Generation of entropy and forced convection of heat in a conduit partially filled with porous media – Local thermal non-equilibrium and exothermicity effects

Torabi, Mohsen; Karimi, Nader; Zhang, Kaili; Peterson, G. P.

doi:10.1016/j.applthermaleng.2016.06.036

Cited by 52 publications

(16 citation statements)

References 50 publications

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“…A general feature of these figures is the clear distinction between the temperature fields of the fluid and porous solid phases, rendering a strong deviation from local thermal equilibrium (LTE). This is consistent with the findings of the previous investigations of internally heat generating porous channels[25,48,60] and highlights the significance of LTNE approach in the current analysis. The effects of variation in the thermal conductivity ratio, , are shown inFig.…”

supporting

confidence: 92%

“…The heat flux is then split based on the thermal conductivities of the respective phases of the porous material and the corresponding temperature gradients. Splitting the heat flux in this manner is referred to as Model A [25,[44][45][46] and has been widely used in literature (see for example [39,40,47,48]). In enacting this procedure, the effective thermal conductivity of each phase is used.…”

Section: Analytical Methods 21 Model Concept Configuration and Assumentioning

confidence: 99%

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The effects of exothermic catalytic reactions upon combined transport of heat and mass in porous microreactors

Hunt

Karimi

Yadollahi

et al. 2019

International Journal of Heat and Mass Transfer

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Microreactors for chemical synthesis and combustion have already attracted significant attention. Exothermic catalytic activity features heavily in these devices and thus advective-diffusive transport is of key importance in their analyses. Yet, thermal modelling of the heat generated by catalytic reactions on the internal surfaces of porous microreactors has remained as an important unresolved issue. To address this, the diffusion of heat of catalytic reactions into three phases including fluid, porous solid and solid walls is investigated by extending an existing interface model of porous media under local thermal non-equilibrium. This is applied to a microchannel fully filled with a porous material, subject to a heat flux generated by a catalytic layer coated on the porous-wall boundary. The finite wall thickness and viscous dissipation of the flow kinetic energy are considered, and a twodimensional analytical model is developed, examining the combined heat and mass transfer and thermodynamic irreversibilities of the system. The analytical solution is validated against the existing theoretical studies on simpler configurations as well as a computational model of the microreactor in the limit of very large porosity. In keeping with the recent findings, the wall thickness is shown to strongly influence the heat and mass transport within the system. This remains unchanged when the symmetricity of the microchannel is broken through placing walls of unequal thicknesses, while deviation from local thermal equilibrium is significantly intensified in this case. Importantly, the Nusselt number is shown to have a singular point, which remains fixed under various conditions. NomenclatureInterfacial area per unit volume of porous media, (m -1 ) Prandtl number Biot number Wall heat flux ratio ′ Modified Brinkman number ′′ Total catalytic heat flux (W m -2 ) Mass species concentration (kg m -3 ) 1 ′′ Lower wall heat flux (W m -2 ) 0 Inlet concentration (kg m -3 ) 2 ′′ Upper wall heat flux (W m -2 ) Specific heat capacity (J K -1 kg -1 ) Reynolds number Mass diffusion coefficient (m 2 s -1 ) Specific gas constant (J K -1 kg -1 ) Darcy number Shape factor of the porous medium Coefficient of thermal mass diffusion (m K -1 kg -1 s -1 ) ̇′ ′′ Volumetric entropy generation due to mass diffusion (W K -1 m -3 ) ℎ 1 Half-thickness of the microchannel to lower wall (m) ′ ′′ Volumetric entropy generation due to fluid friction (W K -1 m -3 ) ℎ 2 Half-thickness of the microchannel to upper wall (m) ̇′ ′′ Volumetric entropy generation in the fluid (W K -1 m -3 ) ℎ 3 Half-height of microchannel (m) ′ ′′ Volumetric entropy generation in the porous solid (W K -1 m -3 ) ℎ Interstitial heat transfer coefficient (W K -1 m -2 ) ̇1 ′′′ Volumetric entropy generation rate from lower wall (W K -1 m -3 )

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confidence: 92%

Section: Analytical Methods 21 Model Concept Configuration and Assumentioning

confidence: 99%

The effects of exothermic catalytic reactions upon combined transport of heat and mass in porous microreactors

