KR102152805B1 - Rail type earthquake resistant construction structure of composite panel - Google Patents

Abstract

The present invention relates to a rail type earthquake-proof installation structure for a composite panel. According to the present invention, a panel bracket can be quickly and conveniently attached to a molded aluminum composite panel, vibration delivery between the panel bracket and the molded aluminum composite panel can be reduced, and a wall bracket fixing a supporter to a wall of a building includes a lateral elastic part reducing lateral vibrations, a vertical elastic part reducing vertical vibrations and a plurality of compression coils reducing forward and backward vibrations so as to enhance an earthquake-proof effect by reducing the delivery of vibrations caused by an earthquake or the like to the supporter, a combination bracket, the panel bracket and the molded aluminum composite panel. In regard to installing the molded aluminum composite panel on the wall of the building, the panel bracket attached to the molded aluminum composite panel and the combination bracket combined with the supporter are combined through a sliding operation without the use of a direct connection type screw nail, which can lead to convenient and quick construction. Also, when the molded aluminum composite panel is installed on the wall, any gap between the molded aluminum composite panels can be minimized, the exterior can be kept elegant because fastening members, such as a direction connection type screw nail, are not exposed on a front side, and the combination bracket and the supporter are combined on a one-touch basis without the use of a direct connection type screw nail, which can allow quick and convenient construction.

Description

Rail type earthquake resistant construction structure of composite panel

The present invention relates to a rail-type seismic installation structure of a composite panel among the technologies in the field of construction, and more specifically, a rail-type seismic resistance of a composite panel that enables quick and easy attachment of a panel bracket to a molded aluminum composite panel. It relates to the installation structure.

In addition, the present invention can attenuate the transmission of vibration between the molded aluminum composite panel and the panel bracket, and the wall bracket for fixing the support to the building wall has a left-right elastic part that attenuates the left-right vibration and a vertical elastic part that attenuates the vertical vibration. A composite panel that can attenuate the vibrations caused by earthquakes, including a plurality of compression coil springs that attenuate negative and anteroposterior vibrations, from being transmitted to the support, coupling brackets, panel brackets, and molded aluminum composite panels to increase the seismic effect. It relates to a rail-type seismic installation structure of.

In addition, in the present invention, when installing the molded aluminum composite panel on the wall of a building, construction is quickly and conveniently performed by sliding the coupling bracket that is coupled to the support and the panel bracket attached to the molded aluminum composite panel without using a direct screw. It relates to a rail-type seismic installation structure of a composite panel that has been made possible.

In addition, the present invention is a composite panel capable of minimizing the gap between the molded aluminum composite panels when the molded aluminum composite panel is installed on the wall, and maintaining a graceful appearance because the fastening members such as direct screw screws are not exposed to the front. It relates to a rail-type seismic installation structure of.

In addition, the present invention relates to a rail-type seismic installation structure of a composite panel so that construction can be quickly and conveniently performed by one-touch coupling without using a direct screw screw in defecting the coupling bracket to the support.

In addition, the present invention relates to a rail-type seismic installation structure of a composite panel so that construction can be quickly and easily performed by directly coupling the panel bracket to the wall bracket without using a support and a coupling bracket.

In general, wall finishing panels are widely used to finish the exterior of buildings by manufacturing them to have a certain area (height × width) and thickness and attaching them to the walls of buildings.

Conventionally, a panel made of synthetic resin manufactured by injection molding of a synthetic resin and an iron panel manufactured by bending a steel plate are used as the conventional wall finishing panel.

Synthetic resin panels have the advantage that they are easy to handle and install because they are light, but they have the disadvantage of being easy to deform, and iron panels have the advantage that they are not easily deformed, but they are heavy, so handling and installation work is difficult.

In order to solve the shortcomings of these synthetic resin panels and iron panels, an aluminum composite panel (ACP) material was developed in which an aluminum plate and a synthetic resin plate were laminated.

The aluminum composite panel material 1 is formed in a three-layer structure in which a synthetic resin plate 1c having a thickness of 3 to 4 mm is bonded between an outer aluminum plate 1a having a thickness of 0.5 mm and an inner aluminum plate 1b having a thickness of 0.5 mm. .

The aluminum composite panel material 1 may be installed by fixing a grid-shaped support frame to the outer wall of a building with anchor bolts and nuts, and fastening a plurality of direct-connected screws penetrating the aluminum composite panel to the support frame.

However, in this case, since the head of the screw is exposed from the front, there is a problem that the appearance is not beautiful.

Therefore, in the prior art, the aluminum composite panel material 1 has a composite panel body portion 3a having a constant width and height, and a depth having an upper and lower left and right bent portions 3b formed bent at four edges of the composite panel body portion 3a. Molded aluminum composite panels (3) molded into a low box shape are widely used.

In the conventional molded aluminum composite panel 3, the step of cutting the aluminum composite panel material 1 into a size having a certain width and height (see FIG. 17), and an inner aluminum plate 1a constituting the aluminum composite panel material 1 ) And the outer aluminum plate (1a) constituting the aluminum composite panel material (1) and the inner side with V grooves (2a) formed in the upper and lower left and right directions in the wealth spaced a certain distance inward from the four edges of the synthetic resin plate (1c). Step of forming a cutout (2b) at a 90 degree angle to the four corners of the aluminum plate (1b) and the synthetic resin plate (1c) (see Fig. 18), and the outside of the V groove (2a) of the aluminum composite panel material (1) It is manufactured through the step of bending the side portion by 90 degrees to form the composite panel body portion 3a and the vertical left and right bent portions 3b (see FIG. 19).

The molded aluminum composite panel 3 may itself have a beautiful appearance, but there is a problem in that an element that damages the appearance occurs in the process of attaching it to a building.

The process of installing the conventional molded aluminum composite panel 3 on the wall includes a rivet hole drilling step, a rivet installation step, a support mounting step, and a molded aluminum composite panel installation step.

The rivet hole drilling step is a panel bracket having a panel bracket body 4a, a rear end bent portion 4b bent at the rear end of the panel bracket body 4a, and a shear bent portion 4c bent at the front end of the panel bracket 4a. (4) is prepared and the rear end bent part (4b) is in close contact with the rear of the composite panel body part (3a), and the panel bracket body (4a) is in close contact with the bent part (3b), and then bent using an electric drill. A plurality of rivet holes H1 and H2 are drilled in the part 3b and the panel bracket body 4a (see FIG. 20).

In the rivet installation step, the rivet (R) is passed through the rivet holes (H1, H2) using a rivet gun and the head is formed at both ends (see Fig. 21).

In the step of installing the support, the support 5 having a horizontal base 5a and a vertical base 5b, and the wall bracket body 6a having a certain length in the front and rear direction and the wall bracket body 6a are bent to form the wall. Prepare a wall bracket (6) having a bent portion (6b) in close contact with the wall, and insert an anchor bolt (Ba) that is buried in the wall and protrudes through the bent portion (6b), and an anchor nut (Na) in the anchor bolt (Ba). By fastening the wall bracket (6) to the wall of the building, pass the coupling bolt (B2) through the horizontal base (5a) and the vertical base (5b) and the wall bracket body (6a), and attach the coupling nut to the coupling bolt (B1). By fastening (N1), the process of installing the support 5 on the wall is performed (see Fig. 22).

In the step of installing the molded aluminum composite panel, use an electric screwdriver to insert a direct screw (SC1) through the rear end bent part (4b) of the panel bracket (4) and fasten it to the horizontal stand (5a) and the vertical stand (5b). The process of attaching the molded aluminum composite panel 3 to the support 5 through (4) (see FIGS. 23 and 24).

In this prior art, in order to couple the panel bracket 4 to the molded aluminum composite panel 3, a plurality of rivet holes H1 and H2 are drilled into the bent portion 3b and the panel bracket body 4a, and rivets Since the rivet (R) is passed through the holes (H1, H2) and the head is formed at both ends, it is cumbersome and time-consuming to combine the molded aluminum composite panel (3) and the panel bracket (4). have.

In addition, in order to install the molded aluminum composite panel (3) on the wall, the panel bracket (4) fixed to the molded aluminum composite panel (3) must be fixed to the support (5) with a plurality of screws (SC1). There is a problem that the installation work of the composite panel 3 is cumbersome and takes a lot of time.

In addition, in order to fasten the direct screw (SC1) through the rear end bent portion (4b) of the panel bracket (4) using an electric driver and fasten it to the horizontal stand (5a) and the vertical stand (5b), adjacent molded aluminum composite panels ( 3) There is no choice but to leave a gap through which the driver bit can pass, and when the molded aluminum composite panel (3) is installed on the wall, the appearance due to the rivet (R) and direct screw (SC1) exposed to the front surface There is a problem that hurts.

In addition, since the direct screw (SC1) cannot be directly fastened to the wall constructed of concrete, installation of the support (5) is required, which complicates construction and lengthens construction time. There is a problem in that the gap between the front surfaces of the composite panel 3 is increased.

In addition, in the conventional molded aluminum composite panel 3, a direct-connected screw (SC1) penetrating the rear end bent portion 4b of the panel bracket 4 fixed to the bent portion 3b is attached to the wall bracket 6 and the anchor bolts (Ba). ) And anchor nut (Na) to the support (5) installed on the wall of the building, and when an earthquake occurs, the vibration of the building wall is prevented from the wall bracket (6), the support (5), and the panel bracket. As it is transferred to the molded aluminum composite panel 3 through (4), there is a problem that the seismic effect cannot be obtained.

