KR100547326B1 - Defrost control apparatus and method for refrigerator - Google Patents

Abstract

The present invention relates to a defrosting control apparatus and method, in particular for a refrigerator, which enables the evaporator of a refrigerator to control power supply with low capacity and large capacity heater generating capacity for defrosting efficiency.

The defrost control device according to the invention comprises an evaporator having a fin-tube; A defrost heater having an insulation film and a heater wire coated on the insulation film so as to face the evaporator side to remove the surface frost layer of the evaporator; A microcomputer for controlling the heating of the heater of the defrost heater to a low capacity and a large capacity according to the degree of frosting of the frost layer on the surface of the evaporator and the temperature of the refrigerating chamber; And a plurality of heater driving units selectively supplying rectified input power by the microcomputer to the defrost heater.

Refrigerator, defrost heater, evaporator, heater drive unit

Description

Defrost control apparatus and method for refrigerator

1 is a schematic cross-sectional view of a refrigerator.

2 is a view showing another defrosting device of a conventional refrigerator.

3 is a flow chart showing a defrosting method of a conventional refrigerator.

4 is a view showing a defrost control device according to an embodiment of the present invention.

5 is a flow chart showing a defrost control method according to an embodiment of the present invention.

6 is a view showing a first embodiment of a defrost apparatus applied to the present invention.

7 is a view showing a second embodiment of the defrost apparatus applied to the present invention.

<Description of the symbols for the main parts of the drawings>

110 ... Evaporator 120 ... Blower Fan

130 ... Freezer 140 ... Return duct

410 ... temperature sensor 420 ... microcom

431,432 ... heat drive unit 210,310,440 ... defrost heater

The present invention relates to a defrosting control apparatus and method, in particular for a refrigerator, which enables the evaporator of a refrigerator to control power supply with low capacity and large capacity heater generating capacity for defrosting efficiency.

The general principle of the cooling action by the refrigerant in the refrigerator is as follows.

In the refrigerator, the refrigerant reaches the evaporator via a compressor, a condenser and a capillary tube and evaporates in the evaporator. At this time, the heat in the vicinity of the evaporator is absorbed by the absorption of the vaporization heat due to the evaporation action, the cold air generated by this process is circulated to the freezer compartment and the refrigerating compartment to cool the inside of the refrigerator.

Some of the cold air deprived of heat from the evaporator is circulated to the freezer compartment, and the other part is circulated in the refrigerator compartment to cool the inside of the refrigerator. On the other hand, the hot air during the circulation between the freezer compartment and the refrigerating compartment is repeated the heat exchange operation to lose heat by passing through the evaporator.

At this time, the cold air circulated in the freezer compartment and the refrigerating compartment is returned to the evaporator in a state containing moisture in the high temperature, and the moisture contained in the cold air adheres to the evaporator surface in the form of frost as it passes through the evaporator at a very low temperature. .

When such a state accumulates, a large amount of frost is formed on the surface of the evaporator, thereby reducing the heat exchange performance of the evaporator. Therefore, the frost must be removed by operating a heater mounted close to the evaporator every predetermined time. This action is called defrosting.

1 is a block diagram illustrating a structure of a general refrigerator. Referring to the refrigerator, when the refrigerant passing through the compressor, the condenser, and the capillary is sucked into the evaporator 1, the refrigerant is completely vaporized while passing through the evaporator 1. It takes away the heat from the surroundings and cools the surroundings.

Thereafter, the air cooled by the evaporator 1 is provided to the freezer compartment (U) and the refrigerating chamber (L), and thus the cold air having a temperature rise after cooling the inside of the refrigerator is provided in the freezer compartment (U) and the refrigerating chamber (L). Are combined in the cooling passage (3a) of the barrier (3) forming a boundary of the () and flows into the evaporator (1) side.

However, since the air introduced into the evaporator 1 is changed into high temperature and high humidity air while passing through the freezing chamber U and the refrigerating chamber L, the air maintains the temperature below minus 30 degrees. When the surface of (1) flows and the heat exchanges with the refrigerant of 32 degrees Celsius flowing inside the evaporator 1, moisture in the air is instantaneously solidified and a frost layer is formed on the surface of the evaporator 1.

As described above, the frost layer formed on the surface of the evaporator 1 changes into hard ice as time passes and acts as a resistance element of heat transfer between the air and the refrigerant, thereby reducing the heat exchange efficiency of the evaporator 1.

Therefore, in order to prevent the deterioration of the performance of the evaporator 1 generated by the frost layer as described above, the defroster 1 is periodically provided with a defrosting operation.

