Loads and response from steep and breaking waves on monopiles

Similar documents

Technical Writing - A Case Study of Offshore Wind Farms

NUMERICAL SIMULATION OF REGULAR WAVES RUN-UP OVER SLOPPING BEACH BY OPEN FOAM

The DTU 10-MW Reference Wind Turbine

Prediction of airfoil performance at high Reynolds numbers

Complex terrain wind resource estimation with the wind-atlas method: Prediction errors using linearized and nonlinear CFD micro-scale models

EWEA CREYAP benchmark exercises: summary for offshore wind farm cases

Eu-NORSEWInD - Assessment of Viability of Open Source CFD Code for the Wind Industry

Numerical Modelling of Regular Waves Propagation and Breaking Using Waves2Foam

INNWIND.EU Offshore wind energy DTU Contributions to WP4.2 Technology, ecomony, trends and research. Henrik Bredmose Thomas Buhl

System-Level Simulation of Floating Platform and Wind Turbine Using High-Fidelity and Engineering Models

Product Integration of Polymer Solar cells - from Circuitry to Functional Units

WindScanner systems. Vasiljevic, Nikola. Publication date: Document Version Peer reviewed version. Link to publication

Danish Wind Power Research Arranged by the Danish Research Consortium for Wind Energy. Venue Place: Trinity Gl. Færgevej 30, Fredericia

Drivers of cycling demand and cycling futures in the Danish context.

Application of a Tightly-Coupled CFD/6-DOF Solver For Simulating Offshore Wind Turbine Platforms

Offshore Wind Energy: Research needs and Danish competences

HydrOcean, your numerical hydrodynamic partner

SWITCH MODE POWER AMPLIFIERS FOR CURRENT CONTROLLED LOUDSPEAKERS

The use of GPS and SMS data to investigate travel experiences Reinau, Kristian Hegner; Harder, Henrik; Weber, Michael; Jensen, Anders Sorgenfri

Research and Education in the Field of Wind Energy at the Technical University of Denmark

A study of wave forces on offshore platform by direct CFD and Morison equation

Testing of a new morphing trailing edge flap system on a novel outdoor rotating test rig

Danish Wind Industry Annual Event 2014

The long-range WindScanner system how to synchronously intersect multiple laser beams

Model of a flow in intersecting microchannels. Denis Semyonov

New LED Lighting in Display Cases at Rosenborg Castle

WavePiston Project. Structural Concept Development Hydrodynamic Aspects. Preliminary Analytical Estimates. February 2010

Aeroelastic models for wind turbines

CFD Based Air Flow and Contamination Modeling of Subway Stations

Aalborg Universitet. Energy upgrading measures improve also indoor climate Foldbjerg, Peter; Knudsen, Henrik Nellemose. Published in: REHVA Journal

Department of Wind. Energy E Report Experimental and Theoretical Analysis of a Combined Floating Wave and Wind Energy Conversion Platform

Danish Wind Power Research Arranged by the Danish Research Consortium for Wind Energy. Venue Place: Trinity Gl. Færgevej 30, Fredericia

Wave driven wind simulations with CFD

CFD modelling of floating body response to regular waves

Numerical Wave Generation In OpenFOAM R

NUMERICAL INVESTIGATIONS ON HEAT TRANSFER IN FALLING FILMS AROUND TURBULENCE WIRES

How To Run A Cdef Simulation

TIMES demo models. Genikomsakis, Konstantinos N. ; Gargiulo, Maurizio ; Grohnheit, Poul Erik. Publication date: Link to publication

Plast solceller / fremtidens solcelle(r)

Self Financed One Week Training

A moving piston boundary condition including gap flow in OpenFOAM

Recent Advances in Compressed Air Energy Storage and Thermo-Mechanical Electricity Storage Technologies

MODULE VII LARGE BODY WAVE DIFFRACTION

Computational Modeling of Wind Turbines in OpenFOAM

Offshore Wind Turbine Support Structures

Aeroelastic Investigation of the Sandia 100m Blade Using Computational Fluid Dynamics

