KR100700625B1 - Water cooled thermal insulation door device for shielding heat of melting furnace - Google Patents

Abstract

The present invention is a water-cooled heat exchange with the high heat radiated from the melting furnace to obtain a sufficient cooling power, to prevent distortion and damage of the structure due to high heat, and to shield the radiant heat radiating furnace to ensure the safety of workers from thermal diffusion and impact Provide a water-cooled heat door device. The present invention provides a heat dissipation door for shielding heat dissipated from a melting furnace, comprising: a conveying bogie positioned at a front portion of the melting furnace and transported laterally; The cooling water heat exchange tube having an upper water cooling wall and a lower water cooling wall which is installed and supported on the transport cart and is in contact with and operated, wherein the upper water cooling wall and the lower water cooling wall flow the cooling water distributed from the cooling water supply header and the cooling water supply header. It includes a water-cooled wall door consisting of; The cooling water supplied to the cooling water supply header is configured to absorb and discharge high-temperature radiant heat emitted from the melting furnace while passing through the heat exchange tube.

Melting Furnace, Converter, Water Cooling Wall, Coolant, Transfer Bogie, Heat Exchange Tube

Description

Water cooled thermal insulation door device for shielding heat of melting furnace}

The following drawings, which are attached in this specification, illustrate preferred embodiments of the present invention, and together with the detailed description of the present invention, serve to further understand the technical spirit of the present invention. It should not be construed as limited to.

1 is a block diagram of a conventional melting furnace heat radiation door device,

2 is a block diagram of a water-cooled heat dissipation door device for the furnace radiant heat shield according to the present invention,

3 is a side view of the water-cooled heat dissipation door device viewed from the direction K of FIG.

4 is a cross-sectional view of the water cooling wall viewed from the A-A direction of FIG.

<Explanation of symbols for the main parts of the drawings>

20: Feed cart

30: water cooling wall door

30A: Upper Water Cooling Wall

30B: Lower Water Cooling Wall

40: coolant supply header

50: heat exchange tube

60: flexible joint

70: tilting bar

The present invention relates to a heat dissipation door for protecting equipment and personnel from the heat of the melting furnace, for example, an electric furnace, in particular to have a cooling water passage on the heat dissipation wall to provide excellent cooling performance and to safely protect the equipment and workers. One furnace relates to a water-cooled heat dissipation door device for radiant heat shielding.

In general, the converter of the steelmaking process is to refine the carbon, phosphorus, sulfur, etc. contained in the iron produced in the iron making process by dissolving iron and scrap metal and blowing oxygen to remove impurities. High heat is generated during the refining operation, radiant heat of 1000 ℃ or higher is transferred to the periphery of the converter, and if it is not radiated, it damages the existing equipment and workers.

Therefore, in the past, as shown in FIG. 1, a heat dissipation door 1 made of an iron structure using a metal heat sink has been used to block direct radiant heat. In the case of FIG. 1, the weight 3 is mounted on the transport cart 2, and the heat dissipation door 1 is supported at a predetermined angle through the support structure 4.

However, the heat dissipation method using the apparatus as shown in FIG. 1 has the effect of covering the direct damage from the radiant heat and the flame of the converter 5 to some extent, but radiated heat transmitted when the temperature is placed in a high temperature environment for a long time (6). Due to the thermal stress caused by) and the instantaneous amount of heat, there is a limit, so deformation of the structure due to thermal shock is inevitable.

In addition, it is difficult to sufficiently support the heat dissipation door (1) due to the structure to support a heavy weight structure having a height of 10m or more or to mount other accessories. As a result, the structure is warped and deformed, resulting in a significant decrease in safety and heat dissipation. In addition, due to the rapid thermal diffusion and the velocity pressure of the surrounding air, a large amount of pressure is applied to the structure, causing it to shake more than a certain amount, resulting in unstable elements due to vibration and unevenness of behavior.

Therefore, the present invention is to solve the problems of the prior art as described above, by making a heat exchange with the high heat radiated from the melting furnace by water cooling, to obtain sufficient cooling power, to prevent distortion and damage of the structure due to high heat, It is an object of the present invention to provide a water-cooled heat dissipation door device for shielding radiant heat radiation to ensure the safety of workers from impact.

