JPH10288328A - Exhaust gas combustion tower - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a combustion tower capable of separating scraps or dust contained in an exhaust gas to a satisfactory extent in a simple structure. SOLUTION: This combustion tower is provided with an inlet duct 11 of exhaust gas, which settles out and separates scraps or dust from an exhaust gas generated in a melting furnace of a scrap melting electric furnace or the like and an outlet duct 12. In this case, the tip of the outlet duct 12 is extended into the combustion tower while a downward opening 14 is formed at the tip at the position lower than the elevation of the inlet duct 11.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an exhaust gas combustion tower in a dust collecting facility for collecting scrap and dust from exhaust gas generated in a furnace such as an electric furnace for melting scrap.

[0002]

2. Description of the Related Art Exhaust gas generated in an electric furnace for melting scrap contains scraps and dust and is sent to a dust collecting facility where it is collected. The secondary combustion and dust are separated in the tower and sent to the dust collection facility.

FIG. 2 is a diagram showing an example of the arrangement of electric furnaces and combustion towers. Two electric furnaces, a first electric furnace 1 and a second electric furnace 2, are arranged. Exhaust gas ducts 3, 4
Are connected to the first combustion tower 5 by a duct 9a and are also connected to the first exhaust gas ducts 3 and 4 of the electric furnaces 1 and 2. Further, each of the electric furnaces 1 and 2 has another second exhaust gas duct 6 and 7 connected to the second combustion tower 8, respectively.
Each combustion tower 5, 8 is connected by ducts 9a, 9b,
The second combustion tower 8 is connected to a dust collector via an outlet duct 12. Each of the combustion towers 5 and 8 functions as a scrap catcher for separating scrap and dust from exhaust gas,
Each duct 3, 4, 6, 7, 9 is provided with an opening / closing damper 10.

FIG. 3 shows a conventional combustion tower, and FIG.
(A) is a longitudinal sectional view of a combustion tower in which an inlet duct is provided in a ceiling portion of the combustion tower, and FIG. 3- (b) is a longitudinal sectional view of a combustion tower in which a horizontal inlet duct is provided in an upper part of the combustion tower. is there.

In FIG. 3A, exhaust gas is introduced from a vertical inlet duct 11 opening at the ceiling of the combustion tower 5, and a horizontal opening at a central wall lower than the level of the inlet duct 11. From the outlet duct 12. Large scraps and dust in the exhaust gas introduced into the combustion tower 5 settle down due to gravity and accumulate in a dust box 13 below.

FIG. 3 (b) shows that exhaust gas is introduced from a horizontal inlet duct 11 opening at the upper part of the wall of the combustion tower 5,
The air is discharged from a horizontal outlet duct 12 which is opposed to the inlet duct 11 and at the same level. Scraps and dust in the exhaust gas introduced into the combustion tower 5 settle in the combustion tower and accumulate in the dust box 13 at the lower part.

In the arrangement of the electric furnace and the combustion tower shown in FIG.
The flow of the exhaust gas will be described.

[0008] The scrap is melted in the first electric furnace 1 and
When the scrap is preheated in the electric furnace 2, high-temperature exhaust gas generated in the first electric furnace 1 is sent to the second electric furnace 2 to preheat the scrap charged in the second electric furnace 2. , 2 of the first exhaust gas duct 3, 4 are opened, and the respective open / close dampers 10 of the exhaust gas inlet duct 9 a and the exhaust duct 9 b of the first combustion tower 5 are closed. To prevent the exhaust gas from being sent to the first combustion tower 5. Further, the second electric furnace 2
To separate the dust from the exhaust gas from the
The open / close damper 10 of the second exhaust gas duct 7 of the electric furnace 2 is opened, and the open / close damper 10 of the second exhaust gas duct 6 of the first electric furnace 1 is closed.

When only one of the first electric furnace 1 and the second electric furnace 2 is used and the other is closed, for example, the scrap is melted in the first electric furnace 1 and the second electric furnace 2 is melted.
Is shut down, the opening / closing damper 10 of the first exhaust gas duct 4 and the second exhaust gas duct 7 of the second electric furnace 2 is closed, and the exhaust gas from the first electric furnace 1 is discharged to the first combustion tower 5 and the second exhaust gas duct 2.
In order to send the dust to the dust collector via the combustion tower 8, the open / close dampers 10 of the duct 9 a on the exhaust gas inlet side and the duct 9 b on the outlet side of the first combustion tower 5 are opened, and the second exhaust gas of the first electric furnace 1 is opened. The opening / closing damper 10 of the duct 6 is closed.

In any of the operations, the exhaust gas generated in the electric furnaces 1 and 2 contains scraps and dusts. Therefore, large scraps and dusts are separated in the combustion towers 5 and 8 functioning as a scrap catcher, and the separated dusts are sent to a dust collector. sending.

[0011]

The conventional combustion tower has a structure in which the exhaust duct including the scrap and dust easily flows directly from the inlet duct to the outlet duct because the outlet duct is open to the wall of the combustion tower. I have. For this reason, there is a problem that the residence time of the exhaust gas is short, and the scrap and the duct in the exhaust gas are not completely separated, but are sucked into the outlet duct as they are, and the scrap and the dust cannot be sufficiently separated.

The present invention provides an exhaust gas combustion tower having a simple structure capable of sufficiently separating scrap and dust contained in exhaust gas.

