JP6861748B2 - Hand dryer - Google Patents

Description

The present invention relates to a circuit for suppressing power consumption during standby of a hand dryer that dries wet hands.

Conventionally, a hand dryer that dries hands by applying warm air or high-speed air to wet hands has been known. For example, Japanese Patent Application Laid-Open No. 7-79881 describes a hand dryer equipped with a fan, a DC brushless motor for driving the fan, and a controller. The DC brushless motor is a synchronous motor having a permanent magnet type rotor and a transistor. It has a commutator and a control IC. The control IC and the controller are connected to a low voltage DC power supply for control, a control signal is output from the controller to the control IC, and a transistor commutator operates under the control of the control IC. A hand dryer is disclosed in which a DC brushless motor is operated to blow warm air from an air outlet to dry the hands.
Further, Japanese Patent Application Laid-Open No. 2-83487 includes a fan motor driven by AC100V, a control circuit for driving the fan motor, a power supply unit, and a step-down circuit for supplying drive power to the control circuit. In this hand dryer, the voltage of AC100V is stepped down by the transformer of the power supply section, and the DC drive power supply that is stepped down and rectified by the step-down circuit is connected to the control circuit, and the triac of the power supply circuit is performed based on the signal of the control circuit. A hand dryer that operates and supplies AC100V to a fan motor to drive the fan motor and blow out warm air from an outlet is disclosed.
Further, in Japanese Patent Application Laid-Open No. 2001-169552, as a power supply device for an electronic device that reduces power consumption during standby, a main power supply unit to which an AC power supply is input and a capacitor having a predetermined capacity for the AC power supply unit are sequentially provided. A voltage dividing means in which one capacitor, a second capacitor, and a third capacitor are connected in series, and a rectifying means for rectifying the terminal voltage of the second capacitor constituting the voltage dividing means by a rectifying diode connected in a bridge type. Switching between the standby power supply unit to which the DC voltage rectified by the rectifying means is supplied and the AC power supply supplied to the main power supply unit by the control signal output from the control circuit driven by the standby power supply unit. A power supply device comprising means is disclosed.

Japanese Unexamined Patent Publication No. 7-79881 (paragraphs "0006" to "0007", FIGS. 1 and 2) Japanese Unexamined Patent Publication No. 2-83487 (lower page 2 to upper 3 pages, FIG. 3) JP 2001-169552 (Claim 1, Claim 4, FIG. 1)

However, since the hand dryer disclosed in Japanese Patent Application Laid-Open No. 7-79881 uses a DC motor driven by a DC power supply, energization is applied to each phase winding of the stator of the DC motor (synchronous motor). A control IC that controls the transistor rectifier and the transistor rectifier to be switched is required, and the control IC is always energized so that the DC motor can be driven and air can be blown out from the air outlet as soon as the user puts his hand in it. Since it is in the standby state, there is a problem that power is always consumed even when the DC motor is stopped.
Further, since the hand dryer disclosed in Japanese Patent Application Laid-Open No. 2-83487 uses an AC motor driven by AC100V, a control IC for switching the energization of each phase winding of the stator is unnecessary. However, there is a problem that the transformer always consumes a large amount of power because the power supply circuit uses a transformer to step down the voltage.

Further, even if an attempt is made to apply the power supply device technology for an electronic device that reduces power consumption during standby, which is disclosed in Japanese Patent Application Laid-Open No. 2001-169552, to a hand dryer, wiring of the power supply wiring of the facility where the hand dryer is installed. Since the situation differs depending on the installation facility, the voltage drop in the power supply wiring is large for equipment with high input power (power consumption) and large current consumption such as a hand dryer, and the difference in the power supply wiring status of the facility is significantly different. Therefore, the voltage input to the voltage dividing capacitor varies depending on the installation location. In addition, the voltage division ratio also varies due to the capacitance variation of the voltage dividing capacitor itself. As a result, there is a problem that the voltage input to the voltage regulator of the standby power supply unit varies and is not stable.

In addition, in the current situation where commercial AC power supplies in countries around the world differ greatly from country to country in the range of AC85V to AC265V, the voltage generated by the input voltage changes significantly in the step-down method using capacitor division voltage. Therefore, there is also a problem that a power supply device in which the capacitor voltage dividing ratio is set exclusively for each country is required.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a hand dryer having low standby power consumption.

The hand dryer according to the present invention operates a blower having a motor that blows air to the hand insertion portion, a hand detection sensor that detects the hand of the hand insertion portion, and the motor according to the detection of the hand detection sensor. A hand dryer equipped with a control circuit for controlling, wherein the control circuit is a rectifying smoothing circuit that converts an AC power supply input from the outside into a high-voltage DC power supply, and a high-voltage DC power supply converted by the rectifying smoothing circuit. The low-voltage DC power supply is provided with a switching regulator that converts the voltage into a first low-voltage DC power supply and a voltage stabilizing means for stabilizing the voltage of the first low-voltage DC power supply, and the voltage is stabilized by the voltage stabilizing means. It is used as a power source for the detection sensor.

The hand dryer according to the present invention can reduce the power consumption during standby.

It is a perspective view which shows the appearance of the hand dryer which concerns on Embodiment 1 of this invention. It is a side sectional view of the hand dryer which concerns on Embodiment 1 of this invention. It is a perspective view which shows the appearance in the state which the cover 16 of the hand dryer which concerns on Embodiment 1 of this invention is opened. It is a circuit block configuration of the hand dryer according to the first embodiment of the present invention. It is explanatory drawing explaining the infrared light emission timing of the hand detection sensor 106 of the hand dryer which concerns on Embodiment 1 of this invention. It is a circuit block configuration of the hand dryer according to the second embodiment of the present invention. It is a circuit block configuration of the hand dryer according to the third embodiment of the present invention.

Embodiment 1.
FIG. 1 is a perspective view showing the appearance of the hand dryer according to the first embodiment of the present invention, FIG. 2 is a side sectional view, and FIG. 3 is a perspective view showing the appearance of the hand dryer with the cover 16 opened. .. As shown in FIGS. 1 and 2, the casing 1 forming the outer shell of the hand dryer has a hand insertion port 2 on the front surface, and has a hand insertion portion 3 as a processing space following the hand insertion port 2. Can be inserted and removed. The manual insertion portion 3 is formed in the lower part of the front surface of the casing 1 as an open sink-shaped recess in which the front surface and both side surfaces are open, and the water receiving portion 4 forming the lower portion and the back side are curved at the edge portions thereof. A barrier structure 5 is provided by the rising edge of the water to prevent water from splashing to the side or the front. The bottom of the water receiving portion 4 is inclined downward toward the front, and a drain port 6 is provided at the lower end of the inclination. A drain container 7 for storing water dripping from the drain port 6 is provided below the water receiving portion 4 so as to be freely inserted and removed. The inner surface of the hand-inserted portion 3 is impregnated with a water-repellent coating such as silicon or fluorine, a hydrophilic coating such as titanium oxide, or an antibacterial agent to reduce the adhesion of dirt to the inner surface. , It is designed to reduce the growth of bacteria. A nozzle 12 that blows high-speed air downward toward the hand insertion portion 3 is provided on the upper portion of the hand insertion portion 3.

An AC motor (AC motor) 9a, which is a commutator motor, is contained in a box-shaped space composed of a casing 1 above the hand insertion portion 3 and a base 8 forming the outer shell of the hand dryer on the back side. A high-pressure air flow generator 9 which is a blower provided with a turbo fan 9b fixed to a rotating shaft of an AC motor 9a and rotating, and an intake port 18 provided on the intake side of the high-pressure air flow generator 9 and the side surface of the casing 1. An intake passage 11 that communicates with the above, and an exhaust passage 13 that communicates the exhaust side of the high-pressure airflow generator 9 with the nozzle 12 are provided. A heater 111 is provided in the middle of the exhaust passage 13 in the vicinity of the upstream side of the nozzle 12 to heat the air sent from the high-pressure air flow generator 9 to warm the air. A circuit board 114b provided with a hand detection sensor 106 and an illumination LED 128 is provided in the casing 1 on the back side of the nozzle 12. The light emitting direction and the light receiving direction of the hand detection sensor 106 and the light emitting direction of the illumination LED 128 are all provided toward the hand insertion portion 3, and visible light or visible light provided in a part of the caging 1 on the upper surface of the hand insertion portion 3 is provided. Through the translucent window 1a that transmits infrared rays, the hand detection sensor 106 detects the presence or absence of a hand in the hand insertion portion 3, and the illumination LED 128 as a lighting means illuminates and brightens the hand insertion portion 3.

