A locking assembly includes a horizontal locking structure movable between a first position, in which the horizontal locking structure is arranged to protrude into a horizontal portion opening of a corner mount to restrict movement of the corner mount in a horizontal direction, and a second position to release the corresponding horizontal movement restriction. The locking assembly also includes a vertical locking structure mechanically connected to the horizontal locking structure, the vertical locking structure being movable between a third position, wherein a portion of the vertical locking structure is arranged in an opening of a vertical side of the corner mount to restrict movement of the corner mount in a vertical direction, and a fourth position to release the corresponding vertical movement restriction. An actuator member is structured to control the positions of both the horizontal locking structure and the vertical locking structure by a linear movement.

Lifting system (1) for mounting on a loading surface of a vehicle (3), comprising at least one first lifting arm system (4) on one side of the loading surface in the transverse direction of the vehicle (3) and at least one second lifting arm system (5) on the other side of the cargo area in the transverse direction of the vehicle (3). The lifting arm systems (4, 5) comprises at least one foundation (6) with which the respective lifting arm system (4, 5) is connected to the vehicle (3), The lift arm systems (4, 5) each comprise at least one lifting arm (9) and at least one operating mechanism (15). The lifting device (1) comprises at least one lifting boom (13) extending between the lifting arm (9) in the first lifting arm system (4) and the lifting arm (9) in the second lifting arm system (5), The operating mechanism (15) is operated with at least one actuator (27). The actuating mechanism (15) comprises at least one first operating arm (16), which is rotatably connected at one end, or end thereof, to the base (6) and at its other end, or its proximity is connected to the lifting arm (9) via at least one arm link (22). The operating arm (16) and the arm link (22) are pivotally connected to each other and the arm link (22) is pivotally arranged relative to the lifting arm (9). The operating mechanism (15) further comprises at least one operating link (25) which is pivotally connected to the operating arm (16).

A loading and transport system is disclosed that engages with a transporting vehicle such as a hauler or semi-truck. The system includes a plurality of transporting components including platforms or compartments that are accessible independently for efficiently loading and unloading objects including vehicles or freight boxes.

A trailer for lifting and positioning at least one reel thereon. The trailer includes a pair of articulated arms comprising a first elongate member and a second elongate member pivotally mounted to the first elongate member. The first elongate members are generally horizontal and movable relative to the trailer between a retracted position and a rearwardly extended position. The second elongate members are pivotable between a horizontal position in parallel alignment with the first elongate members and an upright position wherein the second elongate members are orthogonal to the first elongate members. The second elongate members are provided with respective jacks to stabilise them with respect to the ground surface. A hoist to lift the reel from the support surface to an effective height greater than an effective height of a deck of the trailer is disposed between the second elongate members.

A self-loading assembly (10) for a vehicle (12) including a base frame (14) operatively secured to the vehicle (12) and a cargo body (16) operatively adapted to be located on the base frame (14) to be transported by the vehicle (12). The self-loading assembly (10) further includes a loading arm (22) operatively associated with the base frame (14), the loading arm (22) operatively adapted to move relative to the base frame (14) between (i) a transport position in which the cargo body (16) is located on to the base frame (14), and (ii) an offload position wherein the cargo body (16) is offloaded from the base frame (14). The self-loading assembly (10) further includes an actuator assembly (28) operatively adapted to move the loading arm (22) between the transport position and the offload position, the actuator assembly including (i) an arm pivot member (30) on which the loading arm (22) is mounted and about which the loading arm (22) pivots as it moves between the transport position and the offload position, and (ii) a linkage assembly (32) connecting the loading arm (22) with an actuator (34), the linkage assembly (32) adapted to move the loading arm between the transport position and the offload position when the actuator (34) is caused to move between a first position and a second position.

A solar panel dispensing device comprising a hopper and a robotic arm. The hopper includes a base and a frame defining an interior volume and being configured to contain solar panels therein supported in an upright position. The robotic arm is moveable about the hopper in one or more degrees of freedom. The robotic arm includes a solar panel end effector operable to acquire a lead solar panel oriented in the upright orientation. The solar panel end effector includes an interfacing orientation and a release orientation; The robotic arm further includes an arm actuator operable to move the robotic arm and the solar panel end effector between the interfacing orientation and the release orientation. The interfacing orientation and the release orientation of the solar panel end effector correspond respectively to the solar panel being in the upright orientation, and the solar panel being in a presentation orientation.

A self-propelled robot includes a travel cart, a base part provided to an upper part of the travel cart and swivelable on a first rotation axis extending vertically, and a pair of robotic arms coupled to the base part at base-end parts, respectively. Each of the pair of robotic arms has a first link and a second link coupled at a base-end part to a tip-end part of the first link via a joint part. Base-end parts of the pair of first links are coupled to the base part so that the base-end parts are coaxially pivotable on a second rotation axis extending horizontally, and the base-end parts oppose to each other via the base part. The base-end parts of the pair of second links are coupled to side parts of the tip-end parts of the corresponding first links, on the opposing sides of the pair of first links.