JP6717434B2 - Household appliances - Google Patents

Description

The present invention relates to home electric appliances.

BACKGROUND ART Conventionally, as disclosed in, for example, Japanese Unexamined Patent Publication No. 2006-246666, an air conditioner that discharges a residual voltage in a short time when an outlet is cut off is known. In this air conditioner, the residual voltage of the capacitor is discharged when the outlet is pulled out for safety purposes.

Japanese Unexamined Patent Publication No. 2006-246666

Home appliances such as an air conditioner and a dehumidifier include a power supply circuit, an actuator, an actuator drive unit, and a display operation device. The power supply circuit is connected to a power supply plug to generate a power supply. The actuator achieves desired functions such as air conditioning and dehumidification. The actuator drive unit includes a drive circuit. The display operation device is responsible for operation and display of the device.

A smoothing capacitor is often included in at least one of the power supply circuit and the drive circuit. The smoothing capacitor has a residual charge when the power plug is pulled out and the AC power supply is stopped. Due to the influence of low power consumption in recent years, there is a possibility that a defective period may occur in which the power of the display operating device is kept on due to the residual voltage of the smoothing capacitor even if the power plug is pulled out.

The residual voltage of the smoothing capacitor cannot supplement the electric power so large that the actuator is driven during normal operation. During this trouble period, the desired actuator operation is not realized even if an operation is input to the display operation device, although the display operation device is operating. This malfunction period is temporary, and if the residual charge of the smoothing capacitor decreases, it will be resolved and the same state as a normal power-off will be achieved. Therefore, it is not preferable to handle this defect period as occurrence of abnormality such as device failure.

The present invention has been made in order to solve the above problems, and provides an improved home electric appliance capable of suppressing the operation of the equipment when the AC power supply is stopped from being unnecessarily treated as an abnormality. The purpose is to

Home appliances according to the present invention,
A power supply circuit unit that receives AC power and generates an internal power supply;
An interface control unit connected to the operation unit, operated by receiving the internal power supply, and giving an operation command to the actuator drive unit based on an operation received by the operation unit;
A power supply detection unit that detects whether or not the AC power is input to the power supply circuit unit,
Equipped with
When it is detected that the AC power is not input by the power supply detection unit, the interface control unit is caused to execute a predetermined stop process even if the internal power is supplied from the power supply circuit unit ,
A signal wiring for directly connecting the power supply detection unit and the interface control unit without sandwiching another circuit, and transmitting a signal indicating that the AC power is not input to the interface control unit,
Further preparation,
An actuator driven by the actuator driving unit,
A power supply unit switch interposed between the actuator drive unit and the power supply circuit unit and transmitting the internal power generated by the power supply circuit unit to the actuator drive unit by being turned on,
Equipped with
While the home appliance is powered on and the standby mode for stopping the actuator is being executed, the power supply unit switch is turned off,
A power plug connected to an AC power supply for supplying the AC power;
A power supply synchronization detection unit that detects the zero-cross of the AC power,
A detector switch for turning on/off an electrical connection between the power plug and the power synchronization detector,
Equipped with
The detector switch is turned off during execution of the standby mode.

When the AC power supply is stopped, even if the interface control unit continues to receive the power supply due to the residual charge in the capacitor in the power supply circuit unit, the interface control unit can execute the stop process. As a result, it is possible to prevent the device operation when the AC power supply is stopped from being unnecessarily handled as an abnormality.

It is sectional drawing of the household appliances in embodiment of this invention. It is a disassembled perspective view of the household appliances in embodiment of this invention. It is a circuit block diagram of the household appliances in embodiment of this invention. It is a flow chart for explaining operation of household appliances in an embodiment of the invention. It is a circuit diagram of the power supply synchronization detection part of the household electrical appliance in the embodiment of the invention. It is an example of a hardware configuration diagram of an interface control unit.

FIG. 1 is a sectional view of a home electric appliance according to an embodiment of the present invention. FIG. 2 is an exploded perspective view of the home electric appliance according to the embodiment of the present invention.

The home electric appliance 100 according to the embodiment is a dehumidifier, and more specifically, a portable inverter-driven compressor type dehumidifier. It is assumed that the left side of the paper surface of FIG. 1 is “front” of the home electric appliance 100, and the right side of the paper surface of FIG. 1 is “back” of the home electric appliance 100. The housing of the home electric appliance 100 includes a central housing 1, a front housing 2, and a rear housing 3. The central housing 1 is provided in the central portion of the home electric appliance 100. The central housing 1 can stand on its own. The front housing 2 is provided on the front side of the central housing 1 so as to be detachable from the central housing 1. The rear housing 3 is provided on the rear side of the central housing 1 so as to be detachable from the central housing 1.

The discharge port 4 is formed in the upper part of the central housing 1. The blower 5 is provided in the central portion of the central casing 1 in the front-rear direction of the central casing 1. For example, the blower 5 includes a blower fan and a motor. The rotation axis of the blower 5 is parallel to the front-rear direction axis of the home electric appliance 100 in the central portion of the central housing 1. The rotation axis of the blower 5 is oriented in the horizontal direction. The dehumidifying device 6 is provided on the rear side of the central housing 1. The dehumidifying device 6 includes a compressor 6a, a condenser 6b, a pressure reducing device 6c, and an evaporator 6d. Although not shown in FIGS. 1 and 2, a humidity detecting sensor 12 (see FIG. 3) is provided on one side surface of the central housing 1 in the lower portion of the central housing 1.

The front housing 2 includes a display operation device 7 and a water storage tank 8. The display operation device 7 is provided on the upper part of the front housing 2. Although not shown in FIGS. 1 and 2, the display operation device 7 includes an operation unit 32 (see FIG. 3) and a display unit 31 (see FIG. 3). The water storage tank 8 is provided below the front housing 2. The water storage tank 8 can be removed from the front side of the home electric appliance 100 with the front housing 2 attached to the central housing 1.

The rear housing 3 includes a suction port 9. The suction port 9 is provided in the upper part of the rear housing 3.

The home electric appliance 100 includes a display operation device 7 and a control device 10. The control device 10 is provided in front of the central housing 1. The control device 10 controls the operation of the blower 5 based on the operation state of the operation unit 32 of the display operation device 7 and the humidity detected by the humidity detection sensor 12. The motor of the blower 5 rotates at a rotation speed according to the control by the control device 10. As a result, the air A in the room is sucked into the housing from the suction port 9 in the horizontal direction. After that, the air A passes through the evaporator 6d. Then, the blower 5 discharges the air B upward from the discharge port 4 into the room.

The control device 10 controls the operation of the compressor 6a based on the operation state of the operation unit 32 of the display operation device 7 and the humidity detected by the humidity detection sensor 12. The compressor 6 a compresses the refrigerant at a frequency designated by the control of the control device 10. The condenser 6b cools the refrigerant compressed by the compressor 6a. The decompression device 6c decompresses the refrigerant cooled by the condenser 6b. The evaporator 6d removes water contained in the air A by absorbing heat in the refrigerant decompressed by the decompression device 6c. As a result, dehumidified air B is generated. The water removed from the air A is stored in the water storage tank 8.

FIG. 3 is a circuit block diagram of a home electric appliance according to the embodiment of the present invention. The display operation device 7 includes a main power switch 7a, a display unit 31, an operation unit 32, and an interface control unit 30. The display unit 31 is composed of an LED, a liquid crystal or the like. The operation unit 32 may be configured by a mechanical switch such as a button provided around the display unit 31, or may be realized by configuring at least a part of the display unit 31 by a touch panel. The operation unit 32 includes an operation switch 32a. The interface control unit 30 mainly includes the first microcomputer 30a. The first microcomputer 30a executes a display process of an LED or a liquid crystal, and an operation process of accepting an operation of a switch or the like.

