The hoisting arrangement of a hoist of a of a crane, includes a trolley arranged to move along a main support structure of the crane, whereby the trolley includes a support frame structure; bearing wheels which are fastened to the support frame structure and by means of which the trolley is arranged to move along said main support structure; a hoisting mechanism that has a rope drum for a hoisting rope, a rope pulley arrangement which has upper sheave arrangements and lower rope pulley arrangements and through which the hoisting rope may be guided from the rope drum to an attachment point, and a hoisting member in cooperation with the hoisting rope for hoisting a load; whereby the rope drum is supported to the support frame structure of the trolley so that the axle of the rope drum is parallel to the main support structure. In the hoisting arrangement, the disengagement point of the hoisting rope from the rope drum, the attachment point of the sheave, and the attachment point of the first end of hoisting rope are arranged on the same vertical plane of the hoisting arrangement. The rope drum has a first end towards which the hoisting rope is wound in the hoisting member's upper position, and a second end towards which the hoisting rope is unwound in the hoisting member's lower position. The first rope pulley of the rope pulley arrangement is so placed that the release point of the hoisting rope from the first rope pulley to the first sheave is, in the axle direction of the rope drum, further from the second end than the first end of the rope drum.

A walking device with a self-adaptive track gauge and wheel pressure for preventing rail gnawing comprises a first rail, a second rail parallel to the first rail, a driving trolley disposed on the first rail, a driven trolley disposed on the second rail, two beams connected between the driving trolley and the driven trolley and each of which having a sliding groove, and an electric hoist disposed on the two beams. The driving trolley is hung on the first rail through a first bearing wheel, and the driven trolley is hung on the second rail through a second bearing wheel. The driving trolley is connected with a driving motor, and the driving trolley is configured to drive the driven trolley to synchronously move along length directions of the first rail and the second rail through the two beams, so that the electric hoist is driven to synchronously move.

A walking device with a self-adaptive track gauge and wheel pressure for preventing rail gnawing comprises a first rail, a second rail parallel to the first rail, a driving trolley disposed on the first rail, a driven trolley disposed on the second rail, two beams connected between the driving trolley and the driven trolley and each of which having a sliding groove, and an electric hoist disposed on the two beams. The driving trolley is hung on the first rail through a first bearing wheel, and the driven trolley is hung on the second rail through a second bearing wheel. The driving trolley is connected with a driving motor, and the driving trolley is configured to drive the driven trolley to synchronously move along length directions of the first rail and the second rail through the two beams, so that the electric hoist is driven to synchronously move.

A transfer assembly for a hoist unit for a patient includes a motor base, a first frame secured to the motor base for rotation about a pitch axis. The first frame includes one or more first suspension wheels rotatably affixed thereto for rotation about a laterally extending axis. The transfer assembly also includes a second frame secured to the first frame for rotation about a yaw axis. The second frame includes one or more second suspension wheels each of which is rotatably affixed thereto for rotation about a laterally extending axis. The transfer assembly also includes a drive wheel assembly rotatably mounted on the motor base for rotation about a laterally extending drive wheel axis. The transfer assembly also includes a motor assembly secured to the motor base and operatively connected to the drive wheel assembly such that operation of the motor rotates the drive wheel assembly.

An overhead lift unit includes a carriage, a first wheel assembly, a second wheel assembly, and an actuator. The first wheel assembly includes a first wheel coupled to the carriage through a first support arm. The second wheel assembly includes a second wheel coupled to the carriage through a second support arm. The actuator is coupled to the second wheel assembly and is configured to shift the second wheel assembly in a lateral direction relative to the first wheel assembly between an expanded position and a retracted position. Lift systems including the overhead lift unit and methods of transporting the overhead lift unit to and from an overhead rail are also described.

An overhead lift unit includes a carriage, a first wheel assembly, a second wheel assembly, and an actuator. The first wheel assembly includes a first wheel coupled to the carriage through a first support arm. The second wheel assembly includes a second wheel coupled to the carriage through a second support arm. The actuator is coupled to the second wheel assembly and is configured to shift the second wheel assembly in a lateral direction relative to the first wheel assembly between an expanded position and a retracted position. Lift systems including the overhead lift unit and methods of transporting the overhead lift unit to and from an overhead rail are also described.

A frame structure of a hoist, the frame structure including a support frame structure, a bearing wheel arrangement fastened to the support frame structure by suspenders to support the hoist on a main support structure and to move the hoist on the main support structure, whereby the bearing wheel arrangement includes, in the movement direction of the hoist, bearing wheels arranged on opposite sides thereof, and upper sheave arrangements secured to the support frame structure, wherein the support frame structure includes two plates arranged opposite and at a distance from each other, the upper parts of the plates bent towards each other, and in the support frame structure there is arranged an axle passing through both plates, on which axle a sheave is arranged between the plates, and the bent upper parts of the plates are detachably fastenable by a wedge locking to the suspender in order to adjust the mutual distance between the bearing wheels arranged on opposite sides of the support frame structure by means of the suspenders.

A frame structure of a hoist, the frame structure including a support frame structure, a bearing wheel arrangement fastened to the support frame structure by suspenders to support the hoist on a main support structure and to move the hoist on the main support structure, whereby the bearing wheel arrangement includes, in the movement direction of the hoist, bearing wheels arranged on opposite sides thereof, and upper sheave arrangements secured to the support frame structure, wherein the support frame structure includes two plates arranged opposite and at a distance from each other, the upper parts of the plates bent towards each other, and in the support frame structure there is arranged an axle passing through both plates, on which axle a sheave is arranged between the plates, and the bent upper parts of the plates are detachably fastenable by a wedge locking to the suspender in order to adjust the mutual distance between the bearing wheels arranged on opposite sides of the support frame structure by means of the suspenders.

A lifting device is provided, the lifting device providing a cable and a powered winch which winds and unwinds the cable. Each end of the cable provides a slack-adjustable point of attachment to a load. The points of attachment may each be attached to an opposing end of a load, such that each point of attachment provides a counterweight to the other point of attachment. Slack between the points of attachment may be tensed by a bridging connector. The lifting device may lift a load by two lateral points of attachment such that the load may be elevated off a floor with minimal vertical clearance, and may be laterally actuated by casters hanging on a suspended rail.

A lifting device is provided, the lifting device providing a cable and a powered winch which winds and unwinds the cable. Each end of the cable provides a slack-adjustable point of attachment to a load. The points of attachment may each be attached to an opposing end of a load, such that each point of attachment provides a counterweight to the other point of attachment. Slack between the points of attachment may be tensed by a bridging connector. The lifting device may lift a load by two lateral points of attachment such that the load may be elevated off a floor with minimal vertical clearance, and may be laterally actuated by casters hanging on a suspended rail.