JP5984732B2 - Air conditioner - Google Patents

Description

  The present invention relates to an air conditioner.

  Conventionally, in an air conditioner, an indoor unit and an outdoor unit always communicate with each other even during operation standby, and power of the indoor unit and the outdoor unit is consumed. Therefore, Patent Document 1 below discloses a technique for reducing standby power by not supplying commercial power between a signal line and a common line by opening a power line and a signal line by an outdoor activation relay during operation standby. ing.

JP 2010-243051 A

  However, according to the above-described conventional technology, there is a problem in that reactive power is consumed by the noise filter of the outdoor unit when the indoor unit and the outdoor unit are communicating. In addition, depending on the position of the noise filter, there is a problem that reactive power is consumed even during operation standby when communication is not performed.

  The present invention has been made in view of the above, and an object of the present invention is to obtain an air conditioner that can reduce reactive power consumed by an outdoor unit when the outdoor unit is on standby while the indoor unit is in operation. And

  In order to solve the above-described problems and achieve the object, the present invention includes an indoor unit and an outdoor unit, and the indoor unit and the outdoor unit are configured by three cores of a power line, a common line, and a signal line. An air conditioner that is connected and feeds power from a commercial power source supplied to either the outdoor unit or the indoor unit to the other through the power line and a common line, wherein the outdoor unit is A first power supply relay that opens and closes a connection between the commercial power source and the first outdoor rectifier for the outdoor control unit, and a second that opens and closes a connection between the commercial power source and the second outdoor rectifier for the inverter circuit. The inverter circuit noise filter is arranged closer to the second outdoor rectification unit than the second power supply relay.

  According to the present invention, there is an effect that the reactive power consumed by the outdoor unit can be reduced when the outdoor unit is on standby while the indoor unit is in operation.

FIG. 1 is a block diagram of the electrical system when the air conditioner is on standby. FIG. 2 is an electrical system block diagram when one indoor unit of the air conditioner is activated. FIG. 3 is an electrical system block diagram when one indoor unit of the air conditioner is in operation. FIG. 4 is a flowchart showing the operation of the indoor unit. FIG. 5 is a flowchart showing the operation of the outdoor unit.

  Embodiments of an air conditioner according to the present invention will be described below in detail with reference to the drawings. Note that the present invention is not limited to the embodiments.

Embodiment.
FIG. 1 is an electrical system block diagram of an air conditioner according to the present embodiment.
As shown in FIG. 1, in the present embodiment, the air conditioner 1 includes a plurality of indoor units.
Hereinafter, a case where two indoor units A2 and B3 are provided will be described.
The number of indoor units is not limited to this, and may be two or more.

The indoor units A2 and B3 and the outdoor unit 4 are connected through a power line 14, a power signal common line 15, and a signal line 16, respectively.
The outdoor terminal block 37 of the outdoor unit 4 includes terminals S1, S2, and S3 corresponding to the indoor units A2 and B3, respectively.

The commercial power supply 13 is connected to the terminals L and N of the outdoor terminal block 37 of the outdoor unit 4.
The terminal L of the outdoor terminal block 37 is connected to the terminal S1 of the outdoor terminal block 37.
The terminal N of the outdoor terminal block 37 is connected to the terminal S2 of the outdoor terminal block 37.
Thereby, the electric power from the commercial power supply 13 supplied to the terminals L and N of the outdoor terminal block 37 is transmitted from the terminals S1 and S2 of the outdoor terminal block 37 via the power supply line 14 and the power supply signal common line 15 to the room. Supplied to terminals S1 and S2 of indoor terminal block 36 of machines A2 and B3.

The outdoor unit 4 includes an outdoor communication circuit unit 31 according to the number of connected indoor units.
Each outdoor communication circuit unit 31 has one end connected to the communication circuit power supply unit 30 and the other end connected to a terminal S3 to which the signal line 16 of the indoor unit corresponding to the outdoor communication circuit unit 31 is connected.

The outdoor unit 4 includes a diode 33 and power supply cutoff relays (here, power supply cutoff relays A34 and B35) according to the number of connected indoor units.
Each of the power supply cutoff relays A34 and B35 has one end connected to the inrush current prevention relay coil 32 via the diode 33, and the other end connected to the signal line 16 of the indoor unit corresponding to the outdoor communication circuit unit 31. To the terminal S3.
By using the diode 33, it is possible to prevent an influence on other indoor units, such as a voltage applied from the operating indoor unit to the indoor unit on standby. Thereby, in the air conditioner 1, standby power can be reduced safely even when a plurality of indoor units are connected.

