JP7268926B2 - Cutting bit and manufacturing method thereof - Google Patents

Description

The present invention relates to a cutting bit used for cutting and excavating bedrock, rock, concrete, and the like.

A cutting bit is used by being rotatably attached to a holder of a construction machine such as an excavator, and a tip made of cemented carbide is fixed to the tip of a bit body made of steel.

The tip has a high hardness and is hard to wear, but the bit body wears more easily than the tip. Therefore, when the portion of the bit body holding the tip is worn during cutting or excavation work, the tip will come off. It is necessary to replace the cutting bit with a new one before the chip falls off, but the replacement work is time-consuming. Moreover, the replacement work cannot be easily performed on site, for example, in a tunnel.

Therefore, it is considered to improve the durability of the cutting bit. As a means for that purpose, forming a built-up portion at a portion where wear is desired to be suppressed is performed (Patent Document 1 below).

The cladding portion is formed by coating the surface of the bit body with cemented carbide particles made of a cemented carbide by welding. The cemented carbide particles used are obtained by grinding cemented carbide, and the cemented carbide used is scrap.

Cemented carbide particles obtained by pulverization are produced by splitting, so they are in the form of angular particles, as shown in the photograph of a conventional build-up portion formed on a cutting bit (see FIG. 6).

Therefore, the cemented carbide particles present inside the build-up portion are non-uniform and scattered, and the gaps between the cemented carbide particles are large and numerous. As a result, the surroundings of the cemented carbide particles are easily worn. In addition, since the corners of the cemented carbide particles protrude, the cemented carbide particles will easily come off as the periphery of the cemented carbide particles is worn.

Also, perhaps because the bit body wears more easily than the tip, conventional cutting bits have a relatively thick portion 102 for holding the tip 101, as disclosed in Patent Document 2 below. . As shown in FIG. 7, the diameter d1 of the tip holding portion 102 is more than twice the diameter d2 of the tip 101, and the diameter d1 of the tip holding portion 102 is equal to the diameter d3 of the collar portion 103. was set at about 70%.

Japanese Utility Model Laid-Open No. 6-8498 JP-A-9-209678

A main object of the present invention is to improve durability.

Means for that purpose is a method for manufacturing a cutting bit in which a build-up portion having cemented carbide particles is formed on the surface of a bit body having a tip at the tip, wherein the cemented carbide particles are spherical and welded. For cutting, the cemented carbide particles are dropped into a flow of molten cladding material and settled so that the cemented carbide particles are arranged in the cladding portion so as to reduce the gap between them. It is a bit manufacturing method .

In this configuration, since the cemented carbide particles embedded while welding when forming the welded portion are spherical, the cemented carbide particles in the welded portion are arranged relatively orderly. For this reason, a larger amount of cemented carbide particles are present in the interior of the cladding portion with a high degree of integrity, and the cladding portion has a mode in which the corners of the cemented carbide particles do not protrude.

According to the present invention, it is possible to obtain a build-up portion in which the cemented carbide particles adhere in a sufficient amount and have high integrity, and the corners of the cemented carbide particles do not protrude. It is hard and sufficiently fulfills the function of reinforcement. As a result, the durability of the cutting bit can be improved.

FIG. 1 is a half sectional view of a cutting bit; The top view of a bit for cutting. Explanatory drawing which shows the magnitude|size of a bit body. FIG. 5 is an explanatory diagram showing the size of a bit body according to another example; A photograph showing a built-up part. The photograph which shows the conventional build-up part. FIG. 2 is a half sectional view showing the size of a conventional bit body;

One mode for carrying out the present invention will be described below with reference to the drawings.

FIG. 1 shows a half sectional view of the cutting bit 11, and FIG. 2 shows a plan view of the cutting bit 11 viewed from the tip side. As shown in these figures, the cutting bit 11 has a structure in which a tip 15 is provided at the tip of a bit body 13 .

