Analysis of the cavitating flow induced by an ultrasonic horn – Numerical 3D simulation for the analysis of vapour structures and the assessment of erosion-sensitive areas

Analysis of the cavitating flow induced by an ultrasonic horn – Numerical 3D simulation for the analysis of vapour structures and the assessment of erosion-sensitive areas

This paper reports the outcome of a numerical study of ultrasonic cavitation using a CFD flow algorithm based on a compressible density-based finite volume method with a low-Machnumber consistent flux function and an explicit time integration [15; 18] in combination with an erosion-detecting flow a...

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Main Authors: Mottyll Stephan, Müller Saskia, Niederhofer Philipp, Hussong Jeanette, Huth Stephan, Skoda Romuald
Format: Article
Language:English
Published: EDP Sciences 2014-03-01
Series:EPJ Web of Conferences
Online Access:http://dx.doi.org/10.1051/epjconf/20146702078
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spelling doaj-0eda57d332334b698719f41701afc3812021-08-02T01:38:24ZengEDP SciencesEPJ Web of Conferences2100-014X2014-03-01670207810.1051/epjconf/20146702078epjconf_efm-13_02078Analysis of the cavitating flow induced by an ultrasonic horn – Numerical 3D simulation for the analysis of vapour structures and the assessment of erosion-sensitive areasMottyll Stephan0Müller Saskia1Niederhofer Philipp2Hussong Jeanette3Huth Stephan4Skoda Romuald5Ruhr-Universität Bochum, Chair of hydraulic fluid machineryRuhr-Universität Bochum, Chair of hydraulic fluid machineryRuhr-Universität Bochum, Chair of materials technologyRuhr-Universität Bochum, Chair of hydraulic fluid machineryRuhr-Universität Bochum, Chair of materials technologyRuhr-Universität Bochum, Chair of hydraulic fluid machinery This paper reports the outcome of a numerical study of ultrasonic cavitation using a CFD flow algorithm based on a compressible density-based finite volume method with a low-Machnumber consistent flux function and an explicit time integration [15; 18] in combination with an erosion-detecting flow analysis procedure. The model is validated against erosion data of an ultrasonic horn for different gap widths between the horn tip and a counter sample which has been intensively investigated in previous material studies at the Ruhr University Bochum [23] as well as on first optical in-house flow measurement data which is presented in a companion paper [13]. Flow features such as subharmonic cavitation oscillation frequencies as well as constricted vapour cloud structures can also be observed by the vapour regions predicted in our simulation as well as by the detected collapse event field (collapse detector) [12]. With a statistical analysis of transient wall loads we can determine the erosion sensitive areas qualitatively. Our simulation method can reproduce the influence of the gap width on vapour structure and on location of cavitation erosion. http://dx.doi.org/10.1051/epjconf/20146702078
collection DOAJ
language English
format Article
sources DOAJ
author Mottyll Stephan
Müller Saskia
Niederhofer Philipp
Hussong Jeanette
Huth Stephan
Skoda Romuald
spellingShingle Mottyll Stephan
Müller Saskia
Niederhofer Philipp
Hussong Jeanette
Huth Stephan
Skoda Romuald
Analysis of the cavitating flow induced by an ultrasonic horn – Numerical 3D simulation for the analysis of vapour structures and the assessment of erosion-sensitive areas
EPJ Web of Conferences
author_facet Mottyll Stephan
Müller Saskia
Niederhofer Philipp
Hussong Jeanette
Huth Stephan
Skoda Romuald
author_sort Mottyll Stephan
title Analysis of the cavitating flow induced by an ultrasonic horn – Numerical 3D simulation for the analysis of vapour structures and the assessment of erosion-sensitive areas
title_short Analysis of the cavitating flow induced by an ultrasonic horn – Numerical 3D simulation for the analysis of vapour structures and the assessment of erosion-sensitive areas
title_full Analysis of the cavitating flow induced by an ultrasonic horn – Numerical 3D simulation for the analysis of vapour structures and the assessment of erosion-sensitive areas
title_fullStr Analysis of the cavitating flow induced by an ultrasonic horn – Numerical 3D simulation for the analysis of vapour structures and the assessment of erosion-sensitive areas
title_full_unstemmed Analysis of the cavitating flow induced by an ultrasonic horn – Numerical 3D simulation for the analysis of vapour structures and the assessment of erosion-sensitive areas
title_sort analysis of the cavitating flow induced by an ultrasonic horn – numerical 3d simulation for the analysis of vapour structures and the assessment of erosion-sensitive areas
publisher EDP Sciences
series EPJ Web of Conferences
issn 2100-014X
publishDate 2014-03-01
description This paper reports the outcome of a numerical study of ultrasonic cavitation using a CFD flow algorithm based on a compressible density-based finite volume method with a low-Machnumber consistent flux function and an explicit time integration [15; 18] in combination with an erosion-detecting flow analysis procedure. The model is validated against erosion data of an ultrasonic horn for different gap widths between the horn tip and a counter sample which has been intensively investigated in previous material studies at the Ruhr University Bochum [23] as well as on first optical in-house flow measurement data which is presented in a companion paper [13]. Flow features such as subharmonic cavitation oscillation frequencies as well as constricted vapour cloud structures can also be observed by the vapour regions predicted in our simulation as well as by the detected collapse event field (collapse detector) [12]. With a statistical analysis of transient wall loads we can determine the erosion sensitive areas qualitatively. Our simulation method can reproduce the influence of the gap width on vapour structure and on location of cavitation erosion.
url http://dx.doi.org/10.1051/epjconf/20146702078
work_keys_str_mv AT mottyllstephan analysisofthecavitatingflowinducedbyanultrasonichornnumerical3dsimulationfortheanalysisofvapourstructuresandtheassessmentoferosionsensitiveareas
AT mullersaskia analysisofthecavitatingflowinducedbyanultrasonichornnumerical3dsimulationfortheanalysisofvapourstructuresandtheassessmentoferosionsensitiveareas
AT niederhoferphilipp analysisofthecavitatingflowinducedbyanultrasonichornnumerical3dsimulationfortheanalysisofvapourstructuresandtheassessmentoferosionsensitiveareas
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