JP3555644B2 - Control method of air conditioner - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a compressor control technique for an outdoor unit of an air conditioner (inverter air conditioner), and more particularly to a control method of an air conditioner that can appropriately set a minimum rotation speed of a compressor.
[0002]
[Prior art]
This type of air conditioner circulates a refrigerant obtained in a refrigeration cycle to an indoor heat exchanger, and blows cold or hot air exchanged by the indoor heat exchanger into a room by an indoor fan to control room temperature.
[0003]
For example, as shown in FIG. 6, the outdoor unit controller 1 of the air conditioner determines the operating frequency of the compressor 4 constituting the refrigeration cycle according to the set temperature of the remote controller 2 and the room temperature detected by the indoor temperature sensor 3. At the same time, the operating frequency is transferred to the outdoor unit control unit 5 by a code, and the indoor fan is controlled to rotate at a predetermined speed according to the air volume set by the remote controller 2. The outdoor unit controller 5 performs inverter control of the compressor 4 in accordance with the operating frequency code from the indoor unit controller 1.
[0004]
Then, the refrigerant in the predetermined temperature is obtained, the predetermined refrigerant is circulated to the indoor heat exchanger through the capillary or electronic expansion valve, heat exchange takes place in the indoor heat exchanger, an indoor by the rotation of the indoor fan , A desired cool air or hot air is blown out, and the indoor environment is kept comfortable.
[0005]
By the way, when the load of the compressor 4 is heavy and the rotation speed of the compressor 4 is high to some extent, the vibration of the compressor 4 is small due to the action of the moment of inertia. However, when the rotation speed of the compressor 4 is low, the vibration of the compressor 4 increases (the rotation speed becomes uneven due to the influence of torque fluctuation), and a crack or the like may occur in the piping. Further, for example, if the compressor motor is a brushless motor, the vibration of the compressor 4 (unevenness of the rotation speed) adversely affects the position detection control of the rotor, so that appropriate control may not be performed.
[0006]
Therefore, the minimum number of revolutions of the compressor is set to a higher value (for example, 13 rps) in consideration of vibration under heavy load and stress of piping. Therefore, when the load on the compressor 4 is heavy, even if control is performed to set the rotation speed of the compressor 4 to the minimum rotation speed, the vibration of the compressor 4 is suppressed, and the pipe may be damaged. In addition, the safety of the air conditioner is ensured, and the control of the compressor 4 is not adversely affected.
[0007]
[Problems to be solved by the invention]
However, in the control method of the air conditioner, for example, even if the outside air temperature is high, the load on the compressor 4 is not always heavy, that is, the load may not be heavy. In this case, the rotation speed of the compressor 4 is increased. The rotation speed is limited to the minimum, which is not preferable in terms of comfort. For example, when the room temperature is settled near the set temperature and the compressor 4 is controlled at the higher minimum rotation speed or the compressor 4 is shut down, the higher minimum rotation speed is used. In this case, the operation and the stop of the operation are repeated, so that subtle room temperature adjustment cannot be performed.
[0008]
The present invention has been made in view of the above problems, and its object is to pay attention to the fact that the load state can be determined based on the input current to the outdoor unit, and to vary the minimum rotation speed of the compressor according to the input current, By setting, the air conditioner does not increase the vibration of the compressor, does not damage the piping etc. (ensures safety), can finely adjust the room temperature, and improves the comfort Is to provide a control method.
[0009]
[Means for Solving the Invention]
To achieve the above object, the present invention is as described in claim 1, the compressor of the outdoor unit included in the refrigeration cycle to the inverter control, the set temperature of the room to adjust the room temperature In the method for controlling the air conditioner to be maintained, when the compressor is operated at the minimum rotation speed, the compressor is once operated at a predetermined rotation speed lower than the current rotation speed and higher than the minimum rotation speed, and It detects an input current to the outdoor unit, and wherein the benzalkonium change the minimum rotational speed of the compressor in response to the input current.
