TY  - JOUR
AU  - Momčilović, Nikola
AU  - Ilić, Nemanja
AU  - Kalajdžić, Milan
AU  - Ivošević, Špiro
AU  - Petrović, Ana
PY  - 2024
UR  - https://machinery.mas.bg.ac.rs/handle/123456789/7797
AB  - Standard structural assessments of ship hulls include the evaluation of the elastic structural response. Elastic analysis neglects extreme and unpredicted loadings, which can produce catastrophic outcomes, such as the loss of the ship’s ultimate strength. Moreover, hull elements are considered unaffected by age-related degradation. Therefore, this study models and quantifies the effect of corrosion-induced structural degradation on the ultimate strength of a high-tensile-steel (HTS) cargo ship using progressive collapse and nonlinear finite element methods. Uniform and pitting corrosion are modeled through selected scenarios, which hull elements might encounter during exploitation, producing a total of 148 calculation models. The findings show that corrosion-induced degradation can significantly decrease the ultimate strength of the hull (up to 30% for the most severe scenarios assessed). Furthermore, ultimate strength decreases almost proportionally to the amount of wastage considered. It was found that stiffener corrosion has a significant effect on the total ultimate strength. This study’s aim is to emphasize the vast importance of including ultimate strength along with ageing effects in industry-standard structural assessments of large HTS ship structures, designed to last for several decades whilst exposed to excessive and unpredicted bending moments.
PB  - MDPI
T2  - Journal of Marine Science and Engineering
T1  - Effect of Corrosion-Induced Structural Degradation on the Ultimate Strength of a High-Tensile-Steel Ship Hull
IS  - 5
SP  - 745
VL  - 12
DO  - 10.3390/jmse12050745
ER  - 

@article{
author = "Momčilović, Nikola and Ilić, Nemanja and Kalajdžić, Milan and Ivošević, Špiro and Petrović, Ana",
year = "2024",
abstract = "Standard structural assessments of ship hulls include the evaluation of the elastic structural response. Elastic analysis neglects extreme and unpredicted loadings, which can produce catastrophic outcomes, such as the loss of the ship’s ultimate strength. Moreover, hull elements are considered unaffected by age-related degradation. Therefore, this study models and quantifies the effect of corrosion-induced structural degradation on the ultimate strength of a high-tensile-steel (HTS) cargo ship using progressive collapse and nonlinear finite element methods. Uniform and pitting corrosion are modeled through selected scenarios, which hull elements might encounter during exploitation, producing a total of 148 calculation models. The findings show that corrosion-induced degradation can significantly decrease the ultimate strength of the hull (up to 30% for the most severe scenarios assessed). Furthermore, ultimate strength decreases almost proportionally to the amount of wastage considered. It was found that stiffener corrosion has a significant effect on the total ultimate strength. This study’s aim is to emphasize the vast importance of including ultimate strength along with ageing effects in industry-standard structural assessments of large HTS ship structures, designed to last for several decades whilst exposed to excessive and unpredicted bending moments.",
publisher = "MDPI",
journal = "Journal of Marine Science and Engineering",
title = "Effect of Corrosion-Induced Structural Degradation on the Ultimate Strength of a High-Tensile-Steel Ship Hull",
number = "5",
pages = "745",
volume = "12",
doi = "10.3390/jmse12050745"
}

Momčilović, N., Ilić, N., Kalajdžić, M., Ivošević, Š.,& Petrović, A.. (2024). Effect of Corrosion-Induced Structural Degradation on the Ultimate Strength of a High-Tensile-Steel Ship Hull. in Journal of Marine Science and Engineering
MDPI., 12(5), 745.
https://doi.org/10.3390/jmse12050745

Momčilović N, Ilić N, Kalajdžić M, Ivošević Š, Petrović A. Effect of Corrosion-Induced Structural Degradation on the Ultimate Strength of a High-Tensile-Steel Ship Hull. in Journal of Marine Science and Engineering. 2024;12(5):745.
doi:10.3390/jmse12050745 .

Momčilović, Nikola, Ilić, Nemanja, Kalajdžić, Milan, Ivošević, Špiro, Petrović, Ana, "Effect of Corrosion-Induced Structural Degradation on the Ultimate Strength of a High-Tensile-Steel Ship Hull" in Journal of Marine Science and Engineering, 12, no. 5 (2024):745,
https://doi.org/10.3390/jmse12050745 . .

TY  - CONF
AU  - Ilić, Nemanja
AU  - Momčilović, Nikola
PY  - 2023
UR  - https://www.sciencedirect.com/science/article/pii/S2452321623005449
UR  - https://machinery.mas.bg.ac.rs/handle/123456789/7289
AB  - Global structural response of ship hulls is generally assessed using elastic limit criterion defined by technical standards. However, scenarios in which the ship is experiencing extreme and once in lifetime loads are investigated in recent years. Such studies analyse events with potentially catastrophic outcomes, i.e., loss of the complete ship and environmental disaster. Excessive bending moments can be experienced by the hull girder due to ship's failed escape from dangerous storms, grounding, collisions, allisions, unpredicted loads, etc. Therefore, ultimate strength or hull capacity to withstand extreme loadings is emerging as one of the most significant requirements for ship hull girder strength evaluation. Technical standards for large sea-going bulk carriers and oil tankers already have ultimate strength assessment incorporated within their regulations. Ultimate strength of other cargo ships is also addressed in the rules of the classification societies. However, there are no corresponding legislative procedures for inland waterway vessels (IWV) at all. Moreover, according to authors’ knowledge, no complete studies on ultimate strength of IWV are presented in the literature so far. Therefore, the aim of this paper is to transfer the practice of ultimate strength calculations from sea-going ships to IWV and to provide the benchmark calculation. Ultimate strength is calculated here using progressive collapse analysis (PCA) on a case study of typical inland waterway self-propelled tanker vessel operating on one of the most important waterway transport corridors in the EU (Danube and Rhine). Results showed that assessment procedure used in maritime practice can be applicable to IWV. PCA method displayed the collapse sequences of the cross section, mostly governed by the buckling of segments along the vertical axis. Results based on examined vessel showed that such ultimate bending moment differs 3-20% to one calculated according to the more traditional Paik – Mansour method.
PB  - Elsevier
C3  - Structural Integrity Procedia
T1  - Progressive collapse analysis of inland waterway cargo vessel
VL  - 48
DO  - 10.1016/j.prostr.2023.07.126
ER  - 

@conference{
author = "Ilić, Nemanja and Momčilović, Nikola",
year = "2023",
abstract = "Global structural response of ship hulls is generally assessed using elastic limit criterion defined by technical standards. However, scenarios in which the ship is experiencing extreme and once in lifetime loads are investigated in recent years. Such studies analyse events with potentially catastrophic outcomes, i.e., loss of the complete ship and environmental disaster. Excessive bending moments can be experienced by the hull girder due to ship's failed escape from dangerous storms, grounding, collisions, allisions, unpredicted loads, etc. Therefore, ultimate strength or hull capacity to withstand extreme loadings is emerging as one of the most significant requirements for ship hull girder strength evaluation. Technical standards for large sea-going bulk carriers and oil tankers already have ultimate strength assessment incorporated within their regulations. Ultimate strength of other cargo ships is also addressed in the rules of the classification societies. However, there are no corresponding legislative procedures for inland waterway vessels (IWV) at all. Moreover, according to authors’ knowledge, no complete studies on ultimate strength of IWV are presented in the literature so far. Therefore, the aim of this paper is to transfer the practice of ultimate strength calculations from sea-going ships to IWV and to provide the benchmark calculation. Ultimate strength is calculated here using progressive collapse analysis (PCA) on a case study of typical inland waterway self-propelled tanker vessel operating on one of the most important waterway transport corridors in the EU (Danube and Rhine). Results showed that assessment procedure used in maritime practice can be applicable to IWV. PCA method displayed the collapse sequences of the cross section, mostly governed by the buckling of segments along the vertical axis. Results based on examined vessel showed that such ultimate bending moment differs 3-20% to one calculated according to the more traditional Paik – Mansour method.",
publisher = "Elsevier",
journal = "Structural Integrity Procedia",
title = "Progressive collapse analysis of inland waterway cargo vessel",
volume = "48",
doi = "10.1016/j.prostr.2023.07.126"
}

Ilić, N.,& Momčilović, N.. (2023). Progressive collapse analysis of inland waterway cargo vessel. in Structural Integrity Procedia
Elsevier., 48.
https://doi.org/10.1016/j.prostr.2023.07.126

Ilić N, Momčilović N. Progressive collapse analysis of inland waterway cargo vessel. in Structural Integrity Procedia. 2023;48.
doi:10.1016/j.prostr.2023.07.126 .

