JPH0726765B2 - Air conditioner - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to an air conditioner, and more particularly to a so-called multi-type air conditioner that includes a plurality of indoor units and can cool multiple rooms at the same time. The present invention relates to a defroster for growing frost on an indoor heat exchanger that acts as an evaporator during cooling operation.

(Prior Art) Conventionally, in this type of multi-type air conditioner, in order to prevent frost formation in each indoor heat exchanger during simultaneous cooling operation of the multiple rooms, for example, JP-A-49-38252. In the one disclosed in (Conventional example 1), the capacity of the outdoor unit is made variable, and by making the capacity of the outdoor unit substantially correspond to the total capacity of the indoor units during the simultaneous operation in the simultaneous cooling operation of multiple rooms, the evaporation is performed. The temperature is kept high to prevent frost formation in each indoor heat exchanger.

Further, in the one disclosed in Japanese Patent Laid-Open No. 60-193716 (conventional example 2), the capacity of the compressor remains at its full capacity, and two heat exchangers are provided with freezing sensors respectively, and each freezing sensor is attached. When a temperature equal to or lower than a predetermined value is detected, the electromagnetic valve provided on the inlet side of each heat exchanger is closed to defrost each heat exchanger.

(Problems to be Solved by the Invention) However, in the conventional example 1, the presence or absence of frost formation in each indoor heat exchanger is not the same between the indoor units, and the imbalance of installation states between the indoor units and each Depending on the indoor temperature condition and the like, there may be cases where multiple indoor heat exchangers are frosted on only one indoor heat exchanger without frosting. Therefore, even if the above-mentioned conventional measures for preventing frost formation are taken, there is a drawback that the preventive measures are not reliable.

Further, in the conventional example 2, since the capacity of the compressor is not variable, when defrosting enters one heat exchanger, the capacity of the compressor becomes relatively larger than that of the other heat exchanger, and Freezing of the heat exchanger was promoted, and there was a drawback in that it was not comfortable.

The present invention has been made in view of the above problems, and an object thereof is to provide, in a multi-type air conditioner, in addition to capacity control of a compressor according to the number of operating indoor units, installation of an indoor heat exchanger. At the time of frost, by blocking the flow of the refrigerant only to the indoor heat exchanger and defrosting the growing frost of this indoor heat exchanger by the blowing action of the indoor blower fan, to the indoor heat exchanger without frost formation. For example, while continuing the cooling operation, the evaporation capacity of the frosted indoor heat exchanger is restored to improve reliability against frosting of the indoor heat exchanger, and the temperature sensor detects a temporary temperature drop. Even if you do not want to enter the defrosting operation, you can perform comfortable air conditioning by eliminating unnecessary defrosting operation.When defrosting is necessary, surely perform defrosting operation, and when defrosting operation ends Be sure to return to cooling operation It is to be so.

(Means for Solving the Problem) In order to achieve the above object, the solution means of the present invention is, as shown in FIG. 1, arranged in parallel with one outdoor unit (X) containing a compressor (1). It is equipped with a plurality of indoor units (Y) and (Y ') that are connected and are operated at the same time. Each indoor unit (Y) and (Y') includes an indoor heat exchanger (10) and an indoor blower fan (10c). In the built-in air conditioner, the capacity of the compressor (1) and the flow means (17) for allowing and blocking the flow of the refrigerant to the indoor units (Y) and (Y ′) are adjusted. A capacity adjusting means (20) and a temperature sensor (35) for detecting the temperature of the indoor heat exchanger (10) of each of the indoor units (Y), (Y ') during the cooling operation.
And the output of each of the temperature sensors (35), the temperature of any of the indoor heat exchangers (10) is below a first predetermined value and
The temperature of the indoor heat exchanger (10) is higher than the first predetermined value since the state of being equal to or lower than the predetermined value continues for the first predetermined time.
Until the state of the predetermined value or more and the second predetermined value or more continues for the second predetermined time, the flow of the refrigerant to the corresponding indoor unit (Y or Y ′) is blocked, and the other indoor unit (Y ′). Or, each circulation means (17) is controlled so as to permit the circulation of the refrigerant to the other indoor unit (Y ′).
Alternatively, the defrosting operation control means (45) for controlling the capacity adjusting means (20) so as to reduce the capacity of the compressor (1) so that the capacity corresponds to the total capacity of Y), and the defrosting operation control. During the defrosting operation by means (45), the indoor blower fan (10
Indoor fan control means (46) for controlling to drive c)
It has a configuration including and.

