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16.17 Literature
[1] Brecher, C. ”Development of a dynamic simulation of hypoid gears, consid
th
Loepenhaus,C. ering flank topography”, 6 International VDI Conference on
Knecht, P. Gears, Munich Germany, 2015
[2] Brecher, C. ”Influence of Topography Deviations on the Psychoacoustic
th
Loepenhaus C. Evaluation of ground Bevel Gears”, 6 WZL Gear Conference
Knecht, P. in the USA, Ann Arbor, 2016
[3] Gerads, P. ”Reduction of the tonality of gear noise by application of topog
Brecher, C. raphy scattering”, Applied Accoustics, 2018, No. 148, pages
Loepenhaus, C. 344-359
Kasten, M.
[4] Kasten, M. ”Einfluss einer gezielten aufgeprägten Mikrogeometriestreuung
Brecher, C. aus das Anregungsverhalten von Kegelradverzahnungen”,
Loepenhaus C. Forschung im Ingenieurwesen, 2018, Nr. 82, pages 379-393,
Berlin Germany, Springer Publishing
[5] Deruty, E. ”How the Ear Works, Psychoacoustics of the Human Hearing
Experience”, Article in www.soundonsound.com, November
2016
[6] Stadtfeld, H.J. “Psychoacoustic Methodology for the Noise Reduction of
Bevel Gears”, AGMA, Fall Technical Meeting, Columbus, OH,
October 2017
[7] Bollinger, J.G. “Noise Reduction by Applying Modulation Principles”, The
Ewald, D. Journal of the Acoustical Society of America, Vol. 49, No. 5
Pavlovic, A. Part 1), May 1971
[8] Strunk, S. “Surface Structure Shift for Ground Bevel Gears”, AGMA,
Fall Technical Meeting, Pittsburg, PA, October 2016
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