JPH0210112Y2 - - Google Patents

Description

[Detailed Description of the Invention] This invention relates to a dust collection hood for a ladle used for ladle refining of molten steel, and particularly relates to a dust collection hood provided on the upper lid of the ladle.

BACKGROUND ART It has been known that during ladle refining, dust collection of high-temperature exhaust gas generated during the refining is carried out using a dust collection hood provided on the upper lid of the ladle. FIG. 1 shows a schematic front view of the ladle refining equipment, in which a dust collection hood 4 is fixed to the top of a water-cooled top lid 3 of a ladle 2 placed on a trolley 1. Gas inside the hood 4 is sucked through an exhaust duct 5 provided in the hood 4. The high-temperature exhaust gas generated by refining the molten steel 6 in the ladle 2 is passed through the opening 7 of the upper lid 3 and the molten steel heating 3.
The dust flows into the hood 4 through the gap with the phase electrode 8, passes through the exhaust duct 5, and is collected.

By the way, the above-mentioned dust collection of exhaust gas has the following drawbacks. (1) Although the hood 4 is provided with an opening 9 for inserting the electrode 8 into the ladle 2, if the gas suction force inside the hood 4 is weak,
Exhaust gas leaks out of the hood 4 from the gap between the opening 9 and the electrode 8. (2) During refining, the tip of the electrode 8 is worn out, so the electrode 8 must be lowered as it wears out, but the support arm 10 of the electrode 8 becomes an obstacle to this, so the hood 4 is raised higher. I can't. As a result, the fast flowing exhaust gas rising along the electrode 8 leaks out of the hood 4 through the gap between the opening 9 of the hood 4 and the electrode 8.

Therefore, when the exhaust gas inside the hood 4 is strongly sucked in order to improve the dust collection of the exhaust gas, the inside of the ladle 2 becomes negative pressure. Outside air enters into the ladle 2 through the seal between the upper lid 3 and the upper lid 3, resulting in the problem that N ₂ mixes into the molten steel 6.

In view of the above-mentioned current situation, this invention provides a dust collection hood that can efficiently collect dust from high-temperature exhaust gas generated during refining without mixing _N2 into the molten steel contained in the ladle. and consisting of a fixed hood provided on the upper lid of the ladle, a movable hood provided above the fixed hood so as to be movable up and down and covering the fixed hood, and an exhaust duct provided on the movable hood. It has the following characteristics.

Hereinafter, embodiments of this invention will be described in detail based on the drawings.

FIG. 2 is a sectional view showing one embodiment of the dust collecting hood of this invention. The dust collection hood of this invention consists of a fixed hood 11, a movable hood 12, and an exhaust duct 15. The fixed hood 11 is a first
Like the conventional hood 4 shown in the figure, it is provided on the upper part of the water-cooled upper lid 3 of the ladle, but unlike the conventional hood 4, no duct is provided. The movable hood 12 is movable up and down with respect to the fixed hood 11 and is provided so as to cover the upper part of the fixed hood 11. , which have a box structure connected by bellows 14 made of a flexible heat-resistant material. The upper plate 13 of the movable hood 12 is provided with an exhaust duct 15 that opens into the movable hood 12. Furthermore, the movable hood 12 and the fixed hood 11 are provided with openings 16 and 9, respectively, for inserting the electrode into the ladle. The upper plate 13 of the movable hood 12 and the fixed hood 11 are formed by combining a steel plate and a section steel, for example, and are lined with a refractory material to prevent the influence of radiant heat from the electrodes.

Using the dust collection hood configured as above,
To collect dust from the exhaust gas generated during refining, adjust the opening of the damper connected to the exhaust duct 15 and the flow rate of Ar gas blown out from the lance, and set the gauge pressure in the fixed hood 11 to 0 mmaq. (atmospheric pressure). The inside of the ladle 2 is controlled to a positive pressure, for example, +200 mmaq., and the inside of the movable hood 12 is controlled to a negative pressure, for example, about -200 mmaq., and the exhaust gas generated in the ladle 2 is sucked. Further, since the electrode support arm 10 hits the lower electrode 8, the upper plate 13 of the movable hood 12 is lowered in conjunction with the lowering of the electrode 8.

The exhaust gas flows into the fixed hood 11 through the gap between the opening 7 of the upper lid 3 of the ladle 2 and the electrode 8, and then
It flows into the movable hood 12 through the gap between the aperture 9 of the fixed hood 11 and the electrode 8 and is exhausted from the exhaust duct 15. At this time, since the movable hood 12 is further provided on the fixed hood 11, the fast-flowing exhaust gas rising along the electrode 8 can be removed by the movable hood 12.
The liquid is sucked and removed through the duct 15 without leaking from the gap between the opening 16 of No. 2 and the electrode 8.
Therefore, the dust collection efficiency of exhaust gas is improved. Further, since the inside of the ladle 2 is maintained at a positive pressure, outside air does not enter into the ladle 2, and the molten steel contained in the ladle 2 is not mixed with _N2 .

FIG. 3 is a sectional view showing a second embodiment of this invention. In the dust collection hood of this embodiment, a downward bent end 19 is formed at the peripheral edge of the upper plate 18 of the movable hood 17, and a bellows 14 is connected between the bent end 19 and the lower part of the fixed hood 11. It differs from the dust collection hood shown in Figure 2 only in that it has a box structure connected by .

Moreover, FIG. 4 is a sectional view showing a third embodiment of this invention. In the dust collection hood of this embodiment, the movable hood 20 is formed in a box shape using the same material as the material of the upper plate 3 in FIG. This structure allows the fixed hood 11 to slide up and down using the side wall as a guide.

Furthermore, FIG. 5 is a sectional view showing a fourth embodiment of this invention. In the dust collection hood of this embodiment, the movable hood 21 has a guide plate 22 provided outwardly from the fixed hood 11 of the ladle top cover 3, and covers the guide plate 22, and slides up and down using the guide plate 22 as a guide. The box 23 is provided with a box 23 similar to the hood 20 shown in FIG.
The lower end of the side wall of the guide plate 22 and the lower part of the guide plate 22 are connected by a bellows 24.

As is clear from the above explanation, the dust collection hood of this invention is provided with a movable hood that can move up and down to cover the fixed hood on the top of the fixed hood provided on the upper lid of the ladle, and this movable hood An exhaust duct is installed to suck in the exhaust gas, so the exhaust gas generated during molten steel refining can be collected without leaking outside the dust collection hood while maintaining the pressure inside the ladle at a positive pressure. . Therefore, since outside air does not enter into the ladle, the molten steel contained in the ladle can be refined without being mixed with _N2 .

Figure 6 shows that using the dust collecting hood of this invention shown in Figure 2, the pressure inside the ladle, inside the fixed hood, and inside the movable hood is +200 mmaq., 0 mmaq., and -200 mmaq., respectively.
_N2 into the molten steel when the molten steel is refined while collecting exhaust gas and suctioning to about mmaq.
2 is a graph showing the relationship between the amount of contamination and the degree N of molten steel in comparison with the case where the conventional dust collecting hood of FIG. 1 is used. From this graph, _N2 into molten steel
The amount of contamination when using a conventional dust collection hood is
The average is 6.19ppm and the standard deviation is 2.52ppm, whereas when using the dust collection hood of this invention, the average is 2.72ppm and the standard deviation is 1.82ppm, which significantly reduces the amount of _N2 mixed into the molten steel. I know that there is.

[Brief explanation of the drawing]

FIG. 1 is a schematic front view showing a ladle refining equipment equipped with a conventional dust collection hood, FIG. 2 is a cross-sectional view showing the first embodiment of this invention, and FIG.
4 is a cross-sectional view showing the second embodiment, FIG. 5 is a cross-sectional view showing the fourth embodiment, and FIG. 6 is a cross-sectional view showing the third embodiment.
When exhaust gas during refining is collected using the dust collection hood shown in Figures 1 and 2, _N2 is released into the refining molten steel.
It is a graph showing the relationship between the amount of mixture and the frequency of molten steel. In the drawing, 2...Ladle, 3...Ladle top cover, 4, 11...
Fixed hood, 5, 15...Exhaust duct, 12, 1
7,...20,21...Movable hood.

Claims (1)

[Scope of utility model registration request] It is characterized by consisting of a fixed hood provided on the upper lid of the ladle, a movable hood provided above the fixed hood so as to be movable up and down and covering the fixed hood, and an exhaust duct provided on the movable hood. Dust collection hood for ladle refining.