JP6692689B2 - Air conditioner - Google Patents

Description

  The present disclosure relates to a heat pump type air conditioner, and is particularly preferably used for an air conditioner that can use both a DC power source such as a storage battery and a commercial AC power source as drive power sources.

  Conventionally, there has been proposed a technique of driving a compressor of an air conditioner (also referred to as “air conditioner”) by using a DC power supply and a commercial AC power supply together.

  For example, Japanese Patent Laid-Open No. 2001-65927 (Patent Document 1) discloses an air conditioner using a commercial AC power source and a storage battery as power sources. In the air conditioner of this document, an AC voltage from a commercial AC power source is converted into a DC voltage by a rectifying / smoothing circuit, and a DC voltage from a power storage place is boosted by a bidirectional converter. Then, the DC voltage output from the rectifying / smoothing circuit and the DC voltage output from the bidirectional converter are superimposed, and the superimposed DC voltage is supplied to the inverter for driving the compressor.

JP 2001-65927 A

  In order to prevent leakage current between a DC power supply and an AC power supply, the inventors of the present application completely switch between power supply from a DC power supply such as a storage battery and power supply from a commercial AC power supply to supply one power supply. We are developing an air conditioner that supplies only electric power from the compressor to the compressor. An air conditioner of this type has not been known at the time of filing of the present application.

  In this power supply switching type air conditioner, since the output of a DC power supply such as a storage battery is limited, an AC power supply is used when the compressor starts up, and then the power supply is switched from the AC power supply to the DC power supply. Then, at the time of switching the power source, a device such as a compressor that consumes relatively large power is stopped. However, once the compressor is stopped, when restarting the compressor, it is necessary to wait for about 2 to 3 minutes until the differential pressure between the inlet and the outlet of the compressor is completely eliminated. Therefore, the room temperature may change significantly during the temporary suspension period of the compressor.

  The present invention has been made in view of the above problems, and an object thereof is an air conditioner of a system that supplies power to a compressor by switching between power supply from a DC power supply and power supply from an AC power supply, It is an object of the present invention to provide an air conditioner capable of suppressing variations in room temperature as much as possible when switching the power supply from an AC power supply to a DC power supply. Other novel features and advantages of the invention will be apparent from the accompanying drawings and detailed description.

  An air conditioner according to one aspect of the present invention includes a refrigerant circuit, a power supply circuit, and a control unit. The refrigerant circuit includes an outdoor heat exchanger, an indoor heat exchanger, an expansion valve, and a compressor. The power supply circuit is connected to the AC power supply and the DC power supply, and drives the compressor based on only one of the AC power supply and the DC power supply. The control unit controls the power supply circuit to start the compressor based on the AC power supply, temporarily stop the compressor when a predetermined switching condition is satisfied, and restart the compressor based on the DC power supply. To do. The above-mentioned switching condition includes a condition that a predetermined first time has elapsed since the room temperature reached the temperature region corresponding to the set temperature.

  Preferably, the switching condition is that, when the outside air temperature is equal to or lower than the first specified temperature during the cooling operation, the first time has elapsed since the room temperature reached the temperature range, and the outside temperature is below the first temperature during the cooling operation. When the temperature is higher than the prescribed temperature of 1, it means that the time obtained by adding the predetermined second time to the first time has elapsed since the room temperature reached the temperature region.

  Preferably, the switching condition is that, when the outside air temperature is equal to or higher than the second specified temperature during the heating operation, the first time has elapsed since the room temperature reached the temperature range, and the outside temperature is below the first temperature during the heating operation. When the temperature is lower than the specified temperature of 2, it means that the time obtained by adding the predetermined second time to the first time has elapsed since the room temperature reached the temperature region.

  Preferably, the switching condition is that when the absolute value of the temperature difference between the room temperature at the time of starting the compressor and the set temperature is equal to or more than the specified temperature difference, the first time has elapsed since the room temperature reached the temperature range. When the absolute value of the temperature difference between the room temperature at the time of starting the compressor and the set temperature is smaller than the specified temperature difference, the third time is preset from the first time after the room temperature reaches the temperature range. It means that the time reduced is elapsed.

  An air conditioner according to another aspect of the present invention includes a refrigerant circuit, a power supply circuit, and a controller. The refrigerant circuit includes an outdoor heat exchanger, an indoor heat exchanger, an expansion valve, and a compressor. The power supply circuit is connected to the AC power supply and the DC power supply, and drives the compressor by an inverter based on only one of the AC power supply and the DC power supply. The control unit controls the power supply circuit to start the compressor based on the AC power supply, temporarily stop the compressor when a predetermined switching condition is satisfied, and restart the compressor based on the DC power supply. To do. The switching condition includes a condition that a predetermined first time has elapsed after the frequency of the compressor became equal to or lower than the specified frequency due to the room temperature approaching the set temperature.

  Preferably, the switching condition is that when the outside air temperature is equal to or lower than the first specified temperature during the cooling operation, the first time has elapsed since the frequency of the compressor became equal to or lower than the specified frequency, and during the cooling operation. When the outside air temperature is higher than the first specified temperature, it means that the time obtained by adding the second time set in advance to the first time has elapsed since the frequency of the compressor became equal to or lower than the specified frequency.

  Preferably, the switching condition is that when the outside air temperature is equal to or higher than the second specified temperature during the heating operation, the first time has elapsed since the frequency of the compressor became equal to or lower than the specified frequency, and during the heating operation. When the outside air temperature is lower than the second specified temperature, it means that the time obtained by adding the predetermined second time to the first time has elapsed since the frequency of the compressor became equal to or lower than the specified frequency.

  Preferably, when the absolute value of the temperature difference between the room temperature and the set temperature at the time of starting the compressor is equal to or more than the specified temperature difference, the switching condition is the first time after the frequency of the compressor becomes equal to or less than the specified frequency. When the absolute value of the temperature difference between the room temperature and the set temperature at the time of starting the compressor is smaller than the specified temperature difference, the first time after the frequency of the compressor becomes equal to or lower than the specified frequency. Is the time obtained by subtracting the predetermined third time from.

  In one aspect and the other aspect described above, preferably, the refrigerant circuit has a flow path of the refrigerant compressed by the compressor on the outdoor heat exchanger side in order to switch the operation mode of the air conditioner between cooling operation and heating operation. It also includes a four-way valve that switches between the indoor heat exchanger and the indoor heat exchanger. When the control unit detects frost formation on the outdoor heat exchanger during heating operation by driving the compressor based on the DC power supply, the control unit temporarily stops the compressor and sets the four-way valve to outdoor heat. After switching to the exchanger side, the power supply circuit is controlled so as to restart the compressor based on the AC power supply, and then when defrosting completion of the outdoor heat exchanger is detected, the compressor is temporarily stopped, After switching the four-way valve to the indoor heat exchanger side, the power supply circuit is controlled so that the compressor is restarted based on the AC power supply.After that, when the switching condition is satisfied, the compressor is temporarily stopped and switched to the DC power supply. The power circuit is controlled to restart the compressor based on the above.

  According to the present invention, in the air conditioner of the method of switching between the power supply from the DC power supply and the power supply from the AC power supply to supply to the compressor, when the power supply is switched from the AC power supply to the DC power supply, room temperature fluctuations are prevented. It can be suppressed as much as possible.