As prior art related to the conventional composite panel, Korean Patent Registration No. 10-0547435 (announcement on Jan. 31, 2006) "Exterior Panel for Building" and Korean Patent Registration No. 10-1611595 (announcement on Apr. 12, 2016) "Aluminum Composite Panel. Rail-type installation structure" and Korean Patent Registration No. 10-1900749 (announced on September 20, 2018) "Non-combustible composite panel for finishing exterior walls of buildings and a manufacturing method thereof".

Korean Patent Registration No. 10-0547435 (announced on Jan. 31, 2006) "Exterior panel for building" Republic of Korea Patent Registration No. 10-1611595 (Announcement on April 12, 2016) "Aluminum composite panel rail type installation structure" Korean Patent Registration No. 10-1900749 (announced on September 20, 2018) "Non-combustible composite panel for exterior wall finishing of buildings and its manufacturing method"

Accordingly, an object of the present invention is a rail-type seismic installation structure of a composite panel that enables quick and easy attachment of a panel bracket to a molded aluminum composite panel, and dampens vibration transmission between the molded aluminum composite panel and the panel bracket. Is to provide.

Another object of the present invention is a wall bracket for fixing a support to a building wall to provide a left and right elastic part for damping the vibration in the left and right direction, an elastic part in the vertical direction for damping the vibration in the vertical direction, and a plurality of compression coil springs for damping the vibration in the front and rear directions. Including, it is intended to provide a rail-type seismic installation structure of a composite panel that can attenuate the transmission of vibrations caused by earthquakes to the support, coupling brackets, panel brackets, and molded aluminum composite panels, thereby enhancing the seismic effect.

Another object of the present invention is to quickly install a molded aluminum composite panel on a building wall by sliding a coupling bracket that is coupled to a support and a panel bracket attached to the molded aluminum composite panel without using a direct screw. It is intended to provide a rail-type seismic installation structure of composite panels that can be achieved easily.

Another object of the present invention is to minimize the gap between the molded aluminum composite panels when the molded aluminum composite panel is installed on the wall, and to maintain the appearance beautifully because the fastening members such as direct screw screws are not exposed to the front. It is to provide a rail-type seismic installation structure for a composite panel.

Another object of the present invention is to provide a rail-type seismic installation structure of a composite panel so that construction can be quickly and conveniently performed by one-touch coupling without the use of direct screws in the defect of the coupling bracket to the support.

Another object of the present invention is to provide a rail-type seismic installation structure of a composite panel so that construction can be quickly and easily performed by directly coupling the panel bracket to the wall bracket without using a support and a coupling bracket.

The present invention is a composite panel body portion (3a) having a certain width and height in order to achieve the above object, and a box having a low depth by bending a bent portion (3b) at four edges of the composite panel body portion (3a). A plurality of molded aluminum composite panels 3 formed in a shape; A pair of upper and lower panel brackets 110 which are symmetrically attached to the upper and lower portions on the rear surface of each of the molded aluminum composite panels 3; A packing (20) coupled to the panel bracket (110) and having a front surface facing the rear surface of the panel body (3a); A double-sided tape 30 for attaching the front surface of the panel bracket 10 and the front surface of the packing 20 to the rear surface of the panel body 3b; A plurality of supports 140 disposed horizontally on the wall of the building at a constant height interval; A plurality of wall brackets 50 having the rear end fixed to the wall of the building and to which the support 140 is coupled to the front end; The rear end is fixed to the support 40 and the front end is coupled to the panel bracket 10, the coupling bracket 160; comprises a,

The upper and lower pair of panel brackets 110 are extruded from a metal material, and located in a corner between the composite panel body 3a and the upper and lower bent parts 3b of the molded aluminum composite panel 3 A packing coupling part 111 formed in a'c' shape having a packing groove 111a opened toward the rear of the part 3a, and toward the opposite direction of the corner part at the front end of the packing coupling part 111 A panel coupling piece 112 extending vertically and facing the rear surface of the molded aluminum composite panel 3, an elastic connecting piece 113 extending rearward from the rear end of the packing coupling portion 111, and the Consisting of a vertical portion 114 integrally formed at the rear end of the elastic connecting piece 113 and bent vertically, and a'ㅏ'-shaped sliding coupling protrusion 115 integrally formed on the rear surface of the vertical portion 114 Become,

The packing coupling part 111 is formed with a separation preventing protrusion 111b for preventing separation of the packing 20 on the lower surface of the ceiling and the upper surface of the floor of the packing groove 111a,

The packing 20 is formed in an approximately rectangular cross section, and a separation prevention groove 21 into which the separation prevention protrusion 111b is inserted is formed on the top and bottom surfaces,

The double-sided tape 30 is a height at which the front of the packing coupling part 11, the panel coupling piece 12, and the packing 20 can be attached to the rear surface of the panel body part 3b of the molded aluminum composite panel 3 Consists of,

The support 140 is formed of a square pipe having a front and rear plate and an upper and lower plate by extrusion molding of a metal material, and a coupling bracket corresponding to the panel bracket 10 attached to the lower portion of the molded aluminum composite panel 3 installed on the upper side The coupling bracket 160 corresponding to the panel bracket 10 attached to the upper portion of the molded aluminum composite panel 3 installed on the lower side is configured to have a height at which the coupling bracket 160 can be coupled to the lower side,

A plurality of rectangular coupling holes 141 are formed in the front plate of the support 140,

The wall bracket 50 is formed of carbon fiber reinforced plastic (CFRP), is parallel to the building wall, and is fixed to the building wall with anchor bolts (Ba) and anchor nuts (Na). 51), and a left and right elastic portion 52 formed integrally at one end of the wall fixing portion 51 and extending vertically toward the front, and integrally formed at the front end of the left and right elastic portion 52 A first wall bracket (50A) consisting of a first vertical coupling portion (53) disposed vertically, and a second wall bracket (50A) formed of carbon fiber reinforced plastic, and spaced apart from the first vertical coupling portion (53). The vertical coupling part 54 and the vertical coupling part 54 are formed integrally in the middle part in the left and right directions of the second vertical coupling part 54 and extended horizontally toward the front to the vertical elastic part 55 coupled to the support 40. A second wall bracket (50B) and a plurality of compression coil springs (56) disposed horizontally between the first vertical coupling portion (53) and the second vertical coupling portion (54) to provide an elastic force in the front and rear directions, and , A plurality of screw rods 57 passing through the first vertical coupling portion 53 and the second vertical coupling portion 54 and passing through the compression coil spring 56, and the screw rod 57 The first nut 58 is fastened to the rear end and is in close contact with the rear surface of the first vertical coupling part 53, and is fastened to the front end of the screw rod 57 so as to be in close contact with the front surface of the second vertical coupling part 54. It is configured to include a second nut (59),

The first wall bracket (50A) is buried and fixed to the wall of the building, and the anchor bolt (Ba) passing through the wall fixing part 51 from the rear to the front, and the anchor nut (Na) fastened to the anchor bolt (Ba). It is fixed to the wall of the building by

The second wall bracket 50B is formed by a coupling bolt (B1) penetrating the vertical elastic portion 55 and the support 40 in the vertical direction, and a coupling nut (N1) fastened to the coupling bolt (B1). It is fixed to the support 40,

The compression coil spring 56 tightens the first and second nuts 58 and 59 that are fastened to the front and rear ends of the plurality of threaded rods 57 passing through the first and second vertical coupling portions 53 and 54. The compression coil spring 56 is installed in a compressed state in an intermediate state between the free state and the maximum compressed state, and when vibration acts in a direction closer to each other between the first and second wall brackets 50A, 50B. It is configured to attenuate the vibration while being compressed, and when the vibration acts in a direction away from each other, the compression coil spring 56 is elongated to attenuate the vibration,

The coupling bracket 60 is extruded out of a metal material, and the upper sliding coupling portion 161 having an upper sliding coupling groove 161a into which the upper half of the'ㅏ'-shaped sliding coupling protrusion 115 of the panel bracket 110 is inserted. ), and an upper connecting piece 162 extending rearward from the rear end of the upper sliding connecting portion 161, and integrally formed at the rear end of the upper connecting piece 162, and a rectangular connecting hole 141 of the support 140 An upper coupling bracket 160A including an upper inclined guide surface 163a in contact with the upper edge of the support base 140 and an upper hook protrusion 163 having an upper engaging protrusion 163b caught on the rear surface of the front plate of the support 140; A lower sliding coupling part 164 which is extruded from a metal material and having a lower sliding coupling groove 164a into which the lower half of the'ㅏ'-shaped sliding coupling protrusion 115 of the panel bracket 110 is inserted, and the lower sliding coupling The lower connecting plate 165 extending from the rear end of the part 164 to the rear, and integrally formed at the rear end of the lower connecting plate 165 and integrally formed at the rear end of the lower sliding coupling part 164, the support Includes a lower hook protrusion 166 having a lower inclined guide surface (166a) in contact with the lower edge of the rectangular coupling hole (141) of 140 and a lower locking protrusion (166b) that is caught on the rear of the front plate of the support (140) A lower coupling bracket 160B; It provides a rail-type seismic installation structure of a composite panel, characterized in that it comprises an elastic rubber (160C) coupled between the lower surface of the upper hook protrusion 163 and the upper surface of the lower hook protrusion 166.

