JP6567930B2 - Air conditioner - Google Patents

Description

  The present invention relates to an air conditioner including a power supply unit that discharges a capacitor when a power supply is shut off.

  The power supply unit provided in the air conditioner includes a rectifier circuit that converts an input AC voltage into a DC voltage, and a smoothing capacitor that smoothes the DC voltage. The power supply unit supplies a DC voltage generated from a commercial AC power supply to a load such as a fan motor or a compressor. In the power supply unit, a noise absorbing capacitor is provided in front of the rectifier circuit in order to reduce the noise terminal voltage and the noise voltage defined by the Electrical Appliance and Material Safety Law. Further, a discharge resistor for discharging the charge stored in the capacitor is provided in parallel with the capacitor. When the power plug is disconnected from the outlet and no AC voltage is input, the electric charge accumulated in the capacitor is discharged through the discharge resistor.

  The discharge time for discharging the capacitor charge must be within the time stipulated by the Electrical Appliance and Material Safety Law. That is, it must be discharged so that it becomes 1 V or less within 1 second. In order to satisfy such a standard, the capacitance of the capacitor and the resistance value of the discharge resistor are adjusted.

  During the air conditioning operation, the circuit load increases, that is, a large amount of current flows. At this time, the noise level generated in the switching unit of each circuit increases, and the noise terminal voltage and noise power increase. When the capacitance of the capacitor is large, the noise absorption level is improved, and the noise terminal voltage and noise power can be lowered. On the other hand, at the time of standby when the air conditioning operation is not performed, the circuit load is small and the flowing current is small. At this time, the noise level becomes small.

  If the capacity of the capacitor is increased in order to prevent noise from leaking to the outside, the discharge time required to discharge the capacitor charge when the power supply is cut off is increased. If the resistance value of the discharge resistor is reduced, the discharge time can be shortened. However, if the resistance value of the discharge resistor is small, a large amount of current flows through the discharge resistor during standby, and power consumption during standby increases.

  In Patent Document 1, when power is input, the discharge resistor and the capacitor are disconnected from each other, and power consumption during standby can be reduced. When the power supply is cut off, the discharge resistor and the capacitor are connected. In Patent Document 2, normally, the switch element is disabled and no current flows through the discharge resistor. When the power is cut off, the timing until the switch element starts to be conducted is advanced, and the period until the capacitor starts to be discharged is shortened.

JP 2002-48375 A JP 2009-165208 A

  As described above, in order to reduce power consumption during standby, it is only necessary to prevent current from flowing through the discharge resistor. However, in Patent Document 2, the timing at which discharge starts is only accelerated. That is, the discharge time required to discharge the electric charge stored in the capacitor is not shortened. Therefore, it is not possible to reduce the power consumption during standby and to shorten the discharge time when the power is shut off.

  Therefore, in view of the above, an object of the present invention is to provide an air conditioner that can reduce not only power consumption during standby but also discharge time when power is shut off.

  The air conditioner of the present invention includes a power supply unit for converting an AC voltage into a DC voltage and supplying the DC voltage to a load, and the power supply unit discharges a capacitor and a charge stored in the capacitor. In order to shorten the discharge time of the capacitor when the power is cut off, a discharge unit is provided for changing the discharge path from the capacitor to the discharge resistor.

  When there is a discharge path with a long discharge time and a discharge path with a short discharge time, the discharge unit can use a discharge path with a short discharge time when the power supply is shut down such that the power plug is disconnected from the outlet.

  As a capacitor of the power supply unit, a first capacitor having a large capacity for absorbing noise and a second capacitor having a small capacity are provided, and an operation discharge path that does not pass through the second capacitor and a standby discharge path that passes through the second capacitor are formed. The discharge unit uses the operation discharge path during air-conditioning operation and switches to the standby discharge path during standby.

  By using an operation discharge path having a large-capacity capacitor during air conditioning operation, noise generated during operation can be absorbed. At this time, the discharge time by the operation discharge path is long, but even if the power is cut off during the air conditioning operation, the other circuit components are operating, and therefore, the discharge is performed through the other circuit components. A standby discharge path with a small capacitor during standby is used. At this time, when the power supply is cut off, the electric charge stored in the capacitor is small, so that even if a discharge resistor having a high resistance value is used, it can be discharged in a short time. By using a discharge resistor having a large resistance, power consumption during standby can be reduced.

  The discharge unit switches the discharge path when the AC voltage crosses zero. When the AC voltage crosses zero, the capacitor is not charged. By switching the discharge path at this time, it is possible to eliminate the residual charge of the capacitor that is no longer used due to the change of the discharge path.

  The capacitor of the power supply unit is a smoothing capacitor, and a first discharge resistor having a large resistance value and a second discharge resistor having a small resistance value are provided as discharge resistors, and a normal discharge path and a second discharge resistor passing through the first discharge resistor are provided. A rapid discharge path is formed, and the discharge unit uses the normal discharge path during air-conditioning operation and switches to the rapid discharge path when the power is shut off.

  By switching to the rapid discharge path having a low resistance when the power is shut off, the discharge time is shortened compared to the case of using the normal discharge path having a high resistance. During the air conditioning operation, a normal discharge path having a large resistance is used, so that power consumption at the discharge resistance can be reduced.

  When a control unit that is operated by a DC voltage supplied from the power supply unit is provided, a current fuse is provided between the control unit and the power supply unit, and when the current fuse is blown and the power supply to the control unit is shut off, The discharge unit switches from the normal discharge path to the rapid discharge path.

  If power is not supplied to the control unit due to the current fuse being blown, the control unit will not operate. At this time, since the normal discharge path is automatically switched to the rapid discharge path, the electric charge stored in the smoothing capacitor is quickly discharged.

  According to the present invention, by changing from a discharge path having a long discharge time to a discharge path having a short discharge time, it is possible to quickly discharge when the power is cut off, and the subsequent work can be performed without any trouble. In addition, by changing the discharge path so as to use a discharge path with less resistance during standby, power consumption due to the discharge resistance can be reduced, and energy saving can be achieved.

The figure which shows the electrical connection of the indoor unit of the air conditioner of this invention, and an outdoor unit Circuit block diagram of power supply unit and discharge unit of indoor unit of first embodiment Circuit block diagram of power supply unit of outdoor unit Circuit block diagram of power supply unit and discharge unit of indoor unit of second embodiment Diagram showing clock pulse generated at zero crossing of AC voltage Circuit block diagram of power supply unit and discharge unit of indoor unit of fifth embodiment Circuit block diagram of power supply unit and discharge unit of outdoor unit of sixth embodiment Circuit block diagram of power supply unit and discharge unit of outdoor unit of seventh embodiment Circuit block diagram of power supply unit and discharge unit of outdoor unit of eighth embodiment Circuit block diagram of power supply unit according to ninth embodiment The figure which shows the electrical equipment board which loads the circuit protection component The figure which shows the electrical equipment board which loads the conventional circuit protection component The figure which shows the electrical equipment board with the exchange board which loads the circuit protection component The figure which shows the electrical equipment board which mounts the exchange board Circuit diagram of electrical board with replacement board connected The figure which shows the electrical equipment board with the exchange board which mounted the circuit protection component of 10th Embodiment. The figure which shows the electrical equipment board which connected the exchange board The figure which shows the electrical equipment board carrying the circuit protection component for replacement | exchange of 11th Embodiment Circuit diagram of two sets of circuit protection components The figure which shows the electrical equipment board before exchanging the circuit protection component The figure which shows the electrical equipment board after exchanging the circuit protection component The figure which shows the wiring between the indoor unit and outdoor unit of 12th Embodiment The figure which shows the communication circuit of the indoor unit Diagram showing miswiring detector Diagram showing the output of the miswiring detector when it is wired correctly The figure which shows the miswiring detection part of 13th Embodiment The figure which shows the miswiring detection part of 14th Embodiment. (A) The figure which shows the output of the mis-wiring detection part when correctly wired, (b) The figure which shows the output of the mis-wiring detecting part when mis-wired Diagram showing incorrect wiring between indoor unit and outdoor unit The figure which shows the miswiring detection part of 15th Embodiment.

(First embodiment)
The air conditioner of the present embodiment is configured by connecting an indoor unit and an outdoor unit by refrigerant piping and wiring. The indoor unit includes an indoor heat exchanger and a blower fan. The outdoor unit includes a compressor, a four-way valve, an outdoor heat exchanger, an expansion valve, and an outdoor fan. As shown in FIG. 1, the air conditioner converts an AC voltage from a commercial AC power source into a DC voltage, and supplies the DC voltage to a load. A drive unit 2 for driving the load by converting into a load, and a control unit 3 for controlling the operation of the load. In addition, the power supply part 1, the drive part 2, and the control part 3 are each provided in an indoor unit and an outdoor unit.

  Commercial AC power is supplied to the indoor unit and the outdoor unit, respectively. The indoor unit and the outdoor unit are provided with a terminal plate 4, each terminal plate 4 is provided with a plurality of terminals, and the plurality of terminals are connected to each other by a plurality of connection lines. The control unit 3 of the indoor unit and the control unit 3 of the outdoor unit transmit and receive serial signals via a communication connection line. A power switch 6 is provided on the power line 5 in the indoor unit. The power switch 6 composed of a relay is turned on / off by a command from the control unit 3. When the power switch 6 is turned on, AC power is supplied to the outdoor unit. When the power switch 6 is turned off, the AC power to the outdoor unit is cut off.

  As shown in FIG. 2, the power supply unit 1 of the indoor unit includes a rectifier circuit 10 and a smoothing capacitor 11. The rectifier circuit 10 connected to the AC power supply line 12 includes a diode bridge. A smoothing capacitor 11 and a discharge resistor 13 are connected in parallel between the DC power supply lines 14. The drive unit 2 includes a fan motor circuit for driving a load such as a fan motor 15 of the blower fan and the control unit 3, a switching power supply circuit 16, and the like. The control unit 3 includes a microcomputer, a memory, and the like, and operates by a stabilized DC voltage supplied from a switching power supply circuit 16 connected to the DC power supply line 14.

  As shown in FIG. 3, the power supply unit 1 of the outdoor unit has a rectifier circuit 10, a smoothing capacitor 11, and a discharge resistor 13, similarly to the power supply unit 1 of the indoor unit. The drive unit 2 includes a compressor 17, a fan motor 18 for an outdoor fan, a fan motor circuit for driving loads such as the control unit 3, an inverter circuit, and a switching power supply circuit 16. The control unit 3 includes a microcomputer and a memory. Reference numeral 19 denotes a current fuse for protecting the switching power supply circuit 15.

  In the power supply unit 1 of the indoor unit, noise terminal voltage and noise power are reduced so that noise does not leak outside. As shown in FIG. 2, a noise absorbing first capacitor 25 is provided in the AC power supply line 12 as a countermeasure against this noise. A discharge resistor 26 for discharging the charge stored in the first capacitor 25 is connected in parallel with the first capacitor 25.

  Here, the first capacitor 25 and the second capacitor 27 having different capacities are used as noise absorbing capacitors. The capacity of the first capacitor 25 is larger than the capacity of the second capacitor 27. For example, the capacity of the first capacitor 25 is 0.1 μF, and the capacity of the second capacitor 27 is 0.01 μF. In the AC power supply line 12, the first capacitor 25 and the second capacitor 27 are connected in parallel. The discharge resistor 26 is disposed between the capacitors 25 and 27 and the rectifier circuit 10.

  As a result, two discharge paths passing through the capacitors 25 and 27 are formed. The discharge path from the first capacitor 25 through the discharge resistor 26 is the operating discharge path, and the discharge path from the second capacitor 27 through the discharge resistor 26 is the standby discharge path. The operating discharge path is a discharge path that does not pass through the second capacitor 27.

  The large-capacity first capacitor 25 is more effective in reducing noise than the small-capacity second capacitor 27. Therefore, the 1st capacitor | condenser 25 is suitable for using at the time of an air conditioning driving | operation with much generation | occurrence | production of noise. On the other hand, when the compressor 17 and the indoor and outdoor fans are not operating, noise generation is small, so the second capacitor 27 having a small capacity may be used. In addition, since the charge stored in the second capacitor 27 having a small capacity is small, the discharge time is shortened. Therefore, it is suitable to use the second capacitor 27 during standby.

  Therefore, a discharge unit 30 is provided that changes the discharge path according to the operation status. The control unit 3 determines the operation status and operates the discharge unit 30. One of the discharge path during operation and the discharge path during standby is used according to the operation status such as during air-conditioning operation or during standby. In particular, during standby, a standby discharge path is used to shorten the discharge time of the capacitor.

  As shown in FIG. 2, the discharge unit 30 includes a switch element that establishes a discharge path by conducting either the first capacitor 25 or the second capacitor 27. The switch element is a c-contact type switching relay 31. A relay contact 32 of the switching relay 31 is connected in series with the first capacitor 25 and the second capacitor 27. The NC contact is connected to the second capacitor 27 and the NO contact is connected to the first capacitor 25. The relay drive circuit 34 connected to the relay coil 33 of the switching relay 31 operates in accordance with an instruction from the control unit 3 to switch the relay contact 32. When the relay coil 33 is not energized, the relay contact 32 is electrically connected to the NC contact. At this time, a standby discharge path is formed. When the control unit 3 outputs a switching signal, the relay coil 33 is energized, and the relay contact 32 is conducted with the NO contact. As a result, an operating discharge path is formed.

  The control unit 3 outputs a switching signal during an air conditioning operation in which a heating operation or a cooling operation is performed. No switching signal is output during standby when air conditioning operation is not being performed. That is, the control unit 3 stops outputting the switching signal when the air conditioning operation is finished. The NC contact of the switching relay 31 is closed, and the second capacitor 27 is conducted. The discharge path is changed from the operating discharge path to the standby discharge path. Moreover, the control part 3 outputs a switching signal, when starting an air-conditioning driving | operation. The NO contact is closed and the first capacitor 25 is conducted. The discharge path is changed from the standby discharge path to the operating discharge path.

  When the air conditioner is in a standby state, an air conditioning operation is performed when the user operates an operation device such as a remote controller or there is an operation start instruction such as a reserved operation start time. At this time, the control unit 3 outputs a switching signal to the relay drive circuit 34 before starting the operation. The switching relay 31 operates, the NO contact is closed, and the first capacitor 25 becomes conductive. The standby discharge path is switched to the operation discharge path. Thus, when there is an instruction to start operation, the discharge path is switched to the on-operation discharge path before another circuit is operated to start operation. Even if noise occurs at the start of operation, the noise can be quickly absorbed.

  After the discharge path is switched, the control unit 3 turns on the power switch 6. While the power switch 6 is on, the control unit 3 continues to output the switching signal, and the operation discharge path is maintained. Noise generated from the circuit is absorbed by the first capacitor 25 having a large capacity, and the noise voltage during the air conditioning operation is reduced. Here, when the power supply plug is removed from the outlet or the AC power supply is cut off due to a power failure or the like, the power supply is cut off in a state where other circuits are operating, so that the operating circuit functions as a discharge path. Therefore, the electric charge stored in the first capacitor 25 is discharged not only through the discharge resistor 26 but also through other circuits, and the discharge time is shortened.

  When the user operates an operation device such as a remote controller or there is an operation stop instruction such as a reserved operation stop time, the air conditioning operation is stopped. First, the control part 3 will stop the compressor 17, if the instruction | indication of a driving | operation stop is received. When a predetermined time, for example, 90 seconds elapses from the stop instruction, the control unit 3 turns off the power switch 6. During this time, the discharge path during operation remains maintained. Since the outdoor fan is driven to cool the electrical components of the outdoor unit, noise generated at this time is absorbed.

  The controller 3 changes the discharge path when a preset transition time, for example, 3 minutes elapses after the power switch 6 is turned off. When the control unit 3 stops outputting the switching signal, the NC contact of the switching relay 31 is closed, and the operation discharge path is switched to the standby discharge path. During standby, the second capacitor 27 having a small capacity is used. If there is an instruction to start the air conditioning operation before the transition time elapses, the control unit 3 continues to output the switching signal and starts the air conditioning operation.

  During standby, the control unit 3 does not output a switching signal, and the switching relay 31 is not energized. Therefore, an increase in power consumption can be prevented. In addition, during standby, there is little noise generation from the circuit. Even the small-capacitance capacitor 27 in the standby discharge path exhibits a sufficient noise absorption effect. In addition, the charge stored in the second capacitor 27 is less than the charge stored in the first capacitor 25. Here, when the power plug is removed from the outlet or the AC power supply is interrupted due to a power failure or the like, the charge stored in the second capacitor 27 is discharged through the discharge resistor 26. Since the stored charge is small, the discharge time is short.

  For example, when the capacitance of the first capacitor 25 is 0.1 μF, the capacitance of the second capacitor 27 is 0.01 μF, and the resistance value of the discharge resistor 26 is 1 MΩ, the discharge time of the first capacitor 25 is about 0.1 seconds. Become. The discharge time of the second capacitor 27 is about 0.01 seconds. In this case, the discharge time satisfies the standards of the Electrical Appliance and Material Safety Law. Therefore, the resistance value of the discharge resistor 26 can be set to 10 MΩ, for example. The discharge time of the second capacitor 27 is about 0.1 seconds, which satisfies the standards for the Electrical Appliance and Material Safety Law. When the AC power supply is 100 V, the power loss at the discharge resistor 26 is 1 mW. When the resistance value of the discharge resistor 26 is 1 MΩ, the power loss at the discharge resistor 26 is 10 mW. Therefore, by using the discharge resistor 26 having a high resistance value, even when the second capacitor 27 having a small capacity is used during standby, the discharge time when the power is cut off does not become long, and the power consumption during standby is reduced. Can be reduced.

(Second Embodiment)
When switching from the air conditioning operation to the standby state, or when starting the air conditioning operation from the standby state, the discharge path is switched. When the discharge path is switched by the operation of the switching relay 31, the capacitor connected to the OFF side of the switching relay 31 is open on the circuit, so that the charge remains charged. In this case, since the capacitor to be turned off is open in terms of circuit, there is no influence on the discharge of residual charges. However, it is not preferable that the capacitor to be turned off has a charge accumulated. Therefore, in order to prevent electric charge from remaining in the capacitor that is turned off, the timing for switching the discharge path is determined based on the phase of the AC power supply. That is, the control unit 3 switches the discharge path when the AC voltage crosses zero. Other configurations are the same as those of the first embodiment.

  As shown in FIG. 4, a timing detection unit 35 that detects switching timing based on the phase of the AC voltage is provided. The timing detection unit 35 detects an AC voltage in the previous stage of the rectifier circuit 10. Reference numeral 36 denotes a resistor for AC voltage detection. Then, as shown in FIG. 5, the timing detection unit 35 generates a clock pulse when the AC voltage crosses zero, and outputs the clock pulse to the control unit 3. When receiving the clock pulse, the control unit 3 outputs a switching signal or stops outputting the switching signal.

  Thus, the discharge path is changed when the AC voltage crosses zero. Since the capacitor to be turned off is switched when the AC voltage is 0 V, the capacitor is not charged, and the capacitor can be held without charge. Further, when the switching relay 31 operates when the phase of the AC voltage is 90 degrees, that is, at the maximum voltage, the charging current from the first capacitor 25 and the discharging current from the second capacitor 27 are inrush current to the relay contact 32. It flows in. Failures such as welding of the relay contact 32 may occur. However, when the relay is operated at the timing when the AC voltage becomes 0V, the inrush current does not flow through the relay contact 32, and the switching relay 31 can be stably operated.

(Third embodiment)
When the room temperature reaches the set temperature during the air-conditioning operation, a thermo-off in which the indoor fan and the compressor 17 are stopped is performed. Further, when the difference between the room temperature and the set temperature becomes large, thermo-ON is performed, and the compressor 17 and the outdoor fan operate. The control unit 3 changes the discharge path when performing thermo-off or thermo-on. That is, the control unit 3 switches from the operating discharge path to the standby discharge path when the compressor 17 and the indoor and outdoor fans are in a standby state in which the fan does not operate even during the air conditioning operation. Other configurations are the same as those in the first or second embodiment.

  The control unit 3 starts thermo-off and stops the compressor 17 and the indoor fan. When a predetermined time elapses after the stop, the control unit 3 stops the outdoor fan, stops the output of the switching signal after the outdoor fan stops, and changes the discharge path. The discharge path is switched from the operation discharge path to the standby discharge path.

  The controller 3 detects the room temperature during the thermo-off, and performs the thermo-on when the difference between the room temperature and the set temperature increases. First, the control unit 3 outputs a switching signal to change the discharge path. The discharge path is switched from the standby discharge path to the operating discharge path. Thereafter, the controller 3 starts thermo-on and operates the compressor 17 and the indoor and outdoor fans.

  Note that the room temperature is detected when the thermostat is off, but the indoor fan may be operated when the temperature is detected. In this case, the control unit 3 outputs a switching signal before operating the indoor fan. After the discharge path is switched from the standby discharge path to the operating energization path, the indoor fan operates. When the thermo-off is continued after detecting the room temperature, the control unit 3 stops the indoor fan and then stops outputting the switching signal. When the thermo-ON is performed, the control unit 3 outputs the switching signal as it is and maintains the operating discharge path.

  As described above, even when the power is shut off during the thermo-off, the charge of the second capacitor 27 having a small capacity is discharged, so that the discharge time is shortened. In addition, since the switching relay 31 is not energized during the thermo-off, the power consumption can be reduced.

(Fourth embodiment)
As an air conditioning operation, there is an air blowing operation in which only an indoor fan operates. At this time, the power switch 6 is off. Even when the air blowing operation is performed, the discharge path is changed prior to the air blowing operation. Other configurations are the same as those in the first to third embodiments.

  If there is an instruction for the air blowing operation when the air conditioner is in the standby state, the control unit 3 operates the switching relay 31 to change the discharge path. The discharge path is switched from the standby discharge path to the operating discharge path. Thereafter, the control unit 3 operates the indoor fan. During the air blowing operation, the discharge path during operation is maintained. When the air blowing operation ends, the control unit 3 changes the discharge path after stopping the indoor fan. The air conditioner enters a standby state, and the discharge path switches from the operating discharge path to the standby discharge path. Thereby, even if noise occurs during the operation of the indoor fan, the large-capacity capacitor 25 is used, so that the noise can be absorbed reliably.

