JPH06248325A - Device for sealing opening part in steel slab heating furnace - Google Patents

Abstract

PURPOSE:To prevent the free invasion of outer air and the leakage of radiating heat to the outside and to reduce the heat loss by linking the movement of an extractor fork and opening/closing an opening for extractor with swinging seal door. CONSTITUTION:In a heating furnace having an opening 3 for passing a steel slab and the opening 4 for plural extractors connectedly arranged with the above opening 3 at the lower part thereof and charging/ejecting the steel slab to the opening 3 by rectangular movement of the extractor fork 5, a lift type first door 11 for opening/ closing the openings, 4 and the swinging seal door 13 for opening/closing the opening 4 by linking with advancing/retreating movement of the fork 5. At the time of charging the steel slab, the door 11 is opened, but the door 13 is closed. Successively, when the fork 5 supporting the steel slab advances, while linking with this movement, the door 13 is swung to open the opening 4, and when the steel slab is delivered to the supporting table in the furnace by descending the fork 5, the door 11 is descended to close the opening hole part 3. when the fork 5 is retreated to outside of the furnace, while linking with this movement, the door 13 is swung to close the opening 4.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a heating furnace opening seal device for charging and extracting steel slabs by an extractor system or a charger system.

[0002]

2. Description of the Related Art Conventionally, as a billet heating furnace such as a walking beam type heating furnace, as shown in FIG.
The charging section and the extracting section each have a steel slab passage opening 103, and a plurality of extractor openings 104 that are continuously arranged below the steel slab passage opening 103 at predetermined intervals. It is known that an extractor fork 105 or a charger for charging or extracting a steel slab 118 through the steel slab passage opening 103 is used.

In this billet heating furnace, first, the door 101 closing the billet passing opening 103 and the extractor opening 104 is raised to open the extractor opening 104 [Fig. 13 (a ), (B)], the extractor fork 105 through the extractor opening 104.
Is charged into the furnace [see FIGS. 13 (c) and 13 (d)]. Next, the door 101 is lifted to open the billet passing opening 103, and the extractor fork 105 is raised to allow the billet 118 to move with the extractor fork 105.
Are supported (see FIGS. 13D and 13E). Subsequently, the extractor fork 105 is retracted outside the furnace, and the steel slab 118 is extracted through the steel slab passage opening 103. Then, with the steel piece 118 completely extracted outside the furnace, the door 101
Is closed to close the billet passing opening 103 and the extractor opening 104. Finally, the extractor fork 105 is lowered, and the steel slab 118 is placed on a transport table (not shown), whereby one cycle of the steel slab extraction work is completed. The billet charging operation is the reverse of the above.

[0004]

However, in the above billet heating furnace 100, the billet passing opening 103 and the extractor opening 104 are opened and closed by one door 101, so that the billet 118 is opened. Door 10 for extracting
When 1 is raised, the extractor opening 104 is inevitably generated.
Is also opened. That is, the extractor fork 105
The extractor opening 104 is opened even when the engine is waiting outside the furnace. Further, even when the extractor fork 105 is retracted, the extractor fork 105 is
If the steel slab 118 is not completely retracted from the openings 103 and 104, the steel slab passage opening 103 as well as the extractor opening 104 cannot be closed. Therefore, there is a problem in that a large amount of outside air enters the furnace to make it difficult to control O ₂ and a large amount of radiant heat leaks to the outside, resulting in a large heat loss.

[0005]

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it comprises a steel piece passage opening and a plurality of extractors connected under the steel piece passage opening. In a billet heating furnace having a billet opening, and the billet is loaded or extracted from the billet opening by the rectangular motion of the extractor fork, the billet passing opening and the extractor opening. An elevating first door that opens and closes a portion, and a rotary seal door that opens and closes an extractor opening in conjunction with the forward and backward movement of the extractor fork,
Is provided.

Further, in a region excluding the second door which is provided to be able to move up and down outside the lifting type first door and the extractor opening, in the opened state of the lifting type first door, the steel piece passage opening is formed. And a third door advancing to the lower front of the.

[0007]

In the case of the billet charging operation, in the opening sealing device for the heating furnace, the first elevating type door first rises and retracts from the front of the extractor opening. However, the extractor opening is closed by a rotating seal door.
Next, when the extractor fork supporting the steel piece advances toward the extractor opening, the rotary seal door rotates in conjunction with the motion of the extractor fork, and the extractor opening opens. The department is opened. Also,
The liftable first door is also raised to open the billet passing opening. Then, when the steel slab is transferred to the support in the furnace by descending the extractor fork that has entered the furnace, the first elevating type door descends and the steel slab passage opening is closed. Finally, when the extractor fork retracts to the outside of the furnace, the seal door rotates in conjunction with the movement of the extractor fork, and the extractor opening is closed. Further, the first lifting type door descends to cover the front surface of the extractor opening.

