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Proceedings Papers

Proceedings Volume Cover
ASME 2020 39th International Conference on Ocean, Offshore and Arctic Engineering
August 3–7, 2020
Virtual, Online
Conference Sponsors:
  • Ocean, Offshore and Arctic Engineering Division
ISBN:
978-0-7918-8432-4
Volume 2A: Structures, Safety, and Reliability

Structures, Safety, and Reliability

Abnormal and Extreme Waves

A Numerical Investigation of Steep Irregular Wave Properties With a Mixed-Eulerian Lagrangian HOS Method
Sébastien Fouques, Csaba Pákozdi
OMAE 2020; V02AT02A001https://doi.org/10.1115/OMAE2020-18216
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Topics: Waves , Simulation , Seas , Particulate matter , Computational fluid dynamics , Design , Modeling , Nonlinear waves , Physics , Probability
Wave-Induced Turbulence, Linking Metocean and Large Scales
Alexander V. Babanin
OMAE 2020; V02AT02A002https://doi.org/10.1115/OMAE2020-18373
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Topics: Turbulence , Waves , Oceans , Seas , Climate , Arctic region , Ice , Surface waves (Fluid) , Wind velocity , Wind waves
Relation Between Cyclone Evolution and Fetch Associated With Extreme Wave Events in the South Atlantic Ocean
C. B. Gramcianinov, R. M. Campos, R. de Camargo, C. Guedes Soares
OMAE 2020; V02AT02A003https://doi.org/10.1115/OMAE2020-18486
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Topics: South Atlantic Ocean , Waves , Algorithms , Displacement , Storms
Comparison Between ERA5 and CFS Datasets of Extratropical Cyclones Associated With Extreme Wave Events in the Atlantic Ocean
C. B. Gramcianinov, R. M. Campos, C. Guedes Soares, R. de Camargo
OMAE 2020; V02AT02A004https://doi.org/10.1115/OMAE2020-18488
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Topics: Atlantic Ocean , Waves , Climate , Resolution (Optics) , Storms , Computer simulation , Density , Errors , North Atlantic Ocean , Oceans
Surface Waves Under the Sea Ice in the Western Arctic During 2019 R/V Mirai Cruise
Tsubasa Kodaira, Takuji Waseda, Takehiko Nose, Jun Inoue, Kazutoshi Sato, Joey Voermans, Alexander Babanin
OMAE 2020; V02AT02A005https://doi.org/10.1115/OMAE2020-18547
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Topics: Arctic region , Ice , Sea ice , Surface waves (Fluid) , Waves
Linearization of the Wave Spectrum: A Comparison of Methods
Dylan Barratt, Harry B. Bingham, Paul H. Taylor, Ton S. van den Bremer, Thomas A. A. Adcock
OMAE 2020; V02AT02A006https://doi.org/10.1115/OMAE2020-18820
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Topics: Waves , Phase separation , Computer simulation , Engineering simulation , Fast Fourier transforms , Fourier transforms , Ocean engineering , Signals , Simulation , Water
Space-Time Statistics via Trapezoidal Storm Model for Offshore Installations
Valentina Laface, Alessandra Romolo, Elzbieta M. Bitner-Gregersen
OMAE 2020; V02AT02A007https://doi.org/10.1115/OMAE2020-18822
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Topics: Offshore installations , Spacetime , Statistics , Storms , Waves , Approximation , Seas , Design , Marine engineering , Ocean waves
Theory of Nonlinear Fourier Analysis: The Construction of Quasiperiodic Fourier Series for Nonlinear Wave Motion
Alfred R. Osborne
OMAE 2020; V02AT02A008https://doi.org/10.1115/OMAE2020-18850
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Topics: Construction , Fourier analysis , Fourier series , Nonlinear waves , Waves , Dynamics (Mechanics) , Korteweg-de Vries equation , Solitons , Theorems (Mathematics) , Turbulence
Occurrence Frequency of a Triple Rogue Wave Group in the Ocean
Elzbieta M. Bitner-Gregersen, Odin Gramstad, Anne Karin Magnusson, Pierre C. Sames
OMAE 2020; V02AT02A009https://doi.org/10.1115/OMAE2020-19314
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Topics: Oceans , Waves

