Detached eddy simulation of non-reacting swirling flow in a vortex burner

Mansouri, Zakaria; Boushaki, Toufik; Aouissi, Mokhtar

doi:10.18280/ijht.350316

Cited by 6 publications

(3 citation statements)

References 30 publications

(36 reference statements)

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“…It is aligned with the vane leading edge and rotates in the clockwise direction. The swirl intensity used is S i = 0.4 and its defined based on the swirl injector geometry in the combustion chamber and flow velocity [ 42,43 ].…”

Section: Numerical Setupmentioning

confidence: 99%

Heat transfer characteristics of a high-pressure turbine under combined distorted hot-streak and residual swirl: an unsteady computational study

Mansouri

Jefferson-Loveday

2022

International Journal of Heat and Mass Transfer

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Section: Numerical Setupmentioning

confidence: 99%

Heat transfer characteristics of a high-pressure turbine under combined distorted hot-streak and residual swirl: an unsteady computational study

Mansouri

Jefferson-Loveday

2022

International Journal of Heat and Mass Transfer

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“…Moreover, the swirl intensity formula could be reduced to include only U and W velocities, such as S = W/U. 2,4 To highlight the influence of the swirling flow on the inlet temperature transport, three cases of axial DHS (with no-swirl, S = 0) are considered (D1A, D2A, and D3A). Then, a high swirl (S = 0.5) is introduced with each DHS to form the cases D1S, D2S, and D3A.…”

Section: Investigated Casesmentioning

confidence: 99%

“…The LBC is equipped with swirled fuel injectors that generate high swirling flows to stabilize the flame. [1][2][3][4] They contain also several film cooling slots to dilute the hot burned gases. 5,6 The combined effect of both swirling flames and dilution films generate high levels of turbulence and nonuniform temperature contours (known as hot-streak 7 ) at the LBC exit and the high-pressure turbine (HPT) inlet.…”

Section: Introductionmentioning

confidence: 99%

Numerical prediction of heat transfer characteristics on a turbine nozzle guide vane under various combustor exit hot‐streaks

Mansouri¹

2021

Heat Trans

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The precise prediction of the aerothermal conditions at the outlet of modern combustors of aero engines is of primary interest in the aerothermal design of high‐pressure turbines. The use of high swirling flows to stabilize the flame in the new generation of lean‐burn combustors (LBCs) leads to shorter combustor length and high degrees of unsteady temperature. These aspects generate high levels of turbulence and complex temperature nonuniformity patterns at the combustor–turbine interface. Therefore, the nozzle guide vane (NGV) located at the interface exhibits a high inlet temperature gradient called a hot‐streak. The transport mechanism of the hot‐streak across the NGV needs to be decrypted to increase turbine service life and enhance its performance. In this context, the present study aims to examine numerically the effect of three new distorted hot‐streak gradients on the heat transfer characteristics across a turbine NGV. An innovative LBC is used to generate the three inlet hot‐streaks, which are highly swirled and distorted similar to real aero‐engine conditions. The use of such a generation approach avoids any simplification associated with uniform or circular contours that are widely used by researchers. A solid NGV cascade developed by NASA is adopted for the investigations. The results show significant differences in the thermal field on the cascade at each distorted thermal condition. The transport of the hot‐streak behaves differently under axial and swirl conditions. The presence of a swirl induces flow mixing and results in thermal load increasing on the cascade surfaces (NGV, hub, and shroud).

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The influence of inlet swirl intensity and hot-streak on aerodynamics and thermal characteristics of a high pressure turbine vane

Mansouri¹,

Riyadh²

2021

Chinese Journal of Aeronautics

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Detached eddy simulation of non-reacting swirling flow in a vortex burner

Cited by 6 publications

References 30 publications

Heat transfer characteristics of a high-pressure turbine under combined distorted hot-streak and residual swirl: an unsteady computational study

Heat transfer characteristics of a high-pressure turbine under combined distorted hot-streak and residual swirl: an unsteady computational study

Numerical prediction of heat transfer characteristics on a turbine nozzle guide vane under various combustor exit hot‐streaks

The influence of inlet swirl intensity and hot-streak on aerodynamics and thermal characteristics of a high pressure turbine vane

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