(Operation) According to the present invention, during the cooling operation, the temperature of the indoor heat exchanger (10) of any of the indoor units is below the first predetermined value and below the first predetermined value. The temperature of the indoor heat exchanger (10) is higher than the first predetermined value and is equal to or higher than the second predetermined value after the continuation for one predetermined time, and the second
Until the state of the predetermined value or more continues for the second predetermined time,
The defrosting operation control means (45) controls each circulation means (17) to prevent the refrigerant from flowing to the corresponding indoor unit (Y 'or Y), and the indoor fan control means (46) controls the corresponding indoor room. The blower fan (10c) is driven, and the indoor heat exchanger (10) is defrosted by its blowing action. In this case, during defrosting operation of the indoor heat exchanger (10) that has frosted, the other indoor heat exchangers (1
Since the defrosting operation is not performed for 0) due to the non-operation of the refrigerant circulation means (17), the cooling operation is continued due to the circulation of the refrigerant. Moreover, since the capacity of the compressor (1) during the defrosting operation is reduced by the defrosting operation control means (45), the indoor heat exchanger (10) during the cooling operation is frosted due to the defrosting operation. Is less likely to occur. Further, the defrosting operation control means (45) has an indoor heat exchanger (10) detected by the temperature sensor (35).
When the temperature of is less than or equal to the first predetermined value and the state of less than or equal to the first predetermined value continues for the first predetermined time, the flow of the refrigerant is blocked, so that the plurality of indoor units (Y),
(Y ') When this temperature does not continue for the first predetermined time even if the temperature temporarily becomes equal to or lower than the first predetermined value due to a change in the operating condition due to a sudden load change during the simultaneous cooling operation. That is, when the defrosting operation is not necessary, the defrosting operation is not started, and conversely, the temperature of the indoor heat exchanger (10) is below the first predetermined value and below the first predetermined value due to frost formation. The defrosting operation can be started only when the above has continued for the first predetermined time. Further, the defrosting operation control means (45) has an indoor heat exchanger (1) detected by the temperature sensor (35).
If the temperature of 0) is higher than the second predetermined value higher than the first predetermined value and the state of the second predetermined value or higher continues for the second predetermined time, the defrosting operation is completed, and thus defrosting may be insufficient. It will disappear and the defrosting operation will not continue unnecessarily.

(Embodiment) An embodiment of the present invention will be described below with reference to the drawings starting from FIG.

FIG. 2 shows a refrigerant piping system of a multi-type air conditioner, where (X) is an outdoor unit and (Y) and (Y ′) are first and second indoor units, respectively, which are arranged in a predetermined room. Inside the outdoor unit (X), a compressor (1), a four-way switching valve (2) that switches as shown by the solid line in the figure during cooling operation and switches as shown by the broken line in the figure during heating operation, and the outdoor unit An outdoor heat exchanger (3) having a blower fan (3a), a cooling expansion valve (4) for controlling the degree of superheat for adjusting the degree of throttling during cooling operation, and a parallel connection to the cooling expansion valve (4) A heating capillary tube (5), a solenoid valve (6) that opens to flow a refrigerant to the heating capillary tube (5) during a heating operation, and an accumulator (7) are built in as main devices. And each of the devices (1) to (7)
Are connected by a refrigerant pipe (8) so that the refrigerant can flow.

On the other hand, the two indoor units (Y) and (Y ') have the same structure, and the two heat exchangers (10a) and (10
b) are connected in parallel with each other, and have an indoor heat exchanger (10) having one indoor blower fan (10c), an auxiliary heating capillary tube (11), and the auxiliary heating capillary tube (11) in parallel. And a heating solenoid valve (12) for allowing or blocking the flow of the refrigerant to the auxiliary heating capillary tube (11) during the heating operation, and the cooling connected to the auxiliary heating capillary tube (11) in parallel. A cooling electromagnetic valve (13) that opens during operation is built in, and each of the devices (10) to (13) is connected to a refrigerant pipe (15) so that the refrigerant can flow therethrough. The two indoor units (Y) and (Y ') are connected to each other in parallel with the one outdoor unit (X) by the refrigerant pipes (16), so that the compressor ( The refrigerant from 1) is circulated by switching the four-way switching valve (2) as shown by the solid line arrow in the figure, so that the indoor air in the indoor heat exchanger (10) of each indoor unit (Y), (Y ') The amount of heat absorbed from the outdoor unit (X) is repeatedly released to the outside air by the outdoor heat exchanger (3) to cool the two chambers at the same time, while the refrigerant from the compressor (1) is discharged during the heating operation. By circulating the medium as indicated by the solid line arrow, the refrigerant circulation cycle is set to the opposite cycle to the above and the two chambers are heated at the same time.