Ilić, Nemanja, Momčilović, Nikola, "Progressive collapse analysis of inland waterway cargo vessel" in Structural Integrity Procedia, 48 (2023),
https://doi.org/10.1016/j.prostr.2023.07.126 . .

TY  - CONF
AU  - Momčilović, Nikola
AU  - Ilić, Nemanja
AU  - Kalajdžić, Milan
AU  - Ivošević, Špiro
AU  - Petrović, Ana
PY  - 2023
UR  - https://www.sciencedirect.com/science/article/pii/S245232162300522X
UR  - https://machinery.mas.bg.ac.rs/handle/123456789/7291
AB  - In general, ship structural integrity assessments consist of prescribed procedures given by the rules of classification societies, and if necessary, direct calculations. Direct calculations mostly include longitudinal strength analyses and buckling calculations for various service loadings and structural members. Resulting stress is compared to the allowable stress, which is also rule-prescribed and acts as a share of the yield stress of the material. This means that the structure is evaluated upon its elastic response. Moreover, ship structural assessments consider as-built scantlings, not diminished by ageing. Generally, extreme or once-in-a-lifetime loadings are neglected. They can include overloading scenarios that lead to the ship structural collapse or the loss of the ship’s carrying capacity, i.e., ultimate strength. Ultimate strength of the ship is represented by the maximum (ultimate) bending moment the structure can withstand. Its evaluation is important to determine the ship’s structural safety level with respect to its collapse. Therefore, this paper delivers the ultimate strength assessment for a typical bulk carrier having 180 m in length. For this purpose, an incremental-iterative progressivecollapse analysis (PCA) is used. In the first stage, ultimate strength of a bulk carrier is determined using as-built scantlings. In the next, ageing effects are considered within PCA by modeling scenarios that include both pitting and uniform corrosion. Pitting corrosion is defined by pitting intensity degree (DOP) and corrosion intensity degree (DOC), whilst the uniform corrosion is defined by thickness reduction. Results show that corrosion effects can significantly diminish the ultimate strength of the ship. This means that, in the design phase, structural assessments cannot be based just on as-built scantlings, but also might include ageing effects, as ships are designed to be reliable on the long-term.
C3  - Procedia Structural Integrity
T1  - Pitting and uniform corrosion effects on ultimate strength of a  bulk carrier
EP  - 18
SP  - 12
VL  - 48
DO  - 10.1016/j.prostr.2023.07.104
ER  - 

@conference{
author = "Momčilović, Nikola and Ilić, Nemanja and Kalajdžić, Milan and Ivošević, Špiro and Petrović, Ana",
year = "2023",
abstract = "In general, ship structural integrity assessments consist of prescribed procedures given by the rules of classification societies, and if necessary, direct calculations. Direct calculations mostly include longitudinal strength analyses and buckling calculations for various service loadings and structural members. Resulting stress is compared to the allowable stress, which is also rule-prescribed and acts as a share of the yield stress of the material. This means that the structure is evaluated upon its elastic response. Moreover, ship structural assessments consider as-built scantlings, not diminished by ageing. Generally, extreme or once-in-a-lifetime loadings are neglected. They can include overloading scenarios that lead to the ship structural collapse or the loss of the ship’s carrying capacity, i.e., ultimate strength. Ultimate strength of the ship is represented by the maximum (ultimate) bending moment the structure can withstand. Its evaluation is important to determine the ship’s structural safety level with respect to its collapse. Therefore, this paper delivers the ultimate strength assessment for a typical bulk carrier having 180 m in length. For this purpose, an incremental-iterative progressivecollapse analysis (PCA) is used. In the first stage, ultimate strength of a bulk carrier is determined using as-built scantlings. In the next, ageing effects are considered within PCA by modeling scenarios that include both pitting and uniform corrosion. Pitting corrosion is defined by pitting intensity degree (DOP) and corrosion intensity degree (DOC), whilst the uniform corrosion is defined by thickness reduction. Results show that corrosion effects can significantly diminish the ultimate strength of the ship. This means that, in the design phase, structural assessments cannot be based just on as-built scantlings, but also might include ageing effects, as ships are designed to be reliable on the long-term.",
journal = "Procedia Structural Integrity",
title = "Pitting and uniform corrosion effects on ultimate strength of a  bulk carrier",
pages = "18-12",
volume = "48",
doi = "10.1016/j.prostr.2023.07.104"
}

Momčilović, N., Ilić, N., Kalajdžić, M., Ivošević, Š.,& Petrović, A.. (2023). Pitting and uniform corrosion effects on ultimate strength of a  bulk carrier. in Procedia Structural Integrity, 48, 12-18.
https://doi.org/10.1016/j.prostr.2023.07.104

Momčilović N, Ilić N, Kalajdžić M, Ivošević Š, Petrović A. Pitting and uniform corrosion effects on ultimate strength of a  bulk carrier. in Procedia Structural Integrity. 2023;48:12-18.
doi:10.1016/j.prostr.2023.07.104 .