NUMERICAL ANALYSIS OF THE EFFECTS OF WIND ON BUILDING STRUCTURES

IC3 and IC4 Trains Under Risk of Blocking their Wheels

Tectonic Thinking Beim, Anne; Bech-Danielsen, Claus; Bundgaard, Charlotte; Madsen, Ulrik Stylsvig

TWO-DIMENSIONAL FINITE ELEMENT ANALYSIS OF FORCED CONVECTION FLOW AND HEAT TRANSFER IN A LAMINAR CHANNEL FLOW

Wind Energy Study Programs at Aalborg University. Power Cluster WP 3

Performance Comparison of a Vertical Axis Wind Turbine using Commercial and Open Source Computational Fluid Dynamics based Codes

Offshore Code Comparison Collaboration within IEA Wind Annex XXIII: Phase II Results Regarding Monopile Foundation Modeling

OpenFOAM Workshop. Yağmur Gülkanat Res.Assist.

To conclude with recommendations for a second project phase, where one or more demonstration storage systems will be tested experimentally.

CFD and wave and current induced loads on offshore wind turbines

Use of OpenFoam in a CFD analysis of a finger type slug catcher. Dynaflow Conference 2011 January , Rotterdam, the Netherlands

Elbil - scenarier for dansk vejtransport : Energi, CO2 emission og økonomi?

Results of wake simulations at the Horns Rev I and Lillgrund wind farms using the modified Park model

A Cost- Effective Computational Tool for Offshore Floater Design

The Project Design Document

3. Experimental Results

SmartGrid aktiviteterne på Bornholm

Coupled CFD and Vortex Methods for Modelling Hydro- and Aerodynamics of Tidal Current Turbines and On- and Offshore Wind Turbines

Aalborg Universitet. Fast, Fastere, Agile UCD Pedersen, Tina Øvad; Larsen, Lars Bo. Publication date: 2014

Expanding Energy Access by Scaling Up Energy Efficiency in Sub-Saharan Africa

Fremtidens vindenergi en magisters historie på Risø og DTU

Wave loads on offshore wind turbines

Vedvarende energi, Smart Grids og Japan

Some scientific challenges in aerodynamics for wind turbines

Active learners in sustainable electronics and it

E. Marino 1, C. Lugni 2, G. Stabile 1, C. Borri 1

IEA Wind Task 30 OC4 Project. Offshore Code Comparison Collaboration Continuation

Aalborg Universitet. Publication date: Document Version Også kaldet Forlagets PDF. Link to publication from Aalborg University

Analysis of Floating Offshore Wind Turbine Hydrodynamics Using coupled CFD and Multibody Methods

Development of a Dainish infrastructure for spatial information (DAISI) Brande-Lavridsen, Hanne; Jensen, Bent Hulegaard

CFD: What is it good for?

Simulation of Offshore Structures in Virtual Ocean Basin (VOB)

Quantifying the Influence of Social Characteristics on Accident and Injuries Risk: A Comparative Study Between Motorcyclists and Car Drivers

Aeroacoustic Analogy for the Computation of Aeroacoustic Fields in Partially Closed Domains

F1 Fuel Tank Surging; Model Validation

FLOW CONDITIONER DESIGN FOR IMPROVING OPEN CHANNEL FLOW MEASUREMENT ACCURACY FROM A SONTEK ARGONAUT-SW

Development of work in Call Centres

Prevalence and risk of driving under influence of psychoactive substances: Results from epidemiological studies

Ocean Engineering Program Graduate Curriculum at Texas A&M University

O.F.Wind Wind Site Assessment Simulation in complex terrain based on OpenFOAM. Darmstadt,

-1- State-of-the-art and Development Needs of Simulation Codes for Offshore Wind Turbines

Fluid structure interaction of a vibrating circular plate in a bounded fluid volume: simulation and experiment

Which strategy to move the mesh in the Computational Fluid Dynamic code OpenFOAM

Computational Fluid Dynamics in Automotive Applications

STUDY OF DAM-RESERVOIR DYNAMIC INTERACTION USING VIBRATION TESTS ON A PHYSICAL MODEL

FLUID MECHANICS IM0235 DIFFERENTIAL EQUATIONS - CB _1

Beam-Steerable Microstrip-Fed Bow-Tie Antenna Array for Fifth Generation Cellular Communications Ojaroudiparchin, Naser; Shen, Ming; Pedersen, Gert F.

