JP2000333365A - Power supply system on standby and air-conditioner and refrigerator using them - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce power consumption on standby of electrical appliances, such as an air-conditioner and a refrigerator. SOLUTION: In normal operation, a switch means 3 is turned off and a switch means 2 is turned on, power is supplied from a commercial power supply 1 to a power supply 31 of an outdoor unit B, and the outdoor unit B is in operation state. One output of the power supply 31 is supplied to an indoor unit A and charges a double-layer capacitor 7 via a DC-DC converter 11, and the charge voltage of the capacitor 7 becomes the power supply voltage of a microcomputer 9. At standby, the switch means 2 is turned off, and the outdoor unit B is set at halt. In the indoor unit A, the microcomputer 9 monitors the charge voltage of the capacitor 7 by a voltage detection element 8, turns on the switch means 3, when the charge voltage decreases and reaches the lower limit of a prescribed voltage range required as the control voltage of the microcomputer 9, and charges the capacitor 7 by an auxiliary power supply 6. When the charge voltage reaches the upper limit of the above prescribed voltage range, the microcomputer 9 turns off the switch means 3.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a standby power supply system for electric products, and more particularly to a standby power supply system suitable for use in an air conditioner or a refrigerator.

[0002]

2. Description of the Related Art A conventional example of a control circuit of a refrigerator and a power supply circuit for supplying electric power to the control circuit is disclosed in, for example, Japanese Patent Application Laid-Open No.
727. In this conventional example, a switching regulator is used as a DC power supply for supplying a power supply voltage to a control circuit, and a commercial power supply is connected to an input stage of the switching regulator via a rectifier circuit.

[0003] Main control objects of a refrigerator include a compressor for driving a refrigerating cycle, various fan motors for cooling, and a damper for adjusting cool air. DC power is supplied to a control target other than the compressor by the switching regulator, and power is supplied to the compressor from a separately provided power supply circuit for driving the compressor.

When the compressor is stopped, power supply from the power supply circuit for driving the compressor motor to the compressor motor is stopped. In addition, for a control target such as a cooling fan motor other than the compressor motor, DC power is always supplied to the control circuit by the switching regulator even when the drive power of the compressor motor is off. This is because the commercial power is directly connected to the input stage of the switching regulator via the rectifier circuit, so even if the drive power of the compressor motor is off,
This is because the switching regulator supplies DC power to the control circuit.

[0005]

However, in the circuit configuration of the prior art, there is a problem that unnecessary power is consumed even when the load is light, such as when the compressor is stopped, that is, during standby. . Hereinafter, this point will be specifically described.

When the compressor is stopped, heat exchange in the refrigeration cycle is not performed, so that there is almost no need to drive a cooling fan or a damper for adjusting cool air in the refrigerator. Therefore, when the compressor is stopped, power supply to any control circuit may be reduced. Although power is supplied to the control circuit using a switching regulator, since the commercial power is directly connected to the input stage of the switching regulator via a rectifier circuit, even when the drive power of the compressor motor is off, The DC power is always supplied to the control circuit by the switching regulator, and unnecessary power is consumed by the switching regulator and its load. In general, the switching regulator is designed to have the highest efficiency under a normal load, and therefore has a low efficiency at a light load such as when a cooling fan or a damper for cooling air is stopped. The above is the main reason why unnecessary power is consumed during standby.

In general, not only refrigerators but also electric appliances such as air conditioners often consume unnecessary power during standby. In the air conditioner, when the operation is stopped, only the circuit that receives the command signal from the remote controller for starting the operation may be energized to be in the operating state, but actually, even when the operation is stopped. Power is supplied from the control power supply to unnecessary circuits. In home electric appliances such as refrigerators and air conditioners, the electric power in standby mode is as small as several watts, but since the power is always supplied even in standby mode, the ratio of standby power to the total power consumption is relatively large.

SUMMARY OF THE INVENTION An object of the present invention is to solve such a problem, minimize power supply during standby when the load on the power supply circuit is reduced, and significantly reduce power consumption during standby. It is an object of the present invention to provide a standby electric power supply system for an electric product, and an air conditioner and a refrigerator using the same.

[0009]

In order to achieve the above-mentioned object, a standby power supply system according to the present invention provides an electric appliance in which a normal operation state and a standby state are set by a control means. The charging means is charged with the output DC voltage of the power supply means to which power is supplied, and the charged voltage is used as the power supply voltage of the control means. In a normal operation state, commercial AC power is always supplied from the commercial AC power supply to the power supply means. In the standby state, the control unit monitors the charging voltage so that the charging voltage of the charging unit is maintained within a specified voltage range required as a power supply voltage of the control unit. By controlling the switch means,
Turning on the power supply from the commercial AC power supply to the power supply means;
Turn off.

Therefore, in the standby state, the control means can be maintained in the operating state with the minimum necessary power supply. In this case, in the standby state, by cutting off the power supply to the other parts of the electric product, a large reduction in power consumption can be achieved in combination with the above-described power supply method to the control means.