The bit body 13 is made of steel and has a cylindrical mounting shaft portion 31 that is rotatably held by a holder (not shown) of an excavator or the like. , a body shaft portion 33, and a tip shaft portion 34, which are directed forward in this order. The collar portion 32 is a portion that covers the tip surface of the holder during use, and has a disk shape with a larger diameter than the mounting shaft portion 31 . The main body shaft portion 33 has a cylindrical shape with a diameter smaller than that of the flange portion 32, and a front side surface 32a of the flange portion 32 is formed in a flat conical shape, and draws an arc when viewed from the front. The tip shaft portion 34 has a truncated cone shape, and has a tapered surface 34 a tapered from the tip of the body shaft portion 33 over the entire outer peripheral surface. A round hole-shaped recess 35 in which a part of the tip 15 is embedded is formed in the tip surface 34b of the tip shaft portion 34. As shown in FIG. The diameter of the recess 35 is smaller than the diameter of the tip shank 34 . Although the depth of the recess 35 is appropriately set, since the tip 15 is held in the recess 35 formed in the tip shaft portion 34 , the body shaft portion 33 functions as a base for supporting and holding the tip 15 .

The tip 15 is made of cemented carbide, and has a cylindrical holding portion 51 embedded in the recess 35 of the bit body 13 and a substantially conical holding portion 51 protruding from the tip end surface 34b of the bit body 13 when fixed in the recess 35. It has a tip 52 . The tip 15 is integrally connected to the bit body 13 by brazing.

In the cutting bit 11 having such a basic structure, the bit body 13 is devised to reduce the load applied to the cutting bit 11 during cutting or excavation work. On the surface of the bit body 13, build-up portions 37 and 38 are formed to reinforce the bit body 13. As shown in FIG.

First, the shape of the bit body 13 will be described.

As shown in FIG. 3, the thickness of the main body shaft portion 33 is formed thinner than before.

Specifically, the thickness (diameter D1) of the main body shaft portion 33 is set to 0.5 to 0.6 times the diameter D3 of the collar portion 32 and to twice or less than the diameter D2 of the tip 15 .

The diameter D3 of the collar portion 32 is determined by the size of the holder. good. Also, as shown in FIG. 4, when the diameter D3 of the collar portion 32 is φ110 mm and the diameter D2 of the tip 15 is φ30 mm, the diameter D1 of the body shaft portion 33 should be φ60 mm.

Next, the build-up portions 37 and 38 will be explained.

The padding portions 37 and 38 reinforce the surface of the bit body 13 and have a large number of cemented carbide particles 39 . The build-up portions 37 and 38 are formed by adhering cemented carbide particles 39 while welding to form a coating layer having an appropriate thickness on the surface of the bit body 13 . Specifically, the cemented carbide particles 39 are dropped into the iron melted by welding and settled. The cemented carbide particles 39 entering the molten iron stream are closely packed with small gaps between each other.

The cemented carbide particles 39 used for forming the cladding portions 37 and 38 are spherical as shown in FIG. A spherical shape does not mean only a complete sphere, but a shape like a sphere without sharp corners, and a sphere or a shape close to it is sufficient. The cemented carbide particles 39 are not obtained by pulverizing waste cemented carbide, but are formed into a spherical shape by powder metallurgy.

Although the size of the cemented carbide particles 39 depends on the thickness of the build-up portions 37 and 38, the smaller the size, the better. If the size exceeds several millimeters, the gaps between the cemented carbide particles 39 become large, and the integration of the build-up portions 37 and 38 may deteriorate. However, if it is too small, there is a possibility that the workability in forming the padding portions 37 and 38 will deteriorate. Therefore, the particle size of the cemented carbide particles 39 is preferably about φ0.5 mm to φ2 mm, more preferably about φ0.5 mm to φ1.5 mm. The size of the cemented carbide particles 39 to be used may be uniform or may vary.

When the size of the cemented carbide particles 39 is within the range described above, the thickness of the build-up portions 37 and 38 is preferably about 3 mm, for example.

The build-up portions 37 and 38 are formed on the outer peripheral surface of the tip shaft portion 34 , that is, the tapered surface 34 a and the outer peripheral portion of the front side surface 32 a of the collar portion 32 . As shown in FIG. 2, the two built-up portions 37 and 38 are formed by drawing concentric circles.

