JP6797311B2 - Air conditioner - Google Patents

Description

The present invention relates to an air conditioner including an indoor unit and an outdoor unit.

In an air conditioner, the indoor unit and the outdoor unit are generally connected by three wires called a power supply line, a signal line, and a power supply signal common line. Patent Document 1 below discloses an air conditioner having this configuration.

In the conventional air conditioner represented by Patent Document 1 below, a commercial power source is applied from the indoor unit to the outdoor unit when the power is turned on or when the operation is restarted from the operation standby state, and the inrush current prevention relay of the outdoor unit is provided. Operate and start the outdoor unit. The activated outdoor unit starts communication with the indoor unit to establish communication. If communication cannot be established between the indoor unit and the outdoor unit, the control of applying the commercial power supply from the indoor unit to the outdoor unit is performed again to try to establish the communication.

Japanese Unexamined Patent Publication No. 2010-243051

As described above, in the conventional air conditioner, when communication cannot be established between the indoor unit and the outdoor unit, the control of applying the commercial power supply from the indoor unit to the outdoor unit is performed again. However, if the commercial power is reapplied to the outdoor unit in a connected state where the outdoor unit can communicate, there is a problem that an unintended excessive current may flow in the communication path and the outdoor unit circuit may break down. ..

The present invention has been made in view of the above, and an object of the present invention is to obtain an air conditioner capable of suppressing a failure of an outdoor unit circuit that may occur due to reapplication of a commercial power source.

In order to solve the above-mentioned problems and achieve the object, the air conditioner according to the present invention includes an indoor unit and an outdoor unit. The indoor unit activates the outdoor unit. When the outdoor unit is activated, the indoor unit determines whether or not communication can be established with the outdoor unit. If communication cannot be established, self-reception is performed in which the indoor unit receives the first signal generated by the indoor unit. The indoor unit determines whether or not to restart the outdoor unit based on the result of self-reception.

The air conditioner according to the present invention has an effect of being able to suppress a failure of the outdoor unit circuit that may occur due to reapplication of a commercial power source.

Block diagram showing the electrical system of the air conditioner according to the embodiment A flowchart showing the operation of a main part of the air conditioner according to the embodiment. A block diagram showing a configuration example of an indoor communication circuit unit in the air conditioner of the embodiment. A block diagram showing a configuration example of an outdoor communication circuit unit in the air conditioner of the embodiment. Diagram for explaining the operation during a momentary power failure A block diagram showing an example of a hardware configuration in the indoor control unit of the embodiment. A block diagram showing another example of the hardware configuration in the indoor control unit of the embodiment.

The air conditioner according to the embodiment of the present invention will be described in detail with reference to the accompanying drawings. The present invention is not limited to the following embodiments. Further, in the following, the description will be simply referred to as "connection" without distinguishing between "physical connection" and "electrical connection".

Embodiment.
FIG. 1 is a block diagram showing an electrical system of an air conditioner according to an embodiment. As shown in FIG. 1, the air conditioner 100 in the embodiment includes an outdoor unit 1 and an indoor unit 2 that activates the outdoor unit 1. FIG. 1 shows, in particular, the connection state before the outdoor unit 1 is started.

First, a general configuration of the air conditioner 100 according to the embodiment will be described with reference to FIG. The outdoor unit 1 and the indoor unit 2 are connected by three lines, a power supply line 24, a power supply signal common line 25, and a signal line 26. The outdoor unit 1 is connected to the three-phase AC power supply 3. A three-phase AC voltage is applied to the outdoor unit 1 via the power supply line 65. On the other hand, a single-phase AC voltage is applied to the indoor unit 2 from two of the power supply lines 65 via the power supply line 24 and the power supply signal common line 25. That is, the air conditioner 100 according to the embodiment is an air conditioner having a configuration in which the outdoor unit 1 is supplied with a three-phase AC power supply and the indoor unit 2 is supplied with a single-phase AC power supply.

The indoor unit 2 includes an indoor control unit 4 and an outdoor activation relay 8. The outdoor activation relay 8 opens and closes the connection between the power supply line 24 and the signal line 26. "Opening and closing the connection" means switching between the disconnected state and the connected state. The indoor control unit 4 controls the outdoor start relay 8 to supply a single-phase AC power supply between the signal line 26 and the power signal common line 25.

The outdoor unit 1 includes an outdoor rectifying unit 9, a first inrush current prevention relay 10, a power supply relay 12, a second inrush current prevention relay 13, a smoothing capacitor 14, an inverter circuit unit 15, and outdoor control. A unit 16 is provided. Further, the outdoor unit 1 includes a communication circuit power supply unit 18, an outdoor communication circuit unit 19, a power supply switching relay 20, an inrush current prevention relay drive unit 21, and a compressor 80. The compressor 80 is driven by the inverter circuit unit 15.

