KR100546675B1 - radiant heat-structure of direct cooling type refrigerator - Google Patents

Abstract

The present invention is to provide a heat dissipation structure of a direct-cooling refrigerator to increase the heat dissipation area for dissipating heat generated in the condenser, thereby improving the heat dissipation efficiency of the capacitor.

To this end, the present invention and the outer case forming the appearance of the refrigerator; An inner case provided inside the outer case, the rear side of the inner case configured to form an air flow passage spaced apart from the rear side of the outer case by a predetermined distance; A freezing compartment and a refrigerating compartment which are partitioned up and down inside the inner case; A machine room equipped with a compressor, etc. in a predetermined space at the bottom of the rear wall inside the outer case; Insulation material provided on the rear wall surface of the inner case; And, the heat dissipation structure of the direct-cooling refrigerator is provided, characterized in that it comprises a condenser: provided on the rear inner wall surface of the outer case.

Refrigerator, condenser, heat dissipation structure

Description

Radiant heat-structure of direct cooling type refrigerator

1 is a schematic view showing the structure of a conventional direct-cooling refrigerator

FIG. 2 is an enlarged schematic view of portion "A" of FIG. 1 and schematically shows a main part of a conventional capacitor heat dissipation structure; FIG.

Figure 3 is a schematic diagram showing the height of the direct-cooling refrigerator according to an embodiment of the present invention

4 is an enlarged schematic view of portion "A" of FIG. 3, schematically illustrating a main part of a capacitor heat dissipation structure according to an exemplary embodiment of the present invention;

** Description of the symbols for the main parts of the drawings **

100: outer case 200: inner case

210: insulation 300: machine room

310: compressor 400: condenser

500: air flow path 220: inner panel

The present invention relates to a heat dissipation structure of a direct-cooling refrigerator, and more particularly, to a heat dissipation structure of a direct-cooling refrigerator to increase the heat dissipation area of the condenser to improve the cooling efficiency of the condenser.

In general, a refrigerator is a refrigeration and refrigerating device that keeps food fresh for a long period of time as the refrigerant is repeatedly compressed, condensed, expanded, and evaporated, thereby allowing food to be kept fresh for a long time.

Such a refrigerator cools and condenses a compressor for raising and increasing a gas refrigerant of low temperature and low pressure to a high temperature and high pressure gas state, and cooling and condensing the refrigerant of high temperature and high pressure gas state introduced from the compressor by external air. A condenser for converting a liquid refrigerant at 40 ° C. and a pressure of 9 atm, a capillary for depressurizing the refrigerant flowing from the condenser, having a diameter smaller than that of other parts, and a refrigerant having passed through the capillary at low pressure (0 atm) As a basic system, an evaporator absorbs heat in the furnace as a basic system as it evaporates to a low temperature (-30 ° C.).

The refrigeration cycle as described above is continued until the temperature in the refrigerator reaches the set temperature, and when the set temperature is reached, the sensor detects that the set temperature has been reached by a temperature sensor (not shown) and rises above the set temperature by the microcomputer. By stopping the operation of the refrigerator until it is prevented from overcooling and unnecessary waste of power consumption.

The structure of a conventional refrigerator operated by the refrigerating cycle includes a freezer compartment in which cold air heat-exchanged by the evaporator is directly introduced to maintain a room temperature of about −18 ° C., and cold air in the freezer compartment is introduced to be approximately 0 to It is largely divided into a refrigerating chamber that maintains a room temperature of about 7 ℃.

Hereinafter, with reference to Figure 1 showing the structure of a conventional direct-cooling refrigerator in more detail as follows.

Conventional direct-cooling refrigerators, the outer case 100 forming the exterior of the refrigerator, the inner case 200 provided in the outer case 100, and the freezer compartment partitioned up and down inside the inner case 200 ( R) and the refrigerating chamber (F), the machine room 300 equipped with a compressor (310), etc. in a predetermined space on the rear wall bottom of the inner side of the outer case 100, and the rear wall surface of the inner case 200 And a condenser 400 provided on the inner wall surface of the rear side of the outer case 100.

Here, the heat insulator 210 is polyurethane, and is foamed between the inner case 200 and the outer case 100.

In addition, as shown in FIG. 2, a capacitor 400 is embedded between the inner side of the outer case 100 and the heat insulating material 210.

In addition, an aluminum tape 410 is further provided between the outer case 100 and the heat insulating material 210 in which the condenser 400 is embedded to prevent leakage of the foamed heat insulating material 210 and to fix the condenser 400. do.