It is a figure for demonstrating connection of the air conditioner by 1st Embodiment, a DC power supply, and a commercial AC power supply. It is a figure which shows typically the structure of the refrigerant circuit 10 of the air conditioner 50 of FIG. It is a figure which shows the electric system structure of the air conditioner of FIG. It is a flowchart which shows the switching procedure of the operation mode of the air conditioner of FIG. It is a flow chart which shows the procedure which judges whether AC / DC switching conditions are fulfilled. It is a flowchart which shows the procedure for determining whether the AC / DC switching conditions are satisfy | filled at the time of cooling operation in the air conditioner of 2nd Embodiment. It is a flow chart which shows the procedure for judging whether AC / DC switching conditions are fulfilled at the time of heating operation in the air harmony machine of a 2nd embodiment. It is a flowchart which shows the procedure for determining whether the AC / DC switching conditions are satisfy | filled at the time of cooling operation in the air conditioner of 3rd Embodiment. It is a flowchart which shows the switching procedure of DC / AC operation mode at the time of defrosting operation in the air conditioner of 4th Embodiment. 7 is a flowchart of a modified example of FIG. 5. It is a flowchart of the modification of FIG. It is a flowchart of the modification of FIG. It is a flowchart of the modification of FIG.

  Hereinafter, each embodiment will be described in detail with reference to the drawings. In addition, the same or corresponding portions may be denoted by the same reference symbols, and the description thereof may not be repeated.

<First Embodiment>
[Connection method between DC power supply and AC power supply and air conditioner]
FIG. 1 is a diagram for explaining a connection between an air conditioner according to the first embodiment and a DC power supply and a commercial AC power supply. In FIG. 1, an example in which a storage battery 41 is used as a DC power source is shown.

  With reference to FIG. 1, the air conditioner 50 includes an indoor unit 60 and an outdoor unit 70. In the first embodiment, a commercial AC voltage having a rating of 200V is input to the indoor unit 60, and a DC voltage having a rating of 100V is input to the outdoor unit 70 from the storage battery 41.

  Specifically, as shown in FIG. 1, the terminal 42 (the positive side terminal 42P, the negative side terminal 42N) of the storage battery 41 and the terminal 72 (the positive side terminal 72P, the negative side terminal 72N) of the outdoor unit 70 are DC. It is connected via a (DC) 100V power line 54. The outlet plug 51 of the indoor unit 60 is connected to a single-phase three-wire type 200V commercial AC power source. That is, AC (alternating current) 200V is applied between the terminals 51R and 51S of the outlet plug 51. A ground wire is connected to the terminal 51O of the outlet plug 51.

  Further, the indoor unit 60 and the outdoor unit 70 are provided with 3p terminals 61 and 71, respectively. The terminals 61R and 61S of the indoor unit 60 and the terminals 71R and 71S of the outdoor unit 70 are connected by a power supply line 52 of AC200V, and the terminal 61C of the indoor unit 60 and the terminal 71C of the outdoor unit 70 are connected to the communication line 53. Connected by.

  Unlike the case of the present embodiment shown in FIG. 1, both the DC power supply and the AC power supply may be connected to the indoor unit 60. In this case, either the direct current obtained by rectifying the alternating current from the alternating current power source or the direct current from the direct current power source is supplied to the outdoor unit 70.

[Structure of Refrigerant Circuit of Air Conditioner]
FIG. 2 is a diagram schematically showing the configuration of the refrigerant circuit 10 of the air conditioner 50 of FIG. Referring to FIG. 2, the refrigerant circuit 10 includes a compressor 84, an outdoor heat exchanger 35, an expansion valve 88, and a four-way valve 90 provided in the outdoor unit 70, and an indoor heat exchanger provided in the indoor unit 60. And 36. Further, the outdoor unit 70 of the air conditioner 50 includes an outdoor fan 86, and the indoor unit 60 includes an indoor fan 65.

  The compressor 84 compresses the refrigerant. The outdoor heat exchanger 35 exchanges heat between the outdoor air and the refrigerant. The opening of the expansion valve 88 is controlled to adjust the flow rate of the refrigerant. The indoor heat exchanger 36 exchanges heat between the indoor air and the refrigerant. The outdoor fan 86 promotes heat exchange in the outdoor heat exchanger by sending outdoor air to the outdoor heat exchanger 35. The indoor fan 65 blows the air heat-exchanged by the indoor heat exchanger 36 into the room. In this embodiment, the outdoor fan 86 is a propeller fan and the indoor fan 65 is a cross flow fan.

  The four-way valve 90 switches the circulating direction of the refrigerant in the cooling operation and the heating operation. During the cooling operation, as shown by the solid arrow in FIG. 2, the refrigerant is the compressor 84, the four-way valve 90, the outdoor heat exchanger 35, the expansion valve 88, the indoor heat exchanger 36, the four-way valve 90, and the compressor 84 in this order. Goes around. In this case, the outdoor heat exchanger 35 functions as a condenser for condensing and liquefying the compressed high-temperature refrigerant, and the indoor heat exchanger 36 evaporates the liquefied refrigerant to cool the refrigerant to a low temperature. It functions as an evaporator for changing to gas.

  On the other hand, during the heating operation, as shown by the dashed arrow in FIG. 2, the compressor 84, the four-way valve 90, the indoor heat exchanger 36, the expansion valve 88, the outdoor heat exchanger 35, the four-way valve 90, and the compressor 84 are operated. The refrigerant circulates in order. In this case, the outdoor heat exchanger 35 functions as an evaporator, and the indoor heat exchanger 36 functions as a condenser.

  The air conditioner 50 further includes a temperature sensor 31 for measuring the temperature of the outdoor heat exchanger 35, a temperature sensor 30 for measuring the discharge temperature which is the refrigerant temperature at the outlet of the compressor 84, and the indoor heat. A temperature sensor 33 for measuring the temperature of the exchanger 36. These temperature sensors 31, 30, 33 are, for example, thermistors. The temperature sensor 31 for the outdoor heat exchanger 35 and the temperature sensor 33 for the indoor heat exchanger 36 are both arranged between the inlet and the outlet of the heat exchanger. Therefore, in the normal case, the temperature detected when these heat exchangers function as a condenser is the condensation temperature of the refrigerant, and the temperature detected when they function as an evaporator is the evaporation temperature of the refrigerant. is there.

  Further, the outdoor unit 70 is equipped with a temperature sensor 32 for measuring the outside air temperature, and the indoor unit 60 is equipped with a temperature sensor 34 for measuring the indoor temperature. These temperature sensors 32 and 34 can also be constituted by, for example, thermistors.

  In the present embodiment, the heating operation and the cooling operation are described as being switchable, but the air conditioner may be capable of only one of the heating operation and the cooling operation. In that case, the four-way valve 90 is not provided in the refrigerant circuit 10, and the functions of the outdoor heat exchanger 35 and the indoor heat exchanger 36 are fixed as a condenser or an evaporator. Further, unlike the case of FIG. 2, the technology described below can be applied to an air conditioner that is not separated into the outdoor unit 70 and the indoor unit 60 and is integrated.

[Electric system configuration of air conditioner]
(Structure of indoor unit)
FIG. 3 is a diagram showing an electric system configuration of the air conditioner of FIG. 1. Referring to FIG. 3, the indoor unit 60 includes an indoor unit power supply circuit 62, an internal circuit 63, a relay 64 (open / close switch), and an indoor fan 65.

  The indoor unit power supply circuit 62 is connected to the outlet plug 51 and generates a DC voltage to be supplied to the internal circuit 63 based on the AC voltage (AC200V) received from the commercial AC power supply. The indoor unit power supply circuit 62 further includes a drive circuit (not shown) for driving a fan motor for the indoor fan 65. The power supply circuit 20 for the air conditioner 50 is configured together with the power supply circuit 62 for the indoor unit and the power supply circuit 21 for the outdoor unit described later.

  The internal circuit 63 includes, for example, a communication circuit (not shown) for communication with the remote controller, a communication circuit 67 for communication with the outdoor unit 70, and the like. The communication circuit 67 is connected to the communication circuit 94 of the outdoor unit 70 via the communication line 53.