Then, the refrigerant pipe (15) is opened and closed by the heating solenoid valve (12) and the cooling solenoid valve (13) of each of the indoor units (Y) and (Y '), so that the indoor units (Y),
The circulation means (17) is configured to allow and block the circulation of the refrigerant to (Y '), respectively. Further, in the outdoor unit (X), (19) is a three-way solenoid valve that selectively switches communication between the inside of the compressor (1) between its discharge side and suction side, and a diagram of the three-way solenoid valve (19). At the time of switching the discharge side shown by the solid line, the capacity control operation is performed by immediately returning a part of the refrigerant discharged from the compressor (1) to the inside of the compressor (1), while at the time of switching the suction side shown by the broken line. The capacity control means (20) is configured to adjust the capacity of the compressor (1) so that the compressor (1) is operated at full capacity. In the outdoor unit (X), (21) is a discharge pressure adjusting valve for adjusting the discharge pressure of the refrigerant from the compressor (1).

Then, in the two indoor units (Y) and (Y ′), in order to defrost the frost that has grown during the cooling operation of the indoor heat exchanger (10) incorporated therein, the indoor heat exchanger (10) is removed. ) First and second temperature sensors (35) for detecting the temperature Tc of
(35) is provided and the temperature sensors (35), (3
The output signal of 5) controls the three-way solenoid valve (19) and the cooling solenoid valves (12) and (13) of the outdoor unit (X) and the indoor blower fans (10c) and (10c), respectively.
It is input to the control circuit (40) built in U or the like.

Next, the control during the cooling operation by the control circuit (40) will be described based on the flowchart of FIG. After starting, the indoor heat exchanger (1) of the first indoor unit (Y) is started based on the output signal of the first temperature sensor (35) in step S1.
0) determines whether frost has formed. In this determination, the temperature Tc of the indoor heat exchanger (10) is below a first predetermined value (e.g. -7 [deg.] C.) near the frosting temperature and is below the first predetermined value for a first predetermined time (e.g. 10 minutes) When it continues, it is judged that it is frosting and it is performed. in this way,
Whether the temperature Tc of the indoor heat exchanger (10) is below a first predetermined value or not and whether or not the state below this first predetermined value has continued for a first predetermined time is determined whether frost is formed or not. The reason is that the temperature temporarily falls below the first predetermined value due to a change in the operating condition due to a sudden load change during the simultaneous cooling operation of the plurality of indoor units (Y) and (Y '). Also, when this state does not continue for the first predetermined time, that is, when the defrosting operation is not necessary, the defrosting operation is not started, and conversely, the temperature of the indoor heat exchanger (10) is changed to the first predetermined time by frost formation. This is because the defrosting operation can be started only when the state of being equal to or less than the value and equal to or less than the first predetermined value continues for the first predetermined time.

As described above, as an example of the case where the defrosting is not necessary even if the temperature of the indoor heat exchanger temporarily becomes equal to or lower than the first predetermined value, there are the following cases (a) and (b).

(B) For example, 5 indoor units are connected in the multi-type air conditioner, and 2 units are connected during the simultaneous cooling operation of these 5 units.
If the platform is stopped.

At this time, the capacity of the compressor is reduced from the capacity of 5 indoor units to the capacity of 3 indoor units. However, this reduction cannot be performed instantaneously and takes some time, so the capacity of the compressor is temporarily reduced. Becomes excessive. At this time, since the refrigerant cannot sufficiently exchange heat in the indoor heat exchanger, the temperature of the indoor heat exchanger may temporarily drop below the first predetermined value.
However, defrosting is not necessary because the compressor operates stably within the first predetermined time by the capacity of the three indoor units and the temperature stabilizes at a temperature exceeding the first predetermined value.

(B) When the air volume of the indoor blower fan in the indoor unit is switchable and the expansion valve is controlled for superheat, when the air volume of the indoor blower fan is switched from a large air volume to a small air volume.

