KR100581389B1 - ceramic hearth roll - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a ceramic roll for a high temperature furnace, the ceramic roll supporting a steel sheet conveyed from the inside of the high temperature furnace, comprising: a support shaft (52) and a ceramic sleeve fitted to the outside of the center of the support shaft to support the steel sheet. (54) and a plurality of side ceramic disks 55, 56 fitted to both sides of the ceramic sleeve to absorb the axial expansion of the support shaft while supporting the ceramic sleeve in the axial direction. It prevents the damage of the ceramic sleeve due to the expansion of the shaft and prevents the deformation of the shaft to enable high speed operation.

Description

Ceramic roll for high temperature furnace {ceramic hearth roll}

1 is a perspective view showing an example of a ceramic roll for a conventional high temperature furnace,

2 is a cross-sectional view showing another example of a conventional ceramic roll for a high temperature furnace;

3 is a cross-sectional view showing a ceramic roll for a high temperature furnace according to the present invention.

<Description of Symbols for Main Parts of Drawings>

52: support shaft 54: ceramic sleeve

55, 56: side ceramic disk 58: filling disk

62: fixed flange 64: moving flange

66: nuts

The present invention relates to a ceramic roll for a high temperature furnace.

The roll for conveying and conveying and supporting the steel plate currently being manufactured or the steel plate currently being heat-treated used the roll made of steel conventionally. However, such transfer steel rolls are not easy to remove contaminants generated on the surface of the roller when used for a long time, and when used in high temperature applications, they are not only poor in thermal stability, dimensional stability and abrasion resistance but also high thermal conductivity. Due to the defects of the conveyed products due to the development of the transfer roll consisting of the inner steel shaft and the outer asbestos layer, but the asbestos had a disadvantage of not only a harmful problem to the human body but also wear resistance. In order to solve these problems, ceramic rolls having excellent thermal stability, dimensional stability, wear resistance, and low thermal conductivity in high temperature applications have been developed and used in high temperature furnaces.

As a conventional ceramic roll for a high temperature furnace, as shown in Fig. 1, a through hole 2a is formed therein, and a cylindrical ceramic sleeve 2 made of ceramic material and a through hole 2a are formed. Support shaft portions 4 and 4 'which are inserted into the shaft 5 of the steel material to be inserted and the ceramic sleeve 2 and the opposite ends of the shaft 5 to support and rotate the ceramic sleeve 2 in the axial direction. ) A plurality of grooves 2b having the predetermined depth are formed at both end surfaces of the ceramic sleeve 2, and the grooves 2b are positioned at predetermined intervals to draw a circle as a whole. On one side end surface of 4 and 4 ', projections 4a and 4'a fitted into the grooves 2b and holes 4b of a predetermined depth into which end portions of the shaft 5 are fitted are shown. ) Is formed.

The ceramic roll for the conventional high temperature furnace of this type has severe damage and durability such as cracking of the terminal portion of the ceramic sleeve 2 or bending of the protrusions 4a and 4'a of the support shaft portions 4 and 4 'during high-speed rotation. It is weak, and the ceramic roll for the high temperature furnace which improved this is disclosed by Unexamined-Japanese-Patent No. 2004-39898.

As shown in FIG. 2, the published Patent Publication No. 2004-39898 discloses a ceramic sleeve 12 supporting a steel sheet and pressure-adhering to one end of the ceramic sleeve 12 to close the ceramic slab. A second support of the steel material for supporting and rotating the ceramic sleeve in the axial direction by pressing and close contact with the first support shaft portion 14 of the steel material to be rotated while supporting in the axial direction and the other end of the ceramic slab 12 Is formed of the shaft portion 16, the inclined surface (S1) is formed on both ends of the ceramic sleeve 12, the inclined surface of the ceramic sleeve 12 on the first and second support shaft portion (14, 16) It is a structure in which the opposing inclined surface S2 in close contact with S1) was formed.

The ceramic sleeve 12 has a through hole formed in the longitudinal direction therein, and a ceramic tube 22 made of ceramic material, and an inner tube 24 fitted into the ceramic tube 22 to support the ceramic tube. And an insert 26 inserted between the ceramic tube 22 and the inner tube 24 to prevent impact during rotation.

