Full Surface Local Heat Transfer Coefficient Measurements in a Model of an Integrally Cast Impingement Cooling Geometry-Reference-Cited by-同舟云学术

Full Surface Local Heat Transfer Coefficient Measurements in a Model of an Integrally Cast Impingement Cooling Geometry

Published:1998-01-01 Issue:1 Volume:120 Page:92-99
ISSN:0889-504X
Container-title:Journal of Turbomachinery
language:en
Short-container-title:

Author:

Gillespie D. R. H.¹,Wang Z.¹,Ireland P. T.¹,Kohler S. T.²

Affiliation:

1. Dept. of Engineering Science, University of Oxford, Oxford, United Kingdom

2. Rolls Royce, Bristol, United Kingdom

Abstract

Cast impingement cooling geometries offer the gas turbine designer higher structural integrity and improved convective cooling when compared to traditional impingement cooling systems, which rely on plate inserts. In this paper, it is shown that the surface that forms the jets contributes significantly to the total cooling. Local heat transfer coefficient distributions have been measured in a model of an engine wall cooling geometry using the transient heat transfer technique. The method employs temperature-sensitive liquid crystals to measure the surface temperature of large-scale perspex models during transient experiments. Full distributions of local Nusselt number on both surfaces of the impingement plate, and on the impingement target plate, are presented at engine representative Reynolds numbers. The relative effects of the impingement plate thermal boundary condition and the coolant supply temperature on the target plate heat transfer have been determined by maintaining an isothermal boundary condition at the impingement plate during the transient tests. The results are discussed in terms of the interpreted flow field.

Publisher

ASME International

Subject

Mechanical Engineering

Link

http://asmedigitalcollection.asme.org/turbomachinery/article-pdf/120/1/92/5658614/92_1.pdf

Reference14 articles.

1. Bunker R. S. , and MetzgerD. E., 1990, “Local Heat Transfer in Internally Cooled Turbine Airfoil Leading Edge Regions—Part 1: Impingement Cooling Without Film Coolant Extraction,” ASME JOURNAL OF TURBOMACHINERY, Vol. 112, pp. 451–458.

2. Byerley, A. R., 1988, “Heat Transfer Near the Entrance to a Film Cooling Hole in a Gas Turbine Blade,” D. Phil Thesis, Department of Engineering Science, University of Oxford, United Kingdom.

3. Florschuetz, L. W., Metzger, D. E., Takeuichi, D. I., and Berry, R. A., 1980, “Multiple Jet Impingement Heat Transfer Characteristic—Experimental Investigation of In-Line and Staggered Arrays With Crossflow,” NASA Contractor Report 3217.

4. Gillespie, D. R. H., 1996, “Intricate Internal Cooling Systems for Gas Turbine Blading,” D. Phil Thesis, Department of Engineering Science, University of Oxford, United Kingdom.

5. Huber A. M. , and ViskantaR., 1994, “Convective Heat Transfer to a Confined Impinging Array of Air-Jets With Spent Air Exits,” ASME JOURNAL OF HEAT TRANSFER, Vol. 116, pp. 570–576.

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