The condenser 400 forms a part of a refrigerating cycle of a refrigerator, and a refrigerant flows therein.

Here, the refrigerant flowing through the condenser 400 becomes low temperature by being radiated to circulate a predetermined refrigeration cycle.

As such, embedding the condenser 400 between the inner side of the outer case 100 and the heat insulating material 210 corresponding to the side surface of the refrigerator occurs in the condenser 400 using the side surface of the refrigerator having a relatively large surface area. It is to dissipate enough heat.

However, the following disadvantages are pointed out in the heat dissipation structure of the conventional direct cooling refrigerator configured as described above.

Since the condenser 400 is buried between the inner wall surface of the rear side of the outer case 100 and the heat insulator 210, as shown in FIG. 2, the condenser 400 includes the outer case 100. ) Is installed in line contact.

Here, since the condenser 400 is in line contact with the outer case 100, the area for dissipating heat generated by the condenser 400 is extremely small.

For this reason, there is a problem that the heat dissipation area of the condenser 400 is not sufficiently secured and the heat dissipation efficiency of the condenser 400 is lowered.

The present invention has been made to solve the above problems, by providing a heat dissipation structure of the direct-cooling refrigerator to increase the heat dissipation area for heat dissipation generated by the condenser, to improve the heat dissipation efficiency of the condenser. There is this.

In order to achieve the above object, the present invention provides an outer case for forming the appearance of the refrigerator; An inner case provided inside the outer case, the rear side of which is spaced apart from the rear side of the outer case by a predetermined interval so that an air flow passage is formed, and an upper side of the air flow passage is configured to reduce the flow path toward the end; A freezing compartment and a refrigerating compartment which are partitioned up and down inside the inner case; A machine room equipped with a compressor or the like on a predetermined space at the bottom of the rear wall inside the outer case; Insulation material provided on the rear wall surface of the inner case; A condenser provided on a rear inner wall of the outer case; And, the heat dissipation structure of the direct-cooling refrigerator is provided, characterized in that it comprises at least one inlet: formed in the bottom of the outer case to allow the external air to flow to the air flow passage to heat the compressor and condenser.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings, FIGS. 3 to 4.

3 is a schematic view schematically showing the elevation of the direct-cooling refrigerator according to an embodiment of the present invention, Figure 4 is an enlarged portion "A" of Figure 3, the main part of the heat dissipation structure of the condenser according to an embodiment of the present invention It is a schematic diagram schematically.

For reference, prior to describing the configuration of the present invention, in order to avoid duplication of description of the prior art reference to the same reference numerals will be referred to.

That is, as shown in Figure 3, the direct-cooling refrigerator according to an embodiment of the present invention is provided in the outer case 100 and the outer case 100 to form the exterior of the refrigerator, the rear side of the outer case An inner case 200 configured to form an air flow passage 500 spaced a predetermined distance from the rear side of the 100, and a freezer compartment R and a refrigerating compartment F, which are partitioned up and down inside the inner case 200. And, in a predetermined space on the bottom side of the rear wall surface inside the outer case 100, the machine room 300 is provided with a compressor 310, the heat insulating material 210 provided on the rear wall surface of the inner case 200, It has a condenser 400 provided on the rear inner wall surface of the outer case (100).

Here, the inner panel 220 having a predetermined interval with the rear wall surface of the inner case 200, and installed to correspond to the inner case 200, the upper side is further provided with an inner panel 220 formed in a curved shape.

In this case, the inner panel 220 is provided because the upper portion of the inner panel 220 is curved along with the purpose of separating the heat insulating material 210 and the condenser 400. The internal pressure difference of 500 can be changed.

In addition, the outer case 100 has at least one inlet 600 for inflow of external air into the air flow passage 500 is formed.

In the embodiment of the present invention, the inlet port 600 is formed on each of both sides of the bottom of the outer case 100 so that the outside air flows into the air flow passage 500 can be made smoothly.

In this case, the inlet 600 is preferably formed to communicate with the machine room 300 of the refrigerator provided with the compressor 310, the machine room 300 is preferably formed to communicate with the air flow passage (500).

In addition, the inlet 600 may be formed at a position such that the inlet air is discharged to the air flow passage 500 after passing through the compressor 310.

That is, when the outside air flows into each inlet 600 formed to communicate with the machine room 300, the introduced outside air is discharged to the air flow passage 500 after passing through the compressor (310).

