Abstract—
The application of pulsewidth-modulated (PWM) voltages using two-level high-voltage inverters to a squirrel-cage induction motor (SQIM) can cause heating of rotor shaft, voltage spike across the motor terminals, etc. The increase in the number of steps of the motor voltage and hence decreasing the dv/dt applied to the machine terminals can be a solution to this problem. The existing topologies that generate this multistep voltage include cascading of a number of single-phase inverters or use of higher order multilevel inverters. In this paper, a topology with series connection of three-phase three-level inverters is proposed, which addresses the problems of medium-voltage drives. The design of the inverter topology and its various PWM techniques are presented in this paper. This inverter topology and its control are verified on a 7.5-hp SQIM drive. Experimental results validate the steady-state and dynamic performances of the drive.
The application of pulsewidth-modulated (PWM) voltages using two-level high-voltage inverters to a squirrel-cage induction motor (SQIM) can cause heating of rotor shaft, voltage spike across the motor terminals, etc. The increase in the number of steps of the motor voltage and hence decreasing the dv/dt applied to the machine terminals can be a solution to this problem. The existing topologies that generate this multistep voltage include cascading of a number of single-phase inverters or use of higher order multilevel inverters. In this paper, a topology with series connection of three-phase three-level inverters is proposed, which addresses the problems of medium-voltage drives. The design of the inverter topology and its various PWM techniques are presented in this paper. This inverter topology and its control are verified on a 7.5-hp SQIM drive. Experimental results validate the steady-state and dynamic performances of the drive.
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