KR102314672B1 - Apparatus for press forming h-beam - Google Patents

Abstract

An H-beam forming apparatus according to the present invention comprises: an apparatus frame; a beam forming unit installed on the apparatus frame and having a lower pressing roll and an upper pressing roll for pressing the end edges of an H-beam in the longitudinal direction; and a roll guide unit for guiding the alignment of the lower pressing roll and the upper pressing roll of the beam forming unit. The H-beam forming apparatus of the present invention can efficiently process edge of an H-beam with high productivity.

Description

H-beam processing equipment {APPARATUS FOR PRESS FORMING H-BEAM}

The present invention is an H-beam processing apparatus, and relates to an H-beam processing apparatus for processing the edge of the H-beam.

The H-beam for shipbuilding equipment does not use the base material as it is, but rounds the edge to improve the painting quality.

If proper shape processing is not performed in the corner, the thickness of the paint in this area becomes thin, and when used for a long period of time, the paint is peeled off from this corner, causing corrosion.

The processing of the edge of the H-beam may use chamfering (Grinding), but may also be made by pressing.

The compression processing is a method of rounding the edge 1a of the H beam 1 as shown in FIG. 1 by pressing the edge of the H beam using a compression roll having a desired rounding (R).

In this method, the operation is simple compared to the chamfering, the operation time is reduced, and it is possible to obtain a uniform rounding shape of the H-beam (1) edge (1a) as a whole.

Currently, for H-beam edge processing, as shown in FIGS. 2 and 3, the lower part (four sides, 4-edge) is machined in the longitudinal direction using the roll 10 with the upper and lower parts separated, and then the H-beam ( The two steps of turning over the base material of 1) and machining the upper part (four sides, 4-edge) in the longitudinal direction are being performed sequentially.

In general, the specifications (Height, Width, Thickness) of the H-beam 1 to be processed by one processing machine are very diverse.

Accordingly, in order to respond to the various thicknesses of the H-beam 1, the processing roll 10 has a form in which the upper and lower portions are separated, and the reason for sequentially processing the upper and lower portions of the H-beam 1 is also This is to process the H-beam 1 of various thicknesses with one processing machine.

However, this work method causes frequent failure and damage of the compression machine due to the non-uniform pressure applied to the rolls separated from the upper and lower parts, and since the H-beam must be processed twice in the upper and lower order, productivity is reduced.

In addition, variations in machining quality occur due to variations in flatness and straightness that occur during H-beam fabrication.

Republic of Korea Patent Publication No. 10-1997-0005504

The present invention has been devised to solve the above problems, and an object of the present invention is to provide an H-beam processing apparatus capable of efficiently and productively processing the edge of the H-beam.

H-beam processing apparatus according to an embodiment of the present invention in order to achieve the above object, the apparatus frame; a beam processing unit installed in the apparatus frame and having a lower pressing roll and an upper pressing roll for pressing and processing the end edge of the H-beam in the longitudinal direction; and a roll guide unit for guiding the alignment of the lower compression roll and the upper compression roll of the beam processing unit.

Specifically, the beam processing unit, the lower pressing roll for pressing the lower edge of the H-beam; The upper compression roll is disposed on the upper side of the lower compression roll to compress the upper edge of the H-beam; and a roll driving member installed on the device frame to pivotally rotate each of the lower compression roll and the upper compression roll, wherein each of the lower compression roll and the upper compression roll has an end edge of the H-beam inserted vertically A vertical groove may be formed.

Here, the plurality of vertical grooves may be formed in each of the lower compression roll and the upper compression roll, and the plurality of vertical grooves may have different groove sizes.

In addition, two of the lower compression rolls are mounted on the lower rotation shaft, the two upper compression rolls are mounted on the upper rotation shaft, and the two lower compression rolls are movable in the axial direction on the lower rotation shaft, and the two upper compression rolls are movable in the axial direction. The compression roll may be movable in an axial direction on the upper rotational shaft.

In this case, the two lower compression rolls may be keyed to the lower rotation shaft and pivotally rotated at the same time, and the two upper compression rolls may be keyed to the upper rotation shaft and rotated simultaneously.

In addition, the upper compression roll may be configured to be raised and lowered.

