KR101613646B1 - Apparatus for Coupling Sleeve of Roll - Google Patents

Abstract

The present invention relates to a sleeve coupling device for a rolling roll. The sleeve coupling device for a rolling roll comprises: a main support unit ascending and descending while supporting a lower surface of a cylinder of a sleeve in a V shape; a sub support unit supporting an upper outer circumference of the sleeve to a shaft connection direction on a rear end of the shaft connection direction of the main support unit; a moving carriage mounting the main support unit and the sub support unit to be moved; and a diving unit controlling the moving carriage in order for the moving carriage to reciprocate along a moving path. A shaft is assembled on an accurate position of the shaft as a support wherein the heated sleeve is mounted thereon, and moves the sleeve in a horizontal direction using a transfer device. The supports supporting the sleeve presses an outer surface of the sleeve during a thermal contraction process of the sleeve. As such, the sleeve coupling device for a rolling roll is able to remarkably improve a coupling force, and enables a worker to safely conduct a sleeve coupling work. Moreover, the sleeve coupling device enables the worker to rapidly and accurately perform a shaft coupling work.

Description

[0001] Apparatus for Coupling Sleeve of Roll [0002]

The present invention relates to a sleeve coupling apparatus for rolling rolls, and more particularly, to a sleeve coupling apparatus for a rolling roll, in which a support, on which a heated sleeve is mounted, moves the sleeve horizontally by a transfer device, To a sleeve coupling device for rolling rolls in which a plurality of support rods that have been mounted on a sleeve in a heat shrinking process of the sleeve increase the coupling force by pressing the outer surface of the sleeve.

Rolling rolls are generally divided into a mono roll having the same material as the inner and outer rolls, and a sleeve roll having different inner and outer material.

The conventional sleeve roll has a sleeve 1 having a hollow portion 1a penetrating the center of the body and having an outer peripheral surface in contact with the rolled material as shown in Figure 1 and a hollow portion 1a of the sleeve 1, And a roll shaft 2 fixed at both ends thereof to both sides of the sleeve 1 to form a shaft portion for rotating the sleeve 1.

The sleeve 1 and the roll shaft 2 usually have a heat-shrinking method which enables accurate and rigid shaft engagement.

The heat shrinking method is a method in which the hollow portion 1a of the sleeve 1 is heated and expanded and then the roll shaft 2 is joined and cooled to tightly tighten the roll shaft 2 with the hollow portion 1a contracted, .

However, in order to perform the above-described finishing step, the sleeve 1 is passed through the hollow portion 1a of the crane by the wire of the crane, and then is transferred to the crane. The wire of the crane is passed through the hollow portion 1a of the sleeve 1 A portion bent at the time of being caught is formed at the end edge of the hollow portion 1a and the end edge of the sleeve 1 respectively and the portion bent by the end edge of the sharp hollow portion 1a and the end edge of the sleeve 1 There is a problem in that it is damaged.

In addition, the sleeve 1, which is fed by the wire, must be erected vertically for the purpose of shrinking, but there is no separate device for erecting the sleeve 1, so that when the sleeve 1 is laid down on the floor, There is a problem that the outer circumferential surface of the outer circumferential surface is often damaged due to contact with the floor, and the work force and time are required to be increased.

A conventional technique proposed to solve the above problems is disclosed in Korean Patent No. 10-1024737.

FIG. 2 is a perspective view showing a structure of a sleeve tilting apparatus for a rolling roll in the prior art, wherein the above-described conventional technique is applied to a first bottom portion 11 of a sleeve rotating member 10 rotatably coupled to a rotary support casing member 20 The sleeve 1 can be safely transported to a position for heat-shrinking operation by vertically positioning the sleeve 1 by rotating the sleeve rotating member 10 after the sleeve 1 is laid down, It is possible to increase the work convenience and the working efficiency in the heat shrinking work for the production of rolls.

However, since the above-mentioned prior art still needs to move the sleeve by using a crane, there is a high risk of an accident in the moving process, and there is a problem in that the sleeve is raised and heat shrinking operation is laborious and the shaft fitting is not elaborate.

Korean Registered Patent No. 10-1024737 (Registered on March 17, 2011)

SUMMARY OF THE INVENTION The present invention has been made in order to solve the problems described above, and it is an object of the present invention to provide an apparatus and a method for assembling a shaft in which a support, on which a heated sleeve is mounted, And a plurality of supporting rods that are mounted on the sleeve during the process of pressing the outer surface of the sleeve to improve the coupling force.

