JPH0445825B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an image quality control method in an electrostatic recording system.

In the electrostatic recording method, a detection area is formed outside the electrostatic latent image forming area of the latent image carrier, a predetermined charging pattern is formed in this detection area during recording,
This charged pattern is developed to obtain a pattern image using toner, and the density of this pattern image is detected. Based on the detection results, it is possible to replenish toner to the developing device, control the developing bias voltage, or adjust the amount of exposure light. A method of controlling the quality of an electrostatically recorded image to be obtained by performing control is known. The parameters for controlling the toner replenishment, developing bias voltage, exposure light amount, etc. are called image quality parameters.

That is, the density of the pattern image obtained by developing the charging pattern formed in the detection area has a corresponding relationship with the toner density in the developing device.
Therefore, the toner density can be known from the density of the pattern image, and the quality of the electrostatically recorded image can be controlled by replenishing toner or controlling the developing bias voltage.

This image quality control method can be carried out regardless of whether the developing method is wet or dry.

Regarding such image quality control methods, conventionally,
I had a problem as described below.

In other words, when implementing this control method,
The pattern image formed in the detection area of the latent image carrier is not transferred onto the recording sheet. If it were to be transferred, this pattern image would appear on the recording sheet, making the recorded image unsightly.

Furthermore, transferring a visible image onto a recording sheet means repeatedly using the same latent image carrier, and the image quality must be controlled repeatedly. The formed pattern image must also be removed from the latent image carrier during each recording process.

This pattern image is removed by a latent image carrier cleaning device.

By the way, in the conventional method, the charging potential of the charging pattern formed in the detection area is the same potential as the electrostatic latent image forming potential, and therefore, when there is sufficient toner in the developing device, the pattern image cannot be formed. The amount of toner formed is quite large, and when the pattern image is removed from the latent image carrier by the cleaning device, the cleaning conditions imposed on the cleaning device are harsh, which may result in poor cleaning of the pattern image. This problem easily occurs, and this causes the problem that proper image quality control cannot be performed.
Further, it is desirable to keep the cleaning performance as low as possible. This is because the higher the cleaning performance is set, the stronger the load is placed on the latent image carrier during cleaning, and the faster the life of the latent image carrier deteriorates.

An object of the present invention is to improve the above-mentioned image quality control method in order to solve these problems.

Hereinafter, the present invention will be explained based on specific embodiments with reference to the drawings.

In FIG. 1, reference numeral 1 indicates a tourist body which is a photoconductive latent image carrier. Code 2 is charger,
3 is an erase lamp, 4 is an exposure light beam, 5 is a developing device, 6 is a detection system, 7 is a transfer charger, 8 is a cleaning device, 9 is a static eliminator, and S is a recording sheet, respectively. It shows.

In this device, the electrostatic recording process is performed roughly as follows.

That is, during recording, the sightseeing object 1 rotates in the direction of the arrow, that is, in the counterclockwise direction in the figure. charger 2
1 uniformly charges the circumferential surface of the tourist object 1, and the erase lamp 3 eliminates the charge in unnecessary parts by irradiating light.

Image exposure is then performed using the exposure light beam 4.

The exposure light beam 4 may be an imaging light beam that forms an optical image of the original, or a laser beam that scans a line across the photoreceptor 1 in the direction of the rotation axis while turning on and off according to a recording signal.

The electrostatic latent image formed by the image exposure is developed by the developing device 5, and the resulting visible image is transferred onto the recording sheet S by the transfer charger 7. The developing device 5 may be a dry developing device or a wet developing device. Further, the recording sheet S is generally plain paper.

The recording sheet S to which the visible image has been transferred is subjected to necessary processing such as fixing the visible image or drying.
Expelled from the device.

After the visible image has been transferred, the sightseeing object 1 is cleaned by a cleaning device 8 and static electricity is removed by a static eliminator 9. The recording process is thus completed.

