KR20180025012A - Refrigerator and method for controlling defrosting of the same - Google Patents

Abstract

The present invention relates to a refrigerator and a method for controlling defrosting thereof. According to the present invention, to reduce consumption of unnecessary power caused by conventional defrosting, when a predetermined defrosting stop condition is satisfied, defrosting is stopped for a predetermined defrosting stop time. As stated above, when defrosting is stopped for a predetermined time, a frost is continuously removed by remaining heat of a defrosting means. Moreover, power to operate the defrosting means is not consumed to reduce power consumed from defrosting compared to the prior art.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a defroster operation control method for a refrigerator,

The present invention relates to a defrosting control method for a refrigerator and a refrigerator.

The refrigerator is a device which can keep the food fresh for a certain period by cooling the freezing room or the refrigerating room to a specific temperature while repeating a freezing or a refrigerating cycle. Generally, a refrigerator includes a main body defining a storage space and a door opening or closing the storage space. The storage space stores a storage such as food and the user can open the door to store the storage or to withdraw the stored storage.

In order to lower the temperature inside the storage space of the refrigerator, the refrigerator is equipped with an evaporator. The evaporator lowers the ambient temperature by using cool air generated by the circulation of the refrigerant flowing through the cooling pipe. The low-pressure and low-temperature refrigerant flowing in the evaporator evaporates and absorbs the surrounding heat to generate cold.

When the refrigerant flowing through the cooling pipe of the evaporator evaporates as described above, the water vapor introduced into the interior of the room at room temperature or the water vapor evaporated by the moisture contained in the food stored in the compartment is condensed as a glaze on the surface of the low- do. Condensation on the surface of the evaporator lowers the efficiency of heat exchange, thereby lowering the cooling efficiency of the refrigerator and increasing the power consumption. Therefore, defrosting means and defrosting operation for removing condensation on the surface of the evaporator are applied to the refrigerator.

According to the prior art, the defrosting operation is performed according to a certain period (for example, 12 hours interval) in order to remove the condensation which is condensed on the surface of the evaporator or around the evaporator. The defrosting operation should be performed to sufficiently remove the condensation on the surface of the evaporator or around the evaporator, but it is difficult to directly measure the amount of the condensation on the surface of the evaporator or around the evaporator.

Therefore, conventionally, the defrosting operation is performed until a predetermined defrosting operation time (for example, 30 minutes) elapses, or the defrosting device is driven until the surface temperature of the evaporator reaches a preset defrost termination temperature. During the defrosting operation, the condensed gas is melted on the surface of the evaporator and around the evaporator by the heat emitted by the defrosting means.

The defrosting operation time or the defrost termination temperature according to the prior art is set in advance through testing under various conditions at the time of manufacturing the refrigerator. However, the environment in which the user actually uses the refrigerator may differ from the environment at the time of testing. Accordingly, the efficiency of the defrosting operation is changed.

For example, the defrosting operation may continue even though the defrosting operation time or the defrost termination temperature has already reached, even though the defrosting has already melted. In particular, much power is consumed in driving the defrosting means. In this case, unnecessary power for driving the defrosting means is consumed.

As another example, when the defrosting operation time or the defrost termination temperature has reached a preset level and the defrosting operation is terminated, the property may not be sufficiently removed. For example, if the refrigerator is used in an area with higher humidity than other areas due to its local characteristics, a large amount of wind may be generated on the evaporator surface or around the evaporator. If a normal defrosting operation is performed in such a situation, the property may not be sufficiently removed. Therefore, there is a problem that the cooling efficiency of the refrigerator is lowered and the power consumption is increased due to the property remaining on the surface of the evaporator or around the evaporator.

An object of the present invention is to provide a refrigerator and a defrosting control method of a refrigerator which can reduce power consumption due to unnecessary driving of a defrosting means by temporarily stopping the defrosting operation according to a specific condition during a defrosting operation of the refrigerator.

The present invention also relates to a defroster operation control system for a refrigerator and a refrigerator which can increase the defrosting efficiency and the cooling efficiency of the refrigerator by performing the defrosting operation again when the defrosting operation is not sufficiently removed due to the defrosting operation according to the preset defrosting operation time or the defrost termination temperature It is another purpose to provide a method.

