KR101992744B1 - the improved lightweight roof frame structure for vibration proof and heat bridge proof - Google Patents

Abstract

The present invention relates to a roof structure on an upper portion of a construction building. In case a transverse direction and a longitudinal direction are described as an x-axis and y-axis, respectively, the present invention comprises: a plurality of Dufferins (100) installed in parallel after being spaced apart in an x-axis direction; a base plate (200) installed at an upper portion of the Dufferins (100); a plurality of vibration reduction reinforcing materials (300) installed in parallel after being spaced apart in a y-axis direction at an upper portion of the base plate (200); a plurality of Z bars (400) installed in parallel after being spaced apart in an x-axis direction at an upper portion of the vibration reduction reinforcing materials (300); a plurality of reinforcing angles (500) installed in parallel after being spaced apart in a y-axis direction between the plurality of Z bars (400); and an insulation material (600) installed at a space surrounded by the Z bars (400) and the reinforcing angles (500) to perform insulation and sound absorption functions. Therefore, provided in the present invention is a lightweight roof structure with improved vibration reduction performance, thermal bridge blocking performance and structural strength, which is characterized by the fact that vibration from an upper portion applied to the Z bars (400) and the reinforcing angles (500) and vibration from a lower portion applied to the Dufferins (100) is absorbed by the vibration reduction reinforcing materials (300).

Description

[0001] The present invention relates to a lightweight roof structure having improved vibration damping performance, thermal bridging performance, and structural rigidity,

The present invention improves the existing lightweight roof structure and improves the vibration-damping performance and thermal-bridge breaking performance by inserting the impact buffering member inside and outside the roof, and provides a lightweight roof having an increased structural rigidity by cross- Structure.

In the case of the conventional lightweight roof structure, structural stability is poor, and it is susceptible to load and vibration such as an upper load, and the support members installed in the interior convey the temperature of the outside air to the room as it is, come.

In recent years, the use of external environment conditions and new and renewable energy have become important, so that the load is increased by installing a separate fixture in the idle space of the roof, and the shock or vibration to the external stimulus is transmitted to the roof as it is, And the like.

Accordingly, the present inventors have developed a lightweight roof structure of the prior art to form a lattice-type reinforcing structure having excellent workability and structural stability, inserting a heat insulating material in the inner space, and designing a cushioning member for supporting a lattice- Performance and thermal bridging performance and a lightweight roof structure with improved structural rigidity.

[Patent Document 1] Korean Registered Patent No. 10-1470372 'Reinforcing device for beam members and lightweight roof frame using the same', December 02, 2014 [Patent Literature 2] Korea Patent No. 10-0595773 'Joining structure of roof support frame using thin plate light-weight steel', June 23, 2006

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems of the related art. The object of the present invention is to improve a conventional lightweight roof structure to form a lattice-type reinforcing structure having excellent workability and structural stability, insulate the interior space, and design a buffer member supporting the lattice- And to provide a lightweight roof structure with improved thermal bridging performance and structural rigidity.

According to an aspect of the present invention, there is provided a roof structure on an upper part of a building structure, wherein when a lateral direction and a longitudinal direction are respectively defined as an x-axis and a y-axis,

a plurality of purlin (100) arranged in parallel in the x-axis direction and spaced apart from each other;

A base plate 200 installed on the purlin 100;

A plurality of anti-vibration stiffeners 300 disposed on the base plate 200 in parallel and spaced apart from each other in the y-axis direction;

A plurality of Z bars (400) spaced apart from each other in the x-axis direction and arranged in parallel on the vibration-damping stiffener (300);

A plurality of reinforcing angles (500) spaced apart from each other in the y-axis direction and arranged in parallel between the plurality of Z bars (400);

A heat insulating material 600 installed in a space surrounded by the Z bar 400 and the reinforcing angle 500 to perform a heat insulating function or a sound absorbing function;

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Wherein the vibration damping performance is characterized in that the vibration from the upper portion applied to the Z bar (400) and the reinforcing angle (500) and the vibration from the lower portion applied to the purlin (100) And to provide a lightweight roof structure with improved structural rigidity.

According to the present invention, a conventional lightweight roof structure is improved to form a lattice-like reinforcing structure excellent in workability and structural stability, inserting a heat insulating material in the inner space, and designing a buffer member supporting the lattice- Performance and thermal bridging performance and a lightweight roof structure with improved structural rigidity.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a combined perspective view of a lightweight roof structure that improves the vibration damping performance, thermal bridging performance, and structural rigidity of the present invention.
Fig. 2 is an exploded view of the lightweight roof structure of the present invention as viewed in the y-axis direction, which improves the vibration-damping performance, thermal-bridge breaking performance, and structural stiffness.
FIG. 3 is an exploded view of the lightweight roof structure of the present invention as viewed in the x-axis direction, which improves the dustproof performance, thermal bridging performance, and structural rigidity of the present invention.
Fig. 4 is a detailed view showing the coupling relationship of the base plate, the vibration-proof stiffener, the Z bar, and the reinforcing angle viewed in the y-axis and x-axis directions.
Fig. 5 shows the coupling relationship between the vibration-damping stiffener and the reinforcing angle.
Fig. 6 shows the coupling relationship between the reinforcing angles.
FIG. 7 shows the coupling relationship of the purlin, the anti-vibration pad, and the anti-vibration pad in the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view of a lightweight roof structure improved in vibration damping performance, thermal bridge breaking performance and structural rigidity of the present invention,

FIG. 2 is an exploded view of a lightweight roof structure improved in vibration damping performance, thermal bridge breaking performance and structural rigidity according to the present invention as viewed in the y-axis direction.