Now, a detection area is set outside the tip of the electrostatic latent image forming area of the tourist body 1, which is a latent image carrier. This state is conceptually shown in FIG. Arrow A indicates the direction of movement of the circumferential surface of the photoreceptor 1 due to rotation of the photoreceptor 1, area DI is a detection area, and area D2 is an electrostatic latent image forming area. However, in the case of a seamless, endless photoreceptor, the tip of the electrostatic latent image forming area, that is, the boundary between areas D1 and D2, is generally not fixed on the photoreceptor. not present. Therefore, whenever the detection area is set outside the tip of the electrostatic latent image forming area, it means that the area outside the tip of the electrostatic latent image area is used as the detection area. , the detection area does not necessarily need to be fixedly set at a specific position on the photoreceptor.

Now, in the detection area D1 (FIG. 2), a charging pattern P as shown is formed. This charged pattern P is visualized by the developing device 5 to become a pattern image, and the image density is determined by the detection system 6 (Fig. 1).
Detected by

The detection system 6 includes a light source 61 and a light receiving element 62, and irradiates the peripheral surface of the photoreceptor 1 with light from the light source 61, and photoelectrically converts the reflected light with the light receiving element 62. The surface of the latent image carrier, whether photoconductive or dielectric, has a constant reflectance, but if there is toner on the surface, the light from the light source 61 is absorbed by the toner. Therefore, the reflectance becomes low.

Therefore, if the charging pattern P shown in FIG. 2 is uniformly charged, the output of the light receiving element 61 of the pattern image based on this charging pattern P will be as shown in FIG. 3. . When the pattern image area is irradiated with light from the light source 61, the reflected light becomes smaller due to light absorption by the toner.
The output voltage of the light receiving element 62 has a low value of _V1 .

An increase in the output voltage V ₁ means that the reflected light is large, that is, the density of the pattern image is low. In other words, the amount of toner in the developing device 5 is reduced. Therefore, the output voltage V ₁ is
The image quality of electrostatically recorded images can be well controlled by replenishing toner each time a predetermined set voltage range V ₀ is exceeded.

By the way, as mentioned above, if the charging potential of the charging pattern formed in the detection area is the same as the electrostatic latent image forming potential, cleaning of the pattern image will be insufficient, and proper image quality control will not be possible. I get used to it.

Therefore, in the present invention, the charging potential of the charging pattern is set one step lower than the electrostatic latent image forming potential to facilitate cleaning of the pattern image, thereby solving the above problem and controlling image quality appropriately. was made possible.

Therefore, even in normal cases, the density of the pattern image obtained from the charging pattern is about the so-called intermediate density, but even in this case, the state of the presence of toner in the developing device can be sufficiently detected, and image quality control can be performed. There is nothing wrong with the above. That is, the charging potential of the charging pattern, which is set one step lower than the electrostatic line image forming potential, is such that when the charging pattern is normally developed, the pattern image density will be approximately an intermediate density.

By the way, as a method of forming a charging pattern in the detection area, a method of uniformly charging the detection area and then irradiating a light image of a negative pattern of the charging pattern can be considered, but depending on the density of the negative pattern and the illumination light intensity. It is easy to change over time, and the charging pattern may also change over time, causing problems in image quality control.

Therefore, in the present invention, taking these points into consideration,
Without using the method of irradiating a negative pattern light image,
A charging pattern is formed using charging means. Although there are various such methods, three examples will be given here.

In the method shown in FIG.
Switching the discharge voltage in two stages, first uniformly charging the detection area to the charging pattern charging potential Vp,
Next, the charging voltage is increased to the electrostatic latent image forming potential _VI (same figure).

Accordingly, the timing of starting exposure of the detection area with the exposure light beam 4 is adjusted as shown in FIG. 4, and a charging pattern as shown in FIG. 4 is obtained. Note that in the electrostatic latent image forming area, an electrostatic latent image is formed by exposure with the exposure light beam. This is the fourth
In the figure, it is represented by a broken line.

In the method shown in FIG. 5, after the photoreceptor 1 is charged in two stages with voltages Xp and _VI by the charger 2 (see the same figure), the detection area having the voltage Vp is
By determining the timing of the light emission of the erase lamp 3 as shown in FIG. 5 and the timing of the start of exposure by the exposure light beam as shown in FIG. 5, a charging pattern as shown in FIG. 5 is obtained.

