KR101211007B1 - Air conditioning of Thermo defrost the operation method - Google Patents

Abstract

The present invention relates to a defrosting operation method of an air conditioner. The present invention selectively switches the circulation direction of the refrigerant between the indoor unit and the indoor unit having an indoor heat exchanger, an indoor fan having an indoor fan and an auxiliary heater, an outdoor unit having an outdoor heat exchanger, a compressor, an expansion device, and an outdoor fan. In the defrosting operation method of the air conditioner including a four-way valve to operate as a heating cycle when the off (off) and the cooling cycle when on (on), selectively depending on the number of times of the heating operation cycle of the air conditioner Provided is a defrosting operation method of an air conditioner in which a defrosting operation method is determined.

Defrosting method, air conditioner

Description

Air conditioning of Thermo defrost the operation method

1 is a schematic view showing the configuration of an air conditioner according to the present invention;

2 is a block diagram showing the configuration of an air conditioner according to the present invention;

3 (a) to 3 (b) is a flow chart showing a defrosting operation method of the air conditioner according to the present invention,

4 is a graph of the outdoor pipe temperature and the defrosting operation start section and end section of the air conditioner according to the present invention;

5 is a flowchart illustrating a defrosting operation method of an air conditioner according to the related art.

DESCRIPTION OF THE REFERENCE NUMERALS

200: indoor unit 201: power unit

202: room temperature detection unit 203: room piping temperature detection unit

204: outdoor temperature sensor 205: outdoor pipe temperature sensor

206: outdoor humidity detection unit 210: indoor suction

211: indoor fan drive unit 212: auxiliary heater drive unit

213: compressor drive unit 214: outdoor fan drive unit

215: four-side drive unit 220: auxiliary heater

230: indoor heat exchanger 240: indoor fan

250: conduit 300: control unit

310: storage 320: timer

400: outdoor unit 410: four sides

420: compressor 430: outdoor heat exchanger

440: outdoor fan 450: expansion device

The present invention relates to a defrosting operation method of an air conditioner, and more particularly, to a defrosting operation method of an air conditioner that is effectively and simply defrosted by changing the defrosting operation method based on the number of heating operations.

In general, an air conditioner has a cycle in which refrigerant circulating inside circulates in order of compression, condensation, expansion, and evaporation to transfer heat. By this cycle, the air conditioner operates as a cooling cycle for discharging the heat of the room to the outside during the summer, and operates as a heating cycle of the heat pump for supplying heat to the room by circulating opposite to the cooling cycle in the winter.

3 is a flowchart illustrating a defrosting operation method of an air conditioner according to the related art.

As shown in FIG. 3, the air conditioner according to the related art has a predetermined time elapsed after the air conditioner starts heating operation (step S1) (step S2), and the controller measures an outdoor heat exchanger temperature. At this time, if the measured temperature of the outdoor heat exchanger is less than the set temperature (step S3), the controller determines that frost is formed by the surface freezing of the outdoor heat exchanger, and controls the upper valve to operate the cooling cycle in the heating cycle. To perform defrosting operation by switching (S4 step). When the defrosting operation is performed, the outdoor heat exchanger, which acted as an evaporator, begins to release heat while acting as a condenser, and the frost that has been covered on the surface of the outdoor heat exchanger begins to thaw by the heat.

On the other hand, the controller checks the defrosting operation completion condition, such as whether the defrosting operation time reaches the set time or the temperature of the outdoor pipe reaches the set temperature from the time when the defrosting operation is performed (step S5). In addition, when it is determined that the defrosting operation completion condition is satisfied, the controller switches the operation of the air conditioner from the cooling cycle to the heating cycle of the four-way valve to complete the defrosting operation (step S6).

However, the conventional air conditioner as described above may cause deterioration in heating efficiency due to frequent defrosting operation by performing the defrosting operation condition when the temperature is lower than the set outdoor heat exchanger temperature. Therefore, when the temperature of the heat exchanger is less than or equal to the preset temperature, the defrosting operation is frequently performed regardless of the number of times driven by the heating cycle.

The present invention has been made to solve the above problems of the prior art, and an object of the present invention is to provide a defrosting operation method of an air conditioner which is effectively and simply defrosted by changing the defrosting operation method based on the number of heating operations. .

An air conditioner according to the present invention for solving the above problems, an indoor unit including an indoor heat exchanger, an indoor fan and an auxiliary heater, an outdoor unit including an outdoor heat exchanger, a compressor, an expansion device and an outdoor fan, the indoor unit and the outdoor unit It includes a four-way valve to selectively switch the circulation direction of the refrigerant between the operating cycle when the off (off) and the cooling cycle when the on (on), the selective depending on the number of heating cycles of the air conditioner The defrosting operation method is determined.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. 1 is a schematic diagram showing the configuration of an air conditioner according to the present invention, Figure 2 is a block diagram showing the configuration of an air conditioner according to the present invention.

1 and 2, the air conditioner according to the present invention includes an indoor unit 200 and an outdoor unit 400. The indoor unit 200 is installed in an air conditioning space, that is, the indoor space 100. An indoor suction port 210 is positioned at the front of the indoor unit 200, and an auxiliary heater 220, an indoor heat exchanger 230, and an indoor blower fan 240 are provided to the rear of the indoor unit 200. The air in the indoor space 100 is sucked into the indoor unit 200 of the air conditioner through the indoor suction port 210, and the indoor air sucked in this way is heat-exchanged through the indoor heat exchanger 230, and then the temperature thereof is adjusted. Discharged into the indoor space through the indoor discharge port (not shown). In this case, the indoor blower fan 240 forms a flow path for sucking and discharging indoor air into the indoor unit 200, and the auxiliary heater 220 performs a defrosting operation during the heating operation. When the 230 acts as an evaporator, the temperature of the indoor space 100 is prevented from being lowered.

On the other hand, in the indoor unit 200, the power supply unit 201 for supplying power to the air conditioner, the indoor temperature sensor 202 for measuring the temperature of the indoor space 100, and for measuring the temperature of the indoor piping The indoor piping temperature sensing unit 203, the indoor fan driver 211 for driving the indoor blower fan 240, the auxiliary heater driver 215 for driving the auxiliary heater 220, and the overall air conditioner The control unit 300 for controlling the driving is installed.

The outdoor unit 400 is installed outside the air conditioning space, that is, the outdoor unit, connected to the indoor unit 200 through the conduit 250 through which the refrigerant flows. Inside the outdoor unit 400, a four-way valve 410 for adjusting the flow direction of the refrigerant, a compressor 420 for compressing the refrigerant and converting the refrigerant into a high temperature and high pressure refrigerant, and condensing the refrigerant during the cooling operation and during the heating operation. An outdoor heat exchanger 430 for evaporating the refrigerant, an outdoor blower fan 40 for forming a flow path for inhaling and discharging outdoor air into the outdoor unit 400, and an expansion for expanding the refrigerant into a refrigerant having a low temperature and low pressure The apparatus 450 is installed.

On the other hand, in the outdoor unit 400, in order to efficiently control the operation of the air conditioner, various devices for checking the operating state of the air conditioner and its surrounding environment are installed. Representatively, sensing such as an outdoor temperature sensor 204 for measuring outdoor temperature, an outdoor pipe temperature sensor 205 for measuring a temperature of outdoor pipes, an outdoor humidity sensor 206 for measuring outdoor humidity, and the like And a driving unit such as the compressor driving unit 213, the outdoor fan driving unit 214, and the four-way valve driving unit 215.

When the air conditioner starts the heating operation, the control unit 300 sends a control signal for the operation to each of the above-described driving unit. Accordingly, the indoor blower fan 240 starts to rotate, and the compressor 420 compresses and discharges the refrigerant at high temperature and high pressure. The high temperature and high pressure refrigerant discharged from the compressor 420 is introduced into the indoor heat exchanger 230 and then heat exchanges with the air sucked into the indoor unit 200 by the rotational force of the indoor blower fan 240. Indoor air, which has been sucked in a relatively low temperature state, is raised in temperature by the heat exchange.

The refrigerant exchanged through the indoor heat exchanger 230 flows in the order of the expansion device 450, the outdoor heat exchanger 430, and then flows back into the compressor 420. After that, the refrigerant 420 and the indoor heat exchanger ( 230, the expansion device 450 and the outdoor heat exchanger 430 are repeated in order to increase the room temperature to a level desired by the user.

