TY  - CONF
AU  - Vasilev, Matija
AU  - Kalajdžić, Milan
AU  - Suvačarov, Aleksa
PY  - 2023
UR  - https://machinery.mas.bg.ac.rs/handle/123456789/7627
AB  - The bulbous bow is a significant feature integrated into ship designs to improve their overall
performance. However, relying solely on original design assumptions may lead to suboptimal results,
potentially hindering the vessel's efficiency during operation. To address this issue and optimize ship
performance, this paper proposes a practical methodology for retrofitting the bulbous bow to suit the
actual operational profile of container ships. By analyzing four years' worth of operational data, this
study identifies the most frequent sailing conditions, including speed, draft, trim, and displacement.
Using this information, multiple bulbous bow configurations by following Kracht (1978) are derived
and subjected to numerical simulations, tailored to various sailing conditions. The proposed framework
not only optimizes the bulbous bow for container ships but also extends its application to other vessel
types such as bulk carriers, tankers, and large commercial ships. By customizing the bulbous bow design
to match specific operational profiles, significant improvements in fuel efficiency, environmental
sustainability, and overall operational performance can be achieved. This research underscores the
significance of accounting for real-world operational conditions when designing and optimizing the
bulbous bow. Leveraging operational data and conducting numerical simulations facilitates the
identification of optimal configurations, aligning vessel performance with its actual sailing conditions.
Implementing these optimized bulbous bow designs has the potential to revolutionize the maritime
industry by enhancing ship performance and promoting energy efficiency. By prioritizing the practical
considerations of real-world operational conditions, this paper presents a valuable approach to improve
the overall efficiency of ships, contributing to a more sustainable and eco-friendly maritime sector. CFD,
or Computational Fluid Dynamics, has revolutionized the process of bulb optimization. Before its
introduction, research was primarily based on physical model testing. However, CFD has made it
significantly easier and faster to refine bulb designs. This technological advancement has allowed for
the incorporation of economic and ecological considerations into bulb design, going beyond just
hydrodynamics (refer to Schneekluth et al 1998). This advancement enables engineers and designers to
not only improve the hydrodynamic performance of the bulb, but also to take into account factors such
as cost-effectiveness and environmental impact. As a result, bulb optimization has become a more
comprehensive and efficient process, ultimately leading to better-designed vessels and a more
sustainable approach to shipbuilding. The first serious attempts to improve ship design using CFD
began during the previous decades which includes parametric design Lu et al (2016), Yang et al (2016),
Peri et al (2001), Sharma et al (2008), Wagner et al (2014) and many others. A common characteristic
among all of them is that the bulbous bow has a positive effect at higher speeds (refer to Schneekluth
et al (1998)). In this paper, bulb optimization is presented as a measure to improve the energy efficiency
of a container vessel in order to meet the Carbon Intensity Indicator (CII) criteria defined in Resolution
MEPC.353(78) (2022). The concept of a CII within the shipping industry, designed to gauge and
manage the carbon emissions associated with maritime activities, has emerged as a crucial tool in
addressing environmental concerns and reducing the sector's carbon footprint. The aim of the measures
is to improve the fleet average carbon intensity by at least 40% in 2030, relative to 2008 (refer to
Resolution MEPC.377(80), (2023)).
PB  - blueOASIS – Ocean Sustainable Solutions
C3  - NuTTS 2023 25th Numerical Towing Tank Symposium 15 – 17 October 2023. Ericeira, Portugal
T1  - A Practical Approach to Bulbous Bow Retrofit Analysis for Enhanced Energy Efficiency
UR  - https://hdl.handle.net/21.15107/rcub_machinery_7627
ER  - 

