KR20130017981A - Prevented thermal bridge and reinforced structure window - Google Patents

Abstract

PURPOSE: A reinforced structure window for preventing thermal bridges is provided to prevent external heat loss and to reinforce a window frame and a sash frame by inserting a reinforced frame. CONSTITUTION: A reinforced structure window for preventing thermal bridges comprises a glass plate(10), a window frame(20), a sash frame(30), and a reinforcement frame(40). The window frame forms a frame for window to fix the edges of the glass plate. The sash frame is inserted and fixed to an opening to form windows on a building wall. The reinforcement frame reinforces the window and sash frames by being fixed to the internal space in the longitudinal direction.

Description

{Prevented Thermal Bridge and Reinforced Structure Window}

The present invention relates to a thermal bridge preventive structural reinforcement window, and more specifically, through the reinforcement frame inserted into the window frame frame or window frame constituting the window and reinforce the strength of the window frame frame and the window frame as well as the window frame frame and window frame It is to provide a structural reinforcement windows for preventing thermal bridges to prevent external heat loss.

As is well known, windows and doors are becoming an important component of a building that performs indoor ventilation, outdoor network function, windproof and soundproofing, etc. together with the skylight function inside the building using sunlight.

The windows and doors are composed of a glass plate, a window frame for fixing the edge of the glass plate, and a window frame frame installed at a wall opening of the building for installing the window and holding the window frame on which the glass plate is installed.

Conventionally, window frames and window frame frames forming windows and doors are mainly made of a metal material such as aluminum, which is light and durable.

However, in the case of the conventional windows and doors, as the window frame and the window frame frame are made of a metal material such as aluminum, the manufacturing cost increases, thereby causing an external heat loss.

Therefore, in order to improve the above problems, the window frame and the window frame of the window are mainly made of PVC (Polyvinyl Chloride) material, which is lower in manufacturing cost and thermal conductivity than the aluminum metal material.

However, as the size of windows used in buildings has gradually increased in size, sagging and warping caused by external influences such as the load and wind direction of the windows itself, it shortens the durability and service life of windows and secures airtightness due to difficulty in opening and closing windows. Has the disadvantage of being difficult.

Therefore, in order to reinforce the rigidity of the window frame and the window frame of the window and door made of fibish material, a high strength metal reinforcement frame was used inside the window frame and the window frame.

However, as the reinforcement frame uses a high thermal conductivity metal material, the reinforcement frame made of metal forms a heat transfer path connecting the inside and the outside inside the window frame and the window frame frame, thereby generating external heat loss. The problem is caused.

An object of the present invention for solving the above problems is to reinforce the strength of the window frame and the window frame through the reinforcement frame inserted into the window frame or window frame frame forming a window and through the outside of the window frame and the window frame frame It is to provide a thermal bridge preventing reinforcement windows to prevent heat loss.

Thermal bridge preventing structure reinforcement window of the present invention for achieving the above object is a window frame for holding and fixing the glass plate edge; A window frame frame which is fixed to an opening of a building to hold and fix the window frame; And a reinforcement frame inserted into the window frame or the inner space of the window frame frame to reinforce the strength of the window frame or the window frame frame, wherein the reinforcement frame is made of a PVC material; And a steel wire reinforcement cord disposed inside the frame body to reinforce strength.

Here, the window frame and the window frame is preferably made of a PVC material.

In addition, the thermal bridge structure reinforcement window of the present invention comprises a window frame frame that is fixed to the opening of the building to hold the glass plate edge fixed; And a reinforcement frame inserted into the window frame frame to hold the edge of the glass plate and to reinforce the strength of the window frame frame, wherein the reinforcement frame is made of a PVC material; And a plurality of steel wire reinforcement cords for reinforcing strength disposed in the frame body.

Here, the window frame frame is preferably made of a PVC material.

The steel wire reinforcement cord may include a plurality of first reinforcement cords disposed along a length direction of the frame body; And a plurality of second reinforcement cords intersecting the first reinforcement cords and disposed along the width direction of the frame body.

In this case, the first reinforcing cord and the second reinforcing cord may be woven together to form a lattice form.

According to the window of the present invention, by forming a frame body of the reinforcement frame which is inserted into the window frame or the window frame frame inner space portion to reinforce the strength of the window frame or the window frame frame made of PVC material having low thermal conductivity Through this, it is possible to prevent the external heat loss through the window frame and the window frame, and to reinforce the rigidity by installing a steel wire reinforcement cord inside the frame body so that the sufficient strength reinforcement of the window frame and the window frame is achieved. Has

1 is a plan sectional view showing a thermal bridge preventing structural reinforcement window according to a first embodiment of the present invention.
FIG. 2 is an enlarged cross-sectional view of part II of FIG. 1.
3 is a partial perspective view illustrating the reinforcement frame of FIG. 2 separately.
Figure 4 is a plan sectional view showing a thermal bridge preventing structural reinforcement window according to a second embodiment of the present invention.
FIG. 5 is an enlarged cross-sectional view of portion V of FIG. 4.
6 is a partial perspective view illustrating the reinforcement frame of FIG. 5 separately.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and the same or similar components are denoted by the same reference numerals throughout the specification.

