KR200278278Y1 - Thermal barrier door device in vertical furnace - Google Patents

Abstract

The present invention more effectively blocks the flow of high-temperature atmosphere gas to the low-temperature cooling gas to improve the thermal efficiency of the vertical, and does not damage the surface of the strip, such as scratches, the deformation of the strip due to the temperature change from high temperature to low temperature The present invention relates to an in-lane thermal barrier door device that can be improved to improve the quality of the strip.

The present invention is a hollow rectangular casing positioned between the heating table and the cooling table of the vertical furnace; The upper and lower edges of the casing are provided with a movable frame to move in pairs in a direction perpendicular to the strip in a direction perpendicular to the strip, the middle of the moving frame is equipped with a roller and a blocking plate, respectively, the gas blocking mechanism disposed on both sides of the strip And a rack gear formed at the rear end of the movable frame and a pinion gear engaged with the rack gear, and a drive motor for rotating the pinion gear to move the gas shutoff mechanism in a direction perpendicular to the strip. Provides a thermal barrier door device in a vertical furnace including a drive mechanism.

Description

Thermal barrier door device in vertical furnace

The present invention relates to a thermal barrier door device in a vertical furnace which is mounted between a high temperature atmosphere gas and a low temperature cooling gas in a vertical furnace for annealing a cold rolled stainless strip, and more specifically, the high temperature atmosphere gas is a low temperature cooling gas. Improve the thermal efficiency of the vertical furnace by blocking the flow to the side more effectively, do not damage the surface of the strip, such as scratches, and can improve the quality of the strip by correcting the deformation of the strip due to the temperature change from high temperature to low temperature The present invention relates to an in-vehicle thermal barrier door device that has been improved.

Generally, cold rolled stainless strips are annealed in vertical furnaces using reducing hydrogen gas as the atmosphere gas. The vertical furnace 100 is shown in Figure 1, the vertical furnace 100 has a heating table 110 is located on the lower side and the cooling table is located on the upper side, the heating strip 110, the strip passing through the center to the upper side. A plurality of burners 112 are disposed toward (S) to heat the interior of the heating table 110 to approximately 1000 to 1300 ° C. In the cooling stand 120 on the upper side of the heating table 110, a plurality of cooling fans 122 are disposed on the left and right sides of the strip S to cool the strip S at a temperature of about 70 to 80 ° C.

Therefore, in the annealing treatment vertical furnace 100 as described above, in order to prevent the high temperature atmosphere gas of the heating table 110 from flowing into the low temperature cooling gas of the cooling table 120 and lowering the thermal efficiency, as shown in FIG. 2. The same heat shield door device 130 is mounted between the heating table 110 and the cooling table 120.

The conventional vertical furnace thermal cutoff door device 130 as described above is provided with a thermal barrier plate 132 disposed on both sides of the strip (S) in the interior of the vertical path 100, as shown in FIG. The heat shield plate 132 is coupled to the rotation shaft 134 to be rotatable, and the rotation shaft 134 rotates through a plurality of drive cylinders 136 and link members 138 mounted on the outside of the vertical path 100. It is configured to.

Accordingly, when the blocking plate 132 maintains a right angle with respect to the strip S at both sides of the strip S, the blocking plate 132 is rotated to relatively maintain the inclination with respect to the strip S. By adjusting the atmosphere by adjusting the flow rate of the atmosphere gas flows toward the cooling table 120 to achieve the temperature control in the vertical furnace (100).

However, in the conventional thermal barrier device 130 as described above, when the blocking plate 132 maintains a right angle with respect to the strips S on both sides of the strips S to block the atmosphere gas, the heating table 110 is provided. Due to the rapid temperature difference between the cooling zone 120 and the strip (S), the deformation of the strip (S) bent in the C shape in the width direction thereof, and the deformation of the strip (S) is the edges of both sides of the strip (S) Was in contact with the blocking plate 132 to cause a problem of surface quality, such as scratches.

Since the contact between the blocking plate 132 and the strip S may cause not only the surface quality but also the breaking of the strip S, the blocking plate 132 is actually opened, and thus, the strip S Although contact with the gas is prevented, a high-temperature atmosphere gas on the heating stage 110 flows to the cooling stage 120 side, causing excessive heat loss on the heating stage 110 side.