@conference{
author = "Vasilev, Matija and Kalajdžić, Milan and Suvačarov, Aleksa",
year = "2023",
abstract = "The bulbous bow is a significant feature integrated into ship designs to improve their overall
performance. However, relying solely on original design assumptions may lead to suboptimal results,
potentially hindering the vessel's efficiency during operation. To address this issue and optimize ship
performance, this paper proposes a practical methodology for retrofitting the bulbous bow to suit the
actual operational profile of container ships. By analyzing four years' worth of operational data, this
study identifies the most frequent sailing conditions, including speed, draft, trim, and displacement.
Using this information, multiple bulbous bow configurations by following Kracht (1978) are derived
and subjected to numerical simulations, tailored to various sailing conditions. The proposed framework
not only optimizes the bulbous bow for container ships but also extends its application to other vessel
types such as bulk carriers, tankers, and large commercial ships. By customizing the bulbous bow design
to match specific operational profiles, significant improvements in fuel efficiency, environmental
sustainability, and overall operational performance can be achieved. This research underscores the
significance of accounting for real-world operational conditions when designing and optimizing the
bulbous bow. Leveraging operational data and conducting numerical simulations facilitates the
identification of optimal configurations, aligning vessel performance with its actual sailing conditions.
Implementing these optimized bulbous bow designs has the potential to revolutionize the maritime
industry by enhancing ship performance and promoting energy efficiency. By prioritizing the practical
considerations of real-world operational conditions, this paper presents a valuable approach to improve
the overall efficiency of ships, contributing to a more sustainable and eco-friendly maritime sector. CFD,
or Computational Fluid Dynamics, has revolutionized the process of bulb optimization. Before its
introduction, research was primarily based on physical model testing. However, CFD has made it
significantly easier and faster to refine bulb designs. This technological advancement has allowed for
the incorporation of economic and ecological considerations into bulb design, going beyond just
hydrodynamics (refer to Schneekluth et al 1998). This advancement enables engineers and designers to
not only improve the hydrodynamic performance of the bulb, but also to take into account factors such
as cost-effectiveness and environmental impact. As a result, bulb optimization has become a more
comprehensive and efficient process, ultimately leading to better-designed vessels and a more
sustainable approach to shipbuilding. The first serious attempts to improve ship design using CFD
began during the previous decades which includes parametric design Lu et al (2016), Yang et al (2016),
Peri et al (2001), Sharma et al (2008), Wagner et al (2014) and many others. A common characteristic
among all of them is that the bulbous bow has a positive effect at higher speeds (refer to Schneekluth
et al (1998)). In this paper, bulb optimization is presented as a measure to improve the energy efficiency
of a container vessel in order to meet the Carbon Intensity Indicator (CII) criteria defined in Resolution
MEPC.353(78) (2022). The concept of a CII within the shipping industry, designed to gauge and
manage the carbon emissions associated with maritime activities, has emerged as a crucial tool in
addressing environmental concerns and reducing the sector's carbon footprint. The aim of the measures
is to improve the fleet average carbon intensity by at least 40% in 2030, relative to 2008 (refer to
Resolution MEPC.377(80), (2023)).",
publisher = "blueOASIS – Ocean Sustainable Solutions",
journal = "NuTTS 2023 25th Numerical Towing Tank Symposium 15 – 17 October 2023. Ericeira, Portugal",
title = "A Practical Approach to Bulbous Bow Retrofit Analysis for Enhanced Energy Efficiency",
url = "https://hdl.handle.net/21.15107/rcub_machinery_7627"
}

Vasilev, M., Kalajdžić, M.,& Suvačarov, A.. (2023). A Practical Approach to Bulbous Bow Retrofit Analysis for Enhanced Energy Efficiency. in NuTTS 2023 25th Numerical Towing Tank Symposium 15 – 17 October 2023. Ericeira, Portugal
blueOASIS – Ocean Sustainable Solutions..
https://hdl.handle.net/21.15107/rcub_machinery_7627

Vasilev M, Kalajdžić M, Suvačarov A. A Practical Approach to Bulbous Bow Retrofit Analysis for Enhanced Energy Efficiency. in NuTTS 2023 25th Numerical Towing Tank Symposium 15 – 17 October 2023. Ericeira, Portugal. 2023;.
https://hdl.handle.net/21.15107/rcub_machinery_7627 .

Vasilev, Matija, Kalajdžić, Milan, Suvačarov, Aleksa, "A Practical Approach to Bulbous Bow Retrofit Analysis for Enhanced Energy Efficiency" in NuTTS 2023 25th Numerical Towing Tank Symposium 15 – 17 October 2023. Ericeira, Portugal (2023),
https://hdl.handle.net/21.15107/rcub_machinery_7627 .

TY  - JOUR
AU  - Kalajdžić, Milan
AU  - Vasilev, Matija
AU  - Momčilović, Nikola
PY  - 2023
UR  - https://machinery.mas.bg.ac.rs/handle/123456789/6847
AB  - Inland waterways vessels (IWV) have no mandatory regulations regarding their energy efficiency, as sea-going ships have. So far, there are just two proposed design energy efficiency evaluation methods, both based on IMO EEDI approach and data on EU inland navigation. Operational indicators and real-time navigation measurements from available literature do not exist. Therefore, this paper aims to introduce the energy efficiency in operation (EEO), assessed for the typical Danube cargo vessel. Firstly, an operational profile is acquired by tracking the vessel’s voyages, and by identifying actual constraints of each sector the vessel has sailed during the designated time. Secondly, EEO is incorporated within two available methods and calculated based on acquired operational data considering different navigational conditions. The paper shows how the energy efficiency vastly depends on variables such as water depth, current speed, draught, deadweight, river constraints. Analysis is performed for the most employed month of the vessel navigation, and annually. Depending on water level scenarios and during the selected month of sailing, the total amount of CO2 emitted is estimated to be between 22.7 t and 29.9 t, while the necessary average speed reduction (i.e., slow steaming) per sectoral voyage for the requirement compliance is calculated to be in between 4.8%-26%. Slow steaming is assessed to extend the time of voyage for 6.1-10.7 hours on monthly basis and 49-87 hours annually.
PB  - Faculty of Mechanical Engineering and Naval Architecture, University of Zagreb
T2  - Brodogradnja : Teorija i praksa brodogradnje i pomorske tehnike
T1  - Inland waterway cargo vessel energy efficiency in operation
IS  - 3
VL  - 74
DO  - doi.org/10.21278/brod74304
ER  - 