  The AC voltage (AC200V) input from the outlet plug 51 is input to the outdoor unit 70 via the terminals 61R and 61S, the power supply line 52, and the terminals 71R and 71S. The four-way valve 90 of the outdoor unit 70 is directly driven by this AC voltage. A relay 64 (open / close switch) is provided on the line connecting the outlet plug 51 and the terminals 61R and 61S.

(Structure of outdoor unit)
The outdoor unit 70 includes an outdoor unit power supply circuit 21, a compressor 84 driven by the power supply circuit 21, an outdoor fan 86, an expansion valve 88, a microcomputer 89, and a communication circuit 94. Further, the outdoor unit 70 includes a four-way valve 90 driven by an AC voltage supplied via the indoor unit 60.

  The outdoor unit power supply circuit 21 includes relays 73, 92, 93 (open / close switches), a PTC thermistor (Positive Temperature Coefficient Thermistor) 74, and a current transformer (CT: Current Transformer) as an AC ammeter A2. A full-wave rectifier circuit 75, a switching circuit 76, a filter circuit 79, a diode 80, and a detection resistor serving as a DC voltmeter V1 and a DC ammeter A1.

  The AC voltage (AC200V) input via the terminals 71R and 71S is input via the relay 73 (open / close switch) to the full-wave rectifier circuit 75 configured by a diode bridge. The rectified voltage output from the full-wave rectifier circuit 75 is input to the switching circuit 76. A PTC thermistor (Positive Temperature Coefficient Thermistor) 74 is connected in parallel with the relay 73 in order to reduce the exciting inrush current when the relay 73 is turned on. The PTC thermistor is an electronic component that has a substantially constant resistance value near room temperature, but the resistance value sharply increases when the temperature exceeds a certain temperature. The AC ammeter A2 is connected between the relay 73 and the rectifying circuit 75, and measures the AC current input to the indoor unit 60 (current consumption of the outdoor unit 70 during AC operation).

  On the other hand, the DC voltage (DC 100V) input via the terminals 72P and 72N is input to the filter circuit 79 via the relays 92 and 93 (open / close switches). The filter circuit 79 is a low pass filter that blocks high frequency components. The DC voltage output from the filter circuit 79 is input to the switching circuit 76 via the diode 80.

  The diode 80 is provided to protect the outdoor unit power supply circuit 21 when the polarities of the DC power supplies such as storage batteries connected to the terminals 72P and 72N are opposite. That is, the diode 80 blocks the current in the direction from the negative terminal 72N to the inside and the positive terminal 72P to the outside.

  The DC voltmeter V1 measures the voltage between the terminals 72P and 72N for DC input. The DC ammeter V2 measures a DC current (current consumption of the outdoor unit 70 during DC operation) input from the DC power source to the outdoor unit 70.

  The changeover circuit 76 includes relays 77 and 78 (changeover switches). By switching the relays 77 and 78, either one of the rectified voltage output from the full-wave rectifier circuit 75 and the DC voltage (DC 100V) is output.

  The outdoor unit power supply circuit 21 further includes a power factor correction type step-up converter 81, a capacitor 82, a detection resistor serving as a voltmeter V3, inverters 83 and 85, and a step-down converter 87.

  The power factor correction (PFC) type boost converter 81 boosts the rectified voltage or the DC voltage (DC 100 V) output from the switching circuit 76 to a set voltage (for example, DC 340 V). Further, when the input voltage is a rectified voltage, boost converter 81 operates as a power factor correction circuit in the current continuous mode or the current critical mode to match the phases of the input voltage and the input current. A capacitor 82 having a relatively large capacity and a voltmeter V3 are connected between output nodes of boost converter 81. In order to reduce the output ripple of boost converter 81, it is desirable to use an interleaved power factor correction circuit.

  The boosted voltage (DC340V) output from the boost converter 81 is supplied to the inverters 83 and 85 and the step-down converter 87. The inverter 83 converts the boosted voltage into a three-phase AC voltage and supplies it to the synchronous motor of the compressor 84. The inverter 85 converts the boosted voltage into a three-phase AC voltage and supplies it to the synchronous motor for the outdoor fan 86. The step-down converter 87 steps down the step-up voltage (DC340V) to DC12V and supplies it to the stepping motor of the expansion valve 88, and step-down to DC5V to supply it to the microcomputer 89 and the communication circuit 94.

  The microcomputer 89 includes detection values Iu1, Iv1, Iw1 of three-phase AC currents detected by shunt resistors provided in the inverter 83, and detection values of three-phase AC currents detected by shunt resistors provided in the inverter 85. Information on the detected values of Iu2, Iv2, Iw2, and ammeters A1, A2 and voltmeters V1, V3 is input. Further, the microcomputer 89 is input with information such as the indoor temperature, the outdoor temperature, the temperatures of the indoor and outdoor heat exchangers (condensing temperature, evaporation temperature), and the rotation speed (also referred to as frequency) of the compressor. The microcomputer 89 controls the overall operation of the air conditioner 50 based on these pieces of information. Specifically, the microcomputer 89 controls the operations of the switching circuit 76, the step-up converter 81, the inverters 83 and 85 step-down converter 87, the expansion valve 88, the four-way valve 90, and the like.

  In the case of FIG. 3, the four-way valve 90 operates with an AC voltage (AC200V), but it may be replaced with one that operates with a DC voltage output from the step-down converter 87.

(Characteristics and effects of electrical system configuration)
A feature of the above electric system configuration is that by providing the switching circuit 76 in the preceding stage of the PFC boost converter 81, one of the DC voltage and the rectified voltage is selectively input to the PFC boost converter 81. As a result, the DC / DC converter for the DC power supply and the boost converter for the power factor correction circuit, which are conventionally provided separately, can be integrated into one.

  In FIG. 3, the rectifier circuit 75 is provided before the switching circuit 76, but it is also possible to provide the rectifier circuit 75 after the switching circuit 76 and before the boost converter 81. When a DC voltage is input to the rectifier circuit 75, the DC voltage is output almost as it is, although there is some loss due to the diode.

  Further, according to the above electrical system configuration, since the switching circuit 76 insulates the AC side and the DC side from each other, the problem of the AC wave leakage current does not occur. In addition, since the DC (direct current) operation based on the direct current power supply and the AC (alternating current) operation based on the alternating current power supply are independently executed, the user can determine whether the current operating state is the DC operation or the AC operation. There is an advantage that it is possible to prompt the user to save energy by displaying on.

[Operation of air conditioner]
The operation of the air conditioner having the electric system configuration shown in FIG. 3 will be described below. Hereinafter, the case where the switching circuit 76 is switched to the DC power supply side is referred to as a DC operation mode, and the case where the switching circuit 76 is switched to the AC power supply side is referred to as an AC operation mode. Then, the switching procedure between the DC operation mode based on the DC power supply and the AC operation mode based on the AC power supply will be described in detail. The following steps are realized by executing a control program by a microcomputer 89 as a control unit.

  FIG. 4 is a flowchart showing a procedure of switching the operation mode of the air conditioner of FIG. Referring to FIGS. 3 and 4, upon receiving the operation start command from the user (YES in step S100), microcomputer 89 switches switching circuit 76 to the AC power supply side (step S105) to perform the AC operation mode. Then, the operation of the air conditioner 50 is started (step S110). As described above, the reason why the AC operation mode is set at the start of the operation of the air conditioner is that the compressor 84 often rotates at high rotation speed when the air conditioner 50 is started because the difference between the room temperature and the set temperature is large. This is because the power consumption of the air conditioner 50 increases.

  The microcomputer 89 switches the operation mode from the AC operation mode to the DC operation mode when the operation state of the air conditioner 50 becomes stable some time after the activation. Specifically, the microcomputer 89 switches to the DC operation mode when a predetermined AC / DC (AC / DC) switching condition is satisfied (YES in step S115). The AC / DC switching condition will be described in detail with reference to FIG.

