KR20050120265A - A apparatus to watch input voltage and a voltage watching method - Google Patents

Abstract

The present invention relates to an input voltage monitoring device and a voltage monitoring method, and an object of the present invention is to provide an input voltage monitoring device and a voltage monitoring method capable of monitoring an input voltage input to an electric device. The present invention also provides an input voltage monitoring device and a voltage monitoring method capable of measuring the magnitude of an input voltage using a zero crossing detection circuit. In addition, the present invention provides an input voltage monitoring device and a voltage monitoring method for shutting off power applied to an electric device when an unrated voltage is input and applying power to the electric device when an input voltage is restored to a rated voltage.

To this end, the present invention includes an input voltage detector for generating a high or low signal according to the magnitude of an input voltage input to an electric device, and a microcomputer for determining the magnitude of the input voltage by measuring a duration of the high or low signal. It is characterized by.

Description

A apparatus to watch input voltage and a voltage watching method}

The present invention relates to an input voltage monitoring device and a voltage monitoring method, and more particularly, to an input voltage monitoring device and a voltage monitoring method for monitoring a magnitude of a voltage input to an electric device.

In general, an electric device (for example, an air conditioner) can operate normally when a rated voltage is input so that commercially available electric devices are provided with means for protecting the electric device from overvoltage.

An overvoltage protection device of a conventional air conditioner includes a varistor (Variable transistor) connected in parallel to the front end of the rectifier for rectifying the input AC current to convert the DC current, and a fuse connected in series between the varistor and the AC power supply. do. In addition, the rear end of the rectifier is provided with a main circuit unit for receiving the rectified DC current supplied to each device of the air conditioner.

When AC power is applied to such an air conditioner, the AC current is rectified as a DC current at the rectifier and supplied to each device. At this time, if the input AC voltage exceeds the range of the rated voltage, the resistance of the varistor becomes small, the current flows through the varistor, and the fuse installed at the front of the varistor is blown to prevent the overvoltage from flowing to the rectifier.

However, the overvoltage protection device of the conventional air conditioner can protect the circuits of the air conditioner by breaking the fuse when the overvoltage is applied to the air conditioner, but the air conditioner is restored even if the input voltage is restored to normal before replacing the blown fuse. There was a problem that can not be used again.

The present invention is to solve the above problems, an object of the present invention to provide an input voltage monitoring device and a voltage monitoring method that can monitor the input voltage input to the electrical device.

The present invention also provides an input voltage monitoring device and a voltage monitoring method capable of measuring the magnitude of an input voltage using a zero crossing detection circuit.

In addition, the present invention provides an input voltage monitoring device and a voltage monitoring method for shutting off power applied to an electric device when an unrated voltage is input and applying power to the electric device when an input voltage is restored to a rated voltage.

The present invention for achieving the above object is an input voltage detector for generating a high or low signal according to the magnitude of the input voltage input to the electrical device, by measuring the duration of the high or low signal to determine the magnitude of the input voltage Characterized in that it comprises a microcomputer.

The input voltage detector may output a pulse wave in which the high and low signals are alternately maintained, and the microcomputer determines the magnitude of the input voltage by measuring a pulse width of the pulse wave.

The input voltage detector is a zero crossing detector configured to generate a high signal when the magnitude of the input voltage is less than or equal to the reference voltage and to generate a low signal when the magnitude of the input voltage is greater than or equal to the reference voltage. If the width is greater than the reference value, the input voltage is a low voltage, and if the pulse width is smaller than the reference value, it is determined that the input voltage is an overvoltage.

The input voltage detector may output a pulse wave in which the high and low signals persist, and the microcomputer determines the magnitude of the input voltage by calculating a duty ratio of the pulse wave.

The input voltage detector is a zero crossing detector configured to generate a high signal when the absolute value of the input voltage is less than or equal to the reference voltage and to generate a low signal when the absolute value of the input voltage is greater than or equal to the reference voltage. If the ratio is greater than the reference value, the input voltage is a low voltage, and if the duty ratio is less than the reference value, the input voltage is determined to be overvoltage.

