KR100596243B1 - Radiating apparatus of built-in refrigerator - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a heat dissipating device for a built-in refrigerator for improving heat dissipation in a machine room by installing a duct or a passage communicating with the machine room in a bottom surface of a refrigerator main body installed in a built-in cabinet.

The heat dissipation device of the built-in refrigerator according to the present invention, the refrigerator main body installed in the built-in cabinet; A machine room provided below the rear surface of the refrigerator main body and installed with a compressor and a condenser to form a refrigeration cycle; A vertical membrane installed in a predetermined space of the machine room so as to isolate the space between the compressor and the condenser; A suction duct including one or more inlets formed in a lower front surface of the refrigerator body and one or more exhaust ports communicating with the machine room; And a back cover having a ventilation hole communicating with a discharge passage formed between the rear surface of the refrigerator main body and the wall surface, and a grill formed to be inclined upwardly on the peripheral surface of the ventilation hole; Included.

Built-in, Refrigerator, Machine Room, Condenser, Heat Resistant, Duct

Description

Radiating apparatus of built-in refrigerator

1 is a perspective view showing an installation state of a conventional general built-in refrigerator.

2 is a side sectional view taken along the line A-A 'of FIG.

Figure 3 is an embodiment showing the structure of the machine room of a conventional built-in refrigerator.

Figure 4 is a side cross-sectional view showing a conceptual diagram for showing a machine room heat dissipation device of the built-in refrigerator, as an embodiment of the present invention.

5 is a front view for illustrating a front suction port of a built-in refrigerator according to an embodiment of the present invention.

Figure 6 is a perspective view showing a heat radiating device of the built-in refrigerator according to the first embodiment of the present invention.

7 and 8 are side cross-sectional views showing a suction and discharge state according to the first embodiment of the present invention.

9 is a perspective view showing a heat radiating device of a built-in refrigerator according to a second embodiment of the present invention.

<Description of Symbols for Main Parts of Drawings>

20, 30, 40 ... built-in cabinet 21, 31, 41 ... refrigerator body

22, 32, 42 ... door panel 23 ... bottom plate

24 ... Mat bottom 25,35,45 ... Machine room

25a, 35a, 45a ... compressor 25b, 35b, 45b ... condenser

25c, 35c, 45c ... blowing fan 26,36,46 ... back cover

26a, 26b, 36a, 36b, 46a, 46b ...

Suction ducts 29a, 39a ...

29b, 39b, 49a, 49b ... Exhaust vent

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a heat dissipating device for a built-in refrigerator for improving heat dissipation in a machine room by installing a duct or a passage communicating with the machine room in a bottom surface of a refrigerator main body installed in a built-in cabinet. .

In general, a refrigerator is a device that is used for long-term storage of fresh food, and can be broadly divided into a main body having a food storage room for refrigerating and freezing food and a refrigeration cycle for dissipating the food storage room.

Since the refrigerator basically has a certain size, when the refrigerator is installed on one wall of a kitchen or living room, the refrigerator is seen as an outer shape protruding from the wall by the size thereof. There was a problem that the installation structure is not aesthetically good and its utilization is reduced in space.

As an example for solving this problem, as shown in FIG. 1, the refrigerator may be installed in the built-in cabinet 10 as one built-in furniture or installed in a sink.

The built-in refrigerator is divided into a machine room in which a main body is installed with a storage chamber and a refrigerant circulation device for maintaining the inside of the storage chamber at a low temperature. When the built-in refrigerator is installed, heat exchange is smoothly performed in a machine room where air flow is likely to be blocked due to the built-in structure, and a technology for more effectively dissipating heat generated has emerged as an important problem.

2 is a schematic configuration diagram showing a conventional built-in refrigerator.

Referring to FIG. 2, the refrigerator main body 11 installed in the built-in cabinet 10, the baseboard 14 installed in the lower part of the front surface, the machine room 15 provided on the rear surface of the refrigerator main body 11, and the refrigerator main body ( 11 is a heat dissipation passage consisting of a suction passage 18a communicated through a lower portion of the bottom plate 13 supporting the base plate 13 and the vent hole 14a of the base 14 and a discharge passage 18b located at the rear of the refrigerator body. It is composed.