  When the above AC / DC switching condition is not satisfied (NO in step S115), the microcomputer 89 stops the operation of the air conditioner 50 by receiving an operation stop command from the user (YES in step S120) ( Unless step S125) is performed, the AC operation mode is continued.

  On the other hand, the procedure for switching the operation mode when the AC / DC switching condition is satisfied (YES in step S115) is as follows. First, the microcomputer 89 stops the AC operation of the outdoor unit 70 (specifically, the compressor 84 and the outdoor fan 86) (step S130), and then switches the switching circuit 76 from the AC power source side to the DC power source side. (Step S135). After that, the microcomputer 89 starts the DC operation of the outdoor unit 70 (specifically, the compressor 84 and the outdoor fan 86) (step S140). However, when restarting the compressor 84, it is necessary to wait about 2 to 3 minutes until the differential pressure between the inlet and the outlet of the compressor is completely eliminated.

  During the switching of the operation modes described above, the microcomputer 89 operates by the charging voltage of the capacitor 82. Conversely, during switching of the operation mode, the compressor 84, the outdoor fan 86, and the like, which consume large power, must be stopped so that the microcomputer 89 can operate only by the charging voltage of the capacitor 82. Note that, unlike the electric system configuration of FIG. 3, it is possible to drive the microcomputer 89 only by an AC power source. However, also in this case, at least the compressor 84 consuming a large amount of power must be stopped.

  After switching to the DC operation mode, the microcomputer 89 may meet the DC / AC (DC / AC) switching condition (YES in step S145) or by receiving an operation stop command from the user (step S165). YES), the DC operation mode is continued unless the operation of the air conditioner 50 is stopped. The DC / AC switching condition is, for example, that the current consumption of the outdoor unit 70 during the DC operation measured by the ammeter A1 in FIG. 3 exceeds the specified value, or the DC measured by the ammeter A1 and the voltmeter V1. This is because the power consumption of the outdoor unit 70 in the operation mode has exceeded the specified value, or the remaining amount of the storage battery has decreased below the specified amount.

  The operation mode switching procedure when the DC / AC switching condition is satisfied (YES in step S145) is as follows. First, the microcomputer 89 stops the DC operation of the outdoor unit 70 (specifically, the compressor 84 and the outdoor fan 86) (step S150), and then switches the switching circuit 76 from the DC power source side to the AC power source side. It switches (step S155). After that, the microcomputer 89 starts the AC operation of the outdoor unit 70 (specifically, the compressor 84 and the outdoor fan 86) (step S160).

  As described above, by switching from the AC operation mode to the DC operation mode based on the determination as to whether or not the AC / DC switching condition is satisfied, the DC power source such as the storage battery 41 is effectively used to realize energy saving. can do.

[AC / DC switching condition]
FIG. 5 is a flowchart showing a procedure for determining whether or not the AC / DC switching condition is satisfied. Hereinafter, the switching from the AC operation mode to the DC operation mode will be described in more detail with reference to FIGS. The numerical values shown below are examples, and the present invention is not limited to these numerical values.

  For example, it is assumed that the cooling operation is started at the set temperature of 26 ° C. when both the outside air temperature and the room temperature are 35 ° C. (step S110 in FIG. 4). The AC operation mode is set at the start of the operation. Since the difference between the room temperature (35 ° C.) at the start of operation and the set temperature (26 ° C.) is 9 ° C., the microcomputer 89 causes the output of the compressor 84 by rotating the compressor 84 at a relatively high speed. Make it higher

  After the start of operation, the microcomputer 89 reads the temperature inside the room by the temperature sensor 34 in FIG. 2 (step S210 in FIG. 5) and determines whether the room temperature has reached the set temperature (26 ° C.) (step S220). ..

  When the room temperature reaches the set temperature (26 ° C.) in about 15 to 40 minutes (YES in step S220), the microcomputer 89 reduces the rotation speed of the compressor 84 so that the room temperature can be maintained at a low rotation speed. Adjust to. At this time, since the power consumption of the compressor 84 is reduced, it is possible to immediately switch to the DC operation mode. However, at this point, the temperature of the air in the room is 26 ° C., but the ceiling, floor, and walls still retain heat. Therefore, if the compressor is stopped for about 3 minutes when switching the operation mode, the room temperature rises by about 2 ° C. during that time. During that time, the indoor fan 65 is rotating, but the circulation of the refrigerant is stopped, so that the indoor environment becomes uncomfortable.

  Therefore, the microcomputer 89 continues to operate the compressor 84 with the AC power supply for a while after the room temperature reaches the set temperature. Then, when T time (for example, T = 20 minutes) has elapsed since the room temperature reached the set temperature (YES in step S260), the microcomputer 89 can switch the operation mode from the AC operation mode to the DC operation mode. It is determined that there is (step S290), that is, the AC / DC switching condition is satisfied (YES in step S115).

  As a result, the microcomputer 89 stops the compressor 84 (step S130), switches the switching circuit from the AC side to the DC side (step S135), and after about 3 minutes (this time depends on the specifications of the compressor). 84 is restarted (step S140). As described above, after 20 minutes have passed since the room temperature reached the set temperature, the operation mode is switched from the AC operation to the DC operation, so that the temperature rise of the room temperature at the time of the operation mode switching can be suppressed within, for example, about 0.5 ° C. You can

  In the above step S220, whether or not the room temperature has reached the set temperature is used as the criterion, but instead, the room temperature has reached the temperature range corresponding to the set temperature (for example, the set temperature ± 0.5 ° C.). Whether or not it may be used as a criterion. In this case, in step S260, it is determined that the operation mode can be switched after the elapse of T time from the room temperature reaching the temperature range.

  Further, in the heating operation as well, as in the case of the cooling operation, a predetermined T time after the room temperature reaches the temperature range corresponding to the set temperature (this T time does not have to be the same as the case of the cooling operation). After lapse of, the operation mode is switched from the AC operation mode to the DC operation mode. As a result, the operation modes are switched after the heat is sufficiently accumulated on the ceiling, the floor, and the walls, so that the temperature decrease of the room temperature at the time of switching the operation modes can be suppressed to, for example, about 2 ° C or less.

[effect]
As described above, according to the air conditioner of the first embodiment, even if the room temperature reaches the temperature range corresponding to the set temperature, the drive of the compressor based on the AC power supply is maintained for a while, and the predetermined T time is maintained. After a lapse of time, the power supply source to the compressor is switched from the AC current to the DC power supply. With this, when the power source is switched from the AC power source to the DC power source, fluctuations in room temperature can be suppressed as much as possible.

<Second Embodiment>
[Features and effects]
In the second embodiment, the case where the outside air temperature during the cooling operation is higher or the outside air temperature during the heating operation is lower will be described.

  If the outside air temperature during cooling operation is higher, change the duration of AC operation after the room temperature reaches the temperature range corresponding to the set temperature from T time (about 20 minutes) to a longer time (T + α time) To do. As a result, the heat stored in the ceiling, floor, and walls of the room can be radiated more sufficiently, and as a result, it is possible to suppress an increase in room temperature when switching the operation mode even when the outside air temperature is higher. ..

  If the outside air temperature during heating operation is lower, change the duration of AC operation after the room temperature reaches the temperature range corresponding to the set temperature from T time (about 20 minutes) to a longer time (T + α time) To do. As a result, the ceiling, floor, and walls of the room can be further sufficiently accumulated with heat, and as a result, it is possible to suppress a decrease in room temperature when switching the operation mode even when the outside air temperature is lower.

  Hereinafter, the AC / DC switching condition will be specifically described with reference to the drawings. Note that the device configuration of the air conditioner is the same as in the case of FIGS. 1 to 3, and the schematic operation is the same as that of FIG. 4, so description thereof will not be repeated.

[AC / DC switching condition for cooling operation]
FIG. 6 is a flowchart showing a procedure for determining whether the AC / DC switching condition is satisfied during the cooling operation in the air conditioner of the second embodiment.

  With reference to FIGS. 2 to 4 and 6, after the start of the cooling operation (step S110), the microcomputer 89 determines whether the room temperature read by the temperature sensor 34 has reached the set temperature (step S110). S220). When the room temperature reaches the set temperature (YES in step S220), the microcomputer 89 reads the outside air temperature by the temperature sensor 32 (step S230) and determines whether the outside air temperature is higher than a predetermined temperature set in advance. (Step S240).

  When the outside air temperature is equal to or lower than the specified temperature (NO in step S240), the microcomputer 89 starts the AC operation mode after the elapse of a predetermined time T after the room temperature reaches the set temperature (YES in step S260). It is determined that the operation mode can be switched to the DC operation mode (step S290), that is, the AC / DC switching condition is satisfied (YES in step S115).

  On the other hand, when the outside air temperature is higher than the specified temperature (YES in step S240), the microcomputer 89 performs the AC operation after the elapse of a predetermined T + α time after the room temperature reaches the set temperature (YES in step S260). It is determined that the operation mode can be switched from the mode to the DC operation mode (step S290), that is, the AC / DC switching condition is satisfied (YES in step S115).

  In the above step S220, whether or not the room temperature has reached the set temperature is used as the criterion, but instead, the room temperature has reached the temperature range corresponding to the set temperature (for example, the set temperature ± 0.5 ° C.). Whether or not it may be used as a criterion. In this case, in step S260 (S270), it is determined that the operation mode can be switched after the elapse of T time (T + α time) after the room temperature reaches the temperature range.

[AC / DC switching conditions for heating operation]
FIG. 7: is a flowchart which shows the procedure for determining whether AC / DC switching conditions are satisfy | filled at the time of heating operation in the air conditioner of 2nd Embodiment.

  With reference to FIGS. 2 to 4 and 7, after the heating operation is started (step S110), the microcomputer 89 determines whether or not the room temperature read by the temperature sensor 34 has reached the set temperature (step S110). S220). When the room temperature reaches the set temperature (YES in step S220), the microcomputer 89 reads the outside air temperature by the temperature sensor 32 (step S230) and determines whether the outside air temperature is lower than a predetermined temperature set in advance. (Step S240A). This specified temperature is a lower temperature (for example, 5 ° C.), unlike the case of the cooling operation (for example, 35 ° C.).

  When the outside air temperature is equal to or higher than the specified temperature (NO in step S240A), the microcomputer 89 starts the AC operation mode after the elapse of a predetermined T time after the room temperature reaches the set temperature (YES in step S260). It is determined that the operation mode can be switched to the DC operation mode (step S290), that is, the AC / DC switching condition is satisfied (YES in step S115).

  On the other hand, when the outside air temperature is lower than the specified temperature (YES in step S240A), the microcomputer 89 performs the AC operation after the elapse of a predetermined T + α time after the room temperature reaches the set temperature (YES in step S260). It is determined that the operation mode can be switched from the mode to the DC operation mode (step S290), that is, the AC / DC switching condition is satisfied (YES in step S115).

  In the above step S220, whether or not the room temperature has reached the set temperature is used as the criterion, but instead, the room temperature has reached the temperature range corresponding to the set temperature (for example, the set temperature ± 0.5 ° C.). Whether or not it may be used as a criterion. In this case, in step S260 (S270), it is determined that the operation mode can be switched after the elapse of T time (T + α time) after the room temperature reaches the temperature range.

<Third Embodiment>
[Features and effects]
In the third embodiment, in both the cooling operation and the heating operation, the difference (absolute value) between the room temperature and the set temperature at the start of operation of the compressor is a predetermined temperature difference (for example, 3 ° C.). Within) will be described. In this case, the waiting time from when the room temperature reaches the set temperature to when the operation mode is switched is set shorter than the T time of the first embodiment (T-β time). This is because when the temperature difference between the room temperature and the set temperature is relatively small, it is considered that the temperature change at the time of switching the operation mode is also relatively small. As a result, the energy saving performance of the air conditioner can be improved by shifting to DC operation earlier.

  Hereinafter, the AC / DC switching condition will be specifically described with reference to the drawings. Note that the device configuration of the air conditioner is the same as in the case of FIGS. 1 to 3, and the schematic operation is the same as that of FIG. 4, so description thereof will not be repeated.

[AC / DC switching condition]
FIG. 8 is a flowchart showing a procedure for determining whether the AC / DC switching condition is satisfied during the cooling operation in the air conditioner of the third embodiment.

  2 to 4 and 8, the microcomputer 89 reads the room temperature at the start of operation of the compressor 84 with the temperature sensor 34, calculates the absolute value of the difference between the room temperature and the set temperature, and stores it. .. Next, it is determined whether or not the room temperature read by the temperature sensor 34 after the operation of the compressor 84 has reached the set temperature (step S220). When the room temperature reaches the set temperature (YES in step S220), the microcomputer 89 determines whether or not the absolute value of the difference between the room temperature and the temperature sensor 32 at the start of operation of the compressor is smaller than a predetermined specified value. It is determined (step S250).

  When the absolute value of the difference between the room temperature at the start of operation of the compressor and the temperature sensor 32 is equal to or greater than the predetermined specified value (NO in step S250), the microcomputer 89 determines that the room temperature has reached the set temperature. It is possible to switch the operation mode from the AC operation mode to the DC operation mode after the elapse of a predetermined T time from (YES in step S260) (step S290), that is, the AC / DC switching condition is satisfied ( It is determined to be YES) in step S115.

  On the other hand, when the absolute value of the difference between the room temperature at the start of operation of the compressor and the temperature sensor 32 is smaller than the predetermined specified value (YES in step S250), the microcomputer 89 determines that the room temperature is the set temperature. After a lapse of a predetermined T-β time after reaching (YES in step S280), the operation mode can be switched from the AC operation mode to the DC operation mode (step S290), that is, the AC / DC switching condition is It is determined that the condition is satisfied (YES in step S115).

  The third embodiment can be combined with the second embodiment. For example, when the outside air temperature is higher than the specified temperature during the cooling operation and the difference between the room temperature at the start of the operation of the compressor and the set temperature is smaller than the specified temperature difference, the AC / DC is reached after the room temperature reaches the set temperature. The waiting time until the operation mode is switched is set to T + α-β.

  In the above step S220, whether or not the room temperature has reached the set temperature is used as the criterion, but instead, the room temperature has reached the temperature range corresponding to the set temperature (for example, the set temperature ± 0.5 ° C.). Whether or not it may be used as a criterion. Also in this case, in step S260 (S280), it is determined that the operation mode can be switched after the elapse of T time (T-β time) after the room temperature reaches the temperature range.

<Fourth Embodiment>
[Outline and effects]
In the fourth embodiment, a procedure of switching between the DC power supply and the AC power supply when the heating operation is restarted after the heating operation is switched to the defrosting operation will be described. The defrosting operation is an operation for removing frost when frost is accumulated in the outdoor heat exchanger due to the outdoor environment during the heating operation. In the method called reverse defrosting, the heating operation is switched to the cooling operation (however, the indoor fan and the outdoor fan are stopped) to warm the outdoor heat exchanger and defrost it. Therefore, the room cannot be heated during the defrosting operation.

  The defrosting operation is performed by supplying power from an AC power supply (AC operation mode). The reason is as follows. First, in order to complete the defrosting time as short as possible, the rotation speed of the compressor is increased during the defrosting operation. This is because the power consumption of the compressor is large. Further, when the DC power supply is a storage battery, it is necessary to switch to the power supply from the AC power supply when the remaining amount of the storage battery becomes low. This is because if such a situation occurs during the defrosting operation, the defrosting operation must be forcibly ended in an incomplete defrosting state.

