Current Li-Ion Battery Technologies in Electric Vehicles and Opportunities for Advancements
Abstract
:1. Introduction
The Progression of Battery Technologies Used for EV Applications
2. The Li-Ion Batteries
2.1. Positive Electrode
2.1.1. Lithium Cobalt Oxide (LiCoO2)
2.1.2. Lithium Nickel Oxide (LiNiO2)
2.1.3. Lithium Manganese Oxide (LiMn2O4)
2.1.4. Lithium Iron Phosphate (LiFePO4)
2.1.5. Lithium Nickel Manganese Cobalt Oxide (Li(NixMnyCo1−x−y)O2)
2.1.6. Lithium Nickel Cobalt Aluminum Oxide (Li(NixCoyAl1−x−y)O2)
2.2. Negative Electrode
2.2.1. Carbon Based Electrodes
2.2.2. Lithium Titanate (Li4Ti5O12)
2.2.3. Lithium Metal
2.2.4. Alloy Based Electrodes
2.2.5. Silicon Based Electrodes
2.2.6. Conversion Electrodes
2.3. Electrolytes
2.3.1. Aqueous Electrolytes
2.3.2. Organic Liquid Electrolytes
2.3.3. Polymer Electrolytes
2.3.4. Ceramic Electrolytes
2.3.5. Solid Electrolyte Interphase
2.4. Physical Implementation of Li-Ion Batteries
2.5. Comparisons of Different Types of Li-Ion Batteries Used in Electric Vehicles
3. Li-Ion Battery Lifespan
3.1. Temperature
3.2. Charge/Discharge Rate
3.3. Charge/Discharge Depth
3.4. Additonal Ways to Extend the Life of Li-Ion Batteries
4. Recycling and Repurposing
4.1. Recycling
4.2. Repurposing for Power Grid
5. Conclusions
Author Contributions
Funding
Conflicts of Interest
References and Note
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Shape | Cylindrical | Prismatic | Pouch |
---|---|---|---|
Diagram | |||
Electrode Arrangement | Wound | Wound | Stacked |
Mechanical Strength | ++ | + | − |
Heat Management | − | + | + |
Specific Energy | + | + | ++ |
Energy Density | + | ++ | + |
Components of BMS | Functional Details of Each Component |
---|---|
Measurement Block | capture individual cell voltages, battery current, and battery temperature at different points of the battery bank, as well as the ambient temperature, and convert them into digital values |
Battery Algorithm Block | estimate state of charge (SOC) 1 and state of health (SOH) 2 using the measured battery variables such as battery voltage, current, and temperature |
Capability Estimation Block | send information to the engine control unit (ECU) about the present safe level of charging and discharging current of the battery |
Cell Equalization Block | compare the cell voltages, find the difference between the highest and lowest cell voltage, and apply cell balancing techniques |
Thermal Management Block | read ambient and battery temperatures, initiate cooling or heating operation, and send an emergency signal to ECU in case of abnormal rise in temperature |
Depth of Discharge | Discharge Cycles (NMC/LiPO4) |
---|---|
100% | 300–600 |
80% | 400–900 |
60% | 600–900 |
40% | 1000–3000 |
20% | 2000–9000 |
10% | 6000–15,000 |
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Miao, Y.; Hynan, P.; von Jouanne, A.; Yokochi, A. Current Li-Ion Battery Technologies in Electric Vehicles and Opportunities for Advancements. Energies 2019, 12, 1074. https://doi.org/10.3390/en12061074
Miao Y, Hynan P, von Jouanne A, Yokochi A. Current Li-Ion Battery Technologies in Electric Vehicles and Opportunities for Advancements. Energies. 2019; 12(6):1074. https://doi.org/10.3390/en12061074
Chicago/Turabian StyleMiao, Yu, Patrick Hynan, Annette von Jouanne, and Alexandre Yokochi. 2019. "Current Li-Ion Battery Technologies in Electric Vehicles and Opportunities for Advancements" Energies 12, no. 6: 1074. https://doi.org/10.3390/en12061074
APA StyleMiao, Y., Hynan, P., von Jouanne, A., & Yokochi, A. (2019). Current Li-Ion Battery Technologies in Electric Vehicles and Opportunities for Advancements. Energies, 12(6), 1074. https://doi.org/10.3390/en12061074