2022b, Study on mechanical characteristics of rock type I fracture and anchorage strengthening mechanism, Journal of Theoretical and Applied Mechanics, 60, 3, 423-434.
22.
Zhang W., Zhao T.B., Yin Y.C., 2022c, Prefabricated fractured rock under stepwise loading and unloading, Journal of Theoretical and Applied Mechanics, 60, 1, 167-179.
23.
Zhang W., Zhang B.L., Zhao T.B., 2023b, Study on the law of failure acoustic-thermal signal of weakly cemented fractured rock with different dip angles, Rock Mechanics and Rock Engineering, 56, 6, 4557-4568.
24.
Zhao T.B., Guo W.Y., Tan Y.L., Yin Y.C., Cai L.S., Pan J.F., 2018, Case studies of rock bursts under complicated geological conditions during multi-seam mining at a depth of 800m, Rock Mechanics and Rock Engineering, 51, 5, 1539-1564.
25.
Zhao T.B., Zhang W., Gu S.T., Lv Y.W., Li Z.H., 2020, Study on fracture mechanics of granite based on digital speckle correlation method, International Journal of Solids and Structures, 193, 192-199.
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