Three excellent ways to reduce audible noise in motion control applications - 应用 | 黑森尔电子
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Three excellent ways to reduce audible noise in motion control applications

发表于 四月 13, 2023
标签: Medical (2)

With the advent of open floor plans in homes and offices and the growing shift to hybrid and electric vehicles, there is a growing need for quieter, more efficient motor controls. Even very small acoustic differences can have a significant effect on audible noise.


The graph below shows how appliances in a living space affect the overall noise level. Use advanced real-time control technologies such as motor control circuits with higher power density, higher integration and more efficient systems to help you achieve superior system acoustic performance. Some other strategies include vector field oriented control (FOC) algorithms that use continuous pulse width modulation (PWM), specific control algorithms that reduce vibration, and integrated controls that apply dead-time compensation and PWM generation to reduce audible noise.

                      


PWM

The first strategy used to reduce audible noise in motor control applications is continuous PWM. PWM is a technique in which transistors are turned on and off to produce an output waveform that keeps the motor voltage high or low at a given time. Inductors in the motor then filter these waveforms so as to basically average out the waveforms. Adjusting the duty ratio (the ratio of waveform turn-on time to turn-off time) will change the average voltage. The following figure shows an example of sine wave generation using PWM.

Example of sine wave generation using PWM

                

For example, the Texas Instruments (TI) MCF8315A BLDC Integrated Control Grid Driver is a sensorless FOC motor driver that enables continuous and discontinuous space vector PWM solutions. Continuous modulation helps to reduce current ripple in low-inductance motors, but results in higher switching losses because all three phases cross each other. Discontinuous modulation has lower switching losses (because only two phases cross each other at a time) but higher current ripple. In the following two images, see the difference between continuous and discontinuous PWM.

Relationship between phase current waveform and Fast Fourier Transform (FFT) discontinuous PWM

                        

Relationship between phase current waveform and FFT continuous PWM



Dead time compensation

A second strategy used to reduce audible noise in motor control applications is dead-time compensation. In motor control applications, a breakdown can be avoided by inserting a dead time between the switch of the high side and the low side of the MOS field effect transistor in the half-bridge. After the dead-time is inserted, the expected voltage at the phase node will be different from the applied voltage, and the phase node voltage will introduce unnecessary distortion in the phase current, resulting in audible noise.

To manage this extra noise, engineers can use a resonant controller to integrate dead-time compensation in order to control the harmonic components of the phase current, thereby mitigating current distortion due to dead-time, as shown in the figure below.

Time compensation analysis of sensorless FOC dead zone

                         


For example, TI's MCF8316A BLDC Integrated Control Grid Driver (a sensorless FOC motor driver) uses this built-in feature to optimize acoustic performance at multiple motor frequencies, as shown below.

PWM modulation and dead-time compensation are implemented to optimize the acoustic performance of MCF8316A

                     


Variable reversing mode

The final strategy used to reduce audible noise in motor control applications is the variable reversing mode. In trapezoidal commutation, there are two main configurations: 120 degrees and 150 degrees. The 120-degree trapezoidal commutation may result in more acoustic noise, as longer high-impedance periods result in larger torque ripples, as shown in figures 7 and 8. The 150 degree trapezoidal commutation can only be operated at low speeds because of the short window of zero crossing detection.

To address these challenges and improve acoustic performance, engineers can build motor driver systems capable of dynamically switching between 120-degree trapezoidal and 150-degree trapezoidal commutation. This dynamic modulation improves the overall acoustic performance during BLDC motor control.

Phase current and FFT - 120 degree commutation

                    



Phase current and FFT - 150 degree commutation

         


For example, TI Sensorless BLDC integrated trapezoidal control grid drivers (such as MCT8329 and MCT8316) employ this built-in feature to optimize acoustic performance at a variety of motor frequencies, as shown below.

             




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