Experimental Evaluation and Validation of Pressure Distributions in Ice–Structure Collisions Using a Pendulum Apparatus

Jang, Ho-Sang; Hwang, Se-Yun; Lee, Jang Hyun

doi:10.3390/jmse11091761

Cited by 3 publications

(8 citation statements)

References 39 publications

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“…Throughout this process, multiple FEA iterations were undertaken to determine previously undefined material constants. According to the quasi-static compression test results reported by Jang et al [16], it was observed that ice specimens, configured as square columns with cross-sectional dimensions of 100 mm × 100 mm and a height of 250 mm, failed under loads ranging from approximately 25 to 32 kN when compressed by 5 mm (Error! Reference source not found.…”

Section: Finite Element Analysis Simulating Ice Compression Experimentsmentioning

confidence: 99%

“…In this study, the collision pendulum experiment conducted by Jang et al [16] was chosen for numerical simulation. A detailed discussion on the material models associated this simulation is provided in Sections 2, 3.1, and 3.2.…”

Section: Overview Of the Ice-structural Collision Simulation Modelmentioning

confidence: 99%

“…For example, Zhu et al [7] and Cai et al [8] conducted collision experiments with wedge-shaped ice specimens at speeds of 4 to 7 knots to measure the loads applied to the impacted bodies. Additionally, Jang et al [16] presented the results of collision experiments between hemispherical ice specimens and steel plates using a collision pendulum at controlled speeds (5, 7, 10 knots) in a low-temperature chamber. These experiments accurately predict loads under experimental conditions, but they require scaling down the size of the ship and ice, and the experimental conditions are limited.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Numerical Analysis of Ice-Structure Impact: Validating Material Models and Yield Criteria for Enhanced Prediction of Impact Pressure

Jang,

Hwang,

Yoon

et al. 2023

Preprint

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This study explores the application of numerical analysis and material models to predict ice impact loads on ships and offshore structures operating in polar regions. An explicit finite element analysis (FEA) approach was employed to simulate an ice and steel plate collision experiment conducted in a cold chamber. The pressure and strain history during the ice collision were calculated and compared with the experimental results. Various material model configurations were applied to the FEA to account for the versatile behavior of ice—whether ductile or brittle—its elastic-plastic yield criteria, and its dynamic strain rate dependency. In addition to the standard linear elastic perfectly plastic and linear elastic-plastic relationships, this study incorporated the crushable foam and Drucker-Prager models, based on the specific ice yield criteria. Considering the ice’s strain rate dependency, collision simulations were conducted for each yield criteria model to compute the strain and reaction force of the plate specimens. By comparing the predicted pressures for each material model combination with the pressures from ice collision experiments, our study proposes material models that consider the yielding, damage, and behavioral characteristics of ice. Lastly, our study proposes a combination of ice material properties that can accurately predict collision force.

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Section: Finite Element Analysis Simulating Ice Compression Experimentsmentioning

confidence: 99%

Section: Overview Of the Ice-structural Collision Simulation Modelmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Numerical Analysis of Ice-Structure Impact: Validating Material Models and Yield Criteria for Enhanced Prediction of Impact Pressure

Jang,

Hwang,

Yoon

et al. 2023

Preprint

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“…The plastic deformation and energy absorption of a plate and the collision forces during the impact process were studied. Jang et al [14] designed an experimental set-up, including a double-pendulum system situated within a cold chamber, which can predict the collision forces under ice impacts by varying both the collision energy and velocity. Considering the influence of fluid motion on ship-ice impact, Kim et al [15] carried out a series of laboratory-scale tests of freshwater granular ice blocks against stiffened steel panels in the ice tank and analyzed the impact force and the permanent plate deformations of the structure.…”

Section: Introductionmentioning

confidence: 99%

“…Figure 5 is a diagram to introduce the theoretical model of the dynamic response of ice floe-plate impact. (14) can be used to obtain the maximum plastic deformation wm and the maximum impact force Fm of the plate under rigid-mass impact.…”

