KR20120048426A - Refrigerator - Google Patents

Abstract

PURPOSE: A refrigerator is provided to efficiently cut off cold air leakage at the gaps between doors and between the doors and a sealing post by sealing the sealing post and the inner surfaces of the doors. CONSTITUTION: A refrigerator comprises a pair of doors(200), a sealing post(300), a main sealing member(400), and a sub sealing member(500). The doors are hinged on both ends of a main body and open and close storage spaces. The sealing post is movably connected to the free end of the one of the doors. The main sealing member seals the inner surface of the doors and one surface of the sealing post and has a main air room. The sub sealing member is extended from the main sealing member and seals the inner side walls of the doors and both surfaces of the sealing post.

Description

Refrigerator {REFRIGERATOR}

The present invention relates to a refrigerator, wherein the airtight pillars and the inner side of the door are hermetically sealed between the doors of the double door refrigerator, and the cold air flows out through the gaps between the doors and the gap between the doors and the door. It is to provide a refrigerator that can be blocked.

In general, a refrigerator is a device that functions to keep fresh items such as foods from the outside and keep them fresh. In addition, the refrigerator includes a door that opens and closes a space inside the refrigerator to store or remove the stored matter.

In general, a conventional double door refrigerator includes a pair of doors hinged to both ends of the main body so as to open and close the internal space of the main body. A pillar that is rotated is installed at a free end of the door on one side of the pair of doors. Here, the pillar is a pillar that serves as an intermediate wall that supports the inner portion of the pair of doors when the pair of doors are closed.

In addition, the pillar is installed inside any one of the pair of doors, and the pillar is configured to rotate when the door is opened or closed. Here, when the door is closed, the pillar is operated to be parallel to the door to serve as an intermediate wall.

In addition, conventionally, an elastic gasket having a magnet that can seal one surface of the pillar and a portion of the inner side of the pair of doors to each other and be attached to a metal installed on the pillar is installed on the inner portion of the pair of doors. do.

Therefore, the gasket serves to seal the outside of the door and the internal space of the main body to achieve a cold air blocking effect.

However, in the double door refrigerator having the above-described configuration, a predetermined space forming a large gap is formed between the pair of door inner side walls and the side walls of the pillar. Therefore, even if cold air is blocked between the inner part of the door and one side of the pillar by the gasket, the space between the both sides of the pillar and the pair of inner side walls of the pillar forms a large cap, and thus, between the magnet and one side of the pillar. There is a problem that cold air leaks through the minute gaps.

Accordingly, in the related art, a problem arises in which dew forms on both side surfaces of the pillar forming a large gap as described above and the inner side walls of the pair of doors.

The present invention has been made to solve the above problems, and an object of the present invention is to seal a plurality of airtight pillars and the inner side of the door airtight between the doors of the double-door refrigerator, the gap between the doors and the closed column and An object of the present invention is to provide a refrigerator capable of efficiently blocking cold air leakage from a gap between doors.

Another object of the present invention is to provide a refrigerator which can prevent dew from forming on the inner sidewall of the door and the sidewall of the sealed pillar rotatably installed on the door in the door of the double-door refrigerator.

In a preferred embodiment, the present invention provides a refrigerator.

The refrigerator may be hinged to both ends of a main body in which one side is opened and a storage space is formed, and a pair of doors for opening and closing the storage space and a free end of any one of the pair of doors may be rotatable along the top and bottom. A sealing pillar connected to the inner partial surface of the pair of doors and installed in the inner portion of the pair of doors and facing the inner partial surface of the pair of doors and toward the inner partial surface of the door. One side of the airtight one another, and the main airtight member having a plurality of main air room and a certain length extending from the main airtight member, the pair of the inner side wall of the door and the both sides of the sealed column is airtight with each other, multiple sub air And a sub hermetic member having a room.

Here, the main airtight member may include a coupling protrusion coupled to a coupling groove formed in an inner portion of the pair of doors, a first gasket connected to an end of the coupling protrusion and formed of the plurality of main air rooms, and the gasket. It is provided in, and provided with a magnet attached to the metal installed on one surface of the sealed pillar.

The main air room has a first main air room having a lower end connected to an end of the coupling protrusion, a magnet installed at an upper end thereof, and convexly formed at both sides along one surface of the sealed pillar, and a side portion of the first main air room. A second main air room which is bent to enclose a lower end connected to an end of the coupling protrusion and an upper end connected to a side of the magnet, and the bending part is exposed to a side surface of the sealing pillar and an inner side wall of the door. It is good to have.

