KR20120057317A - Vacuum apparatus and vacuum degassing facility having the same - Google Patents

Abstract

PURPOSE: A vacuum apparatus and a vacuum degassing system including the same are provided to improve the efficiency of compressing vapor by using cooling water cooled enough. CONSTITUTION: A vacuum apparatus(100) comprises a condensing container(110), a cooling water supply pipe(130), a cooling water low-temperature holding unit, and a cooling water discharge pipe(150). The condensing container is filled with vapor. The cooling water supply pipe supplies cooling water for condensing the vapor to the inside of the condensing container. The cooling water low-temperature holding unit lowers the temperature of the cooling water by forming a refrigerant spray region(R) which the cooling water supply pipe passes through. The cooling water discharge pipe discharges the cooling water and condensate from the condensing container.

Description

Vacuum apparatus and vacuum degassing facility having the same

The present invention relates to a vacuum apparatus and a vacuum degassing plant. In particular, the present invention relates to a vacuum apparatus and a vacuum degassing apparatus having the same capable of efficiently depressurizing the inside of a vacuum chamber in which molten steel is refluxed for degassing molten steel.

Generally, the molten iron drawn out from the molten steel furnace is first refined in the converter of the steelmaking process and then secondaryly refined in a vacuum degassing plant (commonly referred to as an 'RH degassing plant').

Vacuum degassing equipment is an apparatus for removing impurities contained in molten steel for the production of high clean steel, correcting the temperature of molten steel, and refluxing molten steel to make the composition and temperature of molten steel uniform. Looking at the configuration of a general vacuum degassing equipment, a vacuum degassing equipment is connected to a vacuum tank capable of evacuating, a pair of immersion pipes connected to the lower part of the vacuum tank and deposited on molten steel injected into the ladle and connected to one side of the vacuum tank. It includes a vacuum device for reducing the pressure inside the vacuum state. Here, the pair of immersion pipe is divided into a rising tube in which the molten steel injected into the ladle so that the molten steel can be refluxed, and a falling tube in which the molten steel raised in the vacuum vessel is lowered into the ladle due to iron static pressure.

In this vacuum degassing facility, when reflux gas is injected into the riser while a pair of immersion tubes are deposited in the molten steel injected into the ladle, bubbles are generated in the molten steel and the molten steel gradually rises from the riser, and the inside of the vacuum chamber is decompressed. In this case, reflux of the molten steel that is circulated through the vacuum chamber and the descending tube is generated.

The vacuum apparatus used in the conventional vacuum degassing facility reduced the inside of the vacuum chamber connected with the vacuum apparatus in a manner to reduce the volume by condensing the hot steam filled therein with cooling water. However, in the conventional vacuum apparatus, there is a problem that the cooling water for condensing steam cannot maintain a constant temperature due to external environmental factors such as seasons or weather. That is, when the temperature or humidity of the air is high, the temperature of the cooling water is easily increased, so that the condensation efficiency for condensing steam is lowered. Therefore, the operation efficiency of the vacuum degassing treatment process of the molten steel is reduced, such as a time delay to depressurize the inside of the vacuum chamber during the degassing treatment of the molten steel, and there is a problem that the quality of the molten steel is deteriorated because the molten steel cannot be smoothly refluxed.

The present invention provides a vacuum apparatus and a vacuum degassing apparatus having the same capable of efficiently depressurizing the inside of a vacuum chamber in which molten steel is refluxed for degassing molten steel.

The present invention provides a vacuum apparatus and a vacuum degassing apparatus having the same, which can efficiently reduce the inside of the vacuum chamber by keeping the cooling water condensing steam at low temperature with liquefied nitrogen.

According to an embodiment of the present invention, a vacuum apparatus includes a condensation vessel filled with steam, a cooling water supply pipe for supplying cooling water condensing the steam into the condensation container, and a refrigerant injection via the cooling water supply pipe. And a cooling water cryostat for forming a region to reduce the temperature of the cooling water and a cooling water discharge pipe for discharging the condensed water condensed with the cooling water and the steam from the condensation vessel.