[0010]
In this case, it is preferable to perform the operation at the predetermined rotation speed for a predetermined time, as described in claim 2. Further, as described in claim 3, when the input current to the outdoor unit detected after operating the compressor at the predetermined rotation speed is equal to or higher than a predetermined value, the minimum rotation speed is increased to a lower minimum. It is preferable to change the rotation speed to a lower rotation speed when the input current to the outdoor unit is less than a predetermined value.
[0011]
According to the present invention, the input current to the outdoor unit is detected when the compressor is operated at the higher minimum rotation speed for a predetermined time or more, and the input current is detected. Is smaller than a first predetermined value, the minimum rotation speed is changed to the lower minimum rotation speed.
[0012]
Further, according to the present invention, as described in claim 5, when the compressor is operated at the lower minimum rotation speed for a predetermined time or more, the input current to the outdoor unit is detected, When the input current is greater than or equal to a second predetermined value (second predetermined value> the first predetermined value), the method also includes changing the minimum rotation speed to the higher minimum rotation speed.
[0013]
Further, according to the present invention, a compressor of an outdoor unit included in a refrigeration cycle is inverter-controlled to control a room temperature and maintain an indoor room at a set temperature. In the method, at least two rotation speeds are provided as a minimum rotation speed of the compressor, a higher minimum rotation speed and a lower minimum rotation speed, and when operating the compressor at the minimum rotation speed, the compressor is operated at the minimum rotation speed. After operating for a predetermined time at the higher minimum rotation speed, an input current to the outdoor unit is detected, and when the input current is less than a third predetermined value, the minimum rotation speed is changed to the lower minimum rotation speed. It is characterized by doing.
[0014]
In this case, as described in claim 7, after operating the compressor at the lower minimum rotation speed for a predetermined time or more, the input current to the outdoor unit is detected, and the input current is set to the fourth current. When the value is equal to or more than a predetermined value (fourth predetermined value> the third predetermined value), it is preferable to change the minimum rotation speed to the higher minimum rotation speed .
[0015]
Further, as described in claim 8, after operating the compressor at the higher minimum rotation speed for a predetermined time or more, an input current to the outdoor unit is detected, and the input current is set to the fourth current. An aspect in which the minimum rotation speed is changed to the lower minimum rotation speed when the rotation speed is not equal to or more than the predetermined value is also included in the present invention .
[0016]
Also, the when the an instruction other than the lowest rotational speed when the compressor is operating at the lowest rotational speed, the compressor is operated in accordance with the instructions, again during the operation minimum rotational speed of the When instructed, it is preferable to operate the compressor after performing the above-described procedure.
[0017]
Further, in the present invention, the minimum rotation speed of the compressor can be changed depending on which of the plurality of zones the input current to the outdoor unit enters .
[0018]
BEST MODE FOR CARRYING OUT THE INVENTION
An embodiment of the present invention will be described below with reference to FIGS. Note that the same parts as those in FIG. 6 described above are denoted by the same reference numerals, and redundant description will be omitted.
[0019]
In FIG. 1, the outdoor unit control unit 10 to which the air conditioner control method of the present invention is applied includes, in addition to the function of the outdoor unit control unit 5 shown in FIG. 6, an input current to the outdoor unit (that is, an outdoor unit). means for detecting a value) that corresponds to the power consumption, the value of increasing the minimum frequency in response to the detected input current (e.g. 13Rps), was changed to a lower value (e.g. 9Rps), also the timer is used when the change And a control circuit 10b having A, B, and C timer sections 10a.
[0020]
In the case of an air conditioner having a current detection unit (CT) for detecting an input current to the outdoor unit , the current detection unit may be used. Further, the chamber unit controller 11 has the function of the indoor unit control unit 1 shown in FIG. 6, the AC power supply is also supplied to the outdoor unit via the indoor unit.
[0021]
Next, the control method of the air conditioner of the present invention will be described with reference to the flowcharts of FIGS .