The sub hermetic member may include an extension member extending a predetermined length from an outer surface of the first gasket of the bent portion of the second main air room, and an end of the extension member, wherein the plurality of sub air rooms are formed. A second gasket is provided.

Here, it is preferable that the sub air rooms are partitioned from each other by a wave-shaped partition wall inside the second gasket, and have a first sub air room and a second sub air room having different sizes of room spaces.

The second gasket may include a support surface that is formed to be in close contact with the inner sidewall of the door, and a convex that is convexly formed toward the side of the sealed column to be connected to the support surface to form the multiple sub air rooms. It is preferable that it consists of cotton.

In this case, the second sub-airroom is located adjacent to the extension member side, the room space of the second sub-air room is preferably formed larger than the room space of the first sub-air room.

On the other hand, it is preferable that ribs extending a predetermined length to protrude from the side of the rotational side of the sealed pillar to be in close contact with the convex surface of the second gasket.

In addition, a pair of ribs extending to a predetermined length may protrude from both sides of the sealing pillar to be in close contact with the convex surface of the second gasket.

Here, the end of the rib is preferably formed to have a predetermined curvature.

In addition, a gap between the convex surface of the second gasket and a predetermined gap may be formed on the opposite side of the rotating side of the sealed pillar.

On the other hand, the extension member may be made of a plurality.

In addition, the spaces between the plurality of extension members may be closed.

The present invention has the effect of effectively blocking the leakage of cold air in the gap between the doors and the gap between the door and the sealed pillar and the door by sealing multiple airtight pillars and the inner surface of the door between the doors of the double door refrigerator. .

In addition, the present invention has the effect that can be prevented from forming dew on the inner side wall of the door and the side wall of the closed pillar rotatably installed on the door in the door of the double-door refrigerator.

1 is a cross-sectional view showing a state in which a door is opened in the refrigerator of the present invention.
2 is a cross-sectional view showing a state in which the door is closed in the refrigerator of the present invention.
3 is a cross-sectional view showing doors in which another example of a sealed column according to the present invention is installed.
4 is a sectional view showing a door to which another example of the sub hermetic member according to the present invention is applied.
5 is a sectional view showing a door to which another example of the sub hermetic member according to the present invention is applied.

Hereinafter, with reference to the accompanying drawings, it will be described the refrigerator and its operation of the present invention.

1 and 2, the refrigerator of the present invention has a storage space 110 formed therein, and has a main body 100 having one side open to the outside.

The main body 100 has a pair of doors 200 formed of a first door 210 and a second door 220 that open and close the storage space 110. Side ends of each of the pair of doors 200 are hinged so as to be rotated at one end and the other end of the main body 100. Therefore, the pair of doors 200 can be opened and closed individually.

The free end of the first door 210, which is one of the pair of doors 200, is connected to the sealing pillar 300 to be rotatable. The closed pillar 300 is formed to have a predetermined length along the top and bottom of the free end. Although not shown in the figure, a torsion spring (not shown) is installed at a portion of the hinge 310 at the free end of the sealed pillar 300 and the first door 210, and thus the sealed pillar 300 is The inner part of the first door 210 may be folded and waited. Here, the upper and lower ends of the hinge 310 may be rotatably supported by a portion of the upper end of the first door 210.

In addition, a support member (not shown) for supporting the sealing pillar 300 to be unfolded in parallel with the first door 210 is disposed at an upper end of the opening central portion exposing the storage space 110 of the main body 100 to the outside. Is installed. Here, a guide protrusion (not shown) is formed on the sealed pillar 300, and the guide protrusion is inserted into the support member so that the sealed pillar 300 may be in parallel with the first door 210 (unfolded). 2, a guide groove (not shown) for guiding may be formed.

Therefore, when the first door 210 to which the sealed pillar 300 is connected is closed as shown in FIG. 2, the guide protrusion of the sealed pillar 300 is closer to the support member while the upper end of the sealed pillar 300 is close to the support member. The guide member is inserted into the guide groove of the support member, and may be unfolded so as to be in parallel with the first door 210 which is closed. In this state, when the second door 220, which is the other one, is closed as shown in FIG. 2, some inner surfaces of the pair of doors 200 in the closed state may contact one surface of the sealed pillar 300. It is in a state.

In the inner portion of the pair of doors 200 as described above, a main airtight member 400 is installed to seal between the inner side surface of the door 200 and one surface of the sealing pillar 300.

