KR20220089015A - Ceiling frame system for finishing materials of building ceiling with seismic function - Google Patents

Abstract

A ceiling frame system for a building ceiling finishing material to which the earthquake-resistant function of the present invention is applied for solving the above problems includes a fixing bolt connected to the slab of the building ceiling, a hanger coupled to the lower end of the fixing bolt and formed to support various members, A carrying channel that is seated and fixed on the hanger, an embar positioned below the carrying channel, the upper part is open, and the lower surface is formed so that a ceiling finishing material can be mounted, and the carrying channel is formed to be seated therein; is coupled to the open portion of the embar, characterized in that it comprises a seismic clip for fixing the carrying channel and the embar in close contact with each other.

Description

Ceiling frame system for finishing materials of building ceiling with seismic function

The present invention relates to a ceiling frame system for a building ceiling finishing material to which an earthquake-resistant function is applied, and more particularly, to a ceiling frame system for a building ceiling finishing material to which an earthquake-resistant function is applied, which can prevent the ceiling frame from being separated when vibration occurs due to an earthquake.

In general, a ceiling finishing material for preventing exposure of various wiring or ventilation ducts installed on the ceiling while shielding a concrete slab is installed on the ceiling of a building used by multiple people, such as educational facilities and medical facilities.

The ceiling material is supported by a ceiling frame fixed to the slab, and after installing a carrying channel (Carring chanel) on a plurality of hangers fixed to the ceiling slab, a ceiling finishing material is installed under the carrying M-bar. method is being used.

Since earthquakes occur frequently in Korea, the importance of earthquake-resistant design is being emphasized in order to respond to earthquakes.

In addition, when a building is subjected to vibration or strong shock caused by a natural disaster such as an earthquake or typhoon, the ceiling frame shakes, and in the process of shaking, the members connecting the ceiling frame are twisted or separated, causing the ceiling frame to collapse and cause an accident. .

Korean Patent Publication No. 10-2018-0052205 for solving this problem relates to an earthquake-resistant ceiling structure and a construction method thereof, and it is characterized in that it is prevented from being separated by vibration by fastening and fixing the connection part with a bolt. is doing

However, in the case of the prior art as described above, since it is fastened and fixed by bolts, it can be firmly fixed, but it takes a long time to construct, and since it is necessary to work on the ceiling with tools and members, a safety accident due to a fall during work may occur. There was a risk that

Korean Patent Publication No. 10-2018-0052205

An object of the present invention to solve the above problems is to prevent the clip connecting the carrying channel and the embar from being separated when the building is shaken by an earthquake or typhoon, and to prevent the carrying channel and the embar from being displaced or moved It is to provide a ceiling frame system for a building ceiling finishing material to which an earthquake-resistant function is applied.

Another object of the present invention is to provide a ceiling frame system for a building ceiling finishing material to which a seismic resistance function is applied, since a clip can be easily combined with one touch when the carrying channel is connected to the embar.

Another object of the present invention is to provide a ceiling frame system for a building ceiling finishing material to which a seismic resistance function is applied so that a gap between the clip and the carrying channel is not generated due to the elastic force of the clip, so that the carrying channel and the embar can be firmly in close contact. will be.

A ceiling frame system for a building ceiling finishing material to which the earthquake-resistant function of the present invention is applied for solving the above problems includes a plurality of fixing bolts connected to the slab of the building ceiling, and a plurality of fixing bolts coupled to the lower end of the fixing bolts and formed to support various members A hanger, a plurality of carrying channels seated and fixed on the hanger, a plurality of embars positioned below the carrying channel, the upper part is open, and the lower surface formed so that the ceiling finishing material can be mounted, and the carrying channel are seated inside It is formed so that the lower end is coupled to the open portion of the embar, a plurality of seismic clips for fixing the carrying channel and the embar to each other, and a plurality of minor channels formed on the upper part of the carrying channel to connect each carrying channel to each other , including a plurality of minor clips for fixing the minor channel and the carrying channel by coupling, the seismic-proof clip includes a contact plate formed flat to be in contact with the upper surface of the carrying channel, and a contact plate formed at both ends of the contact plate, respectively, to the lower side It is characterized in that it is formed of a connecting plate that is bent obliquely toward the embar so as to be combined with the embar.

