Driving Control Strategy and Specification Optimization for All-Wheel-Drive Electric Vehicle System with a Two-Speed Transmission
Abstract
:1. Introduction
- (i)
- A method is presented for the simultaneous optimization of motor specifications, reduction ratios, and shift maps, considering torque distribution strategies for both front and rear wheels, which is expected to maximize vehicle performance;
- (ii)
- An objective function was designed by training electric vehicle simulation data using deep learning for application in multi-objective optimization. This approach enhances the credibility of selecting optimal specifications for the AWD EV powertrain.
2. AWD Vehicle Modeling with Two-Speed Transmission
2.1. Parameters of the Target Vehicle
2.2. AWD Electric Vehicle Model-Based Simulation
- (1)
- Driving Cycle and Vehicle: Vehicle speed is calculated based on the driving cycle, and from this speed, driving resistance is computed to determine the vehicle-level output force. The calculation for vehicle-level output force is as follows [16].
- (2)
- VCU: Based on the vehicle-level required torque, values for Accel Pedal (AP) and Brake Pedal (BP) are calculated. Then, the torque distribution logic derives the required torque levels for the front and rear motors. Estimating vertical forces for the front and rear axles is also conducted simultaneously. The formula for estimating vertical forces is as follows.
- (3)
- Motor: Motor efficiency is determined based on the required motor torque and speed calculated by the VCU. The motor efficiency map was adapted by transforming the x- and y-axis scale of the reference motor’s efficiency map. Section 4 discusses the efficiency map scaling method in detail. Then, considering the motor efficiency and the battery’s Open Circuit Voltage (OCV), the battery current is calculated. The speed of the rear motor is inputted, considering the transmission’s first and second-gear ratios. The calculation for the battery current during motor charge and discharge, considering motor torque, speed, and efficiency, is as follows.
- (4)
- Battery: The SOC is calculated using the Open Circuit Voltage and the required battery current. Then, the voltage applied to the motor is computed using the SOC and the circuit voltage values. The battery model utilizes a first-order R equivalent circuit model, as shown in Figure 3. The formulas for calculating the motor applied voltage and SOC are as follows:
- (5)
- Transmission: Unlike internal combustion engine vehicles, electric cars benefit from the torque-speed characteristics of electric motors, which provide high torque at low speeds and maintain constant power across an extended speed range. Due to these characteristics, electric vehicles can achieve the necessary performance with fewer gears [17]. Transmission modeling can consider various structures, and in this paper, a dog clutch-type transmission system was selected. The dog clutch is simple in structure and excellent in power transmission efficiency, making it suitable for electrified transmission systems. Due to these characteristics, it can be utilized in two-speed transmission systems.
2.3. Gear Shift Mechanism
- State 1. Torque Phase and Gear Neutral: When a gear shift command is issued, the torque of the rear motor is controlled to zero. Simultaneously, the torque of the front motor is compensated to maintain maximum total torque [18]. After the torque phase, the control shifts to neutral in the transmission.
- State 2. Speed Synchronization: Control the motor to the target speed range to mitigate shocks during the clutch engagement due to speed changes in the dog clutch gear when shifting. The speed synchronization phase ends when the difference between the target and motor speeds is less than or equal to 1 rad/s. The formula to calculate the motor speed when in neutral is as follows.
- State 3. Gear Engagement and Torque Phase: Engage the dog clutch actuator and normalize the torque distribution between the front and rear motors.
3. Integrated Torque Distribution Logic
3.1. Detailed Torque Distribution Logic
3.1.1. Energy Efficiency-Based Torque Distribution Strategy
3.1.2. Vertical Force-Based Torque Distribution Strategy
3.2. Integration of Torque Distribution Based on Fuzzy Logic
4. Powertrain Specification Optimization Strategy
4.1. Objective Function Creation for Optimization Based on a Surrogate Model
4.1.1. Neural Network Training: Description of Input and Output Variables
4.1.2. Description of Adaptive Sampling Methods and Learning Techniques
4.2. NSGA-II Based Multi-Objective Optimization
5. Results
6. Conclusions
Author Contributions
Funding
Data Availability Statement
Acknowledgments
Conflicts of Interest
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Item | Value [Unit] |
---|---|
Vehicle mass (Sedan/SUV/SUV-Trailer), m | 2265/2728/5803 [kg] |
Base motor power, P/Maximum torque, T | 92 [kW]/230 [Nm] |
Base motor max speed, ωmax/motor base speed, ωbase | 20,000 [RPM]/3820 [RPM] |
Battery capacity, Qn | 77.4 [kWh] |
Initial front gear ratio, if | 10.65 [-] |
Initial rear 1st/2nd gear ratio, ir1/ir2 | 14 [-]/6 [-] |
Indicators | Value [Unit] |
---|---|
Maximum vehicle speed (Sedan/SUV/SUV-Trailer) | 225/170/128 [km/h] |
Maximum climbing grade | 60 [%] |
Acceleration time (0~96 km/h) | 4.1/5.0/20.0 [s] |
Solution | Sedan | SUV | SUV-Trailer |
---|---|---|---|
A | −1.57% | −1.12% | −1.79% |
B | 1.56% | 1.23% | 1.29% |
C | −0.58% | −0.37% | −0.56% |
Solution | Sedan | SUV | SUV-Trailer |
A | 18.8% | 14.1% | 35.7% |
B | −37.2% | −36.4% | −36.5% |
C | −15.1% | −14.6% | −13.1% |
Solution | Sedan | SUV | SUV-Trailer |
---|---|---|---|
A | −1.22% | −1.01% | −3.98% |
B | 0.58% | 0.82% | 0.01% |
C | −0.96% | −0.41% | −1.91% |
Solution | Sedan | SUV | SUV-Trailer |
---|---|---|---|
A | 18.7% | 13.9% | 35.7% |
B | −37.1% | −36.4% | −36.4% |
C | −5.52% | −14.4% | −3.49% |
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Kim, J.; Ahn, J.; Jeong, S.; Park, Y.-G.; Kim, H.; Cho, D.; Hwang, S.-H. Driving Control Strategy and Specification Optimization for All-Wheel-Drive Electric Vehicle System with a Two-Speed Transmission. World Electr. Veh. J. 2024, 15, 476. https://doi.org/10.3390/wevj15100476
Kim J, Ahn J, Jeong S, Park Y-G, Kim H, Cho D, Hwang S-H. Driving Control Strategy and Specification Optimization for All-Wheel-Drive Electric Vehicle System with a Two-Speed Transmission. World Electric Vehicle Journal. 2024; 15(10):476. https://doi.org/10.3390/wevj15100476
Chicago/Turabian StyleKim, Jeonghyuk, Jihyeok Ahn, Seyoung Jeong, Young-Geun Park, Hyobin Kim, Dongwook Cho, and Sung-Ho Hwang. 2024. "Driving Control Strategy and Specification Optimization for All-Wheel-Drive Electric Vehicle System with a Two-Speed Transmission" World Electric Vehicle Journal 15, no. 10: 476. https://doi.org/10.3390/wevj15100476
APA StyleKim, J., Ahn, J., Jeong, S., Park, Y. -G., Kim, H., Cho, D., & Hwang, S. -H. (2024). Driving Control Strategy and Specification Optimization for All-Wheel-Drive Electric Vehicle System with a Two-Speed Transmission. World Electric Vehicle Journal, 15(10), 476. https://doi.org/10.3390/wevj15100476