JP5928423B2 - Air conditioner - Google Patents

Description

  The present invention relates to an air conditioner.

  For example, as described in Patent Document 1, conventionally, an air conditioner in which an outdoor unit and an indoor unit are connected by a plurality of electric wires is known. The air conditioner described in Patent Document 1 supplies power to a switching power supply and a control circuit provided in an indoor unit in order to reduce standby power, but a switching power supply provided in an outdoor unit. The suspend state in which no power is supplied is set in the control circuit and the control circuit of the outdoor unit by switching on the start-up switch by the control circuit of the indoor unit in order to shift from the suspended state to the operable state. It is configured to supply power to the power supply and activate it.

  On the other hand, Patent Document 2 discloses a technique in which a capacitor provided in an inverter system for driving a compressor motor or the like is used as a smoothing capacitor for a switching power supply.

JP 2013-137116 A JP 2010-213473 A

  When trying to apply the inverter system described in Patent Document 2 to the air conditioner of the standby power reduction specification in Patent Document 1, in order to charge the smoothing capacitor of the switching power supply of the outdoor unit, the starter provided in the indoor unit It is necessary to separately provide a charging circuit for charging the smoothing capacitor when the switch is turned on. However, in this case, if a short circuit occurs in the DC power supply line in the inverter system, not only charging of the smoothing capacitor becomes impossible, but an overcurrent flows in the charging circuit and damages parts in the charging circuit. there is a possibility.

  An object of this invention is to provide the air conditioning apparatus which can prevent the overcurrent in the charging electrical circuit for charging the capacitor | condenser of the power supply circuit of an outdoor unit, and can prevent damage etc. of components.

(1) The air conditioner of the present invention is provided between a rectifier circuit connected to an AC power supply, an inverter circuit connected to the rectifier circuit via two DC power supply lines , and two DC power supply lines. Further, a clamp circuit including a clamp capacitor , and a smoothing circuit provided in parallel with the clamp circuit between the two DC power supply lines on the rectifier circuit side of the clamp circuit and having a smaller capacity than the clamp capacitor A first outdoor power supply circuit having a capacitor ;
A room-side power supply circuit that is activated by power supplied from the AC power supply;
An indoor control circuit to which power is supplied from the indoor power supply circuit;
A switch that is on / off controlled by the indoor control circuit;
A second outdoor power circuit using the clamp capacitor for voltage smoothing;
A charging circuit that includes the DC power supply line, is connected to and disconnected by the switch, and charges the clamp capacitor to activate the second outdoor power supply circuit.
The charging circuit is provided with protection means for limiting overcurrent when the two DC power supply lines are short-circuited.

  According to this configuration, it is possible to prevent the components on the charging circuit from being damaged by the overcurrent generated when the two DC power supply lines are short-circuited.

(2) It is preferable that the protection means is a PTC thermistor whose resistance value is increased by a temperature rise due to an overcurrent flowing on the charging circuit.
According to this configuration, even if a short circuit occurs in the two DC power supply lines and an overcurrent flows in the charging circuit, the resistance value increases due to the temperature rise of the PTC thermistor, and the overcurrent is suitably limited. be able to.

  ADVANTAGE OF THE INVENTION According to this invention, the overcurrent in the charge electric circuit for charging the capacitor | condenser of the power supply circuit of an outdoor unit can be prevented, and damage etc. of components can be prevented.

It is a block diagram of the electrical equipment system of the air conditioning apparatus which concerns on one embodiment of this invention. It is a block diagram of the electrical system which shows the state of each relay at the time of forming the circuit charged in the smoothing capacitor of the outdoor power supply circuit in the air conditioner. It is a block diagram of the electrical system which shows the state of each relay after the transfer to a charge state is completed. It is a block diagram of the electrical system which shows the state of each relay at the time of completion of the transition to a wait state. It is a state transition diagram of an air harmony device.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
〔overall structure〕
FIG. 1 is a block diagram of an electrical system of an air conditioner 1 according to an embodiment of the present invention.
The air conditioner 1 is an air conditioner that can cut off the power supply to the outdoor unit 10 during operation stop. As shown in FIG. 1, the air conditioner 1 includes an outdoor unit 10, an indoor unit 20, and a remote controller 30.