A brief description of the built-in refrigerator as described above is as follows.

1 and 2, in the built-in cabinet 10, a refrigerator main body 11 is installed in a space provided as a built-in furniture, and the refrigerator main body 11 is provided with a front door panel 12 and a rear wall surface ( 17) between the bottom plate 13 and the base 14 and the upper cabinet. Here, the base 14 is installed to improve the appearance of the lower part of the built-in cabinet 10 and block the inflow of dirt.

In addition, a lower portion of the rear surface of the refrigerator main body 11 is provided with a machine chamber 15 protected by the back cover 16, and outside air is sucked in and discharged into the machine chamber 15, and a compressor, a condenser, and a blower fan are disposed therein. It is composed.

The built-in cabinet 10 generates heat dissipation passages 18a and 18b to effectively dissipate heat generated inside the machine room 15. The heat dissipation passage is divided into a suction passage 18a at the bottom of the refrigerator main body and a discharge passage 18b at the rear of the refrigerator main body.

Here, the outside air flows into the vent hole 14a of the base 14 installed in the lower part of the front of the built-in cabinet 10, and the introduced air is the bottom plate 13 and the bottom surface installed in the bottom of the built-in cabinet 10 It is discharged to the outside through the discharge flow path 18b between the refrigerator main body 11 and the wall surface 17 through the suction flow path 18a between.

In this structure, when the built-in refrigerator is operated, the compressor, the condenser, and the blowing fan provided in the machine room 15 installed at the lower rear side of the refrigerator main body 11 are operated. At this time, the air sucked through the suction flow path 18a located in the lower part of the refrigerator main body is guided inside the machine room and passes out through the discharge path at the rear of the refrigerator main body through the condenser and the blowing fan.

3 is a front view illustrating a machine room structure of a conventional built-in refrigerator.

Referring to FIG. 3, a compressor 15a on one side, a condenser 15b on the center, and a blower fan 15c on the other side are installed in the machine room 15 installed at the lower rear of the refrigerator main body, and a blower fan 15c may be installed. When activated, the outside air is sucked through the suction hole 16a of the back cover 16, and the air discharged by the blower fan 15c is heat exchanged with the condenser 15b and the compressor 15a, and then the back cover 16 It exits the discharge hole 16b of the).

At this time, the heat exchanged air inside the machine room 15 is discharged to the outside through the discharge passage 18b, and at the same time has a circulation process in which air is introduced through the suction passage 18a.

However, since the suction and the discharge in the machine room of the refrigerator main body are the same, the flow circulation, that is, the discharged flow is introduced again through the compressor, thereby reducing the heat transfer efficiency in the condenser.

In addition, when the refrigerator is installed in the built-in cabinet, the inflow structure of the flow path into the machine room is limited by the bottom plate supporting the refrigerator because it is installed at the bottom of the refrigerator for heat dissipation, thereby making it difficult to form an efficient heat dissipation structure.

The present invention has been made to solve the above problems, an object of the present invention is to provide a heat dissipation device of a built-in refrigerator to install the suction duct in the bottom surface of the refrigerator main body to allow the outside air to be directly sucked into the machine room.

Another object of the present invention is to form a suction duct between the bottom case and the heat insulating material of the refrigerator main body, and having an inlet and an end in the front of the suction duct, while extending to a certain curvature on the exhaust side, the outside air to the machine room It is an object of the present invention to provide a heat dissipation device of a built-in refrigerator that can be evenly sucked.

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Hereinafter, with reference to the accompanying drawings as follows.

Figure 4 is a block diagram showing a heat radiating device of the built-in refrigerator according to the present invention.

Referring to FIG. 4, the refrigerator body 21 installed in the built-in cabinet 20, the door panel 22 on the front of the refrigerator, the bottom plate 23 and the base 24, and the refrigerator main body 21 of the refrigerator 21 are provided. The discharge chamber 28b is fastened to the main body so as to cover the machine room 25 installed below the rear surface, the compressor 25a and the condenser 25b, the blower fan 25c, and the machine room 25 provided in the machine room 25, and the machine room 25. ) And a back cover 26 having a vent hole 26b communicating therewith, and a suction duct 29 formed in the bottom surface of the refrigerator body 21 to guide external air to the machine room 25.