@article{
author = "Kalajdžić, Milan and Vasilev, Matija and Momčilović, Nikola",
year = "2023",
abstract = "Inland waterways vessels (IWV) have no mandatory regulations regarding their energy efficiency, as sea-going ships have. So far, there are just two proposed design energy efficiency evaluation methods, both based on IMO EEDI approach and data on EU inland navigation. Operational indicators and real-time navigation measurements from available literature do not exist. Therefore, this paper aims to introduce the energy efficiency in operation (EEO), assessed for the typical Danube cargo vessel. Firstly, an operational profile is acquired by tracking the vessel’s voyages, and by identifying actual constraints of each sector the vessel has sailed during the designated time. Secondly, EEO is incorporated within two available methods and calculated based on acquired operational data considering different navigational conditions. The paper shows how the energy efficiency vastly depends on variables such as water depth, current speed, draught, deadweight, river constraints. Analysis is performed for the most employed month of the vessel navigation, and annually. Depending on water level scenarios and during the selected month of sailing, the total amount of CO2 emitted is estimated to be between 22.7 t and 29.9 t, while the necessary average speed reduction (i.e., slow steaming) per sectoral voyage for the requirement compliance is calculated to be in between 4.8%-26%. Slow steaming is assessed to extend the time of voyage for 6.1-10.7 hours on monthly basis and 49-87 hours annually.",
publisher = "Faculty of Mechanical Engineering and Naval Architecture, University of Zagreb",
journal = "Brodogradnja : Teorija i praksa brodogradnje i pomorske tehnike",
title = "Inland waterway cargo vessel energy efficiency in operation",
number = "3",
volume = "74",
doi = "doi.org/10.21278/brod74304"
}

Kalajdžić, M., Vasilev, M.,& Momčilović, N.. (2023). Inland waterway cargo vessel energy efficiency in operation. in Brodogradnja : Teorija i praksa brodogradnje i pomorske tehnike
Faculty of Mechanical Engineering and Naval Architecture, University of Zagreb., 74(3).
https://doi.org/doi.org/10.21278/brod74304

Kalajdžić M, Vasilev M, Momčilović N. Inland waterway cargo vessel energy efficiency in operation. in Brodogradnja : Teorija i praksa brodogradnje i pomorske tehnike. 2023;74(3).
doi:doi.org/10.21278/brod74304 .

Kalajdžić, Milan, Vasilev, Matija, Momčilović, Nikola, "Inland waterway cargo vessel energy efficiency in operation" in Brodogradnja : Teorija i praksa brodogradnje i pomorske tehnike, 74, no. 3 (2023),
https://doi.org/doi.org/10.21278/brod74304 . .

TY  - JOUR
AU  - Kalajdžić, Milan
AU  - Vasilev, Matija
AU  - Momčilović, Nikola
PY  - 2022
UR  - https://machinery.mas.bg.ac.rs/handle/123456789/3684
AB  - After introducing an energy efficiency design index (EEDI) in 2011, International Maritime Organization (IMO) pursued their short- and long-term goals to reduce greenhouse gas (GHG) emissions from ships by presenting, among others, an energy efficiency existing ship index (EEXI). Contrary to EEDI which is used for new ships solely, EEXI is addressing an energy efficiency of already built ships and is set to become formally applicable starting from 2023. Existing designs cannot be essentially and rapidly changed to comply the criterion. The only main particular from the preliminary design phase that can be meaningly optimized ???post festum??? is a required engine power, and thus, the speed. Therefore, the paper explores the effect of EEXI policy on a fleet of 153 bulk carriers built between 2000 and 2020 in order to address their near future and prompt design changes, specifically considering the power reduction. For that purpose, an attained and a required EEXI are calculated for each ship. The results showed that only 15% of the ships built in 2000-2012 satisfied 2013-2014 IMO criterion. This impacted the design of ships built in 2013-2022, as they complied the same criterion by 88% of share. However, no ship from the whole database satisfied the present day EEDI requirement and only one ship fulfilled the contemporary EEXI requirement meaning that the current designs are not able to match the emerging criteria to a large extent. In order to meet an energy efficiency criterion, a main engine power reduction and speed are predicted assuming that the engine power and shaft limiter are installed. The investigation showed that MCR reduction of the total fleet taken into account had to be reduced by 50% and speed by 15% on average in order for ships to meet current requirements. Moreover, a graphic method is developed for the estimation of EEXI by using only deadweight (DWT) and could be used on existing bulk carriers with an aim to satisfy novel regulation with reliably evaluate an energy efficiency of existing ships.
PB  - Univ Zagreb Fac Mechanical Engineering & Naval Architecture, Zagreb
T2  - Brodogradnja
T1  - Power reduction considerations for bulk carriers with respect to novel energy efficiency regulations
EP  - 92
IS  - 2
SP  - 79
VL  - 73
DO  - 10.21278/brod73205
ER  - 

