Numerical study on the mixed convection with nanofluids in vertical channel asymmetrically heated

Barbato, Maria; Buonomo, Bernardo; Manca, Oronzio; Sarli, Gianluca

doi:10.1088/1742-6596/2648/1/012068

J. Phys.: Conf. Ser.

2023

DOI: 10.1088/1742-6596/2648/1/012068

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Numerical study on the mixed convection with nanofluids in vertical channel asymmetrically heated

Maria Barbato,

Bernardo Buonomo,

Oronzio Manca

et al.

Abstract: Mixed convection heat transfer in cavities is of great interest in many industrial applications, such as the development of crystals, the thermal control of electronic components, the nuclear reactors and various manufacturing processes. Components are generally located on the wall of a channel, that can be also tilted and their thermal control is carried out by the fluid flow. They can be schematized as thermal sources on vertical boards and the heat flux is removed by natural or mixed convection. As to the m… Show more

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2024

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Cited by 2 publications

References 25 publications

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Numerical Analysis of Micropolar Flow Along a Vertical Flat Plate in a Saturated Porous Medium Under Constant Heat Flux

Quran,

Maaitah,

Elyyan

et al. 2024

Heat Trans

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The present study assesses the constant surface heat flux on a 2D steady convective flow of a micropolar fluid. The flow occurs along a vertical impermeable flat plate immersed in a fluid‐saturated porous medium. Numerical methods are used to convert the governing partial differential equations to gather the locally equivalent ordinary differential equations. Local similarity solutions also visually depict the velocity distribution and microrotation (ω) in the boundary layer. Furthermore, the influence of the physical variables on the flow field is investigated. The numerical results show that the effect of porosity (ε) on the velocity profile demonstrates a negative correlation between ε and velocity. The correlation between microrotation (ω) involving the ε influence also depends on the similarity parameter (η). Although microrotation (ω) increases with porosity (ε) in the region where the fluid is near the surface, this trend changes as the flow moves further away from the surface. The dimensionless microrotation (ω) value remains constant, while rotation is not observed for the similarity parameter (η) values exceeding 4.5. The value of microrotation (ω) value is small for the similarity parameter (η) values in the interval (0 < η < 1.4). Nonetheless, the microrotation (ω) value is high for the similarity parameter (η) values up to η = 4.5. Therefore, the point at η = 1.4 represents a crucial point in the present study. The results of the present study have been validated, and the comparison with related articles showed an excellent matching between results. Outcomes from the current study are very beneficial to enhance the performance of solar panels by improving the cooling of such panels.

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Numerical Analysis of Micropolar Flow Along a Vertical Flat Plate in a Saturated Porous Medium Under Constant Heat Flux

Quran,

Maaitah,

Elyyan

et al. 2024

Heat Trans

View full text Add to dashboard Cite

show abstract

Numerical analysis of the aspect ratio effect on mixed convection in vertical channels asymmetrically heated with nanofluids with assisting and opposing moving plate

Buonomo,

Manca,

Nardini

et al. 2024

J. Phys.: Conf. Ser.

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In this study, a numerical investigation on mixed convection in vertical channel with water-alumina (Al2O3) nanofluids due to the interaction between a buoyancy-driven flow and a moving plate-induced one in a vertical channel is performed. One of the plates that bound the channel is heated by a constant heat flux, while the other, considered adiabatic, moves with a constant velocity in the direction of the buoyancy force or in the opposite direction, with a comparison between the two options. The nanofluid is modelled using the Single-Phase Model. The thermophysical properties are assumed to be constant with temperature, and the fluid flow is considered laminar and incompressible. The governing equations are numerically solved with the finite volume method by means of the ANSYS-FLUENT code. The channel can have three different aspect ratios, ranging between 5 to 20, while the two external reservoirs allow simulating the external ambient and assigning a velocity of zero and the ambient temperature at the boundary of the reservoirs. The impacts of the different values of aspect ratio of the channel, wall heat flux, moving plate velocity, and concentration of the nanoparticles are investigated. Results in terms of temperature and velocity are provided. Finally, correlations for predicting of the average Nusselt number along the heated plate are proposed.

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Numerical study on the mixed convection with nanofluids in vertical channel asymmetrically heated

Cited by 2 publications

References 25 publications

Numerical Analysis of Micropolar Flow Along a Vertical Flat Plate in a Saturated Porous Medium Under Constant Heat Flux

Numerical Analysis of Micropolar Flow Along a Vertical Flat Plate in a Saturated Porous Medium Under Constant Heat Flux

Numerical analysis of the aspect ratio effect on mixed convection in vertical channels asymmetrically heated with nanofluids with assisting and opposing moving plate

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