JP5814784B2 - Air conditioner - Google Patents

Description

  The present invention relates to an air conditioner.

  2. Description of the Related Art Conventionally, an air conditioner installed in a computer room or the like is known in which an air blower is driven by a fan motor via a pulley and a V belt, and the air flow of the air blower is made constant.

  Also, conventionally, the air volume of the blower is changed by the electric power supplied from the control device that controls the air volume (the air volume of the indoor fan is determined according to the difference between the blown air temperature of the air conditioner and the blown air temperature setting value). ) Are disclosed (for example, Patent Document 1).

Japanese Patent Laid-Open No. 10-38350 (summary, FIG. 2)

  In the conventional air conditioner, even when an abnormal state such as a failure of a part of the refrigerant circuit component occurs, the operation is continued by introducing a control method for avoiding various abnormal states. For example, when the temperature detection means for detecting the temperature of a certain part fails, the temperature of the part is predicted based on the temperature detected by the separately provided temperature detection means, and the air conditioner is controlled. Continue driving.

  However, control for avoiding such an abnormality is not performed with respect to the blower and the blower controller. For example, when an abnormality occurs in the blower, the blower is temporarily stopped and then restarted. If the abnormality is not canceled even after the blower is restarted, the fact that it is abnormal is displayed on the display screen or the user is informed that an abnormal state has occurred, and the blower is stopped. For this reason, the stability of the operation of the air conditioner has been low.

  The present invention has been made to solve the above-described problems. Even when an abnormality occurs in the blower or the controller of the blower, the blower or the blower controller is continued so as to continue as much as possible. It aims at controlling and suppressing the fall of stability of operation of an air harmony device.

An air conditioner according to the present invention controls an indoor fan that blows air to an indoor heat exchanger, a fan controller that controls the indoor fan, temperature detection means that detects the temperature of the fan controller, and the indoor fan. An indoor unit controller that transmits a signal to the blower controller, and the indoor unit controller has a frequency of the indoor blower when the temperature detected by the temperature detection means exceeds a predetermined temperature. When it is determined whether the frequency exceeds the first frequency and it is determined that the frequency of the indoor blower exceeds the first frequency, the frequency of the indoor blower is reduced so as not to be equal to or lower than the first frequency. transmits a signal to control so as to the blower controller, the blower controller, der controls the indoor fan on the basis of a signal transmitted from the indoor unit controller .

  The air-conditioning apparatus of the present invention can control the blower or the controller of the blower so as to continue the operation as much as possible even when an abnormality occurs in the blower or the blower controller, and can suppress a decrease in the stability of the operation. .

1 is a structural diagram of an air conditioner according to Embodiment 1 of the present invention. It is a flowchart which shows the control method of the air conditioning apparatus in Embodiment 1 of this invention. It is a structural diagram of the air-conditioning apparatus in Embodiment 2 of the present invention. It is a flowchart which shows the control method of the air conditioning apparatus in Embodiment 2 of this invention. It is a flowchart which shows the control method of the air conditioning apparatus in Embodiment 3 of this invention.

Embodiment 1 FIG.
FIG. 1 is a structural diagram of an air-conditioning apparatus 100 according to Embodiment 1 of the present invention. FIG. 2 shows a control flowchart of the air-conditioning apparatus 100 according to Embodiment 1 of the present invention.

  First, the structure of the air conditioning apparatus 100 in Embodiment 1 will be described with reference to FIG. The air conditioner 100 is provided with an indoor unit 1. The indoor unit 1 is provided with an indoor unit casing 2. In the indoor unit casing 2, an indoor heat exchanger 3, an indoor blower 4, an indoor unit controller 5, a blower controller 6, radiating fins 7, and temperature detection means 8 are provided.

