Three-Level NPC Inverter-Fed IM Drives under PTC, Minimizing the Involved Voltage Vectors and Balancing the DC Bus Capacitor Voltages
Abstract
:1. Introduction
- Minimize the number of applied active voltage vectors to six.
- Reduce the commutation of the inverter power switches thanks to the clamping of the stator phase terminals to the DC bus voltage.
- Simplify the cost functions by the elimination of one or more weighting factors.
2. Induction Motor Modeling
3. 3L-NPC Inverter Modeling
- which can be simplified to .
- which can be simplified to .
- which can be reduced to .
4. PTC Strategies Dedicated to 3L-NPC Inverter-Fed IM Drives
4.1. Conventional PTC Basis
- The estimation of the rotor and stator fluxes at time with is the sampling period,
- The prediction of the stator and rotor fluxes, the stator current, and the electromagnetic torque at time . For the sake of a time delay compensation in a real-time implementation, a second prediction is required at time ,
- The actuation following the minimization of the cost function.
4.1.1. Rotor and Stator Flux Estimation
4.1.2. Stator Flux, Stator Current, and Electromagnetic Torque Prediction
4.1.3. Cost Function Optimization
- Balancing the neutral point voltage. The corresponding error and weighting factor are noted as and , respectively,
- Minimizing the number of switching transitions . The weighting factor is noted as .
- is the reference electromagnetic torque. which corresponds to the output of speed PI controller.
- is the rated electromagnetic torque.
- is the rated stator flux.
- is the weighting flux factor, introduced to account for the difference in units and magnitudes of the torque and flux.
4.2. Introduced PTCs
- The great effort required to tune three weighting factors (, , and ).
- The huge CPU time spent in the online selection among 27 of the suitable voltage vectors.
- The excessive torque and stator flux ripple.
4.2.1. SV-PTC1
- ⋄
- Set 1 = , , , , , that enables the clamping of the stator c-phase to the low level DC bus voltage.
- ⋄
- Set 2 = , , , , , that enables the clamping of the stator b-phase to the high level of the dc-bus voltage.
4.2.2. SV-PTC2
- ⋆
- >: the upper switches are switched ON to achieve the balance;
- ⋆
- <: the lower switches are switched ON to achieve the balance.
5. Case Study
5.1. Simulation Results
- The rotor speed (in blue) followed its reference (in red) under the three PTC schemes.
- The neutral point voltage was well-balanced under the three schemes, with a slight increase limited to 1.25% of the DC bus voltage at low speeds under the SV-PTC2.
- A reduction of the stator current harmonic distortion and damping of the electromagnetic torque ripple were gained thanks to the implementation of SV-PCT1 and SV-PCT2.
- The DC bus capacitance voltages were quite balanced under the three strategies with the neutral point voltage not exceeding 0.2 V for C-PTC, 2 V for the SV-PTC1, and 2.2 V for SV-PTC2,
- The two proposed SV-PTCs mitigated the switching commutation thanks to the clamping of the stator phases to the high and low levels of DC bus voltages, which were regular in the case of SV-PTC1 and arbitrary in the case of SV-PTC2.
- Compared to C-PTC, SV-PTC1 and SV-PTC2 strategies exhibited higher performances in terms of the reduction of the ripple of the stator flux and electromagnetic torque. This statement was confirmed by a firm comparison; the results are provided in Table 6.
5.2. Experimental Validation
5.2.1. Test Bench Description
5.2.2. Transient Behavior
- Figure 9a–c show the scopes illustrating the waveforms of the motor speed and the electromagnetic torque yielded by C-PTC, SV-PTC1, and SV-PTC2, respectively,
- Figure 9d–f show the scopes illustrating the waveforms of the stator flux and the electromagnetic torque yielded by C-PTC, SV-PTC1, and SV-PTC2, respectively,
5.2.3. Steady-State Operation
- Figure 10a–c show the scopes illustrating the sector succession and the sum of the control signals of yielded by C-PTC, SV-PTC1, and SV-PTC2, respectively,
- Figure 10d–f show the scopes illustrating the waveforms of the two DC bus capacitor voltages and yielded by C-PTC, SV-PTC1, and SV-PTC2, respectively.