(Fifth embodiment)
In the power supply unit 1 of the present embodiment, as shown in FIG. 6, the first capacitor 25 and the second capacitor 27 for absorbing noise are connected in series, and the discharge path during operation is formed so as to pass through the first capacitor 25. The standby discharge path is formed so as to pass through the first capacitor 25 and the second capacitor 27. The discharge unit 30 includes a switch element that conducts either one of the operation discharge path and the standby discharge path. When the switch element is turned on, the operation discharge path is conducted, and when the switch element is turned off, the standby discharge path is conducted. Other configurations are the same as those of the first to fourth embodiments.

  The switch element is an a-contact type normally open relay 37. A relay contact 38 of the normally open relay 37 is connected to the second capacitor 27 in parallel. The relay drive circuit 34 connected to the relay coil 39 of the normally open relay 37 operates according to an instruction from the control unit 3 to turn on and off the relay contact 38.

  When the control unit 3 outputs a switching signal, the normally open relay 37 is turned on. The relay coil 39 is energized and the relay contact 38 is closed. As a result, the second capacitor 27 is short-circuited, and an operating discharge path that does not pass through the second capacitor 27 is formed. When the control unit 3 is not outputting a switching signal, the normally open relay 37 is turned off. The relay coil 39 is not energized and the relay contact 38 is opened. Thereby, a standby discharge path connecting the first capacitor 25 and the second capacitor 27 is formed.

  When the capacity of the first capacitor 25 is 0.1 μF and the capacity of the second capacitor 27 is 0.01 μF, the combined capacity of the two capacitors is 0.1 × 0.01 / (0.1 + 0.01) = 0. 009 μF. Thus, the combined capacity of the capacitors in the standby discharge path is smaller than the capacity of the first capacitor 25 in the operating discharge path.

  During standby, the control unit 3 does not output a switching signal. Since the normally open relay 37 does not operate, there is no power consumption by the normally open relay 37. At this time, the two capacitors 25 and 27 serve as noise absorbing capacitors, and the combined capacitance is small. However, since the generation of noise from the circuit is small, it is sufficient to exhibit the noise absorbing function. When the power is cut off during standby, since the charge stored in the first capacitor 25 and the second capacitor 27 is small, it can be discharged in a short time.

  When the air conditioning operation is performed, the discharge path is changed. The controller 3 starts the air conditioning operation after outputting the switching signal. The normally open relay 37 is turned on, the second capacitor 27 is short-circuited, and a discharge path connecting the first capacitor 25 and the relay contact 38 is formed. During the air conditioning operation, the circuit generates a lot of noise, but the large capacity first capacitor 25 absorbs the noise. When the power is shut off during the air-conditioning operation, the other circuit is operating, so the charge stored in the first capacitor 25 is discharged in the other circuit, and the discharge time is short.

(Sixth embodiment)
As shown in FIG. 3, the capacitor used in the power supply unit 1 includes a smoothing capacitor 11 as well as a noise absorbing capacitor. The electric charge stored in the smoothing capacitor 11 is discharged through the discharge resistor 13 provided in the DC power supply line 14 and the load of the switching power supply circuit 16 and the control unit 3. By the way, the power supply unit 1 of the outdoor unit has an inverter circuit for driving and controlling the compressor 17. For this reason, a high voltage, for example, a DC voltage of 280 V, is applied to the smoothing capacitor 11 made of an electrolytic capacitor. In order to drive the control unit 3, the switching power supply circuit 16 generates a low voltage, for example, a DC voltage of 5 V, from the high DC voltage, and supplies the generated DC voltage to the control unit 3. A current fuse 19 is provided between the DC power supply line 14 and the switching power supply circuit 16. The current fuse 19 functions as a safety device when an abnormality occurs in the switching power supply circuit 16 in the short mode.

  When the current fuse 19 is blown during the air conditioning operation, the power supply to the control unit 3 is cut off and the air conditioning operation is stopped. The high voltage charged in the smoothing capacitor 11 is discharged only by the discharge resistor 13. Therefore, it takes time to discharge the smoothing capacitor 11. Even if the operator turns off the power supply to repair the outdoor unit, it is necessary to wait until the voltage of the smoothing capacitor 11 is lowered to a level where there is no problem in safety, and it takes time to start the work. Here, if the resistance value of the discharge resistor 13 is reduced, the discharge time can be shortened. However, while the air conditioner is powered on, current flows through the discharge resistor 13 and power is consumed. In order to save energy, the resistance value cannot be reduced.

  Therefore, in the air conditioner of the present embodiment, the power charged in the smoothing capacitor 11 can be quickly discharged when a situation such as the cutting of the current fuse 19 occurs, and the power consumption at the discharge resistor 13 is reduced. To be able to save energy.

  As shown in FIG. 7, a first discharge resistor 41 having a large resistance value and a second discharge resistor 42 having a small resistance value are provided as discharge resistors for the smoothing capacitor 11. For example, the capacity of the smoothing capacitor 11 is 1800 μF, the first discharge resistor 41 is 660 kΩ, and the second discharge resistor 42 is 1 kΩ. The first discharge resistor 41 and the second discharge resistor 42 are connected in parallel in the DC power supply line 14, and both discharge resistors 41 and 42 are arranged between the smoothing capacitor 11 and the load. A normal discharge path passing through the first discharge resistor 41 and a rapid discharge path passing through the second discharge resistor 42 are formed. A discharge circuit (discharge unit) 43 that switches between two discharge paths according to the situation is provided. Other configurations are the same as those of the first to fifth embodiments.

  The discharge circuit 43 uses a normal discharge path in a normal situation such as air conditioning operation or standby, and uses a rapid discharge path in an emergency situation such as when the power is cut off such as the current fuse 19 being cut. Switch as follows. That is, when the current fuse 19 is blown and the power supply to the control unit 3 is cut off, the discharge unit 43 switches from the normal discharge path to the rapid discharge path.

  The discharge circuit 43 includes a switch element that conducts the rapid discharge path. The switch element is connected in series with the second discharge resistor 42 in the rapid discharge path. When the switch element is off, the rapid discharge path is interrupted and the normal discharge path can be used. When the switch element is turned on, the rapid discharge path is conducted.

  An NPN switching transistor 44 is used as the switch element. The switching transistor 44 has an emitter terminal connected to the second discharge resistor 42 and a collector terminal connected to 0 V of the DC power supply line 14. The base terminal is connected to an intermediate point between the current fuse 19 and the switching power supply circuit 16.

  When a high-voltage DC voltage is supplied to the switching power supply circuit 16 through the current fuse 19, the control unit 3 operates to perform an air conditioning operation. At this time, a DC voltage is applied to the base terminal of the switching transistor 44, but no current flows toward 0 V of the DC power supply line 14 because of the resistance 45 having a high resistance value (for example, 1 MΩ). Therefore, the potential of the base terminal remains high and the switching transistor 44 is off. The rapid discharge path is interrupted and the normal discharge path can be used.

  Here, when the AC power supply is shut off without the current fuse 19 being blown, such as when the power plug is disconnected from the outlet or a power failure, the control unit until the DC voltage supplied to the control unit 3 drops to the minimum operating voltage. 3 operates. Therefore, the charge stored in the smoothing capacitor 11 is discharged not only through the first discharge resistor 41 but also through other circuits such as the switching power supply circuit 16 and the control unit 3. Therefore, the discharge time is short, for example, about 1 minute.

  When the current fuse 19 is blown, the power supply to the control unit 3 is cut off, and the control unit 3 does not operate. At this time, the base terminal of the switching transistor 44 is connected to 0 V of the DC power supply line 14 via the resistor 45, and the potential of the base terminal is lowered. The switching transistor 44 is turned on to form a rapid discharge path. Since the second discharge resistor 42 has a lower resistance value than the first discharge resistor 41, the charge of the smoothing capacitor 11 flows through the rapid discharge path. At this time, the discharge time is about 10 seconds. If discharge is performed through the normal discharge path instead of the rapid discharge path, the discharge time is about 80 minutes.

