KR100210086B1 - Defrost operating change device and method of airconditioner - Google Patents

Abstract

The present invention relates to a defrosting operation variable apparatus and method of an air conditioner, the defrosting operation temperature variable control unit, defrosting operation time variable control unit and defrosting in the defrosting operation control means by the expert at the time of shipment or installation of the air conditioner When the operation pattern variable adjusting unit is adjusted, the defrosting operation of the air conditioner is performed according to the respective set values that are normally adjusted by the control signal of the controller during the defrosting operation of the air conditioner. The defrosting operation condition of the air conditioner can be appropriately changed according to the capacity, power condition and surrounding conditions such as the area where the air conditioner is installed, so that the defrosting operation of the air conditioner according to the surrounding conditions can be optimally performed. .

Description

Defrosting operation variable device and method of air conditioner

The present invention relates to a defrosting operation of an air conditioner generated in accordance with a heating operation, and more particularly, to a defrosting operation variable apparatus and a method of an air conditioner capable of varying a start temperature and a running time of a defrosting operation.

In general, a conventional air conditioner includes a plurality of suction holes 4 fastened to the front lower side of an indoor unit main body (hereinafter, abbreviated as a main body) to suck indoor air, as shown in FIGS. 1 and 2. A suction member 6 formed therein, and a filter member 8 installed inside the suction grill member 6 to filter foreign substances in the indoor air sucked through the suction hole 4 of the suction grill member 6. And an indoor heat exchanger (37) installed inside the filter member (8) to exchange heat from the indoor air filtered by the filter member (8) with cold or warm air, and installed above the main body (2). Discharge means 10 for discharging the air heat-exchanged by the gas 37 and air installed in the upper side of the indoor heat exchanger 37 to discharge heat exchanged through the indoor heat exchanger 37 to the discharge means 10 side. It is installed outside the blower fan 12 and the blower fan 12 and blows toward the discharge means 10 side. The duct member 14 for guiding the flow of air is provided on the front portion of the main body 2, the operation mode of the air conditioner (automatic, cooling, dehumidification, blowing, heating, etc.) and the start and stop of operation, And it is composed of an operation unit 16 for adjusting the air volume and the wind direction of the air discharged through the discharge means (10).

On the other hand, the discharge means 10 is a plurality of left and right wind direction control means (10A) for guiding the cold or warm air heat-exchanged by the indoor heat exchanger 37 to the left and right wind direction controlled discharge, left and right wind direction control means (10A) It is fastened orthogonal to the () is composed of a plurality of vertical wind direction control means 108 for guiding the cold air or hot air is discharged up and down.

On the other hand, the air conditioner is a cooling air conditioner for cooling the hot air indoors to supply cold air to the room, and a heat pump equipped with such a cooling function as well as a heating function for warming the indoor cold air to supply warm air to the room ( Heat pump type air conditioner can be classified, and recently there is an air conditioner having a clean function to clean the contaminated indoor air.

Among the various air conditioners as described above, the cooling operation and the heating operation of the heat pump type air conditioner will be described with reference to FIG. 3.

First, in the cooling operation of the heat pump type air conditioner, as shown by the solid line (→) of FIG. 3, the refrigerant gas compressed by the compressor 30 in the gas state of high temperature and high pressure is controlled by the four-way valve 40. Accordingly, when the outdoor heat exchanger 31 is introduced into the outdoor heat exchanger 31, the outdoor heat exchanger 31 is cooled and condensed in the outdoor heat exchanger 31 to exchange heat with the outdoor air blown by the driving of the outdoor fan 50.

In addition, the refrigerant liquefied through the outdoor heat exchanger (31) flows into the expansion valve (35) through the one-way valve (33), and the high pressure refrigerant liquid introduced is low pressure by the adiabatic expansion effect through the expansion valve (35). Is converted into a refrigerant liquid and flows into the indoor heat exchanger (37).

Then, the refrigerant liquid introduced into the indoor heat exchanger (37) is evaporated through the indoor heat exchanger (37), and is heat-exchanged with the indoor air blown by the driving of the indoor fan (60) to be converted into refrigerant gas. As the heat of the indoor air is deprived of heat by the latent heat of evaporation of the refrigerant in the indoor heat exchanger 37, the cooled indoor air (cold air) is discharged to the room through the air discharging means 10 of the air conditioner. Cooling operation is performed.