@article{
author = "Kalajdžić, Milan and Vasilev, Matija and Momčilović, Nikola",
year = "2022",
abstract = "After introducing an energy efficiency design index (EEDI) in 2011, International Maritime Organization (IMO) pursued their short- and long-term goals to reduce greenhouse gas (GHG) emissions from ships by presenting, among others, an energy efficiency existing ship index (EEXI). Contrary to EEDI which is used for new ships solely, EEXI is addressing an energy efficiency of already built ships and is set to become formally applicable starting from 2023. Existing designs cannot be essentially and rapidly changed to comply the criterion. The only main particular from the preliminary design phase that can be meaningly optimized ???post festum??? is a required engine power, and thus, the speed. Therefore, the paper explores the effect of EEXI policy on a fleet of 153 bulk carriers built between 2000 and 2020 in order to address their near future and prompt design changes, specifically considering the power reduction. For that purpose, an attained and a required EEXI are calculated for each ship. The results showed that only 15% of the ships built in 2000-2012 satisfied 2013-2014 IMO criterion. This impacted the design of ships built in 2013-2022, as they complied the same criterion by 88% of share. However, no ship from the whole database satisfied the present day EEDI requirement and only one ship fulfilled the contemporary EEXI requirement meaning that the current designs are not able to match the emerging criteria to a large extent. In order to meet an energy efficiency criterion, a main engine power reduction and speed are predicted assuming that the engine power and shaft limiter are installed. The investigation showed that MCR reduction of the total fleet taken into account had to be reduced by 50% and speed by 15% on average in order for ships to meet current requirements. Moreover, a graphic method is developed for the estimation of EEXI by using only deadweight (DWT) and could be used on existing bulk carriers with an aim to satisfy novel regulation with reliably evaluate an energy efficiency of existing ships.",
publisher = "Univ Zagreb Fac Mechanical Engineering & Naval Architecture, Zagreb",
journal = "Brodogradnja",
title = "Power reduction considerations for bulk carriers with respect to novel energy efficiency regulations",
pages = "92-79",
number = "2",
volume = "73",
doi = "10.21278/brod73205"
}

Kalajdžić, M., Vasilev, M.,& Momčilović, N.. (2022). Power reduction considerations for bulk carriers with respect to novel energy efficiency regulations. in Brodogradnja
Univ Zagreb Fac Mechanical Engineering & Naval Architecture, Zagreb., 73(2), 79-92.
https://doi.org/10.21278/brod73205

Kalajdžić M, Vasilev M, Momčilović N. Power reduction considerations for bulk carriers with respect to novel energy efficiency regulations. in Brodogradnja. 2022;73(2):79-92.
doi:10.21278/brod73205 .

Kalajdžić, Milan, Vasilev, Matija, Momčilović, Nikola, "Power reduction considerations for bulk carriers with respect to novel energy efficiency regulations" in Brodogradnja, 73, no. 2 (2022):79-92,
https://doi.org/10.21278/brod73205 . .

TY  - JOUR
AU  - Vasilev, Matija
AU  - Kalajdžić, Milan
PY  - 2022
UR  - https://machinery.mas.bg.ac.rs/handle/123456789/6734
AB  - An influence assessment of lightweight change on Energy Efficiency Existing Ship Index/Energy Efficiency Design Index performance for two supramax bulk carriers is presented in this paper. The study covers a variation of lightweight from 100% to 85% with the step of 5% reduction. The influence on ship performance is determined through deadweight, reference speed, and engine load. In one part of the work, deadweight is considered to be constant, so the study covers the impact of displacement change on ship speed and power, while in the other one, displacement was
kept the same so that the direct influence of deadweight on performance indices was considered. Due to displacement change, a new power curve should be derived, and for this purpose, the Holtrop-Mennen method has been used to predict total resistance. Estimated results show that an
increase in speed can be up to 0,7% for the same power and a reduction in power up to 2,6% for the same speed. An increase of a deadweight affects the performance indices up to 3,2%.
PB  - Faculty of Mechanical Engineering, University of Belgrade
T2  - FME TRANSACTIONS
T1  - Influence of Lightweight Change on Ship Performance
VL  - 50
DO  - 10.5937/fme2204615V
ER  - 

@article{
author = "Vasilev, Matija and Kalajdžić, Milan",
year = "2022",
abstract = "An influence assessment of lightweight change on Energy Efficiency Existing Ship Index/Energy Efficiency Design Index performance for two supramax bulk carriers is presented in this paper. The study covers a variation of lightweight from 100% to 85% with the step of 5% reduction. The influence on ship performance is determined through deadweight, reference speed, and engine load. In one part of the work, deadweight is considered to be constant, so the study covers the impact of displacement change on ship speed and power, while in the other one, displacement was
kept the same so that the direct influence of deadweight on performance indices was considered. Due to displacement change, a new power curve should be derived, and for this purpose, the Holtrop-Mennen method has been used to predict total resistance. Estimated results show that an
increase in speed can be up to 0,7% for the same power and a reduction in power up to 2,6% for the same speed. An increase of a deadweight affects the performance indices up to 3,2%.",
publisher = "Faculty of Mechanical Engineering, University of Belgrade",
journal = "FME TRANSACTIONS",
title = "Influence of Lightweight Change on Ship Performance",
volume = "50",
doi = "10.5937/fme2204615V"
}

Vasilev, M.,& Kalajdžić, M.. (2022). Influence of Lightweight Change on Ship Performance. in FME TRANSACTIONS
Faculty of Mechanical Engineering, University of Belgrade., 50.
https://doi.org/10.5937/fme2204615V

Vasilev M, Kalajdžić M. Influence of Lightweight Change on Ship Performance. in FME TRANSACTIONS. 2022;50.
doi:10.5937/fme2204615V .

