KR101952907B1 - Open Curtain Wall Structure using GRP - Google Patents

Abstract

The present invention relates to an open curtain wall structure using GRP.
To achieve the above object, the present invention provides a curtain wall structure in which a multi-layered glass is fixed to a front surface of a main frame having an internal space therein, wherein a heat insulating member made of a glass reinforced plastic material is provided between the multi- An opening is formed in the front face of the frame, and the heat insulating member is coupled to the main frame to cover the opening.
Thus, the heat insulating performance of the curtain wall frame can be improved by blocking the heat transfer by the metallic material, and even when the main frame is used as a horizontal member, the heat insulating member provided between the adjacent double- There is an effect.

Description

Open Curtain Wall Structure using GRP [

The present invention relates to an open curtain wall structure using GRP. More specifically, the present invention is characterized in that a heat insulating member made of glass reinforced plastic (GRP) is provided between adjacent two-layer glass provided on the front surface of a main frame, and an opening is formed in a front surface of the main frame, And an openable curtain wall structure using a GRP in which a cover member is coupled to the front surface of the heat insulating member and the multilayer glass is pressed and fixed.

Generally, windows are installed on walls of buildings for the purpose of sight, sunshine and ventilation. In the case of high-rise buildings, curtain wall structures are mostly installed for the beauty of the elevation.

The curtain wall structure is constructed by attaching a wall as a non-proof structure on the elevation of a building. In general, a bracket is installed at an end of a slab, and then a vertical member (Mullion) and a horizontal member A frame is formed, and a panel made of various finishes is joined to the frame to complete the frame.

In recent years, the curtain wall structure has been provided with a modern feeling by attaching most of the glass panels, and energy is efficiently utilized by using natural light. In the curtain wall structure, Is understood to mean. At this time, it is general that the glass panel secures the heat insulating performance by using a double glass.

The curtain wall structure using such a glass panel is provided with a multi-layered glass to be coupled to a support member which is coupled to the frame so as to be exposed to the outside, or is fixed based on a separate fastening means.

More specifically, in the past, a support member that is coupled outwardly to a vertical member or a horizontal member of a frame is provided with a multilayer glass to support a lateral load such as a weight or a wind load, and a space between the frame and the multilayer glass is filled with a sealant such as silicone The method of attachment was mainly used.

In recent years, as another method, there has been proposed a method in which a multilayer glass is supported by a support member of a frame, and a bolt is successively passed through a hole formed at a corner of the double-layer glass and the bolt, so that the multilayer glass is press- have.

On the other hand, a frame of a curtain wall structure is generally made of aluminum which is lightweight, strong against corrosion, and can secure sufficient strength. However, due to the high thermal conductivity of the aluminum, there is a problem that the warmth of the room escapes, or the heat bridging phenomenon in which the cool air is easily introduced into the outdoor is generated.

However, the synthetic resin material such as polyamide or azone does not exhibit sufficient strength to support the load, although the insulation performance is secured by additionally providing a synthetic resin material insulator such as polyamide or azone in the hollow space formed between adjacent two-layered glass. There is a limitation in that an additional aluminum supporting member is formed on the frame or a separate fastening means is required.

As a prior art document related thereto, there is an 'insulating window frame' of Korean Registered Patent No. 10-1680722 (registered on November 23, 2016, hereinafter referred to as 'Prior Art Document 1'). The prior art document 1 includes a frame 1 and a cover 2 provided with a multilayer glass 4 as shown in Fig. 1A, and supports the frame 1 and the cover 2, To enhance the heat insulating performance.

Although the prior art document 1 succeeds in securing the heat insulating performance by using the heat insulating component including the airgel based on the heat insulating material 3, the heat insulating material 3 provided on the frame 1 is not easily absorbed by the weight of the multi- There is a structural difficulty in accommodating the lateral load by the wind load or the wind load. Therefore, there is a limitation in additionally providing the coupling means 5 for coupling the frame 1 and the cover 2 to each other. The coupling means 5 of the metal material must be the cause of the thermal bridge phenomenon through the frame 1, which has caused deterioration of the heat insulation performance.

