Transient solution for radial two‐zone flow in unconfined aquifers under constant‐head tests

Chang, Yu‐Cheng; Yeh, Hund‐Der; Chen, G. Y.

doi:10.1002/hyp.7610

Cited by 14 publications

(10 citation statements)

References 43 publications

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“…For unconfined aquifers, for example, Chen and Chang [51] considered the skin effect and developed a wellhydraulic theory for CHT in unconfined aquifers. Chang et al [52,53] gave hydraulic head solutions for CHT performed at a partially penetrating well in unconfined aquifers. The review of the recent development in the literature shows that there are a limited number of researches on the CHT in leaky and multilayered aquifers.…”

Section: Constant Head Testmentioning

confidence: 99%

“…The third is the domain decomposition method which divides the flow domain into two or several sub-regions and each region has its own flow equation and associated initial and boundary conditions [5,52,53]. The flow equations are then solved simultaneously via the continuity conditions for the hydraulic head and flow rate at the interfaces of the sub-regions.…”

Section: Effect Of Partial Penetration In Constant Head Testmentioning

confidence: 99%

See 1 more Smart Citation

Recent advances in modeling of well hydraulics

Yeh¹,

Chang²

2013

Advances in Water Resources

129

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Section: Constant Head Testmentioning

confidence: 99%

Section: Effect Of Partial Penetration In Constant Head Testmentioning

confidence: 99%

Recent advances in modeling of well hydraulics

Yeh¹,

Chang²

2013

Advances in Water Resources

129

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“…Hwang and Lu (2007) used the image well method along with convolution‐deconvolution to obtain the semianalytical solution of discharge of a tunnel in a finite width confined fault zone. Other analytical solutions of constant head sinks, that may represent tunnels, in confined (Bennett and Patten 1962; Chang and Yeh 2010), leaky confined (Feng and Zhan 2019) or unconfined (Chang et al 2010) aquifers, are focused on the vertical wells. For more information on the constant head test in this type of wells, the reader may refer to Jiang et al (2020).…”

Section: Introductionmentioning

confidence: 99%

On Inflow to a Tunnel in a Fractured Double‐Porosity Aquifer

Sedghi

Zhan

2021

Groundwater

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Inflow to a tunnel is a great public concern and is closely related to groundwater hydrology, geotechnical engineering, and mining engineering, among other disciplines. Rapid computation of inflow to a tunnel provides a timely means for quickly assessing the inflow discharge, thus is critical for safe operation of tunnels. Dewatering of tunnels is another engineering practice that should be planned. In this study, an analytical solution of the inflow to a tunnel in a fractured unconfined aquifer is obtained. The solution takes into account either the spherical or slab-shaped matrix block and the unsteady state interporosity flow. The instantaneous drainage water table and anisotropic hydraulic conductivities of the fractures network are also considered. Both uniform flux and uniform head boundary condition are considered to simulate the constant head boundary condition in the tunnel. The effects of the hydraulic parameters of the fractured aquifer on the inflow variation of the tunnel are explored. The application of the presented solution to obtain the optimum location and discharge of the well to minimize the inflow to a tunnel is illustrated.

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“…However, in some circumstances, a zone of higher conductivity (negative skin) in the immediate vicinity of a well as compared to regions farther away from the well may also develop due to extensive spalling and fracturing of the wellbore during drilling and/or due to extensive well development [29,30,39,[41][42][43][44]. The skin hydraulics problem for an aquifer of infinite horizontal dimension was solved analytically by several investigators [5,6,11,13,14,20,29,[31][32][33]39,[41][42][43][44] utilizing different assumptions. Whereas Novakowski [29], Yang and Yeh [39], Yeh et al [43], Cimen [14] and Yeh and Yang [44] provided analytical solutions to the problem by neglecting vertical flow, Novakowski [31] provided a solution by assigning a specified head on the well face but a zero head and not a zero flux in the non-active portion of the well, and Hyder et al [20], Yang and Yeh [41], Chiu et al [13], Yeh et al [42] and Chang et al [11] presented solutions by assuming a uniform radial flux at the well screen.…”

Section: Introductionmentioning

confidence: 99%

“…The skin hydraulics problem for an aquifer of infinite horizontal dimension was solved analytically by several investigators [5,6,11,13,14,20,29,[31][32][33]39,[41][42][43][44] utilizing different assumptions. Whereas Novakowski [29], Yang and Yeh [39], Yeh et al [43], Cimen [14] and Yeh and Yang [44] provided analytical solutions to the problem by neglecting vertical flow, Novakowski [31] provided a solution by assigning a specified head on the well face but a zero head and not a zero flux in the non-active portion of the well, and Hyder et al [20], Yang and Yeh [41], Chiu et al [13], Yeh et al [42] and Chang et al [11] presented solutions by assuming a uniform radial flux at the well screen. Cassiani et al [6], using the dual integral method of Cassiani and Kabala [5], presented a semi-analytical solution to the transient skin hydraulics problem for a confined aquifer with a mixed-boundary at the well face by assuming the skin to be infinitesimal small and the aquifer to be infinite in both horizontal and vertical directions.…”

Section: Introductionmentioning

confidence: 99%