KR102040006B1 - sleeve of the deposition roll support device - Google Patents

Abstract

The present invention relates to a sleeve of a continuous roll plating immersion roll support device capable of maximizing wear suppression, thermal stability, durability, and position stability of the continuous roll plating immersion support device sleeve, rotary shaft 450 of the immersion roll A sleeve body connected to the inside, a ceramic sleeve disposed around the outer circumference of the sleeve body, and a stop ring disposed around the outer circumference of the sleeve body, wherein the sleeve body is formed on the left side of the outer circumference of the ceramic One side of the sleeve includes a ceramic sleeve support jaw, wherein the stop ring is in contact with the right side of the ceramic sleeve, characterized in that coupled to the outer circumference of the sleeve body.

Description

Sleeve of the deposition roll support device for continuous hot dip plating

The present invention relates to a deposition roll support device for continuous hot dip plating, and more particularly, continuous melt plating deposition for maximizing wear suppression, thermal stability, durability, and position stability of the continuous roll plating support roll sleeve. A sleeve for a roll support device.

In general, continuous hot dip plating is carried out by a heat treatment process and a rolling process so that a strip having excellent plating adhesion and formability is immersed in the plating material in which the metal is molten and pulled up to the surface of the strip (zinc, tin, aluminum, etc.). This plating is performed sequentially, the step of spraying high pressure air to uniform the plating layer before the plating layer on the strip surface is solidified, and the step of cooling and rolling the plating layer on the strip surface in order.

Facilities for realizing the above process (see FIGS. 7 and 8), a snout (snout-400) to enter the plating bath 300 by inducing the strip 100 before plating to be released from the supply roll 200 and Rotational deposition roll 60 is located in the plating bath 300 to change the outgoing direction of the strip 100, and stabilizing stabilizing the outgoing of the strip 100 is located on the top of the deposition roll ) And a recovery roll 600 for recovering the strip 100 plated with a plating material on the surface by passing through the roll 500 and the plating bath 300. In the above, the deposition roll 60 is fitted on both sides of the rotary shaft 61 of the deposition roll, and the outer periphery of the sleeve 70 and the housing 80 of the bush B, the bush B is concentric The upper and lower arms 90 and 91 are supported by a deposition roll support device 50 including a housing stopper 92 which prevents the housing from being separated.

In the conventional continuous hot dip plating equipment having such a configuration, the process of unwinding from the supply roll and passing through the plating bath, passing through the plating bath, and recovering to the recovery roll is continuously performed. It has a tension by passing the lower circumference closely.

The tension generates a pulling load for moving the deposition roll in the direction of the recovery roll, and the force to be separated from the support device on the deposition roll by the pulling load. That is, a separate load is generated.

The separation load generates a force that causes the sleeve fitted to the rotary shaft of the immersion roll to move upwards within the engagement tolerance with the bush, thereby causing the sleeve and the bush to be eccentric, and the end of the sleeve 70 Contact with the housing stopper 92.

In the above state, the immersion roll is continuously rotated, so that the outer circumference of the sleeve is worn out, and the end of the sleeve is also worn, and the wear and wear of such a sleeve causes the rotation and vibration of the immersion roll.

Republic of Korea Utility Model Publication No. 2009-0004337

The present invention is invented to solve the problems appearing in the sleeve of a conventional immersion roll support device, the object of the present invention is to maximize the wear resistance and position stability of the sleeve.

The sleeve of the continuous roll plating immersion roll support apparatus according to the present invention includes a sleeve body to which the rotary shaft 450 of the immersion roll is connected to the inside, a ceramic sleeve disposed around the outer side of the sleeve body, and an outer side of the sleeve body. Comprising a stop ring disposed on the circumference, the sleeve body comprises a ceramic sleeve support jaw formed on the left side of the outer circumference to contact one side of the ceramic sleeve, the stop ring is in contact with the right side of the ceramic sleeve and the sleeve body It is characterized in that the coupling is fixed to the outer circumference of the.

The present invention has the effect of restraining the wear phenomenon of the sleeve caused by the eccentricity of the sleeve as the rotation support unit of the deposition roll due to the pull load toward the recovery roll direction when plating the strip, this effect is due to the uneven wear of the sleeve It improves the efficiency of plating work by suppressing rotational rotation and vibration of the deposition roll.

In addition, the present invention maintains the bonding state of the immersion roll and the sleeve firmly to suppress the rotation failure and vibration of the immersion roll to improve the stability of the plating operation.

1 is a perspective view showing a combined embodiment of the present invention.
2 is an exploded perspective view showing an embodiment of the present invention.
Figure 3 is an exploded cross-sectional view showing an embodiment of the present invention.
3 is an exemplary cross-sectional view showing an embodiment of the present invention.
5 is a partial cross-sectional view showing a state of use of the present invention.
6 is an exemplary cross-sectional view showing another configuration of the present invention.
7 is an exemplary view briefly showing a continuous hot dip plating facility.
8 is an exemplary view showing a continuous melt plating equipment.

Preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, but the terms or words used in the description of the present invention are not to be construed as being limited to ordinary or dictionary meanings, and the technical features of the present invention. It must be interpreted as meanings and concepts consistent with human thought. Therefore, the embodiments described in the description of the present invention and the configurations shown in the drawings are only one of the most preferred embodiments of the present invention, and do not represent all of the technical idea of the present invention, and these may be replaced at the time of filing of the present invention. It should be understood that there may be various equivalents and variations. The up, down, left and right directions referred to in the description below refer to the directions shown in FIG. 1.

With reference to Figures 1 to 4 looks at the configuration of the present invention.

The sleeve according to the present invention includes a sleeve body 100 to which the rotary shaft 450 of the deposition roll 440 is connected to the inside, a ceramic sleeve 300 disposed around the outer side of the sleeve body 100, and the ceramic sleeve. It includes a stop ring 200 disposed on the right side of the 300 and the outer periphery of the sleeve body (100).

The sleeve body 100 is formed of a wear-resistant metal, the ceramic sleeve 300 is formed by processing and molding a non-metal or inorganic material at a high temperature, the stop ring is formed of a metal. The sleeve body 100 is connected to the rotary shaft 450 of the deposition roll 440, the ceramic sleeve 300 is disposed on the outer periphery of the sleeve body 100 to contact the inner surface of the bush 410, The stop ring 200 is disposed outside the sleeve body 100 to fix the position of the ceramic sleeve 300.

The sleeve body 100 includes a cover 150, and the cover is fixed to the right end of the sleeve body 100. As shown in FIG. 5, the cover 150 is formed of a material having higher wear resistance than the sleeve body 100 in consideration of contact wear with the sleeve stopper 430, thereby improving wear resistance of the sleeve body 100. An inclined contact surface 151 having a right diameter and a smaller left diameter is formed around the cover 150, and the inclined contact surface 151 corresponds to an inner circumference of the cover connecting hole 140 of the sleeve body 100. Shape.

The sleeve body 100 has a coupling catching jaw 110 formed at the left end of the outer circumference, and the ceramic sleeve supporting jaw 120 formed at the right side of the engaging catching jaw 110 and formed at the outer circumference of the sleeve body 100. ) And the stop ring coupling jaw 130 formed at the outer circumference of the sleeve body 100 and formed at the right side of the ceramic sleeve support jaw 120, and formed at the right end of the sleeve body 100, but the left side is narrow. The right side includes a cover connection hole 140 formed wide.

The engaging engaging jaw 110 is a configuration for catching the inner groove of the fixture 420 as shown in FIG. Coupling engaging jaw 110 is a configuration for fixing the sleeve body 100 and the deposition roll 440 when the sleeve body 100 is formed of a high wear resistance material is impossible to be fixed by welding with the deposition and 440. . That is, by fixing the fixture 420 and the deposition roll 440 by welding, the sleeve body 100 and the deposition roll 440 are fixed to each other.