As another prior art document, there is an 'insulating window frame assembly' of Korean Registered Patent No. 10-1688872 (registered on December 16, 2016, hereinafter referred to as 'Prior Art Document 2'). The prior art document 2 has a separate support frame 6 on the frame 1 to solve the structural disadvantage of conventional synthetic resin insulation as shown in Fig. 1B, and the support frame 6 is surrounded The heat insulating performance and the structural stability are secured by forming the heat insulating block 3 so as to be packed.

However, since the heat insulating block 3 is made of synthetic wood, there is a possibility that the synthetic wood is corroded due to the heat bridging and the load of the support frame 6 is applied to the frame 1 through the heat insulating block 3 There is a problem of durability in which the heat insulating block 3 is deformed or deviated as it is transmitted.

DISCLOSURE OF THE INVENTION It is an object of the present invention to solve the above problems and to provide a curtain wall frame in which the heat insulating performance of a curtain wall frame is improved by using a heat insulating material of a GRP material and even when there is no separate supporting member, The present invention provides an open type curtain wall structure using a GRP capable of exhibiting a sufficient supporting force against a lateral load and having an opening formed in the front face of the frame or a heat insulating material inside the frame to further improve the heat insulating performance and the supporting force. .

In order to solve the above-described problems, the open curtain wall structure (CS) using the GRP of the present invention has a curtain wall structure in which a double-layered glass (W) is fixed on a front surface of a main frame (10) (CRP) material is provided between the two-layered glass (W) adjacent to the front surface of the main frame (10), and a heat insulating member (30) made of glass reinforced plastic A pair of front flanges 12 are bent inward to form an opening 11 therebetween and a rail bending portion 13 is formed at one side of the front flange 12 to bend backward And a rail groove 14 is formed on the outer side of the rail bending portion 13. The cover portion 31 of the heat insulating member 30 contacts the front surface of the main frame 10 to cover the opening portion 11 A flange 31a is formed on the rear surface of the flange 31a. The insertion protrusion 31b is formed with a pair of rear ribs 31b-1 on the rear surface of the flange 31a and the rear rib 31b-1 is formed on the insertion protrusion 31b. Rail protrusions 31c are formed on both sides of the rear flange 31b-2 so as to protrude from the front of the rear flange 31b-2 so that the rail flange 31b- And a seating groove 31d is formed between the rear rib 31b-1 and the rail projection 31c to form a locking structure in the front and rear direction by inserting the rail bent portion 13, The support member 32 is integrally formed on the front surface of the cover member 31 and the cover member 20 is fixed to the support member 30 of the heat insulating member 30 by the fastening means P, (32).

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The cover member 20 is provided on the entire surface of the auxiliary heat insulating member 40. The cover member 20 is provided on both sides of the support portion 32 of the heat insulating member 30 and has an inner hollow portion 41 formed therein, The coupling means P can be screwed into the screw groove 32a formed in the support portion 32 through the cover member 20. [

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The insertion protrusion 31b may have a hollow portion 31b-3 formed between a pair of rear ribs 31b-1 and a rear flange 31b-2.

A support portion 32 is integrally formed on the front surface of the cover portion 31 of the heat insulating member 30. The cover portion 31 covers the opening portion 11 on the front surface of the main frame 10 The flange 31a is formed with a flange 31a at both ends of which a thickness gradually increases to form a tapered portion 31a-1. A pair of front surfaces A rear protrusion 15 is formed at an inner side of the rear surface of the flange 12 so that a tapered groove 16 is formed between the front flange 12 and the rear protrusion 15, The tapered portion 31a-1 of the tapered portion 31a can be inserted into the tapered groove 16 to be engaged.

The front flange 12 formed on the main frame 10 is bent obliquely to the rear and the rear protruding portion 15 is bent obliquely forward so that a gap between the front flange 12 and the rear protruding portion 15 A tapered groove 31a-2 may be formed in the flange 31a so that the end of the front flange 12 or the rear protrusion 15 is caught.

The cover 31 has a frame 31 having a width w or length l corresponding to the shape of the space S so as to be inserted into the space S of the main frame 10, The support portion 33 may be formed.

The frame support portion 33 may include at least one transverse member 33a provided in the width direction of the space portion S and at least one longitudinal member 33b provided in the longitudinal direction.

The frame supporting portion 33 may be formed with a hollow portion 33c between the transverse member 33a and the longitudinal member 33b.

The open type curtain wall structure using the GRP according to the present invention is provided with a heat insulating member made of GRP between the two-layered glass adjacent to the front surface of the main frame to prevent heat transfer by the metallic material, thereby improving the heat insulating performance of the curtain wall frame.

In addition, even if a separate supporting member is not formed in the main frame, the heat insulating member provided between the adjacent two-layered glass can effectively support the self-weight and the lateral load of the multi-layer glass.

In addition, an opening is formed on the front surface of the frame, and the heat insulating member is coupled to cover the opening, so that heat transfer with the outside air can be more effectively blocked.

Further, the cover member is coupled to the front surface of the heat insulating member by the fastening means, so that the multilayer glass can be stably pressed and fixed by the cover member. Even if the fastening means is made of metal, it is combined with the heat insulating member, Can be improved.

A frame support portion having a width or length corresponding to the shape of the space portion is formed on the rear surface of the cover portion of the heat insulating member so as to be inserted into and supported by the space portion of the main frame to improve the heat insulating performance, The supporting force can be improved.

Figures 1a and 1b are cross-sectional views of a curtain wall structure according to prior art documents.
FIG. 2A is a cross-sectional perspective view showing a curtain wall structure of a horizontal member according to an embodiment of the present invention; FIG.
FIG. 2B is an exploded perspective view showing a curtain wall structure of a horizontal member according to an embodiment of the present invention. FIG.
3 is a cross-sectional perspective view illustrating a curtain wall structure of a vertical member according to an embodiment of the present invention.
4A is a cross-sectional view illustrating a curtain wall structure according to an embodiment of the present invention.
4B is a cross-sectional enlarged view of a curtain wall structure according to an embodiment of the present invention.
5A is a cross-sectional perspective view illustrating a curtain wall structure of a horizontal member according to another embodiment of the present invention.
FIG. 5B is an exploded perspective view showing a curtain wall structure of a horizontal member according to another embodiment of the present invention. FIG.
6 is a cross-sectional perspective view showing a curtain wall structure of a vertical member according to another embodiment of the present invention.
7A is a sectional view showing a curtain wall structure according to another embodiment of the present invention.
7B is a cross-sectional enlarged view of a curtain wall structure according to another embodiment of the present invention.
8-11 are cross-sectional views illustrating a curtain wall structure in accordance with various embodiments of the present invention.

Hereinafter, an open type curtain wall structure (CS) using the GRP according to the present invention will be described in detail with reference to the accompanying drawings.

Figs. 1A and 1B illustrate curtain wall structures of different techniques according to the prior art. Fig.

1A is a perspective view showing a state in which a double layer glass 4 is provided between a frame 1 and a cover 2 so as to support the double layer glass 4 and a heat insulating material 3 including an airgel in resin between the frame 1 and the cover 2 It is difficult to support the self-weight or other load of the double-layer glass 4 and the joining means 5 for joining together the frame 1 and the cover 2 are additionally provided .

However, since the coupling means 5 is made of a metal material, the coupling means 5 may cause thermal bridging through the frame 1, thereby deteriorating the heat insulating performance.

On the other hand, Fig. 1 (b) shows a case in which a separate support frame 6 is provided on the frame 1 and a heat insulating block 3 is provided so as to surround the support frame 6 in order to solve the structural disadvantages of conventional synthetic resin heat insulators. And to secure the heat insulation performance and the supporting force at the same time.

However, since the heat insulating block 3 is made of synthetic wood, the synthetic wood is corroded by the heat bridging phenomenon, and the load of the support frame 6 is transmitted to the frame 1 through the heat insulating block 3 There is a problem that the heat insulating block 3 is deformed or deviated.

The open curtain wall structure (CS) using the GRP of the present invention has been proposed in order to overcome the problems of the prior art document. As shown in FIG. 2A, the open curtain wall structure CS includes a main frame 10 (Glass reinforced plastic) material is provided between the two-layered glass (W) adjacent to the front surface of the glass (W).

The main frame 10 includes a vertical member (Mullion) and a horizontal member (Transom) as shown in FIGS. 2A and 3, and the curtain wall structure (CS) of the present invention can be applied to a horizontal member As well as vertical members.

In the present invention, the outdoor side of the curtain wall structure CS is defined as a front side, the indoor side is defined as a rear side, the 'inside' of the present invention is defined as a direction toward the center, Define it in the opposite direction.

The glass reinforced plastic (GRP) material forming the heat insulating member 30 is generally made of GRP (glass reinforced plastic or glass fiber reinforced plastic (GFRP), which is different from carbon fiber reinforced plastic (CFRP) plastic. < / RTI >

The glass-reinforced plastic is a material obtained by combining aromatic nylon fibers such as glass fiber, carbon fiber, and Kevlar with a thermosetting resin such as unsaturated polyester, polyamide, or epoxy resin.

As a manufacturing method, various methods are used, but the method of reinforcing glass fiber processed to an unsaturated polyester of 0.1 mm or less in diameter is most used because it is resistant to external impact and has a very high tensile strength.

The following table compares the mechanical strengths of glass reinforced plastics (GRP), aluminum and stainless steel. Glass reinforced plastics are superior in tensile strength and low coefficient of linear expansion despite low specific gravity, This feature is about 1000 times lower.

       Mechanical properties of various materials importance The tensile strength
(kg / mm2) Coefficient of linear expansion
(cm x 10 < 3 & cm ° C ) Thermal conductivity
(Kcal / mhr ° C ) Strength ratio to weight GRP 1.4-1.9 8.5 to 26 2.3 0.22 4.6 to 38 stainless 8.00 59.6 1.6 14.0 3.1 aluminum 2.84 8.5 2.4 199.5 1.0

Accordingly, the open curtain wall structure using the GRP of the present invention can block the heat transfer by various metal members by using the heat insulating member 30 made of glass reinforced plastic (GRP), so that the curtain wall structure with the curtain wall structure It is possible to improve the heat insulation performance by blocking the degree of continuity.

Further, even when the main frame 10 is used as a horizontal member, the heat insulating member 30 provided between the adjacent two-layered glass W can effectively support the load of the double-layered glass W, There is an unnecessary technical advantage.

An opening 11 is formed on the front surface of the main frame 10 and the heat insulating member 30 is coupled to the main frame 10 to cover the opening 11. [ The opening 11 can reduce the contact area between the main frame 10 and the heat insulating member 30 to more effectively achieve heat insulating performance and can indirectly transfer the heat transfer area between the various metal members and the main frame 10 Heat transfer can also be reduced.

At this time, the heat insulating member 30 is coupled to cover the opening 11, so that the heat transfer to the outside air can be blocked more effectively.

2A and 2B, the heat insulating member 30 has a cover portion 31 formed to cover the opening portion 11 and is coupled to the main frame 10, and the cover portion 31 31 may have a support portion 32 integrally protruding from the front surface thereof.

The cover portion 31 of the heat insulating member 30 may cover the opening 11 to block heat transfer and may be formed to cover the entire surface of the main frame 10 to achieve a more excellent heat insulating performance.

The cover member 20 is joined to the front surface of the heat insulating member 30 by the fastening means P so that the multilayer glass W is pressed and fixed by the cover member 20.

The cover member 20 may be made of aluminum or the like as a typical metallic material, but it is preferable to use a glass-reinforced plastic (GRP) composite resin in the same manner as the heat insulating member 30 in order to secure the bonding force and the heat insulating performance.

11, the cover member 20 may be formed of a silicone material and may be formed of a support flange 32b integrally formed in front of the support portion 32 without a separate cover member 20. [ And the outer frame 50 may be coupled to the front.

The fastening means (P) may be a conventional metal fastening means such as a screw or a piece, and a fastening means such as a nylon engineering bolt having sufficient strength of bonding as well as glass reinforced plastic may be used.

The fastening means P can be fastened to the heat insulating member 30 through the cover member 20. The fastening means P can securely fasten the double-layer glass W as the cover member 20 presses the double- .

When the support member 32 is formed on the heat insulating member 30, the cover member 20 may be coupled to the support member 32 of the heat insulating member 30 by the fastening means P, The fastening means P is coupled to the inside of the support portion 32 of the heat insulating member 30 and is prevented from penetrating through the cover portion 31 to prevent the occurrence of thermal bridging.

The support portion 32 may have a support flange 32b formed on its front surface so that the cover member 20 can be stably contacted.

