JP2005059164A - Electro-deposition band saw - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an electro-deposition band saw having excellent performance, such as small processing damage to a cut material, sufficient surface roughness, suppressing of a crack of the outer periphery, smooth discharge of chips and smooth supply of grinding fluid, and sufficient sharpness. <P>SOLUTION: In the electro-deposition band saw, a super-abrasive grain layer is formed in an operating part by electro-deposition along one side edge of a flat metal endless belt. The super-abrasive grain layer is continuously formed over the whole periphery of the above-mentioned endless belt. The electro-deposition band saws are extended from the continuously formed super-abrasive grain layer at a predetermined interval to both surfaces of the endless belt in the width direction. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to an electrodeposited band saw, more specifically, the cutting edge portion can be a shape combining a continuous type and a segment type, processing damage to the work material is small, good surface roughness is obtained, and The present invention relates to an electrodeposited band saw having excellent performance such as chipping of the outer peripheral portion being suppressed, smooth discharge of chips and supply of a grinding fluid, and good sharpness.

Conventionally, superabrasive band saws are widely used for cutting processing such as silicon ingots or grooving processing and cutting processing of quartz glass, optical glass, ceramics, crystal, ferrite, noble metal, carbon and the like. In particular, cutting applications for hard materials such as carbon have been increasing in recent years.
This superabrasive band saw is a metal band saw in which a chip obtained by sintering superabrasive grains together with powder metal is fixed to one side edge of a high-tensile steel strip (steel belt) joined in an endless state at a predetermined interval. Alternatively, there is an electrodeposition band saw in which superabrasive grains are fixed at predetermined positions by electrodeposition. Traveling is performed by a pulley, and tension is applied to the saw by usually pulling two pulleys. The traveling speed is adjusted according to the nature of the work material, and the length of the saw can be changed to accommodate the size of the work material.
Among the band saws, electrodeposited band saws can be thinned relatively easily and can be cut with large diameters with high accuracy, so they are currently widely used for cutting the ends of silicon ingots. In addition, dedicated slicing machines for large diameter ingots of 25 to 30 cm have been studied and are attracting attention. In addition, thin band saws are mainly used for electrodeposition, and are widely used for curving applications such as flat glass, stained glass, and building materials.
In this electrodeposition band saw, an abrasive layer having a U-shaped cross-section is usually formed along one side edge of a base metal endless belt, and the shape of the cutting edge is as follows. Depending on the type of work material, required cutting conditions, machine structure used, (a) continuous type, (b) segment type, (c) gear cutting type and (d) saw blade type are used. However, among these, the continuous type shown in FIG. 1 (a) and the segment type shown in FIG. 1 (b) are generally used.
However, although the above-mentioned continuous type has little processing damage to the work material and has good surface roughness, it cannot smoothly discharge chips and supply grinding fluid, and realizes a good sharpness. Has the disadvantage of being difficult. On the other hand, the above-mentioned segment type can smoothly discharge chips and supply grinding fluid, and can achieve a good sharpness, but the processing damage to the work material is large, so the surface roughness is poor, and the outer periphery There are drawbacks such as easy chipping.

  The present invention overcomes the disadvantages of the shape of the cutting edge in such an electrodeposited band saw that the continuous type and the segment type have a small processing damage to the work material, and a good surface roughness is obtained, And it was made for the purpose of providing an electrodeposition band saw which has excellent performance such as chipping of the outer peripheral part being suppressed, smooth discharge of chips and supply of grinding fluid, and good sharpness can be obtained. It is.

As a result of intensive studies to develop an electrodeposition band saw having the above-described excellent performance, the present inventor has formed a superabrasive layer by electrodeposition on the working portion along one side edge of the endless belt. The object can be achieved by continuously forming the entire circumference of the endless belt and extending the superabrasive grain layer from both sides of the endless belt in the width direction at predetermined intervals. Based on this finding, the present invention has been completed.
That is, the present invention
(1) In an electrodeposited band saw in which a superabrasive grain layer is formed by electrodeposition along one side edge portion of a flat metal endless belt, the superabrasive grain layer is formed on the entire endless belt. It is formed continuously over the circumference, and is extended from the continuously formed superabrasive grain layer at both sides of the endless belt at a predetermined interval in the width direction. And (2) the electrode layer according to claim 1, wherein the shape of the superabrasive layer extending at a predetermined interval in the width direction on both surfaces of the endless belt is substantially semicircular. Arrival band saw,
Is to provide.

According to the present invention, the processing damage to the work material is small, good surface roughness is obtained, chipping of the outer peripheral portion is suppressed, chip discharge and grinding fluid supply are smooth, and good It is possible to provide an electrodeposition band saw having excellent performance such as sharpness.
Since the electrodeposition band saw of the present invention can make the cutting edge part into a shape combining a continuous superabrasive grain layer and a segment superabrasive grain layer, (1) processing damage to the work material is small, Two kinds of advantages are obtained: good surface roughness is obtained and chipping of the outer peripheral portion is suppressed, and (2) the discharge of swarf and the supply of grinding fluid are smooth and good sharpness is obtained. Both can be achieved.

