2020
DOI: 10.11591/ijece.v10i1.pp600-608
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The transient stability analysis of wind turbines interconected to grid under fault

Abstract: Wind farm has been growing in recent years due to its very competitive electricity production cost. Wind generators have gone from a few kilowatts to megawatts. However, the participation of the wind turbine in the stability of the electricity grid is a critical point to check, knowing that the electricity grid is meshed, any change in active and reactive flux at the network level affects its stability. With a rate of 50% wind turbine penetration into the electricity grid, the stability of the rotor angle is a… Show more

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Cited by 7 publications
(7 citation statements)
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“…For determining the direct and quadrature stator fluxes, use (7). The (18) provides the stator flux, and the (19) provides the stator flux angle. The angle of the stator flux as in (20) is crucial in determining the reference stator voltage areas.…”
Section: Formulation Of Reactive and Active Powermentioning
confidence: 99%
“…For determining the direct and quadrature stator fluxes, use (7). The (18) provides the stator flux, and the (19) provides the stator flux angle. The angle of the stator flux as in (20) is crucial in determining the reference stator voltage areas.…”
Section: Formulation Of Reactive and Active Powermentioning
confidence: 99%
“…The doubly fed induction generator (DFIG) is a prominent conversion system used in many real wind turbine systems integrated to power grid networks [230,231]. This is particularly due to its ability to prevent delivery of disturbances to electrical networks by decoupling production between active and reactive power [232]. However, due to the voltage irregularities typical of renewable-integrated power networks, continued and optimal performance of wind turbine using DFIG is often a cause of concern, especially at a penetration rate beyond 50% where the stator angle is no longer stable [232].…”
Section: Wind Energymentioning
confidence: 99%
“…This is particularly due to its ability to prevent delivery of disturbances to electrical networks by decoupling production between active and reactive power [232]. However, due to the voltage irregularities typical of renewable-integrated power networks, continued and optimal performance of wind turbine using DFIG is often a cause of concern, especially at a penetration rate beyond 50% where the stator angle is no longer stable [232]. Whenever there is a voltage dip in the power grid, connoting essentially a sudden and transient drop in amplitude of the RMS voltage affecting certain phases at some points in the power network, effects on DFIG performance often lead to the entire system being shut down as well as a potential damage to the generator.…”
Section: Wind Energymentioning
confidence: 99%
“…Technological progress and the development of wind systems have encouraged their integration into the electrical system [1]. This considerable integration of the wind turbine into grid especially wind systems equipped with doubly feed induction generators (DFIG) [2], [3]. This dominance of DFIG is due to its advantages which are variable speed operation, the converters used are only sized at a fraction 25-30% of the DFIG power rated and the decoupled active and the reactive power control [4][8].…”
Section: Introductionmentioning
confidence: 99%