Research on Control Strategy of APSO-Optimized Fuzzy PID for Series Hybrid Tractors
Abstract
:1. Introduction
2. Power System Structure Design and Parameter Selection
- Pure electric driving mode: Storage Battery → Electric Coupler → Motor → Transmission Device → Driving Wheel.
- Pure engine driving mode: Engine → Generator → Electric Coupler → Motor → Transmission Device → Driving Wheel.
- Hybrid driving mode: Engine → Generator → Storage Battery → Electric Coupler → Motor → Transmission Device → Driving Wheel.
- Driving with charging mode: The energy flows in two ways. Driving mode: Engine → Generator → Electric Coupler → Motor → Transmission Device → Driving Wheel; Charging mode: Engine → Generator → Electric Coupler → Storage Battery.
3. Control Strategy
3.1. The Rule-Based Control Strategy
3.2. MOPFPCS
3.2.1. Determination of Multi-Operating Point
3.2.2. Fuzzy PID Control
- When |e| is large, to improve the system response speed, Kp should be increased. Simultaneously, to avoid excessive integral saturation, Kd should be decreased, and Ki is often set to 0.
- When |e| is moderate, to reduce the system overshoot, it is common to decrease Kp. and Ki can be appropriately increased to enhance the system’s regulation accuracy.
- When |e| is small, to improve system stability, Kp and Ki should be increased. Simultaneously, Kd should select a moderate value to prevent system oscillations near the equilibrium point.
3.3. APSO-Optimized Fuzzy PID Controller
3.3.1. APSO Algorithm Principle
3.3.2. APSO-Optimized Fuzzy PID
4. Modeling and Simulation
4.1. Simulation Model
4.2. Simulation Result Analysis
4.2.1. The Plowing Condition
4.2.2. The Transportation Condition
5. Conclusions
- (1)
- This study focuses on the SDEHT as the research object. A vehicle simulation model is developed, and a method based on APSO-MOPFPCS is proposed. Additionally, this research designs ESOPCS and MOPFPCS for comparative analysis.
- (2)
- The results indicate that in the plowing mode, APSO-MOPFPCS achieves a reduction of 18.3% and 9.5% in equivalent fuel consumption compared to ESOPCS and MOPFPCS, respectively. Similarly, in the transportation mode, APSO-MOPFPCS demonstrates a reduction of approximately 15.0% and 4.6% in equivalent fuel consumption compared to the ESOPCS and MOPFPCS, respectively. These findings highlight the effectiveness of the proposed APSO-MOPFPCS.
- (3)
- The control strategy based on APSO-MOPFPCS can adjust the engine speed according to the actual power demand of the entire vehicle so that the engine can work in the high-efficiency zone, maintain power, and improve fuel economy at the same time.
Author Contributions
Funding
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
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Project | Parameter | Value |
---|---|---|
Engine | Maximum power/kW | 60 |
Rated speed/(r/min) | 2400 | |
Maximum torque/(N·m) | 120 | |
Generator | Rated power/kW | 30 |
Rated speed/(r/min) | 1500 | |
Motor | Rated power/kW | 25 |
Rated speed/(r/min) | 2000 | |
Rated frequency/Hz | 50 | |
Storage battery | Rated voltage/V | 100 |
Rated capacity/Ah | 100 | |
Transmission | One-speed transmission ratio | 12 |
Two-speed transmission ratio | 8.45 | |
Three-speed transmission ratio | 5.65 | |
Four-speed transmission ratio | 3.2 | |
Main speed reducer | Transmission ratio | 3.5 |
ΔKp/ΔKi/ΔKd | E | |||||||
---|---|---|---|---|---|---|---|---|
NB | NM | NS | ZO | PS | PM | PB | ||
Ec | NB | PB/NB/PS | PB/NB/PS | PM/NB/ZO | PM/NM/ZO | PS/NM/ZO | PS/ZO/PB | ZO/ZO/ZO |
NM | PB/NB/NS | PB/NB/NS | PM/NM/NS | PM/NM/NS | PS/NS/ZO | ZO/ZO/PS | ZO/ZO/PM | |
NS | PM/NM/NB | PM/NM/NB | PM/NS/NM | PS/NS/NS | ZO/ZO/ZO | NS/PS/PS | NM/PS/PM | |
ZO | PM/NM/NB | PS/NS/NM | PS/NS/NM | ZO/ZO/NS | NS/PS/ZO | NM/PS/PS | NM/PM/PM | |
PS | PS/NS/NB | PS/NS/NM | ZO/ZO/NS | NS/PS/NS | NS/PS/ZO | NM/PM/PS | NM/PM/PS | |
PM | ZO/ZO/NM | ZO/ZO/NS | NS/PS/NS | NM/PM/NS | NM/PM/ZO | NM/PB/PS | NB/PB/PS | |
PB | ZO/ZO/PS | NS/ZO/ZO | NS/PS/ZO | NM/PM/ZO | NM/PB/ZO | NB/PB/PB | NB/PB/PB |
Optimization Object | Ke | Kec | Ku |
---|---|---|---|
Parameters before optimization | 0.671 | 0.124 | 0.426 |
Parameters after optimization | 0.832 | 0.085 | 0.691 |
Time/s | Plowing Velocity/(km/h) | Plowing Depth/cm |
---|---|---|
8~157 | 5 | 12 |
162~360 | 8 | 20 |
Control Strategy | Fuel Consumption/L | Battery Initial SOC/% | Battery Termination SOC/% | Equivalent Fuel Consumption/L |
---|---|---|---|---|
ESOPCS | 0.264 | 57 | 52.2 | 0.361 |
MOPFPCS | 0.237 | 57 | 52.6 | 0.326 |
APSO-MOPFPCS | 0.211 | 57 | 52.8 | 0.295 |
Control Strategy | Fuel Consumption/L | Battery Initial SOC/% | Battery Termination SOC/% | Equivalent Fuel Consumption/L |
---|---|---|---|---|
ESOPCS | 0.942 | 48 | 52.2 | 0.858 |
MOPFPCS | 0.898 | 48 | 54.8 | 0.764 |
APSO-MOPFPCS | 0.873 | 48 | 55.2 | 0.729 |
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Xu, L.; Wang, Y.; Li, Y.; Zhao, J.; Liu, M. Research on Control Strategy of APSO-Optimized Fuzzy PID for Series Hybrid Tractors. World Electr. Veh. J. 2023, 14, 258. https://doi.org/10.3390/wevj14090258
Xu L, Wang Y, Li Y, Zhao J, Liu M. Research on Control Strategy of APSO-Optimized Fuzzy PID for Series Hybrid Tractors. World Electric Vehicle Journal. 2023; 14(9):258. https://doi.org/10.3390/wevj14090258
Chicago/Turabian StyleXu, Liyou, Yiting Wang, Yanying Li, Jinghui Zhao, and Mengnan Liu. 2023. "Research on Control Strategy of APSO-Optimized Fuzzy PID for Series Hybrid Tractors" World Electric Vehicle Journal 14, no. 9: 258. https://doi.org/10.3390/wevj14090258
APA StyleXu, L., Wang, Y., Li, Y., Zhao, J., & Liu, M. (2023). Research on Control Strategy of APSO-Optimized Fuzzy PID for Series Hybrid Tractors. World Electric Vehicle Journal, 14(9), 258. https://doi.org/10.3390/wevj14090258