Momčilović, Nikola, Ilić, Nemanja, Kalajdžić, Milan, Ivošević, Špiro, Petrović, Ana, "Pitting and uniform corrosion effects on ultimate strength of a  bulk carrier" in Procedia Structural Integrity, 48 (2023):12-18,
https://doi.org/10.1016/j.prostr.2023.07.104 . .

TY  - CONF
AU  - Momcilovic, Nikola
AU  - Kalajdžić, Milan
AU  - Ilić, Nemanja
PY  - 2023
UR  - https://www.kimc.ucg.ac.me/
UR  - https://machinery.mas.bg.ac.rs/handle/123456789/7625
AB  - Ship structural assessments generally consider service loadings anticipated in design phase. Bending moments corresponding to these conditions are then evaluated based on yielding and buckling criteria derived from the allowable stress threshold and linear-elastic behavior of the material. Still, ships might experience extreme and once-in-a-lifetime events such as overloading, extreme bow waves, or grounding. When tied with ageing process resulting from corrosion, these events can accelerate structural deterioration, leading to the catastrophic hull failures, such as “brake-in-two” or loss of the ship. Unfortunately, numerous hull collapses have been recorded in recent years. The collapse of the hull girders (i.e., ultimate strength) of large deep-sea ships is primarily determined by the maximum or ultimate bending moment the hull can withstand. These are highly non-linear problems in terms material behavior and geometry. Therefore, the industry and classification societies have recognized an issue and currently are in the process of developing sophisticated ultimate strength assessment procedures in their technical standards. Most notable ones are delivered for bulk carriers and oil tankers in Common Structural Rules (IACS CSR). The work presented here is a simulation of the ultimate strength performed on a case study of an intact and corrosion-induced ageing bulk carrier, by using two numerical methods: progressive-collapse analysis defined by IACS and nonlinear finite element method. The nature of the hull girder collapse is presented along with the extent of corrosion impact of the reduction of ultimate strength.
PB  - University of Montenegro Faculty of Maritime Studies Kotor
C3  - Book of Abstracts 3rd Kotor International Maritime Conference November 26-29, 2023, Kotor, Montenegro
T1  - Simulating an ultimate bending moment of ageing hulls: a bulk carrier case study
UR  - https://hdl.handle.net/21.15107/rcub_machinery_7625
ER  - 

@conference{
author = "Momcilovic, Nikola and Kalajdžić, Milan and Ilić, Nemanja",
year = "2023",
abstract = "Ship structural assessments generally consider service loadings anticipated in design phase. Bending moments corresponding to these conditions are then evaluated based on yielding and buckling criteria derived from the allowable stress threshold and linear-elastic behavior of the material. Still, ships might experience extreme and once-in-a-lifetime events such as overloading, extreme bow waves, or grounding. When tied with ageing process resulting from corrosion, these events can accelerate structural deterioration, leading to the catastrophic hull failures, such as “brake-in-two” or loss of the ship. Unfortunately, numerous hull collapses have been recorded in recent years. The collapse of the hull girders (i.e., ultimate strength) of large deep-sea ships is primarily determined by the maximum or ultimate bending moment the hull can withstand. These are highly non-linear problems in terms material behavior and geometry. Therefore, the industry and classification societies have recognized an issue and currently are in the process of developing sophisticated ultimate strength assessment procedures in their technical standards. Most notable ones are delivered for bulk carriers and oil tankers in Common Structural Rules (IACS CSR). The work presented here is a simulation of the ultimate strength performed on a case study of an intact and corrosion-induced ageing bulk carrier, by using two numerical methods: progressive-collapse analysis defined by IACS and nonlinear finite element method. The nature of the hull girder collapse is presented along with the extent of corrosion impact of the reduction of ultimate strength.",
publisher = "University of Montenegro Faculty of Maritime Studies Kotor",
journal = "Book of Abstracts 3rd Kotor International Maritime Conference November 26-29, 2023, Kotor, Montenegro",
title = "Simulating an ultimate bending moment of ageing hulls: a bulk carrier case study",
url = "https://hdl.handle.net/21.15107/rcub_machinery_7625"
}

