00846nam--2200337---450-99000290333020331620070413171539.0000290333USA01000290333(ALEPH)000290333USA0100029033320070413d1912----km-y0itay50------bafreFR||||||||001yyAdèle KammPaul SeippelLausannePayot et C.ie[1912]238 p.20 cm20012001001-------2001843.912SEIPPEL,Paul460238ITsalbcISBD990002903330203316XV.5. 832197819 LMXV.5.BKFGSENATORE9020070413USA011715Adèle Kamm989280UNISA06675nam 2201657z- 450 991055767670332120210501(CKB)5400000000044766(oapen)https://directory.doabooks.org/handle/20.500.12854/69244(oapen)doab69244(EXLCZ)99540000000004476620202105d2020 |y 0engurmn|---annantxtrdacontentcrdamediacrrdacarrierModeling of Wind Turbines and Wind FarmsBasel, SwitzerlandMDPI - Multidisciplinary Digital Publishing Institute20201 online resource (488 p.)3-03928-756-7 3-03928-757-5 Wind Power Plant (WPP) and Wind Turbine (WT) modeling are becoming of key importance due to the relevant wind-generation impact on power systems. Wind integration into power systems must be carefully analyzed to forecast the effects on grid stability and reliability. Different agents, such as Transmission System Operators (TSOs) and Distribution System Operators (DSOs), focus on transient analyses. Wind turbine manufacturers, power system software developers, and technical consultants are also involved. WPP and WT dynamic models are often divided into two types: detailed and simplified. Detailed models are used for Electro-Magnetic Transient (EMT) simulations, providing both electrical and mechanical responses with high accuracy during short time intervals. Simplified models, also known as standard or generic models, are designed to give reliable responses, avoiding high computational resources. Simplified models are commonly used by TSOs and DSOs to carry out different transient stability studies, including loss of generation, switching of power lines or balanced faults, etc., Assessment and validation of such dynamic models is also a major issue due to the importance and difficulty of collecting real data. Solutions facing all these challenges, including the development, validation and application of WT and WPP models are presented in this Issue.History of engineering and technologybicsscactive disturbance rejection control (ADRC)Adaptive Proportional Integral (API) controlaerodynamic characteristicsaeroelasticityaggregated, modellingancillary servicesbearing currentcommon mode currentcomplex terraincomputational fluid dynamicscomputational fluid dynamics (CFD)converter controlDC-linked voltage controldemand responseDFIGDIgSILENT-PowerFactoryDoubly Fed Induction Generator (DFIG)doubly fed induction generatorsdoubly-fed generatordroopdynamic modelingdynamic yawing processequivalent input disturbance (EID)fatigue damage evaluation indexfault-ride through capabilityfield testingfrequency containment processfrequency controlfull-scale convertergeneric modelgrey-box parameter identificationHAWThorizontal-axis wind turbine (HAWT)IEC 61400-27-1inertiajoint probability densitykernel density estimationlarge-eddy simulationLESlightning electromagnetic pulse (LEMP)linear matrix inequalities (LMI)linear quadratic regulator (LQR)load frequency control (LFC)long term voltage stabilitylow-voltage ride-through (LVRT) field test dataLQR-PI controlmagnetic field intensitymain bearing loadsMATLABMEXICO experimentmodel validationmulti body simulationmulti-rotor systemmultiple wind farmsnear wakeoptimal identificationordinal optimizationpermanent magnet synchronous generatorspermanent-magnet synchronous-generator (PMSG)PI control algorithmpower controlpower system stabilityprimary controlProportional Resonant with Resonant Harmonic Compensator (PR+HC) controllerrain flow countsreactive power capabilityrecursive least squaresrotor aerodynamicssecond harmonic componentshielding meshshort-circuit currentSpanish PO 12.3start-stop yaw velocitystatistical modellingsubspace identificationterrain-induced turbulencetransient stabilityturbulenceturbulence evaluation indexturbulence intensitytype 3 wind turbineType 3 wind turbineunbalanced grid voltagevalidationvortex sheddingwake aerodynamicswake steeringwindwind energywind farm modelingwind farmswind integrationwind integration studieswind powerwind power collection systemwind power integrationwind power plantwind turbineWind Turbine (WT)wind turbine aerodynamicswind turbine bladewind turbine generatorwind turbine nacellewind turbine near wakewind turbine validationwind turbine wakeswind turbines interactionyaw misalignmentHistory of engineering and technologyGomez-Lazaro Emilioedt1332365Artigao EstefaniaedtGomez-Lazaro EmilioothArtigao EstefaniaothBOOK9910557676703321Modeling of Wind Turbines and Wind Farms3040892UNINA