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Proceedings Papers
In This Volume
Volume 3: Structures, Safety, and Reliability
Structures, Safety, and Reliability
Abnormal or Rogue Waves
Comparison of Temporal and Spatial Statistics of Nonlinear Waves
OMAE 2019; V003T02A001https://doi.org/10.1115/OMAE2019-95357
Topics:
Nonlinear waves
,
Statistics
Extending Integrability of Nonlinear Water Wave Equations: Nonlinear Fourier Analysis of Breather Packets and Rogue Waves at Higher Order
OMAE 2019; V003T02A003https://doi.org/10.1115/OMAE2019-95543
Topics:
Aircraft
,
Boundary-value problems
,
Dimensions
,
Fourier analysis
,
Nonlinear waves
,
Ocean waves
,
Radar
,
Seas
,
Solitons
,
Synthetic aperture radar
Predicting Extreme Waves From Wave Spectral Properties Using Machine Learning
OMAE 2019; V003T02A005https://doi.org/10.1115/OMAE2019-96061
Topics:
Machine learning
,
Waves
,
Probability
,
Seas
,
Statistics
,
Computer simulation
,
Nonlinear waves
,
Oceans
,
Spectra (Spectroscopy)
Nonlinear Airy Wave Pulses on the Sea Surface
OMAE 2019; V003T02A007https://doi.org/10.1115/OMAE2019-96298
Topics:
Seas
,
Waves
,
Stability
,
Water waves
,
Wave packets
,
Shapes
,
Water
,
Energy dissipation
,
Modeling analysis
,
Schrödinger equation
Collision and Crashworthiness
Enhancement of Structural Redundancy of Hull Structure in Accidental Condition by Applying Highly Ductile Steel
OMAE 2019; V003T02A012https://doi.org/10.1115/OMAE2019-95912
Topics:
Collisions (Physics)
,
Hull
,
Redundancy (Engineering)
,
Steel
,
Ferrites (Magnetic materials)
,
Ductility
,
Ships
,
Computer simulation
,
Optimization
,
Petroleum
Data-Driven Models for Marine Structures
Squall Detection and Analysis From Historical Satellite Data
OMAE 2019; V003T02A017https://doi.org/10.1115/OMAE2019-96549
Topics:
Satellites
,
Design
,
Mooring
,
Storms
,
Locations
,
Ships
,
Shorelines
,
Water
Extreme Loading and Responses
Comparison of the Environmental Contour Method and Response-Based Analysis Using Response Emulator for Estimating Extreme Ship Responses
OMAE 2019; V003T02A019https://doi.org/10.1115/OMAE2019-95098
Topics:
Event history analysis
,
Machine learning
,
Marine structures
,
Seas
,
Ships
,
Significant wave heights
,
Stress
,
Structural response analysis
,
Tankers
,
Time series
Wave Load and Response Predictions Combining HOSM, CFD and Machine Learning
Jan Oberhagemann, Jan Kaufmann, Anna Kringlen Ervik, Odin Gramstad, Jens Bloch Helmers, Francois-Xavier Sireta
OMAE 2019; V003T02A023https://doi.org/10.1115/OMAE2019-95352
Topics:
Computational fluid dynamics
,
Machine learning
,
Stress
,
Waves
Experimental Assessment of Form Based Approach for Predicting Extreme Value Distribution of Hull Girder Bending Moment in a Ship
OMAE 2019; V003T02A024https://doi.org/10.1115/OMAE2019-95389
Topics:
Girders
,
Hull
,
Ships
,
Waves
,
Computational fluid dynamics
,
Finite element analysis
,
Statistics
,
Computer simulation
,
Containers
,
Model basin
Evaluation of an Equivalent Design Wave Method to Define Lifetime Combined Loading Scenarios for Trimarans
OMAE 2019; V003T02A025https://doi.org/10.1115/OMAE2019-95497
Topics:
Design
,
Waves
,
Vessels
,
Hull
,
Acceptance criteria
,
Compliance
,
Finite element model
,
Reliability
,
Risk
,
Ships
Analysis of Fatigue Life of Ship Structure Under the Non-Linear Slamming Load
OMAE 2019; V003T02A028https://doi.org/10.1115/OMAE2019-95781
Topics:
Fatigue analysis
,
Ships
,
Stress
,
Fatigue damage
,
Computational methods
,
Fatigue
,
Fatigue life
,
Hull
,
Waves
,
Inflow
A New Approach for Environmental Contour and Multivariate De-Clustering
OMAE 2019; V003T02A030https://doi.org/10.1115/OMAE2019-95993
Topics:
Computation
,
Degrees of freedom
,
Dimensions
,
Reliability
,
Seas
,
Significant wave heights
,
Storms
,
Waves
,
Wind
Experimental Assessment of Vertical Shear Force and Bending Moment in Severe Sea Conditions
OMAE 2019; V003T02A031https://doi.org/10.1115/OMAE2019-96272
Topics:
Seas
,
Shear (Mechanics)
,
Waves
,
Ships
,
Stress
,
Hull
,
Sensors
,
Wavelength
,
Accelerometers
,
Computation
Non-Repeatability, Scale- and Model Effects in Laboratory Measurement of Impact Loads Induced by an Overtopped Bore on a Dike Mounted Wall
Maximilian Streicher, Andreas Kortenhaus, Corrado Altomare, Steven Hughes, Krasimir Marinov, Bas Hofland, Xuexue Chen, Tomohiro Suzuki, Lorenzo Cappietti
OMAE 2019; V003T02A032https://doi.org/10.1115/OMAE2019-96703
Topics:
Dikes (Engineering)
,
Levees
,
Stress
,
Engineering prototypes
,
Flow (Dynamics)
,
Force measurement
,
Water
Fatigue and Fracture Reliability
On Calculating the Crack Growth Within a Single Load-Dwell-Unload Cycle for Metal Structures
OMAE 2019; V003T02A036https://doi.org/10.1115/OMAE2019-95327
Topics:
Cycles
,
Fatigue life
,
Fracture (Materials)
,
Metalwork
,
Seas
,
Stress
,
Submersibles
Computational Fatigue Assessment of Chains Working in Twisted Conditions
OMAE 2019; V003T02A038https://doi.org/10.1115/OMAE2019-96000
Topics:
Chain
,
Fatigue
,
Mooring
,
Failure
,
Fatigue analysis
,
Finite element analysis
,
Stress
,
Cables
,
Cycles
,
Engineers
Multiobjective Reliability-Based Design of Ship Structures Subjected to Fatigue Damage and Compressive Collapse
OMAE 2019; V003T02A040https://doi.org/10.1115/OMAE2019-96666
Topics:
Collapse
,
Design
,
Fatigue damage
,
Reliability
,
Ships
,
Structural elements (Construction)
,
Accounting
,
Deflection
,
Genetic algorithms
,
Hull
Probabilistic and Spectral Wave Models
Estimation and Comparison of Accuracy in Various Data Resolutions on Optimal Ship Routing Across the North Pacific Ocean
OMAE 2019; V003T02A044https://doi.org/10.1115/OMAE2019-95173
Topics:
North Pacific Ocean
,
Ships
,
Databases
,
Meteorology
,
Computer simulation
,
Containers
,
Resolution (Optics)
,
Seas
,
Simulation results
,
Surface roughness
Comparison of VOS and ERA-Interim Wave Data
OMAE 2019; V003T02A045https://doi.org/10.1115/OMAE2019-95287
Topics:
Databases
,
Electromagnetic scattering
,
Errors
,
Radiation scattering
,
Scattering (Physics)
,
Significant wave heights
,
Statistics
,
Vessels
,
Waves
Optimal Methods for Estimating the JONSWAP Spectrum Peak Enhancement Factor From Measured and Hindcast Wave Data
OMAE 2019; V003T02A046https://doi.org/10.1115/OMAE2019-95451
Topics:
Waves
,
Seas
,
Design
,
Resolution (Optics)
,
Physics
,
Shapes
,
Significant wave heights
,
Spectra (Spectroscopy)
,
Time series
Nonlinear Fourier Analysis Algorithm and Models for Water Waves in Terms of Surface Elevation, Amplitude Modulations
OMAE 2019; V003T02A047https://doi.org/10.1115/OMAE2019-95546
Topics:
Algorithms
,
Fourier analysis
,
Water waves
,
Waves
,
Water
,
Radar
,
Modeling
,
Solitons
,
Synthetic aperture radar
,
Aircraft
A Benchmarking Exercise on Estimating Extreme Environmental Conditions: Methodology and Baseline Results
Andreas F. Haselsteiner, Ryan G. Coe, Lance Manuel, Phong T. T. Nguyen, Nevin Martin, Aubrey Eckert-Gallup
OMAE 2019; V003T02A049https://doi.org/10.1115/OMAE2019-96523
Topics:
Construction
,
Design
,
Marine structures
,
Reliability
,
Uncertainty
,
Wind waves
Probabilistic Response Models
A Monte Carlo Based Simulation Method for Damage Stability Problems
OMAE 2019; V003T02A051https://doi.org/10.1115/OMAE2019-95295
Topics:
Damage
,
Simulation
,
Stability
Optimal Control for Response Reduction of Single Hinged Articulated Tower Using MR-Damper
OMAE 2019; V003T02A052https://doi.org/10.1115/OMAE2019-96076
Topics:
Dampers
,
Optimal control
,
Control systems
,
Buoyancy
,
Control equipment
,
Damage
,
Damping
,
Design
,
Feedback
,
Offshore structures
Reliability of Marine Structures
Reliability of Mooring and Riser Systems
An Efficient System Reliability Approach Against Mooring Overload Failures
OMAE 2019; V003T02A057https://doi.org/10.1115/OMAE2019-95048
Topics:
Failure
,
Mooring
,
Reliability
,
Probability
,
Density
,
Floating structures
,
Gulf of Mexico
,
Ocean engineering
,
Seas
,
Simulation
Mean Load Impact on Mooring Chain Fatigue Capacity: Lessons Learned From Full Scale Fatigue Testing of Used Chains
OMAE 2019; V003T02A058https://doi.org/10.1115/OMAE2019-95083
Topics:
Chain
,
Fatigue
,
Fatigue testing
,
Mooring
,
Stress
,
Corrosion
,
Design
,
Fatigue limit
,
Fracture (Materials)
,
Life extension
Finite Element Analysis of the Effect of Twist on Chain Fatigue Performance
OMAE 2019; V003T02A059https://doi.org/10.1115/OMAE2019-95276
Topics:
Chain
,
Fatigue
,
Finite element analysis
,
Fatigue life
,
Plasticity
,
Stress
,
Deformation
,
Mooring
,
Storms
,
Tension
Fatigue Tests on Corroded Mooring Chains Retrieved From Various Fields in Offshore West Africa and the North Sea
Kai-tung Ma, Øystein Gabrielsen, Zhen Li, David Baker, Aifeng Yao, Pedro Vargas, Meng Luo, Amir Izadparast, Alberto Arredondo, Linfang Zhu, Nina Sverdlova, Ingrid Skutle Høgsæt
OMAE 2019; V003T02A060https://doi.org/10.1115/OMAE2019-95618
Topics:
Chain
,
Fatigue testing
,
Mooring
,
North Sea
,
Ocean engineering
,
Fatigue life
,
Fatigue
,
Life extension
,
Corrosion
,
Tension
Review and Comparison of Collated Offshore Mooring Chain Fatigue Test Data
OMAE 2019; V003T02A062https://doi.org/10.1115/OMAE2019-95875
Topics:
Chain
,
Fatigue
,
Fatigue testing
,
Finite element analysis
,
Mooring
,
Ocean engineering
Development of a New, Correlated FEA Method of Assessing Mooring Chain Fatigue
OMAE 2019; V003T02A063https://doi.org/10.1115/OMAE2019-95882
Topics:
Chain
,
Fatigue
,
Finite element analysis
,
Mooring
Fatigue Performance of High Strength and Large Diameter Mooring Chain in Seawater
OMAE 2019; V003T02A064https://doi.org/10.1115/OMAE2019-95984
Topics:
Chain
,
Fatigue
,
Mooring
,
Seawater
,
Steel
,
Fatigue design
,
Fatigue testing
,
Fracture (Materials)
,
Tension
,
American Petroleum Institute
Assessment of the Reliability of the Moorings of a Floating Structure Against the Extreme Cyclone Hazard
OMAE 2019; V003T02A065https://doi.org/10.1115/OMAE2019-96032
Topics:
Floating structures
,
Hazards
