JPH0546547B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] An electrostatic recording device based on electrophotography generally records an image through the processes of latent image formation, development, transfer, and fixing. In these processes, a corona discharger is used for charging the photoreceptor for forming a latent image, transferring it, and separating the transfer paper, and the present invention relates to improvements in this corona discharger.

[Background of the invention]

In an electrophotographic apparatus, a photoreceptor is given photosensitivity by being charged. Since the sensitivity depends on the charging voltage, the corona discharge device is required to have certain discharge characteristics in order to obtain a constant charging voltage. Furthermore, even in transfer, if the discharge current changes, the transfer becomes uneven, which causes deterioration of image quality, so it is required to have a certain discharge characteristic.Furthermore, in separation, if the discharge current changes, separation defects may occur. This can cause paper jams.
It is required to have certain discharge characteristics.

As described above, a corona discharge device used in an electrophotographic apparatus is required to have constant discharge characteristics.

[Problem to be solved by the invention]

A conventional corona discharge device and its problems will be explained based on FIGS. 1 and 2.

Note that in the following description of the conventional example and the description of the present invention, grounding may be actually grounded or may be grounded to the casing of the device.

In FIG. 1, 1 is a power source that outputs a high voltage that generates corona discharge, 2 is a charger (corona discharger), 3 is a grid, and 4 is an image carrier (photoreceptor), which includes a photosensitive layer 41 and a substrate (conductor). gender base) consisting of 42. In this example, by connecting a varistor VD ₁ (or a Zener diode) between grid 3 and ground, even if the voltage of high voltage power supply 1 exceeds a predetermined voltage, the ion flow from charger 2 increases and grid 3
Even if the voltage applied to V _G increases, the grid voltage remains constant.

According to this circuit, although a constant grid voltage can be obtained, this constant voltage cannot be changed. The charging characteristics of a photoreceptor change due to temperature changes, fatigue, and the like. If the grid voltage V _G is fixed as shown in FIG. 1, it is not possible to compensate for changes in the charging characteristics of the photoreceptor. That is, after the photoreceptor becomes fatigued due to repeated copying, the charging voltage of the photoreceptor changes even if the discharge ion flow is constant.
Furthermore, the charging voltage of the photoreceptor similarly changes due to temperature changes.

There is a device shown in FIG. 2 that solves these drawbacks. In this discharge circuit, the grid 3 is connected to a high voltage stabilized power supply 11.
Then, the output voltage of this high voltage stabilized power supply 11 is made variable. However, this discharge circuit has the disadvantage that the device itself becomes large. Furthermore, unless the output impedance of the high-voltage stabilized power supply 11 is made sufficiently low, the output voltage of the high-voltage stabilized power supply 11 will not be constant due to the flow of current from the grid 3. In other words, a high-voltage stabilized power supply with sufficiently low output impedance is required. Although such power supplies are expensive and can be used for laboratory equipment, they are not suitable for machines sold on the market.

The present invention aims to solve the problems in the prior art described above.

That is, an object of the present invention is to provide at a low cost a corona discharge device that has discharge characteristics that do not fluctuate and can be set at various levels.

[Means to solve the problem]

The above objects of the present invention are achieved by the following corona discharge device.

(a) a discharge electrode; (b) a high-voltage power source 1 for the discharge electrode; (c) an ion flow control member 3 that generates a voltage by the ion flow from the discharge electrode and controls the ion flow from the discharge electrode; and (d) the ion flow control member. 3. The voltage control means comprises: (a) a reference voltage generation means that can be set to various voltages;
VR, b Detection means R ₁ , R ₂ for detecting the voltage of the ion flow control member 3; c Comparison means for comparing the voltage of the reference voltage generation means VR and the detection voltage of the detection means R ₁ , R ₂ ;
AMP ₁ and d: a variable impedance element Tr connected between the ion flow control member 3 and the ground and whose impedance changes depending on the output of the comparison means AMP ₁ . corona discharge device.

[Effect]

In the present invention, by setting the set voltage of the set voltage generating means to various values, the voltage of the ion control member can be changed, thereby adjusting the ion flow, and the control means can also be adjusted. It is thus possible to maintain the voltage of the ion control member at a set voltage and to keep the discharge characteristics of the corona discharger constant at an adjusted value.

〔Example〕

The present invention will be explained below with reference to illustrated embodiments.

FIG. 3 is a conceptual diagram for explaining the operating principle of the present invention, and FIGS. 4 and 5 show embodiments of the present invention.

In the figures, the same parts as in FIGS. 1 and 2 are designated by the same reference numerals.

As shown in FIG. 3, in the present invention, a variable impedance element is connected between the grid 3 and the ground.
By connecting V _Z and controlling the grid 3 by the control circuit 5.
The voltage is controlled so that the voltage is constant. Even if the ion current from the charger 2 fluctuates, the impedance of the variable impedance element V _Z remains unchanged.
The control circuit 5 controls and changes the ion current in response to variations in the ion current to keep the grid voltage constant. By operating the control circuit 5, the voltage of the grid 3 can be set to various values.

FIG. 4 shows one embodiment of the present invention.

As shown, the voltage V _G of grid 3 is connected to resistor R ₁ ,
Partial pressure is determined by R ₂ . On the other hand, a set voltage V _S is created by a variable resistor VR. This voltage V _S is a variable resistance
It can be set to various values by changing VR. Error amplifier AMP1 and AMP2 are resistors
The voltage divided by R ₁ and R ₂ is compared with the set voltage V _S and the difference is amplified. The bipolar transistor Tr is a variable impedance element, and the output of the error amplifier AMP2 is input to the base of this transistor Tr. Note that D is a base protection diode. The impedance of the transistor Tr changes depending on the output of the error amplifier AMP2, so even if the grid current fluctuates, the grid voltage V _G
Control is performed so that the voltage becomes a constant voltage corresponding to the set voltage _VS.

With this circuit configuration, the voltage V _G of the grid 3 is held constant even if there are fluctuations in the ion flow from the corona discharger. Further, this voltage V _G can be set to various values by changing the resistance value of the resistor VR and changing the voltage V _S.

In FIG. 5, a varistor _VD2 is inserted between the grid 3 and the transistor Tr. According to this embodiment, the voltage V _G applied to the grid 3 is divided by the varistor VD ₂ and the transistor Tr, so the voltage applied to the transistor Tr becomes low, and the transistor Tr can be used as a low-cost transistor with a low collector breakdown voltage. Transistors can be used.
In fact, when using a 0PC photoreceptor, the varistor VD ₂
The voltage applied to the transistor Tr is about 430V, and the voltage applied to the transistor Tr
If the voltage applied to the grid 3 is set to about 0 to 100V, sufficient control can be performed to eliminate fluctuations in the voltage _VG of the grid 3. Note that the barista
A Zener diode may be used instead of _VD2 .

FIG. 6 shows a variable impedance element according to the present invention for controlling the voltage of the ion flow control member 3.
This is a specific example of a Tr and a control circuit. Further, FIG. 7 is a graph showing the V _S /V _G characteristics of the circuit shown in FIG. 6.
In FIG. 7, the vertical axis V _G represents the grid voltage, the horizontal axis V _S represents the set voltage, and _IT represents the current supplied from the high voltage power supply to the charger. Furthermore, at adjustment point 1 in Figure 7, the current I _G flowing between the grid and ground is 74 μA when I _T = 300 μA, and at adjustment point 2, I _G is 114 μA when I _T = 500 μA, Also, I _T
= 268μA when it was 900μA. As can be seen from Figure 7, at I _T = 500 μA and 900 μA, the set voltage V _S and the grid voltage
V _G shows a good linear relationship regardless of the current I _T . Also, even when I _T =300μA, V _S =0 to 3V
V _S vs. V _G independent of current I _G in the range of
The correspondence relationship is shown.

That is, as is clear from FIG. 7, according to the variable impedance element Tr and control circuit according to the present invention for controlling the voltage of the ion flow control member 3,
It is possible to maintain the voltage of the ion flow control member 3 at a constant value that is not affected by the ion current, and this voltage can be set to various values.

Although the embodiments described above are examples of a discharge device that performs negative charging, it is of course applicable to a discharge device that performs positive charging. In this case, an NPN type transistor is used as the transistor Tr. Further, in the above embodiment, a bipolar transistor is used as the variable impedance element, but a phototransistor or CdS on the output side of an FET or photocoupler may also be used.

Furthermore, although grid voltage control of a scorotron is shown as an example, the present invention is not limited thereto, and can be used to control the back plate voltage of a corotron or scorotron. Furthermore, the present invention can be used not only for charging to impart sensitivity but also for voltage control of a screen electrode used as a means for writing a latent image on a photoreceptor.

Furthermore, the set voltage V _S may be determined by detecting the potential, temperature, degree of fatigue, etc. of the photoreceptor, and changing the voltage V _S in accordance with the detected value. By doing so, charging control is performed in accordance with changes in the charging characteristics of the photoreceptor due to temperature changes, degree of fatigue, etc., and it becomes possible to always carry out appropriate charging.

〔effect〕

In the discharge device of the present invention, since the voltage of the ion flow control member can be set, appropriate charging is always performed according to the conditions of the photoreceptor, etc., and
Constant discharge characteristics are maintained at the set voltage. This discharge device is realized with a relatively simple circuit configuration and can be manufactured at low cost.

[Brief explanation of the drawing]

1 and 2 show a conventional example. Embodiments of the discharge control device of the present invention are shown in FIGS. 3 to 5. FIG. 6 is a circuit diagram of one embodiment of the present invention that was actually created, and FIG. 7 shows the results of an experiment using the circuit shown in FIG. 1... High voltage power supply, 2... Charger (scorotron), 3... Grid, 4... Image holder, 41...
...Photosensitive layer, 42...Base, 5...Control circuit, 11
...High voltage stabilized power supply, VD ₁ , VD ₂ ...Varistor,
V _G ... Voltage applied to the grid (grid voltage),
V _Z ...Variable impedance element, AMP1,
AMP2...error amplifier, T _r ...transistor,
D...Base protection diode, VR...Variable resistor, V _S ...Set voltage, _R1 , _R2 ...Resistance, V _A ...
Voltage applied to the varistor VD ₂ , V _T ... Voltage applied to the transistor Tr, I _T ... Current supplied from the high voltage power supply to the charger.

Claims (1)

[Scope of Claims] 1. A discharge electrode; 2. A high-voltage power source 1 for the discharge electrode; 3. An ion flow control member 3 that generates a voltage by the ion flow from the discharge electrode and controls the ion flow from the discharge electrode. and (d) a voltage control means for controlling the voltage of the ion flow control member 3, wherein the voltage control means includes: (a) a reference voltage generation means that can be set to various voltages;
VR, b Detection means R ₁ , R ₂ for detecting the voltage of the ion flow control member 3; c Comparison means for comparing the voltage of the reference voltage generation means VR with the detection voltage of the detection means R ₁ and R ₂ ;
AMP ₁ and d: a variable impedance element Tr connected between the ion flow control member 3 and the ground and whose impedance changes depending on the output of the comparison means AMP ₁ . corona discharge device. 2. The corona discharge device for an electrostatic recording device according to claim 1, wherein the ion flow control member 3 is a scorotron grid, a back plate, or a screen electrode. 3. A corrodischarge device for an electrostatic recording device according to claim 1, wherein the variable impedance element Tr is a bipolar transistor, an FET, a transistor on the output side of a photocoupler, or a CdS. 4 The variable impedance element Tr is a varistor
_2. The corona discharge device for an electrostatic recording device according to claim 1, wherein the corona discharge device is connected to the ion flow control member 3 via VD 2 , VD or a Zener diode. 5. The reference voltage generating means VR has the potential of the photoreceptor,
2. The corona discharge device for an electrostatic recording device according to claim 1, wherein the corona discharge device is a voltage generating means that detects temperature or fatigue and generates a voltage corresponding to the detected value.