KR100606728B1 - Degassing Apparatus of Container in Refrigerator - Google Patents

Abstract

The present invention relates to a degassing apparatus of a storage container for a refrigerator capable of automatically degassing part of the air inside the storage container. The present invention is accommodated in the inner space of the main body, and a storage container for storing food products; When the storage container is accommodated in the inner space, provides a degassing apparatus of the refrigerator storage container comprising a degassing means for automatically degassing a part of the air inside the storage container.

Refrigerator, Storage Container, Deaerator

Description

Degassing Apparatus of Container in Refrigerator

1 is a partial cross-sectional view of a refrigerator in which a conventional storage container is installed.

Figure 2a is a partial cross-sectional view of the refrigerator installed one embodiment of a storage container degassing apparatus according to the present invention.

Figure 2b is a partial cross-sectional view of the refrigerator showing a state in which the degassing device of Figure 2a is operated.

3 is an enlarged view of a portion “A” of FIG. 2B;

Figure 4a is a partial cross-sectional view of the refrigerator installed another embodiment of a storage container degassing apparatus according to the present invention.

Figure 4b is a partial cross-sectional view of the refrigerator showing a state in which the degasser of Figure 4a is operated.

FIG. 5 is a sectional view taken along line II of FIG. 4B; FIG.

<Description of the symbols for the main parts of the drawings>

30: storage container 40: main body wall

50: protrusion 60: degassing part

61: suction part 64: suction part support member

65: discharge portion 68: discharge portion support member

71: cylinder 72: suction hole

73: piston 74: packing member

75: connecting member

The present invention relates to a refrigerator, and more particularly, to a degassing apparatus of a refrigerator storage container.

In general, a refrigerator is a device for keeping a food compartment at a low temperature for storing foodstuffs, and comprises a refrigerator compartment for storing the foodstuff at a temperature of about 3 ° C to 4 ° C and a freezer compartment for storing the foodstuff at a subzero temperature. The principle of the refrigerator is briefly described as follows.

The refrigerant used in the refrigerator is compressed to high temperature and high pressure in a compressor and sent to the condenser along the refrigerant pipe. After that, the refrigerant is liquefied in the condenser, and is moved to the expansion valve along the refrigerant pipe and then the low temperature and low pressure state by the expansion valve. Then, the refrigerant moved to the evaporator along the refrigerant tube is vaporized to instantly take away the heat of the surroundings. As a result, the temperature inside the refrigerator body is lowered, so that foods and the like can be stored at a low temperature.

On the other hand, in the refrigerator compartment of the refrigerator is formed an internal space for storing a storage container for storing fruits or vegetables in a fresh state. Vegetables and fruits inside the storage container is freshly stored by the cold air in the refrigerating chamber. However, in order to store the fruits or vegetables fresher and longer, the temperature, humidity, air content, etc. in the storage container should be properly maintained.

Referring to Figure 1, the storage container of the conventional refrigerator will be described as follows.

The conventional refrigerator comprises a main body 1 having a constant internal space and a storage container 3 accommodated in the internal space.

The main body 1 includes a refrigerating chamber 1a capable of refrigerating food and a main body inner wall 6 forming an inner space at a lower end of the refrigerating chamber. In addition, a storage container 3 is accommodated in the inner space, and the shape of the inner space corresponds to the storage container 3 and is surrounded by a heat insulating material. And, one side of the main body inner wall (6) is provided with a guide (5) to be accommodated in the correct position when the storage container (3) is accommodated, to facilitate the insertion of the storage container (3). In general, the guide 5 is installed to be located in the middle of the storage container 3, the guide 5 is formed with a guide groove (5a) corresponding to the projection (3a) formed in the storage container. Of course, a predetermined groove is formed in the storage container, and a protrusion corresponding to the groove may be formed in the guide.

The storage container 3 is generally made of a plastic material and is used when storing vegetables or fruits in a refrigerator. The storage container 3 is installed at the lower end of the refrigerator and accommodated in an inner space formed on the inner wall 6 of the refrigerator main body. As described above, the shape of the storage container corresponds to the internal space, and the side surface of the storage container has a predetermined projection 3a corresponding to the guide groove 5a formed in the guide.

In addition, the upper end of the inner space is provided with a humidity control device 4 for controlling the humidity in the storage container (3). The humidity control device 4 is a device that absorbs the moisture in the storage compartment when the humidity inside the storage container is high, and releases the moisture when the humidity inside the storage container 3 is low. The humidity control device 4 is configured to include a humidity control member (not shown) containing a cellulose-based porous material or a saturated salt solution.

The cellulose-based porous material is composed of many cells in the form of a sponge and has a property of absorbing moisture when the surrounding humidity is high and increasing its volume, and reducing the volume by releasing moisture when the surrounding humidity is low. The saturated salt solution absorbs moisture when the surrounding humidity is high, and releases the moisture contained in the saturated solution itself when the ambient humidity is low to control the humidity inside the storage container.

On the other hand, a separate machine room (not shown) is provided inside the main body of the refrigerator. Inside the machine room various components for a cooling system, such as a compressor 7 for compressing a refrigerant flowing inside the evaporator, are mounted in interconnection. In addition, the refrigerator is equipped with various accessories such as various controllers and sensors required for freezing and refrigerating food.

The refrigerator keeps fresh vegetables or fruits in the storage container in a fresh state by directly introducing cold air into the storage container 3 or cooling the outside of the storage container. The vegetables stored in the storage container 3 contain a lot of moisture, but the moisture contained in the vegetables is reduced by the cold air supplied to the storage container. The temperature inside the storage container 3 is kept slightly higher than the temperature of the refrigerating chamber 1a on storage of vegetables and the like. As a result, water droplets are generated on the inner surface of the storage container 3 due to the temperature difference between the inside of the storage container 3 and the refrigerating chamber 1a. When the water droplets grow and the gravity acting on the water droplets itself becomes larger than the surface tension, the water droplets fall on the vegetables being stored. As a result, the stored vegetables, etc. may be barked or freshness may be reduced.

As a result, the storage container of the conventional refrigerator described above has the following problems.

First, in order to store food products for a long time to avoid contact with air as possible, the conventional storage box of the refrigerator contains a large amount of air it was difficult to store the food fresh for a long time.

Second, there is a problem in that a separate degassing apparatus or a degassing apparatus must be installed to artificially perform degassing or supply electric power in order to extract air in the conventional storage container.

The present invention is to solve the above-mentioned problems, an object of the present invention is to provide a degassing apparatus of the refrigerator storage container that can be stored fresh food for a long time in the refrigerator storage container.

Another object of the present invention is to provide a degassing apparatus of a refrigerator storage container which does not require a separate operation or power consumption to remove some of the air inside the storage container.

In order to achieve the above object, the present invention is accommodated in the inner space of the main body, and a storage container for storing food products; When the storage container is accommodated in the inner space, provides a degassing apparatus of the refrigerator storage container comprising a degassing means for automatically degassing a part of the air inside the storage container.

Preferably, the degassing means includes a degassing part through which air is discharged and a degassing operation part through which air is discharged from the degassing part. In addition, the degassing operation portion is preferably composed of a projection formed on the inner wall of the body in which the storage container is accommodated. In addition, it is preferable that a predetermined portion of the storage container compressed by the protrusion is an elastic member free of deformation.

On the other hand, the degassing operation unit is installed on one side of the inside of the storage container, it is preferable that the degassing unit is configured to include a coupling member, a piston installed in the cylinder, connecting the piston and the inner wall of the body. In addition, the degassing operation portion is preferably configured to further include a packing member for blocking the gap between the connecting member and the storage container.

It is preferable that a suction hole is formed in the side surface of the cylinder in communication with the inner space of the storage container. And, it is more preferable that at least one degassing means is installed in the storage container.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment of the present invention that can realize the above object will be described.

The same components as in the related art are denoted by the same names and the same reference numerals for convenience of description, and detailed description thereof will be omitted.

2A, an embodiment of a degassing apparatus for a storage container according to the present invention will be described in detail.

The refrigerator according to the present embodiment includes a main body 10 having a predetermined internal space, a storage container 30 accommodated in the internal space, and a humidity control device 4 for controlling humidity inside the storage container 30. It is composed. In addition, the main body has a refrigerating chamber 11 capable of refrigerating food, and a guide (not shown) for easily inserting the storage container 30 on one side of the inner wall 40 of the main body in which the inner space is formed. Inside, a separate machine room (not shown) is provided. However, detailed description of the above-described components are the same as described in the prior art and will be omitted.

In the present embodiment, unlike the prior art, a degassing means is installed to automatically remove some of the air inside the storage container when the storage container is installed. The degassing means includes a degassing part 60 which is a part which directly discharges air and a degassing operation part which allows the air to be easily discharged from the degassing part. More specifically, the degassing operation portion is preferably composed of a projection (50) protruding from the body inner wall (40).

The degassing part 60 is installed on the wall surface 31 of the storage container in contact with the body inner wall 40 when the storage container 30 is accommodated in an inner space formed in the refrigerator body inner wall 40. The degassing unit 60 is preferably integrally installed on the wall surface 31 of the storage box so that the air inside the storage box 30 cannot be discharged except for the degassing unit 60. Of course, even if the degassing unit 60 is coupled to the storage box 30 by a separate fastener, if the air does not leak from the combined portion may be combined.

The protrusion 50 serves to provide a constant force to the degassing unit 60 so that air is discharged from the degassing unit 60. The protrusion 50 is formed on the main body inner wall 40 in which the storage container 30 is accommodated, and corresponds to the degassing part 60. The protrusion 50 is fixed and preferably made of a material that is not easily deformed by an external force.

The protrusion 50 is formed in a pair on the main body inner wall 40, and has a constant height and length. Of course, at least one protrusion 50 may be formed. The height of the protrusion 50 protruding from the body inner wall 40 is preferably greater than the height of the degassing part 60 protruding to the outside of the storage container 30. This is because the protrusions 50 may press the surface of the storage container around the degassing part 60 when the storage container 30 is completely accommodated in the inner space of the main body.

The length of the protrusion 50 in the lateral direction (vertical direction of the drawing) is preferably slightly longer than the length of the degassing part 60 itself. However, the transverse length of the protrusion may be shorter than the length of the degassing part itself, and may be the same as the transverse length of the storage container in which the degassing part 60 is installed. In addition, the pair of protrusions 50 are protruded at a predetermined distance apart, the interval is greater than the length of the degassing portion 60 itself. Because, when the storage container 30 is accommodated in the internal space of the main body so that the protrusion 50 is applied to the surface of the storage container around the degassing unit 60 so that air is discharged from the degassing unit 60 To do that.

With reference to FIG. 2B, the operation state of the degassing apparatus of FIG. 2A is demonstrated concretely.

As shown in FIG. 2B, when the storage container 30 is completely accommodated in the internal space of the refrigerator body, the protrusions 50 formed on the inner wall 40 of the main body compress the outer wall of the storage container. At this time, since the predetermined region of the portion in which the degassing part 60 is installed is composed of an elastic member free of deformation, the total volume of the storage container 30 is reduced. As a result, a part of the air inside the storage container is automatically discharged to the internal space of the main body through the degassing unit 60 by the reduced volume of the storage container 30. Of course, the entire storage container 30 may be composed of an elastic member free from deformation by external force.

Referring to FIG. 3, the degassing part of FIG. 2B will be described in detail.

The degassing part 60 may include a suction part 61 through which the air inside the storage container is sucked, a suction part supporting member 64 supporting the suction part, a discharge part 65 through which the air is discharged, after passing through the suction part, It is configured to include a discharge portion support member 68 for supporting the discharge portion. In addition, at least one degassing part 60 is preferably installed on the wall surface of the storage container 30.

The suction part 61 is formed with a suction groove 62 through which the air inside the storage container is sucked, and a flute groove 63 through which the air passing through the suction groove 62 makes a sound. The flute groove 63 forms a wider space than the suction groove 62, so that the sound is generated by the difference in air pressure when the air passes.

The suction part supporting member 64 is formed at both sides of the suction part 61, and serves to support the suction part 61. In addition, the suction part supporting member 64 is integrally formed with the surface of the storage container 30. Therefore, when the storage container 30 is deformed by the protrusion 50 formed on the inner wall 40 of the main body, the suction part supporting member 64 also moves together with the surface of the storage container.

The discharge part 65 is provided with a valve plate 67 to allow the air introduced through the suction part 61 to flow in only one direction, that is, the outside of the storage container. The valve plate 67 is installed in the valve plate installation groove 66 formed in the discharge part 65 to move by the pressure of the sucked air. That is, when air is discharged from the inside of the storage container, the valve plate 67 is lifted outward of the storage container by the pressure of the air. Then, the air is discharged between the intervals at which the valve plate 67 is lifted.

The discharge part supporting member 68 is formed at both sides of the discharge part 65, and a hinge 69 is installed at one side of the discharge part supporting member 68 to be connected to the suction part supporting member 64. It is. Lifting the other side of the outlet support member 68 with the hinge 69 as the center of rotation introduces air into the storage vessel 30. That is, as the air is automatically discharged while installing the storage container 30, the increased sealing force inside the storage container 30 is released.

The process of discharging some of the air inside the storage container through the degassing unit 60 will be described below.

When the protrusions 50 formed on the inner wall 40 of the main body compress the outer wall of the storage container 30, the air inside the storage container 30 is sucked because the air pressure inside the storage container 30 is greater than the air pressure inside the main body. The groove 62 flows into the suction part 61. The air flowing into the suction part 61 passes through the flute 63 groove formed in the suction part. As described above, when the air passes through the flute groove (63), a high-pitched sound is produced, and the user can know that the air is being discharged from the storage container (30).

Then, the air passing through the flute groove (63) moves to the valve plate installation groove (66) formed in the discharge portion (65), and lifts the valve plate (67) installed in the valve plate installation groove (66). . The air is then discharged out of the storage container through the space in which the valve plate 67 is lifted. After a certain amount of air is discharged, the external force no longer acts on the storage container 30 so that the air pressure inside the main body is increased than the air pressure of the storage container. Therefore, the valve plate 67 is moved toward the storage container 30 so that outside air does not enter the storage container.

Referring to Figure 4a, another embodiment of the degassing apparatus of the storage container according to the present invention will be described in detail.

The degassing device likewise comprises a degassing unit 60 through which some of the air inside the storage vessel is discharged and a degassing operation unit for discharging air from the degassing unit. However, unlike the above-described embodiment, the degassing operation part of the present embodiment includes a cylinder 71 installed inside the storage container 30, a piston 73 installed inside the cylinder, the piston 73, and a body inner wall ( 40 is configured to include a connecting member 75 for connecting. In addition, the degassing operation portion is preferably configured to further include a packing member 74 for blocking the gap between the connection member 75 and the storage container (30).

The cylinder 71 is installed above the inside of the storage container 30, and has a length smaller than the length of the storage container. In addition, the cylinder 71 has a rectangular cylinder shape, and a suction hole 72 is formed at one side of a wall of the cylinder to suck air into the storage container 30. Of course, the shape of the cylinder 71 may be any cylinder having a constant internal space including a circular cylinder. And, it is preferable that at least one cylinder is installed. In addition, a degassing part 60 is provided at one end of the cylinder, and the degassing part 60 is installed over the inside of the cylinder 71 and the outside of the storage container 30. This is to allow the air inside the cylinder 71 to be discharged to the outside of the storage container 30.

The piston 73 is installed in the cylinder 71 to be in intimate contact with the inner wall of the cylinder. Then, the air in the cylinder is discharged to the outside of the storage container 30 by the reciprocating motion of the piston (73). However, the piston 73 itself is not actually moving, but the piston 73 is stopped, and the cylinder 71 installed in the storage container 30 moves together with the storage container 30. do. The reciprocating motion of the cylinder 71 is made by the user's force when the storage container 30 is inserted into or taken out of the refrigerator body.

