29.7
An ideal Y-Y transformer grounded via neutral impedances has per-unit sequence networks similar to a single-phase transformer when balanced positive or negative-sequence currents flow, negating neutral currents and voltage drops.
Zero-sequence currents from all three phases combine to form a neutral current, causing voltage drops across the neutral impedance and influencing the low-voltage winding voltage.
Practical Y-Y transformers include external impedances in their per-unit sequence networks. Each phase represents a core loss resistor in parallel with a magnetizing inductance.
These transformers have identical per-unit positive and negative-sequence impedances, while the zero-sequence network depends on neutral impedances.
Delta-delta transformers have identical positive and negative-sequence networks, with per-unit impedances independent of winding connections.
To model per-unit sequence for three-phase, three-winding transformers are created by connecting three comparable single-phase transformers using a common S-base and proportional voltage bases.
In the zero-sequence network, the high-voltage connection depends on the high-voltage windings' configuration.
Een ideale Y-Y-transformator, geaard via neutrale impedanties, vertoont per-eenheid sequentienetwerken die lijken op die van een ideale eenfasetransformator wanneer deze wordt onderworpen aan gebalanceerde positieve- of negatieve-sequentiestromen. Deze stromen produceren geen neutrale stromen en de bijbehorende spanningsdalingen.
Nulsequentiestromen, die identiek zijn in grootte en fase, genereren een neutrale stroom, wat resulteert in spanningsdalingen over de neutrale impedantie en de laagspanningswikkeling. Als de nul van de transformator niet geaard is, kunnen nulsequentiestromen niet naar de grond stromen, maar kunnen ze nog steeds binnen de wikkelingen circuleren.
Praktische Y-Y-transformatoren per-eenheid sequentienetwerken bevatten externe impedanties. Hun shunttakken vertegenwoordigen een gebalanceerde Y-impedantiebelasting, waarbij elke fase overeenkomt met een kernverliesweerstand parallel aan de magnetiserende inductantie. Deze transformatoren bezitten identieke positieve- en negatieve-sequentie-impedanties per eenheid, terwijl de neutrale impedanties het nulsequentienetwerk beïnvloeden.
Delta-delta transformatoren hebben per-eenheid sequentienetwerken met identieke positieve- en negatieve-sequentie-impedanties. Verschillende wikkelingsverbindingen kunnen deze impedanties echter beïnvloeden in praktische transformatoren. Per-eenheid sequentiemodellen van driefasen, drie-wikkelingstransformatoren kunnen worden geconstrueerd door drie identieke eenfasetransformatoren aan te sluiten, met behulp van een gemeenschappelijke S-basis voor aansluitingen en proportionele spanningsbases.
In het algemene nul-sequentie netwerk bepaalt de configuratie van de hoogspanningswikkelingen de hoogspanningsverbinding. Negatieve-sequentie netwerkimpedanties per eenheid komen altijd overeen met de positieve-sequentie netwerkimpedanties.
An ideal Y-Y transformer grounded via neutral impedances has per-unit sequence networks similar to a single-phase transformer when balanced positive or negative-sequence currents flow, negating neutral currents and voltage drops.
Zero-sequence currents from all three phases combine to form a neutral current, causing voltage drops across the neutral impedance and influencing the low-voltage winding voltage.
Practical Y-Y transformers include external impedances in their per-unit sequence networks. Each phase represents a core loss resistor in parallel with a magnetizing inductance.
These transformers have identical per-unit positive and negative-sequence impedances, while the zero-sequence network depends on neutral impedances.
Delta-delta transformers have identical positive and negative-sequence networks, with per-unit impedances independent of winding connections.
To model per-unit sequence for three-phase, three-winding transformers are created by connecting three comparable single-phase transformers using a common S-base and proportional voltage bases.
In the zero-sequence network, the high-voltage connection depends on the high-voltage windings' configuration.
From Chapter 29:
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