Numerical investigation of confined multiple-jet impingement cooling over a flat plate at different crossflow orientaions

Numerical Heat Transfer; Part A: Applications

Volumn 55, Issue 11, 2009, Pages 1019-1050

  Miao, Jr Ming ^a   Wu, Chen Yuan ^b   Chen, Ping Hei ^c  

^a NATIONAL DEFENSE UNIVERSITY   (Taiwan)

^b AIR FORCE INSTITUTE OF TECHNOLOGY   (Taiwan)

^c NATIONAL TAIWAN UNIVERSITY   (Taiwan)

Author keywords

[No Author keywords available]

Indexed keywords

CONTROL VOLUME METHODS; CROSS FLOWS; CROSS-FLOW DIRECTION; FLAT PLATE; FLUID FLOW; IN-LINE; JET ARRAYS; JET IMPINGEMENT COOLING; JET-TO-PLATE SPACING; LOCAL NUSSELT NUMBER; MULTIPLE JETS; NEAR-WALL TREATMENT; NON-UNIFORM DISTRIBUTION; NUMERICAL COMPUTATIONS; NUMERICAL INVESTIGATIONS; NUSSELT NUMBER DISTRIBUTION; REYNOLDS; REYNOLDS STRESS; ROUND JETS; TARGET PLATES; THERMAL PERFORMANCE;

COMPUTATIONAL FLUID DYNAMICS; FLOW OF FLUIDS; GAS DYNAMICS; NAVIER STOKES EQUATIONS; NUSSELT NUMBER; REYNOLDS NUMBER; TURBULENCE; TURBULENCE MODELS;

JETS;

EID: 67651213490     PISSN: 10407782     EISSN: 15210634     Source Type: Journal    
DOI: 10.1080/10407780903014335     Document Type: Article

References (32)