Meanwhile, while repeating the above-described heating cycle, the sensing unit periodically checks the state of the air conditioner and its surrounding environment, and the control unit 300 determines the current state of the air conditioner based on the value measured by the sensing unit. After grasping, the air conditioner can be operated efficiently by readjusting the operation state of the driving units based on this.

After a certain period of time after the start of the heating operation, frost is generated on the surface of the outdoor heat exchanger 430. The generated frost becomes more as the outdoor temperature is lower and the heating time is increased. Since the castle generated on the surface of the outdoor heat exchanger 430 acts as a fatal factor for reducing the heating efficiency of the air conditioner, the controller 300 performs a defrosting operation to remove the frost.

In the storage unit 310 of the air conditioner, a data table (ie, a defrosting operation rush condition) for defrosting operation is stored in advance. The controller 300 periodically checks whether the values measured by the detector and the timer 320 match the values of the data table, and if it is determined that the values match, the controller controls the driver to perform defrosting operation immediately. do.

When the defrosting operation is performed, the outdoor heat exchanger, which acted as an evaporator during the heating operation, begins to release heat by acting as a condenser and thaws to the castle that was covered on the surface of the outdoor heat exchanger by the released heat.

2 is a block diagram showing the configuration of the air conditioner according to the present invention, Figure 3 (a) to Figure 3 (b) is a defrosting operation method of the air conditioner according to the present invention 4 is a flow chart of the outdoor piping temperature and the defrosting operation start section and end section of the air conditioner according to the present invention.

3A and 3B, the defrosting operation method of the air conditioner according to the present invention selects the defrosting operation method according to the number of heating cycles of the air conditioner.

3A shows a defrosting operation method when the number of heating cycles of the air conditioner is two or less and a defrosting operation method when the number of heating cycles is four or less.

First, the defrosting operation method for the heating operation from the first to the second of the air conditioner, the heating operation step (S100) in which the air conditioner operates as a heating cycle by heating operation, the number of heating cycles (N) for the heating operation Heating cycle check step (S110) to check, the heating cycle check step (S110) and the number of heating cycles in the comparison step (S120), comparison step (S120) to compare with the number of heating cycles (N) and the reference set number is determined (S120) ) Is less than or equal to the reference set number of times, after the first predetermined time T1 has elapsed (S130), the temperature measured by the sensor 42 installed in the outdoor heat exchanger 20 is measured and the set outdoor heat exchanger temperature ( Comparing A) and determining the defrosting operation condition (S140), if it is determined that the defrosting operation condition in the determination step (S140), the switching step of stopping the heating cycle of the air conditioner, and switching to the cooling cycle (S150) , In the conversion step (S150) After the defrosting operation (S60) and the defrosting operation (S160) of stopping the outdoor blower fan 14 during the operation of the cooling cycle, the temperature of the outdoor heat exchanger 20 is re-measured according to the defrosting operation completion condition. When it is lower than the outdoor heat exchanger temperature (C) set in the judging step (S170) and the judging step (S170), compared to the heat exchanger temperature (C), the defrosting operation step ( Re-converted to the heating cycle in the cooling cycle after the operation step (S180), the operation step (S180) to satisfy the defrosting operation completion condition or the operation step (S180) after the operation step (S180) in S160). After the switching step (S190), the re-switching step (S190) is returned or terminated to the heating operation step (S100) of the air conditioner.

That is, in the heating operation step (S100), when the air conditioner starts heating operation, the indoor blower fan 240 and the outdoor blower fan 440 are operated, and the compressor 420 compresses and discharges the refrigerant at high temperature and high pressure. The high temperature and high pressure refrigerant discharged from the compressor 420 is introduced into the indoor heat exchanger 230 and then heat exchanges with the air sucked into the indoor unit 200 by the rotational force of the indoor blower fan 240. In addition, the four-way valve 410 and the auxiliary heater 220 does not operate. Indoor air, which has been sucked in a relatively low temperature state, is raised in temperature by heat exchange.