In addition, the cooling water supply pipe passing through the refrigerant injection region includes a plurality of corrugated pipes formed by extending the supply path of the cooling water.

In addition, a shower block for spraying the cooling water is provided in the condensation vessel.

The coolant low temperature maintainer may include a coolant spray housing formed to surround the coolant supply pipe, a coolant spray housing having an empty space filled with a coolant therein, and a coolant storage container storing the coolant and supplying the coolant to the coolant spray housing. do.

In addition, liquefied nitrogen is used as the refrigerant.

In addition, the refrigerant injection region is formed between the condensation vessel and the cooling water supply pipe.

Vacuum degassing equipment according to an embodiment of the present invention is vacuum chamber providing a reflux space of the molten steel, and is connected to the lower portion of the vacuum chamber is deposited in the molten steel injected into the ladle, the molten steel is raised to reflux inside the vacuum chamber And a pair of immersion pipes to be lowered and a vacuum device for condensing steam with cooling water lowered by the refrigerant to depressurize the vacuum chamber.

The vacuum apparatus may further include a coolant supply pipe for supplying the coolant to the condensation container filled with the steam, a coolant low temperature maintainer for reducing the temperature of the coolant by forming a coolant spray region through the coolant supply pipe; And a cooling water discharge pipe configured to discharge the cooling water and the condensed water condensed with the steam from the condensation container to circulate the cooling water supply pipe.

The coolant low temperature maintainer may include a coolant spray housing configured to form an empty space filled with a coolant at a temperature lower than the coolant temperature and pass through the coolant supply pipe, and a coolant storage container configured to supply the coolant to the coolant spray housing. do.

According to a vacuum apparatus and a vacuum degassing apparatus having the same according to embodiments of the present invention, a cooling water for condensing the steam charged in the vacuum apparatus is cooled to a low temperature state using liquid nitrogen before spraying it into the vacuum apparatus. Can be adjusted and maintained. Therefore, it is possible to improve the condensation efficiency of the steam in the vacuum apparatus by preventing the cooling water whose temperature rises due to external environmental factors such as weather and seasons to be used for condensing the steam, i. . Therefore, the inside of the vacuum chamber connected to the vacuum device can be quickly and efficiently reduced in pressure, thereby improving the operation efficiency of the process of degassing the molten steel and improving the quality of the molten steel by allowing the molten steel to be smoothly refluxed. Can be.

1 is a view showing the configuration of a vacuum apparatus according to an embodiment of the present invention.
2 is a view showing a driving state of the vacuum device shown in FIG.
Figure 3 is a view showing the configuration of a vacuum degassing plant according to an embodiment of the present invention.
4 is a view showing a driving state of the vacuum degassing facility shown in FIG.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various forms, and only the embodiments of the present invention to complete the disclosure of the present invention, to those skilled in the art It is provided to fully inform the category. Wherein like reference numerals refer to like elements throughout.

1 is a view showing the configuration of a vacuum apparatus according to an embodiment of the present invention, Figure 2 is a view showing a driving state of the vacuum apparatus shown in Figure 1, Figure 3 is an embodiment of the present invention FIG. 4 is a view illustrating a configuration of a vacuum degassing facility, and FIG. 4 is a view illustrating a driving state of the vacuum degassing facility illustrated in FIG. 3.

1 to 4, a vacuum device 100 according to an embodiment of the present invention includes a condensing chamber 110 filled with steam S and a steam At least one cooling water supply pipe 130 for supplying cooling water C _w condensing S) into the condensation vessel 110, and a refrigerant injection region R through which the cooling water supply pipe 130 passes. a formed by the cooling water cooling the low temperature maintained for reducing the temperature of (C _w) (140) and cooling water (C _w) from the condensation vessel 110, and vapor coolant discharge to (S) is discharged to the condensed condensate (S ') The pipe 150 is included.

