KR101573496B1 - System door - Google Patents

Abstract

The system door according to the present invention includes a door for supporting a glass member and a door frame for supporting the door, wherein the door includes an inner door frame, an outer door frame, and an inner door frame, And a door side central insulated structure for connecting the inner frame and the outer door frame, wherein the door frame includes an inner frame, an outer frame, and a frame side central heat insulation structure connecting the inner frame and the outer door frame, Side central insulated structure and the frame-side center-insulated structure, and at least one of the door-side central insulated structure and the frame-side central insulated structure, Characterized in that at least two elongated ribs contact each other when the door is closed to provide a thermal insulation space It shall be. According to the present invention, there is provided a system door capable of providing a system door having a high heat insulation performance, achieving a stable performance with high heat insulation performance, preventing breakage and deformation of parts, and improving durability of a product.

Description

System door {System door}

The present invention relates to a system door. In particular, the present invention relates to a system door for improving heat insulation performance.

In order to give a function to view the outside, the window is increasingly used as a glass. In accordance with this tendency, application of system doors is also increasing. The system door generally refers to a product that uses a thick glass member, enhances airtightness and watertightness, and considers visual aesthetics.

The system door is required to have a high-strength frame performance for supporting the glass and an important function for shutting off the outside air and moisture when it is closed. In particular, the heat insulating performance is lower than that of a general closed type door. Therefore, how to reinforce the adiabatic performance in a certain way becomes a main factor of performance.

Conventional system doors have been widely used to increase the heat insulation performance and to provide two glasses at regular intervals in order to strictly block external air and external moisture. However, there has been a difficulty in meeting the needs of low-energy-consuming buildings that have been strengthened in recent years. As a related art related to this, Korean public utility model 20-2013-0001128, an insulating and safety reinforced glass door is available.

The inventor of the present invention has studied a method for improving the heat insulation performance of a system door and developed a method for solving the problem.

The system door according to the present invention includes a door for supporting a glass member and a door frame for supporting the door, wherein the door includes an inner door frame, an outer door frame, and an inner door frame, And a door side central insulated structure for connecting the inner frame and the outer door frame, wherein the door frame includes an inner frame, an outer frame, and a frame side central heat insulation structure connecting the inner frame and the outer door frame, And the frame side central heat insulating structure is provided with at least two contact portions which are spaced apart from each other when the door is closed and at least two barrier films extending from any one of the door side central heat insulating structure and the frame side central heat insulating structure, And at least two ribs extending from the other of the door-side center-insulated structure and the frame- . According to the present invention, it is possible to effectively reduce the heat loss between the door and the door frame, and to easily provide a heat insulating structure

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In the above invention, the at least two contact portions may be provided at an inclined position. According to this, breakage of the rib can be prevented, and the durability of the system door can be further improved. A gasket provided on a contact portion between the inner door frame and the inner frame; And a gasket provided at a contact portion between the outer door frame and the outer frame, and at least three heat insulating spaces may be provided at the contact portion between the door and the door frame. According to this, heat loss through the contact portion between the door and the door frame hardly occurs.

In the above-described invention, at least two ribs extending from any one of the door-side central insulated structure and the frame-side central insulated structure and the inclined portion provided to the other of the door-side center insulated structure and the frame- . According to this, cleaning can be facilitated. Here, a step may be provided at a portion of the inclined portion where the rib touches. According to this, the heat insulating performance can be improved while being manufactured conveniently.

According to the present invention, the door-side central heat insulating structure includes a door-side heat insulating material supported on one side of the inner door frame and the outer door frame; And a door side heat insulating cover supported on the other side of the inner door frame and the outer door frame. The door side insulating material includes at least one partition wall extending to the door side heat insulating cover. According to this, heat loss through the door's own frame can be reduced.

In the above-mentioned invention, the frame-side central heat insulating structure may include a frame-side heat insulating material supported on one side of the inner frame and the outer frame, And a frame side thermal insulation cover supported on the other side of the inner frame and the outer frame, and the frame side insulation includes at least one partition wall extending to the frame side thermal insulation cover. According to this, heat loss through the frame of the door frame can be reduced.

