Innovation types in the Finnish maritime cluster

The Finnish maritime cluster is an important sector of Finland's economy. However, literature on innovative activities within the cluster is limited. This article focuses on Finnish shipbuilding and marine industry firms. Several innovation types are identified. These are analyzed according to general characteristics of firms. The data is from a survey of 148 shipbuilding and marine industry companies; most of the variables are ordinal scale and are analyzed with standard statistical survey methods. Considering the significance and past technological achievements of the sector the results indicate surprisingly low radical innovation related-activity and attitudes towards it. As well, the results provide no evidence to support previous research, suggesting that the shipbuilding and marine industry produces more organizational than technological innovations. The innovativeness of the firms varies according to distinct characteristics such as size, intensity of in-house and collaborative R&D activities, and level of internationalization. The empirical results provide a platform for policy implications and directions for future research; innovations concerning environmental efficiency are raised as an important future area of development.     

On the numerical accuracy of the wave load distribution on a ship advancing in short and steep waves

Defining numerical uncertainty is an important part of the practical application of a numerical method. In the case of a ship advancing in short and steep waves, little knowledge exists on the solution behaviour as a function of discretisation resolution. This paper studies an interface-capturing (VOF) solution for a passenger ship advancing in steep (kA = 0.24) and short waves (L _w /L _pp = 0.16). The focus is to estimate quantitative uncertainties for the longitudinal distributions of the first–third harmonic wave loads in the ship bow area. These estimates are derived from the results of three systematically refined discretisation resolutions. The obtained uncertainty distributions reveal that even the uncertainty of the first harmonic wave load varies significantly along the ship bow area. It is shown that the largest local uncertainties of the first harmonic wave load relate to the differences in the local details of the propagating and deforming encountered waves along the hull. This paper also discusses the challenges that were encountered in the quantification of the uncertainties for this complex flow case.     

Computational and experimental study on local ship loads in short and steep waves

Currently, little information exists on the validity of interface-capturing methods in predicting local ship wave loads in short and steep waves. This study compares computational and experimental results in such a case (kA = 0.24, L _wave /L _ship = 0.16). The results allow the variation of wave loading between ten locations in the bow area of the ship to be observed. The computations were performed with an unstructured RANS solver that models free-surface flows with a volume-of-fluid method. In the model tests, the wave loads were measured with pressure sensors. The analysis of the results focuses on the wave conditions and on the pressure histories of the local wave loads. The computational and experimental results are in good qualitative agreement and encourage the further use of the computational results.