[0022]
First, when the air conditioner is operated, in a conventional manner while the rotation control indoor fan chamber machine control unit 11, for example in response to the operation of the remote controller 2, commanding (operation frequency code) outdoor unit Transfer to the control unit 10. The outdoor unit controller 10 controls the rotation of the compressor 4 according to the operating frequency code, and controls the electronic expansion valve and the outdoor fan.
[0023]
At this time, when the compressor 4 is started by the command from the indoor unit control unit 11, the outdoor unit control unit 10 proceeds from step ST1 to step ST2, and determines whether or not the command requests the minimum rotation speed. I do. That is, it is determined whether or not the operating frequency code transferred from the indoor unit control unit 11 is the minimum rotation speed of the compressor 4.
[0024]
For example, OPERATION frequency code originally initiated the operation if there a certain large value (a value higher than lowest speed), the process proceeds from step ST2 to step ST3, the it is determined whether a stop request. If the stop request has not been issued, the compressor 4 is operated as usual (step ST4), that is, the rotation of the compressor 4 is controlled in accordance with the operation frequency code from the indoor unit control unit 11, and the stop request is issued due to some abnormality. Is issued, the compressor 4 is stopped (step ST5). In addition, even if it returns to normal operation, if there is a request for the minimum rotation speed again, the above-described processing is executed.
[0025]
Subsequently, when a request for the minimum number of revolutions is issued from the indoor unit controller 11 because, for example, the indoor temperature has reached the set value, the process proceeds from step ST2 to step ST6, the timer A is started, and the compressor 4 is rotated at a predetermined speed. The motor is operated at a speed (for example, a value lower than the current speed and higher than the minimum speed (13 rps)) (step ST7).
[0026]
Subsequently, it is determined whether or not the time of the timer A has expired (step ST8), and it is determined whether or not there is a request for the minimum rotation speed from the indoor unit controller 11 until the time of the timer A has expired (step ST8). ST9). If there is a request for the minimum rotation speed even though the rotation speed of the compressor 4 has been lowered, the process returns to step ST8.
[0027]
If there is no request for the minimum number of revolutions from the indoor unit controller 11 before the timer A times out, the process returns to step ST3 and executes the above-described processing (step ST4 or step ST5). That is, because the indoor temperature has deviated from the set value by setting the compressor 4 to the predetermined rotation speed, it is necessary to return to the normal operation. In addition, even if it returns to normal operation, if there is a request for the minimum rotation speed again, the above-described processing is executed.
[0028]
Subsequently, when the timer A times out, the process proceeds from step ST8 to step ST10, in which the timer B is started, and the minimum rotation speed of the compressor 4 is set to a higher value (13 rps). Subsequently, it is determined whether or not the timer B has timed out (step ST12), and it is determined whether or not there is a request for the minimum rotation speed from the indoor unit controller 11 until the timer B has timed out (step ST13). ). If there is a request for the minimum rotation speed even though the rotation speed of the compressor 4 has been lowered, the process returns to step ST12.
[0029]
If there is no request for the minimum number of revolutions from the indoor unit control unit 11 before the timer B times out, the process returns to step ST3 and executes the above-described processing (step ST4 or step ST5). That is, as described above, since the indoor temperature has deviated from the set value by setting the compressor 4 to the predetermined rotation speed, it is necessary to return to the normal operation. In addition, even if it returns to normal operation, if there is a request for the minimum rotation speed again, the above-described processing is executed.
[0030]
Subsequently, when the timer B times out, the input current of the outdoor unit is detected, and it is determined whether or not the input current is less than a first predetermined value (step ST14). Note that the first predetermined value is a current value when the load is not heavy (normal current value).
[0031]
For example, when the load on the compressor 4 is heavy and the input current is not less than the first predetermined value, that is, when the input current is larger than normal, it is determined whether or not there is a request for the minimum rotation speed (step ST15). . If the compressor 4 is operated at the higher minimum rotation speed for a predetermined time until the timer B times out, that is, the compressor 4 is operated at the higher minimum rotation speed, the compressor 4 is operated at the higher minimum rotation speed. Continue operation with
[0032]
If there is no request for the minimum number of revolutions, the process returns to step ST3 and executes the above-described processing (step ST4 or step ST5). Even after returning to the normal operation, if there is a request for the minimum number of revolutions again, the above-described processing is executed.
