KR20130019595A - Tap hole excavation apparatus - Google Patents

Abstract

PURPOSE: An iron notch excavating apparatus is provided to pulverize excavated refractories by generating relative rotation of a dual drilling bit, thereby facilitating removal of the refractories. CONSTITUTION: An iron notch excavating apparatus(50) comprises a dual rotation type excavating member(60) and a rotation transfer member(52). The dual rotation type excavating member has an excavating member having a dual structure where a drilling bit is included and is able to move relatively according to the rotation direction. The rotation transfer member is connected to the dual rotation type excavating member. The dual rotation type excavating member comprises a first rotation part(62) which excavates refractories corresponding to the outer circumference; a counter rotation connection keeping part(65) which keeps the connection between the first rotation part and the rotation transfer part in a relatively movable manner; a second rotation part(72) which is fixed to the rotation transfer part inside the first rotation part and excavates or pulverizes refractories. The counter rotation connection keeping part includes a spiral connecting part(66) which has a certain length and is installed on one end of the rotation transfer part; a cross section reduction part(67) which moves along the spiral connection part by using a screw thread for link with the spiral connecting part and is installed on the other end of the first rotation part; a front holding part and a back holding part which restrict movement of the cross section reduction part in the axial direction and is installed in the rotation transfer member.

Description

Outlet Excavator {TAP HOLE EXCAVATION APPARATUS}

The present invention relates to an outlet drilling apparatus for facilitating the discharge of refractory dust generated in the process of excavating the outlet of the blast furnace.

In general, when the blast furnace is charged with iron ore, and the heating port is blocked with a refractory and heated, the iron ore is reduced and made into a melt. Then, the molten steel in which the iron ore is molten is collected in the lower part of the blast furnace, and the molten steel is discharged to the outside by passing through the outlet through the air hole, which is a tap opening device.

Referring to FIG. 1, the conventional exit port 2 penetrates a lower portion of the blast furnace 1, and is constructed of a refractory lead 4 so as to withstand a melt therein. Then, the outside of the refractory softening (4) is blocked by the stamp material refractory (6) such as mud.

On the other hand, the refractory material 6 attached to the outlet opening 2 may be oxidized, or may be generated as a long pause during repair work such as shock and large water supply 20 delivered during the opening and closing of the outlet opening. Shrinkage and expansion are repeated due to temperature variation due to the temperature decrease, and in this process, a large amount of blast furnace gas is ejected due to cracks caused by breakage of the refractory material 6, resulting in collapse or partial dropping of the stamp refractory material 6 in the center of the exit port. In order to prevent the opening of the outlet 2 repair work is being done.

Outlet excavation operation is carried out to excavate the refractory 6 filled in the outlet opening 2 during the conventional outlet repair work.

In the conventional tap-hole excavation work, as shown in FIG. 2, first, the center axis of the tap-out port 2, that is, the center, is set using the tap-out bit 10. Then, using a drilling machine equipped with an excavation bit, the periphery is moved around the exit center to excavate a plurality of holes. Next, in the state of mounting the excavation connection bit crusher (20) in the opening, insert into the center of the exit port (2) and proceeds the crushing, excavation work of the refractory (6).

However, conventionally, when the excavation work of the tap opening 2 using the opening machine is not constant, the refractory remains in a part of the tap opening 2, and the worker uses the excavating tool to remove the refractory which is not made. It is being removed.

However, in the related art, as the space is narrowed at the excavation part of the exit port 2, the excavation bit or the excavation connection bit crusher 20 of the opening machine is caused to be bitten by the excavation surface, and thus cannot be rotated. The mass is not discharged from the excavation bit or the excavation connection bit crusher 20, but the work to remove the refractory by the manual work is performed in parallel.

As such, in the prior art, the excavation of the tap opening 2 has a limitation in the excavation by the opening hole, and as the work is progressed by the worker, a long time is required for the excavation for a long time. May leak, increasing the workload.

In addition, the conventional exit repair work can be carried out only during the regular repair period of the blast furnace, and this causes the gas leakage or high-temperature dust in the exit port due to the delay of the exit repair time, which contaminates the working environment. It is becoming.