The control device 10 intervenes between the power supply circuit unit 15, the actuator drive unit 17, and the power supply circuit unit 15 and the actuator drive unit 17, and turns on the power supply generated by the power supply circuit unit 15 to drive the actuator. A power supply unit switch 16 that communicates to the unit 17, a power supply detection unit 18, a power supply synchronization detection unit 19, and a detection unit switch 20 that turns on/off the electrical connection between the power plug 101 and the power supply synchronization detection unit 19, Is equipped with. The power supply circuit unit 15 includes a first smoothing capacitor C1 that stores electric charges when the internal power supply is generated. The actuator drive unit 17 includes a drive circuit 17a. The drive circuit 17a includes a second smoothing capacitor C2.

The actuator drive unit 17 is connected to the compressor 6a, the blower 5, and the discharge port louver drive motor 11, and controls the movements of these. The actuator drive unit 17 includes a drive circuit 17a for realizing such control, and the drive circuit 17a includes a second microcomputer 17b. The compressor 6a compresses the refrigerant while confirming the air condition with the humidity detecting sensor 12. The outlet louver drive motor 11 changes the blowing direction from the outlet 4. The power supply circuit unit 15 receives power supply from the AC power supply 13 and generates a DC internal power supply necessary for control. The power supply detection unit 18 detects that the AC power supply 13 is reliably supplied with power. When the power plug 101 is pulled out, the power detection unit 18 can detect this pulling out. The power supply synchronization detection unit 19 detects the zero cross of the AC power supply 13.

One of the purposes of the power supply synchronization detection unit 19 is to determine the frequency of the input AC power supply 13. Another purpose of the power supply synchronization detection unit 19 is to count the number of zero crossings and use it as a substitute for a timer. Still another purpose of the power supply synchronization detection unit 19 is to measure a predetermined time until the next zero cross with the zero cross point as a base point. This measurement time is used to determine the control timing of the actuator, and is used to control the power supply circuit unit 15 as necessary.

The home electric appliance 100 has a “standby mode”. The standby mode is a state in which the home electric appliance 100 is powered on by turning on the main power switch 7a, but an actuator such as the compressor 6a is not driven. The standby mode is executed when the condition that the home electric appliance 100 is powered on and the operation switch 32a of the operation unit 32 is not on is satisfied. For example, immediately after the power of the home electric appliance 100 is turned on, the standby mode is set until the operation switch 32a for actually starting dehumidification is turned on. In addition, for example, when the operation switch 32a is once turned on after the power of the home electric appliance 100 is turned on and then the operation switch 32a is turned off, the standby mode is executed. Further, for example, after the power supply of the household electric appliance 100 is turned on and the operation switch 32a is turned on, dehumidification is performed for a predetermined time set by a timer, and the dehumidification is automatically switched off, and then the standby mode is executed. Good.

While the "standby mode" is being executed, the power supply unit switch 16 is turned off, so that the actuator drive unit 17 is turned off. As a result, standby power is reduced. Since the power supply synchronization detection unit 19 needs to accurately detect the zero-cross point, the power supply synchronization detection unit 19 is a low impedance circuit that is not easily affected by disturbance. Therefore, the power consumption of the power supply synchronization detection unit 19 is large. The power supply synchronization detection unit 19 is disconnected from the AC power supply 13 by turning off the detection unit switch 20 during execution of the standby mode. Thereby, standby power can be reduced.

The display operation device 7 and the control device 10 are connected by wirings 41 to 45. More specifically, the wirings 41 to 45 are a signal wiring 41, a power supply wiring 42, a control wiring 43, a communication wiring 44, and a synchronization signal wiring 45.

The signal wiring 41 transmits a detection signal of the power supply detection unit 18 that outputs the presence or absence of power supply from the AC power supply 13 from the control device 10 to the display operation device 7. The signal wiring 41 directly connects the power supply detection unit 18 and the interface control unit 30 without sandwiching another circuit.

The signal wiring 41 can transmit a detection signal indicating that AC power is not input to the interface control unit 30 in an extremely short time. When the power supply detection unit 18 detects that AC power is not input, the interface control unit 30 is stopped at a timing sufficiently faster than when the voltage of the first smoothing capacitor C1 falls below the operating voltage of the interface control unit 30. Preferably. When the power supply detection unit 18 detects that AC power is not input, it is preferable that the detection signal be transmitted to the interface control unit 30 within a sufficiently short time such as within several tens of msec. The term “within several tens of msec” is specifically 10 msec to 90 msec, and it is preferable that the time is as short as possible.

The power supply wiring 42 supplies the DC power generated by the power supply circuit unit 15 to the display operation device 7. The control wiring 43 transmits an on/off command from the display operation device 7 to the power supply section switch 16 and the detection section switch 20. The communication wiring 44 is a bidirectional wiring for exchanging information between the interface control unit 30 and the actuator driving unit 17. The communication wiring 44 transmits an actuator operation instruction to the actuator drive unit 17 based on the operation information of the interface control unit 30. Here, at least the compressor 6a, the blower 5, and the discharge port louver drive motor 11 are referred to as an "actuator". The communication wiring 44 transmits information such as operating status monitoring and abnormality of each actuator from the actuator drive unit 17 to the interface control unit 30. The synchronization signal wiring 45 transmits the power supply synchronization signal, which is the output signal of the power supply synchronization detection unit 19, to the actuator drive unit 17.

The role of the power supply detector 18 will be described in detail. If there is power supply from the AC power supply 13, since there is DC power supply from the power supply circuit section 15 to the display operation device 7, the display operation device 7 is always operating. Since the operation of the display operation device 7 can be regarded as the same as the power supply from the AC power supply 13, it seems that it is not necessary to install the power supply detection unit 18. However, the power supply circuit unit 15 includes a large first smoothing capacitor C1 because it is necessary to perform inverter control. Moreover, in the embodiment, when the actuator is stopped, the power switch 16 and the detector switch 20 are turned off to prevent unnecessary current from flowing. As a result, the power supply to the display operating device 7 continues due to the residual voltage of the first smoothing capacitor C1 for a while even after the AC power supply 13 is cut off.

When detecting that the AC power from the AC power supply 13 is exhausted, the power supply detection unit 18 transmits a detection signal to the first microcomputer 30a of the interface control unit 30. This detection signal is transmitted through the signal wiring 41 in an extremely short time. When the interface control unit 30 receives the detection signal indicating that the AC power is exhausted from the AC power supply 13, the interface control unit 30 executes a predetermined “stop processing”.

As a specific example of the stop process, a process at the time of power failure may be performed, and for example, at least the following first to fourth examples can be given. As a first example, the stop processing may include “operation prohibition processing”. The operation prohibition process is a process in which the interface control unit 30 does not accept the operation of the operation unit 32.

In the embodiment, the interface control unit 30 includes the display unit 31 for providing the image to the user. In this case, as a second example, the stop process includes a display stop process of the display unit 31, a predetermined “operation stop image display process” on the display unit 31, and a predetermined “plug extraction” on the display unit 31. One of the processes of “display process of warning screen at occurrence” may be included.

As a third example, the stop processing may include "light-off processing". The turning-off process is a process of turning off the device power lamp when the interface control unit 30 includes the device power lamp.

In the embodiment, the communication wiring 44 is provided between the actuator drive unit 17 and the interface control unit 30 for transmitting the presence/absence of an abnormality. Further, in the embodiment, a notifying unit for notifying a user of an alarm is provided, and this notifying unit is the display unit 31 in the embodiment. In this case, as a fourth example, the stop process may include an “alarm stop process”. The alarm stop process is a process in which the notification unit is not notified of an abnormal alarm indicating that the operation received by the operation unit 32 is not realized by the actuator drive unit 17.

Since the stop processing is executed promptly, it is possible to avoid an error from occurring when trying to operate the actuator even when the AC power supply 13 is disconnected.

When AC power is supplied from the AC power supply 13, the power supply detection unit 18 is energized. From the viewpoint of reducing standby power consumption, it is desirable that the power supply detection unit 18 consume as low power as possible.

FIG. 4 is a flowchart for explaining the operation of home electric appliance 100 in the embodiment of the present invention. The flowchart of FIG. 4 shows a control program executed by the first microcomputer 30a of the interface control unit 30.

When the power plug 101 is connected to the AC power supply 13 and the main power switch 7a is turned on, the first microcomputer 30a is energized. When the first microcomputer 30a is energized, the routine of FIG. 4 starts.

First, in step S101, it is determined whether or not the connection of the AC power supply 13 is detected by the power supply detection unit 18. If the determination result of step S101 is Yes, the process proceeds to step S102. In step S102, the initial screen is displayed on the display unit 31 and the operation unit 32 is ready to accept an operation. Note that, for example, when the household electric appliance 100 is just after being powered on, the operation switch 32a has not been turned on yet, so that the actuator such as the compressor 6a is not driven. Therefore, at this time, the household electric appliance 100 is in the standby mode in step S102.

If the decision result in the step S101 is No, the process advances to a step S110. In step S110, the "stop processing" described above is performed. In the embodiment, it is assumed that, of the stop processing, the operation prohibition processing which is the first example and the display stop processing of the display unit 31 which is one of the second examples are executed. Then, a process progresses to step S105.

In step S105, it is determined whether the energization flag is set to 1. If the energization flag is not 1, the process returns to step S101.

After step S102, the process proceeds to step S103. In step S103, it is determined whether the operation switch 32a included in the operation unit 32 has been turned on. When the ON signal indicating that the operation switch 32a is turned on is generated, the process proceeds to step S104.

In step S104, the power supply unit switch 16 and the detection unit switch 20 are turned on through the control wiring 43, so that the actuator drive unit 17 and the power supply synchronization detection unit 19 are activated. Then, the energization flag is set to 1. As a result, the fact that the power is on is stored in the first microcomputer 30a. An operation command is transmitted to the actuator drive unit 17 according to the operation of the operation unit 32. After that, the process returns to step S101, and the actuator drive unit 17 continues to drive the actuator unless the power source is detected and the operation switch 32a is turned off in step S101.

If the operation switch 32a remains off in step S103, the process proceeds to step S105.

In step S105, the state of the energization flag is determined. Here, if the actuator drive unit 17 is turned on even once in step S104, 1 is set in the energization flag. In this case, the process proceeds to step S106.

In step S106, it is determined whether the 10-second timer is operating. If the 10-second timer is not operating, the process proceeds to step S109 and the 10-second timer is started. When the 10-second timer is operating, the process proceeds to step S107, and it is determined whether or not the 10-second timer indicates that 10 seconds have elapsed. If 10 seconds has not elapsed in step S107, the process returns to step S101 to cycle the program, and repeats step S107, and waits for 10 seconds to elapse.

If 10 seconds have elapsed in step S107, the process proceeds to step S108. In step S108, the power supply section switch 16 and the detection section switch 20 are turned off through the control wiring 43, so that the actuator drive section 17 and the power supply synchronization detection section 19 stop operating. Further, the energization flag is set to 0 and the 10 second timer is reset. Then, the process returns to step S101.

As described above, the home electric appliance 100 according to the embodiment includes the power supply circuit unit 15, the interface control unit 30, and the power supply detection unit 18. The power supply circuit unit 15 receives the AC power input via the power supply plug 101 and generates an internal power supply. The interface control unit 30 is connected to the operation unit 32 and receives an internal power source to operate. The interface control unit 30 gives an operation command to the actuator drive unit 17 based on the operation received by the operation unit 32. The power supply detection unit 18 detects whether AC power is input to the power supply circuit unit 15. As shown in step S110, when the first microcomputer 30a detects that the AC power is not input in the power supply detection unit 18 in step S101, the first microcomputer 30a controls the interface from the power supply circuit unit 15 by the residual charge of the first smoothing capacitor C1. Even if the internal power is supplied to the unit 30, a predetermined “stop processing” is executed.

It is assumed that after the AC power supply 13 is detected in step S101, the standby mode is entered in step S102, the operation switch 32a is detected to be turned on in step S103, and the home electric appliance 100 is operating normally in step S104. At this time, if the power supply plug 101 is pulled out and the supply of the AC power is stopped, the power supply detection is No in step S101. At this time, according to the embodiment, although the interface control unit 30 continues to be supplied with electric power by the electric charge remaining in the first smoothing capacitor C1 in the power supply circuit unit 15, the interface control unit 30 in step S110. Can perform stop processing. As a result, it is possible to prevent the situation in which the operation of the interface control unit 30 is not realized in the actuator drive unit after the power plug 101 is pulled out, so that the device operation when the AC power supply is stopped is unnecessarily treated as an abnormality. Can be suppressed.

In the flowchart of FIG. 4, when the flow completes a cycle, the process always returns to step S101. Therefore, if the power supply is not detected in step S101, the stop process is executed first in step S110, and the interface control unit 30 is in the same state as when the power is off.

According to steps S106, S107 and S109, when the power supply unit switch 16 is turned on from off, the power supply unit switch 16 is held on until a predetermined time of 10 seconds elapses. The reason for providing this 10-second timer is as follows. When the operation switch 32a is frequently turned on/off, the power supply switch 16 is turned on/off to repeatedly energize and deenergize the actuator drive unit 17. The second microcomputer 17b of the actuator drive unit 17 executes an initial process of start-up after the start of energization. When energization and de-energization of the actuator drive unit 17 are repeated, the second microcomputer 17b repeats the initial process many times. Repeating such initial processing may make the operation of the home electric appliance 100 unstable. Therefore, once the power is turned on, the power source switch 16 is kept on for 10 seconds to prevent repetition of the initial process. The time is not limited to 10 seconds, and a time longer or shorter than 10 seconds may be set.

In the home electric appliance 100 according to the above-described embodiment, the power supply unit switch 16 and the detection unit switch 20 are turned off during execution of the standby mode in step S102. As a result, the actuator drive unit 17 and the power supply synchronization detection unit 19 are stopped, and power consumption is suppressed. The relationship between the capacity of the first smoothing capacitor C1 provided in the power supply circuit unit 15 and the power consumption in the standby mode differs depending on the design. For example, by fully suppressing the power consumption, the fully-charged charge amount of the first smoothing capacitor C1 may be a sufficient amount to supplement the power consumption in the standby mode for a sufficient time. The sufficient time is, for example, 1 minute or more. In such a case, if the power plug 101 is pulled out after the process proceeds from step S102 to step S103 to step S105, the screen display state of the display unit 31 in the standby mode may continue for a long time of 1 minute or more. .. In this regard, in the embodiment, the process proceeds to step S110, whereby the interface control unit 30 can promptly execute the stop process. Therefore, it is possible to achieve both suppression of power consumption and suppression of unnecessary abnormality detection.

FIG. 5 is a circuit diagram of power supply synchronization detection unit 19 of the home electric appliance according to the embodiment of the present invention. The power supply synchronization detection unit 19 includes a first resistor 141, a second resistor 144, a reverse voltage blocking diode 142, and a photocoupler 143.

The first resistor 141 receives the AC power of the AC power supply 13 at one end. The anode of the diode 142 is connected to the other end of the first resistor 141. In the photocoupler 143, the current signal flowing from the cathode of the diode 142 is transmitted to the phototransistor via the light emitting diode. Control power is supplied to one end of the second resistor 144, and the other end of the second resistor 144 is connected to the phototransistor of the photocoupler 143. The synchronization signal wiring 45 is connected to the connection point between the other end of the second resistor 144 and the phototransistor of the photocoupler 143. A current signal is output from the synchronization signal wiring 45.

When the AC power supply 13 is connected, only a half-wave current flows through the first resistor 141, the diode 142 and the light emitting diode of the photocoupler 143. The half-wave current turns on the phototransistor of the photocoupler 143. When the phototransistor is turned on, the sync signal transmitted through the sync signal wiring 45 is inverted from the high level to the low level.

The power supply detection unit 18 can also be realized by the same circuit element and circuit connection as the circuit configuration of the power supply synchronization detection unit 19 shown in FIG. In this case, the synchronization signal wiring 45 of FIG. 5 is used as the signal wiring 41 for outputting the detection signal of the power supply detection unit 18. Further, when the first resistor 141 is replaced with the “third resistor” and the second resistor 144 is replaced with the “fourth resistor”, in order to reduce the power consumption in the standby mode, the power supply synchronization detection unit 19 is provided. It is preferable that the resistance value of the third resistor 141 that can be configured be as large as possible. For example, when the AC power supply 13 is 220 V and the circuit of FIG. 5 is used as the power supply synchronization detection unit 19, the resistance value of the third resistor 141 may be 30 kΩ. When the circuit of FIG. 5 is used as the power supply detection unit 18 when the AC power supply 13 is 220 V, the resistance value of the first resistor 141 may be 600 kΩ. When the first resistor 141 is set to 600 kΩ, an erroneous signal is likely to occur due to external noise or the like, but the function of the power supply detection unit 18 that only determines whether the AC power supply 13 is present or not is sufficiently satisfied.

FIG. 6 is an example of a hardware configuration diagram of the interface control unit 30.

The function of the first microcomputer 30a in the interface control unit 30 is realized by a processing circuit. The processing circuit may be dedicated hardware 50. The processing circuit may include a processor 51 and a memory 52. The processing circuit may be partially formed as dedicated hardware 50, and may further include a processor 51 and a memory 52. FIG. 6 shows an example in which a part of the processing circuit is formed as dedicated hardware 50 and includes a processor 51 and a memory 52.

Where at least some of the processing circuitry is at least one dedicated hardware 50, the processing circuitry may be, for example, a single circuit, a composite circuit, a programmed processor, a parallel programmed processor, an ASIC, an FPGA, or the like. The combination is applicable.

When the processing circuit includes at least one processor 51 and at least one memory 52, each function of the interface control unit 30 is realized by software, firmware, or a combination of software and firmware. The software and firmware are described as programs and stored in the memory 52. The processor 51 realizes the function of each unit by reading and executing the program stored in the memory 52. The processor 51 is also called a CPU (Central Processing Unit), a central processing unit, a processing unit, an arithmetic unit, a microprocessor, a microcomputer, and a DSP. The memory 52 corresponds to, for example, a nonvolatile or volatile semiconductor memory such as a RAM, a ROM, a flash memory, an EPROM, and an EEPROM.

In this way, the processing circuit can realize each function of the interface control unit 30 by hardware, software, firmware, or a combination thereof. Each function of the actuator drive unit 17 is also realized by a processing circuit similar to the processing circuit shown in FIG.

1 Central case 2 Front case 3 Rear case 4 Discharge port 5 Blower 6 Dehumidifier 6a Compressor 6b Condenser 6c Pressure reducer 6d Evaporator 7 Display operating device 7a Main power switch 8 Water tank 9 Suction port 10 Control device 11 Discharge port louver drive motor 12 sensor 13 AC power supply 15 power supply circuit section 16 power supply section switch 17 actuator drive section 17a drive circuit 17b second microcomputer 18 power supply detection section 19 power supply synchronization detection section 20 detection section switch 30 interface control section 30a first microcomputer 31 display unit 32 operation unit 32a operation switch 41 wiring (signal wiring)
42 wiring (power wiring)
43 wiring (control wiring)
44 wiring (communication wiring)
45 wiring (synchronous signal wiring)
50 dedicated hardware 51 processor 52 memory 100 home appliance 101 power plug 141 first resistance (third resistance)
142 diode 143 photo coupler 144 second resistor C1 first smoothing capacitor C2 second smoothing capacitor

Claims (8)

A power supply circuit unit that receives AC power and generates an internal power supply;
An interface control unit connected to the operation unit, operated by receiving the internal power supply, and giving an operation command to the actuator drive unit based on an operation received by the operation unit;
A power supply detection unit that detects whether or not the AC power is input to the power supply circuit unit,
Equipped with
When it is detected that the AC power is not input by the power supply detection unit, the interface control unit is caused to execute a predetermined stop process even if the internal power is supplied from the power supply circuit unit,
A signal wiring for directly connecting the power supply detection unit and the interface control unit without sandwiching another circuit, and transmitting a signal indicating that the AC power is not input to the interface control unit,
Further preparation,
An actuator driven by the actuator drive unit,
A power supply unit switch interposed between the actuator drive unit and the power supply circuit unit and transmitting the internal power generated by the power supply circuit unit to the actuator drive unit by being turned on,
Equipped with
While the home appliance is powered on and the standby mode for stopping the actuator is being executed, the power supply unit switch is turned off,
A power plug connected to an AC power supply for supplying the AC power;
A power supply synchronization detection unit that detects the zero-cross of the AC power,
A detector switch for turning on/off an electrical connection between the power plug and the power synchronization detector,
Equipped with
A home electric device that turns off the detection unit switch during execution of the standby mode. A power supply circuit unit that receives AC power and generates an internal power supply;
An interface control unit connected to the operation unit, operated by receiving the internal power supply, and giving an operation command to the actuator drive unit based on an operation received by the operation unit;
A power supply detection unit that detects whether or not the AC power is input to the power supply circuit unit,
Equipped with
When it is detected that the AC power is not input by the power supply detection unit, the interface control unit is caused to execute a predetermined stop process even if the internal power is supplied from the power supply circuit unit,
A signal wiring for directly connecting the power supply detection unit and the interface control unit without sandwiching another circuit, and transmitting a signal indicating that the AC power is not input to the interface control unit,
Further preparation,
An actuator driven by the actuator drive unit,
A power supply unit switch interposed between the actuator drive unit and the power supply circuit unit and transmitting the internal power generated by the power supply circuit unit to the actuator drive unit by being turned on,
Equipped with
While the home appliance is powered on and the standby mode for stopping the actuator is being executed, the power supply unit switch is turned off,
The household electrical appliance is a portable device including a housing that houses the power supply circuit unit, the interface control unit, the power supply detection unit, the actuator, and the power supply unit switch,
A power plug connected to an AC power supply for supplying the AC power;
A power supply synchronization detection unit that detects the zero-cross of the AC power,
A detector switch for turning on/off an electrical connection between the power plug and the power synchronization detector,
Equipped with
A home electric device that turns off the detection unit switch during execution of the standby mode. Further comprising a power supply synchronization detection unit for detecting the zero cross of the AC power,
The power source detection unit,
A first resistor that receives the AC power at one end,
A first diode whose anode is connected to the other end of the first resistor;
A first photocoupler for transmitting a first current signal flowing from the cathode of the first diode;
A second resistor that receives a control power source at one end and is connected to the first photocoupler at the other end,
Equipped with
The first current signal is output from between the other end and the first photocoupler,
The power supply synchronization detection unit,
A third resistor that receives the AC power at one end,
A second diode whose anode is connected to the other end of the third resistor,
A second photocoupler for transmitting a second current signal flowing from the cathode of the second diode,
A fourth resistor having a control power supply at one end and the other end connected to the second photocoupler,
Equipped with
The second current signal is output from between the other end and the second photocoupler,
The home electric appliance according to claim 1, wherein the first resistor has a resistance value higher than that of the third resistor. The home electric appliance according to claim 1, wherein the stop process includes an operation prohibition process that prevents the interface control unit from accepting an operation of the operation unit. The interface control unit includes a display unit for providing an image to a user,
The stop process is any one of a display stop process of the display unit, a display process of a predetermined operation stop image on the display unit, and a display process of a predetermined plug pull-out occurrence warning screen on the display unit. The home electric appliance according to claim 1 or 2, which includes one process. The home electric appliance according to claim 1, wherein the stop processing includes a turn-off processing for turning off the device power lamp when the interface control unit includes a device power lamp. Communication means for transmitting the presence/absence of an abnormality between the actuator drive section and the interface control section, and an informing means for informing an alarm are provided,
The home electric appliance according to claim 1, wherein the stop processing includes alarm stop processing that does not cause the notification unit to notify an abnormal alarm indicating that the operation received by the operation unit is not realized by the actuator drive unit. Further comprising a power supply unit switch interposed between the actuator drive unit and the power supply circuit unit and transmitting the internal power generated by the power supply circuit unit to the actuator drive unit by being turned on,
The home electric appliance according to claim 1, wherein when the power supply unit switch is turned on from off, the power supply unit switch is kept on until a predetermined time elapses.

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