An electric discharge machine is provided. The electric discharge machine includes: an axis drive part moving a tool electrode in at least one axial direction; and a sensor unit detecting a linear movement position of the axis drive part in the axial direction. The sensor unit includes a measurement scale having a linear shape, a position detector scanning the measurement scale and obtaining position information, and a pair of adjustment blocks fixed to both ends of the measurement scale or the position detector and erected perpendicular to an extension direction of the measurement scale. The adjustment blocks are fixed to the axis drive part and are curved in the axial direction due to a temperature change.

An electric discharge machining method for machining a core pin for a resin die using an electric discharge machine including a secondary electrode for molding of a round-bar shaped machining electrode. The electric discharge machining method includes a step of executing generating electric discharge machining for cutting out a schematic shape of the core pin from a work with the machining electrode, a step of transferring a shape element of the secondary electrode to the machining electrode and molding the machining electrode for diesinking electric discharge machining, and a step of applying the diesinking electric discharge machining to the work cut out in the schematic shape of the core pin using the machining electrode molded for the diesinking electric discharge machining.

When measuring the dimensions of a tool having a cutting portion at an edge of a planar portion, first a plurality of points are measured on the planar portion using a measuring probe, then a planar formula for a measurement plane containing the planar portion is determined from these measured values. Next, the measuring probe is moved along the measurement plane expressed by the planar formula from the exterior of the cutting portion toward the cutting portion until the measuring probe contacts the cutting portion. The position of the cutting portion is determined based on the position of the measuring probe when the measuring probe comes into contact with the cutting portion.

An electric discharge machining method for machining a core pin for a resin die using an electric discharge machine including a secondary electrode for molding of a round-bar shaped machining electrode. The electric discharge machining method includes a step of executing generating electric discharge machining for cutting out a schematic shape of the core pin from a work with the machining electrode, a step of transferring a shape element of the secondary electrode to the machining electrode and molding the machining electrode for diesinking electric discharge machining, and a step of applying the diesinking electric discharge machining to the work cut out in the schematic shape of the core pin using the machining electrode molded for the diesinking electric discharge machining.

A wire electric discharge machine has a tank containing a working fluid, a table in the tank for mounting a workpiece, upper and lower guides supporting a wire electrode, a measurement device detachable from or movable relative to an upper guide part having the upper guide, and including a sensor for measuring the workpiece after machining, a plate thickness acquisition unit for acquiring a plate thickness of the workpiece, a level detection unit for detecting a level of the working fluid in the tank, and a level adjustment unit for adjusting the level of the working fluid when measuring the workpiece on the basis of the relative position of the upper guide and the measurement device body, a position of the upper guide, and the plate thickness, to a level not lower than a height of an upper surface of the workpiece and not higher than the measurement device body.

A machining program creation apparatus for a wire electrical discharge machine for creating a machining program for cutting a predetermined machining shape in an object to be machined includes a first unit defining the machining shape; a second unit defining a shape of the object to be machined; a third unit designating a reference position to be used when the machining shape is machined; a fourth unit for generating a first machining path for cutting the machining shape based on the machining shape, the shape of the object to be machined, and the machining reference position; a fifth unit for generating the shape of the object to be machined as a second machining path based on the shape of the object to be machined and the machining reference position; and a sixth unit for drawing the first and the second machining paths on the same screen.

A contact detection unit, after executing a first detection operation of contact between the wire electrode and the workpiece at a first relative movement speed and a first pulse cycle, executes a second detection operation of contact between the wire electrode and the workpiece, at a second relative movement speed which is slower than the first relative movement speed, and at a second pulse cycle which is longer than the first pulse cycle, and a movement speed control unit, after execution of the first detection operation, and prior to execution of the second detection operation, causes the wire electrode and the workpiece to relatively move in a distancing direction.

A gap detection apparatus for determining in real time the gap required for electrochemical machining gap includes a tooling electrode, a plurality of tool adjusting electrodes, a feedback circuit, a processing feed mechanism for controlling the tooling electrode, a three-dimensional driving mechanism, and an automatic control and measurement system. The tooling electrode includes a plurality of through-holes for receiving tool adjusting electrodes. The three-dimensional driving mechanism is mounted upon the processing feed mechanism, which includes a Z-coordinate feeding portion having a thimble for the feeding of the tool adjusting electrodes. The automatic control and measurement system controls the feed of the processing feed mechanism and the three-dimensional driving mechanism, and establishes the required gap for electrochemical machining.

A method of machining a feature in a component using a machine having a support rotatable about a rotation axis and having a cutting tool movable relative to the component, the component being mounted on the support for rotation about a central axis of the component, the method includes: determining coordinates of at least three points on a reference surface of the component, the at least three points being circumferentially offset from one another relative to the central axis; determining an angular correction to apply to the cutting tool based on the coordinates of the at least three points; and machining the feature in the component using the cutting tool angled with the angular correction.

A wire electrical discharge machine for detecting an end face of an object, configured so that when a contact detection movement is started and if contact between the wire electrode and the workpiece is detected, positions in which the contact between the wire electrode and the workpiece is detected are stored as contact detection positions and that when a non-contact detection movement is then started and if non-contact between the wire electrode and the workpiece is detected, positions in which the non-contact between the wire electrode and the workpiece is detected are stored as non-contact detection positions. When it is determined whether or not a set number of times of execution is reached and if the set number of times of execution is reached, a reference position is obtained by adding the radius of the wire electrode and a clearance of the wire guide to an end face determination position.