KR102219721B1 - Metal saw - Google Patents

Abstract

(Task) Prevent metal saw blades from being worn in the thickness direction.
(Solution means) A metal saw having a saw blade formed on the outer circumference thereof, the metal saw integrally having a first plate-like material, a third plate-like material, and a second plate-like material between the first plate-like material and the third plate-like material. , The saw blade is made of a plurality of cutting edge parts made of a first plate-like material, a second plate-like material, and a third plate-like material, and a second plate-like material on the rear side in the rotational direction of the metal saw, respectively. Having a plurality of distributions, the first plate-shaped article and the third plate-shaped article have higher rigidity than the second plate-shaped article, and the second plate-shaped article is more than the first plate-shaped article and the third plate-shaped article. Toughness is high. The first plate-shaped article and the third plate-shaped article may have an intellectual material. The constituent elements of the first plate-like material and their ratio may be different from the constituent elements of the second plate-like material and the ratio thereof.

Description

Metal Saw {METAL SAW}

The present invention relates to a metal saw used when cutting ceramics or the like before sintering.

One of the semiconductor devices used in mobile phones and the like is a multilayer ceramic capacitor. Hundreds of the multilayer ceramic capacitors are mounted on one mobile phone, and are mass-produced daily and consumed in large quantities.

In the multilayer ceramic capacitor, a plurality of raw ceramics (ceramics before sintering) are first laminated, divided into individual chip capacitors by a cutting device, and then sintered to be manufactured. In addition, when dividing by a cutting device is performed after sintering, thermal deformation occurs due to high temperature during sintering, the arrangement of the chip capacitors is distorted, and precise cutting becomes difficult, so the dividing is performed before sintering of the ceramics.

The step of dividing a plurality of sheet-shaped laminates of green ceramics into individual chip capacitors by a cutting device is performed by a cutting device equipped with a metal saw. Patent Document 1 discloses a metal saw (rotating blade) used for cutting raw ceramics and having a saw blade formed on the outer circumference thereof.

Japanese Laid-Open Patent Publication No. Hei 4-179505

However, if the raw ceramic is repeatedly cut using the metal saw, the saw blades on the outer periphery of the metal saw wear. In particular, the edges of both ends in the thickness direction of the cutting surface of the saw blade (the surface between one side of the metal saw and the other side) (the edge between the side of the metal saw and the cutting surface) are severely worn because the cutting load is large, and the saw blade is Gradually, its corners change into a rounded shape.

When the edge portion of the saw blade of the metal saw wears and the edge becomes a rounded shape, the shape is reflected in the part to be processed at the cutting point of the cut raw ceramic. Therefore, there arises a problem that the side surfaces of individual chip capacitors that are manufactured by being divided are also shaped to reflect the shape.

The present invention has been made in view of such a problem, and an object thereof is to provide a metal saw in which abrasion of the edge portion of a saw blade is suppressed. And, even if it is used when dividing the raw ceramic, it is to provide a metal saw that does not have an abnormal shape on the side surface of the formed chip capacitor.

According to an aspect of the present invention, as a metal saw blade formed on the outer circumferential portion, a first plate-like material, a third plate-like material, and a second plate-like material between the first plate-like material and the third plate-like material integrally, The saw blade includes a plurality of cutting edge portions made of a first plate-like material, a second plate-like material, and a third plate-like material, and a plurality of the second plate-like material on the rear side in the rotational direction of the metal saw, respectively. A metal saw, characterized by having a back portion of, is provided.

According to another aspect of the present invention, as a metal saw blade is formed on the outer circumferential portion, a first plate-like material, a third plate-like material, and a second plate-like material between the first plate-like material and the third plate-like material integrally , The saw blade is a first plate-like material or a first plate-like material or a first plate-like material on the rear side in the rotational direction of the metal saw, respectively, a plurality of cutting edge parts made of a first plate-like material, a second plate-like material, and a third plate-like material, and the plurality of cutting edge parts. A metal saw is provided, characterized in that it has a plurality of distributing portions made of three plate-like objects.

