Systems for cooling and directing a cutting wire. The systems include a water cooling box which permits cooling a cutting cable without any loss of cleaning/cooling fluid or contamination of the driving elements of the system. The systems also include a plurality of cutting wire directing elements which permit multiple cutting directions without derailing of the wire out of the guiding pulleys.

Slices are cut from workpieces during a sequence of cut-off operations by a wire saw, having a wire array. The wire array is tensioned in a plane between two wire guide rollers supported between fixed and floating bearings. During each cut-off operation, a workpiece is fed through the wire array perpendicular to a workpiece axis and the wire array plane. The workpiece is fed with simultaneous axial movement of the floating bearings by adjusting a temperature of the fixed bearings in correlation with a first correction profile, which specifies a travel of the floating bearings in dependence on the depth of cut. In dependence on the depth of cut, operating parameters are set, such as the feed rate, an amount of working fluid fed to the wire array per unit time, a temperature of the working fluid, a wire speed, a wire consumption per cut-off operation, or a wire tension.

A slurry sprayer for supplying a slurry to a wire saw during ingot slicing is disclosed. The slurry sprayer includes a main body and a cover plate that is detachable from the main body for cleaning the slurry sprayer. In some embodiments, the slurry sprayer includes an adjustable support that allows the incline angle of the sprayer to be adjusted and allows the vertical and horizontal position of the slurry sprayer to be adjusted. In some embodiments, the slurry sprayer includes two feed openings to allow the slurry pressure to be more equalized across the slurry sprayer.

A method for manufacturing a wire saw apparatus including a wire supply reel; a long roller; wire guides; a wire winding reel; and a tension arm controlled to move within a control angle of ±A (°) set in advance and configured to apply tension to the wire, the method including the steps of: measuring a surface roughness Rmax of the long roller; measuring an angle a (°) of the tension arm at which the tension arm swings outside a range of the control angle set in advance while the wire is extending from the wire supply reel; calculating R1×2×A÷(|a|+A)=R2, where R1 (μm) represents the measured surface roughness Rmax of the long roller; and adjusting the surface roughness Rmax of the long roller to the calculated numerical value R2 or less. The method for manufacturing a wire saw apparatus can prevent the tension arm from greatly swinging outside the control range.

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 a plurality of grooved rollers, the wire being fed from one of a pair of wire reels and taken up by another, the method including feeding a workpiece to the row for slicing while allowing the wire to reciprocate and travel in an axial direction, thereby slicing the workpiece at a plurality of positions aligned in an axial direction of the workpiece simultaneously. Prior to slicing, an abrasive-grain abrading step wherein the wire is allowed to travel without slicing the workpiece, allowing the wire to rub against itself within the reels, and dressing its surface for 30 minutes or more. The method can dress a fixed abrasive grain wire at low cost and suppress thickness unevenness of wafers.

A silicon carbide wafer manufacturing method includes: a bending measuring step of measuring a first edge having the greatest degree of a bending at one surface of a silicon carbide ingot having one surface; a cutting start step of starting a cutting at a second edge having a distance of r×a along an edge of the one surface from the first edge in a direction parallel to or with a predetermined off angle with respect to the one surface through the wire saw, a cutting speed being decreased to a first cutting speed in the cutting start step; a cutting proceeding step in which the first cutting speed is substantially constant within a variation of about ±5% of the first cutting speed; and a finish step in which the cutting speed is increased from the first cutting speed and the cutting of the silicon carbide ingot is completed.

The present subject matter discloses a longitudinal silicon ingot slicing apparatus for lateral slicing of cylindrical ingot to maximize resulting chips yield as compared to the conventional transverse slicing of ingot. The resulting rectangular wafers made from lateral slicing of ingot maximizes yield as by the lateral slicing of ingot, overall chips per wafer ratio gets increased as compared to transversal cutting while the said apparatus and method decreases waste due to conflict between chip and wafer geometry. The novel apparatus of longitudinal slicing of cylindrical ingot is comprising of a wire wounded around a wire reels and a plurality of grooved rollers to form a wire raw to slice the cylindrical silicon ingot. A motors are connected with the wire reels and with at least one grooved roller to slide the wire row back and forth to cut the cylindrical ingot. A work feed table is also configured along with the JIG fixture that holds the cylindrical ingot as well as align the wire raw during slicing.

The invention discloses a method for cutting a substrate wafer from an indium phosphide crystal, and belongs to the field of semiconductor substrate preparation, comprises the following steps of: 1) orientating, cutting the head and the tail of a crystal bar, adjusting the orientation and trying to cut the crystal bar until a wafer with a required crystal orientation cut, wherein the cutting end face is an orientation end face; 2) multi-wire cutting, on a multi-wire cutting apparatus, dividing a crystal bar parallel to an orientation end face into wafers; 3) cleaning, cleaning the wafer until no residue and no dirt existing on the surface; 4) circle cutting, performing circle cutting on the wafer to cut the desired crystal orientation area. According to the technical scheme, for the indium phosphide crystal bar which is difficult to control in diameter and easy to twinning/ poly in the growth process, a barreling process which may grind and remove a large amount of InP materials is abandoned, the crystal bar is multi-wire cut into a wafer, and then the substrate wafer which is available in the crystal direction close to the standard size is cut from the wafer to the maximum extent, so that the wafer output can be greatly increased, and the material loss and the waste can be reduced.

Systems and methods for controlling the surface profiles of wafers sliced in a wire saw machine. The systems and methods are generally operable to alter the nanotopology of wafers sliced from an ingot by controlling the shape of the wafers. The shape of the wafers is altered for example by changing the temperature of a temperature-controlling fluid circulated in fluid communication with side walls attached to a fixed bearing sidewall of the wire saw.

In order to respond flexibly to various processing modes, such as forming curved surface shapes, when cutting a workpiece using a wire saw, this wire saw device (1) is provided with: a single robot arm (2) that is capable of moving freely by means of multi-axis control; a wire saw unit (3) that is detachably connected to the robot arm (2) via a tool changer (7); a wire (8) that spans a plurality of pulleys supported within the wire saw unit (3); and a workpiece cutting zone (20) that is established between the pulleys. The workpiece is cut to a prescribed shape by moving the robot arm (2) in a preset direction while running the wire (8) of the wire saw unit (3) and pressing the wire (8) against the supported workpiece.