KR102437236B1 - Non-welded exterior panel system with anti-shock - Google Patents

Abstract

The present invention relates to an earthquake-resistant non-welded exterior panel system. The earthquake-resistant non-welded exterior panel system is installed on an external wall of a building. The earthquake-resistant non-welded exterior panel system includes: a support frame; at least a rotation fixing-type bolt; exterior members formed in a board shape and arranged to be adjacent to each other on the support frame, wherein the exterior member has an insertion groove individually formed on surfaces facing each other; and an earthquake-resistant bracket. The support frame includes: a first frame formed to be lengthwise in a transverse direction; and a second frame arranged to be lengthwise in a longitudinal direction to cross the first frame, and having a cutting groove in the longitudinal direction; and a connection bracket connecting the first frame and the second frame. The rotation fixing-type bolt includes: a rotation insertion unit connected to the second frame by being inserted into the cutting groove; and a central screw unit formed to be extended from the rotation insertion unit and exposed in the cutting groove to the outside. The earthquake-resistant bracket includes: a coupling unit connected to the second frame by being coupled to the rotation fixing-type bolt to couple the exterior member to the support frame; and an insertion rib connected to the coupling unit, wherein both sides of the insertion rib are individually inserted into the insertion groove of the exterior member. A purpose of the present invention is to provide the earthquake-resistant non-welded exterior panel system capable of remarkably reducing construction costs and construction time.

Description

Non-welded exterior panel system with anti-shock

The present invention relates to an earthquake-resistant non-welded exterior panel system, and more particularly, to absorb vibrations in the event of an earthquake or strong wind to prevent damage and fall of exterior materials, increase work (construction) efficiency, and build a building only with its own structure It relates to a seismic non-welded exterior panel system with an improved structure so that it can be installed in the

In general, exterior panels (finishing panels), which are often used as interior and exterior finishing materials for buildings, are manufactured in a square flat plate and are usually arranged in a grid form in parallel with the wall of the building. Exterior panels are made of tile, terracotta, surrogate, aluminum flat panel, etc. The exterior panels arranged in this way are installed to be spaced apart from other exterior panels adjacent to the top, bottom, left and right at regular intervals so as to cope with deformation caused by external environmental factors.

For high-rise large-scale complex buildings, structural stability due to increased self-weight and weight reduction of the envelope system for reducing self-weight are essential. A metal panel such as a panel or galvanized steel sheet is used as an exterior panel.

The construction of such an exterior panel is performed by first fixing a square pipe-shaped steel structure to the outside of the wall of a building in a grid form, and then fixing the exterior panel to the steel structure. The construction method of the exterior panel is largely divided into a welding construction method and a non-welding construction method. Welding construction method, of course, welding itself is very inconvenient, and when the vertical or horizontal alignment of the exterior panel does not fit properly, it has a great inconvenience of having to tear off all the welded parts and re-weld. Due to these problems, the number of cases in which an exterior panel is installed by applying a non-welding construction method is gradually increasing in recent years.

The conventional exterior panel system installed in this way has a problem in that the risk of fire generated during welding is high, and the exterior panel (exterior material) is separated from the steel structure or the exterior panel is damaged when an earthquake or strong wind occurs. , it requires a separate construction device for the construction of the exterior panel, and has a problem that requires a long construction time.

As a prior art, there is Korean Patent Publication No. 10-1847827.

The present invention has been devised to solve the above problems, and an object of the present invention is to absorb vibration when an earthquake or strong wind occurs to prevent damage and fall of exterior materials, and to provide a welding device for installation in a building and It is intended to provide an earthquake-resistant non-welded exterior panel system that enables installation with its own structure without requiring welding experts, eliminates the risk of fire during welding, and significantly reduces construction costs and construction time.

The problems to be solved of the present invention are not limited to those mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

The seismic non-welded exterior panel system according to the present invention for achieving the above object is provided on the outer wall of a building, and a first frame having a length in the lateral direction and formed elongated, and having a length in the longitudinal direction, the first frame and a support frame having a second frame disposed to cross and forming a cut-out groove along the longitudinal direction, and a coupling bracket for coupling the first frame and the second frame; at least one rotationally fixed bolt having a rotation insertion part inserted into the cut-out groove and connected to the second frame, and a central screw part extending from the rotation insertion part and exposed to the outside in the cut-out groove; an exterior material formed in the form of a plate and disposed adjacent to each other on the support frame in plurality and forming fitting grooves on surfaces facing each other; and a fastening part connected to the second frame by being fastened with the rotationally fixed bolt so as to fasten the exterior material to the support frame, and a fitting rib connected to the fastening part and having both sides fitted into the fitting groove of the exterior material. It comprises a; earthquake-resistant bracket having a.

The earthquake-resistant bracket may include: a bent portion bent at an end of the fastening portion to extend outwardly of the second frame; and a protrusion extending from an end of the bent portion, protruding between one of the exterior materials and the other exterior material, and connected to the fitting rib.

The protrusion may form an inlet groove through which the other exterior material is introduced between one side of the fitting rib and the bent part so that the one exterior material and the other exterior material may be positioned adjacently.

The second frame defines the cut-out groove and forms a locking protrusion on which the rotary insertion part is caught, so that the rotation insertion part inserted into the cut-out groove and the second frame can be maintained in a coupled state, and the central screw part It is preferable to include a separation prevention rib that forms an exposed exposure slit.

The rotational insertion part of the rotationally fixed bolt has a width smaller than the width of the exposure slit, is formed long along the cutout groove, has a length corresponding to the inner width of the cutout groove, and both ends are rounded. As such, it is preferable that the both ends are press-fitted into the incision groove when it is rotated while being inserted into the incision groove through the exposure slit.

The central screw portion of the rotation-fixed bolt sequentially passes through a fastening portion of the seismic bracket and one surface of the coupling bracket in contact with the cut-out groove of the second frame and is coupled with a nut, thereby fastening the support frame, the earthquake-resistant bracket and the exterior material to each other. can also do

The separation prevention rib preferably forms an inclined portion inclined toward the inside of the cutout groove.

The rotational insertion part of the rotationally fixed bolt has a width smaller than the width of the exposure slit and is formed long along the incision groove, is made in the form of a groove having a structure surrounding the central screw part, and is an inclined contact surface in contact with the inclined part By having the formed inclined groove portion, it is possible to introduce the inclined portion into the inclined groove portion when it is rotated while being inserted into the cutout groove through the exposure slit.

In the earthquake-resistant non-welding exterior panel system according to the present invention having the configuration as described above, the first frame and the second frame of the support frame are coupled to each other by a coupling bracket, and the rotational insertion part of the rotational fixing bolt is cut out of the second frame The position is fixed while being inserted into the groove, and the central screw part is exposed to the outside in the cut-out groove and is fastened to the coupling bracket. The fastening part of the bracket is fastened with the rotation fixing bolt and connected to the second frame, and the fitting rib is connected to the fastening part, and both sides are fitted into the fitting groove of the exterior material. It is possible to install exterior materials in a building only with its own structure without requiring welding equipment and welding specialists for installation in a building, and has the effect of eliminating the risk of fire during welding and remarkably reducing the construction cost and construction time. have

Effects of the present invention are not limited to those mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the following description.

1 is a view for explaining a state in which the earthquake-resistant non-welded exterior panel system is attached to a building according to an embodiment of the present invention.
2 and 3 are views for explaining the support frame, rotation-fixed bolts and earthquake-resistant brackets employed in an embodiment of the present invention.
Figure 4 is a view for explaining in more detail the earthquake-resistant bracket and rotation-fixed bolts and coupling brackets employed in an embodiment of the present invention.
5 is a view for explaining the structure of the fixed rotation bolt and the coupling relationship between the rotation fixed bolt and the support frame employed in an embodiment of the present invention.
6 is a view for explaining the coupling relationship between the earthquake-resistant bracket and the exterior material employed in an embodiment of the present invention.
7 is a view for sequentially explaining a process in which the exterior material employed in an embodiment of the present invention is fastened to the support frame by the earthquake-resistant bracket.
8 is a view for explaining a support frame and a rotation fixing bolt employed in the earthquake-resistant non-welding exterior panel system according to another embodiment of the present invention.

