This patent application is based on and claims priority pursuant to 35 U.S.C. §119(a) to Japanese Patent Application Nos. 2014-022635 filed on Feb. 7, 2014, 2014-084292 filed on Apr. 16, 2014, and 2014-132987 filed on Jun. 27, 2014, in the Japan Patent Office, the entire disclosure of each of which is hereby incorporated by reference herein.
1. Technical Field
Embodiments of the present invention generally relate to an image forming apparatus, such as a copier, a printer, a facsimile machine, and a multifunction peripheral (MFP) having at least two of copying, printing, facsimile transmission, plotting, and scanning capabilities.
2. Description of the Related Art
There are image forming apparatuses that superimpose multiple toner images of chromatic colors, such as yellow, magenta, cyan, and black images one on another on a sheet of recording media and fix the superimposed images using a fixing device, thereby obtaining a multicolor toner image. These chromatic color toners are hereinafter referred to as process color toners (i.e., yellow, cyan, magenta, and black).
Currently, image quality is diversified, and use of special toners other than process color toners, such as white toner and transparent toner, is proposed to attain value-added printing that is not attainable with process color toners.
When transparent toner having a high gloss level is superimposed on color images partly or entirely and fixed thereon, the gloss level of color images are enhanced.
In such image forming apparatuses, respective color toner images are formed on latent image bearers in respective image forming units. After the toner images are transferred from the latent image bearers onto a transfer medium such as recording paper or an intermediate transfer member, a cleaning device collects toner remaining thereon. The toner thus collected is transported, as waste toner, through a waste-toner channel and discharged from the cleaning device by a rotatable conveying screw. The waste toner is then collected in a waste-toner container inside the image forming apparatus and may be reused.
An embodiment of the present invention provides an image forming apparatus that includes a controller and multiple image forming units. Each image forming unit includes an image bearer, a toner image forming device to form a toner image on the image bearer, a transfer device to transfer the toner image from the image bearer onto a transfer medium, a cleaning device to remove toner from a surface of the image bearer, a waste-toner tube through which toner removed by the cleaning device is transported, and a toner conveying member to transport toner by rotation and disposed inside the waste-toner tube. The controller changes a rotation speed of the toner conveying member for each of the multiple image forming units according to toner type including a first toner and a second toner having poorer flow properties than the first toner, and at least one image forming units uses the second toner and the remaining image forming units use the first toner.
Another embodiment provides an image forming apparatus that includes a controller and multiple image forming units. Each image forming unit includes the image bearer, the toner image forming device, the transfer device, the cleaning device, the waste-toner tube, and the toner conveying member described above. The cleaning device further includes a lubricant application roller to apply lubricant onto the surface of the image bearer and a driving source to drive both of the lubricant applicator and the toner conveying member. At least one of the multiple image forming units uses second toner having poorer flow properties than the first toner used in the remaining multiple image forming units. The controller sets a rotation speed of the driving source of the cleaning device of the image forming unit using the second toner to an increased rotation speed from a rotation speed of the driving source of the cleaning device of the image forming unit using the first toner.
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 types of toner used in image forming apparatuses include pulverized toner, which is produced by mechanical pulverization and irregular in shape, and polymerization toner, which is produced by polymerization and spherical in shape.
Compared with pulverized toner particles, polymerization toner particles are more uniform and spherical in shape. Reduction in particle diameter of polymerization toner is easier, and use of polymerization toner improves image quality. By contrast, irregular pulverized toner is more easily caught by a cleaning blade or the like of a cleaning device than polymerization toner, thus facilitating cleaning.
Therefore, use of polymerization toner for process color toners is advantageous in enhancing image quality, and use of pulverized toner for transparent toner, which less affects image quality, is advantageous in improving cleaning performance.
Polymerization toner and pulverized toner have different flow properties, that is, ease of transport by a conveying member such as a screw, auger, coil, or a paddle.
It is to be noted that, in this specification, the term “flow properties of toner” means ease of transport of toner by a toner conveying member, and differences in flow properties are represented by differences in the weight of toner transported per unit time under similar conditions (i.e., screw rotation speed and the like). When toner particles are circular in shape and smaller in diameter, flow properties of toner are better. Toner including an additive, such as silica, has better flow properties than toner base particles without additives.
In general, polymerization toner has better flow properties and pulverized toner has poorer flow properties. Therefore, the following inconveniences arise when a common structure is used, for example, for cost reduction, in the image forming unit using polymerization toner and that using pulverized toner.
In the image forming unit using pulverized toner, which has poorer flow properties, the amount per unit time of toner discharged from the cleaning device through a waste-toner channel by a conveying screw is smaller, and the possibility of clogging of the waste-toner channel increases. In particular, when pulverized toner is used as transparent toner, which is typically used in a larger image area ratio than that of process color toner, the possibility of clogging is high.
By contrast, in the image forming unit using polymerization toner, which has better flow properties, the amount per unit time of toner discharged from the cleaning device through the waste-toner channel by the conveying screw is greater, and it is possible that the transport capability of the conveying screw is excessive. As a result, the conveying screw receives an excessive load, and an operational life thereof is reduced.
It is to be noted that special toners are not limited to transparent toner. For example, white toner may be used. White toner is typically used to coat colored paper or transparent film entirely. Accordingly, the possibility of image failure such as line-like stains is lower compared with process color toners, which are used in various image densities.
Therefore, white toner does not require high image quality required for process color toners, and use of pulverized toner is advantageous in improving cleaning performance. Similar inconveniences arise when polymerization toner is used for process color toner and pulverized toner is used for white toner.
Although it is stated above that pulverized toner having poorer flow properties is used for special toner, such as transparent toner and white toner, which requires image quality lower than that of process color toner, it is possible that toner whose flow properties are better than that of process color toner is used. In such cases, similar inconveniences occur.
Referring now to the drawings, wherein like reference numerals designate identical or corresponding parts throughout the several views thereof, and particularly to
An image forming apparatus 1 shown in
The image forming apparatus 1 includes a controller 800 (such as a processor), which in one embodiment includes 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
The image forming engine 3 includes the image forming units 10Y, 10C, 10M, and 10K respectively corresponding to colored toner, namely, yellow (Y), cyan (C), magenta (M), and black (K) toners, and further includes the image forming unit 10S corresponding to transparent toner (S), which may be called “clear toner”. The image forming units 10Y, 10C, 10M, 10K, and 10S are arranged substantially horizontally, and thus the image forming apparatus 1 has a tandem structure. The image forming units 10Y, 10C, 10M, 10K, and 10S are similar in structure except the color of toner used therein.
It is to be noted that the suffixes S, 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.
When toner images of yellow, cyan, magenta, and black are covered with transparent toner, the transparent toner serves as an overcoat to protect the toner images. Additionally, a pattern of transparent toner on a smooth sheet gives a texture like special paper or fancy paper.
It is to be noted that the order of image formation using transparent toner and colored toner is not limited to the description above.
In another embodiment, white toner is used instead of transparent toner. For example, when white toner is used instead of transparent toner, a color image is formed on a transparent sheet of recording media, using at least one of process color toners (e.g., yellow, cyan, magenta, and black toners). Then, a white toner image is formed on the color toner image. With the white color image, when the color toner image is viewed from a backside of the transparent sheet opposite an image side on which the color toner image is formed, the color toner image is not shown through the transparent sheet. Additionally, the transparent recording medium increases the gloss level, thus producing printing with uniform gloss level and added values.
An exposure device 4 disposed above the image forming units 10S, 10Y, 10C, 10M, and 10K exposes surfaces of photoconductors 11S, 11Y, 11C, 11M, and 11K with exposure light such as laser beams according to respective color image data, thereby forming latent images thereon. Thus, the exposure device 4 serves as a latent image forming device.
A transfer device 60 disposed beneath the image forming units 10 includes the endless intermediate transfer belt 61 that rotates in a state looped around a driving roller 651, a tension roller 652, an outer roller 653, and the like.
It is to be noted that reference numeral 203 represents a temperature and humidity sensor that serves as a humidity detector.
The image forming unit 10 includes the photoconductor 11 serving as an image bearer, a charging roller 22 serving as a charging device to charge the surface of the photoconductor 11, and a developing device 30. The charged surface of the photoconductor 11 is irradiated with laser light L by the exposure device 4, and the developing device 30 supplies toner to the latent image on the photoconductor 11, thus developing the latent image into a toner image. The charging roller 22 and the developing device 30 serve as a toner image forming device.
Each image forming unit 10 further includes a cleaning device 40 to remove toner remaining on the photoconductor 11 after the toner image developed by the developing devices 30 is transferred by a primary-transfer roller 62 onto the intermediate transfer belt 61.
The charging roller 22 is electrically connected to a power source that applies a predetermined or a desirable charging bias to the charging roller 22. The charging roller 22 is disposed across a minute gap from the photoconductor 11. In another embodiment, the charging roller 22 is disposed in contact with the photoconductor 11.
The developing device 30 employs two-component developer including magnetic carrier and toner (hereinafter simply “developer”). The developing device 30 is disposed facing the photoconductor 11 to develop the latent image thereon.
The developing device 30 includes a developing roller 31 serving as a developer bearer. The developing roller 31 transports developer to a position facing the photoconductor 11 after a developer regulator adjusts the thickness of a layer of developer on the developing roller 31.
The cleaning device 40 includes a discharge lamp to discharge the photoconductor 11 before cleaned, a cleaning brush roller 42 (a rotatable brush), a cleaning blade 43, an application roller 51, and a leveling blade 53, which are disposed in that order in the direction of rotation of the photoconductor 11 indicated by arrow Y2 in
In the cleaning device 40, the cleaning brush roller 42 and the cleaning blade 43 together serve as a toner remover. The application roller 51 and a solid lubricant 50 held by a bracket and pressed by a pressure spring 52 to the application roller 51 together serve as a lubricating mechanism.
After the toner image is transferred therefrom at a primary-transfer position, where the photoconductor 11 faces the primary-transfer roller 62, the surface of the photoconductor 11 is discharged by the discharge lamp. Then, the cleaning brush roller 42 scrapes toner remaining thereon (i.e., untransferred toner), which facilitates removal of toner by the cleaning blade 43 situated downstream from the cleaning brush roller 42 in the direction of rotation of the photoconductor 11.
The cleaning device 40 further includes a flicker to flick off toner from the cleaning brush roller 42 and a toner outlet 41. The toner is transported through a waste-toner conveying pipe 44, in which a conveying screw 16 is disposed, and discharged as waste toner from the cleaning device 40. The waste toner discharged from the cleaning device 40 is transported by a waste-toner conveyance device 90 to a waste-toner container 100 and stored therein. The waste-toner conveying pipe 44 (i.e., a waste-toner tube) that is a hollow member through which toner removed by the cleaning device 40 is transported.
In the configuration shown in
The cleaning brush roller 42 rotates in the direction indicated by arrow Y4, which follows the direction of rotation of the photoconductor 11. That is, at the position where the cleaning brush roller 42 faces the photoconductor 11, the cleaning brush roller 42 and the photoconductor 11 rotate in an identical direction. The cleaning blade 43 is secured to a rotatable holder and held to contact the surface of the photoconductor 11 in a direction counter to the direction of rotation of the photoconductor 11.
Additionally, the cleaning blade 43 is pressed by a pressure spring against the photoconductor 11 to remove toner from the photoconductor 11.
After toner is removed therefrom, the photoconductor 11 is lubricated by the application roller 51. In the present embodiment, zinc stearate, boron nitride, and alumina are mixed and compressed into the solid lubricant 50.
The application roller 51 scrapes away powdered lubricant from the solid lubricant 50, which is held by the bracket and pressed by the pressure spring 52 to the application roller 51, and the application roller 51 applies the powdered lubricant onto the surface of the photoconductor 11.
The application roller 51 rotates in the direction indicated by arrow Y3, which is opposite the direction of rotation of the photoconductor 11 at the position where the application roller 51 faces the photoconductor 11. The leveling blade 53 is supported to contact the surface of the photoconductor 11 in the direction counter to the direction of rotation of the photoconductor 11. The leveling blade 53 levels off the powdered lubricant applied to the surface of the photoconductor 11 by the application roller 51.
It is to be noted that, as shown in
The transfer device 60 includes the endless intermediate transfer belt 61 that rotates, looped around the driving roller 651, the tension roller 652, and the outer roller 653. The transfer device 60 further includes the primary-transfer rollers 62 to primarily transfer the toner images from the respective photoconductors 11 onto the intermediate transfer belt 61 and a secondary-transfer roller 63 to transfer the toner image from the intermediate transfer belt 61 onto the recording sheet 6.
The primary-transfer rollers 62 are disposed facing the respective photoconductors 11 across the intermediate transfer belt 61. Each primary-transfer roller 62 is electrically connected to a power source and receives a predetermined primary-transfer bias.
The secondary-transfer roller 63 secondarily transfers the toner image from the intermediate transfer belt 61 onto the recording sheet 6 (i.e., a secondary-transfer process). The secondary-transfer roller 63 is opposed to a roller 631 and electrically connected to a power source and receives a predetermined secondary-transfer bias similar to the primary-transfer rollers 62.
Additionally, a belt cleaning device 64 is provided to clean the surface of the intermediate transfer belt 61 after the secondary-transfer process. The image forming apparatus 1 further includes a lubrication device to lubricate the intermediate transfer belt 61.
The image forming apparatus 1 according the present embodiment further includes a contact/separation mechanism to position the photoconductors 11 adjacent to and away from the intermediate transfer belt 61. The contact/separation mechanism in the present embodiment moves away, from the corresponding photoconductor 11, the primary-transfer roller 62 that supports the intermediate transfer belt 61 from an inner circumferential side.
On the left of the transfer device 60 in
Image forming operation of the image forming apparatus 1 in the present embodiment is described below.
According to the image formation type, the contact/separation mechanism positions the photoconductor 11 of each image forming unit 10 used in image formation adjacent to the intermediate transfer belt 61 and moves that of the image forming unit 10 not used away from the intermediate transfer belt 61.
The photoconductor 11 in contact with the intermediate transfer belt 61 rotates counterclockwise in the drawing, driven by a driving unit. The charging roller 22 uniformly charges, to a predetermined polarity, the surface of the photoconductor 11 that rotates. The exposure device 4 directs the laser beam to the surface of the photoconductor 11 thus charged to form an electrostatic latent image thereon. The developing devices 30 supply the corresponding color toners to the electrostatic latent image, thereby developing it into a toner image.
As the photoconductors 11 rotate, the intermediate transfer belt 61 rotate clockwise in
After the toner image is transferred therefrom, toner remaining on the surface of the photoconductor 11 is collected by the cleaning device 40 and transported to the waste-toner container 100 by the waste-toner conveyance device 90 described later.
Meanwhile, the recording sheet 6 is fed from a sheet feeding tray 81 and forwarded by registration rollers 84 to a secondary-transfer position, timed to coincide with the toner image on the intermediate transfer belt 61. With actions of the secondary-transfer roller 63, the toner image is secondarily transferred from the intermediate transfer belt 61 onto the recording sheet 6.
Although the configuration shown in
After the secondary-transfer process, the recording sheet 6 is transported to the fixing device 70. While the recording sheet 6 passes through the fixing device 70, the toner image is fixed thereon with heat and pressure. After the toner image is fixed thereon, the recording sheet 6 is discharged to a paper ejection tray.
The image forming apparatus 1 according to the present embodiment is capable of four different operations (modes) of full-color image formation, monochrome image formation, special image formation, and a combined formation of full-color image and special image.
Full-color image formation is to form full-color images using yellow, magenta, cyan, and magenta toners.
In full-color image formation, the contact/separation mechanism positions the primary-transfer rollers 62Y, 62C, and 62M adjacent to the photoconductors 11Y, 11C, and 11M so that the intermediate transfer belt 61 contacts the photoconductors 11Y, 11C, and 11M.
By contrast, the image forming units 105 and 10K are not used in full-color image formation according to the present embodiment, and the contact/separation mechanism positions the primary-transfer rollers 625 and 62K away from the photoconductors 115 and 11K.
Then, the intermediate transfer belt 61 is stretched flat in a portion between the tension roller 652 and the primary-transfer roller 62Y respectively downstream and upstream from the primary-transfer roller 62S in the direction indicated by arrow Y1 in
The intermediate transfer belt 61 becomes flat similarly in a portion stretched between the primary-transfer roller 62M and the driving roller 651 respectively downstream and upstream from the primary-transfer roller 62K in the belt conveyance direction Y1, and the intermediate transfer belt 61 is disengaged from the photoconductor 11K.
It is to be noted that, in full-color image formation according to another embodiment, black toner is used in addition to yellow, cyan, and magenta toners. In this case, the contact/separation mechanism positions the primary-transfer rollers 62Y, 62C, 62M, and 62K adjacent to the photoconductors 11Y, 11C, 11M, and 11K so that the intermediate transfer belt 61 contacts the photoconductors 11Y, 11C, 11M, and 11K.
