KR20010017916A - Structure of Vegitable storage portion for refrigerator - Google Patents

Abstract

PURPOSE: A vegetable compartment is provided to keep vegetables fresh for a long time by supplying the proper amount of cold air depending on the amount of vegetables kept in a vegetable compartment tray. CONSTITUTION: A vegetable compartment consists of: a vegetable compartment tray(12) accepted in a vegetable compartment(10) formed on the lower portion of a refrigeration compartment(4) of a refrigerator; a partition plate(14) mounted in the refrigeration compartment to cover the vegetable compartment tray; and an elastic member(20) positioned between the lower face of the vegetable compartment tray and the upper face of the vegetable compartment. The elastic member is used with a leaf spring. A gasket(15) is provided on the upper face of the vegetable compartment to keep internal/external airtightness of the vegetable compartment tray. If a large amount of food is kept in the vegetable compartment tray, the elastic member is compressed by a load(L). A clearance(C) is formed between the vegetable compartment tray and the partition plate to supply cold air directly. On the contrary, the vegetable compartment tray is cooled indirectly when a small amount of food is kept therein.

Description

Structure of Vegitable storage portion for refrigerator

The present invention relates to a structure of the vegetable storage unit of the refrigerator, and more particularly, to a structure of the vegetable storage unit configured to supply the cold air of the most suitable conditions according to the amount of vegetables stored in the vegetable compartment tray.

First, as shown in Figure 1a, generally in the lower part of the refrigerator compartment (4) of the refrigerator, a vegetable compartment for storing vegetables is formed, the vegetable compartment (6) containing the vegetable chamber tray (8) It is provided so that a storage is possible. The vegetable chamber tray 8 is kept closed by the partition plate 9 provided on the refrigerating chamber side wall. The vegetable chamber tray 8 provided in the refrigerating chamber is molded in an open state, and the partition plate 9 covers the upper portion of the vegetable chamber tray 8.

The vegetable compartment tray 8 is opened and closed by a user pulling forward or pushing in a drawer type. Accordingly, when the vegetable chamber tray 8 is pulled forward, the open upper part of the vegetable chamber tray 8 is exposed, and through this upper portion, the user can put vegetables or the like to be stored or take out the vegetables in storage.

Cooling the inside of the vegetable compartment tray 8 as described above is usually done in two ways. First, there may be mentioned a direct cooling method as shown in Figure 1a. This is a method of directly supplying the cold air supplied to the vegetable compartment through the lower end of the refrigerating chamber duct 7 for supplying cold air to the refrigerating chamber 4 into the inside of the vegetable chamber tray 8, the cold air in the refrigerating chamber duct 7, In the rear of the vegetable chamber tray 8, the cold air is directly supplied to the inside of the vegetable chamber tray 8 through a gap between the partition plate 9 and the partition plate 9. In FIG. 1A, the supply path of cold air is shown by an arrow.

Alternatively, indirect cooling as shown in FIG. 2 may be mentioned, which is indirectly provided by supplying the cold air in the refrigerating chamber duct for supplying cold air to the refrigerating chamber 4 around the vegetable chamber tray 8. (8) is a way to cool. That is, the downward rib 9a is extended to the rear end of the partition plate 9 to prevent cold air from being directly supplied to the inside of the vegetable chamber tray 8. Therefore, the cold air supplied through the refrigerating chamber duct 7 is supplied to the circumference of the vegetable chamber tray 8, including between the vegetable chamber tray 8 and the inner case 6a corresponding to the bottom of the vegetable chamber. ) To indirectly cool the inside.

There are advantages and disadvantages to these two approaches. In the direct cooling method, since the temperature drops rapidly by supplying cold air directly into the inside of the vegetable chamber tray 8, it is advantageous when there is a large load amount to be cooled or when rapid cooling is required. However, since the cold air circulated inside the vegetable compartment while the cold air is directly supplied, the circulation of the air inside the vegetable compartment is accelerated, thereby promoting the drying of the stored vegetable, which is disadvantageous for long-term storage of the vegetable.

In the case of the indirect cooling method, since the vegetable chamber tray is completely sealed by the partition plate, it is advantageous for long-term storage due to less drying of the vegetables in storage and advantageous in case of low load. However, when the initial load is large, there is a disadvantage in that it takes a long time to cool to a desired temperature, and at the same time, the amount of water droplets generated due to the dewing phenomenon is very large on the bottom surface of the partition plate 9 due to the moisture generated in the large load. When such water droplets fall downward and come into contact with the vegetables being stored, disadvantages arise in terms of storage, such as vegetables being crushed.

According to the prior art as described above, the direct cooling method is somewhat advantageous when the load is large, the indirect cooling method is advantageous when the load is small.

However, according to the conventional technique described above, indirect cooling or direct cooling is set in the design of the vegetable compartment of the refrigerator, which is inconvenient in use.

An object of the present invention is to provide an optimal cooling method according to the amount of storage by being configured to directly supply or indirectly supply cold air according to the amount of vegetables to be stored. Therefore, in the case of a large number of foods to be stored, it is possible to maintain a fresh storage temperature quickly by supplying cold air directly, and in the case of small foods, the indirect cooling method is advantageous for long-term storage.

In the present invention, the focus is on the cooling method is automatically adjusted according to the amount of load to be cooled.

1 shows a structure of a conventional vegetable storage portion,

1A is a cross-sectional view of a structure in which cold air is directly supplied into a conventional vegetable chamber tray.

1B is a cross-sectional view of a structure for indirectly cooling a conventional vegetable chamber tray.

Figure 2 is a cross-sectional view showing an indirect cooling state of the vegetable storage unit according to the present invention.

Figure 3 is a cross-sectional view showing a direct cooling state of the vegetable storage unit according to the present invention.

Explanation of symbols on the main parts of the drawings

4 ..... refrigerator compartment 7 ..... refrigerator compartment

10 ..... Vegetable Room 12 ..... Vegetable Room Tray

14 ..... Partition plate 15 ..... Gasket

20 ..... Elastic member

Vegetable storage unit structure of the refrigerator according to the present invention for achieving the above object, the vegetable compartment tray accommodated in the vegetable compartment provided in the lower side of the refrigerator compartment; A partition plate installed in the refrigerating compartment to cover the vegetable compartment tray; And an elastic member provided between the bottom surface of the vegetable chamber tray and the top surface of the vegetable chamber.

According to the present invention as described above, when there are many food items stored in the vegetable compartment tray, since the elastic member is compressed by the total load of the vegetable compartment tray, a gap is generated between the vegetable compartment tray and the partition plate. Therefore, if there are a lot of stored foods, cold air is directly supplied to the vegetable chamber tray through these gaps, and if there are few stored foods, the vegetable chamber trays are indirectly cooled. This means that the present invention has all the advantages of indirect cooling and direct cooling.

According to an embodiment of the present invention, a gasket for airtightness is provided on either side of the upper outer peripheral surface of the vegetable chamber tray or the upper outer peripheral surface of the vegetable chamber tray. Therefore, it is possible to maintain a sufficient airtight state according to the movement of the vegetable chamber tray up and down, it is possible to increase the operating efficiency of the structure according to the present invention.

And according to another embodiment of the present invention, the elastic member is composed of a leaf spring, this configuration makes it possible to apply the present invention more simply.

Next, the present invention will be described in more detail with reference to the embodiments shown in the drawings.

2 and 3 show the structure of the vegetable storage unit implemented in the lower end of the refrigerating compartment according to the present invention, Figure 2 shows how the vegetable chamber tray is indirectly cooled when the load is small, Figure 3 shows a large load In this case, it shows the direct cooling method in which cold air is supplied directly into the inside of the vegetable chamber tray.

As shown in the drawing, the lower end of the refrigerating compartment 4 is provided with a vegetable compartment 10 which is a space for embedding the vegetable compartment tray 12. And the upper part of the vegetable chamber tray 12 for storing the vegetables in the refrigerated state to maintain the closed state by the partition plate (14). The partition plate 14 is provided on the side of the refrigerating compartment 4.

