KR100544183B1 - High voltage power supply and method correcting a output current performed by the apparatus - Google Patents

Abstract

A high voltage power supply device and an output current correction method performed in the device are disclosed. This device receives pulse width modulated signal optimized for environmental characteristics and converts it into DC voltage, and outputs the output current from fly's width modulated signal processor and flyback transformer to output the pulse width modulated signal converted to DC voltage as a reference signal. And a drive control signal generator for outputting a drive control signal of the switching unit by comparing the signal with a reference signal, and an output current detector for detecting the output current signal. Therefore, according to the present invention, the magnitude of the current output from the high voltage power supply device can be varied according to the characteristics of the surrounding environment, and the varied output current can be output uniformly without an output error.

Description

High voltage power supply and method correcting a output current performed by the apparatus}

1 is a block diagram of an embodiment for explaining the high-voltage power supply apparatus according to the present invention.

2 is a circuit diagram of the high-voltage power supply apparatus according to the present invention shown in FIG.

3 is a waveform diagram illustrating an example of a pulse width modulated signal input to the pulse width modulated signal processor 10.

4 is a diagram illustrating waveforms of a reference signal output by the pulse width modulation signal processor shown in FIG. 1 and an output current signal output by the flyback transformer.

5 is a flowchart of an embodiment for explaining an output current correction method performed in the high voltage power supply according to the present invention.

<Brief description of the major symbols in the drawings>

10: pulse width modulated signal processor 20: drive control signal generator

30: output current detection unit 40: switching unit

50: Flyback Transformer

The present invention relates to a high voltage power supply device used in a laser printer or a multifunction device, and more particularly, it is possible to vary the magnitude of the output current output from the high voltage power supply device according to the environmental characteristics, and the changed output current may The present invention relates to a high voltage power supply device and a method for compensating output current performed in the device.

A multifunction printer or a laser printer having a printing function shoots a laser beam on an electrostatically charged photosensitive drum, creates a latent image of a character or image of one page to be printed, and develops by spraying toner. A multifunction printer or laser printer having a printing function fixes a developed character or image on printing paper, thereby outputting printed matter on which the character or image is printed.

Multifunction devices or laser printers, etc., require a high voltage current to perform the above functions. In order to obtain a high voltage current, a multifunction printer or a laser printer is provided with a high voltage power supply. The high voltage power supply includes a signal input unit, a switching driving control unit, a switching unit, and a fly back transformer (FBT) to output a high voltage current. The signal input unit receives an enable signal corresponding to a control signal of whether to output a high voltage current from the CPU. The switching driving control unit outputs a control signal for driving the switching unit according to the enable signal. The switching unit generates a voltage at the primary side of the flyback transformer according to a control signal input from the switching driving controller. The flyback transformer boosts the voltage generated in the primary coil and outputs it to the output terminal of the secondary coil. The flyback transformer rectifies and outputs the boosted current.

However, conventionally, if the central processing unit decides whether to simply turn on or turn off the output current of the high voltage power supply without considering the change in the surrounding environment, and outputs it as an enable signal, the high voltage power supply may be The output current is turned on or off depending on the enable signal. Therefore, the conventional high-voltage power supply device is impossible to control the output current according to the ambient environment, that is, the temperature or humidity, it is difficult to form a uniform potential in the photosensitive drum, there is a disadvantage that it is difficult to expect a high quality image. In addition, there is a problem that the output current is not evenly output from the flyback transformer due to the device characteristics or other causes inherent in the electronic device used in the high-voltage power supply.

An object of the present invention is to provide a high-voltage power supply device capable of varying the output current according to environmental characteristics and generating a uniform output current without an output error.

Another object of the present invention is to provide an output current correction method performed in the aforementioned high voltage power supply device.

In order to achieve the above object, the high-voltage power supply apparatus according to the present invention receives a pulse width modulated signal optimized for environmental characteristics, converts it into a DC voltage, and outputs a pulse width modulated signal converted into a DC voltage as a reference signal. It is preferable that the modulation signal processing unit, a drive control signal generator for outputting the drive control signal of the switching unit by comparing the output current signal output from the flyback transformer and the reference signal and the output current detection unit for detecting the output current signal.

In order to achieve the above another object, the output current correction method performed in the high-voltage power supply apparatus according to the present invention receives a pulse width modulation signal optimized for environmental characteristics and converts it into a DC voltage, pulse width modulation converted to DC voltage Comparing the signal with the output current signal detected at the secondary side of the flyback transformer as a reference signal, generating a drive control signal of the switching unit, generating a modified voltage at the primary side of the flyback transformer, It is preferable to generate an output current signal corrected in the output error on the secondary side of the flyback transformer and to detect the output current signal generated on the secondary side of the flyback transformer.

