Entropy Generation Optimization for Rarified Nanofluid Flows in a Square Cavity with Two Fins at the Hot Wall

Al‐Kouz, Wael; Almuhtady, Ahmad; Owhaib, Wahib; Al‐Dahidi, Sameer; Hader, M. A.; Abu-Alghanam, Rama

doi:10.3390/e21020103

Cited by 32 publications

(12 citation statements)

References 44 publications

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“…q base (18) At the interface between cooling liquid and solid: A no slip condition and coupled temperature are prescribed:…”

Section: Boundary Conditionmentioning

confidence: 99%

“…None of them consider entropy generation when evaluating the performance of the considered cooling channel designs. Meanwhile, some studies have highlighted the importance of second law thermodynamics in the performance evaluation of a thermal system [13], e.g., cooling channels with porous plates [14], a regenerative cooling channel [15], chemical reactors [16], jet impingement cooling [17], nanofluid flow in a square cavity [18], and cooling of a data center room [19]. By utilizing entropy generation analysis in combination with computational fluid dynamics approach, local losses due to heat transfer, friction, turbulent, mass transfer and phase change can be quantified [20].…”

Section: Introductionmentioning

confidence: 99%

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Entropy Generation and Heat Transfer Performance in Microchannel Cooling

Kurnia

Lim

Chen

et al. 2019

Entropy

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Owing to its relatively high heat transfer performance and simple configurations, liquid cooling remains the preferred choice for electronic cooling and other applications. In this cooling approach, channel design plays an important role in dictating the cooling performance of the heat sink. Most cooling channel studies evaluate the performance in view of the first thermodynamics aspect. This study is conducted to investigate flow behaviour and heat transfer performance of an incompressible fluid in a cooling channel with oblique fins with regards to first law and second law of thermodynamics. The effect of oblique fin angle and inlet Reynolds number are investigated. In addition, the performance of the cooling channels for different heat fluxes is evaluated. The results indicate that the oblique fin channel with 20° angle yields the highest figure of merit, especially at higher Re (250–1000). The entropy generation is found to be lowest for an oblique fin channel with 90° angle, which is about twice than that of a conventional parallel channel. Increasing Re decreases the entropy generation, while increasing heat flux increases the entropy generation.

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“…q base (18) At the interface between cooling liquid and solid: A no slip condition and coupled temperature are prescribed:…”

Section: Boundary Conditionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Entropy Generation and Heat Transfer Performance in Microchannel Cooling

Kurnia

Lim

Chen

et al. 2019

Entropy

View full text Add to dashboard Cite

show abstract

“…There have also been other worthwhile numerical investigations [19][20][21][22][23][24][25][26][27][28][29][30][31][32][33][34][35] about natural convection. In many sectors, such as mobile devices, including varied geometries and functions, traditional nanofluids, as well as their new version dubbed "hybrid nanofluids", are importance to thermal scientists and researchers around the world for supporting cooling processes.…”

Section: Introductionmentioning

confidence: 99%

Hydrothermal and Entropy Investigation of Ag/MgO/H2O Hybrid Nanofluid Natural Convection in a Novel Shape of Porous Cavity

et al. 2021

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In this study, a new cavity form filled under a constant magnetic field by Ag/MgO/H2O nanofluids and porous media consistent with natural convection and total entropy is examined. The nanofluid flow is considered to be laminar and incompressible, while the advection inertia effect in the porous layer is taken into account by adopting the Darcy–Forchheimer model. The problem is explained in the dimensionless form of the governing equations and solved by the finite element method. The results of the values of Darcy (Da), Hartmann (Ha) and Rayleigh (Ra) numbers, porosity (εp), and the properties of solid volume fraction (ϕ) and flow fields were studied. The findings show that with each improvement in the Ha number, the heat transfer rate becomes more limited, and thus the magnetic field can be used as an outstanding heat transfer controller.

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“…Treatments of such domains may be made using the body-fitted method, i.e., converting the complex real physical model into a rectangular computational model. While cavities with regular shapes and fins have been studied extensively in many research works, such as [23][24][25], non-regular geometries have received less focus and the aforementioned method is effective in simulations of the transfer of heat problems concerning them. The real coordinates (x, y) are expressed as functions in new coordinates (ξ, η), and based on these functions, all the partial derivatives of the dependent variables are transformed into the new coordinates [26,27].…”

Section: Introductionmentioning

confidence: 99%

Entropy Generation and MHD Convection within an Inclined Trapezoidal Heated by Triangular Fin and Filled by a Variable Porous Media

et al. 2021

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Analyses of the entropy of a thermal system that consists of an inclined trapezoidal geometry heated by a triangular fin are performed. The domain is filled by variable porosity and permeability porous materials and the working mixture is Al2O3-Cu hybrid nanofluids. The porosity is varied exponentially with the smallest distance to the nearest wall and the permeability is depending on the particle diameter. Because of using the two energy equations model (LTNEM), sources of the entropy are entropy due to the transfer of heat of the fluid phase, entropy due to the fluid friction and entropy due to the porous phase transfer of heat. A computational domain with new coordinates (ξ,η) is created and Finite Volume Method (FVM) in case of the non-orthogonal grids is used to solve the resulting system. Various simulations for different values of the inclination angle, Hartmann number and alumina-copper concentration are carried out and the outcomes are presented in terms of streamlines, temperature, fluid friction entropy and Bejan number. It is remarkable that the increase in the inclination angle causes a diminishing of the heat transfer rate. Additionally, the irreversibility due to the temperature gradients is dominant near the heated fins, regardless of the values of the Hartmann number.

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Entropy Generation Optimization for Rarified Nanofluid Flows in a Square Cavity with Two Fins at the Hot Wall

Cited by 32 publications

References 44 publications

Entropy Generation and Heat Transfer Performance in Microchannel Cooling

Entropy Generation and Heat Transfer Performance in Microchannel Cooling

Hydrothermal and Entropy Investigation of Ag/MgO/H2O Hybrid Nanofluid Natural Convection in a Novel Shape of Porous Cavity

Entropy Generation and MHD Convection within an Inclined Trapezoidal Heated by Triangular Fin and Filled by a Variable Porous Media

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