A three-level vehicle lift. The lift includes a four-post configuration in which each post includes a pair of vertically extending, side-by-side channels. Two platforms are provided. Each includes a carriage configured to engage a respective one of the channels in each post and a hydraulic actuator and lifting cable system disposed within the platform for lifting the platform. An actuation system having a single hydraulic pump is provided with a valve for selectively supplying hydraulic power to either an upper- or a lower-platform hydraulic circuit. The simplified lift and actuation system configuration reduces manufacturing, shipping, installation, and materials costs and complexities.

There is provided a conveying device that can support a car weight with a mechanism lighter in weight. A driving device (6) of a conveying device that lifts and lowers a loading-weight support along a rail (3) includes a wheel unit (13) and a link (14). The wheel unit (13) drives to rotate a driving wheel (15) in contact with a guide surface (11) to lift and lower the loading-weight support. The link (14) includes a first joint (17) connected to the wheel unit (13) and a second joint (18) rotatably supported by the loading-weight support. The second joint (18) is arranged in a position further apart from the guide surface (11) than the first joint (17), and above the first joint (17). The link (14) is arranged such that a straight line connecting the first joint (17) and the second joint (18) is tilted smaller than 45 degrees.

A cord protector comprising at least one elongated body and at least one coupler. The elongated body has a base and a lid, and has a cavity in each of the first end and second end of the elongated body. The base has a channel extending between the first end and the second end in which a cord may rest. The channel may have one or more ridges. The lid is configured to insert into and cover the channel, and may have one or more grooves sized and shaped to receive a ridge. The coupler has a leading end and a trailing end. The leading end is sized and shaped to mate with the cavity of the first end and the trailing end is sized and shaped to mate with the cavity of the second end. Multiple elongated bodies can be coupled together through the use of the couplers.

Lift and slide parking systems employ a plurality of novel trolley apparatus. Each trolley includes a rectangular frame from which a platform may be raised and lowered via cables coupled to lifting bars positioned at each of four corners of the platform. On one side of the frame a slide rail and trolley sliding assembly includes hydraulic cylinders coupled with cables routed through sheaves arranged to enable movement of the trolley horizontally a necessary distance. The slide rail may include grooves in which a sliding block may be slidably retained. On the side opposite the slide rail is a lift rail and platform lift assembly which includes a hydraulic cylinder coupled with one or more belts routed through rollers to a lifting block coupled with cables routed through sheaves and coupled to lifting bars arranged to enable vertical movement of the platform. The lift rail may include grooves in which a cylinder block and lift block are slidably retained. A sliding roller at each corner of the frame is positioned to engage in tracks attached to the superstructure which run the width of the parking system.

A safety barrier assembly is provided for a parking garage is positioned in proximity to an opening for a VRC and includes a horizontal AGV safety beam and upper and lower pedestrian barriers having horizontal railings and vertical legs. The vertical legs are telescoped into openings at opposite ends of the AGV safety beam. The vertical legs of the upper pedestrian barrier are longer than those of the lower pedestrian barrier. The AGV safety beam can be moved vertically between a lower position where the AGV safety beam is substantially adjacent a floor of the parking garage and an upper position where the AGV safety beam is elevated from the floor. The horizontal railings of the pedestrian barriers are parallel to and spaced above the AGV safety beam in the lower position. However, the horizontal railings abut the AGV safety beam in the upper position.

A safety barrier assembly is provided for a parking garage is positioned in proximity to an opening for a VRC and includes a horizontal AGV safety beam and upper and lower pedestrian barriers having horizontal railings and vertical legs. The vertical legs are telescoped into openings at opposite ends of the AGV safety beam. The vertical legs of the upper pedestrian barrier are longer than those of the lower pedestrian barrier. The AGV safety beam can be moved vertically between a lower position where the AGV safety beam is substantially adjacent a floor of the parking garage and an upper position where the AGV safety beam is elevated from the floor. The horizontal railings of the pedestrian barriers are parallel to and spaced above the AGV safety beam in the lower position. However, the horizontal railings abut the AGV safety beam in the upper position.

An object of the instant application is to provide a vehicle that can minimize parking space and a parking facility that can efficiently park a large number of vehicles in a predetermined parking space. The vehicle 1 includes a bottom flap 7 arranged on a bottom surface of a vehicle body and vertically rotatable around a lower rear end of the vehicle body, a rear flap 8, and geared motors 9, 11 for respectively rotating the bottom flap 7 and the rear flap 8. The parking facility 20 for a vehicle 1′ is configured to include an erecting mechanism (a rotating member 22, an electric motor 23, and a link mechanism 24) for erecting the vehicle 1′ upright with a rear surface facing down, and a transfer mechanism (belt conveyor) 25 for transferring the vehicle 1′ erected by the erecting mechanism to a predetermined position.

A parking robot system for a transportation vehicle having wheels and a method for operating a parking robot system. The parking robot system includes a main robot and secondary robots and a method for operating a parking robot system. The secondary robots each have a pair of wheel support arms and each move up autonomously, with the wheel support arms folded in, from outside next to one of the wheels of the transportation vehicle. The secondary robots each lift up the respective wheel by folding out the respective pair of wheel support arms. The main robot accompanies the secondary robot with the lifted up transportation vehicle during travel to a prescribed target position.

The invention relates to a parking platform for a motor vehicle, in particular for a motorized parking apparatus for a motor vehicle. Profile parts are provided which are arranged next to each other along a longitudinal direction and preferably are connected to each other and form a parking space for the motor vehicle. The profile parts each comprise a base region and a projecting region projecting therefrom. In order to provide a generic parking platform with high stability and increased user friendliness for a vehicle operator, the profile parts each comprise a profile section which has at least one base region and at least one projecting region, as well as a covering section which is arranged next to the profile section and is connected thereto. The covering section of a profile part covers at least one projecting region of an adjacent profile part.

According to an embodiment, a management system includes a vehicle management device configured to manage parking of a vehicle in a parking space and delivery of the vehicle from the parking space, and a vehicle conveying device configured to be able to convey the vehicle in forward-backward and widthwise directions of the vehicle. The vehicle management device includes a controller configured to control the vehicle conveying device so that the vehicle is conveyed to the parking space when a request for parking the vehicle located within a section where parking in the parking space is able to be requested has been received.