Numerical Simulation of Natural Convection in the Air Gap of a Vertical Flat Plat Thermal Solar Collector with Partitions Attached to Its Glazing

Laaraba, Adel; Khechekhouche, Abderrahmane

doi:10.17509/ijost.v3i2.12753

Cited by 13 publications

(9 citation statements)

References 9 publications

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“…, , v x y t be velocities of the thin film fluid in horizontal and vertical directions, respectively. Based on Laaraba and Khechekhouche (2018), the conservation of mass is reads:…”

Section: Methodsmentioning

confidence: 99%

The Effects of Surfactant on the Evolution of a Thin Film under a Moving Liquid Drop

Yulianti

Gunawan

Soewono

2020

Indonesian J. Sci. Technol

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The effect of surfactant on the thickness of a thin film bounded by a solid surface and a moving liquid drop was investigated. We proposed a model so that parameters from the liquid drop can be stated in a parameter that acts as normal pressure to the thin film. Using the lubrication approximation, the model was reduced to a set of nonlinear partial differential equations in terms of the film thickness and surfactant concentration. Since we were interested in the role of the surfactant in lifting up the drop, we assumed that the density of the drop is higher than the density of the thin film. Numerically, the results show that the presence of the surfactant tends to delay the decrease of the film thickness insignificantly. However, when the surfactant was added into the system, it tends to significantly increase the film thickness for a certain range value of the normal pressure.

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“…, , v x y t be velocities of the thin film fluid in horizontal and vertical directions, respectively. Based on Laaraba and Khechekhouche (2018), the conservation of mass is reads:…”

Section: Methodsmentioning

confidence: 99%

The Effects of Surfactant on the Evolution of a Thin Film under a Moving Liquid Drop

Yulianti

Gunawan

Soewono

2020

Indonesian J. Sci. Technol

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“…Both fluids (air and water) are sharing the same velocity fields and turbulence. The governing equations for the unsteady, viscous, and vortex formation turbulent flow are continuity and Navier Stokes described (Laaraba & Khechekhouche, 2018) in Equation [4] and [5] respectively:…”

Section: Governing Equationsmentioning

confidence: 99%

Numerical Study and Theoretical Comparison of Outlet Hole Geometry for a Gravitational Vortex Turbine

Sánchez

Rio

Pujol

2021

Indonesian J. Sci. Technol

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The gravitational water vortex turbine is an alternative to renewable energies, it transforms the hydrokinetic energy of the rivers into electric energy and it does not require a reservoir. According to studies carried out, the hydraulic efficiency can increase or decrease according to the turbine geometrical configuration. This paper presents a numerical (CFD) and analytical comparison between conical and cylindrical designs for the outlet. The results show a higher performance for conical geometry than the cylindrical tank. The fluid behavior in CFD and analytical studies presents a tangential velocity increase near to air core and outlet hole (similar behavior). The maximum theoretical power generated was 167 W and 150 W for conical and cylindrical design respectively. The differences between geometries of the outlet holes using CFD and analytical models were 11 and 7%, respectively. However, the closest results to the CFD model had different values of 31 and 29% for conical and cylindrical design, respectively. The furthest result regarding the CFD study was 55%. The principal difference is due to tank geometry, the change in discharge zone, as well as the ratio of diameter tank and outlet hole can increase or decrease the tangential velocity and make a stronger and more stable vortex formation. The theoretical power generated is a good parameter to select the height to place the rotor.

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“…The article by Laaraba and Khechekhouche [21] presents a study of a natural flow in a flat air solar collector fitted with baffles placed on the glass, this collector placed vertically, the object of this article is the study of the influence baffles in the thermal efficiency of the flat air solar collector. They concluded that the increase in the baffles decreased the value of average Nusselt therefore decrease in thermal losses to the outside, the optimal value of the height of the baffles is 0.4, the value of the height of the baffles more than 0.4 decreased the exchanged flow by convection.…”

Section: Introductionmentioning

confidence: 99%

Three-Dimensional Numerical Simulation of a Flat Plate Solar Collector with Double Paths

Amraoui¹

2021

IJHT

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Flat air solar collectors are used for heat transfer between the absorber and the heat transfer fluid, to improve this transfer there are several methods. Among these methods, the exchange surface lengthening and the creation of turbulence. In this work is done to give a comparison between two types of solar collectors, so we have made an improvement of Ben Slama Romdhane's solar collector by creating two air flow passages to increase heat transfer. We made a 3D simulation of a flat air solar collector with transverse baffles which causes turbulence and increases the exchange surface; we use the ANSYS calculation code to make the simulation and gives results with a brief time and minimal cost.

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Numerical Simulation of Natural Convection in the Air Gap of a Vertical Flat Plat Thermal Solar Collector with Partitions Attached to Its Glazing

Cited by 13 publications

References 9 publications

The Effects of Surfactant on the Evolution of a Thin Film under a Moving Liquid Drop

The Effects of Surfactant on the Evolution of a Thin Film under a Moving Liquid Drop

Numerical Study and Theoretical Comparison of Outlet Hole Geometry for a Gravitational Vortex Turbine

Three-Dimensional Numerical Simulation of a Flat Plate Solar Collector with Double Paths

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