Figure 2 shows a conventional defrosting apparatus, a defrost heater 14, which is a glass tube heater or a sheath heater, is installed at the bottom of the evaporator 10. In this case, when the heat is generated, the heater heat is not evenly applied to the entire evaporator 10, but only a lower portion of the evaporator 10, such that the defrosting efficiency of the evaporator 10 is greatly reduced. In addition, it takes a certain time until the heater heat is applied to the entire evaporator 10, such that there is a big problem that the power consumption of the refrigerator is greatly increased.

In addition, in order to install the defrost heater 14 at the bottom of the evaporator 10, the lower end of the evaporator 10 should be formed as long as the installation space of the defrost heater 14, thereby limiting the space utilization of the refrigerator. There was also a huge problem. Furthermore, in the case of the sheath heater of the defrost heater 14, because the power density (Watt Density) is high, the resulting surface temperature is raised to about 600 ℃ or more, by the temperature of the sheath heater of the evaporator 10 There was also a big problem such as the risk that the refrigerant (environmentally friendly alternative refrigerant R-600a: ignition temperature 494 ° C.) in the tube 11 exploded.

Next, the defrosting operation of the conventional refrigerator will be described with reference to FIG. 3.

Conventional defrosting operation is a compressor located inside the machine room under the control of a microcomputer (not shown) when the temperature inside the freezer compartment and the refrigerating compartment sensed by a temperature sensor (not shown) inside the freezer compartment and the refrigerating compartment is below a certain temperature. Is driven to operate the cooling cycle (step 101).

Accordingly, the low temperature refrigerant passing through the evaporator located at the rear of the freezer compartment is heat exchanged in the freezer compartment and the refrigerating compartment, and heat exchanges with the high temperature ambient air introduced through the return duct. The ambient air heat exchanged in this way is cooled again so that a part of the ambient air is cooled and driven into the freezing chamber and the other part is supplied into the refrigerating chamber to perform a cooling function.

On the other hand, the refrigerant passing through the inside of the evaporator is converted to a high temperature due to the heat exchange is introduced into the compressor, the cooling cycle is circulated again in accordance with the operation of the compressor is converted to a low temperature refrigerant to circulate to the evaporator.

As described above, when the low temperature refrigerant inside the evaporator 10 is heat-exchanged with the surrounding air according to the operation of the cooling cycle, moisture is accumulated in the evaporator 10 and implanted in the evaporator 10 in the form of frost. When the frost is formed in this manner, since the heat exchange efficiency of the evaporator 10 is lowered, the defrost heater 14 is attached around the evaporator 10 to periodically generate heat to remove the frost.

In this defrosting operation, the defrosting timing determination method of the prior art accumulates the operation time of the refrigeration cycle of the refrigerator using a timer or a microcomputer, and when the predetermined time is reached, the heater generates heat to start the defrosting operation ( Step 103). When the defrost heater generates heat and the temperature around the evaporator increases, the temperature sensor mounted on the evaporator detects the temperature of the evaporator, and when the temperature exceeds a predetermined temperature, the defrosting heater is cut off to stop the defrosting operation. , Step 109).

And while the defrosting is in progress, the refrigeration cycle operation such as the compressor is stopped, so that the generation of cold air is not made and thus the circulation of the refrigerant is not made. Therefore, after the defrosting operation is completed, the freezer compartment temperature is also slightly increased due to the heat generation of the defrost heater.

Meanwhile, the degree of adhesion of the refrigerator evaporator to the castle may be changed by various peripheral factors. That is, the temperature and humidity around the refrigerator, the type of storage stored in the refrigerator, the number of user's involvement, the number of habits, and the state of evaporator's frost are changed according to the habit.

However, the conventional defrost operation control is to perform the defrost operation with a siege heater located at the bottom of the evaporator or an L-coded heater coupled to the evaporator side, and these heaters are in direct contact with the local part of the evaporator, that is, the tube or the like. By defrosting only the adjacent areas, it is difficult to achieve complete defrosting of the entire evaporator.

In addition, as described above, when the operation of the heater is continued and the heat generation is prolonged, the temperature of the freezer compartment also increases, which causes a problem of lowering the refrigeration or freezing state of the internal storage.

In addition, since the conventional refrigerator performs the defrosting operation periodically even when there is almost no opening of the door (night or short absence), only the power consumption due to the heat generation of the heater is increased. In addition, even when the operation rate of the compressor is high and low, the adhesion degree to the frost occurs. That is, when the operation rate of the compressor is low, the degree of defrosting is small compared with the case where the operation rate is high. However, the conventional refrigerators are very inefficient because they always perform a constant defrosting operation regardless of the operation rate of the compressor.

