Abstract: Electric vehicle battery packs with external side enclosures for containing electrical connectors and other components therein. Each enclosure is sized to support various connectors or other components as desired, and may have a number of openings formed to provide interfaces for connecting various electric vehicle systems to the battery pack. The enclosures may be placed at various locations along one or more sides of the battery pack, and connectors may be routed over an upper surface of a battery pack frame or through a gap formed between the pack frame and cover. Enclosures may be made of any material, including plastic for lower weight applications and metal for improved electromagnetic interference shielding.

Abstract: A vehicle includes a body structure having an occupant compartment, and a frame structure having a chassis. The body structure and the frame structure are fastened together using a plurality of fasteners and an adhesive. To illustrate, the plurality of fasteners may include 20, 50, 70, or more fasteners. The adhesive is arranged at one or more positions along the interface between the body structure to the frame structure. The plurality of fasteners extend beyond the wheel wells, and provide hard mounts between the body structure and frame structure. The adhesive helps to prevent stress concentrations by extending the locations of load transfer between the body structure and the frame structure. Body panels are added before or after the body structure is affixed to the frame structure.

Abstract: A battery enclosure is provided having unswitched positive and negative terminals that are physically separated. The unswitched positive and negative terminals may be connected to circuit protection components, such as contactors and fuses. The contactors are set to an opened or closed state via a contactor control module. The battery enclosure includes external terminals that electrically couple the battery and circuit protection devices to external components, such as charging ports and electrical loads.

Abstract: A battery enclosure is provided having unswitched positive and negative terminals that are physically separated. The unswitched positive and negative terminals may be connected to circuit protection components, such as contactors and fuses. The contactors are set to an opened or closed state via a contactor control module. The battery enclosure includes external terminals that electrically couple the battery and circuit protection devices to external components, such as charging ports and electrical loads.

Abstract: Systems and methods are described herein for venting battery cells in a battery cell pack assembly. An assembly includes a matrix configured to hold battery cells and channel assemblies that each include a venting channel for venting materials (e.g., flammable gas and conductive particulates) from the interior of the matrix to an outlet. Battery cells, particularly lithium ion battery cells, have a chance of entering a thermal runaway condition that causes the production of flammable gas. The assembly is configured such that battery cells are allowed to vent such flammable gas out of the assembly. A ventilation opening and channel in the assembly cause venting materials to be routed through and out of the assembly.

Abstract: Electric vehicle battery pack frames constructed with extruded aluminum side and cross members. Such frames are significantly stronger than conventional cast aluminum frames, while also being much lighter than steel frames. Cross members may be affixed to side members with extruded aluminum brackets. Side members of differing lengths may be employed, to make battery pack frames of differing sizes in modular manner. Battery pack lids and bottom panels may be removably affixed to the frame such as with bolts, for improved serviceability.

Abstract: An electric vehicle battery pack cover with a fiber reinforced multiple-ply composite body whose bottom surface is coated with a high-hardness, high-melting point, and fire- and abrasion-resistant coating. The coating can be any one or more materials that provide sufficient fire and abrasion resistance to allow the battery pack to contain a battery fire. As examples, the coating can be a nickel layer, a steel layer, a high temperature mineral layer such as a mica layer, or any combination of these materials. The composite body can be any composite body that is both compatible with the fire- and abrasion-resistant coating and provides sufficient strength to act as a battery cover. As examples, the composite body can be made of one or more glass fiber plies, carbon fiber plies, aramid fiber plies, or any combination of any number of these plies, with a crosslinked polymer or other matrix.

Abstract: A drain system is described for allowing fluid to drain from a battery pack while maintaining structural integrity of the battery pack. A frame of the battery pack is comprised of several retaining members in which valves are disposed to allow fluid to exit the battery pack. The valves are positioned such that forces normally experienced while driving a vehicle, such as acceleration, deceleration, and turning forces, cause the fluid to flow toward and through the valves.

Abstract: An electric vehicle battery pack with a strike shield affixed to its bottom. The strike shield provides structural support to withstand ground strikes without damaging the batteries within the battery pack. The strike shield is a mixed material sandwich bottom plate structure having a composite top layer, a middle core with one or more hollow members adhesively connected or welded together, or a single integrated structure with elongated stiffeners and/or a base member with elongated channels for stiffness, and a composite bottom layer.

Abstract: Electric vehicle battery packs with external side enclosures for containing electrical connectors and other components therein. Each enclosure is sized to support various connectors or other components as desired, and may have a number of openings formed to provide interfaces for connecting various electric vehicle systems to the battery pack. The enclosures may be placed at various locations along one or more sides of the battery pack, and connectors may be routed over an upper surface of a battery pack frame or through a gap formed between the pack frame and cover. Enclosures may be made of any material, including plastic for lower weight applications and metal for improved electromagnetic interference shielding.