Further, according to another aspect of the present invention, as a metal saw blade is formed on the outer circumferential portion, the first plate-like material, the third plate-like material, and the second plate-like material between the first plate-like material and the third plate-like material are integrated. And the saw blade has a plurality of cutting edge portions made of a first plate-like material, a second plate-like material, and a third plate-like material, and a second plate-like material on the rear side in the rotational direction of the metal saw, respectively. A metal saw is provided which has a plurality of distributing portions composed of, and the first plate-like material and the third plate-like material have higher rigidity than the second plate-like material.

According to another aspect of the present invention, as a metal saw blade is formed on the outer circumferential portion, a first plate-like material, a third plate-like material, and a second plate-like material between the first plate-like material and the third plate-like material integrally , The saw blade is a first plate-like material or a first plate-like material or a first plate-like material on the rear side in the rotational direction of the metal saw, respectively, a plurality of cutting edge parts made of a first plate-like material, a second plate-like material, and a third plate-like material, and A metal saw is provided which has a plurality of distributing portions made of three plate-like objects, and the first plate-like material and the third plate-like material have higher rigidity than the second plate-like material.

In addition, according to another aspect of the present invention, as a metal saw blade is formed on the outer circumferential portion, the metal saw is a first plate-like material, a third plate-like material, and the first plate-like material and the third plate-like material 2 The plate-like material is integrally formed, and the saw blade is a plurality of cutting edge portions composed of a first plate-like material, a second plate-like material, and a third plate-like material, and the plurality of cutting edge portions, respectively, at the rear side in the rotation direction of the metal saw. Has a plurality of distributing portions made of a second plate-like object, and the first plate-like object and the third plate-like object have higher rigidity than the second plate-like object, and the second plate-like object is the first plate-like object, There is provided a metal saw having higher toughness than the third plate-like material.

Further, according to another aspect of the present invention, as a metal saw blade is formed on the outer circumferential portion, the metal saw is a first plate-like material, a third plate-like material, and a third plate-like material between the first plate-like material and the third plate-like material. 2 The plate-like material is integrally formed, and the saw blade is a plurality of cutting edge portions composed of a first plate-like material, a second plate-like material, and a third plate-like material, and the plurality of cutting edge portions, respectively, at the rear side in the rotation direction of the metal saw. The first plate-shaped article or the third plate-shaped article has a plurality of distribution portions, and the first plate-shaped article and the third plate-shaped article are more rigid than the second plate-shaped article, and the second plate-shaped article is A metal saw having a higher toughness than that of the first plate and the third plate is provided.

In addition, in the metal saw according to an aspect of the present invention, the first plate-like material and the third plate-like material may have a paper material. In addition, in the metal element according to an aspect of the present invention, the constituent elements of the first plate-like material and their ratio may be different from the constituent elements of the second plate-like material and the ratio thereof.

According to an aspect of the present invention, there is provided a metal saw in which the first to third plate-like objects are integrally rotatable. In the metal saw according to an aspect of the present invention, since three or more plate-like objects are integrally formed, each property can be set independently. For example, a plate-like material having high rigidity and a plate-like material having high toughness may be laminated in a thickness direction and combined to form a plurality of sheets.

For example, if a plate-like material having high rigidity is disposed on both sides, abrasion resistance of the edge of the saw blade of a metal saw can be improved. In addition, when a plate-like material having high toughness is disposed between the plate-like materials having high rigidity, the metal cow becomes strong against external force or impact, and the durability of the metal cow is increased.

In addition, if a plate-like material with high rigidity is placed on both sides that are likely to be exposed to friction, and the ceramics is cut with a metal saw placed inside the plate-like material with low rigidity that is difficult to be exposed to friction, the cutting surface of the metal saw is uniform. It is consumed. That is, there is no case that only the edge of the saw blade of the metal saw is worn and becomes rounded. Therefore, the side of the chip capacitor to be formed does not have an abnormal shape.