1. K. S. Myung and M. Issam, Experimental and Numerical Investigation of Single-Phase Heat Transfer Using a Hybrid Jet-Impingement/Micro-Channel Cooling Scheme, Int. J. Heat Mass Transfer, vol. 49, pp. 682-694, 2006.
2. M. Roger, R. Buck, and H. Muller-Steinhagen, Numerical and Experimental Investigation of a Multiple Air Jet Cooling System for Application in a Solar Thermal Receiver, ASME J. of Heat Transfer, vol. 127, pp. 863-876, 2005.
3. J.-C. Han, Recent Studies in Turbine Blade Cooling, Int. J. of Rotating Machinery, vol. 10, no. 6, pp. 443-457, 2004.
4. Y. Becko, Impingement Cooling-A Review, Von Karman Institute for Fluid Dynamic, Lecture Series 83, Turbine Blade Cooling, 1976.
5. Z. Neil and L. Noam, Impingement Heat Transfer: Correlations and Numerical Modeling, ASME J. of Heat Transfer, vol. 127, pp. 544-552, 2005.
6. J. Y. San, C. H. Huang, and M. H. Shu, Impingement Cooling of a Confined Circular Air Jet, Int. J. Heat Mass Transfer, vol. 40, pp. 1355-1364, 1997.
7. L. W. Florschuetz, C. R. Truman, and D. E. Metzger, Streamwise Flow and Heat Transfer Distribution for Jet Array Impingement with Crossflow, ASME J. of Heat Transfer, vol. 103, pp. 337-342, 1981.
8. L. W. Florschuetz, D. E. Metzger, C. C. Su, Y. Isoda, and H. H. Tseng, Heat Transfer Characteristics for Jet Array Impingement with Initial Crossflow, ASME J. of Heat Transfer, vol. 106, pp. 34-41, 1984.
9. A. I. Behbahani and R. J. Goldstein, Local Heat Transfer to Staggered Arrays of Impingement Circular Air Jets, ASME J. Eng. Power, vol. 105, pp. 354-360, 1983.
10. Y. Huang, S. V. Ekkad, and J.-C. Han, Detailed Heat Transfer Distributions under an Array of Orthogonal Impinging Jets, AIAA J. Thermophysics and Heat Transfer, vol. 12, pp. 73-79, 1998.
11. G. S. Azad, Y. Huang, and J.-C. Han, Impingement Heat Transfer on Dimpled Surfaces Using a Transient Liquid Crystal Technique, AIAA J. Thermophysics and Heat Transfer, vol. 14, pp. 186-193, 2000.
12. K. W. V. Treuren, Z. Wang, P. T. Ireland, and T. V. Jones, Detailed Measurements of Local Heat Transfer Coefficient and Adiabatic Wall Temperature Beneath an Array of Impinging Jets, ASME J. of Turbomachinery, vol. 116, pp. 369-374, 1994.
13. P. E. D. Bertrand, A. L. James, and K. Koonlaya, Flow Characteristics and Heat Transfer Performances of a Semi-Confined Impinging Array of Jet: Effect of Nozzle Geometry, Int. J. Heat Mass Transfer, vol. 48, pp. 691-701, 2005.
14. C. C. Andrew, R. H. G. David, T. I. Peter, and M. D. Geoffrey, The Effect of Initial Cross Flow on the Cooling Performance of a Narrow Impingement Channel, ASME J. Heat Transfer, vol. 127, pp. 358-365, 2005.
15. S. J. Downs and E. H. James, Jet Impingement Heat Transfer - A Literature Survey, ASME, Paper no. 87-HT-35, 1987.
16. A. M. Huber and R. Viskanta, Effect of Jet-Jet Spacing on Convective Heat Transfer to Confined, Impinging Arrays of Axisymmetric Air Jets, Int. J. Heat Mass Transfer, vol. 37, pp. 2859-2869, 1994a.
17. A. M. Huber and R. Viskanta, Comparison of Convective Heat Transfer to Perimeter and Center Jets in a Confined, Impinging Arrays of Axisymmetric Air Jets, Int. J. Heat Mass Transfer, vol. 37, pp. 3025-3030, 1994b.
18. D. M. Schafer, F. P. Incropera, and S. Ramadhyani, Planar Liquid Jet Impingement Cooling of Multiple Discrete Heat Sources, ASME J. Electron Package, vol. 113, pp. 359-366, 1991.
19. T. H. Park, H. G. Choi, J. Y. Yoo, and S. J. Kim, Streamline Upwind Numerical Simulation of Two-Dimensional Confined Impinging Slot Jets, Int. J. Heat Mass Transfer, vol. 46, pp. 251-262, 2003.
20. A. Sivasamy, V. Selladurai, and P. R. Kanna, Numerical Simulation of Two-Dimensional Laminar Slot-Jet Impingement Flows Confined by a Parallel Wall, Int. J. for Numer. Methods in Fluids, vol. 55, pp. 965-983, 2007.
21. D. H. Lee, J. Song, and M. C. Jo, The Effects of Nozzle Diameter on Impingement Jet Heat Transfer and Fluid Flow, ASME J. Heat Transfer, vol. 126, pp. 554-557, 2004.
22. C. Gau and C. M. Chung, Surface Curvature Effect on Slot-Air-Jet Impingement Cooling Flow and Heat Transfer Process, ASME J. of Heat Transfer, vol. 113, pp. 858-864, 1991.
23. T. J. Craft, H. Iacovides, and N. A. Mostafa, Modeling of Three-Dimensional Jet Array Impingement and Heat Transfer on a Concave Surface, Int. J. Heat and Fluid Flow, vol. 29, pp. 687-702, 2008.
24. J. M. M. Barata, Fountain Flows Produced by Multiple Impinging Jets in a Crossflow, AIAA J., vol. 34, no. 12, pp. 2523-2530, 1996.
25. W. M. Yan, H. C. Liu, C. Y. Soong, and W. J. Yang, Experimental Study of Impinging Heat Transfer of Inline and Staggered Jet Arrays by Transient Liquid Crystal Technique, J. of Flow Visualization & Image Processing, vol. 10, pp. 119-141, 2003.
26. A. R. P. Van Heiningen, Heat Transfer under an Impingement Slot Jet, PhD thesis, McGill University, Montreal, 1982.
27. J. Y. San and M. D. Lai, Optimum Jet-to-Jet Spacing of Heat Transfer for Staggered Arrays of Impinging Air Jets, Int. J. Heat Mass Transfer, vol. 44, pp. 3997-4007, 2001.
28. L. A. El-Gabry and D. A. Kaminski, Numerical Investigation of Jet Impingement with Cross Flow - Comparison of Yang-Shih and Standard κ-ε Turbulence Models, Numer. Heat Transfer A, vol. 47, pp. 441-469, 2005.
29. S. A. Salamah and D. A. Kaminski, Modeling of Turbulence Heat Transfer from an Array of Submerged Jets Impinging on a Solid Surface, Numer Heat Transfer A, vol. 48, pp. 315-337, 2005.
30. J. Y. San, Y. M. Tsou, and Z. C. Chen, Impingement Heat Transfer of Staggered Arrays of Air Jets Confined in a Channel, Int. J. Heat Mass Transferq, vol. 50, pp. 3718-3727, 2007.
31. V. Katti and S. V. Prabhu, Experimental Study and Theoretical Analysis of Local Heat Transfer Distribution Between Smooth Flat Surface and Impinging Air Jet from a Circular Straight Pipe Nozzle, Int. J. Heat Mass Transfer, vol. 51, pp. 4480-4495, 2008.
32. J. M. Miao and C. Y. Wu, Numerical Approach to Hole Shape Effect on Film Cooling Effectiveness over Flat-Plate Including Internal Impingement Cooling Chamber, Int. J. Heat Mass Transfer, vol. 49, pp. 919-938, 2006.