An embodiment of the present invention is to form an excavation bit in a double structure for the removal of the refractory blocking the exit port, the relative rotation occurs in the excavation bit of these dual structure and to crush the excavated refractory to be easily taken out An object of the present invention is to provide a tapping equipment.

Excavation hole excavation device according to an aspect of the present invention is provided with a double structure of the excavation bit provided with the excavation bit is a dual rotation type excavation member provided to be movable relative to the rotation direction; And a rotational transmission member to which the dual rotational excavating member is coupled.

The dual-rotating excavating member is provided to correspond to the outer diameter portion of the exit port and the first rotation part for excavating the refractory, and the rotation-coupling coupling for maintaining the coupling so that the first rotation part and the rotation transfer member can be moved relative to the rotation A holding unit and a second rotating unit which is fixed to the rotating transmission member inside the first rotating unit to excavate or crush the refractory.

In addition, the rotation-adaptive coupling retaining portion is provided with a spiral coupling portion provided on one side of the rotational transmission member with a predetermined length, the other end of the first rotating portion is provided with a screw thread so as to be bitten with the spiral coupling portion is the spiral coupling It may include a cross-sectional reduction portion moving along the portion, and the front end and the rear end engaging portion provided to the spiral coupling portion or the rotary transfer member to limit the axial movement of the cross-sectional reduction portion.

The first rotating part and the second rotating part may each include an opening part provided to discharge refractory, and the opening part may be formed to be rounded at one rear side.

According to one embodiment of the present invention, the dual rotation type drilling member is rotated or reverse rotation is made in the drilling bit, and the refractory remaining inside the double rotation type drilling member can be crushed and easily discharged to the outside.

In addition, in the present embodiment, the double rotation excavation member is excavated twice in the process of excavating the refractory of the exit port, thereby reducing the excavation load generated in the excavation member is not narrow the space of the excavation site Therefore, the drilling performance can be improved, and the durability of the drilling member can be increased.

1 is a cross-sectional view schematically showing the exit port of the blast furnace according to the prior art.
Figure 2 (a) and (b) is a view showing the exit hole excavation process according to the prior art.
Figure 3 is a perspective view of the outlet opening excavation apparatus according to an embodiment of the present invention.
Figure 4 is a perspective view showing a portion of the outlet opening excavation apparatus according to an embodiment of the present invention.
Figure 5 is a cross-sectional view of the tapping hole excavation device according to an embodiment of the present invention.
Figure 6 is a cross-sectional view of the exit hole excavation device according to an embodiment of the present invention in a forward rotation state.
Figure 7 is a cross-sectional view of the starting hole excavation device is a forward rotation according to an embodiment of the present invention.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings. The embodiments of the present invention can be modified into various other forms, and the scope of the present invention is not limited to the embodiments described below. The shape and the size of the elements in the drawings may be exaggerated for clarity and the same elements are denoted by the same reference numerals in the drawings.

Figure 3 is a perspective view of the tapping hole excavation device according to an embodiment of the present invention, Figure 4 is a perspective view showing a part of the tapping hole excavation device according to an embodiment of the present invention cut. In addition, Figure 5 is a cross-sectional view of the tapping hole excavation device according to an embodiment of the present invention.

Referring to Figures 3 to 5, the tapping hole excavation device 50 of the present embodiment can be mounted on a tap opening opening (not shown) for removing the refractory 6 and the like attached to the tap opening 2. .

The outlet opening excavation device 50 may include a rotational transmission member 52 which is provided to be mounted to the outlet opening and is rotated by the opening.

Rotational transmission member 52 may be provided in the form of a long rod in one direction, and can be transmitted to the rotational force generated by the driving device of the opener as it is mounted in the opener.

In addition, the rotation transfer member 52 may be provided with an excavation member for removing the refractory attached to the tap opening (2).

In this embodiment, the excavation member may include a double-rotating excavation member 60 provided with an excavation portion provided in a double structure with an excavation bit.

The double-rotating excavating member 60 may be provided to be relatively movable in different directions in a predetermined section of the excavating portion provided in duplicate in accordance with the rotation direction of the rotation transmission member 52.

