KR101260559B1 - Refrigerator - Google Patents

Abstract

The present invention relates to a refrigerator. The refrigerator according to the present embodiment includes a cabinet forming a storage space; A barrier partitioning the storage space into a refrigerating compartment and a freezing compartment and having a foam insulation formed by filling a foam liquid therein; Recessed in the freezer compartment side of the barrier, the recess which accommodates the evaporator and fan motor assembly; The depression is provided in the foam insulation and a different material, and includes a heat insulating material to insulate between the depression and the refrigerating chamber.

Description

Refrigerator {Refrigerator}

This embodiment relates to a refrigerator.

In general, a refrigerator is a home appliance that allows food to be stored at a low temperature in an interior storage space shielded by a door, and is stored by cooling the inside of the storage space using cold air generated through heat exchange with a refrigerant circulating in a refrigeration cycle. It is configured to keep foods in optimal condition.

Such refrigerators are becoming larger and more versatile as the dietary changes and user's preferences are diversified.

In general, the storage space inside the refrigerator is partitioned by the barrier to form a refrigerating compartment and a freezing compartment, and its shape may be variously configured according to the arrangement of the refrigerating compartment and the freezing compartment.

Of these refrigerators, side by side type refrigerators are arranged side by side on the left and right sides of the refrigerating compartment and the freezing compartment, respectively, and are configured to be individually opened and closed by the refrigerating compartment door and the freezing compartment door.

The side-by-side type refrigerator is usually configured to supply cold air to the refrigerating compartment and the freezing compartment by providing an evaporator at the rear of the refrigerating compartment and / or the freezing compartment. However, the internal volume of the refrigerator is reduced as much as the space where the evaporator is mounted.

In order to solve such a problem, Korean Patent No. 10-039849 discloses a refrigerator provided with an evaporator and a cold air circulation fan in a barrier that divides an inner space into a refrigerator compartment and a freezer compartment.

However, in such a refrigerator, there is a problem that the temperature of the refrigerating chamber is lowered because the barrier of the barrier equipped with the evaporator and the cold air circulation fan is not made. In addition, there is a problem that circulation of cold air flowing in a narrow space inside the barrier is not smooth.

An object of the present embodiment is to provide a refrigerator that can improve the high volumetric capacity while maintaining the thermal insulation performance of the barrier.

Another object of the present embodiment is to provide a refrigerator to smooth the flow of cold air while maintaining the thermal insulation performance of the barrier.

Refrigerator according to the present embodiment, the cabinet to form a storage space; A barrier partitioning the storage space into a refrigerating compartment and a freezing compartment and having a foam insulation formed by filling a foam liquid therein; Recessed in the freezer compartment side of the barrier, the recess which accommodates the evaporator and fan motor assembly; The depression is provided in the foam insulation and a different material, and includes a heat insulating material to insulate between the depression and the refrigerating chamber.

The depression may further include an evaporator accommodating part in which the evaporator is accommodated; A fan motor assembly accommodating portion formed in the recess above the evaporator accommodating portion and accommodating the fan motor assembly; It is formed above the fan motor assembly accommodating part, and includes a flow path part for guiding cold air to the storage space.

In addition, the foam insulation is characterized in that the evaporator receiving portion is formed thicker than the fan motor assembly receiving portion.

In addition, the recess, characterized in that the evaporator is further formed to connect the inclined portion and the fan motor assembly accommodating portion.

In addition, the fan motor assembly is characterized in that it comprises a centrifugal fan blowing in the circumferential direction at the center of rotation.

In addition, the heat insulating material is characterized in that the vacuum heat insulating material.

In addition, the heat insulating material is characterized in that attached to the barrier outer surface corresponding to the depression.

In addition, the heat insulating material is characterized in that it is formed in a shape corresponding to the shape of the depression.

In addition, the insulation is characterized in that provided in the fan motor assembly receiving portion.

The heat insulating material may include a first heat insulating material attached to the evaporator accommodating part and a second heat insulating material attached to the fan motor assembly, wherein the second heat insulating material is formed thicker than the first heat insulating material. It is done.

In addition, the heat insulating material is characterized in that it is provided inside the in-case forming the outer shape of the barrier.

