This patent application is based on and claims priority pursuant to 35 U.S.C. §119(a) to Japanese Patent Application No. 2014-023607, filed on Feb. 10, 2014, in the Japan Patent Office, the entire disclosure of which is hereby incorporated by reference herein.
1. Technical Field
Embodiments of the present invention generally relate to a developing device, a process cartridge, and an image forming apparatus, such as a copier, a printer, a facsimile machine, or a multifunction peripheral (MFP) having at least two of copying, printing, facsimile transmission, plotting, and scanning capabilities, that includes a developing device.
2. Description of the Related Art
Generally, image forming apparatuses include a developing device to develop latent images formed on a latent image bearer with developer. There are two types of developer: one-component developer including toner and two-component developer including toner and carrier. In high speed image forming apparatuses, two-component development is mainly used to secure a durability thereof. In high speed image forming apparatuses, there are demands for high image quality to cope with commercial printing.
In two-component developing devices, a range where a developing sleeve, serving as a developer bearer, faces the latent image bearer, such as a photoconductor, is called a development range. A magnetic field generator provided inside the developing sleeve generates a magnetic field that causes developer particles to stand on end, in the form of a magnetic brush, on the developing sleeve, and the magnetic brush contacts the latent image bearer in the development range. Thus, toner is supplied to the latent image on the latent image bearer, developing it into a visible image (toner image).
In this type of developing devices, toner borne on the developing sleeve moves toward the latent image bearer due to differences in surface potential between the developing sleeve, to which development voltage is applied, and the latent image bearer. Developing that uses voltage including a direct-current (DC) component is hereinafter referred to as “DC bias development”), and developing that uses voltage including an alternating-current (AC) component (i.e., a superimposed bias in which an AC component is superimposed on a DC component) is hereinafter referred to as “AC bias development”.
An embodiment of the present invention provides a developing device that includes a developer bearer to carry, by rotation, developer including toner and magnetic carrier to a development range facing a latent image bearer to bear a latent image, and the developer bearer includes a magnetic field generator having multiple magnetic poles, and a cylindrical developing sleeve to rotate and bear developer on an outer circumferential surface thereof with magnetic force of the magnetic field generator disposed inside the developing sleeve. The developing sleeve receives development voltage including an AC component having a frequency of 2.0 kHz or lower. In the AC component, a duty ratio of a component having a polarity opposite a toner normal charge polarity is within a range from 4% to 20%.
Another embodiment provides an image forming apparatus that includes a latent image bearer to bear an electrostatic latent image thereon, a charging device to charge the surface of the latent image bearer, the above-described developing device to develop the electrostatic latent image, and a first voltage application device to apply the above-described development voltage to the developing sleeve.
A more complete appreciation of the disclosure and many of the attendant advantages thereof will be readily obtained as the same becomes better understood by reference to the following detailed description when considered in connection with the accompanying drawings, wherein:
In describing preferred embodiments illustrated in the drawings, specific terminology is employed for the sake of clarity. However, the disclosure of this patent specification is not intended to be limited to the specific terminology so selected, and it is to be understood that each specific element includes all technical equivalents that operate in a similar manner and achieve a similar result.
The inventors of the present application recognize that the density of images developed in the DC bias development tend to fluctuate cyclically (hereinafter “cyclic density fluctuation”) corresponding to a length of circumference (perimeter) of the developing sleeve. The inventors assume that the cyclic density fluctuation is caused as follows. When the developing sleeve is eccentric due to, for example, manufacturing tolerances, a clearance between the latent image bearer and the developing sleeve (i.e., a development gap) fluctuates in accordance with the cycle of rotation of the developing sleeve.
The inventors have confirmed that, in the AC bias development, the above-described cyclic density fluctuation is alleviated compared with the DC bias development, but have found the following inconvenience. Compared with the DC bias development, in typical AC bias development, it is possible that void at density boundaries, which is an image failure defined below, or image graininess is degraded depending on the frequency of AC component. Specifically, void at density boundaries is degraded as the frequency increases, and granularity (graininess) is degraded as the frequency decreases.
The term “void at density boundaries” used in this specification means image failure in which toner is absent at a boundary between portions different in image density. Additionally, “granularity (graininess)” is an item to evaluate how the image looks grainy, and image quality is high when the value of granularity is small.
Referring now to the drawings, wherein like reference numerals designate identical or corresponding parts throughout the several views thereof, and particularly to
It is to be noted that the suffixes Y, M, C, and K attached to each reference numeral indicate only that components indicated thereby are used for forming yellow, magenta, cyan, and black images, respectively, and hereinafter may be omitted when color discrimination is not necessary.
The image forming apparatus 500 includes a printer unit 100 that is an apparatus body, a document reading unit 4 and a document feeder 3, both disposed above the printer unit 100, and a sheet feeder 7 disposed beneath the printer unit 100. The document feeder 3 feeds documents to the document reading unit 4, and the document reading unit 4 reads image data of the documents. The sheet feeder 7 is a sheet container that contains sheets P (transfer sheets) of recording media and includes a sheet feeding tray 26 in which the sheets P are stored and a sheet feeding roller 27 to feed the sheets P from the sheet feeding tray 26 to the printer unit 100. It is to be noted that broken lines shown in
A paper ejection tray 30 on which output images are stacked is provided on an upper side of the printer unit 100. The printer unit 100 includes four image forming units 6Y, 6M, 6C, and 6K for forming yellow, magenta, cyan, and black toner images, respectively, and an intermediate transfer unit 10. Each image forming unit 6 includes a drum-shaped photoconductor 1 serving as an image bearer on which a toner image is formed, and a developing device 5 for developing an electrostatic latent image on the photoconductor 1 into the toner image.
The image forming units 6Y, 6M, 6C, and 6K respectively corresponding to yellow, magenta, cyan, and black are arranged in parallel, facing an intermediate transfer belt 8 of an intermediate transfer unit 10.
The intermediate transfer unit 10 includes four primary-transfer bias rollers 9Y, 9M, 9C, and 9K in addition to the intermediate transfer belt 8. The intermediate transfer belt 8 serves as an intermediate transfer member onto which the toner images are transferred from the respective photoconductors 1, and the toner images are superimposed one on another thereon, thus forming a multicolor toner image. The primary-transfer bias rollers 9 serve as primary-transfer members to primarily transfer the toner images from the photoconductors 1 onto the intermediate transfer belt 8.
The printer unit 100 further includes a secondary-transfer bias roller 19 to transfer the multicolor toner image from the intermediate transfer belt 8 onto the sheet P. Further, a pair of registration rollers 28 is provided to suspend the transport of the sheet P and adjust the timing to transport the sheet P to a secondary-transfer nip between the intermediate transfer belt 8 and the secondary-transfer bias roller 19 pressed against it. The printer unit 100 further includes a fixing device 20 disposed above the secondary-transfer nip to fix the toner image on the sheet P.
Additionally, toner containers 11Y, 11M, 11C, and 11K for containing respective color toners supplied to the developing devices 5 are provided inside the printer unit 100, beneath the paper ejection tray 30 and above the intermediate transfer unit 10.
The image forming apparatus 500 further includes a controller 60, which is, for example, a computer including a central processing unit (CPU) and associated memory units (e.g., ROM, RAM, etc.). The computer performs various types of control processing by executing programs stored in the memory. Field programmable gate arrays (FPGA) may be used instead of CPUs.
As shown in
In the configuration shown in
In another embodiment, the photoconductor 1 and the developing device 5 are united into a modular unit serving as a process cartridge. In yet another embodiment, the photoconductor 1, the charging device 40, the developing device 5, and the cleaning device 2 are independently installed and removed from the apparatus body. Each of them is replaced with a new one when its operational life expires.
In image formation, toner images are formed on the photoconductor 1 through image forming processes, namely, charging, exposure, development, transfer, and cleaning processes.
Operations of the image forming apparatus 500 to form multicolor images are described below.
When a start button is pressed with documents set on a document table of the document feeder 3, conveyance rollers provided in the document feeder 3 transport the documents from the document table onto an exposure glass (contact glass) of the document reading unit 4. Then, the document reading unit 4 reads image data of the document set on the exposure glass optically.
More specifically, the document reading unit 4 scans the image of the document on the exposure glass with light emitted from an illumination lamp. The light reflected from the surface of the document is imaged on a color sensor via mirrors and lenses. The multicolor image data of the document is decomposed into red, green, and blue (RGB), read by the color sensor, and converted into electrical image signals. Further, an image processor performs image processing (e.g., color conversion, color calibration, and spatial frequency adjustment) according to the image signals, and thus image data of yellow, magenta, cyan, and black are obtained.
Then, the image data of yellow, magenta, cyan, and black are transmitted to an exposure device. The exposure device directs laser beams L to respective surfaces of the photoconductors 1 according to image data of respective colors.
Meanwhile, the four photoconductors 1 are rotated by a driving motor clockwise in
Then, the laser beams L according to the respective color image data are emitted from four light sources of the exposure device. The laser beams pass through different optical paths for yellow, magenta, cyan, and black and reach the surfaces of the respective photoconductors 1 (an exposure process).
In the case of yellow, the laser beam L corresponding to the yellow component is directed to the photoconductor 1Y, which is the first from the left in
Similarly, the laser beam L corresponding to the magenta component is directed to the surface of the photoconductor 1M, which is the second from the left in
Subsequently, the surface of the photoconductor 1 bearing the electrostatic latent image is further transported to the position facing the developing device 5. At that position, the developing device 5 to contain developer including toner (toner particles) and carrier (carrier particles) supplies toner to the surface of the photoconductor 1, thus developing the latent image thereon (a development process). Then, a toner image is formed on the photoconductor 1.
Subsequently, the surfaces of the photoconductors 1 reach positions facing the intermediate transfer belt 8, where the primary-transfer bias rollers 9 are provided in contact with an inner circumferential face of the intermediate transfer belt 8 The primary-transfer bias rollers 9 face the respective photoconductors 1 via the intermediate transfer belt 8, and contact portions therebetween are called primary-transfer nips, where the single-color toner images are transferred from the respective photoconductors 1 and superimposed one on another on the intermediate transfer belt 8 (a transfer process). After the primary-transfer process, a slight amount of toner tends to remain untransferred on the photoconductor 1.
Subsequently, the surface of the photoconductor 1 reaches a position facing the cleaning device 2, where the cleaning blade 2a scraps off the untransferred toner on the photoconductor 1 (cleaning process).
Subsequently, a discharger removes electrical potential remaining on the surface of the photoconductor 1.
Thus, a sequence of image forming processes performed on the photoconductor 1 is completed, and the photoconductor 1 is prepared for subsequent image formation.
The image forming units 6 shown in
As described above, the four primary-transfer bias rollers 9 press against the corresponding photoconductors 1 via the intermediate transfer belt 8, and four contact portions between the primary-transfer bias rollers 9 and the corresponding photoconductors 1 are hereinafter referred to as primary-transfer nips. Each primary-transfer bias roller 9 receives a transfer bias whose polarity is opposite the charge polarity of the toner.
While rotating in a direction indicated by an arrow shown in
The intermediate transfer belt 8 carrying the superimposed single-color toner images (a multicolor toner image) transferred from the four photoconductors 1 rotates counterclockwise in
Additionally, the sheet feeding roller 27 sends out the sheet P from the sheet feeding tray 26, and the sheet P is then guided by a sheet guide to the registration rollers 28. The sheet P is caught in the nip between the registration rollers 28 and stopped. Then, the registration rollers 28 forward the sheet P to the secondary-transfer nip, timed to coincide with the multicolor toner on the intermediate transfer belt 8.
More specifically, the sheet feeding tray 26 contains multiple sheets P (i.e., transfer sheets) serving as recording media and piled one on another. The sheet feeding roller 27 rotates counterclockwise in
In the secondary-transfer nip, the multicolor toner image is transferred from the intermediate transfer belt 8 onto the sheet P (a secondary-transfer process). A slight amount of toner tends to remain untransferred on the intermediate transfer belt 8 after the secondary-transfer process.
Subsequently, the intermediate transfer belt 8 reaches a position facing a belt cleaning device, where the untransferred toner on the intermediate transfer belt 8 is collected by the belt cleaning device. Thus, a sequence of transfer processes performed on the intermediate transfer belt 8 is completed. Thus, a sequence of image forming processes performed on the intermediate transfer belt 8 is completed.
The sheet P carrying the multicolor toner image is sent to the fixing device 20. In the fixing device 20, a fixing belt and a pressing roller are pressed against each other. In a fixing nip therebetween, the toner image is fixed on the sheet P with heat and pressure (i.e., a fixing process).
Then, the sheet P is transported by a pair of paper ejection rollers 25, discharged outside the apparatus body as an output image, and stacked on the paper ejection tray 30 sequentially.
Thus, a sequence of image forming processes performed in the image forming apparatus 500 is completed.
Next, a configuration and operation of the developing device 5 of the image forming unit 6 are described in further detail below with reference to
The developing device 5 includes a casing 58 (shown in
The developing device 5 includes a developing roller 50 serving as a developer bearer disposed facing the photoconductor 1, a supply screw 53, a collecting screw 54, a doctor blade 52 serving as a developer regulator, and a partition 57. In one embodiment, the supply screw 53 and the collecting screw 54 are screws or augers each including a rotation shaft and a spiral blade winding around the rotation shaft and transport developer in an axial direction by rotating. In another embodiment, the supply screw 53 and the collecting screw 54 are paddles.
The casing 58 includes a development opening 58e to partly expose the surface of the developing roller 50 in a development range where the developing roller 50 faces the photoconductor 1.
The doctor blade 52 is disposed facing the surface of the developing roller 50 and adjusts the amount of developer carried on the surface of the developing roller 50.
The supply screw 53 and the collecting screw 54A serve as multiple developer conveying members to stir and transport developer in the longitudinal direction, thereby establishing a circulation channel. The supply screw 53 faces the developing roller 50 and supplies developer to the developing roller 50 while transporting the developer in the longitudinal direction. The collecting screw 54 transports developer while mixing the developer with supplied toner.
The partition 57 divides, at least partly, an interior of the casing 58 into a supply channel 53a in which the supply screw 53 is provided and a collecting channel 54a in which the collecting screw 54 is provided. Additionally, on the cross section (shown in
As shown in
The developing device 5 contains two-component developer including toner and carrier (one or more additives may be included) in a space (e.g., the supply channel 53a and the collecting channel 54a) defined by the casing 58. The supply screw 53 and the collecting screw 54 transport developer in the longitudinal direction (an axial direction of the developing sleeve 51), and thus the circulation channel is established inside the developing device 5. Additionally, the supply screw 53 and the collecting screw 54 are arranged vertically, that is, disposed adjacent to each other at different heights. The partition 57 situated between the supply screw 53 and the collecting screw 54 divides the supply channel 53a from the collecting channel 54a. The developing device 5 further includes a toner density detector to detect the density of toner in developer contained in the supply channel 53a or the collecting channel 54a.
The doctor blade 52 is provided beneath the developing roller 50 in
Further, a toner supply inlet 59 (shown in
In the developing device 5 according to the present embodiment, a constant or substantially constant amount of developer is contained. For example, in the developer usable in the present embodiment, toner particles, including polyester resin as a main ingredient, and magnetic carrier particles, are mixed uniformly so that the density of toner is about 7% by weight. The toner has an average particle diameter of about 5.8 μm, and the magnetic carrier has an average particle diameter of about 35 μm, for example. The supply screw 53 and the collecting screw 54 arranged in parallel are rotated at a velocity of about 600 to 800 revolutions per minute (rpm), thereby transporting developer while mixing toner and carrier, charging the toner. Additionally, the toner supplied through the toner supply inlet 59 is stirred in the developer by rotating the supply screw 53 and the collecting screw 54 to make the content of toner in the developer uniform.
While being transported in the longitudinal direction by the supply screw 53 positioned adjacent to and parallel to the developing sleeve 51, the developer in which toner and carrier are mixed uniformly is attracted by the fifth pole P5 of the magnet roller 55 inside the developing sleeve 51 and carried on the outer circumferential surface of the developing sleeve 51. The developer carried on the developing sleeve 51 is transported to the development range as the developing sleeve 51 rotates counterclockwise as indicated by an arrow shown in
The developing sleeve 51 receives voltage from a power source 151 shown in
The developer on the developing sleeve 51 that has passed through the development range is collected in the collecting channel 54a as the developing sleeve 51 rotates. Specifically, developer falls from the developing sleeve 51 to an upper face of the partition 57, slides down the partition 57, and then is collected by the collecting screw 54.
Inside the developing device 5, developer flows as indicated by arrows shown in
The collecting channel 54a on the upper side and the supply channel 53a on the lower side in
As shown in
It is to be noted that, although the supply channel 53a and the collecting channel 54a are illustrated as if they are away from each other in
As shown in
In the developing device 5, the fourth and fifth poles P4 and P5 (i.e., the developer release pole) generate a repulsive magnetic force. In the area in which the repulsive magnetic force is generated (i.e., a developer release area), developer is released by the developer release pole in a direction of composite of a normal direction and a direction tangential to the rotation of the developing sleeve 51. Then, the developer falls under the gravity to the partition 57 and is collected by the collecting screw 54.
The collecting screw 54 in the collecting channel 54a, which is above the supply channel 53a, transports the developer separated from the developing sleeve 51 in the developer release area axially in the direction opposite the direction in which the supply screw 53 transports developer.