[0013]

SUMMARY OF THE INVENTION The present invention relates to an exhaust gas combustion tower having an exhaust gas inlet duct and an outlet duct for sedimenting and separating scrap and dust from exhaust gas generated in a melting furnace such as an electric furnace for scrap melting. The tip of the outlet duct is extended into the combustion tower, and a downward opening is formed at the tip below the height level of the inlet duct.

The opening of the horizontally extending outlet duct can be opened obliquely downward. Further, a bent portion whose opening is downward may be formed at the tip of the outlet duct.

[0015]

FIG. 1 shows a combustion tower according to the present invention. FIG. 1- (a) is a cross-sectional view of an embodiment in which an inlet duct is provided on the ceiling of the combustion tower, and FIG. It is a longitudinal section of the example in which the horizontal entrance duct was provided in the upper part of the combustion tower.

In FIG. 1A, a vertical inlet duct 11 is provided at the ceiling of the combustion tower 5 arranged as the first combustion tower or the second combustion tower shown in FIG. On the wall, a horizontal exhaust gas outlet duct 12 opening below the level of the exhaust gas inlet duct 11
Is provided. The combustion tower 5, the inlet duct 11, and the outlet duct 12 have a water-cooled structure such as a water-cooled jacket and a double pipe in order to withstand high-temperature exhaust gas of about 1000 ° C.

The horizontal outlet duct 12 extends to the inside of the combustion tower, and is provided such that the tip of the outlet duct 12 is located below the vertical inlet duct 11. The opening 14 at the tip of the outlet duct is formed obliquely downward.

A dust box 13 for storing separated dust is provided below the combustion tower 5.

The separation of scrap and dust from exhaust gas by the combustion tower of this embodiment will be described.

Exhaust gas containing scrap and dust entering the combustion tower from the vertical inlet duct 11 is disturbed by the outlet duct 12 extending to the inside of the combustion tower, and turbulence is generated. After flowing, exit duct 1
2 is sucked from the obliquely downward opening 14. As described above, since the exhaust gas that has entered the combustion tower is not directly sucked from the inlet duct 11 to the outlet duct 12, the residence time of the exhaust gas containing dust in the combustion tower increases, and as a result,
Separation of scrap and dust from exhaust gas can be promoted.

Next, in FIG. 1B, a horizontal inlet duct 11 is provided above the wall of the combustion tower 5, and an outlet duct 12 is provided to face the inlet duct 11. Like the first embodiment, the combustion tower 5, the inlet duct 11, and the outlet duct 12 have a water-cooled structure such as a water-cooled jacket in order to withstand high-temperature exhaust gas.

The end of the outlet duct 12 extends to the inside of the combustion tower, and an opening 14 is formed at the end by bending a downward bent portion 15, and the height of the opening 14 is higher than that of the outlet duct. Down. A dust box 13 for storing the separated dust is provided below the combustion tower 5.

The separation of scrap and dust from exhaust gas by the combustion tower of this embodiment will be described.

Exhaust gas containing crap and dust entering the combustion tower 5 from the horizontal inlet duct 11 is disturbed by the bent portion 15 of the outlet duct 12 extending to the inside of the combustion tower, and turbulence is generated. And is sucked from the downward opening 14 of the bent portion 15 lower than the height level of the inlet duct 11. Since the exhaust gas is not directly sucked from the inlet duct 11 to the outlet duct 12, the residence time of the exhaust gas in the combustion tower increases, and as a result, the separation of scrap and dust from the exhaust gas can be promoted.

[0025]

According to the combustion tower of the present invention, the tip of the inlet duct is extended into the combustion tower, and a simple structure having a downward opening at the tip facilitates separation of scrap and dust contained in exhaust gas. can do.

[Brief description of the drawings]

FIG. 1 shows a combustion tower of the present invention, and FIG. 1- (a) is a longitudinal sectional view of an embodiment in which an inlet duct is provided on a ceiling portion of the combustion tower.
FIG. 1- (b) is a longitudinal sectional view of an embodiment in which a horizontal inlet duct is provided at the upper part of the combustion tower.

FIG. 2 is a diagram showing an example of an arrangement of an electric furnace and a combustion tower.

FIG. 3 shows a conventional combustion tower, FIG. 3- (a) is a longitudinal sectional view of a combustion tower having an inlet duct provided on a ceiling portion of the combustion tower, and FIG. 1 is a longitudinal sectional view of a combustion tower provided with an inlet duct of FIG.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 1st electric furnace 2 2nd electric furnace 3, 4 1st exhaust gas duct 5 1st combustion tower 6, 7 2nd exhaust gas duct 8 2nd combustion tower 9a, 9b duct 10 Damper 11 Inlet duct 12 Outlet duct 13 Dust box 14 Opening Part 15 Bending part

Claims (3)

[Claims] 1. An exhaust gas combustion tower having an exhaust gas inlet duct and an exhaust duct for sedimenting and separating scrap and dust from an exhaust gas generated in a furnace such as an electric furnace for scrap melting, wherein the tip of the outlet duct is located inside the combustion tower. An exhaust gas combustion tower having a downward opening formed at a position below a height level of an inlet duct at the tip. 2. The exhaust gas combustion tower according to claim 1, wherein the opening of the horizontally extending outlet duct opens obliquely downward. 3. The exhaust gas combustion tower according to claim 1, wherein the end of the outlet duct extends to the inside of the combustion tower, and the opening has a downward bent portion at the end.