The objects of the present invention are not limited to the above-mentioned objects, and other objects and advantages of the present invention which are not mentioned can be understood by the following description and more clearly understood by the embodiments of the present invention. Also, the objects and advantages of the invention will be readily appreciated that this can be realized by the means as claimed and combinations thereof.

Defrosting operation should be performed to sufficiently remove condensation on the surface of the evaporator or around the evaporator. However, as described above, it is difficult to directly measure the amount of the condensation on the surface of the evaporator or around the evaporator. Therefore, conventionally, the defrosting operation is performed based on the predetermined defrosting operation time or the defrost termination temperature.

However, since the conventional defrosting operation is performed without consideration of the actual amount of condensation on the surface of the evaporator or the periphery of the evaporator, the defrosting operation may continue even though the air has already melted. In this case, unnecessary power for driving the defrosting means is consumed.

In the present invention, when the predetermined defrost stop condition is satisfied, the defrost operation is stopped for a predetermined defrost stop time to reduce unnecessary power consumption. In this way, when the defrosting operation is stopped for a predetermined time, the defrosting continues due to the residual heat of the defrosting means. On the other hand, since the power is not consumed for driving the defrosting means, the power required for the defrosting operation is reduced.

On the other hand, when the defrosting means is stopped too frequently in order to reduce the power for driving the defrosting means, more power is consumed in stopping and restarting the defrosting means. In addition, if the defrosting means is stopped too frequently, the defrosting means can not reach the target temperature for removing the defrosting, which increases the power consumption. Therefore, in the present invention, the number of times the defrosting operation is stopped is limited to a certain number of times or less.

In addition, as described above, the defrosting operation time or the defrost termination temperature may be reached, and the defrosting may not be sufficiently removed even after the defrosting operation is terminated. In order to solve such a problem, in the present invention, defrosting operation is resumed when the surface temperature of the evaporator is lower than the defrost stop temperature after the defrosting termination condition is satisfied and the defrosting operation is terminated. Accordingly, the remaining property can be removed without being removed by the normal defrosting operation.

A method for controlling a defrost operation of a refrigerator according to an embodiment of the present invention includes the steps of starting a defrosting operation, determining whether a predetermined defrost termination condition is satisfied, determining whether a defrost termination condition Stopping the defrosting operation for a predetermined defrosting stop time when the defrost stop condition is satisfied, and ending the defrosting operation if the defrost termination condition is satisfied.

According to another aspect of the present invention, there is provided a refrigerator comprising: a storage space; an evaporator disposed on one side of the storage space for absorbing heat of a fluid present in a peripheral space to cool the fluid; And a control unit for performing a defrosting operation by driving the defroster means in accordance with a preset condition, wherein the control unit controls the defrosting operation of the defrosting unit Determining whether or not a predetermined defrost termination condition is satisfied, determining whether a predetermined defrost stop condition is satisfied if the defrost termination condition is not satisfied, and, if the defrost stop condition is satisfied, And when the defrost termination condition is satisfied, Characterized in that the entire end.

According to the present invention, there is an advantage that power consumption due to unnecessary driving of the defrosting means can be reduced by temporarily stopping the defrosting operation according to a specific condition at the time of defrosting operation of the refrigerator.

According to the present invention, defrosting operation is performed again when defrosting operation is not sufficiently removed due to defrosting operation according to a predetermined defrosting operation time or defrost termination temperature, thereby improving the defrosting efficiency and the cooling efficiency of the refrigerator.

1 is a longitudinal sectional view schematically showing a configuration of a refrigerator according to an embodiment of the present invention;
2 is a front view of an evaporator provided in a refrigerator according to an embodiment of the present invention;
3 is a configuration diagram of a refrigerator that performs defrosting control according to an embodiment of the present invention.
4 is a flowchart of a defrost operation control method according to an embodiment of the present invention.
5 is a timing chart showing a defrosting operation time according to a defrosting operation control according to an embodiment of the present invention;

The above and other objects, features, and advantages of the present invention will become more apparent by describing in detail exemplary embodiments thereof with reference to the attached drawings, which are not intended to limit the scope of the present invention. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail. Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to denote the same or similar elements.

