KR101108928B1 - Heater driving device - Google Patents

Abstract

The present invention relates to a heater driving device for a hair styler, and more particularly, a heater to which a commercial AC power is input; A temperature sensor detecting a heating temperature of the heater; A constant voltage unit converting the input commercial AC power into a 15V DC voltage and outputting the circuit power; A pair of transistors generating and outputting a zero crossing pulse near 0 V of the input of the commercial AC power source, a transistor operated by a zero crossing pulse outputted from the transistor, and a synchronous operation of the switching operation of the transistor. A zero crossing pulse generating unit for supplying the output circuit power to the temperature comparison and control signal output units as pulse signals synchronized near 0 V of the AC power source; A temperature setting unit comprising a plurality of variable resistors to set an operating temperature of the heater; Compared with the operating temperature set by the temperature setting unit and the heater temperature detected by the temperature sensor, as a result of the first output voltage 15V when the heater temperature is lower than the operating temperature, and outputs 0V when the heater temperature is higher than the operating temperature A comparator, a third comparator for turning on the transistor when the 15 V voltage output from the first comparator is a normal voltage, and a transistor for turning on by the third comparator and outputting a control voltage for driving the heater to the heater controller. A comparison and control signal output unit; The first silicon-controlled rectifier and the first silicon-controlled rectifier are turned on by the control voltage output from the transistor so that the positive part of the input AC power is applied to the heater. The capacitor which is limited and charges the DC voltage input through the diode, and when the (-) part of the AC power is applied, turns on by the (-) AC voltage to convert the DC voltage charged in the capacitor into the second silicon control rectifier. A heater control unit comprising an output transistor and a second silicon controlled rectifier configured to be operated on a direct current voltage supplied by the on operation of the transistor so that a negative portion of the alternating voltage is applied to the heater; An LED display unit including a light emitting diode which is lit green when the AC power is applied to the heater and is lit red when the AC power is not applied; Characterized in that configured.
According to the present invention, two (+) and (-) parts of the AC power supply are used as a heater by using two silicon-controlled rectifiers, and the hair styler can operate as a free bolt, thus making the use of the product convenient. The AC power supplied to the heater can be interrupted according to the heater temperature detected by the temperature sensor, preventing damage to the product due to excessive temperature rise, and the power supplied to the heater is cut off when the temperature sensor is shorted. Overheating of the heater due to sensor malfunction can be cut off, and since the heater generates heat by using all parts of the positive (+) (-) part of the AC power source, the heater can be expected to generate heat at the target temperature in a short time.

Description

Heater driving device of hair styler

The present invention relates to a heater driving device of a hair styler, and more particularly, by supplying all the positive (+) (-) portions of AC power to the heater using two silicon controlled rectifiers so that the heater generates heat in a short time. It relates to a heater driving device of a hair styler.

In general, the hair styler is used to heat the hair to wave the hair or straighten the hair.

The hair styler is provided with a heater for applying heat to the hair, and includes a controller for supplying a driving voltage to the heater.

However, the conventional hair styler has a problem that it takes a long time for the heater to reach the target temperature because the heater is designed to operate only for the (+) part of the AC power source, so that the heater does not operate in the pre-bolt type Since the user is limited to the use of the hair styler, the operation of the pre-bolt type has a problem in that the structure of the product is very complicated and causes the production cost of the product to increase.

The present invention for solving the above problems is to provide a heater driving device of the hair styler to supply all the (+) (-) part of the AC power to the heater using two silicon controlled rectifiers so that the heater generates heat in a short time For the purpose of providing it.

According to an aspect of the present invention,

A heater to which a commercial AC power input is applied;

A temperature sensor detecting a heating temperature of the heater;

A constant voltage unit converting the input commercial AC power into a 15V DC voltage and outputting the circuit power;

A pair of transistors generating and outputting a zero crossing pulse near 0 V of the input of the commercial AC power source, a transistor operated by a zero crossing pulse outputted from the transistor, and a synchronous operation of the switching operation of the transistor. A zero crossing pulse generator comprising a transistor for supplying the output circuit power to the temperature comparison and the control signal output unit as a pulse signal synchronized to 0 V of the AC power source;

A temperature setting unit comprising a plurality of variable resistors to set an operating temperature of the heater;

Compared with the operating temperature set by the temperature setting unit and the heater temperature detected by the temperature sensor, as a result of the first output voltage 15V when the heater temperature is lower than the operating temperature, and outputs 0V when the heater temperature is higher than the operating temperature A comparator, a third comparator for turning on the transistor when the 15 V voltage output from the first comparator is a normal voltage, and a transistor for turning on by the third comparator and outputting a control voltage for driving the heater to the heater controller. A comparison and control signal output unit;

The first silicon-controlled rectifier and the first silicon-controlled rectifier are turned on by the control voltage output from the transistor so that the positive part of the input AC power is applied to the heater. The second silicon control is controlled by the capacitor which charges the DC voltage input through the diode and when the negative part of the AC power is applied to the heater, the DC voltage charged in the capacitor is turned on by the (-) AC voltage. A heater controller comprising a transistor outputting to a rectifier and a second silicon controlled rectifier configured to be turned on by a direct current voltage supplied by the on operation of the transistor so that a negative portion of the alternating voltage is applied to the heater;

An LED display unit including a light emitting diode which is lit green when the AC power is applied to the heater and is lit red when the AC power is not applied; Characterized in that configured.

According to the present invention, two (+) and (-) parts of the AC power supply are used as a heater by using two silicon-controlled rectifiers, and the hair styler can operate as a free bolt, thus making the use of the product convenient. The AC power supplied to the heater can be interrupted according to the heater temperature detected by the temperature sensor, preventing damage to the product due to excessive temperature rise, and the power supplied to the heater is cut off when the temperature sensor is shorted. Overheating of the heater due to sensor malfunction can be cut off, and since the heater generates heat by using all parts of the positive (+) (-) part of the AC power source, the heater can be expected to generate heat at the target temperature in a short time.

1 is a circuit diagram showing a heater driving apparatus of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

The terms defined in describing the present invention have been defined in consideration of the functions of the present invention and should not be construed to limit the technical elements of the present invention.

According to the drawings, the present invention,

A heater 11 to which input commercial AC power is applied;

A temperature sensor 10 for detecting a heating temperature of the heater 11;

A constant voltage unit 1 converting the input commercial AC power into a 15V DC voltage and outputting the circuit power;

A pair of transistors Q4 and Q5 for generating and outputting a zero crossing pulse near 0 V of the commercial AC power input, and a transistor Q3 for switching operation by the zero crossing pulses output from the transistors Q4 and Q5. A transistor for synchronizing with the switching operation of the transistor Q3 and supplying the circuit power output from the constant voltage unit 1 to the temperature comparison and the control signal output unit 4 as a pulse signal synchronized near 0V of the AC power source ( A zero crossing pulse generator 2 composed of Q1);

A temperature setting unit 3 including a plurality of variable resistors VR and VR1 to set an operating temperature of the heater 11;

When the operating temperature set by the temperature setting unit 3 is compared with the heater temperature detected by the temperature sensor 10, and as a result of the comparison, a 15V voltage is output when the heater temperature is lower than the operating temperature, and when the heater temperature is higher than the operating temperature. A first comparator 7 for outputting 0 V, a third comparator 9 for turning on the transistor Q2 when the 15 V voltage output from the first comparator 7 is a normal voltage, and a third comparator 9 A temperature comparison and control signal output section 4 composed of a transistor Q2 for on-operating by and outputting a control voltage for driving the heater 11 to the heater control section 5;

A first silicon controlled rectifier (SCR1) and a first silicon controlled rectifier (SCR1) for turning on by the control voltage output from the transistor (Q2) to apply a positive portion of the input AC power to the heater (11). The capacitor C4 charges the DC voltage input through the diode D2 through the resistor R20 and the varistor RV2 at the time of the ON operation, and the heater 11 has the negative (-) When the portion is applied, the transistor Q6 outputs the DC voltage charged in the capacitor C4 to the second silicon-controlled rectifier SCR2 by operating ON by the (-) AC voltage, and the ON of the transistor Q6. A heater control unit 5 composed of a second silicon control rectifier (SCR2) for turning on the DC voltage supplied by the operation to apply a negative part of the AC voltage to the heater 11;

An LED display unit 6 including a light emitting diode LED1 which is turned on green when AC power is applied to the heater 11 and red when AC power is not applied; Characterized in that configured.

The temperature comparison and control signal output unit 4 compares the reference voltage set by the resistors R10 and R17 with the sensor voltage output from the temperature sensor 10 and detects whether the sensor is short-circuited. It characterized in that it further comprises a second comparator 8 for detecting the output of the first comparator 7 by detecting a short circuit of the sensor when the reference voltage is lower than the reference voltage.

 Referring to the operation of the present invention configured as described above is as follows.

First, the commercial AC power input is supplied to the constant voltage unit 1 and the zero crossing pulse generator 2, and is in a standby state so that the commercial AC power can be supplied to the heater 11.

The AC power input to the constant voltage unit 1 is rectified while passing through the diode D1, and the level is limited to 15 V by the resistors R1 and R2 and the varistor RV1 to charge the capacitor C1. The DC voltage charged in C1) is supplied to the circuit power at a later stage during the switching operation of the transistor Q1.

When the input AC power is input to the zero crossing pulse generator 2, the input AC power is applied to the pair of transistors Q4 and Q5 through the resistors R14 to R16 and the capacitor C3. The pair of transistors Q4 and Q5 generate a zero crossing pulse near 0V of the AC power supply to switch the transistor Q3 at the next stage, and the transistor Q3 switches by the zero crossing pulse to perform the transistor Q1. The switching operation is performed so that the 15V DC voltage output from the constant voltage unit 1 is supplied to the circuit power supply as a pulse signal synchronized near 0V of the AC power supply.

The temperature setting unit 3 applied to the present invention allows the user to set the heating temperature of the heater 11, and the user operates the heater of the first comparator 7 by operating the variable resistors VR and VR1. The temperature is set.

Meanwhile, the first comparator 7 of the temperature comparison and control signal output unit 4 compares the heater operating temperature set by the temperature setting unit 3 with the heater temperature detected by the temperature sensor 10, and the comparison result If the temperature is higher than the heater operating temperature, a voltage of 0V is output so that the heater control circuit blocks the driving power from being supplied to the heater 11, and as a result of the comparison, if the heater temperature is lower than the heater operating temperature, the heater outputs a voltage of 15V. (11) Control operation is to be made.

After determining whether the voltage of 15 V output from the first comparator 7 is a normal voltage from the third comparator 9, and if the voltage is a normal voltage, the transistor Q2 of the rear stage is turned on.

The transistor Q2 is turned on to output a control voltage for driving the heater 11 to the first silicon controlled rectifier SCR1 of the heater controller 5, and the first silicon controlled rectifier SCR1 is turned on. The positive portion of the AC power is supplied to the heater 11.

When the positive part of the AC power is supplied to the heater 11 by the ON operation of the first silicon controlled rectifier SCR1, the AC power is limited after the level is limited by the resistor R20 and the varistor RV2. It is rectified via D2) and charged to the capacitor C4.

The charging operation of the capacitor C4 is performed while the positive portion of the AC power is supplied to the heater 11.

On the other hand, after the positive part of the AC power is supplied to the heater 11, the negative part of the AC power is applied. At this time, the transistor Q6 is turned on by the negative part of the AC power to operate the capacitor. The DC voltage charged in (C4) is output as the control voltage of the second silicon control rectifier (SCR2), and the second silicon control rectifier (SCR2) is turned on by the DC voltage supplied by the on operation of the transistor Q6. (-) Part of the AC voltage is applied to the heater 11, and the negative (-) part of the AC voltage is applied to the heater 11 by the ON operation of the second silicon control rectifier (SCR2). 11) operates for all parts of the positive (-) and negative (-) voltages of the AC voltage.

When the AC power is applied to the heater 11, the light emitting diode LED1 of the LED display unit 6 lights green, and when the AC power is not applied, it lights red to alert the user that the AC power is not applied. Done.

That is, in the present invention, the first silicon-controlled rectifier SCR1 is turned on as a control signal supplied by the on operation of the transistor Q2, so that a positive portion of the alternating voltage is applied to the heater 11, The transistor Q6 is turned on by the (-) part and the second silicon controlled rectifier SCR2 is turned on so that the negative part of the AC voltage is applied to the heater 11. All heat is generated by the +) (-) part so that the target temperature can be reached more quickly.

On the other hand, in the present invention, when the temperature sensor 10 is short-circuited by a failure, the driving of the heater 11 can be interrupted.

This operation is implemented by the second comparator 8, the second comparator 8 compares the reference voltage set by the resistors R10 and R17 with the sensor voltage output from the temperature sensor 10 to determine whether the sensor is short-circuited. When the sensor voltage is lower than the reference voltage is detected as a short circuit of the sensor to cut off the output of the first comparator 7 to prevent the transistor (Q2) to operate on so that the AC voltage is not applied to the heater (11) It is.

This action is to prevent the heater 11 from malfunctioning when the sensor 10 breaks down.

1: constant voltage section, 2: zero crossing pulse generation section,
3: temperature setting part, 4: temperature comparison and control signal output part,
5: heater control unit, 6: LED display unit,
7: first comparator, 8: second comparator,
9: third comparator, 10: temperature sensor,
11: heater, SCR: silicon controlled rectifier,

Claims (2)

delete A heater 11 to which input commercial AC power is applied;
A temperature sensor 10 for detecting a heating temperature of the heater 11;
A constant voltage unit 1 converting the input commercial AC power into a 15V DC voltage and outputting the circuit power;
A pair of transistors Q4 and Q5 for generating and outputting a zero crossing pulse near 0 V of the commercial AC power input, and a transistor Q3 for switching operation by the zero crossing pulses output from the transistors Q4 and Q5. A transistor for synchronizing with the switching operation of the transistor Q3 and supplying the circuit power output from the constant voltage unit 1 to the temperature comparison and the control signal output unit 4 as a pulse signal synchronized near 0V of the AC power source ( A zero crossing pulse generator 2 composed of Q1);
A temperature setting unit 3 including a plurality of variable resistors VR and VR1 to set an operating temperature of the heater 11;
When the operating temperature set by the temperature setting unit 3 is compared with the heater temperature detected by the temperature sensor 10, and as a result of the comparison, a 15V voltage is output when the heater temperature is lower than the operating temperature, and when the heater temperature is higher than the operating temperature. A first comparator 7 for outputting 0 V, a third comparator 9 for turning on the transistor Q2 when the 15 V voltage output from the first comparator 7 is a normal voltage, and a third comparator 9 A temperature comparison and control signal output section 4 composed of a transistor Q2 for on-operating by and outputting a control voltage for driving the heater 11 to the heater control section 5;
A first silicon controlled rectifier (SCR1) and a first silicon controlled rectifier (SCR1) for turning on by the control voltage output from the transistor (Q2) to apply a positive portion of the input AC power to the heater (11). In the on-operation of), when the level is limited through the resistor R20 and the varistor RV2, the capacitor C4 charging the DC voltage input through the diode D2, and the negative portion of the AC power supply are applied. A transistor Q6 which is turned on by the negative AC voltage and outputs a DC voltage charged in the capacitor C4 to the second silicon-controlled rectifier SCR2; A heater control unit 5 composed of a second silicon controlled rectifier (SCR2) for turning on a DC voltage so that a negative portion of the AC voltage is applied to the heater 11,
The temperature comparison and control signal output unit 4 compares the reference voltage set by the resistors R10 and R17 with the sensor voltage output from the temperature sensor 10 to detect whether the sensor is short-circuited, and the sensor voltage is a reference voltage. And a second comparator (8) which detects by a short circuit of the sensor when it is lower and cuts off the output of the first comparator (7).

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