KR200165787Y1 - A fan of heater for refrigerator - Google Patents

Abstract

The present invention is a defrost heater for refrigerators that can greatly improve the reliability of the refrigerator by reducing the starting load by forcibly condensing the heated heat during defrost heater operation to remove frost and reducing the defrost time. To provide a hot air blower of.

To this end, the present invention is a refrigerator in which the defrost heater 80 is mounted on the lower part of the cooler 70 so that defrost is performed by the defrost heater 80, and the heat heated in the defrost heater 80 is cooled by the cooler 70. Hot air blowing means (A) is adjacent to one side of the defrost heater (80) to force convection around the hot air blowing means (A) and the auxiliary blowing fan (2) for blowing the heat and the It consists of a low RPM motor (1) for driving the auxiliary blowing fan (2), the hot air blowing means (A) is operated only when the defrost heater 80 for defrosting to force convection of heated heat It is.

Description

A FAN OF HITER FOR REFRIGERATOR

The present invention relates to a hot air blower for a defrost heater for a refrigerator, and in particular, to condense the heated heat during operation of the defrost heater for eliminating frost, reducing the defrosting time to reduce the temperature rise in the refrigerator to reduce the starting load The present invention relates to a hot air blower for a defrost heater for a refrigerator so as to greatly improve the reliability thereof.

In general, the refrigerator controls the air temperature in a storage compartment in which foods and the like are accommodated by circulation of a refrigerant that is heat-exchanged while being compressed and expanded, thereby refrigerating or freezing the foods stored in the storage compartment. As shown in FIG. 1, the objects (eg, stored food and storage containers, etc.) required for freezing and refrigerating are stored in the upper and lower portions through the intermediate member 20 on the inner middle side of the cabinet 10 and frozen. And refrigeration and refrigerating chambers 30 and 40 are partitioned into a predetermined space so as to be refrigerated, and a rear side of the freezing chamber 30 forcibly circulates air (air) in the freezing and refrigerating chambers 30 and 40. The cold air circulation means 50 is installed so that the cold air is blown in accordance with the operation of the cold air circulation means 50 at the rear side of the freezer compartment 30 at a predetermined distance from the rear wall of the cabinet 10. The damper cover 60 is provided with cold air discharge and suction holes 61 and 62 so as to guide the air and form a cold air environment path in which cold air is discharged to the upper side of the freezing chamber 30 and sucked downward. .

At this time, the cold air circulation means 50 is composed of a blowing motor 51 is driven by the power supplied, and the blowing fan 52 is rotated in accordance with the drive of the blowing motor (51).

The lower part of the cold air circulation means 50 with respect to the damper cover 60 and the cabinet 10 in the freezing and refrigerating chambers 30 and 40 which are smoothed by the blowing force of the cold air circulation means 50. The cooler 70 is installed to heat exchange the cold air to the cold cool water again, and the lower part of the cooler 70 supplies power to remove frost formed on the surface of the cooler 70 when the cooler 70 is operated for a long time. A defrost heater 80 is installed to be turned on and off at regular intervals upon receiving a predetermined time. The defrost heater 80 has a lower portion of the surface of the cooler 70 when the defrost heater 80 is turned on. The drain hose 90 is installed inside the rear wall of the cabinet 10 so as to drain the defrost water generated during the defrosting process.

The lower part of the cabinet 10 collects the defrost water drained along the drain hose 90 at the lower portion of the drain hose 90, and at the same time, the collected defrost water is evaporated by the compression heat of a compressor which will be described later. An evaporation plate 110 is installed at an upper portion of the machine room 100 formed at the rear side, and a compressor 120 is installed at the lower portion of the evaporation plate 110 to compress the circulating refrigerant at a high temperature and high pressure. 10, a condenser 130 is installed on the outer rear wall to receive the gas refrigerant compressed to high temperature and high pressure by the compression action of the compressor 120 and condense it by natural convection.

On the rear side of the intermediate member 20, a first cold passage 150 of a predetermined interval is formed by a cold air flow guide plate 140 so that cold air heat exchanged while passing through the cooler 70 is discharged to the refrigerating chamber 40. On the other side of the intermediate member 20, a second cold passage 160 of a predetermined interval is formed so that the cold air in the refrigerating chamber 40 passes through the cooler 70, and the first cold passage 150 The temperature controller 170 is installed at the upper rear side of the refrigerating chamber 40 to adjust the supply amount of the cold air discharged to the refrigerating chamber 40 through multiple stages (for example, strong cooling or weak cooling).

The front and rear openings of the freezing and refrigerating chambers 30 and 40 are provided with freezing and refrigerating chamber doors 180 and 18l coupled at one end by hinge means (not shown) to open and close in an opening and closing manner. A plurality of shelf members 190 are installed at a predetermined height within 40 so as to be detachable at a predetermined interval from each other so as to load the object.

Here, the cooler 70, as shown in FIG. 2, both side support plates 71 arranged left and right at a predetermined distance from both inner side walls of the mounting space P formed at the inner rear end of the cabinet 10, and the Two pairs of the plurality of refrigerant plates 72 provided at regular intervals in the vertical direction between the two support plates 71 and the ends of the plurality of refrigerant pipes 72 protruding to the outer sides of the both support plates 71. A plurality of return band pipes 73 connected to each other and a refrigerant temperature flowing inside the refrigerant pipe 72 on the outside of the plurality of refrigerant pipes 72 conduct heat to generate heat of the refrigerant and at the same time the cooler 70. Consists of a plurality of heat transfer fins 74 are installed at a predetermined interval to the left and right so as to cool the surface heat exchange with the air rising through the lower portion of the.

At this time, an accumulator (75) is installed at one end of the upper refrigerant pipe (72) among the plurality of refrigerant pipes (72), and one side of the outer circumferential surface of the accumulator (75) is formed of the defrost heater (80). The bimetal thermo 77 (Bimeta1 Thermo) is provided to be bundled by the cable band 76 so as to cut off the power primarily due to the constant overvoltage or failure. The defrost heater 80 is disposed at the lower end of the bimetal thermo 77. A thermo-fuse (79; Thermo Fuse), which is electronically connected via a temperature cable 78, is installed to shut off the power secondaryly due to overvoltage or failure during defrosting.

On the other hand, the both ends of the defrost heater 80, the positive and negative heater cable (8l) 82 is connected so that the AC voltage applied from the power supply means (not shown) is connected, these positive and negative heater cable 81 82 is drawn upward through a predetermined gap formed between both side support plates 71 of the cooler 70 and both inner side walls of the cabinet 10.

In this case, the positive and negative heater cables 81 and 82 are bundled together with the bimetal thermo 77 by the cable band 76 wound around the accumulator 75 according to the mounting method so as not to be loosely fixed.

In the cooler 70 configured as described above, the moisture contained in the water vapor or food in the air contained in the freezer compartment 30 is maintained as the cooler 70 is always cooled. Upon contacting the outer surface and cooling, frost is formed on the outer surface of the cooler 70.

In addition, in the castle generated on the outer surface of the cooler 70, the cooler 70 blocks the contact between the refrigerant flowing into the air and the air contained in the freezer compartment 30, thereby cooling the cooler 70. The efficiency is lowered.

Therefore, the frost generated on the outer surface of the cooler 70 is removed from time to time to facilitate the normal heat exchange action of the cooler 70.

In this case, the frost is removed by using the heat generated by the defrost heater 80 provided as a separate part in the lower portion of the cooler 70 as described above, or the refrigerant flow at a high temperature according to the reverse circulation of the refrigerant, and the freezing chamber 30. The frost is removed by using external air at room temperature according to the opening of the frost.

That is, when the defrost intrudes, the compressor 120 and the blowing fan 52 for circulating cold air are stopped at the same time, and only the defrost heater 80 is operated to remove frost and residual ice of the cooler 70.

However, in the defrosting by the defrost heater 80 in the related art, if only the defrost heater 80 is operated as described above to heat the cold air around the cooler 70 to change the heat to the defrost heater 80, The hot heat heated by the rise of the natural convection through the lower portion of the cooler 70 was defrosted to melt the frost generated on the outer surface of the cooler (70).

Accordingly, when the frost is thick, defrosting takes a long time due to natural convection of heat, and thus the internal temperature rises to increase the starting load, thereby lowering the reliability of the refrigerator.

Therefore, the present invention has been made to solve the above problems, the object of the present invention is to condense the rising heat by heating in the defrost heater to reduce the defrost time by reducing the defrost time to reduce the starting load refrigerator It is to provide a hot air blower for a defrost heater for a refrigerator to significantly improve the reliability of.

The hot air blower for a defrost heater for a refrigerator according to the present invention made to achieve the above object, in the refrigerator to be defrosted by the defrost heater is attached to the lower portion of the cooler, the hot air heated in the defrost heater Hot air blowing means is provided adjacent to one side of the defrost heater to force convection around the cooler.

1 is a longitudinal cross-sectional view showing a conventional refrigerator;

2 is an internal view showing a state in which a defrost heater is installed in a conventional cooler;

Figure 3 is a full longitudinal cross-sectional view of the refrigerator equipped with hot air blowing means according to the present invention,

Figure 4 is an internal view showing a state in which hot air blowing means is installed on one side of the cooler and the defrost heater according to the present invention.

* Explanation of symbols for main parts of the drawings

1: Low RPM motor 2: Auxiliary blower fan

10: cabinet 30: freezer

40: refrigerating chamber 50: cold air circulation means

70: cooler 80: defrost heater

120: compressor 130: condenser

A: Hot air blowing means

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

3 is an entire longitudinal sectional view of a refrigerator equipped with a hot air blowing unit according to the present invention, and 4 is an internal view showing a state where hot air blowing means is installed at one side of the cooler and the defrost heater according to the present invention.

For reference, the same components and the same reference numerals are assigned to the same components as the conventional components in the drawings, and detailed description thereof will be omitted.

3 and 4, the present invention has a defrost heater 80 mounted on the lower portion of the cooler 70, and when the defrost heater 80 starts defrosting, it is heated in the defrost heater 80. Hot air blowing means (A) is provided adjacent to one side of the defrost heater (80) so that the hot air is forced to convection around the cooler (70).

Here, the hot air blowing means (A) is composed of an auxiliary blowing fan (2) for blowing hot heat heated by the defrost heater (80), and a low RPM motor (1) for driving the auxiliary blowing fan (2). The low RPM motor 1 is installed on the inner wall of the cabinet 10 adjacent to the defrost heater 80, and at the same time the compressor 120 and the blower fan 52 stop for the defrosting process. When the 80 is operated, the driving is started to rotate the auxiliary blowing fan 2.

That is, when the defrost heater 80 changes the hot air around the cooler 70 to hot heat, the hot air blowing means A is forced to convection the heated hot air by the blowing force of the auxiliary blowing fan 2. The frost generated on the outer surface of the cooler 70 is quickly melted.

Next, the operation and effects of the present invention configured as described above will be described.

When the compressor 120 installed in the lower part of the cabinet 10 is operated by turning on the main switch (not shown) in order to reach the predetermined temperature, the freezing and refrigerating chambers 30 and 40 are compressed. The high-temperature, high-pressure gas refrigerant compressed by the action flows along the inside of the condenser 130, thereby condensing.

Then, the gas refrigerant condensed while passing through the condenser 130 is phase-reduced into a high temperature and high pressure liquid refrigerant at a temperature slightly higher than the room temperature, which is the ambient temperature of the refrigerator, and decompressed by passing through a capillary tube (not shown). The gas is introduced into the cooler 70 and expanded to vaporize at a low temperature and low pressure, and at the same time, evaporate to cool.

On the other hand, when the blower fan 52 is rotated by receiving the power of the blower motor 51 as the blower motor 51 of the cold air circulation means 50 is operated, the freezing and cooling by the blower of the blower fan 52 The warmth in the refrigerating chambers 30 and 40 merges into the lower part of the cooler 70 through the cold air suction hole 62 formed in the damper cover 60 and the second cold passage 160 formed in the rear side of the intermediate member 20. At the same time, it is raised and passes through the cooler 70, whereby it is heat-exchanged with cold cold by the cooling action of the cooler 70 described above.

The cold air heat exchanged through the cooler 70 is discharged into the freezing chamber 30 through the cold air discharge hole 61 formed at the upper end of the damper cover 60 as the blower fan 52 rotates, thereby freezing the chamber 30. The object stored therein is frozen at a low temperature, and some cold air is introduced into the temperature controller 170 through the first cold air passage 150 formed at the rear side of the intermediate member 20 under the guidance of the cold air flow guide plate 140. At the same time, by controlling the cold air of the temperature control driving unit (not shown), the cold air is supplied into the refrigerating chamber 40 while the cold air supply amount is controlled by strong cooling or weak cooling, thereby refrigerating the object stored in the refrigerating chamber 40 to a low temperature.

Meanwhile, when the cooler 70 is operated for a long time, the defrost heater 80 is operated at regular intervals in order to remove frost formed in the cooler 70. Power is applied to the defrost heater 80 for defrosting. When operated, the cold air around the defrost heater 80 is changed to heat while the compressor 120 and the blowing fan 52 are stopped, and the hot air blowing means provided at one side of the defrost heater 80 ( A low RPM motor (1) of A) is driven to rotate the auxiliary blowing fan (2), by the blowing force of the auxiliary blowing fan (2) heat is forced to convection around the cooler (70) fast time The frost formed on the surface of the cooler 70 is melted within.

In addition, the defrost water flowing into the frost liquid is evaporated plate 110 installed on the rear lower rear side of the cabinet 10 along the drain hose 90 is connected to the evaporation plate 110 and the passage connected to the lower portion of the cooler (70). Is collected.

At this time, the defrost water collected in the evaporation plate 110 is evaporated by the heat of compression by the operation of the compressor 120 installed in the lower portion of the evaporation plate 110.

As described above, according to the hot air blower of the defrost heater for a refrigerator according to the present invention, by providing a hot air blowing means on one side of the defrost heater of the cooler, the hot air heated by the blowing force of the hot air blowing means By forcing convection of heat, it is possible to effectively melt the frost formed on the outer surface of the cooler in a faster time to reduce the starting load caused by suppressing the temperature rise in the refrigerator has the effect of greatly improving the reliability of the refrigerator.

Claims (3)

In a refrigerator in which a defrost heater is attached to a lower part of a cooler to perform defrost by a defrost heater, a hot air blowing means is provided adjacent to one side of the defrost heater so that hot air splatter convectively flows around the cooler in the defrost heater. Hot air blower of the defrost heater for refrigerators. The hot air blower of the defrost heater for a refrigerator according to claim 1, wherein the hot air blower comprises an auxiliary blower fan for blowing heat and a low RPM motor for driving the auxiliary blower fan. The hot air blower of the defrost heater for a refrigerator according to claim 1, wherein the hot air blowing means operates only when the defrost heater is operated.