Specific means of the present invention for achieving the above object, In the heat dissipation door for shielding the heat dissipated from the melting furnace, a transfer bogie positioned in the front portion of the melting furnace and transported to the side; The upper water cooling wall and the lower water cooling wall, wherein the upper water cooling wall and the lower water cooling wall have a cooling water heat exchanger tube for flowing the cooling water distributed from the cooling water supply header and the cooling water supply header. Included; The cooling water supplied to the cooling water supply header is configured to absorb and discharge high-temperature radiant heat emitted from the melting furnace while passing through the heat exchange tube.

In addition, according to the present invention, the upper water cooling wall and the lower water cooling wall is connected through a plurality of flexible joints to prevent the shock and vibration of the water cooling wall door.

In addition, according to the present invention, the upper water cooling wall is configured such that the angle adjustment is made by varying the fixed point position by the tilting bar connected to the transfer bogie.

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

Figure 2 is a front view of the water-cooled heat dissipation door device for melting furnace radiation heat shield according to the present invention, Figure 3 is a side view of the water-cooled heat dissipation door device seen from the K direction of Figure 2, Figure 4 is a water-cooled wall seen from the AA direction of Figure 2 It is a cross section of.

In the present invention, as shown in Figures 2 to 4, a pair of transport trolley 20 which is located in the front portion of the melting furnace 10 (for example, the converter) is transferred to the side.

The transport trolley 20 has a rotating roller 21 which is rotated along the guide rail 15 installed on the ground at the bottom. In addition, a balance weight 22 for lowering the center of gravity of the entire structure including the transport cart 20 is mounted on the transport cart 20. The transport trolley 20 is provided with a support structure 24 for adjusting the inclination of the upper water cooling wall of the water cooling wall door 30 to be described later.

Therefore, the pair of transport trolley 20 is to move along the guide rail 15 to the side while blocking or opening the access to the melting furnace 10. For example, while the melting furnace 10 is operating, the pair of transport trolleys 20 move in close contact with each other to block access to the melting furnace 10 side.

The transport trolley 20 is provided with a water-cooled wall door 30 for standing a heat exchange with high heat on its front surface.

In the present embodiment, the water cooling wall door 30 is divided into an upper water cooling wall 30A and a lower water cooling wall 30B, and the upper water cooling wall 30A is installed to be inclined and adjustable from the lower water cooling wall 30B. have. To this end, in the present embodiment, the upper water cooling wall 30A and the lower water cooling wall 30B are connected through a plurality of flexible joints 60 or more. The flexible joint 60 is, for example, a well-known technique having a connection port at both ends of a corrugated pipe made of a metal material and having a braid surrounding the corrugated pipe.

Therefore, the upper water cooling wall 30A may be inclined at a predetermined angle at the upper end of the lower water cooling wall 30B. This may be adjusted in consideration of the influence of the high heat generation amount of the furnace 10, the flame and splashing water. For example, when more heat is generated from the melting furnace 10 than the average value, the upper water cooling wall 30A may be further separated from the melting furnace 10 by giving an angle more.

The upper water cooling wall (30A) and the lower water cooling wall (30B) is a cooling water heat exchange tube made of a metal material flowing the cooling water distributed from the cooling water supply header 40 and the cooling water supply header 40, as shown in Figs. 50 is provided.

The cooling water heat exchange tube 50 may be installed to send the cooling water in parallel, or may be configured to send the cooling water connected in series.

In this embodiment, the cooling water heat exchange tube 50 is arranged in close contact with each other through the welding joint 51, the outlet of the cooling water heat exchange tube 50 formed in the upper water cooling wall (30A) and the lower water cooling wall (30B) is In the exemplary embodiment, one may be configured, but in some cases, two may be configured.

Meanwhile, the flexible joint 60 has an upper water cooling wall 30A and a lower water cooling wall 30B with the purpose of preventing shock and vibration caused by thermal stress and heat deformation of the water cooling wall door 30 and ambient wind pressure. Separation of the liver can facilitate maintenance.

The upper water cooling wall (30A) is the angle adjustment is made by varying the fixed point position by the tilting bar 70 is connected to the transfer cart (20).

The tilting bar 70 is connected to the rear side bracket 33 of the upper water cooling wall (30A) in one end hinged and the other end is inserted into the structure of the feed cart 10 by screwing the nut 72 It is fixed to).

Therefore, the tilting bar 70 is to adjust the inclination amount of the nut 72, so the connection point of the tilting bar 70 is changed, the inclination of the upper water cooling wall (30A) is to be adjusted.

Reference numeral '80, 81 'is a' guide sliding rail 'for detachment and safe opening and closing of the water cooling wall door 30.