The condensation vessel 110 has an empty space formed therein so that the steam (S) can be filled. Steam (S) filled in the empty space of the condensation vessel 110 is condensed or liquefied by the supply of the cooling water (C _w ) to reduce the volume rapidly to reduce the internal pressure of the condensation vessel (S). Therefore, the vacuum chamber 200 connected with the condensation vessel 110 may be reduced in pressure. The condensation vessel 110 is formed of a metal material having high heat resistance and durability to prevent thermal damage or thermal deformation due to the high temperature steam (S), and to prevent deformation due to a change in the pressure inside the condensation vessel 110. In the present embodiment, the condensation vessel 110 is formed in a cylindrical shape, the upper end portion is formed in a conical shape that the inner diameter and the outer diameter decreases as the lower portion goes down. That is, the cooling water C _w supplied to the inside of the condensation vessel 110 and the condensation water S ′ condensed with the steam S may be smoothly collected at the lower end of the condensation vessel 110 by its own weight. .

One side of the upper end of the condensation vessel 110 as described above is connected to the steam supply pipe 120 for supplying the steam (S) generated from the outside into the condensation vessel 110 (see Fig. 2 (a)). In addition, between the steam supply pipe 120 and the condensation vessel 110 or on the path of the steam supply pipe 120 by controlling the opening and closing of the steam supply pipe 120 can control the supply and the amount of steam (S) and the like. Valve means 122 is provided.

At least one cooling water supply pipe 130 for supplying cooling water C _w may be connected to an upper end of the condensation vessel 110 to condense the steam S filled in the condensation vessel 110. In this embodiment, the cooling water C _w having the same component as the steam S was used as a means for cooling the steam S. Therefore, the condensate (S ') condensed with steam (S') and the cooling water (C _w ) supplied to the condensation vessel 110 is smoothly mixed in the lower portion of the condensation vessel 110, and reused in the lower end of the condensation vessel (110) To the cooling water (C _w ') for. On the other hand, the cooling water supply pipe 130 has a plurality of corrugated pipes through the refrigerant injection region (R) formed on the upper side of the condensation vessel 110, that is, the region for reducing the temperature of the cooling water (C _w ); 134). Therefore, it is possible to improve the efficiency of reducing the temperature of the cooling water (C _w) by extending the feed path (travel path) of the coolant (C _w), even if the coolant emission region (R) is formed smaller. On the path of the cooling water supply pipe 130 is provided with a valve means 132 for opening and closing the cooling water supply pipe 130 can adjust the supply and supply amount of the cooling water (C _w ) supplied to the condensation vessel (110). have.

A shower block (shower block) 114 connected to the cooling water supply pipe 130 is provided at an inner upper end of the condensation vessel 110 to which the cooling water supply pipe 130 is connected. Shower block 114 is a block diagram of a hollow shape which the water (C _w) flows, a bottom surface is formed with a plurality of injection is passing through the flowing coolant (C _w) hole (not shown). The shower block 114 is formed in the same shape and size as the horizontal cross section formed by the inner space of the upper end of the condensation vessel 110 so that the cooling water C _w supplied from the cooling water supply pipe 130 is the center of the condensation vessel 110. It can be spread evenly on the part and the edge part. In this embodiment, the upper end of the condensation vessel 110 is formed in a cylindrical shape so that the shower block 114 has a cylindrical shape.

