KR20120054693A - Drill bit for drilling furnace - Google Patents

Abstract

PURPOSE: A drill bit for drilling a steel making furnace is provided to reduce frictional heat while drilling by supplying cooling water to two-stage drill bits through a cooing channel, thereby minimizing the abrasion of the drill bits. CONSTITUTION: A drill bit for drilling a steel making furnace comprises a drilling rod(110), a small-diameter drill unit(120) which is formed on one end of the drilling rod, and a large-diameter drill unit(130) which is coupled to the rear side of the small-diameter drill unit by a shaft so that the center of rotation passes through the axis of the drilling rod.

Description

Drill bit for drilling furnace

The present invention, the drill bit is fixed to the axis itself without leaving the center of the exit port during the excavation process, has a two-stage bit structure so that the excavation operation can be performed at once without exchanging the bit, two-stage drill The present invention relates to a drill bit steel mill for drilling a steel mill to form a cooling passage for simultaneously supplying a coolant to the bit, thereby reducing frictional heat during excavation work so as to minimize wear of the drill bit.

In general, the iron making furnace (furnace) is the main equipment of the iron making equipment to reduce the iron ore to produce iron, and the iron ore and coke used as fuel and limestone used as a solvent alternately charged and preheated through the tuyere of the lower part of the furnace When the air is blown and burned, it is heated to a high temperature of about 1600 ° C. by the heat of coke combustion.

The hot CO gas produced by the combustion of coke goes up into the furnace, causing a chemical reaction with the iron ore and reducing the iron ore.

The molten iron reduced through the above process is accumulated in the furnace in a state containing C and other impurities Si, Mn, p, s, and the like, and the molten iron is moved through the turret and transported to the post process by opening the furnace exit.

As described above, in order to transport the molten melted state in the furnace to a post process, it is necessary to open the outlet of the furnace. The conventional technique of opening the outlet is to install a bit such as a hammer or a drill in the opening machine. A method of piercing the exit of the furnace has been used.

In particular, the size of the exit port of the furnace is determined according to the condition of the furnace in the furnace, and in the case of unstable furnace, it is necessary to form a large exit port to smooth the discharge of the melt in the furnace and stabilize the operation.

Therefore, in the case of unstable unstable, open the exit using a large diameter drill bit, but when excavating more than 3500mm, which is the depth of the exit opening with a large diameter drill bit, the excavation cross section is relatively widened and the center of the drill axis of the drill bit is twisted during the excavation. There is a problem that the starting hole is formed in an incorrect position, and because the wear of the bit due to the increase in the friction area is severe, there is a problem that the bit must be replaced in the middle without opening the tap at a time.

In this conventional technology, the outgoing blood vessels in which a small amount of molten iron is mixed in the outgoing port due to the delay of the outgoing time due to the replacement of the bit are generated, and the excavation of the outgoing port using the bit is impossible. The problem persisted.

In order to solve this problem, after performing the first excavation work using a small diameter bit, the method of performing the second excavation work using a large diameter bit has been used, but this also has a cumbersome problem. There was a limit to wear.

An object of the present invention devised to solve the problems of the prior art, so that the drill bit does not deviate from the center of the exit port during the excavation process itself is fixed to the shaft center, the excavation operation is performed at once without exchanging the bit It is to provide a drill bit for drilling in steel with a two-stage bit structure to be possible.

Another object of the present invention is to provide a drill bit for drilling by steel in order to minimize the wear of the drill bit by reducing the frictional heat during the excavation operation by forming a cooling flow path for the cooling water supply to the two-stage drill bit at the same time have.

According to one aspect of the invention, the drilling rod; A small diameter drill part formed at one end of the excavation rod; And a large diameter drill part axially coupled such that a rotational center penetrates through an axis of the excavating rod at the rear end of the small diameter drill part.

According to another aspect of the invention, the drilling rod; A small diameter drill part formed at one end of the excavation rod; A large diameter drill unit coupled to the shaft so that a rotational center passes through the drilling rod at a rear end of the small diameter drill unit; And a cooling flow path formed to simultaneously discharge the cooling water supplied through the central pipe formed at the center of the drilling rod through the large-diameter drill part and the small-diameter drill part. Can be.

Here, the small-diameter drill portion may form a first bit that is produced at a diameter of 1 to 2 times the diameter of the drilling rod at one end of the drilling rod.

In addition, the large diameter drill portion, the base plate is coupled to the axis of the drilling rod; And a second bit installed on the upper portion of the base plate and around the excavation rod.

At this time, the base plate, the planar shape is made of a triangle, so that the excavation rod is installed through the center of gravity of the triangle, a plurality of second bits are installed around the excavation rod, the second bit is Hole coupling.

