KR102064605B1 - Observation window of blast furnace to minimize pollution - Google Patents

Abstract

Provided in the present invention is an observation window of a blast furnace with a pollution prevention function, which comprises: an observation body installed at one side of a blast furnace, while forming a through-hole at the center; a supply unit formed at the center of the observation body such that air supplied from the outside may be circulated; a plurality of distribution holes radially formed to uniformly supply the air after being connected to the supply unit; an inducing unit which is connected to the distribution holes to supply the air into the through-hole in order to generate a positive pressure, thereby blocking debris and a high temperature; an auxiliary body installed on the outside of the observation body; and a plurality of observation members connected to the through-hole at the center of the auxiliary body, while being vertically arranged to be spaced from each other with predetermined intervals. Therefore, the positive pressure of the air is generated in the observation window to block the debris, such that pollution of the observation window may be prevented. In addition, because the pollution of the observation window can be prevented, a worker can exactly recognize an inner circumstance such as a combustion state of the blast furnace. Furthermore, the thermal deformation and damage of the observation window can be prevented, thereby increasing durability and service life.

Description

Observation window of blast furnace to minimize pollution

The present invention relates to an observation window of a high-temperature furnace having a pollution prevention function, and more particularly, to an observation window of a high-temperature furnace having a pollution prevention function to prevent contamination by blocking adhesion of impurities to the surface of the observation window. will be.

In general, an observation window is provided for visually identifying an internal situation such as a combustion state of a high temperature furnace (heating furnace).

However, the conventional observation window has a problem in that it cannot perform the function of the observation window because impurities such as ash generated inside the high-temperature furnace are easily attached to the transparent glass plate and contaminated.

In particular, the decomposition and maintenance of the contaminated observation window due to the high temperature environment can not be easily carried out has a problem of reducing the work efficiency.

On the other hand, thermal deformation and cracking of the observation window occur due to the high heat of the high temperature furnace has a problem of shortening the durability and service life.

In addition, the breakage and replacement of the frequent observation window has a problem of lowering the operation and productivity of the high temperature furnace.

Korean Patent Publication No. 10-2007-0048442 (2007.05.09) Korean Patent Publication No. 10-2011-0086699 (2011.07.29) Korean Patent Publication No. 10-2013-0050084 (2013.05.15) Korea Patent Publication No. 10-2013-0056054 (2013.05.29) Korean Patent Publication No. 10-2015-0034868 (2015.04.06)

Therefore, the present invention has been made to solve the above conventional problems,

An object of the present invention is to provide a high-temperature observation window having a pollution prevention function that can block impurities and high heat by supplying a gas of a pressure higher than the internal pressure of the high-temperature furnace to the inside of the observation window.

In addition, the present invention has another object to provide an observation window of a high-temperature furnace having a pollution prevention function that can form a double observation member and supply gas therebetween to improve the cooling efficiency.

Observation window 100 of the high temperature furnace having the present invention pollution prevention function for achieving the above object,

Observation body 110 is installed on one side of the high-temperature furnace 10 to form a through-hole (110a) in the center; A supply unit 120 configured to circulate a gas supplied from the outside in the center of the observation body 110; A plurality of distribution holes 130 connected to the supply part 120 to be radially formed to uniformly supply gas; An induction part 140 connected to the distribution hole 130 to supply gas to the inside of the through hole 110a to generate a positive pressure to block impurities and high heat; An auxiliary body 150 installed outside the observation body 110; And a plurality of observation members 160 connected to the through-hole 110a at the center of the auxiliary body 150 to be spaced apart vertically by a predetermined interval.

Here it is connected between the high heat furnace 10 and the observation body 110, the observation port 20 to form a shape that gradually decreases in the direction of the high heat furnace 10; characterized in that it comprises a.

In particular, the supply unit 120 is characterized in that it is formed in a circular shape so that the gas supplied through the gas supply unit 111 provided on one side of the observation body 110 can circulate around.

In addition, the distribution hole 130 is characterized in that it is formed to be inclined to one side between the supply unit 120 and the induction unit 140.

