KR19990053009A - Refrigeration Dehumidifier - Google Patents

Abstract

The refrigerator has been improved in its structure to improve the cooling performance of the evaporator by adopting a thermoelectric element on the cold air flow path of the trimming plate that partitions the freezer compartment and the refrigerating compartment to appropriately remove the moisture in the cold air that is heat exchanged around the evaporator. Disclosed is a dehumidifier of It is provided on the cold air flow path 310 of the trimming plate 300 for dividing the freezing chamber 100 and the refrigerating chamber 200 and the thermoelectric element 400 and the thermoelectric element in which the flow direction of the heat flow is changed in accordance with the current flow direction. It is provided below the blower fan 500 for promoting the flow of heat flow of the thermoelectric element, and the heat conduction means for conducting the heat of the thermoelectric element and extending the heat dissipation area of the thermoelectric element. The heat dissipation means has a structure in which a predetermined cooling fin 410 is provided to be in contact with one surface of the thermoelectric element 400 to expand the heat dissipation area of the thermoelectric element. The dehumidifying apparatus of the present invention refrigerator having such a configuration has an effect of improving the cooling performance of the refrigerator by effectively removing moisture in the cold air absorbed from the storage while circulating the inside of the refrigerator.

Description

Refrigeration Dehumidifier

The present invention relates to a dehumidifying apparatus of a refrigerator, and more particularly, employing a thermoelectric element on a cold air flow path of a trimming plate partitioning a freezer compartment and a refrigerating compartment to circulate the inside of the refrigerator to effectively absorb moisture in cold air. The present invention relates to a dehumidifying apparatus of a refrigerator having a structure which is improved to remove frost growth on the surface of the evaporator to improve the cooling performance of the refrigerator.

In general, a refrigerator circulates a refrigerant pipe by an operating pressure of a compressor motor, thereby cooling the surrounding air through heat exchange with air around the evaporator while the liquid refrigerant evaporates in the evaporator.

The cold air around the heat exchanged evaporator is forcedly circulated by a blower fan to maintain the freshness of the food through heat exchange with the food stored in the refrigerator while the cold air circulates through the cold air passage in the refrigerator.

However, the cold air circulated in the furnace contains a large amount of water absorbed from the food. The cold air grows frost on the evaporator surface due to mutual temperature difference during the heat exchange process on the evaporator surface, thereby lowering the cooling performance of the evaporator. .

Conventional dehumidification apparatus of the conventional refrigerator for solving the above problems is disclosed in Utility Model Application No. 90-12898 and is shown in Figures 1 and 2, which can properly maintain the moisture content of the cold air circulating in the interior of the refrigerator The heat exchange plate is provided on the cold air flow path of the trimming plate so that the heat exchange plate has a dehumidification process of the cold air, which is described with reference to FIGS. 1 and 2. The freezer compartment cold air passages 20 passing from the rear to the rear side are formed at both sides, and the upper part of the outer wall 30 of the cold air passage 20 is formed with a recess in the upper portion and leaving a slight margin from the front and rear ends thereof. 40) are to be placed.

Therefore, the cold air passage 20 covered with the upper portion by the upper plate 40 is formed with the inlet 50 of the freezer compartment cold air in the front by the front and rear margins and the cold air outlet 60 in the rear.

A protruding inclined surface is formed between the cold air passages 20, and most of the inclined surfaces are covered with a heat exchange plate 70 made of a material having excellent thermal conductivity.

Since the heat exchange plate 70 is spaced apart from the upper plate 40 at appropriate intervals, the heat exchange plate 70 and the upper plate 40 have a structure in which cold air introduced from the freezing chamber can move freely.

In addition, a lower portion of the heat exchange plate 70 is provided with a cold air passage 21 through which cold air introduced from the refrigerating chamber passes, and a lower portion of the cold air passage 21 is blocked by the bottom plate 80.

In addition, the front of the bottom plate 80 is provided with a refrigerating chamber cold air inlet 51 into which cold air of the refrigerating compartment flows, and the cold air introduced into the refrigerating compartment cold air inlet 51 passes through a lower portion of the heat exchange plate 70 to allow the cold air outlet ( 60) to go out.

In addition, a drip tray 90 having a lower position than the bottom plate 80 is formed at the lower portion of the cold air outlet 60, and a drain hole 91 is drilled at the lowermost portion of the drip tray.