1 is a plan sectional view showing a thermal bridge preventing structural reinforcement window according to a first embodiment of the present invention, Figure 2 is an enlarged sectional view showing a portion II of FIG.

1 and 2, the thermal bridge preventing structural reinforcement window (1; hereinafter referred to as "window") according to an embodiment of the present invention is a glass plate 10, window frame 20, window frame frame ( 30) and a reinforcement frame 40.

First, the window frame 20 is configured to form a window frame for holding and fixing the edge of the glass plate 10.

The window frame 20 is composed of a support frame 21 and a fixed frame 25, the fixed frame 25 is a glass plate 10, the edge portion of which is inserted into the glass plate fixing groove 28 of the support frame 21. It is fastened to the outside of the support frame 21 in between to maintain the fixed state of the glass plate (30).

In the present embodiment, the fixing frame 25 illustrates that the fastening protrusion 26 protruding on one side is caught and fixed in a state of being fitted into the first fastening groove 22 formed in the support frame 21.

At this time, the packing members 51 and 52 made of rubber or silicon for shielding the gap between the edge portion of the glass plate 10 and the support frame 21 and the fixing frame 25 may have a magnetic field geography portion of the glass plate 10. It is fitted into and fixed to the fixing grooves 23 and 27 formed on the inner surfaces of the support frame 21 and the fixing frame 25 which are in contact with each other.

On the other hand, the glass plate 10 may be formed in a polygonal shape including a round, oval in addition to the rectangular shape according to the shape of the window 1, the window frame 20 and the window to correspond to the shape of the glass plate 10 and Naturally, the window frame frame 30 may be applied in various forms.

The window frame frame 30 is fitted into and fixed to an opening 6 for forming a window at the wall surface 5 of the building, and the window frame 20 of the window in which the glass plate 10 is fixed to close the opening 6. Fixing or hinge-fixing one side to the opening 6 can be fixed to open and close.

In this embodiment, the window (1) illustrates that the window frame 20 is made of a fixed window that is fastened and fixed to the window frame frame 30 so as to close the opening 6, where the support frame 21 of the window frame 20 The fastening members 29 protruding from each other are inserted into the second fastening grooves 31 of the window frame frame 30 and fastened to each other.

On the other hand, the fastening surfaces of the support frame 21 and the window frame frame 30 of the window frame 20, each of the packing member 53 made of rubber and silicone material to prevent the gap therebetween to be waterproof, windproof and soundproof 54 and the fixing grooves 24 and 32 are formed to be fixed.

 Here, the window frame 20 and the window frame frame 30 is made of a hollow frame having an internal space to reduce its own weight, and the manufacturing cost is low and the heat insulation effect is high compared to a metal material such as aluminum It is preferably made of a PVC material.

In addition, the reinforcement frame 40 is inserted into their inner space along the length direction of the window frame 20 and the window frame frame 30 so as to reinforce the strength of the window frame 20 and the window frame frame 30, Window (1) The deflection and distortion caused by external influences such as its own load and wind direction can be reduced to shorten the durability and service life of the window and to make it difficult to secure airtightness due to impossibility of opening and closing the window.

On the other hand, the reinforcing frame 40 is supported and fixed in the inner space to the spacers (29, 39) protruding to the partition wall partitioning the inner space inside the window frame 20 and the window frame frame (30).

3 is a partially enlarged perspective view of the reinforcement frame of FIG. 2 separated and shown.

As shown in FIG. 3, the reinforcement frame 40 includes a frame body 41 and a steel wire reinforcement cord 45 installed in the frame body 41 to reinforce the strength of the reinforcement frame 41. do.

The frame body 41 is made of a PVC material having low thermal conductivity similar to the window frame 20 and the window frame frame 30, and has a hollow rectangular cross-sectional shape of an “U” shape with one side open. Illustrates that.

However, the frame body 41 of the present invention may be made of various resin materials having low thermal conductivity in addition to the PVC material, and according to the cross-sectional shape of the inner space of the window frame 20 and the window frame frame 30. Naturally, it can be applied in a variety of forms, including the cross-sectional shape of "I", "H", "L" and the like.

As such, the frame body 41 is formed of a low thermal conductivity PCB (PVC) material, whereby a reinforcement frame made of a relatively high thermal conductivity metal material is conventionally formed inside the window frame 20 and the window frame frame 30. It acts as a heat transfer path and prevents it from causing external heat loss.

Therefore, the steel wire reinforcement cord 45 is disposed inside the frame body 41 made of a fibish material and serves to have sufficient rigidity required for the reinforcement frame 40 together with the frame body 41.

Meanwhile, the steel wire reinforcement cord 45 intersects the plurality of first reinforcement cords 46 and the first reinforcement cords 46 disposed along the length direction of the frame body 41, and of the frame body 41. It consists of a plurality of second reinforcing cords 47 arranged along the width direction.

Here, the first reinforcement cord 46 and the second reinforcement cord 47 are more preferably configured to be woven together in a lattice form.

