The invention relates to a method for initializing a motor vehicle, said motor vehicle comprising an assembly having a rolling chassis and a body provided on the rolling chassis. A check is made as to which components and functions are available in the rolling chassis and which components and functions are available in the body. There is a further determination of which components and functions are available in the combined assembly of rolling chassis and body. Parameters are then assigned to the components and functions in the rolling chassis and the body according to this determination. The invention further relates to a device, a rolling chassis, a body, a motor vehicle, a computer program, and to a machine-readable storage medium.

The invention is directed to a vehicle body platform (1) for an automobile, comprising a passenger body module (100) having a front structural interface (110) and a rear structural interface (120). The vehicle body platform further comprises a front body module (200) having a rear structural interface (220) 210 and a rear body module (300) comprising a front structural interface (310). The rear structural interface (220) of the front body module (200) and the front structural interface (110) of the passenger body module (100) are corresponding structural interfaces configured to mechanically interconnect the passenger body module (100) with the front body module (200) and the front structural interface (310) of the rear body module (300) and the rear structural interface (120) of the passenger body module (100) are corresponding structural interfaces configured to mechanically interconnect the passenger body module (100) with the rear body module (300).

In a group of motor vehicles of one vehicle type, hybrid-drive motor vehicles are derived from the electric-drive motor vehicles. By using the architecture of electric-drive motor vehicles for the hybrid-drive motor vehicles, the architecture has a floor pan subassembly that sits in a higher position in comparison to that in motor vehicles having an internal combustion engine drive. An installation space for housing a battery on the underside of the floor pan subassembly is made available, which, in comparison to the motor vehicle in the prior art, allows significantly larger batteries to be housed.

In order to produce different motor vehicles of a vehicle type, which have the different drive concepts of an internal combustion engine, electric motor or a combination of an electric motor and an internal combustion engine, two different floor pan assemblies and two different luggage compartment floor subassemblies are provided. The two subassemblies are each produced using different deep-drawing dies. A combination of one of the two floor pan subassemblies with one of the two luggage compartment floor subassemblies allows the production of motor vehicles for all three drive concepts. The first of these two floor pan subassemblies, when installed in the vehicle, has a higher position than the second floor pan subassembly. The higher floor pan subassembly is used to produce both the electric-drive motor vehicles and hybrid-drive motor vehicles. A large-area installation space below the floor pan subassembly is also made available for the hybrid-drive motor vehicles for housing at least one pack-type battery.

The invention relates to a method for testing a motor vehicle, said motor vehicle comprising an assembly having a rolling chassis and a body provided on the rolling chassis, the rolling chassis comprising multiple first interfaces and the body comprising multiple second interfaces allocated to the first interfaces, so that each pair of first and second interfaces can form a respective connection between the rolling chassis and the body, when the body is assembled on the rolling chassis. The method comprises, for example, a check as to whether all connections are correctly attached. The method comprises, for example, a check as to whether all components of the motor vehicle are responsive. The method also comprises, for example, a check as to whether the body may be used with the rolling chassis. The invention further relates to a device, a computer program, a machine-readable storage medium, a rolling chassis, a body and a motor vehicle.

Land vehicles, modular systems for forming monocoques of land vehicles, and methods of forming monocoques of land vehicles using modular systems are disclosed herein. In certain embodiments, the land vehicles are provided as delivery vehicles and/or utility vehicles. A land vehicle includes a monocoque supporting a plurality of wheels to permit movement of the vehicle relative to an underlying surface in use of the land vehicle.

An amphibious platform vehicle-vessel to support and to move hydraulically operated and controlled earth-moving and lifting equipment, such as excavators and cranes, on solid ground, semi-solid or marshy ground, shallow water, and deeper water. The modular units can be transported to a worksite on separate trailers and assembled and reconfigured on site. Two compartmented pontoon units are mounted to an adaptive cross member that can accommodate different types of moving-lifting equipment through different mounting flanges, and to auxiliary cross members. Propulsion is provided through amphibious cleats on drive chains in chain tracks driven by dual-motor driving drums and over a tension-adjusting passive chain roller, surrounding a sealed pontoon shell internally reinforced with bulkhead partitions, beam shell-bottom stiffeners, and pressed-angle shell-bottom stiffeners. An extendable auxiliary float can be extended outward from each compartmented pontoon for increased stability in floating operations. Spud units having a chain-drive spud and a spud-driving mount unit with spud-mount wear strips are hydraulically raised and lowered by a spud-driver motor at the command of the equipment operator using a spud-control switch.

A vehicle platform for a vehicle is provided. The platform includes a platform base extending in a longitudinal direction, and a loading system for laterally loading and unloading an upper body structure onto the platform base. The loading system includes first and second fork arms supporting the upper body structure with respect to a vertical direction, and a lifting mechanism coupled to the platform base and the first and second fork arms. The lifting mechanism moves the first and second fork arms relative to the platform base along the vertical direction. The first and second fork arms are spaced apart in the longitudinal direction and each are movable along a lateral direction between a retracted position, in which the fork arms completely overlap with the platform base, and an extended position, in which the fork arms protrude in the lateral direction from a lateral side of the platform base.

A military vehicle includes a passenger capsule, a driver seat, a passenger seat, and a belly deflector. The passenger capsule includes a roof, a floor, and sidewalls that define an interior. The sidewalls include mounting interfaces positioned along bottom edges thereof and extending directly therefrom past the floor. The driver seat and the passenger seat are disposed within the interior of the passenger capsule. The belly deflector is positioned beneath the floor. The belly deflector has lateral ends that are coupled to the mounting interfaces such that the lateral ends of the belly deflector are engaged with the passenger capsule. The belly deflector is spaced from the floor such that the floor is configured as a floating floor. The floor and the belly deflector provide two levels of underbody protection.

A military vehicle includes a passenger capsule having a front end and a rear end, a front module coupled to the front end of the passenger capsule, a rear module coupled to the rear end of the passenger capsule, a generator, and an export power kit. The front module includes a front subframe, a prime mover, a front axle assembly, and a front differential coupled to the front axle assembly. The rear module includes a rear subframe, a rear axle assembly, and a transaxle coupled to the rear axle assembly, the prime mover, and the front differential. The generator is configured to be driven by the prime mover to generate electricity. The export power kit is coupled to the generator and configured to facilitate exporting power off of the military vehicle.