An automated parts handling system includes a conveyor, a robotic arm configured to pick parts from a parts receptacle and place the picked parts on the conveyor, a vision device disposed over or adjacent the conveyor and configured to determine the number of parts picked by the robotic arm from the parts receptacle and placed on the conveyor, a memory, and a processor communicatively coupled to the conveyor, the robotic arm, and the vision device. The memory includes program instructions executable by the processor to implement a pick process configured to receive information from the vision device on the number of parts picked by the robotic arm and placed on the conveyor, based on the received information regarding the number of picked parts, selectively control the robotic arm to retrieve from the conveyor a number of the picked parts, and selectively control the robotic arm to place one or more of the retrieved parts back in the parts receptacle when the number of parts picked by the robotic arm differs from a predetermined number of parts specified in the program instructions.

A technique for detecting the completion of work of attaching a workpiece to a pallet is provided. A pallet transport system includes: a transport device for transporting a pallet to which a workpiece can be attached; a pallet housing unit for housing the pallet, a workstation in which a worker is to conduct work of attaching the workpiece to the pallet transported from the pallet housing unit; a machine tool for machining the workpiece attached to the pallet in the workstation; and a control device for controlling the transport device. The control device acquires an indicator indicating progress of the attachment work in the workstation, determines whether or not the attachment work has been completed based on the indicator, and when it is determined that the attachment work has been completed, transports the pallet located in the workstation to the pallet housing unit or the machine tool.

The present invention relates to a removal system and a method for removing parts processed in a processing system (200). The removal system is designed for engagement with a transportation unit (110) which is used for intermediate storage and/or transportation of a workpiece processed with the processing system (200), the processed workpiece comprising the parts to be removed. The removal system comprises a bridge movement system (120) which extends with its central longitudinal axis transversely to the longitudinal axis of the transportation unit (110) and can be moved axially in the longitudinal axis of the transportation unit (110). In addition, the removal system comprises a first parts conveyor system, which is arranged on the bridge movement system (120) and extends substantially parallel to the central longitudinal axis of the bridge movement system. Finally, the removal system comprises control unit which communicates with the transportation unit, the bridge movement system and the first parts conveyor system and provides control commands for the transportation unit, the bridge movement system and the parts conveyor system.

The present invention relates to a removal system and a method for removing parts processed in a processing system (200). The removal system is designed for engagement with a transportation unit (110) which is used for intermediate storage and/or transportation of a workpiece processed with the processing system (200), the processed workpiece comprising the parts to be removed. The removal system comprises a bridge movement system (120) which extends with its central longitudinal axis transversely to the longitudinal axis of the transportation unit (110) and can be moved axially in the longitudinal axis of the transportation unit (110). In addition, the removal system comprises a first parts conveyor system, which is arranged on the bridge movement system (120) and extends substantially parallel to the central longitudinal axis of the bridge movement system. Finally, the removal system comprises control unit which communicates with the transportation unit, the bridge movement system and the first parts conveyor system and provides control commands for the transportation unit, the bridge movement system and the parts conveyor system.

A cam device includes a drive cam, a follower, a holding cam, and a restriction roller. The drive cam reciprocally rotates. The follower intermittently reciprocate linearly by the drive cam. The holding cam is rotationally driven integrally with the drive cam. The restriction roller is provided on the follower and restricts a movement of the follower by coming in contact with the holding cam. The holding cam separates from the restriction roller and the holding cam is in a holding release state, when the drive cam is in an engaged state with the follower.

An embodiment includes a plurality of transport modules forming a transport path on which a carriage that transports a workpiece travels, and a control unit that controls a position of the carriage on the plurality of transport modules based on a drive instruction, and the control unit corrects the drive instruction during carriage motion that is based on the drive instruction and stops the carriage.

An embodiment includes a plurality of transport modules forming a transport path on which a carriage that transports a workpiece travels, and a control unit that controls a position of the carriage on the plurality of transport modules based on a drive instruction, and the control unit corrects the drive instruction during carriage motion that is based on the drive instruction and stops the carriage.

The present subject matter relates to automated gemstone feeding in a gemstone processing machine. In an implementation, the gemstone processing machine has a feeding conduit unit to receive a rough gemstone affixed to a holder from a user. The feeding conduit unit delivers the holder to a base plate. An actuating arm picks the holder from the base plate and transfers the holder to a pre-defined position in the gemstone processing machine. The automated feeding mechanism is controlled by the computing device and uses low-cost hardware equipment having limited or no manual intervention. Thus, providing an apt tradeoff between the accuracy of transfer of the rough gemstone and the cost associated with the equipment used for the processing of the gemstone.

An embodiment includes a plurality of transport modules forming a transport path on which a carriage that transports a workpiece travels, and a control unit that controls a position of the carriage on the plurality of transport modules based on a drive instruction, and the control unit corrects the drive instruction during carriage motion that is based on the drive instruction and stops the carriage.

An embodiment includes a plurality of transport modules forming a transport path on which a carriage that transports a workpiece travels, and a control unit that controls a position of the carriage on the plurality of transport modules based on a drive instruction, and the control unit corrects the drive instruction during carriage motion that is based on the drive instruction and stops the carriage.