Collision and Crashworthiness

State of the Art in Determination of Crack Direction in Shell Structures
Hossein Heidari, Carey L. Walters
OMAE 2020; V02AT02A010https://doi.org/10.1115/OMAE2020-18217
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Topics: Fracture (Materials) , Fracture (Process) , Modeling , Necking , Shells
Axial Compression and Collapse Properties of 3D Re-Entrant Hexagonal Auxetic Structures
Pu Li, Jingxia Yue, Xiaobin Li, Wenchao Wan
OMAE 2020; V02AT02A011https://doi.org/10.1115/OMAE2020-18418
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Topics: Collapse , Compression , Poisson ratio , Deformation , Honeycomb structures , Absorption , Dimensions , Dynamic response , Finite element analysis , Load bearing capacity
Retracted: “Nonlinear Integrated Simulation of Dropped Container Impact With Platform Deck” [Proceedings of the ASME 2020 39th International Conference on Ocean, Offshore and Arctic Engineering, Volume 2A: Structures, Safety, and Reliability, Virtual, Online, August 3–7, 2020, Conference Sponsors: Ocean, Offshore and Arctic Engineering Division, ISBN: 978-0-7918-8432-4, Copyright © 2020 by ASME. Paper No. OMAE2020-18581, V02AT02A012; 10 pages; doi: 10.1115/OMAE2020-18581]
ASME
OMAE 2020; V02AT02A012https://doi.org/10.1115/OMAE2020-18581
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Topics: Arctic engineering , Containers , Ocean engineering , Oceans , Platform decks , Reliability , Safety , Simulation
Simplified Analytical Calculation and Modification of the Crushing Forces of Intersection Units in Vessel-Bridge Collisions
Yin Faqiang, Pan Jin, Huang Shiwen, Xu Mingcai
OMAE 2020; V02AT02A013https://doi.org/10.1115/OMAE2020-18615
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Topics: Bridges (Structures) , Collisions (Physics) , Simulation , Vessels
Dynamic Ship Domain Model Based on AIS Data for Inland Waterways
Yankang He, Di Zhang, Jinfen Zhang, Bing Wu, Carlos Guedes Soares
OMAE 2020; V02AT02A014https://doi.org/10.1115/OMAE2020-18700
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Topics: Collisions (Physics) , Risk , Ships
Collision Experiments of Ship Models in Water Tank
Lijun Xu, Ling Zhu, Xiangbiao Wang, Preben Terndrup Pedersen
OMAE 2020; V02AT02A015https://doi.org/10.1115/OMAE2020-18741
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Topics: Collisions (Physics) , Damage , Dynamic response , Ships , Water
Numerical Studies on Dynamic Behavior of Tubular Pipes Under Repeated Impacts
Ling Zhu, Xiangui Wang, Kailing Guo, Bin Ma
OMAE 2020; V02AT02A016https://doi.org/10.1115/OMAE2020-19270
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Topics: Pipes
Treatment of Bending Deformations in Maritime Crash Analyses
Mihkel Kõrgesaar, Martin Storheim
OMAE 2020; V02AT02A017https://doi.org/10.1115/OMAE2020-19272
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Topics: Deformation , Stress , Fracture (Materials) , Fracture (Process) , Damage , Erosion , Failure , Shells , Ships

Data-Driven Models for Marine Structures

Algorithms for Supervised Machine Learning-Based Structural Performance Evaluation Framework
Xiaowei Wang, YeongAe Heo
OMAE 2020; V02AT02A018https://doi.org/10.1115/OMAE2020-18947
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Topics: Algorithms , Machine learning , Machinery , Model validation , Performance evaluation

Extreme Loading and Responses

Statistical Analysis of In-Line Interaction of Closely Spaced Cylinder Arrays in Random Waves
Jiangnan Lu, J. M. Niedzwecki
OMAE 2020; V02AT02A019https://doi.org/10.1115/OMAE2020-18179
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Topics: Cylinders , Displacement , Statistical analysis , Waves
A New Approach to Compute the Non-Linear Whipping Response Using Hydro-Elastoplastic Coupling
George Jagite, Hervé le Sourne, Patrice Cartraud, Šime Malenica, Fabien Bigot, Jérôme de Lauzon, Quentin Derbanne
OMAE 2020; V02AT02A020https://doi.org/10.1115/OMAE2020-18200
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Topics: Boundary element methods , Collapse , Girders , Hinges , Hull , Shapes , Stress , Tensile strength
Study on Mechanical Properties of Water Mist Acting on Plane Shock Wave
Pengduo Zhao, Haojie Wang
OMAE 2020; V02AT02A021https://doi.org/10.1115/OMAE2020-18335
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Topics: Drops , Mechanical properties , Shock waves , Water
Non Linear Effect on Wave-Induced Loads for Hull Structural Design: Bulk Carrier, Container Carrier, Vehicles Carrier
Kei Sugimoto, Yusuke Fukumoto, Junya Matsuwaki, Tatsuya Akamatsu, Shinsaku Ashida, Koeki Onishi, Hidetaka Houtani, Masayoshi Oka, Hiroshi Kawabe, Kinya Ishibashi
OMAE 2020; V02AT02A022https://doi.org/10.1115/OMAE2020-18413
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Topics: Containers , Hull , Pressure , Seas , Stress , Structural design , Vehicles , Waves
Hull Structural Strength Evaluation Based on Fiber Bragg Gratings Pressure Sensors to Measure Spatial Pressure Distribution on Ship’s Hull in Waves
Yusuke Komoriyama, Daichi Ota, Chong Ma, Hiroshi Sawada, Masayoshi Oka, Sadaoki Matsui, Hidetaka Houtani
OMAE 2020; V02AT02A023https://doi.org/10.1115/OMAE2020-18434
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Topics: Fiber Bragg gratings , Hull , Pressure , Pressure sensors , Waves , Water pressure , Finite element analysis , Inertia (Mechanics) , Strain sensors , Calibration
A Fluid-Structure Coupled Computational Model for the Certification of Shock-Resistant Elastomer Coatings
Wentao Ma, Xuning Zhao, Kevin Wang
OMAE 2020; V02AT02A024https://doi.org/10.1115/OMAE2020-18501
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Topics: Coatings , Computer simulation , Elastomers , Fluids , Shock (Mechanics) , Collapse , Explosions , Finite element analysis , Hydrostatics , Stress
Development of Closed Formula of Wave Load Based Upon Long-Term Prediction: Heave Acceleration and Pitch Angle
Kyohei Shinomoto, Sadaoki Matsui, Kei Sugimoto, Shinsaku Ashida
OMAE 2020; V02AT02A025https://doi.org/10.1115/OMAE2020-18558
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Topics: Stress , Waves , Ships , Hull , Safety , Seas , Construction , Information Analysis Centers , Probability , Service life (Equipment)
Assessment of Global Wave Datasets for Long Term Response of Ships
Guillaume de Hauteclocque, Tingyao Zhu, Michael Johnson, Håvard Austefjord, Elzbieta Bitner-Gregersen
OMAE 2020; V02AT02A026https://doi.org/10.1115/OMAE2020-18874
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Topics: Ships , Waves , Buoys , Design , Electromagnetic scattering , Information Analysis Centers , North Atlantic Ocean , Shorelines , Significant wave heights
Sensitivity Analysis in Parametric Rolling of a Modern Cruise Ship Using Numerical Simulations in 6-DOF
Bülent Düz
OMAE 2020; V02AT02A027https://doi.org/10.1115/OMAE2020-18904
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Topics: Computer simulation , Sensitivity analysis , Ships , Simulation , Damping , Diffraction , Radiation (Physics) , Safety , Statistics , Stress
Estimating Loads From Breaking Waves Using Operational Modal Analysis
Michael Vigsø, Christos Georgakis
OMAE 2020; V02AT02A028https://doi.org/10.1115/OMAE2020-19170
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Topics: Modal analysis , Stress , Waves , Design , Flumes , Offshore structures , Vibration measurement , Wave theory of light
Coupled CFD and FEA to Predict the Dynamic Structural Response of Modern Cruise Ship Deck Outfitting due to Wind-Induced Vibrations
Eetu Kivelä, P. A. Lakshmynarayanana, Spyros Hirdaris
OMAE 2020; V02AT02A029https://doi.org/10.1115/OMAE2020-19187
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Topics: Computational fluid dynamics , Finite element analysis , Fluid structure interaction , Reynolds-averaged Navier–Stokes equations , Ships , Vibration , Vortex shedding , Wind
A New Coupled Model for the Assessment of Offshore Structures in Non-Gaussian Seas
Griet Decorte, Alessandro Toffoli, Geert Lombaert, Jaak Monbaliu
OMAE 2020; V02AT02A030https://doi.org/10.1115/OMAE2020-19345
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Topics: Offshore structures , Seas , Waves

Fatigue and Fracture Reliability

A Stress Magnification Factor for Plates With Welding-Induced Curvatures
Federica Mancini, Heikki Remes, Jani Romanoff
OMAE 2020; V02AT02A031https://doi.org/10.1115/OMAE2020-18094
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Topics: Boundary-value problems , Magnification , Plates (structures) , Stress , Welding
Nonlinear Dynamic and Bilinear Fatigue Performance of Composite Marine Risers in Deep Offshore Fields
Rizwan A. Khan, Suhail Ahmad
OMAE 2020; V02AT02A032https://doi.org/10.1115/OMAE2020-18127
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Topics: Composite materials , Fatigue , Marine drilling risers , Ocean engineering , Pipeline risers , Reliability , Risers (Casting)
Fracture Toughness Characterization of LSAW UOE Pipes in Sour Media and Implications on Burst Pressure
T. Turkalj, S. Cravero, M. Valdez, F. Arroyo, Ph. Darcis
OMAE 2020; V02AT02A033https://doi.org/10.1115/OMAE2020-18319
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Topics: Fracture toughness , Pipes , Pressure
Projection and Detection Procedures for Long-Term Wave Climate Change Impact on Fatigue Damage of Offshore Floating Structures
Tao Zou, Miroslaw Lech Kaminski, Hang Li, Longbin Tao
OMAE 2020; V02AT02A034https://doi.org/10.1115/OMAE2020-18350
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Topics: Climate , Climate change , Fatigue damage , Floating structures , Ocean engineering , Waves
Fatigue Analysis for Mooring System of a Spar-Type Floating Offshore Wind Turbine
Xutian Xue, Xiaoyong Liu, Nian-Zhong Chen, Xifeng Gao
OMAE 2020; V02AT02A035https://doi.org/10.1115/OMAE2020-18478
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Topics: Fatigue , Fatigue analysis , Floating wind turbines , Mooring , Spar platforms , Wing spars
Fretting Fatigue Design of Subsea Connectors: A Generalised Approach to Testing
H. Andresen, D. A. Hills, Anders Wormsen, K. A. Macdonald
OMAE 2020; V02AT02A036https://doi.org/10.1115/OMAE2020-18608
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Topics: Contact mechanics , Design , Engineering prototypes , Fatigue , Fatigue design , Fatigue strength , Fatigue testing , Fracture (Materials) , Materials properties , Nucleation (Physics)
On Normalized Fatigue Crack Growth Modeling
Sebastian T. Glavind, Henning Brüske, Michael H. Faber
OMAE 2020; V02AT02A037https://doi.org/10.1115/OMAE2020-18613
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Topics: Fatigue cracks , Modeling , Fracture (Materials) , Fatigue , Uncertainty , Fatigue life , Maintenance , Risk-based inspection , Calibration , Welded joints
Feasibility of Using Hindcast Data for Fatigue Assessment of Permanently Moored Offshore Units in West-Africa
Remco Hageman, Pieter Aalberts, Didier L’Hostis, Alain Ledoux
OMAE 2020; V02AT02A038https://doi.org/10.1115/OMAE2020-18794
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Topics: Fatigue , FPSO , Hull , Mooring , Ocean engineering
Fretting Fatigue Design of Subsea Connectors: Matching Results Between Pairs of Tests
L. E. Blades, D. A. Hills, A. Wormsen, K. A. Macdonald
OMAE 2020; V02AT02A039https://doi.org/10.1115/OMAE2020-18821
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Topics: Fatigue , Fatigue design , Ocean engineering , Stress , Design , Fatigue cracks , Fatigue life , Fatigue testing , Geometry , High cycle fatigue
A Study on the Difference in Wave Statistics Based on Storm Model for the Ship Structural Assessment
Luis De Gracia, Helong Wang, Wengang Mao, Naoki Osawa
OMAE 2020; V02AT02A040https://doi.org/10.1115/OMAE2020-19048
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Topics: Fatigue , Optimization , Ships , Statistics , Storms , Waves
Comparative Study on Stress Intensity Factors for Surface Cracks in Welded Joint and Flat Plate by Using the Influence Function Method
Phyo Myat Kyaw, Osawa Naoki, Gadallah Ramy, Tanaka Satoyuki
OMAE 2020; V02AT02A041https://doi.org/10.1115/OMAE2020-19261
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Topics: Flat plates , Stress , Surface cracks , Welded joints

Probabilistic and Spectral Wave Models

Environmental Contours Based on a Direct Sampling Approach and the IFORM Approach: Contribution to a Benchmark Study
Erik Vanem, Arne Bang Huseby
OMAE 2020; V02AT02A042https://doi.org/10.1115/OMAE2020-18041
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Topics: Event history analysis , Modeling , Stress , Uncertainty
Study on Ship Operational Effect for Defining Design Values on Ship Motion and Loads in North Atlantic
Rei Miratsu, Tsutomu Fukui, Toshiyuki Matsumoto, Tingyao Zhu
OMAE 2020; V02AT02A043https://doi.org/10.1115/OMAE2020-18193
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Topics: Design , North Atlantic Ocean , Seas , Ships , Stress
Hydrodynamic Assessment of a Biofouled Wave Buoy in Coastal Zone
Hafizul Islam, Ricardo M. Campos, Tobias R. S. Ferreira, C. Guedes Soares
OMAE 2020; V02AT02A044https://doi.org/10.1115/OMAE2020-18235
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Topics: Buoys , Shorelines , Waves , Biofouling , Mooring , Uncertainty , Water , Accuracy and precision , Drag (Fluid dynamics) , Engineering simulation
Estimation of Environmental Contours Using a Block Resampling Method
Ed B. L. Mackay, Philip Jonathan
OMAE 2020; V02AT02A045https://doi.org/10.1115/OMAE2020-18308
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Topics: Fittings , Significant wave heights , Storms , Time series , Wind velocity
Relation Between Atmospheric Circulation Patterns in the North Atlantic and the Sea States in the Iberian Peninsula
C. Lucas, M. Bernardino, C. Guedes Soares
OMAE 2020; V02AT02A046https://doi.org/10.1115/OMAE2020-18654
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Topics: North Atlantic Ocean , Seas , Waves , Ocean engineering , Climate , Design , Engineering simulation , Modeling , Probability , Renewable energy
Global Hierarchical Models for Wind and Wave Contours: Physical Interpretations of the Dependence Functions
Andreas F. Haselsteiner, Aljoscha Sander, Jan-Hendrik Ohlendorf, Klaus-Dieter Thoben
OMAE 2020; V02AT02A047https://doi.org/10.1115/OMAE2020-18668
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Topics: Waves , Wind , Design , Significant wave heights , Wind velocity , Offshore wind turbines , Seas , Shapes , Stress
Assessing Climate Change in the North Atlantic Wave Regimes
M. Bernardino, M. Gonçalves, C. Guedes Soares
OMAE 2020; V02AT02A048https://doi.org/10.1115/OMAE2020-18697
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Topics: Climate change , North Atlantic Ocean , Waves , Climate , Statistics , Wind , Significant wave heights , Ice , Offshore structures , Optimization

Probabilistic Response Models

Influence of Torpedo Piles Parameters When Assessing Final Penetration Depths
Leonardo Sant’Anna do Nascimento
OMAE 2020; V02AT02A049https://doi.org/10.1115/OMAE2020-18505
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Topics: Computer simulation , Damping , Monte Carlo methods , Numerical analysis , Ocean engineering , Soil , Statistical analysis , Uncertainty