  The indoor units A2 and B3 include an indoor rectification unit 5, an indoor control unit 6, an indoor communication circuit unit 7, a power reception method data unit 8, a reception unit 9, an outdoor power supply line 11, and an outdoor activation relay 12.

  The indoor rectification unit 5 is connected to the terminals S1 and S2 of the indoor terminal block 36. The indoor rectification unit 5 converts the AC voltage into an arbitrary DC voltage and supplies it to the indoor control unit 6.

  The indoor communication circuit unit 7 is connected to the terminals S2 and S3 of the indoor terminal block 36. The indoor communication circuit unit 7 communicates with an outdoor communication circuit unit 31 (described later) of the outdoor unit 4 through the signal line 16 and the power signal common line 15.

The power receiving method data unit 8 is connected to the indoor control unit 6. The power reception method data unit 8 includes a switchable means such as a storage device or a switch (not shown), for example, and recognizes the on / off of the switch when the power is turned on, so that the indoor power reception method and Information for identifying the outdoor power receiving method is stored.
In the power receiving method data section 8, the outdoor unit 4 connected to the indoor units A2 and B3 includes outdoor relays A21 and B22 (described later) and inrush current preventing relays A17 and B18 (described later), Information that identifies whether or not the outdoor unit 4 can reduce standby power at the time (hereinafter referred to as “standby power correspondence information”) is stored.

  The receiving unit 9 is connected to the indoor control unit 6. The receiving unit 9 receives a signal from the remote controller 10 and sends the signal to the indoor control unit 6.

  The indoor control unit 6 operates the outdoor activation relay 12. Further, the indoor control unit 6 operates the indoor communication circuit unit 7 to transmit / receive various operation signals and the like to / from the outdoor unit 4.

  One end of the outdoor power supply line 11 is connected to the terminal S <b> 1 of the indoor terminal block 36, and the other end is connected to the outdoor activation relay 12.

The outdoor activation relay 12 switches the connection between the terminal S3 of the indoor terminal block 36 and the indoor communication circuit unit 7, or the connection between the terminal S3 of the indoor terminal block 36 and the outdoor power supply line 11.
That is, the outdoor activation relay 12 opens and closes the connection between the power line 14 and the signal line 16. When the outdoor activation relay 12 is operated, power from the commercial power supply 13 is supplied between the signal line 16 and the power signal common line 15.
The outdoor activation relay 12 connects the terminal S3 of the indoor terminal block 36 and the indoor communication circuit unit 7 in a steady state, and the terminal S3 of the indoor terminal block 36 and the indoor communication circuit unit 7 are operated by the operation from the indoor control unit 6. And the terminal S3 of the indoor terminal block 36 and the outdoor power supply line 11 are connected.

  Although not shown, the indoor units A2 and B3 are provided with an indoor heat exchanger, an indoor fan, a sensor, a display, and the like as a mechanical system.

  The outdoor unit 4 includes inrush current prevention relays A17 and B18, inrush current prevention resistors A19 and B20, outdoor relays A21 and B22, a noise filter 23, outdoor rectification units A24 and B25, capacitors A26 and B27, an inverter circuit 28, an outdoor control unit. 29, a communication circuit power supply unit 30, an outdoor communication circuit unit 31, an inrush current prevention relay coil 32, a diode 33, and power supply cutoff relays A34 and B35.

One end of the inrush current prevention relay A17 is connected to the terminal L of the outdoor terminal block 37, and the other end is connected to the noise filter 23 via the inrush current prevention resistor A19. The inrush current prevention relay A17 is provided in parallel with the outdoor relay A21.
The inrush current prevention relay A <b> 17 opens a contact (normally open) during operation standby, and closes the contact by an operation from the outdoor control unit 29. The inrush current prevention resistor A19 and the terminal L of the outdoor terminal block 37 are short-circuited.

