Natural and Forced Conjugate Heat Transfer in Complex Geometries on Cartesian Adapted Grids-Reference-Cited by-同舟云学术

Natural and Forced Conjugate Heat Transfer in Complex Geometries on Cartesian Adapted Grids

Published:2005-12-06 Issue:4 Volume:128 Page:838-846
ISSN:0098-2202
Container-title:Journal of Fluids Engineering
language:en
Short-container-title:

Author:

Iaccarino Gianluca¹,Moreau Stéphane²

Affiliation:

1. Center for Turbulence Research, Stanford University, CA 94305-3030

2. Valeo Motors and Actuators, 1, rue Tiron, Paris, 75004, France

Abstract

The Cartesian incompressible RANS solver with immersed boundaries, IBRANS, recently developed at Stanford, has been extended to include conjugate heat transfer modeling and used for the simulation of the electrical motor of an automotive engine cooling fan system. Such applications are particularly challenging, as they involve very complex geometries with tight tolerances and rotating parts. The new conjugate heat transfer capability of IBRANS has been verified on natural and forced convection flows. The former involves flows in enclosures around a sphere and electronic chips. The latter focuses on heated cylinders for Reynolds numbers covering flow regimes ranging for a steady laminar flow to unsteady turbulent flows. Excellent agreement is achieved with similar simulations with a conventional body-fitted solver (FLUENT 6.1) using equivalent turbulent models. First three-dimensional simulations of the flow and heat transfer within the complete electrical motor are presented. The numerical predictions of the pressure drop through the motor as a function of flow rate agree very well with the measured data over the complete operating range.

Publisher

ASME International

Subject

Mechanical Engineering

Link

http://asmedigitalcollection.asme.org/fluidsengineering/article-pdf/128/4/838/5594285/838_1.pdf

Reference19 articles.

1. Heat Transfer Simulation for Industrial Applications: Needs, Limitations, Expectations;Péniguel;Int. J. Heat Fluid Flow

2. Hong, T., Rakotovao, M., Moreau, S., and Savage, J., 2001, “Thermal Analysis of Electric Motors in Engine Cooling Fan Systems,” SAE Paper No. 2001-01-1017.

3. Williams, J., and Vemaganti, G., 1998, “CFD Quality—A Calibration Study for Front-End Cooling Airflow,” SAE-980039 paper. Reprinted in “Developments in Vehicle Aerodynamics,” SAE publication No. SP-1318.

4. Markowitz, M. , 1999, “Improving Vehicle A/C Performance by Underhood CFD Analysis With Regards to A/C Condenser Air Flow,” C543/090/99 paper.

5. Immersed Boundary Technique for Turbulent Flow Simulations;Iaccarino;Appl. Mech. Rev.

Cited by 20 articles. 订阅此论文施引文献订阅此论文施引文献，注册后可以免费订阅5篇论文的施引文献，订阅后可以查看论文全部施引文献

1. Immersed boundary method based fluid–structure–thermal interaction solver with conjugate heat transfer;Sādhanā;2023-09-14

2. A versatile immersed boundary method for high-fidelity simulation of Conjugate Heat Transfer;Journal of Computational Physics;2023-09

3. Immersed Boundary Methods: Historical Perspective and Future Outlook;Annual Review of Fluid Mechanics;2023-01-19

4. An immersed boundary method with implicit body force for compressible viscous flow;Journal of Computational Physics;2022-06

5. IMMERSED BOUNDARY METHODS FOR THERMOFLUIDS PROBLEMS;Annual Review of Heat Transfer;2022