KR970000503B1 - Voltage detecting apparatus and its method - Google Patents

Abstract

A method and apparatus for the power voltage detection of the automatic temperature adjustment apparatus of the 110V/220V combined use whereby the main circuit is protected safely because the routine of the power voltage detection program is changed, when the power voltage detection part of the microprocessor is break down, and the wrong action in accordance with the changed power voltage and the outside noise is protected. The said apparatus consist of a microprocessor where executes the automatic temperature adjustment, a power condenser where make to drop down the applied power voltage, the first and second resistor where divides the applied power voltage, a resistor for the limited current where applies the divided voltages to the power voltage detection means.

Description

Power supply voltage detection device and method for 110V / 220V combined thermostat

1 is a block diagram showing the configuration of a 110V / 220V combined thermostat using a conventional microcomputer.

2 is a circuit diagram showing the configuration of a power supply voltage detection unit using a conventional microcomputer.

3 is a circuit diagram showing the configuration of a power supply voltage detection means using a microcomputer of the present invention.

4 is a waveform diagram showing a power supply voltage detection method according to Embodiment 1 of the present invention.

5 is a signal flow diagram showing a power supply voltage detection method according to Embodiment 1 of the present invention.

6 is a waveform diagram showing a power supply voltage detection method according to Embodiment 2 of the present invention.

7 is a signal flow diagram showing a power supply voltage detection method according to Embodiment 2 of the present invention.

* Explanation of symbols for main parts of the drawings

60: power supply voltage detection means VOLT1: power supply detection terminal of the microcomputer

The present invention relates to a 110V / 220V dual-purpose thermostat using a microcomputer, in particular, to prevent the malfunction of the microcomputer due to fluctuations in the applied power supply voltage or external noise, as well as the circuit in the event of a malfunction of the microcomputer damage The present invention relates to a power supply voltage detection device and method for a 110V / 220V combined thermostat that can be safely protected.

In general, a conventional electric heat insulator such as an electric blanket, an electric yoke, an electric blanket, etc., which controls a temperature using a microcomputer, has a power supply voltage detector 10 for detecting whether a power supply voltage is 110V or 220V, as shown in FIG. )Wow; A temperature setting and temperature detecting unit 20 for setting a temperature to be kept warm of the heat preserving heater and detecting a current temperature; Receives the value detected by the power supply voltage detector 10 and proceeds with a predetermined program, and controls the output of the heat preservation thermometer according to the temperature setting and the measured value detected by the temperature detector 20, and other circuits. A microcomputer 30 for controlling each unit; An output control unit 40 which receives a predetermined control signal from the microcomputer 30 and controls the output of the heat preservation thermometer; It consists of a DC power supply unit for supplying a DC power to the microcomputer 30, the microcomputer clock oscillation unit, and the other circuit unit 50 consisting of a safety circuit to be controlled by receiving a control signal to the microcomputer (30).

Such a conventional device operates the microcomputer 30 by making a power supply voltage applied from the DC power supply unit in the other circuit unit 50 to a constant DC employee, and the microcomputer 30 is applied from the power supply voltage detector 10. The detected voltage determines whether the internal program of the microcomputer should be executed based on 110V or 220V.

Thereafter, the microcomputer 30 controls the output controller 40 by detecting and comparing the temperature set by the user by the temperature setting and temperature detecting unit 20 with the temperature of the current heating thermostat, thereby automatically adjusting the temperature of the heating thermostat. It was.

However, in the 110V / 220V combined thermostat using the conventional microcomputer as described above, a malfunction occurs when the element of the power supply voltage detecting unit 10 is destroyed or the power sensing terminal of the microcomputer 30 is destroyed. There was a problem such that the circuit itself was destroyed or a fire occurred.

This will be described in detail as follows. 2 is a circuit diagram showing the configuration of a power supply voltage detector using a conventional microcomputer. As shown in the drawing, divided voltage resistors R4 and R5 connected in series to a power supply terminal to divide an unknown power supply voltage to a predetermined ratio. and; A diode (D1) connected to the common connection point of the voltage divider (R4, R5) for half-wave rectifying the power supply voltage; A smoothing capacitor C1 connected between the cathode terminal of the diode D1 and a ground point for rectifying a half-wave rectified power voltage from the diode R1; A base is connected to the cathode terminal of the diode D1, and an emitter is connected to a “HIGH power supply terminal Vcc”, which is an output of the DC voltage supply unit 951, and a collector (COLLECTOR). A switching element Q1 consisting of a transistor connected to a ground point via a resistor R2, the switching element performing a switching operation in accordance with the potential of the base; The power sensing terminal VOLT of the microcomputer 30 connected to the output terminal of the switching element Q1 through the resistor R1. In the figure, reference numeral R3 denotes a resistor for discharge regression, and GND denotes a ground terminal.

