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International Journal of Advanced Network, Monitoring and Controls
Volume 7 (2022): Numero 4 (January 2022)
Accesso libero
One Novel Soft-Starting Control Strategy for Induction Motor Based on Space Voltage Vectors
Shihong Xie
Shihong Xie
,
Rongmao Liang
Rongmao Liang
,
Li Liang
Li Liang
,
Zhihao Yang
Zhihao Yang
e
Xin Gao
Xin Gao
| 26 mag 2023
International Journal of Advanced Network, Monitoring and Controls
Volume 7 (2022): Numero 4 (January 2022)
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Pubblicato online:
26 mag 2023
Pagine:
59 - 68
DOI:
https://doi.org/10.2478/ijanmc-2022-0037
Parole chiave
Induction Motor
,
Discrete Variable Frequency (DVF)
,
High Starting Torque
,
Space Voltage Vectors
,
Thyristor
© 2022 Shihong Xie et al., published by Sciendo
This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.
Figure 1.
The forming principle of space voltage vectors based on three-phase thyristor circuits. (a) uAB, (b) uAC, (c) uBC, (d) uBA, (e) uCA, (f) uCB.
Figure 2.
Hexagon space voltage vectors
Figure 3.
Frequency f/7 voltage waves of DVF based on space voltage vectors
Figure 4.
Frequency f/4 voltage waves of DVF based on space voltage vectors
Figure 5.
Frequency f/3 voltage waves of DVF based on space voltage vectors
Figure 6.
Circuit model of IM under α-β stationary reference frame
Figure 7.
Voltage and current for frequency f/7. (a)Line Voltage. (b) Phase Current.
Figure 8.
Voltage and current for frequency f/4. (a) Line Voltage. (b) Phase Current.
Figure 9.
Voltage and current for frequency f/3. (a) Line Voltage. (b) Phase Current.
Figure 10.
Induction motor stator flux track. (a) ramp voltage. (b) frequency f/7 (c) frequency f/4. (d) frequency f/3.
Figure 11.
Responses of IM driven by the proposed method. (a) Stator current. (b) Rotor speed.
Figure 12.
Responses of IM driven by the traditional method. (a) Stator current. (b) Rotor speed.
Figure 13.
Experimental system of IM driven by three-phase thyristor circuits
Figure 14.
Voltage and current for frequency f/7. (a) Line Voltage (b) Phase Current.
Figure 15.
Voltage and current for frequency f/4. (a) Line Voltage. (b) Phase Current.
Figure 16.
Voltage and current for frequency f/3. (a) Voltage waveform. (b) Current waveform.
Figure 17.
Rotor speeds of IM. (a) The proposed method. (b) The traditional method