  The indoor unit controller 5 is composed of an arithmetic unit including a general-purpose CPU, a data bus, an input / output port, a nonvolatile memory, a timer, and the like. The indoor unit controller 5 reads data from an operating state detecting means (not shown) (not shown), and transmits a signal for controlling the air volume of the indoor fan 4 to the blower controller 6. The operating state detection means is composed of a temperature detection means for detecting the air temperature and the refrigerant temperature, and a pressure detection means for detecting the refrigerant pressure. The blower controller 6 receives a signal for controlling the air volume of the indoor blower 4 from the indoor unit controller 5 and controls the indoor blower 4 to be driven at a frequency corresponding to the received signal. The heat radiating fins 7 are provided in the blower controller 6. The temperature detecting means 8 is attached directly to the radiating fin 7 or near the upper portion thereof, and detects the temperature value T1 of the blower controller 6.

  Next, the operation of the air conditioner 100 will be described using a flowchart showing a control method of the air conditioner 100 of FIG.

  When an abnormality occurs in the blower controller 6, the temperature of the radiating fin 7 rises, and the temperature of the raised radiating fin 7 is detected by the temperature detection means 8. When the detected temperature value T1 exceeds a threshold value X (for example, X = 100 ° C.) (Yes in step S110), the indoor unit controller 5 temporarily stops the indoor blower 4 and then starts operation again. A signal to be controlled is transmitted to the blower controller 6 (step S120). The blower controller 6 controls the indoor blower 4 based on the signal transmitted from the indoor unit controller 5 (step S120). On the other hand, when the detected temperature value T1 is equal to or lower than the threshold value X (for example, X = 100 ° C.) (No in step S110), the operation of the indoor fan 4 is continued.

  The operation of the indoor blower 4 is temporarily stopped by the blower controller 6, and the operation is started again by the blower controller 6. Thereafter, the temperature value T1 of the blower controller 6 is detected. When the temperature value T1 exceeds a threshold value X (for example, X = 100 ° C.) (Yes in step S130), the indoor unit controller 5 displays that an abnormality has occurred on a remote controller (not shown) ( Step S140). Then, the indoor unit controller 5 transmits a signal for controlling the operating frequency of the indoor blower 4 to be lowered, for example, 2 Hz (corresponding to the first value in the present invention) to the blower controller 6. The blower controller 6 controls the indoor blower 4 based on the signal transmitted from the indoor unit controller 5 (step S150). On the other hand, when the temperature value T1 detected after the operation is started again is equal to or less than the threshold value X (for example, X = 100 ° C.) (No in step S130), the operation of the indoor blower 4 is continued.

  Even if the operating frequency of the indoor fan 4 is lowered in step S150, if the temperature value T1 still exceeds X ° C. (Yes in step S160), the operation of the air conditioner 100 is abnormally stopped. On the other hand, when the temperature value T1 becomes X ° C. or less (No in step S160), the operation of the indoor fan 4 is continued.

  In addition, in this Embodiment 1, it demonstrates that it was set as the structure which lowers an operating frequency by 2 Hz. This is because if the air volume of the indoor blower 4 is excessively reduced, the evaporation temperature is reduced and condensation occurs in the indoor unit casing 2, so that the reduction of the air volume is only allowed up to 5%. In the general-purpose induction motor, the rotational speed of the indoor blower 4 is reduced by about 40 to 60 rpm by lowering the operating frequency by 2 Hz. Here, since the rotation speed of the standard indoor blower 4 is about 1000 rpm, if the rotation speed of the indoor blower 4 is reduced by about 40 to 60 rpm, the air volume is reduced by 5%.

  As described above, according to the air conditioner 100 according to Embodiment 1 of the present invention, when an abnormality occurs in the indoor fan 4, the current flowing through the fan controller 6 is reduced by reducing the operating frequency of the indoor fan 4. And the temperature of the blower controller 6 is lowered. Thereby, even if abnormality occurs in the blower controller 6, the cooling operation can be continued without immediately stopping the air conditioner 100 abnormally.

  Moreover, according to the air conditioning apparatus 100 according to Embodiment 1, if the temperature value T1 exceeds the threshold value X even if the operating frequency of the indoor blower 4 is decreased, the air conditioning apparatus 100 is abnormally stopped. It is configured. Thereby, it is also possible to protect the blower controller 6.

  In the first embodiment, the operation frequency of the indoor blower 4 is lowered by 2 Hz. However, the numerical value of the operation frequency of the indoor blower 4 to be lowered is not limited to this. Depending on the configuration of the air conditioner 100, dew condensation may not occur even if the air volume of the indoor blower 4 is reduced by 10%. Therefore, the operating frequency of the indoor fan 4 may be lowered as long as no condensation occurs (for example, the operating frequency of the indoor fan 4 is lowered by 4 Hz).

  In the first embodiment, the threshold value X is set to 100 ° C., but is not limited to this. Since the threshold temperature varies depending on the position where the temperature detection means 8 is attached, the threshold X may be set to a temperature other than 100 ° C. as long as the inverter can protect the inverter of the indoor blower 4. For example, when the temperature detection means 8 is attached in the vicinity of the upper portion of the radiating fin 7, it is assumed that a lower temperature is detected than when the temperature detection means 8 is directly attached to the radiating fin 7. Therefore, the threshold value X may be set to a temperature lower than 100 ° C. (for example, the threshold value X is set to 95 ° C.).

Moreover, in this Embodiment 1, the indoor unit controller 5 transmits the signal which controls the indoor air blower 4 produced | generated based on the value detected by the temperature detection means 8 to the air blower controller 6, and an air blower controller Although 6 was set as the structure which controls the indoor air blower 4 based on the signal transmitted from the indoor unit controller 5, it is not limited to this.
For example, a temperature detection means for detecting the temperature of the indoor blower 4 is provided, and the indoor unit controller 5 sends a signal for controlling the indoor blower 4 generated based on the value detected by the temperature detection means to the blower controller 6. The blower controller 6 may control the indoor blower 4 based on the signal transmitted from the indoor unit controller 5. At this time, when the temperature value T2 detected by the temperature detecting means exceeds a threshold value Y (for example, Y = 130 ° C.), the indoor unit controller 5 displays on the remote controller that an abnormality has occurred. When the temperature value T2 exceeds a threshold value Y (for example, Y = 130 ° C.), the indoor unit controller 5 transmits a signal for controlling the frequency of the indoor blower 4 to the blower controller 6.
Moreover, the current value detection means for detecting the current value of the indoor blower 4 is provided, and the indoor unit controller 5 sends a signal for controlling the indoor blower 4 generated based on the value detected by the current value detection means. It is good also as a structure which transmits to the controller 6 and the air blower controller 6 controls the indoor air blower 4 based on the signal transmitted from the indoor unit controller 5. FIG. At this time, if the current value I1 detected by the current value detection means exceeds a threshold value Z (for example, Z = 20A), the indoor unit controller 5 displays on the remote controller that an abnormality has occurred. Moreover, if the electric current value I1 exceeds the threshold value Z (for example, Z = 20A), the indoor unit controller 5 transmits a signal for controlling the frequency of the indoor blower 4 to the blower controller 6.

  Moreover, in this Embodiment 1, you may comprise the air blower controller 6 using a silicon carbide element. In this way, since the threshold value X can be set higher than 100 ° C. (for example, X = 200 ° C.), it is possible to further suppress a decrease in the stability of the blower controller 6.

Embodiment 2. FIG.
FIG. 3 shows a structural diagram of the air-conditioning apparatus 100 according to Embodiment 2 of the present invention. FIG. 4 shows a flowchart of a method for controlling the air-conditioning apparatus 100 according to Embodiment 2 of the present invention.
In the second embodiment, differences from the first embodiment will be mainly described, and the same parts as those in the first embodiment will be denoted by the same reference numerals and description thereof will be omitted.

