The present disclosure provides a foot support device for a footwell of a vehicle. The present disclosure includes a plurality of support elements arranged one behind the other and rotatably connected to one another. The plurality of support elements can each move from a rest position to an active position upon the detection of a predetermined driving situation. When set in the rest position, the plurality of support elements are each arranged parallel to the floor of the footwell, and when set in the active position, the plurality of support elements are each inclined with respect to the floor of the footwell to support at least one foot of an occupant. The foot support device includes a drive arrangement lifting at least a foremost support element to the active position, which causes movement of a subsequent support element.

An energy absorber for interposition between a cover and a covered object includes a generally planar matrix of cells. Each of the cells includes a plurality of generally elongate micro-elements interconnected to form a cell micro-structure, with each cell having a respective energy absorption capacity such that an energy absorption capacity of the energy absorber varies across at least one direction. The cells are configured such that impulse of an object with the cover with the energy absorber sandwiched between the cover and the covered object causes a deceleration vs. time response in the object, beginning with a generally linear rise in the deceleration to a peak deceleration within 5 ms after the beginning of the impulse event, followed by a generally nonlinear decrease in the deceleration over a period of not greater than 15 ms to a final target deceleration of not greater than 10% of the peak deceleration.

An energy absorber for interposition between a cover and a covered object includes a generally planar matrix of cells. Each of the cells includes a plurality of generally elongate micro-elements interconnected to form a cell micro-structure, with each cell having a respective energy absorption capacity such that an energy absorption capacity of the energy absorber varies across at least one direction. The cells are configured such that impulse of an object with the cover with the energy absorber sandwiched between the cover and the covered object causes a deceleration vs. time response in the object, beginning with a generally linear rise in the deceleration to a peak deceleration within 5 ms after the beginning of the impulse event, followed by a generally nonlinear decrease in the deceleration over a period of not greater than 15 ms to a final target deceleration of not greater than 10% of the peak deceleration.

A forklift includes a cabin and a seat for use by a driver arranged in the cabin. The cabin has a lateral opening to enter and exit the cabin, and the seat is mounted rotatably relative to the cabin. There is a safety bracket for preventing the driver from involuntarily exiting the cabin through the lateral opening, and for providing lateral impact protection. The safety bracket is mechanically connected to the seat to be rotatable together with the seat.

A forklift includes a cabin and a seat for use by a driver arranged in the cabin. The cabin has a lateral opening to enter and exit the cabin, and the seat is mounted rotatably relative to the cabin. There is a safety bracket for preventing the driver from involuntarily exiting the cabin through the lateral opening, and for providing lateral impact protection. The safety bracket is mechanically connected to the seat to be rotatable together with the seat.

A secondary bar securing device (3) of a safety bar (4) of an amusement ride has a primary securing device that keeps the safety bar (4) in an angular position adapted to the anatomy of the passenger during travel of the amusement ride, and first and second blocking elements (21, 22) arranged at a distance (25) to each other. In the event of a malfunction of the primary securing device, the safety bar (4) can be moved in a tolerance opening angle, which correlates to the distance (25) between the blocking elements (21, 22). If the tolerance opening angle is exceeded, one of the blocking elements (21, 22) block the safety bar (4).

A secondary bar securing device (3) of a safety bar (4) of an amusement ride has a primary securing device that keeps the safety bar (4) in an angular position adapted to the anatomy of the passenger during travel of the amusement ride, and first and second blocking elements (21, 22) arranged at a distance (25) to each other. In the event of a malfunction of the primary securing device, the safety bar (4) can be moved in a tolerance opening angle, which correlates to the distance (25) between the blocking elements (21, 22). If the tolerance opening angle is exceeded, one of the blocking elements (21, 22) block the safety bar (4).

Aside door structure for a vehicle includes a door beam that has hollow sections which are open at two ends in a longitudinal direction, and a hinge reinforcement member including a bent plate body in a crank shape that is joined to one of a front end and a rear end of the door beam. The hinge reinforcement member forms the crank shape by integrally forming a middle portion that closes an opening in the one of the front end and the rear end of the door beam and is joined to a stepped vertical wall of an inner panel of a side door, an outer end portion that is joined to a stepped outer side wall of the inner panel and an outer wall of the door beam, and an inner end portion that is joined to an inner wall of the door beam.

Aside door structure for a vehicle includes a door beam that has hollow sections which are open at two ends in a longitudinal direction, and a hinge reinforcement member including a bent plate body in a crank shape that is joined to one of a front end and a rear end of the door beam. The hinge reinforcement member forms the crank shape by integrally forming a middle portion that closes an opening in the one of the front end and the rear end of the door beam and is joined to a stepped vertical wall of an inner panel of a side door, an outer end portion that is joined to a stepped outer side wall of the inner panel and an outer wall of the door beam, and an inner end portion that is joined to an inner wall of the door beam.

A system of divider panels for a vehicle is provided. The system includes a first divider panel that separates a front seating area from a rear seating area of the vehicle. A second divider panel separates the rear seating area from a cargo area of the vehicle. A third divider panel separates the rear seating area into two separate areas. The first, second and third dividers may be removably coupled in the interior cabin of the vehicle by mounting points defined in the roof of the vehicle, the floor of the vehicle, and seating support structure of the vehicle.