Vasilev, Matija, Kalajdžić, Milan, "Influence of Lightweight Change on Ship Performance" in FME TRANSACTIONS, 50 (2022),
https://doi.org/10.5937/fme2204615V . .

TY  - CONF
AU  - Vasilev, Matija
AU  - Kalajdžić, Milan
PY  - 2022
UR  - https://machinery.mas.bg.ac.rs/handle/123456789/6733
AB  - The biofouling of ship hulls has a significant impact on both the environment and the ship. A negative effect on the environment is manifested by an increase in pollution with greenhouse gasses and disrupting the ecosystem by translocating microorganisms, sea plants or animals from one place to another. Biofouling film which appears on the immersed hull part through the years increases surface roughness and therefore induces a streamlines disturbance and together with increased wet surface affects the increase in total resistance. As a result of greater total resistance, a larger amount of fuel combusts over time, thus greenhouse emission is being increased. A numerical model based on Reynolds Averaged Navier-Stokes (RANS) equations with incorporated different roughness effects as equivalent sand grain roughness height in one Computational Fluid Dynamics (CFD) software has been conducted in this paper. Simulation has been applied to one bulk carrier and represents the effect of dry-docking the ship after several years in operation and treating the hull with high-performance coat such as self-polishing coating (SPC) or silicone- and fluorine-based fouling coatings (FRC).
PB  - Inno Gatin
PB  - Milovan Perić
C3  - Proceedings of 24th Numerical Towing Tank Symposium October 2022 (NuTTS 2022), Zagreb, Croatia
T1  - The Influence of Roughness Change on Ship Resistance in CFD Simulations
UR  - https://hdl.handle.net/21.15107/rcub_machinery_6733
ER  - 

@conference{
author = "Vasilev, Matija and Kalajdžić, Milan",
year = "2022",
abstract = "The biofouling of ship hulls has a significant impact on both the environment and the ship. A negative effect on the environment is manifested by an increase in pollution with greenhouse gasses and disrupting the ecosystem by translocating microorganisms, sea plants or animals from one place to another. Biofouling film which appears on the immersed hull part through the years increases surface roughness and therefore induces a streamlines disturbance and together with increased wet surface affects the increase in total resistance. As a result of greater total resistance, a larger amount of fuel combusts over time, thus greenhouse emission is being increased. A numerical model based on Reynolds Averaged Navier-Stokes (RANS) equations with incorporated different roughness effects as equivalent sand grain roughness height in one Computational Fluid Dynamics (CFD) software has been conducted in this paper. Simulation has been applied to one bulk carrier and represents the effect of dry-docking the ship after several years in operation and treating the hull with high-performance coat such as self-polishing coating (SPC) or silicone- and fluorine-based fouling coatings (FRC).",
publisher = "Inno Gatin, Milovan Perić",
journal = "Proceedings of 24th Numerical Towing Tank Symposium October 2022 (NuTTS 2022), Zagreb, Croatia",
title = "The Influence of Roughness Change on Ship Resistance in CFD Simulations",
url = "https://hdl.handle.net/21.15107/rcub_machinery_6733"
}

Vasilev, M.,& Kalajdžić, M.. (2022). The Influence of Roughness Change on Ship Resistance in CFD Simulations. in Proceedings of 24th Numerical Towing Tank Symposium October 2022 (NuTTS 2022), Zagreb, Croatia
Inno Gatin..
https://hdl.handle.net/21.15107/rcub_machinery_6733

Vasilev M, Kalajdžić M. The Influence of Roughness Change on Ship Resistance in CFD Simulations. in Proceedings of 24th Numerical Towing Tank Symposium October 2022 (NuTTS 2022), Zagreb, Croatia. 2022;.
https://hdl.handle.net/21.15107/rcub_machinery_6733 .

Vasilev, Matija, Kalajdžić, Milan, "The Influence of Roughness Change on Ship Resistance in CFD Simulations" in Proceedings of 24th Numerical Towing Tank Symposium October 2022 (NuTTS 2022), Zagreb, Croatia (2022),
https://hdl.handle.net/21.15107/rcub_machinery_6733 .