The ceramic sleeve support jaw 120 fixes the ceramic sleeve 300 by interaction with the stop ring 200, and the inner circumference of the stop ring 200 is connected to the stop ring coupling jaw 130. The ceramic sleeve support jaw 120 fixes the left side of the ceramic sleeve 300, and the stop ring 200 fixes the right side of the ceramic sleeve 300.

A cover 150 is connected to the cover connection hole 140, and the cover 150 is fixedly coupled to the sleeve body 100. The inner circumference of the cover connection hole 140 is a shape corresponding to the inclined contact surface 151 of the cover 150 and has a wide right diameter and a narrow left diameter, which is a sleeve stopper 430 applied to the cover 150. This is to prevent the cover 150 from moving in the left direction due to the wear pressure of the cover.

The stop ring 200 has a ring shape having a stepped portion 210 formed on an inner circumference thereof, and the stepped 210 has a shape corresponding to the stop ring coupling step 130 of the sleeve body 100. The stop ring 200 is fixedly coupled to the sleeve body 100, and the stop ring 200 has a left side in contact with a right side of the ceramic sleeve 300 and fixes the ceramic sleeve 300. On the left and right sides of the stop ring 200, the anti-rotation jaw 220 is formed to prevent the ceramic sleeve 300 from rotating.

The ceramic sleeve 300 is cylindrical and is fixed to the outer circumference of the sleeve body 100, the inner circumference of the ceramic sleeve 300 is in contact with the outer circumference of the sleeve body 100, and the left side of the ceramic sleeve support jaw ( 120, the right side is in contact with the stop ring 200. The outer circumference of the ceramic sleeve 300 is in contact with the inner surface of the bush 410. On the right side of the ceramic sleeve 300 is formed a rotation preventing groove 310 to which the rotation preventing jaw 220 of the stop ring 200 is connected.

The ceramic sleeve 300, the sleeve body 100, and the stop ring 200 may be fixedly coupled by vacuum blazing. Vacuum blazing is a method of soldering in a vacuum furnace by inserting a base material between a nonmetal material and a metal material, and since it is a known technique, detailed description thereof will be omitted.

The first gasket 320 may be disposed between the ceramic sleeve 300 and the ceramic sleeve support jaw 120, and the second gasket 330 may be disposed between the ceramic sleeve 300 and the stop ring 200. The first gasket 320 and the second gasket 330 are excellent in thermal stability, elasticity, and light weight, and are formed of a material such as graphite. The graphite is a material made by processing carbon carbon once again by burning carbon fiber at a higher temperature, and since it is a known material, detailed description thereof will be omitted. In FIG. 2, the second gasket () is separated, but the second gasket () according to the present invention may be integrally formed as illustrated in FIG. 6.

With reference to Figures 3 to 5 looks at the operation of the present invention.

Referring to Figure 5, the rotary shaft 450 of the immersion roll 440 is connected to the inside of the sleeve body 100, the engaging fastening jaw 110 is fastened to the fastener 420, the fastener 420 is the immersion roll 440 and fixed by a method such as welding. The ceramic sleeve 300 is disposed around the outer circumference of the sleeve body 100, and the ceramic sleeve 300 is fixed by the ceramic sleeve support jaw 120 on the left side and the stop ring 200 on the right side, and the first gasket The 320 is disposed between the ceramic sleeve 300 and the ceramic sleeve support jaw 120, and the second gasket 330 is disposed between the ceramic sleeve 300 and the stop ring 200. The outer circumference of the ceramic sleeve 300 is in contact with the inner circumference of the bush 410, and the cover 150 of the sleeve body 100 is in contact with the sleeve stopper 430.

In the above state, as the immersion roll 440 rotates, the ceramic sleeve 300 is worn in eccentric contact with the bush 410, and the cover 150 of the sleeve body 100 also rotates in contact with the sleeve stopper 430. Wear out.

