KR101907318B1 - Apparatus for ignition of oxygen pipe for blast furnace tapping hole - Google Patents

Abstract

The present invention relates to an apparatus to an ignite oxygen pipe which melts and excavates the inside of a tapping hole of a blast furnace. According to the present invention, an apparatus to ignite an oxygen pipe for excavating a tapping hole of a blast furnace comprises: an ignition rod body having a hollow cylindrical shape and including a plurality of swirling injection holes penetrating the inside along the outer circumferential surface of an end part; a swirling member disposed inside the ignition body, having a cylindrical part formed on one side, and having a separation part formed on the other side by longitudinally dividing a hollow cylinder with a predetermined length; and a refractory member having a cylindrical shape and coupling the cylindrical part of the swirling member to close one end of the ignition rod body. Oxygen primarily discharged to the swirling member through an oxygen pipe is discharged while forming a swirl around the swirling member, and is secondarily discharged to the swirling injection holes to be discharged while forming a swirl around the ignition rod body.

Description

TECHNICAL FIELD [0001] The present invention relates to an oxygen pipe for an excavation of a blast furnace,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an oxygen pipe igniter for excavating a blast furnace, and more particularly, to an oxygen pipe igniter for excavating a blast furnace, To an oxygen pipe ignition apparatus for excavating an outgoing pipe.

Generally, it is a facility used to make iron ore, iron ore, coke fuel, and other additives, and then blowing hot air into the blast furnace to burn iron coke to reduce the iron ore. The inner melt made in the blast furnace becomes solid at the bottom, and when it becomes more than a certain amount, it is discharged to the outside through the outlet formed in the blast furnace wall. These operations are referred to as outgoing operations.

The mud is filled in the outgoing port of the blast furnace before the work is done to close the outgoing port to prevent the charred wire from coming out during the reduction reaction. Then, as described above, a device called open air is used to excavate the mud filled in the exit port and open the exit port for the exit work. The open air has a bar-shaped tapping bar formed with an opening tab at the tip thereof, and the tapping bar is rotated by a drilling motor to excavate the mud closing the exit opening.

In general, however, the outgoing operation is completed by the open air, but depending on the condition of the open air, the aging, and the exit port, it sometimes becomes difficult to penetrate the exit port with only open air. In this case, an additional oxygen pipe is used to dissolve the depth of the exit port.

1 (a) shows the depth portion 2 of the exit port 1 in order to prevent the one-shot bit 40 from being melted and worn by the melt inside the blast furnace flowing out of the exit port cracking outlet, The recessed portion A is formed by the melt in the depth portion 2 by retracting the one-shot bit 40 before the hole is penetrated. At this time, the operator performs an operation of igniting the oxygen pipe 10 and then inserting the oxygen pipe 10 into the depth portion 2 to excavate the inside occluding portion A.

1 (b) shows a state in which the one-shot bit 40 is fused together by the melt in the blast furnace flowing through the depth portion 2 of the exit port 1, And the fused portion B remains as it is in the depth portion 2 as it is. At this time, the operator ignites the oxygen pipe 10 and dissolves and cuts off the one-way bit 40 that has not retreated near the exit port 1, then slowly dissolves the depth portion 2, .

However, for the above operation, the oxygen pipe 10 must be ignited before inserting the oxygen pipe 10 into the depth portion 2 of the exit port 1. [

2 (a) shows a method in which an operator spontaneously ignites the muddy material 20 in a high-temperature region where molten steel slag 4 flows, thereby igniting the oxygen pipe 10. FIG. 2 (b) When the molten metal is received in the molten metal collection mechanism 30, the oxygen pipe 10 is brought into direct contact with the molten metal to make it ignite.

However, the method of igniting the oxygen pipe 10 as described above requires a high level of proficiency to the operator and the ignition time of the oxygen pipe 10 is changed flexibly according to the skill of the work. As a result, the ignition time of the oxygen pipe 10 is delayed, thereby delaying the output of the oxygen pipe 10, resulting in a reduction in the production amount.

In addition, in the oxygen pipe 10 ignition method as described above, when the operator is exposed to a high temperature region for a long time, physical and mental burdens are increased and the risk of occurrence of safety accidents such as burns increases.

