초록 ▼

A lid assembly for use in a battery module includes a lid with apertures extending through the lid in a vertical direction, where each of the apertures is configured to receive a terminal of a battery cell of the battery module. The lid assembly also includes one or more extensions extending away fr

A lid assembly for use in a battery module includes a lid with apertures extending through the lid in a vertical direction, where each of the apertures is configured to receive a terminal of a battery cell of the battery module. The lid assembly also includes one or more extensions extending away from the lid in the vertical direction. Each of the one or more extensions is configured to couple the lid to a printed circuit board assembly of the battery module. The lid assembly also includes walls extending away from the lid in the vertical direction. Each of the walls is configured to extend between a first terminal of a first battery cell and a second terminal of a second battery cell.

대표청구항 ▼

1. A lid assembly of a battery module, comprising: a lid, comprising a plurality of apertures extending through the lid in a vertical direction, wherein the plurality of apertures comprises a first row of apertures extending across the lid in a first direction and a second row of apertures extending

1. A lid assembly of a battery module, comprising: a lid, comprising a plurality of apertures extending through the lid in a vertical direction, wherein the plurality of apertures comprises a first row of apertures extending across the lid in a first direction and a second row of apertures extending across the lid in the first direction, wherein the second row of apertures is spaced from the first row of apertures by a gap defined along a second direction, wherein the second direction is perpendicular to the first direction, and wherein each aperture of the plurality of apertures is configured to receive a terminal of a battery cell of the battery module;one or more snap-in extensions of the lid, wherein each snap-in extension extends away from the lid in the vertical direction, and wherein each snap-in extension is configured to couple the lid to a printed circuit board assembly of the battery module by extending through a corresponding opening of a plurality of openings of the printed circuit board assembly;a vent chamber defined by the lid, wherein the vent chamber is configured to receive gases vented from the battery cells, and wherein the vent chamber extends along an underside of the lid between the first row of apertures and the second row of apertures such that the vent chamber is aligned with the gap;a vent chamber cover disposed on a bottom portion of the lid, wherein the vent chamber cover encloses the vent chamber between the lid and the vent chamber cover; anda vent guide disposed in the vent chamber to reduce an amount of the vented gases that directly contact the vent chamber. 2. The lid assembly of claim 1, comprising a plurality of walls extending away from the lid in the vertical direction, wherein each wall of the plurality of walls is configured to extend between two apertures of the plurality of apertures, such that terminals from two battery cells, when positioned in the two apertures, are on opposite sides of the corresponding wall. 3. The lid assembly of claim 2, wherein the plurality of walls is configured to block electrical shorts between battery cells coupled with the lid via the plurality of apertures, and wherein the one or more snap-in extensions, the plurality of walls, or a combination thereof is integral with the lid. 4. The lid assembly of claim 2, wherein successive walls of the plurality of walls are configured to extend between every other aperture of the plurality of apertures in each of the one or more rows of apertures. 5. The lid assembly of claim 2, comprising a plurality of bus bar cell interconnects, wherein each wall of the plurality of walls is configured to block a short between a corresponding two bus bar cell interconnects of the plurality of bus bar cell interconnects. 6. The lid assembly of claim 5, comprising a plurality of mounting features extending away from the lid in the vertical direction, wherein each mounting feature of the plurality of mounting features couples with a corresponding one of the plurality of bus bar cell interconnects. 7. The lid assembly of claim 6, wherein each mounting feature of the plurality of mounting features is disposed between a corresponding pair of apertures of the plurality of apertures in the lid to position the corresponding bus bar cell interconnect of the plurality of bus bar cell interconnects over the corresponding pair of apertures for contacting terminals received therethrough. 8. The lid assembly of claim 5, wherein each bus bar cell interconnect of the plurality of bus bar cell interconnects is configured to extend between two adjacent apertures of the plurality of apertures. 9. The lid assembly of claim 1, comprising a plurality of indentations, wherein each indentation of the plurality of indentations surrounds a corresponding aperture of the plurality of apertures. 10. The lid assembly of claim 1, wherein the lid is configured to couple to the printed circuit board assembly between the first row and the second row of the one or more rows of apertures across the lid. 11. The lid assembly of claim 1, wherein the vent chamber is tapered between a first end of the vent chamber and a second end of the vent chamber such that the first end of the vent chamber comprises a first width measured along the second direction and such that the second end of the vent chamber comprises a second width measured along the second direction, wherein the first width is larger than the second width. 12. The lid assembly of claim 1, wherein the lid comprises a plurality of flexible fingers integrally formed with the lid along a corresponding plurality of living hinges, wherein each flexible finger of the plurality of flexible fingers is configured to align with a corresponding battery cell of the battery cells when the lid is disposed over the battery cells, wherein each flexible finger of the plurality of flexible fingers is configured to exert a downward force against the corresponding battery cell of the battery cells. 