KR20090015205A - Device for adjusting oscillation of edge dam in twin roll strip caster - Google Patents

Abstract

An apparatus for adjusting oscillation of an edge dam in a twin roll strip caster is provided to extend life of the edge dam refractories and prevent fusion of a scum possessively. An apparatus(400) for adjusting oscillation of an edge dam includes the followings: an oscillation plate(410) vibrated by a combined bushing on an eccentric shaft(430); a tapered bearing(434) combined with the shaft of the eccentric shaft; a slide bushing inserting the bearing and having the taper corresponding to a shape of the bearing in one side; and a cylinder(440) connected with an air supplying unit through a hose and combined with the oscillation plate on other side of the cylinder.

Description

Device for adjusting oscillation of edge dam in twin roll strip caster}

The present invention relates to an edge dam vibration adjusting device of a twin-roll thin plate casting apparatus, and in particular, it is possible to maintain a constant amount of vibration amplitude of the diaphragm and to prevent scum by adjusting the amplitude even during casting, and stopping the diaphragm at a fixed position. The present invention relates to an edge dam vibration control device of a twin roll sheet metal casting device capable of improving the life of an edge dam refractory material.

In general, a strip casting process is a method of continuously supplying molten steel to two rotating rolls and continuously producing a sheet of about several nm directly from the molten steel.

1 is a perspective view of a general twin roll sheet casting apparatus, Figure 2 is a front view of a typical edge dam cassette.

Twin roll type sheet casting apparatus 10 is uniformly supplied between the pair of casting rolls 130 through the molten steel 160 from the tundish 110 through the molten steel supply nozzle 120, casting roll 130 under a constant condition When rotating, the solidified layers of molten steel formed on the surface of each casting roll 130 being cooled are coalesced at the nearest point to produce a thin plate 150 of constant thickness continuously.

In this case, in order to prevent the supplied molten steel 160 from leaking to both sides of the casting roll 130, an edge dam 140 is installed at the side of the casting roll 130. This edge dam 140, as shown in Figure 2, to fix the refractory 144 on the casting roll side surface, the refractory 144 is substantially in close contact with the side of the casting roll 130, which is a casting roll It is made of a flat refractory plate to be in close contact with the side of the 130. Here, the roll contact surface ceramics 142 of the movable surface are in direct contact with the casting roll 130 being cooled, whereas the molten steel contact surface 146 including a part of the roll contact surface ceramics 142 is in contact with the hot molten steel, The portion of the refractory 144 in contact with the casting roll 130 is the refractory 144 is cooled, the heat loss of the molten steel is generated around the portion in contact with the casting roll is a condition that the molten steel can be easily solidified do.

In order to prevent the fusion of the molten steel and improve the quality of the product by vibrating the edge dam 140, the molten steel flows constantly.

Figure 3a is a schematic rear view of a conventional edge dam diaphragm, Figure 3b is an enlarged view of the main portion.

Conventional edge dam vibration device includes a diaphragm 300 for transmitting vibrations by a vibration motor (not shown) to the refractory 142 of the edge dam 140, and a cover inserted into the slide bushing 320 with a certain size tolerance ( 310, a slide bushing 320 coupled to the eccentric shaft 330 to vibrate the diaphragm 300, and an eccentric shaft 330 coupled to a vibration motor (not shown) to eccentrically move.

By this configuration, when the vibration motor (not shown) rotates, the eccentric shaft 330 is rotated accordingly, the slide bushing 320 is in close contact with the cover 310 so that the vibration is transmitted to the diaphragm 300, the diaphragm ( 300, the lower portion of the center of the bearing 301 is oscillated left and right in the direction of the arrow like a clockwork, and thus the refractory 142 of the edge dam vibrates. Therefore, the scum is prevented from being fused at the edge dam 140.

However, such a conventional edge dam vibration device has a problem that can not be removed immediately because the amplitude of the vibration can not be adjusted even after detecting the scum appearing in the camera during casting can cause an accident of equipment interruption casting.

Furthermore, if the vibration of the diaphragm is stopped during casting, the stop position is not determined according to the position due to the eccentric motion and can be stopped at any position within the amplitude range of the diaphragm. There is a problem that can cause breakage.

The present invention has been proposed to solve the above problems, a pair that can maintain a constant vibration amplitude of the diaphragm, can actively prevent scum fusion during casting, and at the same time can improve the life of the edge dam refractory An object of the present invention is to provide an edge dam vibration adjusting device for a roll type sheet casting device.

