An electrode and sodium-ion battery
A sodium-ion battery and electrode technology, applied in battery electrodes, secondary batteries, circuits, etc., can solve problems such as limited batch use, unsatisfactory battery life, and negative electrode collapse and damage, and achieve excellent electrical performance and safety performance.
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Embodiment 1
[0012] Fill the reaction chamber with argon, add 5 kg of antimony and 5 kg of sodium into the furnace, heat to 650 ° C for 2 hours, pour the molten slurry into the mold, cool to room temperature, remove the alloy blank, cut and punch it into an electrode shape, put it into 50 kg of absolute ethanol, soak it for 4 hours, take it out of the reaction chamber and dry it to get the porous antimony alloy electrode. Then use sodium-based Prussian blue as the positive electrode material for sodium-ion batteries, and make positive sheets through slurry mixing, coating, rolling, and slitting, and then use porous antimony alloy electrodes as negative electrodes through lamination, welding, packaging, and baking. A batch of 10Ah sodium-ion power batteries were prepared through processes such as liquid injection, formation, and volume separation.
Embodiment 2
[0014] Fill the reaction chamber with argon, add 7kg of antimony and 3kg of sodium into the furnace, heat to 650°C for 2 hours, pour the molten slurry into the mold, cool to room temperature, remove the alloy blank, cut and punch it into an electrode shape, put it into 50 kg of absolute ethanol, soak it for 4 hours, take it out of the reaction chamber and dry it to get the porous antimony alloy electrode. Then use sodium-based Prussian blue as the positive electrode material for sodium-ion batteries, and make positive sheets through slurry mixing, coating, rolling, and slitting, and then use porous antimony alloy electrodes as negative electrodes through lamination, welding, packaging, and baking. A batch of 10Ah sodium-ion power batteries were prepared through processes such as liquid injection, formation, and volume separation.
Embodiment 3
[0016] Fill the reaction chamber with argon, add 6 kg of antimony and 4 kg of sodium into the furnace, heat to 650 ° C for 2 hours, pour the molten slurry into the mold, cool to room temperature, remove the alloy blank, cut and punch it into an electrode shape, put it into 50 kg of absolute ethanol, soak it for 4 hours, take it out of the reaction chamber and dry it to get the porous antimony alloy electrode. Then use sodium-based Prussian blue as the positive electrode material for sodium-ion batteries, and make positive sheets through slurry mixing, coating, rolling, and slitting, and then use porous antimony alloy electrodes as negative electrodes through lamination, welding, packaging, and baking. A batch of 10Ah sodium-ion power batteries were prepared through processes such as liquid injection, formation, and volume separation.
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