The input voltage may be an AC voltage, and the duty ratio may vary according to the magnitude of the maximum value of the AC voltage when the AC voltage is the same period.

The microcomputer may control to cut off power input to the electric device when the input voltage is determined to be overvoltage.

In addition, a high or low signal is generated corresponding to the magnitude of the input voltage input to the electric device, the duration of the high or low signal is measured, and the magnitude of the input voltage is determined according to the length of the duration. It is done.

The high and low signals may be output as pulse waves having different duty ratios according to the duration, and the magnitude of the input voltage may be determined by calculating the duty ratio of the pulse waves.

In addition, the voltage monitoring method is characterized in that the input voltage input to the electrical device is cut off if the magnitude of the input voltage is overvoltage.

Hereinafter, a first embodiment of the present invention will be described with reference to FIGS. As shown in FIG. 1, the input voltage monitoring device according to the first embodiment of the present invention includes a zero crossing detection unit 10 for detecting a zero crossing of an AC power supply 33, and a pearl output from the zero crossing detection unit 10. A power supply for supplying or disconnecting power to each device of the air conditioner such as the compressor 31 and the blower 32 by the control signal of the microcomputer 20 and the microcomputer 20 that determines the magnitude of the input voltage using the spar. And a relay 30.

The zero crossing detection unit 10 includes a photocoupler 11, a plurality of resistors R1 and R2 connected to an input of the photocoupler 11, and a pull-up resistor R3 connected to an output of the photocoupler 11. do. At this time, the input of the photocoupler 11 is composed of a photo triac 12 which emits light when a current of a predetermined value or more flows, and the output of the photo coupler 11 is a photo receiving the light emitted from the photo triac 12 It consists of a transistor 13.

If the AC voltage input to the zero crossing detection unit 10 is equal to or less than the reference voltage, the current flowing through the phototriac 12 does not emit the phototriac 12 and the phototransistor 13 is turned off, and the microcomputer ( 20, a high signal is input.

However, when the AC voltage inputted to the zero crossing detection unit 10 is equal to or higher than the reference voltage, the phototriac 12 emits light and the photo transistor 13 is turned on, so a low signal is input to the microcomputer 20. The reference voltage is determined by the plurality of resistors R2 and R3 connected to the input of the photo coupler 11.

A pulse wave output from the zero crossing detection unit of FIG. 1 will be described with reference to FIG. 2, a is an AC voltage input to the air conditioner, b is a pulse wave output from the zero crossing detecting unit 10 when the AC voltage is an overvoltage (A), and c is a zero crossing when the AC voltage is a rated voltage (B). The pulse wave output from the detection unit 10, d is a pulse wave output from the zero crossing detection unit 10 when the AC voltage is a low voltage (C).

As shown in the b, c and d graphs of FIG. 2, when the AC voltage exceeds the reference voltage, the zero crossing detection unit 10 continuously outputs a low signal L, and the AC voltage is lower than the reference voltage. If the state is maintained, the zero crossing detection unit 10 continuously outputs the high signal H, so that the output waveform of the zero crossing detection unit 10 becomes a pulse wave.

In addition, the pulse wave output from the zero crossing detection unit 10 gradually increases in duty ratio or pulse width as the maximum magnitude of the AC voltage decreases in the same period. That is, when the AC voltage is an overvoltage (A), the duty ratio or pulse width is relatively smaller than when the AC voltage is the rated voltage (B) (see FIG. 2C), and the AC voltage is At the low voltage C, the duty ratio or the pulse width becomes larger than when the AC voltage is at the rated voltage (see c in FIG. 2) (see d in FIG. 2).

Therefore, when the duty ratio or pulse width of the pulse wave output from the zero crossing detecting unit 10 and input to the microcomputer 20 is calculated, the magnitude of the input AC voltage can be known. For example, if the reference range of the duty ratio when the rated voltage (220 ~ 230V) is input is 40 ~ 45%, the calculated duty ratio is less than 40%, the input voltage is overvoltage, and the calculated duty ratio exceeds 45% The input voltage may be determined to be a low voltage, and the magnitude of the input voltage corresponding to each duty ratio may also be determined.

