JP6765174B2 - Air conditioner and control method of air conditioner - Google Patents

Description

The present invention relates to an air conditioner or the like operated by electric power supplied from an AC power source or a DC power source.

Air conditioners that regulate indoor air temperature, humidity, air cleanliness, etc. have been widely used in the past. Further, in recent years, an air conditioner capable of using both the electric power supplied from a storage battery (DC power source) and the electric power supplied from a commercial power source (AC power source) has been developed (for example, Patent Document 1 below). .. Specifically, Patent Document 1 describes that the storage battery is charged from the commercial power supply line when the voltage of the storage battery drops.

Japanese Unexamined Patent Publication No. 2000-217271 (published on August 4, 2000)

However, with the above-mentioned conventional techniques, it may not be possible to avoid the occurrence of problems that may occur when using a DC power supply. That is, when using a DC power source such as a storage battery, various problems may occur in addition to the decrease in the amount of stored power, but the above-mentioned conventional technology that continues to use the storage battery even after the voltage drop avoids these problems. Can not do it.

For example, the storage battery, the connection part between the storage battery and the air conditioner, the circuit in the air conditioner, etc. may have problems such as poor contact or disconnection. In the above-mentioned prior art, the air conditioner is operated when such a failure occurs. It will not be able to operate. Further, depending on the circuit configuration of the air conditioner, the power supply from the storage battery to the outdoor unit may continue even after the operation of the air conditioner is stopped, and unnecessary standby power may be consumed.

The present invention has been made in view of the above problems, and an object of the present invention is to realize an air conditioner or the like that can avoid the occurrence of problems that may occur by continuing to use the DC power supply. It is in.

In order to solve the above problems, the air conditioner according to the present invention is an air conditioner that operates by electric power supplied from a storage battery capable of storing electric power generated by an AC power source or a solar battery. It was detected that an abnormality occurred in which the voltage supplied from the storage battery was less than a predetermined threshold when the power supply source was the storage battery and the switching unit that switches the supply source between the AC power supply and the storage battery . In this case, a control unit that controls the switching unit to switch the power supply source to the AC power source and a power selling start detection circuit for detecting the start of selling the power generated by the solar battery are provided. The air conditioner includes an indoor unit and an outdoor unit, and the control unit controls the switching unit when the start of power sale is detected based on the output from the power sale start detection circuit. The electric power supply source to the outdoor unit is switched to an AC power source whose selling price is higher than that when the storage battery is used.
Is equipped with.

Then, in the control method of the air conditioner according to the present invention, in order to solve the above problems, the air conditioner operates by the electric power supplied from the storage battery capable of storing the electric power generated by the AC power source or the solar cell. The air conditioner has an indoor unit and an outdoor unit, and has a detection step of detecting that an abnormality has occurred in which the voltage supplied from the storage battery is less than a predetermined threshold value . It was detected that the above-mentioned abnormality occurred in the above-mentioned detection step when the power supply source was the storage battery and the power- selling start detection step for detecting the start of selling the electric power generated by the solar cell. In the case, and when the power supply source is the storage battery and the power sale start is detected based on the output from the power sale start detection step , the power supply source to the outdoor unit is the storage battery. It is characterized by including a switching step of switching to an AC power source, which has a higher selling price than when it is used .

According to each of the above aspects of the present invention, it is possible to avoid the occurrence of problems that may occur by continuing to use the DC power supply.

It is a figure which shows an example of the main part structure of the air conditioner which concerns on Embodiment 1 of this invention. It is a figure which shows the DC power supply SW provided in the said air conditioner, and a modification thereof. It is a figure which shows an example of switching of the power-source used by the outdoor unit microcomputer provided in the said air conditioner. It is a flowchart which shows an example of the switching process which switches a power-source to use from a DC power source to an AC power source when a DC undervoltage error occurs. It is a flowchart which shows an example of the switching process which switches a power-source to use from DC power source to AC power source when a DC undervoltage error occurs after boosting. It is a flowchart which shows an example of the switching process which switches a power source of use from DC power source to AC power source when a terminal temperature rise error occurs. It is a flowchart which shows an example of the switching process which switches a power supply to use from DC power supply to AC power supply when an arbitrary error occurs. It is a flowchart which shows an example of the switching process which switches the power supply used from DC power supply to AC power supply at the time of operation stop. It is a block diagram which shows the outline of the system which switches the power supply source from DC power source to AC power source at the start of power sale which concerns on Embodiment 2 of this invention. It is a figure which shows the main part composition of the outdoor unit and the power conditioner included in the said system. It is a flowchart which shows an example of the switching process which switches a power-source to use from DC power source to AC power source at the time of power sale start detection. It is a figure which shows the example of the power sale start detection circuit which detects the start of power sale using a DC voltage abnormality detection circuit. It is a figure which shows the example of the power sale start detection circuit which provided the structure for suppressing the noise of the transmitted signal.

[Embodiment 1]
Hereinafter, embodiments of the present invention will be described in detail with reference to FIGS. 1 to 8.

[Construction of air conditioner]
The configuration of the air conditioner 1 according to the present embodiment will be described with reference to FIG. FIG. 1 is a diagram showing an example of a main configuration of the air conditioner 1. The configuration (for example, heat exchanger, etc.) that is not related to the feature points of the present invention is not shown as appropriate. The air conditioner 1 is a device that regulates (air-conditions) the air temperature in an air-conditioned space (for example, indoors).

As shown in the figure, the air conditioner 1 includes an indoor unit 10 and an outdoor unit 20. An AC power source 60 is connected to the indoor unit 10, and both a DC power source (DC power source) 50 and an AC power source (AC power source) 60 are connected to the outdoor unit 20. The AC power source 60 is a commercial power source, and the DC power source 50 is a storage battery (secondary battery). The DC power source 50 is connected to a solar cell (not shown), and can store the electric power generated by the solar cell and supply it to the outdoor unit 20.

The indoor unit 10 includes an AC power supply SW11. The AC power supply SW 11 is a switch (relay switch) that switches between a state (ON) in which the power from the AC power supply 60 is supplied to each part of the indoor unit 10 and the outdoor unit 20 and a state (OFF) in which the supply is stopped. In the indoor unit 10, as long as it is connected to the AC power supply 60, the indoor unit microcomputer (not shown) is operating, and a signal from a remote controller (not shown) can be received. The AC power supply SW11 is controlled by the indoor unit microcomputer.

For example, when an operation start instruction is transmitted to the air conditioner 1 by a remote controller (not shown) or the like, the AC power supply SW11 is switched from OFF to ON. As a result, the voltage from the AC power supply 60 is supplied to the outdoor unit 20.

The outdoor unit 20 includes a DC power supply SW21, an AC power supply SW22, a filter circuit 23, a DC voltage abnormality detection circuit (voltage abnormality detection circuit) 24, a diode 25, an ADCC switching SW (switching unit) 26, a converter (boost circuit) 27, and a converter. It includes an abnormality detection circuit (voltage abnormality detection circuit after boosting) 28, an inverter 29, a motor 30, a power supply circuit 31, an outdoor unit microcomputer (control unit) 32, a DC terminal plate temperature fuse 33, and a rectifier circuit 34.

The DC power supply SW 21 is a switch (relay switch) that switches between a state (ON) in which the power from the DC power supply 50 is supplied to each part of the indoor unit 10 and the outdoor unit 20 and a state (OFF) in which the supply is stopped. In the illustrated example, one DC power supply SW21 is provided on the positive electrode side of the DC power supply 50, but it may also be provided on the negative electrode side. This will be described with reference to FIG. FIG. 2 is a diagram showing a DC power supply SW21 and a modified example thereof. The DC power supply SW21 shown in FIG. 1A has the same configuration as the example of FIG. On the other hand, the DC power supply SW21a shown in FIG. 6B is different from the DC power supply SW21 in that switches are provided on both the positive electrode side and the negative electrode side. By providing the two switches in this way, the safety can be improved as compared with the case of one. For example, when the ACDC switching SW26 is welded, the circuit on the DC power supply 50 side can be reliably insulated to avoid problems such as the AC power supply 60 and the DC power supply 50 being energized.

The AC power supply SW22 is a switch (relay switch) for switching between a state (ON) in which the power from the AC power supply 60 is supplied to each part of the indoor unit 10 and the outdoor unit 20 and a state in which the supply is stopped (OFF).

The filter circuit 23 is a circuit that allows a current having a frequency within a predetermined range to pass through the current from the DC power supply 50 and blocks a current having another frequency.

The DC voltage abnormality detection circuit 24 is a circuit for detecting that an abnormality has occurred in the voltage value supplied by the DC power supply 50. More specifically, the DC voltage abnormality detection circuit 24 consists of two resistors (resistors 241 and 242) connected in parallel with the DC power supply 50 and wiring (connected in series) that outputs a reference voltage to the outdoor unit microcomputer 32. It is a circuit including (connected between resistors 241 and 242). From the DC voltage abnormality detection circuit 24, a reference voltage corresponding to the voltage supplied by the DC power supply 50 and the voltage dividing resistance ratio between the resistors 241 and 242 is output to the outdoor unit microcomputer 32. The resistor 241 may be, for example, 780 KΩ, and the resistor 242 may be, for example, 37.5 KΩ. In this case, in the outdoor unit microcomputer 32, the output voltage value from the DC voltage abnormality detection circuit 24 is less than a predetermined threshold value (for example, 3.75 V: corresponding to the case where the supply voltage of the DC power supply 50 is about 80 V). Occasionally, it may be determined that a DC undervoltage error has occurred.

The diode 25 is for preventing backflow of current, and is arranged on the positive electrode side of the DC power supply 50. By arranging the diode 25, even if the positive electrode and the negative electrode of the DC power supply 50 are mistakenly connected in reverse, the current does not flow back in the outdoor unit 20. Further, in this case, the output from the DC voltage abnormality detection circuit 24 becomes 0V, and the outdoor unit microcomputer 32 determines that a DC undervoltage error has occurred. Details will be described later, but when a DC undervoltage error occurs, the power supply source is switched to the AC power supply 60, so even if the positive and negative electrodes of the DC power supply 50 are accidentally connected in reverse. The air conditioner 1 can be operated by the AC power supply 60.

The ACDC switching SW26 is a switch (relay switch) that switches between a state (ON) in which power from the AC power source 60 is supplied to each part of the indoor unit 10 and the outdoor unit 20 and a state (OFF) in which the supply is stopped.

The converter 27 is a booster circuit, and the converter abnormality detection circuit 28 is a circuit for detecting that an abnormality has occurred in the voltage value after boosting by the converter 27. The converter abnormality detection circuit 28 is located between two resistors (resistors 282 and 283) connected in parallel with the converter 27 and wiring (resistors 282 and 283 connected in series) that output a reference voltage to the outdoor unit microcomputer 32. It is a circuit including (connected to). Also included is a capacitor 281 connected in parallel with these resistors 282 and 283. The converter abnormality detection circuit 28 uses the same principle as the DC voltage abnormality detection circuit 24 to obtain a reference voltage according to the voltage after boosting by the converter 27 and the voltage dividing resistance ratio between the resistors 282 and 283. Output to. The outdoor unit microcomputer 32 compares this reference voltage with a predetermined threshold value, and detects that the reference voltage is less than the threshold value, that is, a DC undervoltage error after boosting. For example, this error is detected when the converter 27 malfunctions.

The inverter 29 changes the rotation speed of the motor 30 by converting the direct current into an alternating current and changing the frequency of the alternating current. Further, the motor 30 is for operating a compressor (not shown).

The power supply circuit 31 is a circuit that supplies electric power to the outdoor unit microcomputer 32, and the outdoor unit microcomputer 32 controls each part of the outdoor unit 20 by receiving the electric power supply from the power supply circuit 31. Specifically, when the outdoor unit microcomputer 32 detects that a predetermined event has occurred while the power supply source is the DC power supply 50, the outdoor unit microcomputer 32 controls the ACDC switching SW26 to use the power supply source as the AC power supply. Switch to. Although the details will be described later, the above-mentioned predetermined events are that an abnormality has occurred in the air conditioner 1 and that the air conditioner 1 is stopped. The outdoor unit microcomputer 32 may be realized by a logic circuit (hardware) formed in an integrated circuit (IC chip) or the like, or may be realized by software using a CPU (Central Processing Unit).

The DC terminal plate thermal fuse 33 is a fuse for detecting a temperature abnormality at the connection portion of the DC power supply 50 to the air conditioner 1, and is disconnected when an excessive current flows through the DC terminal plate (not shown). The DC terminal plate temperature fuse 33 is connected to the outdoor unit microcomputer 32 by wiring, and when the DC terminal plate temperature fuse 33 is disconnected, a signal indicating that fact (DC terminal plate temperature fuse disconnection signal) is transmitted via the above wiring. It is output to the outdoor unit microcomputer 32. Then, the outdoor unit microcomputer 32 that has received this signal detects that a terminal temperature rise error has occurred. That is, the DC terminal plate temperature fuse 33 and the above wiring function as a temperature abnormality detection circuit for detecting a temperature abnormality at the connection portion of the DC power source 50 to the air conditioner 1.

The rectifier circuit 34 is a circuit in which an alternating current is a direct current. When the AC power supply SW11 of the indoor unit 10 is ON, the voltage from the AC power supply 60 is applied to the rectifier circuit 34, and the rectifier circuit 34 outputs a direct current to the ACDC switching SW26.

[Switching power supply used]
The switching of the power supply used by the outdoor unit microcomputer 32 will be described with reference to FIG. FIG. 3 is a diagram showing an example of switching the power supply used by the outdoor unit microcomputer 32.

FIG. (A) in the figure shows an example of switching from the AC power supply 60 (AC) to the DC power supply 50 (DC). The opportunity for the outdoor unit microcomputer 32 to switch from the AC power supply 60 (AC) to the DC power supply 50 (DC) is not particularly limited. For example, during a period of high power consumption (high load) such as the period from the start of air conditioning until the room temperature becomes close to the set temperature, the AC power supply 60 with stable output is used, and the room temperature becomes close to the set temperature. You may switch to the DC power source 50 when the power consumption becomes low (the load is low).

In the switching example of (a) in the figure, the outdoor unit microcomputer 32 first switches the AC power supply SW22 from ON to OFF, then switches the ACDC switching SW26 from AC to DC, and then switches the DC power supply SW21 from OFF to ON. Switch to.

On the other hand, (b) in the figure shows an example of switching from DC to AC. Although the details will be described later, the outdoor unit microcomputer 32 switches from DC to AC according to the operating load, when it detects that an abnormality has occurred in the air conditioner 1, and puts the air conditioner 1 in the stopped operation state. It switches from DC to AC when it detects that.

In the switching example of (b) in the figure, the outdoor unit microcomputer 32 first switches the DC power supply SW21 from ON to OFF, then switches the ACDC switching SW26 from DC to AC, and then switches the AC power supply SW22 from OFF to ON. Switch to. For example, when the amount of electricity stored in the DC power supply 50 decreases, the supply voltage to the outdoor unit microcomputer 32 also decreases. Therefore, the above series of switching is performed before the outdoor unit microcomputer 32 becomes inoperable ( It is desirable to do it immediately (while the voltage is supplied to the extent that it can be operated).

[Necessity of switching]
When the power of the air conditioner 1 is not supplied to the outdoor unit 20 while the power is off (during non-operation) and it becomes necessary to operate the outdoor unit 20 by turning on the power (start of operation), the air conditioner 1 is used. The indoor unit 10 turns on the AC power supply SW11. As a result, electric power is supplied to the outdoor unit control microcomputer (not shown), and electric power is also supplied to the outdoor unit 20. After that, the outdoor unit microcomputer 32, which has become operable by supplying electric power from the indoor unit 10, turns on the AC power supply SW22, whereby the control of the outdoor unit 20 is started.

Here, when an abnormality occurs in the air conditioner 1 and the operation is stopped, the AC power supply SW11 controlled by the indoor unit 10 is continuously turned on, and only the outdoor unit 20 is restarted after being stopped for a certain period of time. By doing so, it can be made operational again. Further, depending on the abnormality that has occurred, the indoor unit 10 may turn off the AC power supply SW11 to stop the power supply to the outdoor unit 20. In this case, since AC power is not supplied to the outdoor unit 20, the power supply to the outdoor unit microcomputer 32 is also stopped. Further, even when the operation of the air conditioner 1 is stopped by the user operation, the AC power supply SW11 of the indoor unit 10 is switched to OFF, whereby the power supply to the outdoor unit microcomputer 32 is stopped.

That is, the air conditioner 1 is designed to supply power to the outdoor unit microcomputer 32 by turning on the AC power supply SW11 of the indoor unit 10. In this specification, if the ACDC switching SW26 of the outdoor unit 20 is on the DC side when the AC power SW11 is turned off, the power supply to the outdoor unit microcomputer 32 is stopped, so that the ACDC switching SW26 is moved to the AC side. It cannot be returned. Therefore, even after the AC power supply SW11 of the indoor unit 10 is turned off, the power supply state from the DC power supply 50 to each part of the outdoor unit 20 is maintained.

Further, it is assumed that the connection line with the DC power supply 50 is cut off during the operation using the DC power supply 50, or the DC voltage sufficient for operation cannot be obtained due to the failure of the converter 27. In such a case, if the ACDC switching SW26 is not set to the AC side before the DC voltage drops, the power supply to the outdoor unit microcomputer 32 is stopped while the DC side remains, and the ACDC switching SW26 cannot be switched. In this state, since power cannot be supplied from the AC power source 60, the outdoor unit microcomputer 32 cannot be restarted.

Therefore, when the outdoor unit microcomputer 32 satisfies the condition that the AC power supply SW11 of the indoor unit 10 is turned off (for example, when a user operation for stopping the operation of the air conditioner 1 is detected), the outdoor unit microcomputer 32 switches the ACDC. Switch SW26 to the AC side (commercial power supply side). As a result, after the indoor unit AC power SW is turned off, the power supply to the outdoor unit 20 is stopped, but since the ACDC switching SW26 is on the AC side, the DC power supply 50 is transferred to each part of the outdoor unit 20. The power supply state of is not maintained. Therefore, wasteful power is not consumed when the air conditioner 1 is stopped.

Further, when the outdoor unit microcomputer 32 detects an abnormality that may be related to the DC power supply 50 during operation using the DC power supply 50, before the DC voltage supplied to the outdoor unit microcomputer 32 drops. , Immediately switches the ACDC switching SW26 to the AC side. Alternatively, when the outdoor unit microcomputer 32 detects an abnormality during operation using the DC power supply 50, it determines that all the abnormalities may be related to the DC power supply 50 regardless of the type of the detected abnormality. Then, the same switching as above is performed. As a result, if the AC power SW11 of the indoor unit 10 is switched to ON, power is supplied to each part of the outdoor unit 20 via the ACDC switching SW26, so that it is possible to avoid a state in which the outdoor unit 20 cannot be restarted.

In this way, the outdoor unit microcomputer 32 switches the ACDC switching SW26 to the AC side at an appropriate timing to avoid the occurrence of problems that may occur when the ACDC switching SW26 is on the DC side, and the air conditioner 1 Is made comfortable to use. That is, according to the present invention, it is possible to provide a comfortable and highly convenient air conditioner 1.

Further, when a DC undervoltage error occurs, the ACDC switching SW26 is switched to the AC side, so even if the positive electrode and the negative electrode of the DC power supply 50 are mistakenly connected in reverse, the air conditioner 1 is AC. It can be operated by the power supply 60. Further, when the occurrence of the DC undervoltage error is detected and the power supply source is switched to the AC power supply 60, the user can notice that the DC power supply 50 has an abnormality. Therefore, the user can be made aware of the deficiency in the installation work, and the positive and negative electrodes of the DC power supply 50 can be corrected in the correct directions. Even when the connection line of the DC power supply 50 is not connected, the DC undervoltage error is detected as in the above example, so that the user can be aware of such imperfections in the installation work.

[Flow of switching process (DC undervoltage error)]
The outdoor unit microcomputer 32 switches the power supply used from the DC power supply 50 to the AC power supply 60 when the output voltage from the DC power supply 50 drops and a DC undervoltage error occurs. The flow of this switching process will be described with reference to FIG. FIG. 4 is a flowchart showing an example of a switching process for switching the power supply used from the DC power supply 50 to the AC power supply 60 when a DC undervoltage error occurs.

First, the outdoor unit microcomputer 32 determines whether or not the air conditioner 1 is operated by the AC power supply (AC power supply 60) (S1). When operating on the AC power source 60 (True in S1), the outdoor unit microcomputer 32 ends the process without switching.

On the other hand, when the AC power supply 60 is not operated (False in S1), that is, when the DC power supply 50 is operated, whether or not the DC voltage of the storage battery of the outdoor unit microcomputer 32 is less than a predetermined threshold value (Vdc_btry). (S2, detection step). This determination is a process for detecting the occurrence of a DC undervoltage error, and is performed by comparing the voltage value output from the DC voltage abnormality detection circuit 24 to the outdoor unit microcomputer 32 with a predetermined threshold value.

Here, if it is equal to or higher than a predetermined threshold value (False in S2), the outdoor unit microcomputer 32 ends the process without switching. On the other hand, when it is less than a predetermined threshold value (True in S2), that is, when a DC undervoltage error has occurred, the outdoor unit microcomputer 32 switches the ACDC switching SW26 from DC to AC (S3, switching step). , End the process.

Although not shown in FIG. 4, the outdoor unit microcomputer 32 stops the operation of the compressor or the like having a large power consumption before switching from DC to AC. Further, although not shown in FIG. 4, as described with reference to FIG. 3, the DC power supply SW21 is switched from ON to OFF before the ACDC switching SW26 is switched, and the AC power supply SW22 is switched after the ACDC switching SW26 is switched. Switch from OFF to ON. Hereinafter, the same applies to FIGS. 5 to 8 and 11.

[Flow of switching process (DC undervoltage error after boosting)]
The outdoor unit microcomputer 32 switches the power supply used from the DC power supply 50 to the AC power supply 60 even when the output voltage from the converter 27 drops and a DC undervoltage error occurs after boosting. The flow of this switching process will be described with reference to FIG. FIG. 5 is a flowchart showing an example of a switching process for switching the power supply used from the DC power supply 50 to the AC power supply 60 when a DC undervoltage error occurs after boosting. Here, only S2a, which is a difference from FIG. 4, will be described, and the same description of S1 and S3 as in FIG. 4 will be omitted.

In S2a (detection step), the outdoor unit microcomputer 32 determines whether or not the DC voltage after boosting is less than a predetermined threshold value (Vdc_pfc). This determination is a process for detecting the occurrence of a DC undervoltage error after boosting, and is performed by comparing the voltage value output from the converter abnormality detection circuit 28 to the outdoor unit microcomputer 32 with a predetermined threshold value. Here, if it is equal to or more than a predetermined threshold value (False in S2a), the process is terminated without switching, while if it is less than a predetermined threshold value (True in S2a), that is, a DC undervoltage error occurs after boosting. If so, switch in S3 to end the process.

[Flow of switching process (terminal temperature rise error)]
The outdoor unit microcomputer 32 switches the power supply used from the DC power supply 50 to the AC power supply 60 even when a terminal temperature rise error occurs in which the temperature of the terminal connecting the DC power supply 50 and the outdoor unit 20 rises abnormally. The flow of this switching process will be described with reference to FIG. FIG. 6 is a flowchart showing an example of a switching process for switching the power supply used from the DC power supply 50 to the AC power supply 60 when a terminal temperature rise error occurs. Here, only S2b, which is a difference from FIG. 4, will be described, and the same description of S1 and S3 as in FIG. 4 will be omitted.

In S2b (detection step), the outdoor unit microcomputer 32 determines whether or not the terminal plate temperature fuse disconnection signal has been received. Since the reception of this signal indicates that the temperature of the terminal connecting the DC power supply 50 and the outdoor unit 20 has risen abnormally, the determination of S2b determines whether or not a terminal temperature rise error has occurred. It can be said that. Here, if the terminal plate temperature fuse disconnection signal is not received (False in S2b), the process ends without switching, while if it is received (True in S2b), that is, a terminal temperature rise error occurs. If so, the process is terminated by switching in S3.

In FIGS. 4 to 6 described above, an example of switching from the DC power supply 50 to the AC power supply 60 when an abnormality (error) related to the DC power supply 50 is detected is shown. As in these examples, switching is performed when an error related to the DC power supply 50 is detected, so that an error related to the DC power supply 50 has occurred and switching to the AC power supply 60 is highly necessary. It can be carried out. Therefore, the DC power supply 50 may be used continuously without switching when an error related to the DC power supply 50 is detected as described above and not when an error unrelated to the DC power supply 50 is detected.

[Flow of switching process (arbitrary error)]
In a device such as the air conditioner 1, various errors such as an error not directly related to the DC power supply 50 and an error not related to the DC power supply 50 may occur. Examples of errors include cycle temperature abnormality errors such as discharge / heat exchangers, IPM errors, AC current errors, gas leak errors, fan control errors, compressor control errors, and the like. In many errors, if the AC power supply 60 is switched (the ACDC switching SW26 is set to the AC side), the operation of the air conditioner 1 can be continued after that, and the air conditioner 1 can be continued. It is possible to restart after the operation of 1 is temporarily stopped. Therefore, the DC power supply 50 may be switched to the AC power supply 60 regardless of the type of error detected.

Here, the flow of the switching process of switching the power supply to be used from the DC power supply 50 to the AC power supply 60 when the outdoor unit microcomputer 32 detects an arbitrary error will be described with reference to FIG. FIG. 7 is a flowchart showing an example of a switching process for switching the power supply used from the DC power supply 50 to the AC power supply 60 when an arbitrary error occurs. Here, only S2c, which is a difference from FIG. 4, will be described, and the same description of S1 and S3 as in FIG. 4 will be omitted.

In S2c (detection step), the outdoor unit microcomputer 32 determines whether or not an abnormality (error) has been detected. As the error detection method, a known method according to the type of error can be applied. Here, if an error is not detected (False in S2c), the process ends without switching, while if it is detected (True in S2c), that is, if some error occurs, S3 Switch with to end the process.

[Flow of switching process (when operation is stopped)]
As described above, when the operation of the air conditioner 1 is stopped with the ACDC switching SW26 set to the DC side, the power supply from the DC power supply 60 to the outdoor unit 20 continues even after the operation is stopped. Therefore, when the operation of the air conditioner 1 is stopped, the ACDC switching SW26 is switched to the AC side, and the power supply used is switched from the DC power supply 50 to the AC power supply 60.

Here, the flow of the switching process for switching the power supply used from the DC power supply 50 to the AC power supply 60 when the operation is stopped will be described with reference to FIG. FIG. 8 is a flowchart showing an example of a switching process for switching the power supply used from the DC power supply 50 to the AC power supply 60 when the operation is stopped. Here, only S2d, which is a difference from FIG. 4, will be described, and the same description of S1 and S3 as in FIG. 4 will be omitted.

In S2d (detection step), the outdoor unit microcomputer 32 determines whether or not the operation OFF signal for stopping the operation of the air conditioner 1 has been detected. The operation OFF signal is transmitted from the indoor unit 10 to the outdoor unit microcomputer 32 in response to the user giving an operation stop instruction to the indoor unit 10 by, for example, a remote controller or the like. That is, although not shown in FIG. 1, the air conditioner 1 includes a stop detection circuit for detecting that the air conditioner is in the operation stop state. Then, the stop detection circuit transmits an operation OFF signal to the outdoor unit microcomputer 32 when the air conditioner is put into the operation stop state. Here, if the operation OFF signal is not detected (False in S2d), the process ends without switching, while if it is detected (True in S2d), that is, the operation of the air conditioner 1 is stopped. In that case, switching is performed in S3 to end the process.

When the condition that the AC power supply SW11 of the indoor unit 10 is turned off is satisfied other than when the operation OFF signal is detected, it is preferable to switch from the DC power supply 50 to the AC power supply 60 before the AC power supply SW11 is turned off. For example, when an error such that the AC power supply SW11 of the indoor unit 10 is turned off is detected, the DC power supply 50 may be switched to the AC power supply 60. According to this example, even if the detection of an arbitrary error does not trigger the switching as in the example of FIG. 7, the switching can be appropriately performed when the AC power supply SW11 of the indoor unit 10 is turned off.

[Embodiment 2]
Other embodiments of the present invention will be described below with reference to FIGS. 9 to 13. For convenience of explanation, the same reference numerals will be added to the members having the same functions as those described in the above embodiment, and the description thereof will be omitted.

For example, the following Patent Document 2 is mentioned as a prior art for operating an air conditioner using a solar cell, and for example, the following Patent Document 3 is mentioned as a prior art for operating an air conditioner using a storage area as a power source. Can be mentioned. Further, as a prior art for operating an air conditioner by using a solar cell and a storage battery in combination, for example, the following Patent Document 4 can be mentioned.

Here, the electric power generated by the solar cell can be sold to the electric power company, but in the case of a system using both the solar cell and the storage battery, the selling price differs depending on whether or not the storage battery is used during power generation. It is set. That is, when the storage battery is used during power generation (called “with push-up”), the selling price is set lower than when it is not used (called “without push-up”). This is because the storage battery can be charged by a commercial power source whose purchase price is lower than the selling price of photovoltaic power generation.

The presence or absence of push-up is determined by the power conditioner connected to the solar cell, and the DC of the storage battery is within a predetermined time (0.5 seconds) after the sale of the electric power generated by the solar cell is started. If you do not stop using power, it will be pushed up.

[Patent Document 2] Japanese Patent Application Laid-Open No. 5-168172 (published on July 2, 1993)
[Patent Document 3] Japanese Unexamined Patent Publication No. 2001-65927 (published on March 16, 2001)
[Patent Document 4] Japanese Unexamined Patent Publication No. 2000-217271 (published on August 4, 2000)
However, in the above-mentioned prior art, there is a problem that the sale of electricity is not particularly considered and it cannot be avoided that the power is pushed up. The HEMS (Home Energy Management System) is known as a system for managing various devices used at home, including a power conditioner. By using HEMS, it is possible to detect that the power conditioner has started selling power and switch the power supply source of the air conditioner. However, with such control, it is difficult to switch within the predetermined time because a time loss occurs before switching the power supply source. For example, in HEMS that monitors the power selling state of a power conditioner at intervals of 30 seconds, it is difficult to switch the power supply source within the predetermined time. Further, if the monitoring time interval is set to a short time corresponding to the predetermined time, the load on the HEMS increases remarkably, which is not preferable.

In the present embodiment, in order to solve the above problem, by inputting the power sale information of the power conditioner to the air conditioner 1 as an electric signal, the use of DC power is instantly stopped and the operation is switched to AC power. .. As a result, it is possible to avoid having to push up and sell power at a high selling price without pushing up.

〔System configuration〕
The configuration of the system of this embodiment will be described with reference to FIG. FIG. 9 is a block diagram showing an outline of a system for switching the power supply source from the DC power supply 50 to the AC power supply 60 at the start of selling power. In addition to the configuration shown in FIG. 1, FIG. 9 shows a power conditioner (external device) 70 and a solar cell 80.

The solar cell 80 is a device that converts light energy into electric energy, and the electric power generated by the solar cell 80 is first supplied to the power conditioner 70. The power conditioner 70 is a device that converts the electricity generated by the solar cell 80 so that it can be used in the air conditioner 1 or the like. The power conditioner 70 also controls the sale of electricity. Specifically, the power conditioner 70 causes the electric power generated by the solar cell 80 to flow back to a transmission line (not shown) and supplies the electric power to other power consumption destinations. Then, this supply amount is counted as the power sale amount.

The power conditioner 70 of the present embodiment is different from the conventional power conditioner in that when the power sale is started, the power sale information (signal) indicating that the power sale is started (or started) is output to the outdoor unit 20. It is a difference. Then, the outdoor unit 20 of the present embodiment switches the power supply source from the DC power supply 50 to the AC power supply 60, triggered by the reception of the power sale information.

As a result, the use of the DC power supply 50 is promptly stopped at the start of selling power, so that it is possible to sell power at a high selling price without pushing up. Further, since the power supply source is automatically switched to the AC power supply 60, the user can continue to use the air conditioner 1 without performing any operation. The switching of the present embodiment can be used in combination with the switching of the above embodiment. That is, the air conditioner 1 that switches to the AC power supply 60 when an error or the like occurs and also switches to the AC power supply 60 at the start of selling power is also included in the category of the present invention.

[Detailed configuration]
Subsequently, a more detailed configuration of the outdoor unit 20 and the power conditioner 70 of the present embodiment will be described with reference to FIG. FIG. 10 is a diagram showing a main configuration of the outdoor unit 20 and the power conditioner 70. The outdoor unit 20 has various configurations for switching between AC and DC as in FIG. 1, but the illustration is omitted in FIG.

As shown in the figure, the power conditioner 70 includes a SW71 for notifying the start of power sale. The power sale start notification SW71 is a switch (relay switch) that switches to ON when the power conditioner 70 starts selling power and switches to OFF when the power selling ends. That is, the power sale start notification SW71 is ON during power sale and OFF during non-sale.

On the other hand, the outdoor unit 20 includes a power sale start detection circuit 40. The power sale start detection circuit 40 connects the wiring that connects one terminal of the power sale start notification SW71 to 0V and the other terminal of the power sale start notification SW71 via a resistor (pull-up resistor, for example, 1KΩ) to 5V. Includes wiring to connect to. Further, the power sale start detection circuit 40 includes a wiring for outputting the reference voltage to the outdoor unit microcomputer 32, and the wiring connects the portion between the other terminal and the resistor and the outdoor unit microcomputer 32. are doing.

When the power sale is not performed and the power sale start notification SW71 is OFF, the power sale start detection circuit 40 outputs a 5 V reference voltage (Hi level signal) to the outdoor unit microcomputer 32 via a resistor. .. Even if the outdoor unit microcomputer 32 receives the Hi level signal, the power supply used is not switched.

On the other hand, when the power sale is started and the power sale start notification SW71 is turned on, the power sale start detection circuit 40 outputs a 0V reference voltage (Low level signal) to the outdoor unit microcomputer 32. More specifically, a Low level signal (corresponding to the power sale information in FIG. 9) is output to the outdoor unit microcomputer 32 from the wiring connected to 0V of the power sale start detection circuit 40 via the power sale start notification SW71. Will be done. If the power source used at this time is the DC power source 50, the outdoor unit microcomputer 32 switches the power source used to the AC power source 60.

[Flow of switching process (detection of start of power sale)]
The flow of the switching process executed by the outdoor unit microcomputer 32 of the present embodiment will be described with reference to FIG. FIG. 11 is a flowchart showing an example of a switching process for switching the power supply used from the DC power supply 50 to the AC power supply 60 when the start of power sale is detected. Here, only S2e, which is a difference from FIG. 4, will be described, and the same description of S1 and S3 as in FIG. 4 will be omitted.

In S2e, the outdoor unit microcomputer 32 has detected whether or not the input from the power conditioner 70 (more specifically, the SW71 for power sale start notification) is 0 V (Low level), in other words, the power sale has started. Judge whether or not. As described above, the reference voltage input to the outdoor unit microcomputer 32 is 5V (Hi level) when the power sale start notification SW71 of the power conditioner 70 is OFF, and is 0V (Low level) when it is switched to ON. Become.

Here, if the input is 5V (False in S2e), the process ends without switching. In this case, there is no change in the operation of the outdoor unit 20 including the compressor and the like. On the other hand, if it is 0V (True in S2e), switching is performed in S3 to end the process. As described above, in order to sell the power without pushing up, it is necessary to stop the use of the DC power within a predetermined time after the start of the power sale. Therefore, in S3, the DC power is promptly supplied within the predetermined time. Stop using it. Further, although not shown, as in the above embodiment, the operation of the compressor or the like having a large power consumption is stopped before the switching.

[Use of DC voltage abnormality detection circuit]
It is also possible to detect the start of power sale by using the DC voltage abnormality detection circuit 24. This will be described with reference to FIG. FIG. 12 is a diagram showing an example of a power selling start detection circuit 41 that detects the start of power selling by using the DC voltage abnormality detection circuit 24.

The power sale start detection circuit 41 includes a DC voltage abnormality detection circuit 24. Then, the power sale start detection circuit 41 has a wiring for connecting one terminal of the power sale start notification SW71 to the end of the DC voltage abnormality detection circuit 24 on the resistance 242 side, and the other of the power sale start notification SW71. The terminal includes a wiring for connecting the terminal to a wiring for which the DC voltage abnormality detection circuit 24 outputs a reference voltage. As described above, the resistor 241 may be, for example, 780 KΩ, and the resistor 242 may be, for example, 37.5 KΩ. In this case, in the outdoor unit microcomputer 32, the output voltage value from the DC voltage abnormality detection circuit 24 is less than a predetermined threshold value (for example, 3.75 V: corresponding to the case where the supply voltage of the DC power supply 50 is about 80 V). Occasionally, it may be determined that a DC undervoltage error has occurred.

If the power sale start notification circuit 41 is OFF, the power sale start detection circuit 41 outputs the reference voltage of the DC voltage abnormality detection circuit 24 to the outdoor unit microcomputer 32 as it is. That is, during the period when the power sale start notification SW71 is OFF (during power sale), the power sale start detection circuit 41 functions as a DC undervoltage error detection circuit. Therefore, the outdoor unit microcomputer 32 switches the power supply used from the DC power supply 50 to the AC power supply 60 when a DC undervoltage error occurs, as described with reference to FIG. 4 and the like while the power is not being sold.

On the other hand, when the power sale start notification SW71 is ON, the reference voltage output by the power sale start detection circuit 41 is 0 V (Low level). Therefore, the outdoor unit microcomputer 32 determines that a DC undervoltage error has occurred during power sales, and switches the power supply used from the DC power supply 50 to the AC power supply 60.

In this way, the power sale start detection circuit 41 applies the outdoor unit microcomputer 32 that switches the power supply used from the DC power supply 50 to the AC power supply 60 as it is when the DC undervoltage error occurs, and uses the DC power supply as the power supply at the start of power sale. It is possible to switch from 50 to the AC power supply 60. Similar to the power sale start detection circuit 41, the design of another error detection circuit (for example, converter abnormality detection circuit 28) may be changed so that the output value becomes a value detected as an error at the start of power sale. It is possible.

[Noise suppression]
In the examples of FIGS. 10 and 12 above, a configuration for suppressing noise of the transmitted signal may be added. This will be described with reference to FIG. FIG. 13 is a diagram showing an example of power selling start detection circuits 40a and 41a having a configuration for suppressing noise of a transmitted signal.

In the power selling start detection circuit 40a shown in FIG. 10A, a common mode coil (noise removing unit) 401 and capacitors (noise removing parts) 402 and 403 are added to the power selling start detection circuit 40 in FIG. It is a configuration. The common mode coil 401 is provided so as to straddle two wirings connecting the power sale start notification SW71 of the power conditioner 70 (not shown) and the outdoor unit 20. That is, one of the coils included in the common mode coil 401 is provided in one of the wirings connecting the power sale start notification SW71 and the outdoor unit 20. The other coil included in the common mode coil 401 is provided in the other one of the wirings connecting the power sale start notification SW71 and the outdoor unit 20 so as to face the one coil. As a result, the noise component can be removed from the signal (power selling signal) transmitted between the power selling start notification SW71 and the outdoor unit 20.

Further, the capacitors 402 and 403 are both connected in parallel with the power sale start notification SW71. The capacitor 403 is connected to the power sale start notification SW71 side of the common mode coil 401, and the capacitor 402 is connected to the outdoor unit microcomputer 32 side of the common mode coil 401. Since the filter circuit is formed by the capacitors 402 and 403, the noise component can be removed from the signal (power sale signal) transmitted between the power sale start notification SW71 and the outdoor unit 20.

The power selling start detection circuit 41a shown in FIG. 12B has a configuration in which a common mode coil 401 and capacitors 402 and 403 are added to the power selling start detection circuit 41 of FIG. Similar to the power sale start detection circuit 40a shown in FIG. 13A, a common mode coil 401 and capacitors 402 and 403 are provided in the wiring connecting the power sale start notification SW71 and the outdoor unit 20. As a result, the noise component can be removed from the signal (power selling signal) transmitted between the power selling start notification SW71 and the outdoor unit 20. In the example of FIGS. 13A and 13B, both the common mode coil 401 and the capacitors 402 and 403 are provided, but even if one of the capacitors is provided, the effect of noise removal can be obtained. It is possible to get.

[Embodiment 3]
Another embodiment of the present invention combines the control of the air conditioners of the first and second embodiments. This makes it possible to provide an air conditioner having the characteristics of the first embodiment and the second embodiment.

[Summary]
The air conditioner (1) according to the first aspect of the present invention is an air conditioner that operates by electric power supplied from an AC power source (AC power source 60) or a DC power source (DC power source 50), and uses an electric power supply source. It controls the switching unit (ACDC switching SW26) that switches between AC power supply and DC power supply, and the switching unit when it detects that an abnormality has occurred in the air conditioner when the power supply source is DC power supply. It is equipped with a control unit (outdoor unit microcomputer 32) that switches the power supply source to an AC power source.

According to the above configuration, when it is detected that an abnormality has occurred in the air conditioner in the state of being a DC power supply, the power supply source is switched to the AC power supply, so that the operation by the DC power supply continues after the abnormality occurs. There is no. Therefore, it is possible to avoid the occurrence of various problems that may occur by continuing the usage state of the DC power supply after the occurrence of an abnormality.

The air conditioner according to the second aspect of the present invention is a voltage abnormality detection circuit (DC voltage abnormality detection circuit 24) for detecting an abnormality in which the voltage supplied from the DC power supply is less than a predetermined threshold value in the first aspect. May be provided.

According to the above configuration, it is possible to detect an abnormality in which the voltage supplied from the DC power supply is less than a predetermined threshold value, and therefore, when this abnormality is detected, the power supply source can be switched to the AC power supply. it can. As a result, by continuing to use the DC power supply whose supply voltage has dropped, the air conditioner will stop operating due to insufficient power, or the control unit will not be able to supply power after the operation has stopped, making it impossible to restart. It is possible to avoid the occurrence of problems.

The air conditioner according to the third aspect of the present invention provides a post-boost voltage abnormality detection circuit for detecting an abnormality in which the voltage supplied from the booster circuit of the DC power supply is less than a predetermined threshold in the first or second aspect. You may have it.

According to the above configuration, it is possible to detect an abnormality in which the voltage supplied from the booster circuit of the DC power supply is less than a predetermined threshold value. Therefore, when this abnormality is detected, the power supply source is an AC power supply. You can switch. As a result, by continuing to use the DC power supply in a state where the voltage cannot be boosted to a normal voltage value, it is possible to avoid the occurrence of problems such as the operation of the air conditioner stopping.

The air conditioner according to the fourth aspect of the present invention includes, in any one of the first to third aspects, a temperature abnormality detection circuit for detecting a temperature abnormality at the connection portion of the DC power supply to the air conditioner. You may be.

According to the above configuration, it is possible to detect a temperature abnormality at the connection portion of the DC power supply to the air conditioner, and therefore, when this abnormality is detected, the power supply source can be switched to the AC power supply. .. As a result, by continuing to use the DC power supply in a state of abnormal temperature, it is possible to avoid problems such as the air conditioner not operating normally or the air conditioner and the DC power supply being damaged by overheating. it can.

The air conditioner according to the fifth aspect of the present invention is an air conditioner that operates by electric power supplied from an AC power source or a DC power source, and has a switching unit that switches the power supply source between the AC power source and the DC power source, and the above. A stop detection circuit for detecting that the air conditioner is in an operation stop state, and an operation stop state of the air conditioner based on the output from the stop detection circuit when the power supply source is a DC power supply. It is provided with a control unit that controls the switching unit to switch the power supply source to the AC power source when it is detected.

According to the above configuration, when it is detected that the air conditioner is stopped, the power supply source is switched to the AC power supply, so that the air conditioner is operated in the state where the power supply source is the DC power supply. It will not be stopped. Therefore, it is possible to avoid the problem that the power from the DC power supply continues to be supplied to the air conditioner by continuing the usage state of the DC power supply after the air conditioner is stopped.

The air conditioner according to the sixth aspect of the present invention is a storage battery capable of storing the electric power generated by the solar cell in any one of the first to fifth aspects, and the solar cell generates electric power. A power sale start detection circuit for detecting the start of power sale of the generated power is provided, and the control unit controls the switching unit when the power sale start is detected based on the output from the power sale start detection circuit. Then, the power supply source may be switched to the AC power source.

According to the above configuration, the start of selling power is detected and the power supply source is switched to the AC power supply. Therefore, since the use of the DC power supply (storage battery) is stopped immediately after the start of power sale, it is possible to avoid the problem that the power sale price drops by selling the power with pushing up.

In the air conditioner according to the seventh aspect of the present invention, in the sixth aspect, the power sale start detection circuit outputs a value for detecting an abnormality of the air conditioner when the power is not sold, and the control when the power is sold. The unit outputs a value to be detected as an abnormality of the air conditioner, and the control unit controls the switching unit when the abnormality of the air conditioner is detected based on the output from the power sale start detection circuit. The power supply source may be switched to an AC power source.

According to the above configuration, a value for detecting an abnormality in the air conditioner is output when the power is not sold. Therefore, when an abnormality occurs in the air conditioner when the power is not sold, this is detected and the power supply source is supplied. Can be switched to an AC power supply. Further, at the time of selling power, the power selling start detection circuit outputs a value detected as an abnormality of the air conditioner, so that the power supply source can be switched to the AC power source at this time as well.

Therefore, using one circuit called the power sale start detection circuit, switching to the AC power supply when the air conditioner is abnormal and switching to the AC power supply when the power is sold are judged by one criterion of presence or absence of abnormality. Both can be realized.

In the air conditioner according to the eighth aspect of the present invention, in the sixth or seventh aspect, the telegraph start detection circuit receives a telegraph signal indicating that the telegraph has started or is started from an external device. Then, a value indicating that the power sale signal has been received is output to the control unit, and noise contained in the power sale signal is removed from the wiring that receives the power sale signal from the external device. A noise removing unit may be provided.

According to the above configuration, since the noise included in the power sale signal is removed, the power sale signal can be reliably detected and switched to the AC power supply at the time of power sale.

The control method of the air conditioner according to the ninth aspect of the present invention is a control method of the air conditioner operated by the electric power supplied from the AC power source or the DC power source, and detects that an abnormality has occurred in the air conditioner. The detection step and the switching step of switching the power supply source to the AC power supply when the detection step detects that an abnormality has occurred in the air conditioner when the power supply source is a DC power supply. ,including. According to the control method, the same action and effect as in the above aspect 1 can be obtained.

The control method of the air conditioner according to the tenth aspect of the present invention is a control method of the air conditioner operated by the electric power supplied from the AC power source or the DC power source, and the power supply to the air conditioner is stopped. When it is detected in the detection step that the power supply to the air conditioner is stopped when the power supply source is the DC power supply, the power supply source is changed to the AC power supply. Includes switching steps to switch. According to the control method, the same action and effect as in the above aspect 5 can be obtained.

The present invention is not limited to the above-described embodiments, and various modifications can be made within the scope of the claims, and the embodiments obtained by appropriately combining the technical means disclosed in the different embodiments. Is also included in the technical scope of the present invention. Furthermore, new technical features can be formed by combining the technical means disclosed in each embodiment.

1 Air conditioner 24 DC voltage abnormality detection circuit (voltage abnormality detection circuit)
26 ACDC switching SW (switching unit)
27 Converter (boost circuit)
28 Converter abnormality detection circuit (voltage abnormality detection circuit after boosting)
32 Outdoor unit microcomputer (control unit)
33 DC terminal plate temperature fuse (temperature abnormality detection circuit)
40, 40a, 41, 41a Power sale start detection circuit 50 DC power supply (DC power supply)
60 AC power supply (AC power supply)
70 Power conditioner (external device)
80 Solar cells 402, 403 Capacitor (noise remover)
401 Common mode coil (noise remover)

Claims (9)

An air conditioner that operates with power supplied from a storage battery that can store power generated by an AC power source or a solar cell.
A switching unit that switches the power supply source between the AC power supply and the above storage battery ,
When it is detected that the voltage supplied from the storage battery is less than a predetermined threshold when the power supply source is the storage battery , the switching unit is controlled to switch the power supply source to alternating current. Control unit to switch to power supply and
It is equipped with a power sale start detection circuit for detecting the start of power sale of the power generated by the solar cell.
The air conditioner has an indoor unit and an outdoor unit.
When the control unit detects the start of power sale based on the output from the power sale start detection circuit, the control unit controls the switching unit to use the storage battery as the power supply source for the outdoor unit. An air conditioner characterized by switching to an AC power supply, which has a higher selling price . The air conditioner according to claim 1, further comprising a voltage abnormality detection circuit for detecting the above abnormality. The air conditioner according to claim 1 or 2, further comprising a post-boost voltage abnormality detection circuit for detecting the abnormality in which the voltage supplied from the booster circuit of the storage battery is less than a predetermined threshold value. .. The air conditioner according to any one of claims 1 to 3, further comprising a temperature abnormality detection circuit for detecting a temperature abnormality at a portion of the storage battery connected to the air conditioner. A stop detection circuit for detecting that the user puts the air conditioner into an operation stop state is provided.
When the control unit detects that the user puts the air conditioner in the operation stop state based on the output from the stop detection circuit when the power supply source is the storage battery , the control unit switches the air conditioner. The air conditioner according to any one of claims 1 to 4, wherein the unit is controlled to switch the power supply source to the outdoor unit to an AC power source. The power sale start detection circuit outputs a value for detecting the abnormality when the power is not sold, and the control unit outputs a value detected as the abnormality when the power is sold.
The control unit is characterized in that when the abnormality is detected based on the output from the power sale start detection circuit, the control unit controls the switching unit to switch the power supply source to the outdoor unit to an AC power source. The air conditioner according to any one of claims 1 to 5 . The power selling start detection circuit receives a power selling signal indicating that power selling has started or is started from an external device, and outputs a value indicating that the power selling signal has been received to the control unit. To do
According to any one of claims 1 to 6, the wiring for receiving the power sale signal from the external device is provided with a noise removing unit for removing noise contained in the power sale signal. The described air conditioner. It is a control method of an air conditioner that operates by the electric power supplied from a storage battery that can store the electric power generated by an AC power source or a solar cell.
The above air conditioner has an indoor unit and an outdoor unit.
A detection step for detecting the occurrence of an abnormality in which the voltage supplied from the storage battery falls below a predetermined threshold value, and
The power sale start detection step for detecting the start of selling the power generated by the solar cell, and
When the source of power is the battery, when it is detected that the abnormality occurs in the detecting step, and, when the power source of is the above battery, sold in the power selling start detection step Air conditioning including a switching step of switching the power supply source to the outdoor unit to an AC power source whose selling price is higher than that when the storage battery is used when the start of electric power is detected. How to control the machine. In the detection step, it is detected that the user puts the air conditioner in the stopped state, and the operation is stopped.
In the switching step, when the power supply source is the storage battery and the user detects that the air conditioner is to be stopped in the detection step, the power supply source to the outdoor unit is The control method for an air conditioner according to claim 8 , wherein the air conditioner is switched to an AC power source.

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