,
Mooring
,
Reliability
,
Probability
,
Vessels
,
Databases
,
Simulation
,
Fittings
,
FPSO
Fatigue of Mooring Chains Connected to Offshore Floating Structures Considering Out of Plane Bending Effects
OMAE 2019; V003T02A067https://doi.org/10.1115/OMAE2019-96114
Topics:
Chain
,
Fatigue
,
Floating structures
,
Mooring
,
Ocean engineering
,
Design
,
Bearings
,
Friction
,
Rods
,
Bending (Stress)
Fatigue Assessment of “Corroded” Mooring Chain
David A. Baker, Zhen Li, Sue Wang, Xiying Zhang, Yunliang Shao, Harry Li, Xiaoqin Zhan, Linfang Zhu, Xing (Terry) Tao
OMAE 2019; V003T02A068https://doi.org/10.1115/OMAE2019-96191
Topics:
Chain
,
Fatigue
,
Mooring
,
Fatigue testing
,
Fatigue life
,
Finite element analysis
,
Inspection
,
Teams
,
Consulting practices
,
Corrosion
Extreme Value Estimation of Mooring Lines Top Tension
OMAE 2019; V003T02A069https://doi.org/10.1115/OMAE2019-96210
Topics:
Design
,
Mooring
,
Simulation
,
Tension
Reliability of Renewable Energy Systems
Sensitivity Analysis of a Bottom Fixed Offshore Wind Turbine Using the Environmental Contour Method
OMAE 2019; V003T02A071https://doi.org/10.1115/OMAE2019-95390
Topics:
Offshore wind turbines
,
Sensitivity analysis
,
Seas
,
Dynamic response
,
Design
,
Probability
,
Waves
,
Wind
,
Dynamics (Mechanics)
,
Marine structures
Structural Safety Assessment of Marine Operations From a Long-Term Perspective: A Case Study of Offshore Wind Turbine Blade Installation
OMAE 2019; V003T02A074https://doi.org/10.1115/OMAE2019-96686
Topics:
Blades
,
Offshore wind turbines
,
Safety
,
Ocean engineering
,
Probability
,
Seas
,
Failure
,
Structural failures
,
Crane barges
,
Damage
Risk Analysis and Management
Towards Implementing Condition-Based Maintenance (CBM) Policy for Offshore Blowout Preventer (BOP) System
OMAE 2019; V003T02A076https://doi.org/10.1115/OMAE2019-95539
Topics:
Maintenance
,
Ocean engineering
,
Downtime
,
Petroleum industry
,
Safety
,
Computer software
,
Design
,
Drilling
,
Fault diagnosis
,
Hardware
On Disaster Risk Reduction in Norwegian Oil and Gas Industry Through Life-Cycle Perspective
OMAE 2019; V003T02A077https://doi.org/10.1115/OMAE2019-95622
Topics:
Cycles
,
Disasters
,
Petroleum industry
,
Risk reduction
,
Accidents
,
Risk
,
Gas industry
,
Life cycle assessment
,
Ocean engineering
,
Risk management
Analysing Dependent Failures in a Bayesian Belief Network
OMAE 2019; V003T02A078https://doi.org/10.1115/OMAE2019-95853
Topics:
Failure
Risk Assessment in Offshore Salt Caverns to Store CO2
Marco Aurelio Pestana, Carlos Henrique Bittencourt Morais, Alvaro Maia da Costa, Camila Brandão, Marcelo Ramos Martins
OMAE 2019; V003T02A080https://doi.org/10.1115/OMAE2019-96250
Topics:
Carbon dioxide
,
Ocean engineering
,
Risk assessment
,
Methane
,
Reservoirs
,
Risk analysis
,
Water
Human Reliability Analysis of Ship Maneuvers in Harbor Areas
OMAE 2019; V003T02A081https://doi.org/10.1115/OMAE2019-96251
Topics:
Human reliability analysis
,
Ships
,
Errors
,
Navigation
,
Accidents
,
Collisions (Physics)
,
Seas
,
Water
,
Cycles
,
Damage
The Influence of Non-Prescriptive Legislation in the Evolution of Offshore Well Integrity Practices: An Exploratory Review
Carlos H. B. Morais, Danilo T. M. P. Abreu, Joaquim Santos, Marcos C. Maturana, Danilo Colombo, Marcelo R. Martins