For example, if the reference range of the pulse width when the rated voltage (220 ~ 230V) is input is 0.05 ~ 0.08ms, the measured pulse width is less than 0.05ms, the input voltage is overvoltage, the measured pulse width is 0.08 If ms is exceeded, it may be determined that the input voltage is a low voltage, and the magnitude of the input voltage corresponding to each pulse width may also be determined.

At this time, the microcomputer 20 stores data in which the duty ratio or pulse width values corresponding to the magnitude of the input voltage are arranged in advance.

A voltage monitoring operation of the input voltage monitoring device shown in FIG. 1 will be described with reference to FIG. When power is supplied to the air conditioner provided with the input voltage monitoring device, the zero crossing detection unit 10 outputs a pulse wave, and the output pulse wave is input to the microcomputer 20 (40).

The microcomputer 20 calculates the duty ratio of the input pulse wave (42), and determines whether the calculated duty ratio is within the reference range (44). At this time, the reference range is the duty ratio range of the pulse wave output when the input voltage is the rated voltage.

If the duty ratio is not the reference range, it is determined whether the calculated duty ratio is smaller than the reference range (46). Here, if the duty ratio is less than the reference range, it is determined that the input voltage is an overvoltage greater than the rated voltage (48), and transmits a control signal to the power supply relay 30 to the compressor 31 or the blower fan 32 of the air conditioner. The power applied to the device, such as to cut off (50). However, if the duty ratio is greater than the reference range, it is determined that the input voltage is a low voltage smaller than the rated voltage (52) and returns to step 40.

On the other hand, if the duty ratio is the reference range in step 44 it is determined that the input voltage is a normal voltage (54) and returns to step 40.

In FIG. 3, only whether the input voltage is an overvoltage or a low voltage is determined. However, the duty ratio may be used to determine the magnitude of the input voltage. In addition, although the magnitude of the input voltage is determined using the duty ratio in FIG. 3, the magnitude of the input voltage may be determined by calculating the pulse width.

Hereinafter, a second embodiment of the present invention will be described with reference to FIGS. 4 and 5. In FIG. 4, the configuration except for the zero crossing detection unit 60 is the same as that of FIG. 1, and the description thereof is the same as that of the corresponding part of FIG. 1.

In FIG. 4, the zero crossing detection unit 60 includes a bridge diode 61 for full-wave rectifying the AC current input from the power supply 33, a photo coupler 62, and a plurality of resistors connected to the input of the photo coupler 62. R4 and R5 and reverse voltage prevention diode 65 and pull-up resistor R6 connected to the output of the photo coupler 62. At this time, the input of the photo coupler 62 is formed of a photo diode 63 which emits light when a current of a predetermined value or more flows, and the output of the photo coupler 62 is a photo transistor (receiving light emitted from the photo diode 63). 64).

If the full-wave rectified voltage input to the zero crossing detection unit 60 is equal to or less than the reference voltage, the current flowing through the photodiode 63 does not emit the photodiode 63 and the photo transistor 64 is turned off, and the microcomputer 20 ), A high signal is input.

However, when the full-wave rectified voltage input to the zero-crossing detecting unit 60 is equal to or higher than the reference voltage, the photodiode 63 emits light and the photo transistor 64 is turned on so that a low signal is input to the microcomputer 20. Here, the reference voltage is determined by R4 connected to the input of the photo coupler.

The pulse wave output from the zero crossing detection unit 60 of FIG. 4 will be described with reference to FIG. In Fig. 5, a is a full-wave rectified voltage input to the photo coupler 62, b is a pulse wave of the zero-crossing detecting unit 60 when the full-wave rectified voltage is overvoltage D, and c is a full-wave rectified voltage at rated voltage E. Is a pulse wave of the zero crossing detection unit 60 when d is a pulse wave of the zero crossing detection unit 60 when the full-wave rectified voltage is low voltage (F).

As shown in the b, c, and d graphs of FIG. 5, when the full-wave rectified voltage exceeds the reference voltage, the zero crossing detection unit 60 continuously outputs a low signal L, and the full-wave rectified voltage is referenced. When the state below the voltage is maintained, the zero crossing detection unit 60 continuously outputs the high signal H so that the output waveform of the zero crossing detection unit 60 becomes a pulse wave.

