The Odyssey of Ulysses: Mobile Laboratory For Testing Wind Turbines Madrid, 24-25 Enero 2006
2 Plan -Introduction to E2Q -The challenge of E2Q: ULYSSES -The real-life tests on Wind Turbines -Conclusions
3 Plan -Introduction to E2Q -The challenge of E2Q: ULYSSES -The real-life tests on Wind Turbines -Conclusions
4 Energy to Quality, S.L. is created from Ingepower S.L. and Barlovento Recursos Naturales S.L. to offer type certification of wind turbines. Introduction E2Q OBJECTIFS:. CERTIFICATION OF WIND TURBINES ACCORDING TO NEW GRID CODES (Spain, Germany, Denmark, Ireland, UK, United States, etc ) 2. EMT MODELING OF WIND TURBINES (PowerFactory of DigSilent) 3. MODEL VALIDATION 4. CERTIFICATION OF WIND PARK 5. CERTIFICATION OF POWER QUALITY ACCORDING TO IEC 6400-2 and MEASNET
5 Plan -Introduction to E2Q -The challenge of E2Q: ULYSSES -The real-life tests on Wind Turbines -Conclusions
The challenge of E2Q: ULYSSES.- INNOVATION 2.- ELECTRICAL CONSIDERATIONS: VERSATILITY 3.- SAFETY OPERATION 4.- CONSTRUCTION Testing whether a wind turbine rides through faults is not easy: A voltage sag generator able to perform short circuits of the desired residual voltage and the required duration is needed. FINISHED AT THE END OF 2005 BY AREVA T&D IBERICA (Madrid, Spain) 6
7 The challenge of E2Q: ULYSSES 5.- ACCREDITATION E2Q realization of the test with its mobile laboratory LCOE measurement and accreditation ENAC ISO 7025 Joint venture, first certifications expected at the end of March 2006
8 Plan -Introduction to E2Q -The challenge of E2Q: ULYSSES -The real-life tests on Wind Turbines -Conclusions
The real-life tests on Wind Turbines Previous studies of the impact on the protection system: Site specific, wind park or isolated site Previous studies of the impact on the protection system of the MV and HV NETWORK: Utility The mobile laboratory meets the requirements to test WT according to the P.O.2.3 R.E.E. and ISO 7025 9
0 The real-life tests on Wind Turbines
The real-life tests on Wind Turbines PREVIOUS STUDIES: Impact on the protection scheme to guarantee the selectivity..500 DIgSILENT 0.75 DIgSILENT.000 0.50 0.50 0.25 0.00 0.00-0.500-0.250 -.000-0.500 -.500-0.00 0.06 0.22 0.38 0.54 [s] Circuito Colector: Phase Voltage A in p.u. Circuito Colector: Phase Voltage B in p.u. Circuito Colector: Phase Voltage C in p.u. 0.70-0.750-0.00 0.06 0.22 0.38 0.54 [s] 3-Winding Transformer: Phase Current A/HV-Side in ka 3-Winding Transformer: Phase Current B/HV-Side in ka 3-Winding Transformer: Phase Current C/HV-Side in ka 0.70.500.00 0.50 0.00-0.500 -.000 -.500-0.00 0.06 0.22 0.38 0.54 [s] 3-Winding Transformer: Phase Voltage A/HV-Side in p.u. 3-Winding Transformer: Phase Voltage B/HV-Side in p.u. 3-Winding Transformer: Phase Voltage C/HV-Side in p.u. Limite 0.2pu y= 0.000*p.u./s*x +0.200 p.u. 0.70 9.000 6.000 3.000 0.00-3.000-6.000-9.000-0.00 0.06 0.22 0.38 0.54 [s] 3-Winding Transformer: Power-Phasor, Active Power/HV-Side in MW 3-Winding Transformer: Power Phasor, Reactive Part/HV-Side in Mvar 3-Winding Transformer: Power Phasor, Apparent Power/HV-Side in MVA 0.70 Voltage Sag Generator - 5 MW Wind Turbine - Grounded Xp Three Phase Voltage Sag Voltage EMT Date: 9/3/2005 Annex: /2 Voltage Sag Generator - 5 MW Wind Turbine - Grounded Xp Three Phase Voltage Sag Current EMT Date: 9/3/2005 Annex: /
The real-life tests on Wind Turbines PREFERRED TOOL: PowerFactory (DigSilent GmbH). WIND POWER: DFIG, FC Machines HVDC Light Noise Modulation Tower and Blade Mechanics Pitch Control Graphical Controller Modeling EMT: Detailed Network Model Transformer Saturation and capacitances Distributed Parameter Line Models (Constant and Frequency Dependent) Detailed (Switching) Power Electronics Device Models Easy-to-Use Chart Definition and Interactive Event Definition Variable Step Size Algorithm Breakers open at zero current crossing 2
3 The real-life tests on Wind Turbines FIELD EXPERIENCE: Measurement according to the Procedure of test and verification of WT (AEE) Example of 60%Un, during 200ms Ok Transient overvoltages and harmonics EMT Current measurement performed and processed to calculate P,Q and reactive component. voltage measurement ¼ cycle RMS voltage calculation 3 2 x 0 4 Voltages VA VB VC.2. Voltages (RMS) VA VB VC 0 0.9 V pu - 0.8-2 0.7-3 0.6 900 950 2000 2050 200 250 2200 2250 2300 2350 2400 [ms] 0.5 900 950 2000 2050 200 250 2200 2250 2300 2350 2400 [ms]
The real-life tests on Wind Turbines FIELD EXPERIENCE: Example of 60%Un, during 200ms Increase of voltage during the dip as expected during previous studies and simulations (cfr. Simulation published at the Nov/Dec Infopower: Proceso de certificación de aerogeneradores y parques eólicos ante huecos de tensión ). ¼ cycle RMS voltage calculation Voltages (RMS) 0.95 VA VB VC 0.9 0.85 0.8 0.75 pu 0.7 0.65 0.6 0.55 0.5 800 2000 2200 2400 2600 2800 3000 [ms] 4
The real-life tests on Wind Turbines FIELD EXPERIENCE: Extension of the Spanish requirements with the implementation of the Voltage Sag Classification (M. Bollen). Automatic data processing to know if the WT meets the requirements. VOLTAGE SAG REPORT Magnitude: 0.54535 pu Duration : 204.672 ms Type(s) : A Cause : fault 0.8 0.6 0.4 Spain PO2.3: Yes 0.2 A 800 2000 2200 2400 t [ms] Most Severe Point(s) in Symmetrical Components [pu] RMS VOLTAGE SAG REPORT Magnitude: 0.54535 pu Sequence Components + 0.8 - Duration : 204.672 ms 0 Type(s) : A 0.6 Cause : fault Spain PO2.3: Yes 0.4 0.2 A 0 2000 2200 2400 t [ms] Most Severe Point(s) in Symmetrical Components [pu] neg 0.5 0-0.5 A E/G C F B/D zero 0.5 0-0.5 A E B neg 0.5 0-0.5 A E/G C F B/D zero 0.5 0-0.5 A E B - 0 0.5 pos - 0 0.5 pos - 0 0.5 pos - 0 0.5 pos 5