Further, the air conditioner according to the present invention supplies power from the commercial AC power supply to the power supply means of the outdoor unit, that is, the outdoor power supply means, to supply a power supply voltage to each part of the outdoor unit, In the case where the power supply voltage of the indoor control means for supplying the power to the indoor power supply means and receiving the command from the outside is obtained from the indoor power supply means, the auxiliary power supply, the switch means, and the charging means are provided, and the normal operation state is provided. Then, power is supplied from the commercial AC power supply to the outdoor power supply means, so that the power supply voltage is supplied to each part of the outdoor unit, and a DC voltage is also supplied to the indoor power supply means. The charging means is charged with the output DC voltage to generate the power supply voltage of the indoor control means, and in the standby state, when the power supply from the commercial AC power supply to the outdoor power supply means is cut off. In addition, power is supplied from a commercial AC power supply to the auxiliary power supply via the switch means, and the charging means is charged with the output DC voltage of the auxiliary power supply. At this time, the indoor control means The switch means is turned on and off while monitoring the charging voltage of the charging means so that the charging voltage of the charging means is maintained within a prescribed voltage range required as a power supply voltage of the indoor control means. .

As a result, in the standby state, no power is supplied to the outdoor unit, so that power consumption can be reduced. Also, in the indoor unit, the charging voltage of the charging means drops to the lower limit of the specified voltage range. Only when
Since power is supplied to the auxiliary power supply, it is possible to further reduce power consumption while keeping the indoor control means in the operating state.

Further, in the refrigerator according to the present invention, the commercial AC voltage from the commercial AC power supply is converted into a DC voltage by the rectifying and smoothing means, and this DC voltage is used as the power supply voltage of the inverter and supplied to the power supply means. When the power supply means is configured to generate the power supply voltage of each unit including the control means, the charging means is charged with the output voltage of the power supply means to generate the power supply voltage of the control means, and the switch means is provided. The output DC voltage of the rectifying / smoothing means is supplied to the power supply means via the power supply means.In a normal operation state, the switch means is turned on, and a DC voltage is constantly supplied from the rectification / smoothing means to the power supply means so as to be supplied to each unit. While the power supply voltage is supplied, in a standby state, the control means controls the switching means to turn on and off while monitoring the charging voltage of the charging means, Charging voltage of is to be held within the required defined as a power supply voltage of the control means.

In this way, in the standby state, the supply of the power supply voltage to each part is almost eliminated, so that the power consumption can be greatly reduced. Further, since no power is supplied to the outdoor unit, the power consumption can be reduced. Only when the charging voltage of the charging means drops to the lower limit side of the above-mentioned specified voltage range, power is supplied from the rectifying / smoothing means to the power supply means. The power consumption can be further reduced while maintaining.

[0015]

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is a block diagram showing an embodiment of an electric appliance standby power supply system according to the present invention.
An air conditioner is taken as an example of an electric product. A is an indoor unit, B is an outdoor unit, 1 is a commercial AC power supply, and 2, 3
Is a switch means, 4 is a full-wave rectifier circuit, 4a to 4d are rectifier diodes, 5 is a smoothing capacitor, 6 is an auxiliary power supply, 7 is a double layer capacitor, 8 is a voltage detecting element, 9 is a microcomputer,
10 is a light receiving unit, 11 is a DC-DC converter, 1
2 is an interface H (hybrid) IC, 13 is a panel control circuit, 14 is a panel drive motor, 15 is a wind direction plate control circuit, 16 is a wind direction plate drive motor, 17 is an indoor fan motor control circuit, and 18 is an indoor fan motor. , 19,
20 is a relay switch, 21 is a full-wave rectifier circuit, 21a-
21d is a rectifier diode, 22 is an active converter, 22a is an inductor, 22b is a switching element,
22c is a diode, 23 is a smoothing capacitor, 24 is a control IC, 25 is an inverter, 25a to 25f are semiconductor switching elements, 26a to 26f are drive circuits, 27
Is a compressor motor, 28 is a rotor magnetic pole position detection circuit, 29
Is a full-wave rectifier circuit, 29a to 29d are rectifier diodes, 3
0 is a smoothing capacitor, 31 is a switching power supply, 31a
Is a switching transformer, 31b is a switching element,
32 is a regulator, 33 is a microcomputer, 34 is an electric expansion valve control circuit, 35 is an electric expansion valve, 36 is an outdoor fan motor control IC, and 37 is an outdoor fan motor.

In FIG. 1, an air conditioner using this embodiment includes an indoor unit A installed indoors and an outdoor unit B installed outdoors. Commercial AC power is supplied from the commercial AC power supply 1.

The indoor unit A is provided with a microcomputer 9 as a control means of the indoor unit. The microcomputer 9 receives various commands from a remote controller (not shown) operated by a user via a light receiving unit 10. Data communication is performed between the microcomputer 33 in the outdoor unit B using the power line and the interface HIC12.
The microcomputer 33 serves as control means for the indoor unit.