Referring to the accompanying drawings, the heat dissipation device of the built-in refrigerator according to the embodiment of the present invention configured as described above is as follows.

4 and 5, the built-in cabinet 20 is provided with a refrigerator main body 21, and a machine room 25 is installed at the rear lower portion of the refrigerator main body 21 by the back cover 26. Here, the machine room 25 includes a compressor 25a, a condenser 25b, a blower fan 25c, and the like.

In addition, a suction duct 29 is installed on the bottom surface 21a of the refrigerator main body 21, and is installed in a honeycomb shape as shown in FIG. 5 between the main body bottom surface 21a and the heat insulating material therein to dissipate heat. Necessary air flows into the machine room 25.

That is, the suction duct 29 has a plurality of inlets 29a formed on one side of the lower surface of the refrigerator main body 21 on one side, and the exhaust port 29b communicating with the machine room 25 on the other side. ) Is formed.

Here, a plurality of inlets (29a) formed on the front of the suction duct 29 has a suitable interval and a predetermined height is installed in a plurality of inlet to introduce the outside air in the transverse direction of the refrigerator main body, the inlet air flows in the suction flow path (29c) Is passed through). The exhaust port 29b guides the air introduced from the suction channel 29c to be sucked into the machine room 25.

In addition, in order for air to flow into the inlet 29a of the suction duct 29, the door panel 22 attached to the refrigerator door should not be stuck to the base 24, and the base 24 ) Is installed inside the refrigerator door, the door panel 22 may be lowered to the upper surface of the base 24, but when the base 24 is in the same line as the door panel 22, the door panel ( 22) to make the inlet (29a) by adjusting the length.

In the machine room 25, as shown in FIG. 4, the compressor 25a, the condenser 25b, and the blower fan 25c are arranged at appropriate positions, and an exhaust port 29b communicating with the inside of the bottom surface is formed, and above the back surface. The vent hole 26b is formed. In an embodiment, the installation position and arrangement of the components of the machine room 25 may be adjusted differently.

In the structure as described above, when the refrigerator is operated, the compressor 25a connected to the evaporator in the refrigerator compresses the refrigerant, and the compressed refrigerant is condensed while passing through the condenser 25b and transferred into the refrigerator. At this time, the heat generated from the compressor 25a and the condenser 25b is cooled by heat exchange with the outside air by the blower fan 25c. Then, the heat-exchanged air flows upward through the discharge passage 28b through the vent hole 26b.

At this time, the suction duct 29 formed in the bottom surface 21a of the refrigerator main body 21 introduces air into the inlet port 29a and guides it to be sucked into the machine room 25 through the exhaust port 29b. As the outside air is sucked into the machine room 25 by the blower fan 25c, the compressor 25a and the condenser 25b are cooled and then discharged into the vent hole 26b, and the discharged air is discharged again ( Through 28b).

Here, when the air is discharged to the outside through the back cover of the machine room, the vent hole 26b forms the grille shape of the vent hole 26b to be inclined upwardly so that the air direction is directed upward.

As an embodiment, it will be described in detail with reference to FIGS. 6 and 7 as follows.

As shown in FIG. 6, the suction duct 39 having at least one inlet 39a and the exhaust port 39b is provided inside the bottom 31a of the refrigerator main body 31. That is, the inlet (39a) side of the suction duct 39 is formed in a wide structure to communicate with the outside through a plurality of vents, a single exhaust port 39b communicates with the machine room 35 to allow the suction of external air.

6 and 7, a flow path 39c is formed in the suction duct 39 to communicate the inlet port 39a and the exhaust port 39b, and the exhaust port 39b includes the machine room 35 and the condenser 35b. Communicate the installation site.

Then, as illustrated in FIGS. 7 and 8, the blower fan 35c operates by installing the blower fan 35c at one side of the compressor 35a, the other side of the condenser 35b, and the center thereof, as shown in FIGS. 7 and 8. At the same time, the outside air is sucked in through the suction hole 36a of the back cover 36 and the exhaust port 39b of the suction duct 39.

