An attachment for a skid loader includes a base configured to attached to a loader arm of the skid loader, a rotatable coupling attached to the base on a side opposite the loader arm, and a claw portion attached to the rotatable coupling. The claw portion includes a stationary jaw and a pivoting jaw. The pivoting jaw pivotable with respect to the stationary jaw about a pivot rod. The pivoting jaw is coupled to the rotatable coupling via a hydraulic cylinder such that movement of the pivoting jaw about the pivoting rod is effected by actuation of the hydraulic cylinder.

A rotation device arrangement includes a structure and a suspension part for suspending the rotation device from a boom. The structure includes a first inner body part and first conduits for leading a pressure medium through the first inner body part. A second outer body part is arranged at least partly around the first inner body part completely rotatably. First connections are fitted for leading the pressure medium through the second outer body part. Second conduits are fitted to at least one of an outer surface belonging to the first inner body part and an inner surface belonging to the second outer body part for leading the pressure medium from the first conduit to the first connections. A bearing is arranged to permit the second outer body part to rotate and to carry loads axially and radially. Second connections attach a direct-drive pressure-medium operated turning device to the structure coaxially to transmit torque.

A framework comprises a laser distance meter (LDM), reflector, and excavator comprising a boom, a stick, boom and stick sensors, implement, and a controller. The LA comprises a boom and stick defining LA positions. The LDM is configured to generate a D.sub.LDM and .sub.INC between the LDM and the reflector, and the controller is programmed to generate .sub.B at a plurality of boom positions, generate .sub.S at a plurality of stick positions, and calculate a height H and a distance D between a node on the stick and the LDM based on D.sub.LDM and .sub.INC, build a set of H, D measurements and a corresponding set of .sub.B, .sub.S, and execute a linear least squares optimization process based on the H, D set and corresponding set of .sub.B, .sub.S to determine and operate the excavator using L.sub.B and L.sub.S.

A hoisting apparatus includes a rotation device with connectors for connecting pressure-medium lines to a rotation device, a boom, from which the pressure-medium lines are arranged to lead to the rotation device, and a pivoted joint for suspending the rotation device on the boom. The pivoted joint includes two consecutive pivots in a longitudinal direction of the rotation device. The rotational axes of the pivots are at right-angles to each other. The pressure-medium lines are routed between lugs of the pivot on a boom side of the pivoted joint, past the connectors of the rotation device in the longitudinal direction of the rotation device, to turn towards the connectors to form a hose loop and then routed to the connectors of the rotation device. The pressure-medium lines are arranged on both sides of the rotation device related to a plane defined in the longitudinal direction of the boom and the longitudinal direction of the rotation device.

A utility vehicle comprising a main frame, a movable subframe coupled with the main frame, a work tool coupled with the movable subframe by a rotational attachment, an actuator coupled with the rotational attachment, wherein the work tool rotates, by the rotational attachment, relative to the movable subframe about an axis that is parallel to a central longitudinal axis of the main frame, a position detection sensor operable to detect data related to an orientation of the work tool relative to a direction of gravity, a computer-readable memory storing operation information, where an electronic processor is configured to receive a first work tool position data from the position detection sensor about a first position of the work tool, send a work tool rotation signal to the actuator, move the work tool to a second position wherein the second position comprises a position substantially level with gravity.

The invention relates to a method and an arrangement related to a rotator, especially for a work tool supported by an arm, whereby the rotator (10) comprises a stator (20) and a rotor (30). A fastening ring (50) for the attaching of a work tool is separately journalled (D) relative to the stator (20) independently of a bearing (B, C) between the stator (20) and the rotor (30). A driver (80; 180; 280) is used to transfer the rotational movement of the rotor (30) to the fastening ring (50).

The invention relates to a system and a method for, with a first and a second hand operated control means (11a, 11b), controlling movement on a work tool (5) for a construction machine (1). The construction machine (1) comprises a lower carriage (2), a top (3), a digging arm (4) and a work tool (5). The digging arm (4) comprises an inner link arm (4a) with a first and a second inner link arm end (4a1, 4a2) and an outer link arm (4b) with a first and a second outer link arm end (4b1, 4b2). The work tool (5) is secured in the second outer link arm end (4b2) via an attachment device (6) which enables controlled rotation and controlled tilting of the work tool (5) in relation to the outer link arm (4b). The system is characterized in that the first hand operated control means (11a) is intended to control the position of the second outer link arm end (4b2) and the second hand operated control means (11b) is intended to control the function of the tool (5), comprising controlled rotation and controlled tilting of the work tool (5) in relation to the outer link arm (4b).

In accordance with an example embodiment, a wrist includes a frame, ring gear rotatable about a ring axis, and motor assembly with a pinion subassembly and motor with an output shaft. The pinion subassembly includes an internal spline and pinion connected to opposite sides of an internal shaft and rotatable about a pinion axis, and motor and frame bolt patterns. The motor is fastenable to the pinion subassembly at a plurality of motor-pinion indices via the motor bolt pattern. The pinion subassembly is fastenable to the frame mount at a plurality of pinion-frame indices via the frame bolt pattern so as to mesh the pinion with the ring gear and allow the output shaft to drive the ring gear via the internal spline, internal shaft, and pinion. The distance between the ring axis and the pinion axis varies for the plurality of pinion-frame indices.

A pressure medium cylinder (1) for moving a toothed bar (3), comprising a toothed bar (3) on at least one side of which is formed a toothing (4). Inside the toothed bar (3), a cavity (6, 6a, 6b) is formed, extending to at least one end (7a, 7b) of the toothed bar. The pressure medium cylinder (1) further comprises a longitudinal structure (8, 8a, 8b), the longitudinal structure (8, 8a, 8b) and the toothed bar (3) being adapted movably in relation to each other, and the longitudinal structure (8, 8a, 8b) is adapted at least partly inside said cavity (6, 6a, 6b). The toothed bar (3) and longitudinal structure (8, 8a, 8b) are adapted in a sealed manner in relation to each other so that the toothed bar and the longitudinal structure are movable in relation to each other by the effect of a pressure medium.

Fully rotating rotary actuator of a multi-purpose machine in which an axle supports the frame of a felling head by a bearing mount, there being a rotary mechanism driven by a rotary motor between the axle and the frame, and in which the connection of the axle includes rotatable joints, the axle includes conduits for electrical cables and a processing fluid line, and in which an additive fluid line tube is arranged in the conduit in the axle and connected to its lower end is a rotatable connector, which is connected to a second tube fastened in the frame for the application of the additive fluid.