A Brief Introduction and Discussion of R&D



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Transcription:

: A Brief Introduction and Discussion of R&D, Denmark

We have developed the world s only offshore-proven, grid-connected wind and wave power plant.

FPP s P37 Test Platform Disconnectable Video 3

Smoothed Power Output Video

Where to deploy the commercial devices? Current focus Area of interest

FPP: From P37 to P80 up to 2.6 MW wave power up to 5 MW Wind P37 Site-Specific Design P80 Designed for Probable Commercial Sites 80 m wide Min water depth 45 m

TRL is very linear

Scaled up Approach The Way We Develop Concept tests Design Optimisation Numerical modeling & engineering Commercial Prototypes & Small Arrays Commercial wave-basin and wave-flume tests Dry tests 4 Scaled p37 offshore tests Large scale P80 commercial arrays 8

Sub project Numerical models 1) Floater Waves PTO stationary platform 2) Platform - mooring wind turbines 3) Structural 4) Platform including WECS and mooring - Vaning due to current and waves 9

Sub project Numerical models 1) Floater Waves PTO stationary platform a. b. In partnership with Fritz Schur Energy c. Intro 10

Sub project Numerical models 1) Floater Waves PTO stationary platform 2) Platform - mooring wind turbines 3) Structural 4) Platform including WECS and mooring - Vaning due to current and waves 11

Sub project Numerical models 2) Platform - mooring wind turbines HAWC2-WAMIT coupling In partnership with DTU-Wind Energy (formerly Risø) Excludes WECs and their PTOs 1 2 & 5 & 3 4 6 Aerodynamic model: wake expansion, swirl, dynamic inflow, skew inflow, shear effect on induction Structural Model: includes flexible rotating bodies which include masses, and inertial, centrifugal and gyroscopic forces. Control Model Hydyrodynamic Model: DLL interface to WAMIT 7 Mooring Model: Fully dynamic 12

Sub project Numerical models 1) Floater Waves PTO stationary platform 2) Platform - mooring wind turbines 3) Structural 4) Platform including WECS and mooring - Vaning due to current and waves 13

Sub project Numerical models 3. Structural Finite Element Fatigue Analysis Stress and Strains Materials reduction Two stages: 1. Overall Structure 2. Key Components 14

Sub project Numerical models 1) Floater Waves PTO stationary platform 2) Platform - mooring wind turbines 3) Structural 4) Platform including WECS and mooring - Vaning due to current and waves 15

Sub project Numerical models 4) Platform including WECS and mooring - Vaning due to current and waves Turning Moments from Waves VS Turning Moments from Current Drag Force Turning Moment Need: 1. Wave: a) Distribution of force within chamber and on hinge due to WEC operating 2. Current a) Cross Section at different angles b) Drag Coefficient 16

Key Areas for Development in UK for FPP Classification Certification Due Diligence Environmental Data Gathering Value Chain Development Confidence in the industry!

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