According to the rail-type seismic installation structure of the composite panel of the present invention, since the panel bracket is attached to the molded aluminum composite panel using double-sided tape, the attachment of the panel bracket to the molded aluminum composite panel can be performed quickly and conveniently, Packing is attached to the packing joint of the molded aluminum composite panel, and double-sided tape is attached between the front of the packing joint of the molded aluminum composite panel and the front of the panel attachment and between the front of the packing and the back of the body part of the molded aluminum composite panel. The vibration transmission between the molded aluminum composite panel and the panel bracket is attenuated by the tape.

In addition, according to the rail-type seismic installation structure of the composite panel of the present invention, the wall bracket for fixing the support to the building wall has a first wall bracket having a left and right elastic part that attenuates the vibration in the left and right direction, and a vertical direction that attenuates the vertical vibration. Including a second wall bracket having an elastic part and a plurality of compression coil springs that attenuate the vibration in the front and rear directions, vibrations caused by earthquakes, etc. can be attenuated from being transmitted to the support, the coupling bracket, the panel bracket, and the molded aluminum composite panel. And the second wall bracket is formed of a carbon fiber reinforced plastic having higher strength and higher elasticity than a metal material, so that the seismic effect can be improved.

In addition, according to the rail-type seismic installation structure of the composite panel of the present invention, a sliding coupling part having a'ㅓ'-shaped sliding coupling groove is provided in the wall bracket, and a'ㅓ'-shaped sliding coupling protrusion is provided in the coupling bracket coupled to the support. Therefore, when installing the molded aluminum composite panel on the wall of the building, the installation can be quickly and easily performed by sliding the coupling bracket that is coupled to the support and the panel bracket attached to the molded aluminum composite panel without using direct screws. .

In addition, according to the rail-type seismic installation structure of the composite panel of the present invention, the panel bracket and the coupling bracket are slidably coupled to the panel bracket without being coupled to the support by a direct screw. When the molded aluminum composite panel is installed on the wall The gap between the molded aluminum composite panels can be minimized, and the fastening members such as direct-connected screws are not exposed to the front, so the appearance can be maintained beautifully.

In addition, according to the rail-type seismic installation structure of the composite panel of the present invention, in the defect of the coupling bracket to the support, it is possible to quickly and conveniently perform construction by one-touch coupling without using a direct screw.

In addition, according to the rail-type seismic installation structure of the composite panel of the present invention, by directly coupling the panel bracket to the wall bracket without using a support and a coupling bracket, construction can be made quickly and easily.

1 to 6 show a first preferred embodiment of the rail-type seismic installation structure of the composite panel according to the present invention,
1 is an exploded perspective view of a molded aluminum composite panel, a panel bracket, a packing, a double-sided tape, and a coupling bracket as viewed from the rear,
Figure 2 is a longitudinal left sectional view showing an exploded state of the panel bracket and the support and the coupling bracket coupled to the molded aluminum composite panel;
3 is an exploded perspective view of the support and the wall bracket viewed from the front,
Figure 4 is a perspective view from the front of the state in which the coupling bracket is installed on the support,
5 is a front perspective view of a state in which a molded aluminum composite panel is installed by combining the bonding bracket and the panel bracket;
6 is a front view showing a molded aluminum composite panel installed on a wall of a building,
7 to 11 show a second preferred embodiment of the rail-type seismic installation structure of the composite panel according to the present invention,
Figure 7 is an exploded perspective view of a molded aluminum composite panel, panel bracket, packing, double-sided tape, and coupling bracket as viewed from the rear;
8 is a longitudinal left sectional view showing an exploded state of the panel bracket, the support, and the coupling bracket coupled to the molded aluminum composite panel;
9 is an exploded perspective view of the support and the wall bracket viewed from the front,
10 is a perspective view from the front view of a state in which the coupling bracket is installed on the support,
11 is a front perspective view of a state in which a molded aluminum composite panel is installed by a combination of a bonding bracket and a panel bracket;
12 to 16 show a third preferred embodiment of the rail-type seismic installation structure of the composite panel according to the present invention,
12 is an exploded perspective view of a molded aluminum composite panel, panel bracket, packing, and double-sided tape as viewed from the rear,
13 is a longitudinal left sectional view showing an exploded state of the panel bracket and support coupled to the molded aluminum composite panel;
14 is an exploded perspective view of the wall bracket viewed from the front,
15 is a perspective view from the front view of the wall bracket installed;
16 is a perspective view from the front view of a state in which a molded aluminum composite panel is installed by a combination of a wall bracket and a panel bracket;
17 to 19 are rear perspective views showing a process of forming a molded aluminum composite panel using a conventional aluminum composite panel,
20 is a rear perspective view showing a state in which rivet holes are drilled in a conventional molded aluminum composite panel and a panel bracket;
21 is a rear perspective view showing a conventional molded aluminum composite panel and a panel bracket combined by rivets;
22 is a front perspective view showing a state in which a support is installed on a wall of a building;
23 is a front perspective view showing a state in which a direct screw screw penetrating a panel bracket is fastened to a support;
24 is a front view showing a conventional molded aluminum composite panel installed on a wall of a building.

Hereinafter, a rail-type seismic installation structure of a composite panel according to the present invention will be described in detail according to a preferred embodiment illustrated in the accompanying drawings.

1 to 6 show a first preferred embodiment of a rail-type seismic installation structure of a composite panel according to the present invention.

The rail-type seismic installation structure of the composite panel according to the present embodiment includes a composite panel body portion 3a having a constant width and height, and a bent portion 3b bent at four edges of the composite panel body portion 3a to A plurality of molded aluminum composite panels (3) formed in a low box shape; A pair of upper and lower panel brackets 10 which are symmetrically attached to the upper and lower portions on the rear surface of each of the molded aluminum composite panels 3; A packing (20) coupled to the panel bracket (10) and having a front surface facing the rear surface of the panel body (3a); A double-sided tape 30 for attaching the front surface of the panel bracket 10 and the front surface of the packing 20 to the rear surface of the panel body 3b; A plurality of supports 40 arranged horizontally at a constant height interval on the wall of the building; A plurality of wall brackets 50 having the rear end fixed to the wall of the building and to which the support 40 is coupled to the front end; And a coupling bracket 60 having a rear end fixed to the support 40 and a front end coupled to the panel bracket 10.

The molded aluminum composite panel 3 is formed by bonding a synthetic resin plate 1c having a thickness of 3 to 4 mm between an outer aluminum plate 1a having a thickness of 0.5 mm and an inner aluminum plate 1b having a thickness of 0.5 mm, as in the prior art described above. A composite panel body 3a having a certain width and height using an aluminum composite panel material 1 formed in a three-layer structure, and an upper, lower, left and right bent part formed by bending at the four edges of the composite panel body part 3a ( 3b) is used that is molded into a box with a low depth.

In addition, since the molded aluminum composite panel 3 is manufactured in the same manner as in the prior art, a detailed description thereof will be omitted.

The upper and lower pair of panel brackets 10 are extruded from a metal material, and are located in a corner between the composite panel body 3a and the upper and lower bent parts 3b of the molded aluminum composite panel 3 A packing coupling part 11 formed in a'c' shape having a packing groove 11a opened toward the rear of the part 3a, and toward the opposite direction of the corner part at the front end of the packing coupling part 11 A panel coupling piece 12 extending vertically and facing the rear surface of the molded aluminum composite panel 3, an elastic connecting piece 13 extending rearward from the rear end of the packing coupling portion 11, and the It is integrally formed at the rear end of the elastic connecting piece 13 and includes a sliding coupling portion 14 having a'ㅓ'-shaped sliding coupling groove 14a coupled to the coupling bracket 60 by side sliding.

The packing coupling portion 11 is formed with a separation preventing protrusion 11b for preventing separation of the packing 20 on the lower surface of the ceiling and the upper surface of the floor of the packing groove 11a.

The panel bracket 10 attached to the upper rear surface of the molded aluminum composite panel 3 is disposed such that the packing coupling portion 11 is positioned at the upper portion and the panel coupling piece 12 is positioned at the lower portion, and the molded aluminum composite panel ( The panel bracket 10 attached to the lower rear surface of 3) is disposed such that the packing coupling part 11 is located at the lower side and the panel coupling piece 12 is located at the upper part.

The elastic connecting piece 13 elastically connects the packing coupling part 11 and the sliding coupling part 14 to reduce the transmission of vertical vibration between the packing coupling part 11 and the sliding coupling part 14 Will do.

The sliding coupling groove (14a) is composed of a vertical portion formed on the front side, and a horizontal portion that is open to the rear by communicating with the middle portion of the vertical portion.

The packing 20 is formed in an approximately rectangular cross section, and a separation prevention groove 21 into which the separation prevention protrusion 11b is inserted is formed on an upper surface and a lower surface.

The double-sided tape 30 is a height at which the front of the packing coupling part 11, the panel coupling piece 12, and the packing 20 can be attached to the rear surface of the panel body part 3b of the molded aluminum composite panel 3 Consists of

The support 40 is formed of a square pipe that is extruded from a metal material and has a front and rear plate and an upper and lower plate, and a coupling bracket corresponding to the panel bracket 10 attached to the lower part of the molded aluminum composite panel 3 installed on the upper side (60 is coupled to the upper side, and the coupling bracket 60 corresponding to the panel bracket 10 attached to the upper portion of the molded aluminum composite panel 3 installed at the lower side is configured to have a height that can be coupled to the lower portion.

