KR19990029547U - Electrophotographic development high voltage protection device - Google Patents

Abstract

The present disclosure relates to a high voltage protection device that prevents damage of peripheral elements and phenomenon of contaminated electrophotographic from high voltage generated for image realization in devices such as laser beam printers and copiers.

The disclosed high voltage protection device includes: high voltage control means for generating a switching control voltage for image formation; High voltage generating means for boosting and rectifying the input voltage according to the switching control voltage and outputting the voltage; Voltage interrupting means for regulating the high voltage generating means when the voltage of the high voltage generating means is greater than or equal to a predetermined voltage; Information extracting means for extracting a resultant state of the voltage interrupting means and a switching control voltage of the high voltage control means; And a microprocessor that stops the operation of the high pressure control means according to the extracted information and displays an error message on the operation panel. There is an advantage that the damage of the peripheral device is prevented.

Description

Electrophotographic development high voltage protection device

The present invention relates to an electrophotographic developing apparatus such as a laser printer and a copying machine using an electrophotographic developing method, and more particularly, to self-diagnose a high voltage for realizing an image in an image forming apparatus to output high voltage when an abnormality occurs. The present invention relates to a high voltage protection device of an electrophotographic development method which controls an intermittent and generates an error message to prevent the formation of a contaminated electrophotographic and damage to a peripheral device.

In general, an electrophotographic developing apparatus using an electrophotographic developing method, such as a monochrome / color copier, a monochrome / color laser beam printer, an optical density device, and the like, has a charging roller while the charging roller rotates. At a high voltage, the photosensitive member is evenly charged on the outer circumferential surface of the photosensitive drum.

Then, the photosensitive member charged on the outer circumferential surface of the photosensitive drum forms an electrostatic latent image by light rays emitted from a light source such as a laser diode or the like that converts a digital signal into laser light.

At this time, the electrostatic latent image formed on the photosensitive drum is developed by the toner as it passes through the developing machine, is converted into a visible image, and is charged to the paper to be fed and fed by the pickup roller, so that the visible image of the photosensitive device is transferred onto the paper.

The transferred paper is discharged after the image is fused by heat and pressure of the fixing apparatus.

When a high voltage is supplied to the transfer photograph developing apparatus, warm-up is performed for a predetermined time according to the characteristics of the apparatus, and when warm-up is completed, an on-line mode for executing a print command is performed. .

In addition, if there is no print command or copy command for a predetermined time in the preparation mode, the printer enters the standby mode again. When the print command or copy command is issued in the standby mode, the printing or copying is performed through a warm-up process.

In such a general electrophotographic developing apparatus, a device as shown in FIG. 1 may be used to generate a high voltage for realizing an image.

The apparatus shown in FIG. 1 will be described as an example of the high voltage protection device of the conventional electrophotographic developing apparatus.

The high voltage protection device may include a microprocessor 100 and a microprocessor 100 that control the overall operation of the electrophotographic developing apparatus for realizing an image according to the key operation of the operation panel 101 by an external host computer or a user. In order to adjust the output amount of the high voltage supplied to the charging roller or the like according to the control voltage output from the high voltage control unit 102 for generating a switching control voltage, and generates a high voltage in accordance with the switching control voltage generated from the high voltage control unit 102 A high voltage generator 103 comprising a transformer and a double voltage unit, an output unit 104 for distributing the generated high voltages and supplying them to a charging roller, a transfer roller, a heating roller, and the like through an output terminal 106, and a high voltage generator. The high voltage sense to feedback to the high voltage control unit 102 to sense the output amount of the high voltage generated by the 103 to keep the output of the high voltage constant It is composed of branch 105.

The high voltage protection device of the electrophotographic developing apparatus according to the prior art configured as described above, the microprocessor 100 responsible for the overall control to start or stop the image forming (printing) operation through the electrophotographic developing apparatus is an external host When the print start data supplied from the computer or the on-line key from the operation panel 101 is input, the high voltage controller 102 provides a control voltage for controlling the generation of high voltage.

The high voltage controller 102 compares the control voltage supplied from the microprocessor 100 with the set voltage and supplies the switching control voltage to the high voltage generator 103 to adjust the output amount of the high voltage according to the comparison result.

The high voltage generator 103 generates a high voltage by driving a transformer and a double voltage unit in the self by the switching control voltage of the high voltage controller 102.

The high voltage generated by the high voltage generator 103 is distributed through the output unit 104 and supplied to the charging roller, the transfer roller, the heating roller, and the like through the output terminal 106.

Meanwhile, the high voltage detector 105 detects the level of the voltage generated by the high voltage generator 103 and provides it to the high voltage controller 102.

