This Nonprovisional application claims priority under 35 U.S.C. § 119(a) on Patent Application No. 2016-086469 filed in Japan on Apr. 22, 2016, the entire contents of which are hereby incorporated by reference.
The present invention relates to an image forming apparatus such as copier, multi-functional apparatus, laser printer, facsimile and so forth that performs image forming according to the electrophotography method, and to an image quality adjusting method.
In an image forming apparatus, density of a toner image that is deposited onto a revolving image bearing member may change caused by a change of environment such as temperature and/or humidity, and/or a change over time and so forth. Therefore, where necessary, density adjustment for a gradation correction is performed by carrying out a process control, that is, by forming a test pattern consisting of multiple patches sequentially in different levels of toner density on the image bearing member. More specifically, the process includes detecting the levels of density of the test patches formed on the image bearing member, and changing the image forming conditions such as developing bias and/or the like based on the detected values so that the levels of density agrees with an ideal gradation characteristic.
On the other hand, facing a revolving surface of the image bearing member, the image bearing member, together with an electrostatic charging portion to perform electrostatic charging, a laser exposure portion to form an electrostatic latent image, a developing portion to render the electrostatic latent image manifest by depositing thereto a toner and so forth, constitutes an image forming portion. If mechanical misalignment or a change such as eccentricity and/or the like occurs in a revolving shaft of the image bearing member, distance from the surface of the image bearing member changes in a sub-scanning direction which is rotational direction, and thus unevenness may occur in electrostatic charging characteristics, amount of laser light and toner deposition characteristics. Such mechanical misalignment or a change results in a change of toner deposition amount that is finally deposited onto the image bearing member, thereby lowering the reproducibility of images.
JP 2012-230312A describes an image forming apparatus in which a toner pattern is formed as a preprocessing on a circumferential surface of the image bearing member and, based on the result detected on period or the like of the toner pattern, a period with which a maximum amount of density change appears is determined and, based on the determination result, an arrangement of patches at the time of process control is decided to thereby offset the effect of the density change.
However, in the image forming apparatus described in JP 2012-230312A, it is necessary to decide the arrangement of the patches on the image bearing member depending on the period which is the determination result, and thus, at the time of an image quality adjustment, it is necessary to wait until the position decided on the image bearing member revolves to come to a position that is faced by the density sensor; therefore, there is a problem that doing so takes a time. Accordingly, the time needed to perform an entire image quality adjustment becomes longer. Moreover, in the case of color, because there are four colors, for each of which it is necessary to adjust a phase, the time needed to perform an overall positional adjustment cannot be ignored. Besides, because the image bearing member has to be revolved more to that extent, there is also a problem that its service life becomes shortened.
It is an object of the present invention to provide an image forming apparatus and an image quality adjusting method capable of quickly correcting the effect of density unevenness in a rotational direction of an image bearing member.
An image forming apparatus according to the present invention, in which a toner image is formed onto a revolving image bearing member, includes a density unevenness measurement processing portion, and an image quality adjustment processing portion. The density unevenness measurement processing portion detects density of a density unevenness measurement toner image, which has been formed in a rotational direction of the image bearing member, multiple times in the rotational direction, and captures in a memory portion detected density information associating thereof with rotation phases of the image bearing member. The image quality adjustment processing portion detects density of an image quality adjustment toner image, which has been formed at any position in the rotational direction of the image bearing member, in the rotational direction, and corrects detected density information based on density information that is associated with a rotation phase that matches a rotation phase at which density of the image quality adjustment toner image has been detected among said density information that has been captured in the memory portion by the density unevenness measurement processing portion.
Also, an image quality adjusting method according to the present invention includes a density unevenness measurement step, and an image quality adjustment step. The density unevenness measurement step forms a density unevenness measurement toner image in a rotational direction of an image bearing member, detects, multiple times in the rotational direction, density of the density unevenness measurement toner image that has been formed, and captures in a memory portion detected density information associating thereof with rotation phases of the image bearing member. The image quality adjustment step forms an image quality adjustment toner image at any position in the rotational direction of the image bearing member, detects, in the rotational direction, density of the image quality adjustment toner image that has been formed, and corrects detected density information based on density information that is associated with a rotation phase that matches a rotation phase at which density of the image quality adjustment toner image has been detected among said density information that has been captured in the memory portion in the density unevenness measurement step.
According to these inventions, at the time when the image bearing member was mounted (including replaced and mounted again) onto the apparatus main body, all density information in the sub-scanning direction which is the rotational direction of the image bearing member is detected being associated with the rotation phase of the image bearing member, and detected density information is stored beforehand in the memory portion being associated with the rotation phase of the image bearing member. Subsequently, at the time of the image quality adjustment, the image quality adjustment toner image is formed at any position in the rotational direction of the image bearing member with a quick timing, that is, without waiting for a specific rotation phase position to come, and density of the image quality adjustment toner image that has been formed is detected at the rotation phase. Then, the density of the image quality adjustment toner image that has been detected is corrected based on the density information that is associated with a rotation phase that matches a rotation phase at which the density of the image quality adjustment toner image has been detected among said density information that has been captured in the memory portion. Therefore, the present invention makes it possible to quickly correct the density unevenness in the sub-scanning direction of the image bearing member with a less toner consumption, and to further perform the image quality adjustment with higher accuracy.
As shown in
The image forming portion 10 includes a light beam scanning unit 1, and image forming portions 10A-10D for respective colors that are similarly structured between each other. The light beam scanning unit 1 includes a semiconductor laser, and converts image data of respective pixels for colors R, G, B corresponding to a color document that has been read at the reading portion 70 into density data of black (K), cyan (C), magenta (M) and yellow (Y), and further through a gradation table that sets an input-output characteristic or the like, generates a laser light that has been modulated by a duty ratio corresponding to each of the density data. Each of electrostatic latent images is formed by the laser light that is scanned for exposure on each of surfaces of photoreceptor drums 2A-2D of the image forming portions 10A-10D along each of shaft directions (main scanning directions). The image forming portion 10A, being explained as typical, includes a photoreceptor drum 2A as image bearing member, and, around thereof, an electrostatic charger 3A, a developing unit 4A and a cleaner portion 5A along a rotational direction (sub-scanning direction). The photoreceptor drums 2A-2D and the developing rollers which are parts of the developing units 4A-4D and magnetic rollers facing the photoreceptor drums 2A-2D, respectively (in
The intermediate transfer portion 20 includes an intermediate transfer belt 21, a driving roller 22, an idle roller 23, and primary transfer rollers 24A-24D, and, performs a primary transfer of toner images that have been formed on circumferential surfaces of the photoreceptor drums 2A-2D, respectively, onto a surface of the intermediate transfer belt 21 as image bearing member. The secondary transfer portion 30 performs a secondary transfer of a toner image on the surface of the intermediate transfer belt 21 onto a recording paper sheet. The fixing portion heats and thereby fixes the toner image that has been transferred onto the recording paper sheet, and discharge the paper sheet onto a paper receiving tray. The paper feed portion 50 includes a paper feed cassette and a manual feed tray, and feeds a selected recording paper sheet from a corresponding paper feed cassette to the paper conveyance path 60.
In this embodiment, a density sensor 26 is disposed in such a manner as to face the surface of the belt at an appropriate position in a circulating range of the intermediate transfer belt 21. The density sensor 26, as shown in
The image forming apparatus 100, as shown in
The rotation sensor 132 may be provided at either each or any one of the revolving shafts of the photoreceptor drums 2, and may consist of a rotary encoder, for example. The rotation sensor 132 is one that generates a reference pulse when detecting the passage of a reference position in the circumferential direction of the photoreceptor drum 2, and the one that generates a rotation pulse each time the photoreceptor drum 2 revolves by a predetermined angle. The rotation sensor 132 detects a rotation phase of the photoreceptor drum 2 in real time using rotation phase information consisting of the reference pulse and the rotation pulse. Still, it may be acceptable as another embodiment that the rotation sensor 132 is configured to output (trigger) only the reference pulse, and that the rotation pulse is produced either using the drive signal (specifically, motor drive signal) to the image formation driving portion 131 or using the clock pulse inside the control portion 90.
The control portion 90 functions as a density unevenness measurement mode processing portion 91, an image quality adjustment mode processing portion 92 and a printing job processing portion 93, when a control program stored in the memory portion 901 is executed. Here, for convenience of description, regarding the control portion 90, functional parts that are related to the present invention are mainly shown. The printing job processing portion 93 accepts a printing job instruction from the operation portion 110, and, through the image processing portion 120 and the image formation portion 130, performs a series of operations including converting a print target image into a printing image, transferring and fixing the printing image onto a delivered recording paper sheet, and discharging the printed recording paper sheet.
The density unevenness measurement mode processing portion 91 forms a density unevenness measurement toner image Gt (see
The density unevenness measurement mode process is one that is performed as a preprocessing, and is carried out at least at the time of replacement, for example, mounting and/or reinstallation, of the photoreceptor drum 2. That is to say, even when a small deviation (phase shift and/or shaft misalignment) occurs between the photoreceptor drum 2 and peripheral members thereof resulting from the former's replacement or the like, and hence even when the relationship between the phase and the density unevenness changes, carrying out the density unevenness measurement mode process beforehand makes it possible to perform a density unevenness correction to detected density of the test patches (image quality adjustment toner image) that is obtained in the subsequent process carried out by the image quality adjustment mode processing portion 92, as will be described later.
Additionally, in this embodiment, the apparatus is configured in such a manner that the density unevenness measurement toner image Gt formed on the photoreceptor drum 2 is transferred onto the intermediate transfer belt 21 and there detected by the density sensor 26. Since the photoreceptor drum 2 revolves with the rotation phase thereof being monitored, even when the formation of the density unevenness measurement toner image Gt is started either at any time or at a preset time, it is possible to associate the density unevenness measurement toner image Gt with the rotation phase of the photoreceptor drum 2. That is to say, the toner deposition amount data of the density unevenness measurement toner image Gt that are detected by the density sensor 26 can be obtained being associated with the rotation phase information.
The density unevenness measurement mode process forms the density unevenness measurement toner image Gt which is a belt-shaped toner image having a predetermined width and uniform density around a single complete revolution in the rotational direction, with the photoreceptor drum 2 being revolved at a constant rate.
The density sensor 26 detects the density of the density unevenness measurement toner image Gt that has been transferred and conveyed.
Using the flow chart of
Then, when the capture over the single complete revolution is completed (Yes at step S7), subsequently, calculation of an average value Dav of the acquired toner density Dgi is performed; and then the density information Dgi for each rotation phase φi, here, density unevenness dgi for each rotation phase φi against the average value Dav, is calculated (step S9). Next, the calculated average value Dav and each density unevenness dgi are stored in the memory portion 901 (step S11). As the density unevenness dgi, a differential of the density Dgi from the average value Dav that is expressed in ratio or the like is used, for example. Still, the density unevenness is not limited to the ratio, but may be expressed by the differential itself or in other manners. Further, instead of the density unevenness dgi, as shown in
Adjustment of the toner density is carried out, in cases where the toner characteristic has changed due to changes of temperature and/or humidity and/or a change over time, as a process control procedure to correct the change. The image quality adjustment mode processing portion 92 performs a correction process to automatically adjust the toner density, input-output characteristic and/or the like to a preset ideal gradation characteristic, upon receipt of an instruction from the operation portion 110, or with a predetermined timing such as at every start up or for every predetermined number of printed paper sheets, or at the time when the changes of temperature and/or humidity exceed threshold values.
The image quality adjustment mode process is one that forms the test patch toner image of predetermined density for image quality adjustment, for example by just one toner image, at a predetermined short time width in the rotational direction of the photoreceptor drum 2 on receiving the instruction to perform the image quality adjustment mode while the photoreceptor drum 2 is revolved at a constant rate, and the one that detects the density of the test patch toner image using the density sensor 26.
The image quality adjustment mode processing portion 92 detects the rotation phase φj of the photoreceptor drum 2 at the time when the test patch toner image is formed, and then performs an undermentioned process in order to remove the effect of the density unevenness in the rotational direction of the photoreceptor drum 2. This process extracts (reads out) the density unevenness dgj of the density unevenness measurement toner image Gt that is synchronous (agrees) in the rotational direction with the rotation phase φj of the density Dtp of the test patch toner image, and then corrects the density Dtp using the density unevenness dgj. Calculation for the correction may be, for example, (Dtp/dgj).
Using the flow chart of
Subsequently, the density unevenness correction is carried out. That is to say, the density Dtp and the density unevenness dgj at a rotation phase that agrees with the rotation phase φj corresponding to the density Dtp are read out, and then the density Dtp is corrected using the density unevenness dgj (step S29). In other words, the density Dtp is divided by the density unevenness dgj (Dtp/dgj). Through such a correction process, since the effect of the density unevenness in the rotational direction of the photoreceptor drum 2 is removed and thus correct density of the test patch toner image can be obtained, it is made possible to perform a highly accurate image quality adjustment. Here, the number of the test patch toner images may be either one or more in the rotational direction. In the case of multiple number, similarly detecting the rotation phase of each test patch toner image and performing the density unevenness correction synchronizing thereof with each rotation phase is just what is to be done.
Moreover, the image quality adjustment mode may be a gradation adjustment, or both of these may be included. The gradation adjustment, as is well known, is one in the process control that forms preset multiple kinds of patches sequentially in the rotational direction of the photoreceptor drum 2, and the one that from the density of each patch detected using the density sensor 26 corrects the gradation table of input-output signals. In this case as well, by detecting the rotation phase at the time when each patch is formed, and by capturing the rotation phase and the detected density information with both thereof being associated with each other, it is made possible in the image quality adjustment mode to perform density correction against the rotation phase.
Here, the density unevenness measurement mode process is not limited to one time, but can be carried out whenever necessary. In such cases after the first time, it is preferable to use, as the average value Dav, an average value that was calculated for the first time. This makes it possible to perform the image quality adjustment that will not be affected by average values which include temporal degradation and/or the like. Additionally, although, in the above-mentioned embodiment, the density unevenness measurement toner image Gt is formed over a single complete revolution of the photoreceptor drum 2, other than the single complete revolution, it is also possible with one half revolution, etc.
Moreover, in a case of coping with both of the rotation unevenness of the photoreceptor drum 2 and the developing roller, apart from the above-mentioned embodiment in which the least common multiple is used to set a range of measurement, the undermentioned embodiment may be adopted. For example, an embodiment in which the image formation driving portion 131 drives a means for rotationally driving the photoreceptor drum 2 and a means for rotationally driving the developing roller 14 independently between each other may be adopted. In this case, the control portion 90 perform a control each time the detection is carried out in the image quality adjustment mode so that both the rotation phase of the photoreceptor drum 2 detected by the rotation sensor 132 and the rotation phase of the developing roller 14 detected by a rotation sensor 133 (see
Further, instead of the embodiment where the density detection is performed on the intermediate transfer belt 21 side, as a third embodiment, an embodiment where direct density detection is performed with the density sensor 2 disposed at each photoreceptor drum 2 may be acceptable. This makes it possible to perform the process without being affected by the intermediate transfer belt 21.
Additionally, the above-mentioned embodiments can be implemented to each color in the same manner.
Moreover, the above explanations of the embodiments are nothing more than illustrative in any respect, nor should be thought of as restrictive. Scope of the present invention is indicated by claims rather than the above embodiments. Further, it is intended that all changes that are equivalent to a claim in the sense and realm of the doctrine of equivalence be included within the scope of the present invention.
Number | Date | Country | Kind |
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2016-086469 | Apr 2016 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
7693468 | Ehara | Apr 2010 | B2 |
8831449 | Suzuki | Sep 2014 | B2 |
20120274986 | Harashima et al. | Nov 2012 | A1 |
Number | Date | Country |
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2012-230312 | Nov 2012 | JP |
Number | Date | Country | |
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20170308018 A1 | Oct 2017 | US |