Improving the Flexibility of Ship Propellers Additively Manufactured from High-Density Polyethylene/Long Carbon Fiber Composites by Prepreg Coating
Author:
Neşer Gökdeniz1ORCID, Sözen Ayberk1, Doğru Alperen2ORCID, Liu Pengfei3, Altunsaray Erkin1ORCID, Halilbeşe Akile Neşe4ORCID, Türkmen Serkan3ORCID
Affiliation:
1. Institute of Marine Sciences and Technology, Dokuz Eylul University, Baku Bulv. 32, Balcova, Izmir 35340, Türkiye 2. Aviation Higher Vocational School, Ege University, 1099 S. 114 Sarnic, Gaziemir, Izmir 35100, Türkiye 3. Marine, Offshore & Subsea Technology Group, School of Engineering, Newcastle University, Armstrong Building, Queen Victoria Road, Newcastle upon Tyne NE1 7RU, UK 4. Fatsa Faculty of Marine Sciences, Ordu University, Evkaf, Arslan Aydınlık Cd. 1a, Fatsa, Ordu 52400, Türkiye
Abstract
In efforts to achieve the goal of reducing ship emissions in the fight against climate change, reducing fuel consumption by making ships lighter is stated as one of the solutions. In this study, the possibilities of making composite equivalents of propellers, which are the most complex ship elements and traditionally produced from metal materials, are investigated with the advantages of additive manufacturing, which offers a rapid production opportunity for such forms. In this way, a lighter composite propeller and, therefore, a lighter ship will be achieved, and negative environmental impacts, especially harmful emissions, will be reduced. In the study, a 1/14-scale ship propeller was produced through the material extrusion method of additive manufacturing using an HDPE composite containing long carbon fiber with a 15% weight fraction. An attempt to reduce flexibility with an epoxy-carbon fabric prepreg coating was made, as the flexibility has negative effects on the performance of the produced propeller. The propeller tunnel test showed that the applied carbon fabric epoxy prepreg helped to improve the propeller’s performance by decreasing the flexibility of the propeller and reducing the deformation at the tips. At the same time, the propeller weight was decreased by 60% compared to its metal counterparts.
Funder
Dokuz Eylül University UK Department for Transport (DfT) and Engineering and Physical Sciences Research Council
Reference48 articles.
1. International Maritime Organization (2018). Initial IMO Strategy on Reduction of GHG Emissions from Ships, International Maritime Organization. 2. Lim, S., Turkmen, S., Rostami, A.B., Prini, F., Kurniawati, V.R., Carchen, A., Gibson, M., Benson, S., Birmingham, R., and Dow, R.S. (2018, January 24–25). Ship Performance-Using the Real World as a Laboratory. Proceedings of the Full Scale Ship Performance, London, UK. 3. Polymer Based Composites in Marine Use: History and Future Trends;Procedia Eng.,2017 4. Analysis of the Hydrodynamic Performance of a Gate Rudder System;Turkmen;IOP Conf. Ser. Mater. Sci. Eng.,2023 5. Advanced Lightweight Materials and Manufacturing Processes for Automotive Applications;Taub;Mater. Res. Soc. Bull.,2015
|
|