KR101776605B1 - Refrigerator - Google Patents

Abstract

The present invention provides an underground crop harvester. The underground crop harvester includes a main body having a power transmission shaft receiving power from the outside; An upright guide part installed on a lower side of the main body and forcibly guiding and uprighting the order of the underground crop exposed to the ground by being rotated by receiving the power; A cutting part installed at a lower end of the main body so as to be positioned near the upright guide part, rotated by receiving the power, cutting the upright part; And a stem cutting unit installed on both sides of the lower end of the main body and rotated by receiving the power to cut the stem of the underground crop on the ground. Therefore, the present invention can make the crops of underground crops such as onions exposed to the upper part of the ground properly set up, and then cut them so that crops in the ground crops can be easily harvested.

Description

Refrigerator {REFRIGERATOR}

The present invention relates to a refrigerator, in which a hermetically-closed airtight seal between doors of a side-by-side refrigerator and an inner side surface of a door are sealed in multiple ways so that cool air flows out through gaps between doors and through gaps between the hermetically- To provide a refrigerator that can be shut down.

Generally, a refrigerator is a device that functions to store a food such as food in a fresh state isolated from the outside. The refrigerator has a door for opening and closing a space inside the refrigerator to store or take out the stored product.

2. Description of the Related Art Conventionally, a conventional side-by-side refrigerator has a pair of doors hinged to both ends of a main body so as to open and close a space inside a main body. A pillar is provided at a free end of one door of the pair of doors. Here, the pillar is a column serving as an intermediate wall for supporting a pair of door inner parts when the pair of doors are closed.

The pillar is provided inside one of the pair of doors, and the pillar is configured to be rotated when the door is opened or closed. Here, the pillars are operated so as to act as an intermediate wall when the door is closed, extending in parallel with the door.

In addition, conventionally, an elastic gasket having a magnet capable of attaching to one side of the pillar and a part of the inside surface of the pair of doors can be hermetically sealed to the inside of the pair of doors, do.

Therefore, the gasket functions to seal the outside of the door and the internal space of the main body with each other, thereby achieving a cool air blocking effect.

However, in the double-door type refrigerator having the above-described configuration, a certain space forming a large gap is formed between the pair of door inner side walls and the side walls of the pillars. Therefore, even if the cold air is cut between the inner side surface of the door and the one side surface of the pillar by the gasket, the space between both side surfaces of the pillar and the pair of door inner side walls forms a large cap, There is a problem that the cold air leaks through the fine gaps of

Accordingly, in the conventional art, there is a problem that dew is formed on both side surfaces of the pillars forming the large gap and the inner side walls of the pair of doors.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a refrigerator which is capable of sealing a hermetically sealed pillar between doors of a double door type refrigerator and an inner side surface of a door in multiple, And a refrigerator which can effectively block the outflow of cool air in a gap between the doors.

Another object of the present invention is to provide a refrigerator which can prevent dew from being formed on the inner side wall of a door of a door-side type refrigerator and the side wall of a sealing pillar rotatably installed on the door.

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

The refrigerator includes a pair of doors hinged to both ends of a main body having one side opened and having a storage space formed therein and opening and closing the storage space; And a sealing pillar provided at an inner side portion of the pair of doors and connected to the inner side surface of the pair of doors and the inner side surface of the door, A main airtight member having multiple main air chambers and a plurality of sub air holes extending in a predetermined length from the main airtight member and sealing both side surfaces of the pair of door inner side walls and the airtight seal to each other, And a sub-airtight member having a room.

Here, the main airtight member may include a coupling protrusion that is inserted into and engaged with 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 having the plurality of main air chambers, And a magnet attached to a metal provided on one surface of the closed pillar.

Wherein the main air chamber has a first main air chamber whose lower end is connected to an end of the coupling protrusion and the magnet is installed at an upper end thereof and which is formed to be convex on both sides along one surface of the airtight pillar, A lower end of which is connected to an end of the coupling protrusion and an upper end of which is connected to a side of the magnet, and the bendable portion is exposed to a side of the closed post and an inner side wall of the door, .

