A Local Thermal Non-Equilibrium Approach to an Electromagnetic Hybrid Nanofluid Flow in a Non-Parallel Riga Plate Channel

Sharma, Tanya; Kumar, Rakesh; Chamkha, Ali J.

doi:10.1166/jon.2023.2104

j nanofluids

2023

DOI: 10.1166/jon.2023.2104

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A Local Thermal Non-Equilibrium Approach to an Electromagnetic Hybrid Nanofluid Flow in a Non-Parallel Riga Plate Channel

Tanya Sharma,

Rakesh Kumar,

Ali J. Chamkha

Abstract: The fluid flow in a non-parallel configuration exists in the electronic heat removal devices, microchannel heat sinks, and angled confusers/diffusers. The fluids in these applications are prone to flow separation and bifurcations. To deal with such type of problems, a novel idea of a converging or diverging type Riga plate channel is introduced in this study. The Riga plates are utilised to produce the cross-flow magnetic and electric fields which give rise to an exponentially decaying Lorentz force. Also, a … Show more

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2024

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Cited by 2 publications

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Casson hybrid nanofluid flow over a Riga plate for drug delivery applications with double diffusion

Alnahdi,

Gul

2024

Chinese Phys. B

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Casson fluid-mediated hybrid nanofluids are more effective at transferring heat than traditional heat transfer fluids in terms of thermal conductivity. Heat exchangers, cooling systems, and other thermal management systems are ideal for the use of Casson fluid. Controlling medication flow and release with precision is necessary when using Casson fluids in drug delivery systems because of their unique rheological properties. Nanotechnology involves the creation of nanoparticles that are loaded with drugs and distributed in Casson fluid-based carriers for targeted delivery. To create a hybrid nanofluid in this study, both single-walled carbon nanotubes (SWCNTs) and multi-walled carbon nanotubes (MWCNTs) are dispersed in the Casson fluid with Fourier's and Fick's laws assumptions. The Casson fluid is suitable for various engineering and medical applications due to the enhancement of heat transfer and thermal conductivity by carbon nanotubes. Our objective is to understand how SWCNTs and MWCNTs impact the flow field by studying the flow behavior of the Casson hybrid nanofluid when it is stretched against a Riga plate. The DarcyForchheimer model is also used to account for the impact of the porous medium near the stretching plate. Both linear and quadratic drag terms are taken into account in this model to accurately predict the flow behavior of the nanofluid. In addition, the homotopy analysis method (HAM) is utilized to address the model problem. The outcomes are discussed and deliberated based on drug delivery applications. These findings shed valuable light on the flow characteristics of the Casson hybrid nanofluid comprised of SWCNTs and MWCNTs.It is observed that the incorporation of CNTs makes the nanofluid a promising candidate for medical applications due to its improved heat transfer properties.

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Casson hybrid nanofluid flow over a Riga plate for drug delivery applications with double diffusion

Alnahdi,

Gul

2024

Chinese Phys. B

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Turbulent Flow and Heat Transfer of Al₂O₃–CuO Hybrid Nanofluids in Helically Micro-Finned Tubes Using Mass-Based and Discrete-Phase Models

Jouybari,

Dinarvand,

Tehrani

et al. 2024

j nanofluids

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This numerical study investigates forced convective heat transfer and pressure drop in turbulent hybrid nanofluid flow through a helically finned tube with constant wall temperature. Both single-phase mass-based model (MBM) and discrete-phase method (DPM) approaches are employed to analyze and compare heat transfer characteristics in a three-dimensional helically micro-finned geometry. This study evaluated the effects of various volume flow rates between 0.4 to 1.2 m3/h (Reynolds numbers between 11510 to 34530) and nanoparticle concentrations ranging from 0.5% to 3% on water-base Al2O3–CuO hybrid nanofluids’ thermal and flow characteristics obtained from studied approaches. Results demonstrate that the utilized single-phase MBM predicts higher values for both average heat transfer coefficient and pressure drop compared to values obtained from the discrete phase method (DPM). For a 3.0% hybrid nanofluid, with volumetric flow rates ranging from 0.4 to 1.2 m3/h, the mean absolute percentage deviation (MAPD) in the average heat transfer coefficient between the multiphase DPM and single-phase MBM approaches, relative to pure water, is 1.5% to 7.5%. Also, by increasing the hybrid nanoparticle concentration from 0 to 3%, the deviation between single-phase and multi-phase approaches increases, reaching a maximum of 5.7% for the average heat transfer coefficient at a volume flow rate of 0.8 m3/h. However, at lower nanoparticle concentrations, both single-phase and multi-phase models produce similar results with minimal differences. The main novelty of the present work is that it compares the single-phase mass-based model with multi-phase DPM approaches. In addition, the combination of these modeling methods with the specific geometry of the present problem, turbulent regime, and the present hybrid nanofluid, for the first time in this study is considered. As a result, the single-phase approach offers a simpler and more cost-effective alternative to the more complex multi-phase methods for predicting nanofluid behavior in dilute solutions.

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A Local Thermal Non-Equilibrium Approach to an Electromagnetic Hybrid Nanofluid Flow in a Non-Parallel Riga Plate Channel

Cited by 2 publications

References 28 publications

Casson hybrid nanofluid flow over a Riga plate for drug delivery applications with double diffusion

Casson hybrid nanofluid flow over a Riga plate for drug delivery applications with double diffusion

Turbulent Flow and Heat Transfer of Al₂O₃–CuO Hybrid Nanofluids in Helically Micro-Finned Tubes Using Mass-Based and Discrete-Phase Models

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A Local Thermal Non-Equilibrium Approach to an Electromagnetic Hybrid Nanofluid Flow in a Non-Parallel Riga Plate Channel

Cited by 2 publications

References 28 publications

Casson hybrid nanofluid flow over a Riga plate for drug delivery applications with double diffusion

Casson hybrid nanofluid flow over a Riga plate for drug delivery applications with double diffusion

Turbulent Flow and Heat Transfer of Al2O3–CuO Hybrid Nanofluids in Helically Micro-Finned Tubes Using Mass-Based and Discrete-Phase Models

Contact Info

Product

Resources

About

Turbulent Flow and Heat Transfer of Al₂O₃–CuO Hybrid Nanofluids in Helically Micro-Finned Tubes Using Mass-Based and Discrete-Phase Models