It is another object of the present invention to provide a sleeve coupling device for a rolling roll capable of fast and accurate axial coupling as well as safely performing a sleeve coupling operation.

According to an aspect of the present invention, there is provided a method of manufacturing a semiconductor device, comprising: a main supporting portion for vertically moving a bottom surface of a sleeve in a V-shape; A sub-support for supporting the outer periphery of the upper portion of the sleeve toward the shaft coupling direction at the rear end of the main support portion in the shaft coupling direction; A moving carriage for mounting the main support portion and the sub support portion in a movable state; And a traveling part for controlling the traveling carriage to reciprocate along the traveling path.

Further, the main support portion includes a pair of lower pressing supports for allowing the sleeve to be mounted between mutually facing "V" A pair of main elevating support posts for supporting each of the lower pressurizing supports so as to be able to move up and down; And a first distance adjuster that adjusts the distance between the pair of main lift rails so that the distance between the pair of main lift rails becomes wide or narrow according to the diameter of the sleeve.

The lower pressing support base includes a flat mounting surface for supporting the lower surface of the sleeve, and a pressing surface formed at the rear end corner of the mounting surface with a thickness corresponding to the thickness of the sleeve.

Further, the sub-support portion includes a pair of upper pressure supporters which are mutually opposed "V" -shaped slopes and support the upper end surface of the sleeve in the shaft coupling direction; A pair of sub-lift support posts for supporting each of the upper press support rods so as to be able to move up and down; And a second distance adjuster which adjusts the pair of upper pressure supports to be opened or closed in accordance with the diameter of the sleeve.

As described above, according to the present invention, the supporting base on which the heated sleeve is placed moves the sleeve in the horizontal direction by the conveying device so that the shaft is assembled at the correct position of the shaft, and the plurality of The support has an effect of greatly enhancing the bonding force by pressing the outer surface of the sleeve.

INDUSTRIAL APPLICABILITY The present invention has an effect that not only the sleeve coupling operation can be performed safely, but also an accurate axial coupling operation can be performed.

1 is a perspective view showing a general rolling roll;
2 is a perspective view showing a structure of a sleeve tilting apparatus for a rolling roll of the prior art.
3 is a front view showing an example in which a small diameter sleeve is supported on a sleeve coupling apparatus of a rolling roll according to the present invention.
Fig. 4 is a front view showing an operation example of a main supporting portion and a sub supporting portion of a sleeve coupling device of a rolling roll according to the present invention; Fig.
5 is a front view showing an example in which a large-diameter sleeve is supported by a sleeve coupling apparatus of a rolling roll according to the present invention.
6 and 7 are plan views showing a sleeve coupling operation using a sleeve coupling apparatus for a rolling roll according to the present invention.

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

3 is a front view showing an example in which a small diameter sleeve is supported on a sleeve coupling apparatus of a rolling roll according to the present invention. Referring to FIG. 3, the sleeve coupling apparatus for a rolling roll according to the present invention mainly comprises a main support portion 110, a sub support 120, a moving bogie 130, and a traveling unit 140.

First, a main support portion 110 is disclosed in which the upside and downside of the sleeve 101 are supported in a V-shape.

The main support part 110 supports the sleeve 101 in a horizontal state by receiving the heated sleeve 101.

The main support portion 110 is a columnar structure having a pair of two pillars to support the sleeve 101 and to adjust the height and mutual distance of each main support portion 110, The sleeve 101 can be mounted.

More specifically, the pair of lower pressing supports 111 are formed between the V-shaped inclined surfaces facing each other to allow the sleeve 101 to be mounted thereon.

The lower pressing support base 111 includes a flat mounting surface 111a for supporting a lower surface of the sleeve 101 and a lower pressing support base 111 having a step formed at the rear end corner of the mounting surface 111a by the thickness of the sleeve 101 Thereby providing the pressing surface 111b.

At this time, the stationary surface 111a serves to support the vertical load of the sleeve 101, and the pressing surface 111b serves to push the sleeve 101 in the axial direction when the shaft is engaged.

At this time, the stationary surface 111a is integrally formed with the pressing surface 111b and can be installed to be able to slide on an upper portion of the lower pressing support 111.

The above structure allows the positions of the mounting surface 111a and the pressing surface 111b to be varied with respect to the shaft engaging direction on the lower pressing support 111. This is because the pressing force And provides means for aligning the locations.