At this time, since the refrigerant on the outlet side of the indoor heat exchanger becomes damp due to the decrease in the air volume, the opening of the expansion valve is throttled, and the low pressure decreases as the opening of the expansion valve is throttled, and the indoor heat exchange is reduced. The temperature of the container may temporarily drop below the first predetermined value. However, when the expansion valve is throttled, the refrigerant changes from wet to overheat, and the expansion valve operates again in the first predetermined time to cause the temperature of the indoor heat exchanger to exceed the first predetermined value. Since the opening degree of the expansion valve is stable at an opening degree corresponding to the change in the air volume and the temperature of the indoor heat exchanger is stable at a temperature exceeding the first predetermined value, defrosting is not necessary.

If the above determination is NO, that is, when it is not frosting, the second
On the basis of the output signal of the temperature sensor (35), whether the indoor heat exchanger (10) of the second indoor unit (Y ') is frosted or not is determined by the same determination criteria as above, and this determination is NO. In this case, in step S3, the switching of the three-way solenoid valve (19) to the suction side is continued, which allows the two indoor units (Y), (Y 'while operating the compressor (1) at full capacity. ), The cooling operation is continued, and the process returns to step S1.

On the other hand, if YES in step S1 in which the indoor heat exchanger (10) of the first indoor unit (Y) is frosted, step S
At 4, the heating and cooling solenoid valves (12), (13) of the first indoor unit (Y) are controlled to be closed to prevent the refrigerant from flowing to the first indoor unit (Y), and then the step In S5, the indoor heat exchanger (1) of the second indoor unit (Y ') is further added.
The presence or absence of frost in (0) is determined according to the same determination criteria as above, and if the indoor heat exchanger (10) of the second indoor unit (Y ') is NO without frost, it is determined in step S6 The solenoid valve (19) is switched to the discharge side to switch the operating state of the compressor (1) from full capacity operation to capacity control operation. As a result, in step S7, the defrosting operation in which the growing frost of the indoor heat exchanger (10) is defrosted by the blowing action of the indoor blower fan (10c) is performed on the first indoor unit (Y). Be told,
The cooling operation continues for the second indoor unit (Y '). Then, in step S8, the temperature Tc of the indoor heat exchanger (10) based on the output signal of the first temperature sensor (35) is equal to or higher than a second predetermined value (for example, 7 ° C.) in which there is no fear of frost formation, and this state is After waiting for the completion of defrosting that continues for the second predetermined time (for example, 10 minutes), the heating and cooling solenoid valves (12) and (13) of the first indoor unit (Y) are controlled to be opened, and then the above step is performed.
In step S3, the three-way solenoid valve (19) is switched to the suction side in step S3 to return the operating state of the compressor (1) to full capacity operation, and the process returns to step S1.

Further, in the case of NO in which the indoor heat exchanger (10) of the first indoor unit (Y) has no frost in the above step S1, and in the step S2, the indoor heat exchanger of the second indoor unit (Y '). (1
If there is frost on (0) YES, follow the same steps as above.
In S9, the flow of the refrigerant to the second indoor unit (Y ') is blocked by controlling the closing of the solenoid valves (12) and (13) for heating and cooling the second indoor unit (Y'), and then step S1
Switch the three-way solenoid valve (19) to the discharge side at 0 to turn the compressor (1)
By changing the operating state of the
In S11, the defrosting operation is performed on the second indoor unit (Y ') and the cooling operation is performed on the first indoor unit (Y). Then, in step S12, after waiting for the defrosting operation of the second indoor unit (Y ') to be completed on the basis of the same criteria as in step S8, the solenoid valves for heating and cooling the second indoor unit (Y'). After controlling (12) and (13) to open,
Returning to step S3, the operating state of the compressor (1) is returned to full capacity operation in step S3, and the process returns to step S1.