 The present invention has been made to solve the above problems, the defrost heater having a defrost heater attached to both sides of the evaporator, the defrost control device of the refrigerator capable of multi-stage capacity control based on the internal temperature of the refrigerating chamber And to provide a method.

Another object of the present invention, when selecting the exothermic capacity of the defrost heater attached to both sides of the evaporator, defrosting with low heater heat when low capacity is required according to the refrigerating chamber temperature, defrosting with high heater heat if high capacity is required It is an object of the present invention to provide a defrosting control apparatus and method for a refrigerator to control a current of a heater.

Defrost control device according to the present invention for achieving the above object,

An evaporator having a fin-tube; A defrost heater having an insulation film and a heater wire coated on the insulation film so as to face the evaporator side to remove the surface frost layer of the evaporator; A microcomputer for controlling the heating of the heater of the defrost heater to a low capacity and a large capacity according to the degree of frosting of the frost layer on the surface of the evaporator and the temperature of the refrigerating chamber; And a plurality of heater driving units selectively driven by the microcomputer to supply input power to the defrost heater.

Preferably, the defrost heater comprises a first defrost heater faced to the front of the evaporator, a second surface heater faced to the back of the evaporator, a third defrost heater attached to the defrost receiver.

Preferably, the plurality of heater driving units are selectively driven by the microcomputer to supply half-wave rectified or full-wave rectified input power, and supply the rectified power to the connected first, second, and third defrost heaters. It is done.

Defrost control method according to the present invention, the low-temperature refrigerant passing through the inside of the evaporator located behind the freezer compartment is heat exchanged in the freezer compartment, the inside of the refrigerating compartment and heat exchanged with the high-temperature ambient air introduced through the return duct, the heat exchanged ambient In the defrosting control method performed between the refrigeration cycle in which the air is cooled again and some of the air is supplied to the freezing compartment by the driving of the blowing fan and the other is supplied into the refrigerating compartment to perform the cooling function. step;

Sensing the temperature of the freezing compartment in the case of the defrost time, and controlling any one of the plurality of heater driving units according to the sensed temperature to control the heating of the heater of the defrost heater to a small capacity or a large capacity; And defrosting the heater when the temperature of the refrigerating chamber reaches a predetermined temperature due to defrosting according to the heater heat generation capacity of the defrost heater.

Hereinafter, with reference to the accompanying drawings as follows.

4 is a defrost control device according to an embodiment of the present invention.

Referring to FIG. 4, a defrost heater 440 by half-wave rectifying an input alternating current according to a temperature sensing unit 410 for detecting a temperature of a freezer compartment, a microcomputer 420 for controlling the refrigeration cycle, and a driving control signal of the microcomputer. The first heater driver 431 to be supplied to the second heater driver 431 and the second heater driver 432 for full-wave rectifying the input AC to the defrost heater 440 according to the drive control signal of the microcomputer.

 The first and second heater drivers 431 and 432 share a transformer T1 for converting an input alternating current into a direct current, and the first heater driver 431 switches on / off an output of the transformer T1. S1 and a diode D1 half-wave rectified by turning on the switch S1, the second heater driver 432 includes a switch S2 for turning on / off the output of the transformer T1, and a switch. It consists of the diode D2 which full-wave rectifies by turning on (S2).

The defrosting apparatus and method for a refrigerator according to the present invention as described above will be described with reference to the accompanying drawings.

Defrost control apparatus according to an embodiment of the present invention is the same as Figure 4, Figure 5 is a flow chart illustrating a defrost control method using the defrost control device of FIG.

First, referring to FIGS. 4 and 5, the defrosting operation is performed by a microcomputer (not shown) when the temperature inside the freezer compartment and the refrigerating compartment sensed by the temperature detector 410 inside the freezer compartment and the refrigerating compartment is below a predetermined temperature. Under control, a compressor located inside the machine room is driven to operate a cooling cycle (step 301).

Accordingly, the low temperature refrigerant passing through the evaporator located at the rear of the freezer compartment is heat exchanged in the freezer compartment and the refrigerating compartment, and is heat exchanged with the high temperature ambient air introduced through the return duct. The ambient air exchanged in this way is cooled again, and partly supplied to the freezing chamber by the driving of the blower fan and the remaining part is supplied into the refrigerating chamber to perform the cooling function.

On the other hand, the refrigerant passing through the evaporator is converted to a high temperature due to the heat exchange is introduced into the compressor, the cooling cycle is circulated again in accordance with the operation of the compressor is converted to a low temperature refrigerant to circulate to the evaporator.

As described above, when the low-temperature refrigerant inside the evaporator exchanges heat with the surrounding air in accordance with the operation of the cooling cycle, moisture accumulates in the evaporator and is implanted in the evaporator in the form of frost. If much frost is formed by this action, since the heat exchange efficiency of the evaporator is lowered, the defrost heater is attached around the evaporator to periodically generate heat to remove the frost.

In this defrosting operation, the microcomputer 410 accumulates the operation time of the refrigeration cycle, and when the predetermined time is reached, the defrost heater 440 generates heat to start the defrosting operation. At this time, the temperature sensing unit 410 detects the temperature of the freezer compartment and selects the heater heat generation and the heat generation capacity.

Here, when the temperature of the freezer compartment requires a low heat generation capacity, the first heater driving unit 431 is driven (S1 on). That is, the half-wave rectifier circuits T1 and D1 are driven so that the output of the defrost heater is half-wave rectified relative to the AC input AC. Accordingly, since the capacity of the defrost heater 440 is supplied and cut off every half cycle, the heater generating capacity defrosts the surface frost layer of the evaporator with a low capacity.

Then, when the temperature of the freezer compartment requires a high heat generation capacity, the second heater driving unit is driven (S2 on). That is, the full wave rectifier circuits T1 and D2 are driven to allow full-wave rectification of the output of the defrost heater relative to the AC input AC. As a result, the capacity of the defrost heater is supplied with electric current for the entire cycle, so that the heater generating capacity is high and the surface frost layer of the evaporator is defrosted.

That is, the microcomputer 420 turns on the switch S1 of the first heater driving unit 431 when the heater heating capacity of the low capacity is required, and supplies a half-wave rectified DC to the defrost heater 440, thereby providing surface frost of the evaporator. Defrost the floor. On the contrary, when a large amount of heater heating capacity is required, the switch S2 of the second heater driving unit is turned on so that the output of the transformer T1 is full-wave rectified by the diode D2 via the switch S2 and then the defrost heater. Supplied to 440. Accordingly, the defrost heater 440 is supplied with full-wave rectified DC, thereby defrosting the surface frost layer of the evaporator with a large capacity of the heater generated.

Then, after checking whether or not the temperature of the freezer compartment has reached a certain temperature, if it does not reach again to perform from S305, at this time, it is preferable to enable the capacity switching in the state of continuous power supply to the defrost heater. When the temperature of the freezer compartment reaches a certain temperature, the defrosting heater is turned off to turn off the defrosting operation.

And while the defrosting is in progress, the refrigeration cycle operation such as the compressor is stopped, so that the generation of cold air is not made and thus the circulation of the refrigerant is not made. Therefore, after the completion of the defrosting operation, the freezer compartment temperature is also slightly increased due to the heat generation of the defrost heater.

This defrost control method allows the heater to be controlled with a low capacity and a large capacity for the defrost heater when the capacity of the defrost heater is a large capacity or simultaneously performs defrosting for the entire area of the evaporator. To this end, the defrost heater applied to the present invention is as shown in FIGS. 6 and 7.

6 is a view showing a first embodiment of a defrosting apparatus of a refrigerator applied to the present invention. Referring to FIG. 6A, an evaporator 110 for generating cold air, a blowing fan 120 for discharging the generated cold air, a freezing chamber 130 and a refrigerating chamber, and a return duct 140 for returning cold air And a defrost heater 210 for pressing the sides of the evaporator 110 and the fan shroud 150 and the freezing chamber inner wall 160 to defrost the surface of the evaporator.

As shown in (b) of FIG. 6, the defroster of the refrigerator includes a fin-tube integrated evaporator 110 and a heater wire 211 for removing frost by contacting the evaporator 110 with a curved surface. 212 is covered with a defrost heater 210 formed inside, the outer shape of the wavefront shape.

The evaporator 110 is formed through a louvering process after integrally extruding the tube 111 and the tube 111 to connect the inlet to the outlet of the expansion valve and the outlet to the inlet of the compressor to guide the refrigerant to the compressor. The pin 112 and the tube bracket 113 is arranged on the left and right of the tube 111 to support the tube side portion. The defrost heater 210 is a heating element of the "-" shape of the heater wire 211 and the heat generating in accordance with the power supply, the front and rear of the evaporator is adhered to the inside and the heater wire is crimped for insulation and protection and the bone and It is the structure containing the wave-shaped insulating film 212 which consists of an acid.