Further, in the vicinity of the front surface of the casing 1, inside the casing 1, there are a control circuit 150, an energizing LED 129 as an energizing display means for indicating that the power is on and energizing in the standby state, and an illumination LED 128. A circuit board 114a provided with a changeover switch 130 as a changeover means capable of independently switching ON / OFF of the lighting of the energizing LED 129 is provided. The light emitting direction of the energization display LED 129 and the operation surface of the changeover switch 130 are provided facing the front side. The changeover switch 130 is, for example, a DIP switch.

Further, as shown in FIG. 3, openings 1b and 1c are partially provided in the vicinity of the energizing LED 129 and the changeover switch 130 on the front surface of the casing 1 so as to face the openings 1b and 1c, respectively. Since the energizing LED 129 and the changeover switch 130 are provided, the light of the energization LED 129 can be visually recognized from the outside of the casing 1, and the changeover switch 130 can be operated from the outside of the casing 1. By switching the changeover switch 130, the lighting LED 128 and the energizing LED 129 can be turned on / off independently, and the power is turned on by selecting the lighting LED 128 on the changeover switch 130. And the lighting LED 128 is turned on, and if the changeover switch 130 is selected to turn off the lighting LED 128, the lighting LED 128 is not turned on even when the power is turned on, and remains turned off. Similarly, if the changeover switch 130 selects lighting of the energizing LED 129, the energizing LED 129 lights up when the power is turned on, and if the changeover switch 130 selects the energizing LED 129 to turn off, the power is turned on even if the power is turned on. LED 129 does not turn on and remains off.

Further, on the outside of the front surface of the casing 1, a power switch 21 as a main power switch for switching ON / OFF of the connection between the external commercial AC power supply and the control circuit 150 is provided. Further, the upper part of the hand insertion portion 3 covers the front side of the casing 1 on the outside of the front surface of the casing 1 to form the outer shell of the hand dryer, and the left end is rotatably supported by the casing 1 of the hand dryer. A cover 16 that can be opened and closed and can be attached to and detached from the casing 1 is attached to the front side. A translucent window 16a is provided on the cover 16 so that the light of the energizing LED 129 can be visually recognized from the outside of the cover 16.

Next, the operation during use for drying the hands will be described. When the cover 16 is opened and the power switch 21 is turned on (ON), the external commercial AC power supply is energized to the control circuit 150, and the cover 16 is closed to be in a usable state (hereinafter referred to as a standby state) in which the hand can be dried. .. When the AC power supply is energized in the control circuit 150, the illumination LED 128 lights up when the switching of the illumination LED 128 of the changeover switch 130 is ON, and when the changeover of the energization LED 129 of the changeover switch 130 is ON. The energizing LED 129 lights up. Then, when the user inserts a wet hand from the hand insertion port 2 into the hand insertion portion 3 to the vicinity of the wrist, the hand insertion is detected by the hand detection sensor 106, and the high-pressure air flow generator 9 is activated by the control circuit 150. To do.

When the high-pressure air flow generator 9 is activated, the air outside the hand dryer is sucked in from the intake ports 18 provided on both side surfaces of the casing 1. The air sucked from the intake port 18 passes through the intake air passage 11, passes above the high-pressure air flow generator 9, heads toward the rear side, moves downward, and is sucked from the suction side of the high-pressure air flow generator 9. .. The high-pressure air flow generator 9 converts the air sucked from the intake side into high-pressure air from the exhaust side and exhausts it, and the exhausted high-pressure air passes through the exhaust air passage 13 and becomes a high-speed air flow having high kinetic energy from the nozzle 12. It is converted and blown downward into the hand insertion portion 3. The high-speed air flow blown out from the nozzle 12 hits the wet hand inserted in the hand insertion portion 3, and the moisture adhering to the hand can be peeled off from the surface of the hand and blown off to dry the hand. Further, by moving the hand in the hand insertion portion 3, all the water droplets adhering to the entire hand are eliminated, and the hand is dried. When the heater switch (not shown) provided in the casing 1 is turned on, the heater 111 is energized and the high-pressure air passing through the exhaust air passage 13 is heated, so that warm air is emitted from the nozzle 12. It is blown out and can be used without a feeling of cold wind even in winter.

When the hand is pulled out from the hand insertion portion 3 after the hand drying process is completed, the hand detection sensor 106 detects that the hand has been pulled out, and the high-pressure air flow generator 9 stops. The water droplets blown off from the hand flow down toward the drain port 6 at the water receiving portion 4 having a forward tilting structure, and are housed in the drain container 7 from the drain port 6.

Next, the details of the control circuit 150 will be described. FIG. 4 is a circuit block configuration of the hand dryer according to the first embodiment of the present invention. In the following description, the case where the external commercial AC power supply 100 is AC230V will be described, but since any commercial AC power supply used in the world is sufficient, the external commercial AC power supply 100 is, for example, AC100V, AC200V, etc. The voltage may be such as, and is not particularly limited to AC230V.

As shown in FIG. 4, the control circuit 150 connected to the external AC230V commercial AC power supply 100 is connected to the inrush protection circuit 101 that suppresses the rush current when the power is turned on and the output side of the inrush protection circuit 101. A rectifying smoothing circuit 102 that converts an AC 230V AC power supply input from the outside into a DC 322V high-voltage DC power supply, and a DC 322V high-voltage DC power supply that is connected to the rectifying smoothing circuit 102 and converted by the rectifying smoothing circuit 102 into a low-voltage DC power supply. Insulated switching regulator 103, a motor drive circuit 110 that uses a triac to drive the AC motor 9a of the high-voltage airflow generator 9, a heater drive circuit 109 that controls energization of the heater 111, and hand detection. It includes a microcomputer 107 that outputs an operation or stop command to the motor drive circuit 110 and the heater drive circuit 109 in response to a signal from the sensor 106. The AC motor 9a of the high-pressure air flow generator 9 is a motor that operates with a single-phase AC power supply, and is a commutator motor capable of high-speed rotation. When high-speed rotation is not required, an induction motor or the like that operates with a single-phase AC power supply may be used, or an induction motor that is driven by a three-phase AC power supply may be used.

The low-voltage DC power supply converted by the switching regulator 103 is used as a power source for the microcomputer 107, the hand detection sensor 106, the heater drive circuit 109, and the motor drive circuit 110. When the presence of the hand is detected by the hand detection sensor 106, the microcomputer 107 outputs an operation command to the motor drive circuit 110, operates the AC motor 9a of the high-pressure air flow generator 9 connected to the motor drive circuit 110, and operates the hand. When the presence of the hand is no longer detected by the detection sensor 106, the microcomputer 107 outputs a stop command to the motor drive circuit 110 to stop the AC motor 9a.

This will be described in more detail. The power supply circuit is an isolated flyback converter. A current fuse (not shown) for protecting the control circuit 150 is generally provided between the commercial AC power supply 100 outside the AC230V and the inrush protection circuit 101. The rectifying and smoothing circuit 102 is composed of a diode bridge (not shown) and an electrolytic capacitor (not shown). The AC 230V AC power supply is full-wave rectified by the diode bridge (not shown) and converted to direct current, and then electrolytic. It is smoothed with a capacitor (not shown) to generate a high-voltage DC power supply of DC322V. Due to the capacitor input type power supply circuit configuration, a rush current (charging current) flows through the electrolytic capacitor (not shown) when the power is turned on, and between the diode bridge (not shown) or the inrush protection circuit 101 and the commercial AC power supply 100. Since there is a risk of damaging the provided current fuse (not shown), the inrush protection turn 101 is provided for the purpose of suppressing the rush current.

The switching regulator 103 is composed of a switching power supply IC (not shown) and a switching transformer (not shown), and is an isolated type. The DC322V high-voltage DC power supply converted and generated by the rectifying and smoothing circuit 102 is input to the switching regulator 103. In the switching regulator 103, the input DC322V high-voltage DC power supply is switched at high speed of 100 kHz by a power MOSFET (field effect transistor) (not shown) built in the switching power supply IC (not shown). In the switching transformer (not shown), the input and output are isolated, and the power MOSFET built in the switching power supply IC (not shown) is turned on to apply magnetic energy to the primary coil of the switching transformer (not shown). The power MOSFET built into the switching power supply IC (not shown) is turned off and the energy is output to the secondary side of the switching transformer. The switching transformer (not shown) is a two-output type, and a low-voltage DC power supply of DC12V and DC5V is generated on the secondary side so as to be insulated from a high-voltage DC power supply of DC322V. The DC5V generated by stepping down the pressure by the switching regulator 103 is used as a power source for the microcomputer 107, the hand detection sensor 106, and the like, and the DC12V is a phototriac of the motor drive circuit 110 (not shown) and a phototriac of the heater drive circuit 109 (FIG. Used for power supply (not shown). Since DC12V and DC5V generated by the switching regulator 103 are insulated, there is a risk of electric shock even if the water seal function is destroyed by a changeover switch 130 or a heater switch (not shown) that can be switched from the outside of the casing 1. Absent.
If there is no risk of electric shock with a changeover switch 130 or a heater switch (not shown) that can be switched from the outside of the casing 1, the switching regulator 103 may be a non-insulated type in which the primary side and the secondary side are not insulated. The voltage value of the low-voltage DC power supply generated by the switching regulator 103 may be appropriately set according to the characteristics of the microcomputer 107 and the hand detection sensor 106 to be used.

The AC motor 9a is driven by energizing AC230V of the commercial AC power supply 100, and the motor drive circuit 110 is composed of a triac (not shown) and a phototriac (not shown) as main components, and is formed by a hand detection sensor 106. When a hand is detected, a Hi signal is output from the microcomputer 107 to the photo triac (not shown), and when the photo triac (not shown) is turned on, it becomes a trigger signal for the triac (not shown) and becomes a triac (not shown). ) Turns on and AC230V is energized to the AC motor 9a.

Similarly, the heater drive circuit 109 is configured with a triac (not shown) and a phototriac (not shown) as main parts, and a heater switch (not shown) of the heater 111 provided in the casing 1 is turned on. Only in this case, when the hand detection sensor 106 detects a hand, the microcomputer 107 outputs a Hi signal to the photo triac (not shown), and the photo triac (not shown) is turned on to trigger the triac (not shown). It becomes a signal, the triac (not shown) is turned on, and AC230V is energized to the heater 111.

Further, the inrush protection circuit 101 is composed of a fixed resistor (not shown), and aims to suppress a rush current flowing through an electrolytic capacitor (not shown) of the rectifying smoothing circuit 102 when the power is turned on. The inrush protection circuit 101 may be composed of an NTC thermistor. The current value suppressed by the inrush protection circuit 101 is the surge current withstand capability of the diode bridge (not shown) of the rectifying smoothing circuit 102 or the protection of the control circuit 150 provided between the external commercial power supply 100 and the inrush protection circuit 101. It is determined by the rush current withstand of the current fuse (not shown) or the current withstand of the power switch 21 provided externally, and the rush current withstand of these parts is sufficiently high, and it is necessary to suppress the rush current at power-on. If there is no rush protection circuit 101, the inrush protection circuit 101 may be omitted.

Next, the light emission timing of the hand detection sensor 106, the display LED 128, and the energization LED 129 will be described. FIG. 5 is an explanatory diagram illustrating the infrared light emission timing of the hand detection sensor 106 of the hand dryer according to the first embodiment of the present invention. The hand detection sensor 106 is composed of a pair of a light emitting element (not shown) that emits infrared rays and a light receiving element (not shown) that receives infrared rays emitted from the light emitting element, and the light emitting element (not shown) and A light receiving element (not shown) is provided on the circuit board 114b. As shown in FIG. 5, the infrared emission of the light emitting element (not shown) is turned on for 20 ms with 100 ms as one cycle, and turned off for the remaining 80 ms, regardless of the standby state or the operating state of the hand dryer. The hand detection sensor 106 is constantly pulse-driven. Further, since the display LED 128 and the energizing LED 129 are pulse-driven to the extent that a flicker is not felt even when the display LED 128 and the energizing LED 129 are lit, the average current flowing through the lighting LED 128 and the energizing LED 129 is lowered, which leads to a reduction in power consumption.

