5 sinusoidal vs trapezoidal – CONTREX CXB2040 User Manual

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CHAPTER 2: THEORY OF OPERATION

BRUSHLESS MOTORS/AMPLIFIERS

BRUSHED MOTORS/AMPLIFIERS

ADVANTAGES

DISADVANTAGES

No scheduled maintenance and no brush dust is

generated.

Motor brushes must be checked periodically for

wear and excess brush dust.

Higher RPM limits. Approximately 3000RPM maximum.
Lower inertia/torque ratio.

Higher inertia to torque ratio.

Dissipates heat more efficiently due to windings

being located in stator.

Not as efficient at dissipating heat. Heat is trapped

at rotor and shortens bearing life.

Safer for explosive atmospheres. Quieter and less

electrical noise generated.

Brushes spark and generate electrical and audible

noise.

DISADVANTAGES

ADVANTAGES

Amplifiers are complicated and expensive.

Amplifiers are simpler and less expensive.

Higher torque ripple.

Lower torque ripple.

No Industry standard packaging.

Industry standard packaging.

2.5 SINUSOIDAL vs. TRAPEZOIDAL:

Figure 2.4 shows the two most common waveforms used to drive a brushless motor. Note that in

each case, there are actually three different waveforms. Each waveform drives a motor winding and is

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out-of-phase with the other two. Again, the waveform may be generated from a DC source by linear

or PWM techniques.

Figure 2.4

Trapezoidal and sinusoidal waveform used to drive brushless motor.

The first waveform is known as trapezoidal or six-step since the voltage is literally stepped from

winding to winding (like the Christmas-light analogy). This is the simplest and least expensive method of

driving a brushless motor. Its principal disadvantage is that the large current steps produce high torque

ripple. (Torque ripple is a repetitive fluctuation in torque as the motor turns and is independent of load.)

The second waveform is known as sinusoidal. To minimize torque ripple, the motor current needs to

be constantly varied according to the orientation of the magnets and windings. As it happens, this is a

sine function. In fact, a sine wave is defined as a rotating radius (like a motor shaft) revolving through

time (see figure 2.4). A sine wave is the most natural way to drive a motor and produces the minimum

torque ripple.