Lift assemblies and methods of operating same. A lift assembly for a vehicle includes at least one support member having a longitudinal axis lying on a plane and which is configured for attachment to the vehicle. A mast having a proximal end, a distal end, and a mast axis is pivotably coupled with the at least one support member at the mast proximal end. At least one gear arrangement is coupled between the at least one support member and the mast proximal end. The mast is pivotable relative to the at least one support member about an axis parallel with the plane through an angular displacement greater than 90 degrees. A boom is pivotably coupled with the mast proximate the mast distal end, and a first lift line is coupled with the boom.

Lift assemblies and methods of operating same. A lift assembly for a vehicle includes at least one support member having a longitudinal axis lying on a plane and which is configured for attachment to the vehicle. A mast having a proximal end, a distal end, and a mast axis is pivotably coupled with the at least one support member at the mast proximal end. At least one gear arrangement is coupled between the at least one support member and the mast proximal end. The mast is pivotable relative to the at least one support member about an axis parallel with the plane through an angular displacement greater than 90 degrees. A boom is pivotably coupled with the mast proximate the mast distal end, and a first lift line is coupled with the boom.

Embodiments for a trailer mounted log loader are described. The trailer mounted log loader includes an A-frame made of square beams which have a connection plate attached at one end forming an apex of the A-frame. A hollow connection adapter is positioned between and connected to the connection plates of the A-frame. An extendable boom arm is situated within the hollow connection adapter. The extendable boom arm has an attachment point at a distal end opposite from the hollow connection adapter where an attachable attachment is connectable to the extendable boom arm. A pair of pivot arms are connected to a base of the A-frame. The A-frame pivot arms are in turn pivotally connect to a pair of uprights . . . . The ability to remove the uprights from the support posts allows the trailer mounted log loader to be mounted to any trailer or truck bed or stored when not in use.

Embodiments for a trailer mounted log loader are described. The trailer mounted log loader includes an A-frame made of square beams which have a connection plate attached at one end forming an apex of the A-frame. A hollow connection adapter is positioned between and connected to the connection plates of the A-frame. An extendable boom arm is situated within the hollow connection adapter. The extendable boom arm has an attachment point at a distal end opposite from the hollow connection adapter where an attachable attachment is connectable to the extendable boom arm. A pair of pivot arms are connected to a base of the A-frame. The A-frame pivot arms are in turn pivotally connect to a pair of uprights . . . . The ability to remove the uprights from the support posts allows the trailer mounted log loader to be mounted to any trailer or truck bed or stored when not in use.

A grapple truck with side loader having a generally J-shaped scoop in a lateral recess of the truck bed sidewall. Sometimes loader is longitudinally truncated forming an adjacent debris-bin vertical transport. The power lift system is either a direct lift-pivot with cylinder lifters or a channel-guided lifter with candy-cane shaped channels. Side loader rises from a low, manual loading position to an upper inverted dump position whereat loader displaces debris into truck bed box. Scoop's loader edge is planarly coextensive or inboard truck sidewall, and at or beneath the truck wheel axis line. A chassis mounted, articulated boom, with longitudinally extending arm segments, terminates in a grapple jaw. The articulated boom and grapple jaw has a longitudinally foreshortened stored position in and above the truck bed. In multiple operative positions, the arm extends beyond the truck bed and rear bed wall and laterally over and beyond truck sidewalls.

Lift assemblies and methods of operating same. A lift assembly for a vehicle includes at least one support member having a longitudinal axis lying on a plane and which is configured for attachment to the vehicle. A mast having a proximal end, a distal end, and a mast axis is pivotably coupled with the at least one support member at the mast proximal end. At least one gear arrangement is coupled between the at least one support member and the mast proximal end. The mast is pivotable relative to the at least one support member about an axis parallel with the plane through an angular displacement greater than 90 degrees. A boom is pivotably coupled with the mast proximate the mast distal end, and a first lift line is coupled with the boom.

Lift assemblies and methods of operating same. A lift assembly for a vehicle includes at least one support member having a longitudinal axis lying on a plane and which is configured for attachment to the vehicle. A mast having a proximal end, a distal end, and a mast axis is pivotably coupled with the at least one support member at the mast proximal end. At least one gear arrangement is coupled between the at least one support member and the mast proximal end. The mast is pivotable relative to the at least one support member about an axis parallel with the plane through an angular displacement greater than 90 degrees. A boom is pivotably coupled with the mast proximate the mast distal end, and a first lift line is coupled with the boom.

The invention provides a loader having a boom, a hydraulic motor, a slewing ring, and a boom swing control assembly. The boom is configured to rotate in response to operation of the hydraulic motor. The boom swing control assembly comprises a control gear, a first valve, and a first hydraulic line. The control gear is engaged with a slew gear of the slewing ring such that the control gear rotates in response to rotation of the boom. The hydraulic line is in fluid communication with the first valve and the hydraulic motor. Depending on whether the first valve is in an open or a closed configuration, hydraulic fluid is either free to pass, or is restrained from passing, through the first hydraulic line to the hydraulic motor.

The device comprises a folding handling arm, equipped with a handling head and at least two successive arm parts, in which the arm parts are connected to each other by a folding fastening, the device further comprising a suspension structure (HS) to suspend the handling arm for the purpose of supporting it, the device further comprising a rotating structure to turn the handling arm by turning the suspension structure in relation to the support frame located at the upper part of the cargo space in the device. The suspension structure of the handling arm is essentially a rotationally symmetrical, rotation ring structure disc that is rotatable in relation to its support frame with the rotating structure in order to suspend the handling arm for the purpose of supporting it.

The invention provides a loader having a boom, a hydraulic motor, a slewing ring, and a boom swing control assembly. The boom is configured to rotate in response to operation of the hydraulic motor. The boom swing control assembly comprises a control gear, a first valve, and a first hydraulic line. The control gear is engaged with a slew gear of the slewing ring such that the control gear rotates in response to rotation of the boom. The hydraulic line is in fluid communication with the first valve and the hydraulic motor. Depending on whether the first valve is in an open or a closed configuration, hydraulic fluid is either free to pass, or is restrained from passing, through the first hydraulic line to the hydraulic motor.