1 is a longitudinal sectional view schematically showing a configuration of a refrigerator according to an embodiment of the present invention.

Referring to FIG. 1, a storage space, that is, a freezing chamber 102 and a refrigerating chamber 104 are formed in a main body 106 of a refrigerator along a vertical direction with a partition 118 interposed therebetween. The freezing compartment door 108 and the refrigerating compartment door 110 are hingedly coupled to the main body 106 so that the freezing compartment 102 and the refrigerating compartment 104 can be opened and closed at the front of the freezing compartment 102 and the refrigerating compartment 104, respectively.

A shroud member 112 is provided at a rear portion of the freezing chamber 102 so as to be spaced from the inner wall of the main body 106 by a predetermined distance so that the air flow passage 126 may be formed. A grill member 114 having an air outlet 116 is formed on one side of the shroud member 112. Likewise, a grill member 132 having an air outlet 134 is also provided in the refrigerating chamber 104.

The freezing chamber return flow path 120 is formed in one side of the partition 118 so that the air in the freezing chamber 102 can return to the air flow path 126. In the other side of the partition 118, The refrigerating chamber return flow path 122 is formed so as to return to the air flow path 126.

An evaporator 124 for exchanging the heat of the air introduced into the air passage 126 through the return passages 120 and 122 is provided in the air passage 126 formed in the rear region of the freezing chamber 102. A blowing fan 128 for introducing the air having passed through the evaporator 124 to the inside of the freezer compartment 102 or the refrigerating compartment 104 is provided at an upper portion of the evaporator 124.

A compressor 130 is installed in the rear lower region of the main body 106 so as to compress the refrigerant delivered from the evaporator 124. A refrigerant compressed by the compressor 130 is discharged to one side of the compressor 130, A condenser (not shown) is provided.

With this configuration, when the blowing fan 128 rotates, air in the freezing chamber 102 or the refrigerating chamber 104 flows into the lower portion of the evaporator 124 through the return flow paths 120 and 122. The air introduced into the lower portion of the evaporator 124 is cooled while passing through the evaporator 124 and the cooled air is supplied into the freezing chamber 102 or the refrigerating chamber 104 by the blowing fan 128.

1 is a top-mount type refrigerator in which a freezing chamber 102 is disposed above a refrigerating chamber 104, but the present invention is not limited thereto. That is, the present invention is also applicable to a side-by-side type refrigerator in which a refrigerating compartment and a freezing compartment are arranged in left and right sides, a bottom freezer type refrigerator in which a refrigerating compartment is provided in an upper portion and a freezing compartment is provided in a lower portion Can be applied.

1, an evaporator 124 is disposed only in a rear region of the freezer compartment 102. However, in another embodiment of the present invention, an evaporator may be disposed on a rear surface of the freezer compartment 104. [

Hereinafter, the structure and function of the defrosting device of the present invention for removing the condensation on the surface of the evaporator 124 will be described in more detail with the evaporator 124 as the center.

2 is a front view of an evaporator and a defrost apparatus provided in a refrigerator according to an embodiment of the present invention.

Referring to FIG. 2, the evaporator provided in the rear region of the freezing chamber 102 includes a cooling pipe 208, a plurality of cooling fins 210, and an accumulator 216. As shown in FIG. 2, the evaporator is disposed in one side of a storage space, that is, a freezing chamber or a refrigerating chamber, and absorbs heat of a fluid such as air present in the surrounding space to cool the fluid.

The cooling pipe 208 is repeatedly bent in a zigzag fashion to form a plurality of rows, and the inside is filled with refrigerant. The cooling pipe 208 may be composed of a combination of a horizontal pipe portion and a bending pipe portion. The horizontal piping portions are arranged horizontally to each other in the vertical direction, and are configured to penetrate the cooling fin 210. The bending piping portion is configured to connect the ends of the upper horizontal piping portion and the lower horizontal piping portion to each other to communicate with each other. Further, the cooling pipe 208 may be configured to form a plurality of rows in the front-rear direction.

A plurality of cooling fins 210 are arranged in the cooling pipe 208 at predetermined intervals along the extending direction of the cooling pipe 208. The cooling fin 208 may be formed of a flat plate made of a metal such as aluminum. The cooling pipe 208 can be firmly fixed in the insertion hole by being expanded in a state of being inserted into the insertion hole formed in the cooling fin 210. [

The refrigerant that has passed through the cooling pipe 208 and absorbs the surrounding heat is transferred to the accumulator 216. The accumulator 216 separates the unabsorbed liquid refrigerant from the delivered refrigerant so that the liquid refrigerant is not delivered to the compressor.

On one side of the cooling pipe 208, for example, below the cooling pipe 208, a defrosting means 212, for example a heater, is disposed. The defrosting unit 212 is electrically connected to a power source unit (not shown), and is driven when power is applied under control of a control unit (not shown) to emit heat. The operation in which the defrosting means 212 generates heat for a certain period of time is referred to as a defrosting operation. A control unit (not shown) performs a defrosting operation by driving the defrosting means 212 in accordance with a preset condition. When the defrosting operation is performed, the heat generated by the defrosting means 212 is transferred toward the cooling pipe 208 of the evaporator. Condensation on the surface of the cooling pipe 208 can be removed by the heat transferred in this way.

A blowing fan 128 is provided in an upper area of the cooling pipe 208. The air blowing fan 128 sucks the air in the axial direction and discharges the air in the radial direction. When the blowing fan 128 is driven, the high-temperature, high-pressure air existing in the lower region of the cooling pipe 208 flows through the cooling pipe 208 toward the blowing fan 128. The high-temperature and high-pressure air that has passed through the cooling pipe 208 is converted into low-temperature and low-pressure air due to the cooling action by the cooling pipe 208. The air thus cooled is introduced into the refrigerator by the blowing fan 128, and the introduced air is discharged into the refrigerator through the discharge ports 302, 304, and 306.

The defrost temperature sensor 214 is disposed on one side of the evaporator, measures the surface temperature of the evaporator, and transmits the measured temperature to a control unit (not shown). 2, the defrost temperature sensor 214 is disposed in the upper right region of the evaporator, but the position of the defrost temperature sensor 214 may vary according to the embodiment.

The control unit (not shown) drives the defrosting unit 212 or stops the defrosting unit 212 in accordance with a preset condition.

In an embodiment of the present invention, the control unit (not shown) may drive the defrosting unit 212 so as to satisfy the predetermined defrost termination condition. In the present invention, the defrost termination condition may include whether the defrosting operation time has elapsed or whether the surface temperature of the evaporator and the defrost termination temperature coincide with each other. For example, the control unit (not shown) may drive the defrosting unit 212 until a predetermined defrosting operation time is reached. If the defrost operation time is set to 30 minutes, the control unit (not shown) drives the defrosting unit 212 for 30 minutes.

As another example, the control unit (not shown) may drive the defrosting unit 212 until the surface temperature of the evaporator coincides with the predetermined defrost termination temperature. For example, if the defrost termination temperature is set to 5 캜, the control unit (not shown) can drive the defrosting unit 212 until the surface temperature of the evaporator measured by the defrost temperature sensor 214 reaches 5 캜 have.

Also, in an embodiment of the present invention, the control unit (not shown) may temporarily stop the driving of the defrosting unit 212 when the predetermined defrost stopping condition is satisfied. In the present invention, the defrosting stop condition may include whether or not the surface temperature of the evaporator coincides with the predetermined defrost stop temperature and whether the defrost stopping frequency is less than a predetermined reference frequency. For example, if the defrost stop temperature is set to 0 deg. C and the reference frequency is set to two times, the controller (not shown) controls the evaporator temperature to be 0 deg. C and the defrost stop frequency The defrosting means 212 can be temporarily stopped. At this time, the control unit (not shown) can stop defrosting operation by stopping the defrosting means 212 for a predetermined defrost stopping time (for example, 3 minutes).

In one embodiment of the present invention, the defrost stop temperature is preferably set to be lower than the defrost termination temperature. Also, in one embodiment of the present invention, the reference frequency can be arbitrarily set by the user, and is preferably set to 5 or less. More preferably, the reference number is set to 3 or less.

