Measurement and Simulation of Combustion Noise and Dynamics of a Confined Swirl Flame

Merk, Michael; Polifke, Wolfgang; Gaudron, Renaud; Gatti, Marco; Mirat, Clément; Schuller, Thierry

doi:10.2514/1.j056502

Cited by 20 publications

(9 citation statements)

References 56 publications

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“…The chemistry of the perfectly premixed methane/air flame is described by a same LES setup is used as in Ref. [32], for which the LES was validated. However, the need in the current study of properly measuring the acoustic fluctuations downstream requires the test rig to be equipped with an additional pipe that contains the mounted microphones ME, ME 0 , and ME 00 (see Fig.…”

Section: Large Eddy Simulation/system Identification Methodologymentioning

confidence: 99%

Direct Assessment of the Acoustic Scattering Matrix of a Turbulent Swirl Combustor by Combining System Identification, Large Eddy Simulation and Analytical Approaches

Merk

Silva

Polifke

et al. 2018

Journal of Engineering for Gas Turbines and Power

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This study assesses and compares two alternative approaches to determine the acoustic scattering matrix of a premixed turbulent swirl combustor: (1) The acoustic scattering matrix coefficients are obtained directly from a compressible large eddy simulation (LES). Specifically, the incoming and outgoing characteristic waves f and g extracted from the LES are used to determine the respective transmission and reflection coefficients via System Identification (SI) techniques. (2) The flame transfer function (FTF) is identified from LES time series data of upstream velocity and heat release rate. The transfer matrix of the reactive combustor is then derived by combining the FTF with the Rankine–Hugoniot (RH) relations across a compact heat source and a transfer matrix of the cold combustor, which is deduced from a linear network model. Linear algebraic transformation of the transfer matrix consequently yields the combustor scattering matrix. In a cross-comparison study that includes comprehensive experimental data, it is shown that both approaches successfully predict the scattering matrix of the reactive turbulent swirl combustor.

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Section: Large Eddy Simulation/system Identification Methodologymentioning

confidence: 99%

Direct Assessment of the Acoustic Scattering Matrix of a Turbulent Swirl Combustor by Combining System Identification, Large Eddy Simulation and Analytical Approaches

Merk

Silva

Polifke

et al. 2018

Journal of Engineering for Gas Turbines and Power

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show abstract

“…Thus, a laminar velocity profile is imposed at the inlet. For further details and validation of the LES setup, the reader is referred to [8] .…”

Section: Simultaneous Identification Of Flame Transfer Function and Nmentioning

confidence: 99%

“…if the LES generates sp~nous heat release rate fluctuations), erroneous noise models will result, independent of the chosen mode) structu~e. For the current study the validity of the LES w1th respect to the combustion noise generation was validated in [8] by comparing LES results against measured sound pressure spectra. Note that to a certain extent the combustion noise ~eneration is in~ependent from the flame dynam-1cs.…”

Section: Simultaneous Identification Of Flame Transfer Function and Nmentioning

confidence: 99%

“…Obviously, sound pressure levels in a combustion system may be determined by measurement [6][7][8] . However, experiments are rather laborious and inflexible in regard to changes in the acous-tic boundaries.…”

Section: Introductionmentioning

confidence: 99%

“…However, experiments are rather laborious and inflexible in regard to changes in the acous-tic boundaries. Reactive compressible Large-Eddy Simulation (LES) resolves directly the combustion noise generation as well as the acoustic propagation and reflection within the cavity and has proven itself to be capable of reproducing accurately the sound pressure spectra in confined systems [8][9][10] . Even though changes in the acoustic boundaries are feasible to implement, the computational effort of LES is considerable, and the investigation of a wide range of parameters, say, is prohibitively expensive.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Prediction of combustion noise of an enclosed flame by simultaneous identification of noise source and flame dynamics

Merk

Gaudron

Silva

et al. 2019

Proceedings of the Combustion Institute

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Performance simulation of a low-swirl burner for a Stirling engine

et al. 2019

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Summary A new type of gas burner for Stirling engine that can recover adequate heat from exhaust gas was designed based on the plate heat exchanger and low‐swirl combustion technology, which consists of three components: a cyclone, a burner, and a circular plate heat exchanger. The circular plate heat exchanger tightly wound around the combustion chamber plays a high efficiency of heat recovery role. In consideration of the radial symmetry of the burner, a three‐dimensional numerical simulation was carried out by Ansys15. The velocity distribution, temperature distribution, and pressure distribution of the combustion gas were presented respectively. Strong backflow that came from the exhaust gas around the root of the flame in the combustion chamber and a vortex below the inlet of the exhaust gas channel were found, which were beneficial for the combustion and improving the uniformity of temperature distribution. Combustion behaviors of the burner under standard operating conditions were obtained, the highest temperature was about 2200 K in burner and the exhaust gas entered the plate heat exchanger at the temperature of 1375 K and exited at 464 K, with the waste heat recovery efficiency over 65.8%. And, the air‐fuel ratio and combustion power had negligible effect on the waste heat recovery efficiency.

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Measurement and Simulation of Combustion Noise and Dynamics of a Confined Swirl Flame

Cited by 20 publications

References 56 publications

Direct Assessment of the Acoustic Scattering Matrix of a Turbulent Swirl Combustor by Combining System Identification, Large Eddy Simulation and Analytical Approaches

Direct Assessment of the Acoustic Scattering Matrix of a Turbulent Swirl Combustor by Combining System Identification, Large Eddy Simulation and Analytical Approaches

Prediction of combustion noise of an enclosed flame by simultaneous identification of noise source and flame dynamics

Performance simulation of a low-swirl burner for a Stirling engine

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