KR102184537B1 - Vegetables container and refrigerator having the same - Google Patents

Abstract

In the vegetable compartment and refrigerator for a refrigerator according to an embodiment of the present invention, an opening is formed in the front, and a storage space that is a storage space for storage is formed therein. A drawer for sealing the inside of the case and a guide channel formed on the inner surface of the case to guide water generated inside the case in one direction, and the guide channel is at least two A mountain and a valley disposed between the mountains and recessed to the outside of the case, and the mountains and valleys are arranged alternately from the front to the rear of the case.
In the vegetable compartment and refrigerator for a refrigerator according to an embodiment of the present invention, a case in which an opening is formed in the front and a storage space as a storage space for storage is formed therein, a drawer that seals the interior of the case, and is formed on the lower surface of the case A water collecting part that collects water generated inside the case, an upper inner case positioned on the inner side of the upper surface of the case, and inserted and fixed between both side surfaces of the case, and an inner surface of the upper inner case to be formed inside the case And an upper inner guide passage for guiding the water generated in the water collecting part, and the upper inner guide passage is disposed between at least two mountains protruding to the inside of the case, and is disposed between the mountains, to the outside of the case It includes a valley to be depressed, and the peaks and valleys are arranged alternately from the front to the rear of the case.

Description

Vegetable room for refrigerator and refrigerator equipped with it {VEGETABLES CONTAINER AND REFRIGERATOR HAVING THE SAME}

The present invention relates to a refrigerator vegetable compartment and a refrigerator.

In general, a refrigerator is a device that allows stored materials to be stored in a fresh state for a long period of time by cold air supplied to the interior of a storage room. The cold air supplied into the storage chamber is generated by the heat exchange action of the refrigerant. The cold air supplied to the interior of the storage compartment is evenly delivered to the interior of the storage compartment by convection so that food can be stored at a desired temperature.

The refrigerator has a storage compartment having an open front so that food can be stored inside a main body forming an exterior. In addition, a door for opening and closing the storage compartment is installed in the front of the storage compartment. The door is hinged to the body and rotates to open and close the storage compartment.

Such a refrigerator is typically provided with a vegetable compartment for a refrigerator capable of storing and storing vegetables. In general, in the case of storing vegetables in a refrigerator, it is necessary to maintain the highest freshness, so it is important to maintain a space in which vegetables are stored in optimal conditions.

21 is a perspective view showing a vegetable compartment 1000 for a refrigerator according to the prior art. Bell

The vegetable compartment 1000 for a refrigerator according to the following technology includes a case 1100 and a drawer 1300.

In the case of a two-box shape, the drawer 1300 is inserted into the case 1100 in a drawer type and closed while the inside of the vegetable compartment is sealed to maintain a weak vacuum state, thereby improving the freshness of the stored vegetables.

This conventional two box type is sealed with a drawer to keep food fresh and long. In the conventional case, a vacuum pump is attached to the sealed drawer (1300) or the vegetable compartment (1000) to apply a constant pressure to the vegetable compartment. Keep food fresh and long by keeping the internal vacuum constant.

However, in this case, the opening of the case 1100 into which the drawer 1300 is inserted is deformed in the inner direction of the case due to a pressure difference between the inside and the outside of the case 1100.

In addition, when the case 1100 is deformed, the sealing between the drawer 1300 and the case 1100 is released, and external air is introduced into the case 1100, so that the weak vacuum state in the case 1100 is released. A problem arises.

In addition, when the temperature inside the case 1100 decreases, there is a problem in that dew is generated inside the case 1100.

In addition, there is a problem that the dew generated inside the case 1100 forms on the inner surface of the case 1100 and is recognized by the naked eye of the user.

In addition, when the dew generated inside the case 1100 is dropped and comes into contact with the food stored therein, there is a problem of causing a soreness of the food.

The problem to be solved by the present invention is to provide a refrigerator vegetable compartment and a refrigerator capable of maintaining the inside of the refrigerator vegetable compartment in a vacuum state.

In addition, another problem to be solved by the present invention is to provide a refrigerator vegetable compartment and a refrigerator that guides the user to the collection unit so that dew generated inside the vegetable compartment for a refrigerator cannot be observed with the naked eye.

In order to achieve the above object, in the vegetable compartment for a refrigerator and the refrigerator according to an embodiment of the present invention, an opening is formed in the front, and a storage space that is a storage space for storage is formed therein. A drawer for sealing the inside of the case and a guide channel formed on the inner surface of the case to guide water generated inside the case in one direction, and the guide channel is at least two A mountain and a valley disposed between the mountains and recessed to the outside of the case, and the mountains and valleys are arranged alternately from the front to the rear of the case.

In addition, a vegetable compartment for a refrigerator and a refrigerator according to another embodiment of the present invention include a case in which an opening is formed in the front and a storage space as a storage space for storage is formed therein, a drawer sealing the inside of the case, and A water collecting part formed on the lower surface to collect water generated inside the case, an upper inner case positioned on the inner side of the upper surface of the case and fitted between and fixed between both side surfaces of the case, and an inner surface of the upper inner case And an upper inner guide passage for guiding water generated inside the case to the water collecting part, and the upper inner guide passage is disposed between at least two mountains protruding into the inner side of the case, and disposed between the mountains, and the case It includes a valley that is recessed to the outside of, and the peaks and valleys are arranged alternately from the front to the rear of the case.

In addition, a vegetable compartment for a refrigerator and a refrigerator according to another embodiment of the present invention include a case in which an opening is formed in the front and a storage space as a storage space for storage is formed therein, a drawer for sealing the inside of the case, and the case A water collecting part formed on the lower surface of the case to collect water generated inside the case, a lower surface inner case positioned on the inside of the lower surface of the case and fitted and fixed between both sides of the case, and formed on the inner surface of the lower surface inner case And a lower surface inner guide passage for guiding the water generated inside the case to the water collecting part, and the lower surface inner guide passage is disposed between at least two mountains protruding to the inside of the case, and between the mountains, It includes a valley that is depressed to the outside of the case, and the peaks and valleys are arranged alternately from the front to the rear of the case.

According to the refrigerator of the present invention, one or more of the following effects are provided.

In the embodiment, since the mountains and valleys are repeatedly arranged from the front to the rear of the case, the dew stored in the valley is not visible to the user located in the front of the case.

In addition, when it is formed in a substantially right-angled triangle in the shape of a mountain, the inner angle of the valley is narrowed without increasing the height of the mountain so that the adhesion between the water and the valley can be improved.

In addition, by installing an inner case detachable on the upper and/or lower surfaces of the case and having a guide passage formed therein, it can be easily applied to a general vegetable room.

In addition, in the embodiment, the edge of the opening is designed in an arcuate structure, so that the periphery of the opening of the case can be prevented from bending into the inside of the case.

In addition, by forming a flange on the edge of the opening, there is an advantage of preventing sagging of the edge of the opening and providing a space in which the sealing member and the drawer contact each other.

In addition, since the reinforcing member is coupled adjacent to the edge of the opening, deformation of the edge of the opening can be reduced.

In addition, since the deformation of the edge of the opening is suppressed, there is an advantage in that the inside of the vegetable compartment can be continuously maintained in a vacuum state.

In addition, the dew formed on the inner surface of the case is moved to the valley by the guide passage formed on the inner surface of the case, so that it is not visible to the naked eye of the user.

The upper surface of the case is formed to be inclined downward in the lateral direction of the case, so that the water formed on the upper surface of the case is effectively guided to the lateral direction of the case by gravity.

The lower surface of the case is formed to be inclined downward in the direction of the water collecting part, so that water guided from the upper and side surfaces of the case is effectively guided to the water collecting part.

Since a discharge valve is formed in the water collecting part, it has the effect of easily discharging water inside the case.

The effects of the present invention are not limited to the effects mentioned above, and other effects that are not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 is a perspective view showing a refrigerator according to an embodiment of the present invention,
FIG. 2 is a front view of the refrigerator shown in FIG. 1 when the door is opened;
3 is a perspective view showing a vegetable room for a refrigerator according to an embodiment of the present invention,
4 is a perspective view of a vegetable compartment for a refrigerator according to an embodiment of the present invention when opened;
5 is a perspective view showing a case according to an embodiment of the present invention,
6 is a cross-sectional view showing a combined state of a case and a reinforcing member according to an embodiment of the present invention;
7 is a side cross-sectional view of a case according to an embodiment of the present invention,
8 is a front view of a case according to an embodiment of the present invention,
9 is a partial plan view of an upper surface and a side surface of a case according to an exemplary embodiment;
10A is a partial plan view of an upper surface of a case as viewed from the inside of the case according to an exemplary embodiment;
Figure 10b is the ?-? of Figure 9? Section taken line,
11 is a diagram showing a degree of deformation of a case according to a comparative example;
12 is a diagram showing a degree of deformation of a case according to an embodiment;
13 is an exploded perspective view showing a case according to another embodiment of the present invention,
14 is a perspective view of the upper inner case of FIG. 13;
15 is a front view showing a state in which the upper inner case of the embodiment is coupled to the inside of the case;
16A is a partial plan view of an upper inner case as viewed from the inside of the case according to an exemplary embodiment;
16B is a cross-sectional view of an upper inner case according to an embodiment;
17 is an exploded perspective view showing a case according to another embodiment of the present invention,
18 is a front view showing a state in which the lower inner case of the embodiment is coupled to the inside of the case;
19 is a partial plan view of the lower inner case of FIG. 17 as viewed from the inside of the case;
20 is a partial cross-sectional view of the lower surface inner case according to the embodiment of FIG. 19;
21 is a perspective view showing a vegetable compartment for a refrigerator according to the prior art.

Advantages and features of the present invention, and a method of achieving them will become apparent with reference to the embodiments described below in detail together with the accompanying drawings. However, the present invention is not limited to the embodiments to be posted below, but may be implemented in various different forms, only the present embodiments are intended to complete the disclosure of the present invention, and common knowledge in the technical field to which the present invention pertains. It is provided to completely inform the scope of the invention to those who have, and the invention is only defined by the scope of the claims. The same reference numerals refer to the same components throughout the specification.

Spatially relative terms "below", "beneath", "lower", "above", "upper", etc., as shown in the figure It can be used to easily describe the correlation between components and other components. Spatially relative terms should be understood as terms including different directions of components during use or operation in addition to the directions shown in the drawings. For example, if a component shown in a drawing is turned over, a component described as "below" or "beneath" of another component will be placed "above" the other component. I can. Accordingly, the exemplary term “below” may include both directions below and above. Components may be oriented in other directions, and thus spatially relative terms may be interpreted according to the orientation.

The terms used in the present specification are for describing exemplary embodiments and are not intended to limit the present invention. In this specification, the singular form also includes the plural form unless specifically stated in the phrase. As used herein, “comprises” and/or “comprising” refers to the recited elements, steps and/or actions excluding the presence or addition of one or more other elements, steps and/or actions. I never do that.

Unless otherwise defined, all terms (including technical and scientific terms) used in the present specification may be used as meanings that can be commonly understood by those of ordinary skill in the art to which the present invention belongs. In addition, terms defined in a commonly used dictionary are not interpreted ideally or excessively unless explicitly defined specifically.

In the drawings, the thickness or size of each component is exaggerated, omitted, or schematically illustrated for convenience and clarity of description. Also, the size and area of each component do not fully reflect the actual size or area.

In addition, angles and directions mentioned in the process of describing the structure of the embodiment are based on those described in the drawings. In the description of the structure constituting the embodiment in the specification, when the reference point and the positional relationship with respect to the angle are not clearly mentioned, reference will be made to the related drawings.

Hereinafter, the present invention will be described with reference to drawings for describing a refrigerator according to embodiments of the present invention.

1 is a perspective view illustrating a refrigerator according to an exemplary embodiment of the present invention, and FIG. 2 is a front view of the refrigerator shown in FIG. 1 when the door of the refrigerator is opened.

As shown in FIGS. 1 and 2, the refrigerator according to the present embodiment includes a main body 2 in which storage compartments F and R are formed, a cooling device 40 for cooling the storage compartments F and R, It includes a door (4) (6) for opening and closing the storage compartments (F) (R).

The cooling device 40 cools the storage chambers F and R by exchanging heat with the outside. The cooling device 40 may be composed of a refrigeration cycle device including a compressor, a condenser, an expansion mechanism, and an evaporator, and by applying current to first and second metals that are different in material and are spaced apart from each other, the first metal and the second metal One of them may be made of a thermoelectric element that absorbs heat and the other generates heat, and it will be described as being made of a refrigeration cycle device.

The cooling device 40 cools the evaporator while circulating the refrigerant to a compressor -> condenser -> expansion mechanism -> evaporator -> compressor.

In the cooling device 40, the evaporator is in contact with the outer wall of the storage chamber (F) (R) to directly cool the storage chamber (F) (R), and the air in the storage chamber (F) (R) is transferred to the evaporator and the storage chamber (F). By further including a cold air circulation fan 50 that circulates to (R), the air in the storage chambers (F) (R) may cool the storage chambers (F) (R) while circulating the storage chambers (F) (R) and the evaporator. .

In the storage chambers F and R of the main body 2, shelves 8 and 10 on which storage items such as food ingredients or side dishes are placed may be disposed.

In addition, a vegetable compartment 100 for a refrigerator in which vegetables and fruits are stored may be installed in the storage compartments F and R of the main body 2.

The vegetable compartment 100 for a refrigerator may be installed to be in and out of the storage compartments F and R, or may be fixedly installed.

The doors 4 and 6 are arranged to be rotated on the main body 2 in one of the left and right directions and the up and down directions, and when the doors 4 and 6 are closed, the side facing the storage compartment (F) (R) (i.e. , On the back), a door basket 5 for a refrigerator for storing beverages such as bottled water, milk, juice, liquor or ice cream such as ice cream is disposed.

It is preferable that a plurality of door baskets 5 for refrigerators are installed vertically apart from each other on the doors 4 and 6.

The storage compartment (F) (R) includes a freezer compartment (F) and a refrigeration compartment (R), and the doors (4) and (6) open and close the freezer compartment (F), and a freezer compartment door (4) that opens and closes the refrigeration compartment (R) (6), and the shelves 8 and 10 include a freezer shelf 8 disposed in the freezer compartment F, and a refrigerator compartment shelf 10 disposed in the refrigerator compartment R, and a door basket for a refrigerator ( 5) may be installed in a freezer in which frozen products such as ice cream are stored, or in a refrigerator in which refrigerated products such as beverages such as milk, juice, and alcohol are stored.

Hereinafter, the vegetable compartment 100 for a refrigerator will be described in detail with reference to the drawings.

3 is a perspective view showing a vegetable compartment for a refrigerator according to an embodiment of the present invention, FIG. 4 is a perspective view showing a vegetable compartment for a refrigerator according to an embodiment of the present invention when opened, and FIG. 5 is a view illustrating an embodiment of the present invention. A perspective view showing a case according to the present invention, Figure 6 is a cross-sectional view showing a combined state of a case and a reinforcing member according to an embodiment of the present invention, Figure 7 is a side cross-sectional view of a case according to an embodiment of the present invention, Figure 8 is a view A front view of a case according to an embodiment of the present invention, FIG. 9 is a partial plan view of an upper surface and a side surface of a case according to an embodiment, and FIG. 10A is a partial plan view of the upper surface of the case viewed from the inside of the case according to an embodiment, FIG. 10b is the ?-? of FIG. 9 It is a cross-sectional view taken along the line.

3 to 6, the vegetable compartment 100 for a refrigerator according to the embodiment includes a case 110, a drawer 120, and a guide passage 200.

In addition, the embodiment may further include a water collecting unit 180.

The case 110 forms the exterior of the vegetable compartment 100 for a refrigerator, and has a structure installed in the storage compartments F and R in the main body 2 of the refrigerator. In addition, the case 110 may have a dual structure of an inner case and an outer case, and the outer case may be fixed to the storage chambers F and R, and the inner case may be installed to be in and out of the outer case.

The case 110 may have an opening 113 formed in the front, and a storage space A that is a storage space for storage may be formed therein.

For example, the case 110 may be formed of a rectangular parallelepiped in which the storage space A is formed. More specifically, the case 110 may be formed such that only the front (opening portion 113) through which the drawer 120 is received or withdrawn is opened and the remaining five surfaces are blocked. That is, based on FIG. 2, the case 110 has an opening 113 formed in the front, the rear surface 110d of the case is disposed in the rear, and the upper surface 110a of the case and the lower surface 110c of the case are above and below. ) Is disposed, and side surfaces 110b of the case may be disposed on both sides. In addition, the upper surface 110a of the case and the lower surface 110c of the case may have a larger area than the side surface 110b of the case.

At one side of the case 110, a decompression unit 190 for forming a negative pressure (overvacuum) inside the case 110 may be installed. The decompression unit 190 may be implemented as, for example, a pump (vacuum pump).

In addition, although not shown in the drawings, the pressure reducing unit 190 may be connected to the case 110 by a connection pipe. Thereby, when the drawer 120 is stored in the case 110, air inside the case 110 is discharged to reduce the pressure inside the case 110.

A flange 119 extending to the outside of the storage space A may be further formed on the edge of the opening 113. That is, by extending to the outside in front of the case 110, the flange 119 may be formed.

The flange 119 may be disposed perpendicular to the side surface 110b and the upper and lower surfaces of the case. Here, being arranged vertically means that the flange 119 is formed to be elongated in the vertical and horizontal directions of the case 110. In addition, the above-described vertical meaning does not mean a perfect vertical in a mathematical sense, but in an engineering sense, it means a vertical in a range including errors.

The flange 119 is disposed perpendicular to the upper surface 110a and the lower surface 110b of the case, so that sagging of the edge of the opening 113 caused by negative pressure inside the case 110 can be prevented. Specifically, since the flange 119 is formed in the vertical direction of the case 110, it may function as a bending stress support that resists bending stress generated in the rim of the opening 113.

Further, the flange 119 provides an area in contact with the drawer 120 when the drawer 120 seals the inside of the case 110. In particular, when the inside of the case 110 is kept close to a vacuum, the inside of the case 110 must be completely sealed with the outside, and the flange 119 provides a space in which the drawer 120 contacts, The sealing performance of the vegetable compartment 100 is improved. In addition, when the sealing member 140 is used in the contact area between the drawer 120 and the case 110, a space in which the sealing member 140 contacts is provided.

At least one surface of the rim of the opening 113 may be formed in an arcuate structure in which a central portion protrudes to the outside of the storage space A.

For example, as shown in FIG. 5, the rim of the opening 113 has a quadrangular shape consisting of the upper surface 110a of the case, the lower surface 110c of the case, and the side surface 110b of the case. It is common that the upper surface 110a of the case and the lower surface 110c of the case are formed longer than the side surface 110b of the case, whereby the upper surface 110a of the case and the lower surface 110c of the case 110 Large deformation occurs due to bending stress caused by external pressure difference. Therefore, if one surface of the rim of the opening 113 (for example, the front end of the upper surface 110a of the case) has an arcuate structure in which the central portion protrudes to the outside of the storage space A, the inner direction of the case 110 It is possible to effectively counter the bending stress acting as As a result, when the rim of the opening 113 is designed in an arcuate structure, it is possible to prevent the periphery of the opening 113 of the case 110 from bending into the interior of the case 110.

The case 110 may further include a reinforcing rib 111 that reinforces the strength of the case 110.

The reinforcing rib 111 is a member formed in a direction in which the case 110 is deformed, and may be formed integrally with the case 110 by injection molding.

For example, the reinforcing rib 111 may be formed on the outer surface of the case 110 to secure the storage space A inside the case 110. In addition, a plurality of reinforcing ribs 111 may be formed in a first direction, and a plurality of reinforcing ribs 111 may be formed in a direction crossing the first direction.

A rail 117 guiding the drawer 120 may be formed on the inner surface of the case 110 so that the drawer 120 is in and out of the drawer type. For example, the rail 117 is formed on the side of the inner surface of the case 110, and is formed to extend from the front to the rear.

The drawer 120 on the lower surface of the case 110c seals the inside of the case 110 and forms the exterior of the vegetable compartment 100 for a refrigerator together with the case 110.

For example, the drawer 120 may include an accommodating part 123 that forms an accommodating space in which a storage object is accommodated and a front part 121 disposed in front of the accommodating part 123.

The storage unit 123 is put in and out of the case 110 in a drawer type. For example, a guide 129 is formed on the outer surface of the receiving unit 123 to correspond to the rail 117 of the case 110, so that the receiving unit 123 is the inside of the case 110. It will be moved forward and backward according to the guidance.

For example, the receiving part 123 may have a hexahedral shape with an upper and a front opening.

The front part 121 may be disposed in front of the receiving part 123 and may be formed to have an enlarged size compared to the receiving part 123. Accordingly, the rim of the front part 121 is in contact with the rim of the opening 113 to seal the case 110.

The front part 121 may be implemented in a substantially rectangular (cube) shape. More specifically, it is preferable to have a size and shape corresponding to the size and shape of the flange 119 of the opening 113. That is, the front part 121 may be formed to be in contact with the flange 119 of the case 110.

In addition, a handle 125 for drawing or receiving may be provided on the front part 121.

The handle 125 may be provided in the upper area of the front part 121.

The handle 125 may be formed, for example, to be recessed backward to form a gripping space from the surface of the front portion 121.

When the inside of the case 110 is sealed by the drawer 120, a pressure difference occurs between the inside and the outside of the case 110. That is, when the inside of the case 110 is sealed by the drawer 120, the inside of the case 110 is reduced by the depressurization unit so that the pressure is lower than the outside of the case 110.

A sealing member 140 that seals the inside and outside of the case 110 when the drawer 120 is received may be provided in the mutual contact area between the front portion 121 of the drawer 120 and the rim of the opening 113. have.

The sealing member 140 may be formed of, for example, a rubber material.

The sealing member 140 may be provided in a closed-loop shape along the rim (or flange 119) of the opening 113.

On the other hand, between the case 110 and the drawer 120, when the drawer 120 is received, the airtight holding device 160 to keep the drawer 120 and the inside of the case 110 sealed to the outside. May be provided.

The sealing device 160 is, for example, a drawer 120 and a catching portion coupled to one side of the case 110 and the drawer 120 and the other side of the case 110 to be coupled to the locking portion It may include a fastening part. However, it is not limited thereto, and may have various configurations.

5, 7 and 8, the water collecting unit 180 is a place formed on the lower surface 110c of the case to collect water generated inside the case 110. It is preferable that the water collecting unit 180 is positioned lower than the lower surface 110c of the case so that water generated inside the case 110 is collected by gravity. The water inside the case 110 is dew generated by saturating the moisture inside the case 110 when the temperature drops below the dew point temperature.

More specifically, the water collecting part 180 may be formed by recessing the lower surface 110c of the case downward. In addition, more preferably, the lower surface 110c of the case may be formed to be inclined downward in the direction of the water collecting part 180 in order to effectively guide the water flowing by gravity to the water collecting part 180.

Although various numbers of the water collecting parts 180 may be arranged, when the water collecting parts 180 are arranged as one, it is advantageous for water collection to be disposed approximately at the center of the lower surface 110c of the case.

In addition, the water collecting unit 180 may further include a discharge valve 170 for discharging the water collected by the water collecting unit 180 to the outside of the case 110.

The discharge valve 170 is operated in various ways to discharge water collected by the water collecting unit 180 to the outside of the case 110.

5 to 10, guide passages 200a-200d are formed on the inner surface of the case 110 to guide water generated in the case 110 toward the water collecting part 180. In addition, the guide passages 200a-200d serve to store the dew generated inside the case 110 so that it is not visible to the naked eye.

The guide passages 200a-200d may be formed on at least one surface of the inner surface of the case 110, but preferably, the guide passages 200a-200d may be formed on all inner surfaces of the case 110.

The guide passages 200a-200d may be formed such that the inner surface of the case 110 is depressed and protruded, and may be formed to guide water in the direction of the water collecting part 180.

For example, the guide passages 200a-200d are at least two peaks 210 protruding inwardly of the case 110, and valleys disposed between the peaks 210 and recessed outward of the case 110 ( 220) may be included.

Here, the mountain 210 is formed long in the left-right direction of the case 110, so that a plurality of mountains 210 are repeatedly disposed from the front to the rear of the case 110.

The mountain 210 is a portion protruding from the valley 220 so that water generated inside the case 110 can flow into the valley 220. The valley 220 is formed lower than the mountain 210 between the mountain 210 and the mountain 210 to provide a path through which water is guided.

The peaks 210 and the valleys 220 are alternately arranged from the front to the rear of the case 110. When the temperature inside the case 110 falls below the dew point temperature, dew generated by the moisture inside the case 110 is saturated. This dew flows from the mountain 210 to the valley 220 and is stored in the valley 220. In particular, due to the cohesive force of water and the adhesion between the water and the inner surface of the case 110, the dew is moved to the concave valley 220 rather than the protruding mountain 210.

In addition, when dew is stored in the bone 220, and the mountain 210 and the valley 220 are repeatedly arranged from the front to the rear of the case 110, the bone 220 is provided to the user located in front of the case 110. Visibility of the dew stored in is weakened. This is because the mountain 210 formed long from the left to the right of the case 110 blocks the user's view.

Specifically, referring to FIG. 10B, the shape of the cross-section of the mountain 210 (a cross-section taking a line from the front to the rear of the case 110) may have an approximate right triangle.

More specifically, the mountain 210 may be formed by a first slope 211 and a second slope 212 extending from both ends of the base 213 to form a vertex.

Here, the base 213 is an arbitrary line connecting the adjacent valleys 220 to each other.

The ratio of the lengths of the base 213, the first slope 211, and the second slope 212 (d3:d1:d2) may be 1.4 to 1.6: 1.9 to 2.1: 2.36 to 2.64. Therefore, when applying the Pythagorean theorem, the base 213 and the first inclined side 211 have a shape of a right-angled triangle close to approximately 90 degrees of the inner angle.

In addition, the mountain 210 and the valley 220 are formed symmetrically with respect to the second slope 212.

When the mountain 210 and the valley 220 are formed in a square shape, the dew formed on the inner surface of the case 110 is difficult to move to the valley 220, so that dew forms on the mountain 210, so that the user can see the dew. there is a problem,

When the mountain 210 and the valley 220 are formed in a triangular shape, the dew formed on the inner surface of the case 110 is easily moved to the valley 220. In particular, the dew formed on the inner surface of the case 110 has a large contact area on the surface between the first slope 211 and the second slope 212, and such a large contact area improves the adhesion with the dew. , It will move the dew to the goal (220).

In particular, when the mountain 210 and the valley 220 are formed in a right triangle, the dew formed on the inner surface of the case 110 is easily moved to the valley 220. Specifically, when the inner angle of the valley 220 (the angle between the first slope 211 and the second slope 212) increases, the dew formed at the vertex of the mountain 210 moves to the valley 220 It is difficult to become, and the inner angle of the valley 220 (if the first slope 211 and the second slope 212 are too small, the height of the mountain 210 becomes too high, so the strength of the case 110 is reduced. This is because there is a problem of increasing the thickness of the case 110.

Therefore, when the mountain 210 and the valley 220 are formed in a right triangle, the height of the mountain 210 is not too high, and the inner angle of the valley 220 (the first slope 211 and the second slope (212) by narrowing the angle between, it is possible to improve the adhesion between the water and the valley 220.

Preferably, the first slope 211 of the first slope 211 and the second slope 212 of the mountain 210 is located in front of the case 110 than the second slope 212 I can.

The vertex of the mountain 210 formed by the meeting of the first slope 211 and the second slope 212 is formed to be round, so that when dew is generated at the vertex of the mountain 210, the dew is caused by gravity. 110) can be prevented from falling into the inside, and the dew generated at the vertex of the mountain 210 can be guided to the valley 220.

It is preferable that the pitch P between the peak 210 and the peak 210 is 1.5mm to 2.5mm. When the pitch (P) between the mountain 210 and the mountain 210 is greater than 2.5mm, the dew formed on the inner surface of the case 110 does not easily move to the valley 220, and the mountain 210 and the mountain ( 210) When the pitch P is less than 1.5mm, there is a problem in that the valley 220 does not provide a sufficient space for the dew to gather, so that dew is visible to the naked eye.

In addition, the height of the mountain 210 is preferably 1.5mm to 2.5mm. If the height of the mountain 210 is too high, the strength of the case 110 is lowered, and if the height of the mountain 210 is too low, there is a problem in that the valley 220 does not provide sufficient space for dew to collect.

Again, referring to FIG. 10A, the embodiment may further include an auxiliary passage 225 formed by intersecting the guide passage 200 and the inner surface of the case 110 being recessed.

Dew generated inside the case 110 moves in the left and right directions of the case 110 along the valley 220, and the movement of the case 110 in the front and rear directions is limited by the mountain 210. When the amount of dew generated inside the case 110 is excessive, it may not spread along the valley 220 and may fall into the interior of the case 110.

The auxiliary passage 225 is formed to intersect with the mountain 210 and the valley 220, so that when the amount of dew generated inside the case 110 is excessive, it serves to guide the water to the adjacent valley 220 do.

Specifically, the auxiliary flow path 225 is formed long from the front to the rear of the case 110, and is formed to be in communication with the valley 220.

Although FIG. 10 shows the upper surface 110a of the case, a guide passage 200 may also be formed on the lower surface 110c of the case and the side surface 110b of the case.

Hereinafter, the guide passages 200a-200d formed on each surface of the case 110 will be described in detail.

5 and 7 to 9, the guide passages 200a-200d include an upper guide passage 200a, a side guide passage 200b, a rear guide passage 200d, and a lower guide passage 200c. Can be made of.

The upper surface guide passage 200a is formed on the inner surface of the upper surface 110a of the case. It is preferable that the peaks 210 and the valleys 220 of the upper guide passage 200a are formed long in the direction of both side surfaces 110b of the case. In addition, the peaks 210 and the valleys 220 of the upper guide passage 200a may be formed alternately from the front of the case 110 toward the rear surface 110d of the case.

More preferably, the upper surface (110a) of the case is to be guided by gravity to the side surface (110b) of the case along the upper surface guide passage (200a) along the upper surface (110a) inner surface of the case. It may be formed to be inclined downward in the (110b) direction. That is, as shown in FIG. 8, the upper surface 110a of the case may have an arc shape in which a central portion protrudes upward of the case 110. When the upper surface 110a of the case is formed as described above, the strength of the upper surface 110a of the case increases, and water formed on the upper surface 110a of the case can be guided toward the side surface 110b of the case by gravity. have.

Side guide passages 200b are formed on the inner surfaces of both side surfaces 110b of the case. The peaks 210 and valleys 220 of the side guide passage 200b may be elongated in a direction from the upper surface 110a of the case to the lower surface 110c of the case (a direction parallel to the left and right direction of the case 110). . That is, the peaks 210 and the valleys 220 of the side guide passage 200b may be alternately disposed from the front to the rear of the case 110.

This is to allow water generated from the side surface 110b of the case to flow toward the lower surface 110c of the case by gravity.

In addition, in order for the water formed on the upper surface 110a of the case to be effectively guided to the side surface 110b of the case, the upper surface guide passage 200a and the valley 220 of the side guide passage 200b are connected (communicated) to each other. desirable.

The rear guide passage 200d is formed on the inner surface of the rear surface 110d of the case. The peaks 210 and valleys 220 of the rear guide passage 200d may be elongated from the upper surface 110a of the case toward the lower surface 110c of the case. That is, the peaks 210 and the valleys 220 of the rear guide passage 200d may be alternately arranged in the left and right directions of the case 110.

This is to allow water generated from the rear surface 110d of the case to flow toward the lower surface 110c of the case by gravity.

The lower guide passage 200c is formed on the inner surface of the lower surface 110c of the case.

The peaks 210 and valleys 220 of the guide passage 200c may be formed in the direction of the collecting part 180. This is to allow water generated inside the case 110 to flow in the direction of the water collecting unit 180 by gravity. In addition, for more effective collection, the lower guide passage 200c may be formed to be inclined downward in the direction of the collection unit 180.

For example, the lower guide passage 200c may be formed in a radial shape centered on the water collecting part 180. Of course, for effective collection, the valley 220 of the upper guide passage 200a, the valley 220 of the side guide passage 200b and the valley 220 of the lower guide passage 200c are communicated (connected) to each other. I can.

Accordingly, as shown in FIG. 8, water (dew) generated in the case 110 may be collected by the water collecting unit 180 along the water movement path f.

In addition, although not shown in the drawings, the peaks 210 and the valleys 220 of the lower guide passage 200c may be formed long in the left and right directions of the case 110. That is, the peaks 210 and the valleys 220 of the rear guide passage 200d may be alternately arranged from the front to the rear of the case 110.

The reinforcing part functions to reinforce the strength of the case 110.

For example, the reinforcing part may be implemented as a reinforcing member 130 coupled to at least one surface of the case 110. When the opening 113 is formed in front of the case 110, the pressure inside the case 110 is lower than the pressure outside the case 110, so that the rim of the opening 113 is in the inner direction of the case 110. A sagging phenomenon occurs, and when the reinforcing member 130 is disposed, such sagging can be prevented. Here, the rim of the opening 113 means the upper surface 110a of the case, the lower surface 110c of the case, and the front end portions of both side surfaces 110b of the case 110.

More specifically, the reinforcing member 130 may be disposed on a surface having the largest area among the surfaces of the case 110. That is, as shown in FIG. 5, when the case 110 is formed in a rectangular parallelepiped shape with the opening 113 in the front, the position where the deformation occurs most due to the pressure difference inside and outside the case 110 is the case ( 110) is the front end of the largest surface (the upper surface 110a and the lower surface 110c of the case). Therefore, it is effective to prevent the deformation of the opening 113 when the reinforcing member 130 is adjacent to the edge of the opening 113 and is disposed on a surface having the largest area among the surfaces of the case 110.

The reinforcing member 130 may be disposed on the upper surface 110a of the case. In addition, when the reinforcing member 130 is disposed inside the case 110, the storage space A is reduced, so that the reinforcing member 130 is preferably coupled to the outside of the upper surface 110a of the case. Do.

Since the largest deformation occurs at the edge of the opening 113, the reinforcing member 130 is preferably positioned adjacent to the opening 113.

The reinforcing member 130 may be disposed parallel to the rim of the opening 113. Here, the meaning of parallel does not mean parallel in the mathematical sense, but in the engineering sense, it means parallel including errors. In addition, parallelism includes not only parallelism between straight lines, but also parallel arrangements in a curved line with a certain distance from each other. When the reinforcing member 130 is disposed parallel to the rim of the opening 113, the deformation of the rim of the opening 113 can be more effectively prevented.

In addition, the reinforcing member 130 is disposed on the upper surface 110a or/and the lower surface 110b of the case, and one side may be coupled to the flange 119. Deformation of the edge of the opening 113 may be prevented more effectively by combining the flange 119 and the reinforcing member 130.

The reinforcing member 130 may have various shapes with good resistance to bending stress. For example, the reinforcing member 130 includes a first member 131, a second member 133 disposed spaced apart from the first member 131, and the first member 131 and the second member 133 And a connection member 135 having a through hole 136 through which a bolt fastened to the case 110 passes. That is, the reinforcing member 130 may have a U shape having good resistance to bending stress. A boss 114 to which a bolt is fastened may be formed at a position corresponding to the through hole 136 in the case 110.

Preferably, the first member 131 and the second member 133 may be disposed perpendicular to the upper surface of the case 110 in order to increase resistance to the stress. That is, the first member 131 and the second member 133 may be disposed in the vertical direction of the case 110.

In addition, in order to reduce the space occupied by the reinforcing member 130, one end of the first member 131 and the second member 133 is in contact with one surface of the case 110 and is formed at the same height as the reinforcing rib 111 Can be. In this case, the connection member 135 may be disposed at the same height as the upper end of the reinforcing member 130.

The reinforcing member 130 may be formed of a material having a greater strength than the case 110. For example, the reinforcing member 130 may include a metal material and an alloy material, and specifically, may include at least one of steel, steel alloy, aluminum alloy, titanium alloy, stainless steel, and stainless alloy. However, it is not limited thereto.

11 is a view showing a degree of deformation of a case according to a comparative example, and FIG. 12 is a view showing a degree of deformation of a case according to an embodiment.

11 shows the degree of deformation when negative pressure is formed in the case 110 according to the comparative example. Deformation occurs in the rim of the opening 113 by negative pressure inside the case 110. In particular, a large deformation of 13.22 mm occurs in the center of the upper surface of the rim of the opening 113. In this case, the contact between the flange 119 and the drawer 120 in the opening 113 is released, and external air is introduced into the case 110. Therefore, it is difficult to maintain the inside of the case 110 in a negative pressure state.

12 illustrates a degree of deformation when negative pressure is formed in the case 110 according to the embodiment. In the embodiment, only a small deformation of about 1.5 mm occurs at the center of the upper surface of the edge of the opening 113 at the same negative pressure as the comparative example. Accordingly, contact between the flange 119 and the drawer 120 in the opening 113 is maintained, and external air does not flow into the case 110. As a result, the inside of the case 110 can be maintained in a negative pressure state, and vegetables stored in the case 110 can be freshly stored.

13 is an exploded perspective view showing a case according to another embodiment of the present invention, FIG. 14 is a perspective view of the upper inner case of FIG. 13, and FIG. 15 is a front view showing the upper inner case of the embodiment coupled to the inside of the case FIG. 16A is a partial plan view of an upper inner case as viewed from the inside of the case, and FIG. 16B is a cross-sectional view of an upper inner case according to an exemplary embodiment.

13 to 15, the vegetable compartment 100A for a refrigerator according to the embodiment is located inside the case 110, the drawer 120, the water collecting part 180, and the upper surface 110a of the case. , It is formed on the inner surface of the upper inner case 300 and the upper inner case 300 that are fitted and fixed between the two side surfaces 110b of the case, and collects water generated in the case (the inner surface of the upper inner case 300). It includes an upper inner guide passage (300a) that guides to 180.

Here, since the case 110, the drawer 120, and the water collecting unit 180 are the same as in the embodiment of FIG. 3, a description thereof will be omitted below.

The upper inner case 300 is located inside the upper surface 110a of the case, and is fitted and fixed between both side surfaces 110b of the case.

The width of the upper inner case 300 is formed slightly larger than the width between both side surfaces 110b of the case, so that the upper inner case 300 may be fitted and fixed between the both side surfaces 110b of the case by its own elastic restoring force. .

For example, the upper inner case 300 includes a central portion 330 positioned at the center, two inclined portions 350 extending downwardly inclined from the central portion 330 toward both side surfaces 110b of the case, and an inclined portion ( It may include an edge portion 370 that is bent downward at 350 and is in close contact with the side surface 110b of the case by an elastic force.

The central part 330 forms the center of the upper inner case 300.

The two inclined portions 350 extend from the central portion 330 in the direction of both side surfaces 110b of the case. In addition, the two inclined portions 350 are formed to be inclined downward from the central portion 330 in the direction of both side surfaces 110b of the case, so that dew generated on the inner surface (lower surface) of the upper inner case 300 is removed from the side surface 110b of the case. To flow.

In particular, as described later, when the upper inner guide passage 300a is formed long in the left-right direction of the case 110, the two inclined portions 350 are inclined downward from the central portion 330 to both side surfaces 110b of the case. When formed, the dew generated in the upper inner case 300 may be more easily guided to the side surface 110b of the case.

The edge portion 370 is in close contact with the side surface 110b of the case by an elastic force, and fixes the upper inner case 300 to the side surface 110b of the case.

The edge portion 370 may be bent downward from the inclined portion 350 to have an elastic force, and water guided along the inclined portion 350 may be guided to the side surface 110b of the case through the edge portion 370. have.

More specifically, the edge portion 370 is formed to be rounded, and the thickness may decrease as progressing from the inclined portion 350 to the end of the edge portion 370. When the thickness decreases as the edge portion 370 proceeds from the inclined portion 350 to the end of the edge portion 370, the water guided from the edge portion 370 to the side surface 110b of the case 110 Will not fall.

Referring to FIG. 16, the upper inner guide passage 300a is formed on the inner surface of the upper inner case 300 to guide water generated on the inner surface of the upper inner case 300 in the direction of the water collecting part 180. In addition, the upper inner guide passage 300a serves to store the dew generated inside the case 110 so that it is not visible to the naked eye.

The upper inner guide passage 300a may be formed on the inner surface (lower surface) of the upper inner case 300. Here, the inner surface of the upper inner case 300 refers to a surface exposed to the inside of the case 110 by inserting the upper inner case 300 into the case 110.

The upper inner guide passage 300a is continuously formed in the central portion 330, the inclined portion 350, and the edge portion 370 of the upper inner case 300.

The upper inner guide passage 300a may be formed such that the inner surface of the upper inner case 300 is depressed and protruded, and may be formed to guide water in the direction of the water collecting unit 180 (left and right directions of the case 110).

For example, the upper inner guide passage 300a is disposed between at least two peaks 310 protruding to the inside (downward) of the upper inner case 300 and between the peaks 310, and the upper inner case 300 It may include a bone (320) that is depressed to the outside (upper) of.

Here, the mountain 310 is formed long in the left and right direction of the case 110, and a plurality of mountains 310 are repeatedly disposed from the front to the rear of the case 110.

The mountain 310 is a portion protruding from the valley 320 so that water generated on the inner surface of the upper inner case 300 can flow into the valley 320. The valley 320 is formed lower than the mountain 310 between the mountain 310 and the mountain 310 to provide a path through which water is guided.

The peaks 310 and the valleys 320 are alternately arranged from the front to the rear of the case 110. When the temperature inside the case 110 falls below the dew point temperature, moisture inside the case 110 is saturated and dew is generated. This dew flows from the mountain 310 to the valley 320 and is stored in the valley 320. In particular, due to the cohesiveness of water and the adhesion between the water and the inner surface of the upper inner case 300, the dew is moved to the concave valley 320 rather than the protruding mountain 310.

In addition, when dew is stored in the valleys 320, and the mountains 310 and the valleys 320 are repeatedly arranged from the front to the rear of the case 110, the valley 320 is provided to the user located in front of the case 110. Visibility of the dew stored in is weakened. This is because the mountains 310 formed long from the left to the right of the case 110 obstruct the user's view.

Specifically, referring to FIG. 16B, the shape of the cross section of the mountain 310 (a cross section taking a line from the front to the rear of the case 110) may have an approximate right triangle.

More specifically, the mountain 310 may be formed by a first slope 311 and a second slope 312 extending from both ends of the base 313 and forming a vertex.

Here, the base 313 is an arbitrary line connecting the valleys 320 adjacent to each other.

The ratio of the lengths of the base 313, the first slope 311, and the second slope 312 (d3:d1:d2) may be 1.4 to 1.6: 1.9 to 2.1: 2.36 to 2.64. Therefore, when the Pythagorean theorem is applied, the base 313 and the first inclined side 311 have a shape of a right-angled triangle close to approximately 90 degrees of the inner angle.

And, the mountain 310 and the valley 320 are formed symmetrically with respect to the second slope 312.

When the mountain 310 and the valley 320 are formed in a square shape, the dew formed on the inner surface of the upper inner case 300 is difficult to move to the valley 320, so that dew forms on the mountain 310, and the user sees the dew. There is a problem that can be,

When the mountain 310 and the valley 320 are formed in a triangular shape, dew formed on the inner surface of the upper inner case 300 is easily moved to the valley 320. In particular, the dew formed on the inner surface of the upper inner case 300 has a large contact area on the surface between the first slope 311 and the second slope 312, and such a large contact area increases adhesion to dew. By improving, the dew is moved to the valley (320).

In particular, when the mountain 310 and the valley 320 are formed in a right triangle, the dew formed on the inner surface of the upper inner case 300 is more easily moved to the valley 320. Specifically, when the inner angle of the valley 320 (the angle between the first slope 311 and the second slope 312) increases, the dew formed at the vertex of the mountain 310 moves to the valley 320 It is difficult to do, and the inner angle of the valley 320 (if the first slope 311 and the second slope 312 are too small, the height of the mountain 310 is too high, so the strength of the upper inner case 300) This is because there is a problem of decreasing the thickness and increasing the thickness of the upper inner case 300.

Therefore, when the mountain 310 and the valley 320 are formed in a right triangle, the height of the mountain 310 is not too high, and the inner angle of the valley 320 (the first slope 311 and the second slope (312) by narrowing the angle between, it is possible to improve the adhesion between the water and the valley (320).

Preferably, the first slope 311 of the first slope 311 and the second slope 312 of the mountain 310 may be located in front of the case 110.

The vertex of the mountain 310 formed by the meeting of the first slope 311 and the second slope 312 is formed to be round, so that when dew is generated at the vertex of the mountain 310, the dew is caused by gravity. 110) can be prevented from falling into the interior.

In addition, when the vertex of the mountain 310 formed by meeting the first slope 311 and the second slope 312 is formed to be rounded, the dew generated at the vertex of the mountain 310 easily becomes the valley 320 Can be guided.

The pitch (P) between the peak 310 and the peak 310 is preferably 1.5mm to 2.5mm. When the pitch (P) between the mountain 310 and the mountain 310 is greater than 2.5mm, the dew formed on the inner surface of the upper inner case 300 does not easily move to the valley 320, and the mountain 310 and When the pitch P between the mountains 310 is less than 1.5mm, the valley 320 does not provide a sufficient space for the dew to gather, so that dew is visible to the naked eye.

In addition, the height of the mountain 310 is preferably 1.5mm to 2.5mm. If the height of the mountain 310 is too high, the strength of the upper inner case 300 is lowered, and if the height of the mountain 310 is too low, there is a problem that the valley 320 does not provide sufficient space for dew to collect. .

Referring back to FIG. 16A, the embodiment may further include an upper inner auxiliary passage 325 formed by intersecting the upper inner guide passage 300a and the inner surface of the upper inner case 300 being recessed.

The dew generated on the inner surface of the upper inner case 300 moves along the valleys 320 in the left and right directions of the case 110, and the movement of the case 110 to the front and rear is limited by the mountain 310. . When the amount of dew generated on the inner surface of the upper inner case 300 is excessive, it may not spread along the valleys 320 and may fall into the interior of the case 110.

The upper inner auxiliary passage 325 is formed to intersect with the mountain 310 and the valley 320, so that when the amount of dew generated on the inner surface of the upper inner case 300 is excessive, water is drained to the adjacent valley 320 It serves as a guide.

Specifically, the upper inner auxiliary passage 325 is formed long from the front to the rear of the case 110 and is formed to communicate with the valley 320.

17 is an exploded perspective view showing a case according to another embodiment of the present invention, FIG. 18 is a front view showing a state in which the lower inner case of the embodiment is coupled to the inside of the case, and FIG. 19 is a lower inner case of FIG. 17 A partial plan view as viewed from the inside of the case, and FIG. 20 is a partial cross-sectional view of the lower inner case according to the embodiment of FIG. 19.

17 and 18, the vegetable compartment 100B for a refrigerator according to the embodiment is located inside the case 110, the drawer 120, the water collecting part 180, and the lower surface 110c of the case. , Water generated on the inner surface of the lower inner case 400 and the lower inner case 400, which is inserted and fixed between the two side surfaces 110b of the case, is transferred to the water collecting unit 180 It includes a lower inner guide passage (400a) to guide.

Here, since the case 110, the drawer 120, and the water collecting unit 180 are the same as in the embodiment of FIG. 13, a description thereof will be omitted below.

The lower inner case 400 is positioned inside (above) the lower surface 110c of the case, and is fitted and fixed between both side surfaces 110b of the case.

The width of the lower inner case 400 is formed slightly larger than the width between both side surfaces 110b of the case, so that the lower inner case 400 may be fitted and fixed between the both side surfaces 110b of the case by its own elastic restoring force. .

For example, the lower inner case 400 includes a center portion 430 positioned at the center, two slope portions 450 extending upwardly inclined from the center portion 430 toward both side surfaces 110b of the case, and the slope It may include a wing portion 470 that is bent upward in the portion 450 and is in close contact with the side surface 110b of the case by an elastic force.

The center part 430 forms the center of the inner case 400 when it is lower.

The two slope portions 450 extend from the center portion 430 in the direction of both side surfaces 110b of the case. In addition, the two slope portions 450 are formed to be inclined upward from the center portion 430 toward both side surfaces 110b of the case, so that the dew generated on the inner surface (upper surface) of the lower inner case 400 is removed from the center portion 430 To flow.

In particular, as will be described later, when the lower inner guide passage 400a is formed long in the left and right direction of the case 110, the two slopes 450 are downward from both sides 110b of the case toward the center part 430 When formed to be inclined, the dew can be more easily guided to the center portion 430.

The wing portion 470 is in close contact with the side surface 110b of the case by an elastic force, and fixes the lower inner case 400 to the side surface 110b of the case.

The wing portion 470 may be bent upward at the slope portion 450 to have elasticity, and water guided along the side surface 110b of the case may be guided to the slope portion 450 through the wing portion 470. have.

More specifically, the wing portion 470 is formed to be rounded, and the thickness may be reduced as it progresses from the slope portion 450 to the end of the wing portion 470. When the thickness decreases as the wing portion 470 proceeds from the slope portion 450 to the end of the wing portion 470, the water guided from the side surface 110b of the case to the wing portion 470 is inside the case 110 Will not fall.

In addition, the lower inner case 400 may further include a through hole 435 through which the discharge valve 170 passes.

The through hole 435 is formed to correspond to the discharge valve 170, so that the discharge valve 170 penetrates and provides a place where water flowing through the upper surface of the inner case 400 falls into the water collecting part.

Specifically, the through hole 435 may be located in the center portion 430.

Referring to FIGS. 19 and 20, a lower inner guide passage 400a for guiding water generated on the inner surface (upper surface) of the lower inner case 400 to the water collecting unit 180 may be included.

The lower inner guide passage 400a is formed on the inner surface (upper surface) of the lower inner case 400 to guide water generated on the upper surface of the lower inner case 400 toward the water collecting part 180. In addition, the lower inner guide passage 400a serves to store the dew generated on the inner surface (upper surface) of the lower inner case 400 so that it is not visible to the naked eye.

The lower inner guide passage 400a may be formed on the inner surface (upper surface) of the lower inner case 400. Here, the inner surface of the lower inner case 400 means a surface exposed to the inside of the case 110 by inserting the lower inner case 400 into the case 110.

The lower inner guide passage 400a is continuously formed in the center portion 430, the slope portion 450, and the wing portion 470 of the lower inner case 400.

The lower inner guide passage 400a may be formed such that the inner surface of the lower inner case 400 is depressed and protruded, and may be formed to guide water in the direction of the water collecting unit 180 (left and right directions of the case 110).

For example, the lower inner guide passage 400a is disposed between at least two peaks 410 and the peaks 410 protruding to the inside (upper) of the lower inner case 400, and the lower inner case 400 It may include a bone 420 that is depressed outside (downward) of.

Here, the mountain 410 is formed long in the left-right direction of the case 110, and a plurality of mountains 410 are repeatedly disposed from the front to the rear of the case 110.

The mountain 410 is a portion protruding from the valley 420 so that water generated on the inner surface of the lower inner case 400 flows into the valley 420. The valley 420 is formed lower than the mountain 410 between the mountain 410 and the mountain 410 to provide a path through which water is guided.

The peaks 410 and valleys 420 are alternately arranged from the front to the rear of the case 110. When the temperature inside the case 110 falls below the dew point temperature, moisture inside the case 110 is saturated and dew is generated. This dew flows from the mountain 410 to the valley 420 and is stored in the valley 420. In particular, due to the cohesive force of water and the adhesion of the inner surface of the inner case 400 to the water, the dew is moved to the concave valley 420 rather than the protruding mountain 410.

In addition, when dew is stored in the valley 420, and the mountains 410 and the valley 420 are repeatedly arranged from the front to the rear of the case 110, the valley 420 to the user located in front of the case 110 Visibility of the dew stored in is weakened. This is because the mountain 410 formed long from the left to the right of the case 110 blocks the user's view.

Specifically, referring to FIG. 20, the shape of the cross section of the mountain 410 (a cross section taken along a line from the front to the rear of the case 110) may have an approximate right triangle.

More specifically, the mountain 410 may be formed by a first slope 411 and a second slope 412 extending from both ends of the base 413 and forming a vertex.

Here, the base 413 is an arbitrary line connecting the adjacent valleys 420 to each other.

The ratio of the lengths of the base 413, the first slope 411, and the second slope 412 (d3:d1:d2) may be 1.4-1.6: 1.9-2.1: 2.36-2.64. Therefore, when the Pythagorean theorem is applied, the base 413 and the first inclined side 411 have a shape of a right-angled triangle close to approximately 90 degrees of the inner angle.

In addition, the mountain 410 and the valley 420 are formed symmetrically with respect to the second slope 412.

When the mountain 410 and the valley 420 are formed in a square shape, the dew formed on the inner surface of the inner case 400 is difficult to move to the valley 420, so that dew forms on the mountain 410, and the user sees the dew. There is a problem that can be,

When the mountain 410 and the valley 420 are formed in a triangular shape, the dew formed on the inner surface of the inner case 400 is easily moved to the valley 420. In particular, the dew formed on the inner surface of the lower inner case 400 has a large contact area on the surface between the first slope 411 and the second slope 412, and such a large contact area increases adhesion to dew. By improving, the dew is moved to the valley (420).

In particular, when the mountain 410 and the valley 420 are formed in a right triangle, the dew formed on the inner surface of the inner case 400 is easily moved to the valley 420. Specifically, when the inner angle of the valley 420 (the angle between the first slope 411 and the second slope 412) increases, the dew formed at the vertex of the mountain 410 moves to the valley 420 It is difficult to do, and the inner angle of the valley 420 (if the first slope 411 and the second slope 412 are too small, the height of the mountain 410 is too high, so the strength of the inner case 400) This is because there is a problem of lowering and increasing the thickness of the inner case 400.

Therefore, when the mountain 410 and the valley 420 are formed in a right triangle, the height of the mountain 410 is not too high, and the inner angle of the valley 420 (the first slope 411 and the second slope (412) by narrowing the angle between, it is possible to improve the adhesion between the water and the valley (420).

Preferably, the first slope 411 of the first slope 411 and the second slope 412 of the mountain 410 may be located in front of the case 110.

The vertex of the mountain 410 formed by meeting the first slope 411 and the second slope 412 is formed to be rounded, so that when dew occurs at the vertex of the mountain 410, the dew is caused by gravity. 110) can be prevented from falling into the interior. In addition, when the vertex of the mountain 410 formed by meeting the first slope 411 and the second slope 412 is formed to be rounded, the dew generated at the vertex of the mountain 410 easily becomes the valley 420 Can be guided.

The pitch (P) between the peak 410 and the peak 410 is preferably 1.5mm to 2.5mm. If the pitch (P) between the mountain 410 and the mountain 410 is greater than 2.5mm, the dew formed on the inner surface of the inner case 400 cannot easily move to the valley 420, and the mountain 410 and When the pitch P between the mountains 410 is less than 1.5mm, the valley 420 does not provide a sufficient space for the dew to gather, so there is a problem that dew is visible to the naked eye.

In addition, the height of the mountain 410 is preferably 1.5mm to 2.5mm. If the height of the mountain 410 is too high, the strength of the inner case 400 is lowered, and if the height of the mountain 410 is too low, there is a problem that the valley 420 does not provide sufficient space for dew to collect. .

Again, referring to FIG. 19, the embodiment may further include a lower inner auxiliary passage 425 formed by crossing the lower inner guide passage 400a and the inner surface of the lower inner case 400 being recessed.

Then, the dew generated on the inner surface of the inner case 400 moves in the left and right direction of the case 110 along the valley 420, and the movement of the case 110 to the front and rear is limited by the mountain 410. . When the amount of dew generated on the inner surface of the inner case 400 is excessive, it may not spread along the valleys 420 and may fall into the interior of the case 110.

The lower inner auxiliary flow path 425 is formed to intersect with the mountain 410 and the valley 420, so that when the amount of dew generated on the inner surface of the lower inner case 400 is excessive, water is drained to another adjacent valley 420 It serves as a guide.

In addition, the lower inner auxiliary flow path 425 serves to guide the water stored in the valley 420 to the through hole 435. The water guided through the through hole 435 falls into the water collecting part 180.

Specifically, the lower inner auxiliary passage 425 is formed long from the front to the rear of the case 110 and is formed to communicate with the valley 420. In addition, the lower inner auxiliary flow path 425 may be formed to communicate with the through hole 435.

In the above, preferred embodiments of the present invention have been shown and described, but the present invention is not limited to the specific embodiments described above, and without departing from the gist of the present invention claimed in the claims, Various modifications may be possible by those of ordinary skill in the art, and these modifications should not be individually understood from the technical spirit or prospect of the present invention.

Claims (22)

A case in which an opening is formed in the front and a storage space that is a storage space for storage is formed therein;
A drawer for sealing the inside of the case;
A water collecting part formed on a lower surface of the case to collect water generated inside the case; And
It is formed on the inner surface of the case and includes a guide passage for guiding the water generated inside the case in one direction,
The guide flow path,
At least two mountains protruding inward of the case;
It is disposed between the mountains and includes a valley that is recessed to the outside of the case,
The mountains and valleys are alternately arranged from the front to the rear of the case,
Further comprising an auxiliary flow passage formed by crossing the guide passage and the inner surface of the case being recessed,
The auxiliary flow path is formed in parallel with the front and rear sides of the case,
The guide flow path is
An upper guide passage formed on the inner surface of the upper surface of the case,
Side guide passages formed on the inner surfaces of both side surfaces of the case,
It includes a lower surface guide passage formed on the inner surface of the lower surface of the case,
The peaks and valleys of the upper guide passage are formed long in the direction of both sides of the case,
The peaks and valleys of the side guide passage are formed long from the upper surface of the case toward the lower surface of the case,
The hills and valleys of the lower guide passage are formed in the direction of the collecting part,
The valley of the upper guide passage and the valley of the side guide passage are connected to each other,
A vegetable compartment for a refrigerator, wherein the upper surface of the case is formed to be inclined downward from the center toward both side surfaces of the case.
delete The method of claim 1,
The acid is,
It includes a base, a first slope extending from both ends of the base and forming a vertex, and a second slope,
The ratio of the length of the base of the mountain, the first slope and the second slope,
1.4~1.6: 1.9~2.1: 2.36~2.64 Vegetable room for refrigerator. The method of claim 3,
The vegetable compartment for a refrigerator is formed in a round shape at the peak of the mountain. delete delete delete delete delete delete delete delete delete delete delete delete delete The method of claim 1,
The water collecting part is formed by recessing the lower surface of the case,
The vegetable compartment for a refrigerator further includes a discharge valve configured to discharge water collected in the water collecting part to the outside of the case in the water collecting part. The method of claim 4,
Vegetable room for refrigerator, characterized in that the pitch between the mountain and the mountain is 1.5mm to 2.5mm. The method of claim 1,
Vegetable compartment for a refrigerator further comprising a decompression unit for forming a negative pressure inside the case. The method of claim 1,
Further comprising a reinforcing portion for reinforcing the strength of the case,
The reinforcement part,
Vegetable compartment for refrigerator, characterized in that it is a reinforcing member coupled to at least one surface of the case, located adjacent to the opening, and having a greater strength than the case.


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