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SEE 3433 MESIN ELEKTRIK SYNCHRONOUS MACHINES Basic principles
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General features Doubly excited machine Rotor – field winding – DC current Stator – Armature winding – AC supply Prime mover e.g. operated as a generator Slip rings 3 - Stator terminals Field circuit
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Magnetic axis of rotor Magnetic axis of phase a Salient pole Construction A A’ B B’ C C’ IfIf Rotor - field Stator - Armature - Low speed operation Large number of poles e.g. application in hydroelectric
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Magnetic axis of rotor Magnetic axis of phase a Construction A A’ B B’ C C’ Cylindrical High speed operation Small number of poles e.g. application in steam turbines
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Salient rotor
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Stator under construction
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Synchronous generator – non-salient pole
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Synchronous generators Field current in rotor produce sinusoidal flux in airgap Rotating filed produced when rotor rotates Rotating field induced 3 voltage in 3 phase windings on stator Similar to induction machine, the RMS of induced voltage per phase is E f = 4.44 f N K w E f known as excitation voltage Frequency of induced voltage given by:
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Synchronous generators E f depends on: speed Flux per pole hance I f Open circuit characteristic (OCC) Exhibit saturation as flux in core saturated
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Synchronous generators Application in power system:
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Synchronous motors Stator terminals connected to 3 supply – producing rotating magnetic flux However, rotor won’t be able to rotate or start: Due to inertia, rotor cannot catch-up with the fast rotating field !
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1 Synchronous motors Solved by: Frequency is slowly increased from 0 using power electronics converter
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Synchronous motors Solved by: 2 Rotor has ‘squirrel cage’ construction At synchronous speed no current induced in the winding (Damper winding)
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