| Starting Method | % of Full Voltage | % of Starting Current | % of Starting Torque | % of Starting kVA | |----------------|------------------|----------------------|----------------------|--------------------| | Full Voltage | 100% | 100% | 100% | 100% | | Autotransformer (80% tap) | 80% | 80% | 64% | 64% | | Autotransformer (65% tap) | 65% | 65% | 42% | 42% | | Wye-Delta (Star-Delta) | 58% | 33% | 33% | 33% | | Part-Winding (50-100% winding) | 100% | 50-70% | 20-45% | 50-70% | Problem: A 100 HP, 460V, three-phase motor has a locked rotor current of 600A (Code G motor). Calculate the starting kVA using a wye-delta starter.
Still exceeds 300 kVA transformer capacity. nema mg1-32 amp- 33
In simpler terms, this section defines the standard methods for calculating the apparent power (kVA) that a motor draws from the line —specifically when using reduced-voltage starting methods such as autotransformers, part-winding, or wye-delta starters. Why is MG1-32 Critical? When an induction motor starts, it draws a high inrush current (typically 600% of full-load current) for a few cycles, followed by a starting current (typically 500–600% of full-load amps) until it reaches full speed. This current, multiplied by the voltage, gives the starting kVA . | Starting Method | % of Full Voltage