The wall bracket 50 is formed of carbon fiber reinforced plastic (CFRP), is parallel to the building wall, and is fixed to the building wall with anchor bolts (Ba) and anchor nuts (Na). 51), and a left and right elastic portion 52 formed integrally at one end of the wall fixing portion 51 and extending vertically toward the front, and integrally formed at the front end of the left and right elastic portion 52 A first wall bracket (50A) consisting of a first vertical coupling portion (53) disposed vertically, and a second wall bracket (50A) formed of carbon fiber reinforced plastic, and spaced apart from the first vertical coupling portion (53). The vertical coupling part 54 and the vertical coupling part 54 are formed integrally in the middle part in the left and right directions of the second vertical coupling part 54 and extended horizontally toward the front to the vertical elastic part 55 coupled to the support 40. A second wall bracket (50B) and a plurality of compression coil springs (56) disposed horizontally between the first vertical coupling portion (53) and the second vertical coupling portion (54) to provide an elastic force in the front and rear directions, and , A plurality of screw rods 57 passing through the first vertical coupling portion 53 and the second vertical coupling portion 54 and passing through the compression coil spring 56, and the screw rod 57 The first nut 58 is fastened to the rear end and is in close contact with the rear surface of the first vertical coupling part 53, and is fastened to the front end of the screw rod 57 so as to be in close contact with the front surface of the second vertical coupling part 54. It includes a second nut (59).

The first wall bracket (50A) is buried and fixed to the wall of the building, and the anchor bolt (Ba) passing through the wall fixing part 51 from the rear to the front, and the anchor nut (Na) fastened to the anchor bolt (Ba). It is fixed to the wall of the building.

The second wall bracket 50B is formed by a coupling bolt (B1) penetrating the vertical elastic portion 55 and the support 40 in the vertical direction, and a coupling nut (N1) fastened to the coupling bolt (B1). It is fixed to the support 40.

The wall fixing portion 51 has a through hole through which the anchor bolt (Ba) passes, the first and second vertical coupling portions 53 and 54 have a through hole through which the threaded rod 57 passes, and the vertical elastic part 55 ) And the support 40 are provided with through holes through which the coupling bolts (B1) pass, respectively, which are shown in the drawings, but the reference numerals are omitted.

The compression coil spring 56 tightens the first and second nuts 58 and 59 that are fastened to the front and rear ends of the plurality of threaded rods 57 passing through the first and second vertical coupling portions 53 and 54. The compression coil spring 56 is installed in a compressed state in an intermediate state between the free state and the maximum compressed state, and when vibration acts in a direction closer to each other between the first and second wall brackets 50A, 50B. When the vibration is attenuated while being compressed, and the vibrations act in a direction away from each other, the compression coil spring 56 is configured to be elongated to attenuate the vibration.

The coupling bracket 60 is extruded from a metal material, and is integrally formed with a support coupling portion 61 that can be fixed to the front upper half and the front lower half of the support 40, and the support coupling portion 61. It consists of a'ㅓ'-shaped sliding coupling protrusion 62 that is slidably coupled from the side to the'ㅓ'-shaped sliding coupling groove (14a) of the sliding coupling part (14).

The coupling bracket 60 fixed to the upper front of the support 40 has a'ㅓ'-shaped sliding coupling protrusion 62 located at the lower side, and the coupling bracket 60 fixed to the lower front of the support 40 is'ㅓ The'shaped sliding coupling protrusion 62 is installed to be located at the top.

The coupling bracket 60 may be fixed to the front surface of the support 40 with a direct screw (Sw). That is, the direct connection type screw (Sw) is pressurized and rotated using an electric screw without drilling the support unit 61 and the support unit 40 of the coupling bracket 60 in advance, so that the direct connection type screw (Sw) becomes the coupling bracket (60). ), the coupling bracket 60 can be fixed to the support 40 by being fastened while perforating the support coupling part 61 and the support 40.

The coupling bracket 60 may be installed to have a length corresponding to the length of the panel bracket 10 as in the illustrated example, or may be installed to have a length corresponding to the total length of the support base 40.

Hereinafter, the operation of the rail-type seismic installation structure of the composite panel according to the present invention will be described.

The installation process of the rail-type seismic installation structure of the composite panel according to the present invention includes the steps of coupling the packing 20 to the panel bracket 10 (see Fig. 2), and forming the panel bracket 10 into an aluminum composite panel 3 Attaching to [see Fig. 2], fixing the wall bracket 50 to the wall of the building [see Fig. 4], and coupling the support 40 to the wall bracket 50 [see Fig. 4] , The step of coupling the coupling bracket 60 to the support 40 (see Fig. 4), and the coupling bracket 60 fixed to the support 40 to the panel bracket 10 attached to the molded aluminum composite panel 3 It includes the step of side-sliding coupling [see Fig. 5].

The step of coupling the packing 20 to the panel bracket 10 is performed by pushing one end of the packing 20 from one end of the packing coupling groove 11a of the packing coupling portion 11 of the panel bracket 10.

At this time, the separation prevention protrusion 11b of the packing coupling part 11 and the separation prevention groove 21 of the packing 20 are engaged so that the packing 20 does not deviate arbitrarily from the packing coupling groove 11a.

In the step of attaching the panel bracket 10 to the molded aluminum composite panel 3, the front surface of the packing joint 11 of the panel bracket 10, the front surface of the panel attachment part 12, and the front surface of the packing 20 are formed. It can be attached to the rear surface of the body portion (3a) of the aluminum composite panel (3) by a double-sided tape (30).

In other words, after attaching the front of the double-sided tape 30 to the upper and lower rear of the main body 3a, the front and the front of the packing coupling 11 of the panel bracket 10 and the front of the panel attachment 12 By attaching the front side of the packing 20 to the rear side of the double-sided tape 30, the panel bracket 10 can be attached to the rear side of the main body 3a.

Therefore, in the present invention, in the step of attaching the panel bracket 10 to the molded aluminum composite panel 3, a plurality of rivet holes (H1, H2) for the bent portion 3b and the panel bracket body 4a, which were required in the prior art. A panel bracket (10) using a double-sided tape (30) without going through the process of drilling the rivet and passing the rivet (R) through the rivet holes (H1, H2) using a rivet gun and forming the head at both ends. ) Can be attached to the molded aluminum composite panel 3, it is possible to quickly and conveniently perform the joining operation of the panel bracket 10 to the molded aluminum composite panel 3.

At this time, the panel bracket 10 attached to the upper rear side of the main body 3a is positioned at a corner between the rear side of the main body 3a and the lower surface of the upper bent part 3b, and the packing coupling part 11 The front side of the body part 3a is attached to the rear side of the body part 3a, and the panel bracket 10 attached to the lower side of the back side of the body part 3a is between the back side of the body part 3a and the upper surface of the lower bent part 3b. It is positioned in the corner, and the front of the panel bracket 10 is attached to the rear of the main body 3a.

In addition, the upper surface of the packing coupling part 11 of the panel bracket 10 attached to the upper rear side of the main body 3a is not in close contact with the lower surface of the upper bent part 3b, but is spaced apart, and the rear surface of the main body 3a The lower surface of the packing coupling part 11 of the panel bracket 10 attached to the lower side is not in close contact with the upper surface of the lower bent part 3b, but is spaced apart, so that between the molded aluminum composite panel 3 and the panel bracket 10 Vibration transmission can be attenuated by the packing 20 and the double-sided tape 30.

In the step of fixing the support 40 to the building wall, install anchor bolts (Ba) on the building wall corresponding to the upper and lower portions of the installation positions of each supporter 40 to make it protrude, and equal to the anchor bolts (Ba) located at the upper and lower parts. Thus, the first wall bracket (50A), the second wall bracket (50B), the compression coil spring (56), the screw rod (57), and the first and second nuts (58, 59) are pre-assembled wall bracket (50) By positioning the anchor bolt (Ba) through the wall fixing portion 51 of the wall bracket (50) located in the upper and lower portions to protrude forward, and fasten the anchor nut (Na) to the protruding anchor bolt (Ba) It is achieved by doing.

In the step of coupling the support 40 to the wall bracket 50, the support 40 is positioned between the upper and lower elastic parts 55 of the wall bracket 50 located in the upper and lower parts, and the vertical elastic part 55 And it is achieved by passing the coupling bolt (B1) through the support 40, and fastening the coupling nut (N1) to the coupling bolt (B1).

At this time, the first wall bracket 50A constituting the wall bracket 50 includes an elastic portion 52 in the left and right direction, and the second wall bracket 50B includes an elastic portion 55 in the vertical direction, and the first wall The bracket (50A) and the second wall bracket (50B) are elastically movable in the front and rear directions by the compression coil spring (56), the screw bar (57), and the first and second nuts (58, 59). Therefore, against the vibration applied to the building wall due to earthquake, the left and right elastic parts 52 attenuate the left and right vibration, and the vertical elastic part 55 attenuates the vertical vibration, and the compression coil spring and The threaded rod 57 and the first and second nuts 58 and 59 are able to attenuate the vibration in the front and rear directions, thereby exhibiting a seismic effect.

In addition, the first wall bracket (50A) and the second wall bracket (50B) are formed of carbon fiber reinforced plastic, which has higher strength and higher elasticity than a metal material, so that the left and right elastic parts 52 and the vertical elastic parts 55 It is possible to increase the vibration damping effect.

In the step of coupling the coupling bracket 60 to the support 40, the support coupling part 61 of the coupling bracket 60 is abutted to the front of the support 40, and a direct screw screw (SC) is rotated using an electric screwdriver. , The screw (SC) passes through the support coupling portion 61 to be fastened to the support 40.

The step of side-sliding coupling the panel bracket 10 attached to the molded aluminum composite panel 3 to the coupling bracket 60 fixed to the support 40 is the coupling bracket at the left or right end of the panel bracket 10 The'ㅓ'-shaped coupling groove (14a) of the panel bracket (10) and the'ㅓ'-shaped sliding coupling protrusion (62) are pushed to the right or left while being positioned at the right or left end of (60). It is achieved by

Therefore, in this embodiment, the panel bracket 10 and the coupling bracket 60 can be combined in a one-touch manner by sliding coupling without going through the process of fastening a direct screw using an electric driver that had to go through the prior art. (10) It is possible to quickly and conveniently perform the coupling operation of the coupling bracket 60.

In addition, since the panel bracket 10 and the bonding bracket 60 are slidably coupled without connecting the panel bracket 10 to the support 40 by a direct screw, the gap between the molded aluminum composite panels 3 is reduced. It can be minimized, and the fastening member such as a direct connection type screw is not exposed to the front, so that the appearance can be finished beautifully.

7 to 11 show a second preferred embodiment of the rail-type seismic installation structure of the composite panel according to the present invention.

The rail-type seismic installation structure of the composite panel according to the present embodiment includes a composite panel body portion 3a having a constant width and height, and a bent portion 3b bent at four edges of the composite panel body portion 3a to A plurality of molded aluminum composite panels (3) formed in a low box shape; A pair of upper and lower panel brackets 110 which are symmetrically attached to the upper and lower portions on the rear surface of each of the molded aluminum composite panels 3; A packing (20) coupled to the panel bracket (110) and having a front surface facing the rear surface of the panel body (3a); A double-sided tape 30 for attaching the front side of the panel bracket 110 and the front side of the packing 20 to the rear side of the panel body 3b; A plurality of supports 140 disposed horizontally on the wall of the building at a constant height interval; A plurality of wall brackets 50 having the rear end fixed to the wall of the building and to which the support 140 is coupled to the front end; And a coupling bracket 160 having a rear end fixed to the support 40 and a front end coupled to the panel bracket 110.

In this embodiment, the panel bracket 110, the support 140, and the coupling bracket 160 are different, and the molded aluminum composite panel 3, the packing 20, the double-sided tape 30, and the wall bracket 50 are described above. It is the same as in the first embodiment.

In this embodiment, the panel bracket 110 is extrusion-molded of a metal material, and is located at a corner between the composite panel body 3a and the upper and lower bent parts 3b of the molded aluminum composite panel 3 A packing coupling part 111 formed in a'c' shape having a packing groove 111a opened toward the rear of (3a), and a vertical toward the opposite direction of the corner at the front end of the packing coupling part 111 A panel coupling piece 112 extending from the molded aluminum composite panel 3 and facing the rear surface of the molded aluminum composite panel 3, an elastic connecting piece 113 extending rearward from the rear end of the packing coupling portion 111, and the elasticity It includes a vertical portion 114 integrally formed at the rear end of the connecting piece 113 and bent vertically, and a'ㅏ'-shaped sliding coupling protrusion 115 integrally formed on the rear surface of the vertical portion 114.

The packing coupling part 111 is formed with a separation preventing protrusion 111b for preventing separation of the packing 20 on the lower surface of the ceiling and the upper surface of the floor of the packing groove 111a.

The panel bracket 110 attached to the upper rear surface of the molded aluminum composite panel 3 is disposed such that the packing coupling part 111 is positioned at the top and the panel coupling piece 112 is positioned at the bottom, and the molded aluminum composite panel ( The panel bracket 110 attached to the lower rear surface of 3) is disposed such that the packing coupling part 111 is located at the lower side and the panel coupling piece 112 is located at the upper part.

The elastic connecting piece 113 elastically connects the packing coupling part 111 and the vertical part 114 to act to attenuate the transmission of vertical vibration between the packing coupling part 111 and the vertical part 114. do.

The sliding coupling protrusion 115 is composed of a horizontal portion formed on the front side and a vertical portion integrally formed in the middle portion of the horizontal portion.

The packing 20 is formed in an approximately rectangular cross section, and a separation prevention groove 21 into which the separation prevention protrusion 11b is inserted is formed on an upper surface and a lower surface.

The double-sided tape 30 has a height at which the front of the packing coupling part 111 and the panel coupling piece 112 and the packing 20 can be attached to the rear of the panel body part 3b of the molded aluminum composite panel 3 Consists of

The support 140 is formed of a square pipe having a front and rear plate and an upper and lower plate by extrusion molding of a metal material, and a coupling bracket corresponding to the panel bracket 10 attached to the lower portion of the molded aluminum composite panel 3 installed on the upper side The coupling bracket 160 corresponding to the panel bracket 110 attached to the upper portion of the molded aluminum composite panel 3 installed on the lower side is configured to have a height at which the coupling bracket 160 can be coupled to the lower side.

A plurality of rectangular coupling holes 141 are formed on the front plate of the support 140.

The wall bracket 50 is formed of carbon fiber reinforced plastic (CFRP), is parallel to the building wall, and is fixed to the building wall with anchor bolts (Ba) and anchor nuts (Na). 51), and a left and right elastic portion 52 formed integrally at one end of the wall fixing portion 51 and extending vertically toward the front, and integrally formed at the front end of the left and right elastic portion 52 A first wall bracket (50A) consisting of a first vertical coupling portion (53) disposed vertically, and a second wall bracket (50A) formed of carbon fiber reinforced plastic, and spaced apart from the first vertical coupling portion (53). The vertical coupling part 54 and the vertical coupling part 54 are formed integrally in the middle part in the left and right directions of the second vertical coupling part 54 and extended horizontally toward the front to the vertical elastic part 55 coupled to the support 40. A second wall bracket (50B) and a plurality of compression coil springs (56) disposed horizontally between the first vertical coupling portion (53) and the second vertical coupling portion (54) to provide an elastic force in the front and rear directions, and , A plurality of screw rods 57 passing through the first vertical coupling portion 53 and the second vertical coupling portion 54 and passing through the compression coil spring 56, and the screw rod 57 The first nut 58 is fastened to the rear end and is in close contact with the rear surface of the first vertical coupling part 53, and is fastened to the front end of the screw rod 57 so as to be in close contact with the front surface of the second vertical coupling part 54. It includes a second nut (59).

The first wall bracket (50A) is buried and fixed to the wall of the building, and the anchor bolt (Ba) passing through the wall fixing part 51 from the rear to the front, and the anchor nut (Na) fastened to the anchor bolt (Ba). It is fixed to the wall of the building.

The second wall bracket 50B is formed by a coupling bolt (B1) penetrating the vertical elastic portion 55 and the support 40 in the vertical direction, and a coupling nut (N1) fastened to the coupling bolt (B1). It is fixed to the support 40.

The wall fixing portion 51 has a through hole through which the anchor bolt (Ba) passes, the first and second vertical coupling portions 53 and 54 have a through hole through which the threaded rod 57 passes, and the vertical elastic part 55 ) And the support 40 are provided with through holes through which the coupling bolts (B1) pass, respectively, which are shown in the drawings, but the reference numerals are omitted.

The compression coil spring 56 tightens the first and second nuts 58 and 59 that are fastened to the front and rear ends of the plurality of threaded rods 57 passing through the first and second vertical coupling portions 53 and 54. The compression coil spring 56 is installed in a compressed state in an intermediate state between the free state and the maximum compressed state, and when vibration acts in a direction closer to each other between the first and second wall brackets 50A, 50B. When the vibration is attenuated while being compressed, and the vibrations act in a direction away from each other, the compression coil spring 56 is configured to be elongated to attenuate the vibration.

The coupling bracket 160 is extruded from a metal material, and the upper sliding coupling portion 161 having an upper sliding coupling groove 161a into which the upper half of the'ㅏ'-shaped sliding coupling protrusion 115 of the panel bracket 110 is inserted. ), and an upper connecting piece 162 extending rearward from the rear end of the upper sliding connecting portion 161, and integrally formed at the rear end of the upper connecting piece 162, and a rectangular connecting hole 141 of the support 140 An upper coupling bracket 160A including an upper inclined guide surface 163a in contact with the upper edge of the support base 140 and an upper hook protrusion 163 having an upper engaging protrusion 163b caught on the rear surface of the front plate of the support 140; A lower sliding coupling part 164 which is extruded from a metal material and having a lower sliding coupling groove 164a into which the lower half of the'ㅏ'-shaped sliding coupling protrusion 115 of the panel bracket 110 is inserted, and the lower sliding coupling The lower connecting plate 165 extending from the rear end of the part 164 to the rear, and integrally formed at the rear end of the lower connecting plate 165 and integrally formed at the rear end of the lower sliding coupling part 164, the support Includes a lower hook protrusion 166 having a lower inclined guide surface (166a) in contact with the lower edge of the rectangular coupling hole (141) of 140 and a lower locking protrusion (166b) that is caught on the rear of the front plate of the support (140) A lower coupling bracket 160B; It is configured to include an elastic rubber (160C) coupled between the lower surface of the upper hook protrusion 163 and the upper surface of the lower hook protrusion 166.

The elastic rubber 160C may be adhered to the lower surface of the upper hook protrusion 163 and the upper surface of the lower hook protrusion 166 with an adhesive.

In the illustrated example, it is shown that two coupling brackets 160 are installed at the top and bottom for one molded aluminum composite panel 3, but three or more may be installed depending on the size of the molded aluminum composite panel 3 .

The operation of the rail-type seismic installation structure of the composite panel according to this embodiment will be described.

The installation process of the rail-type seismic installation structure of the composite panel according to the present embodiment includes the steps of coupling the packing 20 to the panel bracket 110 (see FIG. 8), and the panel bracket 110 is molded aluminum composite panel 3 ) Attaching (see FIG. 8), fixing the wall bracket 50 to the building wall (see FIG. 9), and coupling the coupling bracket 160 to the support 140 (see FIG. 10) And, a step of side-sliding coupling the panel bracket 110 attached to the molded aluminum composite panel 3 to the coupling bracket 160 fixed to the support 140 (see FIG. 11).

The step of coupling the packing 20 to the panel bracket 110 is performed by pushing one end of the packing 20 from one end of the packing coupling groove 111a of the packing coupling portion 111 of the panel bracket 110.

At this time, the separation prevention protrusion 111b of the packing coupling part 111 and the separation prevention groove 21 of the packing 20 are engaged so that the packing 20 does not randomly deviate from the packing coupling groove 111a.

In the step of attaching the packon bracket 110 to the molded aluminum composite panel 3, the front of the packing coupling part 111 of the packeng bracket 110 and the front of the panel attachment part 112 and the front of the packing 20 are molded. It can be attached to the rear surface of the body portion (3a) of the aluminum composite panel (3) by a double-sided tape (30).

In other words, after attaching the front of the double-sided tape 30 to the upper and lower rear of the main body 3a, the front of the packing coupling part 111 of the panel bracket 110 and the front and the front of the panel attaching part 112 By attaching the front side of the packing 20 to the rear side of the double-sided tape 30, the panel bracket 110 may be attached to the rear side of the main body 3a.

Therefore, in this embodiment, in the step of attaching the panel bracket 110 to the molded aluminum composite panel 3, a plurality of rivet holes (H1, H2) for the bent portion 3b and the panel bracket 4a, which were required in the prior art. The panel bracket 110 using double-sided tape 30 without going through the process of drilling the rivet and penetrating the rivet (R) in the rivet holes (H1, H2) using a rivet gun and forming the head at both ends. ) Can be attached to the molded aluminum composite panel 3, it is possible to quickly and conveniently perform the joining operation of the panel bracket 110 to the molded aluminum composite panel 3.

At this time, the panel bracket 110 attached to the upper rear side of the main body 3a is positioned at a corner between the rear surface of the main body 3a and the lower surface of the upper bent part 3b, and the packing coupling part 111 The front side of the body part 3a is attached to the rear side of the body part 3a, and the panel bracket 110 attached to the lower side of the back side of the body part 3a is between the back side of the body part 3a and the upper surface of the lower bent part 3b. It is positioned in a corner, and the front of the panel bracket 110 is attached to the rear of the main body 3a.

In addition, the upper surface of the packing coupling part 111 of the panel bracket 110 attached to the upper rear side of the main body 3a is not in close contact with the lower surface of the upper bent part 3b, but is spaced apart, and the rear surface of the main body 3a The lower surface of the packing coupling portion 111 of the panel bracket 110 attached to the lower side is not in close contact with the upper surface of the lower bent portion 3b, but is spaced apart, so that the molded aluminum composite panel 3 and the panel bracket 110 are separated from each other. Vibration transmission can be attenuated by the packing 20 and the double-sided tape 30.

In the step of fixing the support 140 to the building wall (W), install anchor bolts (Ba) on the building wall (W) corresponding to the upper and lower portions of the installation positions of each supporter 140 so that it protrudes, and anchors located at the upper and lower parts. The first wall bracket (50A), the second wall bracket (50B), the compression coil spring (56), the screw rod (57), and the first and second nuts (58, 59) are pre-assembled in parallel to the bolt (Ba). The wall bracket 50 is positioned so that the anchor bolt (Ba) penetrates and protrudes toward the front to the wall fixing portion 51 of the wall bracket 50 located at the top and bottom, and the anchor bolt (Ba) is anchored to the protruding anchor bolt (Ba). It is achieved by tightening the nut (Na).

In the step of coupling the support 140 to the wall bracket 50, the support 140 is positioned between the upper and lower elastic parts 55 of the wall bracket 50 located in the upper and lower parts, and the vertical elastic part 55 And it is achieved by passing the coupling bolt (B1) through the support 140, and fastening the coupling nut (N1) to the coupling bolt (B1).

At this time, the first wall bracket 50A constituting the wall bracket 50 includes an elastic portion 52 in the left and right direction, and the second wall bracket 50B includes an elastic portion 55 in the vertical direction, and the first wall The bracket (50A) and the second wall bracket (50B) are elastically movable in the front and rear directions by the compression coil spring (56), the screw bar (57), and the first and second nuts (58, 59). Therefore, against the vibration applied to the building wall (W) due to earthquake, the left-right elastic part 52 attenuates the left-right vibration, and the vertical elastic part 55 attenuates the vertical vibration, and the compression coil The spring, the threaded rod 57, and the first and second nuts 58 and 59 are able to attenuate the vibration in the forward and backward directions, thereby exhibiting a seismic effect.

In addition, the first wall bracket (50A) and the second wall bracket (50B) are formed of carbon fiber reinforced plastic, which has higher strength and higher elasticity than a metal material, so that the left and right elastic parts 52 and the vertical elastic parts 55 It is possible to increase the vibration damping effect.

The step of coupling the coupling bracket 160 to the support 140 includes the upper hook protrusion 163 of the upper coupling bracket 160A constituting the coupling bracket 160 and the lower hook protrusion 166 of the lower coupling bracket 160B. It is made in a one-touch type by pushing into the rectangular coupling hole 141 of the support 140 as the lead.

That is, when the upper hook protrusion 163 of the upper coupling bracket 160A and the lower hook protrusion 166 of the lower coupling bracket 160B are pushed into the rectangular coupling hole 141 of the support 140, the upper hook The upper inclined guide surface 163a of the protrusion 163 comes into contact with the upper edge of the rectangular coupling hole 141, and the lower inclined guide surface 166a of the lower hook protrusion 166 is at the lower edge of the rectangular coupling hole 141. Contact, and accordingly, the cam action between the upper inclined guide surface (163a) and the upper edge of the rectangular coupling hole 141 and the cam action between the lower inclined guide surface (166a) and the lower edge of the rectangular coupling hole 141 As the coupling bracket 160A descends and the lower coupling bracket 160B rises to compress the elastic rubber 160C and become close to each other, the upper hook protrusion 163 and the lower hook protrusion 166 form a rectangular coupling hole 141. When the upper hook protrusion 163 and the lower hook protrusion 166 completely pass through the rectangular coupling hole 141, the elastic rubber 160C that was compressed is elastically restored and the upper hook protrusion 163 is As it rises and the lower hook protrusion 166 descends, the upper locking protrusion 163b of the upper hook protrusion 163 is caught on the rear of the front plate of the support 140 from the upper edge of the upper edge of the rectangular coupling hole 141, and the lower hook The lower locking protrusion 166b of the protrusion 166 is caught on the rear of the front plate of the support 140 from the lower magnetic edge of the rectangular coupling hole 141, so that the upper coupling bracket 160A and the lower coupling bracket 160B are rectangular It is coupled to the support 140 without any separation from the coupling hole 141.

Therefore, in this embodiment, the coupling of the coupling bracket 160 to the support 140 does not fasten a direct screw, and the cam action and elasticity of the rectangular coupling hole 141 and the upper hook protrusion 163 and the lower hook protrusion 166 Since it is made in a one-touch type by the elastic force of the rubber 160C, the operation can be performed quickly and conveniently.

The step of side-sliding coupling the panel bracket 110 attached to the molded aluminum composite panel 3 to the coupling bracket 160 fixed to the support 140 is a coupling bracket to the left or right end of the panel bracket 110 The upper half and the lower half of the'ㅏ'-shaped coupling protrusion 115 of the panel bracket 110 slide to the right or left while being positioned at the right end or the left end of the 160, respectively, the upper sliding of the upper coupling bracket 160A It is made by being inserted into the coupling groove (161a) and the lower sliding coupling groove (164a) to engage.

Therefore, in the present invention, the panel bracket 110 and the coupling bracket 160 can be combined in a one-touch manner by sliding coupling without going through the fastening process of a direct screw using an electric driver that had to go through the prior art. ) And the coupling bracket 160 can be quickly and conveniently performed.

In addition, since the panel bracket 110 is slidingly coupled to the panel bracket 110 and the coupling bracket 160 without coupling the panel bracket 110 to the support 40 by a direct screw, the gap between the molded aluminum composite panels 3 is reduced. It can be minimized, and the fastening member such as a direct connection type screw is not exposed to the front, so that the appearance can be finished beautifully.

12 to 16 show a third preferred embodiment of the rail-type seismic installation structure of the composite panel according to the present invention.

