KR102424532B1 - roof assembly with seismic strengthening and reinforcing fireproof function - Google Patents

Abstract

The present invention relates to a roof assembly having seismic reinforcement and fire-resistance functions, which can minimize heat loss inside a building, comprising: a plurality of earthquake-resistant units (104); an insulation unit (106) for insulating a heat source inside a building; and a heat blocking unit (116) installed on an upper part of the insulation unit (106).

Description

Roof assembly with seismic strengthening and reinforcing fireproof function

The present invention relates to a roof assembly having earthquake-resistant reinforcement and fire-resistance functions, and more particularly, it is supported by a purlin installed on the upper part of a building and minimizes damage or damage in the event of an earthquake or vibration by an earthquake-resistant buffer structure. It relates to a roof assembly having earthquake-resistance reinforcement and fire-resistance functions that can minimize heat loss through the roof through the roof by constructing a ruler (S)-shaped insulating part and improve fire resistance.

In general, when a large-area steel structure roof such as a factory, auditorium, gymnasium, rest area, and airport is constructed with metal insulation panels, sandwich panels are often used. However, when special design conditions are required, such as sloping the roof or adding a curved shape to create aesthetics, it is not easy to construct only with a sandwich panel composed of an external steel plate, an insulating material, and an internal steel plate.

Accordingly, these sandwich panels are constructed to be supported by the roof structure, and the roof structure is installed on top of the girder, which is stipulated to have a fire-resistance structure in the Building Act, and is constructed to be supported by the main structure beam.

At this time, the main structural beam is usually provided with a steel structure such as an H-beam, and between the main structural beam and the roof structure, a purlin such as a C-beam extending in the transverse direction with respect to the longitudinal direction of the main structural beam is provided. It supports and reinforces the load of the roof including the structure.

An example of a roof structure according to the prior art is disclosed in Republic of Korea Patent Registration No. 10-1233079 (registered on February 07, 2013, hereinafter referred to as 'Patent Document 1') and the like.

However, according to the roof structure according to the prior art, there is a problem that damage or damage may increase when an earthquake or vibration occurs because there is no separate structure for buffering vibration when an earthquake occurs.

In addition, according to the roof structure according to the prior art, since there is no separate structure for blocking heat exchange, heat between the inside and outside of the building based on the roof cannot be insulated, but is transferred as it is, and heat loss inside the building through the roof may increase. There is this.

Republic of Korea Patent Registration No. 10-1233079 (Registered on Feb. 7, 2013)

An object of the present invention is to minimize damage or damage in the event of an earthquake or vibration by an earthquake-resistant buffer structure and at the same time to minimize heat loss inside a building through a roof by a heat exchange blocking structure And to provide a roof assembly having a fire resistance function.

The present invention uses an S-shaped insulating part to block heat from the outside and at the same time improve waterproof performance, absorb and buffer vibrations and shocks excellently in the event of an earthquake, and have a fireproof and fireproof resistance that is safe for fire It aims to provide a roof assembly having a function.

The present invention for achieving the above object is installed on the upper part of the purlin 101 installed on the roof of a building, supported by the purlin, and a top plate 12 in which a plurality of sound-absorbing holes are perforated, and a certain length along the length of the purlin. In a roof assembly provided with a base deck panel 102 having a plurality of concave troughs 14 formed on the upper plate portion 12 at intervals, the base deck panel 102 is supported by a purlin constructed on the upper part of the building. , A plurality of earthquake-resistant unit portions 104 installed in the valley portion 14 to absorb and buffer vibrations when an earthquake occurs to reinforce them from earthquake resistance; an insulator 106 installed on the earthquake-resistant unit 104 to block heat supplied from an external heat source and keep the heat source inside the building; It is installed on the upper portion of the heat insulating unit 106 and includes a heat blocking unit 116 having a waterproof function to block external solar heat and at the same time block moisture such as wind, rain, and water, and the earthquake-resistant unit unit 104 )Is,

a lower cap 118 in which a concave-convex lower body 16 is formed, an upper wing 18 is formed in the left and right directions at the upper end of the lower body 16, and a receiving recess 20 is formed in the inner portion; a compression spring 120 that is inserted and fixed in the receiving recess 20, elastically flows in the vertical direction, and absorbs and buffers vibration; The cap body 22 made of the channel shape is formed, the left and right ends of the cap body 22 are downwardly bent inward to form a lower wing 24, and a coupling groove is formed in the inner portion of the lower wing 24 ( 26) is formed and the upper wing 18 is fitted in close contact with the coupling groove 26 so that the compression spring 120 does not come off and the upper cap 122 is installed to absorb vibration and shock at the same time. ), characterized in that it contains.

The heat insulating part 106,

A heat insulating material fixing member 107 made of bent portions of the S-shaped (S) shape is formed, a lower coupling groove 44 is formed on one side of the lower end of the insulating material fixing member 107, and an upper portion is formed on one side of the upper end. A coupling groove 46 is formed, and the heat insulating material 108 is fitted in the forward direction in the lower coupling recess 44 to insulate, and the upper coupling recess 46 is fitted in the rear direction, thereby the heat insulating material 018 ) is preferably installed in a zigzag manner so that heat insulation is achieved.

The heat block 116 is,

a lower plate 126 comprising a body 48 having a fixing hole 50 at the right end so as to be vertically penetrating and formed in the shape of a niche; It is fitted at the upper part of the body 48 and is bent upwardly at one lower end to form a U-shaped bent part 54, and the upper end of the body 48 is bent in the left direction to bend the U-shaped (U) bent. a fixing clip 128 on which the part 60 is formed; a waterproofing piece 130 fitted to the bent portion 60 and installed to prevent water leakage flowing in from the outside; At the lower end of the panel body 64 formed vertically, a horizontal body 66 formed in the shape of a niche (b) is formed, and the upper end of the panel body 64 is bent in the left direction to form a panel bent portion 70, It is preferable that the panel bending portion 70 includes an upper panel 132 having a coupling groove 72 formed thereon to be seated on an upper portion of the lower plate 126 and installed to be fixedly coupled to the fixing clip 128 . do.

According to the present invention, it is possible to minimize damage or damage in the event of an earthquake or vibration by the earthquake-resistant buffer structure, and at the same time to minimize the heat loss inside the building through the roof by the heat exchange blocking structure, and there is a fire-safe effect.

1 is a perspective view showing the structure of a roof assembly having a seismic reinforcement and fire resistance function according to the present invention;
Figure 2 is a cross-sectional view showing the structure of the seismic unit portion of the roof assembly having a seismic reinforcement and fire-resistance function of the present invention;
3 is an exploded perspective view of FIG.
Figure 4 is a perspective view showing the structure of the insulating portion of the roof assembly of the present invention;
5 is a front sectional view showing the structure of a roof assembly having a seismic reinforcement and fire resistance function of the present invention;
6 is an exploded cross-sectional view showing the structure of the heat shield of the present invention;
7 is a side cross-sectional view showing the structure of a roof assembly having a seismic reinforcement and fire resistance function of the present invention;
8 is an exploded cross-sectional view showing the structure of a heat-blocking unit as another embodiment of the present invention;

The following objects, other objects, features and advantages of the present invention will be readily understood through the following preferred embodiments in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments described herein and may be embodied in other forms.

Rather, the embodiments introduced herein are provided so that the disclosed subject matter may be thorough and complete, and that the spirit of the present invention may be sufficiently conveyed to those skilled in the art.

The embodiments described and illustrated herein also include complementary embodiments thereof.

In this specification, the singular also includes the plural, unless specifically stated otherwise in the phrase. As used herein, the terms 'comprise' and/or 'comprising' do not exclude the presence or addition of one or more other components.

Hereinafter, the present invention will be described in detail with reference to the drawings. In describing the specific embodiments below, various specific contents have been prepared to more specifically explain and help the understanding of the invention. However, a reader having enough knowledge in this field to understand the present invention may recognize that it can be used without these various specific details. In some cases, it is mentioned in advance that parts which are commonly known and not largely related to the invention in describing the invention are not described in order to avoid confusion in describing the invention.

Hereinafter, the spray-type portable smoke sterilizer according to the present invention will be described in detail with the accompanying drawings.

1 is a perspective view showing the structure of a roof assembly having earthquake-resistant reinforcement and fire-resistance functions according to the present invention, and FIG. is an exploded perspective view of FIG. 2, and FIG. 4 is a perspective view showing the structure of the heat insulating part of the roof assembly of the present invention.

And, Figure 5 is a front cross-sectional view showing the structure of the roof assembly having an earthquake-resistant reinforcement and fire-resistance function of the present invention, Figure 6 is an exploded cross-sectional view showing the structure of the heat shield of the present invention, Figure 7 is the earthquake-resistant reinforcement and It is a side cross-sectional view showing the structure of a roof assembly having a fire resistance function.

In addition, FIG. 8 is an exploded cross-sectional view showing the structure of a heat shield according to another embodiment of the present invention.

1 to 8, the roof assembly 100 having an earthquake-resistant reinforcement and fire-resistance function of the present invention is first described with reference to FIG. 1, the C-shaped frame body 10 is A middle purlin 102 formed and installed on the upper part of the building, a base deck panel 102 installed to be supported by the middle purlin 101, and an earthquake-resistant unit that can absorb and buffer vibrations and shocks when an earthquake occurs ( 104), an insulating part 106 that can block external heat, an insulating material 108, a thermal insulation plate 110, a waterproof sheet 112, a sliding clip 114, and a heat blocking part 116. include

More specifically, a plurality of purlins 101 are installed in the horizontal direction on the lower surface, the base deck panel 102 is installed on the upper surface of the purlin 101, and the base deck panel 102 has an earthquake. A seismic reinforcement unit 104 for absorbing vibrations or shocks generated during generation is installed.

The base deck panel 102 is formed with a plate-shaped upper plate portion 12 supported by a purlin 102, and the upper plate portion 12 is formed of a plurality of perforated plates with perforations, and a plurality of concave portions are formed in the longitudinal direction. A plurality of valleys 14 are provided.

The perforation serves as a suction hole and the valley portion 14 is formed to be long in the longitudinal direction.

A plurality of valleys 14 of the base deck panel 102 are provided with a seismic-resistant unit 104 coupled to the plurality of valleys 14 to absorb vibration and shock when an earthquake occurs.

An S (S) shape is provided on the upper portion of the seismic unit 104 and a heat insulator 106 that can block heat from the outside is installed, and the piping materials of the building are installed on the upper portion of the heat insulator 106 . A thermal insulation plate 110 used as a finishing material for thermal insulation is installed.

Next, a waterproof sheet 112 for preventing water leakage from the outside is installed on the upper surface of the insulating plate 110, and an upper panel 132 formed in a seam-folding method is provided on the top of the waterproof sheet 112. A heat-blocking part 116 is installed, and a plurality of sliding clips 114 are fitted and fixed to one side of the upper panel 132 of the heat-blocking part.

The purlin 101 is provided with a metal plate made of aluminum formed in the longitudinal direction, and each of the upper and lower ends is formed in the shape of a seed (C) formed to be horizontally bent.

The heat insulating material 108 is preferably made of a non-combustible heat insulating material such as glass wool, and is fitted and fixed to the front part and the rear part of the heat insulating part 106 , respectively.

That is, the glass wool is fitted into the S-shaped front coupling groove and the rear coupling groove, respectively, to block heat from the outside.

The heat insulating material 108 is a fire-resistant material having heat-shielding and flame-resisting properties, and materials such as flame-retardant boards and flame-retardant plastic boards that can withstand fire without burning well in case of fire are used, or furthermore, glass wool, fiber cement board, gypsum cement. Incombustible materials, such as a board and an extruded cement board, can be used.

Subsequently, the insulating plate 110 and the waterproof sheet 112 are continuously stacked on the upper surface of the heat insulating part 106 and installed.

On the other hand, the sliding clip 114 is installed at the same time as the installation of the upper panel 132, and penetrates the waterproof sheet 112 and the thermal insulation plate 110 to be attached to the fixing means on the upper surface of the insulating material 106. It is fixed by the upper panel 132 and is fitted between the upper panel 132 and fixed to protect it from vibration and shock generated from the outside when an earthquake occurs.

The upper panel 132 is provided in a beaded fold type to finish the roof, and is provided slidably on the upper end of the foldable protrusion, and includes a sliding clip 114 for fastening and fixing the foldable upper panel.

2 and 3 are a front sectional view and an exploded perspective view showing the structure of the seismic unit 104 of the present invention, the lower cap 118 seated and installed in the valley 14, and the inner part of the lower cap 118 A plurality of compression springs 120 seated and installed in the vertical direction to be elastically buffered, and the upper cap 122 and the upper cap 122 installed to flow in the vertical direction while elastically pressing the compression spring 120 . It includes a reinforcing rail 124 that is fitted and fixed at the same time as being seated on the upper part of the .

The compression spring 120 is inserted and fixed to the inner surface of the lower cap 118 , and the upper cap 122 is fitted to the upper portion of the lower cap 118 , and the upper portion of the upper cap 122 is reinforced. The rail 124 is coupled and installed from the top to the bottom.

A plurality of compression springs 120 are fixedly installed in the inner space where the lower cap 118 and the upper cap 122 are coupled, and the plurality of compression springs 120 elastically flow in the vertical direction while vibrating. And buffering is made by absorbing the shock.

3, the lower cap 118 is formed elongated in the transverse direction and is composed of a lower body 16 having a concave coupling groove 20 in the center thereof, and Upper wings 18 that protrude in the left and right horizontal directions are formed on the left and right sides of the upper side, respectively.

The upper cap 122 extends long in the transverse direction to form a cap body 22, and both ends of the cap body 22 are bent inwardly in a digut shape (c) shape, and the lower wing 24 is bent. On the inner side of the lower wing 24, coupling grooves 26 are formed on the left and right sides, respectively.

The reinforcing rail 124 is formed with a rail body 30 elongated in the horizontal direction, and both ends of the rail body 30 are vertically bent downward to form a bent portion 32 .

The upper wing 18 of the lower cap 118 formed as described above is inserted and coupled to the coupling groove 26 of the upper cap 122 , and the lower surface of the upper wing 18 is the lower wing 24 . It is coupled and installed so as to fit into the upper surface part.

As the lower cap 118 and the upper cap 122 are coupled as described above, the compression spring 120 is firmly fixed without being separated, thereby resiliently providing a cushioning action.

On the other hand, a fixing hole 28 is formed in the central portion of the upper cap 122 , and fixing means such as a bolt, a nut, a rivet, and a pin are coupled to the fixing hole 28 in the center of the compression spring 120 . It is preferable to install it so that it penetrates the inner diameter and is fixed to the bottom surface of the lower cap 118 .

As described above, the lower cap and the upper cap installed by the fixing means strongly tighten or loosen the fixing means, so that the compression spring is compressed up and down, the height is adjusted, and the elasticity of the buffer can be adjusted.

The earthquake-resistant unit part 104 is provided to be seated in the valley part 14 of the base deck panel 102, and transmits vibration between the middle purlin 101 and the heat insulating part 106 by the elastic restoring force of the compression spring 120. It fills up

Accordingly, the vibration transmitted from the heat insulation unit 106 to the middle purlin 101 through the base deck panel 102 and the vibration transmitted from the middle purlin 101 to the heat insulation unit 106 through the base deck panel 102 are earthquake-resistant. By effectively absorbing, buffering, and blocking the unit 104, damage or damage can be minimized when an earthquake or vibration occurs.

Continuing, Figure 4 is a view showing the structure of the heat insulating unit 106 of the present invention, the base deck panel 102 is installed at the bottom and the heat insulating unit 106 is installed on the upper surface of the base deck panel 102, have.

The heat insulating part 106 is made of a heat insulating member 107 formed in an S (S) shape and a pair of upper and lower heat insulating materials 108 coupled to the heat insulating material fixing member 107, and the heat insulating material 108 is the front lower end part. It includes a heat insulator that is horizontally coupled to the insulator and a heat insulator that is horizontally coupled to the upper end of the rear surface.

The insulator fixing member 107 is first formed with an intermediate horizontal portion 34 and vertically bent downwardly to the right of the intermediate horizontal portion 34 to form a right vertical portion 36, and the right vertical portion ( 36) is bent in the left horizontal direction to form a lower horizontal portion 38.

Then, the middle horizontal portion 34 is bent upwardly to the left to form a left vertical portion 40 , and is bent in the upper right horizontal direction of the left vertical portion 40 to form an upper horizontal portion 42 . .

At this time, a lower coupling groove 44 concave in the forward direction is formed between the intermediate horizontal portion 34 and the lower horizontal portion 38 , and between the intermediate horizontal portion 34 and the upper horizontal portion 42 . An upper coupling groove 46 concave in the rear direction is formed.

In addition, in the lower coupling groove 44, the heat insulating material 108 horizontally moves from the front direction to the rear direction and is fitted, and in the upper coupling recess 46, the heat insulating material 108 horizontally moves from the rear direction to the front direction, fitting is joined

5 is a front cross-sectional view showing the structure of a roof assembly having earthquake-resistant reinforcement and fire-resistance functions according to the present invention. First, a heat insulator 106 for blocking heat from the outside is installed, at the top of the purlin 101. The base deck panel 102 is installed, and the heat insulating part 106 is installed on the upper surface of the base deck panel 102 .

The heat insulating part 106 is seated and installed so as to be in contact with the upper surface of the earthquake-resistant unit part 104 , and is made to absorb and buffer shock by the earthquake-resistant unit part 104 .

The heat insulating material 108 installed by being inserted into the heat insulating part 106 is made of a glass wool material having a plurality of air layers formed therein, and the upper surface of the heat insulating part 106 is provided with an upper panel 132 formed by seam folding. End 116 is installed.

Between the heat insulating part 106 and the heat blocking part 116, that is, on the upper surface of the insulating part 106, a thermal insulation plate 110 as a thermal insulation finishing material is laminated and installed, and a waterproof sheet is installed on the upper surface of the thermal insulation plate 110. (112) is installed,

A hollow space formed with a plurality of air layers formed between the heat insulating plate 110 used as a finishing material for the roof of a building and the heat insulating part 106 is formed. At the same time, it is possible to prevent deterioration of function and prevent dew condensation, and at the same time, not only discharge of rainwater, but also facilitate drainage to prevent ice dam phenomenon caused by snow accumulation in winter to facilitate ventilation and drainage. can

On the other hand, it is preferable to prevent the penetration of water from the outside of the roof by constructing the waterproof sheet 112 .

According to the structure of the roof assembly of the present invention, earthquake-resistant reinforcement and fire-resistance functions are provided, and water leakage and condensation can be prevented.

6 is an exploded cross-sectional view showing the structure of the heat shield of the present invention, wherein the heat cut part 116 having the upper panel 132 formed by a seam fold includes a lower plate 126 formed in a nieunja (b) shape, and the It includes a fixing clip 128 that is fitted and coupled to the upper portion of the lower plate 126 , and an upper panel 132 that is coupled and installed on the upper portion of the fixing clip 128 .

And the fixing clip (18) is fitted in the upper left portion of the installation is provided with a waterproof piece (130) for preventing water leakage from the outside.

The heat-blocking part 116 coupled and installed as described above is firmly fixed to the upper surface of the heat-insulating part 106 by fixing means 134 such as bolts, pieces, and rivets.

More specifically, the lower plate 126 has a heat-blocking body 48 formed in the shape of a nieunja (b), and a fixing hole 50 penetrating vertically is formed in the body extending to the right. , the above-mentioned fixing means 134 is fixedly installed in the fixing hole 50 .

A fixing clip 128 is installed on the left side of the lower plate 126 so as to be coupled from above to below, and the fixing clip 128 is formed with a body 52 having a giyeok character (a) shape, and the body 52 The lower end of the is bent upward to form a U-shaped bent portion 54 having a U-shape, and a sliding coupling groove 56 is formed at the lower end of the U-shaped bent portion 54. and a fitting hole 58 penetrating vertically is formed on the lower surface of the U-shaped bent part.

The above-described heat-blocking body 48 of the lower plate 126 is vertically coupled to the fitting hole 58 and is fixed by being in close contact without shaking in the left and right directions.

And the upper end of the body 52 is bent horizontally in the left direction, the bent portion 60 is formed in a U-shape, and the seat coupling groove 62 is formed in the inner portion of the bent portion 60. .

A waterproof piece 130 is coupled and fixed to the seat coupling groove 62 of the bent portion 60 to block moisture from the outside, prevent condensation or water from entering, and firmly fix the material.

The waterproof piece 130 is preferably made of a material capable of blocking heat and waterproofing at the same time.

On the other hand, the upper panel 132 is coupled to the upper portion of the waterproof piece 130, the upper panel 132 is formed of a panel body 64 made of a knee-eun (B) shape, the panel body ( At the lower end of the 64), a horizontal body 66 extending long in the right horizontal direction is formed, and a fixing hole 68 penetrating vertically is formed in the horizontal body 66.

The fixing means 134 is fixed to the fixing hole 50 , and it is preferable that the fixing means 134 is formed to be aligned with the fixing hole 50 of the lower plate 126 and fixedly installed so as to be integrated.

The upper end of the body 64 is horizontally bent in the left direction to form a panel bent portion 70 in a U-shape, and a coupling groove 72 is formed in an inner portion of the panel bent portion 70 .

In the heat-blocking part 116 formed in this way, the vertical body 48 of the lower plate 126 is vertically inserted into the fitting hole 58 of the fixing clip 128, and the left side of the body 48 is The fixing clip 128 and the fixing are made so that the right side is supported by the U-shaped bent portion 54 while being in close contact with the right side of the body 52 .

And in a state in which the lower plate 126 and the fixing clip 128 are fixed, the bent part 60 of the fixing clip 128 is inserted and coupled to the coupling groove 72 of the panel bending part 70, and the body ( 52 is installed so as to be in close contact with the left side of the panel body 64 .

Since the waterproof piece 130 is installed in the bent portion 60, the inflow of water flowing in from the outside is prevented.

Then, the lower plate 126 is installed in the shape of a niche (b), the fixing clip 128 is installed to the upper left side of the lower plate 126 , and the upper panel 132 surrounds the fixing clip 128 . , and the fixing means 134 is fixed to the fixing hole 50 and the horizontal body 66 of the upper panel 132 is installed to cover the upper part of the fixing means 134 .

On the other hand, the fixing hole 50 formed on the right side of the body 48 of the lower plate 126 is formed at a lower position than the horizontal. It is preferable that the upper surface of the head of the fixing means 134 is concave so as to be horizontal with the horizontal upper surface of the body 48 .

Continuing, Figure 7 is a side cross-sectional view showing the structure of the roof assembly having a seismic reinforcement and fire-resistance function of the present invention.

First, a plurality of purlins 101 are installed at regular intervals, the base deck panel 102 is installed on the upper part of the purlin 101, and a plurality of seismic unit parts 104 on the upper part of the base deck panel 102. ) and a plurality of heat insulating parts 106 are installed.

And on the upper surface of the plurality of earthquake-resistant unit parts 104, the insulating material fixing member 107 of the insulating part 106 is placed on it so that it flows upwardly elastically and at the same time absorbs vibration generated by an earthquake and buffers it. is done

The insulator fixing member 107 is made in an S (S) shape, and the right side of the insulator 108 is horizontally fitted into the lower coupling groove 44 of the lower left part, and the upper right part of the upper right part of the insulator 108 is coupled. The heat insulating material 108 is horizontally fitted into the coupling groove 46 to thereby insulate.

At this time, it is preferable that the upper panel 132 is laminated and installed on the upper surface of the heat insulating part 106 and fixedly installed by a plurality of sliding clip units 114 .

8 is an exploded cross-sectional view showing the structure of a heat shield according to another embodiment of the present invention, in which the fixing clip 128 and the upper panel 132 are coupled and installed, and the U-shaped (U) bent portion of the fixing clip 128 is shown. A separation space (73) is formed between the panel body (64) coupled to the 54 (54).

Since an empty space is formed in the separation space 73 formed between the bent portion 54 and the panel body 64, when bending or twisting occurs in the separation space 73, a buffer member is used to prevent this. (136) can be inserted and installed.

At this time, the buffer member 136 is provided with a buffer body 74 and a plurality of buffer protrusions 76 formed so as to be downwardly right on the left and right side surfaces of the buffer body 74 .

The cushioning protrusion 76 is formed to have a predetermined angle downward to the right, and is formed to have a counter-force in a clockwise direction in response to an external force in the counterclockwise direction applied to the panel bending portion 70 of the upper panel 132. desirable.

The predetermined angle is preferably formed at 15 to 40 degrees. This is because, in the case of less than 15 degrees, the support counter force is small, so that it cannot cope with the horizontal external force, and when it is larger than 45, it cannot cope with the vertical external force.

The earthquake-resistant reinforcement of the present invention by the buffer member 136 installed in this way can respond to horizontal and vertical displacements, thereby absorbing and buffering vibrations when an earthquake occurs.

Accordingly, earthquake-resistant reinforcement and fire-resistance function that can minimize damage or damage in the event of an earthquake or vibration by the earthquake-resistant unit 104 and minimize heat loss inside the building through the roof by the heat shield 116 at the same time It is possible to provide a roof assembly having a.

That is, according to the roof assembly having earthquake-resistance reinforcement and fire-resistance functions according to the present invention, durability can be strengthened against not only earthquakes but also external forces caused by wind loads, snow loads, and the like.

Although the technical aspects have been described above and in the accompanying drawings, the technical idea of the present invention is for the description, and does not limit the invention, and those of ordinary skill in the art It will be understood that various modifications and changes of the present invention can be made without departing from the technical scope of the present invention as set forth in the claims to be described below.

10: frame body 12: upper plate part
14: bone 16: lower body
18: upper body 20: storage groove
22: cap body 24: lower wing
26: coupling groove 28: fixed hole
30: rail body 32: bent part
34: middle horizontal part 36: right vertical part
38: lower horizontal part 40: left vertical part
42: upper horizontal portion 44: lower coupling groove
46: upper coupling groove 48: heating plate body
50: fixed hole 52: body
54: U (U) bent part 56: sliding coupling groove
58: fitting hole 60: bent part
62: seat coupling groove 64: panel body
66: horizontal body 68: fixed hole
70: panel bent part 72: coupling groove
100: purlin 102: base deck panel
104: seismic unit part 106: heat insulating part
108: insulating material 110: thermal insulation plate
112: waterproof sheet 114: sliding clip
116: heat block 118: lower cap
120: compression spring 122: upper cap
124: reinforcement rail 126: lower plate
128: fixing clip 130: waterproof piece
132: insulating upper panel 134: fixing means
136: buffer member

Claims (3)

A plurality of upper plate parts 12 installed on the upper part of the purlin 101 installed on the roof of a building, supported by the purlin and provided with a plurality of sound-absorbing holes, and the top plate part 12 at regular intervals along the longitudinal direction of the purlin. In the roof assembly provided with a base deck panel 102 having a concave trough 14 formed therein, the base deck panel 102 is installed to be supported by a purlin constructed on the upper part of the building,
A plurality of earthquake-resistant unit portions 104 installed in the valley portion 14 to absorb and buffer vibrations when an earthquake occurs to reinforce them from earthquake resistance;
an insulator 106 installed on the earthquake-resistant unit 104 to block heat supplied from an external heat source and keep the heat source inside the building;
It is installed on the upper portion of the heat insulating unit 106 and includes a heat blocking unit 116 having a waterproof function to block external solar heat and at the same time block moisture such as wind, rain, and water,
The seismic unit 104 is,
a lower cap 118 in which a concave-convex lower body 16 is formed, an upper wing 18 is formed in the left and right directions at the upper end of the lower body 16, and a receiving recess 20 is formed in the inner portion;
a compression spring 120 that is inserted and fixed in the receiving groove 20, elastically flows in the vertical direction, and absorbs and buffers vibration;
A cap body 22 having a channel shape is formed, and the left and right ends of the cap body 22 are downwardly bent inward to form a lower wing 24, and a coupling groove 26 is formed in the inner portion of the lower wing 24. ) is formed and the upper wing 18 is fitted in close contact with the coupling groove 26 so that the compression spring 120 does not come off and the upper cap 122 is installed to absorb vibration and shock at the same time. including,
The heat insulating part 106,
A heat insulating material fixing member 107 made of bent portions of the S-shaped (S) shape is formed, a lower coupling groove 44 is formed on one side of the lower end of the insulating material fixing member 107, and an upper portion is formed on one side of the upper end. A coupling groove 46 is formed, and the heat insulating material 108 is fitted in the forward direction in the lower coupling recess 44 to form heat insulation, and the upper coupling recess 46 is fitted in the rear direction, thereby the heat insulating material 108 ) is installed in a zigzag manner, and a roof assembly having earthquake-resistance and fire-resistance functions, characterized in that it is installed so as to be insulated.
delete According to claim 1,
The heat block 116 is,
A lower plate 126 comprising a body 48 having a fixing hole 50 at the right end so as to be formed in the shape of a nip and penetrate vertically;
Fitted from the upper portion of the body 48 and bent upward at one lower end to form a U-shaped bent portion 54, and the upper end of the body 48 is bent in the left direction to bend U-shaped (U) a fixing clip 128 on which the part 60 is formed;
a waterproof piece 130 fitted to the bent portion 60 and installed to prevent water leakage flowing in from the outside;
At the lower end of the panel body 64 formed vertically, a horizontal body 66 formed in the shape of a niche (b) is formed, and the upper end of the panel body 64 is bent in the left direction to form a panel bent portion 70 and a coupling groove 72 is formed in the panel bent portion 70 to be seated on the upper portion of the lower plate 126 and includes an upper panel 132 installed to be fixedly coupled with the fixing clip 128. A roof assembly having earthquake-resistant reinforcement and fire-resistance functions.

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