[0033]
When the input current is less than the first predetermined value, the timer C is started (step ST16), and the minimum rotation speed of the compressor 4 is set to a lower value (9 rps) (step ST17). That is, since the input current is reduced and becomes about the same as the normal state, even if the minimum rotation speed of the compressor 4 is further reduced, the vibration of the compressor 4 does not increase, and thus the piping is not damaged, and This is because the safety of the harmony machine is ensured and there is no adverse effect on the control of the compressor.
[0034]
Subsequently, the timer C is determined whether the time is up (Step ST1 8), timer C is before time is up, it is determined whether there is a minimum rotation number of requests (step ST19). If there is a request for the minimum rotation speed even though the rotation speed of the compressor 4 has been lowered, the process returns to step ST18.
[0035]
If there is no request for the minimum number of revolutions before the timer C expires, the process returns to step ST3 and executes the above-described processing (step ST4 or step ST5). That is, as described above, since the indoor temperature has deviated from the set value by setting the compressor 4 to the predetermined rotation speed, it is necessary to return to the normal operation. In addition, even if it returns to normal operation, if there is a request for the minimum rotation speed again, the above-described processing is executed.
[0036]
Subsequently, when the timer C times out, the input current of the outdoor unit is detected, and it is determined whether or not the input current is equal to or more than a second predetermined value (step ST20). Note that the second predetermined value is a value larger than the first predetermined value. That is, chattering is less likely to occur in the control.
[0037]
For example, when the load on the compressor 4 does not become heavy and the input current is not equal to or more than the second predetermined value, it is determined whether or not there is a request for the minimum rotational speed (step ST21). As a result of operating the compressor 4 at the lower minimum rotation speed for the time until the timer C times out, that is, for a predetermined time, if there is a request for the minimum rotation speed, the compressor 4 is kept at the lower minimum rotation speed. Continue driving.
[0038]
If there is no request for the minimum number of revolutions, the process returns to step ST3 and executes the above-described processing (step ST4 or step ST5). When the operation returns to the normal operation, the above-described processing is executed if there is a request for the minimum rotation speed again.
[0039]
When the input current becomes equal to or more than the second predetermined value, the process returns from step ST20 to step ST10, and repeats the above-described processing. That is, it is determined that the load on the compressor 4 has become heavy, and the minimum rotation speed is increased to a higher value. Change . That is, if the compressor 4 is operated at a lower minimum rotational speed, the vibration of the compressor 4 increases, which eventually causes damage to the piping.
[0040]
Thus, according to the present invention, the value of increasing the minimum number of revolutions when the input current is equal to or higher than the predetermined value, so that the lower value when the input current is less than the predetermined value, the magnitude of the input current Ru can be changed minimum frequency in response to (the weight of the load of the compressors 4).
[0041]
In particular , when the load is light, the minimum rotation speed is lower than before, so that the vibration of the compressor 4 does not increase (torque fluctuation does not increase), there is no damage to the piping, and the control of the compressor 4 There is no adverse effect, and the lowering of the minimum number of revolutions makes it possible to finely adjust the room temperature, thereby improving comfort. The predetermined values may be the same, but are preferably set to the first and second predetermined values as described in the previous embodiment.
[0042]
Further, in the present invention, when the compressor is operated at the minimum rotation speed, the compressor is once operated at a predetermined rotation speed (rotation speed higher than 13 rps), the input current to the outdoor unit is detected, and the minimum is determined according to the input current. Change the speed. According to this, if the compressors 4 is operated in the vicinity of the minimum frequency For example, there is a high possibility that the command of the minimum frequency is issued from the indoor unit controller 11, in advance operation at a predetermined rotational speed The compressor 4 is quickly operated at the minimum rotation speed in response to the minimum rotation speed command from the outdoor unit control unit 11 by detecting the input current at the time and changing the minimum rotation speed according to the input current. In addition, vibration of the compressor 4 does not increase (torque fluctuation does not increase) as described above, there is no damage to the piping, and there is no adverse effect on control of the compressor 4.
