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Optimization of a coupled launching process considering hydrodynamic interaction effects
Citation Link: https://doi.org/10.15480/882.16925
Publikationstyp
Conference Paper
Date Issued
2023-08-01
Sprache
English
TORE-DOI
First published in
Number in series
1288
Citation
12th International Workshop on Ship and Marine Hydrodynamics 2023
Contribution to Conference
Publisher DOI
Publisher
IOP Publishing
Peer Reviewed
false
Crane-assisted launching and recovering of small boats from a large vessel is common in a wide range of operational scenarios and may be required during research missions or in emergency situations for rescue boats. As the mothership moves in natural irregular seas, the resulting accelerations and motions of the small boat can lead to dangerous situations, such as a collision between the mothership and the small boat or a slamming of the small boat onto the free water surface can occur, posing a great danger to the people involved. In the paper, the development of a coupled simulation method for the motions of the mothership and the small boat during the launching in the time-domain is described. The developed simulation method is based on the impulse response function. The implementation of the suspension on a crane is realised by a holonomic constraint and a Lagrange’s equation. The parameter influencing the launching operation include the current sea state, the stationary wave field induced by the motherships forward speed, at which the small boat is launched and the initial position of the small boat relative to the water surface. By varying the above mentioned parameters, the process can be optimised for different sea states in terms of forces and accelerations. In considering the forward speed of the mother boat during the launching process, it can be observed that in many cases the small boat is operated at high Froude numbers of greater than 0.4. This leads to an exceedance of the operational limits of the programmes used in this paper.
DDC Class
623.8: Naval Architecture; Shipbuilding
530.42: Fluid Physics
004: Computer Sciences
Publication version
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Altenbach_2023_IOP_Conf._Ser. _Mater._Sci._Eng._1288_012021.pdf
Type
Main Article
Size
438.96 KB
Format
Adobe PDF