In addition, in the metal saw according to an aspect of the present invention, the saw blade has a cutting edge portion and a rear portion. The cutting edge portion for cutting ceramics is made of first to third plate-like materials, and the thickness of the portion used for cutting can be sufficiently secured. On the other hand, in the distal portion other than the part used for cutting, since there are no first plate-like and third plate-like objects on the side of the saw blade, space is secured to efficiently remove chips generated during cutting. do.

Therefore, it is possible to reduce abrasion at the time of cutting the edge portion of the cutting edge portion of the saw blade. In addition, since such a shape having the cutting edge portion and the back portion can be easily formed by simply adjusting the shape of each plate-like object without complicated processing on the metal saw, the cost associated with manufacturing the metal saw is suppressed.

Accordingly, according to one aspect of the present invention, a metal saw in which the wear of the edge portion of the saw blade is suppressed is provided. Further, a metal saw is provided in which the side surface of the formed chip capacitor does not have an abnormal shape even when it is used when dividing the raw ceramic.

1 is a perspective view showing an example of a cutting device.
2 is a perspective view schematically illustrating the structure of a cutting unit.
Fig. 3(A) is a schematic diagram when a metal saw is viewed from the side, and Figs. 3(B) and 3(C) are diagrams schematically illustrating a cross-sectional structure of a metal saw.
FIG. 4(A) is a schematic diagram when a metal saw according to another embodiment is viewed from the side, and FIG. 4(B) and FIG. 4(C) are diagrams schematically illustrating a cross-sectional structure of a metal saw.

Embodiments according to the present invention will be described. As an example of a cutting device using a metal saw according to the present embodiment, an external perspective view of a cutting device 2 for cutting a workpiece such as ceramics is shown in FIG. 1. The cutting device 2 includes a main body 4 in which the cutting unit 10 having the metal saw is accommodated in the outer cover 8, a display monitor 6 mounted on the outer cover 8 of the main body 4, etc. It is composed of

On the front surface of the exterior cover 8, a touch panel type display monitor 6 is disposed. With this display monitor 6, the operator inputs a command to the device, and the operation status of the device is displayed on the display monitor 6.

The cutting unit 10 is configured to be movable in the Y-axis direction. Adjacent to the cutting unit 10, the holding table 12 is disposed so as to be movable in the X-axis direction. The holding table 12 holds the workpiece during processing. The mounting table 14 is a mounting table (elevator) for placing a cassette capable of accommodating a plurality of workpieces therein, and is configured to be movable in the vertical direction.

When a cassette for accommodating a work piece is placed on the mounting table 14, the cutting device 2 takes out the work piece from the cassette and mounts it on the holding table 12 by a predetermined conveying mechanism. Then, the holding table 12 applies negative pressure from an unillustrated suction source, and holds the workpiece on the holding table 12 by suction.

Here, a more detailed structure of the cutting unit 10 will be described using FIG. 2. 2 is an exploded view schematically illustrating the structure of the cutting unit 10. As shown in FIG. 2, the cutting unit 10 includes, for example, a spindle housing 16 fixed to a moving mechanism (not shown) of the cutting device 2 or the like. In the interior of the spindle housing 16, a spindle 18 extending in the front-rear direction (Y-axis direction) is rotatably supported. The front end (front end) of the spindle 18 protrudes forward from the spindle housing 16.

An opening 18a is formed at the distal end of the spindle 18, and a screw groove is formed in the inner wall surface 18b of the opening 18a. A rear flange 20 formed of a material containing a ferromagnetic material is attached to the distal end of the spindle 18. The rear flange 20 includes a flange portion 22 extending radially outward and a boss portion 24 protruding forward from the surface (front) of the flange portion 22.

In the center of the flange portion 22, an opening 22a penetrating the flange portion 22 back and forth is formed. Further, on the rear (rear) side of the flange portion 22, a fitting portion (not shown) into which the distal end of the spindle 18 can be fitted is formed. This fitting portion is formed at a position corresponding to the opening 22a.

