KR101328248B1 - Bucking prevented apparatus for coil of hot rolling process - Google Patents

Abstract

An anti-buckling device for a hot rolled coil according to an embodiment of the present invention comprises: a rotary shaft which is inserted into a hot rolled coil and has screw threads; an axial moving member which is formed on the rotary shaft and moves on the rotary shaft when the rotary shaft rotates; an actuating link connected to the axial moving member through a pin; a contact part which is connected to the actuating link through a pin to move along the inner surface of a coil; and guide parts which are formed on both sides of the contact part to move the contact part in a specific direction.

Description

Bucking prevented Apparatus for coil of hot rolling process

The present invention relates to a buckling preventing device for a hot rolled coil, and more particularly to an invention for preventing the buckling in the cooling process after the coil is wound in the hot rolling process.

In general, it is required to improve the strength of the steel sheet used in accordance with the development of the industry, and accordingly, precipitation hardening or solid solution strengthening methods are used to improve the strength of the steel sheet.

As such, a representative industry using steel sheets is the automotive industry. In order to cope with safety, fuel economy, environmental regulations, and the like, a high strength steel having a high thickness and a thin thickness is required.

Accordingly, recently, high strength steels such as Advanced High Strength Steel (AHSS), which have improved strength by using the transformation structure of steel, have been developed, and the yield is continuously increasing.

After the hot rolling, the AHSS runs on a run out table, which is a high-speed cooling section, and undergoes a transformation while being cooled by the amount of water set according to a target coiling temperature.

However, most of the AHSS transformation process is not completed on the run-out table, the transformation process is completed in the state that is wound on the coil strip in the winder and loaded on the cooling yard.

In addition, the coil strip reacts sensitively to temperature and is accompanied by volume expansion during winding or cooling in the cooling yard and in the process of transformation. Accordingly, a gap is generated between the layers on which the strip is wound during the volume expansion process, and thus, the coil strip does not endure the weight of the coil strip, and there is a problem in that deformation (buckling) occurs in the radial direction.

Thus, if the coil is deformed in the radial direction, it causes a lot of losses in productivity and error rate in the hot rolling and cold rolling process. Accordingly, conventional cooling is further performed during or after winding of the coil strip. For example, a method of idling rotation without supplying a coolant to coil coils or withdrawing coil strips immediately after winding is used, but there is a problem of deteriorating hot rolling productivity of coil strips as the additional cooling proceeds. .

In addition to such additional cooling, a method of preventing buckling by applying high temperature winding and low temperature winding according to the winding temperature range is also utilized. In other words, steel grades with high coiling temperature increase the coiling temperature more than the design value to delay the transformation point, and steel grades with low coiling temperature lower the coiling temperature than the design value to complete the transformation on the runout table.

However, this method is not easy to work because the exact cooling mechanism must be derived separately for each steel type, and the winding temperature must be reset for each steel type, and the productivity decrease and the production of dummy products in the process of resetting the winding temperature according to the steel type. Unnecessary waste caused by the situation is occurring. In addition, in the related art, due to the limitation of the winding temperature according to the steel grade, it is difficult to quickly respond to the new steel grade.

Accordingly, the development of technology for improving the reliability of the productivity and quality of the product is required.

An object of the present invention is to provide a buckling preventing device for a hot rolled coil for supporting the coil to prevent buckling from occurring in the coil wound in the hot rolling process to produce a product with improved reliability.

An anti-buckling device for a hot rolled coil according to an embodiment of the present invention is inserted into the inner diameter portion of the hot rolled coil, the shaft is provided with a screw shaft on the rotary shaft to move on the rotary shaft in accordance with the rotation of the rotation shaft, the rotation shaft A moving member, an actuating link pin-connected with the axial movable member, a contact part pinned with the actuating link and the contact portion to move in a predetermined direction so as to move in close contact with the inner diameter surface of the coil according to the movement of the axial movable member. It may include a guide portion provided on both sides of the contact portion.

In addition, the guide portion of the buckling prevention apparatus for hot rolled coils according to an embodiment of the present invention, the guide groove is formed, the arm guide member provided on both sides of the contact portion and the guide tab inserted into the guide groove of the arm guide member It may be formed, and may include a male guide member provided on both sides of the rotating shaft.