  Although illustration is omitted, the outdoor unit 10 is provided with devices such as an electric compressor, an outdoor heat exchanger, an outdoor fan, and an expansion valve, and the indoor unit 20 includes devices such as an indoor heat exchanger and an indoor fan. Is provided. In the air conditioner 1, the refrigerant circuit (illustration omitted) which performs a refrigerating cycle is comprised by these apparatuses.

  The air conditioner 1 receives alternating current (in this example, 200 V three-phase alternating current) from a commercial alternating current power supply 40 (hereinafter also simply referred to as alternating current power supply) in the outdoor unit 10. The electric power of the AC power supply 40 is supplied to a circuit in the outdoor unit 10 and an electric compressor, and further, the two-phase part of the three-phase AC is supplied to the indoor unit 20. Further, the outdoor unit 10 and the indoor unit 20 communicate signals for the purpose of controlling the outdoor unit 10 from the indoor unit 20 side. Therefore, between the outdoor unit 10 and the indoor unit 20, the power line L for transmitting AC power from the AC power source 40, the signal line S for transmitting signals, and the AC power transmission and the signal transmission are shared. Three lines (internal / external wiring) with the common line N are provided.

  In the present embodiment, power wiring L is connected to the R phase of AC power supply 40 in outdoor unit 10, and common line N is connected to the S phase of AC power supply 40 in outdoor unit 10. Therefore, the indoor unit 20 is connected to the R phase and the S phase of the AC power supply 40 and supplied with single-phase AC. In addition to signal transmission / reception, the signal line S is also used for AC power transmission, as will be described later.

[Configuration of outdoor unit 10]
The outdoor unit 10 includes a first outdoor power supply circuit 14, a second outdoor power supply circuit 12, an outdoor unit transmission circuit 11, an outdoor control circuit 13, and relays K13R, K14R, and K15R as an electrical system.

(First outdoor power circuit 14)
The first outdoor power supply circuit 14 converts the three-phase alternating current received from the alternating current power supply 40 into direct current, and supplies the direct current to the inverter circuit and the outdoor fan motor. The inverter circuit converts the input direct current into alternating current having a predetermined frequency and voltage, and supplies alternating current power to the motor of the electric compressor. In the present embodiment, the first outdoor power supply circuit 14 includes a filter circuit 14a, two main relays 14b, a diode bridge circuit (rectifier circuit) 14c, a reactor 14d, a capacitor 14e, a clamp circuit 14f, and the like.

  The filter circuit 14a is formed by a capacitor, a coil, or the like. The two main relays 14b are provided on the supply lines for the three-phase AC R-phase and T-phase, respectively. The diode bridge circuit 14c performs full-wave rectification on the alternating current input through the filter circuit 14a. The output of the diode bridge circuit 14c is connected to an inverter circuit and an indoor fan motor via two DC power supply lines LH and LL.

  The high potential side first DC power supply line LH is provided with a reactor 14d, and a capacitor 14e is provided between the first DC power supply line LH and the low potential side second DC power supply line LL. In this embodiment, the reactor 14d and the capacitor 14e are very small compared to a general smoothing reactor or capacitor. For example, the reactor 14d is about 0.5 mH. For example, a film capacitor of about 30 μF is used as the capacitor 14e.

  Moreover, since the capacity | capacitance of the capacitor | condenser 14e is small, it becomes difficult to absorb the regenerative energy by inertia rotation of motors, such as a compressor, with the capacitor | condenser 14e. Therefore, in this embodiment, a clamp circuit 14f is provided in parallel with the capacitor 14e, and the clamp circuit 14f is configured to absorb regenerative energy.