At this time, the suction duct 39 guides the outside air into the machine room 35 through the suction passage 39c, thereby exchanging heat to the condenser 35b by the sucked outside air, and converts the heat exchanged air into FIG. 8. By discharging through the compressor 35a as described above, the discharged air is discharged to the discharge passage 38b through the vent hole 36b of the back cover.

In an embodiment, the suction hole 36a of the back cover 36 is removed, and the air that has been heat-exchanged in the condenser 35b is re-installed in such a manner that the outside air can be sucked only through the suction duct 39. It can be prevented from entering. In an embodiment, the number and spacing of the inlets of the suction duct may be adjusted differently, and each partition may be formed in the air moving direction.

9 is another embodiment of the present invention.

Referring to FIG. 9, the suction duct 49 includes a plurality of inlets (not shown) in front of the main body, and a plurality of exhaust ports 49a and 49b communicating with the machine room 45, respectively. And 49d) are installed separately.

The structure of the suction chamber 49 and the corresponding mechanical chamber 45 is provided with a compressor 45a on one side, and a condenser 45b on the other side and a blower fan 45c on the front side. The space between 45a) and the condenser 45b can be separated from each other by a vertical film 45d. In addition, one side of the lower portion of the interior of the machine room 45 and the suction duct 49 is in communication with each other.

Accordingly, the built-in refrigerator is operated to generate heat from the compressor 45a and the condenser 45b, and the outside air is sucked through the suction duct 49 by the start of the blower fan 45c, and the back cover 46 is operated. Is discharged to the exhaust holes 46a and 46b.

That is, the suction duct 49 provided in the bottom surface 41a of the refrigerator main body 41 sucks outside air through the suction port and then passes through the plurality of exhaust ports 49a and 49b through different flow paths 49c and 49d. It is discharged to the machine room 45.

At this time, the outside air is introduced into the machine room 45 while being divided into the area of the compressor 45a and the area of the condenser 45b by the vertical membrane 45d.
The exhaust port 49b of the suction duct 49 communicating with the compressor 45a side communicates with the vent hole 46b of the back cover 46 to cool the compressor 45a in a natural convection manner.

The exhaust port 49a of the suction duct 49 communicating with the condenser 45b sucks outside air by the blower fan 45c to heat exchange the condenser 45b, and then vent holes in the back cover 46. Since it is discharged through the 46a, it is discharged to the outside through the discharge passage (not shown).

By forming the suction duct 49 integrally inside the bottom without changing the size of the refrigerator main body of the present invention, the outside and the machine chamber 45 is communicated with each other, so that the heat exchange in the machine chamber due to the suction of external air is prevented. It is possible, of course, because it is a way to suck to one side and discharge to the other side, there is an effect that can solve the problems caused during the conventional heat exchange.

In addition, since the structural shape of the exhaust port 49b of the suction duct 49 can be adaptively changed according to the arrangement of the components inside the machine room 45, it is a structure that does not require vent holes to be processed. .

As described above, the heat dissipation device of the condenser of the built-in refrigerator according to the present invention integrally forms a suction duct to the machine room in the bottom of the refrigerator main body, thereby eliminating the need for installing a ventilation hole in the baseboard and providing an exposed condenser. Since there is no need to limit the installation is effective.

Claims (6)

A refrigerator body installed in a built-in cabinet; A machine room provided under the rear surface of the refrigerator main body, and having a compressor and a condenser installed to form a refrigeration cycle; A vertical membrane installed in a predetermined space of the machine room so as to isolate the space between the compressor and the condenser; A suction duct including one or more inlets formed in a lower front surface of the refrigerator body and one or more exhaust ports communicating with the machine room; And And a back cover having a ventilation hole communicating with a discharge flow path formed between the rear surface of the refrigerator main body and a wall, and a grill formed to be inclined upwardly on the circumference of the ventilation hole. The suction duct is a heat dissipation device of the built-in refrigerator, characterized in that it has a plurality of flow paths by the vertical membrane, the inlet and the exhaust. delete delete The method of claim 1, The air sucked into the suction duct is moved to the compressor side or the condenser side by the vertical membrane, the inlet and the exhaust port, the heat dissipation device of the built-in refrigerator. delete delete

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