When the fixing bolt 26 is tightly tightened to the opening 22a and the opening 18a in a state where the front end of the spindle 18 is fitted into the fitting portion formed in the flange portion 22, the rear flange 20 becomes the spindle ( 18) is fixed. Further, on the outer circumferential surface 26a of the fixing bolt 26, a thread corresponding to the screw groove of the opening 18a is formed.

The surface on the outer circumferential side of the flange portion 22 is a contact surface 22b that abuts on the side surface of the metal cow 28 on the tooth side. This abutting surface 22b is formed in an annular shape when viewed from the axis direction (Y axis direction) of the spindle 18. The boss part 24 is formed in a cylindrical shape, and a thread is formed in the outer peripheral surface 24a.

A circular opening 28a through which the boss part 24 is inserted is formed in the center of the metal small 28, and by inserting the boss part 24 through the opening 28a, the metal small 28 Is mounted on the rear flange (20).

In the state where the metal saw 28 is attached to the rear flange 20, the annular front flange 30 is attached to the side surface of the metal saw 28 on the table side. An opening 30a is formed in the center of the front flange 30, and the boss portion 24 of the rear flange 20 is fitted in the opening 30a. Further, the rear surface on the outer circumferential side of the front flange 30 is a contact surface (not shown) that abuts the side surface on the front side of the metal cow 28. This abutting surface is formed at a position corresponding to the abutting surface 22b of the rear flange 20.

After attaching the front flange 30, the annular fixing nut 32 is tightly tightened to the tip end of the boss portion 24. Thereby, the front flange 30 is pressed to the rear flange 20 side, and the metal material 28 is held by the rear flange 20 and the front flange 30. Further, an opening 32a is formed in the fixing nut 32, and a screw groove is formed in the inner wall surface 32b of the opening 32a.

On the front surface of the spindle housing 16, a blade cover 34 for accommodating a metal cow 28 or the like attached to the spindle 18 is formed. The blade cover 34 is composed of a blade cover body 36 fixed to the front surface of the spindle housing 16, and a slide cover 38 that is slidable in the left-right direction (X axis direction) with respect to the blade cover body 36. Has been.

The slide cover 38 is connected to the blade cover body 36 via the air cylinder 40, and is slid with air supplied through the connector 42. After attaching the metal cow 28 to the spindle 18, by sliding the slide cover 38 to close the blade cover 34, the metal cow 28 can be accommodated inside the blade cover 34.

To the slide cover 38, a pair of substantially L-shaped nozzles 44 that sandwich the lower portion of the metal cow 28 back and forth are fixed. Cutting water is supplied to the nozzle 44 through a connector 46 formed in the slide cover 38. A plurality of slits (not shown) are formed on the front end side of the nozzle 44 so as to face the metal material 28. Cutting water is supplied through the plurality of slits.

On the other hand, in the blade cover main body 36, a supply hole (not shown) for supplying cutting water to the metal saw 28 is formed. This supply hole is connected to the connector 48 formed in the blade cover main body 36, and the metal saw 28 is cooled and cleaned by cutting water supplied from the supply hole through the connector 48.

Next, the structure of the metal material 28 will be described using Figs. 3(A) to 3(C). Fig. 3(A) is a schematic diagram when a metal saw is seen from the side, and Figs. 3(B) and 3(C) are diagrams schematically illustrating a cross-sectional structure of a metal saw in the thickness direction.

As shown in FIG. 3(A), in the center of the metal cow 28, a circular opening 28a through which the above-described boss part 24 is inserted is formed. A saw blade 28b is formed on the outer periphery of the metal saw 28. When the spindle 18 of the cutting unit 10 rotates, the metal saw 28 attached to the cutting unit 10 rotates with the rotation. When the tip of the rotating metal saw 28 reaches the work piece, the work piece is cut by the saw blade 28b.