In other words, the high voltage detection unit 105 is composed of a resistor, and detects it when the level of the high voltage output from the high voltage generation unit 103 is low or high, and feeds it back to the high pressure control unit 102, resulting in a high pressure control unit ( The high voltage generator 103 is controlled by the sensed voltage inputted by the 102 to maintain a constant output amount of the high voltage.

However, the high voltage protection device in the electrophotographic apparatus, such as a copier and a laser beam printer, using the above-described conventional electrophotographic development method, detects an abnormal voltage deviating from a certain processor when an abnormality occurs in a high voltage output, and detects an abnormal voltage from the high voltage controller. Since the feedback input is performed, there is a problem in that the output of the high voltage output from the high voltage generator is insufficient or excessive, resulting in deterioration of image quality and damage of peripheral devices.

Therefore, it is preferable to apply a high voltage protection device to the transfer photographic developing device which can achieve an effect equal to or higher than the conventional one while preventing the deterioration of the image quality and the damage of the peripheral element to the abnormal voltage of the high voltage generator.

Therefore, the present invention excludes the damage of the peripheral device and the contaminated electrophotographic phenomenon caused by the abnormal power generation of the high voltage generator in the above-described conventional technology. As one aspect of the present invention, the high voltage generator is capable of self-diagnosis. It is an object of the present invention to provide a high voltage protection device of the electrophotographic development method which forcibly interrupts the output of high voltage at the time of power generation to prevent damage of peripheral devices and discharge of contaminated images.

As another aspect of the present invention, an object of the present invention is to display an error occurrence on an operation panel when abnormal power is generated from a high voltage generator so as to cope with an error.

1 is a block diagram showing a high voltage protection device in an electrophotographic developing apparatus according to the prior art,

Figure 2 is a block diagram showing an embodiment provided for the description of the high voltage protection device in the electrophotographic developing apparatus according to the present invention.

<Description of Symbols for Main Parts of Drawings>

200: microprocessor 201: operation panel

202: high voltage controller 203: high voltage generator

204: output unit 205: high voltage detection unit

207: voltage interrupter 208: information extractor

The above object is an electrophotographic development-type high voltage generating apparatus for realizing an image, comprising: high voltage control means for generating a switching control voltage for forming an image according to an external control voltage during a printing and copying command; High voltage generating means for boosting and rectifying the input voltage to a target value according to the switching control voltage and outputting the voltage; Voltage interrupting means for dividing and detecting the voltage generated by the high voltage generating means to interrupt the switching control voltage generated by the high voltage control means when a predetermined voltage is abnormal; Information extracting means for extracting a resultant state of the voltage interrupting means and a switching control voltage of the high voltage control means; And a microprocessor which stops driving by blocking a control voltage supplied to the high voltage control means according to the extracted information, and displays an abnormality of the high voltage generating means on the operation panel. By high voltage protection device.

Preferably, the high pressure control means includes a first integrator for integrating the control voltage generated in the microprocessor for a set time constant; A comparator for generating a switching control voltage by comparing the integrated control voltage with a set voltage; And a second integrator for integrating the switching control voltage generated by the comparator for a set time constant and supplying it to the high voltage generating means.

Preferably, the high voltage generating means comprises a first switching element for supplying a voltage to the voltage interrupting means, including a transformer and a double voltage unit and switched according to the level of the voltage supplied to the primary side of the transformer.

Preferably, the voltage interrupting means includes a resistor for dividing the voltage supplied from the first switching element of the high voltage generating means; And a second switching element which switches according to the level of the voltage divided by the resistor and regulates the switching control voltage of the high voltage control means provided to the information extraction means.

Preferably, the information extracting means is composed of a third switching device for providing information to the microprocessor is switched according to the interruption result of the switching control voltage of the voltage interrupting means and the switching control voltage of the high voltage control means. .

In this way, when an abnormal voltage is generated from the high voltage generating means, the voltage interrupting means controls the high voltage control means to stop the high voltage generating means and the information extracting means provides the microprocessor with an abnormal voltage generation, thereby causing the microprocessor to generate an error message. You can see that it displays and displays.

As a result, when an abnormal voltage is generated from the high voltage generating means, it is healed early and an error message is generated by the message, thereby preventing the formation of contaminated electrophotographic and damage to the peripheral device. As a result, the performance of the product is stabilized. There is an advantage.

And, there may be a plurality of embodiments of the present invention, the following will be described in detail with respect to the most preferred embodiment.

Through this preferred embodiment it is possible to better understand the objects, features and advantages of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the high-voltage protection device of the electrophotographic development method according to the present invention.

In addition, the technology of the present invention can be applied to a variety of products for forming an image on a paper by using an electrophotographic development method such as a laser printer, copier and optical density device.

Therefore, FIG. 2 used in the description is a drawing focusing on various products for realizing an image using an electrophotographic development method, not a high voltage protection device of a specific product.