  In this way, in the DC power supply line 14 to which a high-voltage DC voltage is applied, when an emergency situation occurs in which the power supply is cut off, the discharge path is automatically switched, and the smoothing capacitor 11 is passed through the second discharge resistor 42 having a low resistance value. The electric charge stored in can be discharged in a short time. Therefore, when the worker repairs the outdoor unit, the waiting time for discharging can be eliminated, and the work can be started immediately. Further, since the second discharge resistor 42 is not energized during the air conditioning operation or during standby, the resistor 42 does not consume power and does not hinder energy saving.

(Seventh embodiment)
In the present embodiment, as shown in FIG. 8, a b-contact type normally closed relay 46 is used as a switch element of the discharge unit 43, and the normally closed relay 46 is turned on / off according to the operating state of the control unit 3. When the control unit 3 does not operate due to the current fuse 19 being cut, the normally closed relay 46 is turned on and the rapid discharge path is conducted. Other configurations are the same as those in the first to sixth embodiments.

  The relay contact 47 of the normally closed relay 46 is provided in the rapid discharge path. A transistor 49 is connected to the relay coil 48 of the normally closed relay 46, and the drive of the transistor 49 is controlled by the control unit 3. The relay coil 48 is connected to the switching power supply circuit 16, and DC power is supplied from the switching power supply circuit 16. When the transistor 49 is turned on, the relay coil 48 is energized and the normally closed relay 46 is turned on. When the transistor 49 is turned off, the relay coil 48 is not energized, and the normally closed relay 46 is turned off.

  When the control unit 3 outputs a relay off signal to the transistor 49, the transistor 49 is turned on, and a driving voltage of 12 V is applied to the relay coil 48 from the switching power supply circuit 16. The relay coil 48 is energized and the relay contact 47 is opened. The normally closed relay 46 is turned off and the rapid discharge path is interrupted. When the relay-off signal is not output from the control unit 3, the transistor 49 is turned off, the relay coil 48 is not energized, and the relay contact 47 is closed. The normally closed relay 46 is turned on and the rapid discharge path is conducted.

  Here, when the current fuse 19 is blown, the control unit 3 does not operate. That is, the relay off signal is not output from the control unit 3. The normally closed relay 46 is turned on and the rapid discharge path is conducted. As described above, when the control unit 3 is not operated due to an emergency situation of power shutdown, the rapid discharge path having the second discharge resistor 42 is automatically switched. Therefore, the electric charge stored in the smoothing capacitor 11 can be discharged in a short time.

(Eighth embodiment)
When the current fuse 19 is blown and the air conditioning operation is stopped, the electric charge stored in the smoothing capacitor 11 is discharged. In the present embodiment, it is notified that there is such an emergency situation. That is, as shown in FIG. 9, a notification unit 50 is provided for notifying that discharging is occurring when the power is shut off. The notification unit 50 is operated by a discharge current generated at the time of discharging using the rapid discharge path. Other configurations are the same as those of the sixth and seventh embodiments.

  The notification unit 50 notifies by turning on the LED 51. The LED 51 is provided on a board where it can be easily seen. And LED51 is distribute | arranged in a rapid discharge path | route. The LED 51 is connected to the collector terminal of the switching transistor 44 via a resistor 52. A Zener diode 53 is connected in parallel with the LED 51 for overvoltage protection of the LED 51.

  In a normal situation such as during an air conditioning operation, the switching transistor 44 is off and the LED 51 is not energized. When the switching transistor 44 is turned on when the current fuse 19 is blown, a discharge current flows through the LED 51 and the LED 51 is lit. When the discharge is completed, the discharge current stops flowing and the LED 51 is turned off. Thus, it can be recognized that the electric charge of the smoothing capacitor 11 is being discharged, and the operator can be prevented from touching the smoothing capacitor 11 carelessly. This notification is not limited to the LED 51, but may be a sound or a display.

(Ninth embodiment)
There are a plurality of power supply voltages of the AC power supply used in the air conditioner. For example, in Japan, it is 100V and 200V. Any power supply voltage that matches the rated voltage of the air conditioner is used. When an AC power supply that is not compatible with an air conditioner is applied, such as when a power supply voltage of AC200V is applied to a product with a rated voltage of AC100V when an air conditioner is installed, The fan motor may be destroyed. In order to prevent such a situation, as shown in FIG. 10, circuit protection components such as a current fuse 60 and a varistor 61 are provided in front of the rectifier circuit 10. As shown in FIG. 11, the smoothing circuit 62 including the circuit protection component, the rectifier circuit 10, the smoothing capacitor 11, and the discharge resistor 13 is mounted on the electrical board 63. When an overvoltage is applied, the varistor 61 is short-circuit broken and the current fuse 60 is blown. As a result, components arranged downstream from the current fuse 60 can be protected from overvoltage.

  By the way, when an overvoltage is applied and a circuit protection component is destroyed, it becomes necessary to replace these components. As shown in FIG. 12, the patent document (Japanese Patent Laid-Open No. 4-127835) discloses that a current fuse 60 and a varistor 61 are separate from an electrical board 63 so that the replacement work can be easily performed. The dedicated board 64 is connected to the electrical board 63 by a connector 65. The replacement work can be performed by replacing the dedicated substrate 64.

  However, in order to replace the circuit protection component, a new dedicated substrate 64 is required. In particular, when a circuit protection component such as the current fuse 60 is destroyed during the installation of the air conditioner, a new dedicated board 64 must be prepared and cannot be replaced immediately. Therefore, the completion of installation of the air conditioner is delayed. Therefore, in the present embodiment, the circuit board can be easily replaced by providing the circuit board 63 with a replacement circuit protection part in advance. Other configurations are the same as those in the first to eighth embodiments.

  As shown in FIG. 13, a current fuse 60 and a varistor 61, which are circuit protection components, are provided on an electrical board 63 on which circuit components such as the rectifier circuit 10 and the smoothing capacitor 11 are mounted. The current fuse 60 and the varistor 61 are soldered to the electrical board 63. Then, a circuit protection component for replacement is provided on the electrical board 63.

  A current fuse 70 and a varistor 71, which are circuit protection parts for replacement, are mounted on one corner of the electrical board 63, and the current fuse 70 and the varistor 71 are soldered. A cut is formed in one corner of the electrical board 63, and a part of the electrical board 63 can be separated. The separated substrate is used as a replacement substrate 72 on which a circuit protection component for replacement is mounted. That is, the replacement board 72 is provided integrally with the electrical board 63 and can be separated from the electrical board 63. A connector 73 is mounted on the replacement board 72, and a connector 74 for connecting the connector 73 of the replacement board 72 is mounted on the electrical board 63. When the connector 73 of the exchange board 72 and the connector 74 of the electrical board 63 are connected, the circuit protection component of the exchange board 72 is electrically connected to the circuit part of the electrical board 63.

  When an overvoltage is applied to the AC power supply line 12, the varistor 61 is short-circuited and the current fuse 60 is blown. The circuit components subsequent to these circuit protection components are protected from overvoltage. The operator removes the broken circuit protection component and replaces it with a new circuit protection component.

