A processing method for a workpiece includes a cutting step of cutting the workpiece along streets by a cutting blade having a V-shaped tip end, to form V grooves of which shallower parts are wider than deeper parts, and a cleaning step of cleaning a back surface of the workpiece with cleaning water, after the cutting step is carried out.

A cutting apparatus includes a cutting dust collection box that collects cutting dust and a cutting dust guide plate that is disposed on the downstream side in a processing feed direction relative to a chuck table and receives cutting water and the cutting dust that flow to the downstream side after cutting to guide the cutting water and the cutting dust to the cutting dust collection box. A cutting dust breaking unit that breaks the cutting dust into small pieces is disposed at a position onto which the cutting dust that flows from a plate-shaped cover drops over the cutting dust guide plate.

A method for slicing an ingot, including: forming a wire row by a wire spirally wound between a plurality of wire guides and configured to travel in an axial direction; and pressing an ingot against the wire row while supplying a contact portion between the ingot and the wire with a slurry from a nozzle, thereby slicing the ingot into wafers. The slurry is supplied such that slurries whose temperatures are separately controlled by two or more lines of heat exchangers are respectively supplied from two or more sections of the nozzle which are orthogonal to a travelling direction of the wire row. Consequently, a wire saw and a method for slicing an ingot are provided which enable separate control of wafer shapes depending on ingot-slicing positions.

A cutting blade mounting mechanism for mounting a cutting blade to a tip portion of a spindle includes: a blade mount mounted to the tip portion of the spindle; and an air supply unit supplying air to the blade mount. The blade mount includes: a columnar boss section inserted into a through-hole provided in an annular base of the cutting blade; a flange section projecting in a radial direction from a side of a base end of the boss section and having a support surface supporting the cutting blade; and an ejector type blade suction section having a first air passage connecting a supply port supplied with air from the air supply unit and a discharge port discharging air, and a second air passage connecting a suction port opening to a side of the support surface of the flange section and the first air passage.

A cutting apparatus includes a blade changing unit demounting an old cutting blade from a blade mount and mounting a new cutting blade to the blade mount. The blade changing unit includes a blade holder for holding a support base of each cutting blade and a moving portion for moving the blade holder in the axial direction of a boss portion of the blade mount in the condition where each cutting blade is held by the blade holder, thereby mounting the new cutting blade to the boss portion or demounting the old cutting blade from the boss portion. The cutting apparatus further includes a control unit controlling the blade changing unit. The control unit measures a signal indicating a force applied to the moving portion in mounting or demounting, and determines the condition of the blade changing unit and blade mount according to the signal measured by the measuring portion.

A blade mounting and dismounting jig is provided for mounting a blade on and dismounting a blade from a flange of a cutting apparatus which includes a boss, a blade mount for mounting the blade fitted thereover, the flange having an annular end face for supporting the blade thereon and being fixed to a distal end of a spindle, and a holder that cooperates with the flange in gripping and securing the blade in position. The blade mounting and dismounting jig includes a cylindrical jig body, a grip coupled to the jig body and having a diameter larger than the jig body, a plurality of first air ejection ports defined in a distal end portion of the jig body, a plurality of second air ejection ports defined in the jig body at a juncture between the jig body and the grip.

A cutting apparatus includes a cutting unit that cuts a workpiece included in a frame unit, an ultraviolet ray irradiation unit that irradiates the frame unit with ultraviolet rays, and a control unit. The control unit includes a processing mode registration section in which commands to be output to components. The processing mode registration section registers therein a command in a cutting apparatus mode that causes the cutting unit to cut the workpiece and a command in an ultraviolet ray irradiation apparatus mode that causes the ultraviolet ray irradiation unit to irradiate the frame unit with ultraviolet rays.

A method for slicing a workpiece with a wire saw which includes a wire row formed by winding a fixed abrasive grain wire having abrasive grains secured to a surface thereof around multiple grooved rollers, the method including feeding a workpiece to the wire row for slicing while allowing the fixed abrasive grain wire to reciprocatively travel in an axial direction thereof, thereby slicing the workpiece at multiple positions aligned in an axial direction of the workpiece simultaneously. The method includes: supplying a coolant for workpiece slicing onto the wire row when the workpiece is sliced with the fixed abrasive grain wire; and supplying a coolant for workpiece drawing, which differs from and has a higher viscosity than the coolant for workpiece slicing, onto the wire row when the workpiece is drawn out from the wire row after the slicing of the workpiece.

According to the present invention, there is provided an ingot clamp including: a clamp body configured to have a holder mounting groove and a cavity; a fixing part configured to support and fix one side of an ingot holder inserted in the holder mounting groove; a movable fixing part disposed in the cavity and the holder mounting groove and configured to press and fix the other side of the ingot holder; a cover assembly coupled with the clamp body and configured to cover the cavity; and an air supply part coupled with the cover assembly and configured to supply air into the cavity.

A chuck table having a holding portion for holding a workpiece and a frame for supporting the holding portion. The holding portion includes a substrate having a plurality of fine holes arranged like a matrix at given intervals and a plurality of acoustic emission sensors arranged like a matrix on the substrate and spaced from each other so that each fine hole of the substrate is located between any adjacent ones of the acoustic emission sensors. The plurality of fine holes are connected through the frame to a vacuum source, thereby holding the workpiece on the acoustic emission sensors under suction. An elastic wave generated from the workpiece in processing the workpiece is collected at a plurality of positions by the plurality of acoustic emission sensors.