JP4328101B2 - Printing control method and image forming apparatus - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an electrophotographic printing control method and an image forming apparatus in which an image is visualized using colored particles such as toner of a printer, a facsimile machine, a copying machine or the like.
[0002]
[Prior art]
Hereinafter, a conventional printing method will be described. A recording apparatus using an electrophotographic method includes a printing process in which colored particles are visualized as an image on the surface of a recording medium, and a fixing process in which the visualized colored particle images are transferred to the recording medium and fixed. As the colored particles, a powder called toner exclusively for electrophotography is used. In the charging process, the entire surface of the photoconductor is once charged, and subsequently, partial charge discharge is performed by irradiating light in the exposure process. Here, a potential contrast is formed between the charged area and the discharged area on the surface of the photoreceptor, which is called an electrostatic latent image.
[0003]
In the next development step, first, toner particles that are colored particles are charged. The toner charging method includes a two-component developing method using carrier beads and a one-component developing method in which charging is performed by friction between the toner and a member. On the other hand, a method called bias development is often used as a method for developing an electrostatic latent image. In bias development, a bias voltage is applied to the developing roller, and the charged toner particles are separated from the developer on the surface of the developing roller by the action of an electric field generated between the latent image potential formed on the surface of the photoreceptor and the developing roller. Then, it is moved to the surface of the photoconductor to form an image. As the latent image potential (that is, the potential of the image forming portion of the photoconductor), the above-described charging potential or the discharge potential may be used. In general, a method using a charging potential as a latent image potential is called a normal development method, and a method using a discharge potential is called a reversal development method.
[0004]
There are two types of bias development: one that applies only a DC voltage to the developing roller, and one that applies an AC voltage superimposed on the DC voltage. Compared with a DC voltage that is applied with an AC voltage superimposed, it can supply more toner to the latent image on the photoreceptor, and has the advantage of increasing the image density, compared to a DC voltage applied with a development bias of only DC voltage. Have (see, for example, Patent Document 1).
[0005]
Of the charging potential and the discharging potential, the potential that is not used as the latent image potential is called a background potential. The DC voltage of the developing roller bias voltage is set between the charging potential and the discharging potential, and the difference from the latent image potential is called the developing potential difference. Similarly, the difference from the background potential is called the background potential difference. If the development potential difference is large, the electric field formed (referred to as the development electric field) becomes strong, so that the development performance is enhanced. On the other hand, the background potential difference affects the image quality of the background portion of the image. If the background potential difference is small, the fogging of the background portion increases. Incidentally, the toner charge amount is closely related to the development performance. The larger the toner charge amount, the lower the development performance at the same development electric field strength.
[0006]
Next, changes in development performance over time will be described. Factors that cause changes in development performance over time are roughly classified into those caused by fluctuations in the charge amount of the developer and those caused by fluctuations in the developing electric field. In general, the charge amount of toner tends to fluctuate with respect to the humidity of the atmosphere, and increases when the humidity is low, and decreases when the humidity is high. In the case of two-component development, the surface state of the toner and carrier beads changes with time due to friction with the stirring member, and the charge amount of the toner changes.
[0007]
On the other hand, the potential of the discharge region formed by exposure varies due to a change in the temperature of the photoconductor, a change in humidity of the atmosphere, and a change in film thickness over time, regardless of the exposure light amount being constant. This variation in potential in the discharge region is significant when an intermediate potential region that is not completely discharged is provided so as not to give a sufficient amount of light during exposure.
[0008]
By the way, line images, halftone dots, and the like are greatly affected by the peripheral effect of the electric field, and the intensity of the developing electric field is larger than the developing electric field (parallel electric field) generated inside the solid region (solid image portion). Hereinafter, an electric field whose intensity is larger than that of the parallel electric field due to the influence of the peripheral effect is referred to as a peripheral electric field. When the film thickness of the photoconductor changes with time, the parallel electric field and the intensity of the peripheral electric field change as well as the ratio of the intensity of the parallel electric field and the peripheral electric field even under the same development potential difference.
[0009]
In order to make the image quality constant over time, it is necessary to correct the change in the development performance and the change in the development electric field due to the change in the charge amount of the developer.
[0010]
Prior to image formation, a test patch latent image is formed on the photoconductor by a laser writing unit to develop the developed test patch latent image in order to correct the density fluctuation of the printed image that accompanies changes in the charge amount of the developer. The test patch image is developed by a machine and the reflection density (image density) of the test patch image is measured by an optical image density sensor provided upstream of the cleaning device. In the case where the value deviates from the value, a method for controlling the developing bias, the grit voltage of the charger, the replenishment of toner, and the like is known.
[0011]
Also, as a method for correcting fluctuations in the development electric field, the potential of the surface of the photoconductor is detected by a potential sensor, and the film thickness of the photoconductor is detected by some method, and the amount of laser light is changed so that the development electric field is constant. A method for controlling the potential of the photoreceptor surface is known (see, for example, Patent Document 2).
[0012]
Furthermore, a method is also known in which the control using the optical image density sensor is combined with the control using the photoreceptor potential sensor.
[Patent Document 1]
Japanese Patent Laid-Open No. 62-28958 [Patent Document 2]
Japanese Patent Laid-Open No. 11-15214
[Problems to be solved by the invention]
In the above conventional technique, when the distance between the photosensitive member and the developing roller (development gap) varies from product to product, the gradation density variation of 100% area ratio (solid portion) and a low area ratio of 0 to 50% occurs. Although it can be corrected to be relatively small, there is a problem that gradation density variation with a high area ratio of 50 to 90% cannot be corrected.
[0014]
The object of the present invention is to correct all gradation densities from a low area ratio to a high area ratio even when the distance between the photosensitive member and the developing roller (development gap) varies from product to product in an electrophotographic recording apparatus. It is to provide a printing control method that can be performed.
[0015]
[Means for Solving the Problems]
The above object includes a photoconductor, a charger provided with a grid, an exposure unit, a developing device, a control unit, and a sensor for detecting a test patch formed on the photoconductor, and the exposure apparatus. The exposure amount is adjusted by the control means, and a DC voltage and an AC voltage are applied to the developing machine, and a background area and an image area are formed on the photoconductor using the charger and the exposure device. In a printing control method of an electrophotographic image forming apparatus to be formed, a first exposure amount that is an exposure amount adjusted to print the inside of a solid image, a peripheral portion other than the inside of the solid image, a line image, and a halftone dot A second exposure amount that is an exposure amount to be adjusted to print an image, and the control means creates a solid test patch latent image on the photoconductor with the first exposure amount, and the DC voltage And the grid applied to the grid A solid image patch, which is a solid image test patch, by developing the solid image test patch latent image with the developing device after changing the DC voltage and the grid voltage to be constant. The voltage value of the DC voltage and the voltage value of the grid voltage for making a predetermined solid image density are determined by creating and measuring the image density inside the solid image patch with the sensor After the first adjustment is performed, the second exposure amount is changed, and a first halftone dot image patch that is a test patch of a halftone dot image having a constant area ratio is formed on the photoconductor. The second adjustment is performed to determine the second exposure amount to be within the range of the image density of the predetermined halftone image by creating and measuring the image density of the first halftone image patch by the sensor. After performing the second adjustment A second halftone dot image patch, which is a test patch of a halftone dot image having an area ratio of 60% to 80%, is created on the photosensitive member, and the second halftone dot image patch is formed by the sensor. The measurement result image density obtained by measuring the image density is compared with a predetermined image density range of the halftone image, and the measurement result image density is a predetermined image density range of the halftone image. The control means terminates the control, and when the measurement result image density is outside the range of the image density of the predetermined halftone image, the amplitude of the alternating voltage is changed, and the first adjustment and This is achieved by repeating the second adjustment again.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
An embodiment of the present invention will be described below with reference to FIGS.
[0017]
FIG. 1 is a diagram schematically showing a cross section of the recording apparatus of this embodiment. 1 is a photosensitive drum, 2 is a scorotron charger, 3 is a developing machine, 4 is recording paper, 5 is a transfer machine, 6 is a fixing machine, 7 is a cleaner, 8 is an exposure device, 9 is a control device, and 10 is an optical type. It is an image density sensor.
[0018]
A latent image is formed on the surface of the photosensitive drum 1 uniformly charged by the scorotron charger 2 with a resolution of 600 dpi by the exposure device 8 based on the image signal. Thereafter, the toner is developed by the developing machine 3 to which a bias in which an AC voltage is superimposed on a DC voltage is applied. The frequency of the alternating voltage superimposed on the developing bias is preferably 2 to 16 kHz, the amplitude Vpp is preferably 0.4 to 2.0 kV, and the waveform is rectangular, sine, triangular, or the like. The toner developed on the surface of the photosensitive drum 1 is transferred to the recording paper 4 by the transfer machine 5. Thereafter, the transferred toner image is heated and melted by the fixing device 6 and fixed on the recording paper 4. Further, the toner remaining on the surface of the photosensitive drum 1 without being transferred is collected by the cleaner 7 and the series of processes is completed. In this embodiment, a test patch latent image having a predetermined image pattern is formed on the photosensitive member by the exposure device 8, and this test patch latent image is developed by the developing device 3 to form a test patch image. The reflection density of the test patch image is detected by the density sensor 10, and the grit voltage Vg of the scorotron charger, the DC voltage Vb of the developing bias, and the amplitude Vpp of the AC voltage are adjusted by the control device 9 based on the detected value. be able to.
[0019]
FIG. 2 is a diagram schematically showing a developing electric field generated when developing a solid image and a developing electric field generated when developing a halftone dot or a line image with the horizontal axis as a position on the photosensitive member. . 30 corresponds to a developing electric field generated when developing a solid image, and 31 corresponds to a developing electric field generated when developing a halftone dot or a line image. The interior of the solid image is an area that is not affected by the peripheral effect of the electric field. The developing electric field generated in this area is called a parallel electric field, and is indicated by 32 in FIG. On the other hand, the edge of the solid image, the halftone dot, and the line image are affected by the peripheral effect of the electric field, and an electric field stronger than the parallel electric field is generated. The developing electric field generated at the edge of the solid image and the halftone dot or line image is called a peripheral electric field, and is indicated by 33 in FIG. Due to this peripheral electric field, more toner is developed in the halftone dots and line image than in the solid image.
[0020]
In this recording apparatus, an image signal is taken into a memory before exposure, and a portion having a predetermined number of pixels adjacent to a blank portion of all images is detected by a pattern matching method. The portion of the predetermined number of pixels adjacent to the blank paper portion is exposed with the exposure amount E2, and the other portions are controlled by the exposure control means 9 so as to be exposed with the exposure amount E1.
[0021]
The predetermined number of pixels adjacent to the blank paper portion is set to be equal to or less than the number of pixels corresponding to the width of the peripheral electric field generated at the edge of the solid image. In this embodiment, a peripheral electric field is generated at the end of the solid image over a width of about 200 μm, which corresponds to a pixel number of about 5 dots at a resolution of 600 dpi. In order to make this peripheral electric field the same strength as the parallel electric field, it is necessary to set the number of pixels of 5 dots where the peripheral electric field is generated to a predetermined number of pixels. In order to correct the fluctuation of the peripheral electric field, Experiments have shown that the image quality of halftone dots and line images can be stabilized with a smaller number of pixels. In this embodiment, the predetermined number of pixels adjacent to the blank page is set to 2 dots. FIG. 3 shows a 2-dot-width portion adjacent to the detected blank paper portion as 35 and the other portion as 34 for a random image pattern. The two-dot width portion 35 adjacent to the detected blank paper portion is a region having a small image width and an end portion of the solid image, and is a region in which the peripheral electric field is dominant. Next, the relationship between the exposure dose E1 and the exposure dose E2 will be described. FIG. 4 is a diagram showing the light response characteristics of the photosensitive drum 1. The horizontal axis E is the exposure amount and is indicated by the light energy input to the photosensitive drum 1. The vertical axis represents the potential of the photosensitive drum 1 at a fixed time after exposure. V0 on the vertical axis represents the background potential during development. Vr1 on the vertical axis is the potential on the photoreceptor 1 corresponding to the exposure amount E1, and Vr2 is the potential on the photoreceptor 1 corresponding to the exposure amount E2. Vb is a bias voltage of the developing machine, and Vb-Vr1 and Vb-Vr2 are development potential differences.
[0022]
That is, Vb-Vr2 is used as the developing potential for the edge, line image, and halftone of the solid region where the electric field peripheral effect acts strongly, and Vb-Vr1 is used as the developing potential for the solid region (solid image). Use.
[0023]
FIG. 5 is a diagram showing the fluctuation of the gradation curve when the distance between the photosensitive member and the developing roller (development gap) varies from product to product. Reference numeral 14 denotes a gradation curve when the development gap is appropriate. Is a gradation curve when the development gap is narrower than the appropriate development gap, and 16 is a gradation curve when the development gap is wider than the appropriate development gap.
[0024]
FIG. 6 shows a test patch image of an image developed by a parallel electric field (solid image) detected by an image density sensor, and the DC voltage of the development bias is set so that the detected density by the image density sensor becomes a predetermined value. The image density sensor detects a test patch image of an image (a halftone dot image with an area ratio of 50%) developed on the photoconductor by the peripheral electric field while adjusting and maintaining the DC bias condition of the development bias. When the gradation amount is corrected by adjusting the irradiation light amount E2 for exposing an image area having a width of several dots adjacent to the blank paper portion so that the detection density by the image density sensor becomes a predetermined value. It is a gradation curve.
[0025]
In this control method, as shown in FIG. 6, when the distance between the photosensitive member and the developing roller (development gap) varies from product to product, the density of the area ratio 100% (solid image) and the area ratio 0-50. %, The gradation density of the low area ratio can be corrected, but the fluctuation of the gradation density of the high area ratio of 50 to 90% cannot be sufficiently corrected.
[0026]
FIG. 7 shows a comparison of gradation curves when a developing bias of only a DC voltage is applied and when a developing bias in which an AC voltage is superimposed on the DC voltage is applied. 19 is a gradation curve when a developing bias of only a DC voltage is applied, and 20 and 21 are gradation curves when a developing bias in which an AC voltage is superimposed on a DC voltage is applied. Here, 21 corresponds to the case where the amplitude Vpp of the AC voltage is larger than 20. Reference numeral 22 denotes a point where a gradation curve when a developing bias of only a DC voltage is applied and a gradation curve when a developing bias in which an AC voltage is superimposed on the DC voltage are applied intersect. When an AC voltage is superimposed and applied to the developing bias, not only the image density of a solid image with an area ratio of 100% increases, but also the developability of an image with a relatively large area ratio increases, and an image with a small area ratio is developed. The slope of the gradation curve changes due to a decrease in the characteristics. When the AC voltage is applied in a superimposed manner, the rate at which the gradient of the gradation curve changes increases as the amplitude Vpp of the AC voltage increases.
[0027]
The image area ratio at the point 22 where the gradation curve when the development curve of only the direct current voltage is applied and the gradation curve when the alternating current voltage is applied in an overlapping manner is the development bias direct current voltage Vb and on the photoreceptor. It is determined by the relationship of the potential latent image. When the development potential difference and the background potential difference are equal, the intersection is a point where the area ratio of the image is near 50%, and the intersection shifts to the lower area ratio as the development potential difference becomes larger than the background potential difference. For example, when the charging potential is −600 V, the discharge potential is −50 V, and the DC voltage Vb of the developing bias is −400 V, the intersection is a point with an area ratio of about 30%. In a portion with a relatively small area ratio of 50% or less, the development by the peripheral electric field is primarily dominant. Therefore, the change in the image density when the amplitude Vpp of the AC voltage is changed is small. A portion with a relatively large area ratio of 50% or more has a large change in image density when the amplitude Vpp of the AC voltage is changed.
[0028]
Next, the printing control method of the present invention will be described.
[0029]
(Procedure 1)
First, several solid test patch latent images are created on the photosensitive member with a constant exposure amount E1 under the condition of the amplitude Vpp of a certain AC voltage (design center value at the start of control).
Next, while the difference between the DC voltage Vb of the developing bias and the grit potential Vg of the scorotron charger is kept constant, for example, 150V, the test patch latent image is developed by changing Vb and Vg at several points every 50V. Let it be a patch image. Next, the image density inside the test patch image of the solid image (area developed by the parallel electric field) is measured by the optical image density sensor 10, and the development bias DC voltage Vb and the solid image shown in FIG. 9 are measured. Get the concentration relationship. From FIG. 9, the value of the DC voltage Vb of the developing bias that becomes the target solid image density 36 is determined by linear approximation. The grit potential Vg of the scorotron charger is determined to be Vb + 150V.
[0030]
(Procedure 2)
Several test patch latent images of an image mainly developed by a peripheral electric field are formed on the photosensitive member while changing the exposure amount E2 under the conditions of the DC voltage Vb of the developing bias determined in the procedure 1 and the grid potential Vg of the scorotron charger. To do. As the test patch latent image, a halftone image having a constant area ratio (for example, 50%) is used. After developing the test patch latent image to obtain a test patch image, the optical image density sensor 10 measures the image density of the test patch image, and the relationship between the exposure amount E2 and the halftone dot image density shown in FIG. obtain. From FIG. 10, the value of the exposure amount E2 to be the target halftone image density 37 is determined by linear approximation.
[0031]
(Procedure 3)
A test patch latent image of a halftone dot image with an image area ratio of 70% is created under the conditions of the DC voltage Vb of the developing bias determined in steps 1 and 2, the grit potential Vg of the scorotron charger, and the exposure amount E2, and the test patch After developing the latent image into a test patch image, the optical image density sensor 10 measures the image density of the test image of the halftone image and compares it with a predetermined image density range.
[0032]
(Procedure 4)
If the image density of a halftone dot with an image area ratio of 70% is within a predetermined image density range, the control is terminated. On the other hand, when the image density of a halftone dot with an image area ratio of 70% is smaller than a predetermined image density range, the amplitude Vpp of the AC voltage is increased, and conversely, a halftone dot image with an image area ratio of 70%. Is larger than a predetermined image density range, the AC voltage amplitude Vpp is decreased.
[0033]
In Procedure 4, (Procedure 1) to (Procedure 4) are repeated until the image density of a halftone dot having an image area ratio of 70% falls within a predetermined image density range.
[0034]
The change width of the amplitude Vpp of the AC voltage in (Procedure 4) is obtained in advance by obtaining data on the change width of the AC voltage amplitude Vpp and the change rate of the image density. By determining the change width of Vpp, it is possible to quickly converge the image density of halftone dots within a predetermined image density range.
[0035]
FIG. 10 is a gradation curve when gradation correction is performed using the above-described printing control method of the present invention. A test patch image of an image developed by a parallel electric field (solid image) is detected by an image density sensor, and the DC voltage of the development bias is adjusted so that the detected density by the image density sensor becomes a predetermined value, A test patch image of an image (a halftone dot image with an area ratio of 50%) developed on the photosensitive member by a peripheral electric field is detected by an image density sensor while maintaining the condition of the DC voltage of the developing bias. When the tone correction is performed by adjusting the irradiation light amount E2 for exposing the image area of several dots width adjacent to the blank paper portion so that the density detected by the density sensor becomes a predetermined value, FIG. As shown in FIG. 5, when the distance between the photosensitive member and the developing roller (development gap) varies from product to product, it is possible to sufficiently correct the variation in gradation density with a high area ratio of 50 to 90%. Not On the other hand, when gradation correction is performed using the printing control method of the present invention, gradation density with a high area ratio of 50 to 90% can be corrected.
[0036]
In this embodiment, an example in which the image density of a halftone dot having an image area ratio of 70% is adjusted to a predetermined image density has been described. However, the image area ratio used here varies greatly when the development gap varies. If the image area ratio is 60 to 80%, the same effect can be obtained.
[0037]
The above-described printing control is performed at the time of manufacture of the apparatus and after an operation (for example, replacement or repair of the developing machine) in which the development gap may fluctuate, so that the distance between the photosensitive member and the developing roller ( Variations in gradation density due to variations in development gap) can be corrected.
[0038]
Further, only the procedures 1 and 2 are periodically performed when the image forming apparatus is turned on and thereafter after a break in the print job. As a result, stable image quality can be maintained over time for all image patterns even if environmental fluctuations or changes in developer charge amount over time and changes in photoreceptor characteristics occur.
[0039]
Further, in this embodiment, an image signal is taken into a memory before exposure, a portion having a predetermined number of pixels adjacent to the blank portion of all images is detected by a pattern matching method, and a predetermined pixel adjacent to the blank portion is detected. The example in which the exposure is controlled so that the number of portions are exposed with the exposure amount E2 and the other portions are exposed with the exposure amount E1 has been described. However, in the image forming apparatus that exposes all image patterns with the same light amount, By omitting step 2) and performing steps (1), (step 3), and (step 4), it is possible to correct gradation density variations due to variations in the distance between the photosensitive member and the developing roller (developing gap). it can.
[0040]
【The invention's effect】
As described above, according to the present invention, even when the distance between the photosensitive member and the developing roller (development gap) varies from product to product, all gradation densities from a low area ratio to a high area ratio can be corrected. It is possible to provide an image forming apparatus capable of
[Brief description of the drawings]
FIG. 1 is a schematic diagram of a recording apparatus according to an embodiment of the present invention.
FIG. 2 is a schematic diagram of a developing electric field generated when developing a solid image and a developing electric field generated when developing a halftone dot or a line image according to the embodiment of the present invention.
FIG. 3 is an explanatory diagram showing a 2-dot-width portion adjacent to a blank paper portion and other portions using a random image pattern according to the embodiment of the present invention.
FIG. 4 is an explanatory diagram showing optical response characteristics of a photosensitive drum according to an embodiment of the present invention.
FIG. 5 is a diagram illustrating a change in a gradation curve when an interval distance (development gap) between a photoconductor and a developing roller in an embodiment of the present invention varies for each product.
FIG. 6 illustrates gradation bias correction by adjusting a developing bias (DC voltage), a photoreceptor surface potential, and an irradiation light amount for exposing an image area having a width of several dots adjacent to a blank paper portion in the embodiment of the present invention. It is a gradation curve in the case of.
FIG. 7 is a diagram showing a comparison of gradation curves when a developing bias of only a DC voltage is applied and when a developing bias in which an AC voltage is superimposed on the DC voltage is applied in the embodiment of the present invention.
FIG. 8 is an explanatory diagram showing a relationship between a DC voltage Vb of a developing bias obtained by test patch image detection and a solid image density in the embodiment of the present invention.
FIG. 9 is an explanatory diagram showing a relationship between an exposure amount E2 obtained by test patch image detection and a halftone image density in the embodiment of the present invention.
FIG. 10 is a diagram showing a gradation curve when gradation correction is performed using the printing control method of the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Photosensitive drum, 2 ... Scorotron charger, 3 ... Developing machine, 4 ... Recording paper, 5 ... Transfer machine, 6 ... Fixing machine, 7 ... Cleaner, 8 ... Exposure device, 9 ... Control device, 10 ... Optical type Image density sensor, 14 ... gradation curve when development gap is appropriate, 15 ... gradation curve when development gap is narrower than appropriate development gap, 16 ... floor when development gap is wider than appropriate development gap Tone curve, 19: gradation curve when a development bias of only DC voltage is applied, 20, 21: gradation curve when a development bias in which AC voltage is superimposed on DC voltage is applied, 22: development of only DC voltage The point where the gradation curve when the bias is applied and the gradation curve when the alternating voltage is applied are crossed, 30 ... the development electric field generated when developing a solid image, 31 ... the halftone dot or line image Developing an electric field generated when developing the 32: parallel electric field, 33 ... fringe field. 34 ... exposure portion at exposure amount E1, 35 ... exposure portion at exposure amount E2, 36 ... target solid image density, 37 ... target dot image density, V0 ... charge potential or background potential, Vg ... scorotron charger Grid potential, Vb: development bias potential, Vr1, Vr2: discharge potential or image portion potential.

Claims (2)

A photosensitive member, a charger provided with a grid, an exposure unit, a developing device, a control unit, and a sensor for detecting a test patch formed on the photosensitive member, wherein the exposure apparatus includes the control unit; The exposure amount is adjusted by the apparatus, and a DC voltage and an AC voltage are applied to the developing machine, and an electrophotographic image forming a background area and an image area on the photoconductor using the charger and the exposure device. In the image forming apparatus printing control method,
A first exposure amount that is an exposure amount that is adjusted to print the inside of the solid image, and a second exposure that is an exposure amount that is adjusted to print a peripheral portion other than the inside of the solid image, a line image, and a halftone image. The amount and
The control means creates a solid test patch latent image on the photoconductor with the first exposure amount, makes the difference between the DC voltage and the grid voltage applied to the grid constant, After changing the grid voltage, the solid image test patch latent image is developed by the developing device to create a solid image patch, which is a solid image test patch, and the sensor includes a solid image patch inside the solid image patch. By measuring the image density, a first adjustment for determining the voltage value of the DC voltage and the voltage value of the grid voltage to obtain a predetermined solid image density is performed,
After performing the first adjustment, the second exposure amount is changed, and a first halftone dot image patch which is a test patch of a halftone dot image having a constant area ratio is created on the photoconductor, and the sensor uses the sensor. By measuring the image density of the first halftone image patch, and performing a second adjustment for determining a second exposure amount to be within a predetermined image density range of the halftone image,
After performing the second adjustment, a second halftone image patch, which is a test patch of a halftone image having an area ratio of 60% to 80%, is created on the photoconductor, and the sensor And comparing the measurement result image density obtained by measuring the image density of the second halftone dot image patch with the predetermined image density range of the halftone dot image,
When the measurement result image density is within a predetermined image density range of the halftone image, the control means ends the control,
When the measurement result image density is outside a predetermined halftone dot image density range, the amplitude of the AC voltage is changed, and the first adjustment and the second adjustment are repeated again. Control method. A photosensitive member, a charger provided with a grid, an exposure unit, a developing device, a control unit, and a sensor for detecting a test patch formed on the photosensitive member, wherein the exposure apparatus includes the control unit; The exposure amount is adjusted by the apparatus, and a DC voltage and an AC voltage are applied to the developing machine, and an electrophotographic image forming a background area and an image area on the photoconductor using the charger and the exposure device. In the image forming apparatus,
A first exposure amount that is an exposure amount that is adjusted to print the inside of the solid image, and a second exposure that is an exposure amount that is adjusted to print a peripheral portion other than the inside of the solid image, a line image, and a halftone image. The amount and
The control means creates a solid test patch latent image on the photoconductor with the first exposure amount, makes the difference between the DC voltage and the grid voltage applied to the grid constant, After changing the grid voltage, the solid image test patch latent image is developed by the developing device to create a solid image patch, which is a solid image test patch, and the sensor includes a solid image patch inside the solid image patch. By measuring the image density, a first adjustment for determining the voltage value of the DC voltage and the voltage value of the grid voltage to obtain a predetermined solid image density is performed,
After performing the first adjustment, the second exposure amount is changed, and a first halftone dot image patch which is a test patch of a halftone dot image having a constant area ratio is created on the photoconductor, and the sensor uses the sensor. By measuring the image density of the first halftone image patch, and performing a second adjustment for determining a second exposure amount to be within a predetermined image density range of the halftone image,
After performing the second adjustment, a second halftone image patch, which is a test patch of a halftone image having an area ratio of 60% to 80%, is created on the photoconductor, and the sensor And comparing the measurement result image density obtained by measuring the image density of the second halftone dot image patch with the predetermined image density range of the halftone dot image,
When the measurement result image density is within a predetermined image density range of the halftone image, the control means ends the control,
When the measurement result image density is outside the range of the image density of a predetermined halftone image, control is performed to change the amplitude of the AC voltage and repeat the first adjustment and the second adjustment again. Image forming apparatus.

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