A retractable roof apparatus for an autonomous hardtop vehicle is described. The apparatus includes a vehicle roof having an opening to a compartment that extends below the surface of the vehicle roof and a retractable cover assembly that encloses sensor devices. The retractable cover assembly includes a top panel having a peripheral size and shape that matches the roof opening to the compartment. The sensors include an array of cameras having a field of view of the full width of the vehicle in at least the front of the vehicle when the retractable roof cover is in the raised position. The height of the top panel in the raised position above the vehicle roof is a minimal height to accommodate the height of the cameras. When the retractable cover assembly is retracted into the compartment, the top panel is flush with the surrounding roof panel of the vehicle.

Methods of transporting a plurality of freight containers are disclosed, including stacking one or more containers on a transportation vehicle, where one or more of the stacked containers is a vertically collapsible container in a collapsed position, where at least one of the vertically collapsible containers includes: a frame assembly including: a plurality of rectangular frame members; a plurality of articulated vertical frame members disposed between the rectangular frame members; and where the articulated vertical frame members are positioned and arranged to retract to within the frame assembly; a lifting mechanism positioned and arranged to elevate the rectangular frame members from each other; and where the lifting mechanism is disposed between the uppermost rectangular frame member of the frame assembly and the lowermost rectangular frame member of the frame assembly.

A vehicle body frame includes a lower frame fixed to a floor of a vehicle to define a lower region of an internal space in the vehicle, a roof frame connected to an upper portion of the lower frame to define an upper region of the internal space, configured to slid in a vertical direction of the vehicle with respect to the lower frame, to expand the internal space upwards when the roof frame slides upwards, a lower door frame forming a lower portion of a vehicle door, and an upper door frame connected to the lower door frame to form an upper portion of the vehicle door, and configured to slid together with the roof frame to expand the vehicle door upwards when the roof frame slides upwards.

A motor vehicle having a vehicle roof having a roof opening with fixed roof portions relative to the vehicle and a covering unit having at least one rigid roof element and that can be displaced between a lifted operating position compared to the roof portions fixed relative to the vehicle, and a lowered closed position, in which the at least one rigid roof element closes the roof opening. Stud elements supporting the covering unit in the operating position, are articulated to the covering unit to be pivotable. Each of the stud elements, in the operating position, spans a right angle together with a plane that is defined by the at least one rigid roof element so that the covering unit can be set down, on bases fixed relative to the vehicle. Additionally, the covering unit may have at least one securing element lock the stud elements in the operating position.

A construction machine is provided that has an operating platform, an access for entering the operating platform, a roof and an access control. The roof is disposed on a height-adjustable rack structure that can be actuated manually or by means of a drive in order to set the roof from an upper operating position to a lower transport position and vice versa. In this process, the access protection is moved from a storage position to a functional position in which the access to the operating platform is blocked by the access control.

A utility vehicle including a cab assembly, a roof assembly, a windshield assembly, a rear window assembly, and two or more couplers attached to one or more ROPS members. The couplers are each aligned with and are releasably connected with a buckle insert attached to one or more of the roof assembly, windshield assembly, rear window assembly and doors of the cab assembly.

A canopy system for a work machine includes a canopy assembly movable between a lowered position and a raised position. The canopy assembly includes a main canopy panel and a canopy wing, such that the canopy wing is movable relative to the main canopy panel between an extended position and a retracted position. The canopy system also includes a sensor system that generates a detection signal indicative of a presence of an object proximate to the work machine, and a controller communicably. The controller includes a memory and a processor. The processor receives the detection signal from the sensor system, determines a location of the object based on the detection signal, and generates a first control signal to partially move the canopy assembly towards the lowered position and away from the operator station or partially move the canopy wing towards the retracted position.

Methods of transporting a plurality of freight containers are disclosed, including stacking one or more containers on a transportation vehicle, where one or more of the stacked containers is a vertically collapsible container in a collapsed position, where at least one of the vertically collapsible containers includes: a frame assembly including: a plurality of rectangular frame members; a plurality of articulated vertical frame members disposed between the rectangular frame members; and where the articulated vertical frame members are positioned and arranged to retract to within the frame assembly; a lifting mechanism positioned and arranged to elevate the rectangular frame members from each other; and where the lifting mechanism is disposed between the uppermost rectangular frame member of the frame assembly and the lowermost rectangular frame member of the frame assembly.

A collapsible container including frame assembly, a lifting mechanism, a retractable side wall, a retractable end wall, a top member, and a bottom member is disclosed. The frame assembly includes rectangular frame members and articulated vertical frame members disposed between the rectangular frame members. At least one rectangular frame member includes a receptacle member. The articulated vertical frame members are positioned and arranged to retract within the frame assembly. The lifting mechanism is positioned and arranged to elevate the rectangular frame members from each other. The retractable side wall is positioned and arranged to retract into a receptacle member. The retractable end wall is positioned and arranged to retract into a receptacle member. The top member is disposed on an uppermost rectangular frame member. The bottom member is disposed on a lowermost rectangular frame member. A method of transporting a plurality of containers is disclosed.

A surveillance module may be deployed from a vehicle. The vehicle to deploy the surveillance module includes a first portion configured to accommodate a user to operate the vehicle. A second portion includes a module configured to accommodate the user and comprising a roof and an entrance accessible through an interior of the vehicle from the first portion. The second portion also includes a lifting mechanism coupled to the module and operable to move the module vertically from a retracted position to an extended position. A third portion defines an opening to accommodate the module, wherein the roof of the module couples to a periphery of the opening in the retracted position.