Through the developer-lifting opening 72, the downstream end of the supply channel 53a in which the supply screw 53 is provided communicates with the upstream end of the collecting channel 54a in which the collecting screw 54 is provided. The developer at the downstream end of the supply channel 53a accumulates there and pushed up by the developer transported from behind. Then, the developer moves through the developer-lifting opening 72 to the upstream end of the collecting channel 54a.
The toner supply inlet 59 is in the upstream end portion of the collecting channel 54a, and fresh toner is supplied as required by a toner supply device from the toner container 11 (shown in
As described above, the supply screw 53 and the collecting screw 54 rotate in the directions indicated by arrows Y1 and Y3 shown in
In the developing device 5, while the supply screw 53 stirs and transports developer in the supply channel 53a, the developer is supplied onto the developing sleeve 51, and the developer on the developing sleeve 51 is collected in the collecting screw 54. Accordingly, the amount of developer transported in the supply channel 53a decreases toward downstream in the developer conveyance direction by the supply screw 53, and the surface of developer accumulating inside the supply channel 53a is oblique as shown in
Assuming that Wm represents a developer conveyance capability of the supply screw 53, which can be obtained from the diameter and the pitch of the blade of the supply screw 53 and the number of rotation of the supply screw 53, and Ws represents a developer conveyance capability on the developing sleeve 51, developer can be uniformly transported on the surface of the developing sleeve 51 when Wm>Ws. If this relation is not satisfied, it is possible that the amount of developer becomes insufficient on the downstream side of the supply channel 53a in the conveyance direction of the supply screw 53, and developer is not supplied to the developing sleeve 51 on the downstream side. Accordingly, the supply screw 53 is to have a developer conveyance capability (Wm) greater than the amount of developer transported on the developing sleeve 51.
Additionally, when developer is collected from the developing sleeve 51 into the collecting channel 54a, if the bulk of the developer in the collecting channel 54a is excessively large and the level is high, it is possible that developer is not collected in the collecting channel 54a but moves through a clearance between the partition 57 and the developing sleeve 51 to the supply channel 53a. Then, the developer can be supplied to the developing sleeve 51 before stirred sufficiently by the supply screw 53. When the insufficiently stirred developer reaches the development range, it causes substandard images. Accordingly, the collecting screw 54 is to have a developer conveyance capability greater than the amount of developer transported on the developing sleeve 51 as well.
Thus, it is preferred that the developer conveyance capabilities of the supply screw 53 and the collecting screw 54 be greater than the amount of developer transported on the developing sleeve 51. To achieve this, the rotation speed of the supply screw 53 and the collecting screw 54 tend to be relatively high.
The developing bias applied to the developing sleeve 51 is described in further detail below.
In
The developing bias Vb according to the present embodiment is voltage including an AC component not greater than about 2.0 kHz in frequency (1/T). In the present embodiment, a normal charge polarity of toner is negative, and, in the developing bias Vb, the component in the polarity (positive polarity in the present embodiment) opposite the normal charge polarity of toner has a duty ratio (T1/T×100, hereinafter “positive-side duty ratio”) of about 20% or smaller. Further, the difference between a largest value and a smallest value on the negative side of the developing bias Vb is about 1500 V or smaller. The smallest value on the negative side used here means a value closest to zero V in a case where the surface potential of the developing sleeve 51 fluctuates only on the negative polarity side and a greatest value on the positive polarity side in a case where the surface potential fluctuates in a range extending to the positive side.
The term “positive-side duty ratio” used here means the ratio of application time of a positive polarity component, which is on the positive side of an exposure potential VL, in one cycle of the AC bias. The positive-side duty ratio is obtained by dividing, with one cycle time (T) of the AC bias, the time (T1) during which the positive-side voltage is applied in one cycle time (T1/T). It is to be noted that, while the voltage on the positive side of the exposure potential VL is applied, an electrical field that draws back toner adhering to the electrostatic latent image on the photoconductor 1 to the developing sleeve 51 occurs.
The term “frequency” used here indicates the number of waveform cycles in one second and expressed as “1/T” when T represents one cycle time.
The example waveform shown in
In
A lower limit on the negative side (i.e., a largest value on the positive side and the lower limit in
In
The comparative waveform shown in
Compared with the comparative waveform shown in
Additionally, in typical AC bias development, a high frequency of 5 kHz or greater is a mainstream, and the frequency is 9 kHz in the comparative waveform shown in
Thus, compared with the waveform in typical AC bias development, the waveform of the developing bias according to the present embodiment has a low frequency and the duty ratio of component opposite the normal charge polarity of toner is low.
Hereinafter the AC developing bias having the above-described features according to the present embodiment is referred to as “RP developing bias”, and the type of image development employing the RP developing bias is referred to as “RP development” for convenience. The inventors of the present application has experimentally confirmed that, in image formation employing the RP development, cyclic density unevenness due to the rotation cycle of the developing sleeve 51 is suppressed, and simultaneously the occurrence of void at density boundaries (absence of toner at the boundary between portions different in image density) and degradation of graininess are suppressed. In experimental image formation in which conditions of the developing bias applied to the developing sleeve 51 were varied, graininess was alleviated to a level similar to that achieved in the DC bias development, compared with typical AC bias development.
In the RP development using the waveform, for example, shown in
Accordingly, the electrostatic latent image on the photoconductor 1 is developed when, in the negative polarity, the developing bias average Vbav is smaller than the charge potential Vd and greater than the exposure potential VL (Vd>Vbav>VL).
It is to be noted that, in the present embodiment, the exposure potential VL is in the range of 0 V±100 V similar to typical image forming apparatuses. For example, the exposure potential VL is −100 V in
In the RP development, lowering the frequency is effective in suppressing the occurrence of void at density boundaries, which tends to occur in the AC bias development in which the frequency is higher. Additionally, in the RP development, lowering the positive-side duty ratio is effective in alleviating graininess, which tends to occur in the AC bias development in which the frequency is lower and the positive-side duty ratio is higher.
Next, the potential of the developing sleeve 51 and that of the photoconductor 1 are described below.
In typical electrophotographic image forming apparatuses, the surface of the photoconductor 1 is uniformly charged and then exposed by the exposure device, thereby forming an electrostatic latent image. Then, the electrostatic latent image is developed into a toner image. At that time, by applying, to the developing sleeve 51, a potential greater on the normal charge polarity of toner (on the negative side in the present embodiment) than that of the electrostatic latent image, and the potential difference is to transfer toner from the developing sleeve 51 to the electrostatic latent image is secured.
In the case of DC bias application, the surface potential of the developing sleeve 51 is constant since the voltage applied to the developing sleeve 51 is constant. Accordingly, a potential difference that transfers toner from the developing sleeve 51 to the exposed portion on the photoconductor 1 occurs but a potential difference that draws back toner in the opposite direction does not occur.
By contrast, in the case of AC bias application, in a very short period, the potential difference that transfers toner from the developing sleeve 51 to the photoconductor 1 alternates with the potential difference that draws back toner therefrom to the developing sleeve 51 relative to the electrostatic latent image. Even when the potential difference that draws back toner from the photoconductor 1 to the developing sleeve 51 is generated, toner can move to the electrostatic latent image because the potential difference to transfer toner to the photoconductor 1 is secured between an average potential of the AC bias and the potential of the electrostatic latent image.
Application of an AC bias is advantageous over application of DC bias in alleviating image density unevenness. A conceivable cause of this is that the amount of toner adhering to the photoconductor 1 is equalized, thereby reducing differences in color shading, by drawing back toner from the photoconductor 1 to the developing sleeve 51 and again transferring toner to the photoconductor 1. The effective to alleviate image density unevenness is greater when the AC bias frequency is increased, or the peak-to-peak value (difference between the largest value and the smallest value of the developing bias) is increased.
The inventors further recognize the followings.
Increases in the frequency strengthens the action to draw back toner and accordingly increases the possibility of occurrence of void at density boundaries, meaning the image failure in which toner is absent at a boundary between portions different in image density. To alleviate the void at density boundaries, the frequency of AC bias is set to 2 kHz or smaller in the present embodiment.
Additionally, increases in the peak-to-peak value increases the movement of toner and accordingly further inhibit image density unevenness. However, the occurrence of background stains, meaning that adhesion of toner to non-image areas on the photoconductor 1, increases. Therefore, the peak-to-peak value is 1500 V or lower in the present embodiment.
Under these conditions, it is possible that the action of AC bias to draw back toner worsens the image graininess, that is, image uniformity is degraded. Therefore, to alleviate the degradation in graininess, the positive-side duty ratio (T1/T×100 in
Descriptions are given below of experiments in researching desirable setting of the peak-to-peak value, and the frequency and the positive-side duty ratio of the AC bias.
[Experiment 1]
Experiment 1 is executed to confirm an upper limit of the peak-to-peak value (Vpp) based on the relation with background stains. Background stains were evaluated by visually observing the adhesion (i.e., scattering) of toner on non-image areas when a given image was output.
Conditions of experiment 1 are as follows.
