Current Issues on Modeling Extreme Inflows in Stormwater Systems

Vasconcelos, José G.; Wright, Steven J.; Roe, Philip L.

doi:10.14796/jwmm.r225-19

Cited by 6 publications

(5 citation statements)

References 23 publications

(28 reference statements)

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“…One of the implications of this dimensionless presentation is that it could be combined with the results of a single phase flow analysis in order to make prototype predictions. A single phase flow model (such as that proposed by Vasconcelos et al, 2006a;2006b) must be capable of predicting the location and volume of trapped air pockets. At the instant of air entrapment, the conditions associated with bore propagation would be known from the simulation, specifically the water depth in front of the bore.…”

Section: Dimensional Analysismentioning

confidence: 99%

“…Although the assumed flow configuration is not particularly relevant to large sewer systems, it is possible to envision filling scenarios that result in air compression, so the possibility of significant transient pressures should be considered. A version of the numerical model developed by Vasconcelos et al (2006a;2006b) to simulate the filling of nearly horizontal conduits has been applied to the design analysis of proposed combined sewer overflow storage tunnels (Lautenbach et al, 2008). In a number of simulations, the model predicts that a large volume of air will be trapped during the filling process.…”

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confidence: 99%

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Pressure Transients due to Compression of Trapped Air in Rapidly Filling Sewer Storage Tunnels

Wright

Determan

Vargas

2012

JWMM

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Section: Dimensional Analysismentioning

confidence: 99%

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confidence: 99%

Pressure Transients due to Compression of Trapped Air in Rapidly Filling Sewer Storage Tunnels

Wright

Determan

Vargas

2012

JWMM

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“…This enables the transition between free surface and pressurised flow to be captured via the Preissmann slot concept [11]. However, this also means that the method suffers from the well documented limitations of the Preissmann slot concept as discussed by Vasconcelos, Wright and Roe [12] and Malekpour and Karney [13] , which the authors also acknowledge in their work. Furthermore, the method requires further work in order to be suitable for generalised treatment of linear features, as it can only currently simulate pressurisation without overtopping.…”

Section: Introductionmentioning

confidence: 99%

A New Riemann Solver for Modelling Bridges in Flood Flows -- Development and Experimental Validation

Mckenna¹,

Glenis²,

Kilsby³

2022

Preprint

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Flows in rivers can be strongly affected by obstacles to flow or artificial structures such as bridges, weirs and dams. This is especially true during floods, where significant backwater effects or diversion of flow out of bank can result. However, within contemporary industry practice, linear features such as bridges are often modelled using coarse approximations, empirically based methods or are omitted entirely. Presented within this paper is a novel Riemann solver which is capable of modelling the influence of such features within hydrodynamic flood models using finite volume schemes to solve the shallow water equations. The solution procedure represents structures at the interface between neighbouring cells and uses a combination of internal boundary conditions and a different form of the conservation laws in the adjacent cells to resolve numerical fluxes across the interface. Since the procedure only applies to the cells adjacent to the interface at which a structure is being modelled, the method is therefore potentially compatible with existing hydrodynamic models. Comparisons with validation data collected from a state of the art research flume demonstrate that the solver is suitable for modelling a range of flow conditions and structure configurations such as bridges and gates.

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“…The Preissmann slot model, exemplified by the work of Cunge and Wegner (1964), has been used to simulate these transient flows; however, this model is unable to predict subatmospheric pressures. Furthermore, this hypothetical slot can result in spurious oscillations as shown by Trajkovic et al (1999) and Vasconcelos et al (2006). The two-components pressure approach (TPA), an alternative to the Preissmann slot, was proposed by Vasconcelos et al (2006) and further studied by Vasconcelos and Wright (2007) and Vasconcelos and Marwell (2011) to overcome the inability of the Preissmann slot model in calculating subatmospheric pressures.…”

Section: Introductionmentioning

confidence: 99%

“…Furthermore, this hypothetical slot can result in spurious oscillations as shown by Trajkovic et al (1999) and Vasconcelos et al (2006). The two-components pressure approach (TPA), an alternative to the Preissmann slot, was proposed by Vasconcelos et al (2006) and further studied by Vasconcelos and Wright (2007) and Vasconcelos and Marwell (2011) to overcome the inability of the Preissmann slot model in calculating subatmospheric pressures. This approach can capture the relevant experimental data with a good agreement; however, it is subject to oscillatory behaviors, particularly, in presence of high pressure wave speeds (Bousso et al 2013).…”

Section: Introductionmentioning

confidence: 99%

Shock-Fitting Approach for Calculating Air Pocket Entrapment Caused by Full Obstruction in Closed Conduit Transient Flow

Rokhzadi

Fuamba

2020

J. Hydraul. Eng.

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This paper studies the ability of a Shock-Fitting approach in computing air pocket entrapments in a closed conduit transient flow, caused by suddenly blocking the downstream end. The flow is pressurized at the upstream, which detaches from the wall somewhere at the downstream after which a free surface flow develops. In this Shock-Fitting approach a pressurized flow is simulated by the rigid column model and the free surface flow is simulated by the Saint-Venant equations set. A transient region, which is characterized by the speed of the discontinuity, links these two flow regimes. The relevant governing equations of the rigid column model and the transient region are solved using the backward Euler temporal scheme and the Saint-Venant equations set is solved using the method of characteristics. It was found that this Shock-Fitting approach is able to predict the attenuation behavior as well as to calculate the flow variables more efficiently than the rigid column model and the modified Saint-Venant equations. By means of a linear stability analysis, it was shown that these improvements are provided by the speed of discontinuity in the transient region and the pressurized water column length.

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Current Issues on Modeling Extreme Inflows in Stormwater Systems

Cited by 6 publications

References 23 publications

Pressure Transients due to Compression of Trapped Air in Rapidly Filling Sewer Storage Tunnels

Pressure Transients due to Compression of Trapped Air in Rapidly Filling Sewer Storage Tunnels

A New Riemann Solver for Modelling Bridges in Flood Flows -- Development and Experimental Validation

Shock-Fitting Approach for Calculating Air Pocket Entrapment Caused by Full Obstruction in Closed Conduit Transient Flow

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