FIG. 3 is an exploded view of the lightweight roof structure of the present invention as viewed in the x-axis direction, which improves the dustproof performance, thermal bridging performance, and structural rigidity of the present invention.

As shown,

The lightweight roof structure of the present invention, which improves the dustproof performance, thermal bridge breaking performance, and structural rigidity,

When the horizontal and vertical directions are referred to as x-axis and y-axis, respectively,

a plurality of purlin (100) arranged in parallel in the x-axis direction and spaced apart from each other;

A base plate 200 installed on the purlin 100;

A plurality of anti-vibration stiffeners 300 disposed on the base plate 200 in parallel and spaced apart from each other in the y-axis direction;

A plurality of Z bars (400) spaced apart from each other in the x-axis direction and arranged in parallel on the vibration-damping stiffener (300);

A plurality of reinforcing angles (500) spaced apart from each other in the y-axis direction and arranged in parallel between the plurality of Z bars (400);

A heat insulating material 600 installed in a space surrounded by the Z bar 400 and the reinforcing angle 500 to perform a heat insulating function or a sound absorbing function;

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The vibration damping stiffener 300 absorbs vibrations from the upper portion applied to the Z bar 400 and the reinforcing angle 500 and the vibration applied from the lower portion applied to the purlin 100, The bar 400 and the reinforcing angle 500 are installed in a lattice structure to improve the structural performance so as to minimize deformation of the roof due to external load and external force.

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

The lower end of the reinforcing angle 500 may be inserted into the upper portion of the vibration-damping stiffener 300,

Specifically, at the center of the upper portion of the vibration-damping stiffener 300, a reinforcing-angle mounting portion 330 having a slit at its center is formed,

And the lower end of the reinforcing angle 500 is inserted into the slit.

The base plate 200 is formed by folding a sheet material to form a dustproof reinforcement material insertion groove 210 on the upper portion,

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

The Z-bar fixing portion 310 of the vibration-damping stiffener 300 protrudes above the upper surface of the base plate 200,

The Z bar 400 is installed in the Z bar mounting part 310 and the lower surface of the Z bar 400 is not in contact with the base plate 200.

Fig. 4 is a detailed view showing the coupling relationship of the base plate, the vibration-proof stiffener, the Z bar, and the reinforcing angle viewed in the y-axis and x-axis directions.

4 (a) is a detailed view showing the coupling relationship between the base plate, the vibration-proof stiffener, the Z bar, and the reinforcing angle viewed in the y-axis direction. FIG. 4 (b) , Z bar, and reinforcing angle of each of the first, second, and third frames.

As shown in FIG. 4, the base plate 200 may be a conventional product in which a plate is folded. The base plate 200 may have a shape corresponding to the shape of the anti-vibration reinforcement material insertion groove 210 in the anti-vibration reinforcement material insertion groove 210, The vibration-damping stiffener 300 is inserted.

The upper surface of the dustproof stiffener 300 protrudes above the level of the upper surface of the base plate 200 as shown in FIG. 4 (a) to form the Z bar fixing part 310, Even if the Z bar 400 is installed on the base plate 200, the lower surface of the Z bar 400 maintains a clearance with the base plate 200 to correspond to vibration loads.

At this time, the reinforcing angle mounting portion 330 of the vibration-damping stiffener 300 is cut so that the Z bar 400 can pass through the middle portion thereof, and a plurality of cut-out portions are provided to secure the flexibility of the vibration- And may be separately formed in the reinforcing angle mounting portion 330.

Fig. 5 shows the coupling relationship between the vibration-damping stiffener and the reinforcing angle.

As shown in Figure 5,

A reinforcing angle mounting part 330 having a slit at the center is formed at an upper center of the vibration-proof stiffener 300,

And a lower end of the angled reinforcing angle 500 is inserted into the slit.

Fig. 6 shows the coupling relationship between the reinforcing angles. Specifically, Fig. 6 is a detailed view viewed in the x-axis direction.

The reinforcing angle 500 is manufactured and coupled unit by unit so that interference does not occur with the orthogonal Z bar 400,

A lower coupling step 510 protrudes from the upper part of one end of the reinforcing angle 500 to support the lower flange of the Z bar 400,

The upper flange of the other end of the reinforcing angle 500 is extended to form the upper coupling jaw 550 so that the upper flange of the Z bar 400 and the lower coupling jaw 510 support the upper coupling jaw 550 .

One end of the reinforcing angle 500 is pressed against the upper portion of the lower flange of the Z bar 400 and the other end of the reinforcing angle 500 is closely attached to the lower portion of the upper flange of the Z bar 400, And the entire roof is structurally integrated to increase rigidity.

In addition, the reinforcing angle 500 may have an air hole 530 formed under the lower coupling step 510 to smooth the flow of air. In particular, the reinforcing angle 500 has a function of inducing air discharge generated in the heat insulating material 600 do. In addition, the insulation performance is enhanced by the flow of air.

FIG. 7 shows the coupling relationship of the purlin, the anti-vibration pad, and the anti-vibration pad in the present invention.

As shown,

The present invention is for supporting a roof structure on an upper part of a building structure,

A plurality of purlin (100) spaced apart from each other and installed in parallel;

A dustproof pad 700 installed on the purlin 100;

A base plate 200 installed on the vibration damping pad 700;

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The vibration damping stiffener 300 absorbs vibrations from the upper portion applied to the base plate 200 and vibrations from the lower portion applied to the purlin 100.

Further, a dustproof pad fixing table 800 is additionally provided between the purlin 100 and the dustproof pad 700,

The anti-vibration pad fixing table 800 includes:

The upper portion of the purlin 100 is fitted into the lower purlin insertion portion 810,

And the lower portion of the vibration damping pad 700 is fitted into the upper vibration dock pad insertion portion 830.

The purlin 100 includes a web 110 as a vertical member and an upper flange 130 and a lower flange 150 extending horizontally at upper and lower ends of the web 110,

The web reinforcing portion 811 of the dustproof pad fixing base 800 is brought into close contact with the outer surface of the web 110 to prevent the web 110 from being warped,

An upper flange delay section 131 is formed at the other end of the upper flange 130 and a fixing jaw 813 of the vibration damping pad fixing table 800 is fixed to the lower end of the upper flange delay section 131. do.

The vibration damping pad inserting portion 830 includes both walls. The vibration damping pad inserting portion 830 is provided at an upper end of the wall to facilitate the engagement of the vibration damping pad 700, A projection may be formed.

The upper surface of the vibration damping pad 700 is formed with protrusions to prevent slippage between the upper surface of the vibration damping pad 700 and a clearance for shock absorption,

The lower surface of the vibration damping pad 700 may be formed with a groove to increase the coupling force when the upper surface of the vibration damping pad insertion portion 830 is compressed.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention.

It is therefore intended that the appended claims cover such modifications and variations as fall within the true scope of the invention.

100: Purine
110: web
130: upper flange
131: upper plane delay book
150: Lower flange
200: base plate
210: Dustproof reinforcement insertion groove
300: anti-vibration stiffener
310: Z bar mounting part
330: reinforcing angle mounting portion
400: Z bar
500: reinforcement angle
510: Lower coupling chin
530: Air hole
550: upper coupling jaw
600: Insulation
700: anti-vibration pad
800: Antivibration pad holder
811: web reinforcement part
813: Fixed chin
900: Clip
RP: Roof panel
WS: Waterproof sheet

Claims (4)

When the horizontal and vertical directions are referred to as x-axis and y-axis, respectively,
a plurality of purlin (100) arranged in parallel in the x-axis direction and spaced apart from each other;
A base plate 200 installed on the purlin 100;
A plurality of anti-vibration stiffeners 300 disposed on the base plate 200 in parallel and spaced apart from each other in the y-axis direction;
A plurality of Z bars (400) spaced apart from each other in the x-axis direction and arranged in parallel on the vibration-damping stiffener (300);
A plurality of reinforcing angles (500) spaced apart from each other in the y-axis direction and arranged in parallel between the plurality of Z bars (400);
A heat insulating material 600 installed in a space surrounded by the Z bar 400 and the reinforcing angle 500 to perform a heat insulating function or a sound absorbing function;
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The vibration damping stiffener 300 absorbs vibrations from the upper portion applied to the Z bar 400 and the reinforcing angle 500 and vibrations from the lower portion applied to the purlin 100,
The base plate 200 is formed by folding a sheet material to form a dustproof reinforcement material insertion groove 210 on the upper portion thereof,
The anti-vibration stiffener 300 is inserted into the anti-vibration reinforcement material insertion groove 210,
The Z-bar fixing portion 310 of the vibration-damping stiffener 300 protrudes above the upper surface of the base plate 200,
Wherein the Z bar 400 is installed in the Z bar mounting part 310 and the lower surface of the Z bar 400 is not in contact with the base plate 200. [ Lightweight roof structure with improved rigidity.
The method of claim 1,
Wherein the lower end of the reinforcing angle (500) is inserted into the upper portion of the vibration-damping stiffener (300), thereby enhancing the vibration-damping performance, the thermal-bridge breaking performance, and the structural rigidity.
delete The method of claim 1,
A reinforcing angle mounting part 330 having a slit at the center is formed at an upper center of the vibration-proof stiffener 300,
And the lower end of the reinforcing angle (500) is inserted into the slit, thereby fitting the reinforcing angle (500) into the slit.

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