In addition, as the temperature of the cooling gas is increased, the cooling fan 112 is exerted to cause equipment accidents such as burnout of the fan motor (not shown).

The present invention is to solve the conventional problems as described above, its purpose is to more effectively block the flow of high-temperature atmosphere gas to the low-temperature cooling gas side to improve the thermal efficiency of the vertical, and to damage the surface of the strip, such as scratches Therefore, to improve the surface quality of the strip, and to correct the deformation of the strip due to the temperature change from high temperature to low temperature to provide an improved in-vehicle thermal insulation door device to improve the quality of the strip.

1 is a configuration diagram showing a general bright annealing vertical furnace;

Figure 2 is a block diagram showing a vertical thermal barrier door device according to the prior art;

Figure 3 is a perspective view of a vertical furnace thermal barrier door device according to the present invention;

Figure 4 is an exploded perspective view showing a vertical thermal barrier door device according to the present invention;

Figure 5 is a schematic cross-sectional view showing the operating principle of the vertical thermal barrier door device according to the present invention;

Figure 6 is an exploded perspective view showing a rotating roll of the vertical thermal barrier door device according to the present invention;

7 is a cross-sectional view showing a rotating roll mounting configuration of the vertical furnace thermal cutoff door device according to the present invention;

8 is a detailed view of the supporting roller portion provided in the vertical furnace thermal cutoff door device according to the present invention.

Explanation of symbols on the main parts of the drawings

5 ..... Casing 10 ..... Gas shutoff mechanism

12 .... Moving frame 14 ..... Roller

18 .... rack gear 22 ..... drive motor

30 .... Driving mechanism 32 ..... Guide part

42 .. Bearing 60 ..... Skirt

70 .... position detection sensor 110 .... heating table

120 ... cooling stand

In order to achieve the above object, the present invention, in the vertical furnace heat-blocking door device is mounted between the high-temperature atmosphere gas and the low-temperature cooling gas in the vertical furnace for annealing the cold rolled stainless strip,

A hollow rectangular casing positioned between the heating table and the cooling table in the vertical furnace; The upper and lower edges of the casing are provided with a movable frame to move in pairs in a direction perpendicular to the strip in a direction perpendicular to the strip, the middle of the moving frame is equipped with a roller and a blocking plate, respectively, the gas blocking mechanism disposed on both sides of the strip And a rack gear formed at the rear end of the movable frame and a pinion gear engaged with the rack gear, and a drive motor for rotating the pinion gear to move the gas shutoff mechanism in a direction perpendicular to the strip. The drive mechanism; by providing a thermal barrier door device in the vertical furnace characterized in that it comprises a.

Hereinafter, the present invention will be described in more detail with reference to the drawings.

In the vertical furnace thermal cutoff door device 1 according to the present invention is the heating table 110 of the hot atmosphere gas and the cooling table 120 of the low temperature cooling gas in the vertical furnace 100 for annealing the cold rolled stainless strip (S). Mounted between them) to block them.

3 and 4, the heat shield door device 1 of the present invention has a hollow rectangular casing 5 between the heating table 110 and the cooling table 120 of the vertical path 100. The strip (S) passes through the center of the rectangular casing (5).

In addition, the inner side of the casing (5) has a gas blocking mechanism (10) on both sides of the strip (S), respectively, the gas blocking mechanism (10) in the direction perpendicular to the strip (S) in the upper and lower sides of each other It has a movable frame 12 which is slidably movable in pairs to face each other, and a roller 14 and a blocking plate 16 are mounted in the middle portion of the movable frame 12 to be symmetrical to both sides of the strip S, respectively. To be placed.

In addition, a rack gear 18 formed on the rear end of the movable frame 12 and a pinion gear 20 meshed with the rack gear 18, and a drive motor for rotating the pinion gear 20 ( 22) and a drive mechanism 30 for moving the gas shutoff mechanism 10 in a direction perpendicular to the strip S.