Hunt

Karimi

Yadollahi

et al. 2019

International Journal of Heat and Mass Transfer

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“…Although using LTNE method is more costly compared with LTE, it is more reliable and provides more accurate results prediction of the temperature fields inside the system [16]. Most importantly, it has been recently shown that the results of this approach are superior to those of LTE, particularly in the presence of heat generating/consuming chemical reactions [10] [17]. This superiority also improves the mass transfer analysis when the dispersion and energy equations of the fluid phase are coupled by the thermal diffusion of mass [18] [19].…”

Section: Introductionmentioning

confidence: 99%

“…A few points follow from the preceding review of literature. First, the general problem of partially filled porous channels and microchannels have already received significant attention, see for example [17] [25][26] [27]. As an essential commonality, all these investigations ignore the existence of the channel walls.…”

Section: Introductionmentioning

confidence: 99%

Combined heat and mass transfer analyses in catalytic microreactors partially filled with porous material - The influences of nanofluid and different porous-fluid interface models

Guthrie

Torabi

Karimi

2019

International Journal of Thermal Sciences

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This paper reports a theoretical analysis of heat and mass transfer in the microchannels partially filled with porous materials and used in thermos-chemical microreactors. A first order catalytic chemical reaction is considered on the internal surfaces of a parallel-plates microchannel. The local thermal non-equilibrium approach along with two well-established porous-fluid interface models is employed to investigate the heat transfer within the porous section of the microreactor. The analysis further accounts for the finite thickness of the surrounding solid walls of the microchannel. The dispersion equations in both porous and clear sections of the microchannel are coupled with the fluid temperature through considering the thermal diffusion of mass. In addition, to enhance heat transfer in the partially-filled microchannel, the base fluid is replaced by a nanofluid. The results show that inclusion of the finite thickness of the walls in the thermal analysis can majorly affect the temperature fields and Nusselt number (Nu). In particular, the optimal thickness of the porous insert for achieving the maximum Nu is found to be strongly influenced by the wall thickness. It is also shown that the specific porous-fluid interface model, thicknesses of the porous section and that of the walls, and the volumetric concentration of the nanoparticles can all impart significant effects upon the concentration of chemical species and their distribution across the microchannel. More specifically, the concentration field within the porous region is found to be considerably dependent on the implemented porous-fluid interface model.

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“…This approach has been applied by a number of scholars to investigate the effects of radiation on the entropy generation of thermal systems [41]. Hence, the local entropy generation rate across the entire microchannel can be formulated as follows [42][43][44]. …”

Section: Governing Equationsmentioning

confidence: 99%

Non-Equilibrium Thermodynamic Analysis of Double Diffusive, Nanofluid Forced Convection in Catalytic Microreactors with Radiation Effects

Govone

Torabi

Hunt

et al. 2017

Entropy

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This paper presents a theoretical investigation of the second law performance of double diffusive forced convection in microreactors with the inclusion of nanofluid and radiation effects. The investigated microreactors consist of a single microchannel, fully filled by a porous medium. The transport of heat and mass are analysed by including the thick walls and a first order, catalytic chemical reaction on the internal surfaces of the microchannel. Two sets of thermal boundary conditions are considered on the external surfaces of the microchannel; (1) constant temperature and (2) constant heat flux boundary condition on the lower wall and convective boundary condition on the upper wall. The local thermal non-equilibrium approach is taken to thermally analyse the porous section of the system. The mass dispersion equation is coupled with the transport of heat in the nanofluid flow through consideration of Soret effect. The problem is analytically solved and illustrations of the temperature fields, Nusselt number, total entropy generation rate and performance evaluation criterion (PEC) are provided. It is shown that the radiation effect tends to modify the thermal behaviour within the porous section of the system. The radiation parameter also reduces the overall temperature of the system. It is further demonstrated that, expectedly, the nanoparticles reduce the temperature of the system and increase the Nusselt number. The total entropy generation rate and consequently PEC shows a strong relation with radiation parameter and volumetric concentration of nanoparticles.

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Generation of entropy and forced convection of heat in a conduit partially filled with porous media – Local thermal non-equilibrium and exothermicity effects

Cited by 52 publications

References 50 publications

The effects of exothermic catalytic reactions upon combined transport of heat and mass in porous microreactors

The effects of exothermic catalytic reactions upon combined transport of heat and mass in porous microreactors

Combined heat and mass transfer analyses in catalytic microreactors partially filled with porous material - The influences of nanofluid and different porous-fluid interface models

Non-Equilibrium Thermodynamic Analysis of Double Diffusive, Nanofluid Forced Convection in Catalytic Microreactors with Radiation Effects

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