On the other hand, the inner lower portion of the induction part 140, the induction surface 141 for inducing gas to face the direction of the through hole (110a); characterized in that it comprises a.

At this time, the induction part 140 is characterized in that it is formed to be bent toward the center of the through-hole (110a) from the outer side to the inner side when viewed in a planar state.

In addition, a circulation space 161 is formed between the plurality of observation members 160, and the gas is formed inside the circulation space 161 through a gas supply port 151 formed at one side of the auxiliary body 150. After supplying and circulating through the gas outlet 152 formed on the other side of the auxiliary body 150 is characterized in that it is discharged to the outside.

The present invention has the effect of preventing contamination of the observation window by generating a positive pressure of the gas inside the observation window to block impurities.

In particular, the present invention has the effect of preventing the contamination of the observation window to accurately grasp the internal situation, such as the combustion state of the high-temperature furnace.

In addition, the present invention has the effect of preventing the thermal deformation and damage of the observation window to improve the durability and service life.

1 is a cross-sectional view for showing the structure of the observation window of the high-temperature furnace having a pollution prevention function of the present invention.
2 is a cross-sectional view taken along the line AA of FIG.
3 is a cross-sectional view taken along line BB of FIG. 1.
Figure 4 is a cross-sectional view for showing the operating state of the observation window of the high-temperature furnace having a pollution prevention function of the present invention.

When described in detail by the accompanying drawings, the configuration of the present invention as described above are as follows.

1 is a cross-sectional view showing the structure of the observation window of the high-temperature furnace having a pollution prevention function of the present invention, Figure 2 is a cross-sectional view taken along line AA of Figure 1, Figure 3 is a cross-sectional view taken along the line BB of FIG. The cross section for showing the operation state with respect to the observation window of the high-temperature furnace with a pollution prevention function of this invention is shown.

The present invention is installed on one side of the high-temperature furnace 10 observation body 110 to form a through-hole (110a) in the center; A supply unit 120 configured to circulate a gas supplied from the outside in the center of the observation body 110; A plurality of distribution holes 130 connected to the supply part 120 to be radially formed to uniformly supply gas; An induction part 140 connected to the distribution hole 130 to supply gas to the inside of the through hole 110a to generate a positive pressure to block impurities and high heat; An auxiliary body 150 installed outside the observation body 110; And a plurality of observation members 160 connected to the through-hole 110a at the center of the auxiliary body 150 to be spaced apart vertically by a predetermined interval.

In particular, the observation body 110 serves to block impurities and high heat by supplying a gas (gas) to the inside of the through hole (110a) to generate a positive pressure of a pressure higher than the internal pressure of the high temperature furnace (10). .

In the present invention, the gas may use various gases such as nitrogen.

Here, the observation hole 20 is connected between the high-temperature furnace 10 and the observation body 110 to have a shape that gradually decreases in diameter in the direction of the high-temperature furnace 10; and the through hole 110a. The positive pressure of the gas generated inside of can be increased.

In this case, a sealing member 112 such as a gasket or packing of a heat resistant material may be provided between the observation port 20 and the observation body 110.

In addition, the supply unit 120 serves to supply the gas supplied from the outside to the distribution hole 130 through the gas supply unit 111 provided on one side of the observation body (110).

At this time, the supply unit 120 is formed in a circular shape so that the gas can circulate around.

Meanwhile, as shown in FIG. 2, the distribution holes 130 are formed to have a constant diameter so as to uniformly supply gas to the induction part 140 to form a plurality of radially when viewed in a planar state.

In particular, the distribution hole 130 is formed to be inclined to one side between the supply unit 120 and the induction unit 140 to generate a vortex according to the inclination angle of the gas to improve the feed rate and mixing efficiency of the gas Can be.

In addition, the induction part 140 serves to block impurities and high heat by generating a positive pressure by supplying gas to the inside of the through hole 110a.

In this case, the inner lower portion of the induction part 140 includes an induction surface 141 having an inclined surface to face the direction of the through hole 110a. Can block high heat.