Section: Introduction To the Proposed Theoretical Modelmentioning

confidence: 99%

A New Plastic Design Approach for the Vertical-Side-Plating Thickness of Ice-Strengthened Ships Suffering from Ice Floe Impacts

Mu,

Guo,

Cai

et al. 2024

JMSE

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Ice-strengthened ships inevitably suffer from ice floe impacts during navigation in icy regions. Under some extreme-ice-impact loadings, the ship structure will experience plastic deformations. The magnitude of plastic deformation is highly correlated with the ice floe-impact energy level. During most ice impacts, only the ship’s plate undergoes minor plastic deformation. Considering that the structure still has a high structural strength with a minor permanent deformation, developing a structural plastic design method for polar ships has become a hot research issue in current studies. Therefore, in this paper, based on the rigid-plastic theory and the ice-crushing-energy approach, an experimentally verified theoretical model for predicting plastic deformations of the vertical-side plate of polar ship subjected to ice floe impacts was established. According to the analytical solutions of the plastic deformation, the plastic design formula to determine the plating thickness of ice-strengthened ships subjected to ice floe impacts was further derived based on the plastic design criteria. In addition, the parameter analysis of ice strength described by the ice pressure–area relationship, allowable-permanent-set parameter, impact energy and ice shape were conducted, and plating-thickness design curves with different design parameters were given. The design of plating thickness is very sensitive to the determinations of the allowable-permanent set and ice pressure–area curves. The designed plating thickness decreased with the increase of the allowable-permanent set. Moreover, a comparative analysis of the designed plating thickness for ice floe impact and rigid-mass impact was also carried out. Under the same impact conditions, due to energy absorption caused by ice damage, the designed thickness of the plate for rigid-mass impact was much larger than that for the ice impact. It is necessary to consider the impact-induced ice damage and energy dissipation in a structural design, instead of using rigid impact loads for conservative design. The research in this paper can provide some useful references for the structural design of ice-strengthened ships subject to ice floe impacts.

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Numerical Analysis of Ice–Structure Impact: Validating Material Models and Yield Criteria for Prediction of Impact Pressure

Jang,

Hwang,

Yoon

et al. 2024

JMSE

Self Cite

View full text Add to dashboard Cite

This study explores the application of numerical analysis and material models to predict ice impact loads on ships and offshore structures operating in polar regions. An explicit finite element analysis (FEA) approach was employed to simulate an ice and steel plate collision experiment conducted in a cold chamber. The pressure and strain history during the ice collision were calculated and compared with the experimental results. Various material model configurations were applied to the FEA to account for the versatile behavior of ice (whether ductile or brittle), its elastic-plastic yield criteria, and its dynamic strain rate dependency. In addition to the standard linear elastic-perfectly plastic and linear elastic-plastic relationships, this study incorporated the Crushable Foam and Drucker–Prager models, based on the specific ice yield criteria. Considering the ice’s strain rate dependency, collision simulations were conducted for each yield criteria model to compute the strain and reaction force of the plate specimens. By comparing the predicted pressures for each material model combination with the pressures from ice collision experiments, our study proposes material models that consider the yielding, damage, and behavioral characteristics of ice. Lastly, our study proposes a combination of ice material properties that can accurately predict collision force.

show abstract

Experimental Evaluation and Validation of Pressure Distributions in Ice–Structure Collisions Using a Pendulum Apparatus

Cited by 3 publications

References 39 publications

Numerical Analysis of Ice-Structure Impact: Validating Material Models and Yield Criteria for Enhanced Prediction of Impact Pressure

Numerical Analysis of Ice-Structure Impact: Validating Material Models and Yield Criteria for Enhanced Prediction of Impact Pressure

A New Plastic Design Approach for the Vertical-Side-Plating Thickness of Ice-Strengthened Ships Suffering from Ice Floe Impacts

Numerical Analysis of Ice–Structure Impact: Validating Material Models and Yield Criteria for Prediction of Impact Pressure

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