OMAE 2019; V003T02A082https://doi.org/10.1115/OMAE2019-96269
Topics:
Ocean engineering
,
Health and safety
,
Risk analysis
,
Accidents
,
Cycles
,
Design
,
Environmental health and safety
,
Regulations
,
Risk assessment
,
Safety
Risk Based Maintenance
Asset Integrity Control: Prioritization of Offshore Topside Flange Openings During Preventive Maintenance Shutdowns
OMAE 2019; V003T02A085https://doi.org/10.1115/OMAE2019-96576
Topics:
Flanges
,
Maintenance
,
Ocean engineering
,
Inspection
,
Failure
,
Risk
,
Accidents
,
Crude oil
,
Nondestructive evaluation
,
Optical quality control
Structural Analysis and Optimization
Analytical Methods for Preliminary Design of Anchor Flanges for Subsea Structures
Sabesan Rajaratnam, T. Sriskandarajah, Daryl Clayton, Graeme Roberts, Vincent Loentgen, Carlos Charnaux
OMAE 2019; V003T02A086https://doi.org/10.1115/OMAE2019-95051
Topics:
Analytical methods
,
Design
,
Flanges
,
Ocean engineering
,
Stress
Simplifying Methods for Fatigue Analysis of Risers
OMAE 2019; V003T02A087https://doi.org/10.1115/OMAE2019-95386
Topics:
Fatigue analysis
,
Pipeline risers
,
Risers (Casting)
,
Steel catenary risers
,
Seas
,
Damage
,
Fatigue damage
,
Vessels
,
Design
,
Electrical discharge machining
Study on the Effect of Impact Load Generated From Pile Driving on Adjacent Berthing Structure
OMAE 2019; V003T02A092https://doi.org/10.1115/OMAE2019-96092
Topics:
Stress
,
Vibration
,
Gates (Closures)
,
Soil
,
Construction
,
Damping
,
Dynamic testing (Materials)
,
Machinery
,
Marine transportation
,
Modeling
Validation of External Moment Determination for the Shaft-Line of the S.A. Agulhas II
OMAE 2019; V003T02A095https://doi.org/10.1115/OMAE2019-96746
Topics:
Algorithms
,
Antarctic region
,
Errors
,
Ice
,
Measurement systems
,
Modal analysis
,
Propellers
,
Stress
,
Torque
,
Torque measurement
Ultimate Strength
Numerical and Experimental Research on Residual Ultimate Strength of Hull Plates Under Uniaxial Cyclic Loads
OMAE 2019; V003T02A096https://doi.org/10.1115/OMAE2019-95226
Topics:
Hull
,
Plates (structures)
,
Stress
,
Tensile strength
,
Damage
,
Ships
,
Crack propagation
,
Finite element methods
,
Low cycle fatigue
,
Numerical analysis
Study on Residual Strength of Egg-Shaped Pressure Shell With Local Damage
OMAE 2019; V003T02A097https://doi.org/10.1115/OMAE2019-95456
Topics:
Damage
,
Pressure
,
Shells
,
Buckling
,
Deformation
,
Stability
,
Accidents
,
Bionics
,
Collisions (Physics)
,
Computer software
Well Integrity and Reliability Assessment
Tethered BOP Stacks: Performance and Monitoring
OMAE 2019; V003T02A102https://doi.org/10.1115/OMAE2019-95523
Topics:
Drilling
,
Fatigue
,
Monitoring systems
,
Ocean engineering
,
Remotely operated vehicles
,
Seabed
,
Soil
,
Stability
,
Stiffness
,
Tension
Wellhead Fatigue: Benefits of Structural Reliability Analysis Applied to Groups of Wells
Torfinn Hørte, Michael Macke, Andreas Buvarp Aardal, Lorents Reinås, Pål Bjønnes, Erik Kristian Frimanslund
OMAE 2019; V003T02A103https://doi.org/10.1115/OMAE2019-96214
Topics:
Event history analysis
,
Fatigue
,
Wells
Well Integrity: Preliminary Risk Analysis for Different Well Life Cycle Phases
OMAE 2019; V003T02A104https://doi.org/10.1115/OMAE2019-96280
Topics:
Cycles
,
Risk analysis
,
Risk
,
Flow (Dynamics)
,
Failure
,
Wells
,
Accidents
,
Construction
,
Damage
,
Design