The first support shaft portion 14 is slidably fitted to the shaft 32, the shaft 32, the slider 34 in close contact with the inclined surface of the ceramic slab 12, and presses the slider 34 A spring 36 and a stopper 38 coupled to the shaft 32 to prevent separation of the spring 36, the stopper 38 being screwed to the shaft 32 in the axial direction. It is tightened to adjust the pressing force of the spring 36.

The second support shaft portion 16 is fixed to the shaft 42 and the opposite inclined surface (S2) is fitted to the outer surface of the shaft 42 is fixed by the fixing bolt 44 and in close contact with the inclined surface (S1) ( 46).

By the way, the ceramic roll for a high-temperature furnace of Unexamined-Japanese-Patent No. 2004-39898 comprised in this way has the 1st, 2nd support shaft part 14, 16 of the inclined surface S1 formed in the both sides of the ceramic slab 12. Since the opposite inclined surface S2 is supported in close contact, the terminal portion of the ceramic sleeve 12 is prevented from being broken or the support shaft portion is damaged, thereby extending the life of the ceramic roll. However, the first and second support shaft portions (steel material) Its thermal expansion coefficient is significantly larger than that of ceramic sleeves, so it is fundamentally impossible to use it for a long time at high temperature.In order to operate at high speed, more heat should be supplied, but the first and second support shafts are bent, so There was a limit.

Therefore, the present invention has been made to solve the above problems, an object of the present invention is to prevent the damage of the ceramic sleeve due to the expansion of the shaft at high temperature, and to prevent the deformation of the shaft ceramic for high temperature furnace to enable high-speed operation To serve the roll.

The ceramic roll for a high temperature furnace of this invention for achieving the said objective is a ceramic roll which supports the steel plate conveyed in the inside of a high temperature furnace, Comprising: A support shaft and the ceramic slits which are inserted in the center exterior of the said support shaft, and support the said steel plate. And a plurality of side ceramic disks fitted on both sides of the ceramic sleeve to absorb the axial expansion of the support shaft while supporting the ceramic sleeve in the axial direction.

Preferably, a plurality of filling disks are stacked and filled in the longitudinal direction of the support shaft to absorb the axial expansion of the support shaft and radially support the ceramic sleeve between the support shaft and the ceramic sleeve.

One side of the support shaft is provided with a fixing flange for supporting in close contact with the side ceramic disk, and the other side of the support shaft is provided with a moving flange that is supported in close contact with the side ceramic disk, the movement can be adjusted in the longitudinal direction.

Preferably, the thickness of one of the side ceramic disks or the filling disks is 3 to 8 mm.

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

As shown in Fig. 3, the ceramic roll 50 of the present invention supporting the steel sheet conveyed in the inside of the high temperature furnace is sandwiched between the support shaft 52 and the center outside of the support shaft 52 to support the steel sheet. A plurality of side portions fitted to both sides of the ceramic sleeve 54 to absorb the axial expansion of the ceramic sleeve 54 and the support shaft 52 while supporting the ceramic sleeve 54 in the axial direction. Ceramic disks 55, 56, and between the support shaft 54 and the ceramic sleeve 54 absorb axial expansion of the support shaft 52 while radiusing the ceramic sleeve 54. A plurality of filling disks 58 are stacked and filled in the longitudinal direction of the support shaft 52 so as to support in the direction.

On one side (right side) of the support shaft 52, a fixing flange 62, which is in close contact with the side ceramic disk 56, is fixed by welding or the like, and on the other side (left side) of the support shaft 52, the side ceramic A moving flange 64, which is held in close contact with the disk 55 and can be moved in the longitudinal direction, is fixed by the nut 66.

The support shaft 52 is made of ordinary steel, and may be made of stainless steel (SUS 304) or the like. One side (left side) of the support shaft 52 is formed with a male threaded portion so that the nut 66 is coupled, and both ends of the support shaft 52 are formed with a key groove into which a key is inserted to fix the pulley. The ceramic shaft 55, 56, 58 is inserted into the support shaft 52 may be a rectangular cross section, such as a rectangular cross section, a pentagonal cross section so that the ceramic disk is not inserted and rotated, but preferably a circular cross section. .

The ceramic sleeve 54 is a ceramic tube made of a ceramic material in which a through hole is formed in the longitudinal direction thereof, and the filling ceramic disk 58 is inserted therein, and classifies alumina-silica ceramic fibers. It is manufactured by vacuum molding into a cylindrical ceramic molded product by adding water and an inorganic binder, and drying it. It has excellent thermal mechanical stability and consists only of ceramic fibers to form a uniform pore layer. 70 ~ 99.9 wt% classified alumina-silica ceramic fiber was pulverized and adjusted to 3 ~ 5㎛ average diameter and 100 ~ 500㎛ average length Remove only unfibrous spherical particles with a particle diameter of tens of micrometers to a few millimeters and form a uniform fibrous structure containing less than 1%. It is. The ceramic sleeve 54 preferably contains at least 90% purity of the silica (SiO ₂ ).

The side ceramic disks 55 and 56 and the filling disk 58 are leaf-shaped disks formed in the center thereof with the same rectangular holes as the rectangular cross sections of the support shaft 52 so as not to rotate. Similar to the material of (54), the thickness of one is preferably 3 to 8 mm. The filling disk 58 also serves as a heat insulator.

On the other hand, the filling disk 58 may be made of non-asbestos material to increase the role of heat insulation.

The nut 66 has a structure in which two nuts are inserted at the same time to prevent loosening thereof. The nut 66 may be a lock nut to prevent its loosening. The moving flange 64 may be fixed by a vandaling or the like instead of the nut 66.

In addition, the movable flange 64 may be supported and fixed by a stopper which is screwed to the support shaft and tightened in the axial direction to adjust the pressing force of the spring as shown in the prior art of FIG.

According to the ceramic roll for the high temperature furnace according to the present invention configured as described above, since the side ceramic disks 55 and 56 and the filling disk 58 almost completely absorb the expansion of the support shaft 52 and serve as thermal insulation, the ceramic slits There is no fear that the terminal part of the eve is broken or the support shaft part is damaged or deformed (bending deformation), which significantly increases the durability and allows the ceramic roll to be operated at high temperature at high speed.

Specifically, when the ceramic roll is heated to 1000 ° C., the amount of expansion in the axial direction of the support shaft 52 is 17.6 × 10 ⁻⁶ / ° C. When the length of the support shaft is 1 m, the recovery of the ceramic disk is larger than that of 17.6 mm. As the amount is 176mm, it can work at high temperature without breakage of ceramic sleeve or bending of support shaft, and its life will be remarkably extended.

The present invention is not limited to the above embodiment and can be modified in various ways.

According to the ceramic roll for a high temperature furnace according to the present invention, there is an effect to prevent damage to the ceramic sleeve due to expansion of the shaft at a high temperature and to prevent the deformation of the shaft to enable high-speed operation.

Claims (4)

In the ceramic roll which the steel plate conveyed in the inside of a high temperature furnace supports, A support shaft, a ceramic sleeve fitted to the outside of the center of the support shaft to support the steel plate, and a flange coupled to both sides of the support shaft to support the ceramic sleeve in the axial direction, A plurality of side ceramic discs are sandwiched between the ceramic sleeve and the flange to absorb axial expansion of the support shaft while supporting the ceramic sleeve in the axial direction. A high temperature characterized in that a plurality of filling disks are stacked and filled in the longitudinal direction of the support shaft between the support shaft and the ceramic sleeve to absorb the axial expansion of the support shaft while supporting the ceramic sleeve in the radial direction. Ceramic roll for furnace. delete The method of claim 1, The flange is A fixing flange supporting one side of the support shaft in close contact with the side ceramic disk; The ceramic roll for the high temperature furnace, characterized in that the support shaft is in close contact with the side ceramic disk on the other side of the support shaft, but the movable flange is movable in the longitudinal direction. The method of claim 1, The thickness of one of the side ceramic disk and the filling disk is a ceramic roll for a high temperature furnace, characterized in that 3 to 8mm.

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