In the case of the billet extraction work, first, the first lifting type door is lifted and retracted from the front of the extractor opening.
However, the extractor opening is closed by a rotating seal door. Next, when the extractor fork advances toward the extractor opening, the rotary seal door rotates in conjunction with the motion of the extractor fork, and the extractor opening is opened. .
Then, when the extractor fork that has entered the furnace is lifted to support the steel billet, the first elevating door is lifted to open the billet passing opening. Finally, when the extractor fork retracts to the outside of the furnace, the rotary seal door rotates in conjunction with the movement of the extractor fork, and the extractor opening is closed. Further, the lifting type first door also descends to cover the billet passing opening and the extractor opening.

The second door and the third door are in a state in which the elevating first door is raised to open the billet passing opening.
The second door descends to the billet passing opening, and the third door advances to the front lower side of the billet passing opening to prevent leakage of width radiant heat and the like.

[0010]

Embodiments of the present invention will be described below with reference to the accompanying drawings. 1 and 2 are extraction-side cross-sectional views of a region including an extractor opening of a billet heating furnace, and FIGS. 3 and 4 are extraction-side cross-sectional views of a region of a billet heating furnace that do not include an extractor opening. . In the furnace wall 2 on the extraction side of the heating furnace 1 shown in these drawings, a steel piece passage opening 3 through which a steel piece 18 passes.
And the extractor openings 4 continuously formed at predetermined intervals below the steel piece passage opening 3, and the lower end of the steel piece passage opening 3 has a steel piece conveying reference level H.V. It is almost the same as L.

In the opening seal device 10 for opening and closing the openings 3 and 4, the liftable first door 11 is provided on the outside of the furnace wall 2 so as to be lifted and lowered, and the opening 3 for passing the billet and the extractor are provided. The opening 4 is opened and closed. 2nd door 1
The reference numeral 2 is provided so as to be able to move up and down outside the first lifting / lowering door 11 and to project below the first lifting / lowering door 11. The rotary seal door 13 is arranged in the extractor opening 4,
As shown in FIG. 5, the lower end portion is supported by a shaft 14 so as to rotate toward the inside of the furnace. Further, a water cooling box 15 is formed on the rotary seal door 13, and cooling water is supplied from the shaft 14 that also serves as a cooling water supply pipe.

In a region not including the extractor opening 4, that is, in a region X shown in FIG. 5, the third door 16 is rotatably supported outside the furnace, and is retracted from the liftable first door 11 by the cylinder 17. The standby position (see FIG. 3) is switched to the operating position (see FIG. 4) in which the upper surface is substantially aligned with the lower end of the billet passing opening 3 and one end side (furnace side) is in contact with the furnace wall 2 You can do it.

In the opening seal device 10 shown in FIGS.
As shown in FIG. 4, in the start state in which the first lifting / lowering door 11 is closed, the rotary seal door 13 closes the extractor opening 4, and the third door 16 is located in front of the first lifting / lowering door 11. It is evacuating.

When the steel bill 18 in the furnace is to be extracted, first the lifting type first door 11 is raised, and its lower end is the billet passing opening 3.
At the lower end of the sheet, that is, the standard level H. Stop when L is reached. At this time, the rotary seal door 13 closes the extractor opening 4. Therefore, outside air does not enter the furnace in this state. Further, even if outside air may enter the furnace, the amount thereof is extremely small.

Next, the third door 16 rotates in the direction of arrow b,
The operation position is switched to that shown in FIG. Further, the extractor fork 5 advances toward the inside of the furnace and enters the inside of the furnace through the opening 4 for the extractor. At this time, the rotary seal door 13 is interlocked with the motion of the extractor fork 5 and rotates in the direction of arrow a so as not to interfere with it, thereby opening the path of the extractor fork 5 (see FIG. 2). When the operation of the extractor fork 5 entering the furnace is completed, the extractor fork 5 rises and supports the steel piece 18 on its upper surface. At this time, the lifting type first door 11
Goes up in conjunction with the movement of the extractor fork 5,
Interference between the liftable first door 11 and the extractor fork 5 is prevented.

Subsequently, the extractor fork 5 is retracted toward the outside of the furnace, and the steel piece 1 is passed through the steel piece passage opening 3.
Extract 8 out of the furnace. At this time, the rotary seal door 13 is rotated in the direction of the arrow a ′ without interfering with the movement of the extractor fork 5 to close the extractor opening 4. On the other hand, the second door 12 descends to a level not interfering with the steel slab 18 and the extractor fork 5 while the elevating first door 11 opens the steel slab passage opening 3 and the third door 16 is opened. At the same time, it is possible to prevent the outside air from entering the furnace through the billet passing opening 3, the atmosphere in the furnace from leaking, and the radiation heat in the furnace from leaking.

Finally, the extractor fork 5 descends, the steel piece 18 is placed on the transfer stage 6 outside the furnace, and returns to the start position. Further, the third door 16 rotates in the direction of the arrow b'to move to the standby position, the elevating first door 11 descends and returns to the starting state of FIG. 1, and as a result, one cycle of billet extraction work is performed. Ends.

When the steel piece 18 is loaded into the furnace, the rotary seal door 13 is interlocked with the movement of the extractor fork 5 and rotates without interfering with the extractor fork 5. Further, the elevating first door 11 rises when the steel piece 18 and the extractor fork 5 are loaded to open the steel piece passage opening portion 3, and the second door 12 and the third door 16 make the steel piece passage opening portion. It moves to the front of the portion 3 to prevent the outside air from entering the furnace, the atmosphere in the furnace, and the leakage of the radiant heat.

Next, the opening sealing device 1 according to the present invention.
In a heating furnace equipped with a heating furnace equipped with 0 and a conventional sealing device (see FIG. 7), refer to FIGS. 7 and 13 for the amount of air per cycle that enters the furnace as the door is opened and closed. Compare.

In the case of the billet extraction cycle, from the start of the extraction work until the extractor forks 5, 105 enter the extractor openings 4, 104 [Fig.
(A) to (c), FIG. 13 (a) to (c)], in the opening seal device 10 of the present invention, the extractor opening 4 is sealed by the rotary seal door 13, so There is almost no intrusion. On the other hand, in the conventional sealing device, since the fork opening 104 is placed in the open state, an extremely large amount of outside air enters the furnace.

From the time when the extractor forks 5, 105 enter the extractor openings 4, 104 until the extractor forks 5, 105 rise (see FIG. 7).
(C), (d), FIG. 13 (c), (d)], and the outside air intrusion amount of both is equal.

While the extractor forks 5 and 105 retreat toward the outside of the furnace [Fig. 7 (d), (e), Fig. 13]
(D), (e)] In the opening sealing device 10 of the present invention, the outside air is prevented from entering by the second door 12 and the third door 16, and the atmosphere in the furnace and the leakage and release of the radiant heat are prevented. It On the other hand, in the conventional sealing device, the second door and the third door are not provided, and accordingly, a large amount of outside air enters the furnace, and the atmosphere in the furnace and the radiant heat often leak.

From the retracting of the extractor forks 5, 105 from the extractor openings 4, 104 to the return to the starting state [FIG. 7 (e), FIG. 13 (e)],
In the opening seal device 10 of the present invention, the extractor opening 4 is sealed by the rotary seal door 13, and the intrusion of outside air from the extractor opening 4 and the leakage of the furnace width radiant heat and the like are substantially prevented. Although completely prevented, in the conventional sealing device, a large amount of outside air enters into the furnace before the door 101 completely closes the extractor opening 104, and a large amount of radiant heat in the furnace also leaks. .

When the amount of intruding air in the furnace was calculated for a specific case, when the cycle time of the extractor forks was the same (38.5 seconds), the amount of intruding air in the furnace of the conventional heating furnace was 782 Nm ³ / However, in the heating furnace equipped with the sealing device of the present invention, the result was that the amount of air introduced into the furnace was reduced to 204 Nm ³ / h (26% of the conventional heating furnace). Further, even if the cycle time of the extractor fork in the conventional heating furnace is shortened to 29.3 seconds, the amount of air intruding into the furnace is reduced to 602 Nm ³ / h, and the heating furnace equipped with the sealing device of the present invention is used. By comparison, it was still high.

In the above description, the case where the sealing device of the present invention is applied to the billet extraction opening has been described, but it goes without saying that the invention can be similarly applied to the billet charging opening.

Another embodiment of the opening sealing device is shown in FIGS.
2 shows. In the opening seal device 20 shown in these figures, the rotary seal door 21 is supported by a vertical shaft 23 projecting from the bottom of one end of the fork opening 4. The vertical shaft 23 has a double pipe structure, and the rotary seal door 2
The cooling water is communicated with the water cooling box 22 formed in the inside of the No. 1 and the cooling water supplied from the cooling water supply device (not shown) circulates in the water cooling box 22 via the vertical shaft 23. The vertical shaft 23 is rotatably supported by bearings 24 and 25, and is connected via an arm 26 to a drive shaft 27 arranged in parallel with the furnace wall 2 and horizontally to form a ring mechanism. The rotary seal door 21 opens and closes in the directions of the arrows c and c ′ based on the movement of the drive shaft 27 in the directions of the arrows d and d ′. The structure of the region not including the extractor opening 4 is the same as that of the opening sealing device 10 of the above-described embodiment, and the description thereof will be omitted.