The present invention for achieving the above object is in the edge dam vibration adjusting device of a twin-roll thin plate casting apparatus having a vibration plate vibrated by a slide bushing coupled to the eccentric shaft, taper coupled to the eccentric shaft of the eccentric shaft Shaped bearings; A slide bushing in which a taper corresponding to a shape of the bearing is formed at one side and the bearing is inserted and coupled; One side is coupled to the other side of the slide bushing to transfer power forward and backward, the other side is coupled to the diaphragm, characterized in that it comprises a cylinder connected to the air supply through a hose.

Preferably, the slide bushing edge damping vibration adjusting device of a twin-roll thin sheet casting apparatus, characterized in that the taper advances back and forth from the position in which the taper abuts the bearing to the position where the taper is completely separated from the bearing.

Preferably, the cylinder may have a built-in elastic member.

Preferably, the bearing may be provided with rollers on both sides.

The edge dam vibration adjusting device of the twin-roll thin plate casting apparatus according to the present invention is coupled to the eccentric shaft tapered bearing and by advancing the slide bushing having a tapered shape to the bearing by the cylinder coupled to the vibration plate, The vibration amplitude of vibration plate can be kept constant and the amplitude of vibration can be adjusted even during casting. When scum is fused on the edge dam side, the cylinder is operated during casting to adjust the contact tolerance between the slide bushing and the bearing. It is possible to prevent fusion and at the same time, the diaphragm stops at the correct position when the vibration is stopped during casting, thereby improving the life of the edge dam refractory.

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

4 is an exploded cross-sectional view of an edge dam vibration adjusting device of a twin roll thin plate casting apparatus according to an exemplary embodiment of the present invention, and FIG. 5 is an operation principle of an edge dam vibration adjusting device of a twin roll thin plate casting apparatus according to an exemplary embodiment of the present invention. A schematic cross-sectional view (a) of the eccentric shaft for explaining the above, a cross-sectional view (b) of the main portion for explaining the eccentricity of the diaphragm, and a graph (c) showing the relationship between the eccentricity of the diaphragm according to the movement of the slide bushing.

Edge dam vibration adjusting device 400 of the twin-roll thin plate casting apparatus according to an embodiment of the present invention is a vibration plate 410 and a vibration plate 410 that is vibrated by the slide bushing coupled to the eccentric shaft, the vibration plate 410 Slide bushing 420 to vibrate), the eccentric shaft 430 coupled to the vibration motor (not shown) and the tapered bearing 434 coupled to the eccentric shaft 432 of the eccentric shaft 430 And a cylinder 440 coupled between the slide bushing 420 and the diaphragm 410 to transmit power.

The diaphragm 410 is coupled to the other side of the cylinder 440, and fastens the bolt 414 to the bolt insertion hole 412 of the diaphragm 410 and the bolt insertion hole 446 of the cylinder rod 442 to the cylinder 440. It is fixed.

The slide bushing 420 has a taper 422 corresponding to the shape of the bearing 434 on one side thereof, and the bearing 434 is inserted into and coupled to the taper 422.

In addition, the other side of the slide bushing 420 is fixed to the rod 442 of the cylinder 440, the bolt insertion hole 424 of the slide bushing 420 and the bolt insertion groove 448 of the cylinder rod 442 bolts Fastening by fastening 426.

In addition, the slide bushing 420 is preferably made of a copper material because the reciprocating friction movement is performed, it is preferable to feed the lubricant by processing a hole in the side.

The eccentric shaft 430 has a tapered bearing 434 coupled to the eccentric shaft 432 to transfer the eccentric motion of the eccentric shaft 432 to the diaphragm 410 through the slide bushing 420 and the cylinder 440. .

The bearing 434 is provided with rollers 436 on both sides thereof and is inserted into and coupled to the taper 422 of the slide bushing 420. The rollers 436 are bearings 434 generated as the slide bushing 420 moves forward and backward. And friction within the tolerance of the slide bushing 420.

One side of the cylinder 440 is coupled to the other side of the slide bushing 420 to transfer power forward and backward, the other side is coupled to the diaphragm 410, and connected to the air supply (not shown) through the hose 450 do.

The cylinder 440 is, for example, a single-acting hydraulic cylinder, in which a spring 444, which is an elastic member, is inserted into the cylinder rod 442 to move toward the bearing 434 by the elastic force.

The operation of the edge dam vibration adjusting device 400 of the twin-roll thin plate casting apparatus according to the embodiment of the present invention configured as described above will be described.

First, when the vibration motor (not shown) rotates, the eccentric shaft 430 is rotated, as shown in Fig. 5 (a), while the eccentric shaft 432 moves to the eccentric shaft portion 432 ' do. At this time, since the slide bushing 420 is in contact with the bearing 434 without tolerance, the eccentric motion of the eccentric shaft 432 transmitted through the bearing 434 is transmitted to the diaphragm 410 through the cylinder 440. The diaphragm 410 vibrates left and right, such as a clock, around a central bearing (not shown), thereby vibrating the refractory 142 of the edge dam. Therefore, fusion of scum can be prevented by flowing molten steel at the edge dam 140 side.

