KR100517494B1 - Voltage supply of electrophotographic developing equipment - Google Patents

Abstract

The voltage supply circuit of the transfer image forming apparatus includes a charge voltage output unit for supplying a charge voltage to a charge roller by an input control signal; The supply voltage converting unit converts the charging voltage output from the charging voltage output unit into a predetermined supply voltage; The supply voltage switching controller applies or blocks the supply voltage to the supply roller in accordance with the supply voltage input control signal; A transfer voltage converter converts the charge voltage output from the charge voltage output unit into a predetermined transfer voltage; The transfer voltage switching controller is characterized by applying or blocking the transfer voltage to the supply roller according to the transfer voltage control signal. Therefore, the present invention reduces manufacturing costs by converting and supplying the voltage required for the charging roller, the supply roller, and the developing roller by using one transformer.

Description

Voltage supply of electrophotographic developing equipment

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a voltage supply device for an electrophotographic developing apparatus, and more particularly, an electron capable of obtaining multiple outputs with a single transformer by converting a level of a charging voltage applied to a charging roller and supplying it to a supply roller and a developing roller. It relates to a voltage supply device for a photographic developing device.

In general, electrophotographic developing apparatuses generally used in copiers, laser printers, facsimiles, and the like, expose an image or data source obtained from a predetermined source to a photosensitive member to form an latent image of the electrostatic image. A developer is applied to form a visible image, and the desired image is printed by transferring the visible image onto a printing sheet and then fixing it.

1 shows an electrophotographic developing apparatus.

Looking at the printing process, the pickup roller 1, the charging roller 2, the photosensitive drum (OPC: Organic Photo Conductive) 3, the transfer roller 4, the developing roller ( 5), feed roller 6, fuser 7 and exposure apparatus 8. That is, if the photosensitive member formed on the outer circumferential surface of the photosensitive drum 3 is evenly charged while the charging roller 2 charged by the high voltage charging voltage rotates, the photosensitive drum 3 with the light generated by the exposure apparatus 8 is charged. The electrostatic latent image to be printed is formed on the surface of the film. Thereafter, a potential difference is generated between the supply roller 6 to which the high pressure supply voltage is applied and the developing roller 5 to which the voltage of a level lower than the supply roller 6 is applied. The voltage applied to each component here is a charging voltage of -1.4 [kV] on the charging roller 2, a developing voltage of -300 [V] on the developing roller 5, and a maximum of +1.5 [kV on the transfer roller 4]. ], The supply roller 6 is supplied with a supply voltage of -500 [V].

As a result, the toner moves from the supply roller 6 to the developing roller 5. The toner supplied to the developing roller 5 is formed with a uniform amount of toner layer on the surface of the developing roller 5 by a regulating blade (not shown), and is developed on the electrostatic latent image formed on the surface of the photosensitive drum 3. The toner of the roller 5 is applied to form a visible image.

The high pressure transfer roller 4 transfers the visible image formed by the toner applied to the surface of the photosensitive drum 3 onto the printing paper to be conveyed. The visible image transferred to the printing paper is fixed to the printing paper by the high heat and pressure of the fixing unit 7, thereby completing the printing process.

Meanwhile, referring to the voltage supply circuit of the electrophotographic developing apparatus, as shown in FIG. 2, the charging voltage and the supply voltage are determined by the first transformer 12 of the charging voltage output unit 10 and the supply voltage output unit 20. 2 is applied at the transformer 22. That is, the voltage generated at the first and second transformers 12 and 22 by the respective switching controllers 11 and 21 is backed to the charging voltage and the supply voltage in the respective back voltage circuits 13 and 23, respectively, and then the respective outputs. It is applied to the charging roller 2 and the supply roller 6 through the circuits 14 and 24. On the other hand, the developing roller 5 is supplied with a developing voltage in which the supply voltage is boosted to a predetermined level or more by the zener voltage of the zener diode group ZDS connected to the output circuit 24 of the supply voltage output unit 20.

However, according to the voltage supply circuit of the conventional electrophotographic apparatus, the following problems occur.

First, the voltage required for each roller is generated and supplied by several transformers, which increases the manufacturing cost using several transformers.

Second, when the supply voltage and the developing voltage are simultaneously supplied to the supply roller and the developing roller, and there is a need to supply the supply voltage and the developing voltage separately, there is no countermeasure.

Accordingly, the present invention is to solve such problems, the first object of the present invention is to reduce the manufacturing cost by converting and supplying the voltage required for the charging roller, the supply roller and the development roller by using a transformer. .

A second object of the present invention is to enable the supply voltage and the developing voltage to be supplied separately, thereby improving the function of the electrophotographic apparatus in the future.

A feature of the present invention for achieving the above objects is a voltage supply circuit of a transfer image forming apparatus comprising a charge voltage output unit for supplying a charge voltage to a charge roller by an input control signal; The supply voltage converting unit converts the charging voltage output from the charging voltage output unit into a predetermined supply voltage; The supply voltage switching controller applies or blocks the supply voltage to the supply roller in accordance with the supply voltage input control signal; A transfer voltage converter converts the charge voltage output from the charge voltage output unit into a predetermined transfer voltage; The transfer voltage switching controller is adapted to apply or block the transfer voltage to the supply roller in accordance with the transfer voltage control signal.

Here, the supply voltage converting unit is at least one first zener diode group which is connected to the charging voltage output unit and converts the output of the charging voltage output unit to the supply voltage by a first zener voltage which is preset.

The transfer voltage converting unit is at least one second zener diode group which is connected to the charging voltage output unit and converts the output of the charging voltage output unit to the supply voltage by a preset second zener voltage.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. The description of the same parts as in the prior art is omitted.

3 is a circuit diagram showing a voltage supply device of an electrophotographic developing apparatus to which the present invention is applied.

Referring to FIG. 3, the first zener diode group ZDS1 converts a charging voltage of −1.4 [kV] output from the charging voltage output unit 10 into a supply voltage of −500 [V]. One end is connected to the A node to which 10) and the supply roller 6 are connected, and the other end is grounded to the ground GND.

The supply voltage switching controller 100 applies the supply voltage of -500 [V] converted from the first zener diode group ZDS1 to the supply roller 6 or to ground GND according to the supply voltage input control signal. It is connected to node A to pass and block.

The second zener diode group ZDS2 converts the charging voltage of -1.4 [kV] output from the charging voltage output unit 10 into a developing voltage of -300 [V], and the developing roller. One end is connected to node B to which (5) is connected, and the other end is grounded to ground (GND).

The transfer voltage switching controller 200 applies a developing voltage of -300 [V] converted from the second zener diode group ZDS2 to the developing roller 5 or to ground GND according to the developing voltage input control signal. It is connected to node B to pass and block.

Hereinafter, the operation of the voltage supply device of the electrophotographic developing apparatus according to the present invention will be described.

First, when the supply voltage switching controller 100 is switched by the supply voltage control signal while the charging voltage is supplied, the charging voltage of -1.4 [kV] output from the output circuit 14 of the charging voltage output unit 10 is Passed through the node A to the ground (GND) of the supply voltage switching controller 100, no voltage is applied to the supply roller (6).

In this state, when the supply voltage switching controller 100 is switched by the supply voltage control signal, the charge voltage of -1.4 [kV] output from the charge voltage output unit 10 is the zener voltage of the first zener diode group ZDS1. Is converted into a supply voltage of -500 [V] and applied to the supply roller 6.

In addition, when the transfer voltage switching controller 200 is switched by the developing voltage control signal while the charging voltage is supplied, the charging voltage of −1.4 [kV] output from the output circuit 13 of the charging voltage output unit 10 may be Passed through the node B to the ground (GND) of the transfer voltage switching controller 200, no voltage is applied to the developing roller (5).

In this state, when the transfer voltage switching controller 200 is switched by the developing voltage control signal, the charging voltage of -1.4 [kV] output from the charging voltage output unit 10 is the zener voltage of the second zener diode group ZDS2. Is converted into a developing voltage of -300 [V], and is applied to the developing roller 5.

Therefore, it is output from one transformer to convert the charging voltage into a supply voltage and a developing voltage, and supply it to the supply roller and the developing roller, and while the charging voltage is output, the supply voltage and the developing voltage can be supplied separately.

As described above, in the detailed description of the present invention, specific embodiments have been described, but various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined by the claims below and equivalents thereof.

As described above, according to the present invention, the following advantages occur.

First, manufacturing cost is reduced by converting and supplying the voltage required for the charging roller, the supply roller and the developing roller by using one transformer.

Secondly, by separately supplying the supply voltage and the developing voltage, the function of the electrophotographic apparatus is subsequently improved.

1 shows an electrophotographic developing apparatus,

2 shows a circuit diagram of a voltage supply device of an electrophotographic developing apparatus,

3 is a circuit diagram showing a voltage supply device of an electrophotographic developing apparatus to which the present invention is applied.

<Description of the code | symbol about the principal part of drawing>

100: supply voltage switching controller 200: transfer voltage switching controller

ZDS1: First Zener Diode Group ZDS2: Second Zener Diode Group

Claims (3)

A voltage supply circuit of a transfer image forming apparatus, comprising: a charge voltage output section for supplying a charge voltage to a charge roller by an input control signal; A supply voltage converting unit converting the charging voltage output from the charging voltage output unit into a predetermined supply voltage; A supply voltage switching controller configured to apply or block the supply voltage to the supply roller according to a supply voltage input control signal; A transfer voltage converting unit converting the charging voltage output from the charging voltage output unit into a predetermined transfer voltage; And a transfer voltage switching controller configured to apply or block the transfer voltage to the supply roller according to a transfer voltage control signal. The method of claim 1, wherein the supply voltage converter, And at least one first zener diode group connected to the charging voltage output unit and converting an output of the charging voltage output unit to the supply voltage by a first zener voltage preset. The method of claim 1, wherein the transfer voltage converter, And at least one second zener diode group connected to the charging voltage output unit and converting the output of the charging voltage output unit to the supply voltage by a preset second zener voltage.