Hereinafter, a high voltage power supply according to the present invention will be described with reference to the accompanying drawings.

1 is a block diagram of an embodiment for explaining a high-voltage power supply apparatus according to the present invention, a pulse width modulated signal processor 10, a drive control signal generator 20, an output current detector 30, a switching unit 40 ) And fly back transformer (FBT). 2 is a circuit diagram of the high-voltage power supply apparatus according to the present invention shown in FIG.

The pulse width modulated signal processor 10 receives a pulse width modulated signal optimized for environmental characteristics through an input terminal IN1, converts the pulse width modulated signal into a DC voltage, and outputs the pulse width modulated signal converted into the DC voltage as a reference signal. Pulse modulation refers to the transformation of voice signals or other signal waves into pulses. There are continuous level modulation in which the amplitude, width or position of a pulse changes continuously according to the magnitude of the signal wave, and discontinuous level modulation in which the number or position of unit pulses changes. Pulse width modulation (PWM) among continuous level modulation is a method of modulating by changing the width of the pulse in accordance with the magnitude of the signal wave. When the amplitude of the signal wave is large, the width of the pulse becomes large. When the amplitude of the deep wave is small, the width of the pulse becomes small. However, the position and amplitude of the pulse do not change. The signal generated by the pulse width modulation is a pulse width modulation signal. The pulse width modulated signal processor 10 receives a pulse width modulated signal under the control of a central processing unit (CPU) (not shown). The pulse width of the pulse width modulated signal is controlled by the central processing unit in accordance with the environmental characteristics.

3 is a waveform diagram illustrating an example of a pulse width modulated signal input to the pulse width modulated signal processor 10.

For example, when using a laser printer, when the environmental characteristics of temperature or humidity are poor and it is necessary to increase the output current, a pulse width modulated signal such as the waveform diagram shown in FIG. It is input to the pulse width modulation signal processor 10. If the environmental characteristics of temperature or humidity are appropriate when using a laser printer, the output current does not need to be excessive. Therefore, a pulse width modulated signal such as the waveform diagram shown in FIG. The pulse width modulation signal processor 10 is input to the pulse width modulated signal processor 10 under the control of.

The pulse width modulated signal processor 10 uses a low pass filter (LPF) as illustrated in FIG. 2 to convert the input pulse width modulated signal into a DC voltage. The low pass filter is a filter for passing only a low frequency below a predetermined frequency, and converts the pulse width modulated signal into a DC voltage in the capacitor C1 of FIG. 2. The pulse width modulated signal processor 10 outputs the pulse width modulated signal converted into a DC voltage to the driving control signal generator 20 as a reference signal.

4 is a diagram illustrating waveforms of the reference signal 70 output by the pulse width modulation signal processing unit 10 and the output current signal 80 output by the flyback transformer 50 shown in FIG. 1. For example, when the pulse width modulation signal illustrated in FIG. 3A is input by the pulse width modulation signal processing unit 10, a DC voltage waveform corresponding to? Of the reference signal 70 is output, and FIG. 3. When the pulse width modulation signal shown in (b) of FIG. 3 is input, the DC voltage waveform corresponding to ② of the reference signal 70 is output. When the pulse width modulation signal shown in (c) of FIG. 3 is input, the reference signal ( The DC voltage waveform corresponding to ③ in 70) is output.

The driving control signal generator 20 compares an output current signal output from the flyback transformer 50 with a reference signal, and outputs a driving control signal for driving the switching unit 40. The output current signal output from the flyback transformer 50 is input from the output current detector 30. The output current signal 80 shown in FIG. 4 is a current signal actually output from the flyback transformer 50. For example, the driving control signal generator 20 compares the reference signal 70 shown in FIG. 4 with the output current signal 80. That is, the driving control signal generation unit 20 senses an error degree between the output current signal 80 and the reference signal 70, and when the output current signal is lower than the reference signal, the voltage higher than the previously output driving control signal. The driving control signal of the output to the switching unit 40, when the output current signal is higher than the reference signal outputs the driving control signal of a voltage lower than the previously output drive control signal to the switching unit 40.

The output current detector 30 detects an output current signal. The output current detector 30 provides a bipolar operational amplifier OP2 as shown in FIG. 2 to detect an output current signal output from the secondary side of the flyback transformer 50. The output current detection unit 30 can detect the output current signal by a simple component by using the bipolar operational amplifier OP2.