As such, the first reinforcement cords 46 and the second reinforcement cords constituting the steel wire reinforcement cords 45 are configured to be orthogonal to each other and weave, thereby acting on the window frame and the window frame frame by the reinforcement frame 40. Allows to reinforce rigidity against deflection, bending and torsional loads.

Therefore, the window 1 of the present embodiment is relatively low thermal conductivity of the frame body 41 of the reinforcing frame 40 is inserted into the window frame 20 or the inner space of the window frame 30 to reinforce strength. It is formed of a PVC material to prevent external heat loss through the window frame 20 or the window frame frame 30, and also by installing a steel wire reinforcement cord 45 inside the frame body 41 of the fibish material The frame 40 allows sufficient strength reinforcement of the window frame 20 and the window frame frame 30.

Hereinafter, a description will be given with reference to FIGS. 4 to 6 with the windows according to the second embodiment of the present invention being used, and the same reference numerals are used for the same and similar configurations as those of the first embodiment. Is omitted.

Figure 4 is a plan sectional view showing a thermal bridge preventing structural reinforcement window according to a second embodiment of the present invention, Figure 5 is a plan view showing an enlarged portion V of Figure 4, Figure 6 is a reinforcement frame of Figure 5 A partial perspective view showing separately.

4 to 6, the window 100 according to the present exemplary embodiment includes a glass window 10, a window frame frame 130, and a reinforcement frame 140.

That is, the window 100 of the present embodiment is configured to be directly inserted into the window frame frame 130 is fixed to the window frame frame 130 is fitted into the opening 6 of the building 5 compared to the first embodiment described above.

In addition, the reinforcement frame 140 is fitted in the interior space of the window frame frame 130 to reinforce the rigidity of the window frame frame 130, and the reinforcement frame 140 is to hold the edge of the glass window 10 fitted to the window frame frame 130 It is formed to have a "U" shaped cross-sectional shape provided with a glass window fixing groove for fixing.

Here, the window frame frame 130 is made of a hollow frame having an internal space to reduce the weight of the load itself, as described above, compared to a metal material such as aluminum, the manufacturing cost is low and high insulation effect PVC (PVC) ) Is preferably made of a material.

The reinforcement frame 140 includes a body frame 41 and a steel wire reinforcement cord 45 installed in the body frame 41 to reinforce rigidity as described above in the first embodiment.

Here, the body frame 410 is made of a PVC material like the window frame 130, the rigid reinforcement cord 45 is a first reinforcement cord (installed in the longitudinal direction inside the body frame 41 ( 46 and the second reinforcing cords 47 provided in the width direction intersect with each other and are woven.

Therefore, the reinforcement frame 140 is fitted in the interior space of the window frame frame 130 to reinforce the rigidity of the window frame 130 and is fixed to the spaced apart state by the spacer 139 in the window frame frame 130. Accordingly, the cross-sectional area of the part serving as the heat transfer path is reduced to prevent heat loss from occurring.

Furthermore, in the present embodiment, the reinforcing frame 140 is fixed by holding the edge of the glass window 10 fitted inside the window frame frame 130, thereby increasing the heat transfer path to increase the thermal insulation efficiency of the glass window 10. Have

Although the preferred embodiments of the present invention have been described above, the present invention is not limited thereto, and various modifications or changes can be made within the scope of the claims and the detailed description of the invention and the accompanying drawings. In addition, it is natural that it belongs to the scope of the present invention.

1, 100: window 10: glass plate
20: window frame 21: support frame
22: first fastening grooves 23, 24, 27, 32; Fixing groove
25: fixing frame 28: glass plate fixing groove
29: fastening member 30, 130: window frame frame
31: second fastening groove 40, 140: reinforcing frame
41: frame body 45: rigid reinforcement cord
46: first reinforcement cord 47: second reinforcement cord
51, 52, 53, 54: packing member

Claims (6)

Window frame for holding and fixing the edges of glass plates;
A window frame frame which is fixed to an opening of a building to hold and fix the window frame; And
And a reinforcing frame inserted into the window frame or the window frame frame to reinforce the strength of the window frame or the window frame frame.

The reinforcement frame,
A frame body made of a PVC material; And
And a plurality of steel wire reinforcement cords for reinforcing strength disposed in the frame body.
In claim 1,
The window frame frame and the window frame is a thermal bridge structure reinforced windows made of PVC material.
A window frame frame inserted into the opening of the building to hold and fix the edge of the glass plate; And
A reinforcing frame inserted into the window frame frame to secure the glass plate by holding an edge thereof and to reinforce the strength of the window frame frame;

The reinforcement frame,
A frame body made of a PVC material; And
And a plurality of steel wire reinforcement cords for reinforcing strength disposed in the frame body.
4. The method of claim 3,
The window frame frame is reinforced thermal bridge structure made of PVC material (PVC).
The method according to claim 1 or 3,
The steel wire reinforcement cord,
A plurality of first reinforcement cords disposed along a length direction of the frame body; And
And a plurality of second reinforcing cords intersecting the first reinforcing cords and disposed along the width direction of the frame body.
The method of claim 5,
The first reinforcing cord and the second reinforcing cord is formed in a lattice form, the thermal bridge preventing structure reinforcement window is composed of each other.

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