Referring to FIG. 6, in the evaporator 110, cold air generated by taking away ambient heat and evaporating a refrigerant in a gaseous state is discharged to each of the freezer compartment 130 and each shelf of the refrigerating compartment by the blowing fan 120. The refrigerant phase-changed by the evaporator 110 into a low-temperature low-pressure gas phase state is flowed to a compressor (not shown) and compressed from the low temperature low pressure to the high temperature high pressure through the compressor, and the compressed high temperature high pressure gas phase refrigerant passes through the condenser. Cooled and condensed in the process to phase change to a high-pressure liquid state, the refrigerant phase-changed to a high-pressure liquid state is passed through an expansion valve (not shown) while reducing the pressure (e.g., to be easily evaporated by heat exchange in the evaporator 110) Thermal expansion), and then flows to the evaporator 110 where the evaporation process of the refrigerant is performed. As described above, the refrigerant introduced into the evaporator 110 changes its phase into a low-temperature low-pressure gas phase state through an endothermic action that absorbs heat inside the refrigerator. After cooling the air around it, it forms a refrigeration cycle that flows back into the compressor.

At this time, the cooled air (cold air) is lost to the refrigerant through heat exchange with the evaporator 110 is formed on the inner wall of the freezer compartment 130 and the rear side of the refrigerating chamber by the driving of the blower fan 120 installed on the top of the evaporator (110). The temperature of the freezer compartment 130 and the refrigerating compartment is lowered as the discharge circulation circulates through the cold air outlet.

Meanwhile, when each cold air whose temperature is raised by circulating through the freezing chamber 130 and the refrigerating chamber is supplied to the evaporator 110 again through the return duct 140 and recooled, the inside of the tube 111 of the evaporator 110 is cooled. Frost is formed on the surface of the evaporator 110 due to a temperature difference between the refrigerant flowing through the freezing chamber 110 and the refrigerating chamber 120 and re-introduced into the evaporator 110, and implanted on the surface of the evaporator 110. The defrost is defrosted by the defrost heater 210 adhered to both sides of the evaporator.

Since the defrost heater 210 has a wavefront shape and is compressed between both sides of the evaporator and the fan shroud 150 and the refrigerator inner wall surface 160, the defrost heater heat can be directly transmitted from the evaporator. It will melt the frost layer.

In addition, the evaporator 110 is a fin-tube integral type, and includes a tube 111, a fin 112, and a tube bracket 113. The tube 110 has a structure in which the S 110 is stacked and communicated in a vertical direction to guide the refrigerant to the compressor, and arranged in two rows side by side in the horizontal direction. Fin 112 is integrally extruded between the "S" shaped tube 111 arranged horizontally and then formed through a louvering process, thereby improving heat exchange performance. Here, the fin 112 is bent about 70 to 75 degrees along the longitudinal direction of the tube 111 through louvering so that air can pass from the lower end of the tube to the upper direction in the center of the fin formation portion of the tube 111. Many are formed continuously. In addition, the tube bracket 113 has a trapezoidal structure such that a plurality of vertically arranged and horizontally arranged tubes 111 are inserted at the intersections of straight and curved lines at the left and right sides of the “S” shaped tube 111. Will be supported.

On the other hand, the defrost heater 210 is composed of an insulating film 212 and the heater wire 211, the insulating film 212 is a film of a strong and flexible material at a high temperature, the square-shaped surface is acid and valley shape (Or irregularities) to take a wavefront. The defrost heater 210 has a first defrost heater 220 that is opposed to the front of the evaporator 110, a second defrost heater 230 that is opposed to the back of the evaporator 110, the bottom position of the evaporator 110 In the first and second defrost heaters 220, 230, the third defrost heater 240 for receiving the defrost water branching from the lower end is integrally formed.

As described above, the defrost heater 210 is attached to the evaporator 110 to be folded in a round structure to surround the front and the back of the evaporator, the cold air inlet in the lower portion so that the air of the refrigerating chamber and the freezing chamber can pass through the return duct. (Not shown) is open.