The operation of this embodiment configured as described above will be described.

First, the pair of transport trolley 20 is moved to ride on the guide rail 15 as shown in FIG. In the steelmaking process, since the ambient temperature of the melting furnace 10 changes depending on the production volume and the season, the water-cooled wall door 30 must be properly positioned.

Therefore, the operator climbs on the transport cart 20 to operate the tilting bar 70 to adjust the inclination angle of the upper water cooling wall 30A of the water cooling wall door 30. As the angle increases, the distance between the upper water cooling wall 30A and the melting furnace 10 increases. This angle adjustment is appropriately adjusted in consideration of the degree of scattering of the flame and molten metal of the melting furnace (10).

When the posture is adjusted by adjusting the inclination angle of the upper water cooling wall 30A, the cooling water is supplied to the cooling water supply header 40. In this case, the cooling water may be, for example, plant water obtained from a plant intake line. At this time, the plant water has a constant water pressure.

Therefore, the cooling water is distributed from the cooling water supply header 40 and flows through the heat exchange tube 50. The high temperature radiant heat radiated from the melting furnace 10 during the flow of the heat exchange tube 50 is transferred to the cooling water. Therefore, the absorbed radiant heat is included in the cooling water and discharged to the outlet of the heat exchange tube 50. As described above, the present invention cools the water cooling wall door 30 by the cooling water, and thus, sufficient cooling power can be obtained.

At this time, the cooling water discharged through the heat exchange tube 50 is a high temperature of more than 100 ℃ Celsius is a waste water treatment or may be recycled back to industrial use.

Therefore, according to the present invention, by absorbing the radiant heat transmitted in a situation in a high temperature environment for a long time to discharge a large amount of heat to the outside, deformation by the thermal stress and thermal shock of the water-cooled wall door 30 is made I do not lose. This significantly increases work safety and heat dissipation.

In addition, even if pressure is applied to the huge water cooling wall door 30 due to the rapid thermal diffusion of the melting furnace 10 and the ambient air pressure, the structure absorbs the vibration through the flexible joint 60 and thus prevents distortion or damage of the structure. It is to realize a stable heat dissipation door.

On the other hand, the flexible joint 60 may also be used as a means of the intermediate cooling water passage connecting the heat exchange tube 50 constituting the upper water cooling wall (30A) and the lower water cooling wall (30B). In this case, the cooling water will pass through the lower water cooling wall 30B after passing through the upper water cooling wall 30A.

As described above, although the present invention has been described by way of limited embodiments and drawings, the present invention is not limited thereto, and the technical idea of the present invention and the following by those skilled in the art to which the present invention pertains. Of course, various modifications and variations are possible within the scope of equivalents of the claims to be described.

As described above, according to the water-cooled heat-dissipating door device for shielding the radiant heat of the furnace of the present invention, the heat exchange with the high heat radiated from the furnace by the water-cooled to obtain a sufficient cooling power can significantly extend the service life of the equipment, due to high heat structure It prevents warping and damage of the machine, secures the safety of workers from thermal diffusion and shock, and has the advantage of obtaining convenience of maintenance and repair.

Claims (3)

In the heat dissipation door for shielding the heat emitted from the melting furnace 10, A transport cart 20 which is located in the front part of the melting furnace 10 and is transported laterally; The upper water cooling wall 30A and the lower water cooling wall 30B, which are installed and supported on the transport trolley 20 and are in contact with and operate in contact with each other, have the upper water cooling wall 30A and the lower water cooling wall 30B supplied with cooling water. It includes a water cooling wall door 30 made of a cooling water heat exchange tube 50 for flowing the cooling water distributed from the header 40 and the cooling water supply header 40, Cooling water supplied to the cooling water supply header 40 through the heat exchange tube 50, the water-cooled heat-resistant door device for the melting furnace radiant heat shield, characterized in that configured to absorb and discharge the high-temperature radiant heat emitted from the melting furnace 10 . The method of claim 1, The upper water cooling wall 30A and the lower water cooling wall 30B are connected to each other through a plurality of flexible joints 60 to prevent shock and vibration of the water cooling wall door 30. Door device. The method of claim 1, The upper water cooling wall 30A is a water-cooled heat-dissipating door device for shielding the radiant heat by melting, characterized in that the angle adjustment is made by varying the fixed point position by the tilting bar (70) connected to the transfer cart (20).

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