The conventional power supply voltage detection unit 10 configured as described above has a magnitude of the voltage applied to the emitter near 165V by adjusting the voltage dividing ratio of the voltage divider resistors R4 and R5 to the potential of the base terminal of the switching element Q1. In this case, the switching element Q1 is turned on when the power supply voltage is 110V, thereby applying a “high” signal to the power detection terminal VOLT of the microcomputer 30. When the applied power voltage is 220V, the signal is turned off to apply the "low" signal, which is the ground potential. Thereafter, the power detection terminal VOLT of the microcomputer 30 determines the power supply voltage to be 110V or 220V according to the signal and proceeds with a predetermined program.

However, the conventional power supply voltage detection device configured and operated as described above detects the applied power supply voltage by detecting the internal logic of the power detection terminal VOLT of the micom 30 and the power supply voltage external to the micom 30. Due to the device, there is a problem in that the power supply voltage cannot be properly detected when the device of the power supply voltage detection unit 10 or the power detection terminal VOLT of the microcomputer 30 is destroyed.

That is, when the switching device Q1 of the power supply voltage detector 10 is destroyed, the power supply voltage detection unit 110 recognizes 110V (220V when the switching device or the voltage divider ratio is adjusted) regardless of the power supply voltage applied thereto. If the VOLT is destroyed, it is determined as 110V or 220V.

In other words, if the protection diode in the power detection terminal VOLT is broken to 110V, it is recognized as 110V, and if it is broken to 220V, it is recognized as 220V.

An object of the present invention is to solve the conventional problems as described above, in particular, when the routine (ROUTINE) of the power supply voltage detection program inside the microcomputer is changed, when the power supply voltage detection unit is destroyed or the power supply detection terminal of the microcomputer is destroyed. The present invention provides a power supply voltage detection device and method for a 110V / 220V thermostat that can protect a circuit safely and prevent malfunctions caused by fluctuations in an applied power supply voltage or external noise.

Hereinafter, the technical configuration of the embodiment of the present invention will be described in detail.

Example 1

3 is a circuit diagram showing the configuration of the power supply voltage detecting means according to the first embodiment of the present invention. As shown in the drawing, a circuit for detecting a magnitude of a power supply voltage provided with a power supply detecting terminal VOLT1 is detected. Because of controlling the operation of the microcomputer 30 to perform the automatic temperature control function; A power supply capacitor C11 connected to the power supply voltage input terminal to drop a power supply voltage applied thereto; A voltage divider (R12, R13) connected in series between the power capacitor (C11) and a ground point to divide the power voltage applied through the power capacitor (C11) at a predetermined ratio; It is connected between the common connection point of the voltage dividing resistors R12 and R13 and the power sensing terminal VOLT1 of the microcomputer 30, and the voltage divided by the voltage dividing resistors R12 and R13 is sensed by the power supply of the microcomputer 30. It is characterized by the technical configuration that the current limiting resistor R11 is applied to the terminal VOLT1.

The power supply voltage detecting means 60 according to the first embodiment of the present invention configured as described above drops the power supply voltage applied through the power supply capacitor C11, and divides the voltage using the voltage dividing resistors R12 and R13. By adjusting the voltage dividing ratio of the voltage dividing resistors R12 and R13, the potential at the point (A) is set to a desired predetermined value.

In this case, the voltage set at the point (A) is a voltage is applied to the power sensing terminal VOLT1 of the microcomputer 30 through the current limiting resistor R11, and the current limiting resistor R11 is This is to protect the microcomputer 30 because the amount of current applied to the power detection terminal VOLT1 is controlled.

Thereafter, the microcomputer 30 detects the voltage flowing into the power sensing terminal VOLT1 by using a predetermined program to detect the magnitude of the applied power voltage.

This will be described in detail as follows. First, as shown in FIG. 3 and FIG. 4, the voltage dividing ratio of the voltage dividing resistors R12 and R13 is adjusted to set the potential at the point (A) to a constant voltage. For example, if the power supply voltage applied is 110V, the potential at the point (A) is set to 1.8V. When the power supply voltage of 220V is applied, the power supply voltage becomes 3.6V.