A related prior art is Korean Patent Laid-Open No. 10-2011-0101725 (published on September 16, 2011).

DISCLOSURE OF THE INVENTION An object of the present invention is to solve the above-mentioned problems, and to solve the problem that the oxygen pipe used in the discharge work of the conventional blast furnace simply takes a long time until ignition, And it is an object of the present invention to provide an oxygen pipe ignition apparatus for an excavator for an excavation of a blast furnace which can quickly and easily perform an ignition operation of an oxygen pipe by mounting an ignition device at the tip of the oxygen pipe to allow oxygen to stay for a predetermined time.

The apparatus for igniting an oxygen pipe for blast furnace excavation according to an embodiment of the present invention includes an ignition bar body having a hollow cylindrical shape and having a plurality of whirl-jet ports formed therein and penetrating along an outer circumferential surface of the end portion, A spiral generating member which is located in the inside of the ignition bar body and has a cylindrical portion formed at one end thereof and a separating portion which is formed by dividing an empty cylinder having an inner hollow having a predetermined length into a longitudinal direction at the other end thereof; And oxygen discharged to the whirlpool generating member through the oxygen pipe firstly surrounds the whirlpool generating member and forms a whirlpool, and after ejected, And discharged to the whirlpool jet opening by the car to form a whirlpool around the ignition bar body, . ≪ / RTI >

Specifically, the ignition bar body and the whirlpool generating member are made of a combustible material, and the refractory member is made of a refractory material.

Specifically, the ignition-bar body may be manufactured by winding paper rounded a plurality of times.

Specifically, the whirlpool jet opening of the ignition bar body may be formed at a position where the separating portion of the whirl product generating member is located.

Specifically, the whirlpool jet opening of the ignition bar body is formed to be inclined by a predetermined amount with respect to the tangent of the inner circle with respect to the vertical plane of the ignition bar body, and a vertical line drawn from the inner surface with respect to the cross- And is formed to be inclined by a predetermined size.

Specifically, the whirl product generating member may be formed of a combustible plastic.

Specifically, the separating portion of the whirl product generating member includes: a first separating portion having a semicircular shape in which an end face is hollowed out; and a second separating portion having a semicircular shape in which the end face is hollow and whose face is opposed to the first separating portion 2 separator, and a jet port that is a longitudinal groove formed by separating the first separator and the second separator from each other.

Specifically, the first separator and the second separator may be positioned shifted laterally from each other as viewed in cross section.

As described above, according to the present invention, the ignition device is mounted on the oxygen pipe used in the conventional furnace exit work so that the oxygen ejected through the oxygen pipe stays in the ignition device for a certain period of time, Therefore, it is possible to reduce the time required for the ignition of the oxygen pipe and to contribute to the prevention of the safety accident of the worker.

In addition, since oxygen ejected from the oxygen pipe can stay at the end of the oxygen pipe for a certain period of time to form a whirlpool, the oxygen pipe can be easily ignited by spontaneous ignition simply by inserting it into the depth- Therefore, there is no need to separately perform the operation of igniting the oxygen pipe, and it is possible to reduce the time required for the opening work.

1 shows an outgoing excavation work using a conventional oxygen pipe.
Fig. 2 shows a conventional operation for igniting an oxygen pipe.
3 is a perspective view and a longitudinal sectional view of an oxygen pipe ignition apparatus for excavating a blast furnace according to an embodiment of the present invention.
4 is a cross-sectional view of the oxygen pipe ignition apparatus for excavation of the outflow port shown in Fig.
Fig. 5 is a diagram showing the state of operation of the refractory member and the whirl-generating member shown in Fig. 4. Fig.
FIG. 6 is a perspective view and a longitudinal sectional view showing an operating state of the oxygen pipe igniter for excavating the outgoing port shown in FIG. 3; FIG.
FIG. 7 is a view showing an example of an operation when an oxygen pipe igniter for excavating a blast furnace according to an embodiment of the present invention is used in the field.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the inventive concept. Other embodiments falling within the scope of the inventive concept may readily be suggested, but are also considered to be within the scope of the present invention.

