A military vehicle includes a passenger capsule, a front module coupled to a front end of the passenger capsule, and a rear module coupled to a rear end of the passenger capsule. The passenger capsule has a frame rail-less monocoque hull structure. The front module includes a first longitudinal frame member coupled to the front end of the passenger capsule proximate a first side thereof, a second longitudinal frame member coupled to the front end of the passenger capsule proximate an opposing second side thereof, and an underbody support structure coupled to the front end of the passenger capsule, the first longitudinal frame member, and the second longitudinal frame member. The underbody support structure is positioned beneath the first longitudinal frame member and the second longitudinal frame member.

Embodiments of the present invention provide a structural frame for a body of a motor vehicle, the structural frame defining, at least in part, an occupant compartment of the vehicle, the structural frame comprising a pair of spaced pillars joined together at an upper region of each pillar to a roof crossmember and further joined together at respective points below the roof crossmember to a structural cross-brace, the structural cross-brace is further arranged to support a pair of spaced apart vehicle suspension connectors and, wherein the structural cross-brace projects from the pillars beyond the suspension connectors so that the space in the occupant compartment between the pillars is substantially unobstructed by the structural cross-brace and, at least a portion of the structural cross-brace is accommodated within the occupant compartment.

Embodiments of the present invention provide a structural frame for a body of a motor vehicle, the structural frame defining, at least in part, an occupant compartment of the vehicle, the structural frame comprising a pair of spaced pillars joined together at an upper region of each pillar to a roof crossmember and further joined together at respective points below the roof crossmember to a structural cross-brace, the structural cross-brace is further arranged to support a pair of spaced apart vehicle suspension connectors and, wherein the structural cross-brace projects from the pillars beyond the suspension connectors so that the space in the occupant compartment between the pillars is substantially unobstructed by the structural cross-brace and, at least a portion of the structural cross-brace is accommodated within the occupant compartment.

Vehicle platforms, and systems, subsystems, and components thereof are described. A self-contained vehicle platform or chassis incorporating substantially all of the functional systems, subsystems and components (e.g., mechanical, electrical, structural, etc.) necessary for an operative vehicle. Functional components may include at least energy storage/conversion, propulsion, suspension and wheels, steering, crash protection, and braking systems. Functional components are standardized such that vehicle platforms may be interconnected with a variety of vehicle body designs (also referred to in the art as “top hats”) with minimal or no modification to the functional linkages (e.g., mechanical, structural, electrical, etc.) therebetween. Configurations of functional components are incorporated within the vehicle platform such that there is minimal or no physical overlap between the functional components and the area defined by the vehicle body. Specific functional components of such vehicle platforms, and the relative placement of the various functional components, to allow for implementation of a self-contained vehicle platform are also provided.

Vehicle platforms, and systems, subsystems, and components thereof are described. A self-contained vehicle platform or chassis incorporating substantially all of the functional systems, subsystems and components (e.g., mechanical, electrical, structural, etc.) necessary for an operative vehicle. Functional components may include at least energy storage/conversion, propulsion, suspension and wheels, steering, crash protection, and braking systems. Functional components are standardized such that vehicle platforms may be interconnected with a variety of vehicle body designs (also referred to in the art as “top hats”) with minimal or no modification to the functional linkages (e.g., mechanical, structural, electrical, etc.) therebetween. Configurations of functional components are incorporated within the vehicle platform such that there is minimal or no physical overlap between the functional components and the area defined by the vehicle body. Specific functional components of such vehicle platforms, and the relative placement of the various functional components, to allow for implementation of a self-contained vehicle platform are also provided.

The present invention relates to a modular vehicle system and assembly thereof comprising a preassembled Body (Cabin Module) and a preassembled Chassis (Drive Module). More particularly, the present invention relates to the modular vehicle system allowing for the docking of a Cabin Module onto a Drive Module, and wherein Drive Modules can be seamlessly interchanged during the lifespan of the Cabin Module.

A moving body is configured to perform autonomous operation. The moving body includes: a first body including at least one wheel and configured to travel by the at least one wheel; a second body attachable to and detachable from the first body; and a display circuit arranged to face an outer side of the first body. The display circuit is configured to display at least a first schematic pattern of a first eye and a second schematic pattern of a second eye.

A moving body is configured to perform autonomous operation. The moving body includes: a first body including at least one wheel and configured to travel by the at least one wheel; a second body attachable to and detachable from the first body; and a display circuit arranged to face an outer side of the first body. The display circuit is configured to display at least a first schematic pattern of a first eye and a second schematic pattern of a second eye.

A vehicle includes a user compartment and a driving platform, wherein the driving platform is arranged to be in contact with a road/ground, wherein the user compartment is movably connected to the driving platform in a way that it may pivot around a vertical axis of the vehicle. The vehicle may be used in a method of simulating a drifting/skidding movement of the vehicle.

A vehicle includes a user compartment and a driving platform, wherein the driving platform is arranged to be in contact with a road/ground, wherein the user compartment is movably connected to the driving platform in a way that it may pivot around a vertical axis of the vehicle. The vehicle may be used in a method of simulating a drifting/skidding movement of the vehicle.