[0043]
Further, after being commanded from play chamber unit controller 11 minimum rotational speed of the example is issued, it is possible to command from the indoor unit control section 11 of the predetermined number of revolutions to the room temperature abruptly changes is issued, the be the rotational speed instruction is changed so can be brought close to quickly set value room temperature, while requiring less deterioration of the indoor environment, rapidly controlling the compressor 4 from the predetermined rotational speed to the minimum rotational speed As described above, the vibration of the compressor 4 does not increase (the torque fluctuation does not increase), the piping is not damaged, and the control of the compressor 4 is not adversely affected.
[0044]
When the compressor 4 is operated at the minimum rotation speed, the compressor 4 is operated at a predetermined rotation speed (rotation speed higher than 13 rps) for a predetermined time, and then the input current to the outdoor unit is detected. From a high rotational speed in the case where the set value) or more (operated by setting the 13Rps), minimum rotational speed lower when the input current is less than a predetermined value (first set value) (9Rps) Is set to drive.
[0045]
As described above, the minimum rotation speed of the compressor 4 is set to a higher value (13 rps) or a lower value (9 rps) according to the magnitude of the input current to the outdoor unit , that is, the load of the compressor 4. since it is possible to change, (not a large torque variation) vibration does not increase the compressor 4 as described above, no damage to the pipe, also nor adversely affect the control of the compressor 4.
[0046]
Further, after the operation a predetermined time at a minimum a high rotational speed the compressor 4, detects an input current to the outdoor unit, lower if the input current is less than a predetermined value (first set value) The machine is running with the minimum speed set. According to this, after the minimum rotational speed for example 13Rps, (if the load is lighter in other words the compressor 4) when the input current has returned to normal values at the time of down, the lowest speed for example 9rps Therefore, while maintaining the room temperature at the set value, comfort can be achieved. On the other hand, as described above, the vibration of the compressor 4 does not increase (torque fluctuation does not increase), the piping is not damaged, and the compressor is not damaged. 4 does not adversely affect the control.
[0047]
Further, after operating the compressor 4 at a lower minimum rotation speed for a predetermined time, an input current to the outdoor unit is detected, and the input current is set to a predetermined second set value (second set value> first set value) . If the value is equal to or more than the set value, the engine is operated with the higher minimum rotation speed set again. According to this, after the minimum rotation speed is set to, for example, 9 rps, when the input current increases and becomes larger than the normal value (that is, when the load on the compressor 4 becomes heavy), the minimum rotation speed becomes, for example, 13 rps. Therefore, as described above, the vibration of the compressor 4 does not increase (torque fluctuation does not increase), the piping is not damaged, and the control of the compressor 4 is not adversely affected.
[0048]
If the indoor unit issues a rotation speed command other than the minimum rotation speed while operating at the minimum rotation speed (lower value or higher value), the operation is temporarily performed by the rotation speed command (ie, normal operation). However, if there is a command (request) for the minimum rotation speed again, the above-described procedure is performed to operate the compressor 4 at the minimum rotation speed (lower value or higher value). Therefore, during the operation of the air conditioner, the minimum rotation speed is varied in accordance with the magnitude of the input current to the outdoor unit (the load of the compressor 4) whenever the minimum rotation speed is requested. , Can be set.
[0049]
Figure 4 is a schematic block diagram of a control device for a brushless motor for explaining another real 施形 status of the present invention. The same parts as those in FIG. 1 are denoted by the same reference numerals, and redundant description will be omitted.
[0050]
4, the outdoor unit control unit 12 of the control device to which the control method of the brushless motor of the present invention is applied includes, in addition to the function of the outdoor unit control unit 5 shown in FIG. means for setting the value) corresponding to the power consumption of the outdoor unit, the value of increasing the minimum frequency in response to the detected input current (e.g. 13Rps), was changed to a lower value (e.g. 9Rps), also when the change and a control circuit 12b having a timer unit 12a consisting of timer D and timer E is used.