The refrigerator according to the present exemplary embodiment is configured such that an evaporator accommodating part of the recess formed in the barrier filled with the heat insulating material is formed to be stepped with the fan motor assembly accommodating part.

Therefore, the evaporator is mounted so that the heat insulating material can be formed thicker in the portion where the temperature is relatively low, thereby not affecting the temperature change in the refrigerating chamber.

Then, the location of the evaporator to the freezer compartment side can minimize the thickness of the overall barrier while maintaining the insulation performance of the refrigerator compartment side.

In addition, the fan motor assembly accommodating portion is further recessed to secure a space in which the cold air of the evaporator can be introduced into the blower fan, thereby improving the flowability of the cold air.

In addition, since the fan motor assembly accommodating portion and the cold air flow portion are formed in the barrier, the flow of the cold air in the barrier can be made smoother and the overall structure of the barrier can be simplified.

In addition, a heat insulating material different from the foamed heat insulating material inside the barrier may be provided in a recess in which the thickness of the barrier is relatively thin, thereby improving the heat insulating performance of the barrier.

In addition, heat insulation at the recessed portion, which is relatively insulated, is possible, and thus the temperature of the refrigerating compartment can be maintained. In addition, the heat insulation performance is maintained by the additional heat insulation by the heat insulator, so that a plurality of components including the evaporator and the fan motor assembly are provided inside the barrier, thereby maintaining the thickness of the barrier. Therefore, the high internal volume by the barrier is prevented from decreasing.

1 is a perspective view of a refrigerator according to the present embodiment.
2 is a perspective view of an open door according to the present embodiment.
3 is an exploded perspective view of the barrier according to the present embodiment.
4 is a cross-sectional view taken along line II ′ of FIG. 1.
5 is a front view showing the shape of the depression of the barrier according to the present embodiment.
FIG. 6 is a cutaway perspective view of II-II ′ of FIG. 7.
7 is a view of the cold air flow state of the barrier viewed from the freezer side.
8 is a view of the cold air flow state of the barrier viewed from the refrigerating chamber side.
9 is a cutaway perspective view of a barrier according to another embodiment.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings. However, the spirit of the present invention is not limited to the embodiments presented, and other embodiments included within the scope of other inventive inventions or the scope of the present invention can be easily made by adding, changing, or deleting other elements. I can suggest.

1 is a perspective view of a refrigerator according to the present embodiment. 2 is a perspective view of an open door according to the present embodiment.

Referring to FIG. 1, a refrigerator 1 according to an exemplary embodiment of the present invention is formed by a cabinet 10 that forms a storage space and a door 20 that opens and closes the storage space.

The cabinet 10 is formed in a hexahedral shape that is opened forward, and is divided into left and right sides by the barrier 100 to form a freezing chamber 30 and a refrigerating chamber 40, respectively. A plurality of drawers and shelves are provided inside the refrigerating compartment 40 and the freezing compartment 30 so that various foods may be stored therein.

In addition, the door 20 has a refrigerator compartment door 22 and a refrigerator compartment 30 respectively corresponding to the opened front surface of the refrigerator compartment 40 so as to shield the refrigerator compartment 40 and the freezer compartment 30, respectively. And a freezer compartment door 24 corresponding to the front surface.

The refrigerating compartment door 22 and the freezing compartment door 24 are rotatably mounted to the cabinet 10, respectively, and are rotated by the refrigerating compartment door 22 and the freezing compartment door 24. 30) can be configured to open and close. In addition, a plurality of baskets for storing food may be provided at the rear of the refrigerating compartment door 22 and the freezing compartment door 24, and the ice maker, the dispenser, and the home bar may be provided at the refrigerating compartment door 22 and the freezing compartment door 24. Etc. can be provided as needed.

On the other hand, the barrier 100 is formed in the storage space formed in the cabinet 10 in the vertical direction to form the freezing chamber 30 and the refrigerating chamber 40 on both sides. The barrier 100 is formed to be insulated so that heat exchange does not occur between the freezing chamber 30 and the refrigerating chamber 40.

Hereinafter, the barrier will be described in more detail with reference to the accompanying drawings.

3 is an exploded perspective view of the barrier according to the present embodiment. 4 is a cross-sectional view taken along line II ′ of FIG. 1. And, Figure 5 is a front view showing the shape of the depression of the barrier according to the embodiment. 6 is a cutaway perspective view of II-II ′ of FIG. 5.

Referring to FIGS. 3 to 6, the barrier 100 is formed to be vertically long inside the cabinet 10, and an evaporator 110 and a fan motor assembly 130 are mounted therein.

The barrier 100 has an outer shape formed by an in case 150 forming an inner space of the refrigerating compartment 40 and the freezing compartment 30, and is filled with a foam liquid inside the in case 150 to expand the foam insulation. 300 will be formed. The foam insulation 300 is evenly filled in the interior space of the barrier (100).

The foamed heat insulating material 300 may be filled in the entire interior of the barrier 100 formed by the in case 150, and if necessary, the foamed heat insulating material 300 may correspond to a portion provided with the heat insulating material 500 to be described below. Some of the portions may not be filled with the foam insulation (300).

On the other hand, the barrier 100 is formed with a depression 200 that is recessed in the freezing chamber 30 side. The depression 200 is formed by recessing one side of the barrier 100 and is formed by opening toward the freezing chamber 30. The depression 200 provides a space in which the evaporator 110 and the fan motor assembly 130 to be described below are accommodated.

In detail, the recess 200 is an evaporator accommodating part 210 in which an evaporator 110 for generating cold air is accommodated. The fan motor assembly accommodating part 220 accommodating the fan motor assembly 130 for the circulation of the cold air, and the cold air oil for supplying the cold air generated in the evaporator 110 to the refrigerating chamber 40 and the freezing chamber 30. East 230 may be configured.

The evaporator accommodating part 210 is formed below the barrier 100, and is formed larger than the evaporator 110 to completely accommodate the evaporator 110, and is larger than the thickness of the evaporator 110. Depressions can be formed.

The evaporator 110 may be configured such that the refrigerant pipes 112 are arranged in a row on the same upper and lower lines so as to be accommodated inside the evaporator accommodating part 210. If necessary, a header may be provided at both left and right sides, and a multiflow channel type heat exchanger may include a refrigerant pipe configured to form a flow path of the refrigerant between the headers.

On the other hand, the evaporator accommodating portion 210 is formed recessed enough depth so that the evaporator 110 does not protrude out of the barrier 100 when the evaporator 110 is mounted. The evaporator 110 may be fixedly mounted to the evaporator accommodating part 210 by a separate fixing member or a fixing structure.

In addition, a cold air inlet 212 is formed at a lower end of the evaporator accommodating part 210. The cold air inlet 212 is a passage through which cold air inside the refrigerating chamber 40 flows, and may be formed at a rear side of the evaporator accommodating part 210.

An inlet grill 214 is formed outside the cold air inlet 212 to prevent foreign substances from flowing in from the outside. The cold air inlet 212 may be formed at a position corresponding to a position at which a drawer provided in the refrigerating compartment 40 is provided, such that the cold air inlet 212 is not exposed from the outside when the refrigerating compartment door 22 is opened.

And, the lower surface of the evaporator accommodating portion 210 may be further formed a defrost water guide member 120 for discharging the defrost water generated during defrost operation. Defrost water guide member 120 is formed to be inclined, it may be formed to communicate with the machine room of the cabinet (10).

The defrost water guide member 120 may be formed as a separate member and mounted below the evaporator accommodating part 210 corresponding to the bottom of the evaporator 110. The lower end may be formed to be inclined and may have the same shape as the defrost water guide member 120.

On the other hand, the fan motor assembly accommodating portion 220 is formed above the evaporator accommodating portion 210. The fan motor assembly accommodating part 220 provides a space in which the fan motor assembly 130 is accommodated. In addition, the fan motor assembly 130 disposed in the fan motor assembly accommodating part 220 may include a motor 132, a blowing fan 134, and a shroud 136.

In detail, the motor 132 provides power for driving the blower fan 134, and an electric motor generally used may be used. In addition, the blowing fan 134 is mounted on the rotation shaft of the motor 132. The blowing fan 134 may be a centrifugal fan capable of discharging cold air introduced in the rotational axis direction in the circumferential direction, and a turbo fan having excellent blowing ability may be used.