  First, the structure of the air conditioning apparatus 100 in Embodiment 2 will be described with reference to FIG. The air conditioner 100 is provided with an outdoor unit 10. The outdoor unit 10 is provided with an outdoor unit casing 11. In the outdoor unit casing 11, an outdoor heat exchanger 12, a compressor 13, an outdoor unit controller 14, a compressor controller 15, and an outdoor fan 16 are provided. The outdoor unit controller 14 is composed of an arithmetic unit including a general-purpose CPU, a data bus, an input / output port, a nonvolatile memory, a timer, and the like. The outdoor unit controller 14 performs predetermined control on the compressor 13 by reading data from an operating state detection unit (not shown) and transmitting a compressor frequency command to the compressor controller 15. The indoor unit controller 5 and the outdoor unit controller 14 are connected by a control line 17 and transmit and receive detection values and operation commands by various detection means. The indoor heat exchanger 3, the expansion valve 9, the outdoor heat exchanger 12, and the compressor 13 are connected by a refrigerant pipe 18 to form a refrigerant circuit.

  Next, the operation of the air conditioner 100 will be described using a flowchart showing a control method of the air conditioner 100 of FIG.

  When an abnormality occurs in the blower controller 6, the temperature of the radiating fin 7 rises, and the temperature of the raised radiating fin 7 is detected by the temperature detection means 8. If the detected temperature value T1 exceeds a threshold value X (for example, X = 100 ° C.) (Yes in step S210), the indoor unit controller 5 temporarily stops the indoor blower 4 and then starts operation again. A signal to be controlled is transmitted to the blower controller 6 (step S220). The blower controller 6 controls the indoor blower 4 based on the signal transmitted from the indoor unit controller 5 (step S220). On the other hand, when the detected temperature value T1 is equal to or lower than the threshold value X (for example, X = 100 ° C.) (No in step S210), the operation of the indoor fan 4 is continued.

  The operation of the indoor blower 4 is temporarily stopped by the blower controller 6, and the operation is started again by the blower controller 6. Thereafter, the temperature value T1 of the blower controller 6 is detected. When the temperature value T1 exceeds a threshold value X (for example, X = 100 ° C.) (Yes in step S230), the indoor unit controller 5 displays that an abnormality has occurred on a remote controller (not shown) ( Step S240). Then, the indoor unit controller 5 transmits a signal for controlling the operating frequency of the indoor blower 4 to be lowered, for example, 5 Hz (corresponding to the second value in the present invention) to the blower controller 6. The blower controller 6 controls the indoor blower 4 based on the signal transmitted from the indoor unit controller 5 (step S250). On the other hand, when the temperature value T1 detected after the operation is started again is equal to or less than the threshold value X (for example, X = 100 ° C.) (No in step S230), the operation of the indoor fan 4 is continued.

When a signal for controlling the operating frequency of the indoor blower 4 to be lowered by 5 Hz is transmitted from the indoor unit controller 5 to the blower controller 6, a signal indicating that protection control has been started is also sent to the indoor unit controller. 5 to the outdoor unit controller 14.
The outdoor unit controller 14 transmits a signal for controlling the operation frequency of the compressor 13 to be lowered by a predetermined value (for example, “current operation frequency × 0.2” Hz), to the compressor controller 15. The compressor controller 15 controls the compressor 13 based on the signal transmitted from the outdoor unit controller 14 (step S260).

  Even if the operating frequency of the indoor blower 4 and the compressor 13 is lowered in steps S250 and S260, if the temperature value T1 exceeds X ° C. (Yes in step S270), the air conditioner 100 is abnormally stopped. . On the other hand, when the temperature value T1 becomes X ° C. or less (No in step S270), the operation of the indoor blower 4 is continued.

In the second embodiment, a description will be given of a configuration in which the frequency of the indoor blower 4 is lowered by 5 Hz and the operation frequency of the compressor 13 is lowered by “current operation frequency × 0.2 Hz”.
In the air conditioner 100, a general-purpose induction motor is often used as a blower, but by changing the operating frequency by 5 Hz, the rotational speed of the indoor blower 4 is reduced by about 100 to 150 rpm. Here, since the rotation speed of a standard blower is about 1000 rpm, when the rotation speed of the indoor blower 4 is reduced by about 100 to 150 rpm, the air volume is reduced by 10 to 15%.

  When the air volume of the indoor blower 4 is reduced by 10 to 15%, the evaporation temperature is lowered, and there is a concern about dew condensation in the indoor unit casing 2, so it is necessary to lower the operating frequency of the compressor 13 together. When the air volume of the indoor blower 4 is reduced by 10 to 15%, in order not to generate dew condensation, the operating frequency of the compressor 13 may be reduced by about 20%, so that the “current operating frequency × 0.2 Hz” is reduced. did.

  As described above, according to the air conditioner 100 according to Embodiment 2 of the present invention, when an abnormality occurs in the blower controller 6, in addition to reducing the operating frequency of the indoor blower 4, the compressor 13 The operation frequency is reduced. Thereby, since the permissible range of the air volume that can be lowered by the indoor blower 4 can be increased as compared with the first embodiment, the frequency of the indoor blower 4 can be further lowered, and the air conditioner 100 is abnormally stopped. The possibility of becoming can be further reduced.

  Further, according to the air conditioner 100 according to the second embodiment, as in the first embodiment, when an abnormality occurs in the blower controller 6, the blower controller is reduced by reducing the operating frequency of the indoor blower 4. The electric current which flows into 6 is reduced, and the temperature of the air blower controller 6 is reduced. Thereby, even if abnormality occurs in the blower controller 6, the cooling operation can be continued without immediately stopping the air conditioner 100 abnormally.

In the second embodiment, as in the first embodiment, temperature detecting means for detecting the temperature of the indoor blower 4 may be provided. At this time, the indoor unit controller 5 transmits a signal for controlling the indoor blower 4 generated based on the value detected by the temperature detecting means to the blower controller 6. The blower controller 6 controls the indoor blower 4 based on the signal transmitted from the indoor unit controller 5.
Also in the second embodiment, a current value detecting means for detecting the current value of the indoor blower 4 may be provided as in the first embodiment. At this time, the indoor unit controller 5 transmits to the blower controller 6 a signal for controlling the indoor blower 4 generated based on the value detected by the current value detecting means. The blower controller 6 controls the indoor blower 4 based on the signal transmitted from the indoor unit controller 5.

Embodiment 3 FIG.
The third embodiment shows a form of protection control different from the first and second embodiments.
In the first and second embodiments, it is assumed that the cooling operation is continued even if an abnormality occurs in the blower controller 6, and when the cooling operation cannot be continued, the air conditioner 100 is abnormally stopped. . However, depending on the use of the air conditioning apparatus 100, it may be better to continue the air blowing operation than to abnormally stop the air conditioning apparatus 100 when the cooling operation cannot be continued. The third embodiment shows an example thereof. In addition, since the structure of the air conditioning apparatus 100 in this Embodiment 3 is the same as the structure (FIG. 3) of the air conditioning apparatus 100 in Embodiment 2, description of a structure is omitted.

  The operation of the air conditioner 100 will be described with reference to a flowchart showing a control method of the air conditioner 100 of FIG.

  When an abnormality occurs in the blower controller 6, the temperature of the radiating fin 7 rises, and the temperature of the raised radiating fin 7 is detected by the temperature detection means 8. If the detected temperature value T1 exceeds a threshold value X (for example, X = 100 ° C.) (Yes in step S310), the indoor unit controller 5 temporarily stops the indoor blower 4 and then starts operation again. A signal to be controlled is transmitted to the blower controller 6 (step S320). The blower controller 6 controls the indoor blower 4 based on the signal transmitted from the indoor unit controller 5 (step S320). On the other hand, when the detected temperature value T1 is equal to or less than the threshold value X (for example, X = 100 ° C.) (No in step S310), the operation of the indoor fan 4 is continued.