The rail-type seismic installation structure of the composite panel according to the present embodiment includes a composite panel body portion 3a having a predetermined width and height, and a bent portion 3b bent at four edges of the composite panel body portion 3a to A plurality of molded aluminum composite panels (3) formed in a low box shape; A pair of upper and lower panel brackets 10 which are symmetrically attached to the upper and lower portions on the rear surface of each of the molded aluminum composite panels 3; A packing (20) coupled to the panel bracket (10) and having a front surface facing the rear surface of the panel body (3a); A double-sided tape 30 for attaching the front surface of the panel bracket 10 and the front surface of the packing 20 to the rear surface of the panel body 3b; It includes a; a plurality of wall brackets 150; the rear end is fixed to the wall of the building and the panel bracket 10 is coupled to the front end.

In this embodiment, the wall bracket 150 is different, the support 40 is not used, and the panel bracket 10 is directly slidingly coupled to the wall bracket 150, and the molded aluminum composite panel 3 and The panel bracket 10, the packing 20, and the double-sided tape 30 are the same as those of the first embodiment described above.

The upper and lower pair of panel brackets 10 are extruded from a metal material, and are located in a corner between the composite panel body 3a and the upper and lower bent parts 3b of the molded aluminum composite panel 3 A packing coupling part 11 formed in a'c' shape having a packing groove 11a opened toward the rear of the part 3a, and toward the opposite direction of the corner part at the front end of the packing coupling part 11 A panel coupling piece 12 extending vertically and facing the rear surface of the molded aluminum composite panel 3, an elastic connecting piece 13 extending rearward from the rear end of the packing coupling portion 11, and the It is integrally formed at the rear end of the elastic connecting piece 13 and includes a sliding coupling portion 14 having a'ㅓ'-shaped sliding coupling groove 14a which is coupled to the wall bracket 150 in a lateral sliding manner.

The packing coupling portion 11 is formed with a separation preventing protrusion 11b for preventing separation of the packing 20 on the lower surface of the ceiling and the upper surface of the floor of the packing groove 11a.

The panel bracket 10 attached to the upper rear surface of the molded aluminum composite panel 3 is disposed such that the packing coupling portion 11 is positioned at the upper portion and the panel coupling piece 12 is positioned at the lower portion, and the molded aluminum composite panel ( The panel bracket 10 attached to the lower rear surface of 3) is disposed such that the packing coupling part 11 is located at the lower side and the panel coupling piece 12 is located at the upper part.

The elastic connecting piece 13 elastically connects the packing coupling part 11 and the sliding coupling part 14 to reduce the transmission of vertical vibration between the packing coupling part 11 and the sliding coupling part 14 Will do.

The sliding coupling groove (14a) is composed of a vertical portion formed on the front side, and a horizontal portion that is open to the rear by communicating with the middle portion of the vertical portion.

The packing 20 is formed in an approximately rectangular cross section, and a separation prevention groove 21 into which the separation prevention protrusion 11b is inserted is formed on an upper surface and a lower surface.

The double-sided tape 30 is a height at which the front of the packing coupling part 11, the panel coupling piece 12, and the packing 20 can be attached to the rear surface of the panel body part 3b of the molded aluminum composite panel 3 Consists of

The wall bracket 150 is formed of carbon fiber reinforced plastic (CFRP), is parallel to the building wall, and is fixed to the building wall with anchor bolts (Ba) and anchor nuts (Na). 151, the left-right elastic portion 152 formed integrally at one end of the wall fixing portion 151 and extending vertically toward the front, and integrally formed at the front end of the left-right elastic portion 152 A first wall bracket 150A consisting of a first vertical coupling portion 153 disposed vertically, and a second wall bracket 150A formed of carbon fiber reinforced plastic, and spaced forward with respect to the first vertical coupling portion 153 The vertical coupling portion 154 and the vertically extending elastic portion 155 formed integrally in the left and right middle portion of the second vertical coupling portion 154 and extending horizontally toward the front, and the vertical elastic portion 155 ) Is integrally formed at the front end of the vertical plate 156, and is integrally formed on the front surface of the vertical plate 156, and slides from the side in the'ㅓ'-shaped sliding coupling groove 14a of the sliding coupling part 14 It is disposed horizontally between the second wall bracket 150B consisting of a'ㅓ'-shaped sliding coupling protrusion 157 that is coupled in a manner, and the first vertical coupling portion 153 and the second vertical coupling portion 154 A plurality of compression coil springs (SP) that imparts an elastic force in the forward and backward directions, and a plurality of passing through the first vertical coupling part 153 and the second vertical coupling part 154 and passing through the compression coil spring (SP) Two screw rods SR, a first nut N3 fastened to the rear end of the screw rod SR to be in close contact with the rear surface of the first vertical coupling part 153, and a front end of the screw rod SR. It includes a second nut (N4) fastened to the front surface of the second vertical coupling part 154.

The first wall bracket 150A is buried and fixed to the wall of the building, and the anchor bolt (Ba) passing through the wall fixing part 151 from the rear to the front, and the anchor nut (Na) fastened to the anchor bolt (Ba). It is fixed to the wall of the building.

The compression coil spring (SP) tightens the first and second nuts (N3, N4) fastened to the front and rear ends of the plurality of screw rods (SR) passing through the first and second vertical coupling portions (153, 154). The compression coil spring (SP) is installed in a compressed state in an intermediate state between the free state and the maximum compressed state, and when vibration acts in a direction close to each other between the first and second wall brackets 150A, 150B. It is configured to attenuate the vibration while being compressed, and if the vibration acts in a direction away from each other, the compression coil spring (SP) is elongated to attenuate the vibration.

In the illustrated example, the wall bracket 150 is shown to be installed one at the top and bottom for one molded aluminum composite panel 3, but two or more may be installed depending on the size of the molded aluminum composite panel 3 will be.

Hereinafter, the operation of the rail-type seismic installation structure of the composite panel according to the present embodiment will be described.

The installation process of the rail-type seismic installation structure of the composite panel according to the present embodiment includes the step of coupling the packing 20 to the panel bracket 10 (see FIG. 13), and the panel bracket 10 is molded aluminum composite panel 3 ), attaching the wall bracket 150 to the building wall (see FIG. 15), and attaching the panel bracket 10 attached to the molded aluminum composite panel 3 to the wall bracket ( 150) and side-sliding coupling (see Fig. 16).

The step of coupling the packing 20 to the panel bracket 10 is performed by pushing one end of the packing 20 from one end of the packing coupling groove 11a of the packing coupling portion 11 of the panel bracket 10.

At this time, the separation prevention protrusion 11b of the packing coupling part 11 and the separation prevention groove 21 of the packing 20 are engaged so that the packing 20 does not deviate arbitrarily from the packing coupling groove 11a.

In the step of attaching the panel bracket 10 to the molded aluminum composite panel 3, the front surface of the packing joint 11 of the panel bracket 10, the front surface of the panel attachment part 12, and the front surface of the packing 20 are formed. It can be attached to the rear surface of the body portion (3a) of the aluminum composite panel (3) by a double-sided tape (30).

In other words, after attaching the front of the double-sided tape 30 to the upper and lower rear of the main body 3a, the front and the front of the packing coupling 11 of the panel bracket 10 and the front of the panel attachment 12 By attaching the front side of the packing 20 to the rear side of the double-sided tape 30, the panel bracket 10 can be attached to the rear side of the main body 3a.

Therefore, in the present invention, in the step of attaching the panel bracket 10 to the molded aluminum composite panel 3, a plurality of rivet holes (H1, H2) for the bent portion 3b and the panel bracket body 4a, which were required in the prior art. A panel bracket (10) using a double-sided tape (30) without going through the process of drilling the rivet and passing the rivet (R) through the rivet holes (H1, H2) using a rivet gun and forming the head at both ends. ) Can be attached to the molded aluminum composite panel 3, it is possible to quickly and conveniently perform the joining operation of the panel bracket 10 to the molded aluminum composite panel 3.

At this time, the panel bracket 10 attached to the upper rear side of the main body 3a is positioned at a corner between the rear side of the main body 3a and the lower surface of the upper bent part 3b, and the packing coupling part 11 The front side of the body part 3a is attached to the rear side of the body part 3a, and the panel bracket 10 attached to the lower side of the back side of the body part 3a is between the back side of the body part 3a and the upper surface of the lower bent part 3b. It is positioned in the corner, and the front of the panel bracket 10 is attached to the rear of the main body 3a.

In addition, the upper surface of the packing coupling part 11 of the panel bracket 10 attached to the upper rear side of the main body 3a is not in close contact with the lower surface of the upper bent part 3b, but is spaced apart, and the rear surface of the main body 3a The lower surface of the packing coupling part 11 of the panel bracket 10 attached to the lower side is not in close contact with the upper surface of the lower bent part 3b, but is spaced apart, so that between the molded aluminum composite panel 3 and the panel bracket 10 Vibration transmission can be attenuated by the packing 20 and the double-sided tape 30.

In the step of fixing the wall bracket 150 to the building wall, the anchor bolts (Ba) are installed on the building wall to protrude, and the first wall bracket (150A) and the second wall bracket (150A) are equal to the anchor bolts (Ba) located at the top and bottom. The wall bracket 150 is located in the upper and lower parts by placing the wall bracket 150 in which the wall bracket 150B, the compression coil spring (SP), the screw rod (SR), and the first and second nuts (N3, N4) are pre-assembled. ) To the wall fixing portion 151 of the anchor bolt (Ba) to protrude toward the front, it is made by fastening the anchor nut (Na) to the protruding anchor bolt (Ba).

