The Effect of Gas and Surface Temperature on Cold-Side and Hot-Side Turbine Deposition

In this paper the role of mineral composition was assessed for Air Force Research Laboratory test dust (AFRL), for deposition in a realistic gas turbine engine environment. Experiments were performed on an effusion cooling test article with a coolant flow temperature of 894K and surface temperature of 1144K. Aerosolized dust with a 0-10 μm particle size distribution was delivered to the test article. The mineral recipe of AFRL was altered such that the presence of each of the five components ranged from 0% to 100%, and capture efficiency, hole capture efficiency, blockage per gram, and normalized deposit height were reported. Results are compared to a previous study of the inter-mineral synergies in an impingement cooling jet at the same temperature conditions. Despite differences in experimental facility flow geometry, overall agreement was found between the trends in deposition behavior of the dust blends. The strong deposition effects that were observed were shown to be related to adhesion forces of particles, mechanical properties, and chemical properties of the dust minerals. Supplemental testing was performed in a high-temperature (1425–1650 K) impinging jet (200–260 m/s) to evaluate mineral effects at hot gas path conditions. Capture efficiency and morphology of dust deposits are reported. The capture efficiency in this regime was shown to correlate well with temperature, with secondary chemical effects. An attempt was made to predict capture efficiency using chemical assessments such as ratio of bases to acids, Ca:Si ratio, and optical basicity with only modest success.

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The Effect of Gas and Surface Temperature on Cold-Side and Hot-Side Turbine Deposition

Cited by 6 publications

References 43 publications

Experimental assessment of film cooling from cylindrical holes subject to particulate deposition

Experimental assessment of film cooling from cylindrical holes subject to particulate deposition

High-temperature deposition model for molten particle prediction based on droplet-surface interaction criteria

Mineral Composition Effects on Dust Deposition at Realistic Engine Conditions

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