Evangelos Boulougouris scite author profile

Voyage optimization is a practice to select the optimum route for the ship operators to increase energy efficiency and reduce Green House Gas emission in the shipping industry. An accurate prediction of ship operational performance is the prerequisite to achieve these targets. In this paper, a modified Kwon's method was developed to predict the added resistance caused by wave and wind for a specific ship type, and an easy-to-use semi-empirical ship operational performance prediction model is proposed. It can accurately predict the ship's operational performance for a specific commercial ship under different drafts, at varying speeds and in varying encounter angles, and then enables the user to investigate the relation between fuel consumption and the various sea states and directions that the ship may encounter during her voyage. Based on the results from the operational performance prediction model and real time climatological information, different options for the ship's navigation course can be evaluated according to a number of objectives, including: maximising safety and minimising fuel consumption and voyage time. By incorporating this into a decision support tool, the ship's crew are able to make an informed decision about what is the best course to navigate. In this study the Energy Efficiency of Operation (EEO) is defined as an indicator to illustrate the ratio of main engine fuel consumption per unit of transport work. Two case studies are carried out to perform the prediction of ship operational performance for Suezmax and Aframax Oil Tankers, and the results indicate that the semiempirical ship operational performance prediction model provides an extremely quick calculation with very reasonable accuracy, particularly considering the uncertainties related to the parameters of interest for the case study data. Within the case studies, the additional fuel consumption caused by the combined hull and propeller fouling and engine degradation is included in the model as a time-dependent correction factor. The factor may assist the ship owner/operator to determine the hull coating selection, and/or the dry-docking and main engine maintenance strategy

show abstract

Marine dual fuel engine modelling and parametric investigation of engine settings effect on performance-emissions trade-offs

Stoumpos

Theotokatos

Boulougouris

et al. 2018

Ocean Engineering

View full text Add to dashboard Cite

The continuous stringent requirements of the environmental regulations along with the LNG fuel 12 penetration and the development of port and bunkering facilities, render the use of the dual fuel 13 engines an attractive alternative of the traditional ship propulsion plants based on Diesel engines 14 running with HFO for reducing both the plant operating cost and environmental footprint. The present 15 study deals with the computational investigation of a large marine dual fuel (DF) engine of the four-16 stroke type for comparing its performance and emissions, in both diesel and gas mode operation by 17 using the commercial software GT-ISE. The engine diesel model was initially set up and calibrated to 18 adequately represent the engine operation. Subsequently, the engine dual fuel model was further 19 developed by considering the injection of two different fuels; methane in the cylinder inlet ports and 20 pilot diesel fuel into the engine cylinders. The derived results were analysed for revealing the 21 differences of the engine performance and emissions at each operating mode. In addition, the 22 turbocharger matching was investigated and discussed to enlighten the turbocharging system 23 challenges due to the completely different air fuel ratio requirements in diesel and gas modes, 24 respectively. Finally, parametric simulations were performed for gas mode operation at different loads 25 by varying pilot fuel injection timing, inlet valve closing and inlet manifold boost pressure, aiming to 26 identify the engine settings that simultaneously reduce CO 2 and NOx emissions considering the 27 ratio operation window limitations. The parametric study results are discussed to infer the 28 engine optimal settings.

show abstract

Towards Marine Dual Fuel Engines Digital Twins—Integrated Modelling of Thermodynamic Processes and Control System Functions

Stoumpos

Theotokatos

Mavrelos

et al. 2020

JMSE

View full text Add to dashboard Cite

This study aims at developing an integrated model that combines detailed engine thermodynamic modelling and the control system functional modelling paving the way towards the development of high-fidelity digital twins. To sufficiently represent the combustion process, a multi-Wiebe function approach was employed, whereas a database for storing the combustion model parameters was developed. The developed model was employed for the systematic investigation of a marine four-stroke dual fuel engine response during demanding transient operation with mode switching and load changes. The derived results were analysed to identify the critical engine components and their effect on the engine operational limitations. The results demonstrate that the developed model can sufficiently represent the engine and its subsystems/components behaviour and effectively capture the engine control system’s functionality. The appropriate turbocharger matching along with the sufficient design of the exhaust gas waste gate valve and fuel control systems are crucial for ensuring the smooth engine operation of dual fuel engines.

show abstract

Review on the Safe Use of Ammonia Fuel Cells in the Maritime Industry

et al. 2021

View full text Add to dashboard Cite

In April 2018, the International Maritime Organisation adopted an ambitious plan to contribute to the global efforts to reduce the Greenhouse Gas emissions, as set by the Paris Agreement, by targeting a 50% reduction in shipping’s Green House Gas emissions by 2050, benchmarked to 2008 levels. To meet these challenging goals, the maritime industry must introduce environmentally friendly fuels with negligible, or low SOX, NOX and CO2 emissions. Ammonia use in maritime applications is considered promising, due to its high energy density, low flammability, easy storage and low production cost. Moreover, ammonia can be used as fuel in a variety of propulsors such as fuel cells and can be produced from renewable sources. As a result, ammonia can be used as a versatile marine fuel, exploiting the existing infrastructure, and having zero SOX and CO2 emissions. However, there are several challenges to overcome for ammonia to become a compelling fuel towards the decarbonisation of shipping. Such factors include the selection of the appropriate ammonia-fuelled power generator, the selection of the appropriate system safety assessment tool, and mitigating measures to address the hazards of ammonia. This paper discusses the state-of-the-art of ammonia fuelled fuel cells for marine applications and presents their potential, and challenges.

show abstract

scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.

Contact Info

customersupport@researchsolutions.com

10624 S. Eastern Ave., Ste. A-614

Henderson, NV 89052, USA

This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.

Blog Terms and Conditions API Terms Privacy Policy Contact Cookie Preferences Do Not Sell or Share My Personal Information

Made with 💙 for researchers

Part of the Research Solutions Family.