He kuleana koʻikoʻi ka alumini alumini i ke kūkulu ʻana i nā pā lithium-ion. Nui nā hiʻohiʻona i ka 1000-8000 nā huila moʻo i hiki ke hoʻohana ʻia i ka hana pākaukau.
ʻO ka pahu alumini maʻemaʻe: ʻO ka pahu alumini maʻemaʻe i hoʻohana mau ʻia i loko o nā pā lithium e loaʻa nā ʻano like ʻole e like me 1060, 1050, 1145, a 1235. Loaʻa kēia mau pahu i nā mokuʻāina like ʻole e like me O, H14, H18, H24, H22.
ʻOi aku ka alloy 1145. The alloy is known for its high electrical conductivity, low impurity content and good formability, making it suitable for use as a current collector in batteries.
Other aluminum alloys that can be used in battery applications include the 3xxx series of alloys, e like me 3003 a 3104, which offer a balance of strength and formability. Eia hou, some battery manufacturers may use 8xxx series alloys to meet specific performance requirements.
Aluminum-silicon alloy foil: Aluminum foil containing silicon alloy is a promising anode material for next-generation lithium-ion batteries. They offer a balance between low cost, environmental friendliness and high performance.
Researchers found that aluminum foil anodes exhibit higher performance and stability in solid-state batteries compared to traditional lithium-ion batteries. Overall, the selection of aluminum alloys for battery applications depends on factors such as conductivity, formability, strength and cost considerations.
