1. Field of the Invention
The present invention relates to a color image forming apparatus (such as a copying machine, a printer, or a facsimile (FAX)) using an electrophotography method.
2. Description of the Related Art
In recent years, a color image forming apparatus using an electrophotography method is widely used. Since the color image forming apparatus is required to provide precise color reproducibility and color stability, the color image forming apparatus is generally provided with a function for automatically executing image density control. In particular, due to variations in color caused by, for example, changes in the environment in which the color image forming apparatus is used and the history of use of various consumable items, it is necessary to periodically execute the image density control for stabilizing the color at all times.
In an example of the image density control, a plurality of test toner images (patches), formed on an image bearing member while changing an image-formation condition, are detected with an optical image density detector, disposed in the image forming apparatus. In this case, a detection result of the optical image density detector is converted to a toner adhesion amount, to set suitable image-formation conditions on the basis of a conversion result. Here, examples of image-formation conditions include dynamic conditions (such as charging voltage, exposure strength, and development voltage) and corrections (adjustments) of a conversion condition table used when forming a half tone image. Here, when the toner adhesion amount is not a toner amount (g), the toner adhesion amount may be any amount equivalent to the toner amount (g) that can be determined by a printer body.
Here, the operation of the optical image density detector will be described in more detail. First, basically, a patch or an image bearing member is irradiated with light by a light-emitting element, and light reflected from the patch or the image bearing member is received by a photodetector. On the basis of a result obtained when the light is received by the photodetector, the toner adhesion amount of the patch is calculated. Here, for stabilizing detection precision, it is important that the quantity of light emitted from the light-emitting element be set at a suitable value. When the light-emission quantity is too large, the quantity of light reflected from the patch or the image bearing member becomes too large. This causes an output of the photodetector to be fixed at an upper limit. As a result, the toner adhesion amount cannot be precisely calculated. On the other hand, when the light-emission quantity is too small, the quantity of light reflected from the patch or the image bearing member becomes too small. In addition, a change in output of the photodetector becomes small with respect to a change in the toner adhesion amount of the patch. When this is converted to the toner adhesion amount, an error becomes large. Further, the output of the photodetector changes with, for example, a change in reflectivity (caused by deterioration of the image bearing member (which is a detection surface) with time), staining of the image density detector with time, or a lot variation of structural components of the image density detector. From this viewpoint, it is important that the light-emission quantity be set at a suitable value.
On the basis of such a background, in general, sensor characteristics are corrected before detecting a toner adhesion amount (that is, before controlling image density). Practical forms are discussed in, for example, Japanese Patent Laid-Open Nos. 2002-229279 and 2000-13190. Here, the term “correction” refers to adjustment of a toner-adhesion-amount sensor output to a constant/substantially constant value by adjusting the light-emission quantity of a sensor light-emitting element (LED, etc).
In controlling the image density, in general, first, the light-emission quantity is adjusted. Then, after obtaining an output VB of the photodetector when there is no adhesion of toner, the image bearing member is rotated. Then, patches are formed to obtain an output VP of the photodetector. The quantity of light emitted from the light-emitting element is generally made equal to a light-emission quantity obtained on the basis of the outputs VB and VP because it takes time for an output of light to be stabilized. In addition, for adjusting light quantity, it is necessary to form a solid patch on the image bearing member. Further, the solid patch needs to be completely eliminate. This is because, if the output VB is obtained when the solid patch is not sufficiently eliminated, the toner amount cannot be precisely calculated. Here, the term “completely” means “sufficiently” in detecting the density, so that the solid patch is not actually eliminated completely.
According to the above-described background, ordinarily, as shown in
However, as a consequence, in addition to formation/detection of a patch (indicated by reference numeral 2601 in
Although it is known that there is a risk that the solid patch cannot be completely eliminated, reducing the number of rotations of the image bearing member and omitting the removal of the toner make it possible to reduce an image density controlling time. However, in this case, the precision with which the image density is controlled is reduced.
Embodiments of the present invention are provided to overcome the above-described drawbacks of the related technology.