  The clamp circuit 14f includes a clamp diode 14f1, a resistor 14f2, and a clamp capacitor 14f3, which are connected in series between the DC power supply lines LH and LL. The clamp diode 14f1 is arranged with its anode directed to the first DC power supply line LH and its cathode directed to the second DC power supply line LL. The clamp capacitor 14f3 has a larger capacity than the smoothing capacitor 14e, for example, an electrolytic capacitor of about 120 μF.

(Second outdoor power circuit 12)
The second outdoor power supply circuit 12 receives direct current from the first and second DC power supply lines LH and LL, converts it into direct current of a predetermined voltage, and supplies the direct current to the outdoor control circuit 13. The second outdoor power supply circuit 12 of the present embodiment includes a clamp capacitor 14f3 that constitutes the clamp circuit 14f, and a switching power supply 12c. That is, the second outdoor power supply circuit 12 uses the clamp capacitor 14f3 of the clamp circuit 14f to smooth the output of the diode bridge circuit 14c and inputs the smoothed output to the switching power supply 12c. The switching power supply 12 c is configured by, for example, a DC-DC converter, converts the input direct current into a predetermined voltage (for example, 5 V), and outputs it to the outdoor control circuit 13. Thus, by using the clamp capacitor 14f3 of the clamp circuit 14f as the smoothing capacitor of the second outdoor power supply circuit 12, the circuit configuration can be simplified, and the manufacturing cost can be reduced.

(Outdoor unit transmission circuit 11)
The outdoor unit transmission circuit 11 performs signal communication with the indoor unit transmission circuit 21. In this communication, high-level and low-level binary digital signals are communicated based on the potential difference between the signal line S and the common line N. One end of the communication circuit (not shown) in the outdoor unit transmission circuit 11 is connected to the common line N, and the other end of the communication circuit is connected to the signal line S via the relay K14R.

(Relay K13R)
The relay K13R is a relay that switches the AC supply path to the second outdoor power supply circuit 12. The relay K13R is a so-called C contact relay. Specifically, the relay K13R has two fixed contacts and one movable contact. When the coil of the relay K13R is not energized, one fixed contact (referred to as a normally closed contact) and the movable contact are connected. When the coil is energized, the other fixed contact (referred to as a normally open contact) and the movable contact are connected. The outdoor control circuit 13 controls switching of the relay K13R (whether the coil is energized).

  In the present embodiment, the movable contact of the relay K13R is connected to the second DC power supply line LL between the capacitor 14e and the clamp circuit 14f via the charging line 27. On the charging line 27, a diode 28, a resistor 29, and a PTC thermistor 26 are provided. The normally closed contact is connected to the signal line S, and the normally open contact is connected to the R phase of the three-phase alternating current. Therefore, when the coil of the relay K13R is not energized, the normally closed contact and the movable contact are connected, and the second DC power supply line LL is connected to the signal line S. When the coil of the relay K13R is energized, the movable contact and the normally open contact are connected, and a power transmission path (see the thick line in FIG. 3) connecting the R phase to the S phase of the three-phase alternating current is formed. AC is input to the capacitor 14f3 of the circuit 12. The PTC thermistor 26 constitutes the protection means of the present invention, and details thereof will be described later.

(Relay K14R)
The relay K14R is a relay that switches connection and disconnection between the signal line S and the outdoor unit transmission circuit 11. The outdoor control circuit 13 controls the on / off of the relay K14R.

(Relay K15R)
The relay K15R is a relay that switches the presence / absence of power supply to the outdoor unit transmission circuit 11. When relay K15R is turned on, power is supplied from AC power supply 40 to outdoor unit transmission circuit 11, and when relay K15R is turned off, power supply from AC power supply 40 to outdoor unit transmission circuit 11 is cut off. The outdoor side control circuit 13 controls on / off of the relay K15R.