- Figure 10g–i show the scopes illustrating the locus described by the extremities of the applied voltage vectors yielded by C-PTC, SV-PTC1, and SV-PTC2, respectively,
- Figure 10j–l show the scopes illustrating the waveforms of the stator phase voltage and current yielded by C-PTC, SV-PTC1, and SV-PTC2, respectively.
5.3. Simulation versus Experimental Results
6. Conclusions
- The reduction of the switching transitions (thanks to the phases clamping);
- The mitigation of the current distortion and the torque and flux ripples,
- The minimization of the number of weighting factors in the cost function without disturbing the neutral point voltage balance.
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
References
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Zero voltage vectors | |||||
0 0 0 | 0 | 0 | 0 | 0 | |
1 1 1 | 0 | 0 | 0 | 0 | |
-1-1-1 | 0 | 0 | 0 | 0 | |
Small voltage vectors | |||||
1 0 0 | 0 | 0 | |||
0-1-1 | 0 | 0 | |||
1 1 0 | |||||
0 0-1 | |||||
0 1 0 | |||||
-1 0-1 | |||||
0 1 1 | 0 | ||||
-1 0 0 | 0 | ||||
0 0 1 | |||||
-1-1 0 | |||||
1 0 1 | |||||
0-1 0 | |||||
Medium voltage vectors | |||||
1 0-1 | |||||
0 1-1 | 0 | ||||
-1 1 0 | |||||
-1 0 1 | |||||
0-1 1 | 0 | ||||
1-1 0 | |||||
Large voltage vectors | |||||
1-1-1 | 0 | 0 | |||
1 1-1 | |||||
-1 1-1 | |||||
-1 1 1 | 0 | ||||
-1-1 1 | |||||
1-1 1 |
Sector | Selected Vectors | Clamped Phase |
---|---|---|
1 | ||
2 | ||
3 | ||
4 | ||
5 | ||
6 |
Sector | Condition | Selected Vectors | Clamped Phase |
---|---|---|---|
1 | > | ||
< | |||
2 | > | ||
< | |||
3 | > | ||
< | |||
4 | > | ||
< | |||
5 | > | ||
< | |||
6 | > | ||
< |
H | H | e Kg·m | |
H | e N·m·s |
Weighting Factor | C-PTC | SV-PTC1 | SV-PTC2 |
---|---|---|---|
100 | 100 | 100 | |
1 | 1 | 0 | |
1e | 0 | 0 |
(Wb) | (N·m) | |
---|---|---|
C-PTC | 0.0987 | 3.58 |
SV-PTC1 | 0.0711 | 2.62 |
SV-PTC2 | 0.06 | 2.53 |
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Zouari, W.; El Badsi, I.N.; El Badsi, B.; Masmoudi, A. Three-Level NPC Inverter-Fed IM Drives under PTC, Minimizing the Involved Voltage Vectors and Balancing the DC Bus Capacitor Voltages. Sustainability 2022, 14, 13522. https://doi.org/10.3390/su142013522
Zouari W, El Badsi IN, El Badsi B, Masmoudi A. Three-Level NPC Inverter-Fed IM Drives under PTC, Minimizing the Involved Voltage Vectors and Balancing the DC Bus Capacitor Voltages. Sustainability. 2022; 14(20):13522. https://doi.org/10.3390/su142013522
Chicago/Turabian StyleZouari, Wiem, Imen Nouira El Badsi, Bassem El Badsi, and Ahmed Masmoudi. 2022. "Three-Level NPC Inverter-Fed IM Drives under PTC, Minimizing the Involved Voltage Vectors and Balancing the DC Bus Capacitor Voltages" Sustainability 14, no. 20: 13522. https://doi.org/10.3390/su142013522
APA StyleZouari, W., El Badsi, I. N., El Badsi, B., & Masmoudi, A. (2022). Three-Level NPC Inverter-Fed IM Drives under PTC, Minimizing the Involved Voltage Vectors and Balancing the DC Bus Capacitor Voltages. Sustainability, 14(20), 13522. https://doi.org/10.3390/su142013522