At this time, the microcomputer 30 counters the length of the voltage applied to the power detection terminal VOLT1 to a predetermined clock COLOCK and counts the length of the power voltage applied according to the counted value. The size will be judged.

That is, for example, if the magnitude of the voltage to be counted is set to 1.5V as shown in FIG. 4, for the 110V power supply voltage, a few count values are detected as shown in FIG. As for the power supply voltage, a plurality of count values are detected as shown in FIG. Therefore, the microcomputer 30 can determine the magnitude of the applied power voltage according to the count value. Here, the magnitude of the count clock and the set voltage can be arbitrarily adjusted.

On the other hand, an abnormality occurs in the power supply voltage detecting means 60 so that the count value continues to be generated as in part (A) of FIG. 4C, or no count value is generated as in part (B). Or when the count value is partially present, as in (C), that is, when the counted value does not form a square wave compared with the waveform of the power voltage of 60 Hz (or 50 Hz), the power voltage detection means 60 The operation is stopped by determining that an abnormality has occurred.

For example, when the power capacitor C11 is short-circuited among the elements of the power supply voltage detecting means 60, the potential at the point (a) of FIG. The output will be interrupted at the time.

In addition, when the voltage divider R12 and the current limiting resistor R11 are disconnected, the output is stopped. When the voltage divider R13 is disconnected, the output is recognized as 220V. It can protect the circuit against abnormal abnormality.

In addition, even when the power supply voltage applied as shown in FIG. 4 (d) is not normal due to an external inductive load or other causes, the magnitude of the power supply voltage applied by the above-described operation can be accurately recognized. Will be.

5 is a signal flow diagram illustrating a method for detecting a power supply voltage according to Embodiment 1 of the present invention, which is configured and operated as described above. As shown in the drawing, the microcomputer 30 is moved to a predetermined processing step because power is applied. A micom initialization step 110 for initializing; A voltage count step 120 of counting the duration of the voltage higher than the reference detection voltage set among the voltages read from the power detection terminal VOLT1 as the microcomputer 30 is initialized; A power supply voltage judging step 130 for determining the magnitude of the power supply voltage applied by comparing the count value of the voltage counted in the voltage count step 120; It is characterized in that the technical configuration is composed of an error processing step 140 to stop the operation of the microcomputer 30 because the count value counted in the voltage count step 120 is out of the specified value.

In addition, the micom initialization step 110, a reference detection voltage setting step of setting a reference voltage value of the voltage that is counted when counting a value of a predetermined voltage or more of the voltage applied from the power sensing terminal VOLT1 of the microcomputer 30 ( 111); A clock frequency setting step (112) of setting a frequency of a clock for counting a duration of a voltage higher than the reference detection voltage among voltages applied through the power detection terminal (VOLT1); The step (113) of setting an error detection frequency (2) by the error detection processing step (140); The technical configuration is characterized by a processing step 114 for initializing the values of the other coefficients.

In addition, the power voltage determination step 130 is counted because it is determined whether the voltage applied from the power detection terminal VOLT1 exists at a value that is higher than the reference detection voltage set in the initial stage of the microcomputer 110. An error detection step 150 for performing the error processing step 140 when there is no voltage value; Since there is a value counted in the error detection step 150, when the predetermined value (α) indicating that the count value is 110V by comparing the count value, it is recognized as 110V to perform the main program and then turn off the power. 110V detection step 160 for sensing and performing a series of processes; Since the count value detected in the 110V detection step 160 is not a predetermined value α indicating that the count value is 110V, 220V is recognized when the predetermined value β indicating the count value is 220V by comparing the count value. After the main program is executed, it is characterized in that the technical configuration consists of a 220V detection step 160 for performing a series of processes by detecting the power off.

In addition, the 110V detecting step 160 determines whether the value counted in the power count step 120 is a value α indicating 110V, and when it is not a value α indicating 110V, the error processing step 140. A first judging step 161 for performing; Since the count value compared and determined in the first determination step 161 is 110V, it is determined whether the waveform of the counted value forms a regular square wave with respect to the power supply voltage waveform so as not to form a regular square wave. A second judgment step 162 of performing the error processing step 140; Since the count value counted in the voltage count step 12 forms a square wave with respect to the waveform of the power supply voltage, the technical configuration includes a processing step 163 of determining the applied power supply voltage to be 110V and performing a main program. Features of the jacket.