In the outdoor unit 1, the outdoor rectifying unit 9 is connected to the power supply relay 12. The power supply relay 12 opens and closes the connection between the three-phase AC power supply 3 and the outdoor rectifying unit 9. The outdoor rectifying unit 9 rectifies the output of the three-phase AC power supply 3. The smoothing capacitor 14 smoothes the output of the outdoor rectifying unit 9. The outdoor communication circuit unit 19 communicates with the indoor unit 2 via the power signal common line 25 and the signal line 26. The power supply switching relay 20 is connected between the power supply signal common line 25 and the communication circuit power supply unit 18. In the inrush current prevention relay drive unit 21, the single-phase AC voltage applied between the power signal common line 25 and the signal line 26 is passed through the outdoor start relay 8 of the indoor unit 2 and the power supply switching relay 20. Works when supplied. The first inrush current prevention relay 10 is connected in parallel with the power supply relay 12 and is controlled by the inrush current prevention relay drive unit 21. The second inrush current prevention relay 13 is connected in parallel with the first inrush current prevention relay 10 and is controlled by the outdoor control unit 16.

Next, a more detailed configuration of the air conditioner 100 according to the embodiment will be described. The outdoor unit 1 includes an outdoor terminal block 23. The outdoor terminal block 23 has an R terminal 27, an S terminal 28, a T terminal 29, an outdoor S1 terminal 30, an outdoor S2 terminal 31, and an outdoor S3 terminal 32. The R terminal 27, the S terminal 28, and the T terminal 29 are connected to the three-phase AC power supply 3. The electric power from the three-phase AC power supply 3 is supplied to the outdoor unit 1 via the R terminal 27, the S terminal 28, and the T terminal 29.

Inside the outdoor unit 1, the outdoor S1 terminal 30 and the R terminal 27 are connected, and the outdoor S2 terminal 31 and the S terminal 28 are connected. Through these connections, power is supplied to the communication circuit power supply unit 18 by single-phase alternating current via the outdoor S1 terminal 30 and the outdoor S2 terminal 31. The power supplied to the outdoor S1 terminal 30 and the outdoor S2 terminal 31 is not limited to the single-phase power between the R terminal 27 and the S terminal 28, and is the single-phase power between any two phases of the three-phase AC power supply 3. Can be used.

The indoor unit 2 includes an indoor terminal block 22. The indoor terminal block 22 has an indoor S1 terminal 33, an indoor S2 terminal 34, and an indoor S3 terminal 35. The indoor S1 terminal 33 is connected to the outdoor S1 terminal 30 by a power line 24. The indoor S2 terminal 34 is connected to the outdoor S2 terminal 31 by a power signal common line 25. The indoor S3 terminal 35 is connected to the outdoor S3 terminal 32 by a signal line 26.

In addition to the indoor control unit 4 and the outdoor start relay 8 described above, the indoor unit 2 includes an indoor rectifying unit 5, an indoor communication circuit unit 6, an indoor operation switching unit 7, and a remote controller receiving unit 36. The outdoor start relay 8 has an a terminal, a b terminal, and a c terminal. The a terminal is connected to the indoor S1 terminal 33. The b terminal is connected to the indoor communication circuit unit 6. The c terminal, which is the base point of the outdoor start relay 8, is connected to the indoor S3 terminal 35. The contact of the outdoor start relay 8 is connected to either the a terminal or the b terminal. That is, the outdoor activation relay 8 switches between connecting the indoor S3 terminal 35 to the indoor S1 terminal 33 and connecting the indoor S3 terminal 35 to the indoor communication circuit unit 6.

In the following description, for convenience, the state in which the contact of the outdoor start relay 8 is connected to the a terminal is referred to as "ON", and the state in which the contact of the outdoor start relay 8 is connected to the b terminal is referred to as "ON". Called "OFF".

When the outdoor start relay 8 is OFF, the contact of the outdoor start relay 8 is connected to the b terminal, and the indoor S3 terminal 35 and the indoor communication circuit unit 6 are connected via the outdoor start relay 8. Through this connection, a communication line between the outdoor unit 1 and the indoor unit 2 is established via the power signal common line 25 and the signal line 26, and various operation signals are transmitted between the outdoor unit 1 and the indoor unit 2. Send and receive.

On the other hand, when the outdoor start relay 8 is ON, the contact of the outdoor start relay 8 is connected to the a terminal, and the indoor S3 terminal 35 and the indoor S1 terminal 33 are connected. Through this connection, power by single-phase alternating current is supplied between the power signal common line 25 and the signal line 26.

The indoor S1 terminal 33 is connected to the indoor rectifying unit 5. The indoor S2 terminal 34 is connected to the indoor rectifying unit 5 and the indoor communication circuit unit 6. The single-phase AC voltage applied between the power supply line 24 and the power supply signal common line 25 is converted into a DC voltage by the indoor rectifying unit 5, and power is supplied to the indoor control unit 4.

The indoor operation switching unit 7 connected to the indoor control unit 4 determines whether or not to reduce the standby power, which is the power consumed by the outdoor unit 1 during the operation standby. The illustrated example is an example in which whether or not to reduce the standby power is set by a jumper wire. In the indoor operation switching unit 7, if a jumper wire is connected between the c1 terminal and the c2 terminal, the standby power is reduced, and if a jumper wire is connected between the c2 terminal and the c3 terminal, the standby power is reduced. Does not reduce. The method of switching whether or not to reduce the standby power is not limited to the jumper wire, and may be switched by a switch.

The remote controller receiving unit 36 is connected to the remote controller 37 and the indoor control unit 4. The remote controller receiving unit 36 receives the operation command from the remote controller 37 and transmits the received command to the indoor control unit 4.