The commands from the remote controller include an operation stop command, an operation command, an indoor temperature setting, and a change in wind direction. When the microcomputer 9 receives the operation stop command, the microcomputer 9 turns off the switch means 2 and turns off the outdoor unit B. When the supply of the commercial AC power from the commercial AC power supply to the outdoor unit B is stopped and the operation command is received, the switch unit 2 is turned on to supply the commercial AC power from the commercial AC power supply to the outdoor unit B. In this way, in the standby state, the power of each unit of the outdoor unit B that does not need to be operated is shut off, and thus the power consumption can be significantly reduced.

The microcomputer 9 in the indoor unit A
Allows the remote controller to receive commands from the remote controller not only when the air conditioner is in a normal operation state but also in a standby state in which a refrigeration cycle, a fan, and the like are in a stopped state when a stop command is issued from the remote controller. Therefore, the power supply voltage must always be supplied and maintained in the operating state.

In FIG. 1, when the air conditioner is in a normal operation state, the outdoor unit B is in an operation state,
A power supply voltage is constantly supplied to the microcomputer 9 from the switching power supply 31 which is a control power supply of the outdoor unit B via the DC-DC converter 11 of the indoor unit A. Also,
When the air conditioner is in a standby state in response to an operation stop command from a remote controller, power consumption is suppressed to a necessary minimum. The required minimum power is required because the microcomputer 9 and the light receiving unit 10 in the indoor unit A are required.
It is. For this reason, this air conditioner uses the standby power supply system according to the present invention.

This standby power supply system comprises a microcomputer 9, switch means 1 and 2, rectifier circuit 4, smoothing capacitor 5, auxiliary power supply 6, double layer capacitor and voltage detecting element 8.
It is almost composed of In the standby power supply system, during normal operation of the air conditioner, the microcomputer 9 turns on the switch means 2 and turns on the commercial AC power to the outdoor unit B according to the operation command from the remote controller as described above. The power supply voltage is supplied from the outdoor unit B to the microcomputer 9.
In the standby state of the air conditioner, the switch 9 is turned off by the microcomputer 9 to cut off the supply of the commercial AC power to the outdoor unit B. As a result, unnecessary power consumption in the outdoor unit B can be eliminated, but supply of the power supply voltage from the outdoor unit B to the microcomputer 9 and the light receiving unit 10 is also stopped. Therefore, the standby power supply system supplies power directly from the commercial AC power supply 1 to the microcomputer 9 and the light receiving unit 10. And the light receiving unit 10 is supplied with the minimum necessary power.

As described above, in the present embodiment, in the standby state of the air conditioner, the power consumption in the outdoor unit B is eliminated, and the microcomputer 9 which requires power even in this standby state is required to have the minimum necessary power. Is supplied. Therefore, power consumption in the standby state can be significantly reduced.

Next, this embodiment and the operation of an air conditioner using the same will be described with reference to FIG. However, FIG. 2 shows a state of the switch means 2, 3 and the double-layer capacitor 7 constituting this embodiment in a normal operation state and a standby state of the air conditioner.

[0025] When the air conditioner by the operation command from the remote controller is in the normal operating condition is the switching means 2 is turned on by the control signals S ₁ from the microcomputer 9, the commercial AC voltage from the commercial AC power source 1, the It is supplied to the outdoor unit B via the switch means 2.

In the outdoor unit B, the commercial AC voltage is supplied to a full-wave rectifier circuit 2 comprising rectifier diodes 29a to 29d.
9 and a smoothing capacitor 30 rectify and smooth to generate a DC voltage.
A switching power supply 31 serving as a control power supply for the outdoor unit B composed of a switching IC 31 and a switching element 31b drives a control IC 24 that drives the switching element 22b of the active converter 22 from this DC voltage and drives semiconductor switching elements 25a to 25f that constitute the inverter 25. Circuits 26a to 26f, drive circuit 3 for electric expansion valve 35
4. The power supply voltage of the drive circuit 36 of the outdoor fan motor 37 is generated. Further, one output DC voltage of the switching power supply 31 is set to a constant voltage value by the regulator 32, and then the microcomputer 3 as a control circuit of the outdoor unit B.
3 is supplied as a power supply voltage.

When the power supply voltage is supplied in this manner, the microcomputer 33 generates a control signal S ₃ , thereby turning on the relay switches 19 and 20.

Further, one output DC voltage of the switching power supply 31 is supplied to the indoor unit A via the relay switch 20. In the indoor unit A, the DC voltage supplied from the outdoor unit B is applied to the indoor fan motor 1.
8 is supplied as a power supply voltage to the control circuit 17, is converted to a predetermined voltage value by the DC-DC converter 11, and is supplied to the double-layer capacitor 7 as a charging voltage. Drive circuit 1
3 and 15 are supplied as power supply voltages, respectively. The charging voltage for the double-layer capacitor 7 is supplied to the microcomputer 9 as a power supply voltage.