The present invention forms the material of the ceramic sleeve 300 and the cover 150 in the above-described state to maximize the wear resistance, and the positional stability of the ceramic sleeve 300, the cover 150, the sleeve body 100 It is to maximize the durability and position stability of the immersion roll support device for continuous hot dip plating.

Meanwhile, the apparatus for supporting continuous deposition plating rolls according to the present invention operates inside a plating bath in which molten metal is contained, and the inside of the plating bath has a high temperature such that the metal is melted. Thermal expansion will occur.

The ceramic sleeve 300 having strong wear resistance has a coefficient of thermal expansion of about 40 to 800 degrees 4.4 X 10 ^ -6 (assuming that the material of the ceramic sleeve is SIC), and the sleeve body 100 has a coefficient of thermal expansion of 40. ~ 800 degrees 8.0 X 10 ^ -6 (assuming that the material of the sleeve body is Al2O3), the coefficient of thermal expansion between each other is about twice the difference, and if the material changes, more than twice the coefficient of thermal expansion occurs .

As described above, when the sleeve body 100 is largely thermally expanded and the ceramic sleeve 300 is relatively small thermally expanded, the first gasket 320 and the second gasket 330 are the ceramic sleeve 300 and the sleeve body 100. , Filling the gap between the stop rings 200 to firmly fix the ceramic sleeve 300, and prevents the molten metal from penetrating between the sleeve body 100 and the ceramic sleeve 300 to support the continuous roll plating deposition roll support device Maximize thermal stability.

In addition, the first gasket 320 and the second gasket 330 prevents minute scratches of the ceramic sleeve 300 generated when the sleeve body 100 and the ceramic sleeve 300 are assembled, thereby providing durability of the ceramic sleeve 300. To improve.

Referring to Figure 6 looks at another configuration of the present invention.

As shown in Figure 6, the other configuration of the present invention, the coupling catching jaw 110 is omitted in the configuration of the present invention described above, the remaining configuration is the same. Therefore, another configuration of the present invention is fixed to the deposition roll 440 by welding. More specifically, the left end of the ceramic sleeve support jaw 120 and the deposition roll 440 are welded. Detailed description of the ceramic sleeve 300 including the sleeve body 100, the stop ring 200, and the first gasket 320 and the second gasket 330 according to another embodiment of the present invention has been described above and thus will be omitted.

While the embodiments of the present invention have been described above, those skilled in the art will be able to make various modifications and changes without departing from the spirit and scope described in the embodiments of the present invention. If so, all such changes and modifications and equivalents should be considered to be within the scope of the present invention.

100: sleeve body 110: engaging locking jaw
120: ceramic sleeve support jaw 130: stop ring coupling jaw
140: cover connection hole 150: cover
151: inclined contact surface 200: stop ring
210: step 220: anti-rotation jaw
300: ceramic sleeve 310: anti-rotation groove
320: first gasket 330: second gasket
410: bush 420: fixture
430: sleeve stopper 440: immersion roll
450: axis of rotation

Claims (2)

Sleeve body 100 is connected to the rotary shaft 450 of the deposition roll 440 therein,
Ceramic sleeve 300 is disposed around the outer periphery of the sleeve body 100,
It comprises a stop ring 200 disposed around the outer periphery of the sleeve body 100,
The sleeve body 100 is formed on the left side of the outer circumference and includes a ceramic sleeve support jaw 120 in contact with the left side of the ceramic sleeve 300,
The stop ring 200 is in contact with the right side of the ceramic sleeve 300 and the sleeve of the continuous molten plating dip roll support device, characterized in that the coupling is fixed to the outer peripheral right side of the sleeve body (100).
The method according to claim 1,
A first gasket 320 is disposed between the left side surface of the ceramic sleeve 300 and the ceramic sleeve support jaw 120.
A sleeve of the continuous roll plating immersion roll support device, characterized in that the second gasket 330 is disposed between the right side and the stop ring 200 of the ceramic sleeve (300).

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