The saw blade 28b has a plurality of cutting edge portions (rake faces) 28c and a plurality of distributing portions (flank faces) 28d on the rear side of the metal saw 28 in the rotational direction of the plurality of cutting edge portions 28c, respectively. ). Each cutting edge portion 28c has a shape protruding in the outer circumferential direction of the metal saw 28 from the adjacent distributing portion 28d, and cuts the workpiece. Each distributing portion 28d has a shape that is cut in the center direction of the metal saw 28 rather than the adjacent cutting edge portion 28c, and secures a space for efficiently discharging the chips generated by cutting.

Fig. 3(B) is a schematic diagram showing a cross-sectional structure when the metal saw 28 shown in Fig. 3(A) is cut from the plane passing through the one-point chain line A-A' perpendicular to the side surface. 3(B) is a view in which the cutting edge part 28c of the saw blade 28b is included. Fig. 3(C) is a schematic diagram showing a cross-sectional structure when the metal saw 28 shown in Fig. 3(A) is cut so as to pass through the one-point chain line B-B' perpendicular to the side surface. Fig. 3(C) is a view in which a particularly distributing portion 28d of the saw blade 28b is included.

As shown in Figs. 3(B) and 3(C), the metal material 28 includes a first plate-like material 50a, a third plate-like material 50c, and the first plate-like material 50a, and It has a 2nd plate-like material 50b fitted in the 3rd plate-like material 50c. As shown in FIG. 3(B), the cutting edge part 28c is made up of a 1st plate-like material 50a, a 2nd plate-like material 50b, and a 3rd plate-like material 50c. On the other hand, as shown in FIG. 3(C), the distribution part 28d is made of the 2nd plate-shaped material 50b.

A method of forming the metal material 28 will be described. First, metal powder is put in a ring-shaped molding die, and cold press is performed to form a ring-shaped green compact. Next, three ring-shaped green compacts are stacked, sintered, and integrated. When the outer periphery of the obtained sintered body is subjected to cutting edge grinding, metal saw 28 is formed.

The saw blade 28b of the formed metal saw 28 has a cutting edge 28c made of first to third plate-like materials and a distribution 28d made of a second plate-like material, and the metal saw 28 is complex It becomes a structure. However, since the metal cow 28 according to the present embodiment can be manufactured by changing the shape of each plate-like object in this way and sintering it, it does not require complicated processing to manufacture the metal cow 28. .

For example, if it is desired to form the shape of the metal cattle 28 into a single plate, in order to form the shape of the distributing part 28d, each distributing part 28d must be cut out, which is expensive. On the other hand, in forming the metal material 28 according to the present embodiment, such a product is not required. Therefore, the cutting edge portion 28c and the cutting edge portion 28c can be manufactured by reducing the cost of a metal saw blade 28b having a distribution portion 28d having different thicknesses.

In addition, when the first to third plate-shaped articles are manufactured, the physical properties of each plate-shaped article can be adjusted by adjusting the constituent material or composition of the metal powders used as respective raw materials. By adjusting the physical properties of the first to third plate-like articles, the physical properties of the metal material 28 formed by sintering can be adjusted.

For example, in the metal material 28 according to the present embodiment, by adjusting the physical properties of the first to third plate-like objects, the rigidity of the first plate-like material 50a and the rigidity of the third plate-like material 50c It can be made higher than the rigidity of the 2nd plate-like object 50b, respectively.

In general, when the cutting process is repeated using a metal saw, the edges of both ends in the thickness direction are worn at the cutting edge of the saw blade, and the edge of the saw blade 28b on the outer periphery of the metal saw gradually changes to a rounded shape. .

Therefore, in the metal material 28 according to the present embodiment, the first plate-like material 50a and the third plate-like material 50c have rigidity higher than that of the inner second plate-like material 50b. To the third plate-like material, composition, etc. are adjusted. By doing so, since both side surfaces of the metal material 28 become a plate-like material with high rigidity, the wear resistance of the metal material 28 is improved. Therefore, the shape of the metal saw 28 is less likely to change due to abrasion, and the shape of the side surface of the chip capacitor formed by cutting by the metal saw 28 is also difficult to become abnormal.