In addition, auxiliary heat insulating materials 40 may be provided on both sides of the supporting part 32 of the heat insulating member 30 with a hollow part 41 formed therein. The auxiliary heat insulating material 40 may be formed of polyamide or azon which is commonly used to secure economical efficiency. Preferably, the heat insulating material 40 may be made of a glass-reinforced plastic composite resin have.

The hollow portion 41 formed in the auxiliary thermal insulating material 40 may provide a more effective heat insulating performance by the air layer and may be formed in a tightly closed shape so that the hollow portion 41 is not formed.

At this time, a cover member 20 is provided on the front surface of the auxiliary thermal insulation material 40, and the fastening means P passes through the cover member 20 and is screwed into the screw groove 32a formed in the support portion 32. [ .

When the supporting flange 32b is formed on the supporting part 32, the auxiliary insulating material 40 is provided on the rear surface of the supporting flange 32b so as to stably engage with the rear surface of the supporting flange 32b. Can be further improved.

The fastening means P may be fastened in the process of construction through drilling in the state where no additional thread groove 32a is formed in the support portion 32 of the heat insulating member 30, 32a may be provided in advance and a screwing means P formed with a screw thread may be screwed into the screw groove 32a.

5A and 5B, the supporting portion 32 may have a hollow portion 32c formed therein to further improve the heat insulating performance. In this case, a separate screw groove 32a is not formed , So that the fastening means (P) is fastened through drilling.

The fastening means P is coupled so as not to penetrate the heat insulating member 30 so that the end of the fastening means P does not become close to the hollow portion 32c or is provided at least in the hollow portion 32c, It is desirable to prevent the thermal bridge phenomenon through the means P.

2b, the cover 31 of the heat insulating member 30 is formed with a flange 31a to cover the opening 11 by abutting against the front surface of the main frame 10, The insertion protrusion 31b may be formed on the rear surface of the opening 31a so as to be inserted into the opening 11. [

The cover portion 31 of the heat insulating member 30 covering the opening portion 11 and blocking heat transmission may be provided so as to cover the opening portion 11 with the flange 31a formed, It is possible to achieve a more favorable heat insulation performance by forming it to be equal to or larger than the width corresponding to the front surface of the frame 10. [

The insertion protrusion 31b formed on the rear surface of the flange 31a is inserted into the opening 11 formed in the front surface of the main frame 10 to ensure better heat insulation performance, The holding force of the member 30 can be strengthened and the supporting force can be improved.

4A and 4B, a pair of front flanges 12 are bent inwardly on the front surface of the main frame 10 so that an opening 11 is formed therebetween.

The front flange 12 may be stably provided so as not to generate a gap by providing a contact surface so as to be in close contact with the flange 31a of the cover portion 31. Although not shown in the drawing, And can be coupled to the front flange 12 of the main frame 10 by means of a piece or a screw that passes through the flange 31a of the cover portion 31. [

On the other hand, the heat insulating member 30 and the main frame 10 can be coupled by various fastening methods, and they can be formed so that both members are slidably engaged with each other in addition to the above-described fastening means such as a screw or a screw.

In one embodiment, a rail bend 13 may be formed at one end of the front flange 12 to form a rail groove 14 outside the rail bend 13.

Correspondingly, rail protrusions 31c protrude from both sides of the insertion protrusions 31b of the heat insulating member 30 and can be inserted into the rail grooves 14 of the main frame 10.

The insertion protrusions 31b inserted into the rail grooves 14 may be slidably engaged with each other along the longitudinal direction and the width of the rail grooves 14 may be formed to correspond to the thickness of the insertion protrusions 31b, It is preferable to make the thickness of the insertion protrusion 31b less than twice the thickness of the insertion protrusion 31b so as not to cause a flow in the coupling.

A pair of rear ribs 31b-1 are formed on the rear surface of the flange 31a and a rear flange 31b-2 is formed perpendicularly to the rear rib 31b-1. .

The rear flange 31b-2 is provided so as to cover the end portion of the rail bent portion 13 of the main frame 10 to ensure a more intricate heat insulating performance. On both sides of the rear flange 31b-2, The protrusion 31c may protrude from the front surface.

As a result, the front flange 12 and the rail bending portion 13 of the main frame 10 are engaged with the flange 31a of the cover portion 31, the rear rib 31b-1 of the insertion protrusion 31b and the rear flange 31b- 31b-2.

At this time, a seating groove 31d is formed between the rear rib 31b-1 and the rail projection 31c, and the rail bending portion 13 of the main frame 10 is fixed to the seating groove 31d in the longitudinal direction And the width of the seating groove 31d is formed to correspond to the thickness of the rail bending portion 13 so that the thickness of the rail bending portion 13 is twice the thickness of the rail bending portion 13 By weight.

A pair of rear flanges 31b-2 may be formed on one side of one end of the pair of rear ribs 31b-1, and the rear ribs 31b- One rear flange 31b-2 may be formed so that a hollow portion 31b-3 is formed between the rear rib 31b-1 and the rear flange 31b-2.

The hollow portion 31b-3 may provide an air layer between the flange 31a formed in the cover portion 31 of the heat insulating member 30 and the main frame 10 to ensure additional heat insulating performance.

7A to 7B, a support portion 32 is integrally formed on the front surface of the cover portion 31 of the heat insulating member 30 and the cover portion 31 is integrally formed with the main frame 10, A flange 31a is formed on the entire surface of the flange 31a so as to cover the opening 11. The both ends of the flange 31a are gradually thickened to form the tapered portion 31a-1.

A rear protrusion 15 is formed at a corresponding position on the rear surface of a pair of front flanges 12 formed to bend inward of the main frame 10 so that the tapered portion 31a-1 can be inserted, A tapered groove 16 may be formed between the front flange 12 and the rear projection 15.

Thus, the tapered portion 31a-1 of the cover portion 31 can be inserted into the tapered groove 16 to secure a long fastening force.

The front flange 12 formed on the main frame 10 may be bent obliquely rearward to form the taper groove 16 and the rear projection 15 may be bent obliquely forward. Tapered grooves 16 may be formed between the front flange 12 and the rear projection 15, which are bent in different directions from each other.

At this time, the flange 31a is formed with a latching protrusion 31a-2 so that the end of the front flange 12 or the rear protrusion 15 is seated, and the front flange 12 or the rear protrusion 15, So that it can be prevented from being released despite the flow by the latching jaws 31a-2, thereby securing a stable fastening force.

On the other hand, a frame having a width (w) or length (l) corresponding to the shape of the space S is formed on the rear surface of the cover part 31 so as to be inserted into the space S of the main frame 10, The support portion 33 may be formed.

The main frame 10 is generally formed to have a rectangular cross section, but it may be formed in a circular or polygonal cross section for aesthetic reasons depending on design conditions.

8 to 10, the main frame 10 of the present invention may have an opening 11 to insert the insertion protrusion 31b of the cover portion 31 of the heat insulating member 30 And the frame supporting portion 33 may be integrally formed with the insertion protruding portion 31b.

The frame support portion 33 may be formed in various shapes but is preferably formed to have a width w or length l corresponding to the space S of the main frame 10.

The frame supporting portion 33 is formed to have a width w or a length 1 corresponding to the space portion S so that the frame supporting portion 33 does not flow under a vertical load or a lateral load such as a wind load or an earthquake, have.

The length (1) is defined as the length of the main frame (10) except for the end portion of the rail bent portion (13).

The width w and the length l corresponding to the space S are provided such that the frame support portion 33 is inserted and not flow. It is preferable that the ratio of the overall length is formed to be 0.9 or more Do.

The frame supporting portion 33 may be composed of at least one transverse member 33a provided in the width direction of the space portion S and at least one longitudinal member 33b provided in the longitudinal direction, The transverse member 33a effectively functions to cope with the vertical load when the transmission member 30 transmits the load to the main frame 10 and the longitudinal member 33b functions to effectively cope with the lateral load.

Also, in one embodiment, the frame support portion 33 can be manufactured such that its cross-section has an I-shaped cross section as a whole so as to effectively correspond to a load.

Further, the frame supporting portion 33 may be formed with a hollow portion 33c between the transverse member 33a and the longitudinal member 33b, and the hollow portion 31b- An additional airtightness performance can be ensured by forming an air layer between the insertion protrusion 31b formed in the portion 31 and the main frame 10.

Meanwhile, the curtain wall structure CS of the present invention may be provided with an outer frame 50 which is coupled to the front surface of the curtain wall structure CS so as to correspond to the main frame 10 and is exposed to the outside.

The outer frame 50 is generally made of a metal material such as aluminum. However, the outer frame 50 may be made of other materials in consideration of the design of the upper surface. When the outer frame 50 is made of a material other than metal, 20 can be primarily reduced.

It is common that both ends of the outer frame 50 are formed so as to be fitted into fitting grooves 21 formed at both ends of the cover member 20 with a fitting step 51, It is also possible to engage with each other.

A sealant 60 made of a silicone material is provided between the cover portion 31 of the multilayer glass W and the heat insulating member 30 or between the multilayer glass W and the cover member 20 in order to block heat conduction and secure the heat insulating performance. .

The open curtain wall structure (CS) using the GRP of the present invention as described above can be implemented in other specific forms without changing the technical idea or essential feature of the present invention to a person having ordinary skill in the art You will understand.

It is to be understood, therefore, that the above description is intended to be illustrative, and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, Ranges and equivalents thereof are to be construed as being included within the scope of the present invention.

CS: Curtain wall structure W: Double layer glass
10: main frame S: space part
11: open part 12: front flange
13: rail bending portion 14: rail groove
20: cover member 30:
31: cover part 31a: flange
31b: insertion protrusion 31b-1: rear rib
31b-2: rear flange 31b-3: hollow portion
31c: rail projection 31d: seat groove
32: Support portion 32a: Screw groove
33: frame supporting portion 33a:
33b: longitudinal member 33c: hollow portion
40: Auxiliary thermal insulation material 41: Hollow part
50: outer frame 60: sealant
P: fastening means

Claims (13)

A curtain wall structure (CS) in which a multilayer glass (W) is fixed to a front surface of a main frame (10) having a space portion (S) formed therein,
A heat insulating member 30 made of glass reinforced plastic (GRP) is provided between the two-layered glass W adjacent to the front surface of the main frame 10,
A pair of front flanges 12 are bent inward to form an opening 11 therebetween and one end portion of the front flange 12 is provided with a rail bend portion 13 are bent backward to form rail grooves 14 outside the rail bending portion 13,
The cover 31 of the heat insulating member 30 is formed with a flange 31a so as to cover the opening 11 by abutting against the front surface of the main frame 10, The insertion protrusion 31b is formed with a pair of rear ribs 31b-1 on the rear surface of the flange 31a, and the insertion protrusion 31b is formed in the insertion protrusion 31b. A rear flange 31b-2 is formed perpendicularly to the rear rib 31b-1 and a rail projection 31c is formed on both sides of the rear flange 31b- And a seating groove 31d is formed between the rear rib 31b-1 and the rail projection 31c so that the rail bent portion 13 is inserted to form a locking structure in the front-rear direction The supporting portion 32 may be integrally formed on the front surface of the cover portion 31,
Characterized in that the cover member (20) is coupled to the support part (32) of the heat insulating member (30) by the fastening means (P).
delete The method according to claim 1,
A cover member 20 is provided on the entire surface of the auxiliary thermal insulating material 40 and the auxiliary heat insulating member 40 having a hollow portion 41 is formed on both sides of the supporting portion 32 of the thermal insulating member 30, Wherein the fastening means P passes through the cover member 20 and is screwed into the screw groove 32a formed in the support portion 32. [
delete delete delete delete The method according to claim 1,
Wherein the insertion protrusion 31b is formed with a hollow portion 31b-3 between a pair of rear ribs 31b-1 and a rear flange 31b-2.
delete delete The method according to claim 1,
A frame support portion having a width w or length l corresponding to the shape of the space S is formed on the rear surface of the cover portion 31 so as to be inserted into and supported by the space S of the main frame 10 33) are formed on the upper surface of the curtain wall structure.
12. The method of claim 11,
Wherein the frame support part (33) comprises at least one transverse member (33a) provided in the width direction of the space part (S) and at least one longitudinal member (33b) provided in the longitudinal direction. Open curtain wall structure.
13. The method of claim 12,
Wherein the frame support part (33) has a hollow part (33c) formed between the transverse member (33a) and the longitudinal member (33b).

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