An automated lumber handling method for transferring various size boards from multiples board storage stations to a common board-receiving area uses a trolley that carries at least two board pickers that can operate independently. The method provides several operating modes. In a first mode, a first board picker retrieves single boards from various stations, while a second board picker is inactive. In a second mode, two board pickers retrieve two individual boards from a single station. In a third mode, one board picker retrieves one size board from a first station, and s second board picker retrieves a different size board from a second station. The two different boards can be released simultaneously at the board-receiving area. In some examples, the lumber at each station is laser scanned to determine the number of boards at each station, and a worker is notified if a station needs to be restocked.

An automated robotic depalletizing system includes at least one robot for transferring inventory that arrives on a pallet to different storage locations within a warehouse. The robot may perform the automated depalletizing by moving to the pallet having a stacked arrangement of a plurality of objects, identifying, via a sensor, a topmost object of the plurality of objects, aligning a retriever with the topmost object, engaging the topmost object with the retriever, and transferring the topmost object from the pallet to the robot by actuating the retriever. The automated depalletizing may also be performed via coordinated operations of two or more robots. For instance, a first robot may retrieve objects from the pallet, and a second set of one or more robots may be used to transfer the retrieved objects into storage.

An automated robotic depalletizing system includes at least one robot for transferring inventory that arrives on a pallet to different storage locations within a warehouse. The robot may perform the automated depalletizing by moving to the pallet having a stacked arrangement of a plurality of objects, identifying, via a sensor, a topmost object of the plurality of objects, aligning a retriever with the topmost object, engaging the topmost object with the retriever, and transferring the topmost object from the pallet to the robot by actuating the retriever. The automated depalletizing may also be performed via coordinated operations of two or more robots. For instance, a first robot may retrieve objects from the pallet, and a second set of one or more robots may be used to transfer the retrieved objects into storage.

A method for unloading a container having packages with a rail device comprising a rail having a hand element displaceable in the longitudinal direction. The hand element has a plurality of finger elements having two flexible flank elements extending jointly from one end to the opposite end of the finger element. Each are connected flexibly to each other via a plurality of webs. The finger elements adjustable from a curved position into an extended position and back. The packages are stacked in the container forming a front face in which the rail device is brought close to the front face of the stacked packages. One hand element grips one package from the stack of packages and removes it from the stack. Following the removal, it is displaced along the rail and following the displacement grips one further package and removes it from the stack of packages.

A method for unloading a container having packages with a rail device comprising a rail having a hand element displaceable in the longitudinal direction. The hand element has a plurality of finger elements having two flexible flank elements extending jointly from one end to the opposite end of the finger element. Each are connected flexibly to each other via a plurality of webs. The finger elements adjustable from a curved position into an extended position and back. The packages are stacked in the container forming a front face in which the rail device is brought close to the front face of the stacked packages. One hand element grips one package from the stack of packages and removes it from the stack. Following the removal, it is displaced along the rail and following the displacement grips one further package and removes it from the stack of packages.

A main mover and sub mover are made to run while changing a relative distance of the sub mover with respect to the main mover to change contact positions of cams and cam followers based on a holding position of a sheet member detected by a position detection device to thereby change a position in a horizontal plane of a holder and correct a holding position of the sheet member held at the holder to a preset reference position.

A main mover and sub mover are made to run while changing a relative distance of the sub mover with respect to the main mover to change contact positions of cams and cam followers based on a holding position of a sheet member detected by a position detection device to thereby change a position in a horizontal plane of a holder and correct a holding position of the sheet member held at the holder to a preset reference position.

The present invention relates to pick planning for robotic picking applications to improve efficiency of automated picking operations and reduce robot down time. A pick plan is computed by obtaining data of a pick scene, processing the obtained data to identify objects and determine features associated with the objects, and determining an order and pick instructions based on the features. A computed pick plan may be periodically verified by reacquiring data of the pick scene and comparing the reacquired data with previous pick scene data in order to determine if a pick plan remains appropriate or should be updated or discarded and recomputed.

The present invention relates to pick planning for robotic picking applications to improve efficiency of automated picking operations and reduce robot down time. A pick plan is computed by obtaining data of a pick scene, processing the obtained data to identify objects and determine features associated with the objects, and determining an order and pick instructions based on the features. A computed pick plan may be periodically verified by reacquiring data of the pick scene and comparing the reacquired data with previous pick scene data in order to determine if a pick plan remains appropriate or should be updated or discarded and recomputed.

A pick-up device picking up stacked sheet-shaped workpieces from the top, the device includes a nozzle mechanism that pulls up a first workpiece from the top of the stacked workpieces by air blowing, a holding mechanism that holds the first workpiece, a separation mechanism that includes a claw member being inserted into a lower side of the first workpiece with respect to the stacked workpieces, and a forward and backward drive unit causing a tip part of the claw member to move forward and backward, a suction mechanism that pulls up the first workpiece, a control device that controls the above four mechanisms, and a selection unit that selects one or more combinations of the nozzle mechanism, the separation mechanism, and the suction mechanism. The control device controls an operation for picking up the stacked workpieces from the top according to the selection of the selection unit.