However, in general, when the rigidity of the metal material increases, the hardness increases, while there is a tendency to become brittle, and the likelihood of damage due to impact or the like increases. Therefore, in order to realize a metal saw having excellent wear resistance, simply increasing the hardness of the metal saw causes a problem of impact resistance.

Therefore, in the metal material 28 according to the present embodiment, the configuration of the second plate-like material to increase the toughness of the first plate-like material 50a and the second plate-like material 50b sandwiched between the third plate-like material 50c. Adjust the material or composition. A plate-like article having high toughness improves impact resistance and mitigates the impact received from the outside.

When the toughness of the second plate-like material 50b is high compared to the toughness of the first and third plate-like materials, when an external impact is applied to the metal material 28, the second plate-like material 50b alleviates the impact. . By doing so, it is possible to prevent damage to the first plate-like material and the third plate-like material having high rigidity due to the impact. Since the second plate-like material 50b has high toughness and low abrasion resistance, it is easy to wear when cutting by the metal saw 28 is repeated, but the second plate-like material 50b is not particularly at both ends that are prone to wear, so for a long time Can withstand the use of.

That is, the metal saw 28 according to the present embodiment is provided with the first plate-like material 50a and the third plate-like material 50c on the side surface where wear is likely to occur, so that the wear of the side surface of the saw blade 28b The shape change by this is suppressed. On the other hand, since the second plate-like material 50b having high toughness is provided inside, even if an impact is applied to the metal material 28, occurrence of damage or the like is suppressed. Therefore, the life of the metal cow 28 is extended.

The rigidity and toughness of the plate-like material are adjusted according to the constituent elements of the plate-like material and their ratio (content ratio), and the like. And, for example, the constituent elements of the first plate-like material and the content ratio thereof are made different from the constituent elements of the second plate-like material and the ratio thereof to adjust the rigidity and toughness of each. For each plate-like material used for the metal material 28, a material obtained by mixing tungsten carbide (tungsten carbide) and cobalt as a binder is used, but the rigidity and toughness of the plate-like material can be adjusted according to the content of cobalt.

More specifically, in the case of forming a plate-like article having high rigidity, the ratio of cobalt to be contained in tungsten carbide is set to about 5 wt%. In the case of forming a plate-like article having high toughness, the ratio of cobalt to be contained in tungsten carbide is set to about 30 wt%. However, the metal saw according to the present embodiment is not limited to this. The stiffness and toughness are determined along with the thickness of each plate according to the desired properties of the metal material and the type of the object to be processed.

Further, in the metal saw according to the present embodiment, a high-hardness paper material (particle) made of a material such as diamond or alumina is mixed in the first plate-like material and the third plate-like material. When paper materials (particles) are mixed in the first plate-like material and the third plate-like material, abrasion resistance is improved compared to other materials constituting each plate-like material. When paper materials (particles) are mixed in the first plate-like material and the third plate-like material serving as both sides of the metal cow, abrasion of the metal cow can be reduced, and the life of the metal cow can be increased. However, the metal material according to the present embodiment is not limited to the case where the paper material is included.

In addition, in the saw blade 28b of the metal saw 28 according to the present embodiment, the cutting edge portion 28c is made of first to third plate-like objects, and the thickness of the portion to be cut can be sufficiently secured. On the other hand, in the distributing portion 28d, since the first plate-like material 50a and the third plate-like material 50c on the side surface side of the saw blade 28b do not exist, it is intended to efficiently remove cutting debris generated from the workpiece. You can reserve space.

In addition, the present invention is not limited to the description of the above embodiment, and can be implemented with various modifications. For example, in the above-described embodiment, the case where three plate-like objects constituting the metal element is mainly described. However, the plate-like material constituting the metal piece may be composed of four or more sheets, and in that case, the rigidity of the plate-like material on both sides of the metal piece may be higher than the rigidity of the plate-like material on the inner side.