The main hermetic member 200 is provided at an inner portion of the pair of doors 200, respectively.

The main airtight member 400 is coupled to the coupling protrusions 420 inserted into and coupled to the coupling grooves 211 and 212 formed in the inner portion of the pair of doors 200, and connected to the ends of the coupling protrusions 420. The first gasket 410 in which the main air rooms 411 and 412 are formed, and the magnet 430 provided in the first gasket 410 and attached to the metal 330 installed on one surface of the sealing pillar 300. It consists of. Here, the first gasket 410 is preferably made of an elastic material.

The main air rooms 411 and 412 are connected to end portions of the coupling protrusions 420, and the magnets 430 are installed on the upper ends of the main air rooms 411 and 412, and are convexly formed at both sides along one surface of the sealing pillar 300. It is bent to surround the air room 411 and the side of the first main air room 411, the lower end is connected to the end of the coupling protrusion 430, the upper end is connected to the side of the magnet 430, The bent portion includes a second main air room 412 exposed to the side surface of the sealed pillar 300 and the inner sidewall of each of the doors 200.

Here, the first main air room 411 is formed convexly on both sides along the inside of the door 200 so that when the door 200 is closed, between the inner surface of the door 200 and one surface of the sealed pillar 300. The shock due to the closing formed can be dispersed and absorbed on both sides.

In addition, the second main air room 412 formed at the side of the first main air room 411 may be bent to substantially seal the space between the side of the sealed pillar 300 and the inner sidewall of the door 200. Is formed.

In addition, the main hermetic member 400 is connected to the sub hermetic member 500.

The sub hermetic member 500 extends a predetermined length from the main hermetic member 400 and hermetically seals the inner sidewalls of the pair of doors 200 and both side surfaces of the sealing pillar 300, and multiple sub air rooms. (511,512).

In detail, the sub hermetic member 500 is made of an elastic material, and the extension member 520 extending from the outer surface of the first gasket 410 of the bent portion of the second main air room 412 by a predetermined length. And a second gasket 510 connected to an end of the extension member 520 and in which the plurality of sub air rooms 511 and 512 are formed.

Here, the sub air rooms 511 and 512 are partitioned from each other by the wave pattern partition wall 513 inside the second gasket 510, and the first sub air room 511 having different sizes of room spaces. The second sub air room 512 is formed.

The second gasket 510 is connected to the support surface 510a and is formed to be flat to be in close contact with the inner sidewall of the door 200 and the plurality of sub air rooms 511 and 512. Convex surface 510b is formed to be convex toward the side of the sealed pillar 300 to form a.

Here, the second sub air room 512 is located adjacent to the extension member 520 side, the room space of the second sub air room 512 is a room space of the first sub air room 511. It is better to have a certain space larger than.

Referring to the above configuration, when the pair of doors 200 are closed, the second gasket 510 has a support surface 510a in close contact with the inner sidewall of the door 200 and the support surface 510a. The convex surface 510b to be connected is formed to be convex toward the side of the sealing pillar 300. Here, the convex surface 510b is preferably in close contact with the side of the sealed pillar (300).

In the second gasket 510, a convex surface 510b in which the second sub air room 512 is formed, the space of which is larger than the first sub air room 511, is formed in the sealing pillar 300. It can be in close contact with the sides. Here, since the size of the space of the second sub-airroom 512 is larger than the space of the first sub-airroom 511, the door is formed between the side of the sealed pillar 300 and the inner sidewall of the door 200. Since the shock due to the closing is absorbed and the side portion of the second sub air room 512 protrudes convexly into the space where the first gasket 410 is located, the space and the main body (where the first gasket 410 is located) The airtight between the internal storage spaces 110 of 100 may be efficiently maintained.

In addition, the first gasket 410 and the second gasket 510 are connected to each other by an extension member 520. Here, since the extension member 520 is made of an elastic material in a state provided as one, the setting position of the second gasket 510 may be variable in position within the extension length of the extension member 520.

That is, as shown in FIG. 2, when the pair of doors 200 are closed, the second gasket 510 is closely contacted between the inner sidewall of the door 200 and the side surface of the sealing pillar 300. The liquidity of can be secured. In addition, referring to FIG. 1, when the pair of doors 200 are opened, the second gasket 510 is in close contact between the inner sidewall of the door 200 and the side surface of the sealing pillar 300. In the state it is not forcibly detached through the extension member 520 can be stably separated in a state where a certain elasticity is applied.

In addition, as shown in FIG. 4, the present invention may be provided with a plurality of extension members 521. This causes the first gasket 410 and the second gasket 510 to be elastically connected to each other by a predetermined level or more, and the second gasket 520 is separated from the end of the extension member 521 due to the flow of the second gasket 520. The separation phenomenon can be prevented in advance. That is, the first gasket 410 and the second gasket 510 may increase the fixing force between each other as the fixing portion required for connection through the plurality of extension members 520 is increased.

In addition, as shown in FIG. 5, the present invention may include a plurality of extension members 522, and the spaces S between the extension members 522 may form a closed space.

Spaces S between the plurality of extension members 522 may be closed. Therefore, when a plurality of spaces S are provided so that air is filled between the extension members 522, the extension members 522 constituting the plurality of spaces S may be formed in the door 200. The space between the inner side wall and the side surface of the sealed pillar 300 may be multi-sealed, and may also serve to insulate multiple spaces from the outside. Thus, the phenomenon of dew condensation caused by the temperature difference with the outside air on the side of the sealed pillar 300 can be effectively prevented.

On the other hand, as shown in FIG. 2, since the convex surface 510b of the second gasket 510 mentioned above forms a constant curvature, the side surface of the closed pillar 300 which can achieve a predetermined shape Corresponding to the shape can be in close contact efficiently.

The partition wall 513 partitioning the first and second sub air rooms 511 and 512 of the second gasket 510 is formed in a wave pattern connecting the convex surface 510b and the support surface 510a, and the partition wall Since the 513 is formed along the direction in which the pressing force generated between the inner sidewall of the door 200 and the side surface of the sealing pillar 300 is applied, the shape is easily deformed according to the magnitude of the pressing force to facilitate the pressing force. It can absorb. Accordingly, the wave pattern partition 513 can effectively prevent damage such as the second gasket 510 is torn by the pressing force is repeatedly applied.

Of course, the sub hermetic member 500 mentioned above is formed to be connected to the main hermetic member 400 installed in the inner part of each door 200, and preferably, the door 200 to which the sealing pillar 300 is connected. Sub airtight member 500 is installed on the side) is preferably installed so that the convex surface (510b) of the second gasket 510 is in close contact with the side of the sealing pillar 300, the agent is not installed In the sub hermetic member 400 installed on the two door 220 side, the convex surface 510b of the second gasket 510 may form a predetermined gap with the other side of the sealing pillar 300.

That is, the above-mentioned closed pillar 300 may be rotated at the free end of the first door 210, but may be rotated through one fixed rotating shaft (not shown), but the first door 210 may be rotated. It may be installed so that the rotation center from the free end of the flow. Accordingly, the second gasket 510 of the sub hermetic member 300 may be formed on the side surface of the sealing pillar 300 and the first gap in consideration of a gap flowing between the sealing pillar 300 and the free end of the first door 210. It may be disposed in close contact with the inner side wall of the one door (210).

Meanwhile, referring to FIG. 2, a rib 320 protruding a predetermined length to the outside may be further formed on one side of the sealing pillar 300.

The rib 320 protrudes from one side of the sealing pillar 300 and a second gasket of the sub hermetic member 500 installed at an end thereof in the first door 210 in which the sealing pillar 300 is installed. It may be in close contact with the convex surface 510b. Thus, the rib 320 serves as an auxiliary airtight role between the side of the second gasket 510 and the sealing pillar 300, and thus, between the first door 210 and the sealing pillar 300. Cold air inside the main body may be leaked to the outside through the space, or external air may be additionally prevented from flowing into the main body 100, and dew may be provided on the inner sidewall of the first door 210 and the side surface of the sealing member 300. This can solve problems such as condensation.

In addition, as shown in FIG. 3, a pair of ribs 320 and 321 extending to a predetermined length so as to be in close contact with the convex surface 510b of the second gasket 510 are formed on both sides of the sealing pillar 300. It can also be.

Accordingly, each of the second gaskets 510 that seals both side surfaces of the sealed pillar 300 and the inner sidewall of the door 200 may additionally block the cold air through the pair of ribs 320 and 321.

Here, the pair of ribs 320 and 321 may be made of the same material as that of the sealing pillar 300, that is, a solid having no elasticity, and a second door in which the sealing pillar 300 is not installed among the pair of ribs 320 and 321. Only the side ribs 321 may be made of an elastic material.

That is, in the latter case, the second gasket 510 on the side of the second door 220 without the sealing pillar 300 installed along the side of the sealing pillar 300 when the second door 220 is opened or closed. In this case, the rib 321 of the elastic material may solve the problem of being damaged by friction with the second gasket 510.

In addition, end portions of the ribs 320 and 321 may be formed to have a predetermined curvature.

In addition, the opposite side of the rotating side of the closed pillar 300, that is, the second door 220 side, as shown in Figure 2, the gap between the convex surface (510b) of the second gasket 510 is constant It may be formed.

That is, the first door 210 of the pair of doors 200 is disposed so that the sealing pillar 300 is rotated, and the second door 220 is the second pillar 220 because the sealing pillar 300 is not installed. When the door 220 is opened or closed, the second gasket 510 installed inside the second door 220 may have a problem in that it always forms a predetermined frictional force with the side of the sealed pillar 300 and flows. Therefore, it is also desirable to leave a constant gap.

When the outer surface of the second gasket 510 is in close contact with the side surface of the sealed pillar 300 and flows, the convex surface 510b of the second gasket 510 is convex, so that the second gasket is convex. Although 510 is in close contact with the side of the close contact pillar 300, the friction force generated between the side of the closed pillar 300 and the outer surface of the second gasket 510 can be reduced to a minimum.

100: body 110: storage space
200: door 210: first door
211,212: coupling groove 220: second door
300: sealed pillar 310: hinge
320: rib 330: metal
400: main airtight member 410: first gasket
411: First main air room 412: Second main air room
420: engaging projection 430: magnet
500: sub hermetic member 510: second gasket
510a: support surface 520a: convex surface
511: First sub air room 512: Second sub air room
513: partition 520: extension member

Claims (10)

A pair of doors hinged at both ends of a body having one side opened and a storage space formed therein, the door opening and closing the storage space;
A sealing column connected to one of the free ends of the pair of doors so as to be rotatable along the top and bottom, and contacting an inner side surface of the pair of doors;
A main hermetic member installed on a portion of the inner side of the pair of doors, the inner side surface of the pair of doors and one surface of the sealed column facing the inner side surface of the door to each other and having a plurality of main air rooms; And
And a sub hermetic member extending from the main hermetic member for a predetermined length and hermetically sealing the inner sidewalls of the pair of doors and both sides of the hermetic pillar and having a plurality of sub air rooms. The method of claim 1,
The main hermetic member,
A coupling protrusion coupled to a coupling groove formed in a portion of the inner side of the pair of doors, a first gasket connected to an end of the coupling protrusion and formed with the plurality of main air rooms, and provided in the gasket, With a magnet attached to the metal installed on one side,
The main air room has a first main air room having a lower end connected to an end of the coupling protrusion, a magnet installed at an upper end thereof, and convexly formed at both sides along one surface of the sealed pillar, and a side portion of the first main air room. A second main air room which is bent to enclose a lower end connected to an end of the coupling protrusion and an upper end connected to a side of the magnet, and the bending part is exposed to a side surface of the sealing pillar and an inner side wall of the door. Refrigerator comprising a. The method of claim 2,
The sub hermetic member,
An extension member extending a predetermined length from an outer surface of the first gasket of the bent portion of the second main air room, and a second gasket connected to an end of the extension member, wherein the multiple sub air rooms are formed;
The sub air room is partitioned with each other by a wavy pattern partition inside the second gasket, the refrigerator comprising a first sub air room and a second sub air room having different sizes of room spaces. The method of claim 3, wherein
The second gasket,
A support surface which is formed to be in close contact with the inner sidewall of the door, and a convex surface which is connected to the support surface and is convexly formed toward the side of the sealed column to form the multiple sub air rooms,
The second sub-airroom is located adjacent to the extension member side,
And a room space of the second sub air room is larger than a room space of the first sub air room. The method of claim 3, wherein
On the side surface of the rotating side of the said sealed pillar,
The refrigerator of claim 2, wherein a rib extending a predetermined length to be in close contact with the convex surface of the second gasket protrudes. The method of claim 3, wherein
Refrigerator, characterized in that a pair of ribs extending to a predetermined length to be in close contact with the convex surface of the second gasket on both sides of the sealed pillar. The method according to claim 5 or 6,
Refrigerator, characterized in that the end of the rib is made of a predetermined curvature. The method of claim 3, wherein
The opposite side of the rotating side of the said sealed pillar,
And a convex surface of the second gasket and a predetermined gap are formed. The method of claim 3, wherein
The extension member is a refrigerator, characterized in that a plurality. The method of claim 9,
And a space between the plurality of extension members is sealed.

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