By contrast, the image forming unit 10S is not used in full-color image formation, and the contact/separation mechanism positions the primary-transfer roller 62S away from the photoconductor 11S, thereby disengaging the intermediate transfer belt 61 from the photoconductor 11S.
Monochrome image formation is to form images using black toner. In monochrome image formation, the primary-transfer roller 62K is positioned adjacent to the photoconductor 11K so that the intermediate transfer belt 61 contacts the photoconductor 11K.
By contrast, the image forming units 10S, 10Y, 10C, and 10M are not used in monochrome image formation, and the contact/separation mechanism positions the primary-transfer rollers 62S, 62Y, 62C, and 62M away from the corresponding photoconductors 11.
Then, the intermediate transfer belt 61 is stretched flat in a portion between the tension roller 652, downstream from the primary-transfer roller 62S in the direction indicated by arrow Y1 in
Special image formation is to form images using special toner. In special image formation, the primary-transfer roller 62S is positioned adjacent to the photoconductor 11S so that the intermediate transfer belt 61 contacts the photoconductor 11S.
By contrast, the image forming units 10Y, 10C, 10M, and 10K are not used in special image formation, and the primary-transfer rollers 62Y, 62C, 62M, and 62K are positioned away from the corresponding photoconductors 11.
Then, the intermediate transfer belt 61 is stretched flat in a portion between the primary-transfer roller 62S and the driving roller 651 upstream from the primary-transfer roller 62K in the direction indicated by arrow Y1 in
Combined formation of full-color image and special image is to form images using all of the image forming units 10S, 10Y, 10C, 10M, and 10K. In combined formation of full-color image and special image, the contact/separation mechanism positions the primary-transfer rollers 62S, 62Y, 62C, 62M, and 62K adjacent to the photoconductors 11S, 11Y, 11C, 11M, and 11K so that the intermediate transfer belt 61 contacts the photoconductors 11S, 11Y, 11C, 11M, and 11K.
Next, transport of waste toner is described below.
In the present embodiment, waste toner, such as untransferred toner collected by the cleaning device 40, is discharged through the toner outlet 41 of the cleaning device 40.
Then, the waste-toner conveyance device 90 transports the waste toner to a waste-toner container 100.
The waste-toner conveyance device 90 includes a common conveying pipe 91 common to the respective toners. The common conveying pipe 91 is linear and extends substantially horizontally, adjacent to the respective cleaning devices 40. The waste-toner container 100 collects waste toner discharged from the respective cleaning devices 40 to the common conveying pipe 91 via communicating pipes 94 connecting the common conveying pipe 91 with the toner outlets 41 (waste-toner conveying pipe 44) of the respective cleaning devices 40. Each of the communicating pipes 94 serves as a downstream conveyance tube.
The common conveying pipe 91 serves as a downstream conveyance tube to define a common conveyance channel through which toner is transported. The tubular member may be a tube or the like. A conveying screw 92 provided inside the conveying pipe serves as a rotatable developer conveyor to transport waste toner in a direction of rotation axis thereof (hereinafter “axial direction”).
As a driving motor 92a rotates the conveying screw 92, the waste toner inside the common conveying pipe 91 is transported linearly in the axial direction thereof inside the common conveying pipe 91.
The conveying screw 92 includes a rotation shaft and a screw blade provided on the rotation shaft. An outer end of the screw blade is positioned across a small gap from an inner face of the common conveying pipe 91 (i.e., an inner wall of the conveying pipe).
An exit 91E of the common conveying pipe 91 is in a bottom of the common conveying pipe 91 and positioned between a portion connected to the communicating pipe 94M for magenta toner and a portion connected to the communicating pipe 94C for cyan toner.
The conveying screw 92 in the common conveying pipe 91 includes screw blade portions different in winding directions so that the waste toner inside the common conveying pipe 91 is transported in the opposite directions to the exit 91E from both sides.
Specifically, in
With this configuration, by rotating the conveying screw 92 in a predetermined direction, the waste toner inside the common conveying pipe 91 is transported to the exit 91E positioned midway through the common conveying pipe 91. Then, waste toner falls from the exit 91E to a vertical conveyance channel 93.
A lower end of the vertical conveyance channel 93 communicates with an upper face of a first end (a right end in the drawing) of a horizontal conveyance channel 95, and the waste toner falls through the vertical conveyance channel 93 to the first end of the horizontal conveyance channel 95. As a driving motor 96a rotates the conveying screw 96, the waste toner inside the horizontal conveyance channel 95 is transported linearly in the axial direction thereof to a second end side (on the left in the drawing) of the horizontal conveyance channel 95.
The horizontal conveyance channel 95 is in a conveying pipe similar to the common conveying pipe 91, and a conveying screw 96 is provided therein.
An outlet is provided in a bottom of the second end side (on the left in the drawing) of the horizontal conveyance channel 95 to discharge waste toner from the horizontal conveyance channel 95 downward to the waste-toner container 100. On the second end side of the horizontal conveyance channel 95, waste toner falls through the outlet to the waste-toner container 100 and stored therein.
The waste-toner conveyance device 90 according to the present embodiment transports, to the waste-toner container 100, the waste toner collected from the intermediate transfer belt 61 by the belt cleaning device 64 as well.
Specifically, the waste toner discharged from the belt cleaning device 64 is transported from a communicating channel 97A to a second end side (on the left in the drawing) of a horizontal communicating channel 97B.
The horizontal communicating channel 97B is in a conveying pipe similar to the common conveying pipe 91, and a conveying screw 98 is provided therein. As a driving motor 98a rotates the conveying screw 98, the waste toner inside the horizontal communicating channel 97B is transported linearly in the axial direction thereof to a first end side (on the right in the drawing) of the horizontal communicating channel 97B.
A first end (on the right in the drawing) of the horizontal communicating channel 97B is connected to an intermediate portion of the vertical conveyance channel 93. On the first end side of the horizontal communicating channel 97B, waste toner is introduced into the vertical conveyance channel 93 and falls to the first end of the horizontal conveyance channel 95.
With this configuration, the waste toner discharged from the belt cleaning device 64 is transported inside the horizontal conveyance channel 95 to the waste-toner container 100 and stored therein, together with the waste toner discharged from the cleaning devices 40 of the respective image forming units 10.
Next, a distinctive feature of the present embodiment is described below.
In the image forming apparatus 1 according to the present embodiment, in addition to process color toners of yellow (Y), cyan (C), magenta (M), and black (K) toners, transparent toner (S) is used as special toner. It is possible that special toner is different from process color toners in flow properties.
It is to be noted that, in the present embodiment, process color toners are polymerization toners, and transparent toner is pulverized toner.
Referring to
As shown in
Since the shape thereof is irregular, as shown in
When polymerization toner, the flow properties of which are better, is used, the amount per unit time of toner discharged (toner discharge amount per unit time) from the cleaning device 40 to the common conveying pipe 91 is greater. This increases the possibility that the communicating pipe 94, through which waste toner flows from the cleaning device 40 to the common conveying pipe 91, is clogged with toner.
In view of the foregoing, in the present embodiment, in the cleaning device 40 of the image forming unit 10 employing polymerization toner, the rotation speed of the conveying screw 16 is reduced. With this setting, as shown in
When pulverized toner is used, as shown in
In view of the foregoing, in the present embodiment, in the cleaning device 40 of the image forming unit 10 employing pulverized toner, the rotation speed of the conveying screw 16 is increased.
With this setting, compared with a case in which the conveying screw 16 is rotated at a lower speed, the transport capability of the conveying screw 16 is enhanced, thereby facilitating discharge of toner from the waste-toner conveying pipe 44 to the common conveying pipe 91.
Accordingly, the toner discharge amount from the waste-toner conveying pipe 44 to the common conveying pipe 91 is increased relative to the amount of toner input from the cleaning device 40. Accordingly, as shown in
In the present embodiment, the rotational speed of each of the conveying screws 16Y, 16C, 16M, and 16K of the image forming units 10Y, 10C, 10M, and 10K employing polymerization toner for process color toner is set at a reference speed.
While the conveying screws 16Y, 16C, 16M, and 16K are kept at the reference speed, the conveying screw 16S of the image forming unit 10 employing, as transparent toner, pulverized toner that is less easily transported, is set at a speed increased from the reference speed.