Here, the voltage detecting element 8 detects the voltage between both ends of the double-layer capacitor 7 and supplies the detection result to the microcomputer 9. The microcomputer 9 determines whether or not within the voltage range defined that the voltage across the double layer capacitor 7 from the detection result is determined in advance, the control signal S ₂ generated according to this determination result, the control Switch means 3 by signal S ₂
Is turned on and off. During normal operation of the air conditioner, the voltage across the double-layer capacitor 7 charged by the charging voltage from the DC-DC converter 11 is held at substantially the upper limit of this prescribed voltage range. since the switch means 3 is held in the off state by the control signal S _2.

During normal operation, in the outdoor unit B, the commercial AC voltage is supplied from the commercial AC power supply 1 to the full-wave rectifier circuit 21 including the rectifier diodes 21a to 21d via the switch means 2 and the relay switch 19, Thus, a full-wave rectified voltage is generated and the active converter 2
2 is supplied. In this active converter 22,
The control signal S ₄ from the microcomputer 33 by the control IC 24
Switching element 22b that is turned on and off according to
And the inductor 22a. The boosted voltage is supplied to the smoothing capacitor 22a via the diode 22c and smoothed, thereby generating a DC voltage.
This DC voltage is applied to inverter 25 as a power supply voltage.

Also, the microcomputer 9 of the indoor unit A takes in information such as an indoor set temperature and a detected temperature of an indoor temperature sensor (not shown) from a remote controller (not shown) via the light receiving unit 10 and transmits the information via the interface HIC12 to the outdoor unit. Transfer to the microcomputer 33 of B. Therefore, the microcomputer 33 uses the information and the compressor motor 2
The rotor magnetic pole position of 7 to form a control signal S ₅ from the detection output from the position detection circuit 28 for detecting. Drive circuit 26a~26f is on the semiconductor switching element 25a~25f the inverter 25 in accordance with the control signal S _5, off controls. In this way, the drive signal of the compressor motor 27 is generated by the inverter 25, and the compressor motor 27 operates so that the room temperature matches the temperature set by the remote control operation.

As described above, in the normal operation state of the air conditioner, the charging voltage of the double-layer capacitor 7 is maintained at substantially the upper limit of the specified voltage range by the DC voltage from the outdoor unit B. A constant power supply voltage is always supplied to the microcomputer 9 in A, and the microcomputer 9 can receive data from the light receiving unit 10 and detection data from a room temperature sensor (not shown).

Next, in the normal operation state of the air conditioner, when an operation stop command is sent from the remote controller (not shown) via the light receiving unit 10 (time t ₁ ), the standby power of this embodiment is used. The supply system operates. The microcomputer 9 generates a control signals S ₁ on the basis of the operation stop command to turn OFF the switching means 2. Thereby, the supply of the commercial AC voltage from the commercial AC power supply 1 to the outdoor unit B is cut off, and the supply of the charging voltage from the DC-DC converter 11 to the double-layer capacitor 7 is cut off. At this time, since the charging voltage to the double-layer capacitor 7 is set to substantially the upper limit of the specified voltage range, the necessary power supply voltage is supplied to the microcomputer 9.
However, in this case, no DC voltage is output from the DC-DC converter 11 and the switch means 3 is off, so that no voltage is applied to the double-layer capacitor 7 and, therefore, The charging voltage of the double-layer capacitor 7 decreases over time.

On the other hand, the microcomputer 9 constantly monitors the voltage across the double-layer capacitor 7, that is, the charging voltage by the voltage detecting element 8, and when the charging voltage reaches the lower limit of the specified voltage range (time t ₂ , t ₄ ), the microcomputer 9 detects this, and generates the control signal S ₂ to turn on the switch means 3.

Then, a commercial AC voltage is supplied from the commercial AC power supply 1 to the full-wave rectifier circuit 4 composed of the rectifier diodes 4a to 4d via the switch means 3 and rectified. The rectified voltage is smoothed by the smoothing capacitor 5. Thus, a DC voltage is generated and supplied to the auxiliary power supply 6. The auxiliary power supply 6 is a constant voltage circuit, and forms a stable DC voltage having a predetermined voltage value substantially equal to the DC voltage from the DC-DC converter 11 from the DC voltage output from the smoothing capacitor 5. The output DC voltage of the auxiliary power supply 6 is applied to the double-layer capacitor 7. As a result, the double-layer capacitor 7 is charged. When the charged voltage reaches the upper limit of the specified voltage range (time t ₃ , t ₅ ), the microcomputer 9 detects this by the voltage detecting element 8 and outputs the control signal S ₂ is generated and the switch means 3 is turned off.

As described above, the voltage is intermittently supplied from the auxiliary power supply 6 to the double-layer capacitor 7, so that the power supply voltage within the specified voltage range is constantly supplied from the double-layer capacitor 7 to the microcomputer 9. That is, the microcomputer 9 is kept in the operating state.