  The destroyed circuit protection component is removed from the electrical board 63. As shown in FIG. 14, the replacement board 72 is separated from the electrical board 63, and the exchange board 72 is installed at the place where the original circuit protection component of the electrical board 63 was mounted. The connector 73 of the replacement board 72 and the connector 74 of the electrical board 63 are connected by an electric wire. As shown in FIG. 15, in the replacement substrate 72, the current fuse 70 and the varistor 71 are wired in series. The connection terminals of the connectors 73 and 74 are connected by electric wires, and a new circuit protection component is mounted on the AC power supply line 12 of the electrical board 63.

  As described above, when it becomes necessary to replace the circuit protection component of the electrical board 63, since there is a new circuit protection component, it can be replaced immediately. In particular, when an air conditioner is installed, the parts can be exchanged on the spot, so that the exchange work can be completed quickly and the original installation work can be quickly returned to.

(10th Embodiment)
In the present embodiment, the replacement board 72 on which a new circuit protection component is mounted is connected to the electrical board 63 without wiring. That is, as shown in FIG. 16, the connection terminal 76 is formed on the replacement board 72, and the connector 77 for mounting the connection terminal 76 is provided on the electrical board 63. The connection terminal 76 is formed so as to connect one end of the replacement substrate 72 and the electrical component substrate 63, and a plurality of electrodes are formed on the connection terminal 76. Other configurations are the same as those of the first to ninth embodiments.

  In order to replace the circuit protection component, when the replacement board 72 is separated from the electrical board 63, the tip of the connection terminal 76 is separated from the electrical board 63. As shown in FIG. 17, by inserting the tip of the connection terminal 76 into the connector 77, the replacement board 72 is mounted on the electrical board 63, and a new circuit protection component is electrically connected to the electrical board 63.

  Thus, since the replacement substrate 72 is directly connected to the connector 77, wiring for connection becomes unnecessary. Therefore, the replacement work is simple and can be completed quickly. Further, when an overvoltage is applied, the varistor 71 may instantaneously become high temperature, but since it is connected to the substrate without wiring, it does not affect the surroundings through the wiring.

(Eleventh embodiment)
In this embodiment, the replacement circuit protection component is directly mounted on the electrical board 63. As shown in FIG. 18, two sets of circuit protection components are provided on the electrical board 63. One is a circuit protection component composed of a current fuse 70 and a varistor 71 mounted from the time of shipment, and the other is a circuit protection component composed of a replacement current fuse 73 and a varistor 74. Then, the connection member 80 is used to make any one of the circuit protection components usable, and the circuit protection component is electrically connected to the electrical board 63 by the connection member 80. Other configurations are the same as those of the first to ninth embodiments.

  As shown in FIG. 19, two sets of circuit protection components are arranged in parallel in the AC power supply line 12. The varistors 71 and 74 and the rectifier circuit 10 are not wired, and first and second non-connection sections 81 and 82 are formed. In addition, a third non-passage section 83 is also formed in front of the replacement current fuse 73. When the connection member 80 such as a jumper wire or a jumper pin is mounted in these non-connection sections 81 to 83, the non-connection sections 81 to 83 are conducted.

  Here, in the initial state, as shown in FIG. 20, the connection member 80 is mounted in the first non-passage section 81 by soldering. The connection member 80 is not mounted in the second and third non-connection sections 82 and 83. Thereby, one circuit protection component becomes a usable component, and the other circuit protection component becomes a replacement component.

  When an overvoltage is applied and the circuit protection component in use is destroyed, the circuit protection component is replaced with the other circuit protection component. As shown in FIG. 21, the connection member 80 in the first non-connection section 81 is removed. The connecting member 80 may be cut. Then, the connection member 80 is mounted on the second and third non-connection sections 82 and 83 by soldering. Thereby, the destroyed circuit protection component is switched to a new circuit protection component, and the other circuit protection component can be used.

  In this way, by mounting the replacement circuit protection component on the electrical board 63, if only the connection member 80 is prepared, the replacement operation can be completed immediately. Further, it is not necessary to remove the circuit protection component, and the work time for removing it can be omitted. Even if the solder pad is peeled off when the connecting member 80 is desoldered, the connecting member 80 is not reused, so there is no problem in use and the operation reliability of the circuit component is not impaired.

(Twelfth embodiment)
The indoor unit and the outdoor unit of the air conditioner are electrically connected by three connection lines. As shown in FIG. 22, first to third terminals T1 to T3 are provided on the terminal plate 4 of the indoor unit, and first to third terminals S1 to S3 are provided to the terminal plate 4 of the outdoor unit. The first and second terminals T1 and T2 of the indoor unit and the first and second terminals S1 and S2 of the outdoor unit are respectively connected by a pair of connection lines 90 for power. The third terminal T3 of the indoor unit and the third terminal S3 of the outdoor unit are connected by a communication connection line 90. As shown in FIG. 23, the first and second terminals T1, T2, S1, and S2 are connected to the AC power supply line 12, and the third terminals T3 and S3 are connected to the communication circuit 91.

  The control unit 3 of the indoor unit performs serial communication with the control unit 3 of the outdoor unit through a connection line 90 connected to each of the third terminals T3 and S3. In the indoor unit, a reception photocoupler 92 and a transmission photocoupler 93 are connected in series to the communication circuit 91 connected to the third terminal T3. Further, an overvoltage protection diode 94 and a resistor 95 are provided in the communication circuit 91 in order to protect the photocouplers 92 and 93 when an overvoltage is applied. A DC voltage obtained by converting an AC voltage from the AC power supply line 12 is supplied to the communication circuit 91. When a signal is transmitted from the outdoor unit, the reception photocoupler 92 is turned on, and an H signal is input to the input port 96 of the control unit 3. When transmitting a signal from the indoor unit, the control unit 3 outputs an L signal from the output port 97. The transmission photocoupler 93 is turned on and a signal is transmitted to the outdoor unit.

  For example, an incorrect wiring may be performed in which the first terminal T1 of the indoor unit is connected to the third terminal S3 of the outdoor unit, and the third terminal T3 of the indoor unit is connected to the first terminal S1 of the outdoor unit. In this case, the AC power supply line 12 is directly connected to the communication circuit 91, and an AC voltage is applied to the communication circuit 91. At this time, when the control unit 3 outputs a signal, the transmission photocoupler 93 is turned on. A current flows through the communication circuit 91, and an overvoltage is applied to the resistor 95 in the communication circuit 91. There is a risk that the resistor 95 will generate abnormal heat or damage to circuit components.

  In the patent document (Japanese Patent Application Laid-Open No. 2010-236757), when an overvoltage is applied to the communication circuit 91 and the overvoltage state continues, the communication circuit 91 is disconnected to prevent the communication circuit 91 from being destroyed. Have been described. However, when the transmission photocoupler 93 is turned on before the communication circuit 91 is disconnected, a current flows through the communication circuit 91 and a resistive overvoltage is applied.

  Therefore, when there is an incorrect wiring, the communication circuit 91 is not subjected to stress due to overvoltage. For this reason, in this embodiment, when an incorrect wiring is detected, current is prevented from flowing through the communication circuit 91, that is, communication operation is not performed. As shown in FIG. 24, the miswiring detection unit 100 is provided in the AC power supply line 12, and the control unit 3 prohibits the communication operation when the miswiring is detected. Other configurations are the same as those in the first to eleventh embodiments.

  The miswiring detector 100 is provided in a circuit connecting the first terminal T1 and the second terminal T2, and includes a half-wave rectifier circuit in which a diode 101 and a resistor 102 are connected in series, and a photocoupler 103. The miswiring detector 100 outputs a clock signal by the operation of the photocoupler 103 when an AC voltage is applied to the AC power supply line 12, and does not output a clock signal when no AC voltage is applied. A clock signal from the erroneous wiring detection unit 100 is input to the control unit 3. Note that the outdoor unit operates with a separate power source from the indoor unit. The DC power for driving the photocoupler 103 and the control unit 3 is supplied from another power source.