One end of the inrush current prevention relay B18 is connected to the terminal L of the outdoor terminal block 37, and the other end is connected to the outdoor rectification unit B25 via the inrush current prevention resistor B20. The inrush current prevention relay B18 is provided in parallel with the outdoor relay B22.
The inrush current prevention relay B18 is open at the time of operation standby (normally open), and when the inrush current prevention relay coil 32 is energized, the contact is closed (hereinafter also referred to as “short circuit”), and an inrush current prevention resistance. The outdoor rectification unit B25 and the terminal L of the outdoor terminal block 37 are short-circuited via B20.
That is, the inrush current prevention relay coil 32 closes the inrush current prevention relay B18 when the power of the commercial power supply 13 is supplied between the signal line 16 and the power signal common line 15.

The inrush current prevention resistor A19 is provided in parallel with the outdoor relay A21. One end of the inrush current prevention resistor A19 is connected to the terminal L of the outdoor terminal block 37 via the inrush current prevention relay A17. The other end is connected to the noise filter 23.
The inrush current prevention resistor A19 suppresses the inrush current to the capacitor A26.

The inrush current preventing resistor B20 is provided in parallel with the outdoor relay B22. One end of the inrush current preventing resistor B20 is connected to the terminal L of the outdoor terminal block 37 via the inrush current preventing relay B18. The other end is connected to the outdoor rectification unit B25.
The inrush current prevention resistor B20 suppresses an inrush current to the capacitor B27.

One end of the outdoor relay A <b> 21 is connected to the terminal L of the outdoor terminal block 37, and the other end is connected to the noise filter 23.
The outdoor relay A <b> 21 opens a contact during normal operation (normally open), and closes the contact by an operation from the outdoor control unit 29.

One end of the outdoor relay B22 is connected to the terminal L of the outdoor terminal block 37, and the other end is connected to the outdoor rectification unit B25.
The outdoor relay B <b> 22 opens a contact during normal operation (normally open), and closes the contact by an operation from the outdoor control unit 29.

  The noise filter 23 is connected to the terminal L of the outdoor terminal block 37 via the inrush current prevention relay A17, the inrush current prevention resistor A19, or the outdoor relay A21. The noise filter 23 is connected to the terminal N of the outdoor terminal block 37.

The outdoor rectification unit A24 is connected to the terminal L of the outdoor terminal block 37 via the inrush current prevention relay A17 and the inrush current prevention resistor A19, or the outdoor relay A21, and further the noise filter 23. The outdoor rectification unit A <b> 24 is connected to the terminal N of the outdoor terminal block 37 through the noise filter 23.
The outdoor rectification unit A24 converts the AC voltage supplied from the commercial power supply 13 into an arbitrary DC voltage and supplies it to the capacitor A26 and the inverter circuit 28.

The outdoor rectification unit B25 is connected to the terminal L of the outdoor terminal block 37 via the inrush current prevention relay B18, the inrush current prevention resistor B20, or the outdoor relay B22. The outdoor rectification unit B25 is connected to the terminal N of the outdoor terminal block 37.
The outdoor rectification unit B25 converts the AC voltage supplied from the commercial power supply 13 into an arbitrary DC voltage, and supplies it to the capacitor B27 and the outdoor control unit 29.

  The capacitor A26 is provided between the outputs of the outdoor rectification unit A24, smoothes the output of the outdoor rectification unit A24, and supplies a DC voltage to the inverter circuit 28.

  The capacitor B27 is provided between the outputs of the outdoor rectification unit B25, smoothes the output of the outdoor rectification unit B25, and supplies a DC voltage to the outdoor control unit 29.

  The inverter circuit 28 converts the supplied DC voltage into an AC voltage having an arbitrary frequency and an arbitrary voltage. For example, a motor or the like is connected to the inverter circuit 28 and drives a compressor or the like provided in the outdoor unit 4.

The outdoor control unit 29 operates the outdoor relay B22 and the power supply cutoff relays A34 and B35. Moreover, the outdoor control part 29 operates the outdoor communication circuit part 31, and transmits / receives various operation signals etc. between indoor unit A2 and B3.
The outdoor control unit 29 controls the inrush current prevention relay A17, the outdoor relay A21, and the inverter circuit 28.

One end of the communication circuit power supply unit 30 is connected between the outdoor relay B22 and the outdoor rectification unit B25, and the outdoor terminal block 37 is connected via the inrush current prevention relay B18 and the inrush current prevention resistor B20 or the outdoor relay B22. Connected to terminal L. The other end is connected to the terminal S <b> 2 of the outdoor terminal block 37.
The communication circuit power supply unit 30 converts the AC voltage supplied from the commercial power supply 13 into an arbitrary DC voltage and supplies it to the outdoor communication circuit unit 31. The communication circuit power supply unit 30 is configured by, for example, a half-wave rectifier circuit.

  One end of the outdoor communication circuit unit 31 is connected to the terminal S <b> 3 of the outdoor terminal block 37, and the other end is connected to the communication circuit power supply unit 30. The outdoor communication circuit unit 31 performs communication with the indoor communication circuit units 7 of the indoor units A2 and B3 via the signal line 16 and the power signal common line 15.

One end of the inrush current prevention relay coil 32 is connected to the terminal S2 of the outdoor terminal block 37, and the other end is connected to the terminal S3 of the outdoor terminal block 37 via the diode 33 and the power supply cutoff relay A34 (or B35). The
When energized, the inrush current preventing relay coil 32 closes the contact of the inrush current preventing relay B18.

The diode 33 has one end connected to the inrush current prevention relay coil 32 and the other end connected to the power supply cutoff relays A34 and B35.
The diode 33 prevents a voltage from being applied from the operating indoor unit to the indoor unit waiting for operation.

One end of each of the power supply cutoff relays A34 and B35 is connected to the inrush current prevention relay coil 32 via the diode 33, and the other end is connected to the terminal S3 of the outdoor terminal block 37.
The power supply cutoff relays A34 and B35 close their contacts during normal operation (normally closed), and open the contacts and shut off the energization to the inrush current prevention relay coil 32 by the operation from the outdoor control unit 29.

  Although not shown, the outdoor unit 4 is provided with an outdoor heat exchanger, an outdoor fan sensor, an electromagnetic expansion valve, a refrigerant switching valve, and a compressor as a mechanical system.

The power supply signal common line 15 corresponds to a “common line” in the present invention.
The inrush current prevention relay B18 and the outdoor relay B22 correspond to the “first power supply relay” in the present invention.
Further, the inrush current preventing relay B18 and the outdoor relay B22 correspond to the “first inrush current preventing relay” and the “first outdoor relay” in the present invention, respectively.
The inrush current prevention relay A17 and the outdoor relay A21 correspond to the “second power supply relay” in the present invention.
The inrush current prevention relay A17 and the outdoor relay A21 correspond to the “second inrush current prevention relay” and the “second outdoor relay” in the present invention, respectively.
The inrush current prevention relay coil 32 corresponds to the “power supply relay control unit” in the present invention.
The diode 33 corresponds to the “rectifier” in the present invention.

The configuration of the air conditioner 1 has been described above.
Next, the operation of the air conditioner 1 will be described.

<Operation>
First, the supply of electric power during operation standby of the air conditioner 1 will be described.

The electric power from the commercial power supply 13 supplied to the terminals L and N of the outdoor terminal block 37 is supplied from the terminals S1 and S2 of the outdoor terminal block 37 to the terminals S1 and S2 of the indoor terminal block 36 of the indoor units A2 and B3. The power is supplied via the power line 14 and the power signal common line 15.
Then, the electric power of the commercial power supply 13 supplied to the terminals S1 and S2 of the indoor terminal block 36 is input to each indoor rectifier 5.
The indoor rectification unit 5 converts the input AC voltage into an arbitrary DC voltage. The indoor rectification unit 5 supplies the converted DC voltage to the indoor control unit 6 and the components of the indoor units A2 and B3.

The indoor control unit 6 determines whether the air conditioner 1 is the indoor power reception method or the outdoor power reception method based on the data stored in the power reception method data unit 8, and determines that the air reception method is the outdoor power reception method. When it does, control of the outdoor starting relay 12 is made effective.
Moreover, the indoor control unit 6 can reduce the standby power when the outdoor unit 4 connected to the indoor units A2 and B3 is on standby based on the standby power correspondence information stored in the power receiving method data unit 8. 4 is determined.

The outdoor activation relay 12 connects the indoor communication circuit unit 7 to the terminal S3 of the indoor terminal block 36 and the outdoor communication circuit unit 31 in a steady state.
Thereby, each indoor communication circuit unit 7 is connected to the outdoor unit 4 via the signal line 16 and is communicable with the outdoor unit 4.
Further, at this time, the indoor control unit 6 enters a standby state for receiving an operation start request signal transmitted from the remote controller 10 and received via the receiving unit 9.

The inrush current prevention relays A17 and B18 and the outdoor relays A21 and B22 of the outdoor unit 4 are open at the time of operation standby.
At this time, the outdoor activation relays 12 of the indoor units A2 and B3 open the connection between the terminal S3 of the indoor terminal block 36 and the outdoor power supply line 11.
Therefore, power from the commercial power supply 13 is not supplied between the terminals S2 and S3 of the outdoor terminal block 37, and the inrush current prevention relay coil 32 is in a non-energized state.
Therefore, even if the commercial power supply 13 is supplied to the terminals L and N of the outdoor terminal block 37 of the outdoor unit 4, the inrush current prevention relays A17 and B18 and the outdoor relays A21 and B22 are opened.
For this reason, at the time of operation standby, the power supply to each component connected downstream of the inrush current prevention relays A17 and B18 and the outdoor relays A21 and B22 is cut off, and the standby consumed by the outdoor unit 4 at the time of operation standby It becomes possible to reduce electric power.

  Next, the operation at the time of starting the outdoor unit of the air conditioner 1 and during operation will be described.

FIG. 2 is an electrical system block diagram when one indoor unit of the air conditioner is activated.
FIG. 3 is an electrical system block diagram when one indoor unit of the air conditioner is in operation.
Hereinafter, an operation of starting the outdoor unit 4 when an operation start request is transmitted from the remote controller 10 only to the indoor unit A2 will be described.

When the operation start request is transmitted from the remote controller 10 to the indoor unit A2, the indoor control unit 6 of the indoor unit A2 receives the operation start request via the receiving unit 9.
First, the operation of the indoor unit A2 will be described. FIG. 4 is a flowchart showing the operation of the indoor unit. FIG. 5 is a flowchart showing the operation of the outdoor unit. A description will be given based on each step of the flowchart.

(STEP1)
The indoor control unit 6 receives an operation start request from the remote controller 10 via the receiving unit 9.

(STEP2)
The indoor control unit 6 refers to the information in the power receiving method data unit 8, and when the data from the power receiving method data unit 8 is an outdoor power receiving method, operates the indoor communication circuit unit 7 to communicate with the outdoor unit 4. Let it begin.

(STEP3)
The indoor control unit 6 determines whether communication between the indoor communication circuit unit 7 and the outdoor communication circuit unit 31 of the outdoor unit 4 has been established.
If communication between the indoor communication circuit unit 7 and the outdoor unit 4 can be established, the process proceeds to STEP 9.

(STEP4)
On the other hand, when the communication between the indoor communication circuit unit 31 and the outdoor unit 4 cannot be established in STEP 3, the indoor control unit 6 operates (ON) the outdoor activation relay 12 to connect the terminal S3 of the indoor terminal block 36 to the terminal S3. The connection with the indoor communication circuit unit 7 is released, and the terminal S3 of the indoor terminal block 36 and the outdoor power supply line 11 are connected.
As a result, power from the commercial power supply 13 is supplied between the signal line 16 and the power signal common line 15.

(STEP5)
The indoor control unit 6 operates the outdoor activation relay 12 for a predetermined time (see FIG. 2).
For example, the predetermined time is set to a time (n seconds) during which the capacitor B27 of the outdoor unit 4 is charged. The predetermined time is not limited to this.

(STEP6)
After operating the outdoor activation relay 12 for a predetermined time, the indoor control unit 6 stops (OFF) the operation of the outdoor activation relay 12, connects the terminal S3 of the indoor terminal block 36 and the indoor communication circuit unit 7, The connection between the terminal S3 of the indoor terminal block 36 and the outdoor power supply line 11 is opened.

(STEP7)
The indoor control unit 6 operates the indoor communication circuit unit 7 to start communication with the outdoor unit 4.
Then, the indoor control unit 6 again determines whether communication between the indoor communication circuit unit 7 and the outdoor communication circuit unit 14 of the outdoor unit 3 has been established.

(STEP8)
When communication between the indoor communication circuit unit 7 and the outdoor unit 4 can be established, the indoor communication circuit unit 7 starts communication with the outdoor communication circuit unit 31 of the outdoor unit 4.

(STEP9)
The indoor control unit 6 communicates with the outdoor unit 4 through the indoor communication circuit unit 7 to cause the air conditioner 1 to perform a cooling operation or a heating operation.