The material of the flat metal endless belt used in the electrodeposited band saw of the present invention is not particularly limited, and those conventionally used in electrodeposited band saws such as carbon steel, high speed steel, and stainless steel are used. The width of the flat metal endless belt is appropriately selected according to the application, but is generally about 5 to 80 mm, preferably 10 to 60 mm. Furthermore, the thickness is usually in the range of 0.15 to 1.5 mm, preferably 0.2 to 1.0 mm.
In the electrodeposited band saw of the present invention, a superabrasive grain layer is continuously formed over the entire circumference of the endless belt along one side edge of such a flat metal endless belt by electrodeposition on the working part. In addition, the superabrasive grain layer formed continuously has a structure extending on both surfaces of the endless belt at a predetermined interval in the width direction.
FIG. 2A and FIG. 2B are a partial top view and a partial side view, respectively, seen from the blade edge showing an example of the shape of the blade edge part in the electrodeposition band saw of the present invention. In the electrodeposited band saw 10, a superabrasive grain layer 2 b is continuously formed along the one side edge of the flat metal endless belt 1 by electrodeposition on the working portion over the entire circumference of the endless belt 1. At the same time, the superabrasive grain layer 2a is formed from the continuously formed superabrasive grain layer 2b on both sides of the endless belt 1 in the width direction at a predetermined interval (segment type superabrasive grain layer). It has the structure formed.

The segment type superabrasive layer 2a has a substantially semicircular shape. In FIG. 2B, the radius of the semicircular shape is usually 1.0 to 5.0 mm, preferably 1. The interval between the superabrasive grain layers 2a is usually 1 to 50 mm, preferably about 3 to 15 mm. Furthermore, the thickness of the superabrasive grain layer 2a is usually 0.05 to 1.0 mm, preferably about 0.1 to 0.5 mm. On the other hand, the height of the superabrasive grain layer 2b continuously formed over the entire circumference of the endless belt 1 is usually about 0.05 to 0.7 mm, preferably about 0.1 to 0.5 mm.
In the electrodeposited band saw of the present invention, as the superabrasive grains used for forming the superabrasive layer of the blade edge part, diamond abrasive grains and cBN (cubic boron nitride) abrasive grains conventionally used in electrodeposited band saws are used. Can be mentioned. The grain size of the superabrasive grain is not particularly limited and may be appropriately selected depending on the application. In general, however, the grain size is defined by JIS B 4130, and ranges from # 325/400 to # 20/30. Preferably, superabrasive grains in the range of # 270/325 to # 40/50 are used.
The method for producing the electrodeposited band saw of the present invention is not particularly limited as long as it is a method by which an electrodeposited band saw having the above structure can be obtained.

As a method for forming a superabrasive layer by electrodeposition, (1) a method for forming a single superabrasive layer by a general electroplating method, and (2) a multilayer superabrasive by an electroforming method. A method of forming a grain layer can be used.
First, the general electroplating method (1) will be described.
In this method, first, a base metal covered with an insulating masking material is immersed in a plating bath, abrasive grains are placed on the abrasive grain fixing portion, a cathode is connected to the base metal, and an anode is connected to the plating solution. Connect and perform electroplating to temporarily fix the abrasive grains. The base metal is again immersed in the plating bath, the cathode is connected to the base metal, the anode is connected to the plating solution, the abrasive fixed portion is plated, and the abrasive grains are fixed to form a superabrasive layer. . The metal to be plated is not particularly limited as long as it can fix the abrasive grains. For example, nickel, chromium or the like can be used, but nickel can be particularly preferably used. After forming the superabrasive layer in this way, the masking material is peeled off and removed.

Next, the electroforming method (2) will be described.
In this method, as in the case of (1) above, a base metal coated with an insulating masking material is first prepared. Next, in the electroforming bath containing metal ions such as copper, chromium, nickel and the like and dispersed with superabrasive grains, the cathode is connected to the base metal, and the anode is connected to the electroforming solution and energized. Then, superabrasive grains and metal are electrodeposited on the abrasive grain fixing portion of the base metal, and the abrasive grain layer is grown to a predetermined thickness to form a multilayer superabrasive grain layer. Thereafter, the masking material is peeled off and removed.
Nickel is preferred as the plating metal. Note that the thickness of the superabrasive layer is adjusted by the current density and the electrodeposition time.

EXAMPLES Next, although an Example demonstrates this invention further in detail, this invention is not limited at all by these examples.
Example 1
(1) Production of electrodeposited band saw Stainless steel having a thickness of 0.9 mm, a width of 25 mm, and a length of 4340 mm was used as a steel strip, and both ends were welded to produce a base metal made of an endless belt.
A diamond grain having a particle size of 120/140 is fixed to the abrasive layer forming portion as shown in FIGS. 2A and 2B by a nickel electrodeposition method to form an abrasive layer having a thickness of 0.2 mm. It was.
When the electrodeposition band saw manufactured in this example was used to cut hard carbon / optical glass, the sharpness was improved as compared with the continuous type, and the occurrence of work chipping was suppressed as compared with the segment type.

It is a partial front view which shows the example of the shape of the blade edge | tip part in a general electrodeposition band saw, and shows a continuous type. It is a partial front view which shows the example of the shape of the blade edge | tip part in a general electrodeposition band saw, and shows a segment type | mold. It is the partial top view seen from the blade edge which shows an example of the shape of the blade edge | tip part in the electrodeposition band saw of this invention. It is a partial side view which shows an example of the shape of the blade edge | tip part in the electrodeposition band saw of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Flat metal endless belt 2a Segment type superabrasive grain layer extended in the width direction 2b Superabrasive grain layer formed continuously 10 Electrodeposition band saw

Claims (2)

  In an electrodeposited band saw in which a superabrasive layer is formed by electrodeposition along one side edge of a flat metal endless belt, the superabrasive layer is continuous over the entire circumference of the endless belt. The electrodeposition is characterized in that the electrodeposition is formed from the continuously formed superabrasive grain layer at a predetermined interval in the width direction on both surfaces of the endless belt. Band saw.   The electrodeposited band saw according to claim 1, wherein the shape of the superabrasive grain layer extending at a predetermined interval in the width direction on both surfaces of the endless belt is substantially semicircular.

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