KR101090821B1 - Apparatus for shielding moten metal from hot pot - Google Patents

Abstract

The present invention is a shielding device for preventing the molten metal outflow into the gap between the side wall of the plating bath filled with molten metal and the roll shaft penetrating the plating bath, it is rotatably coupled around both sides of the roll shaft Located in the gap, the sleeve having grooves on the inner and outer surfaces, and a power unit for rotating the sleeve to block the molten metal outflow into the gap. The roll shaft shield device of the plating bath of the present invention made as described above can effectively block the molten metal to be discharged along the circumference of the roll shaft.

Description

Roll shaft shield of plating bath {APPARATUS FOR SHIELDING MOTEN METAL FROM HOT POT}             

1 and 2 show a roll shaft shielding device of a conventional plating bath,

Figure 2 shows a cross-sectional view of the main part according to an embodiment of the roll shaft shielding device of the plating bath of the present invention,

3 is a view schematically showing a state of use according to the embodiment of FIG.

Figure 4 shows a cross-sectional view of the main part according to another embodiment of the roll shaft shielding device of the plating bath of the present invention.

Description of the Related Art

100: plating bath 200: steel plate

10: roll 11: axis

20, 25: bearing 30: sleeve

35: groove 50: belt

The present invention relates to a shielding device for preventing the molten metal filled in the plating bath outflow to the gap around the roll shaft, and more particularly to a roll shaft shielding device of the plating bath that can more reliably block the leakage of molten metal will be.

In general, the plating of the steel sheet is made in the plating bath 100 filled with molten metal. As shown in FIG. 1, when the steel sheet 200 is vertically submerged in the plating bath 100 and the roll 10 is returned to the starting point, the surface of the steel sheet 200 is naturally plated by molten metal.

However, since the bearing 20 supporting the roll 10 is installed in the plating bath 100, it is difficult to plate at a high speed and the life of the bearing is shortened.

Conventional techniques for solving this problem include Japanese Patent Laid-Open Nos. 1994-182281 and 1992-346641. These patents use a magnetic field to block the flow of molten metal, and the magnetic field generating device generates a magnetic field perpendicular to the roll axis on the side wall of the plating bath where the roll axis protrudes. However, the shielding method using the magnetic field is not suitable for practical use in general in all plating baths because its performance and efficiency are insufficient in application to large plating baths.

On the other hand, Japanese Laid-Open Patent No. 1992-346641 has a feature in which a nut having a thread is formed on the roll shaft in addition to the magnetic field to force the molten metal to flow out, but the nut is integrally coupled to the roll shaft. There is a problem that the shielding is not properly made. That is, since the rotational speed of the nut depends on the rotational speed of the roll, the flow in the plating bath becomes unstable when the roll rotates at high speed, and when the roll rotates at low speed, the outflow of molten metal is prevented. There is no problem.

The present invention is to solve the above problems, an object of the present invention is to provide a roll shaft shielding device of the plating bath that can more effectively block the molten metal flowing out through the plating bath side wall combined with the roll shaft.

According to an embodiment of the present invention, a shielding device for preventing molten metal from flowing out into a gap between a side wall of a plating bath filled with molten metal and a roll shaft passing through the plating bath, the rotatable device being rotatable around both sides of the roll shaft. A roll shaft shield of the plating bath including a sleeve having a groove in the inner side and the outer side in a coupled state, and a power unit rotating the sleeve to prevent the molten metal from flowing into the gap An apparatus is provided.

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

Figure 2 shows a cross-sectional view of the main part according to an embodiment of the roll shaft shielding device of the plating bath of the present invention, Figure 3 shows a state of use according to the embodiment of FIG.

As shown in FIG. 2, the shaft 11 of the roll 10 is installed to the outside in the plating bath 100. In addition, a cylindrical outer cylinder 110 extending in parallel around the shaft 11 is formed on the sidewall of the plating bath 100.

The bearing 20 and the sleeve 30 are coupled to the shaft 11 of the roll 10. The bearing 20 is installed outside the plating bath 100 to allow the roll 10 to rotate smoothly and at high speed in the plating bath 100, and the sleeve 30 is disposed between the shaft 11 and the outer cylinder 110. Installed in

A portion of the sleeve 30 protrudes out of the outer cylinder 110. The protruding portion is coupled to the belt 25 and the bearing 25 connected to the power unit (not shown). The power unit is installed outside the plating bath to rotate the sleeve 30 via the belt 50. At this time, the bearing 25 supports the sleeve 30 so that the sleeve 30 rotates independently of the roll 10. Therefore, the present invention can independently adjust the rotational speed of the sleeve 30, unlike the prior art. In the present embodiment, the bearing 25 supporting the sleeve 30 is installed outside the plating bath 100, but may be installed between the outer cylinder 110 and the sleeve 30 according to circumstances. If the bearing 25 is installed between the outer cylinder 110 and the sleeve 30, there is a convenience that does not need to install a separate structure for fixing the bearing (25).

On the other hand, if the belt 50 is simply wound around the circumferential surface of the sleeve 30 can be released during high-speed rotation, it is preferable to form a groove in which the belt 50 can be fitted to the circumferential surface of the sleeve 30. . In addition, in the present embodiment has been described as transmitting power to the sleeve 30 using the belt 50, in some cases, a chain or a gear may be used.

Grooves 35 are formed on the inner and outer circumferential surfaces of the sleeve 30. The groove 35 is formed in a spiral shape along the circumferential surface of the sleeve 30, and guides the flow of molten metal flowing out along the circumferential surface of the sleeve 30 in a spiral shape. Therefore, when the sleeve 30 rotates, the molten metal flowing out due to inertia rotates in the direction of the groove 35 to generate pressure, thereby causing the flow of molten metal flowing out between the outer cylinder 110 and the shaft 11 to be slow. Become. At this time, when the rotational speed of the sleeve 30 continues to increase and becomes equal to the outflow pressure of the molten metal, a flow is generated to move inside the plating bath 100 as shown in FIG. 3, and the melt flows out through the outer cylinder 110. The amount of metal is significantly reduced.

However, when the pressure generated as the rotational speed of the sleeve 30 increases is greater than the outflow pressure of the molten metal, the molten metal may be concentrated toward the roll 10, thereby preventing the movement of the plated steel sheet. In addition, the high-speed rotation of the sleeve 30 may destabilize the flow of the molten metal in the plating bath 100 to generate bubbles in the plating bath 100, so that a small amount of molten metal may flow out through the outer cylinder 110. It is desirable to rotate the sleeve 30 to the extent possible. At this time, since the molten metal is not easily discharged into the gap between the sleeve 30 and the outer cylinder 110 in a state where the pressure is generated by the sleeve 30, a small amount of molten metal is installed by installing a heater outside the outer cylinder 110. It is better to let it flow out more smoothly. In addition, it is preferable to install an auxiliary tank under the outer cylinder 110 to temporarily store the molten metal that flows out.

As described above, the present invention can adjust the rotation speed of the sleeve 30 irrespective of the roll 10, so that the sleeve 30 can be rotated according to the amount of molten metal flowing out to the outside and the state of the plating bath. Can be.

On the other hand, the flow rate of the molten metal discharged to the outside of the plating bath 100 is proportional to the gap size between the outer cylinder 110 and the shaft 11, the gap between the sleeve 30 and the outer cylinder 110 and the sleeve 30 and shaft It is good to calculate the thickness of the sleeve 30 so that the clearance between (11) may be several mm. In addition, it is preferable to incline the side of the groove 35 so that a larger amount of molten metal flows along the groove 35.

Figure 4 shows a cross-sectional view of the main part according to another embodiment of the roll shaft shielding device of the plating bath of the present invention.

In this embodiment, the outer cylinder 110 protruding to the outside of the plating bath 100 was protruded inward. As such, when the outer cylinder 110 protrudes, the molten metal of the high temperature is always wrapped outside the outer cylinder 110, and thus, unlike the previous embodiment, the heater is not provided, so the facility is more simple. In addition, in this embodiment, it is possible to install the bearing 20 on the inner wall of the plating bath 100, the shorter distance between the support points of the shaft 11 has the advantage of minimizing the bending phenomenon of the shaft 11 have.

The present invention can effectively block the molten metal flowing out of the plating bath by a sleeve that rotates separately from the roll, and helps the roll rotate more smoothly by high speed by dispersing the molten metal around the roll shaft.                     

The technical idea of the roll shaft shielding device of the plating bath has been described above with the accompanying drawings, but this is only illustrative of the best embodiment of the present invention and is not intended to limit the present invention. In addition, it is obvious that any person skilled in the art can make various modifications and imitations without departing from the scope of the technical idea of the present invention.

Claims (5)

A shielding device for preventing molten metal from leaking into a gap between a side wall of a plating bath filled with molten metal and a roll shaft passing through the plating bath. A sleeve positioned in the gap in a state rotatably coupled around both sides of the roll shaft, the sleeve having grooves on inner and outer surfaces thereof; Roll shaft shielding device of the plating bath comprising a power unit for rotating the sleeve to block the flow of molten metal to the gap. The method according to claim 1, Rolling shielding device of the plating bath, characterized in that the groove is formed in a spiral shape along the circumferential surface of the sleeve. The method according to claim 1, Roll shaft shielding device of the plating bath, characterized in that the bearing is further coupled to the sleeve. The method according to claim 1, The power unit is a roll shaft shield of the plating bath, characterized in that for transmitting power to the sleeve via any one of the belt, chain, or gear. The method according to any one of claims 1 to 4, Roll groove shielding device of the plating bath, characterized in that the groove has at least one inclined side.

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