Here, the induction surface 141 may form a curved inclined surface when viewed in a cross-sectional state to naturally guide gas into the through hole 110a without interference.

In addition, the induction part 140 is formed to be bent toward the center of the through-hole (110a) from the outer side to the inner side as shown in the planar state as shown in Figure 3 to cause the vortex of the gas to improve the generation efficiency of the positive pressure You can.

In addition, the auxiliary body 150 is installed on the outside of the observation body 110 to fix the observation member 160.

In this case, a sealing member 154 such as a gasket or packing of a heat resistant material may be provided between the observation body 110 and the auxiliary body 150.

On the other hand, the observation member 160 is connected to the through-hole (110a) of a transparent glass or synthetic resin material having heat resistance to assist the operator to visually check the internal situation of the high-temperature furnace (10).

Here, the observation member 160 is installed on the upper and lower portions of the auxiliary body 150 to be spaced apart by a predetermined interval to form a circulation space 161 therebetween, formed on one side of the auxiliary body 150 By supplying the gas to the inside of the circulation space 161 through the gas supply port 151 to circulate and discharge to the outside through the gas discharge port 152 formed on the other side of the auxiliary body 150 due to high heat By improving the cooling efficiency of the observation member 160 it is possible to prevent thermal deformation and damage.

In this case, the upper and lower portions of the auxiliary body 150 may be provided with fixing members 153 and 155 of a heat resistant material so as to contact and fix the surface of the observation member 160 as well as to secure airtightness.

Here, the fixing members 154 and 155 may fix the observation member 160 using bolts or support plates.

Therefore, as shown in FIG. 4, impurities generated in the high-temperature furnace 10 by generating a positive pressure by supplying a gas having a pressure higher than the internal pressure of the high-temperature furnace 10 to the inside of the through hole 110a and The high heat may be blocked, and the gas may be supplied and circulated between the observation members 160 to prevent thermal deformation and breakage due to high heat.

As described above, the embodiment of the present invention has been described in detail, but the scope of the present invention is not limited thereto, and the scope of the present invention includes the scope of the present invention to the extent that it is substantially equivalent to the embodiment of the present invention. Of course.

10: high heat 20: observation hole
100: observation window of high temperature furnace having the present invention pollution prevention function
110: observation body 110a: through hole
111: gas supply part 112: sealing member
120: supply unit 130: distribution hole
140: guide portion 141: guide surface
150: auxiliary body 151: gas supply port
152: gas outlet 153: fixing member
154: sealing member 155: fixing member
160: observation member 161: circulation space

Claims (7)

Observation body is installed on one side of the high-temperature furnace to form a through-hole; A supply unit configured to circulate a gas supplied from the outside to the center of the observation body; A plurality of distribution holes radially connected to the supply part to uniformly supply the gas; An induction part connected to the distribution hole to supply gas to the inside of the through hole to generate a positive pressure to block impurities and high heat; An auxiliary body installed outside the observation body; A plurality of observation members connected to the through hole at the center of the auxiliary body, but arranged to fall vertically at regular intervals, wherein the plurality of observation members are connected between the high heat furnace and the observation body and gradually decrease in diameter toward the high heat furnace. It includes; observation port formed to have a; The supply portion is formed in a circular shape so that the gas supplied through the gas supply portion provided on one side of the observation body can be circulated round, the distribution hole is the supply portion and the It is formed to be inclined to one side between the guide portion, the lower portion of the guide portion includes a guide portion for guiding the gas to face the direction of the through hole, the guide portion when viewed in a planar state of the through hole from the outside from the inside It is formed to be bent toward the center, and the inner lower portion of the induction part is seen in the cross-sectional state At the time of forming a curved slope to supply gas to the inside of the through hole to generate a positive pressure to contain impurities and high heat, and to form a circulation space between the plurality of the observation member, the auxiliary High temperature having a pollution prevention function characterized in that the gas is supplied to the inside of the circulation space through the gas supply port formed on one side of the body and then discharged to the outside through the gas outlet formed on the other side of the auxiliary body The observation window to the furnace. delete delete delete delete delete delete

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