An Optimal Sizing Design Approach of Hybrid Energy Sources for Various Electric Vehicles
Abstract
:Featured Application
Abstract
1. Introduction
2. Development of Global Search Algorithm for HEESs
2.1. The Configuration of HEESs
2.2. The Procedures of the GSA
3. Case Study for Five Types of Electric Vehicles
3.1. Electric Sedan
3.2. Electric Forklift
3.3. Long-Distance Electric Bus
3.4. Short-Distance Electric Bus
3.5. Electric Sports Car
4. Simulation Results and Discussion
4.1. Parameters and Specifications of Energy Sources
4.2. GSA Results and Discussion
4.2.1. Optimization of Energy Sources
4.2.2. Case Study of Five Types of EVs
5. Conclusions
- (1)
- Performance indices and vehicle requirement: the average specific price, specific energy at a constant volume, specific energy at a constant mass, and specific power at a constant mass for three energy sources, SCs, LTO batteries, and Li3 batteries, were studied. The vehicle requirements including the maximum output power, vehicle acceleration, climbability, and maximum speed as the design constraints were formulated.
- (2)
- The GSA of the HEES: the global search method with four steps including parameter input, definition of cost function and constraints, global search, and optimal results was developed.
- (3)
- Numerical analysis of five types of EVs: by (1) and (2), five types of EVs including the electric sedan, electric forklift, long-distance electric bus, short-distance electric bus, and electric sports car were analyzed for optimal sizing of the HEES and the optimal position of the DC/DC converter with the lowest cost function. For the electric sedan, the optimal sizing was LTO+Li3 with a ratio of 9.9:90.1 and the DC/DC position was at Li3 side; for the electric forklift, the optimal sizing was SC+Li3 with a ratio of 4.5:95.5 and the DC/DC position was at SC side; for the long-distance electric bus, the optimal sizing was pure Li3 with no DC/DC converter; for the short-distance electric bus, the optimal sizing was LTO+Li3 with a ratio of 44.4:55.6 and the DC/DC position was at Li3 side; and for the electric sports car, the optimal sizing was SC+Li3 with a ratio of 0.58:99.42 and the DC/DC position was at Li3 side.
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Conflicts of Interest
References
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Parameter | Value | Average |
---|---|---|
Specific power (kW/kg) | 5 [24] | 7.3 |
10 [25] | ||
6.9 [26] | ||
Specific price (USD/kWh) | 10,000 [24] | 10,000 |
Power density (kWh/L) | 0.0085 [27] | 0.0085 |
Specific energy (kWh/kg) | 0.005 [24] | 0.00484 |
0.0065 [27] | ||
0.00302 [28] |
Parameter | Value | Average |
---|---|---|
Specific power (kW/kg) | 3.2 [29] | 2.7625 |
2.25 [30] | ||
2.4 [17] | ||
3.2 [2] | ||
Specific price (USD/kWh) | 432 [29] | 578.66 |
899 [2] | ||
405 [31] | ||
Power density (kWh/L) | 0.09 [30] | 0.138 |
0.147 [31] | ||
0.177 [32] | ||
Specific energy (kWh/kg) | 0.085 [33] | 0.0635 |
0.042 [30] | ||
0.0715 [31] | ||
0.046 [2] | ||
0.0464 [17] | ||
0.09 [32] |
Parameter | Value | Average |
---|---|---|
Specific power (kW/kg) | 0.433 [2] | 0.416 |
0.362 [2] | ||
0.454 [17] | ||
Specific price (USD/kWh) | 362 [2] | 397.5 |
433 [2] | ||
Power density (kWh/L) | 0.37 [32] | 0.400 |