The double-rotating excavation member 60 configured as described above may be excavated or crushed refractory by rotating in the same direction with each other provided in the excavation portion provided in a double in accordance with the rotation direction of the rotation transmission member 52. In addition, when the rotational direction of the rotational transmission member 52 is changed, the dual rotation type excavation member 60 may rotate in a different direction, and the double excavation member 60 may be rotated in this process. Refractories remaining inside and not discharged may be crushed, and thus discharge to the outside may be easily performed.

In the present embodiment, the dual rotation type drilling member 60 may include a first rotation part 62 provided to correspond to the outer diameter portion of the tap hole 2. The first rotating part 62 may be provided as a cylindrical drum having an open direction toward the exit port 2.

In addition, a second rotation part 72 may be provided inside the first rotation part 62 to be fixed to the rotation transmission member 52. The second rotating unit 72 may be provided as a cylindrical drum having an open direction toward the exit opening 2, like the first rotating unit 62. In addition, the second rotating unit 72 may have a smaller outer diameter and a shorter protruding length than the first rotating unit 62.

In addition, the second rotation part 72 has a shape in which the opposite direction of the outlet port 2 extends in the axial direction and is blocked, and an end thereof may be fixed to the rotation transmission member 52 by welding or a fastening member.

Meanwhile, the first rotation part 62 and the rotation transmission member 52 may be relatively moved in accordance with the rotation direction of the rotation transmission member 52 while maintaining the coupling between the first rotation part 62 and the rotation transmission member 52. Rotation-adaptive coupling retaining portion 65 may be provided.

Rotation-adaptive coupling retaining portion 65, when the rotational transmission member 62 rotates in the forward direction, after moving the first rotation portion 62 a predetermined distance, and maintains a fixed state, in this state The first rotating part 62 contacts (2) to excavate the refractory 6.

On the other hand, the rotation-responsive coupling holding portion 65 may include a spiral coupling portion 66 formed with a spiral portion at a predetermined length on one side of the rotation transmission member 52.

In one example, the spiral coupling portion 66 may be integrally formed on one side of the rotational transmission member 52, it is also possible to be coupled to the rotational transmission member 52 consisting of a separate member formed with a spiral portion on the outer peripheral surface.

In addition, the other end of the first rotating part 62 may be provided with a cross-sectional reduction part 67 to be bitten and coupled to the spiral coupling portion. To this end, the inner circumferential surface of the cross-sectional reduction portion 67 may be provided with a thread that is engaged with the spiral portion of the spiral coupling portion 66.

The first rotation part 62 may rotate in the threaded direction of the cross-sectional reduction part 67 along the spiral part of the spiral coupling part 66 and move in the longitudinal direction of the rotational transmission member 52.

6 is a cross-sectional view of the exit hole drilling apparatus according to an embodiment of the present invention in a forward rotation state, and FIG. 7 is a cross-sectional view of the exit hole drilling apparatus in a forward rotation state according to an embodiment of the present invention.

Referring to FIG. 6, when the rotational transmission member 52 rotates in the forward direction while the first rotation part 52 is in contact with the excavation surface of the tap hole 2, the first rotation part 52 is a cross-sectional reduction part 67. ) Rotates in a reverse direction along the spiral coupling portion 66 and is fixed and maintained in a state of advancing a predetermined distance, after which the first rotating portion 52 rotates in the forward direction again to excavate the excavation surface of the outlet 2. .

To this end, one side of the spiral coupling portion 66 or the rotational transmission member 52, for example, on the front moving line of the first rotating portion 62 to reduce the cross-sectional reduction portion 67 to limit the movement of the first rotating portion (62) A shearing portion 68 may be provided that engages the front end of and limits the movement. For example, the shear catching portion 68 may be provided as a protrusion such as a pin member provided on one side of the spiral coupling portion 66 or the rotational transmission member 52, and is formed stepwise at the front end portion of the spiral coupling portion 66. Or may be provided without a spiral portion.

In addition, when the rotational transmission member 52 is rotated in the forward direction, the second rotation unit 72 rotates in the forward direction together with the rotational transmission member 52 to excavate the excavation surface of the tap hole 2 or by the first rotational unit 62. The excavated refractory can be broken up.