Next, another embodiment of the metal saw according to an aspect of the present invention will be described. The structure of the metal material 28 according to another embodiment will be described with reference to Figs. 4A to 4C. Fig. 4(A) is a schematic view when a metal saw is seen from the side, and Figs. 4(B) and 4(C) are diagrams schematically illustrating a cross-sectional structure of a metal saw in the thickness direction. The metal material 28 according to another embodiment described below is mainly different from the metal material 28 according to the above-described embodiment in the cross-sectional structure of the distributing portion 28d.

Fig. 4(B) is a schematic diagram showing a cross-sectional structure when the metal saw 28 shown in Fig. 4(A) is cut from the plane passing through the one-point chain line A-A' perpendicular to the side surface. 4(B) is a view in which the cutting edge portion 28c of the saw blade 28b is included. Fig. 4(C) is a schematic diagram showing a cross-sectional structure when the metal saw 28 shown in Fig. 4(A) is cut so as to pass through the one-point chain line B-B' perpendicular to the side surface. Fig. 3(C) is a view in which a particularly distributing portion 28d of the saw blade 28b is included.

As shown in Fig. 4(B) and Fig. 4(C), the metal material 28 is a first plate-like material 50a, a third plate-like material 50c, and the first plate-like material 50a, and It has a 2nd plate-like material 50b fitted in the 3rd plate-like material 50c. As shown in FIG. 4(B), the cutting edge part 28c is made up of the 1st plate-like material 50a, the 2nd plate-like material 50b, and the 3rd plate-like material 50c. On the other hand, as shown in FIG. 4(C), the distribution part 28d consists of the 1st plate-like material 50a, and the 3rd plate-like material 50c.

A method of forming the metal material 28 according to another embodiment will be described. First, metal powder is put in a ring-shaped molding die, and cold press is performed to form a ring-shaped green compact. Next, it is pre-sintered at a low temperature (for example, 500°C) and processed to a predetermined thickness and shape to form each plate. The first plate-like material 50a and the third plate-like material 50c are formed in a shape constituting the cutting edge portion 28c and the distributing portion 28d, and the second plate-like material 50b constitutes the cutting edge portion 28c. It is formed into a shape.

Next, each formed plate-like material is laminated and sintered (for example, 900°C) to be integrated. The sintering is carried out in a state in which the first to third plate-like materials are inserted into two carbon plates at a predetermined pressure. In addition, on the two carbon plates, a convex portion is formed in advance in a region corresponding to the distribution portion 28d of the saw blade 28b.

Then, the first plate-like material 50a and the third plate-like material 50c softened by exposure to the high temperature during sintering are pressed against the convex portion of the carbon plate, and each metal material ( 28) It is deformed toward the inside of. Therefore, both are in contact with each other so as to surround the second plate-like article 50b in the distribution portion 28d. In other words, the first plate-like material 50a and the third plate-like material 50c are deformed so as to fill in the defective portion of the second plate-like material 50b in the distribution portion 28d. And when the outer periphery of the obtained sintered body is ground-cut, the metal stuffing 28 is formed.

The saw blade 28b of the formed metal saw 28 has a cutting edge portion 28c made of first to third plate-like materials, and a distribution portion 28d made of a first plate-like material and a third plate-like material, 28) becomes a complex structure. However, according to the other embodiment, the metal material 28 having such a complex structure can be easily manufactured. In addition, compared to the metal material 28 according to the above-described embodiment, the metal material 28 according to the other embodiment is composed of a plate-like material having high rigidity, so that the distribution portion 28d is The rigidity increases.

In addition, the distribution part 28d should just be comprised by at least one of a 1st plate-shaped article or a 3rd plate-shaped article. That is, it may be constituted by only one of the first plate-like material or the third plate-like material, or may be constituted by both the first plate-like material and the third plate-like material.

In addition, the structure, method, etc. related to the above embodiment can be appropriately changed and implemented as long as they do not deviate from the scope of the object of the present invention.