This setting improves the transport capability of the conveying screw 16S and facilitates discharge of pulverized toner from the waste-toner conveying pipe 44 to the common conveying pipe 91. Accordingly, the occurrence of overflow of toner or clogging with toner of the waste-toner conveying pipe 44 is suppressed. Although polymerization toner serves as the first toner having better flow properties and pulverized toner serves as the second toner having poorer flow properties in the present embodiment, the combination of first and second toners is not limited to the combination of polymerization toner and pulverized toner. Even if both toners are produced by a similar method (i.e., polymerization, pulverization, or the like), flow properties thereof differ depending on particle diameter, additives, and the like. For example, in one embodiment, the first toner is a polymerization toner having a smaller diameter, and the second toner is a polymerization toner having a larger diameter.
It is to be noted that, when white toner that is pulverized toner is used instead of transparent toner, the conveying screw 16S of the image forming unit 10S employing white toner is set at the speed increased from the reference speed. With this setting, the occurrence of overflow of toner or clogging with toner of the waste-toner conveying pipe 44 of the cleaning device 40S corresponding to white toner is suppressed.
It is to be noted that, if the rotation speed of the conveying screw 16 is increased constantly aiming at improving the capability of the conveying screw 16 to transport waste toner, it is possible that the operational life of the conveying screw 16 is shortened due to excessive rotation thereof.
Additionally, in the configuration shown in
Therefore, in the present embodiment, the rotation speed of the conveying screw 16 is increased when the amount of toner removed from the photoconductor 11 by the cleaning device 40 is relatively large. Specifically, the rotation speed of the conveying screw 16 is increased when a toner-related variable, which relates to the amount of toner removed by the cleaning device 40, exceeds a predetermined threshold level. The toner-related variable includes image area ratio and setting of amount of toner adhering to the photoconductor 11 (i.e., toner adhesion amount) when a latent image is developed. In other words, the toner-related variables are criteria for judging whether to increase the rotational speed. For example, the image area ratio is calculated by the controller 800 according to image data input to the image forming apparatus 1.
This control alleviates decreases in operational life of the conveying screw 16 caused by excessive rotation thereof. Additionally, in the above-described configuration in which the conveying screw 16 and the application roller 51 are driven by the common driving source (driving motor 51M), this control inhibits the application roller 51 from excessively scraping off lubricant from the solid lubricant 50, thereby alleviating decreases in operational life of the solid lubricant 50, the charging roller 22, or both.
For example, regarding the toner adhesion amount to the photoconductor 11, a target toner adhesion amount (i.e., setting) is preset in software and retrieved in controlling the rotation speed of the conveying screw 16.
When pulverized toner, which is less easily transported, is used, the toner discharge amount per unit time from the waste-toner conveying pipe 44 to the common conveying pipe 91 does not keep up with the amount of toner input from the cleaning device 40 as shown in
Additionally, as shown in
In view of the foregoing, during continuous image formation in which images are successively formed on multiple number of recording sheets 6, an area between sheets (i.e., a sheet interval area) on the photoconductor 11 is widened depending on toner type used in the image forming unit 10 in the present embodiment. For example, the sheet interval area on the photoconductor 11 is adjusted by changing the timing at which the exposure device 4 exposes the photoconductor 11 or with idle running of the photoconductor 11.
With this operation, as shown in
To keep productively, it is advantageous that widening sheet interval areas is limited to cases where the amount of toner input to the cleaning device 40 is larger, such as image area ratio is greater and the toner adhesion amount to the photoconductor 11 is greater. If sheet interval areas are widened unnecessarily in cases where the amount of toner input is small, productivity is reduced.
If the amount of toner discharged from the waste-toner conveying pipe 44 to the common conveying pipe 91 is excessive, as shown in
In view of the foregoing, in the present embodiment, as shown in
Additionally, increasing the rotation speed of the conveying screw 92 is limited to cases where the amount of toner input to the cleaning device 40 is relatively large, such as when the image area ratio is large or toner adhesion amount to the photoconductor 11 is large. This control alleviates decreases in operational life of the conveying screw 92 caused by excessive rotation thereof.
Referring to
In the present embodiment, depending on toner type such as pulverized toner and polymerization toner, the rotation speed of the conveying screw 16, which is disposed in the waste-toner conveying pipe 44 of cleaning device 40, is changed. For the image forming apparatus 1 to recognize the toner type, toner types used in the respective image forming units 10 are prestored in software, for example.
As shown in
According to the designation of toner type (i.e., toner type data) in each image forming unit 10, the rotation speed of the conveying screw 16 is adjusted as described above.
Referring to
In this case, as shown in
It is to be noted that, although rotation speed of the conveying screw 16 is selectable from three levels of high speed, medium speed, and low speed in
Additionally, the controller 800 controls rotation of the conveying screw 92 in the common conveying pipe 91 and the conveying screw 96 in the horizontal conveyance channel 95 according to the number of the image forming units 10 in which conveyance speed of waste toner in the cleaning device 40 is increased from the reference speed.
Here, referring to
The waste toner discharged from the cleaning devices 40K and 40M of the image forming units 10K and 10M flows through the first portion 91a. By contrast, the waste toner discharged from the cleaning devices 40C, 40Y, and 40S of the image forming units 10C, 10Y, and 10S flows through the second portion 91b.
It is to be noted that the number of the image forming units 10 corresponding to each of the first portion 91a and the second portion 91b is not limited thereto.
Generally, compared with a case where the rotation speed of the conveying screw 16 is increased in one of the cleaning devices 40K and 40M, the amount of waste toner transported through the first portion 91a is greater in a case where the speed is increased in both of the cleaning devices 40K and 40M.
As the number of the conveying screws 16 that are rotated at the increased speed increases, the amount of waste toner transported through the first portion 91a increases, and accordingly the rotation speed of the conveying screw 92 is increased in one embodiment.
Similarly, regarding the cleaning devices 40C, 40Y, and 40S, as the number of the conveying screws 16 that are rotated at the increased speed increases and accordingly the amount of waste toner transported through the second portion 91b increases, the rotation speed of the conveying screw 92 is increased in one embodiment.
It is to be noted that, in the configuration shown in
For example, in a case where the image forming units 10K and 10S employ pulverized toner and the image forming units 10Y, 10C, and 10M employ polymerization toner, the rotation speed of the conveying screw 92 in the common conveying pipe 91 is controlled as follows.
In this case, the conveying screws 16K and 16S to transport pulverized toner are rotated at an increased speed from the rotation speed of the conveying screw 16Y, 16C, and 16M to transport polymerization toner. For example, in the image forming units 10K and 10S, the conveying screws 16K and 10S are rotated at the speed higher than a reference speed.
In the first portion 91a, only one image forming unit 10 (10K) contributes to the increase in rotation speed of the conveying screw 92.
In the second portion 91b, only one image forming unit 10 (10S) contributes to the increase in rotation speed of the conveying screw 92.
Thus, in each of the first portion 91a and the second portion 91b, the number of image forming units 10 contributing to the increase in rotation speed of the conveying screw 92 is one. Accordingly, the rotation speed of the conveying screw 92 is set at a speed corresponding to a case where there is one image forming unit 10 including the conveying screw 16 to rotate at the increased speed.
By contrast, two image forming units 10, namely, the image forming units 10K and 10S contribute to the increase in rotation speed of the conveying screw 96 disposed in the horizontal conveyance channel 95. Accordingly, the rotation speed of the conveying screw 96 is set at a speed corresponding to a case where there are two image forming units 10 each including the conveying screw 16 to rotate at the increased speed.
Alternatively, in a case where the image forming units 10Y and 10S employ pulverized toner and the image forming units 10C, 10M, and 10K employ polymerization toner, the rotation speed of the conveying screw 92 in the common conveying pipe 91 is controlled as follows.
In this case, the conveying screw 16Y and 16S to transport pulverized toner are rotated at an increased speed from the rotation speed of the conveying screw 16C, 16M, and 16K to transport polymerization toner. That is, in the image forming units 10Y and 10S, the conveying screws 16Y and 10S are rotated at the speed higher than the reference speed.
In the first portion 91a, no image forming unit 10 contributes to the increase in rotation speed of the conveying screw 92 since the conveying screws 16M and 16K corresponding to the first portion 91a are not rotated at the increased speed.
In the second portion 91b, two image forming units 10, namely, the image forming units 10Y and 10S contribute to the increase in rotation speed of the conveying screw 92.
Thus, the number of the image forming units 10 contributing to the increase in rotation speed of the conveying screw 92 is zero in the first portion 91a, and two in the second portion 91b. Accordingly, the rotation speed of the conveying screw 96 is set at a speed corresponding to the second portion 91b in which the number of image forming units 10 each of which includes the conveying screw 16 to rotate at the increased speed is two.
By contrast, two image forming units 10, namely, the image forming units 10Y and 10S, contribute to the increase in rotation speed of the conveying screw 96 disposed in the horizontal conveyance channel 95. Accordingly, the rotation speed of the conveying screw 96 is set at a speed corresponding to a case where there are two image forming units 10 each of which includes the conveying screw 16 to rotate at the increased speed.
It is to be noted that the description above concerns the configuration in which the conveying screw 92 in the common conveying pipe 91 and the conveying screw 96 in the horizontal conveyance channel 95 are rotated by separate driving sources, and control of the rotational speed thereof are separately described above.
Alternatively, in one embodiment, the conveying screw 92 and the conveying screw 96 are rotated by a common driving source. In this case, the rotational speed of both of the conveying screw 92 and the conveying screw 96 is set according to the number of the image forming units 10 each of which includes the conveying screw 16 to rotate at the increased speed, simply out of all image forming units 10.
In this case, similar to the description above, the criteria for increasing the rotation speed of the conveying screw 92 include the amount of toner input to the cleaning device 40, image area ratio, and the toner adhesion amount to the photoconductor 11.
In other words, in the common conveying pipe 91, the rotation speed of the conveying screw 92 is increased when the image area ratio or the toner adhesion amount, summed up in each of the first portion 91a and the second portion 91b, exceeds a threshold. Additionally, in the horizontal conveyance channel 95, the rotation speed of the conveying screw 96 is increased when the image area ratio or the toner adhesion amount summed up in all image forming units 10 exceeds a threshold.
A second embodiment is described below with reference to drawings.
The image forming apparatus 1 according to the present embodiment has a configuration similar to that according to the first embodiment, an example of which is shown in
It is to be noted that, in the present embodiment, process color toners, namely, yellow (Y), cyan (C), magenta (M), and black (K) are polymerization toners, and transparent toner is pulverized toner, similar to the above-described first embodiment. Alternatively, in one embodiment, toner type is selectable from polymerization toner and pulverized toner for each image forming unit 10. In this case, toner type is set, for example, as described above with reference to
Differences of the present embodiment from the above-described first embodiment are as follows.
The conveying screw 16 and the application roller 51 are rotated by either a common driving source (i.e., the driving motor 51M) or separate driving sources in the first embodiment. In the present embodiment, however, the conveying screw 16 and the application roller 51 are rotated by a common driving source not separate driving sources.
Additionally, in the present embodiment, the temperature and humidity sensor 203 is used in controlling the transport of waste toner. The temperature and humidity sensor 203 measures absolute humidity that represents an environment in which the image forming apparatus 1 is installed.
Descriptions are given below of determination of rotation speed (the number of revolutions per minute or RPM) of the driving motor 51M.
To protect the surface of the photoconductor 11 with lubrication by the application roller 51, the rotation speed of the driving motor 51M is determined in view of effects of absolute humidity under which the image forming apparatus 1 is used.
As shown in
Referring to
In one embodiment, the rotation speed (i.e., RPM) of the driving motor 51M corresponding to absolute humidity h, which is hereinafter referred to as “motor revolution number R(h), differs depending on toner type. For example, rFC(h) represents the motor speed (motor revolution number) to maintain desirable lubrication of the photoconductor 11 when polymerization toner is used, and rS(h) represents the motor speed (motor revolution number) to maintain desirable lubrication when pulverized toner is used.
In the configuration in which the conveying screw 16 and the application roller 51 are driven by a common driving motor (i.e., the driving motor 51M), the motor speed is determined considering driving of the conveying screw 16 to maintain reliable transport of waste toner, in addition to driving of the application roller 51 to maintain desirable lubrication of the photoconductor 11.
In
As described above, the revolution number rFC(h) to maintain desirable lubrication for polymerization toner, which is also referred to a “revolution number rFC(h) for lubrication”, increases in proportion to the rise in the absolute humidity h. By contrast, the motor speed to maintain reliable transport of waste toner in the case of polymerization toner, which is also referred to as “revolution number WFC for transport of toner”, is constant and independent of the absolute humidity.
When polymerization toner is used, regardless of the absolute humidity h, constantly a relation rFC(h)>WFC is established. Accordingly, the motor revolution number R(h) is set at rFC(h), indicated by a solid line in
In
Also when pulverized toner is used, the revolution number rS (h) of the driving motor 51M to maintain desirable lubrication, which is also referred to as “revolution number rS (h) for lubrication, increases in proportion to the rise in the absolute humidity h. In addition, the motor speed to maintain reliable transport of waste toner in the case of pulverized toner, which is also referred to as “revolution number WS for transport of toner”, is constant and independent of the absolute humidity similar to the cases where polymerization toner is used.
In
In practice, the motor speed is generally changed stepwise, not continuously, relative to the absolute humidity. For example, when absolute temperature range is divided in five ranges as in table 1 below, the revolution number rFC(h) for lubrication, represented by alternate long and short dashed lines in
In table 1, absolute temperature is divided in five ranges of h<h1, h1≦h<h2, h2≦h<h3, h3<h<h4, and h4<h (h1<h2<h3<h4<h5).
The revolution number RFC(h) in the case of polymerization toner to maintain desirable lubrication of the photoconductor 11 is set at RFC1, RFC2, RFC3, RFC4, and RFC5 respectively for the five ranges of absolute humidity in the order mentioned above (RFC1<RFC2<RFC3<RFC4<RFC5).
The revolution number RS(h) in the case of pulverized toner to maintain desirable lubrication of the photoconductor 11 is set at RS1, RS2, RS3, RS4, and RS5 respectively for the five ranges of absolute humidity in the order mentioned above (RS5>WS>RS4>RS3>RS2>RS1). The correlation between the absolute humidity range and the motor speed to maintain desirable lubrication of the photoconductor 11, for each toner type, is prestored in data storage device inside the image forming apparatus 1.
The graph shown in
When polymerization toner is used, relative to the absolute humidity h, the relation RFC (h)>WFC is constantly established (see
By contrast, when pulverized toner is used, RS(h)<WS is true depending on the absolute humidity h. For example, as shown in
Descriptions are given below of control flow of the motor revolution number R(h).
At S11, the temperature and humidity sensor 203 of the image forming apparatus 1 detects the absolute humidity in the environment in which the apparatus is used.
At S12, the controller 800 identifies toner type in that image forming unit 10. In
At S13, from the correlation prestored in the data storage device, the revolution number RFC(h) for lubrication for polymerization toner, corresponding to the absolute humidity detected at S11 is retrieved. At S16, the motor revolution number R(h) is set at RFC(h).
At S14, from the correlation prestored in the data storage device, the revolution number RS(h) for lubrication for pulverized toner, corresponding to the absolute humidity detected at S11 is retrieved. At S15, the motor revolution number R(h) is set at RS(h).
At S17, from the correlation prestored in the data storage device, the revolution number WS(h) for toner conveyance for pulverized toner, corresponding to the absolute humidity detected at S11 is retrieved. At S18, the value of RS(h), to which the motor revolution number R(h) is set at S15, is compared with the value of WS retrieved at S17. When R(h)>WS, the possibility of clogging with waste toner is low, and at S20, R(h) is fixed at RS(h). By contrast, when R(h)≦WS, clogging with waste toner is possible with R(h) fixed at RS(h). Accordingly, at S19, R(h) is updated to WS and fixed at S20.
The process from S12 through S20 is performed for each of the multiple cleaning devices 40.
Typically, the motor revolution number (RFC1, RFC2, RFC3, RFC4, and RFC5) for the cases of polymerization toner and the motor revolution number (RS1, RS2, RS3, RS4, and RS5) for pulverized toner are in the relation of magnitude of RFC1≧RS1, RFC2≧RS2, RFC3≧RS3, RFC4≧RS4, and RFC≧5≧RS5. When the difference between RFCn and RSn (n=1 to 5) is small and ignorable in practice, RSn for each cleaning device 40 is set at a value equal to the value of RFCn in one embodiment. This setting is advantageous in simplifying the process to determine the motor speed since an identical revolution number is applied to all of the cleaning devices 40 of the image forming units 10 employing polymerization toner or pulverized toner when the apparatus is used under the absolute humidity greater than hp (shown in
In the present embodiment, lubricant applied to the photoconductor 11 is scraped by the application roller 51 from the solid lubricant 50 produced by mixing zinc stearate, boron nitride, and alumina and compressing the mixture. Use of zinc stearate as fatty acid metallic salt added to lubricant is advantageous in enhancing the capability of lubricant to suppress degradation with time of image bearers, thereby inhibiting poor cleaning. Use of boron nitride as inorganic lubricant added to lubricant is advantageous in enhancing the capability of lubricant to suppress degradation with time of the cleaning blade 43 and the charging roller 22, thereby inhibiting poor cleaning.
As mentioned in the first embodiment, if the rotation speed of the conveying screw 16 is increased constantly aiming at improving the capability of the conveying screw 16 to transport waste toner, it is possible that the operational life of the conveying screw 16 is shortened due to excessive rotation thereof. Additionally, as in the present embodiment in which the conveying screw 16 and the application roller 51 are driven by a common driving source (i.e., the driving motor 51M), the rotation speed of the application roller 51 increases as the rotation speed of the conveying screw 16 increases. Accordingly, it is possible that the life of the solid lubricant 50 is shortened, or the charging roller 22 is stained due to excessive lubrication of the photoconductor 11, thus shortening the operational life of the charging roller 22.
Therefore, in one embodiment, increasing the rotation speed of the conveying screw 16 is limited to cases where the amount of toner removed from the photoconductor 11 by the cleaning device 40 is relatively large, such as when the image area ratio is large or toner adhesion amount to the photoconductor 11 is large.
Additionally, similar to the first embodiment, the image forming apparatus 1 according to the present embodiment can have a capability of widening the sheet interval area on the photoconductor 11 depending on toner type used in that image forming unit 10 during continuous image formation. It is preferred this operation be limited to cases where the amount of toner input to the cleaning device 40 is relatively large, such as when the image area ratio is large or toner adhesion amount to the photoconductor 11 is large.
A third embodiment is described below with reference to drawings.
The image forming apparatus 1 according to the present embodiment is similar to that according to the first embodiment, an example of which is shown in
It is to be noted that, in the present embodiment, process color toners, namely, yellow (Y), cyan (C), magenta (M), and black (K) are polymerization toners, and transparent toner is pulverized toner, similar to the above-described first embodiment. In one embodiment, toner type is selectable from polymerization toner and pulverized toner for each image forming unit 10. In this case, toner type is set, for example, as described above with reference to
Differences of the present embodiment from the above-described first embodiment are as follows.
The conveying screw 16 and the application roller 51 are rotated by either a common driving source or separate driving sources in the first embodiment. In the present embodiment, however, the conveying screw 16 and the application roller 51 are rotated by a common driving source, the driving motor 51M.
Additionally, the image forming apparatus 1 according to the present embodiment includes the temperature and humidity sensor 203. The temperature and humidity sensor 203 measures the absolute humidity that represents an environment in which the image forming apparatus 1 is installed. Additionally, before image formation, the controller 800 sets the amount of pulverized toner applied to the surface of the photoconductor 11 (hereinafter “pulverized toner adhering amount”). For example, the controller 800 calculates the pulverized toner adhering amount based on image-related data input to the image forming apparatus 1, such as image density setting made by the user or image data of images to be formed. According to the pulverized toner adhering amount thus set, a computing unit 901 calculates the motor speed to maintain reliable transport of waste toner (i.e., motor revolution number for toner conveyance).
Descriptions are given below of determination of number of revolutions of the driving motor.
Determination of number of revolutions of the driving motor 51M in the image forming unit 10 using polymerization toner is similar to that described with reference to
Referring to
In the example shown in
In
The motor speed for transport of toner varies depending on the pulverized toner adhering amount set before image formation. The graph A in
In the case of pulverized toner, similar to the case of polymerization toner, the motor speed for lubrication increases in proportion to the rise in the absolute humidity h, which is referred to as “revolution number rS(h) for lubrication. In addition, the motor speed to maintain reliable transport of waste toner in the case of pulverized toner, which is referred to as revolution number WS for transport of toner, is constant and independent of the absolute humidity similar to the case of polymerization toner. The constant revolution number, however, varies depending on the pulverized toner adhering amount. The revolution number WS in relation to the pulverized toner adhering amount is set at WSmax, WSmid, and WSmin when the pulverized toner adhering amount set at the large amount, the standard amount, and the small amount, respectively.
In the case where the pulverized toner adhering amount is set at the large amount, the relation of magnitude between rS(h) and WSmax is inverted at absolute humidity hpmax in
In the case where the pulverized toner adhering amount is set at the standard amount, the relation of magnitude between rS(h) and WSmid is inverted at absolute humidity hpmid in
In the case where the pulverized toner adhering amount is set at the small amount, the relation of magnitude between rS(h) and WSmin is inverted at absolute humidity hpmin in
It is to be noted that, although the three settings of large amount, standard amount, and small amount are used for pulverized toner adhering amount in
In table 2, according to the range of pulverized toner adhering amount A, five settings (setting a through setting e) are used for the pulverized toner adhering amount. The setting a represents the pulverized toner adhering amount in the range smaller than A1, the setting b represents that in the range of A1≦A<A2, the setting c represents that in the range of A2≦A<A3, the setting d represents that in the range of A3≦A<A4, and the setting e represents the pulverized toner adhering amount A equal to or greater than A4 (A1<A2<A3<A4). The motor speed for transport of toner is set at WS1 corresponding to the setting a, WS2 corresponding to the setting b, WS3 corresponding to the setting c, WS4 corresponding to the setting, d, and WS5 corresponding to the setting e.
As described above in the second embodiment, in practice, the motor speed for lubrication is not varied continuously as indicated by broken lines rFC(h) in
As shown in
As shown in
When the five settings of pulverized toner adhering amount in table 2 are used, the motor speed for transport of toner is as indicated by broken graphs in
In
In
In
In
In
The correlation between the absolute humidity range and the motor speed for lubrication for each toner type, an example of which is shown in table 1, is prestored in data storage device inside the image forming apparatus 1. Similarly, the correlation between pulverized toner adhering amount and the motor speed for transport of toner for each toner type, an example of which is shown in table 2, is prestored in data storage device inside the image forming apparatus 1.
Descriptions are given below of control flow of the motor revolution number R(h).
At S21, the temperature and humidity sensor 203 of the image forming apparatus 1 detects the absolute humidity in the environment in which the apparatus is used.
At S22, the controller 800 identifies toner type in that image forming unit 10. In particular, whether or not pulverized toner is used is judged. When pulverized toner is used (Yes at S22), the process proceeds to S24. When polymerization toner is used, the process proceeds to S23.
At S23, from the correlation prestored in the data storage device, the revolution number RFC(h) for lubrication for polymerization toner, corresponding to the absolute humidity detected at S21, is retrieved. At S26, the motor revolution number R(h) is set at RFC(h) and confirmed at S31.
At S24, from the correlation prestored in the data storage device, the revolution number RS(h) for lubrication for pulverized toner, corresponding to the absolute humidity detected at S21, is retrieved. At S25, the motor revolution number R(h) is set at RS(h).
At S27, the pulverized toner adhering amount set by the controller 800, is retrieved. At S28, from the correlation prestored in the data storage device, the revolution number WS(A) for transport of toner for pulverized toner, corresponding to the pulverized toner adhering amount obtained at S27 is retrieved.
At S29, the value of RS(h), to which the motor revolution number R(h) is set at S25, is compared with the value of WS(A) retrieved at S28. When R(h)>WS(A), the possibility of clogging with waste toner is low, and at S31, R(h) is fixed at RS(h). By contrast, when R(h)≦WS(A), clogging with waste toner is possible with R(h) fixed at RS(h) at S25. Accordingly, at S30, R(h) is updated to WS(A) and fixed at S31.
The process from S22 through S31 is performed for each of the multiple cleaning devices 40.
Typically, the motor revolution number (RFC1, RFC2, RFC3, RFC4, and RFC5) for the cases of polymerization toner and the motor revolution number (RS1, RS2, RS3, RS4, and RS5) for pulverized toner are in the relation of magnitude of RFC1>RS1, RFC2>RS2, RFC3>RS3, RFC4>RS4, and RFC5>RS5. When the difference between RFCn and RSn (n=1 to 5) is small and ignorable in practice, RSn for each cleaning device 40 is equal to RFCn in one embodiment. This setting is advantageous in simplifying the process to determine the motor speed since an identical motor speed is applied to all of the cleaning devices 40 of the image forming units 10 employing polymerization toner or pulverized toner when the apparatus is used in an environment in which the absolute humidity is greater than hp (shown in
In the present embodiment, lubricant applied to the photoconductor 11 is scraped by the application roller 51 from the solid lubricant 50 produced by mixing zinc stearate, boron nitride, and alumina and compressing the mixture. Use of zinc stearate as fatty acid metallic salt added to lubricant is advantageous in enhancing the capability of lubricant to suppress degradation with time of image bearers, thereby inhibiting poor cleaning. Use of boron nitride as inorganic lubricant added to lubricant is advantageous in enhancing the capability of lubricant to suppress degradation with time of the cleaning blade 43 and the charging roller 22, thereby inhibiting poor cleaning.
As mentioned in the first embodiment, if the rotation speed of the conveying screw 16 is increased constantly aiming at improving the capability of the conveying screw 16 to transport waste toner, it is possible that the operational life of the conveying screw 16 is shortened due to excessive rotation thereof. Additionally, as in the present embodiment in which the conveying screw 16 and the application roller 51 are driven by a common driving source (i.e., the driving motor 51M), the rotation speed of the application roller 51 increases as the rotation speed of the conveying screw 16 increases. Accordingly, it is possible that the life of the solid lubricant 50 is shortened, or the charging roller 22 is stained due to excessive lubrication of the photoconductor 11, thus shortening the operational life of the charging roller 22.
Therefore, in one embodiment, increasing the rotation speed of the conveying screw 16 is limited to cases where the amount of toner removed from the photoconductor 11 by the cleaning device 40 is relatively large, such as when the image area ratio is large or toner adhesion amount to the photoconductor 11 is large.
Additionally, similar to the first embodiment, the image forming apparatus 1 according to the present embodiment can have a capability of widening the sheet interval area on the photoconductor 11 depending on toner type used in that image forming unit 10 during continuous image formation. It is preferred this operation be limited to cases where the amount of toner input to the cleaning device 40 is relatively large, such as when the image area ratio is large or toner adhesion amount to the photoconductor 11 is large.
It is to be noted that
The various aspects of the present specification can attain specific effects as follows.
Aspect A: Aspect A concerns an image forming apparatus that includes multiple image forming units each of which includes an image bearer; a toner image forming device to form a toner image on the image bearer; a transfer device to transfer the toner image from the image bearer onto a transfer medium; a cleaning device to remove toner from a surface of the image bearer from which the toner image is transferred; a hollow member (i.e., conveyance channel or waste-toner tube) through which toner removed by the cleaning device is transported; a toner conveying member to transport toner by rotation, disposed inside the tubular member. Toner type (i.e., a second toner) used in at least one of the multiple image forming units is different in flow properties from the toner type (i.e., a first toner) used in the rest of the multiple image forming units, and a rotation speed of the toner conveying member is variable for each of the multiple image forming units according to the toner type used therein. The hollow member through which waste toner flows is not limited to those cylindrical tubes and pipes but may be semicylindrical or rectangular in cross section.
In aspect A, according to toner type, in other words, the flow properties of toner, the toner transport capability of the toner conveying member is adjustable by increasing or reducing the rotation speed of the toner conveying member from a predetermined reference speed for each image forming unit. Accordingly, when the toner of poorer flow properties is used, the rotation speed of the toner conveying member is increased, thereby enhancing the toner transport capability of the toner conveying member. Therefore, clogging of the conveyance channel with toner is inhibited. When the toner of better flow properties is used, the rotation speed of the toner conveying member is reduced, thereby reducing the toner transport capability of the toner conveying member. Therefore, the load on the toner conveying member is reduced, thereby elongating the of the toner conveying member. Accordingly, even in configurations using different types of toners different in flow properties, clogging with toner and wear of the toner conveying member are inhibited while achieving commonality of components of the image forming units.
Aspect B: In aspect A, the rotation speed of the toner conveying member is increased when the amount of toner removed by the cleaning device is greater than the predetermined amount. With this aspect, as described above, the operational life of the toner conveying member is elongated since the rotation speed of the toner conveying member is increased only when high toner transport capability is necessary.
Aspect C: In aspect B, the rotation speed of the toner conveying member is increased when the image area ratio of the toner image on the image bearer is equal to or greater than a predetermined area. With this aspect, as described above, clogging with toner is inhibited while elongating the operational life of the toner conveying member.
Aspect D: In aspect B or C, the rotation speed of the toner conveying member is increased when the toner adhesion amount setting of the toner image on the image bearer is equal to or greater than a predetermined amount. With this aspect, as described above, clogging with toner is inhibited while elongating the operational life of the toner conveying member.
Aspect E: In any of aspects A, B, C, and D, a sheet interval area on the image bearer is widened according to the toner type used in the image forming unit during continuous image formation in which images are successively formed on multiple number of sheets of recording media. With this aspect, overflow of toner and clogging with toner are inhibited as described above.
Aspect F: In aspect E, when the amount of toner removed by the cleaning device is greater than the predetermined amount, the sheet interval area is widened according to the toner type used in the image forming unit. With this aspect, as described above, overflow of toner and clogging with toner are inhibited while reducing degradation in productivity.
Aspect G: In aspect F, the sheet interval area is widened according to the toner type used in the image forming unit when the image area ratio of the toner image on the image bearer is greater than the predetermined area. With this aspect, as described above, overflow of toner and clogging with toner are inhibited while reducing degradation in productivity.
Aspect H: In aspect F or G, the sheet interval area is widened according to the toner type used in the image forming unit when the toner adhesion amount setting of the toner image on the image bearer is greater than the predetermined amount. With this aspect, as described above, overflow of toner and clogging with toner are inhibited while reducing degradation in productivity.
Aspect I: In any of aspects A through D, the image forming apparatus further includes a downstream hollow member (i.e., a downstream conveyance channel) positioned downstream from the waste-toner channel, and a downstream toner conveying member to transport toner by rotation, the downstream toner conveying member disposed inside the downstream hollow member; and the rotation speed of the downstream toner conveying member is increased according to the toner type in the image forming unit. With this aspect, clogging of the downstream conveyance channel with toner is inhibited as described above. The downstream hollow member through which waste toner flows is not limited to those cylindrical tubes and pipes but may be semicylindrical or rectangular in cross section.
Aspect J: In aspect I, the rotation speed of the downstream toner conveying member is increased when the amount of toner removed by the cleaning device is greater than the predetermined amount. With this aspect, as described above, clogging of the downstream conveyance channel with toner is inhibited while elongating the operational life of the downstream toner conveying member.
Aspect K: In aspect J, the rotation speed of the downstream toner conveying member is increased when the image area ratio of the toner image on the image bearer is equal to or greater than a predetermined area. With this aspect, as described above, clogging of the downstream conveyance channel with toner is inhibited while elongating the operational life of the downstream toner conveying member.
Aspect L: In aspect J or K, the rotation speed of the downstream toner conveying member is increased when the toner adhesion amount setting of the toner image on the image bearer is equal to or greater than a predetermined amount. With this aspect, as described above, clogging of the downstream conveyance channel with toner is inhibited while elongating the operational life of the downstream toner conveying member.
Aspect M: In any of aspects A through L, the toner type includes polymerization toner and pulverized toner. With this aspect, as described above, toner type is selectable from polymerization toner and pulverized toner for each image forming unit depending on an intended effect such as image quality improvement or cleaning performance improvement, thus attaining desirable image formation.
Aspect N: In any of aspects A through L, the toner type includes colored toner and transparent toner. With this aspect, transparent toner is used as an overcoat to protect colored toner images or improve the gloss level of images as described above.
Aspect O: In any of aspects A through N, the cleaning device includes a lubricant applicator to apply lubricant onto the surface of the image bearer, and each of the multiple image forming units further includes a driving source to drive both of the lubricant applicator and the toner conveying member, out of the multiple image forming units, the controller sets a rotation speed of the driving source of the cleaning device of the image forming unit using the second toner having poorer flow properties to an increased value from a rotation speed of the driving source of the cleaning device of the image forming unit using the first toner.
In the image forming unit using the toner of poorer flow properties than the toner used in the rest of the image forming units, there is a range of absolute humidity in which a minimum required rotation speed of the driving source (such as the driving motor) for reliable transport of waste toner by the toner conveying member (such as the conveying screw 16) is greater than the minimum required rotation speed of the driving source for desirable lubrication of the image bearer by the application roller 51. When the rotation speed of the driving source of the cleaning device in the rest of the image forming units is set at the rotation speed for desirable lubrication of the image bearer, increasing the rotation speed of the driving source of the cleaning device of the image forming unit using the toner of poorer flow properties than that in the rest of the image forming units is advantageous in transporting waste toner reliably in all image forming units even if the absolute humidity is in the above-described range.
Aspect P: In aspect O, the rotation speed of the driving source is increased when the absolute humidity is in a first range in which the rotation speed for lubrication, required for protecting the image bearer with lubricant, is lower than the rotation speed required for reliable transport of waste toner by the toner conveying member.
In the setting in which the rotation speed for lubrication is identical in all the image forming units and the rotation speed of the driving source of the cleaning device is set at the rotation speed for lubrication in the rest of the image forming units, if the rotation speed of the driving source in the image forming unit using the toner of poorer flow properties is identical to that in the rest of the image forming units when the absolute humidity is in the first range, it is possible that waste toner is not properly transported in the image forming unit using the toner of poorer flow properties. In this case, waste toner can be transported properly in the entire image forming units by increasing the rotation speed of the driving source from that in the rest of the image forming units.
Aspect Q: In aspect P, when the absolute humidity is in the first range, the rotation speed of the driving source in the image forming unit using the toner of poorer flow properties is set at the for transport of toner.
When the absolute humidity is in the first range, there arises an inconvenience if the rotation speed of the driving source of the cleaning device in the image forming unit using the toner of poorer flow properties is identical to that in the rest of the image forming units. Specifically, the rotation speed of the driving source in the image forming unit using the toner of poorer flow properties falls below the rotation speed required for reliable transport of toner by the toner conveying member such as the conveying screw 16. In this case, in the image forming unit using the toner of poorer flow properties, the cleaning device fails to reliably transport waste toner. In view of the foregoing, when the absolute humidity is in the first range, the rotation speed of the driving source is set at the rotation speed for transport of toner in the image forming unit using the toner of poorer flow properties so that waste toner can be transported properly in all the image forming units.
Aspect R: In aspect Q, when the absolute humidity is in a second range in which the rotation speed for lubrication is higher than the rotation speed for transport of toner in the image forming unit using the second toner, the controller sets the rotation speed of the driving source of the cleaning device of the image forming unit using the second toner to the rotation speed for transport of toner.
When the absolute humidity is in the second range, the rotation speed for lubrication is constantly greater than the rotation speed for transport of toner also in the clearing device of the image forming unit using the toner of poorer flow properties. Accordingly, waste toner can be transported properly by the toner conveying member when the rotation speed of the driving source of the cleaning device is set at the rotation speed for lubrication in the image forming unit using the toner of poorer flow properties.
Aspect S: In aspect R, when the absolute humidity is in the second range, the driving sources of the respective image forming units are set to rotate at an identical rotation speed.
When the absolute humidity is in the second range, in the cleaning device of any one of the multiple image forming units, the rotation speed of the driving source for desirable lubrication of the image bearer is constantly greater than the rotation speed for reliable transport of waste toner. In a case where the difference in toner type does not cause a substantial difference in the rotation speed for desirable lubrication among the image forming units, use of an identical rotation speed of the driving source in the multiple image forming units is advantageous in simplifying the process to determine the rotation speed while maintaining reliable transport of waste toner.
Aspect T: In any one of aspects O through S, the lubricant supplied by the application roller includes fatty acid metallic salt and inorganic lubricant.
Use of zinc stearate as fatty acid metallic salt added to lubricant is advantageous in enhancing the capability of lubricant to suppress degradation with time of the image bearer, thereby inhibiting poor cleaning. Use of boron nitride as inorganic lubricant added to lubricant is advantageous in enhancing the capability of lubricant to suppress degradation with time of the cleaning blade 43 and the charging roller 22, thereby inhibiting poor cleaning.
Aspect U: In aspect T, the fatty acid metallic salt is zinc stearate and the inorganic lubricant is boron nitride.
Use of zinc stearate as fatty acid metallic salt added to lubricant is advantageous in enhancing the capability of lubricant to suppress degradation with time of the image bearer, thereby inhibiting poor cleaning in particular. Additionally, use of boron nitride as inorganic lubricant added to lubricant is advantageous in enhancing the capability of lubricant to suppress degradation with time of the cleaning blade 43 and the charging roller 22, thereby inhibiting poor cleaning in particular.
Aspect V: Aspect V concerns an image forming apparatus that includes multiple image forming units each of which includes an image bearer; a toner image forming device to form a toner image on the image bearer; a transfer device to transfer the toner image from the image bearer onto a transfer medium; a cleaning device to remove toner from a surface of the image bearer from which the toner image is transferred; a tubular member to define a waste-toner channel through which toner removed by the cleaning device is transported; a toner conveying member to transport toner by rotation, disposed inside the tubular member. In this configuration, the cleaning device includes a lubricant applicator to apply lubricant onto the surface of the image bearer, and each of the multiple image forming units further includes a driving source to drive both of the lubricant applicator and the toner conveying member. Multiple toner types are usable in the image forming apparatus, and at least one of the multiple image forming units uses a second toner having poorer flow properties than a first toner used in rest of the image forming units. The rotation speed of the driving source is variable individually in the multiple image forming units. The rotation speed of the driving source of the cleaning device of the image forming unit using the second toner having poorer flow properties is set to an increased value from a rotation speed of the driving source of the cleaning device of the image forming unit using the first toner.
Commonality of components among the multiple image forming units is achieved when the rotation speed of the driving source is variable individually in the multiple image forming units including the image forming unit using the toner of poorer flow properties. Additionally, in the image forming unit using the toner of poorer flow properties, there is a range of absolute humidity in which a minimum required rotation speed of the driving source (such as the driving motor) for reliable transport of waste toner by the toner conveying member (such as the conveying screw 16) is greater than the minimum required rotation speed of the driving source for desirable lubrication of the image bearer by the application roller 51. When the rotation speed of the driving source of the cleaning device in the rest of the image forming units is set at the rotation speed for desirable lubrication of the image bearer, increasing the rotation speed of the driving source of the cleaning device of the image forming unit using the toner of poorer flow properties than that in the rest of the image forming units is advantageous in transporting waste toner reliably in all the image forming units even if the absolute humidity is in the above-described range.
Aspect W: In any one of aspects P through U, the controller includes a computing unit to calculate the rotation speed for transport of toner. The computing unit calculates the rotation speed for transport of toner in the image forming unit using the toner of poorer flow properties, according setting of toner adhesion amount on the surface of the image bearer calculated according to image data input to the image forming apparatus.
The above-described rotation speed for transport of toner depends on the toner adhesion amount on the photoconductor 11. The rotation speed for transport of toner is higher when the toner adhesion amount is greater, and the rotation speed for transport of toner is lower when the toner adhesion amount is smaller. The rotation speed, however, is set to an excessively high value if the rotation speed for transport of toner is constantly calculated to respond to the case where the toner adhesion amount is greater. In the configuration in which the conveying screw 16 and the application roller 51 are rotated by a common driving source, the consumption of lubricant increases as the rotation speed of the driving source increases. Accordingly, compared with the image forming unit 10 using toner of different type, in the cleaning device 40 of the image forming unit 10 using pulverized toner, the consumption of lubricant is greater and the useful life of lubricant is significantly shortened. If replacement frequency of the cleaning device 40 in the image forming unit 10 using pulverized toner is high, it is inconvenient for users. In view of the foregoing, excessive increases in consumption of lubricant are inhibited by calculating the toner adhesion amount in the image forming unit using the toner of poorer flow properties based on image data and calculating the rotation speed for transport of toner based on the toner adhesion amount.
It is to be noted that, the steps in the above-described flowcharts may be executed in an order different from that in the flowchart. Further, elements and/or features of different example embodiments may be combined with each other and/or substituted for each other within the scope of this disclosure and appended claims.
Still further, any one of the above-described and other example features of the present specification may be embodied in the form of an apparatus, method, system, computer program and computer program product. For example, the aforementioned methods may be embodied in the form of a system or device, including, but not limited to, any of the structure for performing the methodology illustrated in the drawings. Even further, any of the aforementioned methods may be embodied in the form of a program. The program may be stored on a computer readable media and is adapted to perform any one of the aforementioned methods when run on a computer device (a device including a processor). Thus, the storage medium or computer readable medium, is adapted to store information and is adapted to interact with a data processing facility or computer device to perform the method of any of the above mentioned embodiments.
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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2014-022635 | Feb 2014 | JP | national |
2014-084292 | Apr 2014 | JP | national |
2014-132987 | Jun 2014 | JP | national |