In addition, the 220V detecting step 170 determines whether the value counted in the voltage count step 120 is a value β indicating 220V, and if it is not the value β indicating 220V, the error processing step 140. The first judging step 171 to perform; Due to the value indicating that the count value compared with the first determination step 171 is 220 V, it is determined whether the waveform of the counted value forms a regular square wave with respect to the power supply voltage waveform and thus does not form a regular square wave. A second determination step 172 for performing the error processing step 140; Since the count value counted in the voltage count step 120 forms a configuration wave with respect to the waveform of the power supply voltage, the technical configuration includes a processing step 173 for determining the applied power supply voltage to be 220V and performing a main program. Features of the jacket.

In addition, the error processing step 140, because the count value counted in the voltage count step 120 is an error that is out of the specified value, and determines the error detection frequency, if the number is not a predetermined number (2) Determination step 141 of restarting the error detection by performing a series of operations; Since the number of times of detection of the error detected in the determination step 141 is a predetermined number (2), an error message generation step 142 for generating an error message with an audible alarm sound or visual display device and ; It is characterized by the technical configuration that comprises the step 143 of stopping the operation of the microcomputer 30 after the error message occurs in the error message generation step (142). Since the detection method of the power supply voltage according to the first embodiment of the present invention configured and operated as described above has been described above, the description thereof is omitted.

However, in the first embodiment, in the voltage counting step 120, the power supply voltage is detected by counting the duration of the voltage higher than the set reference detection voltage, but detecting the time until the set reference detection voltage is detected. The magnitude of the power supply voltage may be detected based on the determined value.

As it is known, the distance between the 110V and the 220V in which the slope is set to the reference detection voltage is different, the process is as follows.

That is, the present invention according to another configuration of the first embodiment, the microcomputer initialization step of initializing the microcomputer in a predetermined processing step because the power is applied; A voltage counting step of counting the arrival time until the voltage read from the power supply detection terminal reaches the set reference detection voltage as the microcomputer is initialized; A power supply voltage determining step of determining a magnitude of a power supply voltage applied by comparing a count value of the voltage counted in the voltage counting step; The technical configuration is characterized in that it consists of an error processing step in which the microcomputer stops the operation because the count value counted in the voltage count step is out of a prescribed value. (Signal flow diagram or operation description according to another configuration of the first embodiment) Is omitted because it is almost the same as the first embodiment.)

Example 2

Embodiment 2 of the present invention relates to a second method for determining whether the applied power voltage is 110V or 220V.

That is, in the first embodiment of the present invention, in the method for determining whether the power supply voltage is 110V or 220V, the duration of the voltage of a predetermined magnitude or more is counted among the voltages applied to the power detection terminal VOLT1 of the microcomputer 30. 110V and 220V were determined by using the count value. However, in the second embodiment of the present invention, a section in which the voltage applied through the power detection terminal VOLT1 is recognized as a “HIGH voltage” and a “low” LOW) voltage ”to calculate the value of the section is to provide a method for judging 110V and 220V.

Hereinafter, a power supply voltage detection method according to Embodiment 2 of the present invention will be described with reference to the accompanying drawings.

In the power supply voltage detection method according to Embodiment 2 of the present invention, as shown in FIG. 3 and FIG. 6, the "high voltage" and the "low voltage" are applied to the voltage applied through the power detection terminal VOLT1 of the microcomputer 30. A reference voltage for recognizing "" is determined, and a section recognized as "high voltage" is detected among the voltages applied through the power detection terminal VOLT1, and a section "high voltage" is recognized in the section recognized as "low voltage". By detecting the recognized section, the difference between the section where the "high voltage" is recognized in the section that is recognized as the "low voltage" is to determine the 110V and 220V with the value of the difference (差).

In other words, first, by using the internal program of the microcomputer 30, a reference voltage which becomes a reference point for recognizing “high voltage” and “low voltage” among voltages applied to the power detection terminal VOLT1 is set. Thereafter, the voltage input through the power detection terminal VOLT1 is divided into a “high voltage” and a “low voltage” compared to the reference voltage.

For example, when the reference voltage is set to 1.2V and the voltage input through the power sensing terminal VOLT1 is 110V, the power sensing terminal VOLT1 is set as shown in FIG. The voltage waveform of 110V applied through is recognized as a "high voltage" in the section X1 between the point (a1), which is the point at which the reference voltage is 1.2V or more, and the point (b1) falling again at the reference voltage of 1.2V or less. In the section after the above (b1), it is recognized as a "low voltage" in the section (Y1) between the points (c1), which becomes 1.2 V or more, which is a reference voltage again. Similarly, when the voltage applied through the power detection terminal VOLT1 is 220V, the section (X2) and (b2) and (c2) recognized as the "high voltage" between the points (a2) and (b2) Has a period (Y2) recognized as a "low voltage" between the points.

At this time, when the voltage applied through the power detection terminal VOLT1 is 110V, the value of (Z1), which is a value obtained by subtracting the “high voltage” recognition section (Y1) from the “low voltage” recognition section (X1) formed, is As in the food [1], it becomes larger than the value of (Z2) which is the value obtained by subtracting the "high voltage" recognition section X2 from the "low voltage" recognition section X2 formed at 220V. This is obvious because both 110V and 220V have the same frequency, 60Hz (or 50Hz).

Where (X1 <X2), (Y1> Y2),

Therefore, when detecting (Z1) (Z2), which is a value obtained by subtracting the "high voltage" recognition section (X1), (X2) from the "low voltage" recognition section (Y1), (Y2), the power detection terminal (VOLT1). It is possible to detect whether the recognized power supply voltage is 110V or 220V. The detection of the sections (x1), (y1), (x2), and (y2) can be performed by counting the sections (x1), (y1), (x2), and (y2) with a predetermined clock.

In the second embodiment of the present invention configured and operated as described above, when the (Z1) and (Z2) values are detected, the (Z1) and (Z2) values are not set values. Recognizing that an error has occurred in the detecting means 60 or the microcomputer 30 stops the operation of the microcomputer 30 and other circuits, so that the circuit can be protected even when a sudden abnormal state occurs. Of course, it is possible to take effective measures even when the power supply voltage is not constant due to external causes.

FIG. 7 is a signal flow diagram illustrating a method for detecting a power supply voltage according to Embodiment 2 of the present invention, which is configured and operated as described above. As shown in FIG. A micom initialization step 21 for initializing; A voltage count step 220 for counting the duration of "high voltage" and "low voltage" because the microcomputer 30 reads the voltage from the power detection terminal VOLT1 and compares it with the set reference voltage according to the initial call; Voltage determination step 23 of recognizing the applied voltage as 110V or 220V by processing the “high voltage” duration section S1 and the “low voltage” duration section S2 detected in the voltage count step 220. )Wow; The error processing step of generating an error due to the "high voltage" duration section S2 detected in the voltage count step 22 is not a value Z1 determined as 110V or a value Z2 determined as 220V. 240) is characterized by its technical configuration.

In addition, the microcomputer initialization step 210, a reference voltage setting step of setting a voltage that is a reference for judging the voltage applied from the power sensing terminal VOLT1 of the microcomputer 30 as "high voltage" and "low voltage" ( 211); A clock frequency setting step 212 for setting a frequency of a clock for counting the duration of the "high voltage" and "low voltage"; A 110V recognition reference value setting step 213 for setting a reference value Z1 as a reference for determining that the applied power voltage is 110V; A 220V recognition reference value setting step 214 for setting a reference value Z2 as a reference for determining that the applied power voltage is 220V; Setting (215) an error detection frequency (P) of the error processing step (240); The technical configuration is characterized by a process step 216 for initializing the values of the other coefficients.

In addition, the power counting step 22 compares the voltage value read from the power sensing terminal VOLT1 of the microcomputer 30 with the reference voltage set in the reference voltage setting step 211 to maintain the duration of the “high voltage”. The high voltage count step 250 for counting (S1); and the low voltage count step 260 for counting the duration S2 of the "low voltage" are characterized by the technical constitution.

The voltage judging step 230 may further include a "high voltage" duration section value counted in the high voltage count step 250 from the "low voltage" duration section value S2 counted in the low voltage count step 260. When the value S3 obtained by subtracting (S1) from the value S3 is compared with the value Z1 set in the 110V recognition reference value setting step 213, it is determined that the applied power voltage is 110V and the predetermined main voltage is determined. A 110V detection step 270 for executing a program; A value obtained by subtracting (decreasing) the "low voltage" duration section value S1 counted in the low voltage count step 250 from the "low voltage" duration section value S2 counted in the low voltage count step 260. (S3) is compared with the value Z2 set in the 220V recognition reference value setting step 213, and if they are equal to each other, the 220V detection step 28 of determining the applied power supply voltage to be 220V and performing a predetermined main program (28). It is characterized by its technical configuration.

In addition, the error processing step 240 is a value (Z1) which determines that the "high voltage" duration section value S1 and the "low voltage" duration section value S2 detected in the voltage count step 220 is 110V. When the error occurs due to not being the value (Z2) which is determined as 220V, if the number of error occurrences is detected and the number is not the predetermined number (P), a series of operations are performed to resume error detection. A decision step 241; Since the number of times of detecting the error detected in the determination step 241 is a predetermined number P, an error message generation step 242 for generating an error message in an audible alarm sound or visual display device and ; It is characterized in that the technical configuration consists of a step (243) to stop the operation of the microcomputer 30 after generating an error message in the error message generation step (242). Since the detection method of the power supply voltage according to Embodiment 2 of the present invention configured and operated as described above has been described above, the description thereof will be omitted.

As described above, the power supply voltage detection device and method of the 110V / 220V thermostat of the present invention changes the routine (ROUTNE) of the power supply voltage detection program inside the microcomputer, so that the power supply voltage detection unit is destroyed or It is a very useful invention that can protect the circuit safely even when the power detecting terminal is destroyed, and also prevent the malfunction caused by the fluctuation of the applied power voltage or external noise.

Claims (13)

A microcomputer that performs an automatic temperature control function by detecting a magnitude of a power voltage applied by a power supply detecting terminal and controlling an operation of each circuit part; A power supply capacitor connected to the power supply voltage applying terminal to drop a power supply voltage applied thereto; A first voltage divider and a second voltage divider connected in series between the power capacitor and the ground point to divide the power voltage applied through the power capacitor at a predetermined ratio; A current connected between the common connection point of the first voltage divider resistor and the second voltage divider resistor and a power supply terminal of the microcomputer, and applying a voltage divided by the first voltage divider resistor and the second voltage divider resistor to the power detection terminal of the microcomputer; Power supply voltage detector of a 110V / 220V combined thermostat, characterized by consisting of a limiting resistor. A microcomputer initialization step of initializing the microcomputer with a predetermined processing step due to the power being applied; A voltage count step of reading a voltage from a power detection terminal as the micom is initialized and counting a duration of a voltage higher than a set reference detection voltage among the voltages generated; A power supply voltage judging step of judging the magnitude of the applied power supply voltage by comparing the count value counted in the voltage count step; And an error processing step of stopping the operation of the microcomputer and the circuit part due to the count value counted in the voltage count step being out of a prescribed value. 3. The method of claim 2, wherein the initial step of the microcomputer comprises: a reference detection voltage setting step of setting a reference voltage value of a voltage that is counted when a value of a predetermined voltage or more is counted among voltages applied from a power sensing terminal of the microcomputer; A clock frequency setting step of setting a frequency of a clock for counting a duration of a voltage higher than the reference detection voltage among the voltages applied through the power detection terminal, and setting an error detection frequency of the error detection processing step; ; The power supply voltage detection method of a 110V / 220V dual-purpose thermostat, characterized in that configured to initialize the value of the other coefficients. The method of claim 2, wherein the power voltage judging step determines whether a value that is counted because the voltage applied from the power detection terminal is higher than the reference detection voltage set in the microcomputer initialization step exists. An error detection step of performing the error processing step if not; Since there is a value counted in the error detection step, when the predetermined value indicating that the count value is 110V by comparing the count value, the 110V detection step of performing a series of processes after performing the main program to 110V and ; Since the count value detected in the 110V detection step is not a predetermined value indicating that it is 110V, when the count value is a predetermined value indicating that the count value is 220V, the controller recognizes 220V and executes a main program. Power supply voltage detection method of a 110V / 220V dual-purpose thermostat, characterized in that the 220V detection step to perform the process. The method of claim 4, wherein the detecting of the 110V comprises: a first judging step of determining whether the count value is 110V in the voltage counting step and performing the error processing step if the value is not 110V; Since the count value compared with the first determination step is 110V, it is determined that the waveform of the counted value forms a regular square wave with respect to the power voltage waveform. A second judging step of performing an error processing step; Since the count value counted in the voltage count step forms a square wave with respect to the waveform of the power supply voltage, the 110V / 220V combined automatic temperature control is configured to perform a main program by determining the applied voltage as 110V. Method for detecting power supply voltage of a device. The method of claim 4, wherein the detecting of the 220V comprises: a first determining step of determining whether the value counted in the voltage counting step is 220V and performing the error processing step when the value is not 220V; Since the count value compared with the first determination step is 220V, it is determined whether or not a regular square wave is formed by determining whether the waveform of the counted value forms a regular square wave with respect to the power voltage waveform. A second judging step of performing an error processing step; Since the count value counted in the voltage count step forms a square wave with respect to the waveform of the power voltage, the 110V / 220V combined automatic temperature is characterized in that it is configured to perform a main program by determining the applied power voltage as 220V. Method of detecting power supply voltage of regulator. The method according to claim 2, wherein the error processing step is determined because the count value counted in the voltage count step is an error that deviates from a prescribed value. A determination step of restarting error detection by performing; The error detection time detected in the determination step is a predetermined number, and thus, an error message is generated in an audible alarm sound or a visual display device. Method for detecting power supply voltage of 110V / 220V combined thermostat. An initialization step of initializing the microcomputer with a predetermined processing step due to the power being applied; A voltage counting step of counting the arrival time until the voltage read from the power supply detection terminal reaches the set reference detection voltage as the microcomputer is initialized; A power supply voltage determining step of determining a magnitude of a power supply voltage applied by comparing a count value of the voltage counted in the voltage count step; And an error processing step of stopping the operation of the microcomputer due to the count value counted in the voltage count step being out of a prescribed value. A microcomputer initialization step of initializing the microcomputer with a predetermined processing step due to the power being applied; A voltage count step of counting the duration of "high voltage" and "low voltage" due to the voltage reading from the power detection terminal as compared with the set reference voltage as the microcomputer is initialized; A voltage judging step of recognizing a power supply voltage applied by processing the “high voltage” duration section value and the “low voltage” duration section value detected in the voltage count step as 110V or 220V; The error processing step of generating an error occurs because the value of the "high voltage" persistence interval detected in the voltage count step and the "low voltage" duration interval are not 110V or 220V. Method for detecting power supply voltage of 110V / 220V combined thermostat. 10. The method of claim 9, wherein the initializing of the microcomputer comprises: a reference voltage setting step of setting a reference voltage for determining a voltage applied from a power supply detecting terminal of the microcomputer as a "high voltage" and a "low voltage"; A clock frequency setting step of setting a frequency of a clock for counting a duration of the "high voltage" and "low voltage"; A 110V recognition reference value setting step of setting a reference value as a reference for determining that the applied power voltage is 110V; A 220V recognition reference value setting step of setting a reference value as a reference for determining that the applied power voltage is 220V; Setting the number of error detections in the error processing step; A power supply voltage detection method for a 110V / 220V dual-purpose thermostat, comprising a processing step of initializing values of other coefficients. The high voltage counting step of claim 9, wherein the voltage counting step compares a voltage value read from the power supply detecting terminal of the microcomputer with a reference voltage set in the reference voltage setting step and counts the duration of the “high voltage”. Wow; A low voltage count step of counting the duration of a "low voltage", characterized in that the power supply voltage detection method for a 110V / 220V thermostat. 10. The method of claim 9, wherein the voltage judging step is a value obtained by subtracting (decreasing) the "low voltage" duration interval value counted in the high voltage count step from the "low voltage" duration interval counted in the low voltage count step. A 110V detection step of performing a predetermined main program by determining the applied power supply voltage as 110V when comparing the values set in the 110V recognition reference value setting step with each other; The value set in the 220V recognition reference value setting step is a value obtained by subtracting (decreasing) the value of the "low voltage" persistence interval counted in the low voltage count step from the "high voltage" persistence interval value counted in the high voltage count step. Compared with each other, the power detection method of the 110V / 220V dual-purpose thermostat, characterized in that it consists of a 220V detection step of performing a predetermined main program by determining the applied power voltage to 220V. 10. The method of claim 9, wherein the error processing step is because the value of the "high voltage" and "low voltage" durations detected in the voltage count step is not 110V or 220V. A detection step of detecting an error occurrence frequency and performing a series of operations to restart error detection when an error occurs. An error message generating step of generating an error message in an audible alarm sound or visual display device because the detected number of errors detected in the determination step is a predetermined number of times; And stopping the operation of the microcomputer and the circuit unit after generating an error message in the error message generation step.