In this case, the base plate may be coupled between the excavation rod and the bottom of the opposite side to which the second bit is coupled to form a plurality of ribs to improve the bearing force.

In addition, the cooling passage, the central pipe passage formed to penetrate the inside of the drilling rod in the axial direction; A first cooling passage formed in the first bit of the small-diameter drill portion to diverge the cooling water from the central conduit; A second cooling passage formed in the base plate of the large-diameter drill portion such that the cooling water is branched from the central conduit; And a third cooling passage formed in the second bit of the large-diameter drill portion to be connected to the second cooling passage.

The present invention according to the above configuration, so that the drill bit does not deviate from the center of the exit port in the excavation process itself is fixed to the shaft center, a two-stage bit structure so that the excavation operation can be performed at once without exchanging bits By providing a drill bit for drilling with steel making, it has the effect of greatly reducing the excavation work time to improve the work efficiency.

In addition, the present invention by forming a cooling flow path to the cooling water supply to the two-stage drill bit at the same time, by providing a drill bit for drilling in steelmaking to reduce the frictional heat during the excavation operation to minimize the wear of the drill bit, It can contribute to improving the durability of the bit, has the effect that the excavation work proceeds more quickly.

1 is a front view showing a drill bit according to an embodiment of the present invention.
Figure 2 is a front sectional view showing a drill bit according to an embodiment of the present invention.
3 is a plan view showing a drill bit according to an embodiment of the present invention.
Figure 4 is a bottom view showing a drill bit according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a front view showing a drill bit according to an embodiment of the present invention, Figure 2 is a front sectional view showing a drill bit according to an embodiment of the present invention.

1 and 2, a drill bit 100 for drilling in steelmaking according to a first embodiment of the present invention is disclosed.

<First Embodiment>

Drill bit for drilling steelworks 100 according to the first embodiment of the present invention is largely composed of an excavation rod 110, a small diameter drill portion 120, a large diameter drill portion 130.

First, the excavating rod 110 will be described, the excavating rod 110 is coupled to the rear end extending in the longitudinal direction is coupled to the excavator body (not shown), the axis center is the central conduit in the form of a hollow portion ( 111).

In this case, the central pipe line 111 may be used as a cooling channel for supplying cooling water to cool the frictional heat generated from the excavation surface during the excavation work.

One side of the excavation rod 110 is a small diameter drill portion 120 for excavation is formed.

The small diameter drill unit 120 will be described as follows. The small diameter drill part 120 may be configured to form a first bit 121, which is manufactured at a diameter of 1 to 2 times the diameter of the drilling rod 110 at one end of the drilling rod 110. have.

At this time, the drill tip made of a material such as diamond for cutting the excavation surface is mounted on the front end of the body of the first bit (121).

In addition, the first bit 121 may be manufactured as a single body, but there may be a plurality of bits formed of a plurality of separate bodies in one group.

At the rear end of the small diameter drill part 120, the large diameter drill part 130 is axially coupled to the center of rotation on the axis of the drilling rod 110.

The large diameter drill part 130 will be described as follows. The large-diameter drill portion 130 is composed of a configuration including a large base plate 131, and the second bit (135).

The base plate 131 is coupled on the axis of the excavating rod 110, as shown in Figure 3, 4 can be manufactured in a triangular planar shape.

At this time, the center of gravity of the excavation rod 110 is to be installed through, and the plurality of second bits 135 are installed around the excavation rod 110, the second bit 135 is a hole It may be configured to be combined.

In addition, the base plate 131 may be coupled between the excavation rod 110 at the bottom of the opposite side to which the second bit 135 is coupled, so that a plurality of ribs 133 may be formed to improve the bearing force.

At this time, the shape of the rib 133 may be a variety of forms, one of the two sides forming a right angle is bonded to the longitudinal outer surface of the excavating rod 110, the other side of the base plate 131 bottom It may be made of a bonded form.

Such ribs 133 are arranged around the excavation rod 110 to reinforce the coupling structure with the base plate 131, to improve the structural strength of the drill bit 100 to ensure a stable excavation work is made Can be.

In addition, a plurality of second bits 135 are installed around the base plate 131 and around the excavation rod 110. The second bits 135 form a cylindrical body, and the base plate After machining the hole to 131 is fixed by a method such as welding.

At this time, the second bit 135 serves to extend the secondary drilled hole by the first bit 121 to the secondary, and a drill tip for cutting the periphery of the primary drilling surface is mounted at the front end of the body. It is becoming. In this case, the shape of the drill tip mounted on the tip of the second bit 135 may have a blade shape disposed radially.