Thereafter, when there is an operation command from the remote controller (time t ₆ ), the microcomputer 9 generates a control signal S1 in accordance with the command, turns on the switch means 2 and puts the outdoor unit B into an operation state. As a result, the DC voltage of the outdoor unit B becomes 2 via the DC-DC converter 11.
The double-layer capacitor 7 is supplied to the multilayer capacitor 7.
Is maintained at substantially the upper limit of the specified voltage range. When this is detected by the voltage detecting element 8, the microcomputer 9 generates the control signal S2 and holds the switch means 3 in the off state.

When the air conditioner is disconnected from the commercial AC power supply 1, the switch means 3 is turned on.
The switch means 2 is held in an off state, and when the commercial AC power supply 1 is connected after the air conditioner is attached, the air conditioner enters a standby state, and the commercial AC voltage is completely supplied through the switch means 3. And supplied to the wave rectifier circuit 4. As a result, the double-layer capacitor 7 is charged as described above. When the charged voltage reaches the upper limit of the specified voltage range, the microcomputer 9 outputs the control signal S2 to turn off the switch means 3. After that, until the operation command is given from the remote controller, the switching means 3
Turns on and off to maintain the power supply voltage of the microcomputer 9 within the specified voltage range. When the commercial AC power supply 1 is disconnected while the air conditioner is in a standby state, the switch means 3 is kept on while the charging voltage of the double-layer capacitor 7 is within the specified voltage range. When the microcomputer 9 reaches the lower limit of the specified voltage range, the microcomputer 9 outputs the control signal S2
And the switch means 3 is turned on. Therefore,
When the commercial AC power supply 1 is kept disconnected, the switch means 3 is kept in the ON state.

As described above, in this embodiment, in the standby state of the air conditioner, not only the power supply to the outdoor unit B is cut off, but also in the indoor unit A,
It only supplies power to the microcomputer 9 that takes in commands from the remote controller, and also supplies power to the microcomputer 9 for the required period while keeping the power supply voltage from the double-layer capacitor 7 within the specified voltage range. Therefore, the power consumption of the air conditioner in the standby state can be minimized while the microcomputer 9 is kept operating, and the power consumption can be significantly reduced.

FIG. 3 is a block diagram showing another embodiment of a standby electric power supply system for electric products according to the present invention. Here, a refrigerator is used as an example of the electric products. , 41 is a voltage doubler rectifier circuit, 4
1a and 41b are rectifier diodes, 42a and 42b are smoothing capacitors, 43 is a switching means, 44 is a switching power supply as a control power supply, 44a is a switching transformer, 44b is a switching element, 45a and 45b are regulators, 46 is a double layer capacitor, 47 is a voltage detecting element, 48 is a microcomputer, 49 is an IP constituting an inverter.
M (Intelligent Power Module), 49a to 49f are semiconductor switching elements, 50a to 50f are drive circuits, 51 is a control circuit, 52 is a compressor motor, 53 is a rotor magnetic pole position detection circuit, 54 is a damper control circuit, and 55 is an electric motor. A damper 56 is a control circuit for the internal fan and the machine room fan, 57 is an internal fan motor, and 58 is a machine room fan motor.

In the same figure, rectifier diodes 41a, 41
1b and the smoothing capacitors 42a and 42b constitute a voltage doubler rectifier circuit 41. A commercial AC voltage is supplied from a commercial AC power supply 40, and a DC voltage having a higher voltage value than the commercial AC voltage is generated. This DC voltage is supplied to the IPM 49 as a power supply voltage. Drive circuits 50a to 50f for driving the semiconductor switching elements 49a to 49f of the IPM 49, a control circuit 51 for these switching elements, a control circuit 54 for the electric damper 55, a control circuit 56 for the in-compartment fan motor 57 and the machine room fan motor 58 The power supply voltage of each of the rotor magnetic pole position detection circuits 53 for detecting the position of the rotor magnetic pole of the compressor motor 52 is supplied from a switching power supply 44 as a control power supply including a switching transformer 44a and a switching element 44b, or a regulator 45a. Is supplied after being set to a predetermined voltage value.

The control circuit 54 for the electric damper 55 and the control circuit 5 for the fan motor 57 in the refrigerator and the fan motor 58 in the machine room
The output voltage of the switching power supply 44, which is supplied to the power supply 6 as a power supply voltage, is set to a predetermined voltage value by a regulator 45b, and then supplied to a double-layer capacitor 46 to charge it. The charging voltage of the double-layer capacitor 46 is supplied to the microcomputer 48 as a power supply voltage. Further, the voltage across the double-layer capacitor 46, that is, the charging voltage, is constantly detected by the voltage detecting element 47. The microcomputer 48 takes in the detection result of the voltage detecting element 47 to charge the double-layer capacitor 46. The voltage is constantly monitored.

Voltage doubler rectifier circuit 41 and switching power supply 4
4 is connected via a switch means 43, and the switch means 43 controls the control signal S _A from the microcomputer 48.
On and off.

The microcomputer 48 is a system control circuit for managing and controlling the entire refrigerator system. The microcomputer 48 receives the detection output of the rotor magnetic pole position detection circuit 53 and the detection output of a temperature sensor (not shown) in the refrigerator, and outputs these detection outputs. generated by the drive circuit a control signal S _B corresponding to 50a~50
control f. In response, the control circuit 51 sets the IPM 49
Are turned on and off to rotate the compressor motor 52 at the rotation speed specified by the microcomputer 48.

The case of a refrigerator, the microcomputer 48 always monitors the internal temperature, the internal temperature is different from the set temperature, and supplies to the drive circuit 50a~50f outputs a control signal S _B, according to this By operating the IPM 49, the compressor motor 52 is rotationally driven to bring a refrigeration cycle (not shown) into an operating state. At the same time, the microcomputer 48 sends a control signal to the control circuits 54 and 56 to operate the electric damper 55, the internal fan motor 57, and the machine room fan motor 58.

Such a state is hereinafter referred to as a normal operation state. In this normal operation state, the microcomputer 48 outputs the control signal S
_A turns on the switch means 43 so that the DC voltage output from the voltage doubler rectifier circuit 41 is always supplied to the switching power supply circuit 44. The switching power supply 44 supplies the microcomputer 48 and the drive circuits 50a to 50a
f, A power supply voltage is supplied to the control circuits 51, 54, 56 and the rotor magnetic pole rotational position detection circuit 53. In this case, the microcomputer 48 does not take in the detection output of the voltage detection element 47.

When the internal temperature is stable at the above set temperature, it is not necessary to operate the refrigeration cycle.
The microcomputer 48 stops the operation of the IPM 49 to stop the compressor motor 52, and stops the operations of the control circuits 54 and 56. Such a state is hereinafter referred to as a standby state or a stopped state.

Even in this stopped state, the microcomputer 48 needs to monitor the temperature inside the refrigerator, and therefore, it is necessary to keep the microcomputer 48 in an operating state. Therefore, in order to reduce the power consumption to the necessary minimum in this stopped state, it is necessary to supply power only to the microcomputer 48. Therefore, in this refrigerator, the standby power supply system according to the present invention is provided, and the power consumption in the stopped state is reduced to the necessary minimum.

In FIG. 3, the standby power supply system according to the present invention comprises a switch 43 and a double-layer capacitor 4.
6 and a voltage detection element 47. Hereinafter, the operation of the standby power supply system will be described with reference to FIG. FIG. 4 shows the operation of the switch means 43 and the change in the charging voltage of the double-layer capacitor 46 when the compressor motor 52 is in the normal operation state and in the stopped (standby) state.

In the normal operation state, as described above, the microcomputer 48 turns on the switch means 43 by the control signal S _A , and supplies the power supply voltage from the switching power supply 44 to each of the above components. In addition, microcomputer 4
8, a charging voltage of the double-layer capacitor 46 is supplied as a power supply voltage. In this case, the microcomputer 48 does not take in the detection output of the voltage detection element 47 and keeps the switch means 43 in the ON state. Accordingly, the double-layer capacitor 46 is always charged by the output DC voltage of the switching power supply 44, and the charged voltage is always kept at substantially the upper limit of the specified voltage range required as the power supply voltage of the microcomputer 48.

When the compressor motor 52 is stopped and stopped (time t ₁ ′) because the internal temperature is stable, the microcomputer 48 turns off the switch means 43 by the control signal S _A. . Thereby, the voltage doubler rectifier circuit 4
1 to the switching power supply 44 is cut off, and the drive circuits 50a to 50f and the control circuits 51, 5
4, 56, the supply of the power supply voltage to the rotor magnetic pole rotational position detection circuit 53 is stopped. However, since the double-layer capacitor 46 remains charged, the charging voltage is supplied as it is to the microcomputer 48 as the power supply voltage, and the microcomputer 48 is maintained in the operating state.

At the same time as the stop state, the microcomputer 48 starts taking in the detection output of the voltage detection element 47.
That is, the microcomputer 48 constantly monitors the charging voltage of the double-layer capacitor 46 based on the detection output of the voltage detecting element 48, and when the charging voltage of the double-layer capacitor 46 decreases and reaches the lower limit of the specified voltage range, the microcomputer 48 48 to turn on the switching means 43 by a control signal S _a
(Time t ₂ ′, t ₄ ′). Thereby, the voltage doubler rectifier circuit 4
1 supplies a DC voltage to the switching power supply 44, and the output voltage of the switching power supply 44 increases the charging voltage of the double-layer capacitor 46. When the charging voltage of the double layer capacitor 46 has reached the upper limit of the specified voltage range, detects this microcomputer 48 by the detection output of the voltage detector 47 again turns OFF the switching means 43 by a control signal S _A To

In the stop state, this operation is repeated, whereby the charging voltage of the double-layer capacitor 46, that is,
The power supply voltage of the microcomputer 48 is kept within the specified voltage range.

Thereafter, when the microcomputer 48 detects a change in the internal temperature of the refrigerator that is greater than a preset value, the microcomputer 48
Holds the switch means 43 in the ON state by the control signal SA and sets the switch to the normal operation state (time t ₆ ′).

When the commercial AC power supply 1 is disconnected when the refrigerator is installed at a predetermined place in the room, the switch means 43 is in the ON state, and the commercial AC power supply 1 is connected and A DC voltage is supplied from the rectifier circuit 41 to the switching power supply 44 to set a normal operation state.

As described above, in this embodiment, the power supply voltage of the microcomputer 48 is constantly supplied from the double-layer capacitor 46 by turning on and off the switch means 43 during standby. 48 can be maintained in an operating state, and supply of power supply voltage to circuits other than the microcomputer 48 can be cut off. Therefore,
In the standby state, power can be supplied to only the microcomputer 48 with the minimum power consumption. In addition, when the charging voltage of the double-layer capacitor 46 reaches the lower limit of the specified voltage range, the commercial AC power is supplied. Since power may be supplied from the power supply 1, power consumption during standby can be significantly reduced.

In the refrigerator shown in FIG. 3, the switch means 43 is turned on during standby, and wasteful power is supplied from the switching power supply 44 to circuits other than the microcomputer 48. Multilayer capacitor 4
In the case of the microcomputer 6, the charging period is almost negligibly shorter than the discharging period.
The power consumption in circuits other than 8 is negligible.

Although the embodiments of the present invention have been described above using an air conditioner and a refrigerator as an example, the present invention is not limited to these embodiments, but can be applied to other electric appliances. Needless to say, there is.

[0059]

As described above, according to the standby power supply system of the present invention, power is supplied from the commercial AC power supply via the charging means to the control means which needs to be kept operating at all times. In the stand-by state, it is sufficient to supply power from the charging means only when the charging voltage is reduced, and the power consumption in the stand-by state is greatly reduced while the control means is kept in the operating state. Can be reduced.

According to the air conditioner of the present invention,
In the normal operation state, the charging voltage of the charging unit charged with the output voltage of the outdoor power supply unit that supplies the power supply voltage to each unit of the indoor unit is used as the power supply voltage of the indoor control unit,
Further, in the standby state, the power supply from the commercial AC power supply to the outdoor power supply unit is shut off, and in the indoor unit,
Power is supplied to the auxiliary power supply from the commercial AC power supply via the switch means, and the charging means is charged with the output voltage of the auxiliary power supply, and the indoor control means monitors the charging voltage of the charging means while the switch means Is turned on and off so that the charging voltage is maintained within a specified voltage range required as the power supply voltage of the indoor control means. Therefore, in either the normal operation state or the standby state. Also, the power consumption in the standby state can be significantly reduced while the indoor control means is kept in the operating state.

Further, according to the refrigerator of the present invention, in the normal operation state, the power is always supplied to the power supply through the switch, and the power supply generates the power supply voltage of each section and the output of the power supply. Charge the charging means with voltage,
The charging voltage of the charging means is used as the power supply voltage of the control means for controlling each section. In a standby state, the control means controls the switching means on and off while monitoring the charging voltage of the charging means. Since the charging voltage is maintained within a specified voltage range required as the power supply voltage of the control means, the indoor control means is maintained in the operating state in both the normal operation state and the standby state. Meanwhile, power consumption in the standby state can be significantly reduced.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a configuration of an air conditioner using an embodiment of a standby power supply system according to the present invention.

FIG. 2 is a diagram showing the operation of the embodiment shown in FIG.

FIG. 3 is a block diagram illustrating a refrigerator using a standby power supply system according to another embodiment of the present invention.

FIG. 4 is a diagram showing the operation of the embodiment shown in FIG.

[Explanation of symbols]

 Reference Signs List A Indoor unit of air conditioner B Outdoor unit of air conditioner 1 Commercial power supply 2, 3 Switch means 4 Full-wave rectifier circuit 5 Smoothing capacitor 6 Auxiliary power supply 7 Double layer capacitor 8 Voltage detection element 9 Microcomputer 10 Light receiving unit 11 DC-DC Converter 12 Interface HIC 13 Panel control circuit 14 Panel drive motor 15 Wind direction board control circuit 16 Wind direction board drive motor 17 Indoor fan motor control circuit 18 Indoor fan motor 19, 20 Relay switch 21 Full-wave rectifier circuit 22a Inductor 22b Switching element 22c Diode 23 Smoothing capacitor 24 Control IC 25 Inverter 25 a to 25 f Semiconductor switching element 26 a to 26 f Drive circuit 27 Compressor motor 28 Rotor magnetic pole position detection circuit 29 Full-wave rectification circuit 30 Smoothing Capacitor 31 switching power supply 33 microcomputer 40 commercial AC power supply 41 double pressure reduction rectifier circuit 43 switch means 44 switching power supply 46 double layer capacitor 47 voltage detection element 48 microcomputer 49 IPM 49a to 49f semiconductor switching element 50a to 50f drive circuit 51 control circuit 52 compressor Motor 53 Rotor magnetic pole position detection circuit 54 Damper control circuit 55 Electric damper 56 Control circuit for internal fan and machine room fan 57 Internal fan 58 Machine room fan motor

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Noboaki Arakawa 800, Tomita, Ohira-machi, Shimotsuga-gun, Tochigi Prefecture Inside the Cooling Division, Hitachi, Ltd. (72) Koji Kato 800 F, Tomita, Ohira-cho, Ohira-cho, Shimotsuga-gun, Tochigi F-term (ref.) 3L045 AA02 BA01 CA02 DA02 EA01 GA07 HA01 LA01 MA20 NA19 3L060 AA03 CC10 DD01 EE45 5G065 AA01 DA04 DA06 DA07 EA06 FA01 GA04 GA06 HA16 JA07 KA02 KA05 LA01 MA01 MA02 MA03 MA09 MA10 5H007 AA00 BB06 CA01 CB05 CC07 CC12 DB03 DB09 DB12

Claims (5)

[Claims] 1. A converter for converting a commercial AC voltage from a commercial AC power supply into a DC voltage, a controller for controlling each unit, and a DC voltage for a power supply voltage of the controller based on an output DC voltage of the converter. Generating means for generating an electric power, wherein the control means sets a normal operation state and a standby state. The electric power supply system at the time of standby is configured to supply a DC voltage from the converting means to the generating means. on,
Switch means for turning off; and charging means charged with the output voltage of the generation means and using the charged voltage as a power supply voltage for the control means, wherein the control means always turns on the switch means during normal operation. During standby, the switch means is turned on and off such that the charging voltage of the charging means is maintained within a predetermined voltage range required as a power supply voltage of the control means. Standby power supply system. 2. An outdoor control means for controlling each part such as an inverter to an outdoor unit and an outdoor power supply means for receiving a commercial AC power from a commercial AC power supply and generating a power supply voltage for each part including the outdoor control means. An air conditioner provided with an indoor control means for receiving an external command to the indoor unit and an indoor power supply means for generating a power supply voltage of the indoor control means from an output voltage of the outdoor power supply means; First switch means for turning on / off the supply of the commercial AC power from the AC power supply to the outdoor power supply means; an auxiliary power supply to which the commercial AC power is supplied from the commercial AC power supply; Second switch means for turning on / off the supply of the commercial AC power to the auxiliary power supply, and charged with the output voltage of the indoor power supply means and the output voltage of the auxiliary power supply; A standby power supply system comprising: charging means for setting a power supply voltage of the internal control means; and charging voltage detecting means for detecting a charging voltage of the charging means. The indoor control means receives a normal operation command from outside. The first switch means is turned on and the second switch means is turned off. When a standby command is received from the outside, the first switch means is turned off. Monitoring the charging voltage of the charging means from the detection output of the charging voltage detecting means, and controlling the charging voltage within a prescribed voltage range required as a power supply voltage of the second control means. An air conditioner characterized in that on / off control of the second switch means is performed. 3. The indoor control unit according to claim 2, wherein the indoor control unit turns on the second switch unit when a charging voltage of the charging unit reaches a lower limit of the predetermined voltage range, and charges the charging unit. The air conditioner according to claim 1, wherein when the voltage reaches the upper limit of the specified voltage range, the second switch is turned off. 4. A rectifying / smoothing means for converting a commercial AC voltage from a commercial AC power supply into a DC voltage, and an inverter for generating a drive signal for a compressor motor of a refrigeration cycle using the output DC voltage of the rectifying / smoothing means as a power supply voltage. A driving unit for the inverter, a control unit for controlling the driving unit, and a power supply unit for generating a power supply voltage for the driving unit and the control unit from an output DC voltage of the rectifying and smoothing unit. A refrigerator that can be set to a normal operation state in which the compressor motor is driven to rotate to operate the refrigeration cycle and a standby state in which the compressor motor is stopped to stop the refrigeration cycle. Switch means for turning on and off the supply of a DC voltage from the rectifying / smoothing means to the power supply means; and charging by the output voltage of the power supply means, and charging the charged voltage to the power supply of the control means. A standby power supply system comprising: a charging means for detecting the charging voltage of the charging means; and a charging voltage detecting means for detecting a charging voltage of the charging means. When the standby state is set, the charging voltage of the charging means is monitored from the detection output of the charging voltage detecting means, and the charging voltage is maintained within a specified voltage range required as the power supply voltage of the control means. Wherein the switch means is controlled to turn on and off. 5. The control unit according to claim 4, wherein the control unit turns on the switch unit when the charging voltage of the charging unit reaches a lower limit of the specified voltage range, and the charging voltage of the charging unit is adjusted to the specified voltage. Wherein the switch is turned off when the upper limit of the voltage range is reached.