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Investigation of the Sound Source Regions in Open and Closed Organ Pipes

Viktor Hruška Pavel Dlask
Archives of Acoustics | 2019 | vol. 44 | No 3 | 467-474 | DOI: 10.24425/aoa.2019.129262
Keywords Particle Image Velocimetry acoustics of music instruments organ pipes edge aerophones
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Abstract

The airflow in the mouth of an open and closed flue organ pipe of corresponding geometrical proportions is studied. The phase locked particle image velocimetry with subsequent analysis by the biorthogonal decomposition is employed in order to compare the flow mechanisms and related features. The most significant differences lie in the mean velocity distribution and rapidity of the jet lateral motion. Remarks on the pressure estimation from PIV data and its importance for the aeroacoustic source terms are made and a specific example is discussed.

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Authors and Affiliations

Viktor Hruška
Pavel Dlask

Revisiting the Open-End Reflection Coefficient and Turbulent Losses in an Organ Pipe with Low Mach Number Flowipe with low Mach number flow

Viktor Hruška Pavel Dlask
Archives of Acoustics | 2021 | vol. 46 | No 2 | 197-204 | DOI: 10.24425/aoa.2021.136575
Keywords organ pipe reflection coefficient end correction flow-acoustic interactions
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Abstract

The reflection coefficient of the open end belongs among the essential parameters in the physical description of a flue organ pipe. It leads directly to practical topics such as the pipe scaling. In this article, sound propagation is investigated inside an organ pipe with the most intense mean flow that is achievable under musically relevant conditions. A theoretical model is tested against the experimental data to obtain a suitable formula for the reflection coefficient when a non-negligible flow through the open end is considered. The velocity profile is examined by means of particle image velocimetry. A fully developed turbulent profile is found and interactions of the acoustic boundary layer with the turbulent internal flow are discussed. A higher value of the end correction than expected from the classical result of Levine and Schwinger is found, but this feature shall be associated with the pipe wall thickness rather than the mean flow effects.
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Bibliography

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Authors and Affiliations

Viktor Hruška
1
Pavel Dlask
1
  1. Academy of Performing Arts in Prague, Musical Acoustics Research Centre, Prague, Czech Republic

On a Robust Descriptor of the Flue Organ Pipe Transient

Viktor Hruška Pavel Dlask
Archives of Acoustics | 2020 | vol. 45 | No 3 | 377-384 | DOI: 10.24425/aoa.2020.134054
Keywords flue organ pipes transient signal Prony’s method Strouhal number
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Abstract

The initial transient of an organ pipe is known to be of great influence to the perceived sound quality. At the same time, the unsteady process of the tone onset is essentially nonlinear and lacks exact repeatability, so the search for a robust descriptor is in place. Initial transients were recorded using an adjustable flue organ pipe. The blowing pressure and cut-up height were varied. Prony’s method was employed to analyze the results. Utilizing the Principal Component Analysis (PCA) on the standardized exponential model coefficients, it was shown that the transients are well described by just one scalar parameter. Its value is predominantly dependent on the number of important Prony’s components taking part in the transient process (i.e., the overall complexity of the transient signal). A strong correlation was found between the PCA component and the Strouhal number inverse.

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Authors and Affiliations

Viktor Hruška
Pavel Dlask

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