The switching unit 40 performs a switching operation to generate a modified voltage on the primary side of the flyback transformer 50 in response to the driving control signal input from the driving control signal generator 20. Upon receiving the input, the switching unit 40 performs a switching operation, so that the modified voltage is generated on the primary side of the flyback transformer 50. For example, when a driving control signal having a voltage higher than the previous driving control signal is applied, the switching unit 40 switches so that a higher voltage is oscillated on the primary side of the flyback transformer 50 and then, than the previous driving control signal. When a low voltage driving control signal is applied, the switching unit 40 switches so that a low voltage is oscillated on the primary side of the flyback transformer 50.

The secondary side of the flyback transformer 50 outputs an output current signal whose output error is corrected by the voltage corrected at the primary side through the output terminal OUT1. The flyback transformer 50 boosts the voltage corrected by the switching operation of the switching unit 40 using a coil, rectifies the boosted current and outputs it as an output current signal. The output current signal is supplied for printing of a printer or the like, and is also applied to the output current detector 30.

Hereinafter, an output current correction method performed in the high voltage power supply apparatus according to the present invention will be described with reference to the accompanying drawings.

FIG. 5 is a flowchart illustrating an output current correction method performed in a high voltage power supply according to the present invention. The output is corrected by driving a switching unit using a signal generated by comparing a reference signal and an output current signal. Generating a current signal (steps 100 to 108).

First, a pulse width modulation signal optimized for environmental characteristics is received and converted into a DC voltage (step 100). The pulse width modulated signal optimized for the environmental characteristics is generated and supplied by the control of the central processing unit. In operation 100, the pulse width modulated signal is converted into a DC voltage using a low pass filter.

After the 100th step, the pulse width modulation signal converted into the DC voltage is compared with the output current signal detected at the secondary side of the flyback transformer 50 as a reference signal to generate a drive control signal of the switching unit 40 ( Step 102). Step 102 is a step of comparing the output current signal and the reference signal using a proportional integration controller.

After step 102, a modified voltage is generated on the primary side of the flyback transformer 50 (step 104).

After step 104, an output current signal having an output error corrected on the secondary side of the flyback transformer 50 is generated by the modified voltage (step 106).

After step 106, an output current signal generated at the secondary side of the flyback transformer 50 is detected (step 108). In operation 108, the output current signal is detected using a bipolar operational amplifier.

As described above, the high voltage power supply device and the output current correction method performed by the device may vary the magnitude of the output current output from the high voltage power supply device according to environmental characteristics. In addition, there is an effect that the uniform current can be output to the output error of the current, which must be caused by the characteristics of the electronic device.

Claims (8)

In the high voltage power supply having a switching unit and a flyback transformer, A pull width modulated signal processor configured to receive a pulse width modulated signal optimized for environmental characteristics and convert the pulse width modulated signal into a DC voltage and output the pulse width modulated signal converted into the DC voltage as a reference signal; A driving control signal generation unit configured to output the driving control signal of the switching unit by comparing the output current signal output from the flyback transformer with the reference signal; And An output current detector for detecting the output current signal; Switching the switching unit to generate a modified voltage on the primary side of the flyback transformer in response to the driving control signal, and outputting the output current signal whose output error is corrected by the modified voltage on the secondary side of the flyback transformer High voltage power supply characterized in that the output. The pulse width modulation signal processor of claim 1, wherein A high voltage power supply using a low pass filter to convert a pulse width modulated signal to a DC voltage. The method of claim 1, wherein the driving control signal generator And a proportional integral controller to compare the output current signal with the reference signal. The method of claim 1, wherein the output current detection unit And detecting the output current signal using a bipolar operational amplifier. In the output current correction method performed in the high voltage power supply having a switching unit and a flyback transformer, (a) receiving a pulse width modulated signal optimized for environmental characteristics and converting the signal to a DC voltage; (b) generating a driving control signal of the switching unit by comparing the pulse width modulated signal converted into a DC voltage with an output current signal detected at the secondary side of the flyback transformer as a reference signal; (c) generating a modified voltage at the primary side of the flyback transformer; (d) generating the output current signal whose output error is corrected at the secondary side of the flyback transformer by the modified voltage; And (e) detecting the generated output current signal on the secondary side of the flyback transformer. The method of claim 5, wherein step (a) An output current correction method performed in a high voltage power supply, characterized by converting a pulse width modulated signal into a DC voltage using a low pass filter. The method of claim 5, wherein step (b) And a proportional integral controller to compare the output current signal with the reference signal. The method of claim 5, wherein step (e) An output current correction method performed in a high voltage power supply, characterized in that for detecting the output current signal using a bipolar operational amplifier.

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