KR101197491B1 - Filler panel - Google Patents

Abstract

The present invention discloses a filler panel, wherein the filler panel is disposed between the slab panels, a frame having an upper surface having an open rectangular lower portion and having an inner frame connecting the lower long sides; And a pillar bracket coupled to an upper portion of the inner frame of the frame and hinged to an end of a slab panel support beam for supporting the slab panels adjacent to each other in the long side direction of the frame. The inner frame includes a pair of beams in which first bolt holes are formed at symmetrical positions.

Description

Filler panel

The present invention relates to a filler panel, and more particularly to a filler panel disposed between the slab panel and coupled to the slab panel support beam.

In order to construct a multi-layer concrete structure, wall formwork is made, and a plurality of slab panels are horizontally installed on the wall formwork, and then concrete is poured, and such construction is repeated to construct a multi-layer concrete structure.

The slab panel should be installed at a certain height corresponding to the ceiling height of the concrete structure, so it should be robust, easy to install, and easy to dismantle after pouring concrete. In addition, the device system for the installation and disassembly of the slab panel needs a simple structure so that any worker can be easily installed and dismantled, and the time required for installation and dismantling is small.

Korean Registered Utility Model Publication No. 20-0439291 discloses a connector for connecting a wall formwork and a tech support bar. In addition, Korean Patent Publication No. 10-0202049 discloses a ceiling plate system. In addition, Korean Patent Publication No. 10-0812551 discloses a slab formwork support bar that is easy to dismantle.

However, the structure of the members for supporting the slab panel is complicated, the installation and disassembly of the slab panel is not only easy, but also takes a lot of time, the complex structure has the disadvantage that the manufacturing cost increases.

In addition, the Korean Patent Application No. 10-2009-0078517 by the applicant of the "apparatus system for the installation and disassembly of the slab panel" has been disclosed, but the development of a system that can be installed and dismantled slab panel in a simpler way It is hoped.

The problem to be solved by the present invention is to provide a filler panel that can be used to install the slab panel more conveniently.

The slab panel assembly according to the present invention, the slab corner is coupled to the top of the wall formwork and the corner bracket is inserted, the filler panel is disposed at a position spaced apart from the slab corner and the filler bracket is installed at the bottom, the slab corner and the filler panel The slab panels disposed between the slab corners and the filler panel support the slab panels and the tie beams connected to the drop beams and the tie rods connected to the drop beams to the outer wall. A drop assembly including a pivot pipe which is pivotally coupled to the tie rod and is movable, and a spindle nut screwed with the tie rod to regulate movement of the pivot pipe, is installed in both ends of a longitudinal direction and is disposed at both ends of the drop assembly. The slab corner brackets are respectively And a hinge coupled to the filler bracket and separating the main pin while supporting the slab panel on the upper side, the tie rod is pivoted by the hinge coupling of the drop beam, and is pivoted to the pivot pipe which is moved along the pivoted tie rod. The slab panel is characterized in that it comprises a slab panel support beam for lowering the slab panel.

Filler panel used to arrange the slab panels arranged horizontally according to the present invention, the frame is disposed between the slab panels and has an upper frame having an upper surface having an open bottom and having an inner frame connecting between the long sides of the lower, And a pillar bracket coupled to an upper portion of the inner frame of the frame and hinged to an end of the slab panel support beam for supporting the slab panels adjacent to each other in the long side direction of the frame.

Herein, the inner frame of the frame may include a pair of beams in which first bolt holes are formed at symmetrical positions.

In addition, the filler bracket includes second bolt holes corresponding to the first bolt holes formed in the beam of the inner frame to penetrate the first and second bolt holes, and end portions of the first bolts. As long as the first assembly is coupled to the inner frame by a first nut coupled to the first hinge portion and the first hinge hole inclined to the side extending from the first assembly portion includes a first hinge portion formed for the hinge coupling. A pair of first bracket plates, and a first hinge pin is inserted into the first hinge hole facing each other so that the end of the slab panel support beam is fastened to the first hinge pin to achieve the hinge coupling.

The filler bracket may include pillar units installed at both ends of the inner frame, and the pillar unit may include third bolt holes corresponding to the first bolt holes formed in the beam of the inner frame. The second assembly part coupled to the inner frame by the second bolt penetrating the first and third bolt holes and the second nut coupled to the end of the second bolt and the second assembly part, The second hinge hole extending inclined in the end direction and inclined in the extended direction includes a pair of second bracket plates including a second hinge portion formed for the hinge coupling, and the second hinge hole facing each other includes a second hinge plate. 2 hinge pins may be inserted so that the end of the slab panel support beam is fastened to the second hinge pins to achieve the hinge coupling.

The slab panel support beam according to the present invention includes a drop beam hinged to the bracket, and a tie rod having a screw formed on an outer surface thereof is coupled to the opposite side to be hinged to the drop beam and guided to the tie rod of the drop beam. The first and second drop assemblies including the pivot pipe, the movement of the movement on the tie rod is controlled by the adjustment of the spindle nut screwed to the rod, the first and second drop assemblies are respectively configured therein and whether the main pin is coupled The first and second drop assemblies may be coupled to or disassembled, and pivoted by the pivot pipe and the pivot pin, and a first open area may be formed on an upper surface to ensure rotation of the drop beam by the pivot coupling. The second open area is formed on the bottom to ensure the rotation of the pivot pipe and the tie rod by the pivot coupling A first and a second main beam, a middle beam disposed between the first and second main beams symmetrically arranged in opposite directions, a first coupling member and the middle for coupling the middle beam and the first main beam And a second coupling member coupling the beam to the second main beam, wherein the main pin includes the first drop assembly and the first main beam, and the second drop assembly and the second pin assembly to support the slab panel. When the main pin is disassembled to disassemble the slab panel on the upper side and penetrate the second main beam, respectively, the pivot pipe which is pivotally coupled supports the slab panel on the upper side by adjusting the spindle nut. Guided to the rod can be lowered.

The first and second drop assemblies may include a main pin groove into which a main pin is inserted into a side of the first and second drop assemblies, the hook being hinged to the bracket and formed at an end thereof and having a space recessed downward on the opposite side where the hook is formed. A hook locker which can be switched to a released and locked state by being rotated on a side of the drop beam, and the hook of the drop beam supporting the lower portion of the drop beam coupled to the bracket in the locked state; The tie rod coupled in the longitudinal direction opposite to the hook is formed, coupled with the tie rod is guided in movement and the pivot pin is located in the recessed space of the drop beam while pivoting the first and second main beams. Washers and spindles which are screwed into the pivot pipe and the tie rod to be coupled to control the movement of the pivot pipe. It may include a bit.

The first and second main beams have a space having a rectangular cross section to accommodate the first and second drop assemblies, and main pin grooves through which the main pins are inserted are inserted into both side surfaces of the position where the drop beams are installed. Pivot pin holes are formed on both sides of the pivot pipe corresponding to the position of the pivot pin of the pivot pipe, and a first open area is formed on the upper surface to ensure rotation of the drop beam, thereby ensuring rotation of the pivot pipe and the tie rod. A second open area may be formed on the bottom surface.

The first coupling member may include a first internal connector commonly inserted in the first main beam and the middle beam, and first external connectors in contact with both side walls of the first main beam and the middle beam. A first bolt is fastened by a first connecting hole penetrating the first external connectors, the first internal connector, and the first main beam, and the second external connectors, the first internal connector, and the A second connecting hole penetrating the middle beam may be formed to fasten the second bolt.

The second coupling member may include a second internal connector commonly inserted into the second main beam and the middle beam, and second external connectors contacting both sidewalls of the second main beam and the middle beam. And a third bolt is formed through the second external connectors, the second internal connector, and the second main beam, and a third bolt is fastened, and the second external connectors, the second internal connector, and the A fourth connecting hole penetrating the middle beam may be formed to fasten the fourth bolt.

Drop assembly according to the present invention, the hook is hinged to the bracket is formed on the end of the drop beam having a space recessed downward on the opposite side formed with the hook is formed a main pin groove into which the main pin is inserted, the drop It can be switched to the unlocked and locked state by being rotated on the side of the beam, a hook locker for supporting the lower portion in which the hook of the drop beam is coupled to the bracket in the locked state, a screw is formed on the outer surface of the drop beam A tie rod coupled in the longitudinal direction to the opposite side of the hook is formed, coupled to the tie rod is guided to move and a pivot pin is located in the recessed space of the drop beam and the pivot pin pivotally engages with the main beam forming the outer wall Washer and spindle nut screwed with pivot pipe and tie rod to control movement of pivot pipe It characterized in that it comprises.

The filler panel, the slab channel support beam, the drop assembly, and the slab panel assembly including the same according to the present invention have a simple and robust structure, easy installation of the slab panel, and easy disassembly of the slab panel after pouring concrete. There is this.

In addition, the filler panel, the slab channel support beam, the drop assembly, and the slab panel assembly including the same have a simple structure and can be easily installed and dismantled by anyone, requiring little time for installation and dismantling, and safety according to work. There is an effect that can significantly reduce the risk of accidents.

1 is an assembly view showing a preferred embodiment of a slab panel assembly according to the present invention.
2 is a perspective view of a filler panel.
3 is a cross-sectional view illustrating a state in which the filler panel is assembled as shown in FIG. 1.
Figure 4 is a perspective view showing an embodiment of a filler bracket installed on the lower portion of the filler panel.
5 is an exploded perspective view of the filler bracket of FIG. 4.
6 is a perspective view illustrating the hinge pin.
7 is an exploded perspective view illustrating a state in which an inner frame and a filler bracket of a lower filler panel are coupled to each other.
8 is a perspective view as viewed from the bottom of the filler panel is coupled to the filler bracket of FIG.
9 is a perspective view illustrating another embodiment of a filler bracket installed on a lower portion of a filler panel.
10 is an exploded perspective view of the pillar bracket of FIG. 9.
FIG. 11 is an exploded perspective view illustrating a state in which an inner frame and a filler bracket of a lower filler panel are coupled.
12 is a perspective view as viewed from the bottom of the filler panel is coupled to the filler bracket of FIG.
FIG. 13 is a perspective view of the slab corner installed in FIG. 1. FIG.
14 is a perspective view of a corner bracket installed in the slab corner of FIG.
FIG. 15 is a perspective view of the slab panel support beam installed in FIG. 1. FIG.
16 is an exploded perspective view of the slab panel support beam of FIG. 15.
17 is an exploded perspective view illustrating the structure of the main beam of FIG. 15.
18 is a perspective view illustrating a state in which the drop assembly installed in FIG. 15 is coupled to a corner bracket.
FIG. 19 is a perspective view illustrating the drop assembly of FIG. 18. FIG.
20 is a cross-sectional view illustrating a state in which the drop assembly of FIG. 19 is installed in the slab panel support beam of FIG. 15.
FIG. 21 is a partial cross-sectional view illustrating a state in which the drop beam of the drop assembly of FIG. 18 is hinged by a hook locker.
FIG. 22 is a partial cross-sectional view illustrating a state in which the hook locker is released to the drop beam of the drop assembly of FIG. 18.
23 to 26 are views for explaining a procedure of disassembling the slab panel.
27 is a perspective view illustrating a state in which a vertical support for supporting a slab corner installed on a wall is installed.
28 is an exploded perspective view of the vertical support of FIG. 27.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the following embodiments are provided to those skilled in the art to fully understand the present invention, and may be modified in various forms, and the scope of the present invention is limited to the embodiments described below. It doesn't happen. Wherein like reference numerals refer to like elements throughout.

1 is an assembly view showing a preferred embodiment of the slab panel assembly according to the present invention, the slab corner 12 is coupled to the top of the wall formwork and the corner bracket 10 is installed and spaced apart from the slab corner 12 A filler panel 16 disposed between the slab panel 12 and the slab corner 12 and the filler panel 16 to form a ceiling formwork, and a slab panel support beam 20) is configured.

Here, the filler panel 16 may be arranged and used in the longitudinal direction, and the panel prop head 22 may be disposed therebetween, and the panel prop head 22 or the filler panel 16 may be fastened. It may optionally be supported by a vertical support 26 with the device 24. In addition, the filler panel 16 is not assembled using the panel-type prophead 22 or the filler panel 16 is manufactured in one piece according to the intention of the manufacturer, and thus the slab panel is manufactured. It may be used between the fields 18.

The position of installing the vertical support 26 may be selected in consideration of the load by the manufacturer, the vertical support 26 may be adjusted by the height of the vertical support by the fastening device 24 configured on the top, At this time, the fastening device 24 may be used to adopt a conventional pin coupling method or a rotary tightening method.

In addition, a filler panel 28 having no filler bracket 14 at the lower portion may be further disposed between the slab panels 18 according to the needs of the manufacturer, and the filler panel 28 is disposed with the slab panel 18. If the space does not fit the predesigned slab panel can be used for the buffer thereof.

The slab panel support beam 20 is installed between the slab corner 12 and the filler panel 16 arranged in the longitudinal direction.

Here, referring first to the configuration of the filler panel 16 with reference to FIG. 2, the filler panel 16 has an upper surface 30 and forms an open rectangular lower body and connects the inner side of the lower sides 32. (See FIG. 8) and a slab for fastening the upper part of the frame 34 and the inner frame 32 of the frame 34 and both sides of the slab panels 18 adjacent to each other in the longitudinal direction of the frame. A pillar bracket 14 is hinged to the end of the panel support beam 20 (see FIG. 1).

A more detailed configuration of the filler panel 16 will be described with reference to FIGS. 3 to 12, and FIGS. 3 to 12 illustrate a first embodiment of the filler bracket 14, and FIG. 9. 12 illustrate a second embodiment of the filler bracket 14. Here, the first embodiment of the pillar bracket 14 is an example of the hinge structure of both sides formed integrally when the width is narrow, the second embodiment of the pillar bracket 14 is a hinge structure of both sides when the width is wide This is an example of what is divided into two pillar units (40).

First, the filler bracket 14 of the pillar panel 16 has an assembly portion 36 and a hinge portion 38, and the assembly portion 36 is installed inside the lower portion of the filler panel 16 as shown in FIG. The hinge portion 38 is hinged to the drop beam 50 of the slab panel support beam 20 supporting the slab panel 18 upward.

First, the configuration of the filler bracket 14 configured as the first embodiment will be described with reference to FIGS. 4 to 8.

The filler bracket 14 includes a pair of bracket plates 60, each bracket plate 60 including an assembly portion 36 and a hinge portion 38, and the assembly portion 36 includes a frame 34. Bolt holes 62 corresponding to the bolt holes 33 formed in the beam of the inner frame 32 of the fixing bolt 64 and the end of the bolt 64 passing through the bolt holes 33 and 62 are formed. It is coupled to the inner frame 32 by a nut 65 coupled to it. Then, the hinge portion 38 is provided with a hinge hole 66 is formed to be inclined to the side extending extending from the assembly portion 36 for the hinge coupling.

Here, a hinge pin 68 is inserted into the hinge hole 66 formed on the pair of bracket plates 60 to face each other, and a drop beam at the end of the slab panel support beam 20 is inserted into the hinge pin 68. 50 is fastened.

In addition, the pair of bracket plates 60 may be configured to be coupled to the vertical plate 70 and the lower bracket base 72 so that the separated distances may be maintained, and the hinge pin 68 may have a pin head 76. ) And a pinhole 77 are configured at both ends, and the pin 78 may be inserted into the pinhole, and the washer 79 may be coupled to the inside of the pinhole.

The filler bracket 14 according to the first embodiment described above may be coupled to the inner frame 32 of the filler panel 16 as shown in FIG. 8 in a state in which the filler bracket 14 is arranged as shown in FIG. 7.

On the other hand, the configuration of the filler bracket 14 configured in the second embodiment will be described with reference to FIGS. 9 to 12.

The pillar bracket 14 of the second embodiment includes pillar units 40a and 40b respectively installed at both ends of the inner frame 32, and each pillar unit 40a and 40b has a pair of bracket plates 60a and 60b. ).

Each bracket plate 60a, 60b includes assembly parts 36a, 36b and hinge parts 38a, 38b, and the assembly parts 36a, 36b are bolted holes 33 formed in the beam of the inner frame 32. Bolt holes 62a and 62b corresponding to the grooves are formed, and the bolts 64a and 64b passing through the bolt holes 33 and 62a and 33 and 62b are coupled to ends of the bolts 64a and 64b. It is coupled to the inner frame 32 by the 65a, 65b, the hinge portion 38a, 38b extends while inclined in the end direction of the inner frame 32 to the assembly portion (36a, 36b) in an extended direction Inclined hinge holes 66a and 66b are formed for hinge coupling. Here, hinge pins 68a and 68b are inserted into the hinge holes 66a and 66b facing each other so that the ends of the slab panel support beam 20 are fastened to the hinge pins 66a and 66b to form a hinge coupling.

In addition, the pair of bracket plates 60a and 60b may be configured to be coupled to the connecting plates 74a and 74b so that the separated distances may be maintained, and the connecting plate 74 may be disposed between the bracket plates 60a and 60b. Arranged in the horizontal direction or inclined direction may be coupled to the bracket plate (60a, 60b) of a pair of adjacent hinge pins, the coupling between them may be made by a welding method.

The plug bracket 14 according to the second embodiment described above may be coupled to the inner frame 32 of the pillar panel 16 as shown in FIG.

On the other hand, Figure 13 is a perspective view of the slab corner 12 is provided with a corner bracket 10 is coupled to the drop beam 50 of the slab panel support beam 20 according to the present invention, the corner bracket 10 is a slab corner ( It is installed by bolting in the channel formed in 12). Corner bracket 10 has a configuration as shown in FIG. One end of the corner bracket 10 is inserted into and coupled to the inner circumferential surface of the slab corner 12, and the other end protrudes into the opening of the slab corner 12. Corner bracket 20 is inserted into the inner peripheral surface of the slab corner 12 is fixed by the bracket for adjusting the upper and lower brackets (26). The hook 52 of the drop beam 50 is coupled so as to span the round bar-shaped engaging bar 10a of the corner bracket 10 protruding into the opening of the slab corner 12, and inserted into the slab corner 12, respectively. The corresponding pair of corner brackets 10 are installed to face each other. The corner bracket 10 is provided with a locking bar 10a, and has a diagonal guide channel 10b for providing a path through which the locking bar 10a is moved. The guide channel 10b has a structure which penetrates diagonally through two opposing flat plates 10c protruding from the opening of the slab corner 12, and the two opposing flat plates 10c are joined by a welding or coupling member or the like. .

The slab panel support beam 20 may be described with reference to FIGS. 15 and 16. The main beam 110 included in the slab panel support beam 20 may be described with reference to FIG. 17, and the drop assembly 120 is coupled to the corner bracket 10 with reference to FIGS. 18 and 19. The state in which the drop assembly 120 is installed in the main beam 110 may be described with reference to FIG. 20.

The slab panel support beam 20 supports the slab panels 18 upward between the slab corner 12 and the filler panel 16, and includes a drop assembly 120, a main beam 110, and a middle beam 160. And a coupling member.

The main beam 110 has a drop assembly 120 is configured therein, each of which is coupled or disassembled with the drop assembly 120 depending on whether the main pin 100 is coupled to the main beam 110 by the pivot pipe 121 and the pivot pin 122. The first open area A is formed on the upper surface to pivot the drop beam 50 by the pivot coupling, and the pivot pipe 121 and the tie rod 123 rotate by the pivot coupling. In order to ensure a second open area (B) is formed on the bottom. The main beams 110 are symmetrically arranged at both ends in the longitudinal direction, and the drop assemblies 120 inside the main beams 110 spaced apart from each other are also symmetrically arranged as in the arrangement state of the main beams 110.

Referring to the drawings of FIG. 17, the main beam 110 has a structure in which two channels 112 are combined into one, and it is understood that the main beam 110 is illustrated as two channels 112 in FIG. 17. For the purpose of illustration only integrally formed may be configured.

The main pin hole 114a is formed at the side of the end of the main beam 110 where the drop beam 50 is disposed, and the pivot pin hole 116 is formed at the side corresponding to the area where the pivot pin 122 of the pivot pipe 121 is located. ) Is formed. In addition, two or more connecting holes 118 are formed at opposite ends of the main beam 110. The reinforcement patch 150 may be further coupled to the side surface on which the main pin hole 114a and the pivot pin hole 116 of the main beam 110 are formed, and the main pin hole 114a of the main beam 110 abuts on the reinforcement patch 150. ) And a main pin hole 114b and a pivot pin hole 116 corresponding to the pivot pin hole 116 may be formed, and the main pin 100 is coupled through the main pin holes 114a and 114b and pivot pipe 121 is formed. The pivot pin 122 is inserted through the pivot pin hole 116 of the main beam 110 and the reinforcement patch 150.

In addition, the middle beam 160 may be disposed between the main beams 110 arranged symmetrically in opposite directions as described above, and may be formed of a pipe having the same cross section as the cross section of the main beam 110, and the middle beams. Two or more connecting holes 162 are formed in the longitudinal sidewalls from which the main beam 110 continues.

The middle beam 160 may be fastened to both main beams 110 and the first and second coupling members, and the first and second coupling members include an inner connector 130 and an outer connector 140. In the internal connector 130 and the external connector 140, connecting holes 132 and 142 corresponding to the connecting holes 118 and 162 formed in the main beam 110 and the middle beam 160 are formed, respectively. The main beams 110 may be connected to both sides of the middle beam 160 by fastening bolts (not shown) through the connecting holes 118, 132, 162 and 142 corresponding to each other.

Here, the inner connector 130 may be composed of a pipe in which both ends are commonly inserted into the middle beam 160 and the main beam 110, and the outer connector 140 may be the main beam 110 and the middle beam. It may be composed of patches that are in common contact with both side walls of the (160).

Meanwhile, the drop assembly 120 installed on the main beam 110 includes a drop beam 50 hinged to the corner bracket 10 or the filler bracket 14 and a tie rod 123 having a screw formed on an outer surface thereof. On the tie rod 123 by adjusting the spindle nut 124 coupled to the hinge coupled opposite side of the drop beam 50 and guided to the tie rod 123 of the drop beam 50 and screwed to the tie rod 123. It includes a pivot pipe 121 in which movement is controlled.

More specifically, referring to FIGS. 18 and 19, the configuration of the drop assembly 120 includes a drop beam 50 having a hook 52 for hinge coupling formed at an end thereof and downwardly opposite to the hook 52. The main pin groove 114c into which the main pin 100 is inserted is formed at the side with the recessed space C. The recessed space C serves as a space in which the pivot pin 122 of the pivot pipe 121 is mounted.

In addition, the drop beam 50 has a structure in which the horizontal plane 56 is coupled between the vertical surfaces 54 which are symmetrical to each other, and the tie rod fixing bracket 59 may be installed between the vertical surfaces 54, and the tie rods. The fixing bracket 59 may be fixed by bolts or welding by inserting one end of the tie rod 123. In addition, the hook locker 58 is coupled to the outside of the vertical surface 54 of one surface of the drop beam 50.

The hook locker 58 can be switched to the unlocked and locked state by being rotated on the side of the drop beam 50 and has a structure for supporting a lower portion to which the hook 52 of the drop beam 50 is hinged in the locked state. . The hook locker 58 is coupled to the drop beam 50 by the U bolt 126, and two holes 127 into which the U bolt 126 is inserted are respectively inserted into the hook locker 58 and the drop beam 50. It is formed at the corresponding position.

The U bolt 126 has a long axis 126a penetrating from the rear surface of the drop beam 50 on which the hook locker 58 is installed, and a short axis 126b in which an end of the long axis 126a is bent in a U shape. Spring 128 is inserted into the back surface of the drop beam 50 into which the 126a is inserted to provide elastic force, and the hook locker 58 and the holes 127 of the drop beam 50 into which the long axis 126a is inserted. The spacer bolt 129 is inserted therebetween to support the rotation of the hook locker 58, and the short axis 126b of the U bolt 126 serves to fix the other holes of the hook locker 58 and the drop beam 50. It is configured to penetrate, and the length of the short axis 126b is preferably formed to the extent that the spring 128 is pushed away from the hook locker 58 when the U bolt 126 is pressed in close contact.

The locked state of the hook locker 58 is the same as that of FIG. 21 and the open state of the hook locker 58 is the same as that of FIG.

The tie rod 123 coupled to the lengthwise direction in which the screw is formed on the outer surface and the slab panel support beam 20 extends is coupled to the opposite side on which the hook 52 of the drop beam 50 is formed.

In addition, the pivot rod 121 is coupled to the tie rod 123, and the pivot pipe 121 is guided by the tie rod 123, and the pivot pin 121 is moved to the recessed space C of the drop beam 50. 122 is mounted and the pivot pin 122 is coupled to the pivot pin hole 116 of the main beam 110 forming an outer wall. Then, the washer 125 and the spindle nut 124 which control the movement of the pivot pipe 121 are screwed to the end where the pivot pipe 121 of the tie rod 123 is coupled.

In the embodiment according to the present invention configured as described above will be described for the hinge coupling and pivot coupling.

The hook 52 of the drop beam 50 is coupled with the hinge pin of the corner bracket 10 of the slab corner 12 or the filler bracket 14 of the filler panel 16, and the hook 52 of the drop beam 50. Hinge coupling of) may be supported by the hook locker 58 installed in the drop beam 50 is locked in accordance with the operation of the U bolt 126. The hook locker 58 remains locked while the slab panels 18 are installed or dismantled on the slab panel support beam 20.

The drop beam 50 and the main beam 110 are fixed by the insertion of the main pin 100, and the drop beam 50 is not rotated in the state in which the main pin 100 is inserted. When the main pin 100 is separated, the drop assembly 120 is rotated around the pivot pin 122 of the pivot pipe 121. That is, the state in which the drop beam 50 is fixed is dismantled so that the drop assembly 120 pivoted with the main beam 110 is rotated. When the drop assembly 120 is rotated, the drop beam 50 is rotated upwards. The pivot pipe 121 and the tie rod 123 are rotated downward. In this state, the pivot pipe 121 in which the pivot pin 122 is configured is formed by the load of the slab panel support beam 20 in which the main beams and the middle beams are assembled, and the slab panels 18 therein. Lowered along the tie rods 123, their lowered state can be adjusted by rotating the spindle nut (124).

The slab panel assembly according to the present invention can assemble and disassemble the slab panel 18 based on the hinge coupling and pivot coupling described above, and the disassembly procedure of the slab panel assembly will be described with reference to FIGS. 23 to 26.

23 is a state in which the drop beam 50 at both ends of the slab panel support beam 20 is hinged to the corner bracket 10 of the slab corner 12 and the filler bracket 14 of the filler panel 16. As the main beam 110 of the beam 50 and the slab panel support beam 20 are coupled by the main pin 100, the drop assembly 120 is fixed to the main beam 110 without being rotated. . Here, the slab panel 18 is supported on the slab panel support beam 20, and the slab panel 18 is assembled with the filler panel 28 in which the filler bracket is not formed. And, the upper portion of the slab panel 18 and the filler panel (16, 28) is cast concrete is formed that the ceiling structure 200 is formed.

When the main pin 100 is dismantled from the drop beam 50 and the main beam 110 of the slab panel support beam 20 in the above-described state of FIG. 23, the slab panel support beam 20 is dropped as shown in FIG. 24. Supported by the pivot coupling 122 formed on the 120 and the pivot pipe 121, the drop beam 50 of the drop assembly 120 by the load of the slab panel support beam 20 is hook ( 52 is rotated in the hinged state is rotated toward the space formed on the main beam 110 of the slab panel support beam 20 and the pivot pipe 121 and tie rod 123 of the slab panel support beam 20 It is rotated to the lower part of the main beam 110. At this time, in conjunction with the rotation of the drop assembly 120, the slab panel support beam 20 is slightly lowered.

In the state in which the slab panel support beam 20 is slightly lowered as shown in FIG. 24, the upper slab panel 18 may be dismantled and seated on the slab panel support beam 20 as shown in FIG. 25, and the drop assembly 120 may be used. When the spindle nut 124 is rotated, the pivot pipe 121 is gradually lowered, and as the pivot pipe 121 is gradually lowered, the slab panel support beam 20 pivotally coupled thereto is also slab panel ( Descend with 18).

As a result, when the pivot pipe 121 is completely lowered by rotating the spindle nut 124 of the drop assembly 120 as shown in FIG. 26, the slab panel support beam 20 is also completely lowered, and the operator easily supports the slab panel. The slab panels 18 mounted on the beam 20 can be removed.

As described above, the slab panel assembly according to the present invention can easily assemble and dismantle the slab panel 18, thereby improving workability and securing work safety.

On the other hand, the slab corner 12 may be supported by the structure as shown in Figure 27 by a lower structure, such as a vertical support as shown in Figure 28, the vertical support for supporting the slab corner 12 is composed of L-shaped steel The horizontal bracket 220 may include a vertical fixing body 222 bonded to the lower portion of the horizontal bracket 220, the horizontal bracket 220 is a method such as the upper slab corner 12 and the pin coupling, bolt coupling, etc. The vertical fixture 222 may be coupled to the upper horizontal bracket 220 by welding or the like.

The vertical fixture 222 may be coupled to the protrusion 212 and the bolt 224 is fixed to the concrete wall 210, the vertical fixture 222 is a plurality of penetrations for coupling with the bolt 224 A ball 226 can be formed.

In addition, the vertical fixture 222 may be configured by combining the L-shaped steel (222a, 222b), the recess 228 may be formed corresponding to the region in which the protruding piece 212 is inserted.

As mentioned above, although preferred embodiment of this invention was described in detail, this invention is not limited to the said embodiment, A various deformation | transformation by a person of ordinary skill in the art within the scope of the technical idea of this invention is carried out. This is possible.

10: corner bracket 12: slab corner
14: pillar bracket 16, 28: pillar panel
18: slab panel 20: slab panel support beam
50: drop beam 52: hook
58: hook locker 100: main pin
110: main beam 120: drop assembly
121: pivot pipe 122: pivot pin
123: tie rod 130: internal connector
140: external connector 150: reinforcement patch
160: middle beam

Claims (3)

In the filler panel used to arrange the slab panels arranged horizontally,
A frame having an inner frame disposed between the slab panels and having an upper surface and having an open rectangle at the bottom thereof and connecting the long sides of the lower slab; And
And a pillar bracket coupled to an upper portion of the inner frame of the frame and hinged to an end of the slab panel support beam for supporting the slab panels adjacent to each other in the long side direction of the frame.
The inner frame of the frame includes a pair of beams in which first bolt holes are formed at symmetrical positions,
The pillar bracket has second bolt holes corresponding to the first bolt holes formed in the beam of the inner frame, and is coupled to the first bolt passing through the first and second bolt holes and the end of the first bolt. The first assembly is coupled to the inner frame by a first nut that is a pair of first hinge portion including a first hinge hole formed for the hinge coupling the first hinge hole inclined to the side extending from the first assembly portion Filler comprising a first bracket plate, a first hinge pin is inserted into the first hinge hole facing each other to form the hinge coupling by the end of the slab panel support beam is fastened to the first hinge pin panel. delete delete

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