(STEP10)
On the other hand, when the communication between the indoor communication circuit unit 7 and the outdoor unit 4 cannot be established in STEP 7, the indoor control unit 6 operates the indoor communication circuit unit 7 again to communicate with the outdoor unit 4. Let it begin.
Then, the indoor control unit 6 determines whether or not communication between the indoor communication circuit unit 7 and the outdoor unit 4 has been established for a predetermined time (n seconds).

(STEP11)
If the communication between the indoor communication circuit unit 7 and the outdoor unit 4 cannot be established by elapse of n seconds in STEP 10, the indoor control unit 6 determines that the communication is abnormal.

  Next, the operation of the outdoor unit 4 will be described with reference to FIGS.

(STEP12)
When the outdoor activation relay 12 of the indoor unit A2 is turned on and power from the commercial power supply 13 is supplied between the signal line 16 and the power signal common line 15, the terminals S2 and S3 of the outdoor terminal block 37 of the outdoor unit 4 are provided. During this period, power from the commercial power supply 13 is supplied.

(STEP 13)
When power from the commercial power supply 13 is supplied between the terminals S2 and S3 of the outdoor terminal block 37, the inrush current prevention relay coil 32 is energized through the power supply cutoff relay A34, and the inrush current prevention relay B18 is short-circuited. (See FIG. 2).
When the inrush current prevention relay B18 is short-circuited, the commercial power supply 13 supplied to the terminals L and N of the outdoor terminal block 37 is supplied to the outdoor rectification unit B25 via the inrush current prevention resistor B20.
The outdoor rectification unit B25 converts the AC voltage supplied from the commercial power supply 13 into an arbitrary DC voltage and supplies the DC voltage to the capacitor B27, the outdoor control unit 29, and the communication circuit power supply unit 30.
The communication circuit power supply unit 30 converts the AC voltage supplied from the commercial power supply 13 into an arbitrary DC voltage and supplies it to the outdoor communication circuit unit 31.

(STEP14)
When the DC power is supplied from the outdoor rectification unit B25, the outdoor control unit 29 short-circuits the outdoor relay B22.

(STEP 15)
Next, the outdoor control unit 29 operates the power supply cutoff relay A34 to open the contact.

(STEP 16)
When the power supply cutoff relay A34 is opened, the inrush current prevention relay coil 32 is deenergized and opens the inrush current prevention relay B18 (see FIG. 3).
Thereby, during operation of the outdoor unit 4, a short circuit between the terminals S <b> 2 and S <b> 3 of the outdoor terminal block 37 can be prevented, and communication between the indoor communication circuit unit 7 and the outdoor communication circuit unit 31 becomes possible.

(STEP 17)
Next, the outdoor control unit 29 operates all the outdoor communication circuit units 31 to start communication with the indoor unit A2 or B3.
Each outdoor communication circuit unit 31 starts communication with the indoor communication circuit unit 7 of the corresponding indoor unit via the power signal common line 15 and the signal line 16.

(STEP 18)
The outdoor control unit 29 determines whether communication between each outdoor communication circuit unit 31 and the indoor communication circuit unit 7 of the corresponding indoor unit has been established.
The outdoor control unit 29 repeats STEP 17 until communication with the indoor communication circuit unit 7 of either the indoor unit A2 or B3 is established.

(STEP 19)
Here, since the indoor communication circuit unit 7 of the indoor unit A2 is operating, it is assumed that communication between the outdoor communication circuit unit 31 and the indoor communication circuit unit 7 of the indoor unit A2 can be established.
In this case, the outdoor unit 4 starts communication with the indoor unit A2.

(STEP20)
The outdoor control unit 29 operates the inrush current prevention relay A17 to short-circuit it.
This operating condition is set to a timing at which the compressor provided in the outdoor unit 4 is operated. The operating conditions are not limited to this.
When the inrush current prevention relay A17 is short-circuited, the commercial power supply 13 supplied to the terminals L and N of the outdoor terminal block 37 is supplied to the noise filter 23 through the inrush current prevention resistor A19.
The noise filter 23 eliminates noise included in the AC voltage supplied from the commercial power supply 13 and supplies the AC voltage to the outdoor rectification unit A24.
The outdoor rectification unit A24 converts the AC voltage from which noise has been removed by the noise filter 23 into an arbitrary DC voltage and supplies it to the capacitor A26 and the inverter circuit 28.