  Since the room temperature often decreases after the defrosting operation, it is necessary to increase the rotation speed of the compressor. Therefore, the compressor is started by the power supply from the AC power supply. After that, even if the room temperature reaches the set temperature, the compressor is continuously operated in the AC operation mode for a while until the ceiling, walls, and floor in the room are sufficiently warmed. When T time (for example, about 20 minutes) elapses after the room temperature reaches the set temperature, the AC operation mode is switched to the DC operation mode.

  As described in the second embodiment, when the outside air temperature is lower than the specified temperature, the room temperature is lowered at the time of switching to the DC operation mode by further warming the ceiling, floor, and walls. Need to be prevented. For this reason, the operating mode is switched from the alternating-current operating mode to the direct-current operating mode when the time T + α longer than the time T has elapsed since the room temperature reached the set temperature.

[Switching between DC / AC operation mode during defrosting operation]
FIG. 9: is a flowchart which shows the switching procedure of DC / AC operation mode at the time of defrosting operation in the air conditioner of 4th Embodiment. The device configuration of the air conditioner is the same as in the case of FIGS. 1 to 3, and the outline of the procedure for switching the DC / AC operation modes other than the defrosting operation is the same as that in FIG. 4, and therefore the description thereof will not be repeated.

  With reference to FIGS. 2 to 4 and 9, first, it is assumed that the heating operation is being executed in the DC operation mode (step S300). When the microcomputer 89 determines that the outdoor heat exchanger 35 is frosted (YES in step S305), it stops the compressor 84, the outdoor fan 86, and the indoor fan 65 (step S310). When the temperature of the outdoor heat exchanger 35 is lower than the normal temperature according to the outdoor temperature, it can be determined that frost has formed.

  After that, the microcomputer 89 switches the four-way valve 90 so that the refrigerant compressed by the compressor 84 is supplied to the outdoor heat exchanger 35 side, switches the switching circuit 76 to the AC power source side, and restarts the compressor 84. to start. As a result, the defrosting operation is started (step S315). There is a predetermined waiting time (about 2 to 3 minutes) after the compressor 84 is stopped and before it is restarted.

  Next, when the microcomputer 89 determines that the defrosting of the outdoor heat exchanger 35 is completed because the temperature of the outdoor heat exchanger 35 becomes higher than 0 ° C. (YES in step S320), the compressor 89 The AC operation of 84 is stopped (step S325).

  After that, the microcomputer 89 switches the four-way valve 90 so that the refrigerant compressed by the compressor 84 is supplied to the indoor heat exchanger 36 side, and operates the compressor 84, the outdoor fan 86, and the indoor fan 65. Start. As a result, the heating operation is started in the AC operation mode (step S330).

  After the heating operation is started, the microcomputer 89 reads the temperature inside the room by the temperature sensor 34 in FIG. 2 (step S335 in FIG. 5) and determines whether the room temperature has reached the set temperature (step S340).

  The microcomputer 89 can switch the operation mode from the AC operation mode to the DC operation mode (step S350) after a lapse of a predetermined time T after the room temperature reaches the set temperature (YES in step S345), that is, , AC / DC switching conditions are satisfied (YES in step S115).

  The above steps S335 to S350 can be replaced with FIG. 7 of the second embodiment or FIG. 8 of the third embodiment.

<Fifth Embodiment>
[Overview]
In the first to fourth embodiments, the operation mode is switched from the AC operation mode to the DC operation mode after a lapse of T time (T + α or T−β in some cases) after the room temperature reaches the set temperature. On the other hand, in the fifth embodiment, when T time (in some cases, T + α or T−β) elapses after the frequency of the compressor 84 is reduced to the specified frequency, the AC operation mode is switched to the DC operation mode. The operation mode is switched.

  When the frequency of the compressor 84 is controlled by the feedback control, when the room temperature approaches the set temperature, the frequency of the compressor 84 decreases to such an extent that the room temperature can be maintained at the set temperature. Therefore, essentially the same control is performed when the AC / DC operation mode is switched based on the room temperature and when the AC / DC operation mode is switched based on the frequency of the compressor 84. It will be. In the following, changes in the AC / DC operation mode switching based on the frequency of the compressor 84 from the previous embodiments will be described. The same or corresponding steps will be denoted by the same reference symbols and description will not be repeated.

[Modification of First Embodiment]
FIG. 10 is a flowchart of the modified example of FIG. In FIG. 10, step S220B is provided instead of steps S210 and S220 of FIG. In step S220B, it is determined whether the frequency of the compressor 84 has dropped to the specified frequency. If the frequency of the compressor 84 has dropped to the specified frequency (YES in step S220B), the process proceeds to step S260B.

  In FIG. 10, step S260B is provided instead of step S260 of FIG. In step S260B, it is determined whether or not a predetermined T time has elapsed since the frequency of the compressor 84 dropped to the specified frequency. When the time T has elapsed after the frequency of the compressor 84 has dropped to the specified frequency (YES in step S260B), the microcomputer 89 determines that the operation mode can be switched from the AC operation mode to the DC operation mode ( Step S290).

[Modification of Second Embodiment]
FIG. 11 is a flowchart of the modified example of FIG. FIG. 12 is a flowchart of the modified example of FIG. 7. 11 and 12, step S270B is provided instead of step S270 of FIGS. 6 and 7 in addition to the same changes as in the case of FIG.

  Step 270B is executed in the cooling operation of FIG. 11 when the outside air temperature is higher than the specified temperature (YES in step S240), and in the heating operation of FIG. 12 when the outside air temperature is lower than the specified temperature (YES in step S240A). To be done. In step 270B, it is determined whether or not the time T + α longer than the time T has elapsed since the frequency of the compressor 84 decreased to the specified frequency. When T + α time has elapsed after the frequency of the compressor 84 has dropped to the specified frequency (YES in step S270B), the microcomputer 89 determines that the operation mode can be switched from the AC operation mode to the DC operation mode. (Step S290).

[Modification of Third Embodiment]
FIG. 13 is a flowchart of the modified example of FIG. In FIG. 13, step S280B is provided instead of step S280 in FIG. 8 in addition to the same changes as in the case of FIG.

  Step S280B is executed when the difference between the room temperature and the set temperature at the start of operation of the compressor is smaller than the specified value (YES in step S250), and the time T has passed after the frequency of the compressor 84 has dropped to the specified frequency. It is determined whether a shorter T-β time has elapsed. When the T-β time has elapsed since the frequency of the compressor 84 decreased to the specified frequency (YES in step S280B), the microcomputer 89 can switch the operation mode from the AC operation mode to the DC operation mode. Is determined (step S290).

[effect]
As described above, in the fifth embodiment, when the T time (in some cases, T + α or T−β) elapses after the frequency of the compressor 84 decreases to the specified frequency, the AC operation mode is switched to the DC operation mode. The mode is switched. Also in this case, the same effects as those of the first to fourth embodiments already described can be obtained.

<Appendix>
Hereinafter, some of the inventions disclosed by the above embodiments will be listed.

  [1] An air conditioner 50 including the refrigerant circuit 10, the power supply circuit 20, and the control unit 89 is provided. The refrigerant circuit 10 includes an outdoor heat exchanger 35, an indoor heat exchanger 36, an expansion valve 88, and a compressor 84. The power supply circuit 20 is connected to an AC power supply and a DC power supply, and drives the compressor 84 based on only one of the AC power supply and the DC power supply. The control unit 89 starts the compressor 84 based on the AC power source, temporarily stops the compressor 84 when a predetermined switching condition is satisfied, and restarts the compressor 84 based on the DC power source. The power supply circuit 20 is controlled. The above-mentioned switching conditions include a condition that a predetermined first time T has elapsed after the room temperature reached the temperature region corresponding to the set temperature.