The sub airtightness member may include an extension member extending a predetermined length from the outer surface of the first gasket of the bent portion of the second main air chamber and an end portion of the extension member, As shown in Fig.

Preferably, the sub air chambers are divided into first sub air chambers and second sub air chambers which are partitioned from each other by wave-shaped partition walls in the second gasket, and the room spaces are different in size.

The second gasket may include a support surface formed to be flat to be in contact with the inner sidewall of the door and a convex portion formed to be convex toward the side surface of the closed pillar, Plane.

In this case, it is preferable that the second sub air room is located adjacent to the extension member side, and the room space of the second sub air room is formed to be larger than the room space of the first sub air room.

It is preferable that a rib extending in a predetermined length is formed to protrude from the side surface of the rotating side of the closed pillar so as to be in close contact with the convex surface of the second gasket.

In addition, a pair of ribs may be formed on both sides of the closed column so as to be in contact with the convex surface of the second gasket.

Here, it is preferable that the ends of the ribs have a predetermined curvature.

The opposite side of the pivoting side of the closed column may be formed with a certain gap with the convex surface of the second gasket.

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

Further, the space between the plurality of extension members may be sealed.

The present invention has the effect of sealing the airtight sealing pillar between the doors of the side-by-side refrigerator and the inner side surface of the door in multiple ways to effectively block the air gap between the doors and the clearance between the closing pillar and the door .

Further, the present invention has the effect of preventing the dew from being formed on the inner side wall of the door of the door-side type refrigerator and the side wall of the closed column rotatably installed on the door.

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

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

Referring to FIGS. 1 and 2, the refrigerator of the present invention has a body 100 in which a storage space 110 is formed and one side thereof is open to the outside.

The main body 100 has a pair of doors 200 including a first door 210 for opening and closing the storage space 110 and a second door 220. The side ends of the pair of doors 200 are hingedly connected to one side end and the other side end of the main body 100, respectively. Accordingly, the pair of doors 200 can be individually opened and closed.

A sealing pillar 300 is rotatably connected to the free end of the first door 210, which is one of the pair of doors 200. The closed column 300 is formed to have a predetermined length along the upper and lower sides of the free end. Although not shown, a torsion spring (not shown) is installed at a portion of the hinge 310 at the free ends of the hermetic column 300 and the first door 210, It can be folded and waited on the inner part of the first door 210. The upper and lower ends of the hinge 310 may be rotatably supported on a part of the upper end of the first door 210.

A support member (not shown) for supporting the sealing pillar 300 so that the sealing pillar 300 can be spread in parallel with the first door 210 is provided at an upper portion of the opening center of the opening of the main body 100 to expose the storage space 110 to the outside Respectively. A guide protrusion (not shown) is formed in the hermetic column 300 and the guide protrusion is inserted in the support member so that the hermetic column 300 can be in parallel with the first door 210 (Not shown) for guiding the guide grooves (see Fig.

2, when the upper end of the hermetic column 300 is close to the support member, the guide protrusion of the hermetic column 300 is positioned at the upper end of the hermetic column 300, The first door 210 can be opened so as to be in parallel with the first door 210 which is guided and guided by the guide groove of the support member. When the second door 220 is closed as shown in FIG. 2, a part of the inner side of the pair of doors 200 in the closed state is brought into contact with one surface of the sealing pillar 300 .

A main airtightness member 400 is installed in a part of the inner side of the pair of doors 200 to seal between the inner surface of the door 200 and one surface of the airtight cylinder 300.

The main airtightness member 200 is provided at a portion inside the pair of doors 200, respectively.