On the other hand, the gas shutoff mechanism 10 and the drive mechanism 30 has the same structure and function as the moving frame 12 or the roller 14 and the blocking plate 16 located on both sides of the strip S, respectively. Effect, only its operating direction is symmetrically about the strip S, and only the mounting positions of the blocking plate 16 and the roller 14 are made opposite to each other as will be described later. In the following description, only those shown on the right side of FIG. 3 will be described in more detail for simplicity, and the left side will be denoted by the same reference numerals as the right side.

The gas shutoff mechanism 10 is inserted into the movable frame 12 so as to be slidably movable on both sides of the hollow guide part 32 protruding to the side of the casing 5 to move to the side opposite to the casing 5. The other end of the frame 12 is configured to protrude along the guide tool 32a. In addition, a plurality of sealing packings 36 are mounted on the guide part 32 and the guide tool 32a through which the moving frame 12 penetrates. The roller 39 is rotatably mounted on the lower side of each of the guide part 32 and the guide tool 32a for smooth slide movement of the moving frame 12.

In addition, the roller 14 is mounted in the middle of the moving frame 12 so as to be rotatable through the bearing 42, and the roller 14 is made of carbon and made of carbon. The wear is minimized during friction, and both ends 14a of the roller 14 are mounted on the bearing 42 as shown in FIGS. 6 and 7, respectively.

That is, one end shaft 14a of the roller 14 is inserted into the socket 47 extending from the inner race (not shown) of the bearing 42 and a circular hole 49 is formed on one side of the shaft. A screw 51 penetrating the socket 47 is inserted into the hole 49 to be firmly coupled. However, the other end shaft 14a of the roller 14 has a long hole 53 formed in one side thereof in the longitudinal direction, and the long hole 53 extends from the inner race of the other bearing 42. The screw 55 passing through the socket 54 is inserted.

Therefore, the screw 55 inserted into the long hole 53 does not allow the circumferential rotation of the roller shaft 14a with respect to the socket 54, but the thermal expansion in the longitudinal direction due to the temperature change of the roller 14 It is to allow the roller 14 to be displaced in its longitudinal direction so that it can be absorbed.

In addition, a blocking plate 16 is mounted to the middle lower side of the movable frame 12. The blocking plate 16 has a rear edge formed with a bent portion 16a toward the upper side, and the front edge thereof is configured to extend to the center of the lower surface of the roller 14 of the moving frame 12 as shown in FIG. 5. will be.

On the other hand, the roller 14 and the blocking plate 16 is slightly different from the mounting position of the left and right, which is the right side in Figure 4 the roller 14 is located on the upper side of the moving frame 12 and the blocking plate 16 is attached to the lower side of the moving frame 12, the bent portion 16a is formed to face the upper side, unlike the above, the roller 14 and the blocking plate 16 on the left is the roller 14 Is located on the lower side of the movable frame 12, the blocking plate 16 is attached to the upper side of the movable frame 12, the bent portion (16a) is formed to face the lower side (see Fig. 5).

And, as shown in FIG. 4, the bending edge 16a of the blocking plate 16 moves the blocking plate 16 toward the strip S side so that the high temperature atmosphere gas under the blocking plate 16 is raised upward. If it is to be prevented, the guide portion (3) from the casing (5) by contacting the skirt (60) extending from the upper edge of the guide portion 32 to the lower side between the casing (5) and the guide portion (32) ( It is configured to prevent the gas introduced into the 32 to be delivered to the upper side of the blocking plate (16).

In addition, the driving mechanism 30 for moving the gas shutoff mechanism 10 back and forth with respect to the strip S may be provided to the rack gear 18 and the rack gear 18 formed at the rear end of the moving frame 12. It has an interlocking pinion gear 20 and a drive motor 22 for rotating the pinion gear 20. The drive motor 22 is mounted on the deck portion 62 protruding outwardly rearward of the guide portion 32, and is capable of forward and reverse rotation, and its rotation shaft 22a connects the rear end of the moving frame 12. The pinion gears 20 are coupled to the rack gear 18 by mounting the pinion gears 20 respectively.

The rotating shaft 22a is fitted to a pair of fixing bars 65 protruding from the outside of the guide part 32 so as to be rotatable in a fixed position, and moves to the rear end of each of the moving frames 12. The frame 12 is equipped with a position detection sensor 70 for detecting the forward movement displacement with respect to the strip S.

