Low-Cost DTC Drive Using Four-Switch Inverter for Low Power Ranges
Abstract
:1. Introduction
1.1. Market Size of AC Drives
1.2. History of DTC and Pioneer Contributors
1.3. Evolution toward High-Performance AC Drive
- Scalar Control Drives:
- 2.
- Vector Control (VC) or Field Oriented Control (FOC) Drives:
- 3.
- Direct Torque Control (DTC) Drives:
2. Principles of the DTC Strategy Using a B6 Inverter
2.1. Block Diagram and Core Components of DTC
- Motor transient model to compute the stator flux vector and electromagnetic torque;
- Dual hysteresis on/off controllers: one for the flux and the other for the torque;
2.2. Space Vector Representation
2.3. Control of the Stator Flux and Electromagnetic Torque
2.4. Machine Model Used with the DTC
2.4.1. Computation of Stator Voltage Vector
2.4.2. Computation of Stator Current Vector
2.4.3. Computation of Stator Flux Vector
2.4.4. Computation of Electromagnetic Torque
3. Advantages and Drawbacks (Limitations) of DTC
3.1. Advantages of DTC
- DTC provides quick torque and flux response [21];
- With DTC, rated electromagnetic torque can be produced at zero speed;
- It is based on a machine model with moderate complexity;
- The DTC system can be implemented with conventional data acquisition cards;
- The conventional algorithm of the DTC needs a few machine parameters;
- Sensorless operation is possible with good accuracy.
3.2. Disadvantages and Limitations of DTC
- The conventional DTC scheme is not appropriate for servo applications [22];
4. DTC Using a Four-Switch Inverter as a Non-Conventional Inverter Scheme
4.1. Operation of Four-Switch Inverter
- Since the incorporation of PWM LSC increases the overall cost of the drive, there is a desire to reduce the cost and achieve an economical AC drive with a satisfactory performance.
4.2. Possible Configurations of Low-Cost AC Drives
4.3. Space Vector Representation of the Four-Switch Inverter
- The vectors are not equal; they have different magnitudes;
- The vectors are displaced 90° electrically from each other [34];
4.4. Principles of Flux and Torque Control with the Four-Switch Inverter
5. Experimental Setup
- ▪
- Three-phase IGBT inverter (with an open control feature) is constructed with all necessary auxiliary circuits (isolation, drive, over-current protection, and short circuit protection). One inverter leg can be disabled and substituted by two identical capacitors (1200 μF) to select between FSTPI and SSTPI topologies;
- ▪
- A data acquisition card PCL-1800 (using C code) is used to carry out all software routines of the DTC algorithm. The parameters of the IM (stator resistance and number of poles) and the set point of the stator flux are plugged into the program. They can be modified according to the motor rating. The reference electromagnetic torque is an external analog input to the data acquisition card;
- ▪
- Two Hall-effect current transducers are utilized to measure the motor phase currents;
- ▪
- A Hall-effect voltage transducer is employed to measure the DC link voltage to calculate the orthogonal components of the stator voltage vector (Vα and Vβ).