In this case, the introduced external air passes through the compressor 310 having a high external surface temperature, so that air having a higher temperature than the existing air of the air flow passage 500 is introduced from the machine room 300 by the air flow passage 500. To be discharged.

This is by using a natural convection phenomenon, when the external air introduced into each inlet port 600 passes through the compressor 310 to increase the temperature, the inlet air of the elevated temperature is the air flow passage 500 After passing through the heat dissipation of the condenser 400, it is discharged to the upper portion of the air flow passage (500).

Here, the discharged inlet air is hotter air than the air inside the existing air flow passage 500, and the higher the temperature of the inlet air is higher than the temperature of the air therein, the faster the cold air is introduced. It will rise with the hot air.

In addition, the upper side of the air flow passage 500 is formed to reduce the flow passage toward the upper end approximately.

That is, the air flowing into the air flow passage 500 is formed so that the upper side of the air flow passage 500 toward the end to reduce the flow path so that the natural convection is more smoothly due to the pressure difference in the air flow passage. This is desirable.

Referring to the heat dissipation effect of the direct-cooling refrigerator configured as described above through the embodiment as follows.

The refrigerant compressed to high temperature and high pressure by the compressor 310 of the direct cooling refrigerator flows into the condenser 400 in a vapor state.

At this time, in order to dissipate the condenser 400, the outside air introduced into the machine room 300 is provided in the machine room 300 through the inlets 600 respectively provided on both sides of the bottom of the outer case 100. After passing through the compressor 310 is discharged to the air flow path (500).

At this time, the air discharged into the air flow passage 500 is mixed with the existing air in the air flow passage 500, the mixed air is condensed 400 by the natural convection inside the air flow passage 500 To the side.

At this time, in order to use the internal pressure difference of the air flow passage 500, the upper side of the air flow passage 500 is formed to be reduced in the passage toward the upper end approximately, and thus, the air flow passage 500 Mixed air in the interior of the air flow passage 500 is a natural convection phenomenon is made smoothly.

That is, the heat generated by the condenser 400 may be radiated by the air moving inside the air flow passage 500 due to the natural convection phenomenon.
As described above, since the air flow passage 500 is provided inside the direct-cooling refrigerator, the heat dissipation area for dissipating the high temperature and high pressure heat generated by the condenser 400 is increased, thereby improving heat dissipation efficiency of the condenser 400. Can be improved.
On the other hand, since the inlet port 600 is formed at the bottom of the outer case 100, the external air introduced through the inlet port 600 passes through the machine room, and thus the heat radiation of the compressor can be obtained.

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In addition, a heat radiation effect due to natural convection of the air inside the air flow passage 500 may be obtained along with a heat radiation process by the conventional conduction.

As described above, the present invention is provided with an air flow passage in the direct-cooling refrigerator, the heat dissipation area for heat dissipation generated by the condenser is increased, thereby improving the heat dissipation efficiency of the condenser.

In particular, when the flow path is reduced toward the upper end of the air flow passage, the natural convection is smoothly made in the air flow passage, thereby improving the heat dissipation efficiency of the condenser.

Claims (7)

An outer case forming an exterior of the refrigerator; An inner case provided inside the outer case, the rear side of which is spaced apart from the rear side of the outer case by a predetermined interval so that an air flow passage is formed, and an upper side of the air flow passage is configured to reduce the flow path toward the end; A freezing compartment and a refrigerating compartment which are partitioned up and down inside the inner case; A machine room equipped with a compressor or the like on a predetermined space at the bottom of the rear wall inside the outer case; Insulation material provided on the rear wall surface of the inner case; A condenser provided on a rear inner wall of the outer case; And, And at least one inlet formed at a bottom of the outer case to allow external air to flow into the air flow passage to dissipate the condenser. The method of claim 1, The heat dissipation structure of the direct-cooling refrigerator having a predetermined interval with the rear wall surface of the inner case, the inner case is provided to correspond to the inner case, and further includes an inner panel formed in a curved shape on the upper side. delete The method of claim 1, The inlet is a heat dissipation structure of the direct-cooling refrigerator, characterized in that formed on both sides of the bottom of the outer case. The method of claim 1, The inlet is formed so as to communicate with the machine room of the refrigerator equipped with a compressor, etc., the machine room is a heat dissipation structure of the direct-cooling refrigerator, characterized in that configured to communicate with the air flow passage. The method of claim 5, The inlet is a heat dissipation structure of the direct-cooling refrigerator characterized in that the inlet air is formed in a position to be discharged to the air flow passage after passing through the compressor. delete

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