In addition, the same space as the cold air inlet (not shown), which is opened for air circulation in the lower portion of the defrost heater 210, is attached to the defrost water receiver as the third defrost heater 240 for defrost water receiving, so that defrost water falling from the evaporator, or If ice cubes that do not become water fall on the defrost tray, they are heated and the heated air rises to convection. That is, a cold air inlet for air circulation is provided in the lower portion of the defrost heater 210 and a third defrost heater 240 for defrost water receiving is installed to defrost ice chunks that have not become water, thereby opening a flow path through which defrost water flows. It prevents occlusion, and as it is located at the bottom of the evaporator, the heated air rises by convection to aid in defrosting.

The defroster is designed to operate at a predetermined time by the refrigerator control system. In the case of medium / large size, the surface temperature of the defrost heater rises to a certain temperature (for example, about 200 ° C.) during operation, so that the frost accumulated on the surface of the evaporator is increased. The layer can be melted.

7 is another defrosting apparatus applied to the present invention. As shown in FIG. 7, the defrost heater 310 for defrosting the evaporator 110 is a planar heater, and has a rectangular insulation film 312 and a heater wire having a loop having a “d” shape inside the insulation film. 311 is fixed at a predetermined interval, and the first and second defrost heaters 320 and 330 surround the front and rear surfaces of the evaporator 110 and are in surface contact with each other, and the third defrost heater 340 is disposed on the defrost water receiver. By being attached, it is possible to perform defrosting evenly in the defrost and defrost receiver in contact with the evaporator tube exposed surface.

As the defrost heater applied to the present invention is in surface contact with both sides of the evaporator as shown in FIGS. 6 and 7, the microcomputer selects a plurality of heater driving units as shown in FIG. 4 to control the heater heat generation capacity of the defrost heater. By controlling to be supplied, faster defrosting is possible by maximizing the heater generating capacity, thereby controlling the current capacity in multiple stages so that defrosting can be performed more efficiently and with optimal power consumption.

For example, when the defrost heaters illustrated in FIGS. 6 and 7 are divided into first, second, and third defrost heaters, respectively, and each of the defrost heaters is to be driven as an independent heater or an independent loop, the respective defrost heaters May be connected to different heater driving units to control defrost by supplying half-wave rectified or full-wave rectified power to individual or shared power.

The fixing structure of the defrost heater configured as described above is not only a top-type refrigerator applied as an embodiment of the present invention, but also a bottom-type in which a refrigerating compartment is located at the top and a freezer compartment is at the bottom. The refrigerator and the freezer compartment and the refrigerating compartment of the can also be applied to the side by side type (Side By Side-Type) refrigerators located on the left and right sides of the main body.

As described above, according to the defrosting apparatus for a refrigerator according to the present invention, when a small amount of heater heat generation amount is required for a defrost heater that surrounds and contacts both sides of the evaporator, each heater is required. By controlling the defrosting by using the drive unit, the heater generates heat at a high or low temperature, by controlling the heat generation of the defrost heater in multiple stages according to the amount of implantation, there is a safety effect against explosion-hazardous substances such as R-600a have.

Claims (4)

An evaporator having a fin-tube; A defrost heater having an insulation film and a heater wire coated on the insulation film so as to face the evaporator side to remove the surface frost layer of the evaporator; A microcomputer for controlling the heating of the heater of the defrost heater to a low capacity and a large capacity according to the degree of frosting of the frost layer on the surface of the evaporator and the temperature of the refrigerating chamber; And a plurality of heater driving units selectively supplying rectified input power driven by the microcomputer to the defrost heater. The method of claim 1, The defrost heater comprises a first defrost heater attached to the front of the evaporator, a second surface heater attached to the back of the evaporator, a third defrost heater attached to the defrost receiver. The method according to claim 1 or 2, Defrost control, characterized in that the plurality of heater driving unit is selectively driven by the microcomputer to supply half-wave rectification and full-wave rectification of the input power, and supply the rectified power to the connected first, second, third defrost heater Device. Low-temperature refrigerant passing through the evaporator located behind the freezer compartment is heat exchanged inside the freezer compartment and the refrigerating compartment to exchange heat with the high-temperature ambient air introduced through the return duct. In the defrosting control method is made between the refrigeration cycle of which a part is supplied to the freezer compartment and the remaining part is supplied into the refrigerating compartment to perform a cooling function, Checking whether the defrosting time is performed by a refrigeration cycle operation; Sensing the temperature of the freezing compartment in the case of the defrost time, and controlling any one of the plurality of heater driving units according to the sensed temperature to control the heating of the heater of the defrost heater to a small capacity or a large capacity; Defrosting control method comprising the step of turning off the heater when the temperature of the refrigerating chamber reaches a predetermined temperature in the defrost according to the heater heat generation capacity of the defrost heater.

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