The main airtight member 400 includes an engaging projection 420 that is engaged with and engages with an engaging groove 211 or 212 formed in a part of the inside of the pair of doors 200 and a connecting projection 420 that is connected to an end of the engaging projection 420, A first gasket 410 on which the main air chambers 411 and 412 are formed and a magnet 430 provided on the first gasket 410 and attached to the metal 330 installed on one surface of the sealing pillar 300, . Here, the first gasket 410 may be made of an elastic material.

The main air chambers 411 and 412 are connected to the ends of the coupling protrusions 420 at the lower ends thereof and the magnets 430 are installed at the upper ends of the main air chambers 411 and 412, The lower end of the air chamber 411 is connected to the end of the coupling protrusion 430 and the upper end of the air chamber 411 is connected to the side of the magnet 430, And a second main air chamber 412 in which the bent portions are exposed to the side surfaces of the closed pillar 300 and the inner side walls of the doors 200, respectively.

The first main air chamber 411 is formed to be convex on both sides along the inner side of the door 200 so that the door 200 is closed between the inner side of the door 200 and one side of the sealing pillar 300 The impact due to the formed closing can be dispersed and absorbed on both sides.

The second main air chamber 412 formed at the side of the first main air chamber 411 is bent substantially to seal the space between the side of the sealing pillar 300 and the inner side wall of the door 200 .

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

The sub airtightness member 500 is extended from the main airtightness member 400 by a predetermined length so that the inner side walls of the pair of doors 200 and the both sides of the airtight pillar 300 are sealed to each other, (511, 512).

The sub airtightness member 500 is made of an elastic material and extends from the outer surface of the first gasket 410 of the bend portion of the second main air chamber 412 to an extension member 520 And a second gasket 510 connected to an end of the extension member 520 and having the multiple sub air chambers 511 and 512 formed therein.

Here, the sub air chambers 511 and 512 are partitioned from each other by the wavy-patterned partition walls 513 in the second gasket 510, and the first sub air chambers 511 and 511, And a second sub air room 512.

The second gasket 510 includes a support surface 510a formed to be flat to be in contact with the inner sidewall of the door 200 and a plurality of sub air chambers 511 and 512 connected to the support surface 510a. And a convex surface 510b formed to be convex toward a side surface of the hermetic column 300 to form a convex surface.

The second sub air room 512 is positioned adjacent to the extension member 520 and the room space of the second sub air room 512 is located adjacent to the room space 511 of the first sub air room 511, It is preferable that a larger space is formed.

When the pair of doors 200 are closed, the supporting surface 510a of the second gasket 510 is in close contact with the inner side wall of the door 200, and the supporting surfaces 510a, The convex surface 510b to be connected is formed so as to be convex toward the side surface of the hermetic column 300. Here, it is preferable that the convex surface 510b is substantially in contact with the side surface of the sealing column 300. [

In the second gasket 510, a convex surface 510b on which the second sub air chamber 512 having a larger space than the first sub air chamber 511 is located is formed on the upper surface of the sealing pillar 300 It is preferable that it can be brought into close contact with the side surface. Since the space of the second sub air chamber 512 is formed to be larger than the space of the first sub air room 511, Since the side portion of the second sub air chamber 512 is convexly protruded into the space where the first gasket 410 is located, the space in which the first gasket 410 is positioned and the space The airtightness between the internal storage spaces 110 of the internal combustion engine 100 can be efficiently maintained.

The first gasket 410 and the second gasket 510 are connected to each other by the extension member 520. Since the extension member 520 is made of a resilient material in a state where the extension member 520 is provided as a single unit, the setting position of the second gasket 510 can be varied within the extension length of the extension member 520.

2, when the pair of doors 200 are closed, the second gasket 510 is in close contact with the inner side wall of the door 200 and the side surface of the sealing pillar 300, It is possible to secure the fluidity of the fluid. 1, when the pair of doors 200 are opened, the second gasket 510 is in close contact with the inner side wall of the door 200 and the side surface of the sealing post 300 The elastic member 520 can be stably released in a state in which elasticity is applied through the extension member 520 without being forcedly released.