Reliability of Marine Structures

Reliability Analysis of FPSO Oil and Gas Processing System Based on Petri Net
Jichuan Kang, Xinyuan Geng, Liping Sun, Peng Jin
OMAE 2020; V02AT02A050https://doi.org/10.1115/OMAE2020-18163
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Topics: Event history analysis , FPSO , Natural gas processing
Study of the Efficiency and Reliability of Pressure Vessel Composite Repair
Geovana Drumond, Rodrigo Ribeiro, Ilson Pasqualino, Marcelo Igor de Souza, Valber Perrut, Luiz Daniel Lana
OMAE 2020; V02AT02A051https://doi.org/10.1115/OMAE2020-18835
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Topics: Composite materials , Maintenance , Pressure vessels , Reliability , Pressure , Corrosion , Vessels , Engineering standards , Laminates , Nozzles

Reliability of Mooring and Riser Systems

Reliability Analysis of Mooring Lines of Floating Structures Under Corrosion and Material Degradation
Ricardo Soares Gomes Junior, Paulo Mauricio Videiro, Paulo de Tarso Themistocles Esperança, Luis Volnei Sudati Sagrilo
OMAE 2020; V02AT02A052https://doi.org/10.1115/OMAE2020-18306
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Topics: Chain , Corrosion , Event history analysis , Floating structures , Materials degradation , Mooring , Offshore structures
Influence of Mean Tension on Mooring Line Fatigue Life
Erling N. Lone, Bernt J. Leira, Thomas Sauder, Vegard Aksnes, Øystein Gabrielsen, Kjell Larsen
OMAE 2020; V02AT02A053https://doi.org/10.1115/OMAE2020-18628
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Topics: Fatigue life , Mooring , Tension , Stress , Design , Fatigue damage , Semi-submersible offshore structures , Chain , Cycles , Engineering simulation
Method for Fatigue Testing of Subsea Wellhead Connector Segments
Pedro Barros, Agnes Marie Horn, Anders Wormsen, Per Osen, Kenneth A. Macdonald
OMAE 2020; V02AT02A054https://doi.org/10.1115/OMAE2020-18652
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Topics: Fatigue testing , Ocean engineering , Stress , Fatigue , Testing , Finite element analysis , Drilling , Drilling rigs , Boundary-value problems , Friction
Benefit From Structural Reliability Analysis in Risk Evaluation of Collapse of Externally Supported Casing
Torfinn Hørte, Arve Bjørset, Dan Tudor Zaharie, Sune Pettersen
OMAE 2020; V02AT02A055https://doi.org/10.1115/OMAE2020-18887
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Topics: Collapse , Event history analysis , Finite element analysis , Risk assessment
Floating Hose Behavior During Different Scenarios of an Offloading Operation
Nathalia Paruolo, Thalita Mello, Leonardo Brandão
OMAE 2020; V02AT02A056https://doi.org/10.1115/OMAE2020-19225
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Topics: Bending strength , Computer simulation , Dynamic positioning systems , Failure , FPSO , Hazards , Mooring , Numerical analysis , Ocean engineering , Pipelines