TY  - CONF
AU  - Kalajdžić, Milan
AU  - Vasilev, Matija
AU  - Momčilović, Nikola
PY  - 2022
UR  - https://machinery.mas.bg.ac.rs/handle/123456789/6725
AB  - Inland waterway industry is far smaller than maritime and therefore, provides less environmental impact. However, its local effect is not negligible. Even though maritime practice has been addressing energy efficiency of ships for decade, no corresponding measures were delivered in inland waterway industry, considering the Green Deal goals. However, there are few proposals for addressing the energy efficiency of inland vessels. Hence, this work tries to gather such proposals and provide a review on their current status.
PB  - Faculty of Mechanical Engineering and Naval Architecture, University of Zagreb
C3  - SORTA 2022 PROCEEDINGS - 25th SYMPOSIUM ON THE THEORY AND PRACTICE OF SHIPBUILDING
T1  - Energy Efficiency of Inland Vessels: Current Status
UR  - https://hdl.handle.net/21.15107/rcub_machinery_6725
ER  - 

@conference{
author = "Kalajdžić, Milan and Vasilev, Matija and Momčilović, Nikola",
year = "2022",
abstract = "Inland waterway industry is far smaller than maritime and therefore, provides less environmental impact. However, its local effect is not negligible. Even though maritime practice has been addressing energy efficiency of ships for decade, no corresponding measures were delivered in inland waterway industry, considering the Green Deal goals. However, there are few proposals for addressing the energy efficiency of inland vessels. Hence, this work tries to gather such proposals and provide a review on their current status.",
publisher = "Faculty of Mechanical Engineering and Naval Architecture, University of Zagreb",
journal = "SORTA 2022 PROCEEDINGS - 25th SYMPOSIUM ON THE THEORY AND PRACTICE OF SHIPBUILDING",
title = "Energy Efficiency of Inland Vessels: Current Status",
url = "https://hdl.handle.net/21.15107/rcub_machinery_6725"
}

Kalajdžić, M., Vasilev, M.,& Momčilović, N.. (2022). Energy Efficiency of Inland Vessels: Current Status. in SORTA 2022 PROCEEDINGS - 25th SYMPOSIUM ON THE THEORY AND PRACTICE OF SHIPBUILDING
Faculty of Mechanical Engineering and Naval Architecture, University of Zagreb..
https://hdl.handle.net/21.15107/rcub_machinery_6725

Kalajdžić M, Vasilev M, Momčilović N. Energy Efficiency of Inland Vessels: Current Status. in SORTA 2022 PROCEEDINGS - 25th SYMPOSIUM ON THE THEORY AND PRACTICE OF SHIPBUILDING. 2022;.
https://hdl.handle.net/21.15107/rcub_machinery_6725 .

Kalajdžić, Milan, Vasilev, Matija, Momčilović, Nikola, "Energy Efficiency of Inland Vessels: Current Status" in SORTA 2022 PROCEEDINGS - 25th SYMPOSIUM ON THE THEORY AND PRACTICE OF SHIPBUILDING (2022),
https://hdl.handle.net/21.15107/rcub_machinery_6725 .

TY  - JOUR
AU  - Kalajdžić, Milan
AU  - Vasilev, Matija
AU  - Momčilović, Nikola
PY  - 2022
UR  - https://machinery.mas.bg.ac.rs/handle/123456789/6728
AB  - In order to address the decarbonization policy, International Maritime Organization (IMO) has been dealing with energy efficiency of ships for more than a decade. Firstly, procedures for energy efficiency assessment are introduced through the regulative, but only for new ships. Consequently, IMO also introduced energy efficiency criterion for already built ships that is set to be applicable starting from 2023. Regulative is already having an impact on ship design. While the new ships can be adapted in design phase, built ones will not have so many options. So far, almost all the solutions include reduction of the speed, i.e., slow steaming. Nevertheless, there are numerous technical and operational measures. The paper presents the calculation of energy efficiency performed for the fleet of existing 11 cargo ships categorized into four different ship classes. Calculation is based on the current IMO regulations covering the evaluation of energy efficiency of existing ships index (EEXI). Input parameters for analysis are obtained using two approaches:
technical files (design parameters of the ship) & sea-trial reports and statistical method (when technical files & sea-trail reports are not available). Authors examined if the difference in two input approaches and potential class notation change could lead to different energy efficiency evaluation results. Moreover, the main goal of the research was to investigate on how the present conventionally designed cargo ships compare to the novel regulations.
PB  - Faculty of Maritime Studies in Kotor, University of Montenegro
T2  - Journal of Maritime Sciences
T1  - Assessment of Energy Efficiency for the Existing Cargo Ships
EP  - 46
IS  - 1
SP  - 33
VL  - 23
DO  - https://doi.org/10.56080/jms220502
ER  - 

