KR880002021Y1 - Refrigerator - Google Patents

Abstract

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Description

Refrigerator

The drawings show one embodiment of the present invention.

1 is a longitudinal cross-sectional view of the whole.

2 is a perspective view of the whole except the cover box.

3 is a pipe configuration diagram of a refrigeration cycle.

* Explanation of symbols for main parts of the drawings

1: refrigerator body 3a: refrigerator cooler

4: freezer cooler 9: machine room

11: compressor 12: condensation tube

14: evaporation pipe part 16, 17: aeration pipe part

18: heat dissipation tube

The present invention relates to a refrigerator in which a compressor having a compressor or the like installed on an upper part of a refrigerator main body, in particular, improves the piping configuration of a flame-retardant pipe for refrigerant distribution.

It is already known that the machine room provided in the lower part of the refrigerator main body can be arrange | positioned above the refrigerator main body, and the installation area of the refrigerator can be reduced by installing a compressor in the machine room. In this type, it is conceivable to incorporate a condensation tube part in the machine room. However, this configuration increases the temperature in the machine room and causes the drive motor of the compressor to heat up, resulting in low compressor efficiency and low refrigerant circulation efficiency. In addition, there may be a problem that the compressor is affected by vibration caused by the ejection of the refrigerant from the condensation tube part. In addition, there is a problem that the condensation tube unit can not properly exhibit condensability due to the high temperature effect in the machine room.

Accordingly, an object of the present invention is to provide a refrigerator which improves the cooling performance by improving the circulation structure of the refrigerant passing heat dissipation tube to improve the circulation efficiency of the refrigerant, and thus embeds the condensation tube in the machine room.

The present invention divides the heat dissipation tube for refrigerant distribution into a condensation tube portion installed above and below the refrigerator body, and an evaporation tube portion installed in the front side of the refrigerator body wall, and the refrigerant flows in the order of the evaporation tube portion, the condensation tube portion, and the conduit tube portion. Piping to flow to

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

(1) is a refrigerator main body, which is configured by filling an insulating material (5) between the enclosure (2), the enclosure (3) and the box-shaped freezer compartment cooler (4), and the inside of the enclosure (3) 6), and the inside of the freezer compartment cooler (4) is the freezer compartment (7). The refrigerating chamber cooler 3a is provided in the upper part of the refrigerating chamber 6. (8) is a cover box provided on the upper part of the refrigerator main body 1, and let this be the machine room 9 inside. The front of the cover box is formed with a long groove-shaped heat sink (10). (11) and (12) are the compressor and the condensation pipe part disposed in the machine room 9, and the condensation pipe part 12 is formed by bending the sinusoidal pipe as a whole in an approximately L shape as shown in FIG. A plurality of heat dissipation wires 13 are installed at the side. Denoted at 14 is an evaporation tube part installed in a meander shape at the lower part of the refrigerator main body 1, 15 is a rear tube part installed at the rear wall of the refrigerator main body 1, and 16 and 17 are front surfaces of the refrigerator main body 1, respectively. An approximately spherical annular diverging pipe portion provided in the heat insulating material 5, which is a side outer wall, and an intermediate portion of the outer relieving pipe portion 16 is on the partition wall 5a separating the refrigerating chamber 6 and the freezing chamber 7 from each other. According to meandering.

The condensation pipe part 12, the evaporation pipe part 14, the back pipe part 15, and the conduit pipe parts 16 and 17 constitute the heat dissipation pipe 18, and the piping configuration of the heat dissipating pipe 18 is the refrigeration of FIG. It is displayed on a cycle. That is, the discharge port 11a of the compressor 11 is connected to the inlet end of the evaporation pipe part 14 through the distribution tube 19, and the outlet end of the evaporation pipe part 14 is the rear pipe part 15 and the connection pipe part. 20, the condensation tube part 12, the conduit pipe part 16, 17, and the dryer 21 are sequentially connected to the inlet end of the capillary tube 22, and again the outlet end of the capillary tube 22 for the refrigerator compartment It is connected to the inlet port 11b of the compressor 11 through the cooler 3a, the freezer compartment cooler 4, and the suction pipe 23 in sequence. In addition, 24 and 25 are doors for a freezer compartment and a refrigerating compartment, and the evaporation plate 26 is provided on the evaporation tube part 14.