The second bit 135 may be disposed at the outermost center of the rotation center of the base plate 131, that is, at each corner of the triangle, and a plurality of the second bits 135 may be disposed to be closer to the excavation rod 110.

At this time, the rotation radius (excavation radius) of the second bit 135 disposed on the base plate 131 and the rotation radius (excavation radius) of the second bit 135 disposed close to the excavation rod 110 are partially. It is preferable to arrange the regions so that the regions can overlap each other, and in particular, the rotation radius (excavation radius) of the second bit 135 and the rotation radius (excavation radius) of the first bit 121 are disposed close to the excavation rod 110. It is preferable to arrange so that a partial area may overlap.

Hereinafter, with reference to FIGS. 1 and 2, the drill bit 100 for drilling steelworks according to the second embodiment of the present invention will be described.

Second Embodiment

Drill bit for drilling steelworks 100 according to a second embodiment of the present invention is largely made of a configuration including an excavation rod 110, a small diameter drill portion 120, a large diameter drill portion 130, cooling passages .

First, the excavating rod 110 will be described, the excavating rod 110 is coupled to the rear end extending in the longitudinal direction is coupled to the excavator body (not shown), the axis center is the central conduit in the form of a hollow portion ( 111).

In this case, the central pipe line 111 may be used as a cooling channel for supplying cooling water to cool the frictional heat generated from the excavation surface during the excavation work.

One side of the excavation rod 110 is a small diameter drill portion 120 for excavation is formed.

The small diameter drill unit 120 will be described as follows. The small diameter drill part 120 may be configured to form a first bit 121, which is manufactured at a diameter of 1 to 2 times the diameter of the drilling rod 110 at one end of the drilling rod 110. have.

At this time, the drill tip made of a material such as diamond for cutting the excavation surface is mounted on the front end of the body of the first bit (121).

In addition, the first bit 121 may be manufactured as a single body, but there may be a plurality of bits formed of a plurality of separate bodies in one group.

At the rear end of the small diameter drill part 120, the large diameter drill part 130 is axially coupled to the center of rotation on the axis of the drilling rod 110.

The large diameter drill part 130 will be described as follows. The large-diameter drill portion 130 is composed of a configuration including a large base plate 131, and the second bit (135).

The base plate 131 is coupled on the axis of the excavating rod 110, as shown in Figure 3, 4 can be manufactured in a triangular planar shape.

At this time, the center of gravity of the excavation rod 110 is to be installed through, and the plurality of second bits 135 are installed around the excavation rod 110, the second bit 135 is a hole It may be configured to be combined.

In addition, the base plate 131 may be coupled between the excavation rod 110 at the bottom of the opposite side to which the second bit 135 is coupled, so that a plurality of ribs 133 may be formed to improve the bearing force.

At this time, the shape of the rib 133 may be a variety of forms, one of the two sides forming a right angle is bonded to the longitudinal outer surface of the excavating rod 110, the other side of the base plate 131 bottom It may be made of a bonded form.

Such ribs 133 are arranged around the excavation rod 110 to reinforce the coupling structure with the base plate 131, to improve the structural strength of the drill bit 100 to ensure a stable excavation work is made Can be.

In addition, a plurality of second bits 135 are installed around the base plate 131 and around the excavation rod 110. The second bits 135 form a cylindrical body, and the base plate After machining the hole to 131 is fixed by a method such as welding.

At this time, the second bit 135 serves to extend the secondary drilled hole by the first bit 121 to the secondary, and a drill tip for cutting the periphery of the primary drilling surface is mounted at the front end of the body. It is becoming. In this case, the shape of the drill tip mounted on the tip of the second bit 135 may have a blade shape disposed radially.

The second bit 135 may be disposed at the outermost center of the rotation center of the base plate 131, that is, at each corner of the triangle, and a plurality of the second bits 135 may be disposed to be closer to the excavation rod 110.

At this time, the rotation radius (excavation radius) of the second bit 135 disposed on the base plate 131 and the rotation radius (excavation radius) of the second bit 135 disposed close to the excavation rod 110 are partially. It is preferable to arrange the regions so that the regions can overlap each other, and in particular, the rotation radius (excavation radius) of the second bit 135 and the rotation radius (excavation radius) of the first bit 121 are disposed close to the excavation rod 110. It is preferable to arrange so that a partial area may overlap.

In the second embodiment of the present invention, the cooling water supplied through the central conduit 111 formed at the center of the drilling rod 110 is simultaneously discharged through the large diameter drill part 130 and the small diameter drill part 120. A cooling flow path is formed.

