KR102153885B1 - Ceiling structure system that improves economic efficiency and earthquake resistance - Google Patents

Abstract

The present invention relates to a ceiling structure system and, more specifically, to a ceiling structure system which can selectively install one of a T-bar and an M-bar installed to be perpendicular to a mainframe by using a seismic TM clip installed on the mainframe to improve constructability. The mainframe is slid and installed on a coupling unit of a seismic hanger. The height of the coupling unit is higher than the height of the mainframe to allow the mainframe to move vertically. The seismic TM clip is slid to be installed to be moved in the longitudinal direction of the mainframe. A subframe is slid to be installed on the seismic TM clip to be moved. Ceiling panels are connected by a seismic locking device, and the outermost ceiling panel is fixed by an elastic fixing pin to improve stability and earthquake resistance.

Description

Ceiling structure system that improves economic efficiency and earthquake resistance}

The present invention relates to a ceiling structure system, and in more detail, by using a seismic TM clip installed on the main frame, it is possible to selectively install any one of T-Bar and Emba installed to be orthogonal to the main frame, thereby improving workability. On the other hand, a main frame is seated and installed in the coupling portion of the earthquake-resistant hanger, and the height of the coupling portion is higher than the height of the main frame so that the main frame can flow up and down, and the seismic TM clip in the longitudinal direction of the main frame The subframe is installed to allow flow by sliding on the seismic TM clip, and the ceiling panels are connected by a seismic locking device and at the same time, the outermost ceiling installed on the wall adjacent to the ceiling slab This is a technical field related to a ceiling structure system in which the panel is fixed by an elastic fixing pin, thereby improving economy and earthquake resistance.

In general, a ceiling material, that is, a ceiling panel (ceiling finish plate), is installed on the ceiling of a building used by multiple people, such as educational facilities and medical facilities, to shield concrete slabs and prevent exposure of various wiring or ventilation ducts installed on the ceiling.

The ceiling member is supported by a ceiling frame fixed to the slab, and an example of the ceiling frame is a Light Weight Steel Type Ceiling Frame. The ceiling frame is a ceiling frame of a direct suspension method in which a ceiling joist is directly connected to a plurality of hangers fixed to a ceiling slab, and the semi-self-receiving frame is provided using a half-jaw holder, that is, a carrying channel. It can be classified as a supporting indirect suspension type ceiling frame.

The diaphragm is classified into M-Bar, T-Bar, and Clip-Bar according to the cross-sectional shape of the diaphragm, and the diaphragm is the diaphragm holder, that is, a carrying channel ('carrying channel). It is arranged in a direction orthogonal to the'channel') and is fixed to the carrying channel by a binding member called a semi-magnetic clip.

In recent years, since earthquakes are frequently occurring in Korea, the importance of seismic design is emphasized in order to cope with natural disasters such as earthquakes, but conventional ceiling frames such as conventional lightweight steel ceiling frames, such as earthquakes or typhoons, If the building is subjected to vibration or strong impact due to natural disasters, it is difficult to firmly support the ceiling material and the resistance to deformation or shock absorption is weak, so that the ceiling may collapse or death may occur due to the falling of the ceiling material. There are limitations in that it is difficult to fasten the anti-self clip and the anti-self belt, it takes a long time to construct the ceiling frame, and the skill of the worker is greatly required.

Korean Patent Registration No. 10-1990353 (2019.06.12.) Republic of Korea Patent Publication No. 10-2005-0015964 (2005.02.21.) Korean Patent Publication No. 10-2019-0011435 (2019.02.07.)

The present invention is a technology conceived to solve the problems according to the prior art described above, using a seismic TM clip installed on the main frame, it is possible to selectively install any one of the T-Bar and the Emba installed in a direction perpendicular to the main frame. Of course, in particular, during the construction of the T-bar, the T-bar is easily combined to improve workability, and the main frame is installed so that the main frame can flow up and down on the earthquake-resistant hanger, and the seismic TM clip is installed to slide on the main frame. The seismic TM clip is installed so that the T-bar or the embar can slide, so that the construction is easy, so that the economy and the earthquake resistance and stability are improved, and the ceiling panels are connected by a seismic locking device, and the outermost ceiling panel is An object of the present invention is to provide a ceiling structure system that is fixed by an elastic fixing pin, so that vibration due to wind pressure and earthquake is minimized, and excellent economy and earthquake resistance are improved.

The present invention is to realize the desired object as described above, a hanger bolt installed on the ceiling slab, the hanger bolt is installed to be connected to the upper, and a coupling part is formed at the lower end, and the coupling part of the anti-resistant hanger The main frame to be coupled, the seismic TM clip seated on the upper part of the main frame, the sub-frame consisting of any one of T-Bar or Emba that slides in a direction perpendicular to the main frame and coupled to the lower portion of the seismic TM clip, and the sub Consisting of a ceiling panel installed on the frame and a finishing molding installed on a wall surface adjacent to the ceiling slab, the ceiling panel protrudes downward, a lower body having a coupling groove formed on the slope, and one side of the coupling groove Consisting of including a seismic locking device in which the other side is inserted into and coupled to the coupling groove of the adjacent ceiling panel, and the finishing molding is formed in the longitudinal direction on the inner surface, and the support protrusion is formed to protrude to form the internal groove And, an elastic fixing pin having one side inserted into the interior groove and the other side inclined downward to elastically fix the upper part of the ceiling panel installed on the outermost side, characterized in that it improves economy and earthquake resistance. The proposed ceiling structure system is presented.

In addition, the seismic TM clip of the present invention extends downwardly on both sides of the seating portion and the seating portion to be seated on the upper portion of the main frame, and an extension portion covering opposite sides of the main frame and an inner side surface of the extension portion. At least one first support rib protruding from the lower portion, an embar groove formed in the lower front and rear of the extension portion, a t-bar groove formed in the lower center of the extension portion, and a second support rib protruding outwardly of the t-bar groove. Including, but characterized in that the lower portion of the second support rib is formed to extend upward.

In addition, the present invention is characterized in that when the subframe is made of embar, the ceiling panel is fixed and installed by a screw on the lower part of the embar, and when installed on the outermost side, one side is seated and installed on the finish molding. To do.

In addition, in the present invention, when the sub-frame is made of a t-bar, it is configured to include a cross t-bar coupled to the side of the t-bar in an orthogonal direction, and the ceiling panel is installed with an edge mounted on a stepped portion of the t-bar and It features.

In addition, the seismic locking device of the present invention includes an elastic body formed in a zigzag shape and a coupling protrusion formed protruding from one side and the other side of the elastic body and inserted into the coupling groove of the ceiling panel to enclose the elastic body. It characterized in that it comprises a closing member that is fitted in the lower portion of the elastic body.

In addition, the coupling portion 210 of the anti-progress hanger 200 of the present invention is characterized in that it is configured to include a guide groove formed on both sides of the bent portion and a bent hole formed through the middle.

In the ceiling structure system with improved economy and earthquake resistance according to the present invention presented as described above, the main frame is mounted on the coupling part of the shockproof hanger, but the height of the coupling part is higher than the height of the main frame, so the main frame can flow left and right. And, the seismic TM clip seated on the upper part of the main frame is slid and flowable along the length direction of the main frame, and the subframe that is slid and coupled to the seismic TM clip so as to be perpendicular to the main frame is also longitudinal As it can be flown, the effect of improving the earthquake resistance can be obtained.

In addition, the present invention is easy to construct as it is combined in a slide manner as described above, and in particular, a t-bar or embar-type subframe can be selectively installed in a direction perpendicular to the main frame under the seismic TM clip. It is possible to obtain a further improved effect and economical efficiency.

In addition, the present invention is more easily installed and separated through the curved surface formed to be alternately formed in the pair of t-bar grooves when installing the t-bar-shaped subframe to the seismic TM clip, so that the construction and maintenance are easy and economical. After being secured, it is possible to obtain the effect of maintaining a more stable installed state by the second support ribs formed alternately in a pair of t-bar grooves after being installed.

In addition, in the present invention, when the subframe is made of a T-bar, the ceiling panel and the ceiling panel are connected by a seismic locking device to maintain a more stable installation state, and at the same time, the ceiling panel located on the outermost side can be secured by using an elastic fixing pin. By fixing it, it is possible to maintain the installed state stably even against shaking due to wind pressure or earthquake, as well as to obtain the effect of easy maintenance due to easy separation.

1 is an exploded perspective view showing a ceiling structure system according to a preferred embodiment of the present invention.
Figure 2 is a perspective view (a), a front view (b), a side view (c) showing a seismic TM clip according to a preferred embodiment of the present invention.
3 is a perspective view showing a ceiling structure system using embar according to a preferred embodiment of the present invention.
Figure 4 is a schematic diagram showing a ceiling structure system using embar according to a preferred embodiment of the present invention.
Figure 5 is a partial side view showing a ceiling structure system using embar according to a preferred embodiment of the present invention.
Figure 6 is a partial front view showing a ceiling structure system using embar according to a preferred embodiment of the present invention.
7 is a partial side view showing the outermost side of the ceiling structure system using embar according to a preferred embodiment of the present invention.
Figure 8 is a perspective view showing a ceiling structure system showing a T-bar according to a preferred embodiment of the present invention.
9 is a schematic diagram showing a ceiling structure system using a T-bar according to a preferred embodiment of the present invention.
10 is a partial side view showing a ceiling structure system using a T-bar according to a preferred embodiment of the present invention.
11 is a partial front view showing a ceiling structure system using a T-bar according to a preferred embodiment of the present invention.
12 is a perspective view showing a ceiling panel according to a preferred embodiment of the present invention.
13A is a perspective view (a) and a bottom perspective view (b) showing a seismic locking device according to a preferred embodiment of the present invention.
13b is a bottom view (a) and a side view (b) showing a seismic locking device according to a preferred embodiment of the present invention.
14A is an exploded perspective view (a) and an exploded bottom perspective view (b) showing a seismic locking device according to a preferred embodiment of the present invention.
14B is an exploded bottom view (a) and a side view (b) showing a seismic locking device according to a preferred embodiment of the present invention.
15 is a partial side view showing the outermost side of the ceiling structure system using a T-bar according to a preferred embodiment of the present invention.
16 is a perspective view showing a coupling relationship between a finishing molding and a ceiling panel according to a preferred embodiment of the present invention.
17 is an exploded perspective view showing a coupling relationship between a finishing molding and a ceiling panel according to a preferred embodiment of the present invention.
18 is a perspective view showing a coupling relationship between an internal hanger and a main frame according to a preferred embodiment of the present invention.

The present invention relates to a ceiling structure system, and in more detail, a subframe 500 that is installed in a direction orthogonal to the main frame 300 under the seismic TM clip 400 installed on the main frame 300 ), it is possible to selectively install any one of the t-bar 510 or the em-bar 520, so that improved workability can be obtained, and the main frame 300 is installed so as to be able to flow up, down, left and right on the anti-resistance hanger 200, and the The seismic TM clip 400 is installed to be slid and flowable on the main frame 300, and the sub-frame 500 is slid and installed on the seismic TM clip 400 so as to be movable, thereby improving seismic resistance due to earthquakes. Of course, it is a technology related to a ceiling structure system with improved stability and economy.

In addition, in the present invention, when the sub-frame 500 is made of a t-bar 510, a seismic locking device 630 is installed between the ceiling panels 600 that are seated and installed on the step of the t-bar 510 to The installed state is stabilized by pressing the ceiling panel 600 installed on the outermost side using the elastic fixing pin 720 installed on the finish molding 700 while maintaining a stable installed state even in the event of an earthquake or the like. As well as being able to maintain it, the effect of easy maintenance can be obtained.

The configuration for achieving the present invention as described above is a hanger bolt 100 installed on a ceiling slab; and an anti-progress hanger installed so that the hanger bolt 100 is connected to the upper part, and the coupling part 210 is formed at the lower part ( 200); And the main frame 300 is seated and coupled to the coupling portion 210 of the anti-resistant hanger 200; And the seismic TM clip 400 seated on the upper portion of the main frame 300; And the seismic TM A subframe 500 made of one of a t-bar 510 or an embar 520 that slides in a direction perpendicular to the main frame 300 and is coupled to the lower portion of the clip 400; And a ceiling panel 600 installed on the subframe 500.

In addition, the seismic TM clip 400 of the present invention has a seating portion 410 that is seated on the upper portion of the main frame 300; and the main frame extending downwardly on both sides of the seating portion 410. 300) extending portions 420 covering opposite sides of each other; and at least one first support rib 430 protruding under the inner surface of the extension portion 420; and a lower portion of the extension portion 420 Emba grooves 440 formed in the front and rear sides; and t-bar grooves 450 formed in the lower center of the extension part 420; And extending outwardly in the lower center of the extension part 420, and being formed to be located in the front or rear lower part of the t-bar groove 450, and when formed in one extension part 420, the lower part is rear or front It is formed to extend upward, when formed on the other side extension 420, the lower portion is formed to extend to the front or rear upper second support rib 460; characterized in that it comprises a.

In addition, the present invention comprises a finishing molding 700 installed on the wall surface 10 adjacent to the ceiling slab, and the ceiling panel 600 includes, when the subframe 500 is made of an embar 520, When the embar 520 is fixed and installed by a screw and installed on the outermost side, one side is mounted and installed on the finishing molding 700.

In addition, the present invention is configured to include a; in the case where the sub-frame 500 is made of a t-bar 510, a cross t-bar 530 coupled to a side surface of the t-bar 510 in an orthogonal direction; and the ceiling panel 600 ) Is characterized in that the rim 610 is seated and installed on the stepped jaws of the ti bar 510 and the cross ti bar 530.

In addition, the present invention comprises a finishing molding 700 installed on the wall surface 10 adjacent to the ceiling slab, and when the ceiling panel 600 is installed on the outermost side, one edge is the finishing molding 700 ) Is installed and installed, and the rim 610 excluding the one side rim 610 is mounted and installed on the stepped jaws of the tee bar 510 and the cross tee bar 530.

In addition, the finishing molding 700 of the present invention is formed in the longitudinal direction on the inner surface, a support protrusion 710 which is formed to protrude to form an internal groove 712; and one side is inserted into the internal groove 712 , An elastic fixing pin 720 installed so that the other side is inclined in a downward direction; and the elastic fixing pin 720 is an elastic reinforcing part 722 formed by bending both end surfaces of the inclined surface in the horizontal direction. It characterized in that it is configured to include;

In addition, the ceiling panel 600 of the present invention protrudes downward and has a lower body 620 having a coupling groove 622 formed on the slope; and one side is inserted into the coupling groove 622 to be coupled, and an adjacent ceiling It characterized in that it comprises a; seismic locking device 630; the other side is inserted into the coupling groove 622 of the panel 600 is coupled.

In addition, the seismic locking device 630 of the present invention has an elastic body 632 formed in a zigzag shape; and a coupling groove 622 of the ceiling panel 600 protruding from one side and the other side of the elastic body 632 ) The coupling protrusion 634 is inserted into and coupled; And a closing member 636 fitted in the lower portion of the elastic body 632 so as to surround the elastic body 632.

Hereinafter, the present invention will be described in detail with reference to FIGS. 1 to 18 showing embodiments of the present invention.

First, the ceiling structure system (hereinafter, referred to as'ceiling structure system') having improved economy and earthquake resistance of the present invention includes a plurality of hanger bolts 100 fixedly installed on the ceiling slab, and the hanger bolts ( An anti-progress hanger 200 to be described in detail later is installed below the 100).

In addition, the hanger bolt 100 is between a pair of nuts and the pair of nuts or the pair of nuts that are coupled to the lower portion so that the earthquake-resistant hanger 200 can have earthquake resistance when combined with the shock-resistant hanger 200 It may be configured to include a spring installed on the lower outer periphery so as to be positioned between any one of the nuts and the internal hanger 200.

Next, the earthquake-resistant hanger 200, which is the main component for achieving the present invention, is

It is installed so that the lower portion of the hanger bolt 100 is connected on the upper part, and the coupling part 210 is formed at the lower part, and the pair of the previously described pair of the hanger bolt 100 and the above-described so as to have seismic resistance due to earthquakes, etc. It can be connected and installed by a nut and a spring, and the upper part is bent in one direction and the lower part of the hanger bolt 100 is passed through and then connected and installed by the pair of nuts, and the main frame 300 is connected to the coupling part ( 210).

The coupling part 210 is bent in the upper direction after the lower part of the anti-resistance hanger 200 of the present invention is bent in one direction, and finally, the end, that is, the bent part is bent in the other direction, so that the upper part of the hole is partially opened. It is formed in a shape, and the main frame 300 is inserted and installed.

Specifically, the coupling portion 210 is characterized in that the lower portion of the anti-resistance hanger 200 of the present invention is bent in one direction before the main frame 300 is installed, and then bent in the upper direction. , This realizes the effect of allowing the main frame 300 to be easily seated and installed.

In addition, the method of installing the main frame 300 on the coupling portion 210 is, after mounting the main frame 300 on the coupling portion 210, the end of the coupling portion 210, that is, bending By bending the part in the other direction and installing the main frame 300 in a temporarily fixed state, the main frame 300 can be easily installed.

In addition, the coupling portion 210 includes a guide groove formed on both sides of the bend line corresponding to the lower end of the bent portion and a bent hole formed through the reference line in order to easily bend the end, that is, the bent portion in the other direction. It can be configured, the operator can easily bend the end of the coupling portion 210, that is, the bent portion in the other direction without tools through the guide groove and the bending hole.

At this time, the coupling portion 210 is characterized in that it is formed to have a height higher than the height of the main frame 300, that is, the height of the portion bent in the other direction is higher than the height of the main frame 300. , This enables the main frame 300 to flow in the vertical direction by vibrations such as wind pressure or earthquake, thereby realizing the effect of improving the seismic resistance, as well as making the installation of the main frame 300 easy. do.

In addition, the coupling portion 210 may be configured to include screw holes formed through both sides, and by coupling a screw to the screw hole, the seismic TM clip 400, subframe 500, etc., which will be described later in detail. It is possible to further improve stability rather than seismic resistance through temporary fixing or complete fixing of the main frame 300 for installation, and the screw hole is formed in a position where the main frame 300 can be fixed.

In addition, the main frame 300 is coupled to the coupling part 210 of the anti-resistant hanger 200 and uses a'C' shaped channel or the like.

Next, the seismic TM clip 400 that is the main component for achieving the present invention is

As to be mounted on the upper portion of the main frame 300, the subframe 500, which will be described later in detail, can be installed in a direction perpendicular to the main frame 300, and the main frame ( After being mounted and installed on 300), it is movable by sliding along the longitudinal direction of the main frame 300, and after being moved, it can be fixed with screws or bolts.

In particular, the seismic TM clip 400 of the present invention, as shown in Figure 1, the main frame 300 and the sub-frame 500 is installed in a direction orthogonal to the bottom, the sub-frame 500 is a T-bar ( 510) or embar 520, that is, both the shape of the t-bar 510 and the embar 520 can be installed. Accordingly, the disassembly and assembly of the ceiling panel 600 is easy and maintained. Either one of the tibar 510 or the embar 520 to facilitate maintenance can be selectively installed, thereby realizing an effect of improving workability.

Specifically, the seismic TM clip 400 of the present invention includes a plate-shaped seating portion 410 that is seated and installed on the upper portion of the main frame 300 and the seating portion 410, as shown in FIG. A pair of extension portions 420 extending downwardly on both sides to surround opposite sides of the main frame 300, and at least one first protruding under the inner side of the extension portion 420 A support rib 430, an embar groove 440 formed in the lower front and rear of the extension part 420, a T-bar groove 450 and the extension part 420 formed in the lower center of the extension part 420 Doedoe extending outwardly in the lower center of the t-bar groove 450 is formed to be located in the front or rear lower portion of the t-bar groove 450, when formed on one side extension 420, the lower portion is formed to extend rearward or front upper portion, the other side When it is formed on the extension part 420, it is characterized in that it comprises a second support rib 460 having a lower portion extending forward or rearward.

That is, the seismic TM clip 400 of the present invention allows the first support to be stably seated and installed on the top of the main frame 300 through the seating portion 410 and the extension portion 420 By stably supporting the lower portion of the main frame 300 by a rib 430 to prevent separation from the main frame 300 in the upper direction, as well as preventing the flow in the vertical direction, which will be described in detail later. To facilitate installation of the subframe 500.

At this time, the seismic TM clip 400 of the present invention may be coupled in a manner that is slid on the main frame 300 as well as in a manner that is seated from the top to the bottom, and is slid on the main frame 300 having a predetermined length. When combined, the working time may be increased, so it is preferable that the first support rib 430 be combined in a manner that is seated from the top to the bottom. For this purpose, the first support rib 430 is formed with an inclined surface so that the bottom is inclined to increase inward. , When the main frame 300 is seated from the top to the bottom, the extension part 420 is widened outward by the inclined surface and then restored again to obtain a stable and easy installation effect.

The embar groove 440 is formed in a pair in the lower front and rear of each of the pair of extension parts 420, and the main frame 300 and the subframe 500 installed in the front and rear direction, in particular, the embar 520 are orthogonal. It is characterized in that a total of four, that is, two pairs are formed so that they can be installed in both directions.

In addition, the embar 520 has an annular engaging portion (not shown) in cross section on both sides of the upper portion, and the engaging portion is installed to be caught in a total of four embar grooves 440, thereby seismic resistance TM of the present invention It is installed on the clip 400 so as to be slidable in both directions, thereby improving stability and earthquake resistance.

The t-bar groove 450 is formed in the lower center of each of the pair of extension portions 420, and the main frame 400 and the sub-frame 500 installed in the front and rear directions, in particular, the t-bar 510 in a perpendicular direction. It is characterized in that a total of two, that is, a pair is formed so that it can be installed in both directions.

In addition, the second support rib 460 is formed to extend outwardly in the lower center of the extension part 420, and is formed to be located in the front or rear lower part of the t-bar groove 450, and one extension part 420 When formed in front of ), the other extension part 420 is formed in the rear so as to be point symmetric.

In addition, when the second support rib 460 is formed on one extension part 420, the lower part extends rearward or forward and upward, and when formed in the other extension part 420, the lower part extends forward or rearward and upward. It is formed, for example, when formed in front of one extension part 420, the lower part is formed to extend rearward and upward, and when it is formed in the rear of the other extension part 420, the lower part is formed to extend forward and upward to extend one side. It is characterized in that a pair is formed in a point symmetrical shape on the portion 420 and the other extension portion 420.

That is, the t-bar 510 is installed with an upper portion inserted into the t-bar groove 450, and the locking portion formed at the upper portion, that is, a lower portion of the head (not shown), is installed to be caught by the second support rib 460, It is installed to be slidable in both directions on the seismic TM clip 400 of the present invention, and accordingly, an effect of improving stability and earthquake resistance may be obtained.

At this time, the t-bar groove 450 is formed in the lower rear when the second support rib 460 is formed in the front, and the first round surface formed in the lower front when the second support rib 460 is formed in the rear 452, and when the second support rib 460 is formed in the front, the second round surface 454 is formed in the rear upper portion, and when the second support rib 460 is formed in the rear, It characterized in that it is configured to include.

The first round surface 452 and the second round surface 454 are characterized in that they are formed for easier installation because it is difficult to install by sliding in the case of the T-bar 510 having a predetermined length. A sufficient gap can be secured through the round surface 452 to allow the head of the t-bar 510 to enter, and the head of the t-bar 510 entered through the second round surface 454 is the t-bar groove 450 ), the second support rib 460 can more easily be caught on the locking portion formed in the lower portion of the head of the t-bar 510 by entering as much as possible.

In addition, in the t-bar groove 450, the second support ribs 460 are formed to be staggered in a point symmetrical shape, so that the t-bar 510 cannot enter and be installed from the bottom, but the head of the t-bar 510 Regardless of the second support rib 460, the lower part is expanded so that it can be easily entered, that is, inserted, and the first round surface 452 is formed to realize the effect of allowing it to be inserted more easily. .

In addition, the t-bar groove 450 is greater than the extended lower portion so that the head of the t-bar 510 can be stably installed after entering, that is, being inserted, that is, to support the top of the head of the t-bar 510 The upper part is formed to have a narrow width, and the head of the T-bar 510 more easily enters the upper part through the second round surface 454 so that the second geo-rib 460 is the head of the T-bar 510 It is to be easily caught on the locking part formed in the lower part.

In addition, the T-bar groove 450 is formed at the center of one extension part 420 and the other extension part 420, respectively, and the second support rib 460 is formed at a point symmetrical position. When explaining the installation method of the t-bar 510 in more detail, the head of the t-bar 510 is first tilted into the t-bar groove 450 on one side, and then the second support rib 460 is installed so that the locking portion of the head is caught. And, by tilting the head of the t-bar 510 into the other t-bar groove 450 and entering the second support rib 460 to the locking portion of the head, at this time, the t-bar 510 to the other t-bar groove 450 ), the head of the t-bar 510 first entered into the t-bar groove 450 on one side by the second round surface 454 formed in the t-bar groove 450 on one side is a second support rib ( It can be easily inclined in a state supported by 460, so that the head of the t-bar 510 can more easily enter the t-bar groove 450 on the other side, and thereafter, the second support rib formed in the t-bar groove 450 on the other side (460) In addition, it is possible to obtain the effect of being more easily installed in the head locking portion of the t-bar 510.

In other words, the t-bar groove 450 means that it is easy to separate the t-bar 510 in the reverse order, and during maintenance, the t-bar 510 can be separated by a detachable method rather than a sliding method, making it easier to maintain. It makes it possible to realize the effect of implementing remuneration.

Next, the main component for achieving the present invention, the subframe 500

The seismic TM clip 400 is made of either a t-bar 510 coupled in a sliding or detachable manner with the main frame 300 in a perpendicular direction or an embar 520 coupled by sliding, and the interior is frequently The ti-bar 510 is coupled to a replacement peddler or a hospital where maintenance is often required, and an embar 520 is installed in the interior of a general building where maintenance is not often required.

That is, the operator of the subframe 500 of the present invention can selectively use the T-bar 510 or the Emba 520 according to the use environment, and the T-bar 510 or the lower part of the seismic TM clip 400 described above Emba 520 is selectively coupled.

Next, the ceiling panel 600, which is the main component for achieving the present invention, is

It is installed on the sub-frame 500, and when the sub-frame 500 is made of an embar 520, the sub-frame 500 is fixed and installed by a screw under the embar 520, and the sub-frame 500 is In the case of 510, it is mounted and installed on the stepped jaws formed under the cross tee bar 530 and the tee bar 510 to be described in detail later.

In addition, the ceiling structure system of the present invention includes a finishing molding 700 that is installed on the wall surface 10 adjacent to the ceiling slab so that one side of the ceiling panel 600 on which the subframe 500 is not installed can be supported. It characterized in that it is configured to.

At this time, in the ceiling panel 600 installed on the outermost side of the ceiling panel 600 of the present invention, when the subframe 500 is made of the embar 520, one side is seated and installed on the finish molding 700 , The other side is fixed to the lower portion of the embar 520 through a screw and installed.

In connection with the above, the ceiling structure system of the present invention is configured to include a cross tee bar 530 coupled in a perpendicular direction to the side of the ti bar 510 when the sub-frame 500 is made of the tab 510 In the case of the t-bar 510, the ceiling panel 600 is mounted and installed. In order to stably support the slope of the ceiling panel, the cross-ti bar 530 as described above is preferably additionally installed.

At this time, the t-bar 510 has a through hole (not shown) through which the front or the other side of the cross t-bar 530 can be inserted and installed, and the cross t-bar 530 is a t-bar 510 positioned at the front and rear. The front and the rear are inserted into the through-hole of and are coupled, thereby realizing the effect of stably supporting and installing the rim 610 of the rectangular ceiling panel 600.

That is, in the ceiling panel 600 of the present invention, when the sub-frame 500 is made of a t-bar 510, a frame 610 is mounted on the stepped jaws of the t-bar 510 and the cross t-bar 530 to be installed.

Specifically, when the sub-frame 500 is made of a tibaro 510, the ceiling panel 600 of the present invention includes an edge 610 protruding outwardly on a slope, as shown in FIG. 12, It characterized in that it is configured to include a lower body 620 protruding downward. In other words, the rim 610 is formed to protrude outwardly on the upper outer surface of the lower body 620, but protrudes on the slope.

That is, in the ceiling panel 600 of the present invention, the frame 610 is mounted and installed on the lower step of the tee bar 510 and the cross tee bar 530, so that the operator can easily lift and separate it during maintenance. The effect of easy installation can be obtained.

At this time, since the ceiling panel 600 of the present invention is seated and installed when the subframe 500 is made of a t-bar 510, a coupling groove on the slope to prevent flow due to wind pressure, draft, earthquake, etc. 622) is formed.

In more detail, the lower body 620 of the ceiling panel 600 of the present invention protrudes in a lower direction than the lower surface of the T-bar 510, and a coupling groove 622 is formed on the slope, The ceiling panel 600 of the present invention includes a seismic locking device 630 in which one side is inserted and coupled to the coupling groove 622, and the other side is inserted and coupled to the coupling groove 622 of the adjacent ceiling panel 660. It characterized in that it is configured to.

In other words, the ceiling structure system of the present invention realizes the effect of being able to stably maintain the installed state even when the adjacent ceiling panels 600 are organically connected through the seismic locking device 630 and shakes such as wind pressure.

Specifically, the seismic locking device 630 has an elastic body 632 formed in a zigzag shape, and is formed protruding from one side and the other side of the elastic body 632 to the coupling groove 622 of the ceiling panel 600. It characterized in that it is configured to include a coupling protrusion 634 that is inserted and coupled.

As shown in Fig. 13b), the elastic body 632 is formed in a zigzag shape, that is, a zigzag shape, and has elasticity in the longitudinal direction because the bent shape is formed to be curved, and the coupling protrusion 634 is formed in the ceiling panel. When inserting into the coupling groove 622 of 600, the coupling protrusion 634 is compressed by an operator, and then the coupling protrusion 634 is positioned in the coupling groove 622, and then the compression is released so that the coupling protrusion 634 By being inserted into the groove 622, the seismic locking device 630 is installed, and accordingly, the adjacent ceiling panels 600 are organically connected, thereby improving stability and earthquake resistance.

In addition, the seismic locking device 630 protects the elastic body 632 and at the same time makes the appearance beautiful, as well as in the installed state, that is, the state in which the ceiling panels 600 are connected, so that the elastic body ( It is characterized in that it is configured to include a closing member 636 fitted in the lower portion of the elastic body 632 so as to surround the 632.

The finishing member 636 is designed to be installed more easily after the operator installs the seismic locking device 630, that is, after inserting the coupling protrusion 634 into the coupling groove 622 of the ceiling panel 600. As shown in 14a), it is preferable that the elastic body 632 is connected to the first connection part, and the first connection part is made of a flexible synthetic resin material so that the closing member 636 is more easily connected to the elastic body 632. Make it possible to combine.

At this time, the seismic locking device 630, that is, the elastic body 632, the coupling protrusion 634, and the closing member 636 are preferably made of a synthetic resin material like the first connection part to facilitate molding, that is, manufacturing. And, it is preferable that the first connection portion is formed to have a thin thickness by adjusting the thickness, so that it can be easily bent.

In addition, the closing member 636 is formed protruding from the inner upper surface, a plurality of first support protrusions (636a) formed to protrude so as to be positioned between the elastic body 632 and protruding from the inner upper surface, the It characterized in that it is configured to include a plurality of second support protrusions (636b) protruding so as to be positioned on the upper portion of the elastic body (632).

In addition, the first support protrusion 636a prevents the elastic body 632 from being compressed by the flow of the ceiling panel 600, and the second support protrusion 636b is the elastic body 632 ) To minimize the vertical flow, so that the elastic body by the first support protrusion (636a) and the second support protrusion (636b) even if the seismic locking device (630) is the ceiling panel 600 flows. It is possible to obtain the effect of preventing the 632 from being easily released by being compressed.

In addition, the closing member 636 is formed to protrude at both ends of the inner side, and is configured to include a coupling protrusion 636c formed to be inclined in an outward direction, and the elastic body 632 is inclined inward to the lower end rim By including a guide surface 632a formed to be formed, when the closing member 636 is coupled to the elastic body 632, it is spread outward by the coupling protrusion 636c and the guide surface 632a. By restoring again, it is possible to obtain an effect that the closing member 636 is coupled to the elastic body 632 can be maintained.

In connection with the above, the elastic body 632 may have one end and the other end connected to each of the adjacent one side and the other side adjacent to each other through a second connection part, the second connection part, one end and the other side of the elastic body 632 The ends are connected to one adjacent side and the other side adjacent to each other to reduce the elastic force, thereby obtaining an effect of maintaining a more stable state in which the coupling protrusion 634 is coupled to the coupling groove 622.

That is, the second connection part allows the elastic length of the elastic body 632 to be adjusted so that the connected state by the seismic locking device 630 can be more stably maintained according to the spaced distance between the ceiling panels 600. It is characterized in that it is easy to install the seismic locking device 630 without breaking the second connection when the spaced distance between the ceiling panels 600 is long, but the spaced distance between the ceiling panels 600 is In a narrow case, the operator may selectively break the second connection to facilitate installation of the seismic locking device 630. Of course, it is obvious that the separation distance between the ceiling panels 600 does not exceed the distance at which the seismic locking device 630, that is, the coupling protrusion 634 of the elastic body 632 can be inserted into the coupling groove 622 something to do.

In connection with the above, when the subframe 500 is made of the T-bar 510, the ceiling panel 600 installed on the outermost side of the ceiling panel 600 of the present invention has one edge of the finish molding 700 described above. The rim 610 other than the one side rim 610 is mounted on and installed on the stepped jaws of the tee bar 510 and the cross tee bar 530.

In addition, when the ceiling panel 600 of the present invention is made of the subframe 500 as the T-bar 510, one side of the ceiling panel 600 installed on the outermost side is seated and installed on the finishing molding 700. , Stably supported, one side of the ceiling panel 600 installed on the outermost side has no edge 610 formed, and one side of the lower body 620 is mounted and installed on the finish molding 700.

At this time, the finishing molding 700 is formed in the longitudinal direction on the inner surface, as shown in Figs. 16 and 17, a support protrusion 710 which is formed to protrude to form an internal groove 712, and the internal groove ( It is characterized in that it is configured to include at least one elastic fixing pin 720 that is inserted into one side of the 712 and the other side is inclined in the lower direction of the other side.

That is, in the finishing molding 700, one side of the elastic fixing pin 720 is supported by the internal groove 712 so that the other side of the elastic fixing pin 720 is elastically supported in a downward direction, and the ceiling panel ( After one side of 600) is seated, it is elastically supported in a downward direction by the other side of the elastic fixing pin 720, thereby realizing the effect of maintaining a more firmly and stably fixed state.

At this time, the elastic fixing pin 720 is configured to include an elastic reinforcing portion 722 formed by bending one side downward at one end, and when the elastic reinforcing portion 722 is inserted into the inner groove 712, the other side An elastic force is generated in the downward direction to realize the above effect.

In addition, the elastic fixing pin 720 may be configured to further include an elastic reinforcing portion 722 formed by bending both end surfaces of the inclined surface in the horizontal direction, which allows the operator to use one side of the elastic fixing pin 720 The elastic force can be generated regardless of one side or the other side by allowing the end surface of the elastic reinforcing part 722 to be installed in the inner groove 712 of the finish molding 700 so that the end faces face down without dividing the side and the other side. By making it possible, an effect of improving workability can be obtained.

On the other hand, it will be apparent that the ceiling panel 600 of the present invention can be installed by being replaced with an LED lamp, as shown in FIGS. 6 and 11, and when the subframe 500 is made of a T-bar 510, the When the LED luminaire is installed with an edge mounted like the ceiling panel 600, and the subframe 500 is made of an embar 520, the edge of the LED luminaire may be coupled to the embar 520 by a screw.

As a result, the ceiling structure system of the present invention can obtain the effect of securing economical efficiency by improving the workability by using the seismic TM clip 400 that can selectively install the tibar 510 and the embar 520, In particular, when the T-bar 510 is installed as a sub-frame 500, the ceiling panels 600 are organically connected and elastically fixed by using the seismic locking device 630 to improve the stability of the ceiling panel 600. The ceiling panel 600 located on the outermost side using the pin 720 is also able to stably maintain the installed state even in a shake due to wind pressure or earthquake, thereby improving stability, economy, and earthquake resistance.

The above has been described with reference to a preferred embodiment of the present invention, and is not limited to the above embodiment, and through the above embodiment, those of ordinary skill in the art to which the present invention belongs do not depart from the gist of the present invention. This can be done with various changes in.

100: hanger bolt 200: resistant hanger 210: coupling portion
300: main frame 400: seismic TM clip 410: seat
420: extension part 430: first support rib 440: embar groove
450: T-bar groove 452: Round 1 surface 454: Round 2 surface
460: second support rib 500: subframe 510: t-bar
520: Emba 530: Cross-Tiva 600: Ceiling panel
610: frame 700: finished molding 710: support protrusion
712: internal groove 720: elastic fixing pin

Claims (7)

Hanger bolts 100 installed on the ceiling slab; And
An anti-progress hanger 200 that is installed so that the hanger bolts 100 are connected to the upper part and the coupling part 210 is formed at the lower part; and
The main frame 300 seated on the coupling part 210 of the earthquake-resistant hanger 200; And
Seismic TM clip 400 mounted on the upper portion of the main frame 300; And
A sub-frame 500 made of any one of a t-bar 510 or an embar 520 that slides and is coupled to the main frame 300 under the seismic TM clip 400 in a perpendicular direction; and
A ceiling panel 600 installed on the subframe 500; And
It is configured to include; a finishing molding 700 installed on the wall surface 10 adjacent to the ceiling slab,
The ceiling panel 600 is
A lower body 622 protruding downward and having a coupling groove 622 formed on the slope; and
And a seismic locking device 630 in which one side is inserted and coupled to the coupling groove 622 and the other side is inserted and coupled to the coupling groove 622 of the adjacent ceiling panel 600, and includes,
The finishing molding 700 is
Doedoe formed in the longitudinal direction on the inner surface, the support protrusion 710 which is formed to protrude to form an internal groove 712
Including; an elastic fixing pin 720 for elastically fixing the upper portion of the ceiling panel 600 installed on the outermost side by being installed so that one side is inserted into the inner groove 712 and the other side is inclined downward,
The seismic locking device 630 is
An elastic body 632 formed in a zigzag shape; And
A coupling protrusion 634 protruding from one side and the other side of the elastic body 632 to be inserted into and coupled to the coupling groove 622 of the ceiling panel 600; And
A ceiling structure system having improved economy and earthquake resistance, comprising: a closing member 636 fitted under the elastic body 632 so as to surround the elastic body 632.
The method of claim 1,
The seismic TM clip 400 is
A seating portion 410 that is seated on the upper portion of the main frame 300; and
Extension portions 420 formed extending downwardly on both sides of the seating portion 410 to surround opposite side surfaces of the main frame 300; And
At least one or more first support ribs 430 protruding below the inner surface of the extension part 420; And
Emba grooves 440 formed in the lower front and rear sides of the extension part 420; And
A t-bar groove 450 formed in the lower center of the extension part 420; And
Including; a second support rib 460 protruding outwardly of the T-bar groove 450, wherein the lower portion of the second support rib 460 extends upwardly, providing economical and earthquake-resistant properties. Improved ceiling structure system.
The method of claim 1,
The ceiling panel 600 is
When the subframe 500 is made of an embar 520, it is fixed and installed by a screw at the lower part of the embar 520, and when installed at the outermost side, one side is seated and installed on the finish molding 700 Ceiling structure system with improved economy and earthquake resistance, characterized in that it is.
The method of claim 1,
When the sub-frame 500 is made of a t-bar 510, a cross t-bar 530 coupled to a side surface of the t-bar 510 in an orthogonal direction; a ceiling having improved economy and vibration resistance, characterized in that it includes Rescue system.
The method of claim 4,
The ceiling panel 600 is
A ceiling structure system with improved economy and earthquake resistance, characterized in that the rim 610 is mounted and installed on the stepped jaws of the ti bar 510 and the cross ti bar 530.
delete The method of claim 1,
The coupling portion 210 of the anti-seismic hanger 200 is a ceiling structure system with improved economy and earthquake resistance, characterized in that it is configured to include a guide groove formed on both sides of the bent portion and a bent hole formed through the middle.

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