Furthermore, in the case of YES when it is determined that the indoor heat exchangers (10) and (10) of both the indoor units (Y) and (Y ') are frosting in the above steps S1 and S5, in step S13. The heating and cooling solenoid valves (12) and (13) of the second indoor unit (Y ') are also controlled to be closed, so that both the first and second indoor units (Y) and (Y') are controlled. After blocking the flow of the refrigerant, the operation of the compressor (1) is stopped in step S14, so that both indoor units (Y),
The defrosting operation is performed on (Y '). Then step
When the defrosting operation of the first indoor unit (Y) is completed before the second indoor unit (Y ') in S16, the heating and cooling solenoid valves (12), (13) incorporated therein After controlling the opening of the indoor unit (Y), the process proceeds to step S10 to start the cooling operation only for the first indoor unit (Y), and conversely, the second indoor unit (Y) before the first indoor unit (Y). When the defrosting operation of Y ′) is completed, the solenoid valves for heating and cooling (12), (1
After controlling 3) to open, the process proceeds to step S6 to start the cooling operation only for the second indoor unit (Y '), and defrost operation for both indoor units (Y), (Y'). Is completed, both indoor units (Y),
After controlling the heating and cooling solenoid valves (12) and (13) of (Y ') to open, the process proceeds to step S3 to start the cooling operation for both indoor units (Y) and (Y'). . Therefore, in the operation flow of FIG. 3, the steps S1, S2,
S4 to S6, S8, S9, S10, S12, S16 receive the output of the temperature sensor (35) of each indoor unit (Y), (Y ') and receive the temperature Tc of any indoor heat exchanger (10). Is below a first predetermined value (for example, -7 ° C.) near the temperature immediately before frost formation, and when the state of being below the first predetermined value continues for a first predetermined time, the temperature of the indoor heat exchanger (10) is the first Blocking the flow of the refrigerant to the corresponding indoor unit (Y or Y ') until the state of the second predetermined value higher than the predetermined value and the second predetermined value or more continues for the second predetermined time, The heating solenoid valve (12) and the cooling solenoid valve (13) are each opened and closed to allow the refrigerant to flow to another indoor unit (Y 'or Y), and the three-way solenoid valve (19) is discharged. By switching to the side, the capacity of the compressor (1) is reduced to half the total capacity corresponding to the capacity of the other indoor unit (Y 'or Y'). Yo constitute a defrosting operation control means for controlling the capacity adjusting means (20) (45). Also, by steps S7 and S11,
An indoor fan control means (46) is configured to control the indoor blower fan (10c) to be driven during the defrosting operation by the defrosting operation control means (45).

Therefore, in the above-described embodiment, as shown in FIG. 4, during the cooling operation of the two chambers by the both indoor units (Y) and (Y ′) in the state where the compressor (1) is operating at full capacity,
For example, the indoor heat exchanger (10) of the first indoor unit (Y)
If the temperature Tc is less than or equal to the first predetermined value (−7 ° C.) and the state of less than or equal to the first predetermined value continues for 10 minutes, it is determined that frost has formed at this point, and the defrosting operation control means (45) determines Solenoid valve (1) for heating and cooling the indoor unit (Y)
2) and (13) are controlled to be closed, which prevents the refrigerant from flowing to the first indoor unit (Y), so that the growing frost of the indoor heat exchanger (10) is blown by the indoor blower fan ( Ten
It is gradually defrosted by the air blowing action of c).

Then, by this defrosting operation, the temperature of the indoor heat exchanger (10)
If Tc rises above the second predetermined value (7 ° C) and remains in this state for 10 minutes, it is determined that defrosting has been completed at this point, and the heating and cooling electromagnetic waves of the first indoor unit (Y) are determined. Since the valves (12) and (13) are controlled to be opened, the defrosting operation for the first indoor unit (Y) ends and the cooling operation restarts. In this case, during the defrosting operation for the first indoor unit (Y), the heating and cooling solenoid valves (12), (13) are in the open state in the second indoor unit (Y ') and the refrigerant is Distribution is allowed and the second
Since the cooling operation in the indoor unit (Y ') of the first indoor unit (Y') is continued, the indoor unit (Y ') of the first indoor unit (Y) that is frosted while ensuring good indoor comfort on the side of the second indoor unit (Y'). The defrosting operation of the indoor heat exchanger (10) can be performed. Moreover, during the defrosting operation, the compressor (1) shifts from the full capacity operation to the capacity control operation, and the capacity of the outdoor unit (X) is the capacity of the second indoor unit (Y ') during the cooling operation. Therefore, frost formation on the indoor heat exchanger (10) of the second indoor unit (Y ') is unlikely to occur.

In the above embodiment, two indoor units (Y),
The present invention is applied to an air conditioner having (Y ′),
Of course, the same can be applied to an air conditioner having three or more indoor units. In this case, the capacity control of the compressor (1) may be performed in a plurality of stages according to the number of installed indoor units.

