KR100661837B1 - Refrigerator - Google Patents

Abstract

A refrigerator is provided to reduce noises for an operation of a compressor because of cutting off a portion of the noise generated from the compressor by a heat guide plate formed at a defrost water tray. In a refrigerator, a heat guide part is extended to a compressor(11) side and covers at least one side of the compressor. The compressor and the heat guide part are installed with a predetermined gap. A defrost water tray is installed at an inside wall of a machine room wherein installing the compressor with a predetermined gap. And, a path connects a space located between the compressor and an evaporation room of the defrost water tray.

Description

Refrigerator {Refrigerator}

      1 is an exploded perspective view showing the shape and installation structure of a conventional defrost water tray.

      2 is a perspective view showing the structure of a machine room in which a defrost water tray of a refrigerator according to the present invention is installed.

      3 is an exploded perspective view illustrating the tray and the compressor separately in FIG. 2.

      Figure 4 is a side cross-sectional view showing the installation structure and air flow of the tray in FIG.

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

      10: machine room, 11: compressor

      12: base plate, 13: defrost water tray,

      13b: evaporation space, 13d: diffusion groove

The present invention relates to a refrigerator, and more particularly, to a defrosting water tray having improved evaporation efficiency in order to efficiently treat condensate or defrost water generated in a cooler as a refrigeration cycle of the refrigerator is performed.

In general, a refrigerator circulates refrigerant as a compressor operates, and a refrigeration cycle is operated. In the refrigerator, the refrigerant evaporates and cools a freezing compartment or a refrigerating compartment.

The air passing through the cooler reaches the dew point, which causes frost in the cooler, and a defrost heater is installed in the cooler to remove the air.

Since the castle is continuously generated as the refrigeration cycle is operated, the refrigerator needs a device for treating the defrost water generated by the defrost heater, which is a defrost tray.

1 is an exploded perspective view showing the shape and installation structure of a conventional defrost water tray. The defrost water tray 1 is installed at the upper portion of the compressor 2, and the defrost water receiving space 3 is provided inside.

A drain pipe (not shown) is embedded in the rear wall of the refrigerator so that the defrost water generated from the cooler (not shown) can be sent to the defrost water tray 1, and the defrost water receiving space at the end of the drain pipe (not shown) ( It is located above 3).

In order to treat the defrost water continuously generated without discharging it to the outside of the refrigerator, the amount of defrost water is greater than or equal to at least the amount of defrost water to be prevented from overflowing the defrost water tray.

Accordingly, as the heat source for evaporating the defrost water, the defrost water tray 1 is positioned above the compressor 2 to use the heat of compression generated during the refrigerant compression process of the compressor 2. In order to compensate for the insufficient heat transfer, a part of the refrigerant discharged from the compressor 2 and sent to a condenser (not shown) is branched to configure the condensation pipe 4 to be embedded in the bottom surface of the defrost water tray 1.

However, the structure of this conventional defrost water tray 1 constitutes the condensation pipe 4 in addition to processing the condensation pipe 4 and assembling it with the compressor 2. And it must be installed in the defrost water tray (1) and must also include a support structure to suppress the generation of vibration, there was a problem that the production cost is increased due to the difficulty of the parts addition and assembly process.

In addition, when a large amount of water vapor is introduced into the freezer or refrigerating chamber or generated in the freezer or refrigerating chamber, when the generation of defrost water increases rapidly, the processing efficiency of the defrost water tray decreases, causing defrost water to overflow and causing a failure.

In order to solve this problem, an object of the present invention is easy to secure the heat amount for the defrost water evaporation, the defrost water tray can be widely distributed without the installation of a condensation pipe to improve the evaporation efficiency by widening the defrost water To provide a refrigerator comprising a.

In order to achieve the above object, a refrigerator according to the present invention includes a defrost water tray installed on an upper portion of a compressor for evaporating defrost water generated in a freezing cycle.

The defrost water tray is provided with a heat guide formed extending downward to the compressor side, the heat guide is configured to cover at least one side of the compressor, the compressor and the heat guide is characterized in that it is installed to be spaced apart a certain distance.

In addition, the defrost water tray is characterized in that a flow path communicating between the compressor and the evaporation space of the defrost water tray is formed between the defrost water tray and the inner wall of the machine room spaced apart from the inner wall of the machine room in which the compressor is installed. It is done.

In addition, the evaporation space of the defrost water tray is characterized in that a plurality of diffusion grooves are formed on the bottom surface.

In addition, the evaporation space is characterized in that the bottom surface is formed to be inclined in one direction.

In addition, the evaporation space is characterized in that the bottom surface is inclined downward toward the heat guide portion.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described in more detail.

 2 is a perspective view showing a structure of a machine room in which a defrost water tray of a refrigerator according to the present invention is installed, FIG. 3 is an exploded perspective view showing the tray and the compressor separately in FIG. 2, and FIG. 4 is an installation structure of the tray and air in FIG. 2. A side sectional view showing the flow.

2, in the refrigerator according to the present invention, a machine room 10 is provided at a lower part of the main body, and a compressor 11 is mounted on the base plate 12 in the machine room 10.

The defrost water tray 13 is installed above the compressor 11, and a screw fastening piece 13a is provided at one end of the upper surface of the defrost water tray 13 to fix the upper part of the machine room 10 with the upper end of the machine room 10. It is configured to be.