Here, when it is necessary to adjust the vibration amplitude of the diaphragm 410 according to the generation of scum during casting, when the pressure is applied to the cylinder 440 through an air supply (not shown), the rod 442 of the cylinder 440 is a diaphragm As it is reversed to the 410 side, the slide bushing 420 coupled to the rod 442 is also reversed. Accordingly, the bearing 434 starts to deviate from the taper 422 of the slide bushing 420 and the tolerance between the bearing 434 and the slide bushing 420 increases, thereby reducing the amount of eccentricity of the eccentric shaft 430, thereby causing amplitude of vibration. Is also reduced.

Referring to the principle of the vibration adjustment in more detail, as shown in Figure 5 (b), when the slide bushing 420 is reversed and a tolerance is formed between the bearing 434, the amount of eccentricity is changed accordingly, As shown in FIG. 5C, the tolerance with the bearing 434 is increased by the moving distance of the slide bushing 420, that is, the reverse distance, so that the amount of eccentricity is reduced.

In this way, the slide bushing 420 is controlled from the position where the taper 422 abuts against the roller 436 of the bearing 434 under the control of the cylinder 440, and the position where the taper 422 is completely separated from the bearing 434. By moving back and forth, the vibration amplitude of the diaphragm 410 is adjusted.

At this time, when the hydraulic pressure of the cylinder 440 is removed, the rod 442 of the cylinder 440 advances back to the bearing 434 by the elastic force of the spring 444 installed inside the cylinder 440. The slide bushing 420 fixed to the front is also advanced. Accordingly, the bearing 434 begins to be inserted and coupled to the taper 422 of the slide bushing 420 again, thereby reducing the tolerance between the bearing 434 and the slide bushing 420, as shown in FIG. , The amount of eccentricity of the eccentric shaft 430 is increased, the amplitude of vibration is also increased.

On the other hand, when the slide bushing 420 is retracted toward the diaphragm 410 by the cylinder 440 and the slide bushing 420 is completely separated from the bearing 434, the eccentric motion of the eccentric shaft 430 is moved to the diaphragm 410. Since it is not transmitted, as shown in FIG. 5C, the amount of eccentricity becomes "0", and the vibration amplitude of the diaphragm 410 also becomes "0". At this time, since the diaphragm 410 is completely separated from the eccentric shaft 430, the diaphragm 410 stops at its original position. In this way, the diaphragm 410 stops at the correct position, thereby preventing the damage of the edge dam refractory. It can improve the service life.

1 is a perspective view of a typical double roll type sheet casting device.

2 is a front view of a typical edge dam cassette.

Figure 3a is a schematic rear view of a conventional edge dam diaphragm, Figure 3b is an enlarged view of the main portion.

Figure 4 is an exploded cross-sectional view of the edge dam vibration control device of the twin-roll thin plate casting apparatus according to an embodiment of the present invention.

Figure 5 is a schematic cross-sectional view (a) of the eccentric shaft for explaining the operation principle of the edge dam vibration control device of the twin-roll thin sheet casting apparatus according to an embodiment of the present invention, cross-sectional view (b) of the main portion for explaining the eccentric amount of the diaphragm And (c) showing the relationship between the eccentricity of the diaphragm according to the movement of the slide bushing.

Explanation of symbols on the main parts of the drawings

400: edge dam vibration control device 410: diaphragm

420: slide bushing 422: taper

430: eccentric shaft 432: eccentric shaft

434: Bearing 436: Roller

440: cylinder 442: rod

444: spring

Claims (4)

In the edge dam vibration control device of a twin-roll thin plate casting device having a diaphragm vibrating by a slide bushing coupled to an eccentric shaft, A tapered bearing coupled to the eccentric shaft of the eccentric shaft; A slide bushing in which a taper corresponding to a shape of the bearing is formed at one side and the bearing is inserted and coupled; One side is coupled to the other side of the slide bushing to transfer power forward and backward, the other side is coupled to the diaphragm, the twin roll type sheet casting apparatus comprising a cylinder connected to the air supply through a hose Edge Dam Vibration Control Device. The method of claim 1, And the slide bushing is moved forward and backward from a position where the taper is in contact with the bearing to a position where the taper is completely separated from the bearing. The method of claim 1, The cylinder is an edge dam vibration control device of a twin-roll thin plate casting apparatus, characterized in that the elastic member is built-in. The method of claim 1, Edge bearing vibration adjusting device of the twin-roll thin plate casting apparatus, characterized in that the bearing is provided on both sides.

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