Momcilovic, N., Kalajdžić, M.,& Ilić, N.. (2023). Simulating an ultimate bending moment of ageing hulls: a bulk carrier case study. in Book of Abstracts 3rd Kotor International Maritime Conference November 26-29, 2023, Kotor, Montenegro
University of Montenegro Faculty of Maritime Studies Kotor..
https://hdl.handle.net/21.15107/rcub_machinery_7625

Momcilovic N, Kalajdžić M, Ilić N. Simulating an ultimate bending moment of ageing hulls: a bulk carrier case study. in Book of Abstracts 3rd Kotor International Maritime Conference November 26-29, 2023, Kotor, Montenegro. 2023;.
https://hdl.handle.net/21.15107/rcub_machinery_7625 .

Momcilovic, Nikola, Kalajdžić, Milan, Ilić, Nemanja, "Simulating an ultimate bending moment of ageing hulls: a bulk carrier case study" in Book of Abstracts 3rd Kotor International Maritime Conference November 26-29, 2023, Kotor, Montenegro (2023),
https://hdl.handle.net/21.15107/rcub_machinery_7625 .

TY  - CONF
AU  - Ilić, Nemanja
AU  - Momčilović, Nikola
PY  - 2023
UR  - https://machinery.mas.bg.ac.rs/handle/123456789/7624
AB  - In service, ships are likely to be subjected to various types of loads which are foreseen in the
design phase. In addition, ships can experience rare events and consequently, extreme or oncein-
a-lifetime loads (Paik, 2018). The cause of these loads can be attributed to failed attempts
to evade storms, ship overloading, incidents of grounding and collisions. Such scenarios might
produce a hull girder bending moment reaching the hull’s collapse, i.e., hull girder ultimate
capacity (UC). Thus, the main idea behind the ultimate strength assessments of ships is to
predict the structural capacity of the hull girder until its collapse. Rules and regulations for
sea-going ships have acknowledged the issue (IACS, 2022).
Nevertheless, for inland vessels (or even river-sea ships), no fully developed technical
standards and studies involving state-of-the-art methods for UC assessments exist in practice.
Moreover, studies using sophisticated progressive collapse analysis (PCA) are rare, see one
in (Ilić & Momčilović, 2023). Compared to sea-going ships, inland vessels have a larger length
to height ratio and low hull modulus, and thus, they are prone to longitudinal strength issues.
Coupled with the prolonged service life of inland vessels, UC can be vastly affected. This can
significantly reduce UC and decrease the margin between the elastic and the ultimate strength
response.
Therefore, in order to benchmark the phenomena, the effects of corrosion-induced degradation
on UC of a typical inland waterway vessel are explored by using incremental-iterative
progressive collapse analysis (PCA), a procedure thoroughly defined in (IACS, 2022). The
selected inland vessel is a typical Danube mild steel made barge with the following
dimensions: Loa = 72.9 m, B = 11.40 m, H = 3.7 m, T = 3.55 m. The cross-section of the
vessel is divided into segments according to (IACS, 2022), see Figure 1. The vessel is already
assessed for UC (Ilić & Momčilović, 2023), but just for intact condition.
Firstly, UC is determined using as-built scantlings (new ship). Secondly, ageing effects are
considered by modelling scenarios which include both pitting and uniform corrosion (ageing
ship). Pitting corrosion is defined by pitting intensity degree (DOP) and corrosion intensity
degree (DOC) which define the actual total loss of the volume of the element (ΔV), using the
approach given by (Piscopo & Scamardella, 2021). On the other hand, uniform corrosion is
defined by corrosion wastage (thickness reduction). Namely, uniform corrosion is considered
by 10% of corrosion wastage applied to all structural elements, which is a corrosion level
often found in such structures. In addition, pitting corrosion incidence is presumed in several
locations (segments: 4*, 7*, 8*, and 9*.) and throughout three cases in which ΔV has occurred
(Figure 1): 4%, 10%, and 20%. Pit affected segments were chosen due to their service life. Although corrosion models were not severe, the vessel’s UC is significantly reduced (up to
20%) when various real-service degradation scenarios were considered. Thus, the corrosion
effect significantly influences the UC of the vessel and should not be neglected in the design
phase for the estimations of the strength of ageing ships.
PB  - ZONGULDAK BÜLENT ECEVİT UNIVERSITY MARITIME FACULTY
C3  - I. INTERNATIONAL MARITIME AND LOGISTICS CONGRESS (DELOK’23) 22-23 SEPTEMBER
T1  - Hull Girder’s Ultimate Capacity of the Inland Vessel Under Corrosion Effect
VL  - 1
UR  - https://hdl.handle.net/21.15107/rcub_machinery_7624
ER  - 

