Pack Ice Loads on Seasonally Operating Semi-Submersible in the Labrador Sea

Thijssen, Jan; Fuglem, Mark; Dolny, John

doi:10.4043/27333-ms

Cited by 3 publications

(6 citation statements)

References 6 publications

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“…The values were selected by considering the capabilities of the testing apparatus, i.e., its power output. Experiments showed that the indentation depth in the studied range had no significant effect on the measured reaction forces [8]. While most of the indenter's surface is constantly in contact with the ice, the pressure on the surface varies.…”

Section: Related Workmentioning

confidence: 89%

“…Finally, different studies use different values for the failure stress parameters, and such discrepancies are due to the differences in geometries, types of experimentally obtained data, and calibration approaches. In a recent series of experiments, medium-scale indentation tests were conducted with rigid indenter and laboratory-grown samples of freshwater ice [8]. The diameter of the indenter is 32.4 cm, which is intended to mimic a pipeline.…”

Section: Related Workmentioning

confidence: 99%

“…For model calibration, we rely on the data presented in Figures 2 and 3, which are representative of the RHITA tests. Details about the remaining experimental tests are available in the publication [8].…”

Section: Related Workmentioning

confidence: 99%

“…In the RHITA experiments [8], the ice block is grown in a container that is one meter tall. Side walls are subsequently removed to expose the top half of the sample.…”

Section: Boundary Conditionsmentioning

confidence: 99%

“…In RHITA tests [8], the maximal height of an ice sample is approximately 1 m, and the experiments provide accurate measurements of the fracture forces for such samples. However, the question remains about the relevancy of these data to the fracture of actual icebergs.…”

Section: Influence Of Block Heightmentioning

confidence: 99%

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Investigating Ice Loads on Subsea Pipelines with Cohesive Zone Model in Abaqus

Gribanov,

Taylor,

Thijssen

et al. 2023

Modelling

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Subsea pipelines and cables placed in ice-prone regions may be at risk of iceberg damage. In particular, pipes that are not buried may come in direct contact with iceberg keels. Knowing the range of interaction forces helps to assess the types and magnitudes of potential damage. Experimental studies provide the most valuable data about the interaction forces, while numerical modeling may give insight into configurations that are difficult to study experimentally. This work applies the cohesive zone model to investigate the fracture behavior of ice samples. Simulations are performed in 2D with Abaqus explicit solver. Modeled interaction forces from multiple simulations are recorded and compared to understand how the geometry of the samples affects the fracture. Repeat interactions with different grain configurations are conducted to investigate associated variance in fracture patterns and loads. t-tests show that the force application angle and the indenter’s position significantly affect the fracture force.

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Section: Related Workmentioning

confidence: 89%

Section: Related Workmentioning

confidence: 99%

Section: Related Workmentioning

confidence: 99%

“…In the RHITA experiments [8], the ice block is grown in a container that is one meter tall. Side walls are subsequently removed to expose the top half of the sample.…”

Section: Boundary Conditionsmentioning

confidence: 99%

Section: Influence Of Block Heightmentioning

confidence: 99%

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Investigating Ice Loads on Subsea Pipelines with Cohesive Zone Model in Abaqus

Gribanov,

Taylor,

Thijssen

et al. 2023

Modelling

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Probabilistic Approach to Determine Combined Sea Ice and Wave Actions

Fuglem

Thijssen

Stuckey

et al. 2018

Day 3 Wed, November 07, 2018

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Design of offshore structures for arctic and subarctic regions requires consideration of wave, wind and ice actions. If individual actions are not mutually exclusive, then combined actions also need consideration. ISO 19906 recommends that, when possible, extreme level combined actions should be determined based on the joint probability distribution of the actions. As an alternative, ISO 19906 provides a framework where a user can determine principal and companion extreme actions independently, and sum these with calibrated combination factors applied. While the combination factors in ISO 19906 were calibrated over a range of conditions and platforms, site-specific information is not taken into account when applying the method. In this paper, a procedure is presented for determining extreme level combined actions for sea ice and waves based on site-specific sea ice and wave information, accounting for the joint probability distribution of the actions. The procedure is demonstrated for an example fixed structure on the Grand Banks off Canada's east coast. The results are compared with extreme actions determined using the ISO 19906 combination factors.

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Ice Risk Analysis for Floating Wind Turbines, Offshore Newfoundland and Labrador

King

Ralph

Fuglem

et al. 2022

Day 3 Wed, May 04, 2022

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The move to reduce greenhouse gas emissions in the offshore hydrocarbons production industry has resulted in a growing interest in the possibility of using offshore wind to reduce on-platform power generation. While some offshore areas are progressing towards or planning for the use of offshore wind to electrify hydrocarbon producing platforms, they do not have the challenges associated with Newfoundland & Labrador's offshore environment.This region is prone to incursions by icebergs and pack ice, which would present a risk to offshore wind turbines. Analysis approachesto assess these risks, along with preliminary results, are presented herefor floating offshore wind turbines (FOWT). An area of interest (AOI), covering 45°N to 51°N and 45°W to 51°W, was defined covering all development licenses on the Grand Banks, Flemish Pass and Orphan Basin. Iceberg and pack ice contact rates and loads were calculated using data from the Nalcor NESS Metocean database, Canadian Ice Service (CIS) ice charts and satellite imagery. Ice loads corresponding to 50-year return periods levels were assessed, with and without ice management, giving a basis for determining whether ice management and/or disconnection capabilities are required. The frequency and severity of atmospheric icing of turbines was also modelled using available data and models.

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Pack Ice Loads on Seasonally Operating Semi-Submersible in the Labrador Sea

Cited by 3 publications

References 6 publications

Investigating Ice Loads on Subsea Pipelines with Cohesive Zone Model in Abaqus

Investigating Ice Loads on Subsea Pipelines with Cohesive Zone Model in Abaqus

Probabilistic Approach to Determine Combined Sea Ice and Wave Actions

Ice Risk Analysis for Floating Wind Turbines, Offshore Newfoundland and Labrador

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