Image forming apparatus: Ricoh imagio MP C5000;
Developer: Cyan;
Developing sleeve: Aluminum sleeve coated with tetrahedral amorphous carbon (hereinafter “ta-C coating); and
Developing bias: DC bias only and DC bias superimposed with AC component (frequency: 990 Hz and positive-side duty ratio: 7%
Inhibition of background stains is rated according to the following criteria:
5: Background stains not observed;
4: No problem;
3: Acceptable;
2: Not acceptable; and
1: Bad (worse than 2).
In experiment 1, background stains under different developing bias conditions were evaluated according to the criteria described above, and
As the different developing bias conditions, images were formed under DC bias application and AC bias application, and the peak-to-peak value Vpp was set to 1.25 kV, 1.5 kV, and 1.75 kV in AC bias application.
As shown in
[Experiment 2]
Experiment 2 was executed to confirm an upper limit of the frequency of the developing bias based on the relation between the frequency of the developing bias and the void at density boundaries. Images patterned with check of solid areas and half density areas were visually checked for void at density boundaries.
Conditions of experiment 2 are as follows.
Image forming apparatus: Ricoh imagio MP C5000;
Developer: Cyan;
Developing sleeve: Aluminum sleeve coated with ta-C coating; and
Developing bias: DC bias only and DC bias superimposed with AC component (peak-to-peak value: 800 V and positive-side duty ratio: 7%)
Inhibition of void at density boundaries was rated according to the following criteria:
5: Void at density boundaries not observed;
4: No problem;
3: Acceptable;
2: Not acceptable; and
1: Bad (worse than 2).
Results of experiment 1 under different developing bias conditions, evaluated according to the criteria described above, are in
As the different developing bias conditions, images were formed under DC bias application and AC bias application, and the peak-to-peak value frequency was set to 0.99 kHz, 2 kHz, 5.5 kHz, and 9 kHz in AC bias application.
As shown in
Further, in
When the frequency is extremely low, however, image density unevenness resulting from the cycle of AC bias is degraded to be visually recognizable. Specifically, stripes due to image density differences in the direction in which the sheet P is transported appears.
When the frequency was shifted lower from 990 Hz, image density unevenness was not recognizable with eyes in the range from 990 Hz to 800 Hz. When the frequency was 700 Hz, however, stripes become recognizable with eyes, and the stripes were clear when the frequency was 600 Hz. Therefore, in the present embodiment, the frequency is 800 Hz or greater.
[Experiment 3]
Experiment 3 was executed to confirm an upper limit of the positive-side duty ratio of the developing bias based on the relation between the positive-side duty ratio of the developing bias and image graininess. For image graininess evaluation, images having an image area ratio of 70% were visually checked.
Conditions of experiment 3 are as follows.
Image forming apparatus: Ricoh imagio MP C5000;
Developer: Cyan;
Developing sleeve: Aluminum sleeve with ta-C coating; and
Developing bias: DC bias only and DC bias superimposed with AC component (peak-to-peak value: 800 V and frequency: 990 Hz)
Image graininess is rated according to the following criteria:
5: Graininess preferable;
4: No problem;
3: Acceptable;
2: Not acceptable; and
1: Bad (worse than 2).
Results of experiment 3 under different developing bias conditions, evaluated according to the criteria described above, are in
As the different developing bias conditions, images were formed under DC bias application and AC bias application, and the positive-side duty ratio was set to 4%, 7%, 20%, and 50% in AC bias application.
According to
As shown in
The positive-side duty ratio of 7% is more advantageous than 20% in further alleviating image graininess.
As shown in
As shown in
According to the graph in
As shown in
According to
The RP development having waveform shown in
Specifically, at the edges of images, electrical potentials increase from the exposure potential VL due to edge effects. In the waveform shown in
For example, it is assumed that the edge effects cause the potential of an image area to increase by 20 V from the exposure potential VL. In this case, the developing potential Vpot is 200 V in the AC bias development having the waveform shown in
By contrast, in the RP development having the waveform shown in
In conventional AC bias development, image graininess is degraded when the positive-side duty ratio is in a range from 50% to 70% and the frequency is set to 1 kHz or smaller to inhibit the occurrence of void at density boundaries. Therefore, in the experiment, the range of positive-side duty ratio was widened to find a range to keep both of graininess and image density unevenness at “Acceptable” levels or better.
The ratings of image graininess in
5: Image density unevenness not observed;
4: No problem;
3: Acceptable;
2: Not acceptable; and
1: Bad (worse than 2).
In
Additionally, an experiment was performed to research the behavior of toner on the surface of the photoconductor 1 passing through the developing nip in both cases where the developing bias had the waveform shown in
Specifically, in the experiment, a transparent glass drum was used instead of the photoconductor 1, the developing nip was shot consecutively from inside the glass drum, and the behavior of toner was checked on the images of the developing nip.
When the developing bias having the waveform shown in
The followings are assumed factors that have caused the above-described difference in behavior.
In the AC bias development, image are developed due to the difference between the developing bias average Vbav and the exposure potential VL. Additionally, even when the largest value on the positive side of the developing bias Vb is identical, the developing bias average Vbav is shifted to the positive direction as the positive-side duty ratio increases.
In the comparative waveform shown in
Since the potential difference is smaller and the force to draw back toner from the photoconductor 1 to the developing sleeve 51 is weaker, toner on the photoconductor 1 does not return to the developing sleeve 51 but just vibrates on the photoconductor 1.
By contrast, in the waveform shown in
Since the potential difference is larger and the force to draw back toner from the photoconductor 1 to the developing sleeve 51 is stronger, it is conceivable that most of the toner on the photoconductor 1 cyclically returns to the developing sleeve 51.
In the case of the waveform shown in
There are the following advantages when most of toner adhering to the photoconductor 1 is drawn back to the developing sleeve 51 as in the waveform shown in
That is, when an excessive amount of toner adheres to the photoconductor 1 due to, for example, a relatively narrow development gap GP, the excessive toner on the photoconductor 1 can be partly returned to the developing sleeve 51 and thus collected. By contrast, even if the amount of toner adhering to the photoconductor 1 is excessive, in the waveform shown in
The waveform shown in
It is to be noted that, in the graph of RP development in
As shown in
In the arrangement shown in
According to a further research by the inventors, even in the above-described RP development, it is possible that the image graininess is degraded when the linear velocity ratio, meaning the ratio of the speed at which the surface of the developing sleeve 51 moves relative to the speed at which the surface of the photoconductor 1 moves, is improper.
In an experiment, the rotation speed of the developing sleeve 51 was varied under a developing bias condition of RP development in which the peak-to-peak value Vpp was 1000 V, the frequency was 990 Hz, and the positive-side duty ratio was 7%.
When the surface movement speed of the developing sleeve 51 is Vs (m/s) and the surface movement speed of the photoconductor 1 is Vg (m/s), the linear velocity ratio is expressed as Vs/Vg.
When the surface movement speed of the developing sleeve 51 was identical to the surface movement speed of the photoconductor 1 (linear velocity ratio Vs/Vg=1.0), the image graininess was degraded. When the linear velocity ratio Vs/Vg was 1.2, the image graininess was improved from that in the case where Vs/Vg was 1.0, but the improvement was not sufficient.
In a range of linear velocity ratio from 1.3 to 1.8, the image graininess was preferable level. When the linear velocity ratio was increased from 1.8, the image graininess was again degraded.
Therefore, in the present embodiment, the range of linear velocity ratio Vs/Vg is from 1.3 to 1.8.
The image forming apparatus 500 according to the present embodiment includes the multiple image forming units 6, and the respective developing devices 5 of the image forming units 6 use different color toners. In the case of image forming apparatuses including the multiple developing devices 5 similar to the image forming apparatus 500 shown in
For example, the developing device 5K for black employs the DC bias development, and the other three developing devices 5 may employ the RP development described above.
Since image density unevenness is less perceivable and degradation in image uniformity (graininess) is more perceivable in black images, the DC developing bias, which is effective in inhibiting graininess, is applied to the developing sleeve 51 of the developing device 5K for black. By contrast, the RP developing bias, in which the positive-side duty ratio is smaller, is applied to the developing sleeves 51 of the developing devices 5 for the other colors (Y, M, and C). This configuration is effective in inhibiting image density unevenness while inhibiting degradation of graininess.
Descriptions are given below of causes that make image graininess in black images more recognizable.
An experiment was conducted to evaluate dot area standard deviation and graininess when the charge amount of developer was varied.
The results shown in
Apparatus used: RICOH Pro C751EX;
Developing device used: Developing devices for black, cyan, and magenta;
Developing potential (difference between the developing bias and potential in image portions on the photoconductor): Adjusted to attain an image density of 1.5; and
CCD camera: Micro scope VHX-100 from Keyence corporation
Image graininess (degradation of image uniformity) is rated according to the following criteria:
5: Graininess not recognized;
4: No problem;
3: Acceptable;
2: Not acceptable; and
1: Bad (worse than 2).
