Investigation of Magneto-Convection Characteristics in A Sudden Expanding Channel with Convex Surface Geometry Under Thermally Developing Flow Conditions

Gürsoy, Emrehan; Pazarlıoğlu, Hayati Kadir; Gürdal, Mehmet; Arslan, Kamil; Gedik, Engin; Dağdeviren, Abdullah

doi:10.21203/rs.3.rs-3449356/v1

2023

DOI: 10.21203/rs.3.rs-3449356/v1

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Investigation of Magneto-Convection Characteristics in A Sudden Expanding Channel with Convex Surface Geometry Under Thermally Developing Flow Conditions

Emrehan Gürsoy,

Hayati Kadir Pazarlıoğlu,

Mehmet Gürdal

et al.

Abstract: The current study presents a novelty with focusing on the magnetic field effect on a sudden expansion tube with expansion ratio, total length, and pitch length of the dimpled fin is 2.5, 1500 mm, and 3.0, respectively. The magnetizable Fe3O4/H2O Ferrofluid with different nanoparticle volumetric concentrations (φ = 1.0% and 2.0%) were used as a heat transfer fluid, and magnetohydrodynamic effects were elaborately investigated in this study. The numerical analysis was conducted under laminar flow regime and the … Show more

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Cited by 3 publications

References 59 publications

(19 reference statements)

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Employing nonuniform magnetic fields to improve energy transfer of flow after a sudden expansion inside a miniature channel: A hydrothermal study

Bahrami,

Ghaedi,

Attarzadeh

2024

Engineering Reports

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This study aims to use single/multiple dipoles to control the flow field after a two‐dimensional milli channel, including a sudden expansion. The study is done numerically and using a finite volume based software. First, a single dipole is positioned under the lower boundary of the channel located after the step (which is heated), and the influences of the different locations of the dipole under the heat transfer and pressure drop are analyzed. The same analysis is done for a dipole located on the opposite wall. The results show that the best performance is achieved when the dipole is located under the heated wall, where it enhances local heat transfer by 700%. The study also reveals that when multiple dipoles are used in the domain, some enhancement happens in the local Nusselt number, but the resulting pressure loss is so high. For example, when three dipoles are used, the local heat transfer enhances by 15% in specific places, but the pressure drop increases by five times. The higher strength of the dipoles also results in a much higher pressure drop. Also, the study of the inlet flow Reynolds number shows that magnetic effects on the flow decrease as the Reynolds number rises.

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Employing nonuniform magnetic fields to improve energy transfer of flow after a sudden expansion inside a miniature channel: A hydrothermal study

Bahrami,

Ghaedi,

Attarzadeh

2024

Engineering Reports

View full text Add to dashboard Cite

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MLFV: a novel machine learning feature vector method to predict characteristics of turbulent heat and fluid flow

Bashtani,

Abolfazli Esfahani

2024

HFF

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Purpose This study aims to introduce a novel machine learning feature vector (MLFV) method to bring machine learning to overcome the time-consuming computational fluid dynamics (CFD) simulations for rapidly predicting turbulent flow characteristics with acceptable accuracy. Design/methodology/approach In this method, CFD snapshots are encoded in a tensor as the input training data. Then, the MLFV learns the relationship between data with a rod filter, which is named feature vector, to learn features by defining functions on it. To demonstrate the accuracy of the MLFV, this method is used to predict the velocity, temperature and turbulent kinetic energy fields of turbulent flow passing over an innovative nature-inspired Dolphin turbulator based on only ten CFD data. Findings The results indicate that MLFV and CFD contours alongside scatter plots have a good agreement between predicted and solved data with R2 ≃ 1. Also, the error percentage contours and histograms reveal the high precisions of predictions with MAPE = 7.90E-02, 1.45E-02, 7.32E-02 and NRMSE = 1.30E-04, 1.61E-03, 4.54E-05 for prediction velocity, temperature, turbulent kinetic energy fields at Re = 20,000, respectively. Practical implications The method can have state-of-the-art applications in a wide range of CFD simulations with the ability to train based on small data, which is practical and logical regarding the number of required tests. Originality/value The paper introduces a novel, innovative and super-fast method named MLFV to address the time-consuming challenges associated with the traditional CFD approach to predict the physics of turbulent heat and fluid flow in real time with the superiority of training based on small data with acceptable accuracy.

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Study of Heat Transfer and Flow Mechanism in Circular Backward-Facing Step Considering Ferrofluid Flow Under Magnetic Field Effect

Gürsoy,

Gedik

2023

Bulletin of the Polytechnic Institute of Iași. Electrical Engineering, Power Engineering, Electronics Section

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The backward-facing step is critical in heat transfer applications, especially in heating and cooling systems, due to its unique flow phenomena like reattachment and separation. Expansion ratio, angle, flow regime, and thermo-physical properties of the working fluid significantly impact heat transfer and flow mechanisms. In the present work a numerical study was conducted on circular cross-section backward-facing step with 2.5 expansion ratio and 90° angle. Magnetizable ferrofluid with volume concentrations of φ=1.0, 1.5, and 2.0% were used in laminar flow regimes (500≤Re≤2000), exposed to a constant magnetic field (B=0.3, 0.5, 0.7, and 1.0T) and a constant heat flux (q”=600 W/m2). Results showed that φ=1.0% ferrofluid had the highest Nusselt number and performance evaluation criterion. Besides, the increment of magnetic field strength not only enhances convective heat transfer but also causes its reduction. The magnetic field significantly influenced reattachment and recirculation, and the optimum case is acquired in B=0.5T at Re=500.

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Investigation of Magneto-Convection Characteristics in A Sudden Expanding Channel with Convex Surface Geometry Under Thermally Developing Flow Conditions

Cited by 3 publications

References 59 publications

Employing nonuniform magnetic fields to improve energy transfer of flow after a sudden expansion inside a miniature channel: A hydrothermal study

Employing nonuniform magnetic fields to improve energy transfer of flow after a sudden expansion inside a miniature channel: A hydrothermal study

MLFV: a novel machine learning feature vector method to predict characteristics of turbulent heat and fluid flow

Study of Heat Transfer and Flow Mechanism in Circular Backward-Facing Step Considering Ferrofluid Flow Under Magnetic Field Effect

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