[12] In any one of the above-mentioned inventions, the glass member may be provided with three pieces of glass and supported by the outer door frame; And a supporting rubber interposed between the striking member and the glass member. According to this, it is possible to prevent deformation, deformation, and breakage, which may occur in the case of a heavy door with a heavy weight, and to obtain a large durability and stable operation. Here, the stiffening member is provided with a predetermined gap with the door side central heat insulating structure, so that the durability of the heat insulating structure provided by a resin material such as polyamide is improved and the reliability of the product is improved .

According to the present invention, there is provided a system door capable of providing a system door having a high heat insulation performance, achieving a stable performance with high heat insulation performance, preventing breakage and deformation of parts, and improving durability of a product.

1 is a front view of a system door according to an embodiment;
2 is a sectional view taken along line A-A 'in Fig.
Fig. 3 is an enlarged view of the contact portion between the door and the door frame in Fig. 2; Fig.
4 is an enlarged view of a contact portion between a door and a door frame in a system door according to another embodiment;

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. It will be understood by those skilled in the art that the present invention may be embodied in many other specific forms without departing from the spirit or essential characteristics thereof. On the other hand, in the following description, it will be described based on insulation that the cold air flows into the room in winter, but it is also understood that it is used to block the inflow of heat into the room in summer. Also, even in the case where the drawings are different, the same reference numerals are given to parts that perform the same function in the same configuration, so that the ideas of the invention can be easily understood.

The inventor of the present invention has confirmed that there are the following kinds of factors causing deterioration of the heat insulating performance. A heat loss due to insufficient heat insulating performance of a visual opening member such as a glass member supported by a first frame, a heat loss due to heat transfer between inside and outside frames forming a skeleton of a system door, It is confirmed that the main cause of the heat loss due to the inflow of the outside air on the connection part.

On the other hand, in order to solve the first problem, the inventors attempted to provide a glass member by stacking three layers of glass. However, when three layers of glass members are overlapped, the self-load of the glass member greatly increases, so that various members can not support the glass member, and when the glass member is damaged or deformed for a long time, the frame is totally distorted. Particularly, in the case of the door, the door rotates about one support point, so that the frame is more likely to be distorted. In order to solve these problems, the inventor carried out additional research and development, and proposed a solution to the problem.

1 is a front view of a system door according to an embodiment.

Referring to Fig. 1, a door frame 2 and a door 1 supported by the door frame 2 are shown. The door 1 is provided with a handle 4 so that the user can grasp it and open and close the door 1. The door 1 can be rotated with respect to the door frame 2 by the hinge 3.

As already described, the factors affecting the heat insulation through the system door include heat transfer through the glass provided in the first door, heat transfer through the second door 1 and each frame of the door frame 2, 1) and the door frame (2).

The heat transfer through the glass of the door, which is the first of these, provides the door 1 with three pieces of glass, thereby maximizing the heat insulating effect and obtaining a predetermined effect. However, as the three glass pieces are provided to the door, the load increases greatly, and in particular, the door is supported on one side of the hinged door, thereby causing a problem that the door is largely deflected.

2 is a cross-sectional view taken along line A-A 'in Fig.

Referring to Fig. 2, as already explained, the door 1 is provided with a glass member 80 provided with three pieces of glass. The gap between each glass 5, 6, 7 placed in the glass member 80 can be provided in vacuum to increase the heat insulation efficiency.

An inner door frame 11, an outer door frame 12 and a door side central heat insulating structure 30 are provided on the frame side of the door 1 supporting the glass member, 13). The door side fastening members 13 may be provided at predetermined intervals over the entire frame so as to provide sufficient fastening force.

The door frame 2 is provided with an inner frame 8, an outer frame 9 and a frame side central heat insulating structure 20, which are fastened by a frame fastening member 10. The frame fastening members 10 may be provided at predetermined intervals over the entire frame so as to provide a fastening force.

On the other hand, the above description describes the contact portion of either the door 1 or the door frame 2, but it is to be understood that all the surfaces of the four corners can be similarly provided, and the same explanation can be applied.

Fig. 3 is an enlarged view of the contact portion between the door and the door frame in Fig.