0.493 [31] | ||
0.339 [34] | ||
Specific energy (kWh/kg) | 0.174 [30] | 0.201 |
0.214 [31] | ||
0.241 [17] | ||
0.144 [2] | ||
0.241 [2] | ||
0.24 [35] | ||
0.153 [34] |
HEES Configuration | HP Capacity (kWh) | HE Capacity (kWh) | Total Capacity (kWh) | HP Power (kW) | HE Power (kW) | Power Demand (kW) | Weight (kg) | Volume (L) | Price (USD) | DCDC Position |
---|---|---|---|---|---|---|---|---|---|---|
LTO+Li3 | 7.459 (9.94%) | 67.541 (90.05%) | 75 | 324.50 | 139.78 | 464.25 | 453.49 | 222.62 | 33,111 | HE |
SC+Li3 | 0.216 (0.29%) | 74.784 (99.71%) | 75 | 345.79 | 154.78 | 455.64 | 416.69 | 212.06 | 33,842 | HE |
HEES Configuration | HP Capacity (kWh) | HE Capacity (kWh) | Total Capacity (kWh) | HP Power (kW) | HE Power (kW) | Power Demand (kW) | Weight (kg) | Volume (L) | Price (USD) | DCDC Position |
---|---|---|---|---|---|---|---|---|---|---|
LTO+Li3 | -- | -- | -- | -- | -- | -- | -- | -- | -- | -- |
SC+Li3 | 1.357 (4.52%) | 28.643 (95.48%) | 30 | 2046.71 | 59.281 | 2000 | 422.87 | 231.14 | 24,973 | HP |
HEES Configuration | HP Capacity (kWh) | HE Capacity (kWh) | Total Capacity (kWh) | HP Power (kW) | HE Power (kW) | Power Demand (kW) | Weight (kg) | Volume (L) | Price (USD) | DCDC Position |
---|---|---|---|---|---|---|---|---|---|---|
LTO+Li3 | 0 | 100 | 100 | 0 | 441.62 | 300 | 9211.5 | 199.67 | 39,750 | -- |
SC+Li3 | 0 | 100 | 100 | 0 | 441.62 | 300 | 9211.5 | 199.67 | 39,750 | -- |
HEES Configuration | HP Capacity (kWh) | HE Capacity (kWh) | Total Capacity (kWh) | HP Power (kW) | HE Power (kW) | Power Demand (kW) | Weight (kg) | Volume (L) | Price (USD) | DCDC Position |
---|---|---|---|---|---|---|---|---|---|---|
LTO+Li3 | 32 (44.4%) | 40 (55.6%) | 72 | 1392.12 | 82.79 | 528.66 | 13,702 | 331.72 | 34,914 | HE |
SC+Li3 | -- | -- | -- | -- | -- | -- | -- | -- | -- | -- |
HEES Configuration | HP Capacity (kWh) | HE Capacity (kWh) | Total Capacity (kWh) | HP Power (kW) | HE Power (kW) | Power Demand (kW) | Weight (kg) | Volume (L) | Price (USD) | DCDC Position |
---|---|---|---|---|---|---|---|---|---|---|
LTO+Li3 | -- | -- | -- | -- | -- | -- | -- | -- | -- | -- |
SC+Li3 | 0.578 (0.578%) | 99.422 (99.422%) | 100 | 871.77 | 422.26 | 692.67 | 595.1 | 298.4 | 45,315 | HE |
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Chen, S.-Y.; Chiu, C.-Y.; Hung, Y.-H.; Jen, K.-K.; You, G.-H.; Shih, P.-L. An Optimal Sizing Design Approach of Hybrid Energy Sources for Various Electric Vehicles. Appl. Sci. 2022, 12, 2961. https://doi.org/10.3390/app12062961
Chen S-Y, Chiu C-Y, Hung Y-H, Jen K-K, You G-H, Shih P-L. An Optimal Sizing Design Approach of Hybrid Energy Sources for Various Electric Vehicles. Applied Sciences. 2022; 12(6):2961. https://doi.org/10.3390/app12062961
Chicago/Turabian StyleChen, Syuan-Yi, Chu-Yang Chiu, Yi-Hsuan Hung, Kuo-Kuang Jen, Gwo-Huei You, and Po-Lin Shih. 2022. "An Optimal Sizing Design Approach of Hybrid Energy Sources for Various Electric Vehicles" Applied Sciences 12, no. 6: 2961. https://doi.org/10.3390/app12062961
APA StyleChen, S. -Y., Chiu, C. -Y., Hung, Y. -H., Jen, K. -K., You, G. -H., & Shih, P. -L. (2022). An Optimal Sizing Design Approach of Hybrid Energy Sources for Various Electric Vehicles. Applied Sciences, 12(6), 2961. https://doi.org/10.3390/app12062961