A method cuts semiconductor wafers. The method includes: cutting a semiconductor ingot into a workpiece; and sawing the workpiece into slices using a wire grid having a fixed abrasive grain wire, while moving workpiece towards the wire grid. At a first contact of the workpiece with the wire grid, an initial cutting speed is less than 2 mm/min, coolant flow is less than 0.1 l/h and a wire speed is greater than 20 m/s. The workpiece is then guided through the wire grid until a first cutting depth is reached, and then the coolant flow is increased to at least 2000 l/h. The cutting speed is reduced to less than 70% of the initial cutting speed between the first contact of the workpiece with the wire grid up to a cutting depth of half a diameter of the cylinder, and is then increased.

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.

An abrasive article comprising a substrate having an elongated body and abrasive particles attached to the elongated body, the content of the abrasive particles oscillates along the length of the body between a minimum and maximum value, and the minimum content is greater than 0.

A wire saw apparatus including: a plurality of wire guides; a wire row formed of a wire which is wound around the plurality of wire guides and configured to reciprocatively travel in an axial direction; a nozzle configured to supply a coolant or slurry to the wire; a workpiece-holding portion configured to suspend and hold a workpiece plate having a workpiece bonded thereto with a beam interposed therebetween; a workpiece-feeding mechanism configured to press the workpiece against the wire row; and a mechanism configured to adjust a parallelism of axes of the plurality of wire guides around which the wire row is formed. Thereby, a wire saw apparatus and a method for manufacturing a wafer are provided which enable manufacturing of a wafer having any warp shape by controlling a warp in a wire travelling direction of a sliced workpiece.

Methods, wires, and apparatus for use in cutting (e.g., slicing) hard, brittle materials is provided. The wire can be a super-abrasive wire that includes a wire core and super-abrasive particles bonded to the wire core via a metal bonding layer. This wire, or another type of wire, can be used to slice workpieces useful for producing wafers. The workpieces can be aligned within a holder to produce wafers using the device and methods presently provided. The holder rotates about its central axis, which translates to workpieces moving in orbit around this axis. A single abrasive wire, or multiple turns of wire stretched tightly between wire guides, is then contacted with the rotating holder to slice the workpieces.

A method is disclosed for slicing an ingot by which wire rows are formed by using a wire that is spirally wound between a plurality of wire guides and travels in an axial direction. An ingot is pressed against the wire rows while supplying a working fluid to a contact portion of the ingot and the wire, thereby slicing the ingot into wafers, and a ratio of a wire new line feed amount per unit time in slicing of a slicing start portion of a first ingot to that in slicing of a centration portion of the same at the time of slicing the ingot after replacement of the wire is controlled to be ½ or less of the ratio at the time of slicing second and subsequent ingots after the replacement of the wire.

Semiconductor wafers are produced from a workpiece by means of a wire saw, by feeding the workpiece through an arrangement of wires tensioned between wire guide rollers and divided into wire groups, the wires moving in a running direction producing kerfs as wires engage the workpiece. For each of the wire groups, a placement error of the kerfs of the wire groups determined, and for each of the wire groups compensating movements of the wires of the wire group are induced as a function of the placement error, in a direction perpendicular to the running direction of the wires during feeding of the workpiece through the arrangement of wires, by activating at least one drive element.

A three-dimensional object manufacturing method for manufacturing a three-dimensional object by ejecting a liquid shaping material and then solidifying the ejected shaping material includes: an interior forming process of forming an interior portion of the three-dimensional object by the shaping material; and a periphery forming process of forming a peripheral portion of a periphery of the interior portion by stacking a plurality of layers by the shaping material, where the shaping material for forming the interior portion in the interior forming process has a larger rigidity in a solid state compared to the shaping material for forming the peripheral portion in the periphery forming process, the periphery forming process is a process of forming a groove configuring one part of the peripheral portion, and the interior forming process is a process of forming the interior portion by placing the liquid shaping material in the groove.

A method cuts semiconductor wafers. The method includes: cutting a semiconductor ingot into a workpiece; and sawing the workpiece into slices using a wire grid having a fixed abrasive grain wire, while moving workpiece towards the wire grid. At a first contact of the workpiece with the wire grid, an initial cutting speed is less than 2 mm/min, coolant flow is less than 0.1 l/h and a wire speed is greater than 20 m/s. The workpiece is then guided through the wire grid until a first cutting depth is reached, and then the coolant flow is increased to at least 2000 l/h. The cutting speed is reduced to less than 70% of the initial cutting speed between the first contact of the workpiece with the wire grid up to a cutting depth of half a diameter of the cylinder, and is then increased.

A wire saw apparatus including: a plurality of wire guides; a wire row formed of a wire which is wound around the plurality of wire guides and configured to reciprocatively travel in an axial direction; a nozzle configured to supply a coolant or slurry to the wire; a workpiece-holding portion configured to suspend and hold a workpiece plate having a workpiece bonded thereto with a beam interposed therebetween; a workpiece-feeding mechanism configured to press the workpiece against the wire row; and a mechanism configured to adjust a parallelism of axes of the plurality of wire guides around which the wire row is formed. Thereby, a wire saw apparatus and a method for manufacturing a wafer are provided which enable manufacturing of a wafer having any warp shape by controlling a warp in a wire travelling direction of a sliced workpiece.