Specifically, two of the lower compression rolls are mounted on the lower rotation shaft, the two upper compression rolls are mounted on the upper rotation shaft, and the device frame includes: a base frame that is seated and supported on the floor; a lower frame installed on the base frame and mounted to rotate the lower rotating shaft; and an upper frame having one end rotatably installed on the upper portion of the lower frame, and an upper frame on which the upper rotating shaft is axially mounted, a cylinder body is rotatably installed on the base frame, and a cylinder rod is installed at the other end of the upper frame The upper compression roll may be raised and lowered while the upper frame rotates based on one end of the cylinder rod when the cylinder rod is expanded and contracted.

On the other hand, the roll guide unit, a lower alignment guide for aligning the lower compression roll; and an upper alignment guide for aligning the upper compression roll.

Specifically, the lower alignment guide is disposed on the lower side of the lower compression roll, a lower roll alignment groove into which the lower compression roll is inserted is formed on the upper surface, and the upper alignment guide is disposed above the upper compression roll, An upper roll alignment groove into which the upper compression roll is inserted is formed on a lower surface of the roll guide unit, and the roll guide unit is installed in the apparatus frame and further includes a roll elevating member for elevating each of the lower alignment guide and the upper alignment guide. , lower inclined portions are formed on both inner side surfaces of the lower roll alignment groove so that when the lower alignment guide is raised toward the lower compression roll by the roll lifting member, the lower compression roll is pushed toward the center while being light chained, the roll lifting and lowering parts are formed. Upper inclined portions may be formed on both inner side surfaces of the upper roll alignment groove so that when the upper alignment guide is lowered toward the upper compression roll by a member, the upper compression roll is pushed toward the center while being light chained.

At this time, two lower roll alignment grooves are formed in the lower alignment guide to correspond to the two lower compression rolls, and two upper roll alignment grooves are formed in the upper alignment guide to correspond to the two upper compression rolls. can be

Meanwhile, the present invention may further include a beam centering unit disposed at the front end of the beam processing unit and configured to center the H-beam.

Specifically, the beam centering unit, one side centering member for pushing one side of the H-beam; a centering member for pushing the other side of the H-beam; and a centering driving member for reciprocating each of the one centering member and the other centering member toward the H-beam.

As an example, when the one centering member is moved to the H-beam side and stopped, the centering driving member may be controlled so that the other centering member pushes the H-beam to the one centering member.

In addition, each of the centering member on one side and the centering member on the other side may be equipped with a roller at an end of the H-beam side.

The H-beam processing apparatus according to the present invention comprises a beam processing unit having a lower pressing roll and an upper pressing roll for crimping the end edge of the H-beam in a round manner, and each of the lower pressing roll and the upper pressing roll is It has two vertical grooves and is movable in the lateral direction and at the same time the upper compression roll is raised and lowered, so that it can be structurally adjusted to correspond to the various thicknesses, widths, and heights of the H-beams according to the H-beams of various standards. of H-beam can be processed by one device, which has the effect of improving productivity.

In addition, the present invention is composed of a roll guide unit for guiding the alignment of the lower compression roll and the upper compression roll of the beam processing unit, so that even if the positions of the lower compression roll and the upper compression roll are changed during the processing of the H beam, the lower compression roll By automatically aligning the upper and upper compression rolls to their initial positions, it has the advantage of stable and accurate H-beam processing.

And, according to the present invention, the beam centering unit for centering the H-beam is configured, thereby accurately centering the H-beam toward the beam processing unit and entering it, and thus has the advantage of being able to perform stable and accurate H-beam processing.

1 is a view showing an H-beam press-processed so that the end edge is rounded.
2 and 3 are views showing an H-beam processing apparatus according to the prior art.
4 is a view showing that the end edge of the H-beam is processed by the H-beam processing apparatus according to the present invention.
FIG. 5 is a view showing that the two upper compression rolls and the two lower compression rolls are transversely moved in the H-beam processing apparatus of FIG. 4 .
6 and 7 are views showing that the upper compression roll is raised and lowered in the H-beam processing apparatus.
8 is a view showing a roll guide unit for guiding the alignment of the lower compression roll and the upper compression roll in the H-beam processing apparatus according to the present invention.
9 and 10 are views showing a longitudinal cross-section of the roll guide unit of FIG.
11 is a view showing a beam centering unit for centering the H-beam in the H-beam processing apparatus according to the present invention.

Hereinafter, it will be described in detail with reference to exemplary drawings of the present invention. Note that in adding reference numerals to the components of each drawing, the same components are given the same reference numerals as much as possible even though they are indicated on different drawings. In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

4 is a view showing that the end edge of the H-beam is processed by the H-beam processing apparatus according to the present invention, FIG. 5 is the H-beam processing apparatus of FIG. It is a view showing the movement, and FIGS. 6 and 7 are views showing that the upper compression roll is raised and lowered in the H-beam processing apparatus.

Referring to the drawings, the H-beam processing apparatus according to the present invention includes an apparatus frame 100 , a beam processing unit 200 , and a roll guide unit 300 .

Here, the apparatus frame 100 is a member for supporting the beam processing unit 200 and the roll guide unit 300, and can stably support the beam processing unit 200 and the roll guide unit 300 in an appropriate arrangement. Of course, the specific structure is not limited by the present invention if it is configured to be able to.

In addition, the beam processing unit 200 is installed in the apparatus frame 100, it is configured to press the end edge of the H-beam (1) in the longitudinal direction to round.

Specifically, the beam processing unit 200 may include a lower compression roll 210, an upper compression roll 220, and a roll driving member (M).

At this time, the lower pressing roll 210 is configured to press the lower end edge of the H-beam (1).

In addition, the upper pressing roll 220 is configured to press the upper edge of the H-beam (1).

And, the roll driving member (M) is installed in the device frame 100, is configured to rotate the lower compression roll 210 and the upper compression roll 220, respectively.

Here, each of the lower compression roll 210 and the upper compression roll 220 may be formed with a vertical groove G into which an end edge of the H-beam 1 is vertically inserted.

Due to such a lower compression roll 210 and an upper compression roll 220, the present invention rapidly processes the edge of the H-beam (1) by pressing the edges of the lower and upper ends of the H-beam (1) at the same time. It can be processed, and by processing the end edge of the H-beam 1 while pressing it from the vertical side instead of the horizontal side, it is possible to process the end edge of the H-beam 1 stably and easily.

More specifically, a plurality of vertical grooves G may be formed in each of the lower compression roll 210 and the upper compression roll 220 , and each of the plurality of vertical grooves G may have different groove sizes. .

In general, the H-beam 1 has a wide variety of specifications, and the thickness of the end edge of the H-beam 1 also varies according to these various specifications.

As described above, in order to correspond to the various thicknesses of the end edges according to the standard of the H-beam (1), the present invention may have a plurality of vertical grooves (G) formed in each of the lower compression roll 210 and the upper compression roll 220. have.

In addition, two of the lower compression rolls 210 may be mounted on the lower rotation shaft 211 , and two of the upper compression rolls 220 may be mounted on the upper rotation shaft 221 .

Here, the two lower compression rolls 210 are movable in the axial direction on the lower rotation shaft 211 , and the two upper compression rolls 220 are movable in the axial direction on the upper rotation shaft 221 . .

According to the specifications of the various H-beams 1, the widths of the H-beams 1 (the length in the width direction in the drawing) also vary.

In order to respond to various widths according to the standard of the H-beam 1, the present invention has two lower compression rolls 210 moving in the axial direction on a lower rotation shaft 211, and two upper compression rolls 220. may have a structure that moves in the axial direction on the upper rotation shaft 221 .

That is, the lower compression roll 210 has a structure in which the lower rotation shaft 211 is penetrated, and the upper compression roll 220 has a structure in which the upper rotation shaft 221 is penetrated. By moving the two lower compression rolls 210 to adjust the separation distance for the two lower compression rolls 210, by moving the two upper compression rolls 220, the separation distance for the two upper compression rolls 220 can be adjusted.

At this time, the two lower compression rolls 210 are keyed to the lower rotation shaft 211 and rotated at the same time, and the two upper compression rolls 220 are keyed to the upper rotation shaft 221 and rotated simultaneously.

As an example, a key K protruding from each of the lower rotary shaft 211 and the upper rotary shaft 221 is formed, and a key groove corresponding to the key K is formed in each of the lower compression roll 210 and the upper compression roll 220 . By forming this, it is possible to achieve a key fastening structure.

In this way, the two lower compression rolls 210 rotate at the same time, and the two upper compression rolls 220 simultaneously rotate, thereby compressing the end edge of the H-beam 1 with the same and uniform force along the longitudinal direction. go and know

On the other hand, the upper compression roll 220 may be configured to be lifted.

According to the specifications of the various H-beams 1, the heights (longitudinal lengths in the drawing) of the H-beams 1 also vary.

In order to respond to the various heights according to the standard of the H-beam 1 , the present invention may be configured such that the upper compression roll 220 is raised and lowered in a state in which the lower compression roll 210 has a fixed height structure.

Specifically, the device frame 100 may include a base frame 110 , a lower frame 120 , and an upper frame 130 .

Here, the base frame 110 is a member that is seated and supported on the floor.

In addition, the lower frame 120 is installed on the upper portion of the base frame 110, the lower rotating shaft 211 is mounted to rotate.

In addition, one end of the upper frame 130 is rotatably installed on the upper portion of the lower frame 120 , and the upper rotating shaft 221 is rotatably mounted.

And, the present invention may further include a lifting cylinder (C).

At this time, the lifting cylinder (C) is installed so that the cylinder body is rotated on the base frame (110), and the cylinder rod is installed to rotate at the other end of the upper frame (130).

Accordingly, when the cylinder rod of the elevating cylinder (C) is expanded and contracted, the upper frame 130 rotates based on one end and the upper compression roll 220 can be raised and lowered.

8 is a view showing a roll guide unit guiding the alignment of the lower compression roll and the upper compression roll in the H-beam processing apparatus according to the present invention, and FIGS. 9 and 10 are views showing a longitudinal section of the roll guide unit of FIG. .

Referring to the drawings, the H-beam processing apparatus according to the present invention may further include a roll guide unit 300 .

The roll guide unit 300 serves to guide the alignment of the lower compression roll 210 and the upper compression roll 220 .

The H-beam (1 in FIG. 6) is manufactured so that the edge of the end is formed in a straight line in the longitudinal direction, but it may take a structure in which a part is bent or bent during the manufacturing process or in the transport process.

In this way, when the lower compression roll 210 and the upper compression roll 220 process the H-beam with a partially deformed shape, the positions may be changed to a certain extent depending on the deformation of the edge of the H-beam during the machining process. In this case, the following In order to process the H-beam inserted between the lower compression roll 210 and the upper compression roll 220 in turn, as the operator has to adjust the lower compression roll 210 and the upper compression roll 220 to their initial positions, It is inefficient in terms of labor load and time.

In order to overcome this point, in the present invention, the roll guide unit 300 for guiding alignment with respect to the lower compression roll 210 and the upper compression roll 220 is configured.

Specifically, the roll guide unit 300 may include a lower alignment guide 310 and an upper alignment guide 320 .

Here, the lower alignment guide 310 is configured to align the lower compression roll 210 .

In addition, the upper alignment guide is configured to align the upper compression roll 220 .

The lower alignment guide 310 may be disposed on the lower side of the lower compression roll 210 , and a lower roll alignment groove 311 into which the lower compression roll 210 is inserted may be formed on the upper surface of the lower alignment guide 310 .

In addition, the upper alignment guide 320 may be disposed on the upper side of the upper compression roll 220, the upper roll alignment groove 321 into which the upper compression roll 220 is inserted may be formed on the lower surface.

In addition, the roll guide unit 300 may further include a roll elevating member, although not shown in the drawings.

At this time, the roll elevating member is installed in the device frame 100 and serves to elevate each of the lower alignment guide 310 and the upper alignment guide 320 .

More specifically, when the lower alignment guide 310 is raised toward the lower compression roll 210 by the roll elevating member, the lower compression roll 210 is pushed toward the center as the light chain slides inside the lower roll alignment groove 311. Lower inclined portions 311a may be formed on both sides.

That is, when the lower alignment guide 310 rises toward the lower compression roll 210, the lower inclined portions 311a formed on both inner side surfaces of the lower roll alignment groove 311 also rise. By sliding along the inclined surface of the lower inclined portion 311a by the lower inclined portion 311a that continuously rises while in contact with the lower inclined portion 311a, the lower inclined portion 311a is pushed toward the center, so that it can be aligned to the initial position.

In addition, when the upper alignment guide 320 is lowered toward the upper compression roll 220 by the roll elevating member, the upper compression roll 220 is pushed toward the center while being light chained. On both inner side surfaces of the upper roll alignment groove 321 An upper inclined portion 321a may be formed.

That is, when the upper alignment guide 320 descends toward the upper compression roll 220, the upper inclined portions 321a formed on both inner side surfaces of the upper roll alignment groove 321 also rise. By sliding along the inclined surface of the upper inclined portion 321a by the upper inclined portion 321a that continuously descends while in contact with the upper inclined portion 321a, the upper inclined portion 321a is pushed toward the center, so that it can be aligned to the initial position.

At this time, two of the lower roll alignment grooves 311 are formed in the lower alignment guide 310 to correspond to the two lower compression rolls 210, and the upper roll alignment groove 321 includes the two upper compression rolls ( 220) and two corresponding to the upper alignment guide 320 may be formed.

11 is a view showing a beam centering unit for centering the H-beam in the H-beam processing apparatus according to the present invention.

Referring to the drawings, the H-beam processing apparatus according to the present invention may further include a beam centering unit 400 .

The beam centering unit 400 may be arranged at the front end of the beam processing unit 200 and configured to center the H-beam (1).

Specifically, the beam centering unit 400 may include a centering member 410 on one side, a centering member 420 on the other side, and a centering driving member (not shown).

Here, the one side centering member 410 serves to push one side of the H-beam (1).

In addition, the other side centering member 420 serves to push the other side of the H-beam (1).

In addition, although not shown in the drawing, the centering driving member provides a driving force to reciprocate each of the one centering member 410 and the other centering member 420 toward the H-beam 1 side.

In the beam centering unit 400 configured as described above, when one centering member 410 is moved to the H-beam 1 and stopped, the other centering member 420 pushes the H-beam 1 to one centering member 410. The centering driving member may be controlled to operate.

For reference, the one side described above refers to one lateral direction, and the other side in contrast to this refers to the opposite lateral direction of the one side, and does not refer to a specific lateral direction except in lateral directions opposite to each other.

Furthermore, each of the one centering member 410 and the other centering member 420 may be equipped with a roller R at an end of the H-beam 1 side.

That is, each of the centering member 410 and the centering member 420 on the other side is equipped with a roller (R) in a portion in contact with the H-beam (1) so as to cause rolling friction when in contact with the H-beam (1), so that the H-beam ( The side of 1) can be prevented from being damaged by friction.

As a result, the H-beam processing apparatus according to the present invention is a beam processing unit 200 having a lower pressing roll 210 and an upper pressing roll 220 for crimping the end edge of the H-beam 1 in a round manner in the longitudinal direction. This is configured, and each of the lower compression roll 210 and the upper compression roll 220 has a plurality of vertical grooves G and is movable in the lateral direction and at the same time the upper compression roll 220 is raised and lowered. As it is structurally adjustable to correspond to various thicknesses, widths, and heights of the H-beam 1 according to the H-beam 1 of can improve

In addition, in the present invention, the roll guide unit 300 for guiding the alignment with respect to the lower compression roll 210 and the upper compression roll 220 of the beam processing unit 200 is configured, so that in the processing of the H-beam (1) Even if the positions of the lower compression roll 210 and the upper compression roll 220 are changed, the lower compression roll 210 and the upper compression roll 220 are automatically aligned to their initial positions, resulting in a stable and accurate H-beam (1) processing can be done.

And, according to the present invention, the beam centering unit 400 for centering the H-beam 1 is configured, thereby accurately centering the H-beam 1 toward the beam processing unit 200 and entering the H-beam ( 1) It can be processed.

As described above, although the present invention has been described with reference to limited embodiments and drawings, the present invention is not limited thereto, and the technical idea of the present invention and the following by those of ordinary skill in the art to which the present invention pertains. Of course, various modifications and variations are possible within the scope of equivalents of the claims to be described.

1: H beam
100: device frame 110: base frame
120: lower frame 130: upper frame
C: Elevating cylinder
200: beam processing unit 210: lower compression roll
211: lower rotary shaft 220: upper compression roll
221: upper rotation shaft M: roll driving member
K: key
300: roll guide unit 310: lower alignment guide
311: lower roll alignment groove 311a: lower inclined portion
320: upper alignment guide 321: upper roll alignment groove
321a: upper inclined part
400: beam centering unit 410: one side centering member
420: centering member on the other side R: roller

Claims (14)

device frame;
a beam processing unit installed in the apparatus frame and having a lower pressing roll and an upper pressing roll for pressing and processing the end edge of the H-beam in the longitudinal direction; and
It includes; a roll guide unit for guiding the alignment with respect to the lower compression roll and the upper compression roll of the beam processing unit;
The beam processing unit,
The lower compression roll for pressing the lower edge of the H-beam;
The upper compression roll is disposed on the upper side of the lower compression roll to compress the upper edge of the H-beam; and
and a roll driving member installed on the device frame and rotating each of the lower and upper compression rolls axially;
Each of the lower compression roll and the upper compression roll is formed with a vertical groove into which the end edge of the H-beam is vertically inserted,
The roll guide unit,
a lower alignment guide for aligning the lower compression roll; and
and an upper alignment guide for aligning the upper compression roll;
The lower alignment guide is disposed on the lower side of the lower compression roll, and a lower roll alignment groove into which the lower compression roll is inserted is formed on the upper surface,
The upper alignment guide is disposed on the upper side of the upper compression roll, and an upper roll alignment groove into which the upper compression roll is inserted is formed on a lower surface thereof,
The roll guide unit,
It further includes; a roll elevating member installed on the device frame and elevating each of the lower alignment guide and the upper alignment guide,
When the lower alignment guide is raised toward the lower compression roll by the roll elevating member, lower inclined portions are formed on both inner side surfaces of the lower roll alignment groove so that the lower compression roll is pushed toward the center while being light chained,
When the upper alignment guide is lowered toward the upper compression roll by the roll elevating member, the upper compression roll is pushed toward the center while being light chained. H-beam, characterized in that upper inclined portions are formed on both inner side surfaces of the upper roll alignment groove processing equipment.
delete According to claim 1,
A plurality of vertical grooves are formed in each of the lower compression roll and the upper compression roll,
Each of the plurality of vertical grooves H-beam processing apparatus, characterized in that the groove size is different from each other.
According to claim 1,
Two of the lower compression rolls are mounted on the lower rotation shaft, and two of the upper compression rolls are mounted on the upper rotation shaft,
The two lower compression rolls are movable in the axial direction on the lower rotation shaft, and the two upper compression rolls are movable in the axial direction on the upper rotation shaft.
5. The method of claim 4,
The two lower compression rolls are keyed to the lower rotating shaft and pivotally rotated at the same time, and the two upper compression rolls are keyed to the upper rotating shaft and pivotally rotated at the same time.
According to claim 1,
The upper compression roll H-beam processing apparatus, characterized in that configured to be lifted.
7. The method of claim 6,
Two of the lower compression rolls are mounted on the lower rotation shaft, and two of the upper compression rolls are mounted on the upper rotation shaft,
The device frame,
a base frame supported by being seated on the floor;
a lower frame installed on the base frame and mounted to rotate the lower rotating shaft; and
An upper frame having one end installed to be rotated on the upper portion of the lower frame, and an upper frame on which the upper rotating shaft is axially rotated; and
The cylinder body is installed to rotate on the base frame and the cylinder rod is installed to rotate at the other end of the upper frame; further including,
H-beam processing apparatus, characterized in that the upper compression roll is raised and lowered while the upper frame rotates based on one end when the cylinder rod is expanded and contracted.
delete delete According to claim 1,
Two of the lower compression rolls are mounted on the lower rotation shaft, and two of the upper compression rolls are mounted on the upper rotation shaft,
Two of the lower roll alignment grooves are formed in the lower alignment guide to correspond to the two lower compression rolls, and two upper roll alignment grooves are formed in the upper alignment guide to correspond to the two upper compression rolls. H-beam processing equipment with
According to claim 1,
a beam centering unit disposed at the front end of the beam processing unit and configured to center the H-beam;
H-beam processing apparatus further comprising a.
12. The method of claim 11,
The beam centering unit,
a centering member for pushing one side of the H-beam;
a centering member for pushing the other side of the H-beam; and
a centering driving member for reciprocating each of the one centering member and the other centering member toward the H-beam;
H-beam processing apparatus comprising a.
13. The method of claim 12,
When the one centering member is moved to the H-beam side and stopped, the centering driving member is operated and controlled so that the other centering member pushes the H-beam to the one centering member.
13. The method of claim 12,
Each of the centering member on one side and the centering member on the other side, H-beam processing apparatus, characterized in that the roller is mounted on the end of the H-beam side.

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