Also, as shown in FIG. 4, the present invention may have a plurality of extension members 521. This allows the second gasket 520 to be separated from the end of the extension member 521 due to the flow of the second gasket 520 while the first gasket 410 and the second gasket 510 are elastically connected to each other So that the phenomenon of separation can be prevented in advance. That is, the fixing force between the first gasket 410 and the second gasket 510 can be increased as the fixed portion required for connection is increased through the plurality of extension members 520.

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.

The spaces S between the plurality of extension members 522 may be sealed. The extension members 522 constituting the multiple spaces S may be formed in such a manner that the space S between the extension members 522 and the extension members 522 of the door 200 The space between the inner sidewall and the side surface of the sealing column 300 can be multiple hermetically sealed, and the space between the inner side wall and the sealing pillar 300 can be insulated from the outside. Accordingly, it is possible to effectively prevent the phenomenon of dew formation caused by the temperature difference between the side surface of the closed column 300 and the outside air.

2, since the convex surface 510b of the second gasket 510 mentioned above forms a certain curvature, the convex surface 510b of the side surface of the sealing column 300, which can achieve a predetermined shape, And can be efficiently brought into close contact with the shape.

A partition wall 513 for partitioning the first and second sub air chambers 511 and 512 of the second gasket 510 is formed in a wavy pattern connecting the convex surface 510b and the support surface 510a, Since the pressing member 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 post 300 acts, the shape is easily deformed according to the magnitude of the pressing force, Can be absorbed. Accordingly, the wavy barriers 513 can effectively prevent breakage such as tearing of the second gasket 510 due to repetitive pressing force.

The sub airtightness member 500 is formed to be connected to the main airtightness member 400 installed on a part of the inner side of each door 200 and is preferably connected to the door 200 The sub airtightness member 500 provided on the side of the sealing pillar 300 is preferably provided so that the convex surface 510b of the second gasket 510 is in close contact with the side surface of the sealing pillar 300, The sub airtightness member 400 provided on the side of the door 220 may have a predetermined gap with the other side surface of the sealing pillar 300 such that the convex surface 510b of the second gasket 510 is positioned.

In other words, the above-mentioned closed pillar 300 may be rotatable on the free end of the first door 210, but may be rotated through a single fixed rotation axis (not shown) So that the center of rotation can flow from the free end of the free end. Therefore, the second gasket 510 of the sub airtightness member 300 may be formed on the side surface of the sealing column 300 and the side surface of the second door 210 in consideration of the gap that flows between the sealing column 300 and the free ends of the first door 210. [ 1 door 210. In addition,

Referring to FIG. 2, a rib 320 may be formed on one side of the hermetic column 300 to protrude to the outside.

The rib 320 may be formed in the second gasket 500 of the sub airtightness member 500 protruding from one side of the airtight cylinder 300 and installed at the inner side of the first door 210 where the airtight cylinder 300 is installed. 510) convex surface 510b. Accordingly, the rib 320 functions as an auxiliary hermetic seal between the second gasket 510 and the side surface of the sealing pillar 300, and thereby, the gap between the first door 210 and the sealing pillar 300 It is possible to prevent the outside air from flowing into the inside of the main body 100 through the space and to prevent the outside air from flowing into the inside of the main body 100, And the like can be solved.

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 closed column 300, It can be.

Accordingly, each of the second gasket 510, which hermetically seals the both side surfaces of the hermetically-sealed column 300 and the inner side wall of the door 200, can additionally block the cold air through the pair of ribs 320 and 321.

The pair of ribs 320 and 321 may be made of the same material as that of the sealing pillar 300 or may be made of a solid material having no elasticity and the pair of ribs 320 and 321 may include a second door Only the ribs 321 on the side of the elastic member 220 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 on which the closing pillar 300 is not installed is moved along the side surface of the closing pillar 300 when the second door 220 is opened or closed At this time, the rib 321 made of an elastic material may solve the problem of being broken due to friction with the second gasket 510, and the like.

