A system for changing work tools on a loading crane includes a first coupling member on the work tool side or the loading crane side with a receiving opening and a second coupling member on the loading crane side or the work tool side with a guide member extending along a longitudinal axis. The guide member engages in the receiving opening by moving the first and second coupling members toward each other. The first coupling member comprises a support surface for axially abutting the second coupling member and the second coupling member comprises a bearing surface complementary to the support surface and a locking element which is movable by a drive between disengaged and engaged positions. The locking element has a clamping surface for frictionally abutting the first coupling member and the first coupling member has an abutment surface complementary to the clamping surface for zero-play axial clamping of the first and second coupling members.

A system includes: a detection means that detecting the weight of the load that is being manipulated is integrated into a load-sensitive guide pin that forms part of the axle bearing and that can output a signal that is proportional to the effect that is caused by the load, a power source to provide driving power for the load-sensitive guide pin, a sensor cable for the transfer of a driving voltage from the power source to the load-sensitive guide pin, a calculation means that is in signal-transfer connection with the load-sensitive guide pin in order to calculate the weight of the load that corresponds to the signal from the load-sensitive guide pin.

Described is a system for connecting a lifting device to a load to be lifted. The system includes a first connector member and a second connector member. The first connector member includes at least one pin. The second connector member includes an indexer mechanism defining a track that includes at least one track opening. At least a portion of the second connector is receivable in at least a portion of the first connector. At least a portion of the at least one pin is receivable in the track via the at least one track opening. The first connector member is reversibly coupleable to the second connector member via the pin and the indexer mechanism in response to a first series of longitudinal movements of the first or second connector members.

A truck-mounted vacuum material handler and quick disconnect for use on a truck with a with a boom for handling plate steel. The handler includes a coupler [32] that has a boom connector [44], a removable carrier [36, 38] with a carrier connector [60], and a base [34] located between the boom connector and the removable carrier. A locking mechanism [66] located in the base is arranged to move between an unlocked position and a locked position relative to the carrier connector. In the unlocked position the carrier connector is removable from the base. In the locked position the carrier connector is secured in the opening and opposing face surfaces [48, 50, 62] of the base and removable carrier are mated to one another. The removable carrier may include a rotator-receiving recess [42] or a rigging hardware eyelet [40] arranged opposite the carrier connector.

A hydraulic swivel drive for a grab that has two gripping arms or shells movable like tongs, including two swivel shafts parallel to each other and rotatably mounted in a drive housing, whose shaft ends are connectable with the gripper arms or shells, wherein the swivel shafts each have two oppositely threaded screw engagement portions, with which two pistons movable in opposite directions by means of hydraulic pressure for driving the swivel shafts are in screw engagement. Two differently large and differently contoured cylinder pressure chambers can be assigned to each piston in order to optimally adapt the cross-sectional area of the pistons for each of the reciprocating positioning movements and to appropriately select the pressure conditions. To be able to run in the differently contoured and dimensioned cylinder pressure chambers, each of the pistons is provided with different piston portions which are adapted to the respective cylinder pressure chamber.

A platform system includes a station including a moving portion and a guide configured to guide movement of the moving portion, and a manipulator configured to pick up an object from the moving portion or to place the object on the moving portion, where the moving portion is configured to move in response to the manipulator picking up the object from the moving portion or placing the object on the moving portion.

A rotary assembly for a hoist includes at least one of a rotary union and a slip ring. A bearing is positioned radially outward of the rotary union and/or slip ring with respect to a central axis. A first plurality of axially extending support columns are radially outward of the rotary union and/or slip ring and fixed to the bearing. A second plurality of axially extending support columns are radially outward of the rotary union and/or slip ring and fixed to the bearing. The second plurality of axially extending support columns is axially opposite the bearing from the first plurality of axially extending support columns.

The invention relates to a rotator (100) for a tool (200). The rotator (100) comprises a stator (102) and a rotor (104) rotatably arranged inside the stator (102). The rotor (104) comprises a radial bearing (122) having a first axial extension (a1) in the rotator (100). The rotator (100) comprises a separate bearing (112) arranged radially outside the rotor (104). The separate bearing (112) is configured to carry an external load of the rotator (100). The rotator (100) further comprises an electrical swivel (108) and/or an angle meter (116) arranged inside the rotor (102), and the electrical swivel (108) and/or the angle meter (116) at least partially extends axially in the first axial extension (a1) in the rotator (100). Thereby, a compact rotator design is provided.

The application relates to a cable drum support for rotatably supporting a cable drum, including a cross beam, on which two holding arms are arranged, which are aligned parallel to one another, wherein each holding arm has a respective laterally protruding and rotatably supported bearing pin on a free end, wherein the bearing pins are arranged aligned with one another on the holding arms so as to face one another and aligned parallel to the cross beam, and wherein at least one of the holding arms is shiftably supported along the cross beam. The cable drum support further including at least one actuatable actuator, which is formed to shift at least the one of the holding arms and/or to apply a torque to at least one bearing pin for rotating about its longitudinal central axis.

The present disclosure refers to a link member on an arm of a crane, which is pivotable around the horizontal axis (x) connected to said arm of said crane by means of a pivot joint, and is also pivotable around a further horizontal axis (y) perpendicular to the horizontal axis (x), wherein the link member is connected to a grabber furnished with a rotator for controlled rotation of the grabber around the vertical geometric axis (z). The purpose of the present disclosure is to provide accurate weighing of a free hanging load held by the grabber during transportation of the load, wherein said link member is configured to facilitate controlled rotation of the grabber around the substantially vertical geometric axis (z) despite inertial forces, which occur due to the acceleration or deceleration of the load when being rotated around said substantially vertical axis (z). In particular, link member comprises an elastically deformable area arranged between said pivot joints and is deformable depending on stresses to which said link member is subjected, which is caused by the weight of the load. The weight of each load is determined on the basis of deformations within said elastically deformable area of the link member, which are detected by means of suitably arranged sensors.