(Outdoor control circuit 13)
The outdoor control circuit 13 includes a microcomputer and a memory that stores a program for operating the microcomputer. The outdoor control circuit 13 controls the electric compressor and the like in response to a signal received from the indoor unit transmission circuit 21 by the outdoor unit transmission circuit 11, for example, and also performs control (described later) when the outdoor unit 10 is started. When the air-conditioning apparatus 1 is in the suspended state (described later in detail), the outdoor side control circuit 13 stops the operation because the power supply is cut off.

[Configuration of indoor unit 20]
The indoor unit 20 includes an indoor power supply circuit 22, an indoor unit transmission circuit 21, an indoor control circuit 23, a relay K2R, a diode D1, and the like as an electrical system.

(Indoor side power supply circuit 22)
The indoor power supply circuit 22 includes a diode bridge circuit 22b, a smoothing capacitor 22c, and a switching power supply 22d. The indoor side power supply circuit 22 converts the alternating current supplied from the alternating current power supply 40 through the power wiring L and the common line N into a direct current (for example, a direct current of 5 V) and supplies the direct current to the indoor control circuit 23.

  In the present embodiment, the diode bridge circuit 22b performs full-wave rectification on the alternating current input from the power line L and the common line N. The smoothing capacitor 22c is formed of, for example, an electrolytic capacitor, and smoothes the output of the diode bridge circuit 22b. The switching power supply 22d is constituted by, for example, a DC-DC converter or the like, converts the direct current smoothed by the smoothing capacitor 22c into a predetermined voltage (5V), and outputs the same to the indoor control circuit 23.

(Indoor unit transmission circuit 21)
As described above, the indoor unit transmission circuit 21 communicates signals with the outdoor unit transmission circuit 11. In this communication, since digital signal communication is performed based on the potential difference between the signal line S and the common line N, one end of the communication circuit of the indoor unit transmission circuit 21 is connected to the signal line S, and the other end is common. Connected to line N.

(Relay K2R)
The relay K2R is provided on the bypass line 25 that connects the power line L and the signal line S, and functions as a switch that switches connection and disconnection between the power line L and the signal line S. That is, when the relay K2R is turned on, the power line L and the signal line S are connected, and when the relay K2R is turned off, the power line L and the signal line S are disconnected. The indoor side control circuit 23 controls ON / OFF of the relay K2R. The relay K2R is an example of a switch in the present invention, and has a function as an activation unit that starts power supply to the outdoor unit 10 from which power supply is interrupted.

(Diode D1)
The diode D1 is provided in series with the relay K2R on the bypass line 25 that connects the power line L and the signal line S. Specifically, the diode D1 has an anode connected to the connection node ND1 between the bypass line 25 and the signal line S, and a cathode connected to the relay K2R. The diode D1 has a function of blocking an alternating current flowing in the direction into the indoor unit transmission circuit 21.

(Indoor control circuit 23)
The indoor side control circuit 23 includes a microcomputer and a memory storing a program for operating the microcomputer. The indoor side control circuit 23 receives an instruction from the remote controller 30 and controls the operating state of the air conditioner 1. The indoor side control circuit 23 is always supplied with power by the indoor side power supply circuit 22 in order to receive a command from the remote controller 30.

(Remote controller 30)
The remote controller 30 receives a user operation and transmits a signal corresponding to the user operation to the indoor control circuit 23. For example, the user can start and stop the air conditioner 1 and adjust the set temperature by operating a button on the remote controller 30. The remote controller 30 may be configured as a so-called wired remote controller connected to the indoor control circuit 23 with a signal line, or may be configured as a so-called wireless remote controller that communicates with the indoor control circuit 23 using infrared rays or radio waves. May be.