The ends of the ribs 320 and 321 are preferably formed to have a constant curvature.

As shown in FIG. 2, the opposite side of the pivotal side of the sealing column 300, that is, the side of the second door 220, has a predetermined gap with the convex surface 510b of the second gasket 510 .

That is, since the first door 210 of the pair of doors 200 is arranged to rotate the closing column 300 and the second door 220 is not provided with the closing column 300, When the door 220 is opened or closed, the second gasket 510 installed inside the second door 220 may always have a constant frictional force with the side surface of the sealing column 300, Therefore, it is also preferable to set a constant gap.

Since the convex surface 510b of the second gasket 510 is convex when the outer surface of the second gasket 510 is in close contact with the side surface of the hermetic column 300, The frictional force generated between the side surface of the sealing pillar 300 and the outer surface of the second gasket 510 can be minimized even if the sealing member 510 closely contacts the side surface of the close pillar 300.

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

Claims (10)

A pair of doors hinged to both ends of a main body having a storage space to open and close the storage space, and having coupling grooves on respective inner surfaces thereof;
A sealing pillar coupled to any one of the doors and rotatable, the sealing pillar being located between the doors when the storage space is closed; And
And a hermetic member which is inserted into and fixed to the coupling groove and closely attached to the door, and hermetically seals the space between the hermetic column and the door,
The gas-
A main airtight member provided on one side of an inner side of each of the doors and having a first gasket for forming a plurality of main air chambers, the main airtight member being in contact with a front portion of the airtight post and sealing the space between the airtight post and each of the doors;
And a second gasket which forms a plurality of sub air chambers protruding toward the side surface of the closed column, wherein the sub airtightness member hermetically seals between the other inner side of the respective doors and the side surface of the closed column; And
And an extension member connecting the main airtight member and the sub airtight member,
Wherein the sealing pillar is in contact with the first gasket and the second gasket, respectively, to block the outflow of cool air from the storage space. The method according to claim 1,
The main gas-
And a magnet attached to the metal provided on one side of the sealing pillar, the magnet being attached to the first gasket, wherein the engaging protrusion is engaged with an engaging groove formed in an inner portion of the pair of doors,
Wherein the first gasket is connected to an end of the engaging projection to form the plurality of main air chambers,
Wherein the main air chamber has a first main air chamber whose lower end is connected to an end of the coupling protrusion and the magnet is installed at an upper end thereof and which is formed to be convex on both sides along one surface of the airtight pillar, A lower end of which is connected to an end of the coupling protrusion and an upper end of which is connected to a side of the magnet, and the bendable portion is exposed to a side of the closed post and an inner side wall of the door, The refrigerator comprising: 3. The method of claim 2,
Wherein the extension member is made of a material having an elastic force and extends a certain length from the bending portion of the second main air chamber,
Wherein the sub air room comprises a first sub air chamber and a second sub air chamber which are partitioned from each other by a wavy-patterned partition wall in the second gasket and have different sizes of room spaces. The method of claim 3,
The second gasket
And a convex surface connected to the support surface and formed to be convex toward a side surface of the closed pillar to form the multiple sub air chambers,
The second sub air chamber is located adjacent to the extension member side,
Wherein a room space of the second sub air room is formed to be larger than a room space of the first sub air room. The method of claim 3,
On both sides of the closed column,
And a rib extending in a predetermined length to protrude from the convex surface of the second gasket. The method of claim 3,
A pair of ribs protruding from both sides of the sealing column to extend to a predetermined length so as to be in close contact with the convex surface of the second gasket, and the rib is made of an elastic material to reduce interference due to friction with the second gasket Features a refrigerator. The method according to claim 5 or 6,
Wherein an end of the rib is formed with a predetermined curvature. delete The method of claim 3,
Wherein the extension member is composed of a plurality of the extension members. 10. The method of claim 9,
And the spaces between the plurality of extension members are sealed.

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