  When the indoor unit and the outdoor unit are correctly wired, an AC voltage is applied to the AC power supply line 12 from the first terminal T1. Since the photocoupler 103 is turned on and off at a constant timing, the miswiring detection unit 100 outputs a clock signal at a constant timing as shown in FIG. The controller 3 determines that the indoor unit and the outdoor unit are correctly wired when a clock signal is input at a fixed timing. At this time, the control unit 3 allows the communication operation of the communication circuit 91. That is, the L signal can be output from the output port 97 of the control unit 3.

  When the wiring is incorrect, an AC voltage is applied to the communication circuit 91. Since no AC voltage is applied to the AC power supply line 12, the miswiring detection unit 100 does not output a clock signal. The control unit 3 determines that the wiring is incorrect because there is no input of the clock signal. The control unit 3 prohibits the communication operation of the communication circuit 91. The L signal is not output from the output port 97 and no current flows through the communication circuit 91. Therefore, it is possible to prevent an overvoltage from being applied to the resistor 95 of the communication circuit 91. In addition, since an overvoltage is not applied to the resistor 95 of the communication circuit 91, a low-power type resistor can be used, and power consumption during standby when communication is not performed can be reduced.

(13th Embodiment)
In the present embodiment, power for driving the photocoupler 103 of the miswiring detection unit 100 is supplied from the AC power supply line 12. As shown in FIG. 26, the switching power supply circuit 104 is connected to the AC power supply line 12. The switching power supply circuit 104 converts the alternating voltage into a direct current voltage of 5V and supplies it to the photocoupler 103 and the control unit 3. That is, the indoor unit and the outdoor unit operate with the same power source. Other configurations are the same as those in the first to twelfth embodiments.

  When the indoor unit and the outdoor unit are correctly wired, an AC voltage is applied between the first terminal T1 and the second terminal T2. The miswiring detector 100 outputs a clock signal at a certain timing. When the control unit 3 detects a clock signal input at a constant timing, the control unit 3 determines that the indoor unit and the outdoor unit are wired correctly, and enables the signal from the output port 97 to be output.

  When the second terminal T2 and the third terminal T3 are miswired, no AC voltage is applied to the AC power supply line 12. The switching power supply circuit 104 generates a DC voltage for driving the photocoupler 104 from the AC voltage applied between the first terminal T1 and the third terminal T3. However, since an AC voltage is not applied to the AC power supply line 12, the miswiring detector 100 does not output a clock signal. Since there is no clock signal input, the control unit 3 determines that the wiring is incorrect and prohibits the communication operation. Therefore, no current flows through the communication circuit 91.

(14th Embodiment)
In the present embodiment, as shown in FIG. 27, the terminal plate 4 is provided with first to third terminals T1 to T3 and a ground terminal TE. AC 200 V is applied between the first terminal T1 and the second terminal T2. 100 VAC is applied between the third terminal T3 and the ground terminal TE. Power for driving the photocoupler 103 of the erroneous wiring detection unit 100 is supplied from the AC power supply line 12. Other configurations are the same as those in the first to thirteenth embodiments.

  When the indoor unit and the outdoor unit are correctly wired, an AC voltage is applied between the first terminal T1 and the second terminal T2. As shown in FIG. 28A, the miswiring detector 100 outputs a clock signal for a time corresponding to the AC voltage (200V) at a constant timing. When the control unit 3 detects the clock signal from the miswiring detection unit 100, the control unit 3 determines that the indoor unit and the outdoor unit are wired correctly, and enables the signal from the output port 97 to be output.

  As shown in FIG. 29, the second terminal T2 of the indoor unit and the third terminal S3 of the outdoor unit, the third terminal T3 of the indoor unit and the grounding terminal SE of the outdoor unit, the grounding terminal TE of the indoor unit and the second terminal of the outdoor unit. Terminals T2 are connected to each other, and the indoor unit and the outdoor unit are miswired. At this time, AC 100 V is applied between the first terminal T1 and the second terminal T2. AC 200 V is applied between the first terminal T1 and the third terminal T3. As shown in FIG. 28B, the miswiring detection unit 100 outputs a clock signal for a time corresponding to the AC voltage (100 V) at a constant timing. The output time of the clock signal when miswired is shorter than the output time of the regular clock signal when correctly wired. When it is confirmed that the output time of the input clock signal is shorter than the specified time, the control unit 3 determines that the wiring is incorrect and prohibits the communication operation.

(Fifteenth embodiment)
In the present embodiment, as shown in FIG. 30, an AC transformer 105 is used in the miswiring detection unit 100 instead of a photocoupler. The number of secondary turns of AC transformer 105 is less than the number of primary turns. The AC transformer 105 outputs an AC voltage obtained by stepping down the input AC voltage to a level that can be input to the control unit 3. The output AC voltage is rectified by the diode 106, and a clock signal is generated at a certain timing. The incorrect wiring detection unit 100 outputs a clock signal to the control unit 3. Other configurations are the same as those in the first to fourteenth embodiments.

  When the indoor unit and the outdoor unit are correctly wired, an AC voltage is applied to the AC power supply line 12 from the first terminal T1. The miswiring detector 100 outputs a clock signal at a certain timing. The control unit 3 determines that the indoor unit and the outdoor unit are correctly wired based on the input of the clock signal from the miswiring detection unit 100. At this time, the control unit 3 allows a communication operation.

  When miswired, no AC voltage is applied to the AC power supply line 12, or an AC voltage different from the regular AC voltage is applied. The miswiring detection unit 100 does not output a clock signal or outputs a clock signal having an output time different from a regular clock signal. The control unit 3 determines the presence or absence of miswiring based on the presence or absence of a clock signal or the output time of the clock signal. If the control unit 3 determines that the wiring is incorrect, the control unit 3 prohibits the communication operation.

  As described above, the air conditioner of the present invention includes the power supply unit 1 for converting an AC voltage into a DC voltage and supplying the DC voltage to a load. The power supply unit 1 is stored in the capacitor and the capacitor. In order to shorten the discharge time of the capacitor when the power is shut off, a discharge unit 30 that changes the discharge path from the capacitor to the discharge resistor is provided.

  In order to shorten the discharge time of the capacitor, the charge stored in the capacitor may be reduced or the discharge resistance may be reduced. Therefore, the discharge time can be shortened by changing to a discharge path having a small-capacitance capacitor or a discharge path having a small resistance when the power is shut off.

  As a capacitor of the power supply unit 1, a large-capacity first capacitor 25 and a small-capacitance second capacitor 27 for absorbing noise are provided, and an operation discharge path that does not pass through the second capacitor 27 and a standby state that passes through the second capacitor 27. A discharge path is formed, and the discharge unit 30 uses the discharge path during operation during air-conditioning operation and switches to the standby discharge path during standby. Thus, when the power is cut off during standby, the battery can be discharged in a short time through the standby discharge path.

  The discharge unit 30 switches the discharge path when the AC voltage crosses zero. When the AC voltage crosses zero, the capacitor is not charged. Therefore, it is possible to prevent electric charges from accumulating in the capacitor of the switched discharge path.

  The first capacitor 25 and the second capacitor 27 arranged in the preceding stage of the rectifier circuit 10 are connected in parallel, and the discharge unit 30 makes one of the first capacitor 25 and the second capacitor 27 conductive so that the discharge path is It has a switch element to be formed. The switch element switches between two discharge paths. Thereby, capacitors having different capacities can be properly used according to the situation, and an effect of absorbing noise during air-conditioning operation and an effect of shortening discharge time during standby can be obtained.