The outdoor unit 1 further includes an inrush current prevention resistor 11 and an outdoor operation switching unit 17. The R terminal 27 of the outdoor unit 1 is connected to each end of the first inrush current prevention relay 10 and the second inrush current prevention relay 13 and to the a terminal, which is one of the terminals on one end side of the power supply relay 12. Will be done. The other ends of the first inrush current prevention relay 10 and the second inrush current prevention relay 13 are connected to one end of the inrush current prevention resistor 11. The other end of the inrush current prevention resistor 11 is connected to the b terminal, which is one of the terminals on the other end side of the power supply relay 12, and the outdoor rectifying unit 9. Further, both ends of the first inrush current prevention relay 10 and the second inrush current prevention relay 13 are connected to the outdoor operation switching unit 17.

The S terminal 28 is connected to the c terminal, which is one of the terminals on one end side of the power supply relay 12. The d terminal, which is the other terminal on the other end side of the power supply relay 12, is connected to the outdoor rectifying unit 9. The T terminal 29 is connected to the outdoor rectifying unit 9 without going through the power supply relay 12.

Note that FIG. 1 shows an example in which the a terminal and the c terminal, which are terminals on one end side of the power supply relay 12, are connected to the R terminal 27 and the S terminal 28, respectively, but the present invention is not limited to this. Any two of the R terminal 27, the S terminal 28, and the T terminal 29 may be connected to the a terminal and the c terminal of the power supply relay 12.

Further, one end and the other end of the circuit portion in which the inrush current prevention resistor 11 is connected in series to the parallel circuit of the first inrush current prevention relay 10 and the second inrush current prevention relay 13 are the a terminal and the other end, respectively, in FIG. It is connected to the b terminal, but is not limited to this. One end and the other end of the circuit unit may be connected to the c terminal and the d terminal, respectively. That is, one end and the other end of the circuit unit may be connected to the input / output of any one contact of the power supply relay 12.

Further, although the power supply relay 12 shows a two-contact relay in FIG. 1, it may have a configuration in which two one-contact relays are provided.

The outdoor rectifying unit 9 rectifies the AC voltage of the three-phase AC power supply 3 and converts it into an arbitrary DC voltage. The power supply relay 12 and the second inrush current prevention relay 13 operate under the control of the outdoor control unit 16, and when they do not operate, the contacts are opened as shown in FIG.

The outdoor operation switching unit 17 is connected to both ends of the first inrush current prevention relay 10 and is also connected to the outdoor control unit 16. The outdoor operation switching unit 17 determines whether or not to reduce the standby power during the operation standby. The illustrated example is an example in which whether or not to reduce the standby power is set by a jumper wire. If a jumper wire is connected between the a1 terminal and the a2 terminal in the outdoor operation switching unit 17, the standby power during operation standby is reduced. On the other hand, if a jumper wire is connected between the b1 terminal and the b2 terminal, the b1 terminal and the b2 terminal form a current path that bypasses the first inrush current prevention relay 10. Therefore, the standby power during the operation standby is not reduced. Information on whether or not to reduce the standby power during the operation standby is transmitted from the outdoor operation switching unit 17 to the outdoor control unit 16.

Both ends of the smoothing capacitor 14 are connected to the outdoor rectifying unit 9. The DC voltage smoothed by the smoothing capacitor 14 is applied to the inverter circuit unit 15 and the outdoor control unit 16.

The power supply switching relay 20 has an a terminal, a b terminal, and a c terminal. The a terminal is connected to the communication circuit power supply unit 18. The b terminal is connected to the inrush current prevention relay drive unit 21. The c terminal is connected to the outdoor S2 terminal 31. The c terminal, which is the base point of the power supply switching relay 20, is connected to the outdoor S2 terminal 31. The contact of the power supply switching relay 20 is connected to either the a terminal or the b terminal. That is, the power supply switching relay 20 switches between connecting the outdoor S2 terminal 31 to the inrush current prevention relay drive unit 21 and connecting the outdoor S2 terminal 31 to the communication circuit power supply unit 18.

In the following description, for convenience, the state in which the contact of the power supply switching relay 20 is connected to the a terminal is referred to as "ON", and the state in which the contact of the power supply switching relay 20 is connected to the b terminal. Is called "OFF".

The outdoor control unit 16 controls the power supply switching relay 20. When the power supply switching relay 20 is OFF, the contact of the power supply switching relay 20 is connected to the b terminal, and the outdoor S2 terminal 31 and the inrush current prevention relay drive unit 21 are connected via the power supply switching relay 20. With this connection, when single-phase alternating current is energized between the power signal common line 25 and the signal line 26 by the indoor unit 2, the inrush current prevention relay drive unit 21 is energized. When the inrush current prevention relay drive unit 21 is energized, the contacts of the first inrush current prevention relay 10 are closed.

On the other hand, when the power supply switching relay 20 is ON, the contacts of the power supply switching relay 20 are connected to the a terminal. At this time, the outdoor S2 terminal 31 is connected to the communication circuit power supply unit 18 via the power supply switching relay 20. The communication circuit power supply unit 18 generates a DC voltage from the single-phase AC voltage applied between the power supply line 24 and the power supply signal common line 25, and applies the DC voltage to the outdoor communication circuit unit 19. The generation of the DC voltage can be realized by a half-wave rectifier circuit or a full-wave rectifier circuit, but other circuits may be used.

The inverter circuit unit 15 is controlled by the outdoor control unit 16 and converts the applied DC voltage into an AC voltage having an arbitrary frequency and an arbitrary voltage. The inverter circuit unit 15 applies the converted AC voltage to the compressor 80 to drive the compressor 80.

Next, the operation of the air conditioner 100 during standby operation will be described with reference to FIG. First, the power of the three-phase AC power supply 3 is supplied to the outdoor unit 1 via the R terminal 27, the S terminal 28, and the T terminal 29. Here, during operation standby, the contacts of the first inrush current prevention relay 10, the second inrush current prevention relay 13, and the power supply relay 12 are open, so that the inverter circuit unit 15, which is an outdoor unit load, is outdoors. No power is supplied to the operation switching unit 17 and the outdoor control unit 16.

One end of the communication circuit power supply unit 18 is connected to the power supply line 24 via the outdoor S1 terminal 30, but the other end is disconnected from the outdoor S2 terminal 31 by the power supply switching relay 20. Therefore, power is not supplied to the communication circuit power supply unit 18. As a result, power is not supplied to the outdoor communication circuit unit 19. One end of the inrush current prevention relay drive unit 21 is connected to the power signal common line 25 via the outdoor S2 terminal 31, but the other end is connected to the signal line 26 via the outdoor S3 terminal 32. No power is supplied.

Due to the above operation mode, power is not supplied to the inverter circuit unit 15, the outdoor control unit 16, the outdoor operation switching unit 17, the communication circuit power supply unit 18, and the outdoor communication circuit unit 19 during the operation standby, and the outdoor unit 1 The standby power for operation is reduced.

Next, the operation until the air conditioner 100 starts the operation operation will be described. When the electric power from the three-phase AC power source 3 is supplied to the indoor unit 2 via the power supply line 24 and the power signal common line 25, the electric power is supplied to the indoor control unit 4 and the indoor unit 2 is started. After startup, the setting of the indoor operation switching unit 7 is confirmed. In the illustrated example, since the jumper wire is connected to the c1 terminal and the c2 terminal, it is recognized as an air conditioner that reduces the standby power during the operation standby. The indoor control unit 4 shifts to a state of waiting for an operation command from the remote controller 37 via the remote controller receiving unit 36.

When the indoor control unit 4 receives the operation command signal from the remote controller 37, the indoor control unit 4 turns on the outdoor start relay 8 to start the outdoor unit 1. At this time, the connection between the indoor S3 terminal 35 and the indoor communication circuit unit 6 is disconnected, and the connection is switched between the indoor S3 terminal 35 and the indoor S1 terminal 33. By this control, a single-phase AC voltage is applied between the outdoor S2 terminal 31 and the outdoor S3 terminal 32.

When power is supplied between the outdoor S2 terminal 31 and the outdoor S3 terminal 32, the inrush current prevention relay drive unit 21 is energized via the power supply switching relay 20, and the contact of the first inrush current prevention relay 10 is engaged. It is closed. By closing the contact of the first inrush current prevention relay 10, the AC voltage from the three-phase AC power supply 3 is converted into a DC voltage by the outdoor rectifying unit 9. The converted DC voltage is applied to the smoothing capacitor 14 and the inverter circuit unit 15.

Here, in the power supply path passing through the first inrush current prevention relay 10, the inrush current prevention resistor 11 is inserted in the path, so that the inrush current can be prevented. The outdoor control unit 16 is activated by applying a DC voltage. The outdoor control unit 16 closes the contact of the second inrush current prevention relay 13 after the start-up. The outdoor control unit 16 monitors the voltage charged in the smoothing capacitor 14, confirms that the voltage is stable at the set voltage, and then closes the contact of the power supply relay 12. After that, the outdoor control unit 16 opens the contact of the second inrush current prevention relay 13. The second inrush current prevention relay 13 is a relay for increasing the possibility of self-recovery from a momentary power failure and improving the convenience of the user. A momentary power outage is a phenomenon in which the power supply from the outside is temporarily cut off. The operation of the second inrush current prevention relay 13 at the time of a momentary power failure will be described later.

The indoor control unit 4 turns off the outdoor start-up relay 8 after an arbitrary set time has elapsed since the outdoor start-up relay 8 was turned on. At this time, the connection between the indoor S3 terminal 35 and the indoor S1 terminal 33 is disconnected, and the connection is switched between the indoor S3 terminal 35 and the indoor communication circuit unit 6. By this control, the single-phase AC voltage applied between the outdoor S2 terminal 31 and the outdoor S3 terminal 32 is cut off, and the inrush current prevention relay drive unit 21 is de-energized. As a result, the contacts of the first inrush current prevention relay 10 are opened. By this operation, it is possible to prevent the inrush current in the outdoor unit starting operation.

When the inrush current prevention relay drive unit 21 is de-energized, the outdoor control unit 16 turns on the power supply switching relay 20 to open the connection between the outdoor S2 terminal 31 and the inrush current prevention relay drive unit 21, and is outdoors. The connection is switched between the S2 terminal 31 and the communication circuit power supply unit 18. By this control, the single-phase AC voltage applied between the outdoor S1 terminal 30 and the outdoor S2 terminal 31 is applied to the communication circuit power supply unit 18. The communication circuit power supply unit 18 converts the single-phase AC voltage into an arbitrary DC voltage and applies it to the outdoor communication circuit unit 19.

