RU2612112C2 - Abrasive wire - Google Patents

Abstract

FIELD: instrument making.

SUBSTANCE: invention relates to abrasive tools, intended for cutting into plates stone-like materials of high hardness (more than 8 on Mohs scale), for example, sapphire, used in production of electronic devices. Abrasive wire comprises long metal bearing base with cutting diamond layer in form of grains of working diamonds, distributed in peripheral layer attached to base. Metal bearing base is made undulating with size of working diamonds in rage of one grain fraction, that is, in diamonds of one fraction are used in making diamond wire.

EFFECT: higher efficiency of cutting process and low cost thereof.

1 cl, 3 dwg

Description

The invention relates to an abrasive tool intended for cutting stone-like materials, mainly of increased hardness (more than 8 on the Mohs scale) into plates, for example, sapphires widely used in the manufacture of electronic devices.

Known round in cross section wave-like structured wire, used mainly for cutting material with a hardness below 8 on the Mohs scale [1].

The cutting process using this wire is as follows.

An abrasive slurry consisting of a liquid and abrasive particles (including diamond) of high hardness 5-30 μm in size is fed to a wire moving in the longitudinal direction.

However, this tool is not effective for cutting materials with a hardness higher than 8, since when cutting a material of such hardness it is required to apply high pressure to the wire and at the same time the abrasive particles are destroyed, and not the cut workpiece.

Also known is an abrasive wire containing a long metal bearing base and a cutting diamond layer, made in the form of a peripheral layer attached to the base and distributed in it grains of working diamonds [2].

It is a round in cross section wire of high-strength steel with a hardness of 3400-4100 N / mm ^{2 and a} diameter of 100-300 microns with a diamond layer applied in a spiral. As a rule, the cutting diamond layer is made with a thickness of 10-60 microns from natural or synthetic diamonds with a size of 20-120 microns on a galvanic (nickel or nickel-cobalt) bond.

The principle of cutting using such a wire is that the wire moving in the longitudinal direction at a speed of 1-20 m / s, to which the coolant is supplied, scratches the cut material with diamonds in the zone of their contact.

The advantage of this tool is the ability to cut the material while cutting up to 4000 cuts by creating from the same wire the required number of turns around the guide bushings.

However, the use of this tool for materials with a hardness of more than 8 on the Mohs scale is ineffective, because when cutting, a large number of diamonds are in operation and for effective work it is necessary to create a large pressure, which is achieved by increasing the wire tension. To prevent its breakage in this case, its diameter should be increased, which leads to an increase in the width of the cut, and, consequently, to a decrease in the number of finished products.

In addition, this tool has a high cost due to the complexity of manufacturing a spiral layer of diamond coating, which excludes its wide industrial use.

The result, to which this technical solution is directed, is to increase the efficiency and reduce the cost of the process of cutting stone-like materials of increased hardness (more than 8 on the Mohs scale).

This result is achieved due to the fact that for an abrasive wire containing a long metal bearing base and a cutting diamond layer made in the form of a peripheral layer attached to the base and working diamond grains distributed therein, the metal bearing base is made wavy.

The size of the working diamonds is made in the range of the size of one grain fraction, and the amplitude A of the wave of the wave-like wire is larger than the nominal size of the fraction.

An example of the implementation of the inventive device is illustrated by drawings, where in FIG. 1 shows an abrasive wire, in FIG. 2 - section BB, in FIG. 3 - place B.

The abrasive wire 1 contains a long (extended) metal supporting base 2 and a cutting diamond layer in the form of grains of working diamonds 3 distributed in a peripheral layer attached to the base 4. The metal supporting base is made wavy.

The size of the working diamonds is made in the size range of one fraction of the grain, that is, in the manufacture of the diamond wire, diamonds of one fraction are used. The size of the fraction for the manufacture of diamond wire is selected depending on the material being cut and the cutting requirements.

The metal supporting base is made of a circular cross-section of high-strength steel with a hardness of 3400-4100 N / mm ² . As a rule, the peripheral layer is performed on a galvanic (nickel or nickel-cobalt) bond, as well as on an organic (polymer) bond.

The process of cutting material using this diamond wire is as follows.

The diamond wire is moved in the longitudinal direction at a speed of 1-30 m / s and coolant is supplied to it. Working diamonds 6, placed on its surface in the bend zone 7, scratch the cut workpiece 5 in the area of their contact. Slurry from the material to be cut is accumulated in the cavity between the cut workpiece and the bends of the wire and is discharged when the wire is moved.

When the working diamonds 6 and the peripheral layer 4 of the diamond wire are worn, the wire descends slightly stretches. In this case, gradually, as diamonds 6 wear out in the bend zone 7, neighboring working diamonds 8 are included in the work, which creates the effect of “self-sharpening" of the wire and makes it possible to use the vast majority of working diamonds during operation. This is achieved due to the fact that the size of the working diamonds is made in the range of the size of one grain fraction, and the amplitude A of the wave of the wave-like wire is larger than the nominal size of the grain fraction.

High cutting speed is provided due to the fact that due to the wave-like profile of the diamond wire, it becomes possible to create large specific pressures on the cut workpiece without increasing the wire tension. This increases the depth of scratches and, accordingly, the cutting speed due to volumetric destruction of the material, that is, the cutting process becomes less energy-intensive.

The ability to create large specific pressures on the workpiece being cut without increasing the wire tension also reduces the loss of the material being cut, and, therefore, increases the yield of the wafers, since it is possible to use a smaller wire diameter, and the cut thickness depends on the wire diameter and the size of the cutting diamond layer.

Improving the cutting efficiency is ensured by the effective removal of sludge from the material being cut in the cavity between the cut workpiece and the bends of the wire, which makes it possible to increase the speed of movement of the wire, as well as simultaneous cutting up to 4000 cuts by creating from the same wire the required number of turns around the guide bushings, including blanks of any hardness with dimensions up to 1 m.

The decrease in wire consumption occurs due to the fact that a large amount of coolant is supplied to the cutting zone, which excludes overheating of the cutting diamond layer and, accordingly, its destruction, as well as from the effect of "self-sharpening" of the wire.

Thus, this technical solution will allow:

- increase the efficiency of the process of cutting stone-like materials of increased hardness (more than 8 on the Mohs scale);

- reduce the cost of the cutting process;

- increase the yield of products when cutting material into plates.

Information sources

1. Patent WO 2013/135895 A1, IPC B23D 61/18, 09/19/2013.

2. RF patent for utility model No. 91924, IPC B26D1 / 547, 2009.

Claims (1)

An abrasive wire containing a long metal bearing base with a cutting diamond layer made in the form of a peripheral layer attached to the base with working diamonds grains distributed in it, characterized in that working diamonds with a grain size selected from the size range of one grain fraction are used, and long the supporting base is made wavy with a wave amplitude exceeding the nominal grain size from the mentioned size range.

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