KR200143549Y1 - Guide device for cool air flow of a refrigerator - Google Patents

Abstract

Air flow guide device of the refrigerator according to the present invention, in the cold air flow guide device of the refrigerator, the blowing fan 52 so that the cold air heat exchanged through the evaporator 70 is guided in the direction of rotation of the blowing fan 52 ) And the flow of cold air heat exchanged through the inner guide rib 310 and the evaporator 70 installed between the one side wall of the cabinet 10 and the inner side is guided in the rotational direction of the blower fan 52. Since the guide ribs 141 and the outer guide ribs 320 are installed at positions that surround both sides and the upper portion of the blowing fan 52, it is possible to flow the flow of cold air regularly, thereby In addition to minimizing the impact of irregular cold air can eliminate the reflux of cold air.

Description

Refrigeration air flow guide device

1 is a longitudinal cross-sectional view showing a conventional refrigerator.

Figure 2 is a schematic diagram showing the installation state of the conventional cold air flow guide plate.

3 is a schematic view showing the installation state of the cold air flow guide plate according to the present invention.

* Explanation of symbols for main parts of the drawings

10: cabinet 30: freezer

52: blower fan 70: evaporator

300: cold air flow guide plate 310: inner guide rib

311: vertical plane 312: horizontal plane

313: slope 320: outer guide rib

321: first vertical surface 322: horizontal surface

323: second vertical surface 324: inclined surface

The present invention relates to a cold air flow guide device of the refrigerator, and more particularly, to the cold air flow guide device of the refrigerator, in which cold air heat exchanged while passing through the evaporator is guided to one side by the cold air flow guide plate to easily flow into the refrigerating chamber. It is about.

Conventional refrigerators, as shown in Figure 1, the object required for freezing and refrigeration (e.g., stored food and storage at the upper and lower portions through the intermediate member 20 on the inner middle side of the cabinet 10, as shown in FIG. Containers and the like), and the freezing and refrigerating chambers 30 and 40 are partitioned into a predetermined space so as to store and freeze and refrigerate, and the air flow inside the freezing and refrigerating chambers 30 and 40 is located at the rear side of the freezing chamber 30. Cool air circulation means (50) is provided so as to forcibly circulate the air, and the rear side in the freezing chamber (30) at a rearward of the rear wall of the cabinet (10) of the cold air circulation means (50) The damper cover having cold air discharge and suction holes 61 and 62 is formed to guide the flow of cold air blown with operation and to form a cold air environment path in which the cold air is discharged to the upper side of the freezing chamber 30 and sucked downward. 60 is provided.

At this time, the cold air circulation means 50 is a blown motor 51 is driven by receiving power, the blower fan 52 is rotated in accordance with the drive of the blower motor 51, and the blower motor 51 It consists of a bracket (53) fixed to the cabinet (10).

On the other hand, in the lower portion of the cold air circulation means 50 with respect to the damper cover 60 and the cabinet 10 is freezing and refrigerating chamber 30, 40 circulated by the blowing force of the cold air circulation means (50) The evaporator 70 is installed to exchange heat in the cold air again with cold cold, and the evaporator 70 has a lower portion to remove frost formed on the surface of the evaporator 70 when the evaporator 70 is operated for a long time. A defrost heater 80 is provided to turn on and off electricity at regular intervals by receiving power. A surface of the evaporator 70 is provided when the defrost heater 80 is turned on at a lower portion of the defrost heater 80. A drain hose 90 is installed therein along the rear wall of the cabinet 10 to drain the defrost water generated in the defrost process in which the frost melts.

At the bottom of the bath hose (90) to collect the defrost water drained along the drain hose (90) and at the same time the collected defrost water on the outer lower rear side of the cabinet (10) to be evaporated by the compression heat of the compressor described later An evaporation plate 110 is installed at an upper portion of the formed machine room 100, and a compressor 120 is installed at a lower portion of the evaporation plate 110 to compress the circulating refrigerant at a high temperature and high pressure. The cabinet 10 The outer rear wall of the condenser 130 is installed to condense by the natural convection method to receive the gas refrigerant compressed to high temperature and high pressure by the compression action of the compressor (120).

On the other hand, the first side of the intermediate member 20 is formed by the cold air flow guide plate 140 by the cold air flow guide plate 140 so as to discharge the cold heat exchanged through the evaporator 70 to the refrigerating chamber 40 is formed at a predetermined interval. On the other side of the intermediate member 20, a second cold passage 160 of a predetermined interval is formed so that the cold air in the refrigerating chamber 40 passes through the evaporator 70, and the first cold passage 150 The temperature controller 170 is installed at the upper rear side of the refrigerating compartment 40 to adjust the supply amount of the cold air discharged to the refrigerating compartment 40 through a plurality of stages (for example, strong cooling or weak cooling).

At this time, the cold air flow guide plate 140, as shown in Figure 2, the damper cover 60 is installed at a predetermined interval with the rear wall of the cabinet 10 in the freezer compartment 30, the refrigerator compartment ( An inner guide rib 141 and an outer guide rib 142 are formed at one side (right side) of the cabinet 10 so as to form a cold air flow path flowing into the cabinet 40.