  According to the above configuration, even if the room temperature reaches the temperature range corresponding to the set temperature, the driving of the compressor based on the AC power supply is maintained for a while, and the power is supplied to the compressor after a predetermined T time elapses. The source is switched from alternating current to direct current power. With this, when the power source is switched from the AC power source to the DC power source, fluctuations in room temperature can be suppressed as much as possible.

  [2] In the above [1], the switching condition is that, when the outside air temperature is equal to or lower than the first specified temperature during the cooling operation, the first time T elapses after the room temperature reaches the temperature range, When the outside air temperature is higher than the first specified temperature during the cooling operation, the time obtained by adding the predetermined second time α to the first time T has elapsed since the room temperature reached the temperature range. is there.

  According to the above configuration, when the outside air temperature during the cooling operation is relatively high, the waiting time from when the room temperature reaches the temperature range to when the power supply source is switched is increased. As a result, the heat stored in the wall, ceiling, and floor of the room is sufficiently radiated, so that when the power supply is switched from the AC power supply to the DC power supply, fluctuations in room temperature can be suppressed as much as possible.

  [3] In the above [1], the switching condition is that, when the outside air temperature is equal to or higher than the second specified temperature during the heating operation, the first time T elapses after the room temperature reaches the temperature range, When the outside air temperature is lower than the second specified temperature during the heating operation, the time obtained by adding the predetermined second time α to the first time T has elapsed since the room temperature reached the temperature range. is there.

  According to the above configuration, when the outside air temperature during the heating operation is relatively low, the waiting time from when the room temperature reaches the temperature range to when the power supply source is switched is increased. As a result, the walls, ceiling, and floor of the room are sufficiently stored with heat, so that when the power source is switched from the AC power source to the DC power source, fluctuations in room temperature can be suppressed as much as possible.

  [4] In the above [1], when the absolute value of the temperature difference between the room temperature when the compressor 84 is started and the set temperature is equal to or more than the specified temperature difference, the switching condition is that the room temperature reaches the above temperature range. When the absolute value of the temperature difference between the room temperature at the time of starting the compressor and the set temperature is smaller than the specified temperature difference because the first time T has elapsed, the first time after the room temperature reaches the above temperature range That is, the time obtained by subtracting the predetermined third time β from the time T has passed.

  When the temperature difference between the room temperature and the set temperature is relatively small as described above, it is considered that the temperature change at the time of switching the operation mode is also relatively small. Therefore, the energy saving performance of the air conditioner can be improved by shifting to the DC operation earlier.

  [5] An air conditioner 50 including the refrigerant circuit 10, the power supply circuit 20, and the control unit 89 is provided. The refrigerant circuit 10 includes an outdoor heat exchanger 35, an indoor heat exchanger 36, an expansion valve 88, and a compressor 84. The power supply circuit 20 is connected to an AC power supply and a DC power supply, and drives the compressor 84 by an inverter based on only one of the AC power supply and the DC power supply. The control unit 89 starts the compressor 84 based on the AC power supply, temporarily stops the compressor 84 when a predetermined switching condition is satisfied, and restarts the compressor based on the DC power supply. Control the circuit 20. The switching condition includes a condition that the predetermined first time T has elapsed after the frequency of the compressor 84 becomes equal to or lower than the specified frequency due to the room temperature approaching the set temperature.

  The configuration of the above [5] corresponds to the above [1] and has the same effect as the above [1].

  [6] In the above [5], the switching condition is that when the outside air temperature is equal to or lower than the first specified temperature during the cooling operation, the first time T elapses after the frequency of the compressor 84 becomes equal to or lower than the specified frequency. That is, when the outside air temperature is higher than the first specified temperature during the cooling operation, the second time α predetermined in the first time T after the frequency of the compressor 84 becomes equal to or lower than the specified frequency. It means that the time obtained by adding is elapsed.

  The configuration of the above [6] corresponds to the above [2] and has the same effect as the above [2].

  [7] In the above [5], the switching condition is that when the outside air temperature is equal to or higher than the second specified temperature during the heating operation, the first time T elapses after the frequency of the compressor 84 becomes equal to or lower than the specified frequency. That is, when the outside air temperature is lower than the second specified temperature during the heating operation, the second time α predetermined in the first time T after the frequency of the compressor 84 becomes equal to or lower than the specified frequency. It means that the time obtained by adding is elapsed.

  The above configuration [7] corresponds to the above [3] and has the same effect as the above [3].

  [8] In the above [5], the switching condition is that when the absolute value of the temperature difference between the room temperature at startup of the compressor 84 and the set temperature is equal to or greater than the specified temperature difference, the frequency of the compressor is equal to or less than the specified frequency. When the absolute value of the temperature difference between the room temperature and the set temperature when the compressor 84 is started is smaller than the specified temperature difference, the frequency of the compressor 84 is specified. This means that the time obtained by subtracting the predetermined third time β from the first time T has elapsed since the frequency became equal to or lower than the frequency.

  The above configuration [8] corresponds to the above [4] and has the same effect as the above [4].

  [9] In the above [1], [3] to [5], [7], and [8], the refrigerant circuit 10 switches the operation mode of the air conditioner between the cooling operation and the heating operation. It further includes a four-way valve 90 that switches the flow path of the refrigerant compressed by the outdoor heat exchanger 35 side and the indoor heat exchanger 36 side. When the control unit 89 detects the frost formation of the outdoor heat exchanger 35 during the heating operation by driving the compressor 84 based on the DC power source, the control unit 89 temporarily stops the compressor 84 and When the valve 90 is switched to the outdoor heat exchanger 35 side and then the power supply circuit 20 is controlled so as to restart the compressor 84 based on the AC power supply, and thereafter, when defrosting completion of the outdoor heat exchanger 35 is detected. Controls the power supply circuit so that the compressor 84 is temporarily stopped, the four-way valve 90 is switched to the indoor heat exchanger 36 side, and then the compressor 84 is restarted based on the AC power supply, and then the above switching conditions are set. When is satisfied, the compressor 84 is temporarily stopped, and the power supply circuit 20 is controlled so as to restart the compressor 84 based on the DC power supply.

  Also in the case of restarting the compressor after the defrosting operation, when the switching condition similar to the above is satisfied, the source of power to the compressor can be switched from the AC power supply to the DC power supply.

  The embodiments disclosed this time are to be considered as illustrative in all points and not restrictive. The scope of the present invention is shown not by the above description but by the scope of the claims, and is intended to include meanings equivalent to the scope of the claims and all modifications within the scope.

  10 refrigerant circuit, 20 power supply circuit, 21 outdoor unit power supply circuit, 30, 31, 32, 33, 34 temperature sensor, 35 outdoor heat exchanger, 36 indoor heat exchanger, 41 storage battery, 50 air conditioner, 51 outlet plug , 60 indoor unit, 62 indoor unit power supply circuit, 65 indoor fan, 70 outdoor unit, 75 full-wave rectifier circuit, 76 switching circuit, 81 step-up converter, 82 capacitor, 83,85 inverter, 84 compressor, 86 outdoor fan, 87 step-down converter, 88 expansion valve, 89 microcomputer (control unit), 90 four-way valve.

