KR100927001B1 - The bit of cutter for stone and production method thereof - Google Patents

Abstract

PURPOSE: A bit for a stone cutter and a manufacturing method thereof are provided to increase work speed while reducing the load applied and the generation amount of the fine stone powder on a motor drastically. CONSTITUTION: A bit for a stone cutter includes a super hardness-metallic layer(10) and a low hardness layer(20). The super hardness-metallic layer and the low hardness layer are laminated alternatively. A plurality of super hardness-metallic layers are prepared. The super hardness-metallic layer is formed by sintering, laminating and compressing the mixed powder. A protrusion part on the super hardness-metallic layers is formed on an edge part contacting with the low hardness layer. The protrusion is protruded toward the low hardness layer.

Description

BIT OF CUTTER FOR STONE AND PRODUCTION METHOD THEREOF}

The present invention relates to a bit which is a component of a cutter for cutting or processing stone.

Stone structures and products are preferred by consumers because they are more durable and beautiful than cement-based concrete structures and products.

Recently, the production of stone structures and products is increasing due to the consumer's preference and the development of stone processing technology.

In order to produce stone structures or products, operations to cut and process raw stones are necessary. Cutters are used for these operations.

Stone cutters are largely divided into stone cutters and stone cutters, both of which have bits.

Most of the above bits are cemented carbides made by mixing binders with tungsten carbide, compression molding and sintering. It acts or impacts the edges of the stone to make the stone fall off.

In other words, the stone cutter is a form that allows the bit as described above to repeatedly contact the stone to be cut or polished stone.

In most cases, the bit is repeatedly in contact with the stone to scrape the stone, which was a problem that generates a large amount of fine stone powder, environmental pollutants.

That is, the fine stone powder is not only difficult to recycle, but its use is very limited, and it is a substance having a problem of causing environmental pollution by being scattered even by a weak wind in the field and washed off in rainwater.

On the other hand, since the bit is a form that scrapes the stone has a problem that a very strong load is also applied to the motor for rotating the stone cutter to reduce the life of the motor and the like.

In order to solve this problem, in order to implement the bit, such as Korean Patent Application No. 10-1996-038551, a technique for placing the iron piece between the cemented carbide layer and the cemented metal layer has been devised.

The technology reduces the amount of cemented carbide powder by reducing the area of the cemented carbide layer, and the iron pieces without cutting ability are worn out before the cemented metal and are consumed so that irregularities are formed. It is a technique to form.

However, the prior art as described above has a problem that the iron piece is not firmly integrated with the cemented carbide layer, and thus the life of the bit is very short.

In particular, the bond between the cemented carbide layer and the iron piece becomes more vulnerable when subjected to heat. The stone cutter generates high heat as it rubs against the stone, so the bonding force between the cemented carbide layer and the iron piece is weaker when the cutter is used.

Due to the high heat, the binding force between the cemented carbide layer and the iron piece is weakened, so it was inevitable to slow down the work speed in cutting or processing the stone to prevent the occurrence of high heat.

On the other hand, through the prior art as described above, the effect of reducing the amount of stone powder generated or the load on the motor was only a small level.

The reason is that when the thickness of the iron piece is thick, the separation of the cemented carbide layer and the iron piece is more easily generated, and the thickness of the iron piece is inevitably reduced, and a considerable amount of stone powder is generated even when the steel piece is in contact with the stone due to its high hardness. .

In addition, in order for the parts corresponding to the iron pieces to fall off to the particle size such as sand, vibration must be generated, and as much vibration as necessary is not generated, so that stone fragments of particle size such as sand are generated. .

The present invention is to solve the above problems, and more specifically, it is possible to greatly reduce the amount of fine stone powder generation and the load on the motor, to increase the working speed, long lifespan bits for stone cutters The purpose is to provide.

In the present invention, the copper is mixed with the cemented carbide powder to form a cemented carbide metal layer, and the width of the hardness layer is reduced by forming a low hardness layer having a lower hardness than the cemented carbide layer using only copper or a mixture containing copper. It is wider than in the prior art to greatly reduce the amount of stone powder generated and the load on the motor.

In addition, even if the rotation speed of the cutter provided with the bit of the present invention is increased, the separation between the cemented carbide layer and the low hardness layer does not occur, thereby increasing the speed of cutting or processing stone and at the same time increasing the working speed of the cutter. Do not lose.

Such a bit of the present invention is a mixed powder comprising a cemented carbide powder and a copper powder or a copper powder, in which a plurality of cemented metal layers and a lower hardness layer having a lower hardness than that of the cemented metal layer are laminated in a reverse order. This sequence is stacked, compression molded and sintered to form a cemented carbide layer and a low hardness layer.

In another embodiment, a plurality of cemented carbide layers and a lower hardness layer having a lower hardness than that of the cemented carbide layer are laminated in a reverse order, but a cemented powder containing zinc powder and a copper powder in which copper powder is mixed. The superhard metal layer and the low hardness layer are formed by compressing and sintering the laminate while changing them.

Bits for the stone cutter of the present invention, the superhard metal layer of high hardness and the low hardness layer of relatively low hardness are laminated while changing the order so that copper is mixed in the cemented carbide powder, using only copper or copper The mixture containing it forms the low hardness layer of lower hardness than the cemented carbide layer.

Therefore, the bonding strength between the cemented carbide layer and the low hardness layer is excellent, so that the width of the low hardness layer can be wider than in the prior art, thereby greatly reducing the amount of stone powder generated and the load on the motor.

In addition, even if the rotational speed of the cutter provided with the bit of the present invention is increased, the separation between the cemented carbide layer and the low hardness layer does not occur, so the speed of cutting or processing the stone can be increased, and the cemented carbide layer and It has a long service life such as the low hardness layer is not separated.

Hereinafter, the technical spirit of the present invention will be described in more detail with reference to the accompanying drawings.

However, the accompanying drawings are only examples to illustrate the technical idea of the present invention in more detail, and thus the technical idea of the present invention is not limited to the accompanying drawings.

The present invention relates to a bit provided in a stone cutter for cutting or processing a stone.

In the present invention, the bit is made of cemented carbide, as is the case with ordinary bits.

By the way, if the bit is made of cemented carbide only, a large amount of stone powder is generated when cutting or processing the stone using the stone cutter, as well as a large load on the motor.

For this reason, in the present invention, the cemented carbide layer 10 and the cemented carbide layer 10 having a lower hardness than the cemented carbide layer 10 are alternately arranged so as to form a bit in a stacked form.
At this time, the cemented carbide metal layer 10 is laminated two or more times to form a plurality.

However, if the cemented carbide layer 10 and the low hardness layer 20 do not maintain a firm coupling state, they may not be able to perform the role of the bit smoothly, and lead to a problem of short life of the bit. Bits are installed, but even if only one bit of the problem occurs, the life of the cutter itself is often reached.)

The means for firmly bonding the cemented carbide metal layer 10 and the low hardness layer 20 should be such that the bonding force can be maintained even in a high temperature state.

This is because the use environment of the stone cutter is in a high temperature state.

That is, high heat is generated because the cutter is rotated at high speed in contact with the stone, and this heat is transmitted to the components of the cutter including the bit.

Of course, water or lubrication is sprayed, but that alone does not lower the heat generated.

If the rotational speed of the stone cutter is lowered in order to prevent high heat from occurring, a problem that takes longer time is required for cutting or processing the stone.

Therefore, the cemented carbide layer 10 and the low hardness layer 20 should be firmly coupled even at high temperatures.

On the other hand, even if the low hardness layer 20 has a lower hardness than the cemented carbide metal layer 10, if the hardness is too high, since a considerable amount of stone powder is generated when the low hardness layer 20 and the stone collides, the amount of stone powder generated The reducing effect is lowered.

On the other hand, if the hardness of the low hardness layer 20 is too low, significant difficulties arise in transferring or processing the stone.

In addition, the width of the low hardness layer 20 can be formed to be very narrow, the effect of reducing the amount of stone powder generated through the low hardness layer 20 and the load on the motor, etc. is very insignificant.

For this reason, in the present invention, in forming the cemented metal layer 10 and the low hardness layer 20, the mixed powder containing the cemented carbide powder and the copper powder mixed with the copper powder is laminated in alternating order to compression molding and sintering. The cemented carbide metal layer 10 and the low hardness layer 20 are formed. (Generally, cemented carbide is manufactured by compression molding and sintering cemented carbide powder mixed with tungsten carbide powder and iron powder. The description of the cemented carbide powder, the compression molding method and the sintering method are already known, so detailed description of this part is omitted.)

