JP2532528B2 - Hair dryer automatic voltage switching device - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an automatic voltage switching device for a hair dryer that automatically switches a circuit in accordance with a supplied AC power supply voltage.

(Prior art) The AC power supply voltage is different in each country, such as 120V or 240V, and when traveling abroad, a hair dryer according to the AC power supply voltage specifications of each country is required. For this reason, a hair dryer is known in which a changeover switch is attached to the hair dryer body, and this switch is changed over in accordance with the AC power supply voltage specification (for example, Jikken Sho 60-20).
(See Japanese Patent No. 323).

However, in this type of conventional device, since the power supply voltage supplied in advance is checked and the changeover switch is operated to switch to the heater according to the power supply voltage, the hair dryer body is connected to the outlet. It is necessary to check the supplied power voltage before connecting, and it is troublesome to handle, and if you forget the operation or make an incorrect switch, the heater will be burnt out or become overheated abnormally. There was fear.

As a solution to the above, a hair dryer has been proposed in which the supplied power voltage is detected by the electric circuit of the hair dryer body and the heater is automatically switched to a heater according to the power voltage. (See JP 62-58503).

However, the hair dryer that has applied the above solution has the first thyristor and the relay connected in series,
When the power supply voltage is 200V (240V), activate the relay to
The heater configuration is for 0V, and when the power is off, 100V (1
Heater configuration for 20V). Therefore, if the power is turned on when the power supply voltage is 200 V, the heater configuration for 100 V will be set to 20 V until the power supply voltage is detected and the relay operates.
A power supply voltage of 0 V is directly applied, and a current that is twice the steady state (100 V) flows to the contacts of the heater and relay, and a voltage that is twice the steady state (100 V) is also applied to the motor, and each electric component of the hair dryer. However, there was a problem that the reliability of the device deteriorated and the failure rate increased.

(Object of the Invention) The present invention solves the above problems, and automatically switches the heater circuit in accordance with the supplied AC power supply voltage, and provides a heater configuration for 200 V when the power is off. By doing so, it is an object of the present invention to provide a highly reliable automatic voltage switching device for a hair dryer in which each electric component has few failures.

(Structure of the Invention) The present invention relates to a heater circuit having a first heater and a second heater, one ends of which are connected to different poles of an AC power source, a motor connected to the heater circuit, and a rotational drive by the motor. And a fan and an automatic voltage switching circuit for switching the connection between the first heater and the second heater in parallel or in series in accordance with the supplied AC voltage voltage. The automatic voltage switching circuit includes a first thyristor, a constant voltage element for conducting or disconnecting the first thyristor according to the supplied AC power supply voltage, and a first thyristor.
A first and a second switching element that conducts or cuts off according to an ON-OFF operation, a relay that operates by the first switching element, and a second thyristor that operates by the second switching element, A second thyristor is connected between one end of the first heater and the other end of the second heater, and the movable contact of the relay is connected to the first thyristor.
Is connected to the other end of the heater, one fixed contact is connected to the other end of the second heater, and the other fixed contact is connected to one end of the second heater.

With the above configuration, when the power supply voltage being supplied is 100 V, the constant voltage element does not conduct and the first thyristor turns off.
The first and second switching elements are turned on, the second thyristor is turned on, the relay is operated, the possible contact is connected to one pole of the power supply, and the first and second heaters are AC. Connected in parallel to the power supply. When the power supply voltage being supplied is 200 V, the constant voltage element conducts, the first thyristor turns on, the first and second switching elements turn off, and the second thyristor turns off.
In addition, the relay does not operate and the movable contact remains connected to the first heater, and the first and second heaters are connected in series to the AC power supply.

(Embodiment) FIG. 1 shows a circuit structure of a hair dryer according to an embodiment of the present invention, and FIG. 2 shows a sectional structure of the hair dryer.

In FIG. 1, 1a and 1b are terminals for supplying AC power supply voltage,
2 is a power switch, 3 is a thermo switch that opens and closes according to the temperature of the hot air of the hair dryer, and 4 is one end connected to different poles of the AC power supply according to the AC power supply voltage supplied from the supply terminals 1a and 1b. It is an automatic voltage switching circuit that switches each of the first heater 5a and the second heater 5b to parallel connection or series connection. This circuit will be described in detail below.

Resistor 10 and diode connected to the above supply terminal 1b
Reference numeral 11 is for half-wave rectifying the AC power supply voltage supplied from the terminal 1b via the power switch 2 and the thermoswitch 3 and converting it into a DC power supply voltage. Further, the voltage dividing resistors 12 and 13 connected in series between the terminal 1a and the diode 11 divide the above DC power supply voltage, and this divided voltage is applied to the series circuit of the constant voltage diode (constant voltage element) 14 and the resistor 15. Is applied. When the divided voltage becomes equal to or higher than a predetermined voltage, the constant voltage diode 14 becomes conductive, and a voltage is generated in the resistor 15 due to the conduction, and the voltage generated in the resistor 15 is the first thyristor (unidirectional three-terminal thyristor). ) 16 gates applied to the first
The thyristor 16 is configured to conduct.

On the other hand, for this first thyristor 16, a resistor 17 and a resistor
18 are connected in series, and further the first thyristor 16
And resistor 18 to capacitor 19 and constant voltage diode
20 are connected in parallel. This capacitor 19 smoothes the half-wave rectified DC power supply voltage, and the first thyristor
Keep the conduction current at the time of conduction of 16 always above the conduction holding current,
This ensures that the conduction of the first thyristor 16 is maintained. The constant voltage diode 20 is for operating the automatic voltage switching circuit 4 at a constant voltage.

The base of the first transistor (switching element) 22 and one end of the resistor 23 are connected to the anode terminal of the first thyristor 16 via the resistor 21.
A drive coil 25a of a relay 25 is connected to the collector of the first transistor 22. This first transistor 22 becomes conductive when a voltage is applied to its base,
Due to this conduction, the drive coil 25a is connected to the DC power supply voltage via the resistor 24 and driven. Also this drive coil
A smoothing capacitor 26 and a constant voltage diode 27 are connected in parallel to 25a, and the voltage applied to the drive coil 25a is smoothed by the smoothing capacitor 26 and the constant voltage diode 27.

Further, the base of the second transistor (switching element) 32 and one end of the resistor 33 are connected to the anode terminal of the first thyristor 16 via the delay circuit 30 including the resistor 28 and the capacitor 29 and the resistor 31. And
Resistors 34 and 35 are connected in series to the collector of the second transistor 32. The delay circuit 30 delays the start of conduction of the second transistor 32 from the start of conduction of the first transistor 22.

The gate of the second thyristor (bidirectional three-terminal thyristor) 36 is connected to the connection point of the resistors 34 and 35, and when the second transistor 32 becomes conductive, the terminal T ₁ of the second thyristor 36, There is conduction between T ₂ . That is, a voltage is applied to the connection point of the resistors 34 and 35, that is, the gate of the second thyristor 36 by the conduction of the second transistor 32, and the terminals T ₁ and T _{2 of} the second thyristor 36 are electrically connected.

Contact of relay 25 to terminal T ₂ of the second thyristor 36
25b normally closed contact (fixed contact) NC and second heater 5b
The other end is connected, and when the second thyristor 36 becomes conductive, an AC power supply voltage is applied to both ends of the second heater 5b. Further, the contact 25b has a normally open contact (fixed contact) NO and a movable contact C in addition to the normally closed contact NC, and the movable contact C is a normally closed contact NC or a movable contact C based on the drive of the drive coil 25a. It can be switched to the normally open contact NO. The other end of the first heater 5a is connected to the movable contact C, the switching of the contact 25b, and the second thyristor 36.
The first heater 5a and the second heater 5b are switched to parallel connection or series connection by the operation (conduction or interruption).

Further, a rectifying bridge is provided in a part of the first heater 5a.
Motor 39 is connected via 37 and resistor 38,
This motor 39 has an AC power supply voltage of 100 V or
It is connected to the first heater 5a so that the same voltage is applied to the motor 39 regardless of which of 200V is switched. The capacitor 40 smoothes the waveform that is full-wave rectified by the rectifying bridge 37.

The rectifying bridge 37, the resistor 38, the motor 39 and the capacitor 40 may be connected to a part of the second heater 5b.

Next, the structure of the hair dryer of this embodiment will be described with reference to FIG. In the figure, the dryer main body housing has a hot air discharge port 6 and an air suction port 7. Inside, a fan 8 driven to rotate by a blower motor 39 and a first heater 5a for obtaining warm air are provided. , A heater circuit including a second heater 5b, an automatic voltage switching circuit 4, and the like.

Next, the operation of switching the heater circuit according to the AC power supply voltage in the above configuration will be described.

First, a case where 100 V is supplied to the supply terminal 1 as an AC power supply voltage will be described. When the power switch 2 is turned on, the automatic voltage switching circuit 4 is connected via the thermo switch 3.
100V is supplied, and accordingly, a divided voltage is generated at the connection point of the voltage dividing resistors 12 and 13. However, since this divided voltage value is lower than the Zener voltage value of the constant voltage diode 14,
The constant voltage diode 14 does not conduct. Therefore, no voltage is applied to the gate of the first thyristor 16, so that the first thyristor 16 does not conduct. As a result, a current flows to the base of the first transistor 22 via the resistors 17, 18, and 21,
The first transistor 22 is conducting. This conduction drives the drive coil 25a of the relay 25, and the contact 25b is a normally closed contact.
The NC is switched to the normally open contact NO, and the AC power supply voltage 100V is applied to both ends of the first heater 5a.

On the other hand, a current also flows through the delay circuit 30 via the resistors 17 and 18, and a voltage is gradually applied to the base of the second transistor 32 by the capacitor 29 of the delay circuit 30, and eventually the second transistor 32 is turned on. When the base voltage of V reaches a predetermined voltage, the second transistor 32 becomes conductive. Due to this conduction, a voltage is applied to the gate of the second thyristor 36 via the resistors 34 and 35, conduction is established between the terminals T ₁ and T ₂ of the second thyristor 36, and both ends of the second heater 5b are connected. AC power supply voltage of 100V is applied.

Note that a constant voltage diode (not shown) may be inserted in series with the resistor 31 in order to set the conducting voltage of the second transistor 32 with certainty.

The time constant of the delay circuit 30 is the contact 25 of the relay 25.
After the switching operation of b is completed, the terminal T of the second thyristor 36
Set so that there is continuity between ₁ and T ₂ . This is because when the conduction between the terminals T ₁ and T ₂ of the second thyristor 36 is faster than the switching operation of the contact 25b of the relay 25, the second contact is made between the normally closed contact NC and the normally open contact NO of the contact 25b. When the AC power supply voltage is applied through the thyristor 36 and the movable contact C operates at this time, the contact N
An arc is generated between C and NO, and this arc may short-circuit the AC power supply. Therefore, the conduction of the second thyristor 36 is delayed as compared with the switching operation of the contact 25b to prevent the AC power supply from being short-circuited.

By the above operation, the first heater 5a and the second heater 5b are connected in parallel, and the AC power supply voltage 100V is applied to the heaters 5a and 5b via the power switch 2 and the thermoswitch 3.

Next, a case where 200 V is supplied to the supply terminal 1 as an AC power supply voltage will be described. When the power switch 2 is turned on, the automatic voltage switching circuit 4 is connected via the thermo switch 3.
200V is supplied, and a divided voltage is generated at the connection point of the voltage dividing resistors 12 and 13. Since this divided voltage value is higher than the Zener voltage value of the constant voltage diode 14, the constant voltage diode 14 becomes conductive. As a result, a voltage is applied to the gate of the first thyristor 16 and the first thyristor 16 becomes conductive. As a result, since no current flows through the resistor 21, no current also flows through the base of the first transistor 22. Therefore, the first transistor 22 is cut off. Due to this interruption, the drive coil 25a is not driven, so the movable contact C remains fixed to the normally closed contact NC. That is, the other end of the first heater 5a is connected to the second heater 5 through the movable contact C and the normally closed contact NC.
It remains connected to the other end of 5b.

In addition, the conduction of the first thyristor 16 causes the delay circuit 30
Since no current flows through the second transistor 32, no current flows through the base of the second transistor 32. Therefore, the second transistor
32 is cut off, and due to this cutoff, no voltage is applied to the gate of the second thyristor 36, so the second thyristor 36
Also remains blocked.

Therefore, the first heater 5a and the second heater 5b are connected in series, and the AC power supply voltage 200V is applied to the first heater 5a and the second heater 5b connected in series via the power switch 2 and the thermoswitch 3. Is applied.

Thus, the first heater 5a and the second heater 5b are automatically switched to the parallel connection or the series connection according to the supplied AC power supply voltage, which saves the trouble of checking the AC power supply voltage before use. Further, when the AC power supply is OFF, the first heater 5a and the second heater 5b are connected in series (heater configuration for 200V). Therefore, even if the power is turned on when the power supply voltage is 200V, the Since 200V is not directly applied to the first heater 5a and the second heater 5b, the contact 25b of the first heater 5a and the second heater 5b, and the relay 25 connecting the two heaters 5a and 5b. There is no overcurrent flowing in. Also, by delaying the conduction start timing of the second thyristor 36 from the start of the switching operation of the relay 25 by the delay circuit 30, the AC power supply voltage may be directly applied to the contact 25b of the relay 25 during the switching operation. Absent.

(Effects of the Invention) As described above, according to the present invention, the connection of the heater circuit is automatically switched in parallel or in series according to the supplied AC power supply voltage, so that a failure such as burnout of the heater due to a malfunction is prevented. be able to. Furthermore, since the heater circuit is connected in series before power is turned on, the divided AC power voltage is applied to each heater immediately after power is turned on.
The current that flows to the heater immediately after the power is turned on is half that in the case where the heater configurations before the power is turned on are connected in parallel.
Also, since the motor is connected in parallel to one of the heaters,
The voltage applied to the motor immediately after the power is turned on is half that in the case where the heater configurations before the power is turned on are connected in parallel. Therefore, even if the heater, the contact of the relay connected in series to the heater, and the motor have a low rating, it is possible to prevent the reliability from being lowered due to a failure. By delaying the timing of conduction of the second thyristor with respect to the switching operation of the relay by the delay circuit, the AC power supply voltage is not directly applied to the contact of the relay during the switching operation of the relay, and the relay contact It is possible to prevent an AC power supply short circuit accident due to an arc.

[Brief description of drawings]

FIG. 1 is a circuit diagram of an automatic voltage switching circuit according to an embodiment of the present invention, and FIG. 2 is a sectional view of a hair dryer of this embodiment. 4 ... Automatic voltage switching circuit, 5a ... First heater, 5b ...
Second heater, 6 ... Blower motor, 7 ... Fan, 14
...... Constant voltage diode (constant voltage element), 16 …… First thyristor, 22 …… First transistor (switching element), 25 …… Relay, 25a …… Drive coil, 25b …… Contact, 32 …… Second transistor (switching element),
36 …… Second thyristor.

Claims (2)

(57) [Claims] 1. A heater circuit having a first heater and a second heater each having one end connected to different poles of an AC power source, a motor connected to the heater circuit, and a fan rotationally driven by the motor. An automatic voltage switching device for a hair dryer, comprising: an automatic voltage switching circuit that switches the connection between the first heater and the second heater in parallel or in series in accordance with the supplied AC power supply voltage. Is a first thyristor, a constant voltage element for conducting or interrupting the first thyristor according to the supplied AC power supply voltage, and the first thyristor.
A first and a second switching element that conducts or cuts off according to an ON-OFF operation, a relay that operates by the first switching element, and a second thyristor that operates by the second switching element, A second thyristor is connected between one end of the first heater and the other end of the second heater, and the movable contact of the relay is connected to the first thyristor.
Of the heater, the one fixed contact is connected to the other end of the second heater, and the other fixed contact is connected to one end of the second heater. Switching device. 2. A delay circuit is provided at the input stage of the second switching element to delay the conduction time of the second thyristor from the completion of the operation of the relay. Automatic voltage switching device for the hair dryer described.