C. T. Srinivasa scite author profile

C. T. Srinivasa

4Publications

69Citation Statements Received

106Citation Statements Given

How they've been cited

104

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Affiliations

Vijayanagara Sri Krishnadevaraya University, Sri Krishnadevaraya University

Publications

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Entropy generation and heat transport analysis of Casson fluid flow with viscous and Joule heating in an inclined porous microchannel

Gireesha

Srinivasa

Shashikumar

et al. 2019

Proceedings of the Institution of Mechanical Engineers, Part E:

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The combined effects of the magnetic field, suction/injection, and convective boundary condition on heat transfer and entropy generation in an electrically conducting Casson fluid flow through an inclined porous microchannel are scrutinized. The temperature-dependent heat source is also accounted. Numerical simulation for the modelled problem is presented via Runge–Kutta–Felhberg-based shooting technique. Special attention is given to analyze the impact of involved parameters on the profiles of velocity [Formula: see text], temperature [Formula: see text], entropy generation [Formula: see text], and Bejan number [Formula: see text]. It is established that entropy generation rate decreases at the walls with an increase in Hartmann number [Formula: see text], while it increases at the center region of the microchannel.

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Unsteady natural convection flow of a rotating fluid past an exponential accelerated vertical plate with Hall current, ion-slip and magnetic effect

Singh

Srinivasa²

2018

MMMS

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Purpose The purpose of this paper is to deal with an unsteady natural convection flow of a rotating fluid past an exponential accelerated vertical plate. The effect of Hall current, ion-slip and magnetic field is considered. Two types of plate temperature, namely, uniform and ramped temperature are considered to model heat transfer analysis. Design/methodology/approach The Laplace transform technique is employed to find the closed form solutions for velocity, temperature and concentration. Findings The effects of flow governing parameters on the velocity profile, temperature profile, concentration profile, skin friction, Nusselt and Sherwood numbers are discussed and presented through graphs and tables. It is found that fluid velocity in the primary flow direction decreases with the increase in the magnetic parameter. Originality/value First time in the literature, the authors obtained closed form solution to natural convection flow of a rotating fluid past an exponential accelerated vertical plate.

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Unsteady Hydromagnetic Heat and Mass Transfer Natural Convection Flow Past an Exponentially Accelerated Vertical Plate With Hall Current and Rotation in the Presence of Thermal and Mass Diffusions

Singh¹,

Joshi²,

Begum³

et al. 2016

Frontiers in Heat and Mass Transfer

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In the present analytical study, we have considered unsteady hydromagnetic heat and mass transfer natural convection flow of an electrically conducting, heat absorbing and chemically reacting fluid past an exponentially accelerated vertical plate in a uniform porous medium taking Hall current and rotation into account. The species concentration near the plate is considered to be varies linearly with time. Two particular cases for plate temperature are considered i.e. (i) plate temperature is uniform and (ii) plate temperature varies linearly with time and after some time it is maintained at uniform temperature. The coupled partial differential equations governing the fluid flow problem are solved analytically for fluid velocity, temperature and species concentration using Laplace transform method. To examine the physical characteristic of this problem the graphs for velocity, temperature, species concentration, skin friction, Nusselt number and Sherwood number distributions are computed and generated for various values of different pertinent flow parameters. It is observed that for small thermal diffusion, the free stream value of velocity and temperature are achieved nearer to the plate in comparison to that for large thermal diffusion.

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Effect of Variable Fluid Properties on Magnetohydrodynamic Flow of Nanofluid Past a Flat Plate

Srinivasa¹,

Singh²,

Gireesha³

et al. 2019

j nanofluids

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C. T. Srinivasa

Entropy generation and heat transport analysis of Casson fluid flow with viscous and Joule heating in an inclined porous microchannel

Unsteady natural convection flow of a rotating fluid past an exponential accelerated vertical plate with Hall current, ion-slip and magnetic effect

Unsteady Hydromagnetic Heat and Mass Transfer Natural Convection Flow Past an Exponentially Accelerated Vertical Plate With Hall Current and Rotation in the Presence of Thermal and Mass Diffusions

Effect of Variable Fluid Properties on Magnetohydrodynamic Flow of Nanofluid Past a Flat Plate

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