In the above description, the procedure is that the first inrush current prevention relay 10 is turned off after the outdoor start relay 8 is turned off by the indoor control unit 4, but the order is reversed and the power supply is supplied first. The supply switching relay 20 may be turned on. When the power supply switching relay 20 is turned on, the inrush current prevention relay drive unit 21 is de-energized and the first inrush current prevention relay 10 is turned off. Therefore, even if the order is changed, the outdoor unit 1 is started. Is possible.

Next, the operation of the main part of the air conditioner 100 according to the embodiment will be described with reference to the drawings of FIGS. 1 to 4. FIG. 2 is a flowchart showing the operation of a main part of the air conditioner 100 according to the embodiment. FIG. 3 is a block diagram showing a configuration example of the indoor communication circuit unit 6 in the air conditioner 100 of the embodiment. FIG. 4 is a block diagram showing a configuration example of the outdoor communication circuit unit 19 in the air conditioner 100 of the embodiment.

As shown in FIG. 3, the indoor communication circuit unit 6 includes a transmission unit 38, a reception unit 39, a transmission control unit 50, and a reception control unit 51. The transmitting unit 38 and the receiving unit 39 are connected in series and inserted between the power supply signal common line 25 and the signal line 26.

Further, as shown in FIG. 4, the outdoor communication circuit unit 19 includes a transmission unit 40, a reception unit 41, a transmission control unit 60, and a reception control unit 61. The transmitting unit 40 and the receiving unit 41 are connected in series and inserted between the power supply signal common line 25 and the signal line 26.

In step S1, the indoor unit 2 is activated. As described above, the indoor unit 2 is started by supplying electric power from the three-phase AC power source 3 to the indoor unit 2.

In step S2, the outdoor start relay 8 is controlled to be ON. By this control, the indoor S3 terminal 35 and the indoor S1 terminal 33 are connected, and a single-phase AC voltage is applied between the outdoor S2 terminal 31 and the outdoor S3 terminal 32. When a single-phase AC voltage is applied between the outdoor S2 terminal 31 and the outdoor S3 terminal 32, the outdoor unit 1 is started.

Further, after the outdoor start relay 8 is controlled to the ON state, the outdoor start relay 8 is returned to the OFF state. As a result, the connection between the indoor S3 terminal 35 and the indoor S1 terminal 33 is opened, and the connection is switched between the indoor S3 terminal 35 and the indoor communication circuit unit 6.

In step S3, the power supply switching relay 20 is controlled to be ON. As a result, the connection between the outdoor S2 terminal 31 and the inrush current prevention relay drive unit 21 is released, and the connection is switched between the outdoor S2 terminal 31 and the communication circuit power supply unit 18. As a result, a single-phase AC voltage is applied to the communication circuit power supply unit 18.

In step S4, power is supplied to the communication circuit power supply unit 18. When the power is supplied to the communication circuit power supply unit 18, the communication circuit power supply unit 18 converts the single-phase AC voltage into an arbitrary DC voltage and applies it to the outdoor communication circuit unit 19.

In step S5, communication is started between the outdoor unit 1 and the indoor unit 2. The communication in step S5 is performed by the main operation of the outdoor unit 1. That is, the outdoor unit 1 is the master and the indoor unit 2 is the slave. The details of the communication operation performed between the outdoor unit 1 and the indoor unit 2 will be described later.

In step S6, it is determined whether or not communication can be established between the outdoor unit 1 and the indoor unit 2. If communication can be established (steps S6 and Yes), the process proceeds to step S7. In step S7, steady communication is performed between the outdoor unit 1 and the indoor unit 2. In steady communication, various information necessary for controlling the air conditioner 100 is exchanged.

In step S8, the outdoor control unit 16 of the outdoor unit 1 receives the operation start command from the indoor unit 2 and starts the operation of the heating operation or the cooling operation.

On the other hand, if communication cannot be established (steps S6 and No), the process proceeds to step S9. Step S9 is a communication path confirmation process, and includes processes from steps S10 to S16. As described above, if the commercial power supply is reapplied to the outdoor unit 1 under the connection state in which the outdoor unit 1 can communicate, an unintended excessive current may flow in the communication path and the outdoor unit circuit may break down. .. Therefore, the process of step S9 is added.

In step S10, the indoor unit 2 transmits a test signal and determines whether or not self-reception is possible. Here, the self-reception means a process of receiving a signal generated by the transmission unit 38 of the indoor unit 2 by the reception unit 39 of the same indoor unit 2. The reception process by self-reception can be performed independently of the process in step S5, that is, at an asynchronous timing. The details of the reception process by self-reception will be described later. The test signal may be any type of signal as long as it is a communication signal whose self-reception function can be confirmed. The signal generated by the transmission unit 38, that is, the test signal may be referred to as a "first signal" for convenience.

If the test signal can be self-received (step S10, Yes), the process proceeds to step S11. If self-reception is possible, it means that the communication path between the indoor unit 2 and the outdoor unit 1 is correctly connected, and that the functions of the transmitter 38 and the receiver 39 of the indoor unit 2 are normal. To do. That is, when self-reception is possible, it is determined that the communication on the indoor unit 2 side is operating normally. Therefore, in step S11, the indoor unit 2 waits for the reception of the outdoor transmission. Here, the outdoor transmission means a transmission operation performed by the outdoor unit 1 to the indoor unit 2. That is, step S11 is in a standby state as to whether or not the signal generated by the transmitting unit 40 of the outdoor unit 1 can be received by the receiving unit 39 of the indoor unit 2. The signal generated when performing outdoor transmission may be referred to as a "second signal" for convenience.