The structure may also be provided as a means for separating the shaft-coupled sleeves 101 in reverse order.

For example, in the case of separating the sleeve 101, the position of the stationary surface 111a may be moved to be positioned at the front end in the shaft coupling direction of the sleeve 101, so that the pressing surface 111b may be positioned on the opposite side of the shaft 101 from the front end of the sleeve 101 So that the sleeve 101 can be separated.

At this time, the sleeve 101 may be sufficiently heated to produce a separation clearance.

A pair of main elevating spools 113 for supporting each of the lower pressurizing supports 111 in a state where they can be raised and lowered is formed.

The main elevating spool 113 is made of a square metal column, and is composed of an outer column and an inner column so that the inner column can be moved up and down using the power of a motor or the like.

At this time, a lower pressing support 111 is mounted on the inner pillar and is moved up and down together. In order to minimize oscillation during ascending and descending, an LM guide is provided between the outer pillar and the inner pillar to slide the inner pillar, So that the lifting strength can be provided.

The main lifting platform 113 as described above provides a structure capable of adjusting the mutual distance.

To this end, in the present invention, a first distance adjusting portion 115 is formed to adjust the distance between the pair of main elevating spools 113 to be widened or narrowed according to the diameter of the sleeve.

The first distance adjuster 115 forms a rail on which the main elevating strut 113 can move, and connects the main elevating strut 113 with a ball screw, So that the spacing between the main lifting platform 113 and the main lifting platform 113 can be adjusted.

A sub-support 120 for supporting the outer peripheral edge of the upper portion of the sleeve 101 toward the shaft coupling direction at the rear end of the main support portion 110 in the shaft coupling direction is disclosed.

The sub support part 120 serves to press the upper part of the sleeve 101 in the axial direction by helping the main support part 110 when the sleeve 101 is engaged with the shaft. do.

A pair of upper pressing supports 121 for supporting a rear end of the upper surface of the sleeve 101 in the shaft coupling direction are formed in a shape of a "V" -shaped slope facing each other do.

The upper pressing support 121 may be provided in the form of a metal block to prevent deformation when a pressing force is applied.

A pair of sub-lifting support pillars (123) for supporting each of the upper pressing supports (121) in a state of being able to move up and down are formed.

The configuration of the sub-lifting and supporting strut 123 is similar to that of the main lifting strut 113 described above. The sub-lifting strut 123 is composed of an outer pillar and an inner pillar in the form of a square metal column, Down operation.

At this time, the upper pressing support 121 is mounted on the inner column, and the upper pressing support 121 is moved up and down together. In order to minimize vibration during ascending and descending, an LM guide is provided between the outer and inner pillars, So that the lifting strength can be provided.

A second distance adjuster 125 is provided to adjust the pair of upper pressure supports 121 so as to be spaced apart or narrowed according to the diameter of the sleeve.

The second distance adjuster 125 slides and fixes the upper pressure support 121, which is supported on the sub-lifting support 123 in a cantilever fashion, to provide a structure for expansion and contraction.

For example, the upper pressing support 121 may be formed on the arm tip of the cantilever type, and the arm may be coupled to the slide block formed on the sub-lifting and supporting strut 123 to fix the variable position.

A moving carriage 130 for mounting the main supporting portion 110 and the sub supporting portion 120 in a movable state is formed.

The moving carriage 130 is provided with a main supporting portion 110 and a sub supporting portion 120 on a plate-shaped base structure, and provides a structure capable of moving a rail in a shaft coupling direction.

A traveling unit 140 for controlling the traveling carriage 130 to reciprocate along the traveling route is formed.

The traveling unit 140 provides a rail-type moving path through which the moving truck 130 moves to the floor of the workplace and provides driving power for driving the moving truck 130. [

At this time, power can be transmitted to the moving truck 130 using a motor and a ball screw.

FIG. 4 is a front view showing an operation example of a main supporting portion and a sub supporting portion of a sleeve coupling apparatus of a rolling roll according to the present invention, and FIG. 5 is a front view of a sleeve coupling apparatus of a roll for rolling according to the present invention, And FIGS. 6 and 7 are plan views showing a sleeve coupling operation using a sleeve coupling apparatus for a rolling roll according to the present invention.

4 to 7, a description will be given of a sleeve coupling operation using the sleeve coupling apparatus of the rolling roll of the present invention.