Reliability of Renewable Energy Systems

An Efficient Importance Sampling Method for the Long-Term Mooring Lines Response Estimation Considering Wind Sea and Swell
Marina Leivas Simão, Paulo Maurício Videiro, Mauro Costa de Oliveira, Luis Volnei Sudati Sagrilo
OMAE 2020; V02AT02A057https://doi.org/10.1115/OMAE2020-18175
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Topics: Design , Mooring , Sampling methods , Seas , Simulation , Wind
Long-Term Analysis Applied to Mooring Systems Design
Pedro Seabra, Luis Volnei Sudati Sagrilo, Paulo Esperança
OMAE 2020; V02AT02A058https://doi.org/10.1115/OMAE2020-18211
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Topics: Design , Mooring , Offshore platforms
Numerical Simulation of the Domino Effect of Mooring System Failure for an Aquaculture Net Cage Under Waves and Currents
Hung-Jie Tang, Ray-Yeng Yang, Tzu-Chieh Wen, Po-Hung Yeh, Chai-Cheng Huang
OMAE 2020; V02AT02A059https://doi.org/10.1115/OMAE2020-18232
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Topics: Computer simulation , Currents , Failure , Mooring , Morison equation , System failures , Waves
Informing Components Development Innovations for Floating Offshore Wind Through Applied FMEA Framework
Giovanni Rinaldi, Philipp Thies, Lars Johanning, Paul McEvoy, Georgios Georgallis, Anastasia Moraiti, Carlos Cortés Lahuerta, Marijan Vidmar
OMAE 2020; V02AT02A060https://doi.org/10.1115/OMAE2020-18349
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Topics: Cables , Failure mode and effects analysis , Innovation , Mooring , Ocean engineering , Reliability , Wind
Influence of Wind Shear Uncertainty in Long-Term Extreme Responses of an Offshore Monopile Wind Turbine
David Barreto, Madjid Karimirad, Arturo Ortega
OMAE 2020; V02AT02A061https://doi.org/10.1115/OMAE2020-18506
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Topics: Ocean engineering , Offshore wind turbines , Uncertainty , Wind shear , Wind turbines
Investigations Into Fatigue of OPB Loaded Offshore Mooring Chains
Gary H. Farrow, Simon Dimopoulos, Andrew A. Kilner
OMAE 2020; V02AT02A062https://doi.org/10.1115/OMAE2020-18609
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Topics: Chain , Fatigue , Finite element analysis , Mooring , Ocean engineering
On the Use of Artificial Neural Networks for Estimating the Long-Term Mooring Lines Response Considering Wind Sea and Swell
Gabriel Mattos Gonzalez, Marcos Queija de Siqueira, Marina Leivas Simão, Paulo Maurício Videiro, Luis Volnei Sudati Sagrilo
OMAE 2020; V02AT02A063https://doi.org/10.1115/OMAE2020-18868
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Topics: Artificial neural networks , Mooring , Seas , Wind
Development of a Pile Mooring System for Large Scale FSRUs
Taeyoon Park, Junhwan Jeon, Jung Kim, Sangbae Jeon, Bongjae Kim, Dongyeon Lee
OMAE 2020; V02AT02A064https://doi.org/10.1115/OMAE2020-19179
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Topics: Mooring