[0051]
Operation of the control method in the another real 施形 condition will depend on the flow chart of FIG. 5, FIG. 5, as is apparent from the figure, except ST10 to not step ST6 shown in FIG. 2, as in FIG. 2 and FIG. 3 It is. That is, step ST30 is ST1, step ST31 is ST2, step ST32 is ST3, step ST33 is ST4, step ST34 is ST5, step ST35 is ST10, step ST36 is ST11, step ST37 is ST12, Step ST38 is ST13, step ST39 is ST14, step ST40 is ST15, step ST41 is ST16, step ST42 is ST17, step ST43 is ST18, step ST44 is ST19, step ST45 is ST20, and step ST46 is ST46. Corresponds to ST21. Further, the timer D corresponds to the timer B, the timer E corresponds to the timer C, the third set value corresponds to the first set value, and the fourth set value corresponds to the second set value.
[0052]
In this embodiment, when a command for the minimum number of revolutions is issued from the indoor unit control unit 11, the control circuit 12b of the outdoor unit control unit 12 operates the compressor 4 without operating the compressor 4 at the predetermined number of revolutions for a predetermined time. Immediately at the higher minimum rotation speed (13 rps), the same processing as in the previous embodiment is executed as shown in the flowchart of FIG. Therefore, for the operation of this embodiment, refer to the description of the previous embodiment.
[0053]
As described above, when the minimum rotation speed is requested, the compressor 4 is immediately set to the higher minimum rotation speed (13 rps), so that it is possible to quickly control the indoor temperature change, and to control the outdoor unit. When a microcomputer is used for the control of the present embodiment, the number of timers is one less than in the previous embodiment, so that the software program can be simplified, the memory capacity can be reduced, and It is clear that the same effect as in the embodiment can be obtained.
[0054]
In the above-described two embodiments, two predetermined values (first and second predetermined values or third and fourth predetermined values) are prepared. The minimum rotation speed of the compressor 4 may be varied and set according to which of the plurality of zones the input current to the outdoor unit enters.
[0055]
Further, in the above-described two embodiments, two kinds of minimum rotation speeds, that is, a high value (13 rps) and a low value (9 rps), are prepared. The minimum rotation speed may be set for each zone. By doing so, the variable and setting control of the minimum rotation speed can be performed more finely.
[0056]
【The invention's effect】
As described above, by the inventions of this lever, the compressor of the outdoor unit included in the refrigeration cycle to the inverter control, in the control method of an air conditioner to keep the room temperature setting and adjust the room temperature When operating the compressor at the minimum rotation speed, the compressor is once operated at a predetermined rotation speed lower than the current rotation speed and higher than the minimum rotation speed, and the input current to the outdoor unit at that time is detected. And changing the minimum rotation speed of the compressor according to the input current. That is, when the input current is equal to or higher than a predetermined value, the minimum rotation speed is set to a higher value, and when the input current is lower than a predetermined value, a lower value is set. depending on the weight of the load of the compressor by which is adapted to change the minimum rotational speed, not particularly because the minimum rotational speed is lower than conventionally when the load is light, vibration of the compressor is large as ( Torque fluctuation Not increase), without damage to the pipe, also without adversely affecting the control of the compressor, moreover enables subtle climate by minimum rotation speed is low, the effect of can be improved comfort is there.
[0057]
When the compressor is operated at the minimum rotation speed, the compressor is operated at a predetermined rotation speed lower than the current rotation speed and higher than the minimum rotation speed. they change their rotational speed command after is issued, since the rotational speed of the compressor is higher than the minimum rotational speed, it can be brought close to quickly set value room temperature, to free less deterioration of indoor environment .
