LEADER 06654nam  2201645z- 450 
001 9910557676703321
005 20231214133425.0
035   $a(CKB)5400000000044766
035   $a(oapen)https://directory.doabooks.org/handle/20.500.12854/69244
035   $a(EXLCZ)995400000000044766
100   $a20202105d2020      |y             0
101 0 $aeng
135   $aurmn|---annan
181   $ctxt$2rdacontent
182   $cc$2rdamedia
183   $acr$2rdacarrier
200 10$aModeling of Wind Turbines and Wind Farms
210   $aBasel, Switzerland$cMDPI - Multidisciplinary Digital Publishing Institute$d2020
215   $a1 electronic resource (488 p.)
311   $a3-03928-756-7 
311   $a3-03928-757-5 
330   $aWind 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.
606   $aHistory of engineering & technology$2bicssc
610   $abearing current
610   $acommon mode current
610   $adoubly fed induction generators
610   $apermanent magnet synchronous generators
610   $awind turbine generator
610   $adoubly-fed generator
610   $aconverter control
610   $ashort-circuit current
610   $asecond harmonic component
610   $alow-voltage ride-through (LVRT) field test data
610   $acomplex terrain
610   $aterrain-induced turbulence
610   $aturbulence intensity
610   $aLES
610   $avortex shedding
610   $afrequency control
610   $awind power integration
610   $apower system stability
610   $aturbulence
610   $astatistical modelling
610   $aWind Turbine (WT)
610   $aDoubly Fed Induction Generator (DFIG)
610   $aunbalanced grid voltage
610   $aDC-linked voltage control
610   $aProportional Resonant with Resonant Harmonic Compensator (PR+HC) controller
610   $aAdaptive Proportional Integral (API) control
610   $apower control
610   $awind turbine near wake
610   $awind turbine wakes
610   $awake aerodynamics
610   $acomputational fluid dynamics
610   $arotor aerodynamics
610   $awind turbine validation
610   $aMEXICO experiment
610   $awind energy
610   $amodel validation
610   $awind turbine aerodynamics
610   $awind farms
610   $awind turbines interaction
610   $awind farm modeling
610   $akernel density estimation
610   $amultiple wind farms
610   $ajoint probability density
610   $aordinal optimization
610   $areactive power capability
610   $awind power plant
610   $awind power collection system
610   $aaggregated, modelling
610   $awind integration studies
610   $along term voltage stability
610   $afault-ride through capability
610   $aIEC 61400-27-1
610   $aSpanish PO 12.3
610   $aType 3 wind turbine
610   $ainertia
610   $awind power
610   $adroop
610   $aprimary control
610   $afrequency containment process
610   $awind integration
610   $ademand response
610   $aancillary services
610   $awind turbine nacelle
610   $alightning electromagnetic pulse (LEMP)
610   $amagnetic field intensity
610   $ashielding mesh
610   $awake steering
610   $ayaw misalignment
610   $amulti body simulation
610   $amain bearing loads
610   $arain flow counts
610   $aaeroelasticity
610   $amulti-rotor system
610   $awind turbine
610   $acomputational fluid dynamics (CFD)
610   $ahorizontal-axis wind turbine (HAWT)
610   $apermanent-magnet synchronous-generator (PMSG)
610   $alinear quadratic regulator (LQR)
610   $aPI control algorithm
610   $aLQR-PI control
610   $awind turbine blade
610   $alarge-eddy simulation
610   $aturbulence evaluation index
610   $afatigue damage evaluation index
610   $aDIgSILENT-PowerFactory
610   $aMATLAB
610   $atransient stability
610   $atype 3 wind turbine
610   $aDFIG
610   $afield testing
610   $afull-scale converter
610   $ageneric model
610   $avalidation
610   $aHAWT
610   $aaerodynamic characteristics
610   $adynamic yawing process
610   $anear wake
610   $astart-stop yaw velocity
610   $aload frequency control (LFC)
610   $aequivalent input disturbance (EID)
610   $aactive disturbance rejection control (ADRC)
610   $awind
610   $alinear matrix inequalities (LMI)
610   $adynamic modeling
610   $agrey-box parameter identification
610   $asubspace identification
610   $arecursive least squares
610   $aoptimal identification
615  7$aHistory of engineering & technology
700   $aGomez-Lazaro$b Emilio$4edt$01332365
702   $aArtigao$b Estefania$4edt
702   $aGomez-Lazaro$b Emilio$4oth
702   $aArtigao$b Estefania$4oth
906   $aBOOK
912   $a9910557676703321
996   $aModeling of Wind Turbines and Wind Farms$93040892
997   $aUNINA