After step S11, the process proceeds to step S12. In step S12, it is determined again whether or not communication has been established between the outdoor unit 1 and the indoor unit 2. The determination of whether or not communication has been established is performed based on the result of whether or not the receiving unit 39 of the indoor unit 2 has received the signal transmitted by the transmitting unit 40 of the outdoor unit 1.

If communication can be established (step S12, Yes), the process proceeds to step S7. The operations after step S7 are as described above, and the description thereof is omitted here.

On the other hand, if communication cannot be established (steps S12, No), the process proceeds to step S13. In step S13, it is determined that the communication is abnormal, and the flow exits from FIG.

Returning to the determination process in step S10, if the indoor unit 2 cannot self-receive the test signal (steps S10, No), the process proceeds to step S14. If the test signal cannot be self-received, the communication path between the outdoor unit 1 and the indoor unit 2 may not be connected correctly, and the functions of the transmitter 38 and the receiver 39 of the indoor unit 2 may not be normal. In addition to the nature, there is a possibility that the functions of the transmitting unit 40 and the receiving unit 41 of the outdoor unit 1 are not normal. Therefore, in step S14, the outdoor unit 1 is restarted. The restart is performed by turning on the outdoor start relay 8.

After step S14, the process proceeds to step S15. In step S15, it is determined whether or not the number of restarts is within the specified number of times. If the number of restarts is within the specified number of times (steps S15, Yes), the process returns to step S2 and the processing from step S2 is repeated.

On the other hand, if the number of restarts exceeds the specified number (steps S15, No), the process proceeds to step S16. In step S16, it is determined that the communication is abnormal, and the flow exits from FIG.

As described above, in the flowchart of FIG. 2, the process of step S10 is prepared. By this process, it is suppressed that the commercial power supply is reapplied to the outdoor unit 1 under the connected state in which the outdoor unit 1 can communicate. As a result, it is possible to suppress an unintended failure of the outdoor unit circuit while the communication circuit is formed.

Further, in the flowchart of FIG. 2, the process of step S15 is added. By this process, it is possible to eliminate the event that the restart cannot be performed due to an accidental factor, so that the accuracy of determining that the communication is abnormal can be improved.

Next, the communication operation performed between the outdoor unit 1 and the indoor unit 2 will be described. Hereinafter, the communication between the outdoor unit 1 and the indoor unit 2 is appropriately referred to as "internal / external communication".

A communication current supplied from the communication circuit power supply unit 18 flows between the power supply signal common line 25 and the signal line 26. The communication current is a current used for communication between the outdoor unit 1 and the indoor unit 2. The outdoor unit 1 and the indoor unit 2 communicate by detecting a state in which a current is flowing and a state in which a current is not flowing.

The transmission unit 38 includes an element that switches the state of the path through which the communication current flows during internal / external communication between a state in which the communication current flows and a state in which the communication current does not flow. An example of the device is a photocoupler. Hereinafter, the path through which the communication current flows during internal / external communication is referred to as a "current loop". The current loop is formed by inserting the transmitting unit 38 and the receiving unit 39 of the indoor unit 2 and the transmitting unit 40 and the receiving unit 41 of the outdoor unit 1 in series between the power signal common line 25 and the signal line 26. It is formed. In the following description, the state in which the communication current flows in the current loop is referred to as "ON state" or simply "ON", and the state in which the communication current does not flow is referred to as "OFF state" or simply "OFF".

In the indoor unit 2, the transmission unit 38 controls ON or OFF of the current loop according to the control of the transmission control unit 50. The transmission unit 38 transmits data to the outdoor unit 1 by controlling ON or OFF of the current loop.

Further, in the indoor unit 2, the receiving unit 39 includes an element that receives data transmitted from the outdoor unit 1. The receiving unit 39 receives data by detecting whether the communication current value flowing in the current loop is larger or smaller than the current threshold value. An example of the device is a photocoupler. The reception unit 39 outputs the reception result to the reception control unit 51.

The transmission control unit 50 controls ON or OFF of the transmission unit 38 according to "0" or "1" of the transmission data. When the transmission data is "0", the transmission unit 38 may be controlled to be ON or OFF. When the transmission data is "1", the transmission unit 38 may be controlled to be ON or OFF.

The reception control unit 51 determines "0" or "1" of the received data from the output of the reception unit 39.

In the outdoor unit 1, the transmission unit 40 includes an element that switches the state of the current loop between a state in which a communication current flows and a state in which a communication current does not flow. An example of the device is a photocoupler. The transmission unit 40 controls ON or OFF of the current loop according to the control of the transmission control unit 60. The transmission unit 40 transmits data to the indoor unit 2 by controlling ON or OFF of the current loop.

Further, in the outdoor unit 1, the receiving unit 41 includes an element that receives data transmitted from the indoor unit 2. The receiving unit 41 receives data by detecting whether the communication current value flowing in the current loop is larger or smaller than the communication current threshold value. An example of the device is a photocoupler. The receiving unit 41 outputs the output result to the receiving control unit 61.