According to the configuration as described above, while the copper contained in the cemented carbide powder and the copper contained in the mixed powder for forming the low hardness layer 20 are bonded, the solid between the cemented carbide metal layer 10 and the low hardness layer 20. Bonding force can be obtained.

Of course, only the cemented carbide powder and the copper powder may be laminated by changing the order, compression molding, and sintering to form the cemented carbide metal layer 10 and the low hardness layer 20.

In the case of copper, it has been found to have a relatively suitable hardness and strength to achieve the object of the present invention. (Of course, when the low hardness layer 20 is formed using only copper, the width of the low hardness layer 20 may be narrowed. There are only drawbacks.)

Bits as described above, the cemented carbide metal layer 10 is in the form of scraping stone and the low-hardness layer 20 is worn by the stone but does not generate stone powder, so the processing surface of the stone and the surface of the bit is shown in Figure 2 Will be in the same state as

As the stone is processed in the state as shown in FIG. 2, the portion corresponding to the low hardness layer 20 at any moment falls to the size of the grain of sand by impact.

If the strength of the low-hardness layer 20 is too high, the low-hardness layer 20 is broken away without being worn by the stone, and if the strength is too low, considerable difficulty occurs in cutting or processing the stone.

In view of this, it has been found that copper has a very suitable hardness and strength.

In forming the low hardness layer 20 of the present invention, the use of the mixed powder in which the zinc powder is mixed with the copper powder is used to form the low hardness layer 20 using only the copper powder or mixed with other metals with copper. Better performance than that obtained was obtained.

It was found that the mixture of copper powder and zinc powder is very effective as a material for forming the low hardness layer 20 for achieving the object of the present invention.

Through various experiments, it was concluded that the proper mixing ratio of copper and zinc was 3-4: 7-6.

On the other hand, when performing the work of cutting or processing the stone using the cutter, the work of matching the center of the cutter to a specific point must be easy, so that the cutting or processing of the stone can be made conveniently and quickly.

Considering this point, in the bit of the present invention, in the superhard metal layer 10 and the low hardness layer 20 are stacked, the upper and lower symmetry around the one hard metal layer 10 or one low hardness layer 20 It is preferable that they are laminated so as to form the shape of.

That is, by setting one cemented carbide layer 10 as a reference or one cemented carbide layer 20 as a reference, setting the center of the cutter when the center of the cemented carbide layer or low hardness layer coincides with the center of the point to be processed Is to make this happen.

If the width of the cemented carbide layer 10 or the low hardness layer 20 is narrow, it is easy to match the center. (A width of about 1 mm is preferable.)

In the present invention, the cemented carbide metal layer 10 may be implemented to have a point 11 broken in the lateral direction as shown in FIG. 3.
That is, when the cemented carbide layer 10 and the low-hardness layer 20 are laminated, they are not placed to be in a vertical arrangement of the upper and lower sides, but are placed in a horizontally arranged state of left and right. The cemented metal layer 10 is to have a point 11 broken in the transverse direction.

According to this configuration, the water or lubricating liquid sprayed at the working point flows smoothly into the broken point 11 of the cemented carbide metal layer 10, and thus cutting or processing can be performed more smoothly.

In addition, the area of the cemented carbide metal layer 10 can be further reduced to reduce the amount of stone powder generated, and due to the broken point 11, an appropriate impact is applied to the stone, so that the portion corresponding to the low hardness layer 20 is sand grain size. You can make it fall smoothly.

In other words, the impact for causing the portion corresponding to the low hardness layer to fall to the size of the grain of sand should not be too strong or too weak.

If the impact is too strong, it causes a failure in components, etc. for rotating the cutter, and if the impact is too weak, the amount of fine stone powder is increased without the stone falling off well.

Water or lubricating liquid sprayed at the working point flows smoothly into the broken point 11 of the cemented carbide, and the broken point of the cemented metal so that the introduced water or lubricating fluid can be smoothly discharged together with the stone powder or the stone fragments. It is desirable to match the transverse direction as shown in FIG.
That is, the broken points 11 formed for each of the cemented carbide metal layers 10 are positioned on one straight line extending in the left and right transverse directions as the forming direction thereof so as to correspond to the left and right transverse directions.

As described above, the cemented carbide layer 10 may have the broken point 11 when the cemented metal powder and the mixed powder including copper are repeatedly stacked. Can be implemented.

In the present invention, as shown in FIG. 4, the cemented carbide metal layer 10 may be embodied in a form having a protrusion 12 at an edge portion thereof.
That is, when the cemented carbide layer 10 and the low hardness layer 20 are laid so as to be in a horizontally arranged state arranged left and right, the cemented carbide layer 10 faces the low hardness layer 20. It is to have a projection 12 protruding toward the low hardness layer 20 in the portion.

According to this configuration, not only the amount of stone powder generated by the cemented metal layer 10 can be greatly reduced, but also a shock suitable for causing a portion corresponding to the low hardness layer 20 to fall out to the size of the grains of sand can be generated.

Although the shape of the protrusion 12 as described above may be variously implemented, a shape repeatedly protruding while forming a rounded curved surface is preferable.

Having the protrusion 12 as described above in the cemented carbide metal layer 10 may be implemented by stacking the cemented carbide powder with the protrusion 12 when the cemented carbide powder is repeatedly laminated. Can be.

In the present invention, the cemented carbide metal layer 10 may be an odd number.

Reference numeral 2 is a rotating body which is a component of the cutter.

1 is a schematic diagram illustrating a bit for a stone cutter of the present invention, the bit is laid down

Figure 2 is a schematic view of the use state for explaining the state that the stone is cut or processed by the bit of the present invention

3 is a schematic diagram illustrating a bit of the present invention having a cemented carbide metal layer broken in the transverse direction;

A: perspective view of the bit lying down

B: Schematic diagram showing the surface (bottom surface) in contact with stone for cutting or processing

4 is a schematic diagram illustrating a bit of the present invention having a cemented carbide metal layer with protrusions formed thereon;

A: perspective view of the bit lying down

B: Schematic diagram showing the surface (bottom surface) in contact with stone for cutting or processing

<Explanation of symbols for main parts of drawing>

1. Stone 2. Cutter rotating body

10. Carbide metal layer 11. Broken point

12. protrusion 20. low hardness layer

Claims (8)

In the bit installed in the cutter for cutting or processing stone, The cemented carbide layer 10 and the lower hardness layer 20 having a lower hardness than the cemented carbide layer 10 are laminated and bonded in a reverse order, but a plurality of cemented carbide layers 10 are stacked and copper powder is mixed. The cemented carbide powder and the mixed powder including the copper powder or the copper powder are laminated in alternating order, compression molded and sintered to form the cemented carbide metal layer 10 and the low hardness layer 20, and the cemented carbide in the bonded state. When the metal layer 10 and the low hardness layer 20 are placed so as to be in a horizontally arranged state arranged left and right, the cemented carbide metal layer 10 has a point 11 broken in the left and right transverse directions. , Bits for stone cutters. In the bit installed in the cutter for cutting or processing stone, The cemented carbide layer 10 and the lower hardness layer 20 having a lower hardness than the cemented carbide layer 10 are laminated and bonded in a reverse order, but a plurality of cemented carbide layers 10 are stacked and copper powder is mixed. The cemented carbide powder layer and the mixed powder including zinc powder and copper powder are laminated and press-molded and sintered in alternating order to form the cemented carbide metal layer 10 and the low hardness layer 20, and the cemented carbide in the bonded state. When the metal layer 10 and the low hardness layer 20 are placed so as to be in a horizontally arranged state arranged left and right, the cemented carbide metal layer 10 has a point 11 broken in the left and right transverse directions. , Bits for stone cutters. delete delete The method according to claim 1 or 2, The broken point (11) formed for each of the cemented carbide metal layer (10) is characterized in that the same in the transverse direction of the left, right as the formation direction, a bit for a stone cutter. The method according to claim 1 or 2, When the cemented carbide layer 10 and the low hardness layer 20 are placed in a horizontally arranged state arranged left and right, the cemented metal layer 10 is disposed at an edge portion facing the low hardness layer 20. A bit for a stone cutter, characterized in that it has a projection 12 protruding toward the low hardness layer 20. The method of claim 5, When the cemented carbide layer 10 and the low hardness layer 20 are placed in a horizontally arranged state arranged left and right, the cemented metal layer 10 is disposed at an edge portion facing the low hardness layer 20. A bit for a stone cutter, characterized in that it has a projection 12 protruding toward the low hardness layer 20. delete

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