Generator systems for WED Jochen Bard, Peter Kracht; Fraunhofer IWES

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WP 3 PTO Systems Generator systems for WED Jochen Bard, Peter Kracht; Fraunhofer IWES

Overview Design of rotating generator system Use case ¼ OWC Simulation technologies Ongoing Research on linear generators

Generator system design Key part / Impact on: Reliability, Efficieny, O&M costs etc. => Project success depends on good generator design! Research aims at: Knowledge base on requirements and characteristics Improved design process Simulation technologies etc Horn s ref Windpark Horns Rev (source: Wikipedia)

Generator system design Marine Environment Maintenance. Requirements on generator system control Control Generator system Mooring Grid connection Turbine Hull

Generator system design Design process Tools: Knowledge base, Simulation software, HIL tests etc.

Generator system design Impulse Turbine Low operational speed, High starting torque, High efficiency over wide flow range Expectable power range 0.5 1 MW Characteristics of an example air turbine Structural integration Turbine characteristics Generic requirements: Variable speed operation Low operational speeds Possibly no gear box High part load efficiency High overload capacity High mechanical reliability... Similar requirements for other frequently used turbine types

Generator system design Candidate systems Doubly fed induction generator (DFIG) Asynchronous generators (ASG) Permanent magnet synchronous generators (PMG) Separate excited synchronous generators (SG) Control G frequency converter generator system

Generator system design Efficiency Overload Capacity Control time constants ~ 90 95% (full load) Torque_max/ rated ~ 2 4 2..20ms Power factor 0 1 Independently controllable Fault ridethrough Transient short circuit torques Performance of FC generator systems Good performance Up to 15 times the rated torque Torque vs speed curve (source: DiracDelta)

Generator system design Benchmarking of generator systems DFIG ASG PMG SG Efficiency (full load) +++ ++ ++ Efficiency (part load) ++ ++ Maintenance (slip ring) + + + Investment costs + + ( magnets?) + Reliability (slip ring) ++ ++ + (?) Range of rated speeds +++ ++ Availability + Comparison of generator systems at 1MW rated power DFIG no option due to slip ring wear out ASG transitional technology, demonstration projects SG & PMG most promising for future full scale WECs

Use case ¼ scale OWC CORES EU / FP7 Project (source: HMRC)

Use case ¼ scale OWC (oebuoy) (source: OceanEnergy Ltd.) Device characteristics Requirements from dynamic simulations Generator specifications OWC Floating structure Backward Bent Duct ¼ scale Impulse Turbine Rated power: 11kW Rated speed: 785 RPM Operating speed: 300 1300 Run away speed: 1600 RPM Overload capacity: 20% PMG turned down mainly due to delivery time and costs! 8 pole Asynchronous generator Rated power 11kW Overload capacity 300% Rated speed: 769RPM Operating speed: 0 3000 RPM Marine version (certified by DNV, GL) Standard frequency converter (IP21)

Usecase¼ scale OWC OEBuoy in storm event (source: OceanEnergy LTD.) Results of 3 month sea trial period No mechanical or electrical faults in fc generator system 100% availability Peak power up to 25kW delivered to the onboard grid 900 800 700 600 500 400 300 200 100 0 Drehzahl drehmoment verlauf 1 113 225 337 449 561 673 785 897 1009 1121 1233 1345 1457 1569 1681 1793 1905 2017 2129 2241 2353 2465 2577 2689 2801 2913 Measured data from OEBuoy in operation May 17th, 2011 Lessons learned Starting torque underestimated Hardware in the Loop test significantly reduced comissioning time Design process would significantly benefit from further simulation! FC_SPEED [RPM] FC_TORQUE [Nm]

Simulation technologies G Modelling by set of characteristic curves, limits Suitable for investigations on: Control schemes Annual yield PTO hull interaction Generator system specifications. Sufficient model grade for most use cases Torque limit Max speed Control response time.

Simulation technologies Hull Turbine Integration in Wave to Wire model Generator system Physical connection Signal path Control Grid Connection Tools: Adams Matlab/Simulink Modelica.

Ongoing research Matlab/Simulink model of PTO and hydrodynamics Wavestar (SDWED) Aiming at investigations on PTO system layout and control schemes

Ongoing research Linear generator technologies NEMOS WEC (source: Nemos)

Funded by The International Research Alliance

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