The transmission control unit 60 controls ON or OFF of the transmission unit 40 according to "0" or "1" of the transmission data. When the transmission data is "0", the transmission unit 40 may be controlled to be ON or OFF. When the transmission data is "1", the transmission unit 40 may be controlled to be ON or OFF.

The reception control unit 61 determines "0" or "1" of the received data from the output of the reception unit 41.

The flow of operation when data is transmitted from the outdoor unit 1 to the indoor unit 2 is as follows. When the indoor unit 2 receives the data from the outdoor unit 1, the transmission control unit 50 of the indoor unit 2 controls the transmission unit 38 of the indoor unit 2 to the ON state.

Step 1: The transmission control unit 60 of the outdoor unit 1 performs ON control or OFF control of the transmission unit 40 of the outdoor unit 1 based on “0” or “1” of the transmission data.
Step 2: The reception unit 39 of the indoor unit 2 outputs the reception result to the reception control unit 51 of the indoor unit 2.
Step 3: The reception control unit 51 of the indoor unit 2 determines "0" or "1" of the received data from the input result.

The operation flow when data is transmitted from the indoor unit 2 to the outdoor unit 1 is as follows. When the outdoor unit 1 receives the data from the indoor unit 2, the transmission control unit 60 of the outdoor unit 1 controls the transmission unit 40 of the outdoor unit 1 to the ON state.

Step 1: The transmission control unit 50 of the indoor unit 2 performs ON control or OFF control of the transmission unit 38 of the indoor unit 2 based on "0" or "1" of the transmission data.
Step 2: The receiving unit 41 of the outdoor unit 1 outputs the reception result to the reception control unit 61 of the outdoor unit 1.
Step 3: The reception control unit 61 of the outdoor unit 1 determines "0" or "1" of the received data from the input result.

The operation flow when the indoor unit 2 self-receives the test signal is as follows. The timing at which the indoor unit 2 self-receives its own test signal is the timing at which the transmission control unit 60 of the outdoor unit 1 controls the transmission unit 40 of the outdoor unit 1 to the ON state.

Step 1: The transmission control unit 50 of the indoor unit 2 performs ON control or OFF control of the transmission unit 38 of the indoor unit 2 based on "0" or "1" of the transmission data.
Step 2: The reception unit 39 of the indoor unit 2 outputs the reception result to the reception control unit 51 of the indoor unit 2.
Step 3: The reception control unit 51 of the indoor unit 2 determines "0" or "1" of the received data from the input result.

Next, the operation of the second inrush current prevention relay 13 at the time of a momentary power failure will be described with reference to the drawings of FIGS. 1 and 5. FIG. 5 is a diagram for explaining the operation at the time of a momentary power failure. As described above, the second inrush current prevention relay 13 is a relay for increasing the possibility of self-recovery from a momentary power failure and improving the convenience of the user.

In FIG. 5, the sequence operation of the power supply relay 12 is shown on the left side, and the sequence operation of the second inrush current prevention relay 13 is shown on the right side in relation to the bus voltage. The "bus voltage" referred to here is the voltage of the DC bus that connects the outdoor rectifying unit 9 and the inverter circuit unit 15, and corresponds to the voltage of the smoothing capacitor 14 in the example of FIG. In the following description, the "voltage of the smoothing capacitor 14" will be referred to as a "bus voltage".

As described above, the bus voltage is monitored by the outdoor control unit 16. When the power supply is cut off, the bus voltage drops because some load is connected to the circuit. The heavier the load, the faster the bus voltage drops. Since the contact of the power supply relay 12 is closed while the outdoor unit 1 is energized, if the power supply is immediately restored, the bus voltage instantly rises to a smoothed voltage and is restored. On the other hand, when the power supply is not restored, the bus voltage continues to decrease.

Therefore, when the bus voltage drops below the first voltage threshold value Vth1, the contacts of the power supply relay 12 are opened, and then the contacts of the second inrush current prevention relay 13 are closed. Since it is a sequence operation, the bus voltage when the contact of the second inrush current prevention relay 13 is closed may be a voltage Vth1'which is further lower than the first voltage threshold value Vth1.

As long as the outdoor control unit 16 can operate even if the bus voltage falls below the first voltage threshold value Vth1 and continues to decrease, the outdoor control unit 16 connects the contacts of the second inrush current prevention relay 13. to continue. When the power supply is restored at a voltage at which the outdoor control unit 16 can operate, the voltage of the smoothing capacitor 14 can be recovered by the path passing through the second inrush current prevention relay 13 and the inrush current prevention resistor 11. Further, since the inrush current prevention resistor 11 is used, the inrush current value can be limited, and the failure of the subsequent circuit, for example, the outdoor rectifying unit 9 due to the excessive inrush current can be prevented.

When the bus voltage recovers and the power supply voltage returns to the stable voltage _VDD , the outdoor control unit 16 closes the contact of the power supply relay 12 after confirming that it is stable at the stable voltage _VDD , and then enters the second inrush. The contacts of the current prevention relay 13 are opened. As long as the power supply from the three-phase AC power supply 3 continues, the charging current to the smoothing capacitor 14 is supplied to the smoothing capacitor 14 via the power supply relay 12 and does not pass through the second inrush current prevention relay 13. .. By the above control operation, the unnecessary electric power in the air conditioner 100 can be reduced.

Finally, the hardware configuration for realizing the function of the indoor control unit 4 in the embodiment will be described with reference to the drawings of FIGS. 6 and 7. FIG. 6 is a block diagram showing an example of a hardware configuration in the indoor control unit of the embodiment. FIG. 7 is a block diagram showing another example of the hardware configuration in the indoor control unit of the embodiment.

When the function of the room control unit 4 in the embodiment is realized, as shown in FIG. 6, the processor 200 that performs the calculation, the memory 202 in which the program read by the processor 200 is stored, and the input / output of the signal are input / output. The configuration can include the interface 204 to be performed.

The processor 200 may be an arithmetic unit, a microprocessor, a microcomputer, a CPU (Central Processing Unit), or a DSP (Digital Signal Processor). Further, the memory 202 includes a non-volatile or volatile semiconductor memory such as a RAM (Random Access Memory), a ROM (Read Only Memory), a flash memory, an EPROM (Erasable Programmable ROM), an EEPROM (Electrically EPROM), a magnetic disk, and a flexible disk. A disk, an optical disk, a compact disk, a mini disk, and a DVD (Digital Versaille Disc) can be exemplified.

The memory 202 stores a program that executes the function of the room control unit 4 and a table referenced by the processor 200. The processor 200 sends and receives necessary information via the interface 204, the processor 200 executes a program stored in the memory 202, and the processor 200 refers to a table stored in the memory 202, thereby performing the above-mentioned arithmetic processing. It can be performed. The calculation result by the processor 200 can be stored in the memory 202.

Further, the processor 200 and the memory 202 shown in FIG. 6 may be replaced with the processing circuit 203 as shown in FIG. The processing circuit 203 corresponds to a single circuit, a composite circuit, an ASIC (Application Specific Integrated Circuit), an FPGA (Field-Programmable Gate Array), or a combination thereof.

The configuration shown in the above-described embodiment shows an example of the content of the present invention, can be combined with another known technique, and is configured without departing from the gist of the present invention. It is also possible to omit or change a part of.

1 outdoor unit, 2 indoor unit, 3 3-phase AC power supply, 4 indoor control unit, 5 indoor rectifier unit, 6 indoor communication circuit unit, 7 indoor operation switching unit, 8 outdoor start relay, 9 outdoor rectifier unit, 10 1st Inrush current prevention relay, 11 Inrush current prevention resistance, 12 Power supply relay, 13 Second inrush current prevention relay, 14 Smoothing capacitor, 15 Inverter circuit unit, 16 Outdoor control unit, 17 Outdoor operation switching unit, 18 Communication circuit power supply unit , 19 outdoor communication circuit, 20 power supply switching relay, 21 inrush current prevention relay drive, 22 indoor terminal block, 23 outdoor terminal block, 24 power line, 25 power signal common line, 26 signal line, 27 R terminal, 28 S terminal, 29 T terminal, 30 outdoor S1 terminal, 31 outdoor S2 terminal, 32 outdoor S3 terminal, 33 indoor S1 terminal, 34 indoor S2 terminal, 35 indoor S3 terminal, 36 remote relay receiver, 37 remote controller, 38, 40 transmitter , 39,41 Receiver, 50,60 Transmission Control, 51,61 Receive Control, 65 Power Line, 80 Compressor, 100 Air Conditioner, 200 Processor, 202 Memory, 203 Processing Circuit, 204 Interface.

Claims (6)

An air conditioner including an indoor unit and an outdoor unit, wherein the indoor unit activates the outdoor unit.
When the outdoor unit is activated, the indoor unit determines whether or not communication can be established with the outdoor unit, and even if communication cannot be established, the outdoor unit is not restarted. In addition, the indoor unit receives the first signal generated by the indoor unit by self-reception, and based on the result of the self-reception, it is determined whether or not to restart the outdoor unit. Air conditioner to do. The air conditioning according to claim 1, wherein when the indoor unit can receive the first signal in the self-reception, it determines that the communication on the side of the indoor unit is operating normally. Machine. When the indoor unit can receive the first signal in the self-reception, the indoor unit waits to receive the second signal generated by the outdoor unit, and cannot receive the second signal. The air conditioner according to claim 1, wherein the air conditioner is determined to have a communication abnormality without restarting the outdoor unit. When the indoor unit can receive the first signal in the self-reception, it waits to receive the second signal generated by the outdoor unit , and when it can receive the second signal, the indoor unit waits. The air conditioner according to claim 1, wherein steady communication is performed between the indoor unit and the outdoor unit. The air conditioner according to claim 1, wherein the indoor unit restarts the outdoor unit when the first signal cannot be received in the self-reception. The indoor unit and the outdoor unit are connected by three lines, a power supply line, a power supply signal common line, and a signal line.
The indoor unit and the outdoor unit each include a transmitting unit and a receiving unit.
A current loop is formed by inserting the transmitting unit and the receiving unit of the indoor unit and the transmitting unit and the receiving unit of the outdoor unit in series between the power supply signal common line and the signal line.
The air conditioner according to any one of claims 1 to 5 , wherein the indoor unit and the outdoor unit communicate by detecting a communication current flowing in the current loop.

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