The dehumidifying apparatus of the conventional refrigerator having the above configuration includes the upper surface of the heat exchange plate 70 while the cold air of the freezer compartment located at the upper portion of the trimming plate 10 flows into the cold air inlet 50 and passes through both cold air passages 21. On the other hand, the cold air of the refrigerating chamber located under the trimming plate 10 enters the cold air inlet 51 and passes through the cold air passage 21 to hit the bottom of the heat exchange plate 70. 70) is cooled to a lower temperature than the cold air of the refrigerating chamber by the cold air of the freezing chamber flowing through the upper surface, so that when the cold air of the refrigerating chamber collides with the heat exchange plate 70, the moisture contained in the cold air of the refrigerating compartment condenses. Dehumidification and dehumidification water generated by the dehumidification action flows down the bottom surface of the inclined heat exchange plate 70 and is then drained to a predetermined place through the drain hole 91 of the drip plate 90.

However, the dehumidifying apparatus of the conventional refrigerator as described above has a low dehumidification efficiency due to the dehumidification of the refrigerating compartment cold air by the cold air of the hot and humid freezer after heat exchange with the storage while circulating the freezer compartment and the refrigerating compartment, so that the moisture absorbed by the evaporator is low. There is a problem that occurs excessively.

In addition, if the amount of defrost water implanted on the heat exchange plate 70 continues to be loaded, the dehumidification efficiency is lowered and the defrost water is absorbed by the cooling air circulated while being in contact with the heat exchange plate. Since the circulating furnace accelerates the growth of the frost on the surface of the evaporator, a predetermined device is required to drain when defrost water of a predetermined amount or more is collected.

The present invention has been made to solve the above problems, has the following object.

First, by arranging a thermoelectric module on the cold air flow path of the trimmer plate, it absorbs moisture from the cold air that contains excessive moisture from food while circulating the inside of the food, so that the amount of cold air circulated through the cold air flow path to the evaporator is titrated. It is an object of the present invention to provide a dehumidifying apparatus of a refrigerator having an adjustable structure so that the structure of the evaporator can prevent growth of frost on the surface of the evaporator.

Second, by adopting a thermoelectric element in which the flow direction of the heat flow is formed according to the current flow direction on the cold air flow path, when a predetermined amount of defrost water forms on the thermoelectric element, the defrost water is frequently drained by converting the electrode of the thermoelectric element. The dehumidifier of the refrigerator having improved structure to improve the cooling performance of the evaporator by maintaining an appropriate amount of moisture in the cold air circulated to the evaporator by preventing the defrost water from being reabsorbed by the cold air passing through the cold air passage while being in contact with the thermoelectric element. The purpose is to provide.

Third, by providing cooling fins that conduct heat between the thermoelectric element and the thermoelectric element on the cold air flow path to forcibly absorb moisture from the circulated cold air, the amount of cold air flowing into the evaporator is reduced, and the frost on the surface of the evaporator grows. The present invention provides a dehumidifying apparatus for a refrigerator having a structure which is suppressed and its structure is improved to reduce power consumption according to a defrosting operation of the evaporator.

1 is a main portion perspective view showing a defrosting device of a conventional refrigerator;

2 is a cross-sectional view of FIG.

3 is a cross-sectional view showing a refrigerator employing a dehumidifying apparatus of the present invention refrigerator;

Figure 4 is an exploded perspective view showing a dehumidifying apparatus of the present invention refrigerator.

* Explanation of symbols for main parts of the drawings

100 ... Freezer 200 ... Freezer

300 ... Trimming plate 310 ... Cold flow path

400 thermoelectric module 410 cooling fins

500 ... blowing fan

The dehumidifying apparatus of the present invention, which achieves the above object, is provided on a cold air flow path of a trimming plate for dividing a freezer compartment and a refrigerating compartment, and a thermoelectric element in which a flow direction of heat flow is changed in accordance with a current flow direction, and a thermoelectric element below It is characterized in that it comprises a blower fan provided in the to facilitate the heat flow flow of the thermoelectric element, and heat dissipation means for conducting heat of the thermoelectric element and extending the heat dissipation area of the thermoelectric element.

The heat dissipation means has a structure in which a predetermined cooling fin is provided to be in contact with one surface of the thermoelectric element so that the heat dissipation area of the thermoelectric element is expanded.

