High-frequency wall heat flux measurement during wall impingement of a diffusion flame

The efficiency of internal combustion engines is limited by heat losses to the wall of the combustion chamber. A precise characterization of wall heat flux is therefore needed to optimize engine parameters. However, the existing measurements of wall heat fluxes have significant limitations; time res...

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Veröffentlicht in:	International journal of engine research 2021-03, Vol.22 (3), p.847-855
Hauptverfasser:	Moussou, Julien, Pilla, Guillaume, Sotton, Julien, Bellenoue, Marc, Rabeau, Fabien
Format:	Artikel
Sprache:	eng
Schlagworte:	Aerodynamics Combustion chambers Engineering Sciences Gas temperature Heat exchange Heat flux Heat transfer Impingement Internal combustion engines Thermocouples
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container_title	International journal of engine research
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creator	Moussou, Julien Pilla, Guillaume Sotton, Julien Bellenoue, Marc Rabeau, Fabien
description	The efficiency of internal combustion engines is limited by heat losses to the wall of the combustion chamber. A precise characterization of wall heat flux is therefore needed to optimize engine parameters. However, the existing measurements of wall heat fluxes have significant limitations; time resolution is often higher than the timescales of the physical phenomena of flame–wall interaction. Furthermore, few studies have investigated diesel flame conditions (as opposed to propagation flames). In this study, the heat flux generated by a diffusion flame impinging on a wall was measured with thin-junction thermocouple, with a time resolution of the whole acquisition chain better than 0.1 ms. The effects of variations in ambient gas temperature, injection pressure and injector–wall distance were investigated. Diesel spray impingement on the wall is shown to cause strong gas–wall thermal exchange, with convection coefficients of 6–12 kW/m2/K. Those results suggest the necessity of close-wall aerodynamic measurements to link macroscopic characteristics of the spray (injection pressure, impingement geometry) to turbulence values.
doi_str_mv	10.1177/1468087419878040
format	Article
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subjects	Aerodynamics Combustion chambers Engineering Sciences Gas temperature Heat exchange Heat flux Heat transfer Impingement Internal combustion engines Thermocouples
title	High-frequency wall heat flux measurement during wall impingement of a diffusion flame
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