JPS61208064A - Electrostatic charger - Google Patents

Abstract

PURPOSE:To stabilize electrifying performance and to cope with high speed processing by providing a electrification control means which controls the electrification in such a way that the electrification by a scorotron electrostatic charger is started after a certain period has expired since the start of the electrification by a corotron electrostatic charger. CONSTITUTION:When a subject 4 to be electrified in a potential at a certain extent reaches the position facing a grid electrode 7, only a control signal from the control means C is turned off. Thus the grounding of the grid electrode 7 caused by a switching means 6b is released, and the grid electrode 7 attains the state where only a constant voltage element 6a is substantially connected. Then a corona ion electrifies the subject 4 to be electrified through the grid 7 until the potential of said subject 4 reaches that set by the constant voltage element 6a. At this time, since the subject 4 to be electrified has been electrified to a certain extent, the quantity of corona ions reaching the subject 4 through the grid electrode 7 are comparatively less, and a potential difference between the grid electrode 7 and the subject 4 is also small, whereby the grid voltage 7 will not fluctuate, and the electrifying performance is stabilized and accelerated.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a charging device that applies a uniform charge to the surface of an object to be charged such as a photoreceptor. Corona discharge is generally used as a means for this purpose. Charging methods using corona discharge include the corotron method, in which a corona voltage is applied to a corona electrode placed opposite to the photoreceptor surface, and the photoreceptor surface is charged by the corona ions generated at that time, and the corotron method, in which the corona electrode and the photoreceptor are A scorotron method is known in which a grid electrode to which a bias is applied is disposed between the photoreceptors and the surface of the photoreceptor is charged to approximately the same potential as the bias voltage of the grid electrode.

Although the corotron type charging device has a simple structure, it is difficult to accurately control the charging potential of the photoreceptor. On the other hand, a scorotron type charging device can accurately control the charging potential of the photoreceptor by controlling the bias voltage applied to the grid electrode. Therefore,
Copying machines that require high image quality use a scorotron charging device.

Problems to be Solved by the Invention Nowadays, electronic copying machines are required not only to have high image quality but also to have high processing speed. However, in order to make a scorotron-type charging device compatible with high-speed processing, when trying to increase the applied voltage to the charging device to activate corona discharge and improve the charging ability, the grid electrode vibrates and the photoconductor There was a problem with the surface being damaged. The reasons why the grid electrode vibrates are as follows: fi) Corona discharge becomes active, and the ion wind formed by the flow of ions passing through the grid electrode acts strongly on the grid electrode. (11)
It is thought that the force of the electric field between the grid electrode and the photoreceptor acts strongly on the grid electrode, and that these synergistic effects cause intense vibrations.

However, in the conventional charging device, there is no way to eliminate the above-mentioned cause other than reducing the applied voltage, and in the end, it was not possible to make the charging device compatible with high-speed processing.

SUMMARY OF THE INVENTION An object of the present invention is to provide a charging device that has a high output that can handle high-speed processing without impairing the stable charging characteristics of the scorotron system, and that does not cause vibration of the grid electrode that damages the photoreceptor.

In order to solve the above problems, the present invention provides a charging device that applies a uniform charge to the surface of a moving object to be charged.
a scorotron charging means having a grid electrode to which a bias voltage of a desired charging polarity is applied; and a scorotron charging means provided adjacent to the scorotron charging means on the upstream side in the moving direction of the object to be charged than the position where the scorotron charging means is provided. a corotron charging means that applies a charge having the same polarity as the charging polarity of the scorotron charging means; and a charging control that controls the scorotron charging means to start charging after a predetermined period of time after the corotron charging means starts charging. and control means.

Operation In the above configuration, the charging control means energizes the scorotron charging means after a certain period of time after energizing the corotron charging means, so that the moving object to be charged is first charged by the corotron charging means and then charged by the corotron charging means. Charged by a scorotron charging means. In other words, when the scorotron charging means starts charging, the object to be charged, which the scorotron charging means attempts to charge, has already been charged to a certain level of potential. The object to be charged, which has been charged to a certain potential, is further charged by a scorotron charging means until it reaches a predetermined potential. Charging by this scorotron charging means applies charges to a charged object that has been charged to a certain potential to charge it to a predetermined potential, so the amount of charge applied to the charged object is equal to that of an uncharged object This is significantly less than when applied to a charged object. Therefore,
The amount of corona ions passing through the grid electrode of the scorotron charging means is small, and the influence of ion wind acting on the grid electrode can be reduced.

At the same time, since the potential difference between the grid electrode and the object to be charged is small, the electric field force therebetween can also be reduced. As a result, vibration of the grid electrode can be prevented due to the interaction between the two.

Embodiment FIG. 1 shows the first embodiment of the charging device of the present invention. In the figure, (1) is a shield case made of a conductive material such as stainless steel molded into a U-shape. The wire-shaped first corona electrode (2) and second corona electrode (3) are stretched adjacent to each other inside the electrode, and the opening (1a) is located on the right side in the figure. It is disposed so as to face the object to be charged (4) which is moving towards it. The first corona electrode (2) and the second corona electrode (3) are connected to the same DC corona power source (5). Furthermore, between the second corona electrode (3) and the object to be charged (4), there is provided a bias voltage applying means (6) made of metal formed into a mesh shape.
) is connected to a grid electrode (7).

The bias voltage application means (6) is composed of a constant voltage element (6a) such as a varistor, and a switching element (6b) such as a transistor that grounds the grid electrode (7) according to a control signal from the control means (C). ing.

The operation of the charging device will be explained with reference to FIG. 2. When starting to charge the object to be charged (4) moving in the direction of the arrow in the figure, first, the DC corona power supply (5) is energized,
Corona voltage is applied to corona electrodes (2) and (3) to start corona discharge. At this time, at the same time, the control means (C1
A control signal is sent from the switch to the switching element (6b), and the grid electrode (7) is grounded.

In this state, corona ions generated by corona discharge head toward the charged object (4) through the opening (1a) of the shield case (1), but the grid electrode (in the area where the force is applied) (7) is in the grounded state, most of the corona ions are absorbed by the grid electrode (7).
), very little of it passes through the grid electrode (7) and reaches the charged object (4).

Therefore, very few corona ions pass through the grid electrode (7), and the number of corona ions passing through the grid electrode (7) and the charged object (4) is very small.
) is substantially SS o//, so
The grid electrode (7) does not generate any vibration.

As a result, the moving object (4) is located at the opening (1) upstream of the position facing the grid electrode (7).
The grid electrode (7) is charged by the corona ions passing through a), and is charged to a certain potential.
come to a position where you will face him.

When the object to be charged (4) charged to the above-mentioned certain potential comes to a position facing the grid electrode (7), only the control signal from the control means (q) is turned off. ), the grounding of the grid electrode (7) is released, and substantially only the constant voltage element (6a) is connected to the grid electrode (7), and the potential of the object to be charged (4) is lower than that of the constant voltage element. Corona ions pass between the grid electrodes (7) and charge the object to be charged (4) until the potential set in (6a) is approximately reached.At this time, the object to be charged (4) is , the amount of corona ions that pass through the grid electrode (7) and reach the charged object (4) is relatively small, and the distance between the grid electrode (7) and the charged object is relatively small. Since the potential difference between the grid electrode (7) and the object (4) is small, the grid electrode (7) does not generate vibrations.

As described above, the charging device performs corona discharge with the grid electrode (7) grounded for a certain period of time from the start of charging, and discharges the corona discharge directly to the charged object (4) without passing through the grid electrode (7). The object to be charged (4) facing the grid is charged by the corotron method that applies corona ions (7).
) is charged to a certain extent, then bias application to the grid electrode (7) is started to charge the grid electrode (7) using the scorotron method. That is, when charging by the scorotron method starts, the object to be charged (4) facing the grid electrode (7) is already charged to a certain level of potential; Since the object to be charged (4) is charged with a charge to a predetermined potential, the amount of charge applied to the object to be charged is lower than that when applied to an uncharged object (4). Much less is enough. Therefore, the grid electrode (7
) The amount of corona ions passing through the grid electrode (7) is small, and the potential difference between the grid electrode (7) and the charged object (4) is small. Vibration can be effectively prevented.

Furthermore, the object to be charged (4) is stably charged to a predetermined potential by scorotron charging.

The bias application timing of the grid electrode (7) in the charging device is set according to various conditions such as the moving speed of the object to be charged (4) and the voltage of the DC corona power source (5). For example, the moving speed of the charged object (4) is set to 450 f.
f/see, when the voltage of the DC corona power supply 5 and the set potential of the grid electrode (7) 7a is +600V, the bias voltage application delay time to the grid electrode (7) is 90m5
ec, the object to be charged (4) could be well charged to a predetermined potential without vibration of the grid electrode (η).

In the above embodiment, two corona electrodes are provided, but the number is not limited to two, and the number may be two or more, or may be one. Also,
The DC corona power supply (5) has corona electrodes (2), (3
) may be provided, and in that case, a small corona power source can be used for each corona power source.

FIG. 3 shows a second embodiment of the present invention, in which the first corona electrode (
2) and the second corona electrode (3), respectively, are connected to an independent first corona power source (5a) and a second corona power source (5b), and a constant voltage element (6a) such as a varistor is connected to the grid electrode (7). ) or connected. In addition, this example and the above-mentioned first
Components that are common to the embodiments are given common numbers, and detailed explanations thereof will be omitted.

In the above configuration, when charging the object to be charged (4), first, the first corona power source (5a) is energized and the first corona electrode (
2) Generate corona nearby and charge the charged object (4) facing the first corona electrode (2). When the charged object (4), which has been charged to some extent by the corona discharge from the first corona electrode (2), comes to a position facing the grid electrode (7), the second corona power source (5b) is energized. and second
A corona is generated near the corona electrode (2) and charges are applied to the charged object (4) via the grid electrode (7). Therefore, as in the previous embodiment, since the charged object (4), which is charged to some extent, is charged by the scorotron method, the grid electrode (7) is also used in this embodiment.
) can reduce the amount of corona ions passing through the grid electrode (7), reduce the potential difference between the grid electrode (7) and the charged object (4), and prevent vibration of the grid electrode (7). can do.

Note that the energization timing of the second corona power source (5b) in this embodiment may be such that the second corona power source (5b) is turned on after a certain period of time after the first corona power source (5a) is turned on, or as shown in FIG. Additionally, the voltage rise time of the second corona power source (5b) may be lengthened so that it is turned on at the same timing as the first corona power source. Furthermore, the first and second corona electrodes (
The corona power supplies applied to (2) and (3) may not be independent, but a single one, and the corona voltages may be supplied through appropriate switching means.

Effects of the Invention As is clear from the above explanation, the charging device according to the present invention can prevent vibration of the grid electrode with an extremely simple configuration, so it has stable charging performance of the scorotron system. In addition, a high-output charging device that can handle high-speed processing can be obtained.

[Brief explanation of the drawing]

FIG. 1 is a diagram showing a first embodiment of the charging device according to the present invention, FIG. 2 is a time chart showing control timing, and FIG.
The figure shows the second embodiment, and FIG. 4 is a time chart showing an example of the control timing in the second embodiment. 2... First corona electrode, 3... Second corona electrode, 6
...Bias means, 7...Grid electrode applicant Minolta Camera Co., Ltd. 0s OFF Figure 3 Figure 4 Electrical system

Claims (1)

[Claims] 1. A charging device that imparts a uniform charge to a moving object to be charged, comprising: a scorotron charging means having a grid electrode to which a bias voltage of a desired charging polarity is applied; and the above-mentioned scorotron charging means. a corotron charging means that is provided adjacent to the scorotron charging means on the upstream side in the moving direction of the object to be charged, and applies an electric charge having the same polarity as the charging polarity of the scorotron charging means; A charging device comprising: a charging control means for controlling the Scorotron charging means to start charging after a predetermined period of time after the start of charging by the Scorotron charging means. 2. The charge control means first energizes the corotron charging means to apply a charge to the surface of the moving charged object, and then the surface portion of the charged object charged by the corotron charging means is at least connected to the scorotron. The charging device according to claim 1, wherein the charging device is controlled so that the scorotron charging device is energized to start charging when the scorotron charging device reaches a position facing the charging device. 3. The charging device according to claim 2, wherein the scorotron charging means includes bias voltage applying means for applying a bias voltage to the grid electrode. 4. The bias voltage applying means is switchable between a first state in which a bias voltage is applied to the grid electrode and a second state in which the grid electrode is grounded. charging device. 5. A patent claim characterized in that the control means keeps the bias voltage application means in the second state for a certain period of time from the start of charging, and switches the bias voltage application means to the first state after the elapse of the certain period of time. 4. The charging device according to item 4.