International Shipbuilding Progress - Volume 68, issue 1-2

Authors: Hopman, Hans

Article Type: Introduction

DOI: 10.3233/ISP-210010

Citation: International Shipbuilding Progress, vol. 68, no. 1-2, pp. 1-2, 2021

Authors: Lena, Christian | Bonci, Matteo | van Walree, Frans

Article Type: Research Article

Abstract: Ships can experience serious difficulties in keeping a straight course when sailing in stern-quartering seas. Design modifications like the addition of stern passive fins, or the modification of active control surfaces, are common solutions to improve the ship course-keeping. However, the success of such design modifications depends on the delicate balance between the excitation forces induced by the waves on the appended hull, the stabilization forces provided by the lifting surfaces as appended fins, and the steering forces provided by the control surfaces. This research investigates which of these aspects of a ship design play a concrete role in improving …the ship course-keeping in waves. The study is carried out with the intention of looking at the different behaviors of the ship originating from different stern appendages configurations. Three modifications of stern appendages on three different ship hulls were investigated in various mild-to-rough sea conditions. The behavior of the vessels were simulated using a time domain, boundary element potential method, with the addition of semi-empirical formulations for the modelling of the stern lifting surfaces. The simulations were carried out in long crested irregular waves at three different direction, using the JONSWAP spectrum. The results showed that although larger stern appendages improve the directional stability of relatively large and slow vessels, in most cases they worsen their course-keeping ability, increasing the yaw motions. For smaller and faster vessels instead, passive and active fins tend to improve the course-keeping, because at high speed the lift provided by the appendages stabilizes the vessel. This effect is compensated by the wave excitation force at lower speed. Similarly to yaw, the roll motions increases with larger stern appendages. Show more

Keywords: Course-keeping, directional stability, manoeuvrability-in-waves, following seas, panel method, stern appendages

DOI: 10.3233/ISP-201006

Citation: International Shipbuilding Progress, vol. 68, no. 1-2, pp. 3-31, 2021

Authors: Mauro, Francesco | Benci, Aron | Ferrari, Victor | Della Valentina, Enrico

Article Type: Research Article

Abstract: In some specific environmentally protected areas, conventional mooring systems cannot be used by large yachts for stationing at anchor and therefore, the adoption of a dynamic positioning system is required. It becomes then necessary to evaluate the station keeping capabilities of a yacht since the early-design stage. Adopting a quasi-static approach, it is possible to perform a standard capability analysis, as commonly done for the offshore industry, obtaining a capability plot as output. However, capability plots are referring to specific wind-wave correlation that are not covering all the possible wave combinations present in a sea area. Here, it is proposed …to use a scatter diagram approach for the dynamic positioning analysis of a large yacht, considering the specific sea areas where the yacht shall operate, in order to figure out the downtime period of the DP system per each sea area. The proposed method can be coupled with traditional ship motions analysis, leading to a combination between comfort assessment and DP predictions. In the present work, use has been made of a traditional displacement yacht 72 m long, comparing five different DP system configurations and evaluating an enhanced comfort ranking combining ISO AWI-22834 guidelines for large yachts with ISO AWI-22822 DP analysis. Show more

Keywords: Large yachts, comfort on-board, DP predictions, early-design stage, ship motions

DOI: 10.3233/ISP-210508

Citation: International Shipbuilding Progress, vol. 68, no. 1-2, pp. 33-60, 2021

Authors: Bagué, Alec | Degroote, Joris | Demeester, Toon | Lataire, Evert

Article Type: Research Article

Abstract: In this paper an open-source implementation of the vortex-lattice method to perform a dynamic stability analysis for hydrofoil crafts is discussed. The difference with existing vortex-lattice codes is the addition of a free-surface boundary condition which is needed to analyse surface piercing foils. This code, called Typhoon, can be used to perform a dynamic stability analysis (DSA) on hydrofoil vessels. The goal of this code is to have an easy-to-use and cheap alternative to compare different designs in early design stages. This paper gives a brief background to all the concepts used, followed by a short theoretical explanation of the …vortex-lattice method. The second part of this paper focuses on a practical example of how this code can be used on an example. Show more

Keywords: Foiling, vortex-lattice method, free-surface, dynamic stability

DOI: 10.3233/ISP-210006

Citation: International Shipbuilding Progress, vol. 68, no. 1-2, pp. 61-78, 2021