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Large Blade Testing Facility LARGE WIND TURBINES. Rahul Yarala Executive Director, Wind Technology Testing Center May 12, 2011. WHY OFFSHORE WIND?. A POWERFUL RESOURCE IN US. Resource near load centers Minimize greenhouse gas emissions from electricity generation
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Large Blade Testing FacilityLARGE WIND TURBINES Rahul Yarala Executive Director, Wind Technology Testing Center May 12, 2011
WHY OFFSHORE WIND? A POWERFUL RESOURCE IN US • Resource near load centers • Minimize greenhouse gas emissions from electricity generation • Minimal water consumption for electricity generation • Energy Independence • Green Jobs and local economic development • Higher Capacity Factors • Low shear and turbulence • Higher wind speeds • Turbines can spin at higher tip speeds and hence higher energy production
CHALLENGES and OPPORTUNITIES • Rotor Blade Structure • New materials • Two-piece • Larger Chords • New Tower concepts • Composite materials • Lighter and corrosion resistance • Drivetrain • Direct drive or low speed • Foundations
CHALLENGES and OPPORTUNITIES • Corrosion protection • Site specific wind data collection and correlation with mesoscale weather prediction models for wind assessment. • Further research and data collection using newer offshore friendly technology like LIDAR, SODAR etc… is very important • Demonstration platforms or prototype farms are required for offshore wind specific technology development and long term cost competitiveness of offshore wind. This is similar to land based turbine testing at NREL and UK’s (public-private) initiative to have 100MW offshore wind farm available for prototyping and testing.
BLADES - Statement of the Problem • Static strength testing and accelerated fatigue testing of wind turbine blades are required for • Turbine certification • Reduce the risk of widespread failures • Improve blade reliability • Reduce COE • Blades over 50m can not be fatigue tested in the United States • Blades 62m long are in production and longer blades are being designed • This project will reduce COE by • Reducing frequency of blade failures • Lowering machine cost • Introducing more efficient blades • Reducing technical and financial risk of large-scale deployment • Providing industry with low cost test facilities to comply with certification requirements and support value engineering Slide courtesy of Jason Cotrell of NREL
Technical Approach Development of Test Equipment • Procuring a state of the art hydraulic based static test system from MTS • Working with MTS to scale up NREL UREX Fatigue Test System • Designing and procuring a new generation of the NREL data acquisition hardware • Developing a new version of data acquisition software Schematic of MTS Static Test System Courtesy of MTS website Slide courtesy of Jason Cotrell of NREL
Static and Fatigue Testing • Latest hydraulic actuators/winches will allow matching various specified bending moment distributions. • Dual-axis resonant test system (NREL patent pending) Picture courtesy of MTS and NREL