A welding robot is provided. The welding robot is adapted for operating in the space between an upper and a lower platen of a press and comprises a support frame. A welding tool is movable mounted to the support frame. A grinding tool is movable mounted to the support frame. At least a camera is adapted for capturing a view of a working area. A processor is adapted for executing executable commands stored in a storage medium connected thereto. The processor when executing the commands identifies defects on a surface of one of the upper and the lower platen based on image data received from the at least a camera and controls the welding tool and the grinding tool in dependence on the image data. The processor receives data indicative of the repair area, automatically determines toolpath data for welding and grinding in dependence upon the data indicative of a repair area, and generates and provides control data for controlling the welding tool and the grinding tool in dependence upon the toolpath data.

A foldable boom for conveying an item, said foldable boom being foldable about at least one folding axis, said foldable boom being locatable in a folded stowed position, and moveable to unfolded extended positions; said foldable boom having a near end arranged for pivotal movement about a first horizontal axis located on a turret, said turret being rotatable about a vertical axis; said foldable boom having first conveying apparatus to convey an item therealong, internally within said foldable boom, to a remote end of the foldable boom; wherein said foldable boom is foldable about a folding axis, and a pivoting shuttle equipped with a clamp to releasably hold an item is provided at said folding axis to transfer said item between said first conveying apparatus in boom elements connected about said folding axis.

A transferring system for transferring an object disposed in a storage area includes telescopic units, sucking disc units respectively connected to the telescopic units, and a control unit. The control unit calculates an area related to an object according to an image obtained by an imaging unit, and calculates a value of N based on the area. The value of N is a number of the sucking disc units used for picking up the object and is equal to or greater than one. The control unit determines N positions on the object, controls N telescopic units to move N sucking disc units toward the N positions, and controls the N sucking disc units to adhere respectively to the N positions so as to pick up the object from the storage area.

An autonomous moving transfer robot, including a main body with a base and a vertical plate; a traveling mechanism having a driving wheel and a driven wheel mounted on the base; a working mechanism having two manipulators, each with a mechanical arm, a proximal end of which is connected to the vertical plate, and a clamp pivotally connected to a distal end of the mechanical arm; the mechanical arms enable the clamps to reach a desired position, and the manipulators drive the clamps to grip and release a target object; a carrying mechanism having a plurality of plate-shaped carrying members for carrying the target object, the carrying members being fixed on the same side of the vertical plate, and arranged at intervals along the vertical direction; and a control system for controlling the walking/stopping and steering of the traveling mechanism and the movement of the manipulators.

In one example there is disclosed, an apparatus (10) for vacuum cleaning a tank (11). The apparatus (10) includes a main body (12) coupled to a working arm (14) and a plurality of support legs (16) coupled to the main body (12). The main body (12) includes a main conduit (40) extending lengthwise therethrough and a common central actuator (32) fitted about by the main conduit (40). The working arm (14) includes a vacuum conduit (50) in fluid communication with the main conduit (40). The plurality of support legs (16) are operatively coupled to the common central actuator (32) so as to be simultaneously moveable at least between a collapsed condition so as to fit through an opening 18 of the tank 11, and an extended condition in which the plurality of support legs (16) are moved relatively outwardly so as to be telescopically extendable within the tank (11) to engage a side wall (20) of the tank to support the main body (12). Other examples of the apparatus, a system and related methods are also disclosed.

A nuclear dismantling system for dismantling equipment contaminated with radioactive contamination, including a dismantling apparatus to be operated remotely while in a nuclear facility and a control system communicatively coupled to the dismantling apparatus to control the dismantling apparatus remotely.

A refuse vehicle includes a chassis, tractive elements, a lift apparatus, and a reach assembly. The tractive elements couple with the chassis and support the refuse vehicle. The lift apparatus includes a track and a grabber assembly. The track includes a straight portion and a curved portion. The grabber assembly releasably grasps a refuse container and ascends or descends the track to lift and empty refuse into a body of the refuse vehicle. The reach assembly includes an outer member, a first extendable member, and a second extendable member. The first extendable member is received within an inner volume of the outer member and translates relative to the outer member. The second extendable member is received within an inner volume of the first extendable member and translates relative to the first extendable member. The lift apparatus is fixedly coupled at an outer end of the second extendable member.

A linear motion mechanism includes: a plurality of cylinders, assembled telescopically in multiple stages; a block row with a head block connected to the head cylinder; guide rails and configured to accommodate the block row in a circular arc shape; a torque generating unit configured to generate torque for feeding the block row from the guide rails and pulling back the block row from the guide rails; and an arm for transmitting the torque generated by the torque generating unit to the block row. A rotary shaft of the torque generating unit is arranged at a circular arc center of the guide rails, one end of the arm is connected to a rotary shaft of the torque generating unit, and another end thereof is connected to a rearmost block among a plurality of blocks.

Provided is a long arm supported in a cantilever manner with light weight and high rigidity. The rod 30 is formed from rods 31-33 so as to be a multi-stage telescopic configuration. The rods 32, 33 respectively have upright columns 42, 43 on the tips. The wire 11 is suspended between the tip of the rod 31 and the lead end of the arm via the top of the column 42. The wire 12 is suspended between the base of the column 42 and the lead end of the arm via the top of the column 42. The wire 22 is suspended between the top of the column 42 and the lead end of the arm via the top of the column 43. The tension generation means 50 pulls the wires 10, 20. The air pressure generation means 60 applies pressure to the inside of the rod 30.

A door opening device comprising a multi-directional head and a telescoping pole is provided. The multi-directional head allows the operator to choose the angle when opening the door and the telescoping pole allows the operator to remain at a distance away from the doorway while operating the doorknob. By allowing an operator to remain around a corner when opening a door, an armed and cornered individual is less able to harm the operator by shooting through the door.