R. Kaess scite author profile

R. Kaess

5Publications

59Citation Statements Received

8Citation Statements Given

How they've been cited

121

How they cite others

Affiliations

Safran (Belgium), Technical University of Munich, Airbus (India)

Publications

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Identification of the aeroacoustic response of a low Mach number flow through a T-joint

Martinez-Lera

Schram

Föller

et al. 2009

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A methodology to study numerically the aeroacoustic response of low Mach number confined flows to acoustic excitations is presented. The approach combines incompressible flow computations, vortex sound theory, and system identification techniques, and is applied here to study the behavior of a two-dimensional laminar flow through a T-joint. Comparison with experimental results available in literature shows that the computed source models capture the main physical mechanisms of the sound production in the shear layer of the T-joint.

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A Time-Domain Impedance Boundary Condition for Compressible Turbulent Flow

Kaess¹,

Huber²,

Polifke³

2008

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Influence of Scaling Rules on the Loss of Acoustic Energy

Morgenweck¹,

Sattelmayer²,

Fassl³

et al. 2011

Journal of Spacecraft and Rockets

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Identification of Flame Transfer Functions From LES of a Premixed Swirl Burner

Chong¹,

Komarek²,

Kaess³

et al. 2010

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Large eddy simulations of compressible, turbulent, reacting flow were carried out in order to identify the Flame Transfer Function (FTF) of a premixed swirl burner at different power ratings. The Thickened Flame model with one step kinetics was used to model combustion. Time-averaged simulation results for inert and reacting flow cases were compared with experimental data for velocity and heat release distribution with good agreement. Heat losses at the combustor walls were found to have a strong influence on computed flame shapes and spatial distributions of heat release. For identification of the FTF with correlation analysis, broadband excitation was imposed at the inlet. At low power rating (30 kW), measured and computed FTFs agree very well at low frequencies (corresponding to Strouhal numbers St < 4), showing a pronounced maximum of the gain at St ≈ 2. At higher frequencies, where the flame response weakens, the agreement between experiment and computation deteriorates, presumably due to decreasing signal-to-noise ratio. At higher thermal power (50 kW), a high-frequency instability developed during the simulation runs, resulting in poor overall signal-to-noise ratio and thus to unsatisfactory prediction of the gain of the flame transfer function. The phase of the FTF, on the other hand, was predicted with good accuracy up to St < 5. An analytical expression for the FTF, which models the flame dynamics as a superposition of time-delayed responses to perturbations of mass flow rate and swirl number, respectively, was found to match the experimental results.

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Reconstruction of Acoustic Transfer Matrices from Large-Eddy-Simulations of Compressible Turbulent Flows

Föller

Kaess

Polifke

2008

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R. Kaess

Identification of the aeroacoustic response of a low Mach number flow through a T-joint

A Time-Domain Impedance Boundary Condition for Compressible Turbulent Flow

Influence of Scaling Rules on the Loss of Acoustic Energy

Identification of Flame Transfer Functions From LES of a Premixed Swirl Burner

Reconstruction of Acoustic Transfer Matrices from Large-Eddy-Simulations of Compressible Turbulent Flows

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