2 is a block diagram illustrating an embodiment provided to explain a high voltage protection device in an electrophotographic developing apparatus according to the present invention.

According to the present embodiment, the microprocessor 200 which controls the copying and printing of the image data of the original, and the function key of the system have a plurality of keys that can generate data, and when the key data is generated, the microprocessor 200 (OPE) operating panel (201) having a liquid crystal display (201a) capable of inputting the display data of the microprocessor (200) and the display data of the microprocessor (200), and the control voltage and the set voltage generated by the microprocessor (200). The high voltage control unit 202 generates a switching control voltage according to the comparison result, and drives the transformer 203a through the switching element Q1 according to the generated switching control voltage to drive the voltage of the power supply terminal Vcc. Each of the high voltage generator 203 and the rectified high voltage to excite and output the excited voltage to a high voltage to a target value through the double voltage unit 203b and output the same. The output unit 204 is distributed through each output terminal 206 to be supplied to the charging roller, the transfer roller, the heating roller, and the like, and the output amount of the high voltage generated by the high voltage generator 203 is sensed to maintain the output of the high voltage. The voltage through the high voltage detecting unit 205 made up of the resistors R8 and R9 fed back to the high voltage control unit 202 and the switching element Q1 of the high voltage generating unit 203 is maintained. A voltage dividing unit 207 for dividing and detecting the voltage through R12 and switching the switching element Q2 according to the divided voltage level to interrupt the switching control voltage generated by the high voltage control unit 202; Whether the switching control voltage of the high voltage controller 202 is generated according to whether the voltage interrupter 207 is interrupted is detected and displayed on the liquid crystal display 201a of the operation panel 201 through the microprocessor 200 to display the resistance (R13). ), An information extracting unit 208 composed of (R14) and switching element (Q3). The.

The high voltage controller 202 integrates the control voltage generated by the microprocessor 200 during the set time constants of the resistors R1, R2 and the capacitor C1, and integrates the control voltage and the resistor R3, ( The reference voltage of the power supply terminal Vcc through R4) is compared with the comparator 202a to generate a switching control voltage, and the generated reference voltage is compared with the resistors R5, R6, R7 and the capacitor C2. It is configured to output by integrating during time constant.

The high voltage protection device of the electrophotographic development method according to the present invention made as described above will be described in more detail below.

First, the microprocessor 200 which is in charge of the overall control of starting or stopping the image forming operation through the electrophotographic developing apparatus receives input of print start data supplied from an external host computer or online key data from the operation panel 201. If so, the control voltage for controlling the generation of high voltage is provided to the high voltage controller 202.

The high voltage controller 202 integrates the control voltage supplied from the microprocessor 200 during the time constants of the resistors R1 and R2 and the capacitor C1 to provide the non-inverting terminal (+) of the comparator 202a. .

The comparator 202a is integrated and compares the control voltage inputted with the reference voltages of the power supply terminal Vcc which is divided by the resistors R3 and R4 and input to its inverting terminal (-). It generates a switching control voltage to adjust the output amount of.

The generated switching control voltage is supplied to the base of the switching element Q3 through the resistor R13 of the information extraction unit 208, which will be described later, and during the time constants of the resistors R5-R7 and the capacitor C2. It is integrated and supplied to the primary side of the transformer 203a included in the high voltage generator 103.

At this time, the switching element Q3 of the information extraction unit 208 is conducted by the switching control voltage generated by the high voltage control unit 202 and input through the resistor R13.

When the switching element Q3 is turned on, the voltage of the power supply terminal Vd is bypassed to the ground through the resistor R14, and as a result, a low potential is applied to the microprocessor 200.

Therefore, when the low potential is input from the information extraction unit 208, the microprocessor 200 displays on the liquid crystal display 201a of the operation panel 201 that the high voltage generator 203, which will be described later, operates normally. .

On the other hand, the switching control voltage generated by the high voltage control unit 202 is supplied to the base of the switching element Q1 through the primary coil of the transformer 203a included in the high voltage generator 203 to supply the switching element Q1. It becomes conductive.

Accordingly, the voltage of the power supply terminal Vcc applied to the primary coil of the transformer 203a is supplied to the power supply intermittent portion 207 through the emitter of the switching element Q1, and the transformer 203a is supplied to the switching element Q1. The conduction of excitation causes the voltage of the power supply terminal Vcc to be excited to its secondary side.

The voltage excited to the secondary side of the transformer 203a is boosted and rectified at a high voltage from the double voltage unit 203b of the high voltage generator 203 to a target value, and is transferred to the transfer roller through the output unit 204 and the output terminal 206, Supply to a charging roller or the like.

However, the high voltage generated by the high voltage generator 203 is determined according to the magnitude of the switching control voltage applied to the base terminal of the switching element Q1.