The same reference numerals are used to designate the same components in the same reference numerals in the drawings of the embodiments.

FIG. 3 is a perspective view and a longitudinal sectional view of an oxygen pipe igniter for excavating a blast furnace according to an embodiment of the present invention, and FIG. 4 is a cross-sectional view of an oxygen pipe igniter for excavating the blast- The oxygen pipe ignition apparatus 100 for excavating the blast furnace of the blast furnace may include a firing bar body 110 as an external body, a whirlpool generating member 120 as an internal body, and a refractory member 130.

First, in the oxygen pipe ignition apparatus 100 for excavating the blast-furnace exit as described above, the oxygen discharged from the oxygen pipe 10 forms a whirl due to the internally generated vortex generating member 120, and the vortex generating member 120, And a whirlpool is formed by the whirlpool jet opening 111 of the external ignition bar body 110 to surround the ignition bar body 110 so that the oxygen pipe 10 is kept at the depth of the exit port 1, So that the spontaneous ignition can be easily and quickly caused by the high-temperature radiant heat inside when inserted into the main body 2.

The ignition bar body 110 has a hollow cylindrical shape and is provided with a plurality of whirlpool ejection openings 111 formed therein and penetrating along the outer circumferential surface of the one end portion.

The ignition bar body 110 is made of a combustible material and can easily ignite by radiant heat of high temperature together with oxygen injected to the outside. In an embodiment of the present invention, the paper of a certain length and width is wound round a plurality of times . Of course, it is of course possible to manufacture the ignition bar body 110 using other materials that can be used as a flammable material in addition to the paper.

The whirlpool jet opening 111 of the ignition bar body 110 may be formed at one or more ends along the circumference of the end portion of the ignition bar body 110. In an embodiment of the present invention, ㅀ, and 180 ㅀ. Of course, it is natural that the number of the whirlpool jetting ports 111 may vary depending on the material and size of the ignition bar body 110, and the size of the whirlpool jetting ports 111. In other words, the larger the diameter of the cross-sectional area of the ignition bar body 110, the greater the number of the vortex jetting openings 111 and the larger the diameter of the vortex jetting openings 111, .

The whirlpool jet opening 111 of the ignition bar body 110 is formed at the position where the separating portions 122 and 123 of the whirl product generating member 120 are located so that the oxygen ejected from the whirl product generating member 120 is immediately discharged through the whirlpool jet opening 111 So that it can be easily ejected.

The whirlpool jet opening 111 of the ignition bar body 110 is formed so as to be inclined so as to surround and spray the ignition bar body 110 when oxygen is jetted. In other words, the oxygen is formed obliquely with respect to the longitudinal plane of the ignition bar body 110 and is inclined again with respect to the cross-sectional plane, and the oxygen to be jetted is discharged from the ignition bar body 110 through the plurality of whirl- As shown in FIG. This is effective when the oxygen is sprayed and does not directly go outward but stays around the ignition-bar body 110 for a certain period of time.

3 (b), the whirlpool jet opening 111 of the ignition bar body 110 is inclined by a predetermined size? ₁ when the tangent line is drawn on the inner circle with respect to the vertical plane of the ignition bar body 110 .

That is, if the whirlpool jet opening 111 is perpendicular to the tangent of the inner circle, the shape of the sparkle jet opening 111 extends directly from the center in the form of radiation from the center of the vertical plane of the ignition bar body 110, so that the jetted oxygen is immediately ejected to the outside. However, in an embodiment of the present invention, the whirlpool jet opening 111 is formed to be inclined by 30 to 60 degrees with respect to the tangent of the inner circle, so that the jetted oxygen is blown around the circumference of the ignition bar body 110 Preferably by about 45 [mu] m. Of course, the above-described whirlpool jet opening 111 is merely an example of being tilted by about 45 degrees from the tangent of the inner circle, and it is only an example. It depends on the size and material of the ignition bar body 110, the amount of oxygen ejected into the oxygen pipe 10, It is natural to be able to change it.

4 (b), the whirlpool jet opening 111 of the ignition bar body 110 once again has a vertical line drawn from the inner side to the outer side with respect to the cross section of the ignition bar body 110, ₂ < / RTI > size.