  The operation of the indoor blower 4 is temporarily stopped by the blower controller 6, and the operation is started again by the blower controller 6. Thereafter, the temperature value T1 of the blower controller 6 is detected. When the temperature value T1 exceeds a threshold value X (for example, X = 100 ° C.) (Yes in Step S330), the indoor unit controller 5 displays on the remote controller that an abnormality has occurred (Step S340). Then, it is determined whether the frequency of the indoor blower 4 exceeds the lowest frequency (corresponding to the first frequency in the present invention) (step S350).

  If it is determined that the frequency of the indoor blower 4 is higher than the minimum frequency (Yes in step S350), the indoor unit controller 5 controls to lower the operating frequency of the indoor blower 4 (for example, lower by 10 Hz). A signal to be transmitted is transmitted to the blower controller 6. The blower controller 6 controls the indoor blower 4 based on the signal transmitted from the indoor unit controller 5 (step S360).

  When a signal for controlling the operation frequency of the indoor blower 4 to be lowered is transmitted from the indoor unit controller 5 to the blower controller 6, a signal indicating that protection control has started is sent from the indoor unit controller 5 to the outdoor unit. It is transmitted to the controller 14. When it is determined that the operation frequency of the compressor 13 exceeds the lowest frequency (corresponding to the second frequency in the present invention) (Yes in step S380), the outdoor unit controller 14 A signal for controlling the operation frequency to be lowered by a predetermined value (for example, “current operation frequency × 0.2 Hz” is lowered) is transmitted to the compressor controller 15. The compressor controller 15 controls the compressor 13 based on the signal transmitted from the outdoor unit controller 14 (step S390).

  If the temperature value T1 exceeds X ° C. with the operating frequencies of the indoor blower 4 and the compressor 13 lowered (Yes in step S410), it is determined again whether the frequency of the indoor blower 4 exceeds the minimum frequency. (Step S350). If it is determined that the frequency of the indoor blower 4 exceeds the minimum frequency (Yes in step S350), the indoor unit controller 5 further reduces the operating frequency of the indoor blower 4 (for example, lowers by 10 Hz). A signal to be controlled is transmitted to the blower controller 6. The blower controller 6 controls the indoor blower 4 based on the signal transmitted from the indoor unit controller 5 (step S360). On the other hand, when the temperature value T1 does not exceed X ° C., the operation of the indoor fan 4 is continued (No in step S410).

  When step S360 is executed, it is determined again whether or not the frequency of the compressor 13 exceeds the minimum frequency (step S380). When it is determined that the frequency of the compressor 13 is higher than the minimum frequency (Yes in step S380), the outdoor unit controller 14 further reduces the operating frequency of the compressor 13 (“current operating frequency × 0 .2 Hz “further lower”) is transmitted to the compressor controller 15. The compressor controller 15 controls the compressor 13 based on the signal transmitted from the outdoor unit controller 14 (step S390).

  When the operating frequency of the compressor 13 is lower than the minimum frequency (No in step S380), the compressor 13 is stopped (step S400), and the operation mode of the indoor blower 4 is changed to the minimum frequency by switching to the blowing operation. Will be reduced. Even if the operating frequency of the indoor blower 4 reaches the lowest frequency, if the temperature value T1 exceeds X ° C. (No in step S350), the air conditioner 100 is abnormally stopped (step S370).

  As described above, according to the air-conditioning apparatus 100 according to Embodiment 3 of the present invention, the cooling operation is continued as much as possible by lowering the operation frequency of the indoor blower 4 stepwise to the lowest frequency. When it is impossible to continue the cooling operation, it is possible to shift to the air blowing operation, so that the possibility that the air conditioner 100 is abnormally stopped can be reduced.

  Further, according to the third embodiment, as in the first and second embodiments, when an abnormality occurs in the blower controller 6, the current flowing through the blower controller 6 is reduced by reducing the operating frequency of the indoor blower 4. And the temperature of the blower controller 6 is lowered. Thereby, even if abnormality occurs in the blower controller 6, the cooling operation can be continued without immediately stopping the air conditioner 100 abnormally.

In the third embodiment, temperature detecting means for detecting the temperature of the indoor blower 4 may be provided as in the first and second embodiments. At this time, the indoor unit controller 5 transmits a signal for controlling the indoor blower 4 to the blower controller 6 based on the value detected by the temperature detection means. The blower controller 6 controls the indoor blower 4 based on the signal transmitted from the indoor unit controller 5.
Also in the third embodiment, a current value detecting means for detecting the current value of the indoor blower 4 may be provided as in the first and second embodiments. At this time, the indoor unit controller 5 transmits a signal for controlling the indoor blower 4 to the blower controller 6 based on the value detected by the current value detecting means. The blower controller 6 controls the indoor blower 4 based on the signal transmitted from the indoor unit controller 5.

  DESCRIPTION OF SYMBOLS 1 Indoor unit, 2 Indoor unit casing, 3 Indoor heat exchanger, 4 Indoor fan, 5 Indoor unit controller, 6 Blower controller, 7 Radiation fin, 8 Temperature detection means, 9 Expansion valve, 10 Outdoor unit, 11 Outdoor unit Casing, 12 outdoor heat exchanger, 13 compressor, 14 outdoor unit controller, 15 compressor controller, 16 outdoor fan, 17 control line, 18 refrigerant pipe, 100 air conditioner, I1, I2, I3 current value, T1 , T2, T3 Temperature values, X, Y, Z thresholds.

Claims (4)

An indoor fan for blowing air to the indoor heat exchanger;
A blower controller for controlling the indoor blower;
Temperature detecting means for detecting the temperature of the blower controller;
An indoor unit controller that transmits a signal for controlling the indoor blower to the blower controller;
The indoor unit controller is
When the temperature detected by the temperature detection means exceeds a predetermined temperature, it is determined whether the frequency of the indoor blower exceeds a first frequency, and the frequency of the indoor blower exceeds the first frequency. When it is determined that the frequency exceeds the first blower controller, a signal for controlling the indoor blower so as not to be lower than the first frequency is transmitted to the blower controller.
The blower controller is
The air conditioner characterized in that the indoor blower is controlled based on a signal transmitted from the indoor unit controller. A compressor,
A compressor controller for controlling the compressor;
An outdoor unit controller that transmits a signal for controlling the compressor to the compressor controller;
The indoor unit controller is
When the temperature detected by the temperature detection means exceeds the predetermined temperature, a command to lower the frequency of the compressor is transmitted to the outdoor unit controller,
The outdoor unit controller is
Upon receiving a command transmitted from the indoor unit controller, a signal for controlling the frequency of the compressor to be decreased by a second value is transmitted to the compressor controller.
The compressor controller is
The air conditioner according to claim 1, wherein the compressor is controlled based on a signal transmitted from the outdoor unit controller. Before outdoor unit controller,
When receiving a command transmitted from the indoor unit controller, it is determined whether the frequency of the compressor is higher than a second frequency, and it is determined that the frequency of the compressor is higher than the second frequency. If so, a signal for controlling the frequency of the compressor so as not to be lower than the second frequency is transmitted to the compressor controller,
The determination by the indoor unit controller is repeated until the temperature detected by the temperature detecting means becomes equal to or lower than the predetermined temperature,
The air conditioner according to claim 2, wherein when the frequency of the indoor fan becomes equal to or lower than the first frequency, the operation of the indoor fan is stopped. The blower controller is composed of a silicon carbide element,
The said predetermined temperature was set to 200 degreeC. The air conditioning apparatus as described in any one of Claims 1-3 characterized by the above-mentioned.

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