2018
DOI: 10.1017/jfm.2018.476
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Importance of the nozzle-exit boundary-layer state in subsonic turbulent jets

Abstract: To investigate the effects of the nozzle-exit conditions on jet flow and sound fields, large-eddy simulations of an isothermal Mach 0.9 jet issued from a convergent-straight nozzle are performed at a diameter-based Reynolds number of $1\times 10^{6}$. The simulations feature near-wall adaptive mesh refinement, synthetic turbulence and wall modelling inside the nozzle. This leads to fully turbulent nozzle-exit boundary layers and results in significant improvements for the flow field and sound predictions compa… Show more

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Cited by 193 publications
(261 citation statements)
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“…In turn, changes in the optimal mode will be accompanied by changes in the orthogonal sub-optimals. The localisation of optimal forcing in the present results may furthermore be linked to the observed sensitivity of LES statistics with respect to flow details in the nozzle boundary layer [32]. Numerous previous studies addressing the linear modelling of wavepackets in turbulent jets, when only boundary forcing at the inflow was considered, observed discrepancies in the initial amplitude growth at low Strouhal numbers, typically St ≤ 0.3 [5,13,59], which play an important role in the generation of jet noise.…”
Section: Comparison With Linear Jet Studies In the Recent Literaturesupporting
confidence: 59%
“…In turn, changes in the optimal mode will be accompanied by changes in the orthogonal sub-optimals. The localisation of optimal forcing in the present results may furthermore be linked to the observed sensitivity of LES statistics with respect to flow details in the nozzle boundary layer [32]. Numerous previous studies addressing the linear modelling of wavepackets in turbulent jets, when only boundary forcing at the inflow was considered, observed discrepancies in the initial amplitude growth at low Strouhal numbers, typically St ≤ 0.3 [5,13,59], which play an important role in the generation of jet noise.…”
Section: Comparison With Linear Jet Studies In the Recent Literaturesupporting
confidence: 59%
“…The reader is referred to Brès et al (2017b) for further details on the numerical method, meshing strategy and subgrid-scale model. A detailed validation of the M j = 0.9 jet including the nozzle-interior turbulence modeling (i.e., synthetic turbulence, wall model) can be found in Brès et al (2017a). The subscripts j and ∞ refer to jet and free-stream conditions, a is the speed of sound, ρ density, D nozzle diameter, µ dynamic viscosity, T temperature, and U j to the axial jet velocity on the centerline of the nozzle exit, respectively.…”
Section: Large Eddy Simulationmentioning
confidence: 99%
“…[22] for an early experimental and [23] for a recent numerical example, use SPOD to analyze jet turbulence. Our first is example is an LES of a Mach 0.9 jet at a jet diameter-based Reynolds number of 1.01 · 10 6 [19].…”
Section: Example 1: Large Eddy Simulation Of a Turbulent Jetmentioning
confidence: 99%