Next, the operation of the above configuration will be described. In operation of the refrigerator, the refrigerant discharged from the discharge port 11a of the compressor 11 is distributed tubing 19-evaporation tube section 14-rear tube section 15-as shown by arrows in FIG. 2 for convenience. Connection pipe 20-Condensation pipe part 12-Drain pipe part 16, 17-Dryer 21-Capillary tube 22-Refrigerator cooler 3a, Freezer cooler 4-Suction pipe 23 ) Is sequentially passed to the inlet 11B of the compressor 11, and the heat radiating tube 18 dissipates as the circulation operation is repeated, and the refrigerator compartment cooler 3a and the refrigerator compartment cooler 4 are refrigerating compartment 6. ) And the freezer compartment 7 are cooled to the set temperatures, respectively.

In the heat dissipation tube 18 of the refrigerating cycle configured as described above according to the present invention, the refrigerant is gradually liquefied as the evaporation tube portion 14, the back tube portion 15 and the condensation tube portion 12 flows in turn, and the conduit tube portion 16 After flowing (17), approximately all become liquefied state. However, assuming that the piping of the refrigerant flows between the condensation pipe part 12 and the conduit pipe parts 16 and 17 in reverse order, the temperature of the condensation pipe part 12 is reduced because the refrigerant is almost in a liquid state and the temperature is considerably lowered. Is lowered. As a result, since the compressor 11 is at a high temperature, the condensation tube part 12 receives heat from the compressor 11 to the contrary, thereby impairing the normal heat exchange function.

Therefore, in order to solve such a problem, the back pipe part 15 and the outlet pipe part 16 are connected and connected, and the condensation pipe part 12 is connected between the discharge port 11a of the compressor 11 and the distribution tube 19. In order to solve the problems of circulation efficiency as described above, the refrigerant discharged from the compressor 11 to the condensation pipe part 12 may be liquefied because the machine chamber 9 may be relatively high. Is difficult, and the amount of liquefaction is not only small but also in a gaseous state, which also causes a difficulty in lowering the circulation efficiency of the liquid. At this time, even if the amount of liquefaction of the refrigerant is small, the liquefaction of the refrigerant proceeds, so that the condensation tube part 12 emits a large amount of heat, so that the temperature in the machine room 9 increases significantly, and the driving motor of the compressor 11 is heated. Since it becomes a state, there exists a possibility that the efficiency may worsen. Furthermore, since the refrigerant blows directly into the condensation pipe part 12 from the discharge port 11a having a relatively small aperture of the compressor 11, pulsation is likely to occur at this time, which may cause vibration.

On the other hand, according to the structure of this embodiment, since the evaporation pipe part 14, the back pipe part 15, the condensation pipe part 12, and the conduit pipe parts 16 and 17 are piped so that a refrigerant may flow in order, condensation will occur. The refrigerant flowing through the pipe part 12 is in a mixed state of gas and liquid, and then flows downward by gravity action to the downcoming pipe parts 16 and 17 below. Therefore, the circulation state of the refrigerant flowing from the condensation pipe part 12 to the conduit pipe part 16 is smooth, so that the circulation efficiency of the refrigerant is improved as a whole, thereby improving cooling performance.

In addition, since the refrigerant which has been liquefied to some extent flows into the condensation tube part 12 through the evaporation tube part 14 and the rear tube part 15, the amount of heat dissipation in the condensation tube part 12 is not so large. Therefore, the temperature rise in the machine room 9 is extremely controlled, the drive motor of the compressor 11 does not become a heating state, and the condensation tube part 12 does not vibrate by the ejection of a refrigerant | coolant.

In addition, this invention is not limited to the Example by the above-mentioned description and drawing, For example, the back pipe part 15 and the discharge pipe part 17 may be provided as needed, and is within the range which does not deviate from the summary. It is a matter of course that it can be appropriately modified.

As described above, the present invention has a piping configuration in which the refrigerant flows in the evaporation tube portion, the condensation tube portion, and the conduit tube portion in order to increase the circulation efficiency of the refrigerant, thereby providing a refrigerator capable of improving the cooling performance.

Claims (1)

In the refrigerator of the type which supplies the refrigerant | coolant from the compressor arrange | positioned in the machine room of the upper part of a refrigerator main body to the cooler in the said refrigerator main body via a heat dissipation tube, The said heat dissipation tube 18 is below the refrigerator main body 1; The refrigerant is divided into the evaporation tube section 14, the condensation tube section 12 disposed in the machine room, and the conduit tube sections 16 and 17 disposed in the front portion of the main body wall of the refrigerator. A refrigerator, characterized in that configured to be piped so as to flow in the order of the pipe section 12 and the conduit pipe section (16, 17).