A machine tool system and an opening stop position calculating device are provided. The machine tool system includes an openable and closable door for closing an opening of a cover surrounding a machine tool. Furthermore, the machine tool system includes an opening width setting unit for setting an opening width of the door, an opening stop position calculating unit for calculating an opening stop position of the door at which a total time, which is obtained by summing a time required to move the door from a fully closed position to a position of the set opening width and a time required to move the door from an opening stop position where the door is opened and stopped to the fully closed position, is minimized, and a door control unit for controlling opening and closing of the door based on the calculated opening stop position when exchanging the workpiece.

A workpiece information recognition system includes a workpiece placing tool (20) capable of placing a workpiece, a reference block (31) detachably provided on workpiece placing tool (20), an information detector configured to detect information about reference block (31), and a control device configured to receive the information of reference block (31) from the information detector. The control device includes a storage configured to store data on a relationship between the information about reference block (31) and information about the workpiece and a controller configured to recognize the information about the workpiece placed on workpiece placing tool (20) by checking the information about reference block (31) detected by the information detector with the data stored in the storage. With this configuration, the workpiece information recognition system capable of easily cope with a change in a type of the workpiece is provided.

A system and method for placing an object, which is to be processed on a production apparatus in a precise position, is provided. The system includes at least one location-determining system for determining a relative location of an object in relation to a production apparatus and a positioning apparatus for positioning the object on the production apparatus. The positioning apparatus has a receiving apparatus for receiving and discharging the object, and a movable arm for moving the object from one location to another. The location-determining system has at least one location-detecting device to detect a relative location of the receiving apparatus in relation to the location-detecting device. The location-detecting device is configured to detect a relative location of the object in relation to the location-detecting device and also a relative location of the production apparatus in relation to the location-detecting device.

This gantry type conveying device is provided with: a beam which is horizontally installed; a runner traveling along the beam; an elevator supported to be movable in the vertical direction with respect to the runner; and a loading part which is supported by the lower portion of the elevator and on which a workpiece is loaded. This processing line has the gantry type conveying device and a machine tool. The machine tool is provided with: a base; and a workpiece supporting device provided movable with respect to the base in a forward and backward direction perpendicular to the extending direction of the beam when viewed in a plane.

This gantry type conveying device is provided with: a beam which is horizontally installed; a runner traveling along the beam; an elevator supported to be movable in the vertical direction with respect to the runner; and a loading part which is supported by the lower portion of the elevator and on which a workpiece is loaded. This processing line has the gantry type conveying device and a machine tool. The machine tool is provided with: a base; and a workpiece supporting device provided movable with respect to the base in a forward and backward direction perpendicular to the extending direction of the beam when viewed in a plane.

The invention relates to a robot cell (1) provided for use on machine tools and/or assembly machines. The robot cell (1) includes a handling device, e.g. an industrial robot (2). By means of the robot cell (1), a workpiece (4) to be processed on the machine tool or the assembly machine can be removed from an incoming transport container, pre-processed, orientated, inserted into the machine tool or assembly machine, removed from the machine tool or the assembly machine, measured and placed or stacked in an outgoing transport container. The robot cell (1) can be used on different machine tools or assembly machines. In order to facilitate operation of a robot cell (1) of this kind, the robot cell (1) can be used on the machine tool or the assembly machine without being linked or connected to the machine tool or the assembly machine, the robot cell (1) has an optics device (5), by means of which, in conjunction with reference markings on the machine tool or assembly machine, the robot cell (1) can be positioned in its operating position on the machine tool or the assembly machine, wherein by means of a control apparatus (6) and the handling device connected thereto or the industrial robot (2) connected thereto of the robot cell (1), operating elements on the machine tool or assembly machine can be contacted, operated and controlled.

The invention relates to a robot cell (1) provided for use on machine tools and/or assembly machines. The robot cell (1) includes a handling device, e.g. an industrial robot (2). By means of the robot cell (1), a workpiece (4) to be processed on the machine tool or the assembly machine can be removed from an incoming transport container, pre-processed, orientated, inserted into the machine tool or assembly machine, removed from the machine tool or the assembly machine, measured and placed or stacked in an outgoing transport container. The robot cell (1) can be used on different machine tools or assembly machines. In order to facilitate operation of a robot cell (1) of this kind, the robot cell (1) can be used on the machine tool or the assembly machine without being linked or connected to the machine tool or the assembly machine, the robot cell (1) has an optics device (5), by means of which, in conjunction with reference markings on the machine tool or assembly machine, the robot cell (1) can be positioned in its operating position on the machine tool or the assembly machine, wherein by means of a control apparatus (6) and the handling device connected thereto or the industrial robot (2) connected thereto of the robot cell (1), operating elements on the machine tool or assembly machine can be contacted, operated and controlled.

Embodiments described herein relate to systems and methods for manipulating the position and/or orientation of an object while it is held in a robotic gripper. In one such embodiment, one or more physically possible and stable displacements for moving an object relative to a gripper using one or more frictional pushes may be determined and applied to the object to move the object from a first position and orientation to a second position and orientation while the object is held by the gripper. In certain embodiments, the physically possible and stable displacements may be determined using an appropriate motion cone approximation.

Embodiments described herein relate to systems and methods for manipulating the position and/or orientation of an object while it is held in a robotic gripper. In one such embodiment, one or more physically possible and stable displacements for moving an object relative to a gripper using one or more frictional pushes may be determined and applied to the object to move the object from a first position and orientation to a second position and orientation while the object is held by the gripper. In certain embodiments, the physically possible and stable displacements may be determined using an appropriate motion cone approximation.

A method for processing profile beam parts includes providing a machining station, an in-feed transport system, and an out-feed transport system. The method further includes transporting and in-feeding a first profile beam part together with a second profile beam part to the machining station, machining at least the first profile beam part in the machining station, out-feeding the first profile beam part with the out-feed transport system from the machining station to an intermediate position which is at a variable distance X from a discharge position between the machining station and the discharge position, and in-feeding the second profile beam part in the machining station with the in-feed transport system over a distance Y and simultaneously out-feeding the first profile beam part over the distance X from the intermediate position to the discharge position. The capacity of the system is improved with the method.