[Operation of the air conditioner 1]
As shown in FIG. 5, the air-conditioning apparatus 1 of the present embodiment transitions between four states: a suspend state, a charge state, a wait state, and an operation state. When the operation of the air conditioner 1 is started, the transition is made from the suspended state to the operating state in the order shown by the solid line arrows in FIG. 5, and when the operation is stopped, the broken line arrows are shown in the same figure. In order, the operation state changes to the suspend state.
In the following, standby power refers to “power that is steadily consumed when the device is not in use or is waiting for some input (command instruction or the like)”. Specifically, in the air conditioning apparatus 1, the power necessary for performing only the standby of the remote controller 30 is standby power.

(1) Suspended state The suspended state is a state in which power is supplied to the indoor unit 20 and power is not supplied to the outdoor unit 10.
As an example, the suspended state of the present embodiment is a state where the power consumption of the entire air conditioner 1 is minimized. Specifically, in the suspended state of the present embodiment, the outdoor unit 10 receives power and supplies it to the indoor unit 20, but power is supplied to each circuit, electric compressor, and the like inside the outdoor unit 10. It is a state that has not been done. Thus, in the suspended state, power supply to each circuit of the outdoor unit 10 is cut off, and standby power can be reduced.

  On the other hand, the indoor unit 20 is in a state in which standby power is minimized, and a portion of the indoor side control circuit 23 that is involved in signal reception from the remote controller 30 operates by receiving power from the indoor side power supply circuit 22. Note that the remote controller 30 is also in a state where standby power is minimized, but a button operation can be accepted. Note that the power consumption (standby power) of the indoor unit 20 and the remote controller 30 is not limited to this.

(2) Charging state In the outdoor unit 10, a circuit that charges the smoothing capacitor (clamp capacitor) 14 f 3 of the second outdoor power supply circuit 12 is formed in the outdoor unit 10, and the outdoor unit transmission circuit 11 and the indoor unit transmission circuit 21. This means a state in a period until signal transmission is started. At this time, the power consumption of the indoor unit 20 is the same as in the suspended state.

(3) Wait state The wait state is a state in which the charging state is exited at the start of operation, and a transition from the operation state (described later) when the operation is stopped. In any case, the outdoor unit 10 is in a state where it can immediately shift to an operation state (described later). In the weight state, the outdoor unit transmission circuit 11 and the outdoor control circuit 13 can be operated. In particular, the weight state when the operation is stopped is provided for equalizing the refrigerant pressure in the electric compressor or when a schedule operation that repeats the operation start and operation stop is set. For example, 10 minutes. The power consumption of the indoor unit 20 is the same as that in the suspended state. In FIG. 5, after returning from the wait state to the suspend state, the transition from the charge state to the wait state is performed again by an operation start instruction or the like by operating the remote controller 30.

(4) Operational state The operational state refers to a state where the main relay 14b of the first outdoor power supply circuit 14 is turned on and the electric compressor and the outdoor fan can be operated or are in operation. This also applies to so-called phase loss energization and thermo-off state. In the indoor unit 20, the indoor fan or the like is in an operating state, and the power consumption is greater than in each of the above states.

[Electrical system in suspended state]
The state of the electrical system in the suspend state will be described.
In FIG. 1, in the suspended state, the outdoor unit 10 is in a state where the main relay 14 b is off, and no power is supplied from the first outdoor power supply circuit 14 to the intelligent power module or the outdoor fan motor. Further, the relay K14R and the relay K15R are also in the off state. For this reason, the outdoor unit transmission circuit 11 is disconnected from the signal line S and also supplied with power. Further, the smoothing capacitor 22c in the indoor side power supply circuit 22 is charged by the electric power from the AC power supply 40, and the switching power supply 22d is brought up, and the indoor side control circuit 23 is activated by the power supply from the indoor side power supply circuit 22 It becomes a state.

  The relay K13R is in a state where the normally closed contact and the movable contact are connected. Further, in the indoor unit 20 in the suspended state, the relay K2R is in the off state, and the bypass line 25 between the signal line S and the power line L is in a disconnected state. Therefore, in this state, power is not supplied to the second outdoor power supply circuit 12 and power supply to the outdoor control circuit 13 is not performed. Therefore, in the suspended state, the outdoor unit 10 is not supplied with power.