@conference{
author = "Ilić, Nemanja and Momčilović, Nikola",
year = "2023",
abstract = "In service, ships are likely to be subjected to various types of loads which are foreseen in the
design phase. In addition, ships can experience rare events and consequently, extreme or oncein-
a-lifetime loads (Paik, 2018). The cause of these loads can be attributed to failed attempts
to evade storms, ship overloading, incidents of grounding and collisions. Such scenarios might
produce a hull girder bending moment reaching the hull’s collapse, i.e., hull girder ultimate
capacity (UC). Thus, the main idea behind the ultimate strength assessments of ships is to
predict the structural capacity of the hull girder until its collapse. Rules and regulations for
sea-going ships have acknowledged the issue (IACS, 2022).
Nevertheless, for inland vessels (or even river-sea ships), no fully developed technical
standards and studies involving state-of-the-art methods for UC assessments exist in practice.
Moreover, studies using sophisticated progressive collapse analysis (PCA) are rare, see one
in (Ilić & Momčilović, 2023). Compared to sea-going ships, inland vessels have a larger length
to height ratio and low hull modulus, and thus, they are prone to longitudinal strength issues.
Coupled with the prolonged service life of inland vessels, UC can be vastly affected. This can
significantly reduce UC and decrease the margin between the elastic and the ultimate strength
response.
Therefore, in order to benchmark the phenomena, the effects of corrosion-induced degradation
on UC of a typical inland waterway vessel are explored by using incremental-iterative
progressive collapse analysis (PCA), a procedure thoroughly defined in (IACS, 2022). The
selected inland vessel is a typical Danube mild steel made barge with the following
dimensions: Loa = 72.9 m, B = 11.40 m, H = 3.7 m, T = 3.55 m. The cross-section of the
vessel is divided into segments according to (IACS, 2022), see Figure 1. The vessel is already
assessed for UC (Ilić & Momčilović, 2023), but just for intact condition.
Firstly, UC is determined using as-built scantlings (new ship). Secondly, ageing effects are
considered by modelling scenarios which include both pitting and uniform corrosion (ageing
ship). Pitting corrosion is defined by pitting intensity degree (DOP) and corrosion intensity
degree (DOC) which define the actual total loss of the volume of the element (ΔV), using the
approach given by (Piscopo & Scamardella, 2021). On the other hand, uniform corrosion is
defined by corrosion wastage (thickness reduction). Namely, uniform corrosion is considered
by 10% of corrosion wastage applied to all structural elements, which is a corrosion level
often found in such structures. In addition, pitting corrosion incidence is presumed in several
locations (segments: 4*, 7*, 8*, and 9*.) and throughout three cases in which ΔV has occurred
(Figure 1): 4%, 10%, and 20%. Pit affected segments were chosen due to their service life. Although corrosion models were not severe, the vessel’s UC is significantly reduced (up to
20%) when various real-service degradation scenarios were considered. Thus, the corrosion
effect significantly influences the UC of the vessel and should not be neglected in the design
phase for the estimations of the strength of ageing ships.",
publisher = "ZONGULDAK BÜLENT ECEVİT UNIVERSITY MARITIME FACULTY",
journal = "I. INTERNATIONAL MARITIME AND LOGISTICS CONGRESS (DELOK’23) 22-23 SEPTEMBER",
title = "Hull Girder’s Ultimate Capacity of the Inland Vessel Under Corrosion Effect",
volume = "1",
url = "https://hdl.handle.net/21.15107/rcub_machinery_7624"
}

Ilić, N.,& Momčilović, N.. (2023). Hull Girder’s Ultimate Capacity of the Inland Vessel Under Corrosion Effect. in I. INTERNATIONAL MARITIME AND LOGISTICS CONGRESS (DELOK’23) 22-23 SEPTEMBER
ZONGULDAK BÜLENT ECEVİT UNIVERSITY MARITIME FACULTY., 1.
https://hdl.handle.net/21.15107/rcub_machinery_7624

Ilić N, Momčilović N. Hull Girder’s Ultimate Capacity of the Inland Vessel Under Corrosion Effect. in I. INTERNATIONAL MARITIME AND LOGISTICS CONGRESS (DELOK’23) 22-23 SEPTEMBER. 2023;1.
https://hdl.handle.net/21.15107/rcub_machinery_7624 .

Ilić, Nemanja, Momčilović, Nikola, "Hull Girder’s Ultimate Capacity of the Inland Vessel Under Corrosion Effect" in I. INTERNATIONAL MARITIME AND LOGISTICS CONGRESS (DELOK’23) 22-23 SEPTEMBER, 1 (2023),
https://hdl.handle.net/21.15107/rcub_machinery_7624 .

TY  - JOUR
AU  - Ilić, Nemanja
AU  - Momčilović, Nikola
PY  - 2023
UR  - https://www.mas.bg.ac.rs/_media/istrazivanje/fme/vol51/1/10_n._momcilovic_et_al.pdf
UR  - https://machinery.mas.bg.ac.rs/handle/123456789/6775
AB  - Due to the sudden nature of hull girder collapse caused by extreme
loadings, the ultimate strength of ships, i.e., ultimate capacity, has to be
evaluated. Ultimate strength analysis procedures have already been
provided within the rules of the classification societies for sea-going ships.
However, rules for inland vessels are not fully addressing the issue. In
addition, literature data on the ultimate strength of inland vessels are
almost negligible, which is alarming, considering the frequency of
grounding and overloading events in inland navigation. Moreover, inland
vessels' structural elements are prone to buckling due to their slender
plates. In order to evaluate ultimate strength, an inland waterway (IW)
barge is chosen for progressive collapse analysis (PCA) employment. PCA
has demonstrated that the buckling collapse of structural elements vastly
governs a vessel's ultimate capacity. Results show the extent of the safety
zone between the actual loss of the ultimate capacity and the linear-elastic
behavior of the structure.
PB  - University of Belgrade - Faculty of Mechanical Engineering
T2  - FME Transactions
T1  - On ultimate strength of an inland waterway barge
EP  - 98
IS  - 1
SP  - 90
VL  - 51
DO  - doi: 10.5937/fme2301090I
ER  - 

@article{
author = "Ilić, Nemanja and Momčilović, Nikola",
year = "2023",
abstract = "Due to the sudden nature of hull girder collapse caused by extreme
loadings, the ultimate strength of ships, i.e., ultimate capacity, has to be
evaluated. Ultimate strength analysis procedures have already been
provided within the rules of the classification societies for sea-going ships.
However, rules for inland vessels are not fully addressing the issue. In
addition, literature data on the ultimate strength of inland vessels are
almost negligible, which is alarming, considering the frequency of
grounding and overloading events in inland navigation. Moreover, inland
vessels' structural elements are prone to buckling due to their slender
plates. In order to evaluate ultimate strength, an inland waterway (IW)
barge is chosen for progressive collapse analysis (PCA) employment. PCA
has demonstrated that the buckling collapse of structural elements vastly
governs a vessel's ultimate capacity. Results show the extent of the safety
zone between the actual loss of the ultimate capacity and the linear-elastic
behavior of the structure.",
publisher = "University of Belgrade - Faculty of Mechanical Engineering",
journal = "FME Transactions",
title = "On ultimate strength of an inland waterway barge",
pages = "98-90",
number = "1",
volume = "51",
doi = "doi: 10.5937/fme2301090I"
}

Ilić, N.,& Momčilović, N.. (2023). On ultimate strength of an inland waterway barge. in FME Transactions
University of Belgrade - Faculty of Mechanical Engineering., 51(1), 90-98.
https://doi.org/doi: 10.5937/fme2301090I

Ilić N, Momčilović N. On ultimate strength of an inland waterway barge. in FME Transactions. 2023;51(1):90-98.
doi:doi: 10.5937/fme2301090I .

Ilić, Nemanja, Momčilović, Nikola, "On ultimate strength of an inland waterway barge" in FME Transactions, 51, no. 1 (2023):90-98,
https://doi.org/doi: 10.5937/fme2301090I . .