Overcharge protection assembly for a battery module

The invention claimed is: 1. A lithium-ion battery module, comprising: a housing; a plurality of prismatic lithium-ion battery cells disposed in the housing, wherein each of the plurality of prismatic lithium-ion battery cells comprises a first terminal with a first polarity, a second terminal with a second polarity opposite to the first polarity, an overcharge protection assembly, and a casing electrically coupled to the first terminal such that the casing has the first polarity, wherein the casing comprises an electrically conductive material; a vent of the overcharge protection assembly, wherein the vent is electrically coupled to the casing, wherein the vent comprises an outer ring, a recessed surface coupled to the outer ring, and a convex portion coupled to the recessed surface via an inner ring; and a conductive component of the overcharge protection assembly, wherein the conductive component is electrically coupled to the second terminal and the vent is configured to contact the conductive component to cause a short circuit and to vent a gas from the casing into the housing when a pressure in the casing reaches a threshold value, wherein the vent is configured to tear along at least a portion of a circumference of the inner ring to form an aperture when the pressure in the casing reaches the threshold value, wherein the conductive component comprises a plurality of openings configured to enable the gas to pass through the conductive component from the aperture, wherein the vent is configured to move from a first position to a second position to contact the conductive component when the vent tears along at least the portion of the circumference of the inner ring, and wherein a solid portion of the conductive component overlaps with the aperture relative to a flow path of the gas, such that the conductive component forms a contact area for the convex portion of the vent disk to contact the conductive component and cause the short circuit. 2. The lithium-ion battery module of claim 1 , wherein the recessed surface is configured to move when the vent moves from the first position to the second position. 3. The lithium-ion battery module of claim 1 , wherein the recessed surface is configured to remain substantially stationary when the vent moves from the first position to the second position. 4. The lithium-ion battery module of claim 1 , wherein at least the portion of the circumference of the inner ring is coined, and wherein an additional portion of the circumference of the inner ring is not coined, such that the additional portion is configured to maintain contact between the vent and the casing when the vent is in the second position. 5. The lithium-ion battery module of claim 4 , wherein at least the portion of the circumference of the inner ring is configured to tear when the pressure in the casing reaches the threshold value such that the convex portion at least partially contacts the conductive component. 6. The lithium-ion battery module of claim 1 , wherein the aperture is formed between the recessed surface and the convex portion when the vent moves from the first position to the second position. 7. The lithium-ion battery module of claim 1 , wherein the outer ring is laser welded to the casing. 8. The lithium-ion battery module of claim 1 , comprising an insulative component disposed between the conductive component and the casing. 9. The lithium-ion battery module of claim 8 , comprising an opening extending through the casing, the insulative component, and the conductive component, and wherein the vent is disposed within the opening. 10. The lithium-ion battery module of claim 1 , wherein the conductive component comprises a recess configured to position the conductive component proximate to the casing. 11. The lithium-ion battery module of claim 1 , wherein the vent comprises aluminum. 12. A lithium ion battery cell, comprising: a first terminal with a first polarity; a second terminal with a second polarity opposite to the first polarity; a casing coupled to the first terminal and having an electrically conductive material, wherein the casing has the first polarity; and an overcharge protection assembly comprising a vent, a first conductive component, an intermediate conductive component, and an insulating component, wherein the vent comprises an outer ring, a recessed surface coupled to the outer ring, and a convex portion coupled to the recessed surface via an inner ring; wherein the first conductive component is electrically coupled to the second terminal, the intermediate conductive component is electrically coupled to the casing, the insulating component is positioned between the first conductive component and the casing such that a gap is formed between the first conductive component and the casing, the intermediate conductive component is disposed in a groove of the insulating component when the intermediate conductive component is in a first position, the vent is configured to vent a gas from the casing and to urge the intermediate conductive component from the first position to a second position when a pressure in the casing reaches a threshold value; wherein the intermediate conductive component is out of the groove, extends across the gap, and contacts the first conductive component such that a short circuit occurs when the intermediate conductive component is in the second position. 13. The lithium ion battery cell of claim 12 , wherein the intermediate conductive component comprises aluminum. 14. The lithium ion battery cell of claim 12 , wherein the first conductive component comprises copper. 15. The lithium ion battery cell of claim 12 , wherein the convex portion of the vent urges the intermediate conductive component to contact the first conductive component when the vent moves from the first position to the second position. 16. The lithium ion battery cell of claim 12 , wherein the groove of the insulating component is configured to block the intermediate conductive component from moving toward the first position when the intermediate conductive component is in the second position.