On the other hand, the control unit (not shown) compares the surface temperature of the evaporator with the defrost stop temperature after the defrost termination condition is satisfied, and when the surface temperature of the evaporator is lower than the defrost stop temperature, The defrosting operation can be resumed. It is preferable that the operation time of the defrosting operation resumed at this time is shorter than the predetermined defrosting operation time.

FIG. 3 is a block diagram of a refrigerator for performing a defrost operation control according to an embodiment of the present invention, and FIG. 4 is a flowchart of a defrost operation control method according to an embodiment of the present invention. Hereinafter, a defrosting control method according to an embodiment of the present invention will be described in detail with reference to FIGS. 1 to 4. FIG.

First, the control unit 302 drives the defrosting means 304 to start defrosting operation (402). As described above, the control unit 302 can start defrosting operation in accordance with a preset cycle (for example, 12 hours).

When the defrosting operation is started, the control unit 302 determines whether a predetermined defrost termination condition is satisfied (404). In the present invention, the defrost termination condition may include whether the defrosting operation time has elapsed or whether the surface temperature of the evaporator and the defrost termination temperature coincide with each other.

For example, in step 404, the control unit 302 can determine whether the driving time of the defrosting means 304 measured by the timer 306 has reached a preset defrosting operation time (for example, 30 minutes) . If the driving time of the defrosting means 304 reaches the defrosting operation time, the control section 302 terminates the defrosting operation by stopping the driving of the defrosting means 304 (410). However, if the driving time of the defrosting means 304 has not yet reached the defrosting operation time, the controller 302 makes a judgment according to the step 406. [

As another example, the control unit (not shown) may drive the defrosting unit 212 until the surface temperature of the evaporator coincides with the predetermined defrost termination temperature. For example, when the surface temperature of the evaporator measured by the defrost temperature sensor 308 reaches 5 占 폚 in a state where the defrost termination temperature is set to 5 占 폚, the control unit 302 stops driving the defrosting means 304, The operation is terminated (410). However, if the surface temperature of the evaporator has not reached 5 [deg.] C, the controller 302 performs the determination according to step 406. [

Referring again to FIG. 4, when it is determined that the predetermined defrost termination condition is not satisfied, the control unit 302 determines whether the predetermined defrost stop condition is satisfied (406).

In the present invention, the defrosting stop condition may include whether or not the surface temperature of the evaporator coincides with the predetermined defrost stop temperature and whether the defrost stopping frequency is less than a predetermined reference frequency. Depending on the embodiment, the defrost stop condition may include at least one of the above two conditions.

As described above, when the defrosting means 304 is driven continuously in accordance with the defrosting operation time or the defrost termination temperature set in advance, the defrosting means 304 is continuously driven to cause unnecessary power consumption have. Therefore, in the present invention, when the defrost stop temperature is set and the surface temperature of the evaporator reaches the defrost stop temperature, the driving of the defrosting means 304 is temporarily stopped even if the defrosting operation time or the defrost end temperature is not reached. Even if the driving of the defrosting means 304 is temporarily stopped in this way, the defrosting can be continuously performed due to the residual heat of the defrosting means 304.

Since the temporary stop of the defrosting means 304 must be performed before the defrost termination temperature is reached, the defrost stop temperature is preferably set to be lower than the defrost termination temperature.

On the other hand, when the defrosting means 304 is restarted to be driven again after the defrosting means 304 is temporarily stopped, a certain amount of power is consumed to raise the temperature of the defrosting means 304. Therefore, in the present invention, the number of times of stopping the defrosting means 304 is limited to a predetermined number, that is, less than the reference number. Accordingly, it is possible to prevent the defrosting means 304 from being stopped too frequently.

In the present invention, the maximum number of times the defrosting means 304 is stopped, that is, the reference number of times, can be experimentally determined in consideration of the power consumption amount of the defrosting means 304. In one embodiment of the present invention, the reference number is preferably set to 5 or less. In particular, in order to prevent the defrosting means 304 from being stopped too often, the reference number is preferably set to 3 or less.