That is, the inner guide rib 141 is projected in an I 'shape so as to be located between the blowing fan 52 and one side wall of the cabinet 10, and the upper end thereof is positioned at the center height of the blowing fan 52. It is.

The outer guide ribs 142 are protruded in the 'A' shape to surround one side and the top of the inner guide ribs 141 and the blowing fan 52.

In the drawings, reference numerals 180 and 181 are freezing and refrigerating chamber doors of which one side is hinged to open and close the front openings of the freezing and refrigerating chambers 30 and 40, and 190 is a predetermined height within the refrigerating chamber 40. It is a shelving means that can load the object while being selectively moved.

However, according to the conventional cold air flow guide device configured as described above, although the upper end sides of the inner and outer guide ribs 141 and 142 of the cold air flow guide plate 140 are simply formed in the vertical and horizontal shapes, respectively, The structure of the blower fan 52 is rotated because the cold air flow that has been heat exchanged while passing through the evaporator 70 collides (vortex) on both sides of the blower fan 52 as shown by the arrow bar shown in FIG. When the heat exchanged cold air does not pass between the inner guide ribs 141 and the outer guide ribs 142, there is a problem in that a backflow phenomenon occurs due to the partially collided cold air.

Therefore, the present invention has been made to solve the above problems, and the present invention is intended to partially transform the shape of the inner and outer guide ribs to prevent cold air collision in advance, so that the heat exchanged cold air can be guided to a predetermined position. It is also to provide a cold air flow guide device of the refrigerator so as not to reflux.

The cold air flow guide device of the refrigerator according to the present invention made to achieve the above object, in the cold air flow guide device of the refrigerator, the cooling fan heat-exchanged through the evaporator is concentrated inward and guided in the rotational direction of the blower fan and In the position that surrounds both sides and the upper portion of the inner guide rib and the blowing fan so that the flow of cold air heat exchanged through the inner guide rib and the evaporator installed between one side wall of the cabinet is guided in the direction of rotation of the blowing fan. It is characterized by having an outer guide rib installed.

Hereinafter, one embodiment of the present invention will be described in detail with reference to the accompanying drawings.

In the drawings, the same components as those in the related art are denoted by the same names and the same reference numerals, and detailed description thereof will be omitted.

According to the present invention, as shown in FIG. 3, the cold air flow guide plate 300 includes an inner guide rib 310 positioned between the blower fan 52 and one side wall of the cabinet 10, and the inner guide. The outer guide rib 320 surrounding the rib 141 and the blowing fan 52 is formed.

At this time, the inner guide rib 310 is a vertical surface 311 protruding in the vertical direction up to the center height of the blowing fan 52, and in the horizontal direction toward the blowing fan 52 from the upper end of the vertical surface 311 It consists of a horizontal surface 312 extending protruding in length, and the inclined surface 313 extending in an oblique direction toward the vertical surface 311 from the left end of the horizontal surface (312).

The outer guide rib 320 is in a vertical direction of a height higher than the top height of the vertical surface 311 of the inner guide rib 310 so that a cold air flow path is formed at a certain distance from the right side of the inner guide rib 310. A protruding first vertical surface 321, a horizontal surface 322 protruding from an upper end of the first vertical surface 321 to a predetermined length beyond an upper portion of the blowing fan 52, and a left end of the horizontal surface 322 The second vertical surface 323 protruding in a vertical direction to the bottom height of the blowing fan 52 at a predetermined distance toward the blowing fan 52 in the inclined direction from the lower end of the second vertical surface 323 It consists of a protruding inclined surface 324.

At this time, the inclined surface 313 of the inner guide rib 310 and the inclined surface 324 of the outer guide rib 320 pass through the evaporator 70 so that the heat-exchanged cold air is concentrated toward the blowing fan 52. Inclined at opposite angles to each other.

Next, the operation and effects of the present invention configured as described above will be described.

When the compressor 120 installed in the lower part of the cabinet 10 is operated by turning on the main switch (not shown) in order to reach the predetermined temperature, the freezing and refrigerating chambers 30 and 40 are compressed. By the high temperature and high pressure gas refrigerant compressed by the flow along the inside of the condenser 130 is a condensation action is made.

The gas refrigerant condensed while passing through the condenser 130 is changed into a high temperature and high pressure liquid refrigerant at a temperature slightly higher than the room temperature of the refrigerator, and decompressed by passing through a capillary tube (not shown). As it is introduced into the evaporator 70 and expanded, it is evaporated to low temperature and low pressure and at the same time evaporated, thereby cooling.

On the other hand, when the blower fan 52 is rotated by receiving the power of the blower motor 51 as the blower motor 51 of the cold air circulation means 50 is operated, the freezing and cooling by the blower of the blower fan 52 The air in the refrigerating chambers 30 and 40 has a cold air suction hole 62 formed in the damper cover 60 and a second cold passage 160 formed in the rear side of the intermediate member 20 as shown in the arrow direction shown in FIG. Through each of the suction through the evaporator 70 through the cooling action of the above-described evaporator 70 is exchanged to the cold cold.

And the cold air heat exchanged through the evaporator 70 is concentrated inward by the inclined surface 313 of the inner guide rib 310 and the inclined surface 324 of the outer guide rib 320, as shown in FIG. The concentrated cold air flows through the flow path formed between the horizontal surface 312 of the inner guide rib 310 and the horizontal surface 322 of the outer guide rib 320 as the blowing fan 52 rotates. A flow path formed between the vertical surface 311 of 310 and the first vertical surface 321 of the outer guide rib 320 flows downward.

At this time, the inclined surfaces 313 and 324 of the inner and outer guide ribs 310 and 320 are guided to flow in one direction while collecting the rising cold air inwards, thereby allowing the flow of the rising cold air to flow regularly. As a result, it is possible to minimize the collision of irregular cold air as well as to eliminate the phenomenon of reflux of cold air.

In addition, a part of the cold air passing through the flow path formed between the vertical surface 311 of the inner guide rib 310 and the first vertical surface 321 of the outer guide rib 320 is dependent on the blowing force of the blower fan 52. The object stored in the freezing chamber 30 is frozen at a low temperature by being discharged into the freezing chamber 30 through the cold air discharge hole 61 formed at the upper end of the damper cover 60.

In addition, some of the cold air is introduced into the temperature controller 170 through the first cold passage 150 formed on the rear side of the intermediate member 20 under the guidance of the cold air flow guide plate 300 and at the same time of the temperature control driver (not shown) According to the cold air control, the cold air supply amount is controlled by strong cooling or weak cooling, and then discharged into the refrigerating chamber 40 to cool the object stored in the refrigerating chamber 40 to a low temperature.

On the other hand, when the defrost heater 80 is operated at regular intervals in order to remove frost formed in the evaporator 70 when the evaporator 70 is operated for a long time, the defrost heater 80 is heated by applying a cloud cloud to the evaporator 70. The frost formed on the surface of the) is melted, and the defrost water flowing down by frost is liquefied and falls on the defrost tray (not shown) installed at the bottom of the evaporator 70 and at the same time, the drain hose connected to the defrost receiver and the passage ( Along the 90 is collected to the evaporation plate 110 installed on the rear lower rear side of the cabinet (10).

At this time, the defrost water collected in the evaporation plate 110 is heavy due to the heat of compression by the operation of the compressor 120 installed under the evaporation plate 110.

As described above, according to the cold air flow guide device of the refrigerator according to the present invention, the inner and outer guide ribs of the cold air flow guide plate collect one side of the heat exchanged cold air while passing through the evaporator according to the rotation of the blower fan in one direction. Since the inclined surface guiding to flow to the ridges can be a regular flow of the rising cold air, thereby minimizing the impact of irregular cold air as well as has the effect of eliminating the backflow of cold air.

Claims (4)

In the cold air flow guide device of the refrigerator, between the blower fan 52 and one side wall of the cabinet 10 so that the cool air exchanged through the evaporator 70 is concentrated inward and guided in the rotational direction of the blower fan 52. The flow of cold air heat-exchanged through the inner guide ribs 310 and the evaporator 70 installed in the inner side of the guide ribs 141 and the blower fan 52 is guided in the rotational direction of the blower fan 52. Cold air flow guide device of the refrigerator having an outer guide rib 320 installed in a position surrounding the sides and the upper portion. According to claim 1, wherein the inner guide rib 310 is perpendicular to the vertical surface 311 protruding in the vertical direction to the center height of the blowing fan 52, the vertical surface 311 is perpendicular to the blowing fan 52 Cold air flow of the refrigerator comprising a horizontal surface 312 protruding at a predetermined length in a direction and an inclined surface 313 protruding in an oblique direction from the left end of the horizontal surface 312 toward the vertical surface 311. Guide device. According to claim 1, wherein the outer guide rib 320 is higher than the top height of the vertical surface 311 of the inner guide rib 310 so that a cold air flow path is formed at a predetermined distance from the right side of the inner guide rib 310. A first vertical surface 321 protruding in the vertical direction of the height, a horizontal surface 322 protruding from the upper end of the first vertical surface 321 by a predetermined length beyond the top of the blowing fan 52, and the horizontal surface The second vertical surface 323 of the second vertical surface 323 protruding in the vertical direction from the left end of the 322 to the lower height of the blowing fan 52 at a predetermined distance toward the blowing fan 52, and the second vertical surface 323 Cold air flow guide device of the refrigerator, characterized in that consisting of the inclined surface 324 extending in the inclined direction from the bottom. The inclined surfaces 313 and 324 are inclined at opposite inclination angles so that the cold heat exchanged while passing through the evaporator 70 is concentrated toward the blowing fan 52. Cold air flow guide device of the refrigerator.