Higher Order Chemical Reaction on MHD Nanofluid Flow with Slip Boundary Conditions: A Numerical Approach

Swain, Kharabela; Parida, Sampada Kumar; Dash, G. C.

doi:10.18280/mmep.060218

Cited by 13 publications

(4 citation statements)

References 13 publications

(16 reference statements)

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“…Gireesha et al [38] analyzed heat and mass transfer on MHD Casson fluid over a stretching surface. Swain et al [43] studied by numerical results on MHD nanofluid with slip boundary conditions in presence of higher order chemical reaction. Sadiq [44] discussed the MHD nanofluid stagnation point flow on plate with Anisotropic Slip.…”

Section: Numerical Modelmentioning

confidence: 99%

Three dimensional MHD nanoluid stagnation point low withhigher order chemical reaction

Jagadha

Gopal

KUMAR

et al. 2022

Journal of Thermal Engineering

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In hot and dry climates, evaporative cooling of the air by water spray can be applied in several requirements, such as evaporative condensers which the airflow is precooled by the water spray before it reaches the condenser. The interaction between water droplets and the air is a complicated two-phase flow that is affected by the several parameters. Here, an Eulerian-Lagrangian 3D model was developed to investigate the influence of important parameters on spray cooling performance in a rectangular duct. The evaluated parameters include the number of nozzles, inlet air flow rate, and spray water flow rate. The results represented that growth in the number of nozzles causes a reduction in the spray cooling efficiency. Thi s is due to decrease of droplets retention time within the duct by increasing the number of nozzles at a constant total spray flow rate in the cases. The maximum and minimum spray cooling efficiency be long to th e ca ses wi th on e no zzle at water flo w rat e of 20 l/h and fou r nozzle at water flow rate of 5 l/h, respectively. The difference between spray cooling efficiency at 3 and 4 number of nozzles is less than 1.8%. Moreover, increasing the air flow rate from 0.5 l/h to 2 l/h (by 300%) makes a decrease in the spray cooling efficiency up to 58.6%.

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Section: Numerical Modelmentioning

confidence: 99%

Three dimensional MHD nanoluid stagnation point low withhigher order chemical reaction

Jagadha

Gopal

KUMAR

et al. 2022

Journal of Thermal Engineering

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“…Mahanthesh et al [8] have analysed numerically the flow of nanofluid over a bidirectional nonlinear stretching with heat flux. A numerical solution was carried out by Swain et al [9] on MHD nanofluid flow past a stretching sheet with higher order chemical reaction. Krupalakshmi et al [10] have studied an upper-convected Maxwell fluid flow over a convectively heated stretching sheet with nonlinear thermal radiation.…”

Section: Nomenclaturementioning

confidence: 99%

Numerical analysis of three-dimensional MHD flow of Casson nanofluid past an exponentially stretching sheet

Senapati¹,

Swain²,

Parida³

2020

Karbala International Journal of Modern Science

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“…Rout and Mishra 3 made a comparative study of nontransient and transient transport of nanoliquid on an elongating sheet. Swain et al 4 carried out a numerical study to analyze the influence of slip boundary conditions on the transition of nanoliquid along the stretchable sheet. Barik et al 5 examined the chemically reactive nanofluid past an inclined elongated sheet with slip conditions.…”

Section: Introductionmentioning

confidence: 99%

Significance of exponential space‐based heat source and inclined magnetic field on heat transfer of hybrid nanoliquid with homogeneous–heterogeneous chemical reactions

Al‐Kouz

Swain²,

Mahanthesh

et al. 2021

Heat Trans

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Many chemical reactive methods, like combustion, catalysis, and biochemical involve homogeneous–heterogeneous chemical reaction (HHCR). The collaboration among the heterogeneous and homogeneous reactions is exceedingly multifarious, including the creation and depletion both within the liquid and catalytic surfaces. Here, we observe the influences of Cu and Al2O3 nanoparticles past an elongating sheet under HHCR. An inclined magnetic field with an acute angle is applied to the direction of the flow. Further, radiative heat, temperature, and exponential space‐based heat source aspects are modifying the thermal equation. The governing nonlinear equations are deciphered by utilizing the Runge–Kutta‐based shooting method. It is found that HHCR reduces the solute layer thickness, whereas the increase in the angle of inclination of applied magnetism thickens momentum layer thickness.

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Higher Order Chemical Reaction on MHD Nanofluid Flow with Slip Boundary Conditions: A Numerical Approach

Cited by 13 publications

References 13 publications

Three dimensional MHD nanoluid stagnation point low withhigher order chemical reaction

Three dimensional MHD nanoluid stagnation point low withhigher order chemical reaction

Numerical analysis of three-dimensional MHD flow of Casson nanofluid past an exponentially stretching sheet

Significance of exponential space‐based heat source and inclined magnetic field on heat transfer of hybrid nanoliquid with homogeneous–heterogeneous chemical reactions

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