1.
Erik Rotteveel, Auke van der Ploeg; Hekkenberg, Robert
Optimization of ships in shallow water with viscous flow computations and surrogate modeling Conference
13th International Symposium on Practical Design of Ships (PRADS), Copenhagen, Denmark, 2016.
@conference{Rotteveel2016,
title = {Optimization of ships in shallow water with viscous flow computations and surrogate modeling},
author = {Erik Rotteveel, Auke van der Ploeg and Robert Hekkenberg},
url = {http://www.marin.nl/web/Publications/Papers/Optimization-of-ships-in-shallow-water-with-viscous-flow-computations-and-surrogate-modeling.htm},
year = {2016},
date = {2016-09-04},
booktitle = {13th International Symposium on Practical Design of Ships (PRADS), Copenhagen, Denmark},
pages = {ID083},
abstract = {Shallow water effects change the flow around a ship significantly which can affect the optimum design of the hull. This paper describes a study into the optimization of the aft ship region for various water depths. The research focuses on variations of the following parameters of a hull form: The athwart ship’s propeller location, the tunnel top curvature, the flat-of-bottom shape in the stern region and the stern bilge radius. All hull form variants are evaluated in 3 different water depths using a viscous flow solver, and a surrogate model is created for each water depth. Pareto plots are used to present the trade-off between the optimization for one or another water depth. Finally, specific hull forms are chosen and the differences in flow behavior among hull forms and water depths are explained.},
keywords = {},
pubstate = {published},
tppubtype = {conference}
}
Shallow water effects change the flow around a ship significantly which can affect the optimum design of the hull. This paper describes a study into the optimization of the aft ship region for various water depths. The research focuses on variations of the following parameters of a hull form: The athwart ship’s propeller location, the tunnel top curvature, the flat-of-bottom shape in the stern region and the stern bilge radius. All hull form variants are evaluated in 3 different water depths using a viscous flow solver, and a surrogate model is created for each water depth. Pareto plots are used to present the trade-off between the optimization for one or another water depth. Finally, specific hull forms are chosen and the differences in flow behavior among hull forms and water depths are explained.
2016
Erik Rotteveel, Auke van der Ploeg; Hekkenberg, Robert
Optimization of ships in shallow water with viscous flow computations and surrogate modeling Conference
13th International Symposium on Practical Design of Ships (PRADS), Copenhagen, Denmark, 2016.
Abstract | Links | BibTeX | Tags: Computational fluid dynamics, Hull form optimization, inland ships, shallow water
@conference{Rotteveel2016,
title = {Optimization of ships in shallow water with viscous flow computations and surrogate modeling},
author = {Erik Rotteveel, Auke van der Ploeg and Robert Hekkenberg},
url = {http://www.marin.nl/web/Publications/Papers/Optimization-of-ships-in-shallow-water-with-viscous-flow-computations-and-surrogate-modeling.htm},
year = {2016},
date = {2016-09-04},
booktitle = {13th International Symposium on Practical Design of Ships (PRADS), Copenhagen, Denmark},
pages = {ID083},
abstract = {Shallow water effects change the flow around a ship significantly which can affect the optimum design of the hull. This paper describes a study into the optimization of the aft ship region for various water depths. The research focuses on variations of the following parameters of a hull form: The athwart ship’s propeller location, the tunnel top curvature, the flat-of-bottom shape in the stern region and the stern bilge radius. All hull form variants are evaluated in 3 different water depths using a viscous flow solver, and a surrogate model is created for each water depth. Pareto plots are used to present the trade-off between the optimization for one or another water depth. Finally, specific hull forms are chosen and the differences in flow behavior among hull forms and water depths are explained.},
keywords = {Computational fluid dynamics, Hull form optimization, inland ships, shallow water},
pubstate = {published},
tppubtype = {conference}
}
Shallow water effects change the flow around a ship significantly which can affect the optimum design of the hull. This paper describes a study into the optimization of the aft ship region for various water depths. The research focuses on variations of the following parameters of a hull form: The athwart ship’s propeller location, the tunnel top curvature, the flat-of-bottom shape in the stern region and the stern bilge radius. All hull form variants are evaluated in 3 different water depths using a viscous flow solver, and a surrogate model is created for each water depth. Pareto plots are used to present the trade-off between the optimization for one or another water depth. Finally, specific hull forms are chosen and the differences in flow behavior among hull forms and water depths are explained.