Provided is an off-road robot, including a front side portion, a rear side portion and a middle portion. The front side portion includes a front vehicle frame, a front wheel and a first driving system; the front wheels and the first driving system are disposed at the front vehicle frame; and the first driving system drives the front wheels. The rear side portion includes a rear vehicle frame, a rear wheel and a second driving system; the rear wheel and the second driving system are disposed at the rear vehicle frame; and the second driving system drives the rear wheels. The middle portion includes a first frame and a second frame; the first frame and the second frame are detachably connected; the front vehicle frame is connected with the first frame; and the rear vehicle frame is connected with the second frame.

A mobility vehicle hub configured to function as a terminal for an air mobility vehicle, a ground mobility vehicle, or a water mobility vehicle, includes a plurality of layers through a combination of: a water layer connected to the surface of water and having an entrance for a water mobility vehicle; a port layer having a take-off and landing pad for an air mobility vehicle; or a ground layer configured to be connected to a ground and having an entrance for a ground mobility vehicle, wherein an elevation passage is provided between the layers, the elevation passage has an internal space extending in an up-down direction of the mobility vehicle hub, the internal space is connected to each of the water, port and ground layers, and the air mobility vehicle, the ground mobility vehicle, or the water mobility vehicle is lifted or lowered through the internal space.

An assembled body of a vehicle may include a plurality of body parts, each of which forms a portion of the vehicle body, and forming the vehicle by being assembled during combination thereof; a magnetic module provided in each of the body portions and combining the plurality of body portions with each other by use of magnetic flow of the magnetic module; and a controller engaged to the magnetic module and configured for controlling a closed circulating magnetic path produced in the magnetic module such that the plurality of body portions is combined with each other to form the assembled body or to be separated from each other according to a control signal of the controller.

A modular robot with a drive platform including: a first lateral drive module having at least two wheels and at least one motor for driving at least one of the wheels, a second lateral drive module having at least one wheel and at least one motor for driving the at least one wheel, a front crossmember module connecting first ends of the first and the second lateral drive module, and a rear crossmember module connecting first ends of the first and the second lateral drive module. One of the two lateral drive modules has a control unit for controlling the motors of the two lateral drive modules. The two drive modules have first connecting devices at their respective ends and the two crossmember modules have second connecting devices in the region of their respective ends. The first and the second connecting devices have mechanical connections. At least one of the two drive modules has at least one docking device for docking an application unit on the drive platform and the at least one docking device has mechanical and/or electrical connections.

An automatic guided vehicles (AGV) can include: motors, wheels, motor controllers, and batteries coupled to an elongated frame. The two wheels can be mounted on opposite sides of the elongated frame. The wheels can be coupled to motors which can be controlled by motor controllers. The motors and motor controllers can be attached to the frame and a connector flange can be mounted on a center portion of the AGV frame. Linkages are used to couple a plurality of AGVs together. In a two AGV embodiment, the AGVs can be mounted to a front portion and a rear portion on a centerline of a platform. In a four AGV embodiment, front width, rear width, left length, and right length linkages can form a parallelogram with AGVs couple to each of the four corners of the parallelogram.

A personal modular trunk and a modular trunk system employing the personal modular trunk for reducing privacy issues and inconveniences that may arise when a vehicle is shared. The personal modular trunk includes: a trunk body; a first communication unit installed in the trunk body and configured to communicate with a vehicle; a first driving unit installed in the trunk body and configured to transport the trunk body; a first engagement unit installed in the trunk body and configured to engage or disengage with a loading space of the vehicle; and a first control unit configured to control the first communication unit to communicate with the vehicle, control the first driving unit to transport the trunk body toward the vehicle, and control the first engagement unit to engage or disengage with the loading space of the vehicle so that the trunk body is coupled to or separated from the vehicle.

A vehicle assembly method includes assembling a chassis platform, mounting a floor pan to the platform, mounting a modular interior to the floor pan, assembling a body top-hat separate from the platform and the floor pan, and mounting the body top-hat to the platform and the floor pan after mounting the modular interior to the floor pan.

An apparatus and methods are provided for a front structural bulkhead for improving the strength of an off-road vehicle chassis. The chassis is a welded-tube variety of chassis that includes a front portion and a rear portion that are joined to an intervening passenger cabin portion. Frontward stays and a bulkhead mount couple the front structural bulkhead to the front portion. Bulkhead mount pillars and a bulkhead mount crossmember couple the front structural bulkhead to the passenger cabin portion. The front structural bulkhead includes a modular chassis for supporting drivetrain components that are operably coupled with front wheels of the vehicle. The front structural bulkhead includes upper and lower mounting points configured to receive front suspension controls arms. The upper and lower mounting points are configured to allow the front wheels to move vertically due to the vehicle traveling over terrain.

At least one machine configuration system provides formation of machines/tools in order to realize different works by means of various components and equipment which can be essentially fixed onto and removed from at least one body having at least one drive element, at least one wheel which is moved by said drive element, and at least one chassis whereon said wheel and the drive element are positioned. The novel side of the machine configuration is that in order to transfer any item from one location to another location, there is essentially at least one platform which is positioned at the upper vicinity of said body.

A guiding vehicle (100) for an intralogistics system, wherein the guiding vehicle (100) is remote controlled or autonomous and configured to be connected to a self-propelled load bearing cart (200), and guide and control the propulsion of the self-propelled load bearing cart (200) such that the load bearing cart (200) can transport a load in the intralogistics system. The guiding vehicle (100) comprising a mechanical connector (170) for mechanically connecting the guiding vehicle (100) to the load bearing cart (200) and a connector for transferring data. The guiding vehicle (100) is configured to receive navigation data from the self-propelled load bearing cart (200), using the connector for transferring data, in the form of information concerning the movement of a drive wheel of the load bearing cart (200) obtained from at least one motor of the load bearing cart (200) or from at least one encoder connected to the drive wheel.