The height adjustment and the first distance adjustment unit 115 using the main lift rails 113 of the main support unit 110 may be adjusted so that the main support unit 110 is set according to the diameter of the sleeve 101 for the operation. So that the diameter of the sleeve 101 is adjusted.

Next, the sub support portion 120 is set. The position of the upper pressing support 121 is positioned at the rear end of the sleeve 101 by using the second distance adjuster 125 after the height of the sub support part 120 is adjusted using the sub lifting support bar 123.

Then, the traveling unit 140 is operated to move the moving truck 130 in the shaft coupling direction.

At this time, it is possible to perform an axial aligning operation for aligning the axial centers of the shaft (SH) and the sleeve (101). The axis alignment operation may be performed by simultaneously operating the main support portion 110 and the sub support portion 120.

Thereafter, the moving bogie 130 is moved so that the sleeve 101 and the shaft SH are axially coupled.

In the axial coupling process, the lower pressing support 111 and the upper pressing support 121 press the rear end of the sleeve 101 simultaneously at the upper and lower portions to achieve stable axial coupling.

As described above, according to the present invention, the supporting base on which the heated sleeve is placed moves the sleeve in the horizontal direction by the conveying device so that the shaft is assembled at the correct position of the shaft, and the plurality of The support has an effect of greatly enhancing the bonding force by pressing the outer surface of the sleeve.

INDUSTRIAL APPLICABILITY The present invention has an effect that not only the sleeve coupling operation can be performed safely, but also an accurate axial coupling operation can be performed.

As described above, the present invention is not limited to the above-described specific preferred embodiments, and any person skilled in the art can make various modifications without departing from the gist of the present invention. It is to be understood that such changes and modifications are intended to fall within the scope of the appended claims.

101: sleeve 110: main support
111: lower pressing support 113: main lift rail
115: first distance adjusting unit 120:
121: Upper pressure support 123: Sub lift member
125: second distance adjusting unit 130: moving lane
140:

Claims (4)

A main support portion 110 for moving up and down the sleeve 101 in a state in which the bottom surface of the sleeve 101 is supported in a V shape;
A sub support portion 120 for supporting the outer peripheral edge of the upper portion of the sleeve 101 toward the shaft coupling direction at the rear end of the main support portion 110 in the shaft coupling direction;
A moving carriage (130) for mounting the main support part (110) and the sub support part (120) in a movable state; And
And a traveling unit (140) for controlling the traveling bogie (130) to reciprocate along the traveling route,
The main support portion 110 includes:
A pair of lower pressing supports 111 for mounting the sleeve 101 between the "V" -shaped slopes opposed to each other;
A pair of main lifting platform 113 for supporting each of the lower pressing pedestals 111 in a state of being able to move up and down; And
And a first distance adjusting unit (115) for adjusting the distance between the pair of main elevating spools (113) to be opened or narrowed according to the diameter of the sleeve,
Characterized in that the sleeve is in a contracted state after heating,
The sub-
A pair of upper pressure supports 121 for supporting the upper rear end of the sleeve 101 in the shaft coupling direction;
A pair of sub-lifting support pillars (123) for supporting each of the upper pressure support bases (121) so as to be able to ascend and descend;
And a second distance adjusting unit (125) for adjusting the pair of upper pressing supports (121) to be opened or closed in accordance with the diameter of the sleeve,
The lower pressing support base 111 has a flat mounting surface 111a for supporting a lower surface of the sleeve 101 and a pressing surface 111a formed at the corner of the mounting surface 111a with a thickness equal to the thickness of the sleeve 101 111b)
Wherein the pressing surface is variably installed at a front edge portion or a rear edge portion,
The main lifting platform 113 is made of a square metal column and is composed of an outer column and an inner column so that the inner column moves up and down using motor power,
An LM guide is installed between the outer and inner pillars in order to minimize the vertical vibration of the inner pillars.
The first distance adjuster 115 is formed with rails on which the main elevating struts 113 are movable and is connected to the main elevating struts 113 by a ball screw, The interval between the pair of main lift rails 113 is adjusted,
The second distance adjusting unit 125 slides and fixes the upper pressing support 121 supported on the upper portion of the sub-lifting strut 123 in the form of a cantilever, and the upper pressing support 121 is attached to the tip of the arm of the cantilever type And the arm is coupled to a slide block formed on the sub-lifting strut 123 to fix the variable position. delete delete delete

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