KR950000390Y1 - Supplying device for a developing bias voltage - Google Patents

Abstract

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Description

Developing bias power supply of electrophotographic copying device

1 is a schematic structural diagram of a developing apparatus to which a power supply device according to the present invention is applied.

* Explanation of symbols for main parts of the drawings

100: drum 200: Daejeon corona device

300: photosensitive portion 400: developing electrode

500: transfer corona device 600: antistatic lamp

700: developing bias power supply VZ: varistor

The present invention relates to a developing bias power supply device that can be used in a device using an electrophotographic technique such as a laser printer or a copying machine. In particular, the electrostatic induction generated from the developing electrode by frictional charging is applied even if a separate bias voltage is not applied from the outside. The present invention relates to a developing bias power supply of an electrophotographic copying device for supplying a developing developing bias voltage using a voltage.

In general, the developing apparatus performs the following printer operations, i.e., when a charging signal from the microprocessor is applied to the developing apparatus, the charging corona apparatus located at the top of the drum is normally subjected to high pressure of -4KV to -6KV. Therefore, the surface of the drum is uniformly charged to -500V to -700V by the charging corona device, and the charged drum rotates to move to the photosensitive portion. In the photosensitive unit, only the potential of the light-exposed portion, that is, the exposed portion, is varied by 0V to -100V by irradiating light on the surface of the drum using an all-optical conversion element.

When the drum rotates and moves toward a developing electrode subjected to a developing bias voltage of about -200 V to -400 V, an electrostatic force is generated on the exposed portion of the developing electrode and the drum surface due to a potential difference. When the drum is rotated and moved toward the transfer corona device, electrostatic force is generated on the transfer corona device and the drum surface by about 6 KV of high pressure applied to the transfer corona device. Toner is transferred to paper.

In addition, when the drum rotates and moves toward an erasure lamp, the charge on the exposed portion of the drum surface is removed by the antistatic lamp, so that the drum surface has a constant electric potential and the paper is printed by repeating the above operation. do.

Therefore, in order to perform the print operation as described above, a high voltage power must be applied to a charging corona device, a developing electrode, and a transfer corona device. In the related art, each power supply device is separately installed to supply the high voltage power required from the outside. There was a problem that the internal structure is complicated due to the device and the accompanying circuits, and as the structure is complicated, the number of parts also increases, resulting in high cost and high power consumption.

Accordingly, an object of the present invention is to provide a developing bias power supply device for supplying a developing developing bias voltage by using an electrostatic induction voltage generated in a developing electrode in a electrophotographic copy apparatus to solve the above problems. have.

In order to achieve the above object, the present invention provides a drum, a charging corona apparatus for uniformly charging the drum surface, a photosensitive part that emits light on the drum surface, and an electrostatic force generated by a potential difference between the developing bias voltage and the drum surface. An electrophotographic copying apparatus comprising: a developing electrode for attaching toner to an exposed portion of a drum surface by means of; and a transfer corona device for transferring toner of a drum surface to paper using electrostatic force; A first voltage regulator for adjusting the generated electrostatic induction voltage to a desired developing bias voltage; A second voltage regulator for varying the developing bias voltage for controlling image density; And a switching unit switched according to a bias driving signal applied to a bias driving signal terminal so that developing bias voltages adjusted by the first and second voltage regulators are supplied to the developing electrodes.

Hereinafter, the present invention will be described with reference to the accompanying drawings.

1 is a schematic structural diagram of a developing apparatus to which a power supply device according to the present invention is applied.

The developing apparatus shown in FIG. 1 includes a drum 100, a charging corona apparatus 200 positioned at an upper end of the drum 100 to uniformly charge the drum surface, and a charging corona apparatus 200 during charging. The toner is attached to the exposed portion of the drum surface using a power supply 210 for supplying the necessary high voltage power, a photosensitive portion 300 for emitting light on the drum surface, and an electrostatic force generated by the development bias voltage and the potential difference between the drum surface. A developing electrode 400, a transfer corona device 500 positioned at a lower end of the drum 100 to transfer the toner on the drum surface to paper using electrostatic force, and a high pressure required for transferring to the transfer corona device 500. A developing device consisting of a power supply device 510 for supplying power, a destatic lamp 600 for removing the electric charges from the exposed portion, and a drum surface having a constant electric potential; a bias driving signal terminal 10 and a developing electrode 400; ) Between Air, consists of a developing bias power supply 700 for adjusting the electrostatic induced voltages generated in the developing electrode 400 as a bias voltage required.

Here, the developing bias power supply 700 includes a first voltage regulator for reducing the electrostatic induction voltage of the developing electrode 400 to a desired developing bias voltage, for example, a varistor VZ, and the developing bias for controlling image concentration. A second voltage regulator for varying the voltage, for example, the variable resistor VR and the resistor R1 and a switching unit for switching the developing bias voltage to the developing electrode 400, for example, the transistor TR1 to be switched according to the bias driving signal. It is composed of

Referring to the operation and effects of the developing bias power supply of the present invention configured as described above in detail as follows.

As described above, in the developing electrode 400 supplying the toner to the drum surface, the electrostatic toner and the positively charged carrier are mixed by an agitator (not shown). Is generated.

However, since the electrostatic induction voltage is not low enough as the developing bias voltage (-200V to -400V) required by the developing electrode 400, the developing bias power supply 700 is connected to the developing electrode 400 to provide the By adjusting the electrostatic induction voltage, a desired developing bias voltage is supplied. That is, when the electrostatic induction voltage is generated in the developing electrode 400 as described above, when the bias driving signal supplied from the microprocessor (not shown) is applied through the bias driving signal terminal 10, the developing bias power source is applied. Since the transistor TR1 of the supply device 700 is turned on, current flows from the developing electrode 400 through the varistor VZ, the variable resistor VR, the resistor R1, and the transistor TR1.

At this time, when the electrostatic induction voltage is applied to the varistor (VZ), the varistor (VZ) flowing through the varistor (VZ) due to the characteristics of the varistor (VZ) that is a resistor having a large change ratio of the current (I) to the change of the applied voltage (V). The current increases nonlinearly, so that the varistor VZ causes the electrostatic induction voltage to be lowered by the desired developing bias voltage. In other words, when the characteristic expression of the varistor VZ is represented by I = kV ⁿ (where n is usually 4 to 5), the varistor VZ having a proportional constant k required to obtain a desired developing bias voltage may be selected.

On the other hand, if the development bias voltage is varied by adjusting the resistance value of the variable resistor VR, the electrostatic force generated on the developing electrode 400 and the drum surface is changed, so that the toner adheres to the drum surface, that is, the image density is changed. It becomes possible.

The transistor TR1 is switched in accordance with a bias drive signal applied from the microprocessor (not shown) to the bias drive signal terminal 10, and is adjusted by the varistor VZ, the variable resistor VR1 and the resistor R1. The developing bias voltage is supplied to the developing electrode 400.

As described above, in the developing bias power supply device according to the present invention, in the electrophotographic copying device, the configuration is simplified because there is no need for a separate power supply device and accompanying circuits by using the electrostatic induction voltage generated in the developing electrode. Rather, this reduces costs and reduces power consumption.

Claims (1)

A toner on the exposed portion of the drum surface by using a drum, a charging corona apparatus for uniformly charging the drum surface, a photosensitive portion that emits light on the drum surface, and an electrostatic force generated by the development bias voltage and the potential difference between the drum surface. An electrophotographic copying apparatus comprising: a developing electrode for attaching a film; and a transfer corona device for transferring a toner on a drum surface to a paper by using electrostatic force, wherein the electrostatic induction voltage generated by frictional charging in the developing electrode is a desired developing bias. A first voltage regulator for adjusting the voltage. A second voltage regulator for varying the developing bias voltage for controlling image density; And a switching unit switched according to a bias driving signal applied to a bias driving signal terminal so that the developing bias voltage adjusted by the first and second voltage regulators is supplied to the developing electrode. Device.