In the heating cycle check step (S110), the air conditioner starts the heating cycle for the heating operation and checks the number of heating cycles N continuously operated. Here, the heating operation cycle defines the case where the air conditioner enters the first operation and is heated once. That is, when the air conditioner is heated and then defrosted once, and the heating operation is performed again, the heating cycle becomes two cycles. In this way, the heating cycle is checked, and the defrosting operation method of the present invention is changed depending on the number of heating cycles, the defrosting operation conditions and the method of performing the defrosting operation to enter the defrosting operation will be described in detail later. Explain.

In the comparison step S120, the heating operation time required for the measurement based on the defrosting operation condition is adjusted by comparing with the number of heating cycles N measured in the heating cycle checking step S110 and the reference set number.
Referring to FIG. 3A, the heating operation time for the defrosting operation condition may be changed to the first predetermined time T1, the second predetermined time T2, or the third predetermined time T3 according to the heating cycle number N. FIG. have. When the number of heating cycles N performed by the air conditioner is two or less, the heating cycle may be performed for the first predetermined time. When the number N of heating cycles performed by the air conditioner is 4 or less, the air conditioner may perform the heating cycle for a second predetermined time. When the number of heating cycles N performed by the air conditioner is five or more times, the air conditioner may perform the heating cycle for a third predetermined time.

After the start of the heating operation, when the first predetermined time (T1) has elapsed (S130), the frost is generated on the surface of the outdoor heat exchanger 430, the lower the outdoor temperature in the generated castle, the more the heating time increases More.

In this embodiment, the first predetermined time T1 is 10 minutes.

The determination step S140 is performed after the first predetermined time T1 has elapsed, and the temperature of the outdoor heat exchanger 430 and the set outdoor heat exchanger temperature measured by the outdoor temperature detector 202 installed in the outdoor heat exchanger 430. Compared to (A), if the set value is less than the set outdoor heat exchanger temperature (A), the defrosting operation is satisfied to perform the defrosting operation, and the measured outdoor heat exchanger (430) temperature is higher than the set outdoor heat exchanger temperature (A). If high, the heating operation is repeatedly performed for the first predetermined time T1.

In the switching step S150, when the defrosting operation condition is satisfied in the determining step S140, the switching cycle is switched from the heating cycle to the cooling cycle.

Here, the heating operation of the air conditioner operated by the heating cycle is stopped, and the indoor heat exchanger 230, the outdoor blowing fan 440, and the compressor 420 are turned off. In addition, the four-way valve 410 is turned on (Off) for approximately 30 seconds to remove the remaining heat remaining in the indoor heat exchanger 230, not limited to this, an appropriate value may be selected. The auxiliary heater 220 is operated in conjunction with the indoor blowing fan 440, and operates when the room temperature falls below a preset room temperature (B). The preset temperature B may be selected from various values. In the present invention, the auxiliary heater 220 and the indoor fan 240 are driven when the indoor temperature is 1.5 ° F. or less than the desired temperature.

Such a switching step (S150) lasts for a predetermined time, for example, in the present invention lasts for 3 minutes, but is not limited thereto.

The defrosting operation (S160) prevents the temperature drop of the outdoor heat exchanger 430 by maintaining the outdoor blower fan 440 installed in the outdoor unit 400 in a stopped state while the outdoor heat exchanger 430 is heated. In addition, the indoor blower fan 240 and the compressor 420 are operated.

Defrosting operation (S160) lasts for a predetermined time, for example, in the present invention lasts for 6 minutes, but is not limited thereto.

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In the step S170, after the defrosting operation, the temperature of the outdoor heat exchanger 430 is re-measured and compared with the set outdoor heat exchanger temperature C. Here, the judging step (S170) satisfies the completion of the defrosting operation when the comparison result is equal to or greater than the set outdoor heat exchanger temperature (C) and is converted from the cooling cycle to the heating cycle, and is less than or equal to the set outdoor heat exchanger temperature (C). In this case, since the defrosting operation completion condition is not satisfied, the defrosting operation (S160) is passed to the operation step (S180) of operating the outdoor blower fan 24.

The set outdoor heat exchanger temperature C of the defrosting operation S160 is 21 ° C. (70 ° F.), but is not limited thereto.

In operation S180, the compressor 420, the indoor blower fan 240, the four-way valve 410, and the auxiliary heater 220 operate in the same manner as in the defrosting operation step S160 and the outdoor blower fan 440 operates. Rotate and operate for a predetermined time Q1.

In this embodiment, the predetermined time Q1 is 3 minutes.

In the re-switching step (S190), when the air conditioner satisfies the defrosting operation completion condition, the air conditioner is switched from the cooling cycle to the heating cycle.

Since the re-switching step (S190) is the same as described above in the switching step (S150), a detailed description thereof will be omitted, where the auxiliary heater 220 is operated in conjunction with the indoor blower fan 440, a preset It operates when the room temperature drops below the room temperature (D). The preset temperature (D) may be a variety of values can be selected, in the present invention is to drive the auxiliary heater 220 and the indoor fan 240 when the room temperature is 1.5 ° F or less than the desired temperature.

Here, when the re-switching step (S190) is completed, it is returned to the heating operation step (S100), the heating operation of the air conditioner is restarted.

The defrosting operation method for the heating operation of the 3rd to 5th stage of the air conditioner operates as follows.

The same as the first, second heating operation and defrost operation method of the air conditioner, and if the number of heating cycles (N) continuously operated in the comparison step (S120) does not match, the reference set in the first comparison step (S200) Compared with the number of times and the number of heating cycles N, the heating operation time required for the measurement based on the defrosting operating condition is adjusted.

In the first determination step S220, after the second predetermined time T2 has elapsed, the outdoor heat exchanger set with the temperature of the outdoor heat exchanger 430 measured by the outdoor temperature detector 202 installed in the outdoor heat exchanger 430. Compared to the air temperature (A), if it is less than the set outdoor heat exchanger temperature (A), the defrosting operation condition is satisfied to perform the defrosting operation, and the measured outdoor heat exchanger (430) temperature is set outdoor heat exchanger temperature (A) If higher than), the heating operation is repeatedly performed for the second predetermined time T2.

Since the same as the switching step (S150) of Figure 3 (a), a detailed description thereof will be omitted.

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3 (a) is a flow chart showing the continuous defrosting operation method for the fifth order or more, the defrosting operation method for the heating operation up to the fifth order of the air conditioner operates as follows.

The same as the first, second heating operation and defrost operation method of the air conditioner, and if the number of heating cycles (N) continuously operated in the first comparison step (S200) does not match, in the second comparison step (S230) The heating operation time required for the measurement based on the defrosting operation condition is adjusted in comparison with the reference number of times and the number of heating cycles N.

After the start of the heating operation, when the third predetermined time (T3) has elapsed (S240), the frost is generated on the surface of the outdoor heat exchanger 430, the lower the outdoor temperature in the generated castle, the more the heating time increases More.

In the present embodiment, the third predetermined time T3 is the same as the second predetermined time T2, but the present invention is not limited thereto.

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In the second determination step S250, after the third predetermined time T3 has elapsed, the outdoor heat exchanger temperature measured by the outdoor temperature detector 204 installed in the outdoor heat exchanger 430 and the set outdoor heat exchanger temperature A ) Is compared to the set outdoor heat exchanger temperature (A), the defrosting operation condition is satisfied to perform the defrosting operation, and if the measured outdoor heat exchanger temperature is greater than the set outdoor heat exchanger temperature (A) the third predetermined time Repeat operation with heating cycle during T3.

The defrosting operation step S260 is a process of converting the cooling cycle into the cooling cycle when the air conditioner satisfies the defrosting operation condition. Here, the air conditioner operated by the heating cycle is stopped, and the outdoor blower fan 440 driven for heat exchange of the indoor heat exchanger 230 during the heating operation is turned on, and the compressor 420 is turned off. The four-way valve 410 is turned on after being turned off for 30 seconds to remove residual heat remaining in the indoor heat exchanger 230.

Here, the auxiliary heater 220 is operated in conjunction with the indoor blowing fan 440, and operates when the room temperature falls below a preset room temperature (B). The preset temperature (B) may be a variety of values can be selected, in the present invention to drive the auxiliary heater 220 and the indoor fan 240 when the room temperature is less than -10 ℃ (1.5 ° F) compared to the desired temperature. do.

After removing the residual heat remaining in the indoor heat exchanger 230 after a predetermined time elapses, the stopped air conditioner is operated in a cooling cycle. Here, the predetermined time is about 3 minutes and is not limited thereto.

In this embodiment, the room temperature (B) is -33.5 ℃.

In operation S270, after the defrosting operation, the temperature of the outdoor heat exchanger 430 is re-measured and compared with the set outdoor heat exchanger temperature E. FIG. Here, when the comparison result is greater than or equal to the set outdoor heat exchanger temperature (E), the defrosting operation is completed, and when the comparison result is less than or equal to the set outdoor heat exchanger temperature (E), the defrosting operation is further performed.

In the present embodiment, the set outdoor heat exchanger temperature E is 6.5 ° C. (45 ° F.), but is not limited thereto.

When the defrosting operation is completed in the determination step (S270), it is returned to the heating operation step (S100), and the heating operation.

Figure 4 is a graph of the outdoor pipe temperature and the defrosting operation start section and end section of the air conditioner according to the present invention.

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FIG. 4 is a graph showing a measurement result of an outdoor pipe temperature, and shows a defrosting start point and a defrosting end point based on the set outdoor heat exchanger temperatures shown in FIGS. 3A and 3B.

Here, a section is a section in which the heating operation is started.

Section b is a section which is switched to perform the defrosting operation when the set outdoor temperature (A) is lower than the set outdoor temperature (A).

Section c is a section indicating the defrosting operation start point and the defrosting operation end point.

Section d is a section in which the defrosting operation is completed and converted into a heating cycle.

The e section is a section in which the heating operation is performed.

The f section is a section that is switched for defrosting operation after checking the defrosting operation condition again during heating operation.

As described above, the defrosting operation method of the air conditioner according to the present invention has been described with reference to the illustrated drawings. Can be.

The defrosting operation method of the air conditioner according to the present invention configured as described above can effectively remove the frost generated on the pipe surface of the outdoor heat exchanger during the heating operation by changing the defrosting operation method according to the heating cycle of the air conditioner.

Claims (10)

An indoor unit having an indoor heat exchanger, an indoor fan and an auxiliary heater, an outdoor unit having an outdoor heat exchanger, a compressor, an expansion device, and an outdoor fan, and selectively switching the circulation direction of the refrigerant between the indoor unit and the outdoor unit to be turned off In the case of), in the defrosting operation method of the air conditioner including a four-way valve for operating the defrosting operation that is operated in the heating cycle and the cooling cycle in the case of (on), the heating cycle and the defrosting operation is alternately repeated, The defrosting operation method of the air conditioner is selectively determined according to the number of repetition of the heating cycle performed by the air conditioner. The method of claim 1, wherein the defrosting operation method, A heating cycle checking step of checking the number of heating cycles of the air conditioner; A determination step of determining whether a defrosting operation condition is satisfied based on the number of heating cycles; A defrosting operation step of performing a defrosting operation for a predetermined time after the determining step; After the defrosting operation step, the defrosting operation method of the air conditioner comprising a judging step of determining whether the defrosting operation termination condition is satisfied. The defrosting operation condition of claim 2, The defrosting operation method of the air conditioner by measuring the temperature of the outdoor heat exchanger and comparing with the set outdoor heat exchanger temperature, and performing the defrosting operation step when the temperature is less than the set outdoor heat exchanger temperature. The method of claim 2, The defrosting operation method of the air conditioner to operate by the heating cycle, if the defrosting operation conditions are not satisfied. The method of claim 2, The defrosting operation method of the air conditioner according to the number of the heating cycle performed by the air conditioner, the time for performing the heating cycle is variable. 6. The method of claim 5, If the number of heating cycles identified in the heating cycle check step is less than two times, the heating cycle is defrosting operation method of the air conditioner is operated for a first predetermined time. 6. The method of claim 5, When the number of heating cycles identified in the heating cycle check step is four or less, the heating cycle is defrosting operation method of the air conditioner is operated for a second predetermined time. 6. The method of claim 5, If the number of heating cycles identified in the heating cycle check step is five or more times, the heating cycle is defrosting operation method of the air conditioner is operated for a third predetermined time. The method of claim 2, The defrosting operation method of the air conditioner further comprises the operation step of performing a defrosting operation for a predetermined time, when not satisfying the judging step. The defrosting operation termination condition according to claim 2, Defrosting operation method of the air conditioner is satisfied if the outdoor heat exchanger temperature is less than the set outdoor heat exchanger temperature.

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