Which cooling system works best in electric vehicles?
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Battery thermal management systems are still a highly researched topic. What we know about them is going to change and develop over the coming years as engineers continue to rethink how our car engines work.
There are a few options to cool an electric car battery: phase change material, fins, air or a liquid coolant.
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Phase change material absorbs heat energy by changing state from solid to liquid. While changing phase, the material can absorb large amounts of heat with little change in temperature. Phase change material cooling systems can meet the cooling requirements of the battery pack. However, the volume change that occurs during a phase change restricts its application. Also, phase change material can only absorb heat generated, not transfer it away, which means that it won't be able to reduce overall temperature as well as other systems. Although not favorable for use in vehicles, phase change materials can be useful for improving thermal performance in buildings by reducing internal temperature fluctuations and reducing peak cooling loads.
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Cooling fins increase surface area to increase the rate of heat transfer. Heat is transferred from the battery pack to the fin through conduction, and from the fin to the air through convection. Fins have high thermal conductivity and can achieve cooling goals, but they add a lot of additional weight to the pack. The use of fins has found a lot of success in electronics. Traditionally, they have been used as an additional cooling system on internal combustion engine vehicles. Using fins to cool the electric car battery has fallen out of favor since the additional weight of the fins outweighs the cooling benefits.
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Air cooling uses the principle of convection to transfer heat away from the battery pack. As air runs over the surface, it will carry away the heat emitted by the pack. Air cooling is simple and easy, but not very efficient and relatively crude compared to liquid cooling. Air cooling is used in earlier versions of electric cars, such as the Nissan Leaf. As electric cars are now being used more commonly, safety issues have arisen with purely air-cooled battery packs, particularly in hot climates. Other car manufacturers, such as Tesla, insist that liquid cooling is the safest method.
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Liquid coolants have higher heat conductivity and heat capacity (ability to store heat in the form of energy in its bonds) than air, and therefore perform very effectively and own advantages like compact structure and ease of arrangement. Out of these options, liquid coolants will deliver the best performance for maintaining a battery pack in the correct temperature range and uniformity. Liquid cooling systems have their own share of safety issues related to leaking and disposal, as glycol can be dangerous for the environment if handled improperly. These systems are currently used by Tesla, Jaguar and BMW, to name a few.
A research group from the National Renewable Energy Lab (USA) and the National Active Distribution Network Technology Research Center (China) compared four different cooling methods for Li-ion pouch cells: air, indirect liquid, direct liquid and fin cooling systems. T
The results show that: an air-cooling system needs two to three times more energy than other methods to keep the same average temperature; an indirect liquid cooling system has the lowest maximum temperature rise; and a fin cooling system adds about 40% extra weight of cell, which weighs most when the four kinds cooling methods have the same volume.
Indirect liquid cooling is a more practical form than direct liquid cooling, though it has slightly lower cooling performance. (Comparison of different cooling methods for lithium-ion battery cells)
The determining features of an electric vehicle battery cooling system are temperature range and uniformity, energy efficiency, size, weight, and ease of usage (i.e., implementation, maintenance).
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Each of these proposed systems can be designed to achieve the correct temperature range and uniformity. Energy efficiency is more difficult to achieve, as the cooling effects need to be greater than the heat generated when powering the cooling system. Also, a system with too much additional weight will drain energy from the car as it outputs power.
Phase change material, fan cooling and air cooling all fail at the energy efficiency and size and weight requirements, though they may be just as easy to implement and maintain as liquid cooling. Liquid cooling is the only remaining option that does not consume too much parasitic power, delivers cooling requirements, and fits compactly and easily into the battery pack.
Tesla, BMW i-3 and i-8, Chevy Volt, Ford Focus, Jaguar i-Pace, and LG Chem's lithium-ion batteries all use some form of liquid cooling system. Since electric vehicles are still a relatively new technology, there have been problems maintaining temperature range and uniformity in extreme temperatures even when using a liquid cooling system. These are likely due to manufacturing problems, and as companies gain experience developing these systems, the thermal management issues should be resolved.
In liquid cooling systems, there is another division between direct and indirect cooling'whether the cells are submerged in the liquid or if the liquid is pumped through pipes.
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Direct cooling systems place the battery cells in direct contact with the coolant liquid. These thermal management schemes are currently in the research and development stage, with no cars on the market using this system. Direct cooling is more difficult to achieve, due to the fact that a new type of coolant is required. Because the battery is in contact with the liquid, the coolant needs to have low to no conductivity.
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Indirect cooling systems are similar to ICE cooling systems in that both circulate liquid coolant through a series of metal pipes. However, the construction of the cooling system will look much different in electric vehicles. The structure of the cooling system that achieves maximum temperature uniformity is dependent on the shape of the battery pack and will look different for each car manufacturer.
As electric vehicles (EVs) become more prevalent, the need for effective thermal management solutions in their battery systems has never been more critical. These systems, primarily composed of lithium-ion (Li-ion) cells, offer a superior combination of high energy density, extended life cycles, and the ability to charge and discharge rapidly. However, the electrochemical nature of Li-ion batteries makes them susceptible to heat generation, which can pose significant challenges to safety, performance, and longevity.
Why is Thermal Management Vital for EV Batteries?
Li-ion batteries have revolutionized the EV industry due to their ability to power vehicles for hundreds of miles on a single charge. However, the very properties that make them suitable for this purpose also create the need for efficient thermal management. Here's why:
- Electrochemical Heat Generation: The internal reactions within Li-ion cells produce considerable heat during charging, discharging, and vehicle operation. Without proper cooling mechanisms, this heat can accumulate, leading to performance degradation.
- Flammable Electrolyte Composition: The electrolyte in Li-ion batteries, which facilitates the flow of electric charges, is made of organic compounds that are highly flammable. This increases the risk of thermal runaway, where excessive heat triggers uncontrolled chemical reactions, potentially leading to fires that are notoriously difficult to extinguish.
Li-ion Batteries and Temperature Sensitivity
Temperature fluctuations play a significant role in the aging and effectiveness of Li-ion cells. When temperatures fall below 0°C, the batteries experience rapid degradation, and their ability to deliver power diminishes. In extreme cold, such as below -40°C, battery failure becomes a real concern. On the opposite end, excessive heat accelerates aging, reduces power capacity, and can trigger thermal runaway events, threatening the safety of the entire system.
Key Benefits of Thermal Management for EV Batteries
- Heat Dissipation: Proper thermal management systems dissipate excess heat generated by Li-ion batteries, preventing localized hot spots that could compromise performance or lead to dangerous malfunctions.
- Isolation of Overheating Cells: In multi-cell battery packs, it's crucial to contain the heat from overheating cells to prevent chain reactions that could lead to system failure or fires.
- Enhanced Structural Support: Beyond temperature regulation, thermal management materials like thermally conductive adhesives provide structural support to battery assemblies, improving overall system integrity.
- Prevention of Uneven Cell Aging: Temperature variations can cause individual cells to age at different rates, leading to imbalances in the battery pack. Thermal management systems ensure uniformity in aging and performance across all cells.
- Electrical Insulation: Effective solutions also insulate battery components from electric arcing, which can otherwise damage sensitive parts or pose safety risks.
The Role of Advanced Thermal Management Solutions in EV Safety
Electric vehicles rely heavily on thermally conductive materials to ensure not only efficiency but also safety. These solutions are essential for dissipating heat during regular operation, isolating faulty cells, and preventing thermal runaway events. As EV adoption grows, integrating advanced thermal management technologies is vital for the safety, reliability, and longevity of EV battery systems.
To learn more about thermal management for electric vehicle battery systems, download H.B. Fuller's latest e-book or reach out to [ protected]
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