DEVELOPMENT AND APPLICATIONS OF TUNED/HYBRID MASS DAMPERS USING MULTI-STAGE RUBBER BEARINGS FOR VIBRATION CONTROL OF STRUCTURES

NUMERICAL ANALYSIS OF WELLS TURBINE FOR WAVE POWER CONVERSION

Extension of the OpenFOAM CFD tool set for modelling multiphase flow

FLOWSTAR-Energy Validation NoordZee Wind Farm

International Journal of Innovative Research in Science, Engineering and Technology Vol. 2, Issue 5, May 2013

Analysis of Near Field in Front of a Piston Wavemaker and MIKE 21 BW s Handling of Surfzone. by Anders Wedel Nielsen Hans Jacob Simonsen

Wind resources and wind turbine wakes in large wind farms. Professor R.J. Barthelmie Atmospheric Science and Sustainability

Transcription:

Downloaded from orbit.dtu.dk on: Jan 12, 2016 Loads and response from steep and breaking waves on monopiles Bredmose, Henrik; Schløer, Signe; Sahlberg-Nielsen, Lasse; Slabiak, Peter ; Larsen, Torben J.; Kim, Taessong ; Paulsen, Bo Terp; Bingham, Harry B.; Jacobsen, Niels Gjøl; Tornfeldt Sørensen, Jacob; Schlütter, Flemming ; Nielsen, Anders Wedel Publication date: 2013 Link to publication Citation (APA): Bredmose, H., Schløer, S., Sahlberg-Nielsen, L., Slabiak, P., Larsen, T. J., Kim, T.,... Nielsen, A. W. (2013). Loads and response from steep and breaking waves on monopiles [Sound/Visual production (digital)]. Danish Wind Power Research 2013, Fredericia, Denmark, 27/05/2013 General rights Copyright and moral rights for the publications made accessible in the public portal are retained by the authors and/or other copyright owners and it is a condition of accessing publications that users recognise and abide by the legal requirements associated with these rights. Users may download and print one copy of any publication from the public portal for the purpose of private study or research. You may not further distribute the material or use it for any profit-making activity or commercial gain You may freely distribute the URL identifying the publication in the public portal? If you believe that this document breaches copyright please contact us providing details, and we will remove access to the work immediately and investigate your claim.

Loads and response from steep and breaking waves on monopiles With contributions from Henrik Bredmose Signe Schløer Lasse Sahlberg-Nielsen Peter Slabiak Torben J. Larsen Taessong Kim Bo Terp Paulsen J Harry Bingham Niels Gjøl Jacobsen Jacob Tornfeldt Sørensen Henrik Bredmose Associate prof, DTU Wind Energy Flemming Schlütter Anders Wedel Nielsen Statkraft

Hydrodynamic loads Simplest: Linear wave kinematics and Morison equation Better: Fully nonlinear wave kinematics and Morison equation Advanced: CFD and coupled CFD Zang and Taylor (2010)

Wave loads on offshore wind turbines ForskEL. DTU Wind, DHI, DTU MEK. 2010-2013. Task D: Task A: Physical validation test Boundary conditions for phase resolving wave models Task C: Task B: Aero-elastic response to fully nonlinear waves CFD computation of monopile loads

Forces from a fully nonlinear potential flow solver OceanWave3D, Engsig-Karup et al (2009) Allan Engsig-Karup, Harry Bingham and Ole Lindberg

Response in bottom of tower Fully nonlinear waves versus linear waves Schløer et al (OMAE 2012)

The OC4 jacket Jacket and reference turbine modelled in Hawc2. Fully nonlinear wave loads. Storm sea state. Turbine standstil. Severe ringing/impulsive excitation. Torben Juul Larsen Taesong Kim Larsen et al Europ. Offsh. Wind 2011

Wave loads on offshore wind turbines ForskEL. DTU Wind, DHI, DTU MEK. 2010-2013. Task D: Task A: Physical validation test Boundary conditions for phase resolving wave models Task C: Task B: Aero-elastic response to fully nonlinear waves CFD computation of monopile loads

The OpenFOAM CFD solver Open source CFD toolbox Vast attention during last 3 years This study: interfoam solver 3D incompressible Navier-Stokes two phases (water and air) VOF treatment of free surface Waves2foam wave generation toolbox has been developed and validated (Niels Gjøl Jacobsen PhD thesis 2011; Paper in Int. J. Num. Meth. Fluids) OMAE2010

Platform height of 8.96m t=58.8s Bredmose & Jacobsen OMAE 2011

Platform height of 8.96m t=58.9s

Platform height of 8.96m t=59.0s

Platform height of 8.96m t=59.1s

Platform height of 8.96m t=59.2s

Platform height of 8.96m t=59.3s

Platform height of 8.96m t=59.4s

Platform height of 8.96m t=59.5s

Platform height of 8.96m t=59.6s

Platform height of 8.96m t=59.7s

Platform height of 8.96m t=59.8s

Platform height of 8.96m t=59.9s

Platform height of 8.96m t=60.0s

Platform height of 8.96m t=60.1s

Platform height of 8.96m t=60.2s

Platform height of 8.96m t=60.3s

Platform height of 8.96m t=60.4s

Platform height of 8.96m t=60.5s

What is ringing? Excitation of natural frequency by higher-harmonic forcing from nonlinear waves ^ F fnatural f fw 2fw 3fw

Detailed calculation of forces from steep regular waves secondary load cycle Bo Terp Paulsen

Third-harmonic force compared to FNV theory Terp Paulsen et al IWWWFB 2012

Coupling of OpenFOAM and OceanWave3D Compute outer flow field with potential flow wave model Compute inner field with wave-structure interaction with CFD-VOF model Terp Paulsen et al (2012)

Coupling of OpenFOAM and OceanWave3D Terp Paulsen et al (2012)

Coupling of OpenFOAM and OceanWave3D Terp Paulsen et al (2012)

Coupling of OpenFOAM and OceanWave3D Terp Paulsen et al (2012)

Wave loads on offshore wind turbines ForskEL. DTU Wind, DHI, DTU MEK. 2010-2013. Task D: Task A: Physical validation test Boundary conditions for phase resolving wave models Task C: Task B: Aero-elastic response to fully nonlinear waves CFD computation of monopile loads

Wave loads Task D Physical validation test New tests at DHI with a rigid and a flexible structure DHI: Flemming Schlütter Anders Wedel Nielsen Jacob Tornfeldt Sørensen DTU: Henrik Bredmose Torben Larsen Signe Schløer Bo Terp Paulsen Harry Bingham

Wave loads Task D Physical validation test PVC pipe Scale 1:80 Two masses right natural frequencies (1,2)

Experimental setup side-view top-view of wave gauges

Results and brief analysis for flexible pile Irregular JONSWAP waves, unidirectional h=20m Tp=14s Hs=11m Free surface elevation 0.15m from pile Measured inline force on pile Acceleration of top point Displacement of top point

Results and brief analysis

continuous forcing of 1st natural mode Impulsive load from breaking from wave-nonlinearity /near breaking wave

Which waves give the largest accelerations? acceleration Fx in top accelerometer [m/s2] Bredmose et al (OMAE 2013)

Which waves give the largest accelerations? Bredmose et al (OMAE 2013)

Numerical reproduction of experiments FEM model Linear wave detection Nonlinear wave transformation Force model

Wave transformation

Response, h=40.8 m

Response, h=20.8 m

Wave loads on offshore wind turbines ForskEL. DTU Wind, DHI, DTU MEK. 2010-2013. Task D: Task A: Physical validation test Boundary conditions for phase resolving wave models Experiments with flexible monopile Impulsive response Numerical reproduction Higher-harmonic loads (ringing loads) Coupling of pot flow model and CFD Structural excitation from nonlinear waves Task C: Task B: Aero-elastic response to fully nonlinear waves CFD computation of monopile loads

Loads and response from steep and breaking waves on monopiles Henrik Bredmose, hbre@dtu.dk Associate prof, DTU Wind Energy