KR20240000322U - Multipurpose Drill Bit - Google Patents

Abstract

The present invention relates to a drill bit with improved chip ejection function, in which four bit blades are formed to protrude from the lower part of the bit body, and one first groove is formed in the middle of the bit blades in symmetrical positions. , Two second grooves are formed at the upper and lower ends of the remaining two bit blades, and the first groove and the second groove are formed alternately, which occurs in the process of drilling an object using the bit blade. The chip is moved to the first groove formed in the middle of the bit blade through the second groove formed in the lower end of the bit blade, and the chip moved to the first groove is moved to the bit blade through the second groove formed in the upper end of the bit blade. Because it moves upward, it is possible to facilitate the discharge of chips, which prevents the drill bit's drill bit drilling speed and rotational speed from decreasing, while also preventing the bit blade from overheating and changing physical properties as much as possible. A blade surface inclined in the opposite direction to the direction in which the bit is rotated can be formed on the outer surface of the bit blade to facilitate drilling of objects, and a pair of guided discharges are provided on the outer peripheral surface of the bit body where the bit blade is provided at the bottom. The groove is formed in a spiral shape so that chips discharged to the top of the bit blade through the first groove and the second groove can be easily discharged to the outside of the bit.

Description

Drill bit with improved chip evacuation function { Multipurpose Drill Bit }

The present invention relates to a drill bit with improved chip ejection function, and more specifically, four bit blades are formed to protrude from the lower part of the bit body, and one first blade is formed in the middle of the bit blades in symmetrical positions. A groove is formed, and two second grooves are formed at the upper and lower ends of the remaining two bit blades. By forming the first groove and the second groove alternately, the bit blade can be used to cut an object, especially a ceramic product. Chips generated in the process of drilling high-density products in powder form, such as jars and glass, move to the first groove formed in the middle of the bit blade through the second groove formed in the lower part of the bit blade. Since the chips moved to the first groove are moved to the top of the bit through the second groove formed at the upper end of the bit blade, chip discharge can be facilitated, which reduces the drill bit's drilling speed and rotation speed. It is possible to prevent the bit blade from overheating and change its physical properties as much as possible, and by forming a blade surface inclined in the opposite direction to the direction in which the bit is rotated on the outer surface of the bit blade, it is possible to drill an object. This can be facilitated, and a pair of guided discharge grooves are formed in a spiral shape on the outer peripheral surface of the bit body where the bit blade is provided at the bottom, so that the chips discharged to the top of the bit blade through the first groove and the second groove are discharged from the bit. This relates to a drill bit with an improved chip ejection function that allows for easy ejection to the outside.

In general, a drill bit is mounted on a rotating tool and used to drill an object.

A conventional drill bit consists of a lead portion and a blade portion formed below the lead portion.

A fixing part that is fixed to the chuck of the rotary tool is formed at the top of the lead part, and a blade part for drilling an object is formed at the bottom of the lead part.

Therefore, while the fixing part provided in the lead part is coupled to the chuck of the rotary tool, the blade part is used to drill an object.

However, the problem with conventional drill bits is that the chips generated in the process of drilling an object using the blade cannot be discharged to the outside, so the rotation speed of the drill bit is lowered, which makes drilling difficult to do efficiently. This happened.

In addition, in the process of using a drill bit to drill an object, especially high-density products such as ceramic products, jars, and glass, in which chips are generated in powder form, the chips generated remain inside the object, causing friction between the blade and the object. This increases, and as a result, the problem of deformation occurs due to a decrease in the physical properties of the blade part.

◈ Prior art literature ◈

Korean Patent Publication No. 10-2012-0052093

Therefore, in the present invention to solve the above problem, four bit blades are formed to protrude from the lower part of the bit body, one first groove is formed in the middle of the bit blades in symmetrical positions, and the remaining two grooves are formed in the middle of the bit blades in symmetrical positions. Two second grooves are formed at the upper and lower ends of the bit blades. By forming the first grooves and the second grooves alternately, the bit blades can be used to chip objects such as ceramic products, jars, and glass. The chips generated in the process of drilling this high-density product in powder form are moved to the first groove formed in the middle of the bit blade through the second groove formed in the lower part of the bit blade, and into the first groove. Since the moved chip is moved to the upper part of the bit through the second groove formed at the upper end of the bit blade, it is possible to facilitate the discharge of the chip, thereby preventing the drill bit's perforation speed and rotation speed from being lowered. It is possible to prevent the bit blade from overheating and changing physical properties as much as possible, and by forming a blade surface inclined in the opposite direction to the direction in which the bit is rotated on the outer surface of the bit blade, it is possible to facilitate drilling of objects. A pair of guided discharge grooves are formed in a spiral shape on the outer peripheral surface of the bit body, where the bit blade is provided at the bottom, so that chips discharged to the top of the bit blade can be easily discharged to the outside of the bit through the first groove and the second groove. The purpose is to provide a drill bit with improved chip evacuation function.

The present invention to solve the above problem is,

In a multi-purpose drill bit including a bit consisting of a bit body and four drilling bit blades,

The bit blade is formed radially to protrude from the lower outer side of the bit body,

One first groove is formed in the middle of the bit blade formed at a position symmetrical to each other,

Form two second grooves at the upper and lower ends of the remaining two bit blades,

The formation positions of the first groove and the second groove are offset from each other, so that the chips generated in the process of drilling an object using a bit blade easily flow through the first groove and the second groove and are in the upper part of the bit blade. It is characterized in that it is configured to be discharged to.

According to the present invention, four bit blades are formed to protrude from the lower part of the bit body, one first groove is formed in the middle of the bit blades in symmetrical positions, and the upper and lower portions of the remaining two bit blades are formed. In forming two second grooves, the first groove and the second groove are formed alternately with each other, and the bit blade is used to produce high-density chips in powder form from objects such as ceramic products, jars, and glass. Chips generated in the process of drilling a product are moved to the first groove formed in the middle of the bit blade through the second groove formed in the lower part of the bit blade, and the chips moved to the first groove are of the bit blade. Since it moves to the top of the bit through the second groove formed at the top, the effect of facilitating chip ejection can be expected.

In addition, since chips are discharged to the outside through the first groove and the second groove, it is possible to prevent the perforation speed and rotation speed of the drill bit from decreasing during the process of drilling the object, and the bit blade is overheated and the physical properties change. You can expect the effect of preventing this from happening as much as possible.

In addition, a blade surface inclined in the opposite direction to the direction in which the bit is rotated is formed on the outer surface of the bit blade to facilitate drilling of the object.

In addition, a pair of guided discharge grooves are formed in a spiral shape on the outer peripheral surface of the bit body where the bit blade is provided at the bottom, so that chips discharged to the top of the bit blade through the first groove and the second groove can easily be discharged to the outside of the bit. You can expect effective results.

Figure 1 is a perspective view of the drill bit of the present invention.
Figure 2 (a) is a front view of the drill bit of the present invention.
Figure 2 (b) is a top view of the drill bit of the present invention.
3 to 5 are diagrams showing the operating state of the drill bit of the present invention.
Figure 6 is a diagram showing the state of use of the present invention.

Hereinafter, a preferred embodiment of the present invention will be described using the attached FIGS. 1 to 6 as follows.

According to the drawing, the present invention is,

In the multi-purpose drill bit including a bit (10) consisting of a bit body (20) and four drilling bit blades (30),

The bit blade 30 is formed radially to protrude from the lower outer side of the bit body 20,

One first groove 50 is formed in the middle of the bit blade 30 formed at a position symmetrical to each other,

Two second grooves (51) are formed at the upper and lower ends of the remaining two bit blades (30),

The formation positions of the first groove 50 and the second groove 51 are formed to be offset from each other, so that the chips generated in the process of drilling the object using the bit blade 30 are formed in the first groove 50 and the second groove 51. 2 It is characterized in that it is configured to be discharged to the upper part of the bit blade (30) while easily flowing through the groove (51).

A blade surface 40 inclined in a direction opposite to the direction in which the bit 10 is rotated is further formed on the outer surface of the bit blade 30.

A pair of guided discharge grooves 60 are formed in a spiral shape on the outer peripheral surface of the bit body 20.

The present invention relates to a drill bit 10 that is coupled to a rotating tool and used to drill an object, as shown in FIG. 6.

Objects to be drilled using the bit 10 include fragile tiles, marble, glass, jars, bricks, etc.

The bit 10 is roughly divided into a bit body 20 formed in the longitudinal direction as shown in FIG. 1 and a bit blade 30 formed at the lower part of the bit body 20.

A hexagon-shaped engaging part 21 is formed on the upper part of the bit body 20, and a coupling groove 22 is formed in an annular shape to be spaced apart from the top of the engaging part 21, so that it is attached to the chuck provided in the rotary tool. Combine so that the coupling groove (22) is inserted.

The bit blades 30 are formed radially to protrude from the lower part of the bit body 20 as shown in FIG. 1 .

At this time, the lower part of the bit blade 30 is formed in a semi-circular shape so that the tip portion 31 is provided at the lower end of the bit blade 30.

The tip portion 31 provided at the bottom of the bit blade 30 allows the drilling operation to be performed by positioning the bit 10 at the desired position by allowing the lower end of the bit 10 to be driven in as much as possible when drilling the object for the first time. Let it happen.

On the outer peripheral surface of the bit blade 30 formed in this way, a blade surface 40 inclined in the opposite direction to the direction in which the bit 10 is rotated is formed.

By forming a blade surface 40 inclined in the opposite direction to the direction in which the bit 10 is rotated on the outer peripheral surface of the bit blade 30, the outer peripheral surface of the bit blade 30 can be formed sharp, thereby allowing the object to be Allows drilling work to be done while minimizing the contact area.

On the blade surface 40 provided on the outer surface of the bit blade 30, a first groove 50 and a second groove 51 having a triangular side cross section are formed at different heights.

The first groove 50 is formed in the center of the outer surface of the blade surface 40 of the bit blade 30 that is symmetrical to each other as shown in Figure 2, and the second groove 51 is formed on the blade surface of the remaining two bit blades 30. They are formed at the upper and lower ends of the outer surface of the surface 40, respectively.

Accordingly, the first grooves 50 and the second grooves 51 provided on the bit blade 30 are formed alternately at different heights.

That is, the bit blade 30 consists of a first blade body 31 and a second blade body 32 that are symmetrical to each other as shown in (b) of Figure 2, and in the middle of the first blade body 31, A first groove 50 is formed as shown in (a) of 2, and second grooves 51 are formed in the lower and upper ends of the second blade body 32.

Accordingly, the first groove 50 and the second groove 51 are formed on the outer surface of the bit blade 30 at different heights and staggered with each other.

Meanwhile, a guided discharge groove 60 is formed in a spiral shape on the outer peripheral surface of the bit body 20 provided at the lower part of the bit blade 30, and the guided discharge grooves 60 are formed in a pair.

The preferred operating state of the present invention configured in this way is described as follows.

First, with the bit 10 coupled to the chuck of the rotary tool as shown in FIG. 5, the tip 31 provided at the bottom of the bit blade 30 is brought into contact with an object (ceramic product, jar, ceramics, glass, etc.) do.

When the tip 31 comes into contact with an object, the bit 10 is rotated using a rotating tool.

As the bit 10 receives the rotational force of the rotary tool and rotates clockwise as shown in FIG. 3, while drilling the object using the bit 10, the powder-type chips generated on the object are pierced by the bit blade. It is discharged to the outside through the first groove 50 and the second groove 51 provided in (30).

In this way, if the chips generated in the object are discharged to the outside through the first groove 50 and the second groove 51, using FIGS. 3 to 5, it will be explained,

The chip generated on the object by the bit blade 30 is connected to the first blade body 31 by the second groove 51 provided at the lower end of the second blade body 32 constituting the bit blade 30. It flows into the space (G) provided between and the second blade body (32).

The chips flowing into the space G between the first blade body 31 and the second blade body 32 are adjacent to the space (G) by the first groove 50 formed in the middle of the first blade body 31 ( It flows into G1).

And the chips flowing into the neighboring space (G1) flow into the neighboring space (G) through the second groove 51 provided at the upper end of the second blade body 32, and the chips flowing into the space (G) The chip is moved to the top of the bit blade (30).

In this way, the chips moved to the upper surface of the bit blade 30 are discharged to the top of the object through a pair of guided discharge grooves 60 formed in a spiral shape on the outer peripheral surface of the bit body 20, although not shown in the drawing.

10: bit, 20: bit body,
21: coupling portion, 22: coupling groove,
30: bit blade, 31: first blade body,
32: second blade body, 40: blade surface,
50: first groove, 51: second groove,
60: Guided discharge groove, G: Space

Claims (3)

In the multi-purpose drill bit including a bit (10) consisting of a bit body (20) and four drilling bit blades (30),
The bit blade 30 is formed radially to protrude from the lower outer side of the bit body 20,
One first groove 50 is formed in the middle of the bit blade 30 formed at a position symmetrical to each other,
Two second grooves (51) are formed at the upper and lower ends of the remaining two bit blades (30),
The formation positions of the first groove 50 and the second groove 51 are formed to be offset from each other, so that the chips generated in the process of drilling the object using the bit blade 30 are formed in the first groove 50 and the second groove 51. 2 A drill bit with improved chip ejection function, characterized in that it is configured to easily flow through the groove (51) and be discharged to the top of the bit blade (30).
The method of claim 1,
A drill bit with improved chip ejection function, characterized in that a blade surface (40) inclined in the direction opposite to the direction in which the bit (10) is rotated is further formed on the outer surface of the bit blade (30).
The method of claim 1,
A drill bit with improved chip discharge function, characterized in that a pair of guided discharge grooves (60) are formed in a spiral shape on the outer peripheral surface of the bit body (20).

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