The dehumidifier of the refrigerator of the present invention having the structure as described above provides a thermoelectric element in which a flow direction of heat flow according to the application of current is provided on the cold air flow path to circulate the cold air flow path to force moisture in the cold air circulated around the evaporator. In addition to improving the cooling performance of the refrigerator as well as the absorption of frost growth on the surface of the evaporator is suppressed is characterized in that the power consumption of the defrost of the evaporator is reduced.

Hereinafter, a dehumidifying apparatus of the present invention will be described in detail with reference to the accompanying drawings.

3 and 4 schematically illustrating the dehumidifying apparatus of the refrigerator of the present invention, the dehumidifying apparatus of the refrigerator of the present invention is a cold air flow path of the trimming plate 300 that divides the freezer compartment 100 and the refrigerating compartment 200. A thermoelectric module 400 is provided on the 310 and in which a flow direction of the heat flow is formed according to the flow direction of the current due to the peltier effect.

And the lower portion of the thermoelectric element 400 is provided with a blowing fan 500 to facilitate the flow of heat flow of the thermoelectric element 400 and the heat of the thermoelectric element 400 is conducted by a predetermined heat dissipation means and the thermoelectric element (thermoelectric module) has a structure in which the heat dissipation area is expanded.

In addition, the heat dissipation means is provided with a predetermined cooling fin 410 in contact with the one surface of the thermoelectric element 400, resulting in the expansion of the heat dissipation area of the thermoelectric element 400, so that the bulky thermoelectric element A structure is configured to effectively expand the heat dissipation area of 400.

The dehumidifier of the refrigerator of the present invention configured as described above performs heat exchange with the stored materials while the cold air heat-exchanged around the evaporator 600 circulates through the freezing chamber 100 and the refrigerating chamber 200, and the temperature of the cold air is increased during the heat exchange process. Cold air is absorbed by the stored water and circulated back around the evaporator through the cold air passage 310 formed in the trimming plate 300 to operate a heat exchange operation with the evaporator 600.

As described above, the moisture in the hot and humid cold air passing through the cold air flow passage 310 is condensed on the surface of the cooling fin 410 by the formation of the heat flow of the thermoelectric element 400, and converted into a fluid to form a fine droplet. When the defrost water is collected on the surface of the cooling fin 410 for a predetermined amount or more, the defrost water is smoothly changed by changing the current flow direction of the thermoelectric module 400 to reverse the flow direction of the heat flow. It is operated to drain.

In addition, the defrost water defrosted by the thermoelectric element 400 as described above is because the trimming plate 300 is formed to be inclined to the rear of the refrigerator, the water bottle provided below the defrost heater 700 along the inclined surface of the trimming plate ( 710 to drain.

The dehumidifying apparatus of the refrigerator according to the present invention configured as described above has the following effects.

First, the thermoelectric element 400 installed on the cold air flow passage 310 circulating around the evaporator 600 to circulate around the evaporator 600, the circulation of the freezing chamber 100 and the refrigerating chamber 200 while absorbing a large amount of water from the respective storage. By forcibly absorbing), the dehumidification efficiency in the refrigerator is improved, and the growth of the frost on the surface of the evaporator is suppressed, thereby improving the cooling performance of the evaporator.

Second, growth of frost around the evaporator 600 is suppressed by the thermoelectric element 400 and the cooling fins 410 provided on the cold air flow passage 310 of the trimming plate 300, thereby shortening the defrosting time of the defrost heater. In addition, there is an effect of reducing the power consumption required for defrosting.

Third, the heat flow of the thermoelectric element is smoothly performed by the blowing fan 500 provided below the thermoelectric module 400, so that the dehumidification performance of the thermoelectric element and the cooling fin 410 is improved.

On the other hand, the present invention as described above, of course, various modifications can be made without departing from the scope of the technical idea of the present invention.

Claims (2)

A thermoelectric element provided on a cold air flow path of a trimming plate for dividing the freezer compartment and the refrigerating compartment, and having a change in the flow direction of the heat flow according to the current flow direction, a blower fan provided below the thermoelectric element to promote the heat flow of the thermoelectric element; And a heat dissipation means for conducting heat of the thermoelectric element and expanding the heat dissipation area of the thermoelectric element. The dehumidifying apparatus of the refrigerator of claim 1, wherein the heat dissipation means includes a predetermined cooling fin in contact with one surface of the thermoelectric element to expand the heat dissipation area of the thermoelectric element.