KR102152036B1 - Solder Thin Plate Structure - Google Patents

Abstract

Disclosed is a solder thin plate structure, comprising a first solder layer, a second solder layer, and a metal layer interposed between the first solder layer and the second solder layer and having a melting temperature higher than those of the first solder layer and the second solder layer. In the solder thin plate structure of the present invention, the metal layer has a plurality of through holes. The solder thin plate structure according to the present invention, when a cutting tip is coupled to a shank of a cutting tool such as a cutting saw blade or a core drill bit by soldering, enables the cutting tip to be strongly coupled to the shank of the cutting tool.

Description

Solder Thin Plate Structure {Solder Thin Plate Structure}

The present invention relates to a thin solder structure, and more particularly, when the cutting tip is coupled to the shank of a cutting tool such as a cutting saw blade or a core drill bit by soldering, the cutting tip is strongly coupled to the shank of the cutting tool. It relates to a thin solder plate structure.

Cutting tools such as diamond saw blades and core drill bits are used for cutting. The diamond saw blade is used to cut workpieces such as stone, brick, concrete, and asphalt, and the core drill bit is mounted on the core drill and rotated to make holes in the walls of buildings, etc.

1 shows a schematic configuration of a conventional cutting tool 1'. As shown in FIG. 1, the cutting tool 1'includes a shank 10 forming a part of the body of the cutting tool 1'and a plurality of cutting tips 20 coupled to the shank 10. . The shank 10 is made of metal, usually steel. The cutting tip 20 is typically formed of a diamond cutting tip. Diamond cutting tips are manufactured by a powder metallurgy method in which diamond powder and metal powder serving as a binder are mixed, molded, and then sintered. Carbide alloys are sometimes used instead of diamonds.

As shown in FIG. 1, the cutting tip 20 is generally made thicker than the thickness of the metal shank 10 in order to avoid friction between the metal shank 10 and the workpiece during cutting. The cutting tip 20 is coupled to the shank 10 by laser welding or solder welding, particularly silver solder welding. At this time, laser welding means that the base material is melted and welded by a laser, and silver-lead welding is a type of soldering as welding using a silver-lead material as a welding rod.

In order to couple the cutting tip 20 to the shank 10 by silver solder welding, pressure and heat must be applied while a silver solder thin plate is interposed between the shank 10 and the cutting tip 20. Then, the silver solder layer 30 is interposed between the cutting tip 20 and the shank 10 as the silver solder of the silver solder sheet is melted and cooled, so that the cutting tip 20 is coupled to the shank 10.

2 and 3 show a conventional silver-lead thin plate structure instead of the single-layered silver-lead thin plate 30. The conventional silver-lead thin plate structure 300 ′ includes a first silver-lead layer 310, a second silver-lead layer 320, and a metal layer interposed between the first silver-lead layer 310 and the second silver-lead layer 320, especially a copper layer. Includes 330. At this time, the metal layer, in particular, the copper layer 330 has a melting temperature higher than the melting temperature of the first silver solder layer 310 and the second silver solder layer 320.

It is said that the conventional silver-lead thin plate structure 300 ′ having such a structure mitigates the difference in thermal expansion coefficient to prevent cracks from occurring in the silver-lead layers 310 and 320. It is understood that the conventional silver-lead thin plate structure 300' is based on the following recognition.

That is, in the prior art, when the cutting tip 20 is coupled to the shank 10 by using a single layer of silver solder thin plate 30, the single silver solder layer 30 in the combined cutting tool 1'is a shank Since there is a large difference in coefficient of thermal expansion between the cutting tool 10 and the cutting tip 20, cracks are generated in the silver solder layer 30 by the heat generated while using the cutting tool 10, and the cutting tip 20 becomes the shank 10 It is understood that there is an increased fear of being separated from ).

Patent Publication No. 2002-0037939 (published on May 23, 2002) Patent registration No. 10-1090404 (registered on November 30, 2011) Patent registration No. 10-0791435 (registered on December 27, 2007)

When manufacturing a conventional cutting tool (1') by bonding the cutting tip 20 to the shank 10 by solder welding, in particular, silver solder welding, the cutting tip 20 and the shank 10 are coupled by silver solder. To do this, it must be heated and pressurized above the melting temperature of silver lead. At this time, a significant portion of the molten silver solder is pressed by the pressure applied and flows out from the bonding surface of the cutting tip 20 and the shank 10, and only a portion of the molten silver solder is pressed by the cutting tip 20 and the shank 10. It remains on the coupling surface of the cutting tip 20 and participates in the coupling with the shank 10.