At this time, the first wall bracket 150A constituting the wall bracket 150 includes an elastic part 152 in the left and right direction, and the second wall bracket 150B includes an elastic part 155 in the vertical direction, and the first wall The bracket 150A and the second wall bracket 150B are elastically coupled in the front and rear direction by means of a compression coil spring (SP), a screw bar (SR), and first and second nuts (N3, N4). Therefore, against the vibration applied to the wall of the building due to earthquake, the left and right elastic parts 152 attenuate the left and right vibration, and the vertical elastic part 155 attenuates the vertical vibration, and the compression coil spring and The threaded rod SR and the first and second nuts N3 and N4 are capable of attenuating the vibration in the front and rear directions, thereby exhibiting a seismic effect.

In addition, since the first wall bracket 150A and the second wall bracket 150B are formed of carbon fiber reinforced plastic, which has higher strength and higher elasticity than metal materials, the elastic parts 152 in the left and right directions and the elastic parts in the vertical direction 155 It is possible to increase the vibration damping effect.

The step of slidingly coupling the panel bracket 10 attached to the molded aluminum composite panel 3 to the wall bracket 150 fixed to the building wall includes the left end or the right end of the panel bracket 10 as the wall bracket 150. It is achieved by pushing the'ㅓ'-shaped coupling groove (14a) of the panel bracket (10) and the'ㅓ'-shaped sliding coupling protrusion (157) by pushing it to the right or to the left while being positioned at the right or left end of the panel. Lose.

Therefore, in this embodiment, the panel bracket 10 and the wall bracket 150 can be combined in a one-touch manner by sliding coupling without going through the process of fastening a direct screw using an electric driver that had to go through the prior art. (10) It is possible to quickly and conveniently perform the coupling operation of the wall bracket 150.

In addition, since the panel bracket (10) fixed to the molded aluminum composite panel (3) is directly slidingly coupled to the wall bracket (150) fixed to the building wall without using a separate support, the construction can be performed more quickly and easily. You will be able to.

In addition, since the panel bracket 10 and the wall bracket 150 are slidably coupled without coupling the panel bracket 10 to the support by a direct screw, the gap between the molded aluminum composite panels 3 can be minimized. In addition, a fastening member such as a direct connection type screw is not exposed to the front so that the appearance can be finished beautifully.

The present invention is not limited to the technical spirit and scope by the above-described embodiments, and a person of ordinary skill in the art to which the present invention pertains will be able to make various modifications and variations without departing from the technical spirit and scope of the present invention. , These modifications and variations should be construed as belonging to the scope of the present invention.

3: molded aluminum composite panel 3a: body part
3b: bent portion 10: panel bracket
20: packing 30: double-sided tape
40: support 50: wall bracket
50A: 1st wall bracket 50B: 2nd wall bracket
60: coupling bracket 110: panel bracket
140: support 150: wall bracket
160: coupling bracket

Claims (1)

A composite panel body portion 3a having a certain width and height, and a plurality of molded aluminum composite panels formed in a box shape with a low depth by bending a bent portion 3b at four edges of the composite panel body portion 3a. 3) and; A pair of upper and lower panel brackets 10 which are symmetrically attached to the upper and lower portions on the rear surface of each of the molded aluminum composite panels 3; A packing (20) coupled to the panel bracket (10) and facing the rear surface of the composite panel body (3a); A double-sided tape 30 for attaching the front surface of the panel bracket 10 and the front surface of the packing 20 to the rear surface of the composite panel body 3a; A plurality of supports 140 disposed horizontally on the wall of the building at a constant height interval; A plurality of wall brackets 50 having the rear end fixed to the wall of the building and to which the support 140 is coupled to the front end; The rear end is fixed to the support 140 and the front end is coupled to the panel bracket 10, the coupling bracket 160; comprises a,
The upper and lower pair of panel brackets 10 are extruded from a metal material, and are located in a corner between the composite panel body 3a and the upper and lower bent parts 3b of the molded aluminum composite panel 3 A packing coupling part 111 formed in a'c' shape having a packing groove 111a opened toward the rear of the part 3a, and toward the opposite direction of the corner part at the front end of the packing coupling part 111 A panel coupling piece 112 extending vertically and facing the rear surface of the molded aluminum composite panel 3, an elastic connecting piece 113 extending rearward from the rear end of the packing coupling portion 111, and the Consisting of a vertical portion 114 integrally formed at the rear end of the elastic connecting piece 113 and bent vertically, and a'ㅏ'-shaped sliding coupling protrusion 115 integrally formed on the rear surface of the vertical portion 114 Become,
The packing coupling part 111 is formed with a separation preventing protrusion 111b for preventing separation of the packing 20 on the lower surface of the ceiling and the upper surface of the floor of the packing groove 111a,
The packing 20 is formed in an approximately rectangular cross section, and a separation prevention groove 21 into which the separation prevention protrusion 111b is inserted is formed on the top and bottom surfaces,
The double-sided tape 30 is a height at which the front of the packing coupling part 11, the panel coupling piece 12, and the packing 20 can be attached to the rear surface of the panel body part 3b of the molded aluminum composite panel 3 Consists of,
The support 140 is formed of a square pipe having a front and rear plate and an upper and lower plate by extrusion molding of a metal material, and a coupling bracket corresponding to the panel bracket 10 attached to the lower portion of the molded aluminum composite panel 3 installed on the upper side The coupling bracket 160 corresponding to the panel bracket 10 attached to the upper portion of the molded aluminum composite panel 3 installed on the lower side is configured to have a height at which the coupling bracket 160 can be coupled to the lower side,
A plurality of rectangular coupling holes 141 are formed in the front plate of the support 140,
The wall bracket 50 is formed of carbon fiber reinforced plastic (CFRP), is parallel to the building wall, and is fixed to the building wall with anchor bolts (Ba) and anchor nuts (Na). 51), and a left and right elastic portion 52 formed integrally at one end of the wall fixing portion 51 and extending vertically toward the front, and integrally formed at the front end of the left and right elastic portion 52 A first wall bracket (50A) consisting of a first vertical coupling portion (53) disposed vertically, and a second wall bracket (50A) formed of carbon fiber reinforced plastic, and spaced apart from the first vertical coupling portion (53). The vertical coupling part 54 and the vertical coupling part 54 are formed integrally in the middle part in the left and right directions of the second vertical coupling part 54 and extended horizontally toward the front to the vertical elastic part 55 coupled to the support 40. A second wall bracket (50B) and a plurality of compression coil springs (56) disposed horizontally between the first vertical coupling portion (53) and the second vertical coupling portion (54) to provide an elastic force in the front and rear directions, and , A plurality of screw rods 57 passing through the first vertical coupling portion 53 and the second vertical coupling portion 54 and passing through the compression coil spring 56, and the screw rod 57 The first nut 58 is fastened to the rear end and is in close contact with the rear surface of the first vertical coupling part 53, and is fastened to the front end of the screw rod 57 so as to be in close contact with the front of the second vertical coupling part 54 It is configured to include a second nut (59),
The first wall bracket (50A) is buried and fixed to the wall of the building, and the anchor bolt (Ba) passing through the wall fixing part 51 from the rear to the front, and the anchor nut (Na) fastened to the anchor bolt (Ba). It is fixed to the wall of the building by
The second wall bracket 50B is formed by a coupling bolt (B1) penetrating the vertical elastic portion 55 and the support 140 in the vertical direction, and a coupling nut (N1) fastened to the coupling bolt (B1). It is fixed to the support 140,
The compression coil spring 56 tightens the first and second nuts 58 and 59 that are fastened to the front and rear ends of the plurality of threaded rods 57 passing through the first and second vertical coupling portions 53 and 54. The compression coil spring 56 is installed in a compressed state in an intermediate state between the free state and the maximum compressed state, and when vibration acts in a direction closer to each other between the first and second wall brackets 50A, 50B. It is configured to attenuate the vibration while being compressed, and when the vibration acts in a direction away from each other, the compression coil spring 56 is elongated to attenuate the vibration,
The coupling bracket 160 is extruded from a metal material, and the upper sliding coupling portion 161 having an upper sliding coupling groove 161a into which the upper half of the'ㅏ'-shaped sliding coupling protrusion 115 of the panel bracket 110 is inserted. ), and an upper connecting piece 162 extending rearward from the rear end of the upper sliding connecting portion 161, and integrally formed at the rear end of the upper connecting piece 162, and a rectangular connecting hole 141 of the support 140 An upper coupling bracket 160A including an upper inclined guide surface 163a in contact with the upper edge of the support base 140 and an upper hook protrusion 163 having an upper engaging protrusion 163b caught on the rear surface of the front plate of the support 140; A lower sliding coupling part 164 which is extruded from a metal material and having a lower sliding coupling groove 164a into which the lower half of the'ㅏ'-shaped sliding coupling protrusion 115 of the panel bracket 110 is inserted, and the lower sliding coupling The lower connecting plate 165 extending from the rear end of the part 164 to the rear, is integrally formed at the rear end of the lower connecting plate 165 and integrally formed at the rear end of the lower sliding coupling part 164 and the support Includes a lower hook protrusion 166 having a lower inclined guide surface (166a) in contact with the lower edge of the rectangular coupling hole (141) of 140 and a lower engaging protrusion (166b) that is caught on the rear of the front plate of the support (140) A lower coupling bracket 160B; Rail-type seismic installation structure of a composite panel, characterized in that it comprises an elastic rubber (160C) coupled between the lower surface of the upper hook protrusion (163) and the upper surface of the lower hook protrusion (166).

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