KR19980026444U - Blockage prevention device of the blast furnace - Google Patents

Abstract

The present invention filters the spectral components of a certain diameter or more at the front end of the lance to stably operate the furnace in a proper state by inhaling and analyzing the gas inside the furnace. This filter relates to a storage blockage preventing device of the smelting furnace which enables a stable operation of the equipment by remarkably lengthening the replacement cycle of the filter, and the gas suction port 162 formed at the inner end of the smelting furnace of the storage delance 110. Equipped with a spectroscopic strainer (1) is fixed by the screw member (2) to block the), the body 10 of the spectroscopic strainer (1) having a space (12) formed inside the upper end at the open end side of the furnace The front blocking plate 20 is installed to rotate at the center of rotation, and the through-hole 17 of the appropriate size is formed in the rear side closed end wall 16 of the body 10. The front blocking plate 20 is formed of several, characterized in that for forming a plurality of through-holes 24 of the appropriate size and the gas suction space 26 is larger than the size of the through-holes 24. .

Description

Blockage prevention device of the blast furnace

The present invention relates to an apparatus that collects only gas components through a storage delance in a gas analysis chamber in a sonde facility that performs stable operation in a proper state by inhaling and analyzing gas in a furnace. By filtering out spectral components of a certain diameter or more from the lance tip first, only spectral components with a small diameter are filtered out by the gas component measurement filter, and the replacement cycle of the filter is significantly longer than before. The present invention relates to a clogging prevention device.

Shaft Sonde is a measurement equipment for the analysis of the furnace temperature, pressure and composition of the furnace.

During operation during the operation of the furnace, the storage delance is inserted into the center of the furnace and the retardation is inserted into the center of the furnace, and then the sample gas is sucked in a number of places for a certain period of time. And pressure.

The component data value of the gas thus analyzed becomes a criterion for judging the state of the gas inside the furnace, and thus becomes a value for the operation of the furnace.

The storage zone is usually operated once or twice a day to collect the gas and use it in the operation of the furnace as a gas state therefor, and an approximate configuration thereof is as shown in FIG.

That is, the storage delance 110 is fitted to the upper side of the furnace 100 so that the inner end thereof is mounted to move in the radial direction of the furnace in the state where the inner end is located inside the furnace 100, the furnace of the lance 110 (100) The gas blocking gate valve 112 is provided to open and close the inner gas flow passage of the lance 110 at an appropriate outside portion, and the outer end of the blast furnace 100 of the lance 110 has a measuring pipe 120. ) And the measured gas to be delivered to the appropriate place, the measurement pipe 120 is a gas intake shutoff valve 122, the primary filter 131 for removing spectral components, and for removing water It is connected to the gas analysis chamber 10 via the secondary filter 132.

Further, a nitrogen gas purge pipe 150 is provided with a purge valve 152 between the rear end of the lance 110 and the gas suction blocking valve 122 of the measurement pipe 120, and the As shown in FIG. 2, a tip gas suction body 160 having a gas suction port 162 is mounted at the tip end of the furnace 100, and a lance is used to collect a gas component in the upper part of the furnace 100. After inserting the 110 into an appropriate position in the upper portion of the furnace 100, the purge valve 152 is shut off, and the gas blocking gate valve 112 and the gas suction blocking valve 122 are opened to the tip gas suction body 160. Analyze the gas component by inhaling the gas for a predetermined time through the gas analysis chamber 140 and continuously backing the lance 110 for a predetermined distance and analyzing the gas for a predetermined time in the same manner as described above. Done.

When the gas component analysis is completed, the purge valve 152 is opened, and the gas blocking gate valve 112 and the gas suction blocking valve 122 are blocked, so that nitrogen is introduced into the furnace 100 through the tip gas suction body 160. By purging the gas to clean the lance 110 to wait for the next work.

By the way, the main problem that occurs during the gas analysis work in the furnace is that the intake of gas through the lance 110 is not made properly, which is about 5 ~ 75mm of the particle size of the charge used in the operation of the furnace, charged in the furnace The charged contents are reduced and differentiated to have a smaller particle size. A large amount of spectroscopy is sucked together with the gas through the lance 110 while the lance 110 is operated for the yellowing analysis. The main factor is to block the gas and the spectral component is fixed to the inner surface of the lance 110 to block the flow of gas, but in the past it does not prevent the problem and often replace the filter and purge nitrogen gas Although gas analysis was performed by solving the problem, the iron spectroscopy was fixed to the inner surface of the lance 110, but only by the purge of nitrogen gas. You can not solve such problems was to be carried out through a separate task, but also frequent exchange of filter was causing extra work factor for the maintenance of the facility.

The present invention has been devised to solve such a conventional problem, and its purpose is to accumulate only the gas components in the Sonde facility to perform stable operation in an appropriate state by inhaling and analyzing gas in the interior of the furnace. By collecting the gas through the analysis chamber, to prevent clogging of the lance and filter, etc. to provide a clogging prevention device for the storage of the furnace to ensure the stable operation of the equipment.

1 is a schematic configuration diagram showing a gas component analysis equipment of a typical furnace.

Figure 2 is a cross-sectional detail view showing a conventional lance tip configuration.

Figure 3 is a schematic configuration diagram showing the lance front end having a clogging prevention device of the blast furnace according to the present invention.

Figure 4a is a perspective view of the spectral strainer that is the main portion of the clogging prevention device of the blast furnace according to the present invention.

Figure 4a is a front sectional view of the spectral strainer that is the main part of the blockage preventing device of the blast furnace according to the present invention.

* Description of the symbols for the main parts of the drawings *

1: spectral manure

10: body

12: Space

14: Screw hole

16: closed end wall

17: Through hole

20: Front blocking board

22: hinge

24: through hole

100: furnace

110: Lance

As a technical configuration for solving such a conventional problem, the present invention is a device for sucking and analyzing gas components inside the furnace by inserting a storage delance on one side of the furnace, and formed at the inner end of the furnace of the storage delance. Equipped with a spectroscopic strainer that is fixed by a screw member to block the gas inlet, the body of the spectroscopic strainer formed a space therein is provided with a front blocking plate to rotate in the open end side of the furnace with the upper end in the rotation center, The rear side closed end wall of the body is formed with a plurality of through-holes of the appropriate size, the front blocking plate is formed a plurality of through-holes of the appropriate size and to form a gas suction space larger than the size of the through-holes. By providing a clogging prevention device for the storage of the furnace characterized in that.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

A rough facility for the gas analysis of the furnace shown in FIG. 1, that is, a storage delance 110 is fitted on one side of the furnace 100 in the radial direction of the furnace with the inner end of the furnace 100 positioned inside the furnace 100. The gas blocking gate valve 112 is installed to move and to open and close the gas flow passage of the lance 110 at an appropriate location outside the blast furnace 100 of the lance 110. The outer end of the furnace 100 is connected to the measurement pipe 120 to deliver the measured gas to the appropriate place, the measurement pipe 120 is a gas intake shutoff valve 122, for removing the spectral components It is connected to the gas analysis chamber 140 through the primary filter 131 and the secondary filter 132 for removing water, and the rear end of the lance 110 and the gas suction blocking valve 122 of the measurement pipe 120. The nitrogen gas purge pipe 150 has a purge valve 152 between the About a configuration in which connection is the same as that of the prior art.

The present invention forms a gas suction port 162 of the lance 110 to fix the spectral strainer 1 to the tip gas suction body 160 mounted on the front end of the furnace 100 through the screw member 2. In addition, the spectral strainer (1) as shown in more detail in Figures 4a and 4b to form an empty space (12) inside and consists of a hollow cylinder-shaped body (10) of which one end is closed and the other end is open; In the proper portion of the center portion of the body 10, a screw hole 14 to which the screw member 2 is fastened is formed, and one closed end wall 16 has a plurality of through holes 17 having a proper diameter. The main body 10 is fitted into the gas suction port 162 of the tip gas suction body 160 so that the closed end wall 16 faces the lance 110 and is fixed as a screw member 2, wherein the body ( The outer diameter of 10) is equal to the inner diameter of the gas suction port 162 of the tip gas suction unit 160.

The front blocking plate 20 is mounted at the front opening of the body 10, and the hinge 22 is mounted at the upper end of the front blocking plate 20 so that the front blocking plate 20 is mounted on the body ( 20, the front blocking plate 20 is rotatable by the hinge 22, and the front blocking plate 20 is formed in a substantially disc shape, but the lower end portion of the front blocking plate 20 is removed. When the front blocking plate 20 is in surface contact with the open end side of the body 20 to form a gas suction space 26 having a size larger than the size of the through hole 24 to be described later, such a front The blocking plate 20 is formed with a plurality of through holes 24. Preferably, the diameter of the through holes 24 is larger than the diameter of the through holes 17 of the closed end wall 16. It is good to form, which is a sequential order from the large diameter formed By removing to a more efficient removal it is possible. In addition, the size of the through hole 17 of the closed end wall 16 and the through hole 24 of the front shielding plate 20 is the size of the spectral generated by the charges charged into the furnace (usually 3 to 28 mm). Diameter), which should be formed smaller than the size of the spectroscopy. In addition, although the shape of the through-holes 17 and 24 is indirectly circular in the above description, it is natural to form other shapes such as an ellipse or a polygon.

After installing the clogging prevention device of the blast furnace according to the present invention having the above-described configuration, the lance 110 is operated to suck gas inside the blast furnace 100 (see arrow (A) of FIG. 4A). The front blocking plate 20, which is rotatable by suction force, rotates about the hinge 22 to close the front open portion of the body 10. At this time, a spectral component having an appropriate diameter together with the furnace gas component is sucked together. Of these spectral components, those larger than the proper size are primarily blocked by the front blocking plate 20 of the spectral strainer 1 of the present invention. Or through the through hole 24 of the front blocking plate 20 to the internal space 12 of the body 10.

Of course, the spectral component having a large diameter through the gas suction pipe 26 will also be slightly sucked into the space 12 side.

The spectral component first filtered by the gas sucked into the space 12 and the front blocking plate 20 moves to the rear side of the body 10, and thus passes through the through hole 17 of the closed end wall 16. Spectral components that could not be removed from the front barrier plate 20 and the gas suction space 26 are blocked and remain in the space 12, and only the very fine spectral components and gas components are passed through the lance 110 through the gas analysis chamber 140. To the side.

Therefore, the fine spectral components are filtered by the filter 131, so that the replacement cycle of the filter 131 is remarkably increased as compared to the conventional one, and the stable operation of the equipment for gas component analysis is possible.

After the gas suction process for the gas component analysis is completed, the nitrogen component is supplied to the spectral strainer 1 through the lance 110 (see arrow (B) of FIG. 4B), in which case the nitrogen pressure is spectroscopically. It extends to the front blocking plate 20 of the mandrel (1), the front blocking plate 20 is rotated about the hinge 22 so that the body 10 is completely open the front opening, and thus in the space 12 The remaining spectroscopic 44 component is removed into the furnace 100.

Thus, the standby state for the next gas suction.

As described above, according to the anti-clogging device of the blast furnace according to the present invention, when the lance is inserted into the blast furnace and the gas constituents are sucked from the lance, the spectral component having a predetermined diameter or more at the tip of the lance is first filtered. As a gas component measurement filter, only a spectral component having a small diameter is filtered out, and the replacement cycle of the filter is significantly longer than in the related art, thereby having an excellent practical effect that enables stable operation of the equipment.

Claims (2)

In the apparatus for sucking and analyzing the gas components inside the furnace 100 by inserting the storage delance 110 on one side of the furnace 100, The spectrometer equipped with a spectral strainer (1) fixed by the screw member (2) to block the gas inlet 162 formed at the inner end of the furnace of the storage delance 110, the spectrometer having a space 12 therein The body 10 of the sieve 1 is provided with a front blocking plate 20 so as to rotate on the open end of the furnace side with the upper end as the center of rotation, and an appropriate size on the rear closed end wall 16 of the body 10. A plurality of through holes 17 are formed, and the front blocking plate 20 has a plurality of through holes 24 of a suitable size and is larger than the size of the through holes 24. The clogging prevention device of the blast furnace, characterized in that to form a). The method of claim 1, The size of the through-hole 24 of the front blocking plate 20 is closed end wall blocking device 16, characterized in that the formed larger than the size of the through-hole 17.