[0058]
Further, when the compressor is operating at a lower minimum rotation speed for a predetermined time or more, an input current to the outdoor unit is detected, and when the input current is equal to or more than a second predetermined value , since so as to operate the compressor at a minimum a high rotational speed, does not occur chattering to those the control, there is an effect that it is stable control.
[Brief description of the drawings]
FIG. 1 shows an embodiment of the present invention, and is a schematic block diagram of a control device to which an air conditioner control method is applied.
FIG. 2 is a schematic flowchart illustrating the operation of the control device shown in FIG. 1;
FIG. 3 is a schematic flowchart illustrating the operation of the control device shown in FIG. 1;
FIG. 4 is a schematic block diagram of a control device of an air conditioner showing a modified embodiment of the present invention.
FIG. 5 is a schematic flowchart illustrating the operation of the control device shown in FIG. 4;
FIG. 6 is a schematic block diagram of a control device of a conventional air conditioner.
[Explanation of symbols]
1,11 Indoor unit control unit 4 Compressors 5, 10, 12 Outdoor unit control unit 10a Timer unit (timer A, timer B, timer C)
10b, 12b Control circuit 12a Timer section (timer D, timer E)

Claims (8)

The compressor of the outdoor unit included in the refrigeration cycle to the inverter control, in the control method of an air conditioner to keep the room temperature setting by adjusting the room temperature,
In operating the compressor at the minimum rotation speed, the compressor is once operated at a predetermined rotation speed lower than the current rotation speed and higher than the minimum rotation speed, and an input current to the outdoor unit at that time is detected. the control method of an air conditioner, wherein the benzalkonium change the minimum rotational speed of the compressor in response to the input current. The control method for an air conditioner according to claim 1, wherein the operation at the predetermined rotation speed is performed for a predetermined time . When the input current to the outdoor unit detected after operating the compressor at the predetermined rotation speed is equal to or more than a predetermined value, the minimum rotation speed is changed to a higher minimum rotation speed, and the input current to the outdoor unit is changed. The control method for an air conditioner according to claim 1 or 2, wherein when the value is less than a predetermined value, the minimum rotation speed is changed to a lower minimum rotation speed . Detecting an input current to the outdoor unit when the compressor is operating at the higher minimum rotation speed for a predetermined time or more, and detecting the minimum rotation speed when the input current is less than a first predetermined value; 4. The control method for an air conditioner according to claim 3, wherein is changed to the lower minimum rotation speed . An input current to the outdoor unit is detected when the compressor is operating at the lower minimum rotation speed for a predetermined time or more, and the input current is detected as a second predetermined value (a second predetermined value> the first predetermined value). 4. The control method for an air conditioner according to claim 3, wherein the minimum rotation speed is changed to the higher minimum rotation speed when the rotation speed is equal to or more than a predetermined value . In the control method of the air conditioner, which controls the compressor of the outdoor unit included in the refrigeration cycle by inverter, and adjusts the room temperature to keep the room at the set temperature.
At least two rotation speeds, a higher minimum rotation speed and a lower minimum rotation speed, are prepared as the minimum rotation speed of the compressor, and when the compressor is operated at the minimum rotation speed, the compressor is moved to the higher rotation speed. After operating for a predetermined time at the minimum rotation speed, an input current to the outdoor unit is detected, and when the input current is less than a third predetermined value, the minimum rotation speed is changed to the lower minimum rotation speed. Characteristic air conditioner control method. After operating the compressor at the lower minimum rotation speed for a predetermined time or more, an input current to the outdoor unit is detected, and the input current is set to a fourth predetermined value (a fourth predetermined value> the third predetermined value). 7. The control method for an air conditioner according to claim 6, wherein the minimum rotation speed is changed to the higher minimum rotation speed when the rotation speed is not less than (value) . After operating the compressor at the higher minimum rotation speed for a predetermined time or more, an input current to the outdoor unit is detected, and when the input current is not equal to or more than the fourth predetermined value, the minimum rotation speed is set to the 8. The control method for an air conditioner according to claim 6, wherein the rotation speed is changed to a lower minimum rotation speed .

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