(Effects of the Invention) As described above, according to the multi-type air conditioner of the present invention, when the indoor heat exchanger (10) of one indoor unit (Y or Y ') is frosted, that indoor unit is frosted. The indoor blower fan (10
The defrosting operation is performed by the blowing action of c), and the capacity of the compressor (1) is reduced to frost the indoor heat exchanger (10) of another indoor unit (Y 'or Y) without frost. It is possible to defrost the frosted indoor heat exchanger (10) while continuing the cooling operation of the other indoor unit (Y ′ or Y) while preventing You can

Moreover, the refrigerant is prevented from flowing when the temperature of the indoor heat exchanger (10) is equal to or lower than the first predetermined value and the state of being equal to or lower than the first predetermined value continues for the first predetermined time. Even if the temperature temporarily becomes equal to or lower than the first predetermined value due to a change in the operating condition due to a sudden load change during the simultaneous cooling operation of the indoor units (Y) and (Y ′)
When this state does not continue for the first predetermined time, that is, when the defrosting operation is not necessary, the defrosting operation is not started, and conversely, the temperature of the indoor heat exchanger (10) is below the first predetermined value due to frost formation. And, the defrosting operation can be started only when the state of being equal to or less than the first predetermined value continues for the first predetermined time, and therefore, comfortable air conditioning can be performed by the amount that the wasteful defrosting operation is not performed, When defrosting is necessary, the defrosting operation can be surely performed. Further, the defrosting operation is completed when the temperature of the indoor heat exchanger (10) is equal to or higher than the second predetermined value which is higher than the first predetermined value and the state of the second predetermined value or more continues for the second predetermined time, The defrosting will not be insufficient, and the defrosting operation will not be continued unnecessarily, and comfortable air conditioning will be possible.

[Brief description of drawings]

FIG. 1 is a block diagram showing the configuration of the present invention. 2 to 4 show an embodiment of the present invention, FIG. 2 is a refrigerant piping system diagram, FIG. 3 is a flow chart diagram showing an operation sequence of a control circuit, and FIG. 4 is an operation explanatory diagram. (X) ... Outdoor unit, (Y), (Y ') ... Indoor unit, (1) ... Compressor, (10) ... Indoor heat exchanger,
(10c) …… Indoor fan, (17) …… Distribution means, (2
0) ... Capacity adjusting means, (35) ... Temperature sensor, (45)
...... Defrosting operation control means, (46) …… Indoor fan control means.

 ─────────────────────────────────────────────────── ─── Continuation of the front page Judgment panel Judge General Masahide Sakai Judge Utaki Megumi Judge Shizuo Takimoto (56) References JP-A-60-193716 (JP, A) JP-A-49-38252 (JP, A) ) JP-A-58-88580 (JP, A)

Claims (1)

[Claims] 1. An indoor unit comprising a plurality of indoor units (Y), (Y ') connected in parallel to one outdoor unit (X) containing a compressor (1) and operated simultaneously. (Y) and (Y ') are the air conditioners having the indoor heat exchanger (10) and the indoor blower fan (10c) built therein, and the flow of the refrigerant to the indoor units (Y) and (Y'). Flow means (17) for allowing and blocking the above, capacity adjusting means (20) for adjusting the capacity of the compressor (1), and indoor heat of the indoor units (Y), (Y ') during cooling operation. Temperature sensor (35) for detecting the temperature of the exchanger (10)
And the output of each of the temperature sensors (35), the temperature of any of the indoor heat exchangers (10) is below a first predetermined value and
The temperature of the indoor heat exchanger (10) is higher than the first predetermined value since the state of being equal to or lower than the predetermined value continues for the first predetermined time.
Until the state of the predetermined value or more and the second predetermined value or more continues for the second predetermined time, the flow of the refrigerant to the corresponding indoor unit (Y or Y ′) is blocked, and the other indoor unit (Y ′). Or, each circulation means (17) is controlled so as to permit the circulation of the refrigerant to the other indoor unit (Y ′).
Alternatively, the defrosting operation control means (45) for controlling the capacity adjusting means (20) so as to reduce the capacity of the compressor (1) so that the capacity corresponds to the total capacity of Y), and the defrosting operation control. During the defrosting operation by means (45), the indoor blower fan (10
Indoor fan control means (46) for controlling to drive c)
An air conditioner comprising: