Journal is indexed in following databases:



2023 Journal Impact Factor - 0.7
2023 CiteScore - 1.4



HomePage
 




 


 

ISSN 2083-6473
ISSN 2083-6481 (electronic version)
 

 

 

Editor-in-Chief

Associate Editor
Prof. Tomasz Neumann
 

Published by
TransNav, Faculty of Navigation
Gdynia Maritime University
3, John Paul II Avenue
81-345 Gdynia, POLAND
www http://www.transnav.eu
e-mail transnav@umg.edu.pl
Improving the Efficiency of a High Speed Catamaran Through the Replacement of the Propulsion System
1 Technical University of Catalonia, Catalonia, Barcelona, Spain
2 TRASMAPI, Ibiza, Spain
ABSTRACT: The high speed vessels are primarily designed for short distances services as public transport of passengers and vehicles. The range of high speed, according to the Code of high-speed vessels begins at 20 knots, which depends on the cruise speed you desire for your vessel; you will have to use the most appropriate type of propellant. In general, in the past 20 years, they have been building high-speed vessels with speeds above 33 knots, which meant installing water jet propellants coupled to powerful engines and therefore of high consumption of fuel, increasing operating costs and causing increased air pollution. Although the prices of fuel have been reduced to half, due to the sharp fall in oil prices, the consumption of fuel and the air pollution remains high at these speeds and powers used, in addition to that the reduction of the time spent on each trip is not excessive, mainly in short routes that are less than an hour . This article is about adapting a ship of high-speed service, with a maximum speed in tests of 34 knots and to reduce its operating costs (fuel, maintenance, etc.) and make it economically viable; before the transformation, this vessel was operating with a service speed of 22 knots, and with a consumption per mile of 135 litters of MGO. The transformation process has consisted by: ? Replacement of the two original water jet with four shaft lines with fix pitch propeller. ? Replacement of the two original main engines (2 x 6500 kW = 13000 kW) by four engines (4 x 1380kW = 5.520 kW). ? Changing the underwater hull shape to fit the new propellers and maximize its efficiency. ? Relocation of auxiliary engines, to achieve the most efficient trim. ? Installation of two lateral propellers to improve maneuverability and shorten the total time of journey. After the reform and the return to service of the vessel with a service speed of over 22 knots, it has been verified that the consumption per mile is of 45 litters MGO, representing a reduction of 65% of consumption and even more reduction of emissions as the new engines comply with the latest regulations.
REFERENCES
Stability Report, Hull 54, “TURGUT REIS 1”
Furness, P (Editor), “Hydrostatic” Australian Maritime College
HSC Code- International Code of Safety for High Speed Craft 1994
MEPC.1/Circ.684. Directrices Para La Utilización Voluntaria Del Indicador Operacional De La Eficiencia Energética Del Buque (EEOI)
MEPC.1/Circ.795/Rev.1. Interpretaciones Unificadas al anexo VI MARPOL
MEPC 64-INF.22 Primera Versión de las Directrices de la Industria para el Cálculo y Verificación del EEDI
MEPC.1/Circ.815. Orientaciones De 2013 Para El Tratamiento De Las Tecnologías Innovadoras De Eficiencia Energética En El Cálculo Y La Verificación Del EEDI Obtenido
MEPC.213 (63). Directrices De 2012 Para La Elaboración De Un Plan De Gestión De La Eficiencia Energética Del Buque (SEEMP)
MEPC. 231(65). 2013 Guidelines For Calculation Of Reference Lines For Use With The Energy Efficiency Design Index (EEDI)
MEPC.232 (65). 2013 Interim Guidelines For Determing Minimum Propulsion Power To Maintain The Manoeuvrability Of Ships In Adverse Conditions
MEPC.233 (65). 2013 Guidelines for Calculation of Reference Lines for Use with the Energy Efficiency Design Index (EEDI) For Cruise Passenger Ships Having Non-Conventional Propulsion.
MEPC.234 (65). Amendments to the 2012 Guidelines on Survey and Certification of the Energy Efficiency Design Index (EEDI) (Resolution MEPC.214 (63)), As Amended.
MEPC 67/INF.3. Reduction of GHG Emissions from Ships Third IMO GHG Study 2014 – Final Report. (Adopted October 2014)
COM (2013) 479. Comunicación de la Comisión. Integrating maritime transport emissions in the EU's greenhouse gas reduction policies.
COM (2013) 480. Propuesta de Regulación. On the monitoring, reporting and verification of carbon dioxide emissions from maritime transport and amending Regulation (EU) No 525/2013
Citation note:
de Melo Rodríguez G., Echevarrieta I., Serra J.M.: Improving the Efficiency of a High Speed Catamaran Through the Replacement of the Propulsion System. TransNav, the International Journal on Marine Navigation and Safety of Sea Transportation, Vol. 9, No. 4, doi:10.12716/1001.09.04.09, pp. 531-535, 2015
Authors in other databases:
Germán de Melo Rodríguez: Scopus icon55649310700
Ignacio Echevarrieta:
Juan Marí Serra:

Other publications of authors:

M. Dramski, H. Koivisto, T. Gregorič, G. de Melo Rodríguez, A. Chronopoulos, R. Ziarati
I. Bodus-Olkowska, I. Garczyńska, A. Lisaj, M. Mąka, M. Dramski, A. Chronopoulos, T. Gregorič, H. Koivisto, G. de Melo Rodríguez, R. Ziarati, K. Filipiak

File downloaded 859 times








Important: TransNav.eu cookie usage
The TransNav.eu website uses certain cookies. A cookie is a text-only string of information that the TransNav.EU website transfers to the cookie file of the browser on your computer. Cookies allow the TransNav.eu website to perform properly and remember your browsing history. Cookies also help a website to arrange content to match your preferred interests more quickly. Cookies alone cannot be used to identify you.
Akceptuję pliki cookies z tej strony