As a result, when the voltage applied to the base of the switching element Q1 increases, the emitter voltage also increases, so that the voltage dividing resistors R11 and R12 of the voltage interrupter 207 may malfunction during the abnormal operation of the high voltage generator 203. An emitter voltage larger than the partial pressure time constant of is input to the base of the switching element Q2 to conduct.

When the switching element Q2 of the voltage interrupter 207 is turned on, the switching control voltage generated in the comparator 202a of the high voltage control unit 202, such as the differential amplifier, is bypassed to the ground through the switching element Q2. The high voltage generated by the high voltage generator 203 is interrupted.

Then, when the switching element Q2 of the voltage interrupter 207 is conducted, the switching element Q3 of the information extraction unit 208 is inverted from the conduction state to the cutoff state.

Accordingly, the voltage of the power supply terminal Vd is input to the microprocessor 200 through the resistor R14, and the microprocessor 200 detects this to control the high voltage control unit 202 and the liquid crystal of the operation panel 201. An error message is provided to the display unit 201a to be displayed.

On the other hand, as a comparative example, unlike the prior art, that is, the high voltage detection unit detects an abnormal voltage deviating from a certain processor when an abnormality occurs in the high voltage output and feeds it back to the high voltage control unit, the present invention provides an abnormal voltage to the high voltage generating unit. It can be seen that the high-voltage control unit controls the output of the high voltage at the time of occurrence and displays a high voltage generation error message on the liquid crystal display of the operation panel.

As a result, according to the present invention, when abnormal voltage is generated from the high voltage generator in a product such as a laser printer and a copier using the electrophotographic development method, the high voltage is cut off and an error message is displayed immediately, thereby causing damage to peripheral devices and It can be seen that the phenomenon of contaminated electrophotography is prevented.

As described above, in the present embodiment, when an abnormality occurs in a high voltage for implementing image formation in various products such as a laser printer and a copying machine using an electrophotographic development method, the high voltage is blocked and an error state is displayed. It is possible to service the error quickly without causing contamination of the photoelectric breakdown and electrophotographic phenomenon.

In addition, although specific embodiments of the present invention have been described and illustrated above, it is obvious that the present invention may be variously modified and implemented by those skilled in the art.

Such modified embodiments should not be individually understood from the technical spirit or the prospect of the present invention, and such modified embodiments shall fall within the appended utility model registration claims of the present invention.

It is clear from the above description that, according to the electrophotographic development high voltage protection device according to the present invention, the high voltage generation unit is forcibly intercepted when the high voltage power supply is generated from the high voltage generation device and the high voltage power is shifted from the constant processor. By returning to the processor, it is possible to prevent the discharge of contaminated images and the damage of peripheral devices, and to indicate the occurrence of errors and to quickly cope with system errors.

Claims (6)

In the high voltage generator of the electrophotographic development method for realizing an image: High voltage control means for generating a switching control voltage for forming an image according to a control voltage input at the time of printing and copying commands; High voltage generating means for boosting and rectifying the input voltage to a target value according to the switching control voltage and outputting the voltage; Voltage interrupting means for dividing and detecting the voltage of the high voltage generating means and controlling the switching control voltage when the voltage is higher than a predetermined voltage to control the high voltage generating means; Information extraction means for extracting a resultant state of the voltage interrupting means and a switching control voltage of the high voltage control means; And And a microprocessor which stops driving by blocking the control voltage supplied to the high voltage control means according to the extracted information, and displays an abnormality of the high voltage generating means on an operation panel. The method of claim 1, The high pressure control means may include: a first integrator for integrating a control voltage generated in the microprocessor during a set time constant; A comparator for generating the switching control voltage by comparing the integrated control voltage with a set voltage; And And a second integrator for integrating the switching control voltage for a set time constant and supplying the switching control voltage to the high voltage generating means. The method of claim 1, The high voltage generating means includes a first switching element including a transformer and a double voltage part and switched according to the level of the switching control voltage supplied to the primary side of the transformer to supply a voltage to the voltage interrupting means. Electrophotographic development high voltage protection device. The method according to claim 1 or 3, The voltage interrupting means may include: a resistor for dividing the switching control voltage supplied from the first switching element of the high voltage generating means; And And a second switching element which is switched according to the level of the divided switching control voltage to regulate the switching control voltage of the high voltage control means provided to the information extraction means. The method of claim 1, And the information extracting means comprises a third switching element which is switched according to the result of the interruption of the switching control voltage of the voltage interrupting means and the switching control voltage of the high voltage control means to provide error information to the microprocessor. Photo development high voltage protection device. The method of claim 4, wherein When the switching control voltage supplied from the first switching element is greater than the time constant of the voltage divider resistor, the second switching element is turned on to interrupt the switching control voltage of the high voltage control means. High voltage protection device.