In addition, the guide groove of the buckling prevention apparatus for a hot rolled coil according to an embodiment of the present invention, the direction holding groove formed in the radial direction of the rotary shaft and the guide tab is fitted to prevent the reverse rotation of the rotary shaft, It may be connected to the groove, and may include a reverse rotation prevention groove formed in the circumferential direction of the rotating shaft.

In addition, the rotation axis of the buckling preventing apparatus for a hot rolled coil according to an embodiment of the present invention is provided at one end of the split shaft, so as to associate the respective number of the divided shaft and the same number of the divided shaft and the number of the axial movement member. It may include a joint member.

In addition, the axial movement member of the buckling preventing device for a hot rolled coil according to an embodiment of the present invention includes a moving hole member and a nut hole member provided in the moving hole member and the nut connected to the operation link, the nut Screw bone can be formed only in the hole member.

In addition, the buckling preventing apparatus for a hot rolled coil according to an embodiment of the present invention may further include a support rod associated with the moving hole member to prevent the axial movement member to rotate to move on the rotation axis.

The buckling preventing apparatus for hot rolled coils according to the present invention has an effect of preventing buckling from occurring in the coil by being inserted into an inner diameter portion of a coil wound in a hot rolling process to support the coil. As a result, a material deviation can be reduced, and an advantage of improving the quality of the product is generated.

In addition, by preventing the rotation of the axial movement member, there is an effect that can prevent the contact portion associated with the axial movement member bent by the twist through the operation link.

In addition, there is an effect that the contact portion in close contact with the coil can be prevented from being unexpectedly released by the reverse rotation of the rotating shaft.

In addition, by dividing the rotating shaft by the same number as the axial movement member, there is an advantage that it is easy to adjust the axial movement member at equal intervals.

In addition, by separately configuring the nut hole member screwed to the rotary shaft and the moving hole member connected to the operation link, there is an advantage that facilitates replacement of the nut hole member due to wear caused by the screw coupling.

1 is a perspective view schematically showing a buckling preventing device for a hot rolled coil according to an embodiment of the present invention.
2 is a front view schematically showing a buckling preventing device for a hot rolled coil according to an embodiment of the present invention.
3 is a side view schematically showing the anti-rotation groove of the anti-buckling device for a hot rolled coil according to an embodiment of the present invention.
Figure 4 is a schematic diagram showing the operation of the anti-buckling device for a hot rolled coil according to an embodiment of the present invention.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the inventive concept. Other embodiments falling within the scope of the inventive concept may readily be suggested, but are also considered to be within the scope of the present invention.

The same reference numerals are used to designate the same components in the same reference numerals in the drawings of the embodiments.

1 is a perspective view schematically showing a buckling preventing device 1 for a hot rolled coil according to an embodiment of the present invention, Figure 2 is a schematic view of a buckling preventing device 1 for a hot rolled coil according to an embodiment of the present invention It is a front view shown as.

1 and 2, the buckling preventing device 1 for a hot rolled coil according to an embodiment of the present invention is inserted into the inner diameter portion 2a of the hot rolled coil 2, and has a threaded shaft 10. In accordance with the rotation of the rotary shaft 10 to move on the rotary shaft 10, the axial movement member 20 provided in the screw combination to the rotary shaft 10, the operation link 30 is pin-connected with the axial movement member 20 ), The contact portion 40 and the contact portion 40 are pin-connected to the operation link 30 to move in close contact with the inner diameter surface 2b of the coil 2 as the axial movement member 20 moves. It may include a guide portion 50 provided on both sides of the contact portion 40 to move in a predetermined direction.

In the buckling preventing device 1 for a hot rolled coil according to the present invention, the coil 2 wound in the hot rolling process is transformed by cooling before winding, does not have the necessary rigidity, and is cooled after winding, thereby winding the coil 2. It is an invention for preventing bucking from occurring due to gaps between strip layers of the substrate.

To this end, the present invention may include a rotary shaft 10, the axial movement member 20, the operation link 30, the contact portion 40 and the guide portion 50. That is, after the buckling preventing device 1 for hot rolled coil of the present invention is inserted into the inner diameter portion 2a of the coil 2, the contact portion 40 is in close contact with the inner diameter surface 2b of the coil 2. The inner diameter surface 2b of the coil 2 is pushed and supported so as to prevent buckling from occurring in the coil 2.

The rotary shaft 10 serves to move the on-axis moving member 20 to be described later by a predetermined interval by the rotation. To this end, the rotary shaft 10 may be formed with a screw thread for screwing the axial movement member 20. Rotation of the rotary shaft 10 may be connected to the external rotation drive means to be rotated. The rotation driving means may be a motor or the like.