In addition, the motor 132 and the blowing fan 134 are disposed at the center of the fan motor assembly accommodating part 220. The motor 132 on which the blowing fan 134 is mounted may be fixedly mounted to the fan motor assembly accommodating part 220 through a separate mounting member.

The fan motor assembly accommodating part 220 is provided with a shroud 136. The shroud 136 is formed to guide the inflow of cold air into the blowing fan 134 and the cold air discharged from the blowing fan 134.

That is, the shroud 136 accommodates the blowing fan 134 inside, the inlet 137 is opened in the rotation center direction of the blowing fan 134, the cold air flow portion to be described in detail below The discharge port 139 is formed to open in the direction. In addition, the remaining part is shielded and configured to allow the cool air introduced through the inlet 137 to be discharged to the discharge port 139 through the blower fan 134.

The shroud 136 may be mounted to the fan motor assembly accommodating part 220 or may be mounted to the barrier cover 400 to be described below. Of course, if necessary, the shroud 136 may be integrally formed on the barrier cover 400. In addition, the motor 132 coupled with the blowing fan 134 may be fixedly mounted inside the shroud 136.

In addition, cold air guides 222 are further formed at both sides of the fan motor assembly accommodating part 220. The cold air guide part 222 allows the cold air on the evaporator accommodating part 210 to both face the inside of the shroud 136. To this end, the cold air guide portion 222 is formed to be narrower from the lower side toward the upper side.

In detail, the lower end of the fan motor assembly accommodating part 220 has the same width as the upper end of the evaporator accommodating part 210, and the upper end of the fan motor assembly accommodating part 220 is a cold air flow part 230 to be described below. It is formed to have the same width as the bottom of. In this case, an upper end of the fan motor assembly accommodating part 220 is formed to have the same width as the discharge port 139 of the shroud 136.

The cold air guide 222 may be formed to be inclined or may have a round shape, and the cold air moved along the cold air guide 222 may be guided into the shroud 136.

Meanwhile, the fan motor assembly accommodating part 220 is formed to be recessed more than the evaporator accommodating part 210 and the cold air flow part 230 to be described below. In this case, the fan motor assembly accommodating part 220 is formed to be spaced apart from the shroud 136. Therefore, the cool air flowing from the evaporator receiver 210 side can be smoothly moved to the inlet 137 side through the spaced space between the fan motor assembly receiver 220 and the shroud 136. do.

Since the evaporator accommodating part 210 and the fan motor assembly accommodating part 220 have different recessed depths, the evaporator accommodating part 210 and the fan motor assembly accommodating part 220 are formed to be stepped with each other. Therefore, the thickness of the foam insulation 300 inside the barrier 100 corresponding to the evaporator accommodating part 210 and the fan motor assembly accommodating part 220 is also different from each other.

In detail, since the evaporator accommodating portion 210 is less recessed than the fan motor assembly accommodating portion 220, the thickness of the foam insulation 300 corresponding to the evaporator accommodating portion 210 becomes thicker. . Therefore, the heat insulation on the side of the evaporator 110 having a lower temperature can be made better.

In addition, since the fan motor assembly accommodating part 220 is more recessed than the evaporator accommodating part 210, the thickness of the foam insulation 300 corresponding to the evaporator accommodating part 210 becomes relatively thinner. . Therefore, when the fan motor assembly 130 is mounted, it is possible to secure a smooth flow passage of cold air.

Meanwhile, the stepped portion of the evaporator accommodating part 210 and the fan motor assembly accommodating part 220 is connected by the connecting part 240. The connection part 240 forms a boundary between the evaporator accommodating part 210 and the fan motor assembly 130 and is formed to be inclined. Therefore, the cool air inside the evaporator accommodating part 210 may be smoothly introduced into the fan motor assembly accommodating part 220.

The cold air flow part 230 is formed above the fan motor assembly accommodating part 220. The cold air flow unit 230 is used to guide the cold air discharged from the discharge port 139 of the shroud 136 to the refrigerating chamber and the freezing chamber 30, and extends to an upper portion of the barrier 100.

The cold air flow part 230 is formed to have a width corresponding to the width of the opened upper end of the fan motor assembly accommodating part 220, or to have a width corresponding to the width of the discharge port 139 of the shroud 136. It can be formed to have.

The cold air flow part 230 is formed to be less recessed than the fan motor assembly accommodating part 220. Accordingly, the thickness of the foam insulation 300 at the position corresponding to the cold air flow part 230 may be formed to be thicker than the thickness of the insulation at the position corresponding to the fan motor assembly accommodating portion 220.

The cold air flow unit 230 forms a cold air flow path by being shielded by the barrier cover 400 to be described below. In addition, a cold air outlet 232 is formed at an upper end of the cold air flow part 230. The cold air outlet 232 may be located at the upper center of the barrier 100 and may be exposed to the refrigerating chamber 40. The cold air outlet 232 may further include an outlet grill 234 for guiding the direction of the discharged cold air.

Meanwhile, the cold air flow unit 230 corresponding to the cold air outlet 232 is provided with a cold air distribution device 140. The cold air distribution device 140 is for selectively supplying the cold air supplied from the cold air flow unit 230 to the cold air outlet 232, and is formed to have a size corresponding to the cold air outlet 232.

The cold air distribution device 140 may be formed as a damper-like structure, and the passage to the cold air outlet 232 is selectively opened and closed. Therefore, when the cold air distribution device 140 is opened, the cold air guided through the cold air flow unit 230 may be discharged to the cold air outlet 232 and introduced into the refrigerating compartment. On the other hand, when the cold air distribution device 140 is closed, the cold air guided through the cold air flow unit 230 is not discharged to the cold air outlet 232 side but discharged only to the freezing chamber 30 side.

On the other hand, the depression 200 is provided with a different heat insulating material 500 different from the foam heat insulating material 300. The heat insulator 500 is to compensate for the heat insulation of the recess 200 having a relatively thin thickness than the other parts of the barrier 100, and may be formed in a thin sheet or plate shape.

The heat insulating material 500 is formed of a material having a high efficiency as compared with the foam heat insulating material 300. For example, the insulation 500 may be a vacuum insulation panel (Vaccum Insulation Panel).

The vacuum insulator has a core material in which a vacuum state is imparted to the inside of the shell material having a low gas permeability, and has a relatively high heat insulation performance while being relatively thin as compared with polyurethane or styrofoam.

Therefore, the area in which the insulation 500 is attached can reduce the filling amount of the foam insulation 300, and thus the barrier 100 corresponding to the thickness of the depression 200, that is, the depression 200. It becomes possible to make thickness of more slim.

On the other hand, the heat insulating material 500 is attached to the outer surface of the in-case 150 forming the barrier (100). In addition, the heat insulating material 500 may be formed in a shape corresponding to the shape of the depression part 200 to be attached to the inside of the depression part 200.

The heat insulating material 500 is a first heat insulating material 510 formed in a shape corresponding to the shape of the evaporator accommodating portion 210 and a second shape formed in a shape corresponding to the shape of the fan motor assembly accommodating portion 220. The heat insulating material 520 and the third heat insulating material 530 formed in a shape corresponding to the cold air flow part 230 may be formed.

In addition, the first insulation 510 may be attached to the evaporator accommodating portion 210, and the second insulation 520 may be attached to the fan motor assembly accommodating portion 220. In addition, the third insulating material 530 may be attached to the cold air flow part 230.

On the other hand, the second heat insulating material 520 may be formed thicker than the first heat insulating material 510 and the second heat insulating material 520 in the fan motor assembly accommodating portion 220 having the relatively small thickness. However, the fan motor assembly accommodating part 220 to which the second insulating material 520 is attached is provided so that the cold air supplied to the fan motor assembly accommodating part 220 may be smoothly moved past the evaporator accommodating part 210. The space of) may be provided at a position recessed inward from the evaporator accommodating portion 210 to which the first insulation 510 is attached.

In addition, since the cold air flow part 230 is relatively thick, the third heat insulating material 530 may be formed thinner than the first heat insulating material 510 and the second heat insulating material 520.

As described above, the heat insulating material 500 may be separately formed into the first heat insulating material 510, the second heat insulating material 520, and the third heat insulating material 530. And, each of these insulation 500 is attached to both the evaporator receiver 210 and the fan motor assembly receiver 220 and the cold air flow 230.

However, depending on the thickness of the barrier 100, the heat insulating material 500 may be mounted only on at least one side of the evaporator accommodating part 210, the fan motor assembly accommodating part 220, and the cold air flow part 230. . In this case, the heat insulating material 500 may be formed to have a shape corresponding to the portion to which it is attached.

In addition, the heat insulating material 500 may be formed in one sheet shape corresponding to the overall shape of the recess 200. In this case, the heat insulating material 500 may be attached over the entire area of the depression 200.

On the other hand, the depression 200 is shielded by the barrier cover 400. The barrier cover 400 is formed in a plate shape and shields the recess 200 to form a part of the side surface of the barrier 100, that is, a part of the inner wall surface of the freezing chamber 30. In addition, the barrier cover 400 forms the same plane as the side surface of the barrier 100 when the barrier cover 400 is mounted on the barrier 100.

The barrier cover 400 may be entirely formed of one plate, and may be divided into a plurality of parts as necessary. When divided into a plurality of portions may be divided into a portion covering the evaporator accommodating portion 210 and a portion covering the fan motor assembly 220 and the cold air flow portion 230.

In addition, the side surface of the barrier 100 facing the surface on which the barrier cover 400 is mounted is also formed in a flat shape without protruding to the outside to form a part of the inner wall surface of the refrigerating chamber 40. Therefore, both sides of the barrier 100 may be formed in a planar shape.

In addition, a rear surface of the barrier cover 400 corresponding to the evaporator 110 may contact the evaporator 110 to fix the evaporator 110 in close contact, and a mounting guide having a shape corresponding to the evaporator 110 may be provided. A 420 may be formed to assist in fixing the evaporator 110.

In addition, a rear surface of the barrier cover 400 corresponding to the fan motor assembly accommodating part 220 may shield an opened portion of the freezing compartment 30 side of the fan motor assembly accommodating part 220 so that cool air may be exposed to the shroud. To be guided to the inlet 137 of 136.

In addition, a rear surface of the barrier cover 400 corresponding to the cold air flow part 230 may shield a portion of the cold air flow part 230 that is open to the freezing compartment 30 to form a flow path through which cold air may flow. Done.

Meanwhile, a cover inlet 430 is formed at a lower end of the barrier cover 400 corresponding to the evaporator accommodating part 210. The cover inlet 430 guides the cold air of the freezer compartment 30 to the evaporator accommodating part 210 as a portion where cold air flows.

In addition, a plurality of cover outlets 410 are formed on the barrier cover 400 corresponding to the cold air flow part 230. The cover outlet 410 may be formed in plural at regular intervals, and the cold air flowing through the cold air flow unit 230 may be introduced into the freezing compartment 30.

Meanwhile, mounting portions 440 for mounting the barrier cover 400 are further formed at both ends of the barrier cover 400, and a coupling member is fastened to the mounting portion 440 so that the barrier cover 400 is mounted. Can be fixed to the side of the barrier (100). The side surface of the barrier 100 corresponding to the mounting portion 440 may be recessed to prevent the mounting portion 440 from protruding to the outside.

Hereinafter, the operation of the refrigerator according to the embodiment of the present invention having the above configuration will be described with reference to the accompanying drawings.

7 is a view of the cold air flow state of the barrier viewed from the freezer side. 8 is a view of a cold air flow state of the barrier viewed from the refrigerating chamber side.

7 and 8, when power is applied to the refrigerator 1, a refrigeration cycle inside the refrigerator 1 is driven. Cold air is generated in the evaporator 110 by driving of the refrigeration cycle.

First, referring to FIG. 7, the cold air is supplied to the freezing compartment 30. In order to supply cold air to the freezing compartment 30, the blowing fan 134 is driven by driving the motor 132. The cold air of the freezer compartment 30 introduced into the cover inlet 430 by the driving of the blower fan 134 is heat-exchanged in the evaporator 110 to become a cooler cold state, and the driving of the blower fan 134. Is moved upwards.

The cold air moved upward from the evaporator accommodating part 210 is moved into the fan motor assembly accommodating part 220 along the connection part 240, and the shroud is guided by the cold air guiding part 222. Flows into the inlet 137 of 136.