In the present embodiment, the circuit board 114a and the circuit board 114b are separately provided and connected to each other by a plurality of lead wires. However, the control circuit is divided into three or more lead wires. Alternatively, the lighting LED 128, the energizing LED 129, the hand detection sensor 106, and the changeover switch 130 may be arranged in a single circuit board by changing the arrangement positions.

In order to save power of the hand dryer, which has a longer standby time than the usage time, it goes without saying that the power consumption during the operation of driving the high-pressure air flow generator 9 is reduced, but the power consumption during the standby time is also reduced. That is also very important. In such a hand dryer, according to the above configuration, the high-voltage air flow generator 9 that blows air to the manual insertion portion 3 is configured by the AC motor 9a, and the low-voltage DC power supply is supplied by the rectifying smoothing circuit 102 and the switching regulator 103. Since it is generated, there is no need for an inverter circuit for switching the energization of each phase winding of the stator and a control IC for switching each switching element of the inverter circuit, unlike a DC motor, and the hand detection sensor 106 is used during standby. The control IC is always energized so that the high-voltage airflow generator 9 can be operated as soon as a hand is detected, and power consumption during standby can be suppressed without consuming power. Since it generates a low-voltage DC power supply for the 107, the motor drive circuit 110, and the hand detection sensor 106, it can be used because the power loss at the time of generation can be smaller than that of a conventional transformer to generate a low-voltage power supply. Of course, it is possible to obtain a hand dryer in which the power consumption during standby is reduced as much as possible.

In addition, since an auxiliary power supply circuit consisting of a voltage dividing capacitor and a relay is not required, the voltage drop in the power supply wiring causes the supply voltage to the voltage dividing capacitor to vary depending on the power supply wiring status of the installation facility, resulting in standby power supply. The voltage input to the voltage regulator of the unit does not become unstable, and the voltage balance is lost due to the capacitance variation of the voltage dividing capacitor itself, so that the voltage dividing ratio does not become unstable. In addition, since a triac is used without using a relay, there is no concern about the life of a device such as a hand dryer that frequently repeats a standby state and an operating state due to repeated ON-OFF operations. In addition, there is no increase in board size or cost for voltage dividing capacitors and relays.

Further, since the voltage is stepped down by using the switching regulator 103, the input voltage can be adjusted from AC85V to AC265V by the same control circuit, and it can be widely used for commercial AC power supplies different in countries around the world.

Further, since the lighting LED 128 that illuminates the hand-inserted portion 3 is provided and the switching switch 130 such as a DIP switch that can arbitrarily switch the lighting ON-OFF of the lighting LED 128 from the outside is provided, the installation location is always the same. In the case of an installation environment where the lighting of the manual insertion part 3 is not required in a bright place, the changeover switch 130 can be turned off to always turn off the lighting LED 128 according to the installation environment, and the power consumption, especially the power consumption during standby, can be reduced. It can be reduced.

Similarly, a changeover switch 130 such as a DIP switch which is provided with an energization LED 129 which lights up when energized to indicate an energization state and can arbitrarily switch ON-OFF of the energization LED 129 when energized from the outside. Therefore, when it is desired to reduce the power consumption, particularly the power consumption during standby, the changeover switch 130 can be turned off to always turn off the energizing LED 129, and the power consumption during standby can be particularly reduced. it can.

Further, since the DC12V and DC5V generated by the switching regulator 103 are insulated from the high-voltage DC power supply 322V by using the insulation type switching regulator 103, the changeover switch 130 and the heater switch (switching operation can be performed from the outside of the casing 1). Even if the water seal function is destroyed due to (not shown), there is no risk of electric shock.

Embodiment 2.
FIG. 6 is a circuit block configuration of the hand dryer according to the second embodiment of the present invention. The difference from the first embodiment is that the DC5V power supply used in the microcomputer 107 and the hand detection sensor 106 is configured by the series regulator 104, and other than that, it is the same as or equivalent to the first embodiment and has the same reference numeral. The detailed description will be omitted. In FIG. 6, a general 3-terminal regulator or low saturation regulator IC (LDO: Low Drop Out) is used as the series regulator 104, and the loss due to the series regulator 104 can be further reduced by using the LDO. The switching regulator 103 generates a low-voltage DC power supply of DC12V, inputs the DC12V power supply to the 3-terminal regulator constituting the series regulator 104, and further lowers the voltage with the 3-terminal regulator to generate a low-voltage DC power supply of DC5V. The output voltage generated by the series regulator 104 may be set according to the characteristics of the microcomputer 107 and the hand detection sensor 106 to be used.

According to the above configuration, the same effect as that of the first embodiment can be obtained, and the voltage accuracy of the low-voltage DC power supply can be improved by using the series regulator 104, and the voltage accuracy of the microcomputer 107 and the hand detection sensor 106 can be improved. It is possible to supply a stable low-voltage DC power supply. Further, if a low saturation regulator IC (LDO) is used, the power consumption during standby can be further reduced.

Embodiment 3.
FIG. 7 is a circuit block configuration of the hand dryer according to the third embodiment of the present invention. The difference from the first embodiment is that the power factor improving circuit 120 is added between the rectifying smoothing circuit 102 and the switching regulator 103, and other than that, the configuration is the same as or the same as that of the first embodiment. Reference numerals are given and detailed description thereof will be omitted. In FIG. 7, a power factor improving circuit 120 is provided between the rectifying smoothing circuit 102 and the switching regulator 103. Since the switching regulator 103 is equipped with a capacitor input type rectifying and smoothing circuit, the input current does not become a sine wave, the peak current becomes high, and current harmonics are generated. The generation of harmonics is a factor that increases power supply infrastructure equipment and energy consumption, and reduction of harmonics is important for improving power supply efficiency. What is needed to reduce harmonics is a power factor improvement (PFC: Power Factor Direction) that brings the input current closer to a sine wave. Since the peak of the harmonic current can be lowered, the load on the power plant can be reduced, and a high energy saving effect can be expected. The PFC circuit includes an active system that switches at high speed using a power semiconductor and a passive system that is composed of a capacitor and a reactor, and one of them may be selected according to the cost and size according to the equipment to be used.

According to the above configuration, since the power factor improving circuit is provided in addition to the same effect as that of the first embodiment, it is possible to lower the peak of the harmonic current, and the energy saving effect by reducing the load of the power plant is expected. it can.

1 Casing 1a Translucent window 1b Opening 1c Opening 2 Hand insertion port 3 Hand insertion part 4 Water receiving part 5 Barrier structure 6 Drainage port 7 Drain container 8 Base 9 High-pressure air flow generator (blower)
9a AC motor 9b Turbo fan 11 Intake passage 12 Nozzle 13 Exhaust passage 16 Cover 16a Translucent window 18 Intake port 21 Power switch 100 Commercial AC power supply 101 Rush protection circuit 102 Rectifier smoothing circuit 103 Switching regulator 104 Series regulator 106 Hand detection sensor 107 Microcomputer 109 Heater drive circuit 110 Motor drive circuit 111 Heater 114a Control board 114b Control board 120 Power factor improvement circuit 128 Lighting LED (lighting means)
129 Energizing LED (energizing display means)
130 changeover switch (changeover means)
150 control circuit

Claims (4)

A blower having a motor for blowing air to the hand insertion portion, a hand detection sensor for detecting the hand of the hand insertion portion, and a control circuit for controlling the operation of the motor in response to the detection of the hand detection sensor are provided. It ’s a hand dryer
The control circuit includes a rectifying and smoothing circuit that converts an AC power supply input from the outside into a high-voltage DC power supply.
A switching regulator that converts the high-voltage DC power supply converted by the rectifying and smoothing circuit into the first low-voltage DC power supply,
A voltage stabilizing means for stabilizing the voltage of the first low-voltage DC power supply,
With
A hand dryer characterized in that a low-voltage DC power source whose voltage is stabilized by the voltage stabilizing means is used as a power source for the hand detection sensor. The control circuit includes a microcomputer that outputs a command for operating or stopping the motor according to the detection state of the hand detection sensor.
The hand dryer according to claim 1, wherein a low-voltage DC power source whose voltage is stabilized is used as a power source for the hand detection sensor and the microcomputer. The control circuit includes a motor drive circuit that operates the motor according to a command from the microcomputer.
The hand dryer according to claim 2, wherein the first low-voltage DC power source is used as a power source for the motor drive circuit. The hand dryer according to any one of claims 1 to 3, wherein the motor is an AC motor that operates with an AC power supply.

Images