Multilevel inverters are power electronic devices used to convert DC (direct current) voltage into AC (alternating current) voltage with multiple levels of voltage output. They are commonly used in motor drives and other high-power applications to achieve higher voltage and power levels while minimizing the harmonic distortion in the output waveform. The principle of multilevel inverters for motor drives can be understood through the following key concepts:
Pulse Width Modulation (PWM):
The fundamental principle of multilevel inverters relies on the concept of Pulse Width Modulation (PWM). PWM is a technique where the width of the pulses in an AC waveform is varied to control the average voltage applied to the motor. By adjusting the pulse widths, the effective voltage and frequency can be regulated.
H-bridge Configuration:
The building block of a multilevel inverter is the H-bridge, which consists of four power switching devices (typically insulated gate bipolar transistors - IGBTs or power MOSFETs). Each H-bridge can generate two different voltage levels, either +Vdc or -Vdc, across its output terminals depending on the state of the switching devices.
Cascaded Structure:
In a multilevel inverter, several H-bridges are connected in series or cascaded. Each H-bridge generates a discrete voltage level, and by combining these levels, the multilevel inverter can synthesize a stepped approximation of a sinusoidal output waveform. The number of voltage levels in the output waveform determines the "level" of the inverter.
Reduced Harmonic Distortion:
The multilevel inverter can produce a staircase-like voltage waveform with several voltage steps, which allows it to generate a smoother and less distorted AC output compared to conventional two-level inverters. By using multiple voltage levels, the output voltage waveform more closely approximates a sinusoidal waveform, resulting in reduced harmonic content.
PWM Control:
To control the multilevel inverter output voltage, a sophisticated PWM control scheme is employed. The control system calculates the required pulse widths for each H-bridge in real-time to achieve the desired AC output voltage and frequency. This control strategy ensures smooth motor operation and minimizes losses and harmonic distortions.
Advantages of multilevel inverters for motor drives include reduced harmonic content, lower switching losses, and improved motor efficiency. These features make them particularly useful in high-power applications such as electric traction, renewable energy systems, and industrial motor drives. However, designing and implementing multilevel inverters can be more complex than traditional two-level inverters due to the increased number of power switching devices and control requirements.