The cold air introduced into the shroud 136 is discharged to the discharge port 139 of the shroud 136 and guided to the cold air flow part 230. The cold air guided to the cold air flow part 230 is supplied to the freezing compartment 30 through a cover outlet 410 formed in the barrier cover 400.

At this time, the cover outlet 410 is formed in a plurality of up and down, through the plurality of the cover outlet 410 it is possible to evenly discharge the cold air in the freezer compartment (30). The cold air discharged as described above cools the inside of the freezing compartment 30, and the cold air of the freezing compartment 30 is circulated through the cover inlet 430 while the blower fan 134 is driven. do.

In addition, since the cold air distribution device 140 provided at the cold air outlet 232 is in a closed state, cold air is not supplied to the refrigerating compartment 40, and only cold air is supplied to the freezing compartment 30.

Meanwhile, the evaporator accommodating part 210, the fan motor assembly accommodating part 220, and the cold air flow part 230 may be shielded by the barrier cover 400 made of a relatively thin plastic material. Therefore, the cold air of the evaporator 110 itself or the cold air moved in the recess 200 may be transferred by the conduction to the inside of the freezing chamber 30 by the barrier cover 400.

Referring to FIG. 8, when the cool air is supplied to the refrigerating chamber 40, the blower fan 134 is driven by driving the motor 132 to supply the cool air to the refrigerating chamber 40. The cold air of the freezing compartment 30 and the refrigerating compartment 40 introduced into the cover inlet 430 and the cold air inlet 212 by the driving of the blower fan 134 is heat-exchanged in the evaporator 110, so that the cold air is further cooled. In response to the driving of the blower fan 134, it is moved upwards.

The cold air moved upward from the evaporator accommodating part 210 is moved into the fan motor assembly accommodating part 220 along the connection part 240, and the shroud is guided by the cold air guiding part 222. Flows into the inlet 137 of 136.

The cold air introduced into the shroud 136 is discharged to the discharge port 139 of the shroud 136 and guided to the cold air flow part 230. The cold air guided to the cold air flow part 230 is supplied to the freezing chamber 30 through a cover outlet 410 formed in the barrier cover 400.

At this time, the cover outlet 410 is formed in a plurality of up and down, through the plurality of the cover outlet 410 it is possible to evenly discharge the cold air in the freezer compartment (30). The cold air discharged as described above cools the inside of the freezing compartment 30, and the cold air of the freezing compartment 30 is circulated through the cover inlet 430 while the blower fan 134 is driven. do.

In addition, the cold air guided through the cold air flow unit 230 is supplied to the cold air distribution device 140 at the upper end of the cold air flow unit 230. In the state for supplying cold air to the refrigerating chamber 40, the cold air distribution device 140 is open. Therefore, cold air is discharged to the cold air outlet 232 through the cold air distribution device 140.

The cold air supplied into the refrigerating compartment 40 through the cold air outlet 232 cools the inside of the refrigerating compartment 40, and through the cold air inlet 212 while the blower fan 134 is driven. The cold air of the refrigerating chamber 40 may be circulated while the cold air is introduced again.

On the other hand, the inner side of the barrier 100 is formed with a foam heat insulating material 300, to block the transmission of cold air by the conduction on the freezing chamber 30 side. In addition, the heat insulation performance of the movement path of the cold air generated by the evaporator 110 and the evaporator 110 is compensated for by the heat insulating material 500 attached to the inside of the recess 200 having a relatively thin thickness.

Therefore, heat transfer between the refrigerating chamber 30 and the depression 200 inside the barrier 100 and the refrigerating chamber 40 can be blocked, so that the refrigerating chamber 40 can maintain a constant temperature inside the refrigerator. .

On the other hand, the refrigerator according to the present invention will be possible other embodiments in addition to the above-described embodiment.

Hereinafter, another embodiment of the present invention will be described. Another embodiment of the present invention is characterized in that the heterogeneous insulation is further provided inside the barrier in which the foam insulation is formed. Therefore, since only the internal structure of the barrier is different, other configurations are the same as in the above-described embodiment, and thus the detailed description of the same configuration will be omitted and the same reference numerals will be used.