Claims (8)

A refrigerant circuit including an outdoor heat exchanger, an indoor heat exchanger, an expansion valve, and a compressor,
A power supply circuit that is connected to an AC power supply and a DC power supply and that drives the compressor based on only one of the AC power supply and the DC power supply;
The power supply circuit for starting the compressor based on the AC power supply, temporarily stopping the compressor when a predetermined switching condition is satisfied, and restarting the compressor based on the DC power supply. And a control unit for controlling
The switching condition is that, when the outside air temperature is equal to or lower than the first specified temperature during the cooling operation , a predetermined first time elapses after the room temperature reaches a temperature region corresponding to the set temperature , When the outside air temperature is higher than the first specified temperature during the cooling operation, it means that the time obtained by adding the second time set in advance to the first time has elapsed since the room temperature reached the temperature range. There is an air conditioner. A refrigerant circuit including an outdoor heat exchanger, an indoor heat exchanger, an expansion valve, and a compressor,
A power supply circuit that is connected to an AC power supply and a DC power supply and that drives the compressor based on only one of the AC power supply and the DC power supply;
The power supply circuit for starting the compressor based on the AC power supply, temporarily stopping the compressor when a predetermined switching condition is satisfied, and restarting the compressor based on the DC power supply. And a control unit for controlling
The switching condition is that, when the outside air temperature is equal to or higher than the second specified temperature during the heating operation , a predetermined first time elapses after the room temperature reaches a temperature region corresponding to the set temperature , When the outside air temperature is lower than the second specified temperature during the heating operation, the time obtained by adding a predetermined second time to the first time has elapsed since the room temperature reached the temperature range. There is an air conditioner. A refrigerant circuit including an outdoor heat exchanger, an indoor heat exchanger, an expansion valve, and a compressor,
A power supply circuit that is connected to an AC power supply and a DC power supply and that drives the compressor based on only one of the AC power supply and the DC power supply;
The power supply circuit for starting the compressor based on the AC power supply, temporarily stopping the compressor when a predetermined switching condition is satisfied, and restarting the compressor based on the DC power supply. And a control unit for controlling
The switching condition, wherein when the absolute value of the temperature difference between the compressor startup at room temperature and the set temperature is equal to or greater than the prescribed temperature difference, determined in advance after reaching temperature range room temperature according to the set temperature When the absolute value of the temperature difference between the room temperature at the time of starting the compressor and the set temperature is smaller than the specified temperature difference, the room temperature reaches the temperature range. The air conditioner, which is obtained by subtracting a predetermined third time from the first time . A refrigerant circuit including an outdoor heat exchanger, an indoor heat exchanger, an expansion valve, and a compressor,
A power supply circuit that is connected to an AC power supply and a DC power supply and drives the compressor by an inverter based on only one of the AC power supply and the DC power supply,
The power supply circuit for starting the compressor based on the AC power supply, temporarily stopping the compressor when a predetermined switching condition is satisfied, and restarting the compressor based on the DC power supply. And a control unit for controlling
When the outside air temperature is equal to or lower than the first specified temperature during the cooling operation , the switching condition is a first predetermined value after the frequency of the compressor becomes equal to or lower than the specified frequency due to the room temperature approaching the set temperature. It is the passage of time , and when the outside air temperature is higher than the first specified temperature during the cooling operation, it is predetermined in the first time after the frequency of the compressor becomes equal to or lower than the specified frequency. The air conditioner, which is that the time obtained by adding the second time has elapsed . A refrigerant circuit including an outdoor heat exchanger, an indoor heat exchanger, an expansion valve, and a compressor,
A power supply circuit that is connected to an AC power supply and a DC power supply and drives the compressor by an inverter based on only one of the AC power supply and the DC power supply,
The power supply circuit for starting the compressor based on the AC power supply, temporarily stopping the compressor when a predetermined switching condition is satisfied, and restarting the compressor based on the DC power supply. And a control unit for controlling
When the outside air temperature is equal to or higher than the second specified temperature during the heating operation , the switching condition is a first predetermined value after the frequency of the compressor becomes equal to or lower than the specified frequency due to the room temperature approaching the set temperature. It is the passage of time , and when the outside air temperature is lower than the second specified temperature during the heating operation, it is predetermined in the first time after the frequency of the compressor becomes equal to or lower than the specified frequency. The air conditioner, which is that the time obtained by adding the second time has elapsed . A refrigerant circuit including an outdoor heat exchanger, an indoor heat exchanger, an expansion valve, and a compressor,
A power supply circuit that is connected to an AC power supply and a DC power supply and drives the compressor by an inverter based on only one of the AC power supply and the DC power supply,
The power supply circuit for starting the compressor based on the AC power supply, temporarily stopping the compressor when a predetermined switching condition is satisfied, and restarting the compressor based on the DC power supply. And a control unit for controlling
The switching condition, wherein when the absolute value of the temperature difference between the compressor startup at room temperature and the set temperature is equal to or greater than the prescribed temperature difference, the frequency of the compressor is defined frequency by the room temperature approaches the set temperature It means that a predetermined first time has elapsed since the following , and when the absolute value of the temperature difference between the room temperature and the set temperature at the time of starting the compressor is smaller than the specified temperature difference, An air conditioner in which a time obtained by subtracting a third predetermined time from the first time has elapsed since the frequency of the compressor became equal to or lower than the specified frequency . An air conditioner,
A refrigerant circuit including an outdoor heat exchanger, an indoor heat exchanger, an expansion valve, a four-way valve, and a compressor,
A power supply circuit that is connected to an AC power supply and a DC power supply and that drives the compressor based on only one of the AC power supply and the DC power supply;
And a control unit,
The four-way valve, in order to switch the operation mode of the air conditioner between cooling operation and heating operation, the flow path of the refrigerant compressed by the compressor is set to the outdoor heat exchanger side and the indoor heat exchanger side. Switch with
The control unit starts the compressor based on the AC power supply, temporarily stops the compressor when a predetermined switching condition is satisfied, and restarts the compressor based on the DC power supply. and controls the power supply circuit as,
The switching condition is seen including a condition that has passed the first predetermined time after reaching the temperature region the room temperature according to the set temperature,
The control unit is
When frosting of the outdoor heat exchanger is detected during heating operation by driving the compressor based on the DC power source, the compressor is temporarily stopped and the four-way valve is Control the power circuit to restart the compressor based on the AC power source after switching to the outdoor heat exchanger side,
After that, when the completion of defrosting of the outdoor heat exchanger is detected, the compressor is temporarily stopped, the four-way valve is switched to the indoor heat exchanger side, and then the compressor is operated based on the AC power source. Controlling the power supply circuit to restart,
After that, when the switching condition is satisfied, the compressor is temporarily stopped, and the power supply circuit is controlled so as to restart the compressor based on the DC power supply . An air conditioner,
A refrigerant circuit including an outdoor heat exchanger, an indoor heat exchanger, an expansion valve, a four-way valve, and a compressor,
A power supply circuit that is connected to an AC power supply and a DC power supply and drives the compressor by an inverter based on only one of the AC power supply and the DC power supply,
And a control unit,
The four-way valve, in order to switch the operation mode of the air conditioner between cooling operation and heating operation, the flow path of the refrigerant compressed by the compressor is set to the outdoor heat exchanger side and the indoor heat exchanger side. Switch with
The control unit starts the compressor based on the AC power supply, temporarily stops the compressor when a predetermined switching condition is satisfied, and restarts the compressor based on the DC power supply. and controls the power supply circuit as,
The switching condition is seen including a condition that has passed the first predetermined time from when the following the frequency of the compressor is defined frequency by approaching the room temperature set temperature,
The control unit is
When frosting of the outdoor heat exchanger is detected during heating operation by driving the compressor based on the DC power source, the compressor is temporarily stopped and the four-way valve is Control the power circuit to restart the compressor based on the AC power source after switching to the outdoor heat exchanger side,
After that, when the completion of defrosting of the outdoor heat exchanger is detected, the compressor is temporarily stopped, the four-way valve is switched to the indoor heat exchanger side, and then the compressor is operated based on the AC power supply. Controlling the power supply circuit to restart,
After that, when the switching condition is satisfied, the compressor is temporarily stopped, and the power supply circuit is controlled so as to restart the compressor based on the DC power supply .

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