Hereinafter, an earthquake-resistant non-welding exterior panel system according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a view for explaining a state in which a seismic non-welded exterior panel system according to an embodiment of the present invention is attached to a building, and FIGS. 2 and 3 are a support frame and a rotation-fixed bolt and It is a view to explain the earthquake-resistant bracket, and Figure 4 is a view for explaining in more detail the earthquake-resistant bracket, rotation-fixed bolt and coupling bracket employed in an embodiment of the present invention, Figure 5 is a rotation adopted in an embodiment of the present invention It is a view for explaining the structure of the fixed bolt and the coupling relationship between the rotation and fixed bolt and the support frame, FIG. 6 is a view for explaining the coupling relationship between the earthquake-resistant bracket and the exterior material employed in an embodiment of the present invention, FIG. It is a view for sequentially explaining a process in which the exterior material employed in an embodiment of the present invention is fastened to the support frame by the earthquake-resistant bracket.

As shown in these drawings, the non-welded exterior panel system according to an embodiment of the present invention includes a support frame 100 , a rotation-fixing bolt 200 , an exterior material 300 , and an earthquake-resistant bracket 400 .

The support frame 100 is installed on the exterior wall of the building by a bolt coupling method, etc. and fastened to the exterior material 300 , so that the exterior wall of the building can be constructed with the exterior material. The support frame 100 includes a first frame 110 and a second frame 120 and includes a coupling bracket 130 for coupling the first frame 110 and the second frame 120 to each other.

The first frame 110 of the support frame 100 has a length in the transverse direction and is formed to be long, and a cut-out groove H1 is formed therein along the longitudinal direction, and the second frame 120 and the coupling bracket are formed. (130). The first frame 110 is preferably made of an aluminum material having corrosion resistance, etc., and at least one of the rotation fixing bolts is inserted into the cut-out groove H1 so that it can be positioned.

On the other hand, the first frame 110 may be fastened to the coupling bracket 130 by a screw coupling method without forming a cut-out groove H1 and without a rotation fixing bolt, and the second frame 110 by the coupling bracket 130 It may be combined with the frame 120 . In this embodiment, the first frame 110 forms a cut-out groove H1 like the second frame 120, and the rotation fixing bolt is inserted into the cut-out groove.

The second frame 120 of the support frame 100 is disposed on the outer wall of the building, has a length in the longitudinal direction, is disposed to cross the first frame 110, and forms a cut-out groove H2 along the length direction. do. The second frame 120 is connected to the second frame 120 in a state in which the rotation-fixing bolt 200 is inserted into the cutout groove H2 of the second frame 120 , and is fastened with the coupling bracket 130 , so that the first frame (110) and the second frame 120 to be coupled to each other.

The coupling bracket 130 provided in the support frame 100 has one side positioned on the first frame 110 and any one rotational fixed type inserted into the cutout groove H1 of the first frame 110 . It is fastened with the bolt 200 . In addition, the other side of the coupling bracket 130 is located in the second frame 120 and is fastened with the other rotation fixing bolt 200 inserted into the cutout groove H2 of the second frame 120 . For this reason, the coupling bracket 130 connects the first frame 110 and the second frame 120 to cross each other.

As described above, the rotation-fixed bolt 200 is inserted into the cutout grooves H1 and H2 respectively formed in the first frame 110 and the second frame 120 and fixed, and then the coupling bracket 130 . By being fastened to one side and the other side of the, the first frame 110 and the second frame 120 are stably coupled.

The rotation-fixed bolt 200 includes a rotation insertion portion 210 and a central screw portion 220 . The rotation insertion part 210 of the rotation fixing bolt 200 is inserted into the cutout groove of the second frame 120 and is connected to the second frame. In addition, the central screw part 220 is formed extending from the rotation insertion part and exposed to the outside in the cut-out groove H2 to be coupled to the coupling bracket 130 and the earthquake-resistant bracket 400 . The rotation fixed bolt 200 and The fastening method between the first frames 110 is the same as the fastening method between the second frames described above.

The rotation-fixed bolt 200 is fixed to the support frame 100 in such a way that it is inserted into the support frame 100 and is fastened with the coupling bracket 130 to realize the support frame 100 , so that the support frame 100 is implemented by a welding method. It lowers the risk of fire, eliminates the need for a separate bonding device and professional manpower for welding, significantly lowers work (construction) time and work cost, and increases efficiency in terms of maintenance and repair.

The exterior material 300 is formed in a plate shape and is disposed adjacent to each other on the support frame in plurality, and fitting grooves 310 are respectively formed on the surfaces facing each other. The exterior material 300 may be made of various materials, but is preferably made of a lightweight aluminum material having corrosion resistance. In addition, the exterior material 300 may be made of various colors, and may be provided with various surface treatment layers to prevent corrosion or provide colors to the outside.

The earthquake-resistant bracket 400 is combined with a coupling bracket 130 for coupling the first frame 110 and the second frame 120 to each other and the rotation-fixed bolt 200 fastened to any one of the exterior materials 300 and The other exterior materials are connected to each other and at the same time the exterior material 300 is connected to the support frame 100 .

The earthquake-resistant bracket 400 includes a fastening part 410 and a fitting rib 420 . The fastening part 410 of the earthquake-resistant bracket 400 is located on the outside of the second frame 120 and is fastened with the rotation fixing bolt 200 to be connected to the second frame 120 . In addition, the fitting rib 420 of the earthquake-resistant bracket 400 is connected to the fastening part 410 and is located in the space between the first frame 110 and the second frame 120 facing each other, so that each By fitting both sides into the fitting groove 310 , it is possible to fasten the exterior material 300 to the support frame 100 .

In the earthquake-resistant non-welding exterior panel system according to an embodiment of the present invention having such a configuration, the first frame 110 and the second frame 120 of the support frame 100 are coupled to each other by a coupling bracket 130 and , the rotational insertion part 210 of the rotationally fixed bolt 200 is fixed in a state inserted into the cut-out groove H2 of the second frame 120, and the central screw part 220 is exposed to the outside in the cut-out groove, so that the coupling bracket It is fastened with 130 , and a plurality of exterior materials 300 are disposed adjacent to each other on the support frame 100 , respectively, to form fitting grooves 310 on the surfaces facing each other, and the fastening part 410 of the earthquake-resistant bracket 400 . ) is fastened with the rotation fixing bolt 200 and connected to the second frame 120 , the fitting rib 420 is connected to the fastening part 410 , and both sides are fitted into the fitting groove 310 of the exterior material 300 , respectively. As a result, it absorbs vibrations in the event of an earthquake or strong wind to prevent damage and fall of the exterior material. It has the effect of eliminating the risk of fire and remarkably reducing the construction cost and construction time.

On the other hand, it is preferable that the second frame 120 employed in this embodiment further includes a separation preventing rib 121 .

The separation prevention rib 121 defines the cut-out groove H2 of the second frame 120 and is formed to protrude from the cut-out groove H2 in a direction facing each other, and the rotation fixing bolt 200 is exposed. By forming an exposure slit (S) and forming a locking jaw on which the rotation insertion part 210 is caught, the rotation insertion part 210 of the rotation-fixed bolt inserted into the cut-out groove H2 becomes the second frame 120 ) to prevent separation from the separation, and to maintain a coupled state between the rotating insert 210 and the second frame 120 .

The separation prevention rib 121 is also provided in the first frame 110, so that the rotation insertion part 210 of the rotation fixing bolt 200 inserted into the cutout groove H1 of the first frame 110 is It will prevent deviation from the first frame.

Here, the rotational insertion part 210 of the rotationally fixed bolt 200 fixed in position in the first frame 110 and the second frame 120 has a width smaller than the width a of the exposure slit S. (a') is formed, is formed long along the incision groove, has a length (b') corresponding to the inner width (b) of the incision groove, and both ends are formed in a rounded shape, so that the exposure slit ( When it passes through S) and rotates while being inserted into the incision groove, the both ends are press-fitted into the incision groove H2. For this reason, the rotation-fixed bolt 200 is fixed in position in the second frame 120 and is coupled to the earthquake-resistant bracket 400 to fix the earthquake-resistant bracket to the second frame.

At this time, the central screw portion 220 of the rotation-fixing bolt 200 is a fastening portion 410 of the coupling bracket 130 and the earthquake-resistant bracket 400 in contact with the cut groove H2 side of the second frame 120 . ) through sequentially passing through and coupled with a nut, so that the support frame 100, the earthquake-resistant bracket 400, and the exterior material 300 are fastened to each other.

In addition, the earthquake-resistant bracket 400 may further include a bent portion 430 and a protrusion 440 . The bent portion 430 of the earthquake-resistant bracket 400 extends from the end of the fastening portion 410 through which the central screw portion 220 of the rotation-fixed bolt passes and is bent to extend to the outside of the second frame, and , which is in surface contact with the outer surface of the second frame 120 .

In addition, the protrusion 440 extends from the end of the bent part 430, is formed to protrude between one of the exterior materials 300 and the other exterior material 300, and is connected to the fitting rib 420 by being connected to the fitting rib. The exterior material 300 fitted with the 420 can be positioned on the support frame 100 . Furthermore, the protrusion 440 forms an inlet groove 441 through which the other exterior material 300 is introduced between one side of the fitting rib 420 and the bent portion 430, so that the fitting groove 310 is formed. ) as the fitting rib 420 is inserted to allow the exterior materials to be positioned adjacent to each other when the exterior materials approach each other.

In the present embodiment having the configurations described above, the rotational insertion part 210 of the rotationally fixed bolt 200 is inserted into the cutout groove H2 of the second frame 120 and then rotated to rotate the second frame 120 . ), the central threaded part 220 of the rotationally fixed bolt 200 is exposed by the exposure slit (S), and the central threaded part 220 is the coupling part of the coupling bracket 130 and the earthquake-resistant bracket 400 . After passing through 410, the second frame 120 and the first frame 110 are coupled by being coupled with the nut, and the earthquake-resistant bracket 400 is connected to the second frame 120 (FIG. 7(a)). ) and (b)).

In addition, the protrusion 440 connected to the bent portion 430 of the rotation-fixed bolt is connected to the fitting rib 420 and protrudes from the outside of the second frame 120 between the bent portion 430 and the fitting rib 420 . A lead-in groove 441 is formed on the , and when one of the exterior materials and the other exterior material approach each other, the fitting ribs 420 are respectively inserted into the fitting grooves 310 formed in the exterior material, and the inlet hops ( Another exterior material is introduced into the 441 , and the exterior materials are disposed adjacent to each other, and the exterior material 300 is stably positioned on the support frame 100 (see FIGS. 7 ( c ) and ( d )).

At this time, in order to prevent interference with the bent part 430 when the other exterior material 300 is introduced into the lead-in groove 441 formed in the earthquake-resistant bracket 400, the bending part 300 is introduced into the lead-in groove 441. By forming the insertion groove 320 into which the 430 is inserted, the fitting rib 420 of the earthquake-resistant bracket 400 can be smoothly fitted into the fitting groove 310 of the exterior material 300 .

In addition, when the exterior materials 300 are positioned adjacent to each other by the earthquake-resistant bracket 400 , a gap is formed between the exterior materials 300 . It is preferable that the sealant 500 is provided in the gap between the exterior materials. The sealant 500 prevents the fitting rib 420 of the earthquake-resistant bracket 400 exposed through the gap from being corroded by the external environment, and prevents external moisture from entering the gap.

In this embodiment, in which the exterior material 300 and the support frame 100 are coupled to each other and installed on the exterior wall of a building through this process, it absorbs vibrations when an earthquake or strong wind occurs to prevent damage and fall of the exterior material, and It does not require welding equipment and welding specialists for installation, and the exterior material can be installed in a building only with its own structure, and has the effect of eliminating the risk of fire during welding and remarkably reducing the construction cost and construction time.

The earthquake-resistant non-welding exterior panel system according to an embodiment of the present invention has been described above. Hereinafter, an earthquake-resistant non-welded exterior panel system according to another embodiment of the present invention will be described with reference to FIG. 8 .

8 is a view for explaining a support frame and rotation fixing bolts employed in the seismic non-welding exterior panel system according to another embodiment of the present invention.

As shown in FIG. 8, this embodiment is similar to most of the configuration of the embodiment described above, but there is a difference in the structure of the rotation inserting part 210 in the support frame 100 and the rotation fixing bolt 200. have.

That is, the separation preventing rib 121 is formed in the direction facing each other in the first frame 110 and the second frame 120 to define the cut-out grooves H1 and H2, and the inside of the cut-out groove is formed. toward the inclined portion 121a. The inclined portion 121a is inserted into the inclined groove portion 211 formed in the rotational insertion portion when the rotational insertion portion 210 of the rotationally fixed bolt rotates in the cutout groove.

The rotational insertion part 210 of the rotationally fixed bolt has a width smaller than the width of the exposure slit (S) and is formed long along the incision grooves (H1, H2), and surrounds the central screw part (220). By having an inclined groove portion 211 formed in the form of a groove and having an inclined contact surface in contact with the inclined portion 121a, the inclined groove portion 211 passes through the exposure slit S and is rotated while being inserted into the incision groove. The inclined portion 121a is introduced into the groove portion 211 .

Therefore, in this embodiment, when the central screw portion 220 and the nut of the rotationally fixed bolt 200 are coupled, the binding force between the rotational insertion portion 210 of the rotationally fixed bolt 200 and the support frame 100 can be effectively increased. have.

Meanwhile, the first frame 110 and the second frame 120 include a reinforcing frame (reference numeral not shown) therein. The reinforcement frame is provided inside the support frame 100 to increase the durability of the support frame and prevent deformation. The shape of the reinforcing frame is not limited to any one, and may be formed in a polygonal or oval shape such as '◇' or '0'.

In the above, preferred embodiments of the present invention have been described, but the present invention is not limited to the embodiments described above, but is defined by the claims, and various modifications and developments can be made in the technical field to which the present invention belongs. self-evident

100: support frame 110: first frame
H1: incision groove 120: second frame
H2: incision groove 121: separation prevention rib
S: exposure slit 130: coupling bracket
200: rotation fixed bolt 210: rotation insert
220: central thread 300: exterior material
310: fitting groove 320: insertion groove
400: seismic bracket 410: fastening part
420: fitting rib 430: bent part
440: protrusion 441: inlet groove
B: building

Claims (7)

A first frame which is provided on the outer wall of a building and has a length in the transverse direction and is long, and a second frame which has a length in the longitudinal direction and is disposed to intersect the first frame and forms a cut-out groove along the longitudinal direction; , a support frame having a coupling bracket for coupling the first frame and the second frame;
at least one rotationally fixed bolt having a rotation insertion part inserted into the cut-out groove and connected to the second frame, and a central screw part extending from the rotation insertion part and exposed to the outside in the cut-out groove;
an exterior material formed in the form of a plate and disposed adjacent to each other on the support frame in plurality and forming fitting grooves on surfaces facing each other; and
In order to fasten the exterior material to the support frame, a fastening part connected to the second frame by being fastened with the rotationally fixed bolt, and a fitting rib connected to the fastening part and fitted with both sides into the fitting groove of the exterior material, respectively. Seismic bracket provided;
The earthquake-resistant bracket may include: a bent portion bent at an end of the fastening portion to extend outwardly of the second frame; and a protrusion extending from an end of the bent portion, protruding between one of the exterior materials and the other exterior material, and connected to the fitting rib;
The fastening part is located in the part in which the cut-out groove is formed in the second frame, and is connected to the second frame together with the coupling bracket by a rotation fixing bolt,
The bent portion is in surface contact with the outer surface of the second frame in a state in which, after being bent at the fastening portion, the cutout groove is not formed and extended to the outside of the second frame,
The central screw portion of the rotation-fixed bolt sequentially passes through a fastening portion of the seismic bracket and one surface of the coupling bracket in contact with the cut-out groove of the second frame and is coupled with a nut, thereby fastening the support frame, the earthquake-resistant bracket and the exterior material to each other. Seismic non-welding exterior panel system, characterized in that
delete According to claim 1,
The protrusion is
Seismic non-welding, characterized in that a lead-in groove for introducing the other exterior material is formed between one side of the fitting rib and the bent part so that the one exterior material and the other exterior material can be positioned adjacently Exterior panel system.
According to claim 1,
The second frame is
In order to maintain the binding state of the rotation insertion part inserted into the cut-out groove and the second frame,
The seismic non-welding exterior panel system, characterized in that it comprises a separation prevention rib defining the cutout groove, forming a locking jaw to which the rotating insert is caught, and forming an exposure slit in which the central screw portion is exposed.
5. The method of claim 4,
The rotational insertion part of the rotationally fixed bolt,
A width smaller than the width of the exposure slit is formed, is formed long along the cutout groove, and has a length corresponding to the inner width of the cutout groove, and both ends are formed in a rounded shape, so that it passes through the exposure slit The seismic non-welding exterior panel system, characterized in that the both ends are press-fitted inside the incision groove when it is rotated in the state inserted into the incision groove.
delete 5. The method of claim 4,
The separation prevention rib forms an inclined portion inclined toward the inside of the incision groove,
The rotational insertion part of the rotationally fixed bolt has a width smaller than the width of the exposure slit and is formed long along the incision groove, is made in the form of a groove having a structure surrounding the central screw part, and is an inclined contact surface in contact with the inclined part By having the formed inclined groove portion, the earthquake-resistant non-welding exterior panel system, characterized in that the inclined portion is drawn into the inclined groove portion when it is rotated while being inserted into the incision groove through the exposure slit.

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