The rotary shaft 10 may be connected to the rotary shaft connecting member 57 of the guide unit 50 to be described later to support the rotation. For rotation, the rotating shaft connecting member 57 may be provided with a bearing.

In addition, the rotation shaft 10 of the buckling preventing device 1 for hot rolled coils according to an embodiment of the present invention is the same number of divided shafts (11, 12) and the number of each of the axial movement member (20) The coupling member 13 may be provided at one end of the dividing shafts 11 and 12 to connect the dividing shafts 11 and 12. Thereby, it is easy to adjust the axial movement member 20 at equal intervals.

That is, each of the axial movement member 20 should be positioned on the rotation shaft 10 so that the contact portion 40 to be described later may be spaced apart from the rotation shaft 10 by the same interval. To this end, it is preferable to adjust the contact portion 40 to be spaced apart at equal intervals from the rotation shaft 10 after each of the axial movement member 20 is coupled to each of the divided shafts (11, 12). This is because the axial movement member 20 should be spaced apart at the same interval, but the contact portion 40 to be described later, which is linked through an operation link to be described later, becomes horizontal and can be in close contact with the inner diameter surface 2b of the coil 2. Because.

In addition, the rotation shaft 10 may include a joint member 13 provided at one end of the division shafts 11 and 12 to connect the respective division shafts 11 and 12. As a result, each of the divided shafts 11 and 12 may be coupled after moving each of the axial moving members 20 on the divided shafts 11 and 12 by a predetermined rotation to a predetermined diameter. In addition, after the division shafts 11 and 12 are coupled, the axial movement members 20 may be moved while maintaining the same distance.

The axial movement member 20 moves on the rotation shaft 10 to serve to closely contact the contact portion 40 connected through the operation link 30 to the inner diameter surface 2b of the coil 2. . To this end, the axial movement member 20 may be screwed with the rotation shaft (10).

In addition, the axial movement member 20 of the buckling preventing device (1) for hot rolled coils according to an embodiment of the present invention is a moving hole member 21 and the moving hole member that is pin-connected with the operation link (30) A nut hole member 22 provided at 21 may be included, and only the nut hole member 22 may have a screw bone.

The movable hole member 21 may move freely on the rotary shaft 10 without screwing the rotary shaft 10. The movable hole member 21 is pin-connected with the actuating link 30, moves up and down in accordance with the movement of the nut hole member 22, and moves up and down the contact portion 40 to be described below which is pin-connected with the actuating link 30. You can. In addition, the movable hole member 21 may be formed with a support rod 60 coupling hole to which the support rod 60 to be described later can be coupled.

The nut hole member 22 may be screwed with the rotation shaft 10 to move in a predetermined direction according to the rotation direction of the rotation shaft 10. As a result, the movable hole member 21 connected to the nut hole member 22 is moved. By separately configuring the nut hole member 22 screwed with the rotary shaft 10 and the movable hole member 21 connected with the operation link 30, it is easy to replace the parts resulting from wear of the screw coupling There is an advantage to this.

That is, the movable hole member 21 connected to the actuating link 30 should be separated from the actuating link 30 in order to replace it. In this case, the contact portion 40 connected to the actuating link 30 is not supported. This makes it difficult to separate the movable hole member 21. In addition, in order to assemble the movable hole member 21 with the operation link 30 again, a component for supporting the contact portion 40 is required, and thus, the assembly of the movable hole member 21 is difficult. On the other hand, separation and assembly of the nut hole member 22 has no effect on the contact portion 40, it is easier than replacing the moving hole member 21. Accordingly, by screwing the nut hole member 22 to the rotary shaft 10, the parts that are worn out are limited to the nut hole members 22, and replacement of parts due to wear with the rotary shaft 10 is performed. It will be easy to.

On the other hand, the shape of the screw bone formed in the nut hole member 22 may be formed along the direction of movement on the rotary shaft (10). That is, a screw thread is formed in the rotation shaft 10 in the clockwise direction, and when the nut hole member 22 is advanced on the rotation shaft 10 when the rotation shaft 10 is rotated in the clockwise direction, the nut hole is used. The nut hole member 22 is formed on the member 22 when the screw hole in the clockwise direction is formed and the nut hole member 22 is reversed on the rotation shaft 10 when the rotation shaft 10 is rotated in the clockwise direction. 22) counterclockwise screw bone is to be formed.