That is, if the whirlpool jet opening 111 has the same direction as the vertical line drawn from the inner side to the outer side with respect to the cross-sectional surface of the ignition bar body 110, it has a shape extending directly from the center in the form of radiation from the center, And is ejected to the outside. However, in an embodiment of the present invention, the whirlpool jet opening 111 is formed by being inclined by 30 to 60 degrees with respect to the vertical line drawn from the inner side to the outer side with respect to the cross section of the ignition bar body 110, It is exemplified that the rod body 110 is wrapped around the circumference of the rod body 110, and it is preferably formed by being inclined by 45 degrees. Of course, the above-described whirlpool jet opening 111 is merely an example of being inclined by about 45 degrees from the vertical line drawn from the inner side to the outer side with respect to the cross-sectional surface of the ignition bar body 110. The size and material of the ignition rod body 110 , The amount of oxygen discharged into the oxygen pipe 10, and the like.

Oxygen ejected by the thus formed whirlpool jet opening 111 functions to form a secondary whirl and to eject the oxygen, which will be described later in detail.

The whirlpool generating member 120 is positioned inside the cylindrical hollow space of the ignition bar body 110 and has a cylindrical portion 121 connected to the refractory member 130 at one end thereof and capable of fixing the whirlpool generating member 120 And the first and second separating parts 122 and 123 are formed at the other end thereof, which are separated in the longitudinal direction by an empty cylindrical shape having a predetermined length.

The whirlpool generating member 120 is made of a combustible material as a whole and can easily be ignited by the radiant heat of high temperature together with oxygen ejected from the oxygen pipe 10. In an embodiment of the present invention, Of plastic materials were used as examples. Of course, it is a matter of course that the whirl-forming member 120 can be manufactured using other materials that can be used as a flammable material in addition to the flammable plastic and easy to mold.

In an embodiment of the present invention, the separator formed at the other end of the whirlpool generating member 120 may have a hollow cylindrical shape with an intermediate portion having a split shape, and may include a first separating portion 122 at an upper portion and a second separating portion 123 at a lower portion, And an air outlet 124 which is a space between the first separator 122 and the second separator 123.

The first separator 122 is formed to have a semi-circular shape having a predetermined thickness and length as seen in section and hollow inside.

The second separator 123 has a shape and a shape corresponding to those of the first separator 122. The second separator 123 has a predetermined thickness and a length similar to the first separator 122, And is formed so as to have a semicircular shape with an empty interior.

The jet port 124 is a longitudinal groove formed by separating the first separator 122 and the second separator 123 from each other and an oxygen pipe connected to the other end of the whirlpool generating member 120 through the groove 10).

Referring to FIG. 3 (b), it can be seen that the first separating portion 122 and the second separating portion 123 are formed to be shifted leftward and rightward from each other as viewed in cross section. In other words, the elliptical generating member 120 has a cylindrical cylindrical portion 121, which is filled with the ⅓ of the entire length, is fixedly coupled to the refractory member 130, and about 2/3 of the total length is a certain thickness And a first separating portion 122 and a second separating portion 123, which are cylindrically and internally hollow, which are vertically shifted and separated from each other.

According to the first separator 122 and the second separator 123 that are vertically shifted and separated from each other as described above, oxygen introduced from the center portion is supplied to the first separator 122 and the second separator 123 So that it has the effect of ejecting along the outer surfaces of the first and second separators 122 and 123 without exiting directly in the form of radiation when exiting the air outlet 124. Details thereof will be described later.

The refractory member 130 has a cylindrical shape and is inserted into one end of the ignition bar body 110 after being coupled with the cylindrical portion 121 of the whirl product generating member 120 and has one end of the ignition bar body 110 Thereby performing a sealing function.

The refractory member 130 is made of a refractory material capable of withstanding oxygen so that the oxygen ejected from the inner whirl product generating member 120 is ignited and oxygen is continuously ejected until the combustion is performed to some extent. Here, refractory materials are materials that can withstand high temperature combustion gases, chemical reactions, and the like, and include clay, high alumina and chromium.