For example, if the defrost stop temperature is set to 0 deg. C and the reference frequency is set to two times, the controller 302 determines that the surface temperature of the evaporator measured by the defrost temperature sensor 308 is 0 deg. C And the defrosting operation is stopped only when the defrosting stop count is less than two (408). The fact that the reference number is set to two means that the defrosting means 304 can be stopped only when there is a history in which the defrosting means 304 has never been stopped or stopped once. In other words, when the reference number of times is set to two, the stopping of the defrosting means 304 will be performed only once at most.

Also, in the present invention, the defrost stop temperature can be set in consideration of the melting point of the property. For example, it is preferable that the defrost stop temperature is set to a temperature between 0 deg. C, which is the melting point of the casting, and the defrost termination temperature. The fact that the surface temperature of the evaporator has reached 0 ° C means that the properties near the evaporator have already started to melt. Further, even if the defrosting means 304 is stopped, it means that the surface temperature of the evaporator is kept at the defrost stop temperature, for example, 0 DEG C or more due to the residual heat of the defrosting means 304. [

In step 408, the control unit 302 may stop the defrosting means 304 for a predetermined defrost stopping time (e.g., 3 minutes). The defrosting stop time may vary depending on the embodiment and may be defined as the time at which the temperature of the defrosting means 304 is maintained above a certain temperature by stopping the defrosting means 304. [

If the defrost stop condition is not satisfied in step 406 or the defrost stop time elapses in step 408, the control unit 302 drives the defrosting unit 304 again to start defrosting operation (402).

If the defrost termination condition is satisfied in step 404, the control unit 302 terminates the defrosting operation by stopping the defrosting unit 304 (step 410).

On the other hand, as described above, when the defrosting operation time or the defrost termination temperature is reached and the defrosting operation is terminated (410), it may happen that the property is not sufficiently removed. For example, if the refrigerator is used in an area with higher humidity than other areas due to its local characteristics, a large amount of wind may be generated on the evaporator surface or around the evaporator. If a normal defrosting operation is performed in such a situation, the defrosting operation may not be sufficiently removed even if the defrosting operation is terminated.

In order to solve this problem, the present invention further checks whether the surface temperature of the evaporator is lower than the defrost stop temperature after the defrost operation is finished (410) as shown in FIG. 4 (412). If the surface temperature of the evaporator is lower than the defrost stop temperature even after the defrosting operation is completed in accordance with the predetermined defrost termination condition, it is possible that the defrosting is not sufficiently performed. In this case, the control unit 302 drives the defrosting means 304 again to resume defrosting operation (414).

When the defrosting operation is resumed (414), the control unit 302 can perform the defrosting operation by driving the defrosting means 304 during a predetermined defrosting operation resuming time. The defrosting operation resuming time is longer than the defrosting operation time previously performed in steps 402 to 410 since a considerable amount of defrosting has been eliminated through the defrosting operation performed in steps 402 to 410. [ Can be set short.

In another embodiment of the present invention, when the defrost operation is resumed (414), the controller 302 may perform the defrost operation until the surface temperature of the evaporator reaches a preset defrost termination temperature. The defrost termination temperature at the time of restarting the defrost operation 414 is referred to in the steps 402 to 410 since the defrost operation performed through the steps 402 to 410 has been canceled The defrost termination temperature may be set to be lower than the defrost termination temperature.

In another embodiment of the present invention, when the defrosting operation is resumed, the control unit 302 may perform the above-described steps 402 to 410 again.

If it is determined in step 412 that the surface temperature of the evaporator is equal to or higher than the defrost stop temperature, the controller 302 terminates the defrost operation without driving the defrosting unit 304 (410).

5 is a timing chart showing a defrosting operation time according to the defrosting operation control according to the embodiment of the present invention.

In Fig. 5, T1 denotes a predetermined defrost operation time. In the present invention, the controller 302 performs the defrosting operation in accordance with a predetermined defrosting operation time T1. If the predetermined defrost stopping condition is satisfied in the defrosting operation time T1, the controller 302 stops the defrosting operation by the predetermined defrost stopping time T2. When the defrost stop time T2 elapses, the control unit 302 starts defrosting operation again. As a result, according to this operation, the defrosting means 304 is driven by the time D1 and the time D2. During the time T2, the defrosting means 304 is not driven and the defrosting by the residual heat of the defrosting means 304 .

