Heat Transfer and Residence Time in Lean Direct Injection Fuel Galleries

Walker, Tom; Peacock, Graham; Brend, Mark; Bonham, Clare; Masters, Jon

doi:10.1115/1.4053716

Journal of Engineering for Gas Turbines and Power

2022

DOI: 10.1115/1.4053716

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Heat Transfer and Residence Time in Lean Direct Injection Fuel Galleries

Tom Walker

Graham Peacock

Mark Brend

et al.

Abstract: In radially staged lean direct injection systems, pilot fuel plays an important role in cooling the mains fuel gallery in regions of the flight envelope where the mains fuel is stagnant. Under these conditions, managing wetted wall temperatures is vital to avoid the formation of carbonaceous particles, which become deposited on the surfaces of the fuel gallery and can lead to a deterioration in system performance. The prediction of wetted wall temperatures therefore represents an important aspect of the inject… Show more

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2023

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Heat Transfer in an Injector-Scaled Additively Manufactured Fuel Passage

Walker,

Bonham

2023

Journal of Turbomachinery

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Additive manufacturing (AM) results in increased surface roughness compared to conventional manufacturing techniques, however limited data exists on how this roughness impacts heat transfer, particularly in liquid flows. This paper solves the inverse heat conduction problem for heat transfer coefficient in liquid flows through rough 90° channel bends typical of the pilot fuel gallery in a lean direct-injection fuel spray nozzle. Heat transfer distributions across two rough surfaces are compared to an equivalent smooth surface. The two rough surfaces have different morphologies but have the same relative effective sand grain roughness which is matched to a prototype AM fuel injector. The sand grain roughness is predicted from a correlation that has been adapted for the high relative roughness scales characteristic of additively manufactured fuel passages. The effective sand grain roughness estimated from surface measurements of a prototype AM fuel gallery was 13% of the passage hydraulic diameter. For the two rough surfaces, the heat transfer enhancement is up to three times the smooth surface value for the straight section preceding the bend and up to four times around the bend. Heat transfer distributions across the two rough surfaces are similar, but the magnitudes differ by 17% depending on the surface morphology. This highlights the importance of the heat transfer effectiveness of surface features, which unlike the sand grain roughness is not matched for the two surfaces considered. Adjusting the data for differences in heat transfer effectiveness corrects the average heat transfer for the rough surfaces to within 7%.

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Heat Transfer in an Injector-Scaled Additively Manufactured Fuel Passage

Walker,

Bonham

2023

Journal of Turbomachinery

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Heat Transfer and Residence Time in Lean Direct Injection Fuel Galleries

Cited by 1 publication

References 31 publications

Heat Transfer in an Injector-Scaled Additively Manufactured Fuel Passage

Heat Transfer in an Injector-Scaled Additively Manufactured Fuel Passage

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