Hereinafter, the operation of the oxygen pipe ignition apparatus for excavating the blast furnace according to one embodiment of the present invention will be described.

6 is a perspective view and a longitudinal sectional view showing an operating state of the oxygen pipe ignition apparatus for excavating the outgoing port shown in FIG. 3, and FIG. 7 is a cross- The oxygen pipe ignition apparatus 100 for excavating a blast furnace according to an embodiment of the present invention is an apparatus in which an oxygen pipe ignition apparatus for excavating a blast furnace according to an embodiment of the present invention is used in the field, The oxygen pipe 10 is connected to the separating portions 122 and 123 in a direction in which the whirlpool generating member 120 is positioned inside the body 110 and then the depth portion 2 of the exit port 1, The oxygen valve connected to the oxygen pipe 10 is opened so that the ignition bar body 110 is ignited by the high-temperature radiant heat of the deep portion 2 and the inside of the igniter generating member 120 ) Be a combustion so that the front end of the oxygen pipes 10 is ignited.

According to the oxygen pipe ignition apparatus 100 for excavating a blast furnace according to the present invention, oxygen is spirally formed from the inside to the first and second sides, so that the oxygen to be sprayed stays at the tip of the oxygen pipe 10 .

6, when the ignition bar body 110 is inserted into the depth portion 2 of the exit port 1 and then connected to the first and second separation portions 122 and 123, which are separation portions of the whirl product generating member 120, Oxygen discharged to the whirlpool generating member 120 through the oxygen pipe 10 is first generated by the jet port 124 formed by the first separator 122 and the second separator 123 being shifted from each other, The first separator 122 and the second separator 123 of the member 120 are wrapped around the first separator 122 and the first separator 122. Also, since the jetted oxygen does not have a place to escape in the direction of the cylindrical portion 121 of the vortex generating member 120, the oxygen that escapes through the vents 124 accelerates the vortex.

Since the end portion of the oxygen ejected by the jet port 124 is sealed by the refractory member 130, the oxygen in the jet port 124, which is located on the outer surface of the first separator 122 and the second separator 123, (111).

At this time, in the embodiment of the present invention, the whirlpool jet opening 111 is inclined in the lateral direction and the longitudinal direction by about 45 degrees at positions of 0 ㅀ, 45 ㅀ, 90 ㅀ, 180 둘 around the circumference of the ignition bar body 110 The spark plugs around the spark plug body 110 to form a second spiral and is trapped in the inner wall of the depth section 2a to further accelerate the spark around the spark plug body 110.

As a result, the oxygen is blown by the whirlpool jet opening 111 to form a whirlpool around the ignition bar body 110, so that the flow velocity and the pressure are lowered, so that the oxygen ejected from the oxygen pipe 10 is discharged for a certain period of time, And remains in the ignition device 100. As a result, the contact area of oxygen is increased, so that spontaneous ignition easily occurs in the ignition bar body 110 due to high-temperature radiation heat in the depth portion 2 of the exit port 1. [

That is, blast furnace gas (N₂: 55% to 60%, CO: 25% to 30%, CO₂: 10% to 14%) exists in the depth portion 2 of the exit port 1, Even if the combustion medium is present, ignition is not performed. However, at the moment when oxygen is injected, the combustion medium such as the ignition bar body 110 is rapidly burned.

Following the burning of the ignition bar body 110, the combustion is transferred to the whirlpool generating member 120, which is made of combustible plastic, and the front end of the oxygen pipe 10 is automatically ignited.

As a result, the ignition bar body 1110 is burned at a high speed and is melted and removed, and then the depth portion 20 of the exit port 10 is melted and excavated by the combustion by the pure oxygen pipe 10.

7A shows an oxygen pipe 10 (FIG. 7A) equipped with an oxygen pipe ignition apparatus 10 for excavating a blast furnace exit, which is an embodiment of the present invention, in a depth section 2 where an obstruction A is formed by an inner melt. FIG. 7 (b) is a view showing a state where the one-shot bit 40 can not be retreated by the internal melt, and when the occluding portion A is formed, 1 shows an operation of cutting an ordinary bit 40 by contacting an oxygen pipe 10 equipped with an oxygen pipe ignition apparatus 10 for excavating a brick-pit, which is an embodiment of the present invention.

Therefore, according to the oxygen pipe ignition apparatus 100 for excavating a blast furnace according to an embodiment of the present invention, it is possible to prevent the oxygen pipe 10 from being ignited at the site where the oxygen pipe 10 is required, 10, the oxygen pipe 10 is ignited by spontaneous ignition. Therefore, the ignition operation of the oxygen pipe 10 can be omitted, and the time required for the opening work can be saved.

As described above, according to the present invention, the ignition device is mounted on the oxygen pipe used in the conventional furnace exit work so that the oxygen ejected through the oxygen pipe stays in the ignition device for a certain period of time, Therefore, it is possible to reduce the time required for the ignition of the oxygen pipe and to contribute to the prevention of the safety accident of the worker.

In addition, since oxygen ejected from the oxygen pipe can stay at the end of the oxygen pipe for a certain period of time to form a whirlpool, the oxygen pipe can be easily ignited by spontaneous ignition simply by inserting it into the depth- Therefore, there is no need to separately perform the operation of igniting the oxygen pipe, and it is possible to reduce the time required for the opening work.

The oxygen pipe ignition apparatus for excavating the blast-furnace outlets of the present invention is not limited to the construction and the operation manner of the embodiments described above. The embodiments may be configured so that all or some of the embodiments may be selectively combined so that various modifications may be made.

1: exit port 2: depth section
2a: inner wall of depth section 3: blast furnace melt
4: Charcoal slag 5:
10: Oxygen pipe 20: Mud material
30: Melt collecting device 40: One-bit
100: Oxygen pipe ignition device for excavation of blast furnace exit
110: firing rod body 111:
120: a whirlpool generating member 121:
122: first separator 123: second separator
124: jet port 130: refractory member
A: Closed part B: Fused part

Claims (8)

An ignition device for igniting an oxygen pipe for melting and excavating an inside of an outflow hole,
An ignition rod body having a hollow cylindrical shape and having a plurality of whirlpool spouts formed therein and penetrating along an outer circumferential surface of the end portion;
A whirlpool generating member positioned inside the ignition bar body and having a cylindrical portion formed at one end thereof and a hollow cylindrical portion having a predetermined length formed at the other end thereof to form a separation portion in the longitudinal direction;
And a refractory member having a cylindrical shape and engaged with a cylindrical portion of the whirl product generating member to seal one end of the ignition bar body,
Oxygen discharged to the whirl product generating member through the oxygen pipe primarily surrounds the whirl product generating member, forms a whirl and is ejected,
And the second portion is discharged to the whirlpool ejection port to surround the ignition bar body and form a whirlpool, and is ejected.
The method according to claim 1,
Wherein the ignition bar body and the whirlpool generating member are made of a combustible material, and the refractory member is made of a refractory material.
The method according to claim 1,
The ignition-
Characterized in that the paper is manufactured by winding the paper round a plurality of times.
The method according to claim 1,
The whirlpool jet opening of the ignition bar body includes:
Wherein the separator is formed at a position where the separator of the whirl product generating member is located.
The method according to claim 1,
The whirlpool jet opening of the ignition bar body includes:
And is formed by being inclined by a preset angle with respect to the tangent of the inner circle with respect to the vertical plane of the ignition bar body and inclined by a predetermined size from a vertical line drawn from the inner surface with respect to the cross section of the ignition bar body. Oxygen pipe ignition device for excavation of blast furnace excavation.
The method according to claim 1,
The whirl product generating member includes:
Wherein the oxygen piping is made of flammable plastic.
The method according to claim 1,
The separator of the whirl-
A first separator having a semicircular shape with a hollow inside;
A second separator having a semicircular shape in cross section and having an empty interior and facing the first separator;
Wherein the first and second separating portions are spaced apart from each other to form a longitudinal groove that is formed by separating the first separating portion and the second separating portion from each other.
8. The method of claim 7,
Wherein the first separating portion and the second separating portion are positioned shifted laterally from each other as viewed in cross section.

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