Browse > Article

3-D THERMAL-HYDRAULIC ANALYSIS FOR AIRFLOW OVER A RADIATOR AND ENGINE ROOM  

Hsieh, C.T. (Department of Mechanical Engineering, National Cheng Kung University)
Jang, J.Y. (Department of Mechanical Engineering, National Cheng Kung University)
Publication Information
International Journal of Automotive Technology / v.8, no.5, 2007 , pp. 659-666 More about this Journal
Abstract
In the present study, a numerical analysis of the three-dimensional heat transfer and fluid flow for a vehicle cooling system was developed. The flow field of the engine room between the grille and radiator was analyzed. The results show that, as the airflow inlet grille angle $\alpha$ is varied from $15^{\circ}$ to $-15^{\circ}$, the air flow rate compared with $\alpha=0^{\circ}$(horizontal) changes from -11.9% to +5.1%; while the heat flux from the radiator changes from -9.2% to +4.4%. When the airflow inlet bumper angle $\beta$ is varied from $-5^{\circ}$ to $+15^{\circ}$, the heat flux from the radiator compared with $\beta=0^{\circ}$(horizontal) increases up to +4.4%. When the airflow inlet grille angle $\alpha=-15^{\circ}$ and the bumper grill angle $\beta=+15^{\circ}$, the airflow rates and heat flux compared with($\alpha=0^{\circ}$, $\beta=0^{\circ}$) can be increased to +9.5% and +7.5%, respectively. The results indicate that the optimal angles for cooling efficiency are used.
Keywords
Heat transfer; Radiator; Thermal engineering; CFD; Numerical simulations; 3-D;
Citations & Related Records
Times Cited By KSCI : 1  (Citation Analysis)
Times Cited By Web Of Science : 2  (Related Records In Web of Science)
Times Cited By SCOPUS : 2
연도 인용수 순위
1 Lee, B. and Cho, C. (2006). Numerical analysis procedure for predicting temperature field in design of automotive friction clutch. Int. J. Automotive Technology 7, 1, 61-68   과학기술학회마을
2 STAR CD V.3.15A (2002). Simulation of Turbulent Flow in Arbitrary Regions. Computional Dynamics Limited. UK
3 Liakopoulos, A. (1984). Explicit representations of the complete velocity profile in a turbulent boundary layer. AIAA J., 22, 844-846   DOI   ScienceOn
4 Lee, Y. L. and Hong, Y. T. (2000). Analysis of engine cooling including flow nonuniformity over a radiator. Int. J. Vehicle Design (IJVD), 24, 1, 121-135   DOI   ScienceOn
5 Witry, A., Al-Hajeri, M. H. and Bondok, A. A. (2005). Thermal performance of automotive aluminum plate radiator. Applied Thermal Engineering, 25, 1207-1218   DOI   ScienceOn
6 Chen, Y. S. and Kim, S. W. (1987). Computation of turbulent flows using an extended $k-{\epsilon}$ turbulence closure model, NASA CR-179204
7 Hsieh, C. T. and Jang, J. Y. (2006). 3-D thermal-hydraulic analysis for louver fin heat exchangers with variable louver angle. Applied Thermal Engineering, 26, 1629-1639   DOI   ScienceOn
8 Wang, T. S. and Chen, Y. S. (1993). Unified navier-stokes flow field and performance analysis of liquid rocket engines, AIAA J. 9, 5, 678-685
9 Yang, Z., Boseman, J., Shen, F. Z. and Acre, J. A. (2003). CFRM concept at vehicle idle conditions. SAE Paper No. 2003-01-0613
10 Schwaller, A. E. (1999). Motor Automotive Technology. 3rd edn.. Delmar Publishers. New York
11 Yang, Z., Boseman, J., Shen, F. Z. and Acre, J. A. (2002). CFRM concept for vehicle thermal system. SAE Paper No. 2002-01-1207