As described above, in the present invention, the controller 302 further determines whether the surface temperature of the evaporator is less than the defrost stop temperature after the defrost operation time T1 has elapsed. If the surface temperature of the evaporator is less than the defrost stop temperature after the defrost operation time T1 has elapsed, the controller 302 drives the defrosting means 304 again to perform additional defrosting for the time D3. At this time, the time D3 is preferably set shorter than the defrosting operation time T1.

According to the present invention, there is an advantage that power consumption due to unnecessary driving of the defrosting means can be reduced by temporarily stopping the defrosting operation according to a specific condition at the time of defrosting operation of the refrigerator.

According to the present invention, defrosting operation is performed again when defrosting operation is not sufficiently removed due to defrosting operation according to a predetermined defrosting operation time or defrost termination temperature, thereby improving the defrosting efficiency and the cooling efficiency of the refrigerator.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, But the present invention is not limited thereto.

Claims (14)

Starting defrosting operation;
Determining whether a predetermined defrost termination condition is satisfied;
Determining whether a predetermined defrost stop condition is satisfied if the defrost end condition is not satisfied;
Stopping the defrosting operation for a predetermined defrost stop time if the defrost stop condition is satisfied; And
And terminating the defrosting operation if the defrost termination condition is satisfied
Control method of defrosting operation of refrigerator.
The method according to claim 1,
Wherein the step of determining whether the defrost termination condition is satisfied
Determining whether a predetermined defrost operation time has elapsed or not
Control method of defrosting operation of refrigerator.
The method according to claim 1,
Wherein the step of determining whether the defrost termination condition is satisfied
Determining whether the surface temperature of the evaporator coincides with a predetermined defrost termination temperature
Control method of defrosting operation of refrigerator.
The method according to claim 1,
Wherein the step of determining whether the defrost stop condition is satisfied
Whether or not the surface temperature of the evaporator coincides with a predetermined defrost stop temperature and whether the defrost stop count is less than a preset reference number
Control method of defrosting operation of refrigerator.
5. The method of claim 4,
The reference number is set to 3 or less
Control method of defrosting operation of refrigerator.
5. The method of claim 4,
The defrosting stop temperature is set to be lower than the defrost termination temperature
Control method of defrosting operation of refrigerator.
The method according to claim 1,
Comparing the surface temperature of the evaporator with the defrost stop temperature after the defrost termination condition is satisfied and the defrost operation terminated; And
And restarting the defrosting operation when the surface temperature is lower than the defrost stop temperature
Control method of defrosting operation of refrigerator.
Storage space;
An evaporator disposed on one side of the storage space for absorbing heat of a fluid present in a peripheral space to cool the fluid;
Defrosting means disposed on one side of the evaporator and generating heat in order to remove gasses formed around the evaporator;
And a controller for driving the defroster means to perform a defrosting operation in accordance with a preset condition,
The control unit
Wherein the control means determines whether or not a predetermined defrost termination condition is satisfied after the defrosting operation by the defrosting means is satisfied and judges whether a predetermined defrost stop condition is satisfied when the defrost termination condition is not satisfied, The defrosting operation is stopped for a predetermined defrosting stop time, and the defrosting operation is terminated when the defrost termination condition is satisfied
Refrigerator.
9. The method of claim 8,
The control unit
It is determined whether or not the defrost operation time set in advance as the defrost termination condition has elapsed
Refrigerator.
9. The method of claim 8,
The control unit
It is determined whether or not the surface temperature of the evaporator coincides with the predetermined defrost termination temperature as the defrost termination condition
Refrigerator.
9. The method of claim 8,
The control unit
It is determined whether or not the surface temperature of the evaporator coincides with the predetermined defrost stop temperature as the defrost stopping condition and whether the defrost stopping frequency is less than a preset reference frequency
Refrigerator.
12. The method of claim 11,
The reference number is set to 3 or less
Refrigerator.
12. The method of claim 11,
The defrosting stop temperature is set to be lower than the defrost termination temperature
Refrigerator.
9. The method of claim 8,
The control unit
The defrosting control unit compares the surface temperature of the evaporator with the defrosting stop temperature after the defrost termination condition is satisfied and the defrosting operation is resumed when the surface temperature is lower than the defrost stop temperature
Refrigerator.

Images