Generation of entropy in micro thermofluidic and thermochemical energy systems-A critical review

Torabi, Mehrdad; Karimi, Nader; Torabi, Mohsen; Peterson, G. P.; Simonson, Carey J.

doi:10.1016/j.ijheatmasstransfer.2020.120471

Cited by 86 publications

(4 citation statements)

References 157 publications

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“…Many researchers focused on heat transfer, fluid mechanics and thermodynamic aspects [28][29][30][31][32][33][34][35][36][37][38][39][40][41][42][43]. In general, when the solar energy reaches the Earth's atmosphere, it is divided into two components: the vertical component (beam) and the non-vertical component, which that scientist calls the diffuse component (Fig.…”

Section: Mathematical Formulationmentioning

confidence: 99%

Using nanoparticles in solar collector to enhance solar-assisted hot process stream usefulness

Alqaed

Mustafa

Sharifpur

et al. 2022

Sustainable Energy Technologies and Assessments

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Section: Mathematical Formulationmentioning

confidence: 99%

Using nanoparticles in solar collector to enhance solar-assisted hot process stream usefulness

Alqaed

Mustafa

Sharifpur

et al. 2022

Sustainable Energy Technologies and Assessments

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“…29 Few recent investigations about irreversibility (entropy rate) analysis are highlighted in Refs. [30][31][32][33][34][35][36][37][38][39][40] Motivated from above-mentioned studies and the numerous industrials applications of the recent problem, it is main interest in this exploration to discuss the melting effect in hydromagnetic flow of second-grade nanofluid with entropy analysis by a stretchable curved surface. Heat equation is scrutinized through first law of thermodynamics with radiation effect.…”

Section: Introductionmentioning

confidence: 99%

Melting aspects in flow of second grade nanomaterial with homogeneous–heterogeneous reactions and irreversibility phenomenon: A residual error analysis

Alzahrani

Khan

2022

Progress in Reaction Kinetics and Mechanism

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Here, we scrutinize the entropy analysis in magnetohydrodynamic flow of second-grade nanomaterials with melting effect subject to stretchable bended surface. Heat attribution is modeled through first law of thermodynamics with radiation effect. Major physical effect of random and thermophoretic motion is also addressed. Feature of irreversibility (entropy rate) analysis is also discussed. Isothermal cubic autocatalyses chemical reaction at catalytic surface is discussed. Nonlinear dimensionless differential system is developed through adequate transformation. Optimal homeotypic analysis method (OHAM) is employed to construct convergent solution. Influence of physical variables on entropy rate, fluid flow, concentration, and thermal field is discussed. An augmentation in fluid flow is noticed through curvature variable, while reverse effect holds for magnetic variable. A reverse effect holds for fluid flow and thermal field through melting variable. Entropy analysis is augmented with variation in melting variable. Reduction occurs in concentration through thermophoretic variable, while an opposite effect holds for thermal field. An increment in melting variable leads to reduced concentration. Larger estimation of radiation variable improves entropy analysis.

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“…Torabi et al 16 presented an excellent review article exploring the mechanisms of entropy generation in microsingle and multiphase thermofluidic systems. They have further recommended the entropy generation analysis of micro‐porous systems using pore‐scale modeling and airflow through microchannels with inserts for future areas of research.…”

Section: Introductionmentioning

confidence: 99%

Influence of conjugate heat transfer on the minimization of entropy generation for forced convective flow through parallel plate channel filled with porous material

Borah

Pati

2021

Heat Trans

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A fluid–solid conjugate heat transfer model is developed to analyze the characteristics of entropy generation for forced convective steady hydrodynamically fully developed laminar flow of a Newtonian fluid through a parallel plate channel filled with porous material by modulating the following parameters: substrate thickness, the ratio of thermal conductivity of wall to fluid, Biot number, the axial temperature gradient in the fluid, and Peclet number. The exteriors of both the walls are subjected to the thermal boundary conditions of the third kind. The mass and Brinkman momentum conservation equations in the fluidic domain and the coupled energy conservation in both the solid and fluidic domain are solved analytically using the local thermodynamic equilibrium model, so as to derive closed‐form expressions for the velocity in the fluid and the temperature both in the fluid and solid walls in terms of relevant parameters. Suitable combinations of influencing factors, namely the geometric parameters of the system, fluid, flow, and substrate properties are identified for which global entropy generation rate is minimized. The findings may be helpful in the design of thermal systems frequently used in diverse engineering applications having heat transfer in the solid wall being a crucial parameter.

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Generation of entropy in micro thermofluidic and thermochemical energy systems-A critical review

Cited by 86 publications

References 157 publications

Using nanoparticles in solar collector to enhance solar-assisted hot process stream usefulness

Using nanoparticles in solar collector to enhance solar-assisted hot process stream usefulness

Melting aspects in flow of second grade nanomaterial with homogeneous–heterogeneous reactions and irreversibility phenomenon: A residual error analysis

Influence of conjugate heat transfer on the minimization of entropy generation for forced convective flow through parallel plate channel filled with porous material

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