The actuating link 30 connects the axial movement member 20 and the contact portion 40 to the inner diameter surface of the coil 2 with the contact portion 40 in accordance with the movement of the axial movement member 20. 2b) to close the contact, or serves to release the contact. To this end, one end of the operation link 30 is pin coupled to the axial movement member 20, the other end may be pin coupled to the contact portion (40). In addition, in order to improve the durability against the force applied to the actuating link 30, the actuating link 30 may be formed with a support plate. That is, the cross-sectional shape of the operation link 30 may be formed in the 'H' shape or the like.

The contact portion 40 is inserted into the inner diameter portion 2a of the coil 2 to be in close contact with the inner diameter surface 2b of the coil 2 and serves to push the inner diameter surface 2b of the coil 2. This makes it possible to prevent the buckling of the coil 2 even if a gap occurs due to the transformation caused by cooling between the strips of the coil 2. To this end, the contact portion 40 is pin-coupled with the operation link 30, in connection with the axial movement member 20 which is moved by the rotation of the rotary shaft 10, the inner diameter surface of the coil (2) ( 2b) can be in close contact or release.

In addition, it is preferable that the contact portion 40 has a curved shape in order to widen the contact area with the inner diameter surface 2b. For example, a cross section of the contact portion 40 may have an arc shape.

In addition, the contact portion 40 may be a combination of divided surfaces having an arc cross section. That is, the contact portion 40 may provide a plurality of divided surfaces in three or four, as well as two divided surfaces in contact with the inner diameter surface 2b of the coil 2. Accordingly, it is preferable that the operation link 30 associated with the dividing surface is further provided corresponding to the number of the dividing surfaces.

The guide part 50 serves to guide the contact part 40 to move in a predetermined direction. As a result, when the contact portion 40 moves in close contact with the inner diameter surface 2b of the coil 2 in connection with the movement of the axial movement member 20, a twist occurs in the contact portion 40, or the contact portion It is possible to prevent the 40 from rotating.

That is, the axial movement member 20 connected to the contact portion 40 through the operation link 30 should not rotate when the rotation shaft 10 rotates, according to the rotation of the rotation shaft 10. The axis of rotation 10 can be moved. By the way, a frictional force may be generated in the screw coupling portion of the rotary shaft 10 and the axial movement member 20, the frictional force may be further increased by the force to buckling the coil (2). Therefore, the axial movement member 20 may be rotated along the rotation shaft 10 by the friction force.

In this case, the contact portion 40 is connected to the axial movement member 20 through the operation link 30 to receive the force that the axial movement member 20 is to rotate. However, since the force received from the contact portion 40 from the axial movement member 20 may vary depending on the magnitude of the frictional force acting on the axial movement member 20, it is pin-connected with the operation link 30 The parts of the contact portion 40 may be different. Thus, the contact portion 40 will be able to receive the twisting force.

However, according to the present invention, the buckling preventing device 1 for hot rolled coils provides the guide part 50 on both sides of the contact part 40, thereby causing the contact part 40 to be unevenly applied to the contact part 40. ) Can be prevented from twisting.

To this end, the guide portion 50 of the buckling preventing device 1 for hot rolled coils according to an embodiment of the present invention, the guide groove 52 is formed, the arm guide member provided on both sides of the contact portion 40 A guide tab 56 inserted into the guide groove 52 of the arm guide member 51 and the arm guide member 51 is formed, and may include a male guide member 55 provided on both sides of the rotation shaft 10.

The arm guide member 51 may be provided to the contact portion 40. In addition, the arm guide member 51 may be provided with a support plate for structural stability corresponding to the torsional force acting on the contact portion 40 through the operation link (30).

In addition, a guide groove 52 to which the guide tab 56 to be described later is inserted and guided may be formed. The guide groove 52 may be formed in the radial direction Y of the rotation shaft 10. This allows the contact portion 40 to move in the radial direction Y of the rotation shaft 10 to the shortest distance to the inner diameter surface 2b of the coil 2 and at the same time as described above. There is an advantage that can prevent the torsion occurs.

In addition, the arm guide member 51 may be formed with a reverse rotation preventing groove 54, which will be described later with reference to FIG.