9 is a cutaway perspective view of a barrier according to another embodiment.

Referring to FIG. 9, the barrier 100 has an outer shape formed by the in case 150. The depression part 200 is formed in the barrier 100 at the side of the freezer compartment, and the depression part 200 includes the evaporator accommodating part 210, the fan motor assembly accommodating part 220, and the cold air flow part 230. It can be composed of).

In addition, a foamed heat insulating material 300 is formed inside the in case 150 by filling a foaming liquid. The foam insulation 300 is evenly formed in the entire interior of the barrier 100, as well as the position corresponding to the depression 200.

In addition, the inside of the case 150 is provided with a heat insulating material 600 different from that of the foamed heat insulating material 300. The heat insulating material may be formed of the same vacuum heat insulating material as the heat insulating material 500 in the above-described embodiment.

In addition, the heat insulating material 600 may be attached to an inner surface of the in case 150. The heat insulating material may be attached to and fixed to an inner surface of the in case 150 forming the depression 200.

In addition, the heat insulating material 600 may be provided at the center of the barrier 100 forming both sides of the barrier 100, and may be fixed by the foam heat insulating material 300 formed by injection of a foam liquid.

As described above, the heat insulating material 600 is provided inside the barrier 100 before the foam heat insulating material 300 is formed, and after the heat insulating material 600 is provided, the foam heat insulating material 300 is injected by the injection of the foam liquid. ) May be formed.

In addition, the heat insulating material 600 may be formed in a shape corresponding to the recess 200, and may be formed at a position corresponding to the recess 200. In addition, the heat insulating material 600 includes a first heat insulating material 610, a second heat insulating material 620, and a third corresponding to the evaporator accommodating part 210, the fan motor assembly accommodating part 220, and the cold air flow part 230. It may be composed of a heat insulating material (630).

In addition, if necessary, the heat insulating material 600 may be formed in a shape corresponding to at least one of the evaporator accommodating part 210, the fan motor assembly accommodating part 220, and the cold air flow part 230. It may be provided at a position.

100. Barrier 200. Recession
210. Evaporator Receptacle 220. Fan Motor Assembly Receptacle
230. Cold air flow section 300. Foam insulation
500,600. Insulation 510,610. 1st insulation
520,620. Second insulation 530,630. 3rd insulation

Claims (11)

A cabinet forming a storage space;
A barrier case partitioning the storage space into a refrigerating compartment and a freezing compartment, and having a foam insulation formed by filling a foam liquid therein;
A depression recessed in the freezer compartment side of the barrier case;
An evaporator provided in the depression and configured to generate cold air;
A blowing fan disposed at one side of the evaporator and providing a blowing force to allow cold air to flow through the evaporator;
A barrier cover coupled to the barrier case and shielding one side of the evaporator and the blower fan;
A motor coupled to the inside of the barrier cover and providing a driving force to the blowing fan; And
A refrigerator including a vacuum insulator provided at a position corresponding to the depression on the inner side or the outer side of the barrier case. The method of claim 1,
Wherein the depression comprises:
An evaporator accommodating part in which the evaporator is accommodated;
A fan motor assembly accommodating portion formed in the recess above the evaporator accommodating portion and accommodating the fan motor assembly;
And a flow path part formed above the fan motor assembly accommodating part and configured to guide cold air to the storage space. The method of claim 2,
The foam insulation,
And a thicker at a position corresponding to the evaporator accommodating portion than the fan motor assembly accommodating portion. The method of claim 2,
Wherein the depression comprises:
The refrigerator characterized in that the evaporator is further formed to connect the inclined portion and the fan motor assembly accommodating portion. The method of claim 1,
The blowing fan is a refrigerator, characterized in that the centrifugal fan. delete delete The method of claim 1,
The vacuum insulator is formed in a shape corresponding to the shape of the depression. The method of claim 2,
And the vacuum insulator is provided in the fan motor assembly accommodating portion. The method of claim 2,
The vacuum insulator,
A first heat insulating material attached to the evaporator accommodating part,
It is configured to include a second insulating material attached to the fan motor assembly,
The second heat insulating material is a refrigerator, characterized in that formed thicker than the first heat insulating material. delete

Images