@article{
author = "Kalajdžić, Milan and Vasilev, Matija and Momčilović, Nikola",
year = "2022",
abstract = "In order to address the decarbonization policy, International Maritime Organization (IMO) has been dealing with energy efficiency of ships for more than a decade. Firstly, procedures for energy efficiency assessment are introduced through the regulative, but only for new ships. Consequently, IMO also introduced energy efficiency criterion for already built ships that is set to be applicable starting from 2023. Regulative is already having an impact on ship design. While the new ships can be adapted in design phase, built ones will not have so many options. So far, almost all the solutions include reduction of the speed, i.e., slow steaming. Nevertheless, there are numerous technical and operational measures. The paper presents the calculation of energy efficiency performed for the fleet of existing 11 cargo ships categorized into four different ship classes. Calculation is based on the current IMO regulations covering the evaluation of energy efficiency of existing ships index (EEXI). Input parameters for analysis are obtained using two approaches:
technical files (design parameters of the ship) & sea-trial reports and statistical method (when technical files & sea-trail reports are not available). Authors examined if the difference in two input approaches and potential class notation change could lead to different energy efficiency evaluation results. Moreover, the main goal of the research was to investigate on how the present conventionally designed cargo ships compare to the novel regulations.",
publisher = "Faculty of Maritime Studies in Kotor, University of Montenegro",
journal = "Journal of Maritime Sciences",
title = "Assessment of Energy Efficiency for the Existing Cargo Ships",
pages = "46-33",
number = "1",
volume = "23",
doi = "https://doi.org/10.56080/jms220502"
}

Kalajdžić, M., Vasilev, M.,& Momčilović, N.. (2022). Assessment of Energy Efficiency for the Existing Cargo Ships. in Journal of Maritime Sciences
Faculty of Maritime Studies in Kotor, University of Montenegro., 23(1), 33-46.
https://doi.org/https://doi.org/10.56080/jms220502

Kalajdžić M, Vasilev M, Momčilović N. Assessment of Energy Efficiency for the Existing Cargo Ships. in Journal of Maritime Sciences. 2022;23(1):33-46.
doi:https://doi.org/10.56080/jms220502 .

Kalajdžić, Milan, Vasilev, Matija, Momčilović, Nikola, "Assessment of Energy Efficiency for the Existing Cargo Ships" in Journal of Maritime Sciences, 23, no. 1 (2022):33-46,
https://doi.org/https://doi.org/10.56080/jms220502 . .

TY  - JOUR
AU  - Kalajdžić, Milan
AU  - Vasilev, Matija
AU  - Momčilović, Nikola
PY  - 2022
UR  - https://machinery.mas.bg.ac.rs/handle/123456789/3726
AB  - Although the International Maritime Organization (IMO) introduced the energy efficiency requirements for ships more than a decade ago, to date, inland navigation has not been affected by corresponding regulations at all. Therefore, inland waterway vessels are left with no mandatory requirements that could push their technology into more energy efficient design. Fortunately, there are certain pioneering attempts to define energy efficiency criteria for inland vessels. This paper tries to gather and provide a review of such methods. Moreover, a typical Danube cargo inland vessel's data are used to evaluate their current energy efficiency levels with respect to provisional criteria. Consequently, two methods are found and used here. They are both based on IMO's energy efficiency concept but modified for the inland waterway vessels. The methods delivered a significant difference in applicability and were difficult to compare. Moreover, shallow and deep-water effects are explored in the same regard but provided unsound conclusions. The final results displayed discrepancies in energy efficiency levels for the same vessels and so the methodology should be improved and harmonised, if it is to be introduced as mandatory for inland waterway vessels. The analysis provided a glimpse into the current condition of the traditional design of the Danube inland fleet, with respect to the emerging energy efficiency policies.
PB  - Sciendo, Warsaw
T2  - Polish Maritime Research
T1  - Evaluating an Inland Waterway Cargo Vessel's Energy Efficiency Indices
EP  - 34
IS  - 2
SP  - 27
VL  - 29
DO  - 10.2478/pomr-2022-0014
ER  - 

@article{
author = "Kalajdžić, Milan and Vasilev, Matija and Momčilović, Nikola",
year = "2022",
abstract = "Although the International Maritime Organization (IMO) introduced the energy efficiency requirements for ships more than a decade ago, to date, inland navigation has not been affected by corresponding regulations at all. Therefore, inland waterway vessels are left with no mandatory requirements that could push their technology into more energy efficient design. Fortunately, there are certain pioneering attempts to define energy efficiency criteria for inland vessels. This paper tries to gather and provide a review of such methods. Moreover, a typical Danube cargo inland vessel's data are used to evaluate their current energy efficiency levels with respect to provisional criteria. Consequently, two methods are found and used here. They are both based on IMO's energy efficiency concept but modified for the inland waterway vessels. The methods delivered a significant difference in applicability and were difficult to compare. Moreover, shallow and deep-water effects are explored in the same regard but provided unsound conclusions. The final results displayed discrepancies in energy efficiency levels for the same vessels and so the methodology should be improved and harmonised, if it is to be introduced as mandatory for inland waterway vessels. The analysis provided a glimpse into the current condition of the traditional design of the Danube inland fleet, with respect to the emerging energy efficiency policies.",
publisher = "Sciendo, Warsaw",
journal = "Polish Maritime Research",
title = "Evaluating an Inland Waterway Cargo Vessel's Energy Efficiency Indices",
pages = "34-27",
number = "2",
volume = "29",
doi = "10.2478/pomr-2022-0014"
}

Kalajdžić, M., Vasilev, M.,& Momčilović, N.. (2022). Evaluating an Inland Waterway Cargo Vessel's Energy Efficiency Indices. in Polish Maritime Research
Sciendo, Warsaw., 29(2), 27-34.
https://doi.org/10.2478/pomr-2022-0014

Kalajdžić M, Vasilev M, Momčilović N. Evaluating an Inland Waterway Cargo Vessel's Energy Efficiency Indices. in Polish Maritime Research. 2022;29(2):27-34.
doi:10.2478/pomr-2022-0014 .