The built-up portion 37 of the tapered surface 34a of the tip shaft portion 34 may be formed on the entire tapered surface 34a. A lower end portion 37 a of the build-up portion 37 extends to a vertical surface of the tip portion of the main body shaft portion 33 .

FIG. 5 shows an enlarged photograph of a portion of the build-up portion 38 formed on the collar portion 32. As shown in FIG. As shown in this photograph, the cemented carbide particles 39 seen in the build-up portion 38 are spherical with no corners, and the build-up portion 38 as a whole has a dense appearance.

In the cutting bit 11 configured as described above, the body shaft portion 33 is thinner than the conventional one, and is set to be 0.5 to 0.6 times the diameter of the flange portion 32, so that cutting during operation is possible. The load on the fork bit 11 is reduced, and wear is reduced. Therefore, the durability of the cutting bit 11 can be enhanced.

Further, since the thickness of the main body shaft portion 33 is not more than twice the diameter of the tip 15, the thickness of the main body shaft portion 33 can be suppressed while maintaining the strength of the main body shaft portion 33.

Moreover, since the tapered surface 34a of the tip shaft portion 34 that holds the tip 15 is formed with the built-up portion 37, the taper surface 34a is reinforced and wear of the tip shaft portion 34 can be reduced. Also from this point, the durability of the cutting bit 11 can be enhanced. Since the main body shaft portion 33 is thinner than the conventional one, the angle of the tapered surface 34a becomes steeper. Therefore, the strength of the padding portion 37 can be increased.

As described above, since the body shaft portion 33 is thin, a frictional force acts on the front side surface 32a of the flange portion 32, but the build-up portion 38 of the flange portion 32 suppresses abrasion of the flange portion 32. Also protects the holder. Since replacement of the holder is expensive, this cutting bit 11 is also beneficial in terms of increasing the durability of the holder.

Moreover, the cladding portions 37 and 38 that reinforce the surface of the bit body 13 are composed of spherical cemented carbide particles 39, and many cemented carbide particles 39 are densely arranged to form a dense structure with sharp corners. Since it is in a non-spherical state, the strength is higher than that of a conventional built-up portion made of cemented carbide particles with corners that are not spherical. Therefore, the durability can be made extremely good.

In this way, the combination of the shape of the bit body 13 and the configuration of the build-up portions 37 and 38 makes it possible to obtain excellent durability that has never been achieved before.

The above configuration is one mode for carrying out the present invention, and the present invention is not limited to the configuration described above, and other configurations can be adopted.

For example, the shape of the bit body does not have to have a flange as described above, and in that case, the portion where the build-up portion is formed is also appropriately set to a portion where friction is desired to be reduced.

DESCRIPTION OF SYMBOLS 11... Bit for cutting 13... Bit main body 15... Tip 31... Mounting shaft part 32... Collar part 32a... Front side surface 33... Main body shaft part 34... Tip shaft part 34a... Tapered surface 35... Recess 37, 38... Thickness Filling portion 37a Lower end portion 39 Cemented carbide particles

Claims (4)

A method for manufacturing a cutting bit having a build-up portion having cemented carbide particles formed on the surface of a bit body having a tip at the tip, the method comprising:
The cemented carbide particles are spherical and
The cemented carbide particles are dropped into the flow of the cladding material melted by welding to settle, and the cemented carbide particles are arranged in the cladding portion so as to reduce the gap between them.
A method of manufacturing a cutting bit. The method of manufacturing a cutting bit according to claim 1 , wherein the surface of the build-up portion is uneven due to the presence of the cemented carbide particles . As the cemented carbide particles, those having a particle size in the range of φ0.5 mm to φ2 mm are used .
3. A method for manufacturing a cutting bit according to claim 1 or 2 . A cutting bit having a built-up portion having cemented carbide particles formed on the surface of a bit body having a tip at the tip,
The cemented carbide particles are formed into a spherical shape by powder metallurgy,
While the cemented carbide particles are arranged inside the build-up portion,
Unevenness was formed on the surface of the build-up portion due to the presence of the cemented carbide particles.
bit for cutting.

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