Risk Analysis and Management

On the Necessity for Minimizing Risk Based Technology Qualification Variability: An Application to Offshore Floating Wind Turbines
S. M. Samindi M. K. Samarakoon, R. M. Chandima Ratnayake
OMAE 2020; V02AT02A065https://doi.org/10.1115/OMAE2020-18139
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Topics: Floating wind turbines , Risk , Failure mechanisms , Mooring
Fire Phenomenon of Natural Gas Leak Accidents on the LNG-Fueled Ship Using Computational Fluid Dynamic
Haris Nubli, Aditya Rio Prabowo, Jung Min Sohn
OMAE 2020; V02AT02A066https://doi.org/10.1115/OMAE2020-18258
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Topics: Accidents , Computational fluid dynamics , Fire , Leakage , Liquefied natural gas , Natural gas , Ships
Risk Assessment and Countermeasure on Drilling and Production Process of Deep Water Gas Hydrate in the South China Sea
Zhu Yuan, Liu Kang, Chan Guoming
OMAE 2020; V02AT02A067https://doi.org/10.1115/OMAE2020-18532
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Topics: China , Countermeasures , Drilling , Manufacturing , Methane hydrate , Risk assessment , Seas , Water
Addressing Uncertainties Within Flow Induced Vibrations in Subsea Piping
Olivier Macchion, Leszek Stachyra, Torfinn Hørte, Charles Renaud-Bezot
OMAE 2020; V02AT02A068https://doi.org/10.1115/OMAE2020-18670
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Topics: Event history analysis , Fatigue failure , Flow (Dynamics) , Statistical distributions , Uncertainty , Underwater pipelines , Vibration
MIL and MIRO Diagrams for Risk-Based Positioning of Drilling Rigs With Dynamic Positioning System
Marcos Coelho Maturana, Victor Rafael Souza, Valentina Clavijo Mesa, Marcelo Ramos Martins, Anderson Takehiro Oshiro, Adriana Miralles Schleder
OMAE 2020; V02AT02A069https://doi.org/10.1115/OMAE2020-18834
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Topics: Drilling rigs , Dynamic positioning systems , Risk , Collisions (Physics) , Vessels , Drilling , Probability , Damage , Decision making , Failure
The Use of Dominance, Influence, Steadiness and Compliance (DISC) Personality Test in the Assessment of Accidents Likelihood on Offshore Drilling Operations
Carlos Henrique Bittencourt Morais, Ulrico Barini Filho, Marcelo Ramos Martins
OMAE 2020; V02AT02A070https://doi.org/10.1115/OMAE2020-18864
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Topics: Accidents , Disks , Human reliability analysis , Underwater drilling
Revisiting the FPSO São Mateus Accident From a Human Reliability Perspective Using Phoenix HRA Methodology
Marilia A. Ramos, Alex Almeida, Marcelo R. Martins
OMAE 2020; V02AT02A071https://doi.org/10.1115/OMAE2020-18911
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Topics: Accidents , FPSO , Human reliability analysis , Ocean engineering , Reliability
Application of Fuzzy Logic and Expert Elicitation for Quantitative Offshore Well Integrity Data Collection
Danilo Taverna Martins Pereira de Abreu, Joaquim Rocha dos Santos, Carlos Henrique Bittencourt Morais, Marcelo Ramos Martins, Danilo Colombo
OMAE 2020; V02AT02A072https://doi.org/10.1115/OMAE2020-18995
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Topics: Data collection , Fuzzy logic , Ocean engineering , Failure data , Cycles , Databases , Event history analysis , Failure , Flow (Dynamics) , Fluids
Development of Accidental Scenarios Involving Human Errors for Risk Assessment in Restricted Waters
Danilo Taverna Martins Pereira de Abreu, Marcos Coelho Maturana, Marcelo Ramos Martins
OMAE 2020; V02AT02A073https://doi.org/10.1115/OMAE2020-18996
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Topics: Errors , Reliability , Risk assessment , Water
Systematic Measures to Cope With Offshore Drilling Hazards: An Interpretive Structural Modeling Approach
Liaqat Ali, Shan Jin, Yong Bai
OMAE 2020; V02AT02A074https://doi.org/10.1115/OMAE2020-19165
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Topics: China , Hazards , Modeling , Safety , Underwater drilling
Barrier Analysis of Emergency Disconnect on DP Mobile Offshore Drilling Units
Haibo Chen, Tommy Bauge, Lorents Reinås, Paul Landeråen
OMAE 2020; V02AT02A075https://doi.org/10.1115/OMAE2020-19184
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Topics: Emergencies , Mobile offshore drilling units
Risk Assessment and Reliability Analysis of Subsea Production Systems
Liaqat Ali, Shan Jin, Yong Bai
OMAE 2020; V02AT02A076https://doi.org/10.1115/OMAE2020-19283
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Topics: Event history analysis , Hazards , Manufacturing systems , Ocean engineering , Risk assessment

Risk Based Maintenance

Cost-Optimal Planning of Inspections and Maintenance of Production Tubings Subject to Scale Deterioration
Akinyemi O. Akinsanya, Jianjun Qin, John D. Sørensen, Michael H. Faber
OMAE 2020; V02AT02A077https://doi.org/10.1115/OMAE2020-18264
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Topics: Inspection , Maintenance
Structural Integrity Management (SIM) via a Digitalized Structural Integrity Compliance System
Sok Mooi Ng, Biramarta Isnadi, Luong Ann Lee, Syahnaz Omar, Siti Nurshamshinazzatulbalqish Saminal, Wan Hariz Fadli Wan Shafie, Riaz Khan
OMAE 2020; V02AT02A078https://doi.org/10.1115/OMAE2020-19064
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Topics: American Petroleum Institute , Computer software , Construction , Databases , Decision making , Design , Failure , Floating structures , Inspection , Maintenance
A Principal Strain Data-Driven Method for Damage Identification of an Offshore Pile Structure
Xingxian Bao, Guanlan Yang, Hongwei Li, Chen Shi
OMAE 2020; V02AT02A079https://doi.org/10.1115/OMAE2020-19284
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Topics: Damage , Ocean engineering
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