3, a stiffening member 63 is provided to stably support the weight of the glass member 80 and a supporting rubber 78 is provided between the stiffening member 63 and the glass member 80, Is provided. The strut member 63 engages the pockets 68 provided in the outer frame 12 and the strut portion 64 supports the load of the glass member 80. The worker also hooks the hook portion 64 to the pocket 68 so that the glass member 80 can be supported by the hook portion 65. A supporting rubber (78) is inserted between the supporting portion (65) and the glass member (80). Even when an impact is applied during opening and closing of the door by the supporting rubber 78, the glass member 80 can be supported by providing a stable elastic force. In addition, the glass member 80 is supported by the supporting member 63 and the supporting rubber 78, and in particular, the supporting member 63 and the door side central heat insulating structure 30 are separated from each other, Can directly contact the door side central heat insulating structure 30 to prevent the heat insulating structure from being damaged. Preferably, the supporting member 78 and the supporting member 78 are provided to support a load in the direction of the moment applied to the hinge from the hinged door and an impact load that may occur when the door is opened and closed.

Spacers 61 and 62 and an inner sealer 67 and an outer sealer 66 may be further provided for stably supporting the glass member 80. [

The outer portion is transmitted to the outer door frame 12 and the inner portion is transmitted through the connecting member 69 to the inner door frame 12 11). The forces transmitted to the door frames 11 and 12 meet each other at the door-side central insulated structure 30.

Since the door frames 11 and 12 have metal rigidity, they can maintain a certain degree of strength even when the load of the glass member 80 is applied. The door-side central heat insulating structure 30 is made of a resin such as polyamide or the like, and may be insufficient in rigidity. Particularly, since the width of the glass member 80 having three sheets of glass is increased, there is a problem that a structure for supporting the glass member 80 must be provided. The door-side central insulated structure 30 has been proposed to solve such a problem.

The door side central heat insulating structure 30 is provided with a door side heat insulating material 31 whose one end is supported at one side of the inner door frame 11 and the outer door frame 12, Side heat insulating cover 32 on the other side of which the door frame 12 is supported. The door side heat insulating material 31 is provided with a partition structure extending from the body 35 toward the door side heat insulating material cover 32. The first door side partition wall 33 and the second door side partition wall 34 are provided in detail. The partition walls 33 and 34 are provided at regular intervals and the inertia moment of the door side heat insulating material 31 is increased by the body 35 and the partition walls 33 and 34, Therefore, it can withstand the bending stress firmly. According to this, even if large bending stress is applied from the glass member 80, it can be sufficiently supported by the partition walls 33 and 34 and deformation can be prevented.

The proof stress against the bending stress and the resistance against the load are applied to the frame side insulated structure 20 as well so that the body 23 and the first frame side partition wall 24 provided to the frame side heat insulating material 21, The effect can be obtained by the two frame side partition walls 25. The frame side walls 24 and 25 may contact the frame side heat insulating cover 22 to improve the heat insulating effect. The frame side central heat insulating structure 20 also functions as a structure provided for supporting the door 1 by the hinge 3. [ In addition, the frame-side heat insulating material 21 is provided with the first, second and third shielding films 26, 27 and 28 so that the moment of inertia is further increased and the load of the glass member can be more firmly sustained.

According to the above-described configuration, it is possible to withstand the static load and the impact load necessary in applying the glass member 80 having a heavy own weight. Therefore, the heat transfer through the glass member can be prevented from the use of the triple glazing, and the problem caused by the increase in the load can be solved.

Hereinafter, a configuration for preventing heat transfer through the space between the door and the door frame will be described.

In the body portion of the door side heat insulating material 31, three ribs 36, 37 and 38 are provided toward the door frame 2 side. The ribs can be fitted and fixed in the grooves of the main body. The ribs may be made of soft rubber or resin to provide a predetermined elastic restoring force. In addition, the first rib 36 on the upper side is positioned on the innermost side and the third rib 38 on the lower side is protruded most outward on the basis of the drawing. This is to prevent interference when the door 1 is opened or closed. Also, the degree of protrusion of the blocking films 26, 27 and 28 is different from each other. In other words, the barrier and the rib are provided in pairs. As a result, the pair of shielding membranes and the ribs can reliably contact each other when the door is closed to block the inflow of outside air. In each pair of the shield and the rib, the contact portion of the rib and the shield can be provided inclined with respect to the other pair. That is, the positions of the contact portions differ from each other in the width of the gap between the door 1 and the door frame 2, and preferably have a tendency to be inclined obliquely. As a result, during the movement of the casement door, it is possible to prevent the end of one of the ribs from being damaged due to contact with the pair of non-paired shielding films, thereby improving the reliability of the product.

An inner gasket 51 is provided at an inner end portion where the inner frame 8 meets the inner door frame 11 and an inner gasket 51 is provided at an inner end of the outer frame 9 and the outer end of the outer door frame 12. [ Is provided in the outer gasket (52).

According to the above configuration, four heat insulating spaces are provided by the pair of ribs and the shielding film, and the gaskets 51 and 52. The heat loss through the space between the door and the door frame can be sufficiently prevented by the four heat insulating spaces and the heat insulating efficiency can be increased. Each insulation space is indicated by ①, ②, ③, ④ in Fig.

Hereinafter, a configuration for interrupting the heat transfer through the door 1 and the door frame 2 will be described.

The door 1 can be formed as a heat insulating space by the inner door frame 11, the door side central heat insulating structure 30 and the outer door frame 12. [ Specifically, the inner space of the inner door frame 11 and the inner space of the outer door frame 12 can form one heat insulating space, respectively. The heat insulating space between the first door side partition wall 33 and the inner door frame 11 and the heat insulating space between the first and second door side partition walls 33 are formed by the door side heat insulating material 31 and the door side heat insulating material cover 32, (34), and a heat insulating space between the second door side partition (34) and the outer door frame (12). That is, five insulation spaces can be provided. Each insulation space is marked with ①, ②, ③, ④, ⑤.

Likewise, the door frame 2 can be provided with a heat insulating space by the inner frame 8, the frame side central heat insulating structure 20 and the outer frame 22. Concretely, the inner space of the inner frame 8 and the inner space of the outer frame 22 can form one heat insulating space, respectively. The heat insulating space between the first frame partition wall 24 and the inner frame 8 and the heat insulating space between the first and second frame partition walls 24 and 25 and the heat insulating space between the second frame partition 25 and the outer frame 25, An insulating space is provided between the frames (9). That is, five insulation spaces can be provided. Each insulation space is marked with ①, ②, ③, ④, ⑤.

As described above, in the door frame and the door frame itself, five heat insulating spaces are provided along the heat transfer direction connected to the indoor and the outdoor. Therefore, heat loss can be reduced.

4 is an enlarged view of a contact portion between a door and a door frame in a system door according to another embodiment. In FIG. 4 and the related description, only the parts that differ from those of the original embodiment are denoted by the same reference numerals, and the numbers and descriptions of the other parts are the same as those of the first embodiment.

Referring to FIG. 4, the door side central heat insulating structure 130 and the frame side central heat insulating structure 120 are distinctively different. The door side heat insulating material 131 is provided with a door side wall 115 extending from the body 135 toward the door side heat insulating material cover 132 and the door side heat insulating material 131 is also provided on the door side heat insulating material cover 132. [ Side partition wall 114 extending toward the rear side.

The door side walls 114 and 115 serve to increase the moment of inertia of the base material and facilitate the manufacturing of the door side heat insulating material 131 and the door side heat insulating material cover 132. In other words, the door side walls 33 and 34 provided long from the door side heat insulating material 131 make it difficult to mold the door side insulating material 131. For example, it is difficult to inject the liquid polyamide badly, And the like. However, it is possible to eliminate the difficulty of injection of defective polyamide and the difficulty in producing a molded block by shortly forming the partition wall from each member.

The above-described barrier structure may be applied to the frame-side central heat insulation structure 120 as well. The frame side wall 113 provided on the body 123 of the frame side heat insulating material 121 and the frame side wall 112 provided on the frame side thermal insulating cover 122 likewise have the effect of increasing the moment of inertia and improving the ease of fabrication Can be obtained.

The body 135 of the door-side heat insulating material 131 is provided at an oblique inclination. In addition, the ribs 137, 138 installed on the body 135 are also inclined obliquely to face upward. By this provision, the sealing performance of the outside air by the end of the rib can be improved.