13. A battery module, comprising: a plurality of prismatic battery cells; anda lid assembly disposed over the plurality of prismatic battery cells, comprising: a lid, comprising a non-conductive material, a first row of apertures extending across the lid in a first direction, and a second row of apertures extending across the lid in the first direction, wherein the second row of apertures is spaced from the first row of apertures by a gap defined along a second direction, wherein the second direction is perpendicular to the first direction, and wherein each prismatic battery cell of the plurality of prismatic battery cells comprises a first terminal that extends through a corresponding aperture of the first row of apertures and a second terminal that extends through a corresponding aperture of the second row of apertures;a plurality of first bus bar cell interconnects, wherein each first bus bar cell interconnect of the plurality of first bus bar cell interconnects is configured to extend between two adjacent apertures of the first row of apertures, and wherein each first bus bar cell interconnect of the plurality of first bus bar cell interconnects is configured to couple the first terminal of one of the plurality of prismatic battery cells to the first terminal of a different one of the plurality of prismatic battery cells;one or more snap-in extensions, wherein each snap-in extension of the one or more snap-in extensions is configured to extend through a corresponding opening of a plurality of openings of a printed circuit board assembly to couple the printed circuit board assembly to the lid;a vent chamber defined by a hollow portion of the lid, wherein the vent chamber is configured to receive gases vented from the prismatic battery cells, wherein the vent chamber extends along an underside of the lid between the first row of apertures and the second row of apertures such that the vent chamber is aligned with the gap; and wherein the vent chamber is tapered between a first end of the vent chamber and a second end of the vent chamber such that the first end of the vent chamber comprises a first width measured along the second direction and such that the second end of the vent chamber comprises a second width measured along the second direction, wherein the first width is larger than the second width; anda vent guide disposed in the vent chamber to reduce an amount of the vented gases that directly contact the vent chamber. 14. The battery module of claim 13, wherein the lid assembly comprises: a plurality of second bus bar cell interconnects, wherein each second bus bar cell interconnect of the plurality of second bus bar cell interconnects is configured to extend between two adjacent apertures of the second row of apertures, and wherein each second bus bar cell interconnect of the plurality of second bus bar cell interconnects is configured to couple the second terminal of one prismatic battery cell of the plurality of prismatic battery cells to the second terminal of a different one of the plurality of prismatic battery cells; anda plurality of second walls, wherein each second wall of the plurality of second walls is configured to extend between two second bus bar cell interconnects of the plurality of second bus bar cell interconnects. 15. The battery module of claim 14, wherein the lid is configured to couple to the printed circuit board assembly between the first and second rows of apertures. 16. The battery module of claim 13, wherein the lid comprises a plurality of first walls, wherein each first wall of the plurality of first walls is configured to extend between two first bus bar cell interconnects of the plurality of first bus bar cell interconnects. 17. The battery module of claim 16, wherein the plurality of first walls and each snap-in extension of the plurality of snap-in extensions are integral with the lid. 18. The battery module of claim 13, wherein the plurality of prismatic battery cells comprise terminal posts extending therefrom for coupling with the lid assembly. 19. The battery module of claim 13, wherein the lid comprises a cell cavity configured to receive a contactor of the battery module. 20. A method of manufacturing a battery module, the method comprising: disposing a plurality of bus bar cell interconnects onto a non-conductive lid of the battery module;extending a plurality of non-conductive snap-in extensions of the lid through openings disposed in a region of a printed circuit board (PCB) of the battery module to couple the PCB to the lid, wherein the PCB comprises a measurement device disposed in the region;disposing the lid with the bus bar cell interconnects over a plurality of prismatic battery cells such that pairs of terminal posts from each battery cell of the plurality of battery cells extend through corresponding pairs of apertures of a plurality of apertures arranged in a first row of apertures extending across the lid in a first direction and a second row of apertures extending across the lid in the first direction, wherein the lid comprises a vent chamber defined by the lid, wherein the vent chamber is configured to receive gases vented from the battery cells, and wherein the vent chamber extends along an underside of the lid between the first row of apertures and the second row of apertures such that the vent chamber is aligned with the gap;disposing or overmolding a vent guide inside the vent chamber, wherein the vent guide is configured to prevent gases vented from the plurality of battery cells from directly contacting the vent chamber; anddisposing a vent chamber cover on a bottom portion of the lid to enclose the vent chamber between the lid and the vent chamber cover; andcoupling the plurality of bus bar cell interconnects to the terminal posts extending through the lid. 21. The method of claim 20, comprising a plurality of walls extending from the lid and disposed between adjacent apertures of the first and second rows of apertures. 22. The method of claim 21, comprising disposing the plurality of bus bar cell interconnects onto a lid of the battery module such that each bus bar cell interconnect of the plurality of bus bar cell interconnects extends between two of the plurality of walls. 23. The method of claim 21, comprising: injection molding the lid having the plurality of walls, the plurality of extensions, the plurality of apertures, and the vent chamber. 24. The method of claim 21, wherein each wall of the plurality of walls extends between two sets of two apertures of the first row of apertures or the second row of apertures. 25. The method of claim 20, wherein coupling the plurality of bus bar cell interconnects to the terminal posts extending through the lid comprises welding. 26. The method of claim 20, comprising mounting each bus bar cell interconnect of the plurality of bus bar cell interconnects onto corresponding posts extending from the lid. 27. The method of claim 26, wherein the posts extending from the lid are oriented such that the bus bar cell interconnects mounted on a first side of the lid corresponding to the first row of apertures are oriented in a third direction and the bus bar cell interconnects mounted on a second side of the lid corresponding to the second row of apertures are oriented in a fourth direction different from the third direction.