The cooling water supply pipe 130 connected to the vacuum device 100 may be exposed to the air, and thus the temperature of the cooling water C _w may be increased by being easily affected by environmental factors such as a season such as summer or high humidity and hot weather. have. When the temperature of the cooling water C _w rises, the condensation efficiency is lowered because the steam S charged in the condensation vessel 110 is not condensed efficiently, thereby reducing the condensation efficiency of the vacuum chamber 200 connected to the vacuum apparatus 100. There was a problem in that the inside can not be reduced to a high vacuum state. According to the present invention In order to solve this problem it was provided with a cooling water (C _w) for supplying to the interior of the condensation vessel (110) around the cooling water (C _w) low-temperature cooling water retainer 140 to lower the temperature. In this embodiment, the temperature of the cooling water Cw passing through the cooling water cryostat 140 may be cooled and maintained to be about 0 ° C., which is a limit temperature for maintaining the liquid phase.

The coolant cryostat 140 may have a coolant having a temperature lower than that of the coolant C _w to form a region in which the temperature of the coolant C _w may be adjusted and maintained at a low temperature, that is, a coolant spray region R. refrigerant; R _f) is to be filled comprises a refrigerant injection housing 142 and the refrigerant (the refrigerant storage container 144 which supplies to store R _f) the coolant housing 142 is provided with an empty space therein. A refrigerant supply pipe 145 and a refrigerant injection housing 145 for supplying the refrigerant R _f stored in the refrigerant storage container 142 to the refrigerant injection housing 142 between the refrigerant injection housing 142 and the refrigerant storage container 142. A refrigerant recovery pipe 146 capable of recovering the refrigerant R _f supplied to the 142 to the refrigerant storage container 142 is provided. In addition, on the path of the refrigerant supply pipe 145 and the refrigerant recovery pipe 146, valve means 147 and 148 are provided to control whether or not the refrigerant R _f is supplied and recovered and the amount of the refrigerant.

The valve means 147 provided in the refrigerant supply pipe 145 is opened, and the refrigerant R _f stored in the refrigerant storage container 142 is supplied to the refrigerant injection housing 142 (see FIG. 2B). The coolant supply pipe 130, in particular, a plurality of corrugated pipes 134, is positioned inside the refrigerant injection housing 142. The refrigerant R _f is injected or injected toward the plurality of corrugated pipes 134 to fill the refrigerant injection housing 142 in which the refrigerant injection region R is formed. The refrigerant R _f filled in the refrigerant injection housing 142 may cool the plurality of corrugated pipes 134 to cool the coolant C _w transferred from the inside of the plurality of corrugated pipes 134 (FIG. 2C). Reference). Therefore, by supplying cooling water (C _w) is low cooling water (C _w) to the condensation temperature vessel 110 can lower the temperature can be efficiently condensed by the steam (S). The coolant R _f supplied to the coolant spray housing 142 may be filled in the coolant spray housing 142 during the cooling of the cooling water C _w or may be in a circulating state where supply and recovery are continuously performed. May exist. The solvent R _f exited from the refrigerant injection housing 142 through the refrigerant recovery pipe 146 may be recovered to the refrigerant storage container 142 for reuse, and may be recovered to a separate refrigerant storage container. On the other hand, in the present embodiment, a liquid nitrogen (liquid nitrogen), which is a colorless, transparent and highly inert, low temperature liquid, is used as the refrigerant R _f for reducing the temperature of the cooling water C _w . A range of the refrigerant is easily maintained at a low temperature the temperature of the cooling water (C _w) to be able to quickly and efficiently reduced it can be applied as a cooling medium for cooling the cooling water (C _w).

When the decompression of the vacuum apparatus 100 is completed, the cooling water C _w and the condensate S ′ which are accumulated at the lower end of the condensation vessel 110 through the cooling water discharge pipe 150 connected to the lower portion of the condensation vessel 110 are completed. It may be discharged to the outside of the condensation vessel 110 (see Fig. 2 (d)). A valve means 152 may be provided on the path of the cooling water discharge pipe 150 to automatically adjust whether or not the cooling water C _w ″ is discharged. A series of procedures may be provided by separately providing a controller for controlling the aforementioned valve means. As a result, the driving of the vacuum apparatus 100 may be controlled.

Hereinafter, a description will be given of the vacuum degassing apparatus having the vacuum apparatus 100 according to the embodiment of the present invention described above. The same contents as those described in the above-described vacuum apparatus 100 will be omitted or simply referred to.

Vacuum degassing equipment 1000 according to an embodiment of the present invention is connected to the lower portion of the vacuum tank 200, the vacuum chamber 200 to provide a reflux space of molten steel (molten steel 1) ladle (ladle; It is deposited by the molten steel 1 injected into 10), the pair of immersion pipe 300 to raise and lower the molten steel 1 to reflux in the interior of the vacuum chamber 200 and the temperature by the refrigerant (R _f ) It includes a vacuum device 100 for condensing the steam (S) with the reduced cooling water (C _w ) to depressurize the vacuum chamber (200).

The vacuum chamber 200 is formed by the upper and lower coupling of the upper tank 210 and the lower tank 220, a pair of immersion pipe 300 is connected to the lower portion of the lower tank 220, one of the molten steel (1) It is used as a rising pipe 310 to be raised to the lower tank 220 and the other is formed as a lower pipe 320 in which the molten steel 1 is lowered from the lower tank 220. One side of the riser 310 is provided with a reflux gas nozzle 312 for injecting the reflux gas (G) inside the riser (310). The ladle 10 in which the molten steel 1 is contained in the lower portion of the vacuum chamber 200 is seated on the ladle elevator 30, and the lower part of the deposition tube 200 is molten steel 1 by vertical movement of the ladle elevator 30. ) Is deposited.

In order to reflux the molten steel 1 injected into the ladle 10 through the rising pipe 310, the lower tank 220, and the lower pipe 320, a vacuum capable of depressurizing the inside of the vacuum chamber 200 to a vacuum state. The apparatus 100 is provided outside of the vacuum chamber 200. The vacuum apparatus 100 applied to the vacuum degassing apparatus 1000 according to the present embodiment includes a cooling water supply pipe 130 for supplying cooling water C _w to a condensation vessel 110 filled with steam S, and Cooling water cryostat 140 for reducing the temperature of the cooling water C _w by forming a refrigerant injection region through which the cooling water supply pipe 130 passes, and cooling water C _w and steam S from the condensation vessel 110. It comprises a cooling water discharge pipe 150 for circulating the condensed water (S ') is condensed to the cooling water supply pipe 130. In addition, the coolant cryostat 140 may include a coolant spray housing 142 which forms an empty space filled with the coolant R _f at a temperature lower than the coolant C _{w, and} passes through the coolant supply pipe 130. And a refrigerant storage container 144 for supplying the refrigerant R _f to the refrigerant injection housing 142.

A pressure reducing pipe 400 is connected between the vacuum chamber 200 and the vacuum apparatus 100 so as to reduce the pressure inside the vacuum chamber 200 by the pressure-reducing effect inside the vacuum apparatus 100, and the pressure reducing pipe 400. The valve means 402 is provided to control the opening and closing of the decompression pipe 400 to prevent the steam S supplied to the vacuum apparatus 100 from flowing into the vacuum chamber 200.

The steam S condensed in the vacuum apparatus 100 is vaporized when the cooling water C _w ″ circulating in the furnace is subjected to high temperature heat and smoothly supplied during the vacuum degassing treatment of the molten steel 1. The steam (S) is filled in the condensation vessel 110 through the steam supply pipe 120, and the cooling water (C _w ) whose temperature is controlled and maintained by the refrigerant (R _f ) such as liquid nitrogen is condensation vessel (110). ) To increase the condensation efficiency of the steam S. That is, the volume of the steam S can be reduced rapidly and a large amount, so that the internal pressure of the vacuum apparatus 100 can be effectively reduced. In addition, the inside of the vacuum chamber 200 connected to communicate with the vacuum apparatus 100 may be quickly decompressed to a high vacuum state.