6. Experimental Results of the Investigated DTC Systems
6.1. Experimental Results of the DTC System Using a B6 Inverter
6.2. Experimental Results of DTC Using a B4 Inverter
6.3. Quantitative Comparison between Both DTC Systems
7. Conclusions
Funding
Data Availability Statement
Conflicts of Interest
Abbreviations
BLDC | Brushless DC motor |
CCW | Counterclockwise |
CW | Clockwise |
DTC | Direct torque control |
DSP | Digital signal processor |
FO | Field orientation |
FPGA | Field programmable gate array |
FSTPI | Four-switch three-phase inverter |
THD | Total harmonic distortion |
SSTPI | Six-switch three-phase inverter |
HIL | Hardware in the loop |
IM | Induction motor |
EV | Electric vehicle |
MPC | Model predictive control |
PC | Personal computer |
PCI | Peripheral component interconnect |
PM | Permanent magnet |
PWM | Pulse width modulation |
RISC | Reduced instruction set computer |
SC | Scalar control |
SRM | Switched reluctance motor |
SVM | Space vector modulation |
VC | Vector control |
VSI | Voltage source inverter |
Symbols | |
Va | Armature voltage of a separately excited DC motor (V) |
Vf | Field voltage of a separately excited DC motor (V) |
Ia | Armature current of a separately excited DC motor (A) |
If | Field current of separately excited DC motor (A) |
Φ | Magnetic flux of separately excited DC motor (Wb) |
Reference value of electromagnetic torque (Nm) | |
Tem | Actual electromagnetic torque (Nm) |
Stator current of three-phase induction motor (A) | |
Rotor current of three-phase induction motor (A) | |
Magnetizing current of three-phase induction motor (A) | |
Airgap flux of three-phase induction motor (Wb) | |
Stator flux vector (Wb) | |
, | Stator flux components in the stationary reference frame (Wb) |
Id, Iq | Direct and Quadrature components of stator current (A) |
Stator voltage space vector (V) | |
S1, S3, S5 | Switching states of the inverter power transistors |
V1 → V6 | Discrete stator voltage space vector |
VDC | DC link voltage of the VSI (V) |
, | Instantaneous values of stator voltage components in stationary reference frame (V) |
, | Instantaneous values of stator current components in stationary reference frame (A) |
HΦ | Hysteresis band of flux controller (%) |
HT | Hysteresis band of torque controller (%) |
Instantaneous flux angle of stator flux vector (deg or rad) | |
ΔΦS | Error between reference and actual stator flux (Wb) |
ΔTe | Error between reference and actual electromagnetic torque (Nm) |
Reference motor speed (rpm) | |
Actual motor speed (rpm) |
Appendix A
Electric Machine | |
Type | squirrel cage IM |
Power rating | 1.35 kW |
P | 4 poles |
Rs | 4.59 Ω |
Rr | 3.95 Ω |
Lm | 0.443 H |
Ls | 0.613 H |
Lr | 0.464 H |
Hall-effect current transducers | LA 55P |
Hall-effect voltage transducers | LV 25P |
Capacitors (C) of B4 inverter | 2 × 1 mF |
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Advantages | Disadvantages | |
---|---|---|
SC Drives |
|
|
VC Drives |
|
|
DTC drives |
|
|
Switching State S1 S3 S5 | Vector Notation Vx | Space Vector | (α–β) Components Vα and Vβ | ||
---|---|---|---|---|---|
Mag. | Angle | Vα | Vβ | ||
0 0 0 | V0 | 0 | N/A | 0 | 0 |
1 0 0 | V1 | 0 | 0 | ||
1 1 0 | V2 | ||||
0 1 0 | V3 | ||||
0 1 1 | V4 | π | 0 | ||
0 0 1 | V5 | ||||
1 0 1 | V6 | ||||
1 1 1 | V7 | 0 | N/A | 0 | 0 |
ΔΦ | ΔTe | Sector 1 0–90 | Sector 2 90–180 | Sector 3 180–270 | Sector 4 270–360 |
---|---|---|---|---|---|
1 | 1 | 1 0 | 1 1 | 0 1 | 0 0 |
1 | −1 | 0 0 | 1 0 | 1 1 | 0 1 |
0 | 1 | 1 1 | 0 1 | 0 0 | 1 0 |
0 | −1 | 0 1 | 0 0 | 1 0 | 1 1 |
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Azab, M. Low-Cost DTC Drive Using Four-Switch Inverter for Low Power Ranges. Vehicles 2024, 6, 895-919. https://doi.org/10.3390/vehicles6020043
Azab M. Low-Cost DTC Drive Using Four-Switch Inverter for Low Power Ranges. Vehicles. 2024; 6(2):895-919. https://doi.org/10.3390/vehicles6020043
Chicago/Turabian StyleAzab, Mohamed. 2024. "Low-Cost DTC Drive Using Four-Switch Inverter for Low Power Ranges" Vehicles 6, no. 2: 895-919. https://doi.org/10.3390/vehicles6020043
APA StyleAzab, M. (2024). Low-Cost DTC Drive Using Four-Switch Inverter for Low Power Ranges. Vehicles, 6(2), 895-919. https://doi.org/10.3390/vehicles6020043