KR19980028429A - 110V / 220V combined thermostat and control method - Google Patents

Abstract

The present invention relates to a 110V / 220V combined thermostat and a control method thereof, and more particularly, to an improvement of a temperature detector capable of maintaining a constant temperature at a predetermined temperature by detecting and controlling a temperature of an electric yaw or a sheet. As a result, according to the power supply voltage applied from the power supply voltage detection unit 200, the set value from the temperature setting unit 62 and the detected value from the temperature detection unit 61 are caused by the microcomputer 70, and the microcomputer 70 The input set value and the detected value are calculated, compared and judged, and the microcomputer 70 synchronizes the SCR of the heat generating unit 40 to turn on / off the heater of the heat generating unit 30, thereby accurately adjusting the temperature of the heat preservation heater. By detecting and controlling, it can keep constant at predetermined temperature.

Description

110V / 220V combined thermostat and control method

The present invention relates to a 110V / 220V combined thermostat and a control method thereof, and more particularly, to an improvement of a temperature detector capable of maintaining a constant temperature at a predetermined temperature by detecting and controlling a temperature of an electric yaw or a sheet. .

A conventional 110V / 220V combined thermostat and a control method thereof are disclosed in detail in Korean Patent Application No. 94-7730 filed on April 13, 1994 by the present applicant.

Referring to FIG. 1, the electromagnetic wave blocking means 10 is connected to the power supply voltage input side to prevent harmful electromagnetic waves from being emitted to the outside, and the resistor R1 and the capacitor C1 are parallel to the input terminal. Is connected.

The power supply display unit 20 shows the on / off state of the power supply and is connected in series with a lamp LAMP and a resistor R2 on the input side.

The heat generating unit 30 is composed of a heating wire for generating heat, a nylon thermistor and a detection wire.

The heat generating unit 40 generates heat by receiving a predetermined control signal from the microcomputer 70 and controls power applied thereto. An anode terminal of the thyristor SCR is connected to the heat generating unit 30. The cathode terminal is grounded, the gate terminal is connected to the microcomputer 70 through the resistor R5, and the capacitor C3 is connected between the common point of the resistor R5 and the thyristor SCR and the ground. Is connected, and a resistor (R4) and a capacitor (C2) are connected in series at both ends of the anode and cathode terminals of the thyristor (SCR).

The resistor R4 and the capacitor C2 are connected in parallel to the thyristor SCR to prevent the thyristor SCR from being damaged due to a surge voltage, and the electromagnetic wave blocking means 10 is connected to an input terminal of a power source. It is composed of a resistor R1 and a capacitor C1 connected in parallel to prevent high frequency harmful electromagnetic waves from being emitted to the outside of the circuit due to the low-pass filter characteristics of the resistor R1 and the capacitor C2.

The hot wire overheat prevention unit 50 is to prevent overheating of the heat generating unit. The diode D1 having an anode terminal connected to a common connection point of the heat generating unit 40 and the cathode terminal of the diode D1 and the power supply (+ Is composed of a resistor R3 connected between the terminals, and the anode terminal is composed of a diode D2 connected to the ground point and a heating resistor R6 connected between the cathode terminal of the diode D2 and the detection line. .

When the thyristor SCR is shorted, a path consisting of the thyristor SCR, the diode D1, and the heat generating resistor R3 is formed to melt the temperature fuse FU2, and the heat generating unit 30 When the heating wire is shorted, the microcomputer 70 loses its function by constructing a path composed of the jumping diode D2, the heating resistor R6, the detection wire, and the heating wire to melt the temperature fuse FU2. Even when the circuit is safe.

The temperature detection and temperature setting unit 60 detects the detected temperature and the set temperature of the heat generating unit 40 and applies a predetermined control signal to the microcomputer 70, and is connected between the heat generating unit 40 and the ground point. Temperature setting unit 61 to be applied to the microcomputer 70 detecting the temperature of the heat generating unit 40 and input terminals on both sides of the power supply voltage, and to set the temperature of the electric heat preservative to be applied to the microcomputer 70. The part 62 is comprised separately.

The temperature detecting unit 61 detects the temperature of the heat generating unit and applies it to the microcomputer 70. The variable resistor VR1 and the voltage dividing resistor R for dividing the voltage applied through the heat generating unit 30 are connected in series. And a current limiting resistor R8 connected in series between a common connection point of the variable resistor VR1 and the voltage dividing resistor R7 and a ground point connected in parallel to the diode D2 of the hot wire overheat protection unit 50. The capacitor C4 is configured to apply the voltage appearing at the common connection contact between the current limiting resistor R8 and the capacitor C4 to the microcomputer 70 according to the temperature change of the heat generating unit 30. It is comprised so that change of the virtual capacitance value CT can be detected.

The temperature setting unit 62 is connected to both input terminals of the power supply voltage, sets the temperature of the heat preservation thermometer, and applies the temperature to the microcomputer 70. The capacitor C5, the variable resistor VR2 and the voltage divider connected in series with the input side are connected. And a voltage appearing at the common connection point of the variable resistor VR2 and the voltage divider resistor R9 to the microcomputer 70.

The microcomputer 70 controls each circuit part by receiving a predetermined signal from each part of the circuit and performing a predetermined process, and the terminal REF for reading the value of the temperature setting part 62. And the terminal SEN for reading the value of the temperature detector 61 and the values of the temperature detector 61 and the temperature setter 62 to perform a predetermined process, thereby generating the heat generating driver 40. Terminal SCR for controlling the power supply, a terminal LVOLT performing a low power function by performing a predetermined process, a terminal FAST performing a heat treatment function by performing a predetermined process, and a predetermined process. The terminal PRI performs a preheating function, and performs a predetermined process to supply each circuit. Here, the detection method of the power supply voltage is provided with display terminals OVLP and PRLP for externally recognizing the operation state of the inventor.

The zero point detecting unit 80 detects a zero point of the applied power voltage and recognizes the micro point 70. The zero point detecting unit 80 includes a resistor R10 and a capacitor C6.

The clock generator 90 applies a clock from the outside to operate the microcomputer 70 and includes a resistor R11 and a capacitor C7.

The microcomputer power supply unit 100 drives the microcomputer 70 by converting a power voltage into a predetermined DC voltage, which is a resistor R12, a capacitor C8, a C10, a diode D3, a D4, Zener diode (ZD1).

The power supply voltage detecting unit 200 detects the magnitude of the power supply voltage applied to the microcomputer 70 and includes a capacitor C11 and resistors R16, R17, and R19.

The switching unit 200 is a switch SW1 (SW2) (SW3) connected between the ground point and the high voltage of the DC power supply. The heating unit 40 is operated by operating the microcomputer 70 in the predetermined process. By controlling the power applied to the (), by operating the switch (SW1) for low-power operation by the connection method of the switch (SW1) (SW2) (SW3) and by operating the microcomputer 70 in a predetermined process By pre-heating by applying power to the heat generating unit 40 by controlling the power applied to the heat generating unit 40 by operating the switch (SW2) to rapidly increase the temperature and operating the microcomputer 70 in a predetermined process. It consists of the switch SW3 which maintains a state.

The display unit 400 receives a predetermined control signal from the microcomputer 400 to display an overheating state of the electric heat preservative, and indicates that the preheating function is selected and is being performed, which is a light emitting diode (LED1) (LED2) and a resistor. It consists of (R14) and (R15).

In the figure, reference numerals C3, C4, and C12 denote noise condensers, TF denotes a temperature fuse and SF denotes a current fuse.

First, when AC 110V or 220V is applied, power is applied to the lamp LAMP through the protection resistor R2 to indicate that power is being applied to the temperature controller, and at the same time, a power supply voltage to the microcomputer power supply 100 is applied. This is applied to generate a constant DC voltage to operate the microcomputer 70. In addition, when power is applied to the microcomputer 70, the microcomputer 70 performs an initialization operation and determines the magnitude of the voltage voltage applied through the power supply voltage detector 200 is 110V or 220V. Here, the clock generator 90 is for applying a clock to the microcomputer 70, and the zero point detector 80 detects the zero point of the applied power voltage and makes the microcomputer 70 recognize it.

Here, the detection method of the power supply voltage is the same as that of the Korean Patent Application No. 94-833, which is a prior application of the present invention, the description is omitted.

On the other hand, after power is applied to the microcomputer 70 and the initialization operation is performed, the microcomputer 70 simultaneously detects the voltage applied by the temperature detection and setting unit 60 within the + period of the power supply voltage to conduct heat transfer. By comparing the present temperature and the set temperature of the warmer, thereby controlling the temperature of the electric heat preservative by turning on / off the thyristor (SCR) which is the output control element.

The degree of progress of the current appearing at the output terminal of the temperature detector 61 is a measure of the temperature of the heat generating unit 30, which is determined by the temperature setting unit 62 composed of the condenser C5 and the variable resistor VR2. The difference between the set temperature and the present temperature can be detected when compared with the advanced waveform of the current appearing at the output stage.

Therefore, when the thyristor (SCR) is turned on / off according to the degree of improvement of the current applied from the temperature detector 61 and the temperature setting unit 62, the heating line of the heat generator 30 is set by the user. The temperature can be kept constant.

Similarly, the voltage waveform can be grounded and the temperature can be adjusted according to the grounded degree.

After the initialization operation of the microcomputer 70 is finished, the microcomputer 70 detects the zero point of the power supply voltage applied by the zero point detection unit 80, and the SEN terminal and the REF terminal within the + period of the power supply voltage. The values of the temperature detector 61 and the temperature setter 62 are read. Thereafter, the microcomputer 70 takes a time until the signal applied to the SEN terminal and the REF terminal reaches a predetermined value or less within a + period of the power supply voltage applied through the zero point detector 80. Reveal and compare and save the time value.

The microcomputer 70 adjusts the temperature of the heat preservation heater by comparing the time value and judging the thyristor.

By repeating the above operation, the temperature of the heat preservation heater is kept constant at the temperature set by the user, even when noise is mixed in the power supply voltage applied by simultaneously detecting the temperature of the heat preservation heater and the set temperature. By detecting the correct temperature, the temperature of the thermal insulation can be kept constant at the value set by the user.

Therefore, since the conventional power supply voltage sensing unit detects the power supply voltage by changing the phase of the power supply voltage in the capacitor C11 resistors R17 and R19, the characteristics of the condenser C11 vary greatly with temperature, as well as the condenser ( There are many problems with the component error of C11).

Since the temperature detector and the temperature controller are connected together, the microcomputer reads the sum of the temperature and the set temperature of the current heating wire, so the microcomputer cannot accurately determine the temperature and the set temperature of the heating wire. The short circuit and disconnection of a sensor line cannot be detected by short-circuiting a sensor part, and this circuit is used when a hardware control method is used, and there exists a problem which requires a comparison waveform generation part.

Because the temperature setting part is distributed in two places in the temperature detecting part and the comparative waveform generating part, it is difficult to adjust in two places, and it is the same as the temperature sensing part, so the microcomputer does not know the current setting value and affects the external temperature (ambient temperature). There is a problem that a lot of characteristics change a lot.

As the microcomputer of phase control method drives the heater by dividing the sine wave of the commercial power supply, a lot of electromagnetic noise is generated, and the temperature detection value of the heater is detected as the resistance value across the sensor wires, the power consumption is determined by the number of stages, and the sensor value This increases or decreases the driving of the heater. In addition, since the sensor value changes little in power consumption, it prevents the abnormal high temperature protection function, divides the sine wave of the commercial power supply, drives the heater, generates a lot of power noise, and the power consumption is constant regardless of the voltage. There was a problem such as need to adjust.

The present invention is to provide a power supply voltage sensing unit that simplifies the voltage sensing method and improves the temperature characteristics in order to improve the above problems.

In addition, since only the temperature of the heating unit needs to be sensed, a comparison waveform generator is not required, and thus the circuit is simple, and the present invention provides a temperature detection unit that enables the microcomputer to know the current temperature.

In addition, it is possible to detect the current setting value independently from the microcomputer by detecting it independently, and to include a circuit for correcting the temperature characteristic of the setting value, and to provide a temperature setting part that constitutes a circuit with simple setting of the maximum and minimum values of the setting value. .

In addition, by turning on / off in synchronism with a sine wave of a commercial power supply, less electromagnetic waves are generated than in a conventional phase control method, and less electromagnetic noise is generated than in a conventional state. Measures and detects the value, compares the set value with the sensor value, turns on / off the heater, and power consumption varies greatly depending on the sensor value. It is to provide on-off type microcomputer with small change of power consumption according to voltage and small temperature change according to capacity.

1 is a circuit diagram of a conventional 110V / 220V combined thermostat

2 is a circuit diagram of a 110V / 220V combined thermostat of the present invention

3 is a basic configuration of the microcomputer of the present invention

4 is a control flowchart using a microcomputer of the present invention

* Explanation of symbols for main parts of the drawings

10: electromagnetic wave blocking means 20: power display unit

30: heat generating part 40: heat generating part

50: hot wire overheat prevention unit 60: temperature detection and temperature setting unit

61: temperature detector 62: temperature setting unit

70: microcomputer 80: zero point detection unit

90: clock generator 100: power supply

200: power supply voltage detection unit 300: switching unit

400: display unit

If described in detail by the accompanying drawings the configuration and operation of the present invention for achieving the above object are as follows.

2 is a circuit diagram of a 110V / 220V combined thermostat of the present invention, FIG. 3 is a basic configuration diagram of the microcomputer of the present invention, and FIG. 4 is a control flowchart using the microcomputer of the present invention.

In FIG. 2, the same code | symbol is attached | subjected to the part same as the prior art of FIG. 1, and description is abbreviate | omitted.

The power supply voltage detecting unit 200 detects the magnitude of the applied power supply voltage and applies the applied voltage to the microcomputer 70. A resistor R13 and a R14 are connected in series between the microcomputer power supply 100 and the ground. The resistor R16 is connected between the common point of the resistor R13 and the resistor R14 and the microcomputer 70, and the capacitor is connected between the common point of the resistor R16 and the microcomputer 70 and the ground. (C11) is connected.

Therefore, the detection method is simple by distinguishing only 110V and 220V using the voltage distribution theory of the resistors R13 and R14.

In addition, the temperature detector 61 detects the temperature of the heat generator 30 and applies it to the microcomputer 70. The resistor R15 and the capacitor C4 are connected in series between the heating wire and the ground terminal of the heat generator 30. The common connection point of the resistor R15 and the capacitor C4 is connected to the SEN terminal of the microcomputer 70.

Therefore, only the temperature change of the heat generating portion 30 is applied by applying a voltage appearing at the common connection contact between the current limiting resistor R15 and the condenser C4 to the microcomputer 70 via the heat generating portion 30. It is configured to be detectable, there is no comparison waveform generating section, and the circuit is simple, and the present temperature can be known by the microcomputer 70.

In addition, the temperature setting unit 62 is connected to both input terminals of the power supply voltage, sets the temperature of the heat preservation thermometer, and applies the temperature to the microcomputer 70. The resistance connected in series between the VLd terminal of the microcomputer 70 and the ground terminal ( R9) is connected to the capacitor C5, and a resistor R7 connected in parallel to the resistor R8 and the variable resistor VR is connected between the common connection point of the resistor R9 and the capacitor C5 and the VLs terminal of the microcomputer. It is connected in series.

Therefore, setting the maximum value and the minimum value of the set value is simple by changing the resistors R7 and R8. The resistor R9 was used to independently detect the value of the variable resistance VR and to correct the value of the variable resistance VR, and the capacitor C5 was used to correct the temperature characteristic. By independently detecting the value, the current setting value can be known from the microcomputer.

2 and 3, the on / off type microcomputer 70 controls the respective circuit parts by receiving a predetermined signal from each part of the circuit and performing calculation theorem correction comparison. The terminal VLd (VLs) for reading the value of 62 and the value for the terminal SEN for reading the value of the temperature detecting unit 61 and the values of the temperature setting unit 62 and the temperature detecting unit 61 are read. By performing a predetermined process, the terminal (SCR) for controlling the heating driver 40, the terminal (VCC) to which a direct current is supplied, the terminal (OSC) to which the clock generator is connected, and the terminal to which the power voltage detection unit is connected (Vk) and the ground terminal (GND).

In FIG. 3, the power supply unit receives a voltage of 110, 220V and applies a microcomputer power supply 5V, and the noise canceling function, the overcurrent protection circuit, the abnormal high temperature prevention function, and the like are built in, which has a 110 or 220V power judgment function.

The set value is set by adjusting the number of stages of the variable resistor VR of the temperature setting section. This setting value input method uses RC charge time.

In the sensor detection method, a sensor value is determined by comparing a detection line of a heating unit with a commercial power supply.

The heating unit driving drives the heater in synchronization with the thyristor (SCR) in the microcomputer (70).

4, the control method of the temperature detection apparatus of a thermostat is demonstrated.

1. Power up step

Initial power-on function (plug applied to power source)

2. Power stabilization time delay step

When the initial power is applied, the unstable state is maintained for about 2 seconds. If driving in this unstable state may cause an error, this time operation is stopped.

3. Initial value setting step

Initialize all variables.

That is, `` -START DIFF = 255: initial sensor correction value, -STEP = 0: process progress, -VR DATA = 0: setting correction value, -VR TIME = 0: setting value, -SR TIME = 0: for correction Reference value, -ON FLAG = 0: Output ON / OFF value, -SENSOR TIME = 0: SENSOR value,-SENSOR DATA = 0: SENSOR corrected value, -ON COUNTER = 0: Number of output ON, -TEMP = 0: Temporary , -OSC F = 0: Sensor correction value

4. Power frequency and microcomputer frequency detection step

-Measure "OSC F" value to calibrate the sensor value.

-Power frequency detects 50Hz, 60Hz.

5. SIN wave rising section detection phase of power

The zero point detection unit 80 of FIG. 2 detects the upper section of the power supply, and if the rising section, the process proceeds to the next step.

6. STEP value inspection step (process value)

The STEP value represents the next process sequence.

7. Sensor value detection step

-Proceed when STEP value is 0,

-Detect the current temperature (sensor value).

-SENSOR TIME (0-255)

8. VR value detection step

-It progresses when STEP value is 2 and detects current setting value.

9. 220V search phase

At -220V, three SIN waves are off and only one SIN wave is on.

(ON FLAG = 1: ON)

If it is -110V, all of them are ON. (ON FLAG = 1: ON)

10. Output drive

Drives the SCR to generate heat in the heater.

11. Operation stage

-SENSOR DATA- SENSOR TIME / OSC F (SENSOR value 1st correction)

-VR DATA-VR TIME / SR TIME (Set Value Correction)

-TEMP-VR DATA * START DIFF / 4 (SENSOR value 2nd correction)

12. Comparison of sensor temperature and set value

Compare SENSOR DATA-TEMP.

13. If "-"

-When sensor temperature is lower than setting value

-Turn on the FLAG by driving the heater.

-Increase the ON value by 1.

-If the number of ON is 6 or more, decrease the START DIFF value by 1.

-If the value of START DIFF is 0, it is in the normal state.

14. 10 minutes of frequency detection

Calibrate the sensor by measuring power frequency and microcomputer OSC frequency every 10 minutes.

15.If `` + '',

-When sensor temperature is higher than setting value

-Turn off the FLAG by driving the heater.

16. START DIFF value correction

-START DIFF START DIFF (ON Time / Time VR DATA)

-In order to correct START DIFF value, measure ON time for 15 minutes and compare START DATA with VR DATA and subtract START DIFF value.

Therefore, a power supply step of receiving a detection voltage from the power supply unit and applying 5V to the microcomputer 70, detects the heater temperature value of the heating unit 30 from the temperature detection unit 61, and corrects the detected signal with the microcomputer 70. ), A temperature detecting step of detecting the value of the variable resistor (VR) from the temperature setting part 62, correcting the temperature setting value with a resistor (R9), and applying it to the microcomputer 70; A voltage test step of recognizing the microcomputer 70 by determining whether the power supply voltage applied by a predetermined process is 110V or 220V, and a control step in which the microcomputer 70 receives a predetermined signal from each unit and calculates and compares the result. And a heater driving step of receiving a predetermined signal from the microcomputer 70 and synchronizing the SCR of the heat generating unit 40 to turn on / off the heater of the heat generating unit 30.

Therefore, according to the power supply voltage applied from the power supply voltage detection unit 200, the set value from the temperature setting unit 62 and the detected value from the temperature detection unit 61 are caused by the microcomputer 70, and the microcomputer 70 The input set value and the detected value are calculated, compared and judged, and the microcomputer 70 synchronizes the SCR of the heat generating unit 40 to turn on / off the heater of the heat generating unit 30, thereby accurately adjusting the temperature of the heat preservation heater. By detecting and controlling, it can keep constant at predetermined temperature.

As described above, according to the present invention, the power supply voltage sensing unit is composed of a circuit for distinguishing only 110V and 220V by using the voltage distribution theory of the resistors R13 and R14, so that the sensing method is simple and the temperature characteristic is good.

In addition, since the circuit is simply configured to sense only the temperature of the heat generating unit, the comparison waveform generating unit is unnecessary, and the present temperature can be known from the microcomputer.

In addition, the temperature setting unit alone detects the variable resistance (VR) value and uses a resistor (R9) to calibrate the VR value so that the microcomputer can know the current setting value and the temperature characteristic of the setting value. Can be corrected, and setting the maximum and minimum of the set value can be simplified.

In addition, the on / off type microcomputer is turned on / off in synchronization with a sine wave of a commercial power supply, and thus generates less electromagnetic waves than the conventional phase control method. It is detected by comparing and measuring the capacitance value.The heater is turned on / off by comparing the set value with the sensor value, and the power consumption varies greatly depending on the sensor value. Is not generated much, the power consumption is changed according to the voltage, and because the temperature change is small depending on the capacity is a useful invention that can facilitate the temperature detection and temperature control.

Claims (6)

Electromagnetic wave blocking means 10 for suppressing the emission of harmful electromagnetic waves, a power supply display unit 20 indicating the on / off state of the power supply, and a heating unit 30 generating heat by receiving a predetermined control signal from the microcomputer 70. A heat generation driver 40 for controlling the power applied to the heat source, a heat ray overheat prevention part 50 for preventing overheating of the heat generation part 30, and the heat generation drive part 40 and the ground connected to each other. The temperature detector 61 detects the temperature of the drive unit 40 and applies it to the microcomputer 70, and the temperature setting unit 62 connected to both input terminals of the power supply voltage to set the temperature of the heat preservation thermometer and apply it to the microcomputer 70. ), The microcomputer 70 for controlling the circuit parts, and the zero point of the power supply voltage applied to the microcomputer 70 are detected by applying a predetermined signal from each circuit part and performing calculation arrangement correction comparison. To recognize the microcomputer 70 A zero point detector 80, a clock generator 90 for applying a clock from outside to operate the microcomputer 70, and a power source voltage for converting a predetermined DC voltage to drive the microcomputer 70. 110V / 220V dual temperature thermostat comprising a microcomputer power supply unit 100 and a power supply voltage sensing unit 200 to detect the magnitude of the voltage applied to the microcomputer 70 The method of claim 1, wherein the power supply voltage detector 200 detects the magnitude of the applied power supply voltage and applies it to the microcomputer 70. The resistor R13 is connected in series between the microcomputer power supply unit 100 and the ground. ) R14 is connected, a resistor R16 is connected between the common point between the resistor R13 and the resistor R14 and the microcomputer 70, and the resistor R16 and the microcomputer 70 110V / 220V combined thermostat, characterized in that the condenser (C11) is connected between the common point and ground. The temperature detecting unit 61 detects the temperature of the heat generating unit 30 and applies it to the microcomputer 70. The resistor R15 is connected in series between the heating line of the heat generating unit 30 and the ground terminal. A condenser (C4) is connected, and a common connection point of the resistor (R15) and the condenser (C4) is connected to the SEN terminal of the microcomputer 70, 110V / 220V combined thermostat. The temperature setting unit 62 is connected to both input terminals of the power supply voltage, sets the temperature of the heat preservation thermometer, and applies the temperature to the microcomputer 70. The temperature setting unit 62 is connected between the VLd terminal of the microcomputer 70 and the ground terminal. Is connected in parallel between the resistor R8 and the variable resistor VR between the common connection point of the resistor R9 and the capacitor C5 and the VLs terminal of the microcomputer. 110V / 220V combined thermostat, characterized in that the resistor (R7) is connected in series. 2. The microcomputer 70 reads the value of the temperature setting section 62 by controlling the respective circuit sections by receiving a predetermined signal from each section of the circuit and performing calculation clearance correction comparison. A predetermined process is performed by reading the terminal SEN for reading the values of the terminal VLd (VLs) and the temperature detector 61 and the values of the temperature setting unit 62 and the temperature detector 61. By doing so, the terminal (SCR) for controlling the heat generating unit 40, the terminal (VCC) to which a direct current is supplied, the terminal (OSC) to which the clock generator is connected, the terminal (Vk) to which the power voltage sensing unit is connected, and the ground terminal ( 110V / 220V combined thermostat, characterized in that consisting of (GND). A power supply step of applying 5V to the microcomputer 70 by receiving the detection voltage from the power supply unit, and detecting the heater temperature value of the heating unit 30 from the temperature detector 61 and correcting the detected signal to the microcomputer 70. A temperature detecting step of applying the temperature, a temperature setting step of detecting the variable resistance VR value from the temperature setting unit 62, correcting the temperature setting value with the resistor R9, and applying it to the microcomputer 70; A voltage inspection step of recognizing the microcomputer 70 by determining whether the power supply voltage applied by the process is 110V or 220V, and a control step of the calculation and comparison of the microcomputer 70 by receiving a predetermined signal from each unit; 110V / 220V combined temperature control, characterized in that the heater driving step of turning on / off the heater of the heat generating unit 30 in synchronization with the SCR of the heat generating unit 40 in response to the predetermined signal from the microcomputer (70). Control method of the device.