A fixture holds a specimen during electrical discharge machining of the specimen and prevents tensile test samples cut from the specimen from bending or curving during the electrical discharge machining. The fixture has first engagement surfaces that clamp to one end of the specimen and has second engagement surfaces that clamp to the opposite end of the specimen during electrical discharge machining of the specimen. The fixture clamping to opposite ends of the specimen prevents the tensile test samples cut from the specimen from bending during electrical discharge machining of the specimen.

A spark erosion machine includes a frame with a space for spark erosion of a workpiece, a wire for cutting by spark erosion, and a wire guide head for guiding the wire across the workpiece, so as to detach an offcut from it; an offcut support mounted movably relative to the guide head, the support being configured to move at least between a retention position under the spark erosion space, where it can collect the offcut, and a retracted position; and an offcut extractor.

To provide a wire electric discharge machine which suppresses the machining speed and machining precision from declining, as well as enabling flexible handling in relation to the shapes of various workpieces, and the generation of sludge and gases which varies accompanying the progression of wire electric discharge machining. A wire electric discharge machine that performs electric discharge machining on a workpiece by causing a wire electrode and the workpiece to relatively move, includes an articulated robot, and a suction mechanism provided to a wrist leading end of the articulated robot, and suctions machining waste and gas generated by wire electric discharge machining.

An electrochemical machining device includes a plurality of electrodes, a guiding member and a plate member. The electrodes are disposed around a workpiece. The guiding member is configured to limit and guide each of the electrodes to move. The plate member is configured to exert a force to each of the electrodes. The driving member is configured to rotate the workpiece. The plate member is connected to each of the electrodes. A force-exerting direction of the force from the plate member to each of the electrodes is parallel to a central axis of each of the electrodes or deflects off the central axis. Each of the electrodes is passed through the guiding member and configured to perform a machining on the workpiece which is rotated by the driving member, and each of the electrodes has an electrochemical machining direction which is perpendicular, oblique or parallel to the workpiece.

A wire electrical discharge machining system includes a securing device that is placed at a cut position where a workpiece on a holding unit has been cut by wire electrical discharge machining when the wire electrical discharge machining has been performed on the workpiece held on the holding unit to reach a predetermined position before the completion of machining and that individually attracts a cut-out portion from the workpiece and a remaining portion on the workpiece at the cut position where the workpiece has been cut, thereby securing the cut-out portion to the remaining portion, and a robot is configured to individually attract both the cut-out portion and the remaining portion with the securing device.

A fixture for drilling a hole in a superalloy turbine blade includes a mount to selectively hold a root of the superalloy turbine blade with the superalloy turbine blade extending from the mount. The fixture may also include an actuator to apply a force to elastically deform at least a portion of the superalloy turbine blade when held by the mount from a relaxed, initial position to an elastically deformed position, the at least a portion of the superalloy turbine blade having a curvature in the elastically deformed position not present in the relaxed, initial position. The fixture may also include a drill guide configured to guide a drilling element into the superalloy turbine blade in the elastically deformed position.

This machine tool system is provided with a tool holder adaptor that has a flange having formed therein: a hole part that contains a tool holder; and an engagement part that engages with a hand of a self-propelled robot, wherein when transporting the tool holder to a machine tool from a tool storage that contains a plurality of tool holder adaptors, the self-propelled robot grasps the tool holder adaptor to transport the tool.

A device for the electrochemical processing of a metal workpiece, including a plurality of electrodes that by way of respective linear drive units are movable in a linear manner relative to the workpiece from an initial position to a terminal position, the electrodes having a reproduction face that is directed toward the workpiece, wherein at least three electrodes are provided, the electrodes being disposed so as to be offset around the circumference of the workpiece and by way of the reproduction faces of the electrodes during the entire readjustment movement from the initial position to the terminal position engaging across one another in portions so as to be in contact, and by way of the reproduction faces of the electrodes delimiting a fluid duct that in a closed manner encircles the circumference of the workpiece.

A linear shaft motor (1) has a slider (10) and a tubular magnetic shaft (30). The slider (10) includes an oblong cuboid shaped motor housing (101) having a rectangular cross-section with a longitudinal central bore (180). The motor housing (101) includes at least two longitudinal cooling holes (161, 162, 163, 164, 165, 166, 167, 168) which are part of an integrated fluid cooling circuit. The at least two longitudinal cooling holes (161-168) are distributed symmetrically at a left and at a right side of the central bore (180), whereas the central axis (15) of any of the longitudinal cooling holes (161-168) lays below the topmost portion (20) of the central bore (180) and above the lowermost portion (25) of the central bore (180).

The present invention relates to an electrochemical machining method for manufacturing a cone. One or more conductive column and an electrode are driven to perform relative convolute motion. Then the conductive column is driven to perform electrochemical machining on the electrode for forming one or more hole in the electrode. Afterwards, the periphery of the hole in the electrode to perform electrochemical machining on the conductive column for forming a cone at one end of the conductive column.