When the extractor fork 5 is located outside the furnace, the opening sealing device 20 shown in FIG.
As shown in FIGS. 10 and 11, the rotary seal door 21 closes the extractor opening 4, and the atmosphere in the furnace and the radiant heat in the furnace leak from the extractor opening 4 and the outside air enters the furnace. Is being prevented.

On the other hand, when the extractor fork 5 enters the furnace, as shown in FIGS. 9 and 12, the drive shaft 27 is moved in the direction of arrow d by a drive source (not shown), which causes the rotary seal door 21. Rotates in the direction of the arrow c without interfering with the movement of the extractor fork 5 to open the extractor opening 4. Further, when the extractor fork 5 that has entered the furnace retracts to the outside of the furnace, the drive shaft 27 moves in the direction of the arrow d ′, and the rotary seal door 21 interferes with the motion of the extractor fork 5 while interlocking with it. Without rotating, the extractor fork 5 retracts outside the furnace and closes the extractor opening 4 at the same time.

[0029]

As is apparent from the above description, according to the sealing device of the present invention, the extractor opening is opened and closed by the rotary seal door in conjunction with the movement of the extractor fork. Even if the first lifting door is opened, outside air does not freely enter the furnace through the extractor opening, and the furnace atmosphere and furnace width radiant heat do not leak outside, and the furnace atmosphere is controlled. Will be easier. Further, by the second door and the third door, it is possible to further reduce the leakage of outside air from the billet passing opening, the atmosphere in the furnace, and the leakage of radiant heat.

[Brief description of drawings]

FIG. 1 is a cross-sectional view showing an opening sealing device of a billet heating furnace.

FIG. 2 is a cross-sectional view showing the movement of the rotary seal door at the time of charging / extracting steel slabs.

FIG. 3 is a cross-sectional view showing movements of a second door and a third door.

FIG. 4 is a cross-sectional view showing movements of a second door and a third door.

FIG. 5 is a cross-sectional view of a rotary seal door.

6 is a sectional view taken along line VI-VI of FIG.

FIG. 7 is a diagram illustrating the opening / closing operation of the first lifting type door and the rotary seal door.

FIG. 8 is a cross-sectional view of another embodiment of the opening sealing device.

FIG. 9 is a cross-sectional view showing the movement of the rotary seal door in the opening seal device according to another embodiment.

FIG. 10 is a partially cut front view of an opening sealing device according to another embodiment.

11 is a sectional view taken along line XI-XI of FIG.

12 is a sectional view showing an open state of the rotary seal door shown in FIG.

FIG. 13 is a diagram for explaining an opening / closing operation of a door in a conventional heating furnace.

[Explanation of symbols]

1 ... Heating furnace, 3 ... Steel piece passage opening, 4 ... Extractor opening, 5 ... Extractor fork, 10, 20
... Opening sealing device, 11 ... Elevating first door, 12 ... Second
Door, 13 ... Rotating seal door, 16 ... Third door, 18 ... Steel billet.

 ─────────────────────────────────────────────────── ─── Continuation of front page (72) Hideki Takaguchi 2-4-7 Kyomachibori, Nishi-ku, Osaka City, Osaka Prefecture Chugai Furnace Industry Co., Ltd. (72) Osamu Noseoka 2 Kyomachibori, Nishi-ku, Osaka City, Osaka Prefecture Chome 4-7 Chugai Reactor Co., Ltd. (72) Inventor Rikio Takeshima 1 Kawasaki-cho, Chuo-ku, Chiba-shi, Chiba Kawasaki Steel Co., Ltd. Chiba Works (72) Inventor Kunio Yoshida Chuo-ku, Chiba-shi, Chiba Kawasaki-cho 1 Kawasaki Steel Co., Ltd. Chiba Steel Works (72) Inventor Masanori Ebihara 1 Kawasaki-machi Chuo-ku, Chiba City Chiba Kawasaki Steel Co., Ltd. Chiba Steel Works

Claims (2)

[Claims] 1. A steel slab passage opening and a plurality of extractor apertures that are continuously provided below the steel slab passage opening, wherein the steel slab passage opening is formed by a rectangular motion of an extractor fork. In a billet heating furnace configured to load or extract billets, an elevating first door that opens and closes the billet passing opening and the extractor opening, and the forward and backward movement of the extractor fork. And a rotary seal door that opens and closes the extractor opening, and an opening seal device for a billet heating furnace. 2. In a region excluding the second door that is vertically movable outside the first door and the extractor opening, the front lower part of the steel piece passage opening in the open state of the first door. The opening sealing device for a billet heating furnace according to claim 1, further comprising: