KR20200014987A - the improved lightweight roof frame structure for vibration proof and heat bridge proof - Google Patents

Abstract

According to the present invention, provided is a light roof structure with improved vibration-proof performance, heat-bridge-proof performance and structural hardness. The light roof structure forms an upper roof structure of a building, and when a transverse direction and a longitudinal direction are defined as an x-axis and an y-axis, respectively, the light roof structure includes: a plurality of purlins (100) installed in parallel by being spaced from each other in an x-axis direction; a base plate (200) installed on the purlins (100); a plurality of vibration-proof reinforcement materials (300) installed in parallel on the base plate (200) by being spaced from each other in an y-axis direction; a plurality of Z-bars (400) installed in parallel on the vibration-proof reinforcement materials (300) by being spaced from each other in an x-axis direction; a plurality of reinforcement angles (500) installed in parallel between the Z-bars (400) by being spaced from each other in an y-axis direction; and an insulator (600) installed in a space surrounded by the Z-bars (400) and the reinforcement angles (500) to perform insulation or sound absorption. The vibration-proof reinforcement materials (300) absorbs vibrations applied from the top to the Z-bars (400) and the reinforcement angles (500) and vibrations applied from the bottom to the purlins (100).

Description

The improved lightweight roof frame structure for vibration proof and heat bridge proof}

The present invention improves the existing lightweight roof structure, by inserting the shock absorbing member into the inside and outside of the roof to improve the dust-proof performance and thermal cross-linking performance, and to install a support member that is configured inside the roof structurally increased lightweight roof It's about structure.

In the case of the conventional lightweight roof structure, structural stability is poor, and it is vulnerable to loads and vibrations such as upper loads, and problems such as thermal bridges and cold bridges are caused by supporting members installed therein by transferring the temperature of the outside air into the room as it is. come.

In recent years, the external environment and the use of renewable energy have become important, and the additional loads are installed in the idle space of the roof, thereby increasing the load, and the impact or vibration of the external stimulus is transmitted to the roof as it is and damaged. Problems such as this have arisen.

Accordingly, the present inventors have improved the conventional lightweight roof structure to form a grid-shaped reinforcement structure having excellent workability and structural stability therein, insert a heat insulator into the inner space, and design a shock absorbing member to support the grid-shaped reinforcement structure. It has led to the development of a lightweight roof structure with improved performance, thermal barrier performance and structural stiffness.

[Document 1] Republic of Korea Patent Registration No. 10-1470372 'Reinforcement of beam member and reinforcement structure of lightweight roof frame using the same', December 02, 2014 [Document 2] Korean Patent Registration No. 10-0595773 'Joint Structure of Roof Supporting Skeleton Using Thin Plated Light Steel', June 23, 2006

The present invention is proposed to solve the conventional problems as described above. The purpose is to improve the conventional lightweight roof structure, to form a grid-type reinforcement structure excellent in construction and structural stability, to insert insulation into the interior space, and to design a cushioning member to support the grid-type reinforcement structure, dustproof performance And to provide a lightweight roof structure with improved thermal cross-linking performance and structural rigidity.

In order to solve the above technical problem, the present invention forms a roof structure on top of a building structure, when the lateral direction and the longitudinal direction are referred to as x-axis and y-axis,

a plurality of purines 100 installed in parallel to be spaced apart from each other in the x-axis direction;

A base plate 200 installed on the upper part of the purlin 100;

A plurality of anti-vibration reinforcement members 300 which are spaced apart from each other in the y-axis direction on the base plate 200 and installed in parallel;

A plurality of Z bars 400 installed on the anti-vibration reinforcement material 300 and spaced apart from each other in the x-axis direction in parallel;

A plurality of reinforcing angles 500 installed in parallel to be spaced apart from each other in the y-axis direction between the plurality of Z bars 400;

A heat insulator 600 installed in a space surrounded by the Z bar 400 and the reinforcement angle 500 to perform a heat insulation or sound absorption function;

Consists of including

Anti-vibration performance, characterized in that the anti-vibration reinforcing material 300 absorbs vibrations from the upper portion applied to the Z bar 400 and the reinforcement angle 500 and vibrations from the lower portion applied to the furin 100. The aim is to provide a lightweight roof structure with improved thermal barrier performance and structural stiffness.

According to the present invention by improving the conventional lightweight roof structure to form a grid-type reinforcement structure excellent in workability and structural stability inside, insert the insulation into the interior space, dust-proof by designing a cushioning member to support the grid-shaped reinforcement structure It provides a lightweight roof structure with improved performance, thermal barrier performance and structural stiffness.

1 is a perspective view of a combination of lightweight roof structure to improve the anti-vibration performance, heat cross-linking performance and structural rigidity of the present invention.
2 is an exploded view of a lightweight roof structure having improved dustproof performance, thermal crosslinking performance, and structural rigidity as viewed in the y-axis direction.
Figure 3 is an exploded view of the lightweight roof structure to improve the dust-proof performance, heat cross-linking performance and structural rigidity of the present invention as viewed in the x-axis direction.
Figure 4 is a detailed view showing the coupling relationship between the base plate, the anti-vibration reinforcement, Z bar, the reinforcement angle viewed in the y-axis and x-axis direction.
Figure 5 shows the coupling relationship between the anti-vibration reinforcement and the reinforcement angle.
6 illustrates a coupling relationship between reinforcement angles.
Figure 7 shows the coupling relationship between the purine, dust pad fixing stand, dust pad in the present invention.

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

1 is a combined perspective view of a lightweight roof structure having improved dustproof performance, thermal crosslinking performance, and structural rigidity of the present invention;

2 is an exploded view of a lightweight roof structure having improved dustproof performance, thermal crosslinking performance, and structural rigidity as viewed in the y-axis direction,

Figure 3 is an exploded view of the lightweight roof structure to improve the dust-proof performance, thermal cross-linking performance and structural rigidity of the present invention as viewed in the x-axis direction.

As shown,

Lightweight roof structure that improves the dustproof performance, heat cross-linking performance and structural rigidity of the present invention,

When forming the roof structure on the upper part of the building structure, when the transverse direction and the longitudinal direction are called x-axis and y-axis,

a plurality of purines 100 installed in parallel to be spaced apart from each other in the x-axis direction;

A base plate 200 installed on the upper part of the purlin 100;

A plurality of anti-vibration reinforcement members 300 which are spaced apart from each other in the y-axis direction on the base plate 200 and installed in parallel;

A plurality of Z bars 400 installed on the anti-vibration reinforcement material 300 and spaced apart from each other in the x-axis direction in parallel;

A plurality of reinforcing angles 500 installed in parallel to be spaced apart from each other in the y-axis direction between the plurality of Z bars 400;

A heat insulator 600 installed in a space surrounded by the Z bar 400 and the reinforcement angle 500 to perform a heat insulation or sound absorption function;

Consists of including

The vibration reinforcement member 300 is characterized in that the vibration-proof reinforcing member 300 absorbs vibrations from the upper part applied to the Z bar 400 and the reinforcement angle 500 and vibrations from the lower part applied to the purlin 100. The bar 400 and the reinforcement angle 500 are installed in a lattice structure to improve structural performance so as to minimize deformation of the roof due to external loads and external forces.

The roof panel RP is installed on the Z bar 400 using the clip 900, and the waterproof sheet WS is installed under the roof panel RP.

A lower end of the reinforcement angle 500 may be inserted into the upper part of the anti-vibration reinforcement 300,

Specifically, in the upper center of the anti-vibration reinforcing material 300 is formed a reinforcement angle mounting portion 330 is formed with a slit in the center,

A lower end of the reinforcement angle 500 may be inserted into the slit.

And the base plate 200 is bent plate to form a dust reinforcement reinforcement groove 210 on the top,

The anti-vibration reinforcement material 300 is inserted into the anti-vibration reinforcement material insertion groove 210,

Z bar portion 310 of the anti-vibration reinforcing material 300 protrudes over the upper surface of the base plate 200,

The Z bar 400 may be installed at the Z bar portion 310, and the lower surface of the Z bar 400 may not contact the base plate 200.

Figure 4 is a detailed view showing the coupling relationship of the base plate, the anti-vibration reinforcement, Z bar, the reinforcement angle viewed in the y-axis and x-axis direction.

Specifically, Figure 4 (a) is a detailed view showing the coupling relationship of the base plate, the anti-vibration reinforcement, Z bar, the reinforcement angle viewed in the y-axis direction, Figure 4 (b) is the base plate, anti-vibration reinforcement viewed in the x-axis direction , Z bar, detail of the coupling relationship between the reinforcement angle.

As shown in FIG. 4, the base plate 200 may use a conventional product in which plate is bent, and corresponds to the shape of the anti-vibration reinforcement insert groove 210 in the anti-vibration reinforcement insert groove 210 generated due to bending. To insert the anti-vibration reinforcement 300 to.

At this time, the upper surface of the anti-vibration reinforcing material 300 is projected above the upper surface level of the base plate 200 as shown in Figure 4 (a) to form a Z bag portion 310, the Z bag portion 310 Even if the Z bar 400 is installed in the lower surface of the Z bar 400 to maintain a clearance with the base plate 200 to correspond to a load such as vibration.

At this time, the reinforcing angle mounting portion 330 of the anti-vibration reinforcement 300 is cut so that the Z bar 400 passes in the middle, and also a plurality of incisions to secure the flexibility of the anti-vibration reinforcement (300) Separately it may be formed in the reinforcement angle mounting portion 330.

Figure 5 shows the coupling relationship between the anti-vibration reinforcement and the reinforcement angle.

As shown in FIG. 5,

In the center of the upper portion of the anti-vibration reinforcing material 300 is formed a reinforcing angle portion 330 is formed with a slit in the center,

The slit is characterized in that the bottom of the reinforcement angle 500 is inserted into the s-shape.

6 illustrates a coupling relationship between reinforcing angles, and specifically, FIG. 6 is a detailed view viewed in the x-axis direction.

The reinforcement angle 500 is to be manufactured and combined in units so that interference with the orthogonal Z bar 400 does not occur,

The lower coupling jaw 510 protrudes from the upper end of the reinforcement angle 500 to support the bottom of the upper flange of the Z bar 400,

Since the upper flange of the other end of the reinforcement angle 500 is extended to form the upper coupling jaw 550, the upper flange of the Z bar 400 and the lower coupling jaw 510 support the upper coupling jaw 550. Done.

In addition, one of both ends of the reinforcement angle 500 is pressed in close contact with the upper flange of the Z bar 400, the other is in close contact with the lower flange of the upper bar of the Z bar 400, the lattice structure in the roof It increases the rigidity by structurally unifying the whole roof by forming.

In addition, the reinforcement angle 500 has an air hole 530 formed under the lower coupling jaw 510 to facilitate the flow of air, and in particular, has a function of inducing air discharge generated from the insulation 600. do. In other words, the heat insulation performance is increased by the flow of air.

Figure 7 shows the coupling relationship between the purine, dust pad fixing stand, dust pad in the present invention.

As shown,

The present invention is to support the roof structure of the upper part of the building structure,

A plurality of purines 100 installed in parallel and spaced apart from each other;

Anti-vibration pad 700 is installed on the furin 100;

A base plate 200 installed on the dustproof pad 700;

Consists of including

The vibration reinforcement member 300 absorbs vibrations from the upper part applied to the base plate 200 and vibrations from the lower part applied to the furin 100.

And between the purine 100 and the dustproof pad 700, a dustproof pad fixing stand 800; is further configured,

The dust pad fixing stand 800,

The upper part of the purlin 100 is inserted into a lower purlin inserting part 810,

The lower part of the anti-vibration pad 700 is inserted into the anti-vibration pad inserting part 830.

In addition, the purlin 100 is composed of a vertical member web 110 and the upper flange 130 and the lower flange 150 extending horizontally from the top and bottom of the web 110, respectively,

The web reinforcing portion 811 of the anti-vibration pad fixing stand 800 is in close contact with the outer surface of the web 110 to prevent bending of the web 110.

The other end of the upper flange 130, the upper flange extending portion 131 is formed at the bottom, so that the fixing jaw 813 of the anti-vibration pad fixing stand 800 is fixed to the lower end of the upper flange extending portion 131 do.

The anti-vibration pad inserting portion 830 is formed of walls on both sides, and the upper side of the wall is inclined to bite and fix the side of the anti-vibration pad 700 in order to facilitate separation of the anti-vibration pad 700 and to prevent detachment. Protuberances may be formed.

The upper surface of the anti-vibration pad 700 is formed with a protrusion to prevent sliding with the member installed on the top and at the same time to secure the play for absorbing shock,

The lower surface of the dustproof pad 700 may form a groove to increase the bonding force when the upper surface of the dustproof pad inserting portion 830 is compressed.

Although the present invention has been described in connection with the preferred embodiment as mentioned above, various modifications and variations are possible without departing from the gist of the present invention, and can be used in various fields.

Therefore, the claims of the present invention include modifications and variations that fall within the true scope of the invention.

100: Purlin
110: web
130: upper flange
131: upper flange extension
150: lower flange
200: baseplate
210: Dustproof reinforcement insert groove
300: dustproof reinforcement
310: Z hook part
330: reinforced angle mounting portion
400: Z bar
500: reinforcement angle
510: lower coupling jaw
530: air hole
550: upper coupling jaw
600: insulation
700: dustproof pad
800: anti-vibration pad holder
811: web reinforcement unit
813: fixed jaw
900: clip
RP: roof panel
WS: Waterproof Sheet

Claims (3)

To support the roof structure of the upper part of the building structure,
A plurality of purines 100 installed in parallel and spaced apart from each other;
Dustproof pad 700 is installed on the furin 100;
A base plate 200 installed on the dustproof pad 700;
Consists of including
The anti-vibration reinforcing material 300 is characterized in that the vibration-proof reinforcing member 300 absorbs vibrations from the upper portion applied to the base plate 200 and vibrations from the lower portion applied to the purine 100, and the structural stiffness. Improved lightweight roof structure.
In claim 1,
Between the furrin 100 and the dustproof pad 700, a dustproof pad fixing stand 800; is further configured,
The dust pad fixing stand 800,
The upper part of the purlin 100 is inserted into a lower purlin inserting part 810,
Lightweight roof structure with improved dustproof performance, thermal cross-cutting performance and structural rigidity, characterized in that the lower part of the anti-vibration pad 700 is fitted into the anti-vibration pad inserting portion 830 of the upper portion.
In claim 2,
The purlin 100 is configured to include a vertical member web 110 and the upper flange 130 and the lower flange 150 extending horizontally from the top and bottom of the web 110, respectively,
The web reinforcing portion 811 of the anti-vibration pad fixing stand 800 is in close contact with the outer surface of the web 110 to prevent bending of the web 110.
An upper flange extension portion 131 is formed at the other end of the upper flange 130 so that the fixing jaw 813 of the dustproof pad fixing stand 800 is fixed to the bottom of the upper flange extension portion 131. Lightweight roof structure with improved dust and thermal barrier performance and structural stiffness.

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