Therefore, there is a problem in that the coupling force between the cutting tip 20 and the shank 10 is weakened in the conventional cutting tool 1 ′, so that the cutting tip 20 is detached during use or the durability is weakened.

On the other hand, the recognition of the prior art with respect to the conventional silver-lead thin plate structure 300 ′ sees the problem of using the single-layer silver-lead thin plate 30 as the occurrence of cracks due to the difference in thermal expansion coefficient, but according to the understanding of the present inventors, Rather, the occurrence of cracks in the silver solder layer 30 is a silver solder layer 30 that is finally left between the cutting tip 20 and the shank 10 as a significant portion of the molten silver solder flows out during the pressing process, as mentioned above. It is understood to be mainly due to the insufficient thickness of ).

Therefore, according to the understanding of the present inventors, the first silver solder layer 310 between the cutting tip 20 and the copper layer 330 and the shank 10 and the copper layer 330 in the conventional silver solder thin plate structure 300' It is understood that the occurrence of cracks in the silver solder layers 310 and 320 has not been fundamentally solved because a significant portion of the molten silver solder flows out of the second silver solder layer 320 in between.

Accordingly, the present invention was devised to solve the problems of the prior art. Accordingly, it is an object of the present invention to provide a thin solder structure in which the cutting tip is strongly coupled to the shank of the cutting tool when the cutting tip is coupled to the shank of a cutting tool such as a cutting saw blade, a core drill bit, etc. .

The thin solder plate structure according to the present invention for achieving the above object is interposed between the first solder layer, the second solder layer, and the first solder layer and the second solder layer, and the first solder layer and the second solder layer. And a metal layer having a melting temperature higher than that of the layer. In this case, the metal layer has a plurality of through holes.

The first solder layer and the second solder layer are melted when pressure and heat are applied while being interposed between the soldered thin plate structure, so that the solder flows into the through holes provided in the metal layer and the first solder Soldering is performed while the layer and the second solder layer are sequentially connected.

The soldered objects may be a shank and a cutting tip of a cutting tool.

It is preferable that the solder used for the first solder layer and the second solder layer is a lead-free solder made mainly of tin.

The metal of the metal layer may be copper or a copper alloy.

Each of the first solder layer, the second solder layer, and the metal layer may have a thickness in a range of 0.05 to 0.5 mm, and a diameter of the through-hole of the metal layer may be in a range of 0.5 to 2 mm.

In the soldered thin plate structure according to the present invention, when a cutting tip is coupled to a shank of a cutting tool such as a cutting saw blade or a core drill bit by soldering, the cutting tip is strongly coupled to the shank of the cutting tool.

1 shows a schematic configuration of a general cutting tool.
2 and 3 show a schematic configuration of a thin solder plate structure according to the prior art.
4 and 5 show a schematic configuration of a thin solder plate structure according to an embodiment of the present invention.
6 shows a schematic configuration of a cutting tool soldered by a thin solder structure according to an embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to the drawings.

4 and 5, the thin solder structure 300 according to the present invention includes a first solder layer 310, a second solder layer 320, and a first solder layer 310 and a second solder layer. It includes a metal layer 330 interposed between (320). At this time, the metal layer 330 has a melting temperature higher than that of the first solder layer 310 and the second solder layer 320. In addition, a plurality of through holes 332 are formed in the metal layer 330.

In the thin solder structure 300 of the present invention, it is preferable that the solder used for the first solder layer 310 and the second solder layer 320 is a lead-free solder made mainly of tin. In particular, it is preferable that it is silver lead. For example, the solder may be an alloy composed of tin-copper (0.7% by weight), tin-silver (3.5% by weight), and tin-silver (3.5% by weight)-copper (0.7% by weight). At this time, the content of tin is the residual content. It is preferable that the solder used in the present invention contains at least 90% by weight of tin.

The metal of the metal layer 330 may be copper or a copper alloy. In addition, as a metal having a melting temperature higher than that of the first solder layer 310 and the second solder layer 320, a metal having an appropriate strength may be employed in the present invention.