According to an aspect of the present invention, there is provided a color image forming apparatus comprising an image forming unit that forms an image; an image bearing member that bears a toner image of a plurality of colors; an optical detecting unit including a light-emitting element that emits light and a photodetector that receives reflected light; a position detecting unit that determines a position of a positional displacement detection image on the basis of a detection result provided when the light is emitted onto the positional displacement detection image of the plurality of colors formed on the image bearing member; a density detecting unit that detects density on the basis of a detection result provided when the light is emitted onto a density detection image formed on the image bearing member; and a light-quantity adjusting unit that determines light-emission quantity when the density is detected with the density detecting unit on the basis of a detection result provided when the light is emitted onto a light-quantity adjustment image formed on the image bearing member. The image forming unit forms the positional displacement detection image and the light-quantity adjustment image within a one-rotation length of the image bearing member. The position detecting unit detects positional displacement on the basis of the detection result of the positional displacement detection image formed within the one-rotation length. The light-quantity adjusting unit determines the light-emission quantity when detecting the density, on the basis of the detection result of the light-quantity adjustment image formed within the one-rotation length using the light-emission quantity provided when emitting the light onto the positional displacement detection image. For example, while maintaining the precision with which the image density is controlled, the image density can be quickly controlled.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings, in which like reference characters designate the same or similar parts throughout the figures therein.
Embodiments of the present invention will now be described in detail with reference to the drawings. It should be noted that the relative arrangement of the components, the numerical expressions and numerical values set forth in these embodiments do not limit the scope of the present invention unless it is specifically stated otherwise.
A first exemplary embodiment will be described as follows. A description will hereunder be given of an example in which adjustment of light quantity of a light-emitting element of an optical detecting sensor 40, which is required when controlling image density, is previously performed using a period of a color-misregistration correction controlling operation (which is periodically performed) and light quantity that is the same/substantially the same as light quantity used for the a color-misregistration correction controlling operation. When the light quantity for density control is previously adjusted, it is no longer necessary to adjust the light quantity when controlling the image density, so that the image density can be controlled in a shorter time. Specifically, the time is reduced due to elimination of the light quantity adjustment performed during the image density control and cleaning operation performed due to this light quantity adjustment. In the color-misregistration correction controlling operation, a light-quantity adjustment patch for controlling the image density is added within one rotation of an intermediate transfer belt, so that an additional cleaning operation is not required. Therefore, the time required for the color-misregistration correction controlling operation itself is not increased. A detailed description will hereunder be given with reference to the drawings. Schematic Sectional View of Image Forming Apparatus:
Referring to
Each photosensitive drum 2 is an electrophotography photosensitive member that is a rotating drum, that is repeatedly used, and that is rotationally driven at a predetermined peripheral speed (process speed). Each photosensitive drum 2 is uniformly charged to a predetermined polarity/electrical potential (which is negative in the embodiment) by its corresponding primary charging roller (charging unit) 3. Then, each photosensitive drum 2 is subjected to image exposure by its corresponding image exposure unit 4 (comprising, for example, a laser diode, a polygon scanner, or a lens unit), to form an electrostatic latent image of corresponding one of a first color component image to a fourth color component image (such as a yellow, a magenta, a cyan, or a black component image).
Next, what is called development, in which toner (developing agent) is adhered to each electrostatic latent image formed on its corresponding image bearing member, is performed. Each development unit comprises its corresponding toner container, which contains toner, and a development roller (development section) 5, serving as a developing-agent bearing member that bears and conveys the toner. Each development roller 5 is formed of elastic rubber whose resistance is adjusted. While each development roller 5 rotates in a forward direction with respect to its corresponding photosensitive drum, each development roller is in contact with its corresponding photosensitive drum 2. By applying a high pressure of a predetermined polarity (negative in the embodiment) to the development rollers 5, the toner that is borne by the development rollers 5 that are friction-charged to a same polarity in their respective development sections is transferred to the electrostatic latent images on the photosensitive drums 2, to perform the development.
The intermediate transfer belt 31 (image bearing member) is rotationally driven by the action of a driving roller 8 at a speed that is substantially the same as those of the photosensitive drums 2 while contacting the photosensitive drums 2. Reference numeral 34 denotes a passive roller. The intermediate transfer belt 31 is placed in a tensioned state on a tension roller 10. The intermediate transfer belt 31 is formed of an endless film member having a thickness on the order of from 50 to 150 μm and having a volume resistivity of from 108 to 1012 Ωcm. The intermediate transfer belt 31 is black and has high reflectivity. By an electrostatic action resulting from a high pressure applied to primary transfer rollers (primary transfer units) 14 disposed opposite to the respective photosensitive drums 2 with the intermediate transfer belt 31 being disposed therebetween, toner images of different colors are transferred to the intermediate transfer belt 31 from the photosensitive drums 2. Each primary transfer roller 14 is a solid rubber roller whose resistance is adjusted in the range of from 107 to 109Ω. Then, any primary transfer residual toner remaining on the photosensitive drums 2 after transferring the toner images from the photosensitive drums 2 to the intermediate transfer belt 31 is removed and collected by respective cleaning blades 6.
A transfer material S, fed from the sheet-feed unit 15, is fed towards a nip portion of the intermediate transfer belt 31 and a secondary transfer roller 35 by a pair of registration rollers 17 that are driven and rotated at a predetermined timing. Then, by electrostatic action resulting from applying high pressure to the secondary transfer roller 35, the toner images on the intermediate transfer belt 31 are transferred to the transfer material S. The secondary transfer roller 35 is a solid rubber roller whose resistance is adjusted in the range of from 107 to 109Ω. A full-color toner image is fixed to the transfer material S by heat and pressure using a fixing unit 18, after which the transfer material S having the full-color toner image fixed thereto is discharged to the outside of the apparatus (that is, outside of the main body of the image forming apparatus). Any secondary-transfer residual toner remaining on the intermediate transfer belt 31 after transferring the toner images onto the transfer material S from the intermediate transfer belt 31 is removed and collected by a cleaning blade 33 serving as a cleaning unit.
While controlling each section of the image forming apparatus using RAM 103 as a working area and on the basis of various control programs stored in ROM 102, a central processing unit (CPU) 101 reduces color variations of an image caused by environmental changes, to perform image density control for stabilizing color. For forming a color image with high precision, the CPU 101 performs, for example, a color-misregistration correction controlling operation for adjusting a timing of forming images of different colors. Further, the CPU 101 also performs calculation, gives instructions, controls each member, and receives data from a sensor (these operations are related to the steps in each flow chart described later). Environmental changes include, for example, (1) exchange of consumables, (2) changes in environment of use of the image forming apparatus (temperature, humidity, deterioration of the apparatus), and (3) changes in condition of use of the consumables (number of prints). ROM 102 stores various control programs, various items of data, and various tables. RAM 103 includes, for example, a program load area, a working area of the CPU 101, and storages areas of various items of data. Reference numeral 104 denotes a test pattern generating unit that generates a toner image of a patch or a line. Reference numeral 106 denotes a toner-adhesion-amount and color-misregistration-amount detecting unit including, for example, the optical detecting sensor 40 that detects a toner image (patch), such as a density-adjustment patch or a light-quantity adjustment patch (also called a light-quantity adjustment image), formed on the intermediate transfer belt 31. An image forming unit 108 includes, for example, the aforementioned photosensitive drums 2, the charging units 3, the image exposure units 4, the development units 5, and the primary transfer units 14. Reference numeral 109 denotes a non-volatile memory that stores various items of data, including, for example, light-quantity settings when executing image density control. The light-quantity settings used when executing image density control are stored in the non-volatile memory by executing the steps of a flow chart shown in
Although, in the embodiment, the various operations are carried out on the basis of the operations of the CPU 101, some or all of the operations that are performed by the CPU 101 can be performed by an application specific integrated circuit (ASIC). Alternatively, some or all of the operations performed by the ASIC can be performed by the CPU 101.
Next, the optical detecting unit 106 will be described in detail with reference to
As shown in
As shown in
Next, the image density control will be described.
In general, in the electrophotography color image forming apparatus, characteristics of toner or the aforementioned individual key parts change due to various conditions, such as (1) exchange of consumables, (2) changes in environment of use of the image forming apparatus (temperature, humidity, deterioration of the apparatus), and (3) changes in condition of use of the consumables (number of prints). The changes in characteristics become noticeable as variations in image density or changes in color reproducibility. That is, due to these variations, a proper color reproducibility can no longer be obtained. To overcome this problem, in the embodiment, for obtaining a precise color reproducibility at all times, a plurality of patches (density detection images) are formed experimentally to detect their densities with the optical detecting sensor 40, while changing image formation conditions when image formation carried out on the basis of an instruction given by a user is not performed. Then, on the basis of a detection result thereof, the image density control is executed as a density detecting operation for controlling a factor that influences image density. The image density control refers to changing the factor that influences the image density and adjusting or updating an image formation condition. Typical examples of the factors which influence the image density are charging bias, development bias, exposure strength, and a lookup table. Hereunder, updating/adjusting a lookup table (refer to
Next, light quantity adjustment as a light quantity adjustment method performed prior to the image density control according to the embodiment will be described.
As shown in
That is, for precisely performing the image density control, as shown in
As mentioned above, in the electrophotography color image forming apparatus, the characteristics of the above-described components change due to various conditions, such as (1) exchange of consumables, (2) changes in environment of use of the image forming apparatus (temperature, humidity, deterioration of the apparatus, etc.), and (3) changes in the number of prints. Changes in characteristics, such as endurance wearing of the driving roller 8, expansion/contraction due to temperature or humidity, or variations in the positions of the photosensitive drums 2 that are irradiated with laser using the image exposure unit 4, become noticeable as color variations in which toners of different colors no longer are precisely superposed upon each other when forming a color image.
Accordingly, for obtaining precise color reproducibility at all times, in the embodiments, when image formation carried out on the basis of an instruction given by a user is not performed, line images of a plurality of colors are experimentally formed to detect them with the optical detecting sensor 40. Then, on the basis of a detection result, color-misregistration adjustment control for adjusting a timing (main scanning direction, subscanning direction) of forming an image is executed with each color. Specific operations for the color-misregistration correction control will be described below.
Accordingly, the color image forming apparatus according to the embodiment forms at least three types of patches, that is, patches (lines) for color-misregistration control (which has been just described), patches for density control (described above), and light quantity adjustment patches for the density control (described above). These may be called, for example, first detection images, second detection images, and third detection images, respectively, to distinguish between the patches.
Next, a specific example of image density control according to the embodiment will be described with reference to
Next, in Step S3, the intermediate transfer belt 31 is rotated twice, and toner adhered to the intermediate transfer belt 31 is removed by the action of the cleaning blade 33. Depending upon the case, the intermediate transfer belt 3 may be rotated three or more times.
Next, when, in Step S4, the light emission of the optical detecting sensor 40 is stabilized, in Step S5, obtaining of reflection-light signals Bb and Bc of the respective photodetectors 40b and 40c from the intermediate transfer belt 31, itself, is started. Then, when the intermediate transfer belt 31 has rotated one more time, patch images of respective colors (such as those shown below reference numeral 804 in
Then, in Step S6, at the centers of the patch images, reflection-light signals Pb and Pc from the respective photodetectors 40b and 40c are obtained. In this case, in Steps S5 and S6, a controlling operation is performed so that the signals at the same/substantially the same location of the intermediate transfer belt 31 are obtained. The centers of the patch images refer to the centers of the individual rectangular patches shown at the lower portion in
In the embodiment, the entire patch images are disposed within a peripheral length of the intermediate transfer belt 31. This is to prevent a processing time from becoming long due to a plurality of cleaning operations being performed after ending the formation of the patches for one rotation, when the length of the entire patch images equals the length of the patch images formed on the intermediate transfer belt 31 that has rotated one or more times.
Then, when, in Step S11, the obtaining of the reflection-light signals Pb and Pc by the photodetectors 40b and 40c in Step S6 is completed, the light-emitting element 40a of the optical detecting sensor 40 is turned off.
In Step S7, for each patch, a toner adhesion equivalent amount is converted on the basis of the results of Steps S5 and S6. Various conversion methods are available. For example, using the signals Bb, Bc, Pb, and Pc, calculations can be carried out with the following Formula (1):
Toner adhesion equivalent amount={Pb−α*(Pc−Bc)}/Bb (1)
Here, α is a constant. The constant used may be one stored in RAM 103 or the nonvolatile memory 109 (calculated by a predetermined operation of the image forming apparatus) or one previously stored in ROM 102. The smaller the toner adhesion equivalent amount, the larger the toner adhesion amount actually is. The numerator of Formula (1) corresponds to a net specular reflected light (resulting from subtracting an irregular reflection component) that is received by the photodetector 40b when the patch images are irradiated with light.
Using a table, such as that shown in
Thereafter, in Step S8, a lookup table is updated on the basis of a result of conversion to the toner adhesion amount or the image density. Then, after ending Step S6, an image formed on the intermediate transfer belt 31 is cleaned (for two rotations of the intermediate transfer belt 31) in Step S9 concurrently with the operations of Steps S7 and S8. Afterwards, when the cleaning ends, in Step S10, the rotation of the intermediate transfer belt 31 is stopped, thereby ending the image density control.
An example of the detailed operation of Step S8 shown in
The horizontal axis of
Next, the operations of the color-misregistration correction control and light-quantity adjustment when controlling image density in some embodiments will be described with reference to
In Step S21, when the color-misregistration correction control is started, the intermediate transfer belt 31 starts to rotate.
Next, in Step S22, a color-misregistration correction control light-emission quantity is set, and the optical detecting sensor 40 is caused to emit light with the set color-misregistration correction control light quantity. In general, an allowable range of precision with respect to the setting of the color-misregistration correction control light quantity is larger than a light-quantity setting provided when performing the image density control. This is because, as mentioned above, the color-misregistration correction control is performed so that a change of an edge of a line image is read. Here, for determining the light quantity for the color-misregistration correction control, for example, prior to the color-misregistration correction control, several light-quantity set values are allocated, to irradiate the intermediate transfer belt 31, itself, and to select the set value of the light quantity so that an output of the photodetector 40b falls within a predetermined range. In this case, compared to when an adjustment patch is formed as in the image density control, the required processing time can be reduced.
Next, in Step S23, the intermediate transfer belt 31 is rotated twice, to remove any residual toner adhered to (remaining on) the intermediate transfer belt 31 by the action of the cleaning blade 33.
First, as indicated by reference numeral 1501 in
Next, in Step S26, positions of the line image are specified on the basis of variations in the output of the photodetector 40b. More specifically, a same line image is disposed on a line at an angle of 45 degrees and a line at an angle of −45 degrees with respect to an axis in a conveying direction of the belt, to specify main-scanning displacement amount and subscanning displacement amount of the line image. A main-scanning length of the line image is set considering that the spot diameter of the photodetector 40b used in the above-described color-misregistration correction control is φ1.0 mm and that changes in outputs at edges of the respective line images can be obtained. With regard to how to specifically correct color misregistration on the basis of the detected main-scanning displacement amount and the subscanning displacement amount, for example, a related method of adjusting a timing (main scanning direction, subscanning direction) of forming an image with each color is known. Therefore, details thereof will not be given here. For example, a technology of changing an image formation condition, such as changing a light-emission timing of a laser diode, from each determined color misregistration is also already well known. Therefore, details thereof will not be given here.
Next, in Step S27, subsequent to forming the oblique line image for the color misregistration detection, an output of the photodetector 40c corresponding to reflected light from the centers of the light-quantity adjustment patches for determining the light quantity for the image density control is obtained. The obtaining method is similar to that in controlling the image density. In Step S27, the light quantity setting provided when detecting the density is also set on the basis of the output of the photodetector 40c. Here, if the setting of the light quantity is changed when emitting light to the light-quantity adjustment patches, a long time is required until the output is stabilized. However, here, the light-quantity adjustment patches cannot be continuously read subsequent to the reading of the color-misregistration detection image. In contrast, in Step S27, when obtaining the output of the light-quantity adjustment patches, the optical detecting sensor 40 is caused to emit light with a light quantity that is the same or substantially the same as the light quantity setting for the color-misregistration correction control. The setting of the light quantity for the density control is actually performed by the time the density control is performed, so that it is not limited to a timing of Step S27.
Next, in Step S30, the light-emitting element 40a of the optical detecting sensor 40 is turned off after completing the obtainment of the output of the light-quantity adjustment patches from the photodetector 40c. With the operation of Step S30, for cleaning the image formed on the intermediate transfer belt 31 in Step S28, the intermediate transfer belt 31 is rotated twice. Then, in Step S29, the rotation of the intermediate transfer belt 31 is stopped. Accordingly, the color-misregistration control and the light quantity adjustment for the image density control end.
The light quantity adjustment for the density control will hereunder be described in more detail with reference to
A predetermined value IO is predetermined on the basis of the characteristics of the photodetectors, and is the smallest detectable light quantity. In other words, by setting the light quantity greater than or equal to the predetermined value IO, light emission by the light-emitting element 40a is started. Since the predetermined value IO is a predetermined value, it is previously stored in the non-volatile memory 109. The storing of the predetermined value IO is performed by a storage control operation by the CPU 101.
IR is a setting of the color-registration-correction light quantity used when detecting the aforementioned light-quantity adjustment patches described above. IR is equivalent to the color-misregistration-correction light-emission quantity that is determined in Step S22.
A maximum value that is provided when four light quantity adjustment patches (yellow, magenta, cyan, and black) are detected by the photodetector 40c is Sc. For example, if an output value of the photodetector 40c for magenta among yellow, magenta, cyan, and black is largest, the output value of magenta is set as Sc in
Here, when the light quantity setting is too large, the outputs of the photodetectors 40c and 40b are fixed to the upper limit. It is most desirable to set the outputs of the photodetectors 40c and 40b to values (to the target line shown in
For achieving this desirable mode, the light quantity setting ID for the image density control is calculated as follows:
ID=(St/Sc)*(IR−I0)+I0 (2)
Then, the calculated light quantity setting for the image density control is stored in the non-volatile memory 109, and is updated. The light quantity setting ID that is stored in the non-volatile memory 109 is equivalent to the value that is read from the non-volatile memory 109 in Step S2 shown in
In the color-misregistration correction control, the type of light used for detecting a color-misregistration correction control patch varies with the state or type of image bearing member on which the patch is to be formed. First, when a low-cost image bearing member is used, irregular reflection is suitable for detecting the color-misregistration correction patch. This is based on the fact that, since a low-cost image bearing member has an extremely uneven surface compared to a high-cost image bearing member, gloss at the surface of the low-cost image bearing member is reduced, resulting in a reduction in the specular reflection component from the surface of the image bearing member. This makes it impossible to provide reflected light for ensuring precision of the color-misregistration correction control. In contrast, when the light is irregularly reflected, a spot diameter is large, so that the amount of reflected light is large. The extent of influence of the uneven surface of the image bearing member is reduced, so that the detection can be performed with higher precision. On the other hand, when a color-misregistration control patch is formed on a high-cost image bearing member, the surface of the high-cost image bearing member is less uneven than that of the low-cost image bearing member. Therefore, even if detection is performed using specular reflected light, it is less necessary to worry about the influence of the uneven surface of the image bearing member. The length of the color-misregistration correction control patch when the low-cost image bearing member is used differs from that when the high-cost image bearing member is used. Since the irregularly reflected light is suitable for use with the low-cost image bearing member, the spot diameter is large, as a result of which the length of the color-misregistration correction control patch is long. On the other hand, the specular reflected light can be used for the high-cost image bearing member. In this case, as shown in
In the embodiment, specular reflected light is used in detecting a color-misregistration correction control patch. As a result, as shown in
Although the light quantity can be adjusted using color-misregistration correction patches may be performed, in such a case, the following problems arise. In adjusting the light quantity, since a solid image is used, the detection amount of irregularly reflected light is generally larger (see
In other words, although the type of reflected light used in the embodiments is not particularly limited, the invention is particularly useful when specular reflected light is used for the color-misregistration correction control rather than irregularly reflected light.
As mentioned above, when an attempt is made to adjust the light quantity when performing the image density control, first, it is necessary to detect the foundation of the intermediate transfer belt 31 (image bearing member) with a corrected light quantity. Therefore, it is necessary to clean the intermediate transfer belt before and after the light-quantity adjustment patches in accordance with a plurality of rotations thereof. In contrast to this related art, according to the description with reference to
According to the operations indicated in
From the viewpoint of reducing the image density control time, light quantity adjustment patches may be formed separately from when the color-misregistration correction control is performed. Comparing this case and the case in which the operations shown in
When the light quantity adjustment patches are detected using a light quantity that is the same as that when detecting color misregistration, a table (conversion method) in which the light quantity adjustment patches can be set is provided. Therefore, a problem in which a certain time is required until the light-emission quantity of the light-emitting diode 40a is stabilized can be overcome. If, as in the condition shown in
A second exemplary embodiment will be described as follows. In the first exemplary embodiment, the light-quantity-versus-photodetector-output characteristics of a solid image and the intermediate transfer belt 31 are described when the light-quantity-versus-photodetector-output characteristics of the solid image have larger values. In contrast, in the second exemplary embodiment, a case in which the light-quantity-versus-photodetector-output characteristics of the solid image have smaller values in the intermediate transfer belt 31 is considered, to set a suitable density-control light quantity.
A specific example of the color-misregistration correction control will hereunder be described with reference to
Then, in Step S48, cleaning of an intermediate transfer belt 31 is started. This cleaning operation is indicated by reference numeral 1806 in
Thereafter, concurrently with the operation of Step S48, in Step S49, a light quantity setting of a light-emitting element 40a is changed to an image density control light quantity (corresponding to a light quantity setting ID) that is stored in a non-volatile memory 109, to turn on the light-emitting element 40a. The turning on of the light-emitting element 40a is indicated by reference numeral 1805 in
In Step S50, light emission of an optical detecting sensor is stabilized.
In Step S51, a reflected light signal from the intermediate transfer belt 31, itself, is obtained for one rotation of the intermediate transfer belt 31 by a photodetector 40b at a predetermined interval (this operation is indicated by reference numeral 1807 in
In another application example, if the operation in Step S51 is executed so that the state of the intermediate transfer belt 31 is a border-line state where the state of the intermediate transfer belt 31 changes from that shown in
When the operation of Step S51 ends, the rotation of the intermediate transfer belt 31 is stopped in Step S52. In addition, in Step S53, the light-emitting element 40a of the optical detecting sensor 40 is turned off, to end the preparation for the color-misregistration correction control and for adjusting the light quantity for the image density control.
The flow chart shown in
An example of adjusting light quantity when controlling the density while considering the sizes of reflectivities of both the intermediate transfer belt 31 and solid image patches for light quantity adjustment will be hereunder described. More specifically, a method of adjusting the light quantity in accordance with a result of comparison between the sizes of output values of the photodetector 40b and a photodetector 40c when the light-emitting element 40a performs irradiation on the intermediate transfer belt 31 and the solid image patches for light quantity adjustment will be described. The output value provided when the light irradiation is performed on the intermediate transfer belt 31 is a maximum value among a plurality of detection results obtained as a result of irradiating the intermediate transfer belt 31 with a certain light quantity (ID). The output value provided when the light irradiation is performed on the solid images for the light quantity adjustment is a maximum value among densities (detection values) of the yellow, magenta, cyan, black solid images.
For example, as shown in
In
In
It is desirable that the outputs of the photodetector 40c and the photodetector 40b be set as large as possible (target lines in
(i) In the case 1, the updating of the light quantity setting ID for the image density control can be calculated as follows. A value ID′ resulting from updating the light quantity setting ID for the image density control is expressed as in Formula (3):
ID′=(St/Sb)*(ID−I0)+I0 (3)
(ii) In the case 2, the light quantity setting ID′ for the image density control can be calculated using Formula (4). Formula (4) corresponds to Formula 2 used to update the value ID according to the first exemplary embodiment:
ID′=(St/Sc)*(IR−I0)+I0 (4)
This light quantity determining method can also be described as follows. The maximum value Sc of the outputs of the photodetector 40c for the four light quantity adjustment patches (yellow, magenta, cyan, black), detected on the basis of the light quantity setting IR for the color-misregistration correction control, is converted into an output value Sc′ (which is assumed when the maximum value is detected on the basis of the light quantity setting ID for the image density control) using the following Formula (5):
Sc′=Sc/(IR−I0)*(ID−I0) (5)
When the larger value of the values Sc′ and Sb is represented as Smax, the updated value ID′ of the light quantity setting ID for the image density control can be calculated using Formula (6):
ID′=(St/Smax)*(ID−I0)+I0 (6)
As described above, even if, when using a predetermined light quantity, the relationship between the maximum value of the outputs of the photodetector 40c that receives irregularly reflected light and the maximum value of the outputs of the photodetector 40b that receives specular reflected light varies in accordance with the condition of use of the image forming apparatus, the light quantity can be properly set. In addition, a proper light quantity setting for the image density control can be calculated with the light quantity for the color-misregistration correction control. Therefore, the detection precision of the image density control can be maintained without making long the time required for the image density control. In the second exemplary embodiment, one extra operation for one rotation of the intermediate transfer belt 31 is included. However, since the image density control can be quickly performed, an advantage that is similar to that according to the first exemplary embodiment can be provided.
A third exemplary embodiment will be described as follows. In each of the above-described embodiments, adjustments are made so that the maximum output values obtained from the photodetectors 40b and 40c are adjusted so as to reach a target line St on the basis of the light quantity setting ID for the image density control (
However, in a further case, for example, lot variations of the optical detecting sensor may cause the photodetector 40b that is designed to primarily receive specular reflected light to receive a large amount of irregularly reflected light. In this case, as with the photodetector 40c, when the toner amount is increased, the output of the photodetector 40c may increase (refer to
Next, a specific example of color-misregistration correction control according to the embodiment will be described with reference to
According to the embodiment, thereafter, when light quantity adjustment patches are formed and outputs thereof are monitored, outputs from both the photodetectors 40b and 40c are obtained (Step S67).
The subsequent Steps S68 to S73 are similar to Steps S48 to S53 according to the second exemplary embodiment.
A following case will hereunder be described. Here, as shown in
Sd′=Sd/(IR−I0)*(ID−I0) (7)
When the largest value that is obtained as a result of comparing the Sd′ value, Sc′ value (refer to Formula (5) according to the second exemplary embodiment) and the Sb value with each other is represented by Smax2, the value ID′ resulting from updating the light quantity setting ID for the image density control can be calculated using Formula (8):
ID′=St/(Smax2)*(ID−I0)+I0 (8)
Therefore, the third exemplary embodiment considers the case in which, when the intermediate transfer belt 31 and patch images are irradiated with a predetermined light quantity using the light-emitting element 40a, a maximum output value among the output values of the yellow (Y), magenta (M), cyan (C), and black (Bk) solid images is larger than the output for the intermediate transfer belt 31 from the photodetector 40b. It becomes possible to calculate a proper light quantity setting for the image density control with the light quantity for the color-misregistration correction control. In addition, it becomes possible to maintain the detection precision for the image density control without increasing the time for the image density control. In the third exemplary embodiment, it is possible to provide the advantage of reducing the time required for the color-misregistration correction control as in the above-described exemplary embodiments.
A fourth exemplary embodiment will be described as follows. In the first to third embodiments, the density control illustrated in
The operation of determining the position of the positional displacement detection image (carried out on the basis of a detection result of the positional displacement detection image formed within a one-rotation length of the image bearing member), the operation of determining the light-emission quantity (carried out on the basis of a detection result of the light quantity adjustment image formed within the one-rotation length of the image bearing member), and the density detection may be continuously executed without printing of a print job between these operations.
For example, the operation represented by reference numeral 1505 in
In another example, the operations represented by reference numerals 1805, 1806, and 1807 in
In the above-described image forming apparatus, although the cleaning blade 33 is used as the cleaning unit of the intermediate transfer belt 31, the cleaning unit is not limited thereto. For example, a cleaning unit may be a type in which a brush or a roller contacts the intermediate transfer belt 31 to (temporarily) mechanically or electrostatically collect toner. In addition, a cleaning unit may be a type in which a charger, such as a roller, a corona member, or a brush, is used to apply electrical charge to toner adhered to the intermediate transfer belt 31, so that the toner is electrostatically returned to the photosensitive drums 2.
While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all modifications and equivalent structures and functions.
This application claims the benefit of Japanese Patent Application No. 2007-309703 filed Nov. 30, 2007, which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | Kind |
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2007-309703 | Nov 2007 | JP | national |