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Akademia Morska w Szczecinie

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Author Kazerooni, Mohammadreza Fathi
Affiliation Sharif University of Technology Center of Excellence in Hydrodynamics & Dynamics of Marine Vehicles, Tehran, Iran
Author Seif, Mohammad Saeed
Affiliation Sharif University of Technology Center of Excellence in Hydrodynamics & Dynamics of Marine Vehicles, Tehran, Iran
ISSN printed 1733-8670
URI http://repository.scientific-journals.eu/handle/123456789/2388
Abstract The calculation of unknown hydrodynamic derivatives of the equations of motion is the first step to estimate ship maneuverability and dynamic stability. These derivatives can be obtained theoretically, experimentally and numerically. Despite the development of the oblique towing model test to measure the hydrodynamic derivatives of displacement ships, limited experimental results are available for hydrodynamic derivatives of high speed crafts and speed dependency of the hydrodynamic derivatives is not understood well. In this paper a systematic series of model tests is described to determine the effect of forward speed on hydrodynamic derivatives of a monohull planing craft and the variations of the hydrodynamic derivatives by forward speed are derived. According to the results, hydrodynamic derivatives of planing hull are dramatically changed by variations of forward speed. Moreover, it is not possible to introduce a constant hydrodynamic derivative in the all the ranges of drift angle. Thus, the method of known constant hydrodynamic derivatives is not applicable to the simulation of planing craft maneuvering and variable hydrodynamic derivatives should be applied.
Pages 40-53
Publisher Scientific Journals Maritime University of Szczecin, Zeszyty Naukowe Akademia Morska w Szczecinie
Keywords maneuvering
Keywords planing hull
Keywords model test
Keywords derivative
Keywords hydrodynamic
Title Experimental evaluation of forward speed effect on maneuvering hydrodynamic derivatives of a planing hull
Type Original scientific article
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ISSN on-line 2392-0378
Language English
Funding No data
Figures 18
Tables 1
DOI 10.17402/199
Published 2017-03-15
Accepted 2017-02-13
Recieved 2016-11-21


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