KR20230037821A - integrated ceiling brace system using in-plane stiffness reinforcement member - Google Patents

Abstract

The present invention relates to a bracing system of a ceiling of a large space using an in-plane rigidity reinforcement material, which comprises: T-bar assemblies arranged in a grid shape in a lower portion of a slab of a building structure; T-bar brackets arranged in a crossed portion of at least one row of the T-bar assembly at a predetermined interval; in-plane rigidity reinforcement materials respectively coupled to one T-bar and the other T-bar to form the single row; a connection bracket coupled to an upper surface of at least one of the in-plane rigidity reinforcement material; and a bracing coupled to the connection bracket in different directions to be fixated to the slab.

Description

Large space ceiling bracing system using in-plane stiffness reinforcement {integrated ceiling brace system using in-plane stiffness reinforcement member}

The present invention relates to a bracing system for a ceiling, and more particularly, to a technique for minimizing damage to a ceiling system by maximizing seismic performance of the bracing system through an in-plane rigid reinforcing member to suppress collision with a wall in the event of an earthquake.

By constructing a ceiling under the concrete slab of a building structure such as an apartment building, exposure of the concrete slab is blocked, as well as various wiring and ventilation ducts installed under the concrete slab are blocked from being exposed to the outside.

At this time, the construction of the ceiling can be done through the ceiling system.

The ceiling system includes a ceiling panel, a ceiling frame, and a hanger, and can be classified into an M-bar or a T-bar according to the cross-sectional shape of the ceiling frame, However, it can be classified as either a direct suspended ceiling system or an indirect suspended ceiling system according to the installation method of the pedestal.

On the other hand, when an earthquake occurs, the ceiling system of the building structure is also affected, so there is a problem in that the ceiling system is damaged.

For this reason, seismic reinforcement technology is applied to the ceiling system to constrain the behavior of the ceiling system so that seismic loads are transferred to structures such as concrete slabs or walls, thereby preventing damage caused by earthquakes. Accordingly, various types of ceiling bracing and ceiling Peripheral support clips and the like have been proposed.

However, in the conventional ceiling system, since the joint of the lightweight steel frame member is weak due to the structural characteristics of the ceiling frame, the seismic load cannot be effectively transmitted to the structure, so the effect of the behavior-constrained built-in reinforcement method is limited.

In order to solve the problem of the conventional earthquake-proof reinforcing method, an earthquake-resistant member using a damper as disclosed in Korean Patent Registration No. 10-1833820 (hereinafter referred to as 'Prior Application Invention 1') has been proposed.

However, the prior invention 1 is a system using a spring, gas and hydraulic damper, but no details for implementing it are proposed, and in particular, since a separate earthquake-resistant member must be manufactured and the damper must be installed, manufacturing, maintenance, and repair are difficult. In addition, in order to express the performance of the damping device for the ceiling of a large space, a number of dampers must be installed, so there is a problem in practical application.

In addition, in order to solve the problem of the conventional earthquake-proof reinforcing method, a seismic member using braces as disclosed in Korean Patent Registration No. 10-1833822 (hereinafter referred to as 'Prior Application Invention 2') has been proposed.

However, due to the low in-plane stiffness of the ceiling system, Invention 2 of the prior application is accompanied by reinforcement of the joint of the lightweight steel frame member constituting the ceiling frame, or a dense arrangement of braces is required, so there are limitations in practical application to the field. there was

For the above reasons, in the field, attempts have been made to develop a reinforcement technology for ceiling systems that can minimize ceiling damage by mitigating collisions with walls by suppressing and reducing the behavior of ceiling systems in the event of an earthquake, but satisfactory results have been achieved so far. is currently not being obtained.

Republic of Korea Patent Registration No. 10-1833820 Republic of Korea Patent Registration No. 10-1833822

The present invention has been proposed to solve the problems of the prior art as described above, and provides a technology capable of securing effective in-plane stiffness in order to solve the problem of the existing bracing system having only a limited effect due to the low in-plane stiffness of the ceiling. The purpose is to provide a bracing system for a large space ceiling using an in-plane rigid reinforcing material that can minimize damage to the ceiling when it occurs and minimize the installation interval of the bracing.

In order to achieve the above object, the present invention,

A T-bar assembly disposed in a lattice form under the slab of the building structure; T-bar brackets disposed at regular intervals at intersections of at least one row of the T-bar assembly; In-plane stiffeners coupled to each other between one of the T-bar brackets and forming one row; a connection bracket coupled to an upper surface of at least one of the in-plane stiffeners; and braces coupled to the connection bracket in different directions and fixed to the slab.

The T-bar assembly may be fixed to the lower portion of the slab by a wire connection.

The T-bar bracket includes a support piece formed in a '+' shape; Extension pieces extending downward from each of the support pieces; and a plurality of bolts protruding upward from the upper surface of the support piece.

The in-plane stiffener includes one end in the longitudinal direction, the other end in the longitudinal direction, and a plurality of bolt through-holes formed between one end and the other end in the longitudinal direction.

The connection bracket includes a support piece formed in a '+' shape; Extension pieces extending in an oblique direction upward from the front end of each of the support pieces; and a plurality of bolt through holes formed on the upper surface of the support piece.

The present invention, a block plate coupled between the top surface of any one of the T-bar brackets and the bottom surface of one end in the longitudinal direction of any one of the in-plane stiffeners to prevent lifting of the in-plane stiffeners; and a fixing bracket fixing the upper end of the brace to the slab.

The block plate includes a plurality of bolt penetration holes formed between one end and the other end in the longitudinal direction.

The bracing system of a large space ceiling using the in-plane stiffener according to the present invention includes the in-plane stiffener, and as the in-plane rigidity of the ceiling system is reinforced by the in-plane stiffener, the impact caused by collision with the wall in the event of an earthquake is reduced. Since falling or collapsing of the ceiling can be prevented or delayed, damage to the ceiling caused by an earthquake can be minimized.

In addition, the bracing system of a large space ceiling using the in-plane stiffener according to the present invention has a relatively simple structure, so it is easy to construct and reduce construction costs, and reinforcement can be performed without removing the existing ceiling system It can reduce maintenance and repair costs.

In addition, the bracing system of a large space ceiling using the in-plane stiffener according to the present invention can minimize the installation of braces as the in-plane rigidity is reinforced by the in-plane stiffener, so a relatively large number of braces can be installed due to the area in particular Seismic reinforcement of a large space ceiling system, which is inevitably required, can be facilitated.

1 is a perspective view showing the overall structure of a bracing system for a large space ceiling using an in-plane stiffener according to the present invention.
2 is an exemplary view showing the installation of a T-bar bracket in a bracing system of a large space ceiling using an in-plane stiffener according to the present invention.
3 is an exemplary view showing the installation of an in-plane stiffener in a bracing system for a large space ceiling using the in-plane stiffener according to the present invention.
4 is an exemplary view showing the installation of a block board in a bracing system of a large space ceiling using an in-plane stiffener according to the present invention.
5 is an exemplary view showing the installation of a connection bracket in a bracing system of a large space ceiling using an in-plane stiffener according to the present invention.
6 is an exemplary view showing the installation of braces in a bracing system of a large space ceiling using an in-plane stiffener according to the present invention.
7 is an exemplary view for explaining the fixing of a brace through a fixing bracket in a bracing system for a large space ceiling using an in-plane stiffener according to the present invention.

Hereinafter, the present invention will be described in detail based on the accompanying drawings.

As shown in FIG. 1, the bracing system (A) of a large space ceiling utilizing the in-plane stiffener according to the present invention includes a T-bar assembly 10; T-bar bracket 20; an in-plane stiffener 30; Connection bracket 40; And braces (50); includes.

The T-bar assembly 10 of the present invention is disposed in a lattice form under a slab (not shown in the drawing) of a building structure.

Therefore, the ceiling finishing panel can be installed by the T-bar assembly 10.

At this time, the T-bar assembly 10 may be fixed to the lower portion of the slab by means of a wire 11 connection.

Here, the wire 11 is connected to the lower surface of the slab from the intersection 12 of the plurality of points of the T-bar assembly 10, so that the T-bar assembly 10 can be stably fixed to the lower portion of the slab.

The T-bar brackets 20 of the present invention are arranged at regular intervals along the intersection 12 of at least one row of the T-bar assembly 10.

Therefore, the in-plane rigidity reinforcing member 30 may be installed on the T-bar assembly 10 by the T-bar bracket 20.

At this time, the T-bar bracket 20 includes a support piece 21 formed in a '+' shape; Extension pieces 22 extending downward from each of the support pieces 21; And a plurality of bolts 23 protruding upward from the upper surface of the support piece 21; by including, the extension pieces 22 leading from each of the support pieces 21 are at the intersection 12 of the T-bar assembly 10. As separate bolts are fastened through the extension piece 22 and the T-bar assembly 10 in a state of close contact, the coupling with the T-bar assembly 10 can be made, and the support piece 21 protrudes upward from the upper surface. As the bolt 23 is fastened through the bolt through-hole 31 formed in the in-plane stiffener 30 to be described below, coupling with the in-plane stiffener 30 can be achieved.

Here, a separate bolt for coupling the T-bar bracket 20 and the T-bar assembly 10 and a washer (not shown) at the tip of the bolt 23 for coupling the T-bar bracket 20 and the in-plane stiffener 30 ) and nuts (reference numerals not shown) are coupled so that the coupling of the T-bar bracket 20 and the T-bar assembly 10 and the coupling of the T-bar bracket 20 and the in-plane rigidity reinforcing member 30 can be stably maintained.

The in-plane stiffener 30 of the present invention is coupled to each of the T-bar brackets 20 between one and the other to form one row.

Therefore, the in-plane rigidity of the bracing system A of the large space ceiling using the in-plane stiffener according to the present invention can be reinforced by the in-plane stiffener 30.

At this time, the in-plane stiffener 30 includes a plurality of bolt through-holes 31 formed between one end in the longitudinal direction, the other end in the longitudinal direction, and one end in the longitudinal direction and the other end, so that the T-bar bracket 20 is formed by the bolt through-hole 31. The penetration of the bolt 23 protruding from the upper surface of the support piece 21 of ) can be made.

Here, the bolt through hole 31 is formed corresponding to the arrangement shape and diameter of the bolt 23 protruding from the upper surface of the support piece 21 of the T-bar bracket 20, so that the support piece of the T-bar bracket 20 ( 21) Insertion of the bolt 23 protruding from the upper surface can be smooth.

The connection bracket 40 of the present invention is coupled to the top surface of at least one of the in-plane stiffeners 30.

Therefore, the brace 50 can be installed by the connection bracket 40.

At this time, the connection bracket 40 includes a support piece 41 formed in a '+' shape; an extension piece 42 extending obliquely from the front end of each support piece 41 upward; And a plurality of bolt through-holes 43 formed on the upper surface of the support piece 41; By including the support piece 41, the extension piece 42 leading from each of the braces 50 is inserted into one end of the screw (reference numeral Not shown) As fastening is performed, coupling with the brace 50 can be made, and the support piece 41 protrudes from the upper surface of the support piece 21 of the T-bar bracket 20 by the bolt through hole 43 formed on the upper surface. The penetration of the bolt 23 can be made.

Here, the bolt through hole 43 is formed corresponding to the arrangement shape and diameter of the bolt 23 protruding from the upper surface of the support piece 21 of the T-bar bracket 20, so that the support piece of the T-bar bracket 20 ( 21) Insertion of the bolt 23 protruding from the upper surface can be smooth.

The bracing 50 of the present invention is coupled to the connecting bracket 40 in different directions and fixed to the slab.

Therefore, the flow of the in-plane stiffener 30 and the T-bar assembly 10 can be suppressed by the brace 50 .

At this time, a plurality of braces 50 are connected in different directions and fixed to different points of the slab, so that the flow of the in-plane stiffener 30 and the T-bar assembly 10 is further suppressed by the support of each brace 50 can

And the bracing system (A) of the large space ceiling utilizing the in-plane stiffener according to the present invention, the block plate (60); And a fixing bracket 70; further includes.

The block plate 60 of the present invention is coupled between the top surface of any one of the T-bar brackets 20 and the bottom surface of one end in the longitudinal direction of any one of the in-plane rigidity reinforcing materials 30.

Therefore, lifting of one end of the in-plane stiffener 30 can be prevented by the block plate 60, that is, vertical movement of one end of the in-plane stiffener 30 can be prevented.

At this time, the block plate 60 includes a plurality of bolt through holes 61 formed between one end and the other end in the longitudinal direction, so that the upper surface of the support piece 21 of the T-bar bracket 20 is formed by the bolt through holes 61. The protruding bolt 23 may be penetrated.

Here, the bolt through hole 61 is formed corresponding to the arrangement shape and diameter of the bolt 23 protruding from the upper surface of the support piece 21 of the T-bar bracket 20, so that the support piece of the T-bar bracket 20 ( 21) Insertion of the bolt 23 protruding from the upper surface can be smooth.

The fixing bracket 70 of the present invention fixes the top of the brace 50 to the slab.

Therefore, the flow of the brace 50 in the slab can be suppressed by the fixing bracket 70.

At this time, the fixing bracket 70 can be coupled with the brace 50 as one end is screwed in a state where one end is inserted into the brace 50, and the other end is screwed in a state in close contact with the slab According to the combination with the slab can be made.

The in-plane rigidity reinforcement in the bracing system (A) of the large space ceiling using the in-plane rigidity reinforcing member according to the present invention will be described in detail as follows.

In the present invention, the T-bar assembly 10 is arranged in a lattice form under the slab of the building structure, and the ceiling finishing panel can be installed by the T-bar assembly 10.

However, since the T-bar assembly 10 is only fixed to the lower part of the slab by the connection of the wire 11, it can flow and collide with the wall due to the external force applied during an earthquake, so the ceiling installed in the T-bar assembly 10 Falling or collapse of finishing panels, etc. may follow.

However, the present invention includes the in-plane stiffener 30 disposed along at least one row of the T-bar assembly 10, and the in-plane rigidity is reinforced by the in-plane stiffener 30, resulting in T Since the flow of the bar assembly 10 is suppressed and the impact caused by the collision with the wall is reduced, the fall or collapse of the ceiling finishing panel installed on the T-bar assembly 10 can be prevented or delayed, thereby preventing or delaying ceiling damage caused by an earthquake. can be minimized.

In addition, the present invention includes a brace 50 coupled between the in-plane stiffener 30 and the slab, and the flow of the T-bar assembly 10 can be further suppressed by the support of the brace 50, resulting in earthquake Since the flow of the T-bar assembly 10 due to the external force applied at the time of occurrence is further suppressed, the impact due to collision with the wall is further reduced, so that the ceiling finishing panel installed in the T-bar assembly 10 is further prevented from falling or collapsing, or It can be delayed, so the ceiling damage caused by the earthquake can be further minimized.

At this time, the installation of the in-plane stiffener 30 and the brace 50 may be cumbersome.

However, the present invention, the T-bar assembly (10) T-bar brackets (20) disposed at regular intervals along the cross section (12) of one row; And a connection bracket 40 coupled to at least one upper surface of the in-plane stiffener 30; by combining the in-plane rigid stiffener 30 between one and the other of the T-bar brackets 20, respectively. Since the rigid stiffener 30 can be simply installed along one row of the T-bar assembly 10, and the brace can be simply installed on the rigid stiffener 30 as the brace is coupled to the connection bracket 40, the in-plane rigid stiffener (30) and braces (50) can reduce the hassle of installation.

Here, the T-bar bracket 20 includes a support piece 21 formed in a '+' shape; Extension pieces 22 extending downward from each of the support pieces 21; And a plurality of bolts 23 protruding upward from the upper surface of the support piece 21; as shown in FIG. 2, the extension piece 22 leading from each of the support pieces 21 is a T-bar assembly ( 10) in a state of being in close contact with the intersection 12, through the extension piece 22 and the T-bar assembly 10, separate bolt fastening is performed, so that the coupling with the T-bar assembly 10 can be easily achieved, FIG. 3 As shown in, the bolt 23 protruding upward from the upper surface of the support piece 21 penetrates through the bolt through-hole 31 formed in the in-plane stiffener 30 to be described below, thereby in-plane rigid reinforcing material 30 ) can be easily combined.

And the connection bracket 40 is a support piece 41 formed in a '+' shape; an extension piece 42 extending obliquely from the front end of each support piece 41 upward; And a plurality of bolt through-holes 43 formed on the upper surface of the support piece 41; as shown in FIG. As the screws are fastened in the inserted state, the coupling with the brace 50 can be easily performed, and as shown in FIG. 5, each of the bolt through holes 43 formed on the upper surface of the support piece 41 has a T-bar bracket ( As each of the bolts 23 protruding from the upper surface of the support piece 21 of 20) penetrates and is fastened, coupling with the in-plane stiffener 30 can be easily performed.

In addition, the bracing system (A) of the ceiling of a large space using the in-plane stiffener according to the present invention is coupled between the upper surface of any one of the T-bar brackets 20 and the lower surface of one of the longitudinal stiffeners 30 in the longitudinal direction Since it includes the block plate 60, lifting of one end of the in-plane stiffener 30 can be prevented by the block plate 60, in other words, the vertical flow of one end of the in-plane stiffener 30 can be prevented, so that the in-plane rigidity In-plane rigidity reinforcement by the reinforcing material 30 may be smooth.

In addition, the bracing system (A) of the ceiling of a large space using the in-plane stiffener according to the present invention includes a fixing bracket 70 for fixing the upper end of the brace 50 to the slab, and from the slab by the fixing bracket 70 Since the flow of the brace 50 can be suppressed, the flow of the T-bar assembly 10 can be further suppressed by the support of the brace 50.

At this time, the block plate 60 includes a plurality of bolt through-holes 61 formed between one end and the other end in the longitudinal direction, as shown in FIG. 4, each of the bolt through-holes 61 has a T-bar bracket 20 As each of the bolts 23 protruding from the upper surface of the support piece 21 of ) is fastened through, coupling with the T-bar bracket 20 can be made.

In addition, as shown in FIG. 7, the fixing bracket 70 can be coupled with the brace 50 as one end is screwed in a state inserted into one end of the brace 50, and the other end is in close contact with the slab. Since the coupling with the slab can be made according to the screw fastening in the screwed state, not only can the installation of the block plate 60 and the fixing bracket 70 be made simple, but also the installation state can be stably maintained.

On the other hand, through the above description, it can only be seen that the brace 50 is coupled to either the extension piece 42 of the connection bracket 40 and the other one to face back and forth, but this is just an example. The brace 50 is connected Not only can it be coupled so as to face left and right to any one of the extension pieces 42 in different directions of the bracket 40 and the other, but it can also be coupled to each of the extension pieces 42 to face front and back and left and right.

Since the present invention as described above is not limited to the above-described embodiments, it can be modified within the scope not departing from the gist of the present invention claimed in the claims, and such changes are defined by the description of the claims below. fall within the protection scope of the invention.

10: T-bar assembly 11: wire
12: intersection 20: T-bar bracket
21: support piece 22: extension piece
23: bolt 30: in-plane rigid reinforcement
31: bolt through hole 40: connection bracket
41: support piece 42: extension piece
43: bolt through hole 50: addition
60: block plate 61: bolt through hole
70: fixing bracket A: bracing system

Claims (7)

A T-bar assembly disposed in a lattice form under the slab of the building structure;
T-bar brackets disposed at regular intervals at intersections of at least one row of the T-bar assembly;
In-plane stiffeners coupled to each other between one of the T-bar brackets and forming one row;
a connection bracket coupled to an upper surface of at least one of the in-plane stiffeners; and
A bracing system for a large space ceiling using an in-plane rigid reinforcing material, characterized in that it includes; bracing coupled to the connection bracket in different directions and fixed to the slab. According to claim 1,
The T-bar assembly is a bracing system of a large space ceiling using an in-plane rigid reinforcing material, characterized in that fixed to the lower portion of the slab by wire connection. According to claim 1,
The T-bar bracket includes a support piece formed in a '+'shape; Extension pieces extending downward from each of the support pieces; and a plurality of bolts protruding upward from the upper surface of the support piece. According to claim 1,
The in-plane stiffener is a bracing system of a large space ceiling using an in-plane stiffener, characterized in that it comprises a plurality of bolt through-holes formed between one end in the longitudinal direction, the other end in the longitudinal direction, and one end in the longitudinal direction and the other end. According to claim 1,
The connection bracket includes a support piece formed in a '+'shape; Extension pieces extending in an oblique direction upward from the front end of each of the support pieces; and a plurality of bolt through-holes formed on the upper surface of the support piece. According to claim 1,
a block plate coupled between an upper surface of any one of the T-bar brackets and a bottom surface of one end of the in-plane stiffener in the longitudinal direction to prevent lifting of the in-plane stiffener; and a fixing bracket for fixing the upper end of the brace to the slab. According to claim 6,
The block plate is a bracing system of a large space ceiling using an in-plane rigid reinforcing material, characterized in that it comprises a plurality of bolt through-holes formed between one end and the other end in the longitudinal direction.

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