(Ebook PDF) Application of Control Volume Based Finite Element Method CVFEM for Nanofluid Flow and Heat Transfer 1st Edition by Mohsen Sheikholeslami ISBN 9780128141533 0128141530 full chapters

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ISBN 10: 0128141530

ISBN 13: 9780128141533

Author: Mohsen Sheikholeslami

Application of Control Volume Based Finite Element Method (CVFEM) for Nanofluid Flow and Heat Transfer discusses this powerful numerical method that uses the advantages of both finite volume and finite element methods for the simulation of multi-physics problems in complex geometries, along with its applications in heat transfer and nanofluid flow. The book applies these methods to solve various applications of nanofluid in heat transfer enhancement. Topics covered include magnetohydrodynamic flow, electrohydrodynamic flow and heat transfer, melting heat transfer, and nanofluid flow in porous media, all of which are demonstrated with case studies.

This is an important research reference that will help readers understand the principles and applications of this novel method for the analysis of nanofluid behavior in a range of external forces.

• Explains governing equations for nanofluid as working fluid
• Includes several CVFEM codes for use in nanofluid flow analysis
• Shows how external forces such as electric fields and magnetic field effects nanofluid flow

Table of Contents:

1. Detailed Explanation of Control Volume-based Finite Element Method

1.1 Introduction

1.2 The Discretization: Grid, Mesh, and Cloud

1.3 The Element and the Interpolation Shape Functions

1.4 Region of Support and Control Volume

1.5 Discretization and Solution

References

2. Simulation of Vorticity Stream Function Formulation by Means of CVFEM

2.1 CVFEM Stream Function-Vorticity Solution for a Lid-Driven Cavity Flow

2.2 CVFEM Stream Function-Vorticity Solution for Natural Convection

References

3. Various Applications of Nanofluid for Heat Transfer Augmentation

3.1 Introduction

3.2 Simulation of Nanofluid Flow and Heat Transfer

References

4. Single-phase Model for Nanofluid Free Convection Heat Transfer by Means of CVFEM

4.1 Introduction

4.2 Nanofluid Hydrothermal Analysis in a Complex Shaped Cavit

4.3 Natural Convection Heat Transfer in a Nanofluid-filled Enclosure With Elliptic Inner Cylinder

4.4 Nanofluid Free Convection Heat Transfer in a Tilted Cavity

References

5. Natural Convection of Nanofluid in Porous Media by Means of CVFEM

5.1 Introduction

5.2 Natural Convection Heat Transfer in a Nanofluid-filled Porous Enclosure

5.3 Natural Convection Heat Transfer in a Porous Enclosure With an Elliptic Inner Cylinder

References

6. Single-phase Model for Nanofluid Forced Convection Heat Transfer by Means of CVFEM

6.1 Introduction

6.2 Forced Convection Heat Transfer in a Microchannel Heat Sink

6.3 Forced Convection Heat Transfer in a Wavy Channel

References

7. Two-phase Model for Nanofluid Heat Transfer by Means of CVFEM

7.1 Introduction

7.2 Two-phase Modeling of Nanofluid Natural Convection in a Cavity

7.3 Two-phase Modeling of Nanofluid Natural Convection in a Porous Medium

References

8. Two-phase Model for Nanofluid Forced Convection Heat Transfer by Means of CVFEM

8.1 Introduction

8.2 Two-phase Modeling of Forced Convection in a Microchannel Heat Sin

8.3 Two-phase Modeling of Forced Convection in a Wavy Channel

References

9. Magnetohydrodynamic Nanofluid Heat Transfer by Means of CVFEM

9.1 Introduction

9.2 Magnetohydrodynamic Natural Convection of Nanofluid in a Complex Cavity

9.3 Magnetohydrodynamic Forced Convection of Nanofluid in a Microchannel

References

10. Radiative Nanofluid Heat Transfer by Means of CVFEM

10.1 Introduction

10.2 Radiative Natural Convection of Nanofluid in a Complex Cavity

10.3 Radiative Forced Convection of Nanofluid in a Microchannel

References

11. Heat Transfer in Hybrid Nanofluids by Means of CVFEM

11.1 Introduction

11.2 Hybrid Nanofluid Natural Convection in a Cavity

11.3 Hybrid Nanofluid Forced Convection in a Microchannel

References

12. Turbulent Nanofluid Heat Transfer by Means of CVFEM

12.1 Introduction

12.2 Turbulent Natural Convection of Nanofluid in a Complex Cavity

12.3 Turbulent Forced Convection of Nanofluid in a Microchannel

References

13. Entropy Generation in Nanofluid Heat Transfer by Means of CVFEM

13.1 Introduction

13.2 Entropy Generation Analysis in Natural Convection of Nanofluid in a Cavity

13.3 Entropy Generation Analysis in Forced Convection of Nanofluid in a Channel

References

14. Optimization of Nanofluid Heat Transfer by Means of CVFEM

14.1 Introduction

14.2 Optimization of Natural Convection in Nanofluid-filled Enclosures

14.3 Optimization of Forced Convection in Nanofluid-filled Channels

References

15. Phase Change Heat Transfer in Nanofluids by Means of CVFEM

15.1 Introduction

15.2 Nanofluid Solidification and Melting in Enclosures

15.3 Nanofluid Phase Change in Porous Media

References

16. Multiphase Nanofluid Flow and Heat Transfer by Means of CVFEM

16.1 Introduction

16.2 Multiphase Nanofluid Natural Convection in Enclosures

16.3 Multiphase Nanofluid Forced Convection in Channels

References

17. Bio-inspired Nanofluid Heat Transfer by Means of CVFEM

17.1 Introduction

17.2 Bio-inspired Geometries in Natural Convection of Nanofluid

17.3 Bio-inspired Geometries in Forced Convection of Nanofluid

References

18. Advanced Computational Approaches in Nanofluid Heat Transfer Using CVFEM

18.1 Introduction

18.2 High-performance CVFEM for Large-scale Nanofluid Simulations

18.3 Machine Learning and AI Integration in Nanofluid Heat Transfer Modeling

References

19. Experimental Validation of CVFEM Nanofluid Models

19.1 Introduction

19.2 Experimental Studies of Natural Convection of Nanofluids

19.3 Experimental Studies of Forced Convection of Nanofluids

References

20. Future Directions and Challenges in Nanofluid Heat Transfer Using CVFEM

20.1 Emerging Trends in Nanofluid Research

20.2 Limitations of Current CVFEM Models and Approaches

20.3 Potential Directions for Advanced Studies

References

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Application,Control Volume,Element Method,CVFEM,Nanofluid Flow,Heat Transfer,Mohsen Sheikholeslami