Burak Can Cerik scite author profile

The offshore industry has been using stiffened thin-walled steel cylindrical structures for decades, particularly as the columns of floating offshore installations. The floating offshore installations may be subjected to severe marine environmental conditions. Accidents such as collisions may also occur. Structural Health Monitoring (SHM) is a viable tool to maintain safe operation of offshore installations. Inverse Finite Element Method (iFEM) is one of the most powerful methods for SHM process. Hence, this study focuses on the application of iFEM methodology to thin-walled cylindrical structures representing the columns of floating offshore installations. iFEM methodology is verified by comparing its displacement results against reference finite element method (FEM) solution. After this verification, four different damage cases with different size, location and number of damages are considered. By using a newly introduced damage parameter and von Mises strain distribution iFEM accurately identified the correct damage locations and sizes. Therefore, it is concluded that iFEM can be used for structural damage prediction in offshore structures with high accuracy even if the number of the strain sensors is limited.

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Simulation of ship collision and grounding damage using Hosford-Coulomb fracture model for shell elements

Cerik

Lee

Park

et al. 2019

Ocean Engineering

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Modeling, testing and calibration of ductile crack formation in grade DH36 ship plates

Cerik

Park

et al. 2019

Marine Structures

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Ductile fracture prediction of EH36 grade steel based on Hosford–Coulomb model

Park

Lee²,

Cerik

et al. 2019

Ships and Offshore Structures

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Rate-dependent combined necking and fracture model for predicting ductile fracture with shell elements at high strain rates

Cerik

Choung

2020

International Journal of Impact Engineering

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Revisiting MARSTRUCT benchmark study on side-shell collision with a combined localized necking and stress-state dependent ductile fracture model

2019

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Damage assessment of marine grade aluminium alloy-plated structures due to air blast and explosive loads

Cerik

2017

Thin-Walled Structures

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Comparative study on ductile fracture prediction of high-tensile strength marine structural steels

Park

Cerik

Choung

2020

Ships and Offshore Structures

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Burak Can Cerik

Dent damage identification in stiffened cylindrical structures using inverse Finite Element Method

Simulation of ship collision and grounding damage using Hosford-Coulomb fracture model for shell elements

Modeling, testing and calibration of ductile crack formation in grade DH36 ship plates

Ductile fracture prediction of EH36 grade steel based on Hosford–Coulomb model

Rate-dependent combined necking and fracture model for predicting ductile fracture with shell elements at high strain rates

Revisiting MARSTRUCT benchmark study on side-shell collision with a combined localized necking and stress-state dependent ductile fracture model

Damage assessment of marine grade aluminium alloy-plated structures due to air blast and explosive loads

Comparative study on ductile fracture prediction of high-tensile strength marine structural steels

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