In a floating unit, a floating mechanism is provided with: a rolling portion that includes a holding portion fixed to one of a first member and a second member, a sphere held by the holding portion so as to be rotatable in all directions; and an opposing portion that is fixed to the other one of the first member and the second member, and has an abutment surface that abuts against the sphere. The abutment surface includes an inclined surface that is formed, over the entire region of the abutment surface in a circumferential direction around a reference position, so as to come close to a side, in the vertical direction, on which the sphere is arranged, while extending outward in the horizontal direction from the reference position.

A lift vehicle comprises a base having a plurality of wheels, a battery arranged within the base, a drive motor powered by the battery and configured to drive at least one of the plurality of wheels and propel the base, a retractable lift including a first end coupled to the base and being movable between an extended position and a retracted position, a work platform supported by a second end of the retractable lift, and a linear actuator having a lift motor with a rotor. The lift motor is powered by the battery, and the linear actuator is coupled to the retractable lift so that rotation of the rotor moves the retractable lift between the extended position and the retracted position. The lift vehicle further includes an electromagnetic brake coupled to a first side of the lift motor.

A scissor arm for an articulating support is configured to rotate about an axis of rotation. The scissor arm includes a central support structure at least a portion of which extends in a plane that is perpendicular to the axis of rotation. The scissor arm also includes a tubular body including first and second members that form opposing sides of the scissor arm and are attached to the central support structure. Each of the first and second members of the tubular body includes an outer wall spaced from the plane, an upper flange extending from the outer wall toward the plane, and a lower flange extending from the outer wall toward the plane.

A mobile lifting apparatus has a platform coupled to elongated lifting arms arranged in a crossed configuration with a hinge at center portions of the lifting arms which allows the lifting arms to rotate in a crossed scissor manner when the platform is raised or lowered. The lower ends of the lift arms are coupled to automatic guided vehicles which move towards each other to raise the platform and move away from each other to lower the platform. A locking mechanism coupled to the lifting arms is actuated to prevent movement of the lifting arms to lock the height of the platform.

A roller reversing and jacking device for handling equipment comprises a directional roller set, at least one set of reversing and jacking assemblies and a reversing roller set. The reversing and jacking assemblies comprises: a jacking slider restricted to and disposed on the frame through a slider guide post; a reversing and jacking eccentric shaft correspondingly disposed on the jacking slider, comprising an eccentric shaft segment, an eccentric roller and a transmission shaft segment; and a reversing and jacking drive motor connected to and/or disconnected from one end of the transmission shaft segment, and the reversing and jacking drive motor fixedly mounted on the frame.

The invention relates to a lifting platform, in particular moveable lifting platform, for lifting vehicles with two base assembly halves (14), which are respectively firmly arranged to one another with a middle part (15) via a connecting point (45, 46), wherein the middle part (15), with a connecting section (48), is detachably fastened to a lateral surface (49) of a housing (21) of the base assembly half (14) to form the connecting points (45, 46) with, respectively, a lifting device (24) arranged on the base assembly half (14), which device is transferable from a starting position arranged on the base into a working position (32), and which respectively comprises a carrier (31) on an end region of the lifting device (24), and each carrier (31) receives at least one support arm (34), wherein the middle part (15) is connected with the respective housing (21) of the base assembly half (14) with one another and are aligned with respect to each other through a form-fit plug connection (51).

Systems and methods for moving a vehicle component relative to the vehicle, the system including first and second upwardly-extending supports; a lift frame between the first and second supports including a crossbeam, and a pair of cambered truss assemblies secured to the crossbeam and configured to be attached to the vehicle component; movable first and second crossbeam support assemblies on the first and second supports to support the rotation of the crossbeam; a first lift mechanism configured to move the first crossbeam support assembly along the first support in response to a first control signal; a rotational drive mechanism configured to rotate the crossbeam relative to the first and second crossbeam support assemblies in response to a second control signal; and an electronic controller configured to generate the first and second control signals to change the position of the vehicle component relative to the vehicle.

An extendable vehicle jack includes a horizontal frame having a rear section with a front section extendable therefrom. Within the front section is a lifting mechanism including a plate that engages the lower surface of the vehicle as it is being raised and lowered. The lifting mechanism includes a hydraulic pump and cylinder that expand and contract a scissors jack. The front section is automatically extended from the rear section with either a hydraulic or pneumatic cylinder. Accordingly, a worker can position the lifting mechanism any desired location beneath the vehicle frame.

A lifting machine comprising a base and a carrying platform, wherein a lifting mechanism for lifting the carrying platform and a power mechanism for supplying power to the lifting mechanism are arranged between the carrying platform and the base. The lifting machine of the present disclosure has simple structure, small volume and good portability, which may satisfy various needs of mobile use such as mobile maintenance, on-the-spot service and road rescue.

The invention relates to a lifting platform for lifting vehicles, with two base assembly halves (14) with in each case one lifting device (24) arranged on the base assembly half (14), which includes a load arm (25) and a guiding arm (27), which arms, by means of at least one drive, are pivotably transferable out of a starting position arranged on the floor into an operating position (32), and which comprises a carrier (31) in in each case one end region of the lifting device (24), which carrier is mounted pivotably to the load arm (25) via a pivot bolt (54) and is mounted pivotably to the guiding arm (27) via a bearing bolt (63), and each carrier (31) receives at least one support arm (34) arranged pivotably thereon, so that the support arms (34) opposite one another are pivotable in a working space (50) formed at least between the lifting devices (24), wherein an angle of inclination is adjustable between the at least one support arm (34) and the lifting device (24).