Further, the body 123 of the frame-side heat insulating material 121 is not provided with separate shielding films 26, 27 and 28 separately, but the inclined portion 111 is provided at an angle as a unit. 127 and 128 are provided at corresponding positions so that the ribs 136, 137 and 138 are contacted to the inclined portion 111. The ribs 136, So that the step and the rib come into contact with each other to completely block the outside air. The inclined portion 111 is provided because it is difficult to clean when the dust, such as dust, is caught in the structure provided with the separate blocking films 26, 27 and 28. That is, when the inclined portion is provided on a relatively slippery surface, the outer surface of the inclined portion can be cleaned only by a few wiping operations. However, in the case of the shielding film, it is difficult to clean the inside of the gap between the shielding films.

The present invention may further include other embodiments in addition to the above-described embodiments. For example, the shielding films 26, 27 and 28 may be provided on the door side insulating material 31 and the ribs 36, 37 and 38 may be provided on the mold side insulating material 21. In this case, the inertia moment of the door side heat insulating material 31 is further increased, and the effect of being able to withstand the bending stress more firmly can be obtained. Of course, it is also possible to guess that the pair of diaphragm and ribs are provided in a stepwise manner so that there is no mutual interference between the rib and the diaphragm when the door is opened. However, the original embodiment can preferably be applied in terms of convenience of manufacture and installation.

According to another embodiment, the heat insulating cover and the heat insulating material may be integrally provided, or the partition may be formed in a different member. However, the original embodiment is preferably presented in terms of ease of manufacture and installation and strength reinforcement.

In yet another embodiment, the contact provided to the rib and the barrier may be provided in three, but not limited to, two or more than three. However, three can be preferably proposed for space securing and manufacturing convenience. Although two of the septa are shown as being provided, one or more septa may be provided.

According to the present invention, it is possible to maximize the heat insulating effect of the door, and to stably use the door by reinforcing the strength. In addition, it is possible to expect the effect that the brigade can be used sufficiently stably on a door to which a large impact load such as a door is applied.

20: Frame-side central insulation structure
30: Central insulation structure on the door side
80: glass member

Claims (10)

A door for supporting the glass member, and a door frame for supporting the door,
Wherein the door includes an inner door frame, an outer door frame, and a door side central insulation structure for connecting the inner door frame and the outer door frame,
The door frame includes an inner frame, an outer frame, and a frame-side central thermal insulation structure connecting the inner frame and the outer door frame,
The door-side central heat insulating structure and the frame-side central heat insulating structure are provided with at least two contact portions spaced apart from each other when the door is closed,
Side central insulated structure and the frame-side central insulated structure, and at least two ribs extending from the other of the door-side center-insulated structure and the frame- . delete The method according to claim 1,
Wherein the at least two contacts are provided at an oblique position. The method according to claim 1,
A gasket provided at a contact portion between the inner door frame and the inner frame; And
And a gasket provided at a contact portion between the outer door frame and the outer frame,
Wherein at least three heat insulating spaces are provided at a contact portion between the door and the door frame. The method according to claim 1,
In the door-side central heat insulating structure,
A door side heat insulation member supported on one side of the inner door frame and the outer door frame; And
And a door side heat insulating cover supported on the other side of the inner door frame and the outer door frame,
Wherein the door side heat insulating material includes at least one partition wall extending to the door side heat insulating cover. The method according to claim 1,
In the frame side central heat insulating structure,
A frame-side heat insulation member supported on one side of the inner frame and the outer frame; And
Side frame and a frame-side heat insulation cover supported on the other side of the outer frame,
Wherein the frame-side heat insulating material includes at least one partition wall extending to the frame-side heat insulating material cover. The method according to any one of claims 1, 3, 4, 5, and 6,
The glass member is provided with three pieces of glass,
A strut member supported on the outer door frame; And a support rubber interposed in contact between the stiffening member and the glass member. 8. The method of claim 7,
Wherein the backing member is provided with a predetermined gap with the door side central heat insulating structure. The method according to claim 1,
At least two ribs extending from any one of the door-side central insulated structure and the frame-side central heat insulation structure, and an inclined portion provided to the other of the door-side central insulation structure and the frame-side central insulation structure. 10. The method of claim 9,
And a step is provided at a portion of the inclined portion where the rib touches.

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