On the other hand, as shown in FIG. 7, when the first rotation part 62 rotates in the opposite direction, the first rotation part 62 has the cross-sectional reduction part 67 as the spiral coupling part 66. Rotation in the forward direction and is fixed and maintained in a retracted state by a predetermined distance, after which the first rotation unit 52 can be rotated in the reverse direction again to excavate the excavation surface of the outlet (2).

To this end, the cross-sectional reduction portion 67 to limit the movement of the first rotating portion 62 on the other side of the spiral coupling portion 66 or the rotational transmission member 52, for example on the rear movement line of the first rotating portion 62; A rear end catching portion 69 that engages with the rear end of and restricts movement can be provided.

In addition, during the reverse rotation of the rotation transmission member 52, the second rotation unit 72 rotates in the reverse direction together with the rotation transmission member 52 to excavate the excavation surface of the tap hole (2) or by the first rotation unit 62 The excavated refractory can be broken up.

As described above, the tapping hole excavation device 50 of the present embodiment has a rotation direction of the first rotation part 62 for a predetermined time during the rotation or rotation of the rotation transmission member 52 in the forward direction. It rotates in the opposite direction, and in this process it is possible to easily crush the refractory in the form of large lumps remaining between the first rotation part 62 and the second rotation part 72.

In addition, in the present embodiment, the outlets 64 and 74 for discharging the excavated refractory may be provided at the side surfaces, ie, the circumferential surfaces of the first and second rotary parts 62 and 72, respectively.

For example, in the present embodiment, the outlets 64 and 74 may be opened in a rectangular shape for the discharge efficiency of the refractory.

In addition, the outlets 64 and 74 may include inclined guide plates 64a and 74a provided to guide the discharge of the refractory to one side of the rear side which is opened and to improve the degree of crushing of the refractory. The inclined guide plates 64a and 74a may be provided in a curved shape in a round shape, for example, in a crescent shape.

In addition, the first rotation part 62 may be provided with a through hole 63 in which water or air is injected into the end portion facing the exit hole excavation surface. The through hole 63 may be connected to flow paths 52a and 62a communicating with the rotational transmission member 52 and the first rotation part 62. In addition, a flexible pipe 56 is provided between the flow path 52a provided in the rotational transmission member 52 and the flow path 62a provided in the first rotating part 62, so that these flow paths 52a and 62a can be connected. .

In addition, the flow path (52a, 62a) may be a coolant or cold air flows from the outside, the cooling water or cold air introduced in this way by spraying the front end of the first rotating part 62 through the through hole 63 outlet In the excavation process, the first rotation part 62 and the second rotation part 72 may be prevented from being overheated.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims and their equivalents. It will be clear to those who have knowledge.

50: excavation device excavation device 52: rotation transmission member
52a, 62a: Euro 56: flexible tube
60: double rotation type excavation member 62: first rotating part
63: through hole 64, 74: outlet
64a, 74a: inclined guide plate 65: rotation support coupling holding portion
66: spiral coupling portion 67: cross-sectional reduction portion
68: front end catching part 69: rear end catching part
72: second rotating part

Claims (4)

An excavation part having an excavation bit provided in a dual structure and provided with a dual rotation type excavating member provided to be movable relative to the rotation direction; And
A rotational transmission member to which the dual rotational excavation member is coupled;
Exit rig including a.
The method of claim 1, wherein the dual rotation type drilling member
A first rotating part provided to correspond to the outer diameter part of the exit port to excavate refractory material,
A rotation-compatible coupling holding unit for holding and holding the first rotating unit and the rotating transmission member so as to be movable relative to each other;
And a second rotary part which is fixed to the rotary transmission member inside the first rotary part to excavate or crush the refractory material.
The method of claim 2, wherein the rotation-responsive coupling holding portion
A spiral coupling portion provided at one side of the rotational transmission member with a predetermined length;
A cross-sectional reduction part provided on the other end of the first rotating part and provided with a screw thread to be bitten with the spiral coupling part and moving along the spiral coupling part;
And a front hook portion and a rear hook portion provided on the spiral coupling portion or the rotation transfer member to limit the axial movement of the cross-sectional reduction portion.
The method according to claim 2,
Each of the first rotating part and the second rotating part includes an opening part provided to discharge refractory material,
The opening part excavating apparatus, characterized in that the opening is formed rounded on one side of the rear.

Images