Total heat transfer between a hot and a cold stream of gas across a nonporous conductive wall is greatest when the two streams flow in opposite directions. This counter-current arrangement outperforms the co-current arrangement because the mean driving temperature difference is larger. This simple concept, whilst familiar in the heat exchanger community, has received no discussion in papers concerned with cooling of hot-section gas turbine components (e.g., turbine vanes/blades, combustor liners, afterburners). This is evidenced by the fact that there are numerous operational systems which would be significantly improved by the application of “reverse-pass” cooling. That is, internal coolant flowing substantially in the opposite direction to the mainstream flow. A reverse-pass system differs from a counter-current system in that the cold fluid is also used for film cooling. Such systems can be realized when normal engine design constraints are taken into account. In this paper, the thermal performance of reverse-pass arrangements is assessed using bespoke 2D numerical conjugate heat transfer models, and compared to baseline forward-pass and adiabatic arrangements. It is shown that for a modularized reverse-pass arrangement implemented in a flat plate, significantly less coolant is required to maintain metal temperatures below a specified limit than for the corresponding forward-pass system. The geometry is applicable to combustor liners and afterburners. Characteristically, reverse-pass systems have the benefit of reducing lateral temperature gradients in the wall. The concept is demonstrated by modeling the pressure and suction surfaces of a typical nozzle guide vane with both internal and film cooling. For the same cooling mass flow rate, the reverse-pass system is shown to reduce the peak temperature on the suction side (SS) and reduce lateral temperature gradients on both SS and pressure side (PS). The purpose of this paper is to demonstrate that by introducing concepts familiar in the heat exchanger community, engine hot-section cooling efficiency can be improved whilst respecting conventional manufacturing constraints.
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November 2014
Research-Article
Reverse-Pass Cooling Systems for Improved Performance
Benjamin Kirollos,
Benjamin Kirollos
1
Osney Thermofluids Laboratory,
Department of Engineering Science,
e-mail: ben.kirollos@eng.ox.ac.uk
Department of Engineering Science,
University of Oxford
,Parks Road
,Oxford OX1 3PJ
, UK
e-mail: ben.kirollos@eng.ox.ac.uk
1Corresponding author.
Search for other works by this author on:
Thomas Povey
Thomas Povey
Osney Thermofluids Laboratory,
Department of Engineering Science,
e-mail: thomas.povey@eng.ox.ac.uk
Department of Engineering Science,
University of Oxford
,Parks Road
,Oxford OX1 3PJ
, UK
e-mail: thomas.povey@eng.ox.ac.uk
Search for other works by this author on:
Benjamin Kirollos
Osney Thermofluids Laboratory,
Department of Engineering Science,
e-mail: ben.kirollos@eng.ox.ac.uk
Department of Engineering Science,
University of Oxford
,Parks Road
,Oxford OX1 3PJ
, UK
e-mail: ben.kirollos@eng.ox.ac.uk
Thomas Povey
Osney Thermofluids Laboratory,
Department of Engineering Science,
e-mail: thomas.povey@eng.ox.ac.uk
Department of Engineering Science,
University of Oxford
,Parks Road
,Oxford OX1 3PJ
, UK
e-mail: thomas.povey@eng.ox.ac.uk
1Corresponding author.
Contributed by the International Gas Turbine Institute (IGTI) of ASME for publication in the JOURNAL OF TURBOMACHINERY. Manuscript received July 7, 2014; final manuscript received July 11, 2014; published online August 26, 2014. Editor: Ronald Bunker.
J. Turbomach. Nov 2014, 136(11): 111004 (10 pages)
Published Online: August 26, 2014
Article history
Received:
July 7, 2014
Revision Received:
July 11, 2014
Citation
Kirollos, B., and Povey, T. (August 26, 2014). "Reverse-Pass Cooling Systems for Improved Performance." ASME. J. Turbomach. November 2014; 136(11): 111004. https://doi.org/10.1115/1.4028161
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