The plurality of through holes 332 provided in the metal layer 330 preferably have a diameter in the range of 0.5 to 2 mm, and in particular, may have a diameter of 1 mm. In addition, it is preferable that the plurality of through holes 332 are uniformly arranged. When the diameter of the through hole 332 is too small, as described below, it may not be possible for the molten solder to flow into it, and when the diameter of the through hole 332 is too large, the metal layer 330 It is not preferable because the actual existence and the degree of contribution therefrom becomes small. When the number of through-holes 332 is too small, it may be insufficient to achieve the object of the present invention, and thus it is preferable to be appropriately selected.

In the solder thin plate structure 300 of the present invention, the thickness of the first solder layer 310, the second solder layer 320, and the metal layer 330 may be in the range of 0.05 to 0.5 mm, respectively, and in particular may be 0.1 mm. have.

As shown in FIG. 6, when pressure and heat are applied while the solder thin plate structure 300 of the present invention is interposed between soldering objects such as the shank 10 and the cutting tip 20 of the cutting tool 1 , The first solder layer 310 and the second solder layer 320 are melted. Then, the solder 334 flows into the through-holes 332 provided in the metal layer 330, so that the first solder layer 310 and the second solder layer 320 are connected to each other to perform soldering.

According to the above-described process, when the shank 10 and the cutting tip 20 of the cutting tool 1 are soldered by the solder thin plate structure 300 of the present invention, the cutting tip 20 and the solder thin plate structure 300 The solder melt of the first solder layer 310 that is melted between the metal layers 330 of the first solder layer 310 flows to the outside, so that the thickness of the first solder layer 310 formed therein can be made thinner, and the shank 10 and the solder The solder melt of the second solder layer 320 that is melted between the metal layers 330 of the thin plate structure 300 flows to the outside, so that the thickness of the second solder layer 320 formed therein may be thinner. However, since the solder 334 is filled in the through-holes 332 widely distributed throughout the metal layer 330 and the first solder layer 310 and the second solder layer 320 are connected to each other, soldering in such portions The shank 10 and the cutting tip 20 are combined with a thicker thickness. Furthermore, the metal layer 300 provides mechanical strength to the regions of the first solder layer 310 and the second solder layer 320 that have become thinner, so that the first solder layer 310 and the second solder layer 320 In addition to supporting regions, solders having a thicker thickness in the through holes 332 of the metal layer 300 are supported from the side to reinforce the strength of such solders.

In this way, as the through holes 332 of the metal layer 330 are filled with the solder 334, the effect of increasing the thickness of the solder and the solder having such a thickness in the through holes 332 are applied to the metal layer 330. The effect of being supported and reinforced by the side prevents the occurrence of cracks in the first solder layer 310 and the second solder layer 320, so the cutting tip for the shank 10 of the cutting tool 1 ( It improves the bonding power of 10).

4 and 5 show a thin solder structure 300 having a size necessary to solder one cutting tip 20 to the shank 10 of the cutting tool 1, but the thin solder structure 300 of the present invention 4 and 5 may have a shape extended in the longitudinal direction and the width direction. In practice, after the solder thin plate structure 300 having a sufficiently expanded shape is manufactured, it is cut into an appropriate width and length and used for soldering.

300: solder thin plate structure 310, 320: solder layer
330: metal layer 332: through hole
334: solder

Claims (6)

Solder comprising a first solder layer, a second solder layer, and a metal layer interposed between the first solder layer and the second solder layer and having a melting temperature higher than that of the first solder layer and the second solder layer It is a thin plate structure,
The metal layer has a plurality of through holes,
The first solder layer and the second solder layer are melted when pressure and heat are applied in the state of being interposed between the soldered thin plate structure, so that solder flows into the through holes provided in the metal layer, and the first solder Soldering is performed while the layer and the second solder layer are connected to each other,
The soldering objects are the shank and cutting tip of the cutting tool,
The solder used for the first solder layer and the second solder layer is a lead-free solder containing tin as a main material,
The metal of the metal layer is copper or a copper alloy,
The first solder layer, the second solder layer, and the metal layer each have a thickness in a range of 0.05 to 0.5 mm, and a diameter of the through hole of the metal layer is in a range of 0.5 to 2 mm.
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