| Institute of Hydrogeology and Environmental Geology, Chinese Academy of Geological Sciences | Host |
| Groundwater Science and Engineering Limited | Publish |
| Citation: |
Qu Ci-xiao, Wang Ming-yu, Wang Peng. 2022. Experimental and numerical investigation of groundwater head losses on and nearby short intersections between disc-shaped fractures. Journal of Groundwater Science and Engineering, 10(1): 33-43. doi: 10.19637/j.cnki.2305-7068.2022.01.004
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Experimental and numerical investigation of groundwater head losses on and nearby short intersections between disc-shaped fractures
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Abstract
Discrete fracture models are used for investigating precise processes of groundwater flow in fractured rocks, while a disc-shaped parallel-plates model for a single fracture is more reasonable and efficient for computational treatments. The flow velocity has a large spatial differentiation which is more likely to produce non-linear flow and additional head losses on and nearby intersections in such shaped fractures, therefore it is necessary to understand and quantify them. In this study, both laboratory experiments and numerical simulations were performed to investigate the total head loss on and nearby the intersections as well as the local head loss exactly on the intersections, which were not usually paid sufficient attention or even ignored. The investigation results show that these two losses account for 29.17%-84.97% and 0-73.57% of the entire total head loss in a fracture, respectively. As a result, they should be necessarily considered for groundwater modeling in fractured rocks. Furthermore, both head losses become larger when aperture and flow rate increase and intersection length decreases. Particularly, the ratios of these two head losses to the entire total head loss in a fracture could be well statistically explained by power regression equations with variables of aperture, intersection length, and flow rates, both of which achieved high coefficients of determination. It could be feasible through this type of study to provide a way on how to adjust the groundwater head from those obtained by numerical simulations based on the traditional linear flow model. Finally, it is practicable and effective to implement the investigation approach combining laboratory experiments with numerical simulations for quantifying the head losses on and nearby the intersections between disc-shaped fractures.
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References
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Qu Ci-xiao, Wang Ming-yu, Wang Peng. 2022. Experimental and numerical investigation of groundwater head losses on and nearby short intersections between disc-shaped fractures. Journal of Groundwater Science and Engineering, 10(1): 33-43. doi: 10.19637/j.cnki.2305-7068.2022.01.004
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Figure 1.
The physical laboratory setup of disc-shaped fracture
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Figure 2.
The numerical representation of a disc-shaped fracture in HGS
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Figure 3.
The schematic diagram of three losses (
$ {H}_{l} $ ,$ {H}_{n} $ and$ {H}_{i} $ ) defined in this paper -
Figure 4.
The relationships between the hydraulic gradient (
$ {\nabla \mathit{H}}_{\mathit{i}\mathit{n}-\mathit{o}\mathit{u}\mathit{t}\_\mathit{e}\mathit{x}\mathit{p}} $ and$ {\nabla \mathit{H}}_{\mathit{p}1-2\_\mathit{e}\mathit{x}\mathit{p}} $ ) and the flow rate (Q) in different experimental scenarios. -
Figure 5.
The percentage of
$ \Delta {\mathit{H}}_{\mathit{s}\_\mathit{e}\mathit{x}\mathit{p}} $ to$ \Delta {\mathit{H}}_{\mathit{i}\mathit{n}-\mathit{o}\mathit{u}\mathit{t}\_\mathit{e}\mathit{x}\mathit{p}} $ in different experimental scenarios -
Figure 6.
The strong turbulent area and dominant flow area in a disc-shaped fracture
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Figure 7.
The percentage of
$ \Delta {H}_{i\_der} $ to$ \Delta {H}_{in-out\_exp} $ in different experimental scenarios