The position detecting sensor 70 is provided with an electric resistor (not shown) that is movable inside, and a known structure that the electric resistance is changed when the resistor is moved inside, so that the displacement can be known. When the moving frame 12 is displaced in the direction of the strip S, the resistor is displaced so that the operator can know the position of the moving frame 12, and ultimately, the moving frame 12 It is to control the operation of the driving motor 22 by grasping how much the mounted roller 14 and the blocking plate 16 are moved relative to the strip S.

The vertical furnace thermal cutoff door device 1 of the present invention configured as described above can effectively block rising of the high-temperature reducing atmosphere gas in the heating zone 110 during the operation of the vertical furnace 100 to the cooling zone 120. . This is because when the operator rotates the drive motor 22 located on both sides of the strip S, the pinion gear 20 and the rack gear 18 are rotated while the rotation shaft 22a of the drive motor 22 is rotated in opposite directions. The moving frame 12 is moved to the strip S side through ().

In this case, the moving frame 12 is smoothly moved forward to the strip S side because the front part and the rear part are supported to slide by the rollers 39 of the guide part 32 and the guide tool 32a, respectively. Thus, the outer circumferential surface of the roller 14 is in contact with both sides of the strip S, respectively. The cross-sectional shape in this case is shown in FIG. 5, which is because the roller 14 pushes the strip S so that the outer circumferential surface of the strip S is in close contact with the roller 14, respectively, to achieve the rotation of the roller 14. It is. In addition, the blocking plate 16 positioned on the lower side of the right roller 14 and the blocking plate 16 positioned on the upper side of the left roller 14 maintain a straight line substantially horizontally with each other. It is close to the strip (S) but is kept in a non-contact state to effectively block the rise of the high-temperature atmosphere gas.

On the other hand, if the roller 14 is thermally expanded by a hot gas in this operation process, the change in the longitudinal direction can be accommodated by the long hole 53 and the screw 55 provided in the roller shaft 14a. The roller 14 is in surface contact with the strip (S) to be smoothly rotatable.

In addition, even when the strip S is deformed to form C due to a sudden temperature difference between the heating table 110 and the cooling table 120, the rollers 14 hold the strip S in place to prevent deformation. Since the contact with the blocking plate 16 is prevented so that the quality coupling such as scratching the surface of the strip (S) does not occur. Therefore, since it is not necessary to open the blocking plate 16 as in the prior art, the high temperature reducing atmosphere gas in the heating table 110 is maintained without flowing out to the upper side, so that the thermal efficiency of the vertical furnace 100 is greatly improved.

In addition, since the rollers 14 correct the strip S deformed by the thermal deviation, the shape of the strip S is also corrected.

According to the present invention as described above, by blocking the high-temperature atmosphere gas flowing to the low-temperature cooling gas more effectively to improve the thermal efficiency of the vertical furnace 100, and without damaging the surface of the strip of the strip (S) of the The surface quality is improved, and by improving the quality of the strip S by correcting the C-shaped deformation of the strip S due to the rapid temperature change from the high temperature to the low temperature, the improved effect is obtained.

Claims (1)

In-vertical thermal cutoff door device mounted between the heating zone 110 of the hot atmosphere gas and the cooling zone 120 of the low-temperature cooling gas in the vertical furnace 100 for annealing the cold rolled stainless strip S. To A hollow rectangular casing 5 positioned between the heating table 110 and the cooling table 120 of the vertical furnace 100; The upper and lower edges of the casing 5 are provided with a movable frame 12 which is slidably movable in pairs opposite to each other in a direction perpendicular to the strip S, each of which has rollers 14 in the middle of the movable frame 12. And a gas barrier mechanism (10) mounted to both sides of the strip (S) and the blocking plate (16); and, the rack gear (18) and the rack gear (formed at the rear end of the moving frame (12) 18, a pinion gear 20 engaged with the pinion gear 20, and a driving motor 22 for rotating the pinion gear 20 to move the gas shutoff mechanism 10 in a direction perpendicular to the strip S. Drive mechanism 30; in-vertical thermal cutoff door device comprising a.