On the other hand, the refrigerant gas converted through the indoor heat exchanger 37 is introduced into the compressor (3) again to form a refrigeration cycle that is repeatedly circulated to continue the cooling operation of the air conditioner.

Next, in the heating operation of the heat pump type air conditioner, as shown by the dotted line (-) in FIG. 3, the refrigerant gas compressed by the compressor 30 in the gas state of high temperature and high pressure is the four-way valve 40. When introduced into the indoor heat exchanger 37 under the control of the heat exchanger, the indoor heat exchanger 37 is cooled and condensed and heat exchanged with the indoor air blown by the driving of the indoor fan 60. At this time, the cold indoor air is heated by the latent heat of condensation of the refrigerant in the indoor heat exchanger 37, and the warm indoor air (hot air) is discharged to the room through the discharge means 10 of the air conditioner, thereby heating the air conditioner. This is done.

The refrigerant heat exchanged through the indoor heat exchanger (37) is decompressed into the refrigerant liquid of low pressure through the expansion valve (35) and the expansion valve for heating (39) and flows into the outdoor heat exchanger (31).

Then, while the refrigerant liquid introduced into the outdoor heat exchanger 31 is evaporated, it is heat-exchanged with the outdoor air blown by the drive of the outdoor fan 50 is converted into a refrigerant gas.

On the other hand, the refrigerant gas converted through the outdoor heat exchanger 31 is introduced into the compressor 30 again to form a refrigeration cycle that is repeatedly circulated, the heating operation of the air conditioner is continuously performed.

On the other hand, when the heating operation of the air conditioner as described above is performed for a predetermined time, the air blown by the driving of the outdoor fan 50 is discharged to the outside when the heat exchanged in the outdoor heat exchanger 31 is cooled The frost is formed on the surface of the outdoor heat exchanger 31 by the cold air, and the longer the frost is formed, the thicker the ice grows, causing the outdoor unit to freeze, and the evaporation temperature and pressure are lowered due to the freezing of the outdoor unit. In other words, problems such as increased power consumption and poor air-conditioning ability occur.

Therefore, it is necessary to perform a defrosting operation to remove frost formed on the surface of the outdoor heat exchanger 31 of the air conditioner as described above.

On the other hand, Figure 4 is a view showing a control device for controlling the defrosting operation of a conventional typical heat pump type air conditioner, the indoor heat exchanger temperature sensor 410, control unit 420, compressor drive unit 430, four-way valve The control unit 440, the outdoor fan driving unit 450 and the indoor fan driving unit 460.

First, the indoor heat exchanger temperature sensor 410 senses the temperature of the indoor heat exchanger 37 in the indoor unit of the air conditioner and provides a corresponding temperature detection signal to the controller 420, and the controller 420 exchanges the indoor heat. Determination of normal operation and defrost operation of the air conditioner based on the amount of temperature change of the indoor heat exchanger 37 detected by the temperature sensor 410 for each operation for normal operation of the air conditioner or defrost operation of the air conditioner Generate a control signal.

Here, in order to detect the start temperature of the defrosting operation, it is preferable to sense the temperature of the outdoor heat exchanger 31, but by mounting a temperature sensor on a predetermined portion of the indoor heat exchanger 37, the outdoor heat exchanger 31 is mounted. By indirectly detecting the temperature of the refrigerant flowing into the indoor heat exchanger 37, the start temperature of the defrosting operation may be sensed.

The compressor driver 430 drives the compressor based on the drive control signal from the controller 420, and the four-way valve controller 440 controls the four-way valve 40 by the control signal from the controller 420. The refrigerant from the compressor 30 is selectively provided to the outdoor heat exchanger 31 or the indoor heat exchanger 37.

In addition, the outdoor fan driver 450 drives the outdoor fan 50 by the drive control signal from the controller 420, and the indoor fan driver 460 uses the indoor fan (the fan by the drive control signal from the controller 420). 60).

Hereinafter, an operation process of the defrosting operation control apparatus of the air conditioner configured as described above will be described.

First, the compressor 30, the four-way valve 40, the indoor heat exchanger 37, the expansion valve 35, as shown by the dotted line (-) in FIG. 3 at the time of heating operation of the heat pump type air conditioner. And a refrigeration cycle in the order of the heating expansion valve 39 and the outdoor heat exchanger 31, wherein hot air (hot air) heat exchanged through the indoor heat exchanger 37 is discharged to the room through the discharge means 10. The heating operation of the air conditioner is performed.

At this time, the controller 420 determines whether the air conditioner is normally operated (heating operation) or defrosting operation based on the temperature change amount of the indoor heat exchanger 37 detected by the indoor heat exchanger temperature sensor 410.

Therefore, when the temperature change amount of the indoor heat exchanger 37 detected by the indoor heat exchanger temperature sensor 410 is not a defrost condition, the air conditioner is continuously operated by each control signal for normal operation from the controller 420. When the heating operation is performed and the temperature change amount of the indoor heat exchanger 37 detected by the indoor heat exchanger temperature sensor 410 is a defrost condition, the control unit 420 generates each control signal for the defrosting operation.

That is, the controller 420 generates a control signal for temporarily stopping driving of the compressor 30 and a control signal for stopping driving of the outdoor fan 50 and the indoor fan 60.

Accordingly, the drive of the compressor 30 is temporarily stopped by the drive stop signal of the compressor driver 430 based on the drive stop control signal from the controller 420, and the outdoor fan based on the drive stop control signal from the controller 420. The driving of the outdoor fan 50 and the indoor fan 60 is stopped by the driving stop signal of the driving unit 450 and the indoor fan driving unit 460.

Then, the compressor 30 is driven again by the drive signal of the compressor drive unit 430 based on the drive control signal from the control unit 420, and the four-way valve control unit based on the refrigerant switching control signal from the control unit 420 ( The high temperature and high pressure refrigerant from the compressor 30 is transferred to the outdoor heat exchanger 31, the one-way valve 33, the expansion valve 35, and the indoor heat exchanger 37 by the four-way valve 40 by the switching control signal of 440. By forming the refrigeration cycle of the order), frost formed on the outdoor heat exchanger 31 is removed by the latent heat of condensation of the refrigerant through the outdoor heat exchanger 31.

On the other hand, when the defrosting operation time of the predetermined time set in the internal timer is completed, the controller 420 generates each control signal for normal operation.

That is, the controller 420 generates a control signal for temporarily stopping driving of the compressor 30 and a control signal for driving the outdoor fan 50 and the indoor fan 60.

Accordingly, the drive of the compressor 30 is temporarily stopped by the drive stop signal of the compressor driver 430 based on the drive stop control signal from the controller 420, and the outdoor fan driver based on the drive control signal from the controller 420. The outdoor fan 50 and the indoor fan 60 are driven by the driving signals of the 450 and the indoor fan driver 460.

Then, the compressor 30 is driven again by the drive signal of the compressor drive unit 430 based on the drive control signal from the control unit 420, and the four-way valve control unit based on the refrigerant switching control signal from the control unit 420 ( The high temperature and high pressure refrigerant from the compressor 30 is transferred to the indoor heat exchanger 37, the expansion valve 35, the heating expansion valve 39, and the outdoor heat exchanger through the four-way valve 40 by the switching control signal of the 440. 31) By forming the refrigeration cycle in sequence, the heating operation of the air conditioner is performed again.

However, as described above, the defrosting operation of the air conditioner according to the prior art, the air according to the predetermined defrosting operation condition by the temperature change amount of the indoor heat exchanger 37 detected through the indoor heat exchanger temperature sensor 410. Since the defrosting operation of the air conditioner is fixed to one specification, there is a problem in that the defrosting operation of the air conditioner is not appropriately changed depending on the capacity of the air conditioner, the power supply condition, and the surrounding conditions such as the area in which the air conditioner is installed. .

Accordingly, the present invention has been made in view of the problems of the prior art as described above, and by varying the defrosting operation conditions of the air conditioner according to the ambient conditions in which the air conditioner is installed, the defrosting operation of the air conditioner is optimally controlled. To provide a defrosting operation variable apparatus and method of an air conditioner.

The defrosting operation variable apparatus of the air conditioner according to the present invention to achieve the above object, in the defrosting apparatus of the air conditioner for removing the frost formed on the outdoor heat exchanger, by detecting the temperature change of the outdoor heat exchanger, Defrost operation adjusting means for setting an initial value for varying the defrosting operation condition of the air conditioner, and compare the temperature of the sensed outdoor heat exchanger and the defrosting operation starting temperature set by the defrosting operation adjusting means and accordingly the air Control means for generating each control signal for the normal operation or defrost operation of the conditioner, and drive means for selectively performing the normal operation or defrost operation of the air conditioner by the control signal from the control means It is done.