Referring to FIG. 3, the defrost water tray 13 is provided with an evaporation space 13b surrounded by four partition walls therein, and a defrost water generated from a cooler (not shown) is provided above the evaporation space 13b. An end thereof is positioned along a drain pipe (not shown) embedded in the inside of the main body so as to be introduced.

In addition, in the defrost tray 13, the heat of compression generated from the compressor 11 and the rising air flow of the air surrounding the compressor 11 evaporate through the rear of the defrost tray 13 along the bottom of the defrost tray 13. As the compressor 11 is spaced apart from the inner wall of the machine room 10 in which the compressor 11 is installed to be introduced into the space 13b, the compressor 11 and the inner wall of the defrost water tray 13 and the machine room 10 are separated from each other. A flow path communicating between the evaporation spaces of the defrost water tray 13 is formed, and a heat guide part 13c extending downward to one side of the compressor 11 is provided.

On the other hand, in order for the water to evaporate actively, the temperature of the water must be high, and the area in contact with the air must be increased.

However, there is a constant surface tension in the water and the dropped water does not spread widely from the bottom surface of the evaporation space (13b) if it does not become a constant water level to form a single large water droplets by agglomeration around the dropped point.

Therefore, a diffusion groove 13d is provided in the bottom surface of the evaporation space 13b to guide the defrost water in multiple directions so that the defrost water falling from the drain pipe can be widely spread on the bottom surface of the evaporation space 13b. .

The diffusion groove 13d has a grid structure, and the diffusion groove 13d increases the contact area between the bottom surface and the defrost water as the lattice spacing becomes narrower, in addition to the effect of diffusing the defrost water. There is an effect of increasing the heat transfer amount of heat generated and transmitted to the bottom surface. Such a lattice structure may be modified in various shapes other than the rectangular lattice as shown.

The bottom surface of the evaporation space 13b is formed to be inclined to further reinforce the action of the defrost water dropped from the drain pipe along the diffusion groove 13d in the bottom surface of the evaporation space 13b.

Since the defrost water tray 13 has a heat guide part 13c as described above, and a space for air flow is preferably formed between the defrost water tray 13 and the compressor 11, the bottom surface Silver is preferably inclined downward toward the heat guide portion (13c).

The defrosting water dropped as the bottom surface is inclined is diffused by a drop along the diffusion groove 13d. If the inclination angle is too large, the defrosting water is excessively concentrated in the direction of the heat guide part 13d, and the defrosting water and air are in contact with each other. Area can be reduced

Therefore, the inclination angle of the bottom surface should not exceed 20 degrees with respect to the ground, assuming that the ground on which the refrigerator is installed is perpendicular to the direction of gravity, preferably, it is preferably configured to about 5 to 10 degrees.

Referring to the operation and effect of the refrigerator according to the present invention made of the above-described configuration are as follows.

When power is applied and the compressor 11 is operated, the compressor 11 becomes a process similar to the adiabatic compression process according to the compression of the refrigerant, thereby generating heat of compression.

Meanwhile, the refrigerant discharged from the compressor 11 passes through a condenser (not shown) to become a liquid refrigerant, and is pressurized through an expansion valve (not shown) or a capillary tube (not shown) to evaporate in the cooler.

The air of the refrigerating compartment or the freezing compartment passing through the cooler is cooled by the evaporation of the refrigerant, and condensate or defrost water generated by the refrigerant is introduced into the defrost water tray 13 along the drain pipe.

The defrost water dropped on the defrost tray 13 is widely spread along the bottom surface where the diffusion groove 13d is formed in the evaporation space 13b, and the heat of compression of the compressor 11 is located above the compressor 11. Is conducted to the bottom surface.

The heat of compression generated by the compressor 11 generates convection along the inside of the heat 13c at the same time in addition to the heat thus conducted, and thus the hot air rising as the defrost water tray 13 is shown in FIG. 4. It is introduced into the evaporation space (13b) along the space of the back, induces evaporation of the defrost water in the evaporation space (13b) is discharged to the upper side of the defrost water tray 13, the opposite side of the flow direction.

As described above, the refrigerator according to the present invention includes a defrost water tray having an improved evaporation efficiency so that the defrost water can be treated by evaporating defrost water without installing a condensation pipe, thereby preventing vibration of the condensation pipe and the condensation pipe according to the condensation pipe. It is possible to omit the structure to be made and the assembly process according to it can be omitted there is an effect of reducing the production cost.

In addition, a part of the noise generated from the compressor is blocked by the heat guide plate formed in the defrost water tray has an excellent effect of reducing the noise due to the operation of the compressor.

Claims (5)

In the refrigerator comprising a defrost water tray installed on the top of the compressor to evaporate the defrost water generated in the refrigeration cycle, The defrost water tray is provided with a heat guide portion extending downward to the compressor side, the heat guide portion is configured to cover at least one side of the compressor, the compressor and the heat guide portion is installed to be spaced a predetermined distance, the defrost water tray And a flow path communicating between the defrost water tray and the machine room inner wall as a space is separated from the inner wall of the machine room in which the compressor is installed, by the evaporation space of the compressor and the defrost water tray. delete The refrigerator according to claim 1, wherein a plurality of diffusion grooves are formed on a bottom surface of the evaporation space of the defrost water tray.       The refrigerator according to claim 1 or 3, wherein the evaporation space has a bottom surface inclined in one direction.         The refrigerator according to claim 4, wherein the evaporation space is formed such that a bottom surface thereof is inclined downward toward the heat guide part.

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