2: cutting device
4: main body
6: display monitor
8: exterior cover
10: cutting unit
12: holding table
14: wit
16: spindle housing
18: spindle
18a: opening
20: rear flange
22: flange portion
22a: opening
22b: contact surface
24: boss
26: fixing bolt
26a: outer peripheral surface
28: metal saw
28a: opening
28b: saw blade
28c: cutting edge
28d: distribution
30: full flange
30a: opening
32: fixing nut
32a: opening
32b: inner wall surface
34: blade cover
36: blade cover body
38: slide cover
40: air cylinder
42: connector
44: nozzle
46: connector
48: connector
50a: first plate-like object
50b: second plate-like object
50c: third plate
52a: opening of the first plate-like object
52b: opening of the second plate-like object
52c: opening of the third plate-like object

Claims (8)

As a metal saw blade formed on the outer periphery,
A first plate-like article, a third plate-like article, and a second plate-shaped article between the first plate-shaped article and the third plate-shaped article are integrally provided,
The saw blade,
A plurality of cutting edge portions comprising a first plate-like material, a second plate-like material, and a third plate-like material,
A metal saw, wherein each of the plurality of cutting edge portions has a plurality of distributing portions made of a second plate-like material on a rear side in the rotation direction of the metal saw. As a metal saw blade formed on the outer periphery,
A first plate-like article, a third plate-like article, and a second plate-shaped article between the first plate-shaped article and the third plate-shaped article are integrally provided,
The saw blade,
A plurality of cutting edge portions comprising a first plate-like material, a second plate-like material, and a third plate-like material,
A metal saw, characterized in that, each of the plurality of cutting edge portions has a plurality of distributing portions made of a first plate-like material or a third plate-like material on a rear side in the rotation direction of the metal saw. As a metal saw blade formed on the outer periphery,
A first plate-like article, a third plate-like article, and a second plate-shaped article between the first plate-shaped article and the third plate-shaped article are integrally provided,
The saw blade,
A plurality of cutting edge portions comprising a first plate-like material, a second plate-like material, and a third plate-like material,
Each of the plurality of cutting edge portions has a plurality of distributing portions made of a second plate-like material on the rear side in the rotational direction of the metal saw,
The first plate-like material and the third plate-like material have higher rigidity than that of the second plate-like material. As a metal saw blade formed on the outer periphery,
A first plate-like article, a third plate-like article, and a second plate-shaped article between the first plate-shaped article and the third plate-shaped article are integrally provided,
The saw blade,
A plurality of cutting edge portions comprising a first plate-like material, a second plate-like material, and a third plate-like material,
Each of the plurality of cutting edge portions has a plurality of distributing portions made of a first plate-like material or a third plate-like material on the rear side in the rotational direction of the metal saw,
The first plate-like material and the third plate-like material have higher rigidity than that of the second plate-like material. As a metal saw blade formed on the outer periphery,
The metal saw integrally has a first plate-like object, a third plate-like object, and a second plate-like object between the first and third plate-like objects,
The saw blade,
A plurality of cutting edge portions comprising a first plate-like material, a second plate-like material, and a third plate-like material,
Each of the plurality of cutting edge portions has a plurality of distributing portions made of a second plate-like material on the rear side in the rotational direction of the metal saw,
The first plate-shaped article and the third plate-shaped article have higher rigidity than the second plate-shaped article,
The second plate-like material has a higher toughness than the first plate-like material and the third plate-like material. As a metal saw blade formed on the outer periphery,
The metal saw integrally has a first plate-like object, a third plate-like object, and a second plate-like object between the first and third plate-like objects,
The saw blade,
A plurality of cutting edge portions comprising a first plate-like material, a second plate-like material, and a third plate-like material,
Each of the plurality of cutting edge portions has a plurality of distributing portions made of a first plate-like material or a third plate-like material on the rear side in the rotational direction of the metal saw,
The first plate-shaped article and the third plate-shaped article have higher rigidity than the second plate-shaped article,
The second plate-like material has a higher toughness than the first plate-like material and the third plate-like material. The method according to any one of claims 1 to 6,
The first plate-like material and the third plate-like material have a paper material. The method according to any one of claims 1 to 6,
A metal element, characterized in that the constituent elements of the first plate-like material and their ratio are different from the constituent elements of the second plate-like material and the ratio thereof.

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