Kalajdžić, Milan, Vasilev, Matija, Momčilović, Nikola, "Evaluating an Inland Waterway Cargo Vessel's Energy Efficiency Indices" in Polish Maritime Research, 29, no. 2 (2022):27-34,
https://doi.org/10.2478/pomr-2022-0014 . .

TY  - CONF
AU  - Kalajdžić, Milan
AU  - Vasilev, Matija
AU  - Momčilović, Nikola
PY  - 2021
UR  - https://machinery.mas.bg.ac.rs/handle/123456789/6729
AB  - Energy efficiency policy has been evolving in the shipping industry over the past decade since the decarbonization has become the main goal. After the energy efficiency design index (EEDI) is 
introduced in 2011 by International Maritime Organization (IMO) to propel the emission reduction for new ships, the same has been pursued in case of existing ships by presenting the energy efficiency of existing ship index (EEXI), that will enter into force on 1st of January 2023. Thus, existing ships are already being adapted in that regard, through the speed and power reduction, finer design hull optimization and application of energy saving devices (ESD). Therefore, this paper
presents the EEXI calculation for four specific ship types: general cargo ship, container ship, bulk carrier and oil tanker. EEXI calculation is performed in two ways here. In the first case, input parameters are obtained from available sea trials data and technical files already used for EEDI calculation; and in other case, all input parameters are acquired solely according to the latest IMO regulations and guidelines. The difference of using these two input approaches and their effect on EEXI are outlined. Further adaptation measures are described in case of these four ship representatives. Moreover, since some of the ships can be potentially classified for more than one purpose, also a short discussion is given considering such effect on EEXI performance.
PB  - Faculty of Maritime Studies in Kotor, University of Montenegro
C3  - Book of Abstracts - 1st Kotor  International Maritime Conference (KIMC 2021), Kotor, Montenegro, 2021.
T1  - Exploring an Effect of  Novel IMO Policies on Energy Efficiency of Existing Ships
UR  - https://hdl.handle.net/21.15107/rcub_machinery_6729
ER  - 

@conference{
author = "Kalajdžić, Milan and Vasilev, Matija and Momčilović, Nikola",
year = "2021",
abstract = "Energy efficiency policy has been evolving in the shipping industry over the past decade since the decarbonization has become the main goal. After the energy efficiency design index (EEDI) is 
introduced in 2011 by International Maritime Organization (IMO) to propel the emission reduction for new ships, the same has been pursued in case of existing ships by presenting the energy efficiency of existing ship index (EEXI), that will enter into force on 1st of January 2023. Thus, existing ships are already being adapted in that regard, through the speed and power reduction, finer design hull optimization and application of energy saving devices (ESD). Therefore, this paper
presents the EEXI calculation for four specific ship types: general cargo ship, container ship, bulk carrier and oil tanker. EEXI calculation is performed in two ways here. In the first case, input parameters are obtained from available sea trials data and technical files already used for EEDI calculation; and in other case, all input parameters are acquired solely according to the latest IMO regulations and guidelines. The difference of using these two input approaches and their effect on EEXI are outlined. Further adaptation measures are described in case of these four ship representatives. Moreover, since some of the ships can be potentially classified for more than one purpose, also a short discussion is given considering such effect on EEXI performance.",
publisher = "Faculty of Maritime Studies in Kotor, University of Montenegro",
journal = "Book of Abstracts - 1st Kotor  International Maritime Conference (KIMC 2021), Kotor, Montenegro, 2021.",
title = "Exploring an Effect of  Novel IMO Policies on Energy Efficiency of Existing Ships",
url = "https://hdl.handle.net/21.15107/rcub_machinery_6729"
}

Kalajdžić, M., Vasilev, M.,& Momčilović, N.. (2021). Exploring an Effect of  Novel IMO Policies on Energy Efficiency of Existing Ships. in Book of Abstracts - 1st Kotor  International Maritime Conference (KIMC 2021), Kotor, Montenegro, 2021.
Faculty of Maritime Studies in Kotor, University of Montenegro..
https://hdl.handle.net/21.15107/rcub_machinery_6729

Kalajdžić M, Vasilev M, Momčilović N. Exploring an Effect of  Novel IMO Policies on Energy Efficiency of Existing Ships. in Book of Abstracts - 1st Kotor  International Maritime Conference (KIMC 2021), Kotor, Montenegro, 2021.. 2021;.
https://hdl.handle.net/21.15107/rcub_machinery_6729 .

Kalajdžić, Milan, Vasilev, Matija, Momčilović, Nikola, "Exploring an Effect of  Novel IMO Policies on Energy Efficiency of Existing Ships" in Book of Abstracts - 1st Kotor  International Maritime Conference (KIMC 2021), Kotor, Montenegro, 2021. (2021),
https://hdl.handle.net/21.15107/rcub_machinery_6729 .