A loading and unloading device for a machine, a machine for machining panel-like workpieces, and a workpiece support for such a machine and a method for loading and unloading such a machine, having a loading and unloading module, wherein the loading and unloading module has a vertically upwardly oriented raising device for lifting a cut-free workpiece part and a vertically downwardly oriented gripping device (38) for holding an unmachined, panel-like workpiece.

Provided is a cutting tool that includes a cutting head, a frame, a working table, a guiding rail assembly, and a fence. The cutting head is configured to perform a cutting function. The frame is configured to support the cutting head. The working table is configured to place an object to be cut. The guiding rail assembly is configured to enable the working table to slide along a first straight line relative to the frame. The fence is mounted to the working table, includes at least one fence surface extending in a direction perpendicular to the first straight line. The cutting tool enables a workpiece to be cut to be stably placed on the working table during a cutting operation.

An inverter manufacturing cell includes a table including a base, a frame configured to receive a work piece, and at least one pivotable lift arm attached to the base and to the frame. The pivotable lift arm is configured to pivot relative to the base about at least one axis such that the frame and work piece rotate from a first, generally horizontal position to a second, generally vertical position. After rotating to the second, vertical position, the frame is configured to slide such that the frame and work piece further rotate to a third, generally horizontal position wherein the frame and work piece are inverted relative to the first, generally horizontal position.

A clamping device and a machining method. The clamping device comprises: a base; a clamping head comprising a blind rivet and a locking member, the blind rivet comprising a middle column segment and enlarged portions at two ends, and the locking member being connected to an upper end of the blind rivet and defining a clamping opening; a lower cavity connected to the base; an upper cavity comprising an annular peripheral wall and a top wall having a central hole, the top wall being clamped between the two enlarged portions, the middle column segment of the blind rivet movably passing through the central hole, and the upper cavity being connected to the lower cavity in a fit manner; an elastic member located in the peripheral wall and supported between the enlarged portion at a lower portion of the blind rivet and the top wall; and a support cylinder movably fitted in the lower cavity, the support cylinder being supported below the elastic member.

A motorized chuck stage controlling method adapted to a wafer probing device is provided. The wafer probing device includes a control rod and a motorized chuck stage. The control rod can be moved between an upper limit position and a lower limit position, and the motorized chuck stage is moved along a Z-axis direction in response to a movement of the control rod. One purpose of the motorized chuck stage controlling method is to allow the operator to define the highest position to which the motorized chuck stage can be moved in response to the movement of the control rod, thereby preventing the probe and the wafer from colliding with each other.

Apparatus and methods for loading parts in a press wherein a conveyor transports the parts in a forward movement direction towards the press. An optical measuring device determines the real position of the parts on the conveyor. At least two transfer devices are configured to grab the parts off the conveyor and place them directly on a first surface of the press. A control unit is configured to receive the real position of the parts determined by the optical measuring device, and to compare the real position with a theoretical loading position of the parts on the first surface of the press. The control unit determines a deviation between the real and theoretical loading positions and uses the calculated deviation to command the transfer devices to correct the deviation and to place the parts on the first surface of the press in the theoretical position.

A locating pin for positioning one or more workpieces on a mounting member is provided. The locating pin includes at least one cam being radially moveable between an extended position and a retracted position. The at least one cam engages the workpiece while in the extended position to hold the workpiece in place. The at least one cam is spaced from the workpiece while in the retracted position to allow the workpiece to be positioned on, or removed from the locating pin.

Disclosed is a method for loading a sheet placement device of a flat bed machine tool with a material sheet, wherein the material sheet is supplied to the machining operation carried out by the flat bed machine tool, starting from a target position assigned to the machining operation in a machine coordinate system, and the flat bed machine tool comprises a camera system having at least one camera. The camera system is designed to produce captured images of the sheet placement device, which are calibrated three-dimensionally in relation to the machine coordinate system of the flat bed machine tool. The method comprises the steps: producing a captured image of the material sheet in the region of the sheet placement device; evaluating the captured image to determine an actual sheet position in the machine coordinate system; measuring a deviation of the determined actual sheet position from the target position; and using the measured deviation to align and position the material sheet.

A cutting machine is provided, including: a cutting table having a first end and a second end aligned along an X-axis; a cutting tool gantry configured to cut parts from plate supported on the cutting table, the cutting tool gantry spanning the cutting table in a Y-axis perpendicular to the X-axis and being configured to travel along the X-axis between the first end and the second end; and a part transfer apparatus configured to remove cut parts from the cutting table, the part transfer apparatus being configured to travel along the X-axis between the first end and the second end, wherein the part transfer apparatus is able to pass underneath the cutting tool gantry while travelling along the X-axis. Methods of manufacturing and storing parts are also provided, along with a method of identifying when a part is in contact with a finishing apparatus.

A broaching unit for rules of die cutters which comprises a supporting structure, for example a frame, a guide of a die cutter rule, and a tool-holding arm equipped with at least one broaching tool is described. The guide defines a sliding surface on which the rule is fed intermittently. The tool-holding arm is mounted on the supporting structure and is susceptible to reciprocating movements with respect to it and with respect to the guide, preferably forward and backwards movements along a transversal direction of the rule, just to intercept the die cutter rule with the broaching tool when the rule is stopped. Advantageously, the tool-holding arm is equipped with at least two broaching tools, for example four tools, and can be oriented with respect to the guide, for example can rotate on itself, to selectively activate one of the broaching tools, i.e. to bring one of the tools into contact with the rule.