A cross-laminated timber processing equipment comprises a longitudinal board loading mechanism, a transverse board loading mechanism, an adhesive spraying mechanism, laying cars, presses, a transfer car, and an unloading car. The longitudinal board loading mechanism lays longitudinal boards on a laying car at an assembly station, and the transverse board loading mechanism lays transverse boards on the laying car. The longitudinal boards and the transverse boards are perpendicularly and alternately laid layer by layer. The adhesive spraying mechanism is provided above the assembly station, and sprays an adhesive on the upper surfaces of assembled boards. The transfer car moves back and forth between a conveying station and an idle press through the assembly station, carries the laying cars and the assembled boards, and feeds the laying cars and the assembled boards into the presses for compaction. The unloading car moves back and forth between a press completing compaction and an unloading station, and conveys an idle laying car to the assembly station. Compared with other international similar equipment, this equipment can implement fully-automatic cross-laminated timber processing and production, and has low apparatus cost, high production capacity, high processing efficiency, and a great leading advantage.

A system for assembly of components, including a vibrating device wherein the components are placed in bulk, which is provided with first and second compartments connected together at their ends by first and second passage zones to form a closed circuit wherein the components can flow, and an articulated gripping arm provided to distribute the components to an automatic assembly installation, the vibrating device including first and second planes inclined in opposite directions included, respectively, in the first and second compartments, the components being able to progress along the first and second inclined planes towards a supply platform on which at least one component can be arranged in advance of its seizure by the articulated gripping arm, the supply platform being located in the second compartment at an exit of the second inclined plane.

A system for assembly of components, including a vibrating device wherein the components are placed in bulk, which is provided with first and second compartments connected together at their ends by first and second passage zones to form a closed circuit wherein the components can flow, and an articulated gripping arm provided to distribute the components to an automatic assembly installation, the vibrating device including first and second planes inclined in opposite directions included, respectively, in the first and second compartments, the components being able to progress along the first and second inclined planes towards a supply platform on which at least one component can be arranged in advance of its seizure by the articulated gripping arm, the supply platform being located in the second compartment at an exit of the second inclined plane.

A method of processing objects is disclosed using a programmable motion device. The method includes the steps of acquiring an object from a plurality of mixed objects at an input area, perceiving identifying indicia in connection with the object, assigning an intermediate station to a destination location for the object responsive to the identifying indicia in connection with the object, and moving the acquired object toward the intermediate station.

A method of processing objects is disclosed using a programmable motion device. The method includes the steps of acquiring an object from a plurality of mixed objects at an input area, perceiving identifying indicia in connection with the object, assigning an intermediate station to a destination location for the object responsive to the identifying indicia in connection with the object, and moving the acquired object toward the intermediate station.

A sampling apparatus is provided, which includes a pressing-up unit configured to press up a sheet piece that is being conveyed by a conveying unit, from a lower side of a conveyance course of the sheet piece to above the conveyance course; and a holding unit configured to hold the sheet piece pressed up by the pressing-up unit.

A sampling apparatus is provided, which includes a pressing-up unit configured to press up a sheet piece that is being conveyed by a conveying unit, from a lower side of a conveyance course of the sheet piece to above the conveyance course; and a holding unit configured to hold the sheet piece pressed up by the pressing-up unit.

Present embodiments relate to a tie plate dispenser which aligns tie plates for dispensing based on rail base rather than outer edges of tie plate. Thus tie plates are aligned and located in a differing manner than prior art systems. Further, the tie plate dispenser includes an opening over which a magnet is disposed to retain a tie plate over the opening. The tie plate over the opening may be selectively released by disengaging the tie plate from the magnet.

A method of processing objects is disclosed using a programmable motion device. The method includes the steps of acquiring an object from a plurality of mixed objects at an input area, perceiving identifying indicia in connection with the object, assigning an intermediate station to a destination location for the object responsive to the identifying indicia in connection with the object, and moving the acquired object toward the intermediate station.

A method of processing objects is disclosed using a programmable motion device. The method includes the steps of acquiring an object from a plurality of mixed objects at an input area, perceiving identifying indicia in connection with the object, assigning an intermediate station to a destination location for the object responsive to the identifying indicia in connection with the object, and moving the acquired object toward the intermediate station.