[Transition from suspended state to charged state]
FIG. 2 is a block diagram of the electrical system showing the state of each relay at the time when the circuit charged to the smoothing capacitor 14f3 of the second outdoor power supply circuit 12 is formed.
As shown in FIG. 2, when the user operates the remote controller 30 in the suspended state and instructs the start of the operation of the air conditioner 1 (for example, the start of the cooling operation), the indoor side control circuit 23 Turn on K2R. Then, from the R phase of the three-phase AC, the power wiring L, the relay K2R and the diode D1 on the bypass line 25, the signal line S, the relay K13R, the resistor 29 on the charging line 27, the diode 28, the PTC thermistor 26, and the clamp circuit 14f Then, a power transmission path (first charging electric circuit P1 indicated by a thick line in FIG. 2) connected to the S phase through the reactor 14d and the diode bridge circuit 14c is formed. As a result, a circuit for charging the smoothing capacitor 14f3 is formed.

  When the three-phase AC R-phase potential is higher than the S-phase potential, the diode D1 prevents AC current flowing in the direction from the power line L to the indoor unit transmission circuit 21 and the outdoor unit 10. . The indoor unit transmission circuit 21 is connected to the R phase via the indoor side power supply circuit 22, but the alternating current flowing in the direction from the indoor unit transmission circuit 21 to the signal line S is blocked by an internal diode or the like. Conversely, when the S-phase potential of the three-phase alternating current is higher than the R-phase potential, an alternating current flows through the charging circuit.

  When charging to the smoothing capacitor 14f3 is started and the input to the switching power supply 12c is stabilized, the switching power supply 12c can output a specified DC voltage (5 V in this example). That is, the switching power supply 12c is activated. Thereby, electric power is supplied from the switching power supply 12c to the outdoor control circuit 13, and the outdoor control circuit 13 is activated.

  When a predetermined time elapses after activation, the outdoor side control circuit 13 energizes the coil of the relay K13R to switch to a state (ON state) in which the normally open contact and the movable contact are connected (see FIG. 3). As a result, a power transmission path (see FIG. 3) connected from the R phase of the three-phase AC to the S phase via the relay K13R, the resistor 29 on the charging line 27, the diode 28, the PTC thermistor 26, the clamp circuit 14f, and the diode bridge circuit 14c. A second charging circuit P2) indicated by a bold line is formed. That is, the second outdoor power supply circuit 12 switches to a state where power is supplied from the AC power supply 40 without going through the signal line S. Further, the outdoor side control circuit 13 turns on the relay K15R at the same time (see FIG. 3). Thereby, electric power is supplied to the outdoor unit transmission circuit 11. Thus, the transition to the charged state is completed.

[Transition from charge state to wait state]
FIG. 4 is a block diagram of the electrical system showing the state of each relay after completion of the transition to the wait state.
As shown in FIG. 4, in the indoor unit 20, the indoor side control circuit 23, after a predetermined time (at least enough time for the outdoor side control circuit 13 to start) has elapsed since turning on the relay K <b> 2 </ b> R, The relay K2R is turned off. Thus, the signal line S can be used for signal transmission / reception.

  Moreover, in the outdoor unit 10, the outdoor side control circuit 13 turns on the relay K14R after a predetermined time has elapsed since it started. As a result, the communication circuit in the outdoor unit transmission circuit 11 is connected to the indoor unit transmission circuit 21 via the signal line S and the common line N, and can communicate with the indoor unit transmission circuit 21. The predetermined time from when the outdoor control circuit 13 is activated to when the relay K14R is turned on is set so that the relay K14R is turned on after the relay K2R is turned off.

Thereafter, the outdoor unit transmission circuit 11 starts communication with the indoor unit transmission circuit 21.
As a result, the air conditioner 1 enters a state (that is, a wait state) in which the air conditioner 1 can exit the charging state and shift to the immediate operation state.