In order to achieve the above object, the defrosting operation method of the air conditioner according to the present invention, in the defrosting operation method of the air conditioner for removing frost formed on the outdoor heat exchanger, the initial stage for the defrosting operation of the air conditioner A step of setting a value, a step of setting a new defrosting operation condition of the air conditioner by checking a defrosting operation initial value of the air conditioner set in the setting step step by step, and a defrosting operation of the air conditioner And defrosting the air conditioner according to the defrosting operation condition of the air conditioner set in the setting step.

1 is a schematic perspective view showing a general air conditioner.

Figure 2 is a longitudinal sectional view schematically showing the internal configuration of a general air conditioner.

3 is a refrigeration cycle for explaining the heating and cooling operation of a conventional conventional air conditioner.

Figure 4 shows a control device for controlling the defrosting operation of a conventional heat pump type air conditioner in the related art.

5 is a schematic block diagram of a defrosting operation variable apparatus of an air conditioner according to a preferred embodiment of the present invention.

Figure 6 is a flow chart for explaining the operation of varying the defrost operation of the air conditioner according to a preferred embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

2: room main body 4: suction hole

6: suction grill member 8: filter member

10: discharge means 12: blowing fan

14 duct member 16 operation unit

30: compressor 31: outdoor heat exchanger

33: one-way valve 35: expansion valve

37: indoor heat exchanger 39: expansion valve for heating

40: four-way valve 50: outdoor fan

60: indoor fan 410: indoor heat exchanger temperature sensor

420,520 control unit 430 compressor driving unit

440: four-way valve control unit 450: outdoor fan drive unit

460: indoor fan drive unit

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

5 is a schematic block diagram of a variable operation of a defrosting operation of an air conditioner according to a preferred embodiment of the present invention, the indoor heat exchanger temperature sensor 410, the defrosting operation control means 510, the control unit 520, the compressor The driving unit 430, the four-way valve control unit 440, the outdoor fan driving unit 450, and the indoor fan driving unit 460 are configured.

On the other hand, the indoor heat exchanger temperature sensor 410, the compressor driving unit 430, the four-way valve control unit 440, the outdoor fan driving unit 450 and the indoor fan driving unit among the components of the defrosting operation variable device of the air conditioner according to the present invention 460 is a constituent member of the control device for performing the defrosting operation of the conventional typical air conditioner as described above, that is, the indoor heat exchanger temperature sensor 410, compressor drive unit 430, four-way valve control unit 440, Since the outdoor fan driver 450 and the indoor fan driver 460 perform substantially the same functions, the description thereof will be omitted in order to avoid overlapping substrates.

Therefore, the most characteristic means of the present invention is the adjustment from the defrosting operation adjusting means 510 and the defrosting operation adjusting means 510 for varying the defrosting operating conditions of the air conditioner at the time of shipment or installation of the air conditioner. As the control unit 520 for generating each control signal for performing the defrosting operation in accordance with the signal, as can be seen with reference to Figure 5, the defrosting operation control means 510 is a variable defrosting operation temperature control unit 512, The defrosting operation time variable adjusting unit 514 and the defrosting operation pattern variable adjusting unit 516.

In FIG. 5, the defrosting operation temperature variable adjusting unit 512 varies the defrost start temperature of the air conditioner by increasing or decreasing the temperature change amount of the indoor heat exchanger 37 detected through the indoor heat exchanger 37, The defrosting operation time variable adjusting unit 514 varies the defrosting operation time for performing the defrosting operation, and the defrosting operation pattern variable adjusting unit 516 is for varying the defrosting operation pattern during the defrosting operation of the air conditioner.

The control unit 520 generates control signals for defrosting the air conditioner according to the values adjusted through the control units 512, 514, and 516 in the defrosting operation control unit 510. do.

Hereinafter, the operation process of the defrosting operation variable apparatus and method of the air conditioner according to the present invention configured as described above will be described.

First, when commercial power is applied to the air conditioner, the control unit 520 initializes the air conditioner (step 610), and at the time of shipment or installation of the air conditioner, the capacity of the air conditioner, the state of power supply, and the area in which it is installed. The defrosting operation control means 510 is adjusted by the expert in accordance with the ambient conditions.

Then, the control unit 520 checks the variable defrosting operation temperature control unit 512 (step 612), and sets the defrosting start temperature of the air conditioner step by step according to the adjusted defrosting operation temperature.

Preferably, the control unit 520 sets the first predetermined value of the defrost start temperature of the air conditioner when the voltage value adjusted by the defrosting operation temperature variable adjusting unit 512 exceeds the set first predetermined value (a). That is, if it is set to a (steps 614 and 616) and the voltage value adjusted through the defrosting operation temperature variable control unit 512 is equal to or greater than the set second predetermined value b and less than the first predetermined value a, The defrost start temperature of the conditioner is set to the set second predetermined value, that is, b (steps 618 and 620).

On the other hand, the controller 520 continuously checks the steps as described above, and finally, the voltage value adjusted by the defrosting operation temperature variable control unit 512 is equal to or greater than the set n-th predetermined value z and n- If it is less than 1 predetermined value y, the defrost start temperature of an air conditioner is set to nth predetermined value, ie, z (step 622, 624).

Next, the control unit 520 checks the defrosting operation time variable adjusting unit 514 (step 630), and sets the defrosting operation time of the air conditioner step by step according to the adjusted defrosting operation time.

In detail, the controller 520 sets the defrosting operation time of the air conditioner when the voltage value adjusted by the defrosting operation time variable adjusting unit 514 exceeds the set first predetermined value (a). The predetermined value, i.e., (a) is set (steps 632 and 634), and the voltage value adjusted by the defrosting operation time variable adjusting unit 514 is equal to or greater than the set second predetermined value (b) and the first predetermined value (( If less than a)), the defrosting operation time of the air conditioner is set to the set second predetermined value, that is, (b) (steps 636 and 638).

On the other hand, the controller 520 continuously checks the steps as described above, and finally, the voltage value adjusted through the variable defrosting operation time adjusting unit 514 is equal to or greater than the nth predetermined value (z). If it is less than n-1 predetermined value (y), the defrosting operation time of an air conditioner is set to nth predetermined value, ie, (z) (step 640, 642).

Next, the control unit 520 checks the defrosting operation pattern variable adjusting unit 516 (step 650), and sets the defrosting operation pattern of the air conditioner step by step according to the adjusted defrosting operation pattern.

In detail, the controller 520 sets the first predetermined value of the defrosting operation pattern of the air conditioner when the voltage value adjusted by the defrosting operation pattern variable adjusting unit 516 exceeds the set first predetermined value ⓐ. In other words, if it is set to ⓐ (steps 652 and 654) and the voltage value adjusted through the defrosting operation pattern variable adjusting unit 516 is greater than or equal to the set second predetermined value (ⓑ) and less than the first predetermined value (ⓐ), The defrosting operation pattern of the machine is set to the set second predetermined value, that is, ⓑ (steps 656 and 658).

On the other hand, the control unit 520 continuously checks the steps as described above, and finally, the voltage value adjusted through the defrosting operation pattern variable adjusting unit 516 is equal to or greater than the n-th predetermined value (ⓩ) and n- If the value is less than one predetermined value, the defrosting operation pattern of the air conditioner is set to the nth predetermined value, that is, ⓩ (steps 660 and 662).

Then, the control unit 520 stores each defrosting operation condition (defrosting operation temperature, defrosting operation time, defrosting operation pattern) set through the steps 410 to 662 as described above, and then stores the air conditioner. The defrosting operation is performed according to the defrosting operation condition set at the defrosting operation (step 670).

More specifically, during the heating operation of the air conditioner, by comparing the temperature change amount of the indoor heat exchanger 37 detected by the indoor heat exchanger temperature sensor 410 and the defrost start temperature set through the steps (414 to 424) The controller 520 determines whether the air conditioner is in normal operation (heating operation) or defrost operation.

Therefore, when the result of comparing the temperature change amount of the indoor heat exchanger 37 sensed by the indoor heat exchanger temperature sensor 410 with the defrost start temperature set through the steps 414 to 424, the controller 520 is not a defrost condition. The air conditioner continuously performs heating operation by each control signal for normal operation.

On the other hand, when the result of the comparison between the temperature change amount of the indoor heat exchanger 37 sensed by the indoor heat exchanger temperature sensor 410 and the defrost start temperature set through the steps 414 to 424, if the defrost condition, the controller 520 Generates each control signal for the defrosting operation.

That is, the driving of the compressor 30 is temporarily stopped by the driving stop signal of the compressor driver 430 based on the control signal for stopping the drive from the controller 520, and the outdoor fan driver 450 and the indoor fan driver 460 are stopped. Drive of the outdoor fan 50 and the indoor fan 60 is stopped.

Then, the compressor 30 is driven again by the drive signal of the compressor drive unit 430 based on the drive control signal from the control unit 520, and the four-way valve control unit based on the refrigerant switching control signal from the control unit 520 The high temperature and high pressure refrigerant from the compressor 30 is transferred to the outdoor heat exchanger 31, the one-way valve 33, the expansion valve 35, and the indoor heat exchanger 37 by the four-way valve 40 by the switching control signal of 440. By forming the refrigeration cycle of the order), frost formed on the outdoor heat exchanger 31 by the latent heat of condensation of the refrigerant through the outdoor heat exchanger 31 is removed.

Meanwhile, when the time counted by the internal timer reaches the defrosting operation time set through the steps 430 to 442, the controller 520 generates each control signal for the normal operation.

That is, the drive of the compressor 30 is temporarily stopped by the drive stop signal of the compressor driver 530 based on the drive stop control signal from the controller 520, and the outdoor fan driver based on the drive control signal from the controller 520. The outdoor fan 50 and the indoor fan 60 are driven by the driving signals of the 450 and the indoor fan driver 460.

Then, the compressor 30 is driven again by the drive signal of the compressor drive unit 430 based on the drive control signal from the control unit 520, and the four-way valve control unit based on the refrigerant switching control signal from the control unit 520 The high temperature and high pressure refrigerant from the compressor 30 is transferred to the indoor heat exchanger 37, the expansion valve 35, the heating expansion valve 39, and the outdoor heat exchanger through the four-way valve 40 by the switching control signal of the 440. 31) By forming the refrigeration cycle in sequence, the heating operation of the air conditioner is performed again.

On the other hand, when each set value adjusted through the defrosting operation control means 510 is not suitable in the current state of the air conditioner, by adjusting the time constant values of the defrosting operation control means 510, it is suitable for the current state of the air conditioner You can simply change it.

As described above, the defrosting operation temperature control unit 512, the defrosting operation time variable control unit 514 and the defrosting operation pattern variable in the defrosting operation adjusting means 510 by experts at the time of shipment or installation of the air conditioner. When the adjusting unit 516 is adjusted, the defrosting operation of the air conditioner is performed according to each set value adjusted through the defrosting operation adjusting unit 510 by the control signal of the controller 520 during the defrosting operation of the air conditioner. Is performed.

Therefore, by using the present invention, the defrosting operation conditions of the air conditioner can be appropriately changed depending on the capacity of the air conditioner, the power supply condition, and the surrounding conditions such as the area in which the air conditioner is installed. There is an effect that can perform the defrosting operation optimally.

Claims (4)

A defrosting apparatus of an air conditioner for performing a defrosting operation when a defrosting operation condition according to a defrosting operation temperature selected by a user is satisfied, the defrosting operation time variable adjusting unit for varying the defrosting operation time of the air conditioner, and the user A control means for outputting a control signal for performing a defrosting operation during the variable defrosting operation time by comparing the defrosting operation temperature selected by the controller with a temperature of the outdoor heat exchanger, when the defrosting operation condition is satisfied; And drive means for performing defrosting operation of the air conditioner according to the control signal from the control means. The method of claim 1, wherein the defrosting operation control means further comprises a defrosting operation pattern variable adjusting unit for varying the defrosting operation pattern of the air conditioner, the control means is variable through the defrosting operation pattern variable adjusting unit Defrosting operation variable device of the air conditioner, characterized in that for outputting a control signal for performing the defrosting operation in the defrosting operation pattern corresponding to the defrosting operation pattern. In the defrosting operation method of an air conditioner for performing a defrosting operation when the defrosting operation condition according to the defrosting operation temperature selected by the user is satisfied, a defrosting operation time selection step in which the user variably selects a defrosting operation time, and the defrosting operation selected by the user. When the defrosting operation condition is satisfied by comparing the operation temperature with the temperature of the outdoor heat exchanger, the defrosting operation performing step of performing defrosting operation and the defrosting operation time counted by counting the defrosting operation time are used in the defrosting operation time selection step. And a defrosting operation termination step of terminating the defrosting operation when the defrosting operation time selected by the variable elapses. 4. The method of claim 3, further comprising a defrosting operation pattern selection step of variably selecting the defrosting operation pattern by the user, and performing defrosting operation corresponding to the defrosting operation pattern variably selected by the user in the defrosting operation pattern selection step. Defrosting operation variable method of the air conditioner, characterized in that.