(STEP21)
The outdoor control unit 29 operates the outdoor relay A21 to short-circuit it.
This operating condition is set to a timing at which a constant charge is charged in the capacitor A26. The operating conditions are not limited to this. Thereby, it is possible to prevent an inrush current from flowing through the capacitor A26.

(STEP22)
The outdoor control unit 29 operates the inrush current prevention relay A17 for a predetermined time.
For example, the predetermined time is set to a time (n seconds) during which the capacitor A26 of the outdoor unit 4 is charged. The predetermined time is not limited to this.

(STEP23)
After operating the inrush current prevention relay A17 for a predetermined time, the outdoor control unit 29 opens the contact of the inrush current prevention relay A17.

(STEP 24)
The outdoor control unit 29 communicates with the indoor unit A2 via the outdoor communication circuit unit 31, and causes the air conditioner 1 to perform a cooling operation or a heating operation.

  Next, an operation when an operation start request is transmitted from the remote controller 10 to the indoor unit B3 while the indoor unit A2 and the outdoor unit 4 are in operation will be described.

When the operation start request is transmitted from the remote controller 10 to the indoor unit B3, the indoor control unit 6 of the indoor unit B3 receives the operation start request via the receiving unit 9.
Thereafter, communication between the indoor communication circuit unit 7 of the indoor unit B3 and the outdoor unit 4 is established by the same operation as STEP1 to STEP3 in the flowchart.

Here, by the above operation, the outdoor unit 4 is already in operation, and the outdoor communication circuit unit 31 connected to the indoor unit B3 repeatedly establishes communication. Therefore, the indoor unit B3 and the outdoor unit 4 are Communication can be established.
Therefore, the indoor control unit 6 of the indoor unit B3 communicates with the outdoor unit 4 via the indoor communication circuit unit 7 by the same operation as STEP3 and STEP9 in the above-described flowchart, and the air conditioner 1 is cooled. Or heating operation.

  Next, the operation | movement which transfers the air conditioner 1 to an operation standby state is demonstrated.

Similarly to the above-described operation, each indoor control unit 6 receives an operation standby signal from the remote controller 10 via the receiving unit 9.
The outdoor control unit 29 of the outdoor unit 4 receives an operation standby signal via each outdoor communication circuit unit 31.
When receiving the operation standby signal from all the indoor units, the outdoor control unit 29 operates the outdoor relays A21 and B22 to open the contacts.

Thereby, the power supply from the commercial power supply 13 to the noise filter 23, the outdoor rectification unit B27, and the communication circuit power supply unit 30 is stopped from the terminals L and N of the outdoor terminal block 37, and the direct current to each component of the outdoor unit 4 is stopped. The supply of power is also stopped.
By such an operation, the operation shifts to the above-described operation standby state (see FIG. 1) again.

<Effect>
As described above, in the present embodiment, even when there are a plurality of indoor units, the inrush current prevention relays A17 and B18 and the outdoor relays A21 and B22 are opened to keep the outdoor unit 4 open during operation standby. The power supply from the commercial power supply 13 is cut off. Also, the reactive power can be suppressed by separating the inverter circuit 28 and the outdoor control unit 29 and connecting the noise filter 23 via the inrush current prevention relay A17 and the inrush current prevention resistor A19 or the outdoor relay A21. . For this reason, even when the outdoor unit 4 is on standby while the indoor unit is in operation, the capacitor A26 having a large line capacitance of the noise filter 23 for the inverter circuit 28 is separated by separating the inverter circuit 28 and the outdoor control unit 29. Therefore, even when the compressor is stopped and the outdoor unit 4 is on standby while the indoor unit is in operation, consumption of reactive power by the noise filter 23 for the inverter circuit 28 can be suppressed.

  In the outdoor unit 4, the inverter circuit 28 and the outdoor control unit 29 are separated from each other. The outdoor control unit 29 is first activated, and the outdoor control unit 29 controls the operation of the inverter circuit 28. Thus, the IPM can be operated safely by starting up the control power supply before the bus voltage is applied to the intelligent power module (IPM).

  Further, even when there are a plurality of indoor units, the outdoor unit 4 can prevent a voltage from being applied from the operating indoor unit to the indoor unit that is in operation standby by way of the diode 33. It is possible to reduce standby power safely.

