A method for deep drying and water removal
A drying and deep technology, applied in the direction of drying solid materials, drying solid materials without heating, drying, etc., can solve the problems of battery performance impact and harm, and achieve the effect of improving drying effect, thorough drying, and not easy to residue
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Embodiment 1
[0017] Example 1, taking the application of battery core drying in the lithium battery industry as an example
[0018] Heat the battery core to 50°C in the oven, vacuumize, and pass a certain amount of methanol. Methanol exists in the form of gas in the vacuum environment, and quickly and fully contacts the surface of the dried battery core, and fills the gap between the battery core and the inside of the battery core. Part of the water molecules are replaced by methanol gas molecules to the outside of the battery core, and then vacuumized for more than 10 minutes to remove the mixture of methanol and water, and the methanol can be recycled and reused. Repeat the above operations until the drying effect is satisfactory, then heat to above 65°C and purge with dry high-purity inert gas to remove excess methanol.
[0019] The drying effect varies with different materials. According to the Karl Fischer Coulometer test, the water content of the battery cells dried by this method is...
Embodiment 2
[0021] Heat the battery core to 70°C in the oven, vacuumize, and pass a certain amount of ethanol. The ethanol exists in the form of gas in the vacuum environment, and quickly and fully contacts the surface of the dried battery core, and fills the gap between the battery core and the inside of the battery core. Part of the water molecules are replaced by ethanol gas molecules to the outside of the battery core, and then vacuumed for more than 30 minutes to remove the mixture of ethanol and water, and the ethanol can be recycled and reused. Repeat the above operations until the drying effect is satisfactory, then heat to above 78°C and purge with dry high-purity inert gas to remove excess ethanol.
[0022] According to the Karl Fischer coulometer test, the moisture content of the battery cells dried by this method is basically less than 100ppm depending on the material of the battery cells.
Embodiment 3
[0023] Example 3, taking the application of transformer insulation fiber drying in the electrical industry as an example
[0024] Heat the insulating fiber to 50°C in the oven, vacuumize, and pass a certain amount of methanol. Methanol exists in the form of gas in the vacuum environment, and quickly and fully contacts the surface of the dried insulating fiber, and fills the gap between the insulating fiber and the battery core. Part of the water molecules are replaced by methanol gas molecules to the outside of the battery core, and then vacuumed for more than 2 minutes to remove the mixture of methanol and water, and the methanol can be recycled and reused. Repeat the above operations until the drying effect is satisfactory, then heat to above 65°C and purge with dry high-purity inert gas to remove excess methanol.
[0025] The drying effect varies with different materials. According to the Karl Fischer coulometer test, the moisture content of the insulating fibers dried by t...
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