The male guide member 55 may be provided at both sides of the rotation shaft 10. In addition, it may provide a guide tab 56 that can be inserted into the guide groove 52 to be guided. Since the guide tab 56 may be formed in a shape that can be guided in the guide groove 52, the cross-sectional shape of the guide tab 56 corresponds to the shape of the cross section of the guide groove 52. It is preferable to make a shape. In addition, in order to be inserted into the reverse rotation prevention groove 54 to be described later, it is preferable to have a shape corresponding to the reverse rotation prevention groove 54.

In addition, the buckling prevention device 1 for hot rolled coils according to an embodiment of the present invention is to prevent the rotation of the axial movement member 20 to move on the rotating shaft 10, to the moving hole member 21 It may further include an associated support rod 60. Thereby, the said contact part 40 can be prevented from being bent by torsion. That is, the support rod 60 can also prevent the torsion occurs in the contact portion 40, like the guide portion 50 described above.

In addition, since the diameter of the rotary shaft 10 is smaller than that of the contact portion 40, only the rotary shaft 10 may be structurally disadvantageous to support the contact portion 40, and further includes the support rod 60. By increasing the structural stability of the rotary shaft 10 it is possible to ensure the straightness of the rotary shaft 10.

To this end, the support rod 60 may pass through the support rod coupling hole 21a of the movable hole member 21. As a result, the movable hole member 21 can move along the support rod 60. That is, the moving hole member 21 is able to move along the rotary shaft 10 and at the same time additionally supported and move along the support rod 60.

3 is a side view schematically showing the anti-rotation groove 54 of the buckling preventing device 1 for a hot rolled coil according to an embodiment of the present invention.

Referring to FIG. 3, the guide groove 52 of the buckling preventing apparatus 1 for hot rolled coils according to an embodiment of the present invention is a direction maintaining groove 53 formed in a radial direction Y of the rotation shaft 10. And the guide tab 56 is fitted to be connected to the direction holding groove 53, to prevent the reverse rotation of the rotary shaft 10, the reverse rotation prevention groove formed in the circumferential direction (X) of the rotary shaft ( 54). Thereby, the close contact state of the contact portion 40 in close contact with the inner diameter surface 2b of the coil 2 can be prevented from being unexpectedly released by the reverse rotation of the rotary shaft 10.

The direction maintaining groove 53 guides the contact portion 40 connected to the arm guide member 51 in a predetermined direction and serves to closely contact the inner diameter surface 2b of the coil 2.

Since the direction holding groove 53 is preferably formed in the direction in which the contact portion 40 moves, it is preferable that the direction holding groove 53 is formed in the direction of the rotation shaft 10. As a result, the contact portion 40 can move at the shortest distance for contacting the inner diameter surface 2b of the coil 2. On the other hand, a plurality of direction holding grooves 53 may be formed in the direction of the rotation shaft (10).

The reverse rotation prevention groove 54 serves to prevent the rotation shaft 10 from unexpectedly rotating. That is, the rotation shaft 10 is in close contact with the inner surface (2b) of the coil (2) by the rotation, the contact portion 40 associated with the axial movement member 20 and the operation link (30). By the force acting on the contact surface of the coil 2, the contact portion 40 is pushed in the direction opposite to the direction in close contact with the inner diameter surface 2b of the coil (2). At this time, the rotary shaft 10 is also affected through the operation link 30 and the axial movement member 20 may be reversely rotated. That is, the contact state between the contact portion 40 and the inner diameter surface 2b of the coil 2 may be released unexpectedly. However, in the present invention, it is possible to prevent the reverse rotation of the rotary shaft 10 by providing the reverse rotation preventing groove 54 formed in the circumferential direction of the rotary shaft 10.

The reverse rotation preventing groove 54 is connected to the direction holding groove 53 in the circumferential direction of the rotation shaft 10, a plurality may be formed. This is because the position of the reverse rotation preventing groove 54 into which the guide tab 56 can be inserted is different for each inner diameter of the coil 2.

On the other hand, since the guide tab 56 is inserted into the reverse rotation prevention groove 54 by the rotation of the guide member 55, the reverse rotation prevention groove 54 is preferably formed in an arc shape. .

In addition, in order to insert the guide tab 56 into the reverse rotation preventing groove 54, a drive means for rotating the guide member 55 by a predetermined angle may be connected to the guide member 55. An example may be a motor or a hydraulic cylinder.

4 is a diagram schematically illustrating an operation state of the buckling preventing apparatus 1 for a hot rolled coil according to an exemplary embodiment of the present invention.

Referring to FIG. 4, FIG. 4A illustrates a process in which the buckling preventing device 1 for a hot rolled coil of the present invention is inserted into the inner diameter portion 2a of the coil 2, and FIG. 4B is a hot rolled coil of the present invention inserted therein. The contact portion 40 of the coil buckling preventing device 1 is shown in close contact with the inner diameter surface (2b) of the coil (2) and shows a process, Figure 4c is a partial cutaway side view in the process of Figure 4b It is shown.

The process of inserting the buckling preventing device 1 for the hot rolled coil of the present invention into the inner diameter portion 2a of the coil 2 is a state in which the contact portion 40 approaches the rotation shaft 10 as much as possible. However, if the contact portion 40 can be inserted into the inner diameter portion (2a) of the coil (2) of the present invention even if it does not approach the rotary shaft 10 as much as possible, fit The contact portion 40 may be set in a state in which the rotary shaft 10 is approached.

The contact portion 40 of the hot-rolled coil buckling preventing device 1 of the present invention is in close contact with the inner diameter surface 2b of the coil 2 to support the inner diameter surface 2b of the coil 2 as described above. Starting with the rotation (R) of the rotary shaft 10 is made of a process of bringing the contact portion 40 in close contact with the inner diameter surface (2b) of the coil (2). That is, the rotation shaft 10 is rotated (R) so that the nut hole member 22 screwed with the rotation shaft 10 is moved (M1) and the movement hole member coupled with the nut hole member 22 ( 21 also moves along the nut hole member 22 (M1). In this case, the movable link member 21 and the operation link 30 which is pin-connected with the contact portion 40 are in close contact with the contact portion 40 to the inner diameter surface 2b of the coil 2 by a mechanical structure. Push to operate (M2). Accordingly, the contact portion 40 may be supported to prevent the occurrence of buckling in the coil 2 by applying a force F1 to the inner diameter surface 2b of the coil 2.

In addition, when the rotary shaft 10 is rotated (R), the elongated shape of the operation link 30 is subjected to a torque force (F2) by a large moment, the contact portion 40 associated with the operation link 30 Bend) can be generated. At this time, the guide unit 50 guides and moves the contact portion 40 to M3, thereby generating a force F3 that reacts to the torque force F2 to prevent bending of the contact portion 40. It becomes possible. As described above, the reaction force F3 is generated by the rigidity of the material for maintaining the shape of the guide hole.

1: Buckling prevention device for hot rolled coil 2: Coil
10: rotating shaft 11, 12: split shaft
13: joint member 20: axial movement member
21: moving hole member 22: nut hole member
30: operation link 40: contact
50: guide portion 51: arm guide member
52: guide groove 53: direction holding groove
54: reverse rotation preventing groove 55: the guide member
56: guide tab 57: rotary shaft connecting member
60: support rod

Claims (6)

Inserted into the inner diameter of the hot rolled coil,
A threaded rotating shaft;
An axial moving member provided in a screw combination on the rotating shaft to move on the rotating shaft according to the rotation of the rotating shaft;
An actuating link pinned to said axially movable member;
A contact portion pinned to the operation link to move in close contact with the inner diameter surface of the coil according to the movement of the axial moving member; And
Guide parts provided on both sides of the contact part to move the contact part in a predetermined direction;
Including;
The guide unit,
Guide grooves are formed and arm guide members provided at both sides of the contact portion; And
A guide tab inserted into the guide groove of the arm guide member and provided on both sides of the rotation shaft;
Buckling prevention device for hot rolled coil comprising a. delete The method of claim 1,
The guide groove,
A direction holding groove formed in a radial direction of the rotation shaft; And
A reverse rotation preventing groove formed in the circumferential direction of the rotation shaft, the guide tab being inserted to be connected to the direction holding groove to prevent reverse rotation of the rotation shaft;
Buckling prevention device for hot rolled coil comprising a. The method according to claim 1 or 3,
The rotation shaft
Division axes equal to the number of the on-axis moving members; And
A joint member provided at one end of the division shaft so as to engage each division shaft;
Buckling prevention device for hot rolled coil comprising a. The method according to claim 1 or 3,
The on-axis moving member,
A moving hole member pinned to the operation link; And
A nut hole member provided in the moving hole member;
Including;
Buckling prevention device for a hot rolled coil having a screw bone formed only in the nut hole member. The method of claim 5,
A support rod associated with the moving hole member to prevent the axial movement member from rotating and move on the rotation shaft;
Buckling prevention device for hot rolled coil further comprising.

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