The cooling flow path may include a central conduit 111 formed to penetrate the inside of the excavation rod 110 in the axial direction, and a first bit of the small diameter drill part 120 to diverge the cooling water from the central conduit 111. The first cooling passage (121a) formed in the 121 and the second cooling passage 131 and the second cooling passage formed in the base plate 131 of the large diameter drill portion 130 so that the cooling water branched from the central pipe (111) And a third cooling passage 135a formed in the second bit 135 of the large-diameter drill part 130 so as to be connected to the second cooling passage 131.

In this case, the first cooling passage 121a formed in the first bit 121 extends in the vertical direction with the central passage 111 and may simultaneously form one passage or a plurality of passages, and discharges through the passage. The cooling water may be discharged in the front and side directions of the first bit 121.

The second cooling passage 131 communicates with the central pipe 111 by processing a drill groove in a horizontal direction from the side of the base plate 131 in a state in which the base plate 131 and the excavating rod 110 are coupled to each other. It may be formed to. At this time, the side surface of the base plate 131 of the drilled second cooling passage 131 may be blocked by a separate operation so that the coolant may not leak.

In addition, the third cooling passage 135a is formed to penetrate the second bit 135 in the vertical direction. The second cooling passage 135 is provided by installing the second bit 135 at a position passing through the second cooling passage 131. The passage 131 and the third cooling passage 135a may communicate with each other.

In this case, the third cooling passage 135a may simultaneously form one passage or a plurality of passages, and the cooling water discharged through the passages may be discharged in the front and side directions of the second bit 135.

As described above, the present invention allows the drill bit to be fixed on its own axis without being separated from the center of the exit port during the excavation process, and has a two-stage bit structure so that excavation work can be performed at once without exchanging the bit. By providing drill bits for drilling in steelmaking, the drilling time is greatly reduced, and the working efficiency is improved, and the cooling flow path is formed to simultaneously supply the coolant to the two-stage drill bit, thereby reducing the frictional heat during the drilling operation. By providing a drill bit for drilling in steel, which minimizes the wear of the bit, it can contribute to improving the durability of the drill bit, and the excavation can be performed more quickly.

100: drill bit 110: drilling rod
111: central pipe line 120: small diameter drill section
121: first bit 121a: first cooling passage
130: large diameter drill part 131: base plate
131: second cooling passage 133: rib
135: second bit 135a: third cooling passage

Claims (7)

Excavation rod 110;
A small diameter drill part 120 formed at one end of the excavation rod 110; And
Large-diameter drill portion 130 is coupled to the axis of rotation through the axis of the drilling rod 110 at the rear end of the small diameter drill portion 120;
Drill bits for drilling in steelmaking comprising a.
Excavation rod 110;
A small diameter drill part 120 formed at one end of the excavation rod 110;
Large-diameter drill portion 130 is coupled to the axis of rotation through the axis of the drilling rod 110 at the rear end of the small diameter drill portion 120; And
Cooling flow path is formed so as to simultaneously discharge the cooling water supplied through the central pipe 111 formed in the center of the drilling rod 110 through the large diameter drill portion 130 and the small diameter drill portion 120;
Drill bits for drilling in steelmaking comprising a.
The method according to claim 1 or 2,
The small diameter drill part 120,
Drill bits for drilling in steelmaking, characterized in that to form a first bit 121 to be produced in a diameter of 1 to 2 times the diameter of the drilling rod 110 at one end of the drilling rod 110.
The method according to claim 1 or 2,
The large diameter drill part 130,
A base plate 131 coupled to the shaft of the drilling rod 110; And
A second bit 135 installed on the upper portion of the base plate 131 and around the excavation rod 110;
Drill bits for drilling in steelmaking comprising a.
The method of claim 4, wherein
The base plate 131,
Planar shape is made of a triangle, the center of gravity of the triangle to be installed through the excavating rod 110, a plurality of second bit 135 is to be installed around the excavating rod 110, the second Drill bits for drilling in steelmaking, characterized in that the bit 135 is to be hole-coupled.
The method of claim 5, wherein
The base plate 131,
Drill bits for drilling of steel mills, characterized in that a plurality of ribs (133) for improving the coupling support force is formed between the excavating rod (110) on the bottom surface opposite to the second bit (135).
The method of claim 2,
The cooling passage, the central pipe passage 111 formed to penetrate the inside of the excavation rod 110 in the axial direction;
A first cooling passage (121a) formed in the first bit (121) of the small diameter drill portion (120) so that the cooling water branches from the central conduit (111);
A second cooling passage 131 formed in the base plate 131 of the large-diameter drill part 130 such that the cooling water is branched from the central conduit 111; And
A third cooling passage 135a formed in the second bit 135 of the large-diameter drill part 130 so as to be connected to the second cooling passage 131;
Drill bits for drilling in steelmaking comprising a.

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