The present document incorporates by reference the entire contents of Japanese priority document, 2005-270085 filed in Japan on Sep. 16, 2005.
1. Field of the Invention
The present invention relates to image forming apparatuses that employs the technique of electrophotography.
2. Description of the Related Art
In electrophotography apparatuses, which are image forming apparatuses that employs the technique of electrophotography, the amount of electric charge on a developing solution changes with changes in temperature and humidity and deterioration of the developing solution with time. If the amount of electric charge on a developing solution changes, its a development value γ changes. A development value γ is a value representing the magnitude of development capability of a developing solution. When the development value γ of a developing solution changes, the capability of the toner (development potential), which is in the developing solution, to get attracted toward an image carrier also changes, thereby changing image density and color reproducibility. To get around this problem, current development value γ of a developing solution is measured and the image forming conditions are changed based on the current development value γ.
Also, in two-component developing devices, unless the toner density in the developing solution is appropriately controlled, an abnormal image with background smudges or image dropping due to carrier attachment occur. To get around this problem, based on information from a toner density sensor measuring a toner magnetic permeability in a developer and information about the printed image area, the toner density is controlled to have a predetermined value.
However, if the toner density is always constant, when the development value γ is significantly changed, control may not be made with the development potential. Here, a reason for uncontrollability with the development potential can be explained by the following problems. That is, for multilevel grayscale in laser exposure, for example, grayscale crush occurs if the development potential is too low. Conversely, if the development potential is too high, the capacity of the power supply has to be increased, thereby increasing cost. If development is performed in an intense electric field, adhesion force is increased to cause a transfer failure.
To address the problems, in a conventional apparatus, as exemplarily disclosed in Japanese Patent Laid-Open Publication No. 2003-91224, when the toner density is normally controlled but the development value γ is significantly off the target, the control target value of the toner density is changed. For example, when the toner density is controlled at 5 weight percent and the development value γ is smaller than the target value by 0.3 mg/cm2·kV, the control target value of the toner density is changed to 7 weight percent. Since the required toner attachment amount can be obtained simultaneously when the development value γ is detected, such as when the toner refilling amount is reduced, the development potential is calculated and used for subsequent image formation.
Meanwhile, when the target value of the toner density is changed, for example, when the target value is changed from 5 weight percent to 7 weight percent as explained above, there are a case where toner is refilled or consumed in advance before image formation (printing) until the toner density becomes the target toner density, and another case where a refill control target value is changed during printing so that the toner density follows the target value with a predetermined time constant. In the former case, the toner density is adjusted as a lead-up to printing, and therefore apparatus downtime (long latency time) occurs. In the latter case, although no downtime occurs, the toner density is changed during printing, thereby changing the image density.
It is an object of the present invention to at least partially solve the problems in the conventional technology.
According to an aspect of the present invention, an image forming apparatus includes an image carrier that caries an electrostatic latent image; a developing device that develops the electrostatic latent image on the image carrier with a developer that contains toner to obtain a toner image; a toner-amount detecting unit that detects amount of toner attached to the toner image; a toner-density detecting unit that detects a density of toner in the developer; and a process control unit that corrects a toner-density target value indicative of a target value of density of toner in the developer based on the amount of toner detected by the toner-amount detecting unit and the density of toner detected by the toner-density detecting unit, and a determines execution timing of next process based on corrected toner-density target value.
The above and other objects, features, advantages and technical and industrial significance of this invention will be better understood by reading the following detailed description of presently preferred embodiments of the invention, when considered in connection with the accompanying drawings.
Embodiments of the present invention are explained below based on the drawings.
Under the photosensitive members 3Y, 3M, 3C, and 3Bk and the image forming units 4, 6, and 7, an exposing device 8 is provided for performing scanning irradiation of the uniformly-charged photosensitive members 3Y, 3M, 3C, and 3Bk with laser light corresponding to image data for each color to form an electrostatic latent image. Between each charging roller 4 and each developing roller 5 is a narrow space (slit) secured so that the laser light emitted from this exposing device 8 enters the photosensitive members 3Y, 3M, 3C, and 3Bk. The exposing device 8 in the depicted example is of a laser scan type using a laser light source, polygon mirror, and others, but an exposing device of a type in combination of an LED array and image forming means can be used.
Above the photosensitive members 3Y, 3M, 3C, and 3Bk is an intermediate transfer belt 12, which is a transfer unit supported by a plurality of rollers 9, 10, and 11 and rotatably driven in a counterclockwise direction. This intermediate transfer belt 12 is common to the photosensitive members 3Y, 3M, 3C, and 3Bk, and is placed so as to be flat and in a horizontal state to make contact with a portion after the developing a step of each of the photosensitive members 3Y, 3M, 3C, and 3Bk. In an inner rim of the belt, transfer rollers 13Y, 13M, 13C, and 13Bk are provided so as to face the photosensitive members 3Y, 3M, 3C, and 3Bk, respectively. In an outer rim of the intermediate transfer belt 12, a cleaning device 14 is provided at a position facing a roller 11. This cleaning device 14 removes unwanted toner remaining on the belt surface. Here, for example, the intermediate transfer belt 12 is a belt made of, as a base substance, a resin film having a thickness of 50 micrometers to 600 micrometers, or rubber, and has a resistance allowing toner images from the photosensitive members 3Y, 3M, 3C, and 3Bk to be transferred.
Also, in the apparatus body 2, paper feeding cassettes of a plurality of stages, two in this example, 23 and 24 are disposed below the exposing device 8 so as to be freely drawn. These paper feeding cassettes 23 and 24 each have a recording medium S, which is selectively fed by paper feeding rollers 25 and 26, respectively. Furthermore, a paper-supply conveying path 27 is formed so as to be approximately vertical toward a transfer position. Adjacent to the intermediate transfer belt 12 is a conveyer belt 35. In a loop of this conveyer belt 35, a transfer roller 18 is provided so as to face a roller 9, which is one of supporting rollers of the intermediate transfer belt 12. The roller 9 and the transfer roller 18 are pressed to each other via the intermediate transfer belt 12 and the conveyer belt 35, forming a predetermined transfer nip. Immediately before the transfer position on the paper-supply conveying path 27, paired resist rollers 28 for timing of paper feeding to the transfer position are provided. Furthermore, above the transfer position, a conveying and delivering path 30 is formed so as to be continued to the paper-supply conveying path 27 and lead to a delivered-paper stack unit 29 on an upper portion of the apparatus body 2. On this conveying and delivering path 30, a fixing device 31 having paired fixing rollers, paired paper delivering rollers 32, and others are disposed.
Here, in the apparatus body 2, a toner-container accommodating unit 33 is provided in a space below the delivered-paper stack unit 29. The toner-container accommodating unit 33 accommodates toner of the colors for use in the photosensitive members 3Y, 3M, 3C, and 3Bk and allows the toner to be conveyed and supplied by a pump, for example, to the corresponding developing device 6.
In such a structure, an operation of forming an image on the recording medium S is explained. First, with the actuation of the exposing device 8, the surface of the photosensitive member 3Y uniformly changed by the charging roller 4Y is irradiated with laser light corresponding to image data for yellow emitted from a semiconductor laser, thereby forming an electrostatic latent image. This electrostatic latent image is subjected to a developing process by the developing device 6Y to be developed with yellow toner, and then becomes a visible image. The image is then subjected to a transfer operation for transfer by the transfer roller 13Y on the intermediate transfer belt 12 moving in synchronization with the photosensitive member 3Y. Such latent-image formation, development, and transfer operations are sequentially and similarly performed at the photosensitive members 3M, 3C, and 3Bk sides in proper timing. As a result, a full-color toner image in which toner images of respective colors of yellow Y, magenta M, cyan C, and black Bk are sequentially overlaid is carried and conveyed on the intermediate transfer belt 12.
On the other hand, the recording medium S is fed from either one of the paper feeding cassettes 23 and 24, and is conveyed through the paper-supply conveying path 27 to the resist rollers 28. In proper timing with the full-color toner image on the intermediate transfer belt 12, the recording medium S is sent from the resist rollers 28. Then, with the operation of the transfer roller 18, the full-color toner image on the intermediate transfer belt 12 is transferred onto the recording medium S. The recording medium S with the full-color toner image transferred thereon is then conveyed by the conveyer belt 35 to the fixing device 31 and, after a fixing process by the fixing device 31, is delivered by the paper delivering rollers 32 to the delivered-paper stack unit 29.
In both-side printing, the recording medium S after fixing is guided to a reversing path 36 by switching a switching claw 38. Then, by switching a switching claw 39, the recording medium S after reversing is again fed from a paper re-feeding path 37 to the resist rollers 28 to turn the sheet over. At this time, a toner image as a back-surface image is previously formed and carried on the intermediate transfer belt 12, and then the toner image is transferred to the back surface (a second surface) of the recording medium S. Then, after a fixing process by the fixing device 31, the recording medium S is delivered by the paper delivering rollers 32 onto the delivered-paper stack unit 29.
Here, the case of full-color printing has been explained. However, even at the time of monochrome printing with a specific color or black, the operation is similar, except that some photosensitive members are not used.
The toner density sensor 18 for use in this example is of an integral type with a toner-density sensor-sensitivity information storage device and a toner density sensor being combined as one. A circuit diagram of the toner-density sensor-sensitivity information storage device is depicted in
As depicted in
Now, the contents of the process control to be executed in the full-color printer in this example are explained.
(1) The apparatus is activated. By activating the apparatus at power-on, various motors and various biases are turned on, thereby preparing for execution of the process control.
(2) The toner-attachment-amount detection sensor 54 is calibrated as required. In the present example, the amount of light emission of a light-emitting diode (LED) is adjusted so that a regular-reflection light-receiving output from an optical sensor is 4 volts. However, calibration of the sensor is not essential to the present invention.
(3) An output (VT0) of the toner density sensor 18 in the developing device 6 is obtained. This measurement is performed to know the current toner density, and is required for correction of the toner density (VTREF).
(4) A gray-tone pattern is generated. This is required to detect the development value γ. Specifically, in this example, to correspond to a position where the toner-attachment-amount detection sensor 54 is provided (a position in an axial direction of the roller around which the intermediate transfer belt 12 is wound), ten gray-tone patterns are generated with a width in a main scanning direction of 15 millimeters, a width in a sub-scanning direction of 16 millimeters, and a pattern interval of 50 millimeters. At the time of writing the formed patterns, it is assumed that the amount of exposure is in full exposure (a value at which the photosensitive drum 3 is sufficiently diselectrified), and a development bias (Vβ) and a charge bias (Vc) are changed for each pattern, thereby generating gray-tone patterns.
(5) The gray-tone patterns are detected by the toner-attachment-amount detection sensor 54. The toner attachment amount of each of the gray-tone patterns generated and transferred onto the intermediate transfer belt 12 is measured by the toner-attachment-amount detection sensor 54. In this example, as explained above, a reflection optical sensor is used.
(6) The development value γ and a development start voltage are found. The development value γ and the development start voltage are found from a relation between the development bias (Vβ) and the toner attachment amount. Specifically, with the development bias being on the horizontal axis and the toner attachment amount being on the vertical axis, the method of least squares is used to find a linear equation. The gradient of this linear equation is referred to as the development value γ, whilst the X intercept is referred to as the development start voltage.
(7) A required development bias is found to obtain a target toner attachment amount. Based on the linear equation, the development bias (horizontal axis) is found from the target toner attachment amount (vertical axis). A value of the target toner attachment amount required to obtain a top density (dark portion) is predetermined (in general, 0.4 mg/cm2 to 0.6 mg/cm2, although depending on the degree of coloring of the toner pigments).
The development bias found here is taken as the development bias (Vβ) of an image portion. The charge bias (Vc) is predetermined so as not to allow a carrier to be flown to the photosensitive member (in general, Vβ=400 volts to 700 volts, and Vc=Vβ+100 volts). Vβ and Vc found in the manner are stored in the RAM 52 of the body control unit.
(8) A toner-density target value (VTREF) is corrected. From the development value γ and a toner-density sensor output (VT0), the toner-density target value (VTREF) is corrected.
That is, Δγ=development value γ detection value−development value γ target value is calculated. Here, the development value γ target value is determined in advance for each apparatus and it is, for example, 1.0 mg/cm2/kV. This means that, with a development potential of 1000 volts (1 kilovolt), toner of 1.0 mg/cm2 is attached to the photosensitive member. When the development start voltage=0 volt and the target toner attachment amount is 0.5 mg/cm2, a development potential (Vp) of 500 volts is required. Since Vp=Vβ−V1, when V1=100 volts, Vβ is 600 volts. V1 represents a potential after exposure, and because of a potential of the photosensitive member after sufficient exposure, this depends on photosensitive-member characteristics. When Δγ exceeds a predetermined value, Vβ exceeds a settable range or an abnormal image occurs. Thus, the target value (VTREF) of the toner density is corrected so that Δγ is within a target range. However, if VT0 and VTREF greatly differ from each other at this time, no correction is made.
An example of correction is as follows.
The first correction condition: when Δγ≧0.30 mg/cm2/kV (high) and VT0−VTREF≧−0.2 volts, VTREF=VT0−0.2 volts. That is, the target value is set so as to decrease the toner density from the present time.
The second correction condition: when Δγ≦0.30 mg/cm2/kV (low) and VT0−VTREF≦0.2 volts, VTREF=VT0+0.2 volts. That is, the target value is set so as to increase the toner density from the present time.
Other than the first correction condition and the second correction condition, it is assumed that VTREF=previous value.
(9) The next process control execution time is determined. Based on Δγ calculated in the manner, the next process control execution time is determined. If Δγ is large, the toner-density target value (VTREF) is change in the process (8), and therefore the toner density is gradually changed through toner refill control at the time of subsequent printing. Therefore, fluctuations in image density occurs. For this reason, the next process control is executed with a smaller number of sheets printed than normal.
An example is as follows.
The first execution condition: when Δγ≧0.30, the next process control execution time is after 30 sheets have been printed.
The second execution condition: when −0.3<Δγ<0.3, the next process control execution time is after 200 sheets have been printed.
The third execution condition: when Δγ≦−0.3, the next process control execution time is after 30 sheets have been printed.
Meanwhile, when the next process control execution time is determined in the manner, if Δγ is equal to or larger (or smaller) than 0.3 for every process control, a process control is executed for each 30 sheets printed. With such frequent process control, apparatus downtime is increased. To get around this problem, how many times such a state (Δγ is equal to or larger or smaller than 0.3) continues may be detected for determining the execution of the process control.
An example in such a case is as follows. When it is assumed that the number of successive times of the state of Δγ being equal to or larger or smaller than 0.3 is N,
The fourth execution condition: when Δγ≧0.3 and N≦3, the next process control execution time is after 30 sheets have been printed. Also, N=N+1.
The fifth execution condition: when Δγ≦−0.3, the next process control execution time is after 30 sheets have been printed. Also, N=N+1.
The sixth execution condition: Other than the fourth and the fifth conditions, the next process control execution time is after 200 sheets have been printed. Also, N=0.
By controlling the execution of the next process control with such execution conditions, the number of times of shortening the execution interval is limited. Therefore, even if a development value γ is not controlled as intended, such as when the toner refilling amount is reduced, the interval of executing the process control is not shortened without limitation.
Also, for example, an operation panel may be provided to set the process control execution time.
By way of example, a selection screen for allowing a process control execution time to be selected is displayed on an operation panel of the full-color printer 1. On this selection screen, as the process control execution time (execution condition), a fixed number of sheets or a variable number of sheets can be selected. Here, if the variable number of sheets is selected, the first to the third conditions or the fourth to the sixth conditions are used. if the fixed number of sheets is selected, the next process control execution time is after 200 sheets have been printed.
In this manner, with the process control execution time being provided to be settable (selectable), a control of shorting the interval of executing the process control can be turned off. With this, a user can select image quality or productivity to prioritize. According to the selection, the process control execution interval (the next process control execution time) can be determined. Therefore, appropriate printing according to a user's desire can be performed.
Here, at the time of power-on of the apparatus body, how the state of the developing solution has been changed since power-off cannot be known. Therefore, a special execution condition is preferably determined.
By way of example, the process control is executed if a predetermined condition is satisfied at the time of power-on of the apparatus body. A first predetermined condition is that more than six hours have elapsed after the previous printing ends. A second predetermined condition is that an amount of change in relative humidity after printing ends is equal to or larger than 30% relative humidity. These thresholds are set to a level at which a change in image density due to a change in charged amount of the developing solution cannot be tolerated.
Next, a toner refilling control in the full-color printer 1 according to the present embodiment is explained. However, the toner refilling control itself is similar to that conventionally known.
(1) Printing of a first sheet is started.
(2) An output (VTn) from the toner density sensor 18 is obtained.
(3) From the number of pixels and resolution, an image area is calculated.
(4) From the image area and a difference between VTn and VTREF, a toner attachment amount for refilling at the time of printing a second sheet is calculated.
By way of example,
toner refill amount at the time of next printing (milligram)=a first proportional factor×(VTn−VTREF)+a second proportional factor×image area×(1+a third proportional factor×(VTn−VTREF)
where the first, the second, and the third proportional factors are constants,
the first proportional factor=50,
VTn=3.20 volts,
VTREF=3.00 volts,
the second proportional factor=0.5,
image area=31 square centimeters, and
the third proportional factor=0.5,
the toner refill amount at the time of next printing=10+0.5×31×(1+0.5×0.2)=27.05 milligrams.
(5) After the next printing is started, a toner refilling clutch is turned on for a predetermined time. The on-time is determined by the toner refilling amount calculated in (4) and refilling capability of the refilling system (in this example, the toner refilling device 40 in
Effects of the present invention are explained in comparison with the conventional technology.
In the conventional apparatus depicted in
By contrast, in the case of the present embodiment depicted in
An embodiment of the present invention has been explained with the example depicted in the drawings, but is not meant to be restrictive.
For example, the developing device can adopt an arbitrary structure as appropriate. Also, the toner density sensor and the toner refilling device can adopt an arbitrary structure as appropriate. The structure and placement of the toner-attachment-amount detection sensor can be changed as appropriate. As for the toner attachment amount, the toner attachment amount on the image carrier (photosensitive member) may be directly detected. The structure of the image forming unit of the image forming apparatus and the exposing device can be arbitrary. Also, the present invention is not restrictively applied to a full-color device, but can be applied to a monochrome device or a plural-color device. The image forming apparatus is not restricted to a printer, but may be a copier, a facsimile machine, and, furthermore, a multifunction product with a plurality of functions.
According to the image forming apparatus of one aspect of the present invention, a process control is executed while the toner density is being changed. In every process control, the toner density is appropriately kept. Therefore, apparatus downtime can be prevented, and an excellent image can be obtained by suppressing a change in image density as much as possible.
According to another aspect, the number of times of shortening an interval of executing a process control is limited. Therefore, even if a development value γ is not controlled as intended, the interval of executing the process control is not shortened without limitation.
According to still another aspect, whether to determine the next process control execution time based on the correction results is selectively provided. Therefore, a control of shorting the interval of executing the process control can be turned off. With this, a user can select image quality or productivity to prioritize, and appropriate printing according to a desire of the user can be performed.
According to still another aspect of the present invention, the process control can be executed at an appropriate time.
According to still another aspect of the present invention, the process control is executed when a predetermined condition is satisfied at power-on of an apparatus body. This can address the case where the state of the developing solution is unknown.
According to still another aspect of the present invention, the predetermined condition includes a condition in which hours not shorter than six hours have elapsed after printing ends. Therefore, even if a printing interval is large, an appropriate image density can be obtained.
According to still another aspect of the present invention, the predetermined condition includes a condition in which an amount of change in relative humidity after printing ends is equal to or larger than 30% relative humidity. Therefore, even if a change in humidity is large, an appropriate image density can be obtained.
Although the invention has been described with respect to a specific embodiment for a complete and clear disclosure, the appended claims are not to be thus limited but are to be construed as embodying all modifications and alternative constructions that may occur to one skilled in the art that fairly fall within the basic teaching herein set forth.
Number | Date | Country | Kind |
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2005-270085 | Sep 2005 | JP | national |