Similarly to the first embodiment, in the second embodiment, the duty ratio or the pulse width gradually increases as the pulse wave output from the zero crossing detection unit decreases as the maximum magnitude of the full-wave rectified voltage in the same period. Therefore, the method of determining the magnitude of the input voltage by calculating the duty ratio or the pulse width of the pulse wave output from the zero crossing detection unit is the same as that of the first embodiment.

Meanwhile, the zero crossing detection unit to which the present invention can be applied may be used in various forms as well as the types illustrated in the first and second embodiments.

As described above in detail, according to the present invention, the magnitude of the input voltage can be measured using a zero crossing detection circuit.

In addition, when the non-rated voltage is input to the electrical device can be cut off the power to protect the electrical device.

In addition, when the rated voltage is input even after the non-rated voltage is input and the power is cut off, the system can be driven again by applying power.

1 is a circuit diagram showing an input voltage monitoring apparatus according to a first embodiment of the present invention.

FIG. 2 is a diagram illustrating a pulse wave output from the input voltage monitoring device of FIG. 1.

FIG. 3 is a flowchart showing the operation of the input voltage monitoring device shown in FIG.

4 is a circuit diagram showing an input voltage monitoring apparatus according to a second embodiment of the present invention.

FIG. 5 is a diagram illustrating a pulse wave output from the input voltage monitoring device of FIG. 4.

* Description of the code for the main functions of the drawings

            10,60: Zero crossing detection part 11,62: Photo coupler

            12: phototriac 13,64: phototransistor

            30: power supply relay 63: photodiode

Claims (10)

Input voltage detection unit for generating a high or low signal according to the magnitude of the input voltage input to the electrical device, And a microcomputer for measuring the duration of the high or low signal to determine the magnitude of the input voltage. The method of claim 1, The input voltage detector outputs a pulse wave in which the high and low signals are alternately maintained, and the microcomputer determines the magnitude of the input voltage by measuring a pulse width of the pulse wave. The method of claim 2, The input voltage detector is a zero crossing detector configured to generate a high signal when the absolute value of the input voltage is less than or equal to the reference voltage and to generate a low signal when the absolute value of the input voltage is greater than or equal to the reference voltage. The input voltage monitoring device, characterized in that if the input voltage is greater than the reference value and the input voltage is a low voltage and the pulse width is less than the reference value, the input voltage is overvoltage.  The method of claim 1, The input voltage detector outputs a pulse wave sustaining the high and low signals, and the microcomputer calculates the duty ratio of the pulse wave to determine the magnitude of the input voltage. The method of claim 4, wherein The input voltage detector is a zero crossing detector that generates a high signal when the absolute value of the input voltage is less than or equal to the reference voltage and generates a low signal when the absolute value of the input voltage is greater than or equal to the reference voltage. The input voltage monitoring device, characterized in that the input voltage is a low voltage if the reference value is larger than the reference value and the input voltage is an overvoltage if the duty ratio is less than the reference value. The method of claim 5, The input voltage is an AC voltage, the input voltage monitoring device, characterized in that the duty ratio is changed corresponding to the magnitude of the maximum value of the AC voltage when the AC voltage is the same period The method of claim 1, The microcomputer input control device, characterized in that for controlling the power supply to the electrical device is cut off when the input voltage is determined to be overvoltage Generates a high or low signal in accordance with the magnitude of the input voltage input to the electrical device, Measure the duration of the high or low signal, The voltage monitoring method of the input voltage monitoring device, characterized in that for determining the magnitude of the input voltage according to the length of the duration. The method of claim 8, The high and low signals are output as pulse waves having different duty ratios according to the duration, and the magnitude of the input voltage is determined by calculating the duty ratio of the pulse waves. The method of claim 8, The voltage monitoring method of the voltage monitoring method of the input voltage monitoring device, characterized in that for blocking the input voltage input to the electrical device if the magnitude of the input voltage is overvoltage.