The water (C _w) supplied to the vacuum device 100 and the steam (S) is condensed condensate (S '), the cooling water discharge pipe 150, the cooling water (C _w is discharged via ") has a circulation tank 30, etc. By recovering and re-supplied to the cooling water supply pipe 120 can be used by circulating the cooling water ( _Cw ) in the degassing process of the molten steel (1).

As described above, according to the vacuum apparatus and the vacuum degassing apparatus including the same according to the embodiments of the present invention, liquefied nitrogen is used before the cooling water for condensing the steam charged in the vacuum apparatus is sprayed into the vacuum apparatus. It can be adjusted and maintained in a low temperature state. Therefore, it is possible to improve the condensation efficiency of the steam in the vacuum apparatus by preventing the cooling water whose temperature rises due to external environmental factors such as weather and seasons to be used for condensing the steam, that is, by using the cooling water that has been kept cooled to a sufficiently low temperature. . Therefore, the inside of the vacuum chamber connected to the vacuum device can be quickly and efficiently reduced in pressure, thereby improving the operation efficiency of the process of degassing the molten steel and improving the quality of the molten steel by allowing the molten steel to be smoothly refluxed. Can be.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. Therefore, it will be apparent to those skilled in the art that the present invention may be variously modified and modified without departing from the spirit of the appended claims.

100: vacuum device 110: condensation vessel
114: shower block 120: steam supply piping
122: valve means 130: cooling water supply pipe
132: valve means 134: corrugated pipe
140: coolant cryostat 142: refrigerant injection housing
144: refrigerant storage container 150: cooling water discharge pipe
200: vacuum chamber 300: immersion tube
1000: vacuum degassing plant

Claims (9)

A condensation vessel filled with steam therein;
A cooling water supply pipe for supplying cooling water for condensing the steam into the condensation vessel;
A coolant low temperature maintainer configured to reduce a temperature of the coolant by forming a coolant spraying region through the coolant supply pipe; And
A cooling water discharge pipe configured to discharge the cooling water and the condensed water condensed with the steam from the condensation vessel;
Vacuum device comprising a. The method according to claim 1,
And the cooling water supply pipe passing through the refrigerant injection region includes a plurality of corrugated pipes formed by extending the supply path of the cooling water. The method according to claim 1,
And a shower block inside the condensation vessel for spraying the cooling water. The method according to any one of claims 1 to 3,
The coolant cryostat,
A refrigerant injection housing formed to surround the cooling water supply pipe and having an empty space filled therein;
A refrigerant storage container storing the refrigerant and supplying the refrigerant to the refrigerant injection housing;
Vacuum device comprising a. The method of claim 4,
Liquid nitrogen is used as the refrigerant. The method according to claim 1,
The coolant spraying region is formed between the condensation vessel and the cooling water supply pipe. A vacuum chamber providing a reflux space of the molten steel;
A pair of immersion pipes connected to a lower portion of the vacuum chamber and deposited on molten steel injected into a ladle, and configured to raise and lower the molten steel to be refluxed in the vacuum chamber;
A vacuum device for condensing steam with cooling water lowered by a refrigerant to depressurize the vacuum chamber;
Vacuum degassing plant comprising a. The method of claim 7,
The vacuum device,
A cooling water supply pipe for supplying the cooling water to the condensation vessel filled with the steam;
A coolant low temperature maintainer configured to reduce a temperature of the coolant by forming a coolant spraying region through the coolant supply pipe;
A cooling water discharge pipe configured to discharge the cooling water and the condensed water condensed with the steam from the condensation container and circulate to the cooling water supply pipe;
Vacuum degassing plant comprising a. The method according to claim 8,
The coolant cryostat,
A refrigerant injection housing forming an empty space filled with a refrigerant having a temperature lower than that of the cooling water and passing through the cooling water supply pipe;
A refrigerant storage container for supplying the refrigerant to the refrigerant injection housing;
Vacuum degassing plant comprising a.

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