In addition, the embar of the ceiling frame system for a building ceiling finishing material to which the earthquake-resistant function of the present invention is applied has a support end protruding horizontally toward the center to support the lower surface of the carrying channel on both upper sides, respectively, and vertical from the support end to the lower side It further includes a locking end that protrudes to the side, wherein the connecting plate protrudes outward from both sides of the lower side to a receiving end formed to be flat so that the locking end can be supported, and a receiving end protruding from the side of the receiving end toward the upper side and the supporting end and a protruding end inserted between the engaging ends to prevent it from escaping to the upper side, and formed at both lower side corners so that when the connecting plate is inserted into the embar, the support end and the engaging end are pushed to both sides to be able to enter It is characterized in that it further comprises an insertion end made of an arc shape.

In addition, the connecting plate of the ceiling frame system for a building ceiling finishing material to which the seismic function of the present invention is applied applies an external force when connecting the carrying channel and the embar so that the bent angle is formed vertically, so that the height of the connecting plate is higher than the height of the carrying channel. The vertical height is formed to be long, and when the connecting plate is inserted and fixed in the embar, the vertical height of the connecting plate is reduced while being restored to the initial angle by an elastic force. characterized in that

In addition, the contact plate of the ceiling frame system for a building ceiling finishing material to which the earthquake-resistant function of the present invention is applied has an embossing projecting to the outside on the inner surface where the carrying channel is in contact, so that a gap occurs when the carrying channel is in contact with the contact plate. It is characterized by preventing it from happening.

In addition, when the connecting plate of the seismic clip of the ceiling frame system for a building ceiling finishing material to which the seismic function of the present invention is applied is lowered toward the open part of the embar, the seismic clip is opened by pushing the open part of the embar to both sides. It is characterized in that it is inserted into the embar to be coupled.

As described above, according to the ceiling frame system for a building ceiling finishing material to which the earthquake-resistant function according to the present invention is applied, when the building is shaken by an earthquake or typhoon, the clip connecting the carrying channel and the embar is prevented from being separated, and the carrying channel and the embar are not separated. It has the effect of preventing it from being misplaced or moved.

In addition, according to the ceiling frame system for a building ceiling finishing material to which the earthquake-resistant function according to the present invention is applied, when the carrying channel is connected to the embar, the clip can be easily combined with one touch, so that the constructability is simple.

In addition, according to the ceiling frame system for a building ceiling finishing material to which the seismic function according to the present invention is applied, a gap generated between the clip and the carrying channel is not generated by the elastic force of the clip, so that the carrying channel and the embar can be firmly attached. have.

1 is a perspective view showing the structure of a ceiling frame system for a building ceiling finishing material to which a seismic function according to the present invention is applied.
Figure 2 is a view showing in detail the state coupled by the earthquake-proof clip of the ceiling frame system for the ceiling finishing material for a building to which the earthquake-resistant function according to the present invention is applied.
3 is a perspective view showing a seismic clip of a ceiling frame system for a building ceiling finishing material to which a seismic function according to the present invention is applied.
Figure 4 is an enlarged view showing the side and the coupling structure of the earthquake-resistant clip of the ceiling frame system for a building ceiling finishing material to which the earthquake-resistant function according to the present invention is applied.
5 is a front view showing the front of the ceiling frame system for a building ceiling finishing material to which the earthquake-resistant function according to the present invention is applied.
6 is a perspective view showing a state in which the seismic clip of the ceiling frame system for a building ceiling finishing material to which the earthquake-resistant function according to the present invention is applied connects the carrying channel and the embar.
7 is a side view showing a state in which the seismic clip of the ceiling frame system for a building ceiling finishing material to which the seismic function according to the present invention is applied is coupled to the embar.

Specific features and advantages of the present invention will be described in detail below with reference to the accompanying drawings. Prior to this, when it is determined that a detailed description of a function and a configuration related to the present invention may unnecessarily obscure the gist of the present invention, a detailed description thereof will be omitted.

The present invention relates to a ceiling frame system for a building ceiling finishing material to which an earthquake-resistant function is applied, and more particularly, to a ceiling frame system for a building ceiling finishing material to which an earthquake-resistant function is applied, which can prevent the ceiling frame from being separated when vibration occurs due to an earthquake.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view showing the structure of a ceiling frame system for a building ceiling finishing material to which a seismic function according to the present invention is applied.

As shown in FIG. 1, the ceiling frame system for a building ceiling finishing material to which the earthquake-resistant function according to the present invention is applied includes a plurality of fixing bolts 110 connected to the slab of the building ceiling, and the lower end of the fixing bolts 110, and various members a plurality of hangers 100 formed to support A plurality of embars 300 formed so that the ceiling finishing material can be mounted therein, and the carrying channel 200 are formed to be seated therein, and the lower end is coupled to the open portion of the embar 300 and the carrying channel 200 and the embar. A plurality of seismic clips 400 for fixing the 300 in close contact with each other, a plurality of minor channels 500 formed on the upper portion of the carrying channel 200 to connect each carrying channel 200 to each other, and a minor It is characterized in that it includes a plurality of minor clips 600 for fixing the channel 500 and the carrying channel 200 by coupling.

The fixing bolt 110 is coupled to the slab of the ceiling, and is used to fix the position of the hanger 100 coupled to the lower end.

At this time, the hanger 100 coupled to the lower end of the fixing bolt 110 is formed to be able to adjust the height, so it is preferable to adjust the position of the carrying channel 200 inserted into the hanger 100 and fixed thereto.

In addition, a plurality of the fixing bolts 110 and the hangers 100 are arranged at regular intervals. As an example, the fixing bolts 110 and the hangers 100 are installed at intervals of 900 mm, and the carrying channel 200 is 300 mm. It can be installed at intervals.

At this time, only a portion of the carrying channel 200 can be fixed by the hanger 100 , and a minor channel 500 is formed on the upper portion of each carrying channel 200 , and the carrying channel 200 and the minor channel 500 are formed. Minor clips 600 for connecting to each other are mounted.

At this time, the minor clip 600 is formed in a U-shape to surround the outer surface of the minor channel 500, and a groove is formed at the bottom so that the side of the carrying channel 200 can be inserted, and the minor clip 600 is mounted. Then, it is possible to fix the minor channel 500 and the carrying channel 200 in a one-touch form.

That is, the carrying channel 200 coupled to the hanger 100 is directly connected to the ceiling slab, and the carrying channel 200 not coupled to the hanger 100 is a minor channel 500 and a minor clip 600. It is connected to the carrying channel 200 coupled to the hanger 100 so that it can be fixed.

Therefore, a plurality of carrying channels 200 are arranged at regular intervals by the hanger 100, the minor channel 500 and the minor clip 600 to be installed on the ceiling, and the minor channel 500 is the hanger 100. It is preferable that the carrying channel 200 is not tilted or sagged by being formed between them.

Embar 300 is to allow the ceiling finishing material to be attached to the lower surface of the building interior, a plurality of pieces are arranged at regular intervals in the lower portion of the carrying channel 200, and in a direction perpendicular to the arrangement direction of the carrying channel 200 will be placed horizontally.

At this time, the upper surface of the embar 300 is open, so that the lower part of the seismic clip 400 for connecting the carrying channel 200 and the embar 300 to each other is inserted into the open upper surface of the embar 300 while being inserted into the embar 300. ) and the carrying channel 200 can be connected to each other to be fixed.

The seismic clip 400 is formed so that the carrying channel 200 can be inserted therein, and the lower part is fixed after being inserted into the open upper surface of the embar 300 to provide the carrying channel 200 and the embar 300. They are fixed in close contact with each other.

The detailed configuration of the seismic clip 400 will be described later in detail with reference to the accompanying drawings.

2 is a view showing in detail the state coupled by the seismic clip 400 of the ceiling frame system for a building ceiling finishing material to which the earthquake-resistant function according to the present invention is applied, and FIG. 3 is a building ceiling finishing material to which the earthquake-resistant function according to the present invention is applied It is a perspective view showing the seismic clip 400 of the ceiling frame system, and FIG. 4 is an enlarged view showing the side and the coupling structure of the seismic clip 400 of the ceiling frame system for a building ceiling finishing material to which the seismic function according to the present invention is applied.

2 to 4, the earthquake-resistant clip 400 of the ceiling frame system for a building ceiling finishing material to which the earthquake-resistant function according to the present invention is applied is a contact that is formed flat to be in contact with the upper surface of the carrying channel 200 It is characterized in that it consists of a plate 410 and a connecting plate 420 formed at both ends of the contact plate 410 and bent in a downward direction so as to be coupled with the Embar 300 .

The contact plate 410 is formed to be flat so as to be in close contact with the upper surface of the carrying channel 200, and it is preferable that the width of the upper surface of the carrying channel 200 is formed so that it can be inserted therein. .

The connecting plate 420 is inclined at an angle set from both ends of the contact plate 410 to the lower side, respectively, and the lower width of the connecting plate 420 is larger than the upper width connected to the contact plate 410 . will be formed

At this time, the connecting plate 420 is formed to be rotated by an external force based on both ends of the contact plate 410, and when the external force is removed, it is restored to its initial position based on both ends of the contact plate 410 by an elastic force. be able to

That is, since the lower part of the connecting plate 420 can be rotated by an external force and is formed to be restored by an elastic force, the building shakes due to an earthquake and the carrying channel 200 and the embar 300 shake while the connecting plate 420 is shaken. Even if one end or the other end is pressed and the position is changed, the position of the carrying channel 200 and the embar 300 can be prevented from being separated while being restored to the initial position by the elastic force.

In addition, the embar 300 has a support end 310 that protrudes in a horizontal direction toward the center to support the lower surface of the carrying channel 200, respectively, on both sides of the upper side, and a hook that protrudes vertically from the support end 310 to the lower side. It is characterized in that it further comprises a stage (320).

In addition, the connection plate 420 of the seismic clip 400 has a receiving end 430 that protrudes from both sides of the lower to the outside so that the engaging end 320 can be supported, and an upper portion from the side of the receiving end 430 . The protruding end 440 protrudes in the direction and is inserted between the support end 310 and the engaging end 320 to prevent it from being separated in the upper direction, and the connecting plate 420 is formed at both lower side corners, respectively, to form the embar (300). It is characterized in that it consists of an insertion end 450 formed in an arc shape so that the support end 310 and the locking end 320 can be pushed to both sides when inserted into the .

When the seismic clip 400 is coupled to the embar 300, the receiving end 430, the protruding end 440, the insertion end are located on both lower sides of the seismic clip 400 to be automatically fastened when pressed in the vertical direction. 450 is formed, respectively, and the embar 300 has a support end 310 and a locking end 320 formed on both sides of the opened upper portion to prevent the protruding end 440 from being separated.

First, the embar 300 has an upper opening, and a support end 310 and a locking end 320 protruding in the shape of an L are formed on both sides of the upper portion.

Here, the support end 310 refers to a portion in which both sides of the embar 300 are bent in a horizontal direction, and the engaging end 320 is a portion in which the support end 310 bent in a horizontal direction is again bent in a vertical direction. .

The receiving end 430 of the seismic clip 400 protrudes from the lower both sides of the connecting plate 420 to the outer surface, and the upper surface is flat so that the engaging end 320 of the embar 300 can be in close contact with it. do.

The protruding end 440 is protruded from the side of the receiving end 430 to the upper direction so that it can be inserted between the engaging end 320 and the supporting end 310 of the Embar 300, but is made of a right-angled triangle shape, but in the form of a hook; Any deformed shape such as a hook shape may also be included.

The insertion end 450 is a resistance generated when the connecting plate 420 is inserted into the upper surface of the open Embar 300 by rounding it in an arc shape from both lower edges of the connecting plate 420 to the protruding end 440 . It is used to reduce the embar 300 through the arc-shaped insertion end 450 and to guide the spread to both sides.

That is, when the seismic clip 400 is inserted into the Embar 300, the Embar 300 can be spread to both sides by the insertion end 450, and when the insertion is complete, the engaging end 320 of the Embar 300 is The receiving end 430 is supported in close contact with the upper surface, and the protruding end 440 is positioned between the supporting end 310 and the engaging end 320 to prevent the seismic clip 400 from falling out from the embar 300 . be able to

In addition, the seismic clip 400 has a rib 460 protruding to the outside is formed, and the seismic clip 400 is inserted into the embar 300 through the rib 460 or a rib caused by an impact force generated when the building shakes ( 460) can be prevented from occurring.

At this time, the rib 460 extends from the connecting plate 420 formed at one end of the contact plate 410 to the connecting plate 420 formed at the other end of the contact plate 410 because the seismic clip 400 is pressed in the vertical direction. It is preferable that the 460 is formed, and a plurality of ribs 460 may be dispersedly formed.

In addition, the rib 460 may be formed by pressing the inner surface in the outer surface direction, and it is preferable that the rib 460 is formed in the width direction at the lower portion of the connecting plate 420 .

Although the present invention shows the form in which the ribs 460 are formed in a U-shape, the number or shape of the ribs 460 may be modified.

In addition, the material of the seismic clip 400 can be made of high carbon steel or carbon tool steel, and in order to improve mechanical properties, primary heat treatment is performed at 750 to 950 degrees Celsius for 5 to 15 minutes, and at 250 to 450 degrees Celsius The hardness can be improved by performing secondary heat treatment for 15 to 25 minutes.

The first heat treatment is performed at high temperature for a short time, and the second heat treatment is performed for a longer time than the first heat treatment to secure the mechanical properties of the seismic clip 400 for supporting the carrying channel 200 and the embar 300 be able to do

5 is a front view showing the front of the ceiling frame system for a building ceiling finishing material to which the earthquake-resistant function according to the present invention is applied.

As shown in FIG. 5 , the seismic clip 400 of the ceiling frame system for a building ceiling finishing material to which the seismic function according to the present invention is applied is a contact plate 410 formed flat to be in contact with the upper surface of the carrying channel 200 . ) and a connecting plate 420 formed at both ends of the contact plate 410 and bent at an angle of 50 to 80 degrees toward the lower side so that it can be combined with the Embar 300. .

The connecting plate 420 is formed to be bent downward from both ends, respectively, and the theta (θ) angle is formed to be inclined by 50 to 80 degrees as shown in FIG. 6 .

When the inclination angle is less than 50 degrees, since the vertical height of the earthquake-resistant clip 400 is lower than the height of the carrying channel 200, the earthquake-proof clip 400 cannot be coupled to the embar 300, and the inclination angle is 80 degrees. When it exceeds, since the seismic clip 400 approaches the U-shape, the vertical height becomes higher than that of the carrying channel 200 , so that a gap is generated between the carrying channel 200 and the contact plate 410 .

That is, the inclination angle is preferably maintained between 50 and 80 degrees so that the carrying channel 200 can be accommodated therein and coupled with the embar 300 , and when combined, the outer surface of the connecting plate 420 is pressed When the connecting plate 420 maintained in a vertical state by elastic force is restored to the initial angle when coupled to the embar 300 after maintaining it in a vertical state, the inner surface of the contact plate 410 is the carrying channel 200 of It can be adhered to the upper surface.

A detailed description related thereto will be provided later along with FIGS. 6 and 7 .

In addition, the contact plate 410 has an embossing 470 protruding outwardly formed on the inner surface to which the carrying channel 200 is in contact, so that a gap is not generated when the carrying channel 200 is in contact with the contact plate 410 . characterized in that

The embossing 470 formed on the contact plate 410 protrudes in the inner surface direction and is used to closely contact the upper surface of the carrying channel 200 when the carrying channel 200 is in contact.

At this time, when the embossing 470 is pressed while in contact with the carrying channel 200, it is preferable to allow the embossing 470 of the contacted surface to be flattened, and the embossing 470 may be formed as a single body as shown in FIG. If necessary, a plurality of embossing 470 may be formed on the contact plate 410 .

In a state in which the seismic clip 400 is coupled to the embar 300 through the embossing 470, the carrying channel 200 is lowered by filling the gap generated by the dimensional tolerance between the carrying channel 200 and the contact plate 410. It is possible to maintain the state in close contact by pressing in the direction.

In addition, if necessary, the upper portion of the contact plate 410 is pressed in the lower direction so that the embossing 470 protrudes in the inner surface direction, or a hole is formed in the upper portion of the contact plate 410 and bolted to fasten the carrying channel 200. It is possible to fill the gap between the and the contact plate 410 .

6 is a perspective view showing a state in which the earthquake-resistant clip 400 of the ceiling frame system for a building ceiling finishing material to which the earthquake-resistant function according to the present invention is applied connects the carrying channel 200 and the Embar 300.

As shown in Fig. 6, the connecting plate 420 of the earthquake-resistant clip 400 formed in the ceiling frame system for a building ceiling finishing material to which the earthquake-resistant function according to the present invention is applied is an external force when connecting the carrying channel 200 and the embar 300. is applied so that the bent angle is formed vertically so that the vertical height of the connecting plate 420 is longer than the height of the carrying channel 200, and when the connecting plate 420 is inserted into the embar 300 and fixed, the elastic force It is characterized in that the vertical height of the connecting plate 420 is reduced while the contact plate 410 is in close contact with the carrying channel 200 to prevent a gap from being generated while being restored to the initial angle.

In order to connect the carrying channel 200 and the embar 300 using the earthquake-proof clip 400, first press the lower end of the earthquake-proof clip 400 inward as shown in FIG. 6 to form the earthquake-proof clip 400 in a U-shape. let it go

In this state, the vertical distance from the connecting plate 420 to the contact plate 410 of the seismic clip 400 becomes the maximum length, so the length remains even in the state in which the carrying channel 200 is inserted. The lower end is in a state protruding toward the upper surface of the embar (300).

That is, since the total length of the seismic clip 400 is longer than the carrying channel 200 even in a state in which the carrying channel 200 is inserted in the seismic clip 400, it is inserted into the open portion of the embar 300 located at the bottom. When the protruding end 440 of the seismic clip 400 is inserted into the supporting end 310 and the engaging end 320 of the embar 300, the seismic clip 400 is constrained in the vertical direction, so the carrying channel ( 200) and the embar 300 can be connected.

In addition, when the external force applied to the connecting plate 420 is removed while the seismic clip 400 is coupled to the Embar 300 , the connecting plate 420 is restored to the initially bent angle by the elastic force, and the connecting plate 420 ) is inclined to both sides, the vertical length from the lower part of the connecting plate 420 to the contact plate 410 is reduced.

That is, when the angle of the connecting plate 420 is restored by the elastic force, the seismic clip 400 is lowered to the lower side, and accordingly, the contact plate 410 is in close contact with the upper surface of the carrying channel 200 to transmit the pressing force. be able to

7 is a side view showing a state in which the seismic clip 400 of the ceiling frame system for a ceiling finishing material for a building to which the seismic function according to the present invention is applied is coupled to the embar 300 .

7, the connection plate 420 of the seismic clip 400 formed in the ceiling frame system for a building ceiling finishing material to which the seismic function according to the present invention is applied is lowered toward the open portion of the embar 300 when the embar ( It is characterized in that the seismic clip 400 is inserted into and coupled to the embar 300 by pushing the opened portion of the 300) to both sides to open it.

The insertion end 450 formed in an arc shape formed on both sides of the lower side of the seismic clip 400 is the support end 310 formed on both sides of the embar 300 when the seismic clip 400 is lowered to the open upper surface of the embar 300 . ) and the engaging end 320 is pushed to the side while being pressed along the shape of the insertion end 450 so that the connection plate 420 of the seismic clip 400 can be inserted.

At this time, when the protruding end 440 extending from the insertion end 450 is inserted into the embar 300, the supporting end 310 and the engaging end 320 are restored to their original state by the elastic force and positioned in a vertical state. and the protruding end 440 formed on the connecting plate 420 is inserted into the gap between the support end 310 and the locking end 320 to prevent the seismic clip 400 from moving upward.

In addition, since the engaging end 320 of the embar 300 is formed in a state in close contact with the upper portion of the insertion end 450, the protruding end 440 is prevented from being separated. and the carrying channel 200 can be firmly fixed.

As described above, according to the ceiling frame system for a building ceiling finishing material to which the earthquake-resistant function according to the present invention is applied, when the building is shaken by an earthquake or typhoon, the clip connecting the carrying channel and the embar is prevented from being separated, and the carrying channel and the embar are not separated. can be prevented from being displaced or moved, and when the carrying channel is connected to the embar, the clip can be easily combined with one touch, making construction simple. This has the effect of making the carrying channel and the Embar firmly adhere.

As described above, the present invention has been mainly described with reference to preferred embodiments, but those of ordinary skill in the art to which the present invention pertains may vary the present invention within the scope that does not depart from the technical spirit and scope described in the claims of the present invention. It can be implemented by modifying or transforming it. Accordingly, the scope of the present invention should be construed by the appended claims including examples of many such modifications.

100: hanger 110: fixing bolt
200: carrying channel 300: embar
310: support end 320: catch end
400: seismic clip 410: contact plate
420: connection plate 430: receiving end
440: protruding end 450: insertion end
460: rib 470: embossing
500: minor channel 600: minor clip

Claims (6)

a plurality of fixing bolts connected to the slab of the building ceiling;
a plurality of hangers coupled to the lower end of the fixing bolt and formed to support various members;
a plurality of carrying channels seated and fixed on the hanger;
a plurality of embars positioned at the lower part of the carrying channel, the upper part is open, and the lower surface is formed so that the ceiling finishing material can be mounted;
a plurality of seismic clips formed so that the carrying channel is seated therein, and the lower end thereof is coupled to an open portion of the embar to fix the carrying channel and the embar in close contact with each other;
a plurality of minor channels formed on the carrying channel to connect each of the carrying channels to each other;
A plurality of minor clips for fixing the minor channel and the carrying channel by coupling them; characterized in that it comprises a
Ceiling frame system for building ceiling finishing materials with seismic resistance applied.
The method of claim 1,
The seismic clip is
a contact plate formed flat to be in contact with the upper surface of the carrying channel;
Connection plates formed at both ends of the contact plate and bent obliquely toward the lower side to be coupled with the Embar; characterized in that it comprises:
Ceiling frame system for building ceiling finishing materials with seismic resistance applied.
3. The method of claim 2,
The embar is
Support ends protruding in a horizontal direction toward the center to support the lower surface of the carrying channel on both upper sides, respectively;
It further comprises;
The connecting plate is
a receiving end protruding from both sides of the lower side to an outer surface and formed flat so that the engaging end can be supported;
a protruding end protruding from the side of the receiving end toward the upper side and inserted between the supporting end and the engaging end to prevent it from being separated toward the upper side;
It is characterized in that it further comprises a; it is formed in each of the lower both corners, the connecting plate made of an arc shape so as to push the support end and the engaging end to both sides to enter when the connecting plate is inserted into the embar.
Ceiling frame system for building ceiling finishing materials with seismic resistance applied.
3. The method of claim 2,
The connecting plate is
When connecting the carrying channel and the embar, the vertical height of the connecting plate is formed to be longer than the height of the carrying channel by applying an external force so that the bent angle is formed vertically,
When the connecting plate is inserted into the embar and fixed, it is restored to the initial angle by an elastic force and the vertical height of the connecting plate is reduced while preventing the contact plate from being in close contact with the carrying channel to prevent a gap from occurring.
Ceiling frame system for building ceiling finishing materials with seismic resistance applied.
3. The method of claim 2,
The contact plate is
An embossing projecting to the outer surface is formed on the inner surface in contact with the carrying channel to prevent a gap from being generated when the carrying channel is in contact with the contact plate.
Ceiling frame system for building ceiling finishing materials with seismic resistance applied.
3. The method of claim 2,
The connecting plate of the seismic clip is
When it descends toward the open portion of the embar, the seismic clip is inserted into and coupled to the embar by pushing the open portion of the embar to both sides to open it.
Ceiling frame system for building ceiling finishing materials with seismic resistance applied.

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