[Transition from wait state to operation state]
When shifting from the weight state shown in FIG. 4 to the operation state, the outdoor control circuit 13 turns on the two main relays 14b. Thereby, electric power is supplied to the intelligent power module and the outdoor fan motor by the first outdoor power supply circuit 14, and the electric compressor or the like is put into an operating state, for example, cooling is performed.

[Operation when PN short circuit occurs]
In the air conditioner 1 configured as described above, for example, as shown in FIG. 2, the first and second DC power supply lines LH and LL of the first outdoor power supply circuit 14 due to adhesion of dust on the substrate or the like. May cause a short circuit (PN (between positive and negative electrodes) short circuit) SH. However, for example, when such a short circuit occurs when shifting from the suspended state to the charged state, the charging circuit P1 indicated by a bold line is to be formed via the clamp circuit 14f when the relay K2R is turned on. Without being formed through the short circuit SH (the first and second DC power supply lines LH and LL and the charging line 27 are directly connected). In this case, an element such as a capacitor that blocks the flow of current from the S phase to the R phase does not exist on the charging circuit P1, and thus an overcurrent may flow.

  In view of such an inconvenience, the PTC thermistor 26 is provided on the charging wire 27 in the air conditioner 1 of the present embodiment. The PTC thermistor 26 is a resistor whose resistance value changes with temperature. In particular, the PTC thermistor 26 is a positive temperature coefficient thermistor whose resistance value increases as the temperature rises. For this reason, the PTC thermistor 26 increases its resistance value due to self-heating when an overcurrent flows through the charging circuit P1, and can limit the overcurrent. Therefore, it is possible to suitably prevent the components 28, 29, K13R, D1, and K2R on the charging circuit P1 from being damaged due to a short circuit between the first and second DC power supply lines LH and LL. It becomes.

The present invention is not limited to the above-described embodiment, and can be appropriately changed within the scope of the invention described in the claims.
For example, a semiconductor switch (such as a transistor) may be used instead of the relays K2R and K14R.
A single-phase alternating current may be used for the commercial alternating current power supply 40.

1: Air conditioner 12: Second outdoor power circuit 14: First outdoor power circuit 14c: Diode bridge circuit (rectifier circuit)
14f: Clamp circuit 14f3: Clamp capacitor 22: Indoor side power supply circuit 23: Indoor side control circuit 26: PTC thermistor 40: AC power supply LH: First DC power supply line LL: Second DC power supply line P1: First charging circuit

Claims (2)

Rectifier circuit connected to an AC power supply (40) (14c), two DC power supply lines (LH, LL) inverter circuit connected the to the rectifier circuit (14c) through said two DC power supply lines ( LH, LL), a clamp circuit (14f) including a clamp capacitor (14f3) , and the two DC power lines (on the rectifier circuit (14c) side of the clamp circuit (14f)) A first outdoor power supply circuit (14) having a smoothing capacitor (14e) provided in parallel with the clamp circuit (14f) between LH, LL) and having a smaller capacity than the clamp capacitor (14f3) ;
A room-side power supply circuit (22) that is activated by power supplied from the AC power supply (40);
An indoor control circuit (23) to which power is supplied from the indoor power supply circuit (22);
A switch (K2R) that is on / off controlled by the indoor control circuit (23);
A second outdoor power supply circuit (12) using the clamp capacitor (14f3) for voltage smoothing;
A charging circuit that includes the DC power supply lines (LH, LL) and is connected to the switch (K2R) and charges the clamp capacitor (14f3) to activate the second outdoor power supply circuit (12) (P1)
The air conditioner characterized in that the charging circuit (P1) is provided with protection means (26) for limiting an overcurrent when the two DC power supply lines (LH, LL) are short-circuited.   The air conditioner according to claim 1, wherein the protection means (26) is a PTC thermistor whose resistance value is increased by a temperature rise caused by an overcurrent flowing on the charging circuit (P1).

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