According to
Additionally, according to the result shown in
Accordingly, in color images (such as cyan and magenta images) other than black images, the effects on graininess are smaller even when the dot area standard deviation increases to a certain degree. In black images, however, image graininess is degraded by the increase in the dot area standard deviation.
Thus, the image graininess is more recognizable in black images.
In the above-described case, black images, which are susceptible to graininess degradation, are developed in the DC development effective in inhibiting graininess, and the other color images are developed in the RP development effective in inhibiting image density unevenness. Thus, image density unevenness is inhibited while inhibiting degradation of image graininess.
Mechanism of degradation of image graininess (granularity) is described below.
As described above, in the AC bias development, the potential different to transfer toner to the photoconductor 1 is secured between the average potential of the AC bias and the potential of the electrostatic latent image on the photoconductor 1, and thus the electrostatic latent image is developed with toner. The electrostatic latent image, however, is not fully filled with toner if the potential difference that draws back toner from the photoconductor 1 to the developing sleeve 51 is large. A trace of returned toner remains in the toner image developed on the photoconductor 1, and toner is partly absent in the toner image. Such an image looks grainy (a grainy image).
To reduce the amount of toner returned from the photoconductor 1 to the developing sleeve 51, it is effective to adopt the above-described RP development in which the positive-side duty ratio of the AC developing bias is reduced.
The results shown in
Image forming apparatus: Modification of Ricoh imagio MP C5000;
Developer: Cyan and Black;
Developing sleeve: Aluminum sleeve coated with ta-C (0.6 μm with deviation of 0.3 μm); and
Developing bias: DC component and AC component superimposed thereon; Frequency of AC component: 1 kHz;
Amplitude of AC component (peak-to-peak): 800 V;
Duty ratio of positive side of AC component: 1% to 30%; and
DC component: Adjusted to attain an image density of 1.5
Ratings of graininess (on image area ratio of 30%) and image density unevenness (on image area ratio of 75%) are as follows.
5: Not observed;
4: No problem;
3: Acceptable;
2: Not acceptable; and
1: Bad
According to
According to
Therefore, inhibition of image density unevenness and that of graininess are balanced in all of the developing devices 5 by employing the DC development in the developing device 5K for black and employing the RP development in the developing devices 5 for other colors.
Next, the developing roller 50 is described in further detail below.
As shown in
Additionally, in the configuration shown in
Next, descriptions are given below of image failure caused “ghost images” (also called “afterimages”) caused by fluctuations in the amount of toner adhering to the latent image bearer.
In any of the development types, to attain full-color images that excel in color reproducibility, uniformity, and sharpness, it is preferred to make the amount of toner supplied to the image bearer, such as the photoconductor, conform to the electrostatic latent image.
It is known that fluctuations in the amount of toner adhering to the latent image bearer are caused by, in addition to fluctuations in the amount of toner change, an inheritance of image history from a preceding image to a subsequent image.
In hybrid development, which has been proposed in addition to one-component development and two-component development, the amount of toner on a toner bearer changes in accordance with a toner consumption pattern of an immediately preceding image, and the image density of a subsequent image tends to fluctuate. This is caused because the amount of toner supplied to the toner bearer is kept identical or similar constantly in hybrid development, the amount of toner on the toner bearer varies depending on the number of times toner is supplied to the toner bearer. That is, in a case where the toner consumption amount of the preceding image is small, the amount of toner remaining on the toner bearer is greater. The amount of toner on the toner bearer further increases after toner is supplied thereto, resulting in increases in image density. By contrast, after an image that consumes a greater amount of toner is printed, a smaller amount of toner remains on the toner bearer. It is possible that the amount of toner on the toner bearer is small even after toner is supplied thereto, resulting in decreases in image density.
By contrast, even in two-component developing devices, like the developing device 5 according to the present embodiment, it is possible that the subsequent image inherits the history of the preceding image and the image density becomes uneven, resulting in a ghost image. It is conceivable that ghost images in two-component developing devices are caused as follows.
That is, the development amount in the subsequent image depends on whether a given portion of the developing sleeve has faced a non-image area or an image area in the preceding image. This is a possible cause of a ghost image in the subsequent image.
Specifically, the non-image area has a potential stronger in keeping away toner than the potential of the developing sleeve. Accordingly, when the surface of the developing sleeve faces the non-image area of the photoconductor in the development range during the development of the preceding image, force heading from the photoconductor toward the surface of the developing sleeve is exerted on the charged toner due to differences in electrical potential between the non-image area and the developing sleeve. Therefore, the toner in two-component developer carried on the surface of the developing sleeve moves toward a root side of the magnetic brush on the developing sleeve, that is, toward the surface of the developing sleeve. Then, a part of the toner contacts the surface of the developing sleeve and adheres thereto.
On the surface of the developing sleeve downstream from the development range in the direction in which the developing sleeve rotates, the magnetic field generator exerts magnetic force to separate carrier particles from the developing sleeve. At that time, although the toner adhering to the carrier generally moves away together with the carrier, the toner adhering to both the carrier and the surface of the developing sleeve remains on one of them that is greater in adhesion force with toner. Accordingly, in a case where the adhesion force of toner to the developing sleeve is greater, when the carrier moves away from the developing sleeve due to the repulsive magnetic force, the toner adhering to the surface of the developing sleeve does not move away together with the carrier but remains on the developing sleeve. Subsequently, when the surface of the developing sleeve reaches the developer supply position, two-component developer is supplied again to the surface of the developing sleeve on which toner remains.
In a state in which the charged toner adheres thereto, the surface potential of the developing sleeve is increased by an amount equivalent to the electrical charge of the toner, and the surface potential is shifted to the side of toner charge polarity. Additionally, in the development range, on the surface of the photoconductor carrying the latent image, toner adheres to an image area having an electrical potential shifted to the opposite polarity (in the present embodiment, positive) of the toner charge polarity from the electrical potential (i.e., a development potential) of the surface of the developing sleeve. Therefore, when the developing sleeve is supplied again with two-component developer and then faces the image area in the development range, the surface of the developing sleeve on which the charged toner remains has stronger force to move toner to the image area of the photoconductor than the surface on which no toner remains. This increases the amount of toner supplied to the image area of the photoconductor.
By contrast, in a case of the surface of the developing sleeve that faces the image area of the photoconductor in the development range in developing the preceding image, the toner on the developing sleeve moves away from the developing sleeve due to differences in electrical potential between the image area and the developing sleeve. That is, the toner moves to a tip side of the magnetic brush. In the development range, a part of the toner in two-component developer moves to the image area, that is, the electrostatic latent image, and develops it into a toner image. At that time, although some of the toner may remain unused in developing the electrostatic latent image, such toner rarely contacts and adheres to the developing sleeve since the toner is on the tip side of the magnetic brush in the development range. When the carrier moves away from the developing sleeve due to the repulsive magnetic force, most of the toner in two-component developer carried on the developing sleeve moves away from the developing sleeve together with the carrier. Then, almost no toner remains on the surface of the developing sleeve.
Subsequently, when the surface of the developing sleeve reaches the developer supply position, two-component developer is supplied to the surface of the developing sleeve on which almost no toner remains. The electrical potential of the surface of the developing sleeve to which almost no charged toner adheres is not shifted to the side of the toner charge polarity. When the developing sleeve is supplied again with two-component developer and then faces the image area in the development range, the surface of the developing sleeve has weaker force to move toner to the image area than the surface on which toner remains.
Thus, the surface of the developing sleeve that has faced the non-image area in the preceding image exerts stronger force to move toner to the image area of the subsequent image than the surface of the developing sleeve that has faced the image area in the preceding image. Consequently, depending on which area (the non-image area or the image area) the surface of the developing sleeve has faced in the preceding image, the amount of toner that adheres to the image area in the subsequent image differs, and the image density fluctuates. It is conceivable that such image density fluctuations result in ghost images.
When toner contacts the developing sleeve, non-electrostatic adhesion force between toner and carrier, and that between toner and developing sleeve decrease. At that time, when a work function of toner is close to that of the developing sleeve, which of the two (the developing sleeve or carrier) the toner adheres is stochastically determined. Additionally, when the work function of the developing sleeve is greater than that of toner, negative electrical charges of toner that is in contact with the developing sleeve is transferred to the developing sleeve, which is a phenomenon called contact electrification. Accordingly, image force between toner and the developing sleeve becomes weaker, and toner does not leave carrier (or adheres again to carrier).
In developing a white solid image (i.e., a blank image), since the developing sleeve faces the non-image area of the photoconductor in the development range, the developing sleeve is smeared with toner (i.e., the smeary sleeve) after developing the white solid image. Accordingly, the surface of the developing sleeve that has developed the white solid image tends to have a surface potential increased by an amount equivalent to the electrical charge of toner adhering to the developing sleeve and, when used in development, the amount of toner that adheres to the image area of the photoconductor (hereinafter “development amount”) increases, thereby increasing the image density.
By contrast, in developing a solid image (i.e., a black solid image), the development field that causes toner to move to the photoconductor is generated in the development range. Then, during the development, toner having normal electrical charges, out of smear of toner adhering to the developing sleeve, moves toward the photoconductor. Consequently, after developing the solid image, the developing sleeve is not smeared with toner.
When the solid image is continuously developed in this state, the smear of toner adhering to the developing sleeve is removed while the developing sleeve makes one revolution. Accordingly, after the formation of the solid image, the increase in the developing bias equivalent to the smear of toner on the developing sleeve is canceled, and the development amount returns to an ordinal amount (reduced from the increased state by the non-image area). The above-described processes arise in developing the black solid image following the development of the white solid image or in developing the black solid image immediately after an interval between sheets. Accordingly, the image density increases in a distance by which a leading end of the solid image goes round on the circumference of the developing sleeve.
A conceivable approach to inhibit ghost images is to provide a low friction film including, for example, tetrahedral amorphous carbon (ta-C) on the surface of the developing sleeve. The low friction film can inhibit toner from remaining on the developing sleeve, thereby inhibiting the occurrence of ghost images.
In the developing device 5, since the surface of the developing sleeve 51 is coated with the low friction film 51b, the occurrence of ghost images can be suppressed. However, it may be difficult to make the thickness of the low friction film 51b uniform, and it is possible that the low friction film 51b has unevenness in thickness. The thickness unevenness can result in cyclic density unevenness. It is conceivable that the density unevenness is caused as follows.
In
In
In the configurations shown in
At that time, since the negatively charged toner particles T leave the magnetic brush, as in the magnetic brushes on the left in
In two-component development typically used, when the amount of charge of the image area (an exposed portion) on the photoconductor 1 is balanced (in equilibrium) with the amount of charge on the side of the developing sleeve 51 including the counter charges remaining on the magnetic brush, the toner particles T stop moving, and development completes.
However, development can be still feasible if the positive charges equivalent to the counter charges are transferred toward the base pipe 51a as indicated by arrow F shown in
The low friction film 51b made of or including tetrahedral amorphous carbon or the like has an electrical resistance greater than that of the base pipe 51a made of or including metal such as aluminum. Accordingly, as the low friction film 51b becomes thinner, it is easier for the positive charges to move toward the base pipe 51a.
Reference character H in
Such portions H where the amount of toner particles T is insufficient result in light density portions, in which the image density is lighter than in other image areas.
As in the configuration shown in
As an example of the thinner low friction film 51b, when a tetrahedral amorphous carbon (ta-C) layer of about 0.1 μm is used, it takes about 0.7 msec (i.e., a transit time) for the positive charges equivalent to the counter charges to move to the base pipe 51a. This transit time (about 0.7 msec in this example) is not greater than a period of time for a given position on the surface of the developing sleeve 51 to pass through the development range (i.e., a developing nip), which is about 7 msec. Accordingly, while the given position of the developing sleeve 51 passes through the development range, the positive charges equivalent to the counter charges can be transferred to the base pipe 51a, and development becomes feasible for the time equivalent to the positive charges thus transferred. Then, the image area where the amount of the toner particles T adhering thereto is insufficient can be filled with the toner particles T, thus inhibiting generation of the light density portions.
By contrast, as in the configuration shown in
As an example of the thicker low friction film 51b, when a ta-C layer of about 0.6 μm is used, it takes about 70 sec for the positive charges equivalent to the counter charges to move to the base pipe 51a. This transit time (about 70 sec in this example) is greater than a period of time for a given position on the surface of the developing sleeve 51 to pass through the development range (i.e., the developing nip), which is about 7 msec. Accordingly, the transfer of the positive charges equivalent to the counter charges to the base pipe 51a does not complete while the given position of the developing sleeve 51 passes through the development range, and the portion H where the amount of the toner particles T adhering thereto is insufficient results in the light density portion.
As explained above with reference to
It is to be noted that the development gap, which is a clearance between the developing sleeve 51 and the photoconductor 1, may be caused to fluctuate by the unevenness in the layer thickness of the low friction film 51b that is the surface layer of the developing sleeve 51. However, in the developing device 5 according to the present embodiment, the low friction film 51b is a deposition layer in nano order, and the unevenness in the layer thickness is about one tenth of several micrometers (m). Since the development gap is about 0.2 mm (=200 μm), it can be deemed that fluctuations in the development gap resulting from the unevenness in the layer thickness rarely affect the image density unevenness.
In the configuration shown in
The term “saturation development” used here means a state in which the development field generated by the potential difference between the electrostatic latent image on the latent image bearer (i.e., the photoconductor 1) and the opposed electrode (i.e., the developing sleeve 51) is canceled by the toner electrical field, and thus the development field has no potential (0). In other words, it means a state in which the amount of toner adhering to the electrostatic latent image on the photoconductor 1 is sufficient and no more toner adheres thereto by the force of electrical field. If saturation development is difficult, there is a risk that the amount of toner adhering to the electrostatic latent image fluctuates due to changes in the development gap between the photoconductor 1 and the developing sleeve 51, and the image density is likely to fluctuate.
Photoconductors and developing rollers typical have runout tolerances and production tolerances, which cause the development gap to fluctuate, and the development amount fluctuates, thereby making the image density uneven. In particular, in the DC bias development, the toner adhesion amount is more susceptible to fluctuations in the development gap GP than that in the AC bias development. Thus, the image density increases as the development gap GP is reduced in size, and the image density decreases as the development gap GP is widened.
The results shown in
Apparatus used: RICOH Pro C751EX;
Developing device used: Developing device for black;
Percentage of toner in developer: 7%
Developing potential (difference between the developing bias and potential in image portions on the photoconductor): 500 V
According to the results in
The inventors of the present invention have found that development can be closer to saturation development in configurations in which the developing bias includes the AC component or the DC component superimposed with the AC component (i.e., AC bias development).
According to experiments to visualize development phenomena and considerations by the inventors, it is conceivable that the followings contribute to development closer to saturation development.
In two-component development, the carrier particles included in two-component developer carried on the developing sleeve stand on end and form the magnetic brush in the development range. Then, the carrier particles near the end of the magnetic blush contact the surface of the photoconductor. In DC bias development, toner particles that contribute to development are only those adhering to the carrier particles that contact the electrostatic latent image on the photoconductor. In other words, toner particles that are contactless with the surface of the photoconductor do not contribute to development.
By contrast, in AC bias development, the toner particles that contribute to development are not only those adhering to the carrier particles that contact the electrostatic latent image. The toner particles in an intermediate portion of the magnetic brush also leave the carrier particles due to the AC electrical field and contribute to development. Thus, in AC bias development, other toner particles than those in contact with the electrostatic latent image can be supplied to the electrostatic latent image. Accordingly, the developability, which is the amount of toner that contributes to development, is greater, and development closer to saturation development is feasible.
Additionally, the inventors of the present invention have found that, even in the configuration in which the low friction film 51b is provided on the developing sleeve 51, the cyclic image density unevenness corresponding to the thickness unevenness of the low friction film 51b can be suppressed using AC bias development, owing to the followings.
In DC bias development, if saturation development is not attained in the portion where the low friction film 51b is thinner, in the portion where the low friction film 51b is thicker and the developability is reduced, the amount of toner adhering to the image area decreases by an amount corresponding to the reduction in developability. Thus, the image density decreases. By contrast, if saturation development or close thereto is attained in the portion where the low friction film 51b is thinner owing to AC bias development, saturation development or close thereto can be maintained even in the portion where the low friction film 51b is thicker and the developability is reduced. Thus, decreases in image density can be suppressed. Further, even if the developability is reduced to a degree incapable of maintaining saturation development, the decrease in the amount of toner adhering can be made smaller than the reduction in developability, and decreases in image density can be suppressed.
Thus, the cyclic image density unevenness corresponding to the thickness unevenness of the low friction film 51b can be suppressed since decreases in image density in the portion where the low friction film 51b is thicker can be suppressed.
In the developing device 5 according to the present embodiment, since the developing sleeve 51 is provided with the low friction film 51b lower in friction coefficient with toner than the base pipe 51a including or made of, for example, aluminum as shown in
By the way, to balance improvement of dot reproducibility and reduction of fog, an alternating voltage may be applied to the developing sleeve such that a first peak-to-peak voltage alternates with a second peak-to-peak voltage lower than the first peak-to-peak voltage.
[Experiment 4]
Experiment 4 was conducted to ascertain the advantage of use of the DC bias development in the developing device 5K and use of the RP development in other developing devices 5.
Configurations used in experiment 4 include configuration 1 that employs the DC bias development, black developer, and the low friction film; configuration 2 that employs the RP development, cyan developer, and the low friction film; and comparative examples 1 to 6. In these configurations, the occurrence of ghost images (also called “afterimages”) and image density unevenness were evaluated.
In experiment 4, a commercially available digital full-color copier, imagio MP C5000 from Ricoh Co., Ltd, was modified to install a developing device different in development conditions, and images produced thereby were evaluated. As the development conditions, relative to the developing device 5 shown in
(Evaluation of Ghost Images)
Regarding ghost images, after printing a chart having an image area ratio (also called “image coverage ratio”) of 5% on 20 sheets (k sheets), an evaluation image for ghost image evaluation was printed. As the ghost image rating is based on differences in image density between an image (a) corresponding to a first revolution of the developing sleeve 51 and an image (b) corresponding to a subsequent revolution of the developing sleeve 51. Specifically, differences in image density between the image (a) and the image (b) were measured using an X-Rite densitometer (X-Rite 939), and a mean density difference ΔID of three positions (b1-a1, b2-a2, and b3-a3) was rated in the following four ratings of “excellent”, “good”, “acceptable”, and “poor”. The rating of “poor” is not acceptable and deemed failure.
Excellent: ΔID≦0.01,
Good: 0.01<ΔID≦0.03,
Acceptable: 0.03<ΔID≦0.06, and
Poor: ΔID>0.06
According to the above-described evaluation method, ghost image evaluation was made.
<Image Density Unevenness Evaluation>
An A3-size single color (cyan) image having an image area ratio of 75% was printed, and lightness deviation (highest lightness−lowest lightness) within the image was measured using the X-Rite densitometer (X-Rite 939). As ratings of image density unevenness, the lightness deviation less than 2.0 was rated “good” (no problem), and the lightness deviation equal to or greater than 2.0 was results was rated “poor” (image density was uneven).
It is to be noted that the apparatus used in experiment 4 is a modification of Ricoh imagio MP C5000 and common to configurations 1 and 2 and comparative examples 1 through 6. Black developer was used in configuration 1 and comparative examples 1 to 3, and cyan developer was used in configuration 2 and comparative examples 4 to 6.
In comparative example 1, the DC developing bias was applied to an aluminum developing sleeve without the low friction film 51b. That is, the developing bias included only the DC component.
Conditions of comparative example 1 are as follows.
Developing sleeve: Aluminum sleeve; and
Developing bias: DC developing bias
In comparative example 1, an aluminum developing sleeve without the low friction film 51b was used, and the AC developing bias, in which the AC component was superimposed on the DC component, was applied to the developing sleeve.
Conditions of comparative example 2 are as follows.
Developing sleeve: Aluminum sleeve; and
Developing bias: AC developing bias
The term “positive-side duty ratio” means a ratio of a positive side component in a single cycle of a developing bias that includes an AC component fluctuating cyclically. In other words, it is a ratio of time during which the developing bias is on the positive side from the DC component of −230 V in one cycle period of fluctuations in the developing bias.
In comparative example 3, an aluminum developing sleeve coated with ta-C was used, and the AC developing bias, in which the AC component was superimposed on the DC component, was applied to the developing sleeve. That is, the developing sleeve 51 including the low friction film 51b was used in the AC bias development.
Conditions of comparative example 3 are as follows.
Developing sleeve: Aluminum sleeve coated with ta-C (0.6 μm with deviation of 0.3 μm) and
Developing bias: AC developing bias
(Configuration 1)
In configuration 1, the developing sleeve 51 including the base pipe 51a and the low friction film 51b (with ta-C coating) was used, and the DC developing bias was applied to the developing sleeve 51.
Conditions of configuration 1 are as follows.
Developing sleeve: Aluminum sleeve coated with ta-C (0.6 μm with deviation of 0.3 μm); and
Developing bias: DC developing bias
In comparative example 4, the DC developing bias was applied to an aluminum developing sleeve without the low friction film 51b. That is, the developing bias included the DC component only.
Conditions of comparative example 1 are as follows.
Developing sleeve: Aluminum sleeve; and
Developing bias: DC developing bias
In comparative example 5, an aluminum developing sleeve without the low friction film 51b was used, and the AC developing bias, in which the AC component was superimposed on the DC component, was applied to the developing sleeve.
Conditions of comparative example 5 are as follows.
Developing sleeve: Aluminum sleeve; and
Developing bias: AC developing bias
In comparative example 6, the developing sleeve 51 including the base pipe 51a and the low friction film 51b (ta-C coating) was used, and the DC developing bias was applied to the developing sleeve 51.
Conditions of configuration 6 are as follows.
Developing sleeve: Aluminum sleeve coated with ta-C (0.6 μm with deviation of 0.3 μm); and
Developing bias: DC developing bias
(Configuration 2)
In configuration 2, an aluminum developing sleeve coated with ta-C was used, and the AC developing bias, in which the AC component was superimposed on the DC component, was applied to the developing sleeve. That is, the developing sleeve 51 including the low friction film 51b was used in the AC bias development.
Conditions of configuration 2 are as follows.
Developer: Cyan developer;
Developing sleeve: Aluminum sleeve coated with ta-C (0.6 μM with deviation of 0.3 μm); and
Developing bias: AC developing bias
Tables 1 and 2 show the results of experiment 4. It is to be noted that, in the columns of image density unevenness and graininess in Tables 1 and 2, parenthesize numerals represent the ratings. Additionally, in Tables 1 and 2, configurations 1 and 2 are represented by “E1” and “E2”, and comparative examples 2 through 6 are represented by “C1” through “C6”, respectively.
According to Table 2, in the developing device 5C for cyan, ghost images, image density unevenness, and graininess are alleviated by providing the low friction film 51b on the developing sleeve 51 and applying the AC developing bias to the developing sleeve 51. Additionally, according to Table 1, in the developing device 5K for black, ghost images are inhibited, and image density unevenness and graininess are suppressed by providing the low friction film 51b on the developing sleeve 51 and applying the DC developing bias to the developing sleeve 51.
[Experiment 5]
Descriptions are given below of experiment 5 executed to confirm the relation between fluctuations in the low friction film 51b and fluctuations in image density under conditions of comparative example 6 and configuration 2 described above.
The evaluation results of comparative example 2 shown in
Causes of the above include the followings.
In the DC bias development using the DC developing bias, differences in thickness of the ta-C coating layer generate a portion (the low friction film 51b is thinner) where it is easy for the counter charges to escape and a portion (the low friction film 51b is thicker) where it is difficult. This is a conceivable reason why the thickness unevenness of the low friction film 51b makes the image density uneven.
By contrast, applying the AC developing bias can facilitate escape of the counter charges generated on the carrier, and development can be closer to saturation development than in DC bias development. Therefore, the thickness unevenness of the low friction film 51b is less likely to result in image density unevenness.
In the case of the AC developing bias, even when the resistance of developer or that of the developing roller is high, the electrical charges can easily move since a large electrical field is instantaneously acts thereon, compared with DC bias development. Thus, escape of the counter charges is facilitated. The following can be a cause why the AC developing bias can make development closer to saturation development. As described above with reference to
An approach to inhibit image density unevenness, resulting from the thickness unevenness of the low friction film 51b, may be reduction in the thickness unevenness of the low friction film 51b itself. However, in an approach to reduce the thickness unevenness of the low friction film 51b to a degree capable of sufficiently inhibiting image density unevenness, yields decrease and the cost increases. Thus, it is not desirable.
<Formation of the Low Friction Film 51b>
As shown in
The friction coefficient of the surface of the developing sleeve 51 can be lowered in the follow manner.
In the present embodiment, the low friction film 51b includes or is made of a ta-C film on the base pipe 51a, and the ta-C film is produced through filtered cathodic vacuum arc (FCVA).
As a brief description of formation of the ta-C film, put high purity carbon (graphite), as a target, in a substantially vacuum chamber, and subject the target to arc discharge. Using electromagnetic induction, guide plasma generated by the arc discharge to the base pipe 51a of the developing sleeve 51. During the electromagnetic induction, remove substances, such as macro particles, neutral atoms, molecules, and the like that are unnecessary for deposition by an electromagnetic spatial filter and extract ionized carbon only. Then, the ionized carbon that reaches the surface of the base material coagulates into a ta-C film.
Through the above-described processes, the low friction film 51b made of the ta-C film is formed on the base pipe 51a.
The low friction film 51b made of the ta-C film can be more uniform in thickness than films formed through plating or application. Further, since formable at a relatively low temperature, the ta-C film is less likely to be distorted by the temperature of the developing sleeve 51. Accordingly, the accuracy in shape of the developing sleeve 51 can be enhanced.
It is to be noted that, since deposition using FCVA is described in, for example, US patent publication No. 6,031,239(A) and widely used in practice, detailed descriptions thereof are omitted.
Alternatively, the low friction film 51b on the base pipe 51a may be made of or include a TiN film by hollow cathode discharge (HCD).
Through ion plating, which is a type of physical vapor deposition (PVD), a film that excels in adhesion can be produced relatively easily. Among ion plating methods, HCD is particularly advantageous in producing a coating that is homogeneous and uniform in thickness along a surface roughness of a base material.
It is to be noted that, since deposition using HCD is described in, for example, Japanese patent publication Nos. JP-H10-012431-A and JP-H08-286516-A and widely used in practice, detailed descriptions thereof are omitted.
The low friction film 51b, which is the surface layer of the developing sleeve 51, is a thin coating of a material, such as tetrahedral amorphous carbon (ta-C), titanium nitride (TiN), or the like, that is lower in friction coefficient with toner than the base pipe 51a.
Needless to say, as long as lower in friction coefficient with toner than the base pipe 51a and agreeable with effects of this specification, the material of the low friction film 51b is not limited to ta-C and TiN but can be other materials such as titanium carbide (TiC), titanium carbonitride (TiCN), molybdic acid, or the like.
It is to be noted that, according to the measurement of friction coefficient (with paper belt) described below, the friction coefficient of aluminum alloy is about 0.5 or greater, that of TiN is about 0.3 to 0.4, that of ta-C is about 0.1 or smaller.
<Measurement of Friction Coefficient>
The friction coefficients of the surfaces of the developing sleeve 51 coated with the low friction film 51b and the developing sleeve without the low friction film 51b were measured using Euler's belt theory.
The measuring device shown in
In this configuration, while the force gauge 901 was pulled by the weight 903, a reading of load when the paper belt 902 moved was assigned in a formula of friction coefficient shown below:
μs=2/π×ln(F/0.98)
wherein μ represents a stationary friction coefficient and F represents a measured value.
Ghost images can arise as follows. While the surface of the developing sleeve 51 passes through the development range, a greater amount of toner adheres to a surface that has faced a non-image area on the photoconductor 1 than a surface that has faced an image area on the photoconductor 1. Since the toner adhering to the developing sleeve 51 has electrical charges, when the surface of the developing sleeve 51 bearing toner again reaches the development range and performs image development, the development potential is increased by the charge amount of toner present on the surface of the developing sleeve 51. As the amount of toner adhering increases, the increase in charge amount increases, and the development amount increases. Accordingly, the development amount is greater in the portion developed by the surface of the developing sleeve 51 that has faced the non-image area in the preceding image, thus resulting in a ghost image.
By contrast, in the developing device 5 according to the present embodiment, the occurrence of ghost images can be suppressed by providing the low friction film 51b on the surface of the developing sleeve 51. With the developing sleeve 51 coated with the low friction film 51b, the adhesion force between toner and carrier can be greater than that between toner and the developing sleeve 51, and accordingly the amount of toner adhering to the developing sleeve 51 decreases. This can suppress the increase in surface potential of the developing sleeve 51 caused by the toner adhering thereto and accordingly inhibit the occurrence of ghost images.
The various aspects of the present specification can attain specific effects as follows.
Aspect A: A developing device includes a developer bearer, such as the developing roller 50, to carry, by rotation, developer including toner and magnetic carrier to a development range facing a latent image bearer, such as the photoconductor 1, and to supply the developer to a latent image on the latent image bearer. The developer bearer includes a magnetic field generator, such as the magnet roller 55, having multiple magnetic poles and a cylindrical developing sleeve, such as the developing sleeve 51, to contain the magnetic field generator, bear developer on an outer circumferential face thereof with magnetic force of the magnetic field generator, and rotate relative to a body of the device. The developing device is further provided with a voltage application device, such as the power source 151, to apply a developing bias to the developing sleeve. The voltage application device applies, to the developing sleeve, a voltage including an AC component having a frequency of about 2.0 kHz or lower, and, a duty ratio of an opposite polarity component, a polarity of which is opposite the toner normal charge polarity, of the development voltage is within a range from about 4% to about 20%.
According to aspect A, as described in the embodiment, compared with the DC bias development, the AC bias development is effective in reducing fluctuations in the amount of toner adhering to the latent image bearer. Accordingly, fluctuations in image density are reduced. Additionally, in the AC bias development in which the frequency is higher and the duty ratio of the opposite polarity component (opposite the toner normal charge polarity) is higher, the void at density boundaries is alleviated better than the DC bias development. By contrast, in the AC bias development in which the frequency is lower and the duty ratio of the opposite polarity component (opposite the toner normal charge polarity) is lower, the void at density boundaries is alleviated to a level similar to that attained by the DC bias without sacrificing the effect to reduce the density fluctuation. Specifically, the AC bias development in which the frequency is about 2.0 kHz or lower is advantageous in alleviating the void at density boundaries over the AC bias development in which the frequency is higher than 2.0 kHz. Although the graininess is degraded in the AC bias development in which the frequency is lower and the duty ratio of the opposite polarity component is higher, the degradation of graininess is inhibited in the AC bias development in which the frequency is lower and the duty ratio of the opposite polarity component is lower. Specifically, although the granularity tends to be degraded when the frequency is relatively low, the degradation of granularity is limited by reducing the time during which the potential difference to draw back toner to the developing sleeve is applied. Then, image formation is reliable without image failure.
Thus, according to aspect A, while the cyclic density fluctuation is inhibited, the occurrence of void at density boundaries and degradation of granularity are suppressed.
Aspect B: In aspect A, in the development voltage such as the developing bias, the difference between the largest value and the smallest value in the direction of the toner normal charge polarity is about 1500 V or smaller.
According to this aspect, background stains, which means the adhesion of toner to non-image areas, are inhibited as described above.
Aspect C: In aspect A or B, the developing sleeve includes a low friction surface layer, such as the low friction film 51b, made of a material lower in friction coefficient with toner than a material of a base, such as the base pipe 51a, that maintains the cylindrical shape of the developing sleeve.
As described above, providing the low friction surface layer can inhibit adhesion of toner to the developing sleeve. Accordingly, this configuration can inhibit the occurrence of ghost images resulting from the smeary sleeve. Additionally, the inventors have found that, compared with application of voltage including the DC component only, application of the voltage including the AC component can better inhibit fluctuations in developability caused by thickness unevenness of the low friction surface layer. Thus, this configuration can inhibit the occurrence of cyclic image density unevenness corresponding to the thickness unevenness of the low friction surface layer. Thus, aspect C can inhibit the occurrence of cyclic image density unevenness while inhibiting the occurrence of ghost images.
Aspect D: In aspect C, the low friction surface layer such as the low friction film 51b includes or is made of tetrahedral amorphous carbon.
With this configuration, as described above in the descriptions of embodiments, the developing sleeve includes the low friction surface layer.
Aspect E: In any of aspects A through D, the outer circumferential surface of the developing sleeve and the surface of the latent image bearer (such as the photoconductor 1) move in an identical direction in the development range, and the linear velocity ratio therebetween is expressed as 1.3≦Vs/Vg≦1.8, wherein Vs represents the surface movement speed of the developing sleeve and Vg represents the surface movement speed of the latent image bearer.
According to this aspect, as described above, degradation of granularity is inhibited, thereby attaining reliable image formation with image failure suppressed.
Aspect F: An image forming apparatus, such as the image forming apparatus 500 shown in
This configuration can inhibit the cyclic image density unevenness, the occurrence of void at density boundaries, and degradation of granularity and accordingly attain reliable image formation.
Aspect G: In aspect F, the image forming apparatus includes a black developing device (such as the developing device 5K) and a color developing device (such as the developing device 5C) for color other than black, the developing device according to any one of aspects A through E is used to as the color developing device, and the black developing device is different in configuration from the color developing device.
According to aspect G, in the color developing device, as described above, the occurrence of void at density boundaries and degradation of granularity are inhibited while inhibiting the cyclic image density unevenness. Accordingly, image formation can be reliable. Image density unevenness is less recognizable in black images. Accordingly, the black developing device uses development type, such as DC bias development, that is effective in suppressing the degradation of granularity through less effective in inhibiting image density unevenness to alleviate the void at density boundaries and granularity while alleviating the cyclic density fluctuation. With this configuration, since the occurrence of void at density boundaries and degradation of granularity are alleviated while alleviating the cyclic image density unevenness in both of the color developing device and the black developing device, multicolor images are formed reliably.
Aspect H: A process cartridge, such as the image forming unit 6, removably installed in an image forming apparatus, includes at least the latent image bearer, the developing device according to any of aspects A through E, and a common unit casing to house those components.
This configuration can inhibit the cyclic image density unevenness, the occurrence of void at density boundaries, and degradation of granularity and further facilitate replacement of the developing device. Additionally, in image forming apparatuses including multiple process cartridges that are independently replaceable, only the process cartridge that requires replacement is replaced. This configuration is effective in providing reliable images at a reduced cost for users.
Numerous additional modifications and variations are possible in light of the above teachings. It is therefore to be understood that, within the scope of the appended claims, the disclosure of this patent specification may be practiced otherwise than as specifically described herein.
Number | Date | Country | Kind |
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2014-023607 | Feb 2014 | JP | national |