The connecting member 75 penetrates the outer wall of the storage container 30 to connect the piston 73 inside the cylinder and the inner wall 40 of the refrigerator main body. The connecting member 75 is firmly fixed to the main body inner wall 40 by the fastener 76. However, it may be formed integrally with the body inner wall 40 as a protrusion protruding from the refrigerator body. In addition, although the connecting member 75 may be configured as a single member, two or more members may be connected to each other by a hinge or the like.

The packing member 74 is installed at a portion where the connection member 75 penetrates the outer wall of the storage container 30. The packing member 74 is for preventing air from flowing in or out through a gap that may occur between the connection member 75 and the storage container 30. Of course, the packing member 74 may be installed inside the storage container 30 or may be installed outside the storage container. The packing member 74 is preferably made of a material such as synthetic rubber as the elastic member.

4B and 5, the operating state of the degassing apparatus of FIG. 4A will be described in detail. FIG. 5 corresponds to a cross sectional view taken along line II of FIG. 4B.

As shown in FIGS. 4B and 5, when the storage container 30 is pushed into the inner space of the main body, the cylinder 71 installed inside the storage container also moves in the direction of the main body inner wall. Then, the piston 73 in the stationary state is naturally located close to the direction of the degassing unit 60 provided on one side of the cylinder. Therefore, the air inside the cylinder is discharged to the outside through the degassing unit 60, the air inside the storage container 30 is moved into the cylinder by the volume of the air discharged from the cylinder (71). At this time, the air inside the storage container moves into the cylinder through the suction hole 72 formed in the cylinder. At least one suction hole 72 is preferably formed. However, without forming the suction hole 72, one end of the cylinder may be opened to communicate with the inside of the storage container (30). In addition, by adjusting the size or number of cylinders it is possible to discharge a greater amount of air.

The process of discharging air from the degassing unit 60 is the same as in the above-described embodiment, and thus will be omitted. However, the degassing part 60 may not have the same structure as the above degassing part. For example, a valve that opens and closes only in one direction may be used to open only when the air inside the reservoir is discharged, and always close the valve.

The present invention is not limited to the above-described embodiments, and those skilled in the art can make modifications without departing from the spirit of the present invention, and such modifications are within the scope of the present invention.

The effects according to the present invention described above are as follows.

First, the refrigerator according to the present invention has the advantage of being able to remove some of the air inside the storage container to keep the food fresh longer.

Second, the degassing apparatus of the refrigerator storage container according to the present invention is automatically degassed when accommodating the storage container in the internal space of the refrigerator, so that no separate work or power consumption is required to remove some of the air inside the storage container. There is an advantage.

Claims (8)

A storage container accommodated in an inner space of the main body and capable of storing foodstuffs; And a degassing means for automatically degassing a part of the air inside the storage container when the storage container is accommodated in the inner space. The degassing apparatus of the refrigerator storage container according to claim 1, wherein the degassing means includes a degassing part through which air is discharged and a degassing operation part through which air is discharged from the degassing part. The degassing apparatus of the refrigerator storage container according to claim 2, wherein the degassing operation part comprises a protrusion formed on an inner wall of the main body in which the storage container is accommodated. The degassing apparatus of the refrigerator storage container according to claim 3, wherein a predetermined portion of the storage container compressed by the protrusion is an elastic member free of deformation. According to claim 2, wherein the degassing operation unit is installed on one side of the inside of the storage container, comprising a cylinder coupled to the degassing unit, a piston installed in the cylinder, connecting member for connecting the piston and the inner wall of the body Degassing apparatus of the refrigerator storage container characterized in. The degassing apparatus of the refrigerator storage container according to claim 5, wherein the degassing operation part further comprises a packing member which closes a gap between the connection member and the storage container. The degassing apparatus of the refrigerator storage container according to claim 5 or 6, wherein a suction hole communicating with an inner space of the storage container is formed at a side surface of the cylinder. The degassing apparatus of the refrigerator storage container according to claim 2, wherein at least one degassing means is installed.

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