In addition, in order to more reliably provide a sealing relationship between the vegetable chamber tray 12 and the partition plate 14, a rubber gasket 15 may be installed. The gasket 15 is molded of a flexible rubber material to ensure the airtightness between the vegetable chamber tray 12 and the partition plate 14, and is installed along the upper edge of the vegetable chamber tray 12, or the vegetable chamber tray. It may be provided at the bottom of the partition plate 14 in contact with the upper end of the 12.

According to the present invention, the elastic member 20 is provided on the bottom face 16 of the vegetable chamber 10. The elastic member 20 is compressed downward when a load is applied, and has an elastic restoring force upward when the applied load is removed. As long as the material having such elastic restoring force, the elastic member 20 can be made of any material. Specific examples thereof include leaf springs. In addition, of course, it is also possible to configure a coil spring having a constant elastic modulus, and of course, it may be made of any material such as rubber within the range having the elastic restoring force as described above.

Next, the state of FIG. 2 will be described. The state shown in FIG. 2 is a case where the quantity of the load L stored in the inside of the said vegetable compartment tray 12 is small. Since the amount of the load L is small, the load by it is also not large. Therefore, since the force acting on the lower elastic member 20 in the vegetable chamber 12 is not large, the elastic member 20 is not in a contracted state. In this state, since the vegetable chamber tray 12 is positioned relatively upward, the vegetable chamber tray 12 is substantially kept closed by the partition plate 14. Therefore, since the cold air supplied through the refrigerating chamber duct 7 is not directly supplied to the inside of the vegetable chamber tray 12, but is supplied through the circumference of the vegetable chamber tray 12, the inside of the vegetable chamber tray 12 is indirectly cooled.

As described above, when the amount of food to be stored in the vegetable compartment tray 12 is small, the present invention is configured to take an indirect cooling method, so that drying of the food to be stored is reduced, so that it is stored while maintaining freshness for a long time. It becomes possible.

3 shows a state in which the amount of vegetables stored in the vegetable compartment tray 12 is large. As shown in the figure, if the amount of vegetables stored in the inside of the vegetable chamber tray 12 is large, the vegetable chamber tray 12 is pushed downward by the load. That is, the total load of the vegetable chamber tray 12 larger than the elastic modulus of the elastic member 20 compresses the elastic member 20, so that the vegetable chamber tray 12 is lowered as a whole. Therefore, the upper end of the vegetable chamber tray 12 is spaced apart from the partition plate 14 and a predetermined gap (C) is generated therebetween.

When a predetermined gap C is generated between the vegetable chamber tray 12 and the partition plate 14, the cold air supplied through the lower end portion of the refrigeration chamber duct 7 of the vegetable chamber tray 12 is formed through the gap C. It can be supplied directly inside.

According to the present invention, when the amount of vegetables stored in the inside of the vegetable chamber tray 12 is large, cold air is supplied directly to the inside of the vegetable chamber tray 12. That is, when the load is large, it is possible to quickly lower the internal temperature by direct cooling. In addition, by such direct cooling, water droplets formed on the bottom surface of the partition plate 14 will also be reduced.

As described above, according to the present invention, by using the elastic member 20 installed below the vegetable chamber tray 12, the cold air is directly stored in the vegetable chamber according to the amount of vegetables stored in the vegetable chamber tray 12. It is the basic technical idea to configure the system so that it can be supplied in the form of heating or indirect cooling. Within the basic technical spirit of the present invention, it will be obvious that other modifications are possible for a person skilled in the art.

According to the present invention as described above it can be seen that it has all the advantages of the indirect cooling method and the direct cooling method for the vegetable compartment. In other words, when there are a lot of stored foods, by supplying sufficient cold air to the inside of the vegetable compartment tray 12, it can be seen that rapid freshness can be maintained and the amount of water droplets due to the dewing phenomenon is also reduced. . In addition, when there are few stored foods, the advantage that it becomes possible to store them fresh for a long time by preventing excessive drying of foods by taking indirect cooling method can be expected.

Claims (1)

A vegetable compartment tray housed in a vegetable compartment provided below the refrigerating compartment; A partition plate installed in the refrigerating compartment to cover the vegetable compartment tray; And Vegetable storage unit structure of the refrigerator characterized in that it comprises an elastic member provided between the bottom surface of the vegetable compartment tray and the upper surface of the vegetable compartment.