  The first capacitor 25 and the second capacitor 27 are connected in series, the discharge path during operation passes through the first capacitor 25, the discharge path during standby passes through the first capacitor 25 and the second capacitor 27, and the discharge unit 30 And a switch element for conducting either one of the discharge path during operation and the discharge path during standby. The switch element is connected in parallel to the second capacitor 27, and the operation discharge path is conducted when the switch element is turned on, and the standby discharge path is conducted when the switch element is turned off. When the air-conditioning operation ends and enters a standby state, the switch element is turned off and the discharge path is switched.

  The capacitor of the power supply unit 1 is a smoothing capacitor 11, and a first discharge resistor 41 having a large resistance value and a second discharge resistor 42 having a small resistance value are provided as discharge resistors, and a normal discharge path passing through the first discharge resistor 41. A rapid discharge path passing through the second discharge resistor 42 is formed, and the discharge unit 43 uses the normal discharge path during the air conditioning operation and switches to the rapid discharge path when the power is shut off. The electric charge of the smoothing capacitor 11 can be quickly discharged through a discharge path having a small resistance when the power is shut off.

  A control unit 3 that is operated by a DC voltage supplied from the power supply unit 1 is provided, a current fuse 19 is provided between the control unit 3 and the power supply unit 1, and the current fuse 19 is blown to supply power to the control unit 3. When is interrupted, the discharge unit 43 switches from the normal discharge path to the rapid discharge path. When the power fuse 19 is blown, power is not supplied to the control unit 3 and the control unit 3 does not operate. However, the discharge unit 43 can switch to a discharge path with a short discharge time. Thereby, measures such as replacement of the current fuse 19 can be performed immediately.

  The discharge circuit 43 includes a switch element that conducts the rapid discharge path. The switch element operates in accordance with an output from the control unit 3 to maintain a state in which the rapid discharge path is cut off, and an output from the control unit 3 is When it disappears, the state of interrupting the rapid discharge path is released, and the rapid discharge path is conducted. Thereby, when the control part 3 stops operating, it is possible to automatically switch to the rapid discharge path.

  An informing unit 50 is provided that operates by a discharge current generated during discharge using the rapid discharge path, and the informing unit 50 informs that discharging is in progress when the power is shut off. The notification unit 50 operates only during the discharge, and stops when the discharge is completed.

  In the air conditioner, a circuit protection component that protects the circuit component from overvoltage is mounted on the electrical board 63, and a replacement circuit protection component that is used when the circuit protection component is destroyed by the overvoltage is provided on the electrical board 63. Provided. Thereby, when a circuit protection component is destroyed, it can be immediately replaced with a new circuit protection component.

  A separable replacement board 72 is provided on a part of the electrical board 63, and a replacement circuit protection component is mounted on the replacement board 72. By mounting the separated replacement board 72 on the electrical board 63, the circuit protection component can be replaced.

  The electrical board 63 is provided with a connector 77 for connecting the exchange board 72, and the exchange board 72 is provided with a connection terminal 76 attached to the connector 77. By connecting the connection terminal 76 of the exchange board 72 to the connector 77, the exchange board 72 can be mounted on the electrical board 63.

  The replacement circuit protection component is mounted on the electrical board 63, and the replacement circuit protection component is electrically connected to the circuit component on the electrical board 63 by the connection member 80. The circuit protection component can be easily replaced simply by preparing the connection member 80.

  In the air conditioner, the indoor unit and the outdoor unit are electrically connected by a plurality of connection lines 90, and the control unit 3 that controls the communication circuit 91 that performs communication between the indoor unit and the outdoor unit includes When erroneous wiring is detected, the operation of the communication circuit 91 is prohibited. When there is an incorrect wiring, the communication circuit 91 does not operate, so no current flows through the communication circuit 91. Thereby, it is possible to prevent an overvoltage due to erroneous wiring from being applied to the communication circuit 91, and damage to circuit components such as the resistor 95 in the communication circuit 91 can be prevented.

  An erroneous wiring detection unit 100 that detects erroneous wiring based on the AC voltage supplied through the connection line 90 is provided. The incorrect wiring detection unit 100 outputs a signal corresponding to the AC voltage supplied when correctly wired, and outputs a signal corresponding to the AC voltage supplied when incorrectly wired. Based on the output from the miswiring detector 100, the controller 3 determines the presence or absence of miswiring.

  In addition, this invention is not limited to the said embodiment, Of course, many corrections and changes can be added to the said embodiment within the scope of the present invention. The configurations of the first to fifteenth embodiments may be applied not only to one of the indoor unit or the outdoor unit but also to the indoor unit and the outdoor unit. The discharge unit may change the discharge path in the noise absorbing capacitor and the discharge path in the smoothing capacitor.

DESCRIPTION OF SYMBOLS 1 Power supply part 2 Drive part 3 Control part 10 Rectifier circuit 11 Smoothing capacitor 13 Discharge resistance 25 1st capacitor 26 Discharge resistance 27 2nd capacitor 30 Discharge part 35 Timing detection part 41 1st discharge resistance 42 2nd discharge resistance 43 Discharge circuit 50 Notification section 60 Current fuse 61 Varistor 63 Electrical board 70 Current fuse 71 Varistor 72 Replacement board 90 Connection line 91 Communication circuit 100 Incorrect wiring detection section

Claims (4)

An air conditioner having a power supply unit for converting an AC voltage into a DC voltage and supplying the DC voltage to a load, and a power switch for power supply to an outdoor unit that is turned on / off in response to the start or stop of air conditioning operation The power supply unit has a capacitor and a discharge resistor that discharges the electric charge stored in the capacitor, and a large-capacity first capacitor for absorbing noise and a small second capacitor are connected in parallel as the capacitor of the power supply unit. Alternatively, an operation discharge path that is connected in series and does not pass through the second capacitor used during air conditioning operation and a standby discharge path that passes through at least the second capacitor used during standby are formed, and the discharge time of the capacitor when the power is shut off Is provided with a discharge part that changes the discharge path according to the operating situation ,
When air conditioning operation is performed, before the air conditioning operation is started, the discharge unit operates, the standby discharge path is switched to the operation discharge path, the power switch is turned on, and there is an instruction to stop the air conditioning operation. The air conditioner is characterized in that after the air-conditioning operation is stopped, the power switch is turned off, and then the discharge unit operates to switch from the operation discharge path to the standby discharge path. The air conditioner according to claim 1, wherein the discharge unit switches the discharge path when the AC voltage crosses zero. An air conditioner having a power supply unit for converting an AC voltage into a DC voltage and supplying the DC voltage to a load. The power supply unit has a discharge resistor for discharging a capacitor and a charge stored in the capacitor. In order to shorten the discharge time of the capacitor when the power is cut off, a discharge unit that changes the discharge path from the capacitor to the discharge resistor is provided,
The capacitor of the power supply unit is a smoothing capacitor, and a first discharge resistor having a large resistance value and a second discharge resistor having a small resistance value are provided as discharge resistors, and a normal discharge path that passes through the first discharge resistor used during air conditioning operation. And a rapid discharge path through the second discharge resistor used when the power is shut off,
When a control unit that is operated by a DC voltage supplied from the power supply unit is provided, a current fuse is provided between the control unit and the power supply unit, and when the current fuse is blown and the power supply to the control unit is shut off, An air conditioner characterized in that the discharge unit switches from a normal discharge path to a rapid discharge path. The air conditioner according to claim 3, wherein a normal discharge path is used when the power supply to the control unit is cut off without the current fuse being blown.

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