  In the present embodiment, a case where a plurality of indoor units are connected has been described. However, the present invention is not limited to this. Regarding the effect of suppressing the consumption of reactive power by the noise filter 23 for the inverter circuit 28, the same effect can be obtained even when there is one indoor unit.

  As described above, the air conditioner according to the present invention is useful for reducing power consumption, and is particularly suitable for reducing power consumption during standby.

  DESCRIPTION OF SYMBOLS 1 Air conditioner, 2 Indoor unit A, 3 Indoor unit B, 4 Outdoor unit, 5 Indoor rectification part, 6 Indoor control part, 7 Indoor communication circuit part, 8 Power receiving system data part, 9 Receiving part, 10 Remote control, 11 Outdoor Power supply line, 12 Outdoor start relay, 13 Commercial power supply, 14 Power line, 15 Power signal common line, 16 Signal line, 17 Inrush current prevention relay A, 18 Inrush current prevention relay B, 19 Inrush current prevention resistance A, 20 Inrush Current prevention resistor B, 21 outdoor relay A, 22 outdoor relay B, 23 noise filter, 24 outdoor rectification unit A, 25 outdoor rectification unit B, 26 capacitor A, 27 capacitor B, 28 inverter circuit, 29 outdoor control unit, 30 communication Circuit power supply unit, 31 Outdoor communication circuit unit, 32 Inrush current prevention relay coil, 33 Diode, 34 Power supply cutoff relay A, 3 Power supply cutoff relay B, 36 indoor terminal block 37 outside the terminal block.

Claims (6)

A commercial unit comprising an indoor unit and an outdoor unit, wherein the indoor unit and the outdoor unit are connected by a three-core power line, a common line, and a signal line, and are supplied to either the outdoor unit or the indoor unit An air conditioner that feeds power from a power source to the other through the power line and the common line,
The outdoor unit is
A first power supply relay that opens and closes a connection between the commercial power source and a first outdoor rectification unit for the outdoor control unit;
A second power supply relay that opens and closes a connection between the commercial power source and a second outdoor rectifier for the inverter circuit;
With
An inverter circuit noise filter is disposed closer to the second outdoor rectification unit than the second power supply relay.
An air conditioner characterized by that. The indoor unit is
An outdoor activation relay that opens and closes the connection between the power line and the signal line;
An indoor control unit for operating the outdoor activation relay and supplying the commercial power between the signal line and the common line;
With
The outdoor unit is
A power supply relay controller that closes the first power supply relay when the commercial power is supplied between the signal line and the common line;
The air conditioner according to claim 1, comprising: The outdoor unit is
An outdoor control unit that operates the second power supply relay and controls the supply of the commercial power to the inverter circuit;
The air conditioner according to claim 2, comprising: The outdoor unit is
A power supply cutoff relay that cuts off power to the power supply relay control unit;
With
The first power supply relay of the outdoor unit is
A first inrush current preventing relay connected to the first rush current prevention resistor in series, operated by energization of the previous SL power supply relay control unit,
A first outdoor relay connected in parallel with the first inrush current prevention resistor and the first inrush current prevention relay and operated by the control of the outdoor control unit;
With
After the contact of the first inrush current prevention relay is closed, the outdoor control unit closes the contact of the first outdoor relay, operates the power supply cutoff relay to open the contact, and the power supply relay Shut off the power to the control unit,
The air conditioner according to claim 3. The second power supply relay of the outdoor unit is
A second inrush current preventing relay connected in series with a second inrush current preventing resistor and operated by the control of the outdoor control unit;
A second outdoor relay connected in parallel with the second inrush current prevention resistor and the second inrush current prevention relay, and operated by the control of the outdoor control unit;
With
The outdoor control unit controls operations of the second inrush current prevention relay and the second outdoor relay after energization by the first outdoor relay.
The air conditioner according to claim 4. When including a plurality of the indoor units,
The number of the outdoor units is equal to the number of the plurality of indoor units.
For each indoor unit, a power supply cutoff relay that is arranged between the signal line and the common line and cuts off the power supply from the signal line to the common line;
A rectifier for energizing the signal line to the common line;
An outdoor communication circuit unit for communicating with the indoor unit;
With
The power supply cutoff relay is connected to the power supply relay control unit through the rectifier.
The air conditioner as described in any one of Claims 2-5 characterized by the above-mentioned.

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