Acoustic Noise Characterization of Space Vector Modulated Induction Motor Drives &amp;#x2013; An Experimental Approach

Binojkumar, A. C.; Saritha, B.; Narayanan, G.

doi:10.1109/tie.2014.2374557

Cited by 42 publications

(31 citation statements)

References 39 publications

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“…Still, the acoustic noise components around 4 kHz are not too high. This may be attributed to the amplification factor not rising very sharply close to the resonant frequency for this specific motor [3]. The noise spectrum is fairly dispersed with VFPWM as demonstrated by Fig.…”

Section: Acoustic Noise Spectramentioning

confidence: 75%

“…The resonant frequency of the 6-kW motor has been reported to be around 4 kHz [3], [26]. Hence, in order to study the effect of including the resonant frequency within the switching frequency range, the experiment is repeated with a nominal carrier frequency, f c,nom of 3 kHz.…”

Section: Resultsmentioning

confidence: 99%

“…One main reason for acoustic noise emission is the injection of harmonic currents by the voltage source inverter (VSI) feeding the induction motor. When the inverter is pulse width modulated at a fixed switching frequency, the acoustic noise emitted by the motor is concentrated in narrow bands around integral multiples of the inverter switching frequency [1]- [3]. Sine pulse-width modulation (SPWM) and conventional space vector pulsewidth modulation (CSVPWM) are well known fixed switching frequency pulse-width modulation (PWM) methods used in industry [4].…”

Section: Introductionmentioning

confidence: 99%

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Variable-Switching Frequency PWM Technique for Induction Motor Drive to Spread Acoustic Noise Spectrum With Reduced Current Ripple

Kumar

Narayanan

2016

IEEE Trans. on Ind. Applicat.

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Pulse width modulation (PWM) of a motor drive at a fixed switching frequency leads to harmonic currents in narrow bands around integral multiples of the switching frequency, resulting in tonal frequency acoustic noise components which are irritating to the human ear. Random variation of carrier frequency to spread the spectrum poses challenges in device loss calculation, thermal design and closed-loop controller design. Random pulse positioning is not quite effective at high speeds of the drive, where the problem of acoustic noise is most pronounced. This paper proposes a simple variable frequency PWM and evaluates the performance of the same experimentally on a 6-kW induction motor drive. The experimental results show that the acoustic noise is spread uniformly over a range of frequencies without introducing low-frequency current harmonics. Compared to fixed frequency PWM, the dominant acoustic noise is reduced significantly over a wide range of speeds. The variable frequency PWM is further shown to reduce line current total harmonic distortion (THD) at high speeds of the drive. The computational effort required by the variable frequency PWM is only marginally higher than that required by fixed frequency PWM.

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Section: Acoustic Noise Spectramentioning

confidence: 75%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Variable-Switching Frequency PWM Technique for Induction Motor Drive to Spread Acoustic Noise Spectrum With Reduced Current Ripple

Kumar

Narayanan

2016

IEEE Trans. on Ind. Applicat.

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“…Further comparison between BCPWM methods shows that 30 • BCPWM is better compared to 60 • BCPWM, in terms N 1d . The resonant frequency of the 6-kW motor is estimated as 4 kHz [12], [38] and magnetic force waves in its proximity are boosted up whereas other force waves are attenuated. Because of this, N 2d is significantly reduced, compared to N 1d .…”

Section: Performance Comparison Of Csvpwm and Bcpwm Methodsmentioning

confidence: 99%

Experimental Comparison of Conventional and Bus-Clamping PWM Methods Based on Electrical and Acoustic Noise Spectra of Induction Motor Drives

Binojkumar

Saritha

Narayanan

2016

IEEE Trans. on Ind. Applicat.

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The acoustic noise emitted by an induction motor, powered by a voltage source inverter, is an environmental issue. Harmonics present in the stator current are the main reason for the increased acoustic noise in motor drives. The pulse-width modulation (PWM) technique used to modulate the inverter is a key factor determining the magnitude of current harmonics. Busclamping pulse-width modulation (BCPWM) techniques have got much attention nowadays due to reduced switching loss, compared to conventional space vector PWM (CSVPWM). In this paper, two BCPWM techniques namely, 60 • and 30 • BCPWM methods are compared with CSVPWM on the basis of electrical spectra as well as acoustic noise spectra. Experiments are conducted on a pulse-width modulated voltage source inverter fed induction motor drives. Harmonic analysis is carried out on the measured line to line voltage, stator current and acoustic noise, corresponding to the three methods, at different fundamental and carrier frequencies. Based on the magnitude and phase of current harmonics, the frequency and normalized magnitude of dominant magnetic force waves are predicted theoretically. Theoretical predictions and experimental results both show that the magnitudes of dominant acoustic noise components around the carrier frequency are reduced significantly with these BCPWM methods, compared to CSVPWM. Further, it is shown that 30 • BCPWM is better than 60 • BCPWM in terms of acoustic pleasantness.

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“…Accordingly, space vector PWM (SVPWM) would offer reduced current and torque ripples, compared with SPWM . The voltage harmonics were also decreased and were concentrated around integer multiples of the VSI switching frequency . The optimal modulation, otherwise known as the selective harmonic elimination PWM (SHEPWM), would determine in advance the switching angles, taking into account the amplitude of the desired output voltage and the harmonics to be eliminated .…”

Section: Introductionmentioning

confidence: 99%

Experimental study of PWM strategy effect on acoustic noise generated by inverter‐fed induction machine

Bouyahi

Smida

Khedher

2019

Int Trans Electr Energ Syst

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Summary Three‐phase voltage source inverters (VSIs) provide high‐order harmonic voltages. The feed of a power induction machine by a VSI increases the acoustic noise, which becomes unacceptable especially for applications requiring a moderate level such as electrical traction. It has been found that the noise level depends on the total harmonic distortion of the VSI. Thus, the level of harmonics depends on the pulse width modulation (PWM) techniques used to control the VSI. Several PWM techniques have been developed in the literature, such as space vector PWM, selective harmonic elimination PWM, and random PWM. This paper presents a study of the PWM impact on the acoustic noise generated by a two‐level inverter‐fed induction machine. The acoustic noise and harmonic spectrum are carried out corresponding the three PWM techniques at a couple of machine operation conditions. The experimental results show that the acoustic noise is significantly reduced with the random PWM strategy. A comparative study is presented and discussed in this paper.

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Acoustic Noise Characterization of Space Vector Modulated Induction Motor Drives – An Experimental Approach

Cited by 42 publications

References 39 publications

Variable-Switching Frequency PWM Technique for Induction Motor Drive to Spread Acoustic Noise Spectrum With Reduced Current Ripple

Variable-Switching Frequency PWM Technique for Induction Motor Drive to Spread Acoustic Noise Spectrum With Reduced Current Ripple

Experimental Comparison of Conventional and Bus-Clamping PWM Methods Based on Electrical and Acoustic Noise Spectra of Induction Motor Drives

Experimental study of PWM strategy effect on acoustic noise generated by inverter‐fed induction machine

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