In the method shown in FIG. 6, the photoreceptor 1 is charged by the charger 2 to two levels of voltages Vp and _VI (simultaneously). The timing of the start of exposure is as shown in the same figure for the detection area with voltage Vp, but in the middle of uniform exposure of the detection area, the exposure light flux is interrupted by a shutter (the part indicated by reference numeral 6-1). ). As a result, a charging pattern as shown in FIG. 6 is obtained. In the above three examples, the charging pattern is formed outside the leading end of the electrostatic latent image forming area, but it may also be formed outside the rear end of the area. Further, in the present invention, the charging potential of the charging pattern need only be smaller in absolute value than the electrostatic latent image forming potential, and the polarity of charging can be applied to either positive or negative.

As mentioned above, if a line image carrier is charged and exposed to light to form a charged pattern, image quality control will become distorted over time, but formation of a charged pattern by charging and exposure is This is also disadvantageous in terms of cleaning the latent image carrier.

That is, when a photoconductive latent image carrier is charged and exposed, the characteristic relationship between the image density of the pattern irradiated by exposure and the charging potential is generally as shown in the curve shown in FIG. 7, as is well known. Become. However, as mentioned above, if there are changes over time in the density of the pattern or the intensity of the illumination light, these changes are generally due to contamination of the optical system or the pattern original, so the apparent density of the pattern image will change due to the changes over time. It gradually changes to become higher.

Therefore, even if the same charging pattern is intended to be formed, the potential of the charging pattern gradually increases with the above-mentioned change over time.

If the above concentration change is ΔD as shown in Figure 7, then
Along with this concentration change, the potential of the charging pattern changes to ΔV
However, in the intermediate concentration region,
This potential increase ΔV is quite large.

As this potential rises, the adhesion force of the toner adhering to the charged pattern also becomes stronger, making it gradually more difficult to clean it. It becomes difficult to keep up. In this case, one possible way to maintain cleaning performance over a long period of time is to set the cleaning performance to a high level with a considerable margin.
It is not preferable to set the cleaning performance to be high in this way because cleaning will accelerate deterioration of the photoreceptor as described above.

On the other hand, when the charging pattern is formed by a charging means as in the present invention, it is possible to prevent the charging potential (dashed line in FIG. 7) of the charging pattern from changing over time, so that the ease of cleaning is always guaranteed.
Deterioration of the latent image carrier due to cleaning is also alleviated.

[Brief explanation of the drawing]

FIG. 1 shows one of the electrophotographic apparatuses to which the present invention is applied.
FIGS. 2 and 3 are explanatory front views schematically showing only important parts of an example; FIGS. 2 and 3 are diagrams for explaining detection areas, charging patterns, and density detection of pattern images; FIG. A diagram to explain the method,
FIG. 5 is a diagram for explaining another method of forming a charged pattern, FIG. 6 is a diagram for explaining another method of forming a charged pattern, and FIG. 7 is a diagram for forming a charged pattern by charging and exposure. FIG. 1... Photoreceptor serving as a photoconductive latent image carrier, 2...
...Charger, 3...Erase lamp, 4...
Exposure light flux, 5...Developing device, 7...Transfer charger, 6...Detection system, 8...Cleaning device,
D1...detection area, D2...electrostatic latent image forming area.

Claims (1)

[Scope of Claims] 1. A charging pattern is formed by charging a detection area set outside the electrostatic latent image forming area in the moving direction of a photoconductive latent image carrier with a charging means, and this charging pattern is an image quality control step of developing a pattern image using a developing means, detecting the density of the pattern image, and after detecting the density, cleaning the pattern image as it is with a cleaning means; A value of an image quality parameter is determined according to the density of the pattern image, and based on the determined value, the electrostatic latent image forming area of the latent image carrier is charged by the charging means and exposed by the exposure means. forming an electrostatic latent image,
This electrostatic latent image is developed by the developing means to obtain a visible image with toner, this visible image is transferred onto a recording sheet, and the latent image carrier after the visible image is transferred is cleaned by the cleaning means. In an electrostatic recording method having an image forming step, the forming potential of the charging pattern in the image quality control step is set to be one step lower in absolute value than the charging potential of the electrostatic latent image forming area in the image forming step. An image quality control method characterized by: