This patent specification is based on and claims priority from Japanese Patent Application Nos. 2010-027208, filed on Feb. 10, 2010 and 2010-036809, filed on Feb. 23, 2010 in the Japan Patent Office, which are incorporated by reference herein in their entirety.
1. Field of the Invention
The present invention generally relates to a development device used in an image forming apparatus such as a copier, a printer, a facsimile machine, or a multifunction machine capable of at least two of these functions, a process cartridge incorporating the development device, and an image forming apparatus incorporating the development device.
2. Description of the Background Art
In general, electrophotographic image forming apparatuses, such as copiers, printers, facsimile machines, or multifunction devices including at least two of those functions, etc., include a latent image carrier on which an electrostatic latent image is formed and a development device to develop the latent image with developer.
There are image forming apparatuses that employ a magnetic brush development method using two-component developer consisting essentially of toner and magnetic carrier. Development devices that employ the magnetic brush development method generally include a developer container such as a casing in which two-component developer is contained, an agitator such as a conveyance screw to transport the developer inside the casing, and a developer carrier such as a development roller. In the magnetic brush development method, the toner (i.e., toner particles) is electrostatically adsorbed to the carrier (i.e., carrier particles), and the development roller conveys the toner electrostatically attracted to the carrier to a development area, where the development roller is partly exposed through an opening formed in the casing of the development device and faces the image carrier. In the development area, the toner particles adhere to the latent image formed on the image carrier, thus developing it into a toner image.
For example, the developer carrier includes a cylindrical development sleeve, and a magnetic field generator such as a magnetic roller or multiple magnets are provided inside the development sleeve to generate magnetic fields for causing the developer (i.e., developer particles) to stand on end on and get piled on a surface of the development sleeve. More specifically, the carrier particles stand on end on the surface of the development sleeve along lines of magnetic force generated by the magnet roller, and the electrically charged toner particles adhere to the carrier particles, thus forming a magnetic brush. The magnet roller has multiple magnetic poles generated by multiple magnets shaped like bars, for example. The multiple magnetic poles includes an attraction pole for attracting the developer to the development sleeve, a main development pole for transferring the toner to the image carrier, and a release pole for releasing the developer from the development sleeve. In particular, the main development pole is provided at the same circumferential position as a position of the development sleeve that faces the development area. The developer that stands on end on the surface of the development sleeve can be transported circumferentially by rotating at least one of the development sleeve and the magnet roller.
Typically, to facilitate conveyance of the developer, the surface of the development sleeve is sandblasted or bead-blasted so as to form grooves or irregularities in its surface. In particular, development rollers having a grooved surface or irregular surface are widely used in multicolor image forming apparatuses such as copiers and printers for attaining high quality images. Abrading the surface of the development sleeve by forming grooves or sandblasting can prevent or reduce slippage of the developer on the surface of the development sleeve and accumulation of the developer thereon, thus preventing a decrease in image density resulting from it.
For example, JP-2009-80447-A proposes using a development sleeve having multiple recesses formed at regular intervals in the surface of the development sleeve. The density of the developer carried on this development sleeve is as dense as that carried on the sandblasted development sleeve having the irregular surface. Simultaneously, this development sleeve has an ability to transport the developer as high as that of the grooved development sleeve.
In such development devices, if the electrical charge of the toner is insufficient due to deterioration of the developer or because the toner is insufficiently mixed with the carrier, the toner cannot be adsorbed to the carrier sufficiently and might be separated from the carrier in the development area or a developer conveyance path through which the developer is conveyed to the development area and collected from the development area. As a result, the toner might leak out the development device and scatter inside or outside the image forming apparatus. In particular, in image forming apparatuses using removably installable development devices, it is preferred that the amount of scattering toner be minimized on the front side in a direction in which users or service persons insert the development device into the image forming apparatus because they also operate or visually check the apparatus there.
Another matter regarding such development devices is carry-over of developer, which is a phenomenon of the developer that is not separated from the developer carrier in the release portion but is carried further by the developer carrier. If the developer after image development, in which the concentration of toner is decreased, is not returned to the developer container but is carried over and supplied again to the development area, image density can become uneven.
In view of the foregoing, in one illustrative embodiment of the present invention, a development device development includes a casing, a developer container housed in the casing, for containing two-component developer consisting essentially of toner and carrier, a hollow, cylindrical nonmagnetic developer carrier rotatably disposed within the casing, to transport the developer while rotating, a magnetic field generator disposed inside the developer carrier, a developer agitator disposed in the developer container, to agitate the developer while transporting the developer in an axial direction of the developer carrier; and a developer regulator housed in the casing, to adjust a layer thickness of the developer carried on the developer carrier. The developer carrier is exposed partly through an opening of the casing and facing the latent image carrier in a development area. The magnetic field generator has multiple magnetic poles including an attraction pole to attract the developer from the developer container to the developer carrier, a developer conveyance pole to keep the developer on the developer carrier downstream from the development area in a direction in which the developer carrier rotates to a developer release portion, and a release pole to separate the developer from the developer carrier and to return the developer to the developer container.
A predetermined gap is kept between an outer circumferential surface of the developer carrier and an inner wall of the casing at a portion downstream from the opening formed in the casing and upstream from the developer release portion in the direction in which the developer carrier rotates. Multiple recesses are formed in the outer circumferential surface of the developer carrier at intervals, and a pitch between adjacent recesses in a circumferential direction of the developer carrier is shorter than half a width of a magnetic flux density of the developer conveyance pole in a direction perpendicular to an axial direction of the developer carrier.
Another illustrative embodiment of the present invention provides a process cartridge removably installable in an image forming apparatus. The development device described above and at least one of the latent image carrier, a charging device, and a cleaning device are housed in a common casing.
Yet another illustrative embodiment provides an image forming apparatus that uses the above-described process cartridge.
In yet another illustrative embodiment of the present invention, a development device includes a developer container housed in a casing, a hollow, cylindrical nonmagnetic developer carrier rotatably disposed in the casing, to transport the developer while rotating, a first magnetic field generator disposed inside the developer carrier, a developer agitator disposed in the developer container, to agitate the developer while transporting the developer in an axial direction of the developer carrier, a developer regulator housed in the casing, to adjust a layer thickness of the developer carried on the developer carrier, and a second magnetic field generator positioned in a first end portion of the development device on a first side of the development device in the axial direction of the developer carrier. The developer carrier is exposed partly through an opening of the casing and facing the latent image carrier in a development area. The first magnetic field generator has multiple magnetic poles including an attraction pole to attract the developer from the developer container to the developer carrier, a developer conveyance pole to keep the developer on the developer carrier downstream from the development area in a direction in which the developer carrier rotates to a developer release portion, and a release pole to separate the developer from the developer carrier.
Multiple oval recesses are formed in the outer circumferential surface of the developer carrier at intervals, and a long axis of each of the multiple recesses is positioned oblique to the axial direction of the developer carrier such that a first longitudinal end thereof on the first side of the development device is positioned upstream in the direction in which the developer carrier rotates from a second longitudinal end thereof opposite the first longitudinal end for transporting the developer in a direction parallel to the axial direction of the developer carrier toward the first side of the development device as the developer carrier rotates. The second magnetic field generator generates a magnetic field for inhibiting the developer in the developer release portion from being moved in the direction toward the first side of the development device by the multiple recesses.
Yet another illustrative embodiment of the present invention provides a process cartridge removably installable in an image forming apparatus. The development device described above and at least one of the latent image carrier, a charging device, and a cleaning device are housed in a common casing.
Yet another illustrative embodiment provides an image forming apparatus that uses the above-described process cartridge.
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.
Referring now to the drawings, wherein like reference numerals designate identical or corresponding parts throughout the several views thereof, and particularly to
Referring to
Referring to
The main body 102 is shaped like a box, for example, and is installed on the floor. The main body 102 contains the sheet feeder 103, the pair of registration rollers 110, the intermediate transfer unit 104, the fixing device 105, the multiple laser writing units 122Y, 122M, 122C, and 122K, and the multiple process cartridges 106Y, 106M, 106C, and 106K.
For example, multiple sheet feeders 103 are provided in a lower portion of the main body 102. Each sheet feeder 103 contains multiple recording sheets 107 and is provided with a sheet cassette 123 that can be pulled out from and retracted into the main body 102 and a feed roller 124. The feed roller 124 is pressed against the recording sheet 107 on the top in the sheet cassette 123. The feed roller 124 picks up and feeds the recording sheet 107 on the top to the pair of registration rollers 110.
The pair of registration rollers 110 is positioned in a conveyance path through which the recording sheet 107 is fed from the sheet feeder 103 to the transfer roller 126. The pair of registration rollers 110 clamps the recording sheet 107 therein and then forwards the recording sheet 107 to the transfer roller 126, timed to coincide with the arrival of an image to be transferred onto the recording sheet 107.
The intermediate transfer unit 104 is provided above the process cartridges 106Y, 106M, 106C, and 106K. The intermediate transfer unit 104 includes a driving roller 128, a driven roller 127, the intermediate transfer belt 129, and intermediate transfer rollers 130Y, 130M, 130C, and 130K. The driving roller 128 is positioned facing the transfer roller 126 via the intermediate transfer belt 129 and driven by a driving source such as a motor. The driven roller 127 is rotatably supported by the main body 102. The intermediate transfer belt 129 is an endless belt and stretched around the driving roller 128 and the driven roller 127. As the driving roller 128 rotates, the intermediate transfer belt 129 rotates around the driving roller 128 and the driven roller 127 counterclockwise in
Each intermediate transfer roller 130 is positioned facing via the intermediate transfer belt 129 a photoconductor drum 108 included in the corresponding process cartridge 106. Yellow, magenta, cyan, and black toner images formed by the respective process cartridges 106 are transferred primarily from the respective photoconductor drums 108 by the respective intermediate transfer rollers 130 of the intermediate transfer unit 104 and superimposed one on another on the intermediate transfer belt 129, thus forming a multicolor toner image. The intermediate transfer belt 129 transports the multicolor toner image to the transfer roller 126, and the transfer roller 126 secondarily transfers the multicolor toner image onto the recording sheet 107. The transfer roller 126 forwards the recording sheet 107 onto which the toner image is transferred to the fixing device 105.
The fixing device 105 is positioned downstream from the transfer roller 126 in the direction in which the recording sheet 107 is transported and includes a pair of rollers 105a and 105b that clamps the recording sheet 107 therebetween. The fixing device 105 fixes the toner image on the recording sheet 107 transported from the transfer roller 126, clamped between the rollers 105a and 105b, with heat and pressure.
The laser writing units 122 are provided beneath the process cartridges 106. The laser writing units 122Y, 122M, 122C, and 122K correspond to the process cartridges 106Y, 106M, 106C, and 106K, respectively. Each laser writing unit 122 directs a laser beam onto the surface of the photoconductor drum 108 in the corresponding process cartridge 106, thus forming an electrostatic latent image, after a charge roller 109 charges the surface of the photoconductor drum 108 uniformly.
The process cartridges 106 is positioned between the intermediate transfer unit 104 and the respective laser writing units 122. The process cartridges 106 are removably insertable into the main body 102. The process cartridges 106 are arranged in parallel to each other in the direction in which the intermediate transfer belt 129 rotates.
As shown in
The cartridge casing 111 is removably insertable into the main body 102 and houses the charge roller 109, the photoconductor drum 108, the cleaning blade 112, and the development device 113. The charge roller 109 charges the surface of the photoconductor drum 108 uniformly. The photoconductor drum 108 is positioned across a predetermined gap from a development roller 115 of the development device 113. The photoconductor drum 108 is columnar and rotatable about an axis of rotation. As described above, the electrostatic latent image is formed by the corresponding layer writing unit 122 on the surface of each photoconductor drum 108. The development device 113 supplies toner to the electrostatic latent image formed on the surface of each photoconductor drum 108, thus developing it into the toner image. The photoconductor drum 108 rotates and conveys the toner image to a portion facing the intermediate transfer belt 129, and then the toner image is transferred onto the intermediate transfer belt 129. The cleaning blade 112 removes any toner remaining on the surface of the photoconductor drum 108 after image transfer.
As shown in
Image formation performed by the image forming apparatus 101 is described below.
Initially, the photoconductor drum 108 starts rotating, and the charge roller 107 charges the surface of the photoconductor drum 108 uniformly to an electrical potential of −700 V, for example. Then, the laser writing units 122 direct the laser beams onto the surfaces of the respective photoconductor drums 108, thus attenuating the exposed portion (i.e., image portion) of each photoconductor drums 108 to an electrical potential of −150 V, for example. Accordingly, electrostatic latent images are formed on the respective photoconductor drums 108. When the latent image is conveyed to a development area 131 (shown in
The multicolor toner image is then transferred onto the recording sheet 107 when the recording sheet 107 fed from the sheet feeder 103 by the feed roller 124 arrives at a position where the intermediate transfer belt 129 faces the transfer roller 126. The image is fixed by the fixing device 105 on the recording sheet 107, and thus the image forming apparatus 101 forms the multicolor image thereon.
Meanwhile, any toner remaining on the photoconductor drum 108 is removed by the cleaning blade 112, and the photoconductor drum 108 is prepared for subsequent image formation.
Additionally, the image forming apparatus 101 performs process control for reducing fluctuations in image quality due to changes in environmental conditions, deterioration of the components or developer over time, and the like. More specifically, the developability of the development device 113 is detected. For example, a given toner pattern is formed on the photoconductor drum 108 or the intermediate transfer belt 129 with the development bias kept constant, and the toner pattern is detected with a photosensor PS1 (shown in
The development device 113 is described in further detail below.
The developer supply unit 114 includes a developer container 117 and a pair of agitation screws 118 serving as developer agitators. For example, the developer container 117 is shaped like a box and has an axial length (i.e., a length in its longitudinal direction) similar to an axial length of the photoconductor drum 108. Additionally, a partition 119 extending in the longitudinal direction is provided inside the developer container 117. The partition 119 divides the developer container 117 into a first compartment 120 and a second compartment 121 that communicate with each other in both end portions in the longitudinal direction.
The developer is contained in both the first compartment 120 and the second compartment 121 of the developer container 117. The developer used in the present embodiment is two-component developer consisting essentially of toner particles and magnetic particles (also “magnetic powder”). Fresh toner is supplied as required by the toner supplier 201 to one of axial end portions of the first compartment 120, which is positioned farther from the development roller 115 than the second compartment 121 is. For example, toner particles are spherical fine particles produced through an emulsion polymerization method or a suspension polymerization method. It is to be noted that, alternatively, toner may be produced by smashing synthetic resin blocks in which various colorants and pigments are mixed or dispersed. The toner particles have a mean particle diameter of within a range from about 3 μm to 7 μm.
A preferable toner for the present embodiment can be produced as follows: At least polyester prepolymer having a functional group including a nitrogen atom, polyester, colorant, and a release agent are dispersed in an organic solvent, thus producing a toner material solution. Then, the toner is produced through at least one of cross-linking and elongation reaction of the toner material solution in a aqueous medium.
The magnetic carrier is contained in both the first and second compartments 120 and 121. The magnetic carrier particles have a mean particle diameter of within a range from about 20 μm to 50 μm.
The agitation screws 118 are provided in the first and second compartments 120 and 121, respectively. The long axes of the agitation screws 118 parallel the longitudinal direction of the developer container 117, the development roller 115, and the photoconductor drum 108. Each agitation screw 118 is rotatable about an axis of rotation. Each agitation screw 118 mixes the toner with the magnetic carrier and transports the developer in the axial direction while rotating.
In the configuration shown in the figures, the agitation screw 118 in the first compartment 120 transports the developer from the axial end portion to which the toner is supplied to the other axial end portion. The agitation screw 118 in the second compartment 121 transports the developer in the opposite direction to the direction in which the developer is transported (hereinafter “developer conveyance direction”) in the first compartment.
In the above-described configuration, while mixing the supplied toner and the magnetic carrier, the developer supply unit 114 transports the toner supplied to the end portion of the first compartment 120 to a downstream end portion in the developer conveyance direction and further to an upstream end portion of the second compartment 121 in the developer conveyance direction therein. The developer supply unit 114 further agitates the toner and the magnetic carrier in the second compartment 121 and then supplies the developer to the surface (i.e., the circumferential surface) of the development roller 115 while transporting it in the axial direction.
The casing 125 is box-shaped and is attached to the developer container 117 of the developer supply unit 114. The casing 125 and the developer container 117 together cover the development roller 115 and the like. Additionally, an opening 125a is provided in a portion of the casing 125 facing the photoconductor drum 108.
The development roller 115 is columnar and is positioned between the second compartment 121 and the photoconductor drum 108, adjacent to the opening 125a. It is to be noted that “cylindrical” and “columnar” used herein includes polygonal columnar shapes. The development roller 115 parallels both the photoconductor drum 108 and the developer container 117. As described above, the development roller 115 is positioned across the predetermined gap from the photoconductor drum 108. The gap between the development roller 115 and the photoconductor drum 108 serves as the development area 131 where the toner in the developer adheres to the photoconductor drum 108, thus developing the electrostatic latent image formed thereon into a toner image. The development roller 115 faces the photoconductor drum 108 in the development area 131.
The doctor blade 116 is provided in an end portion of the development device 113, on the side of the photoconductor drum 108. The doctor blade 116 is attached to the casing 125 at a position across a gap from the surface of the development sleeve 132. The doctor blade 116 removes the developer from the development sleeve 132 when the amount of the developer is excessive, that is, the thickness exceeds a predetermined thickness, and returns the excessive developer to the developer container 117, thereby adjusting the amount of developer conveyed to the development area 131.
The development roller 115 according to a first embodiment is described in further detail below.
As shown in
The magnet roller 133 is formed of a magnetic material and cylindrical. Multiple magnets are fixed inside the magnet roller 133, and thus the magnet roller 133 has multiple fixed magnetic poles. The magnet roller 133 is provided outside an outer circumferential surface of the metal core 134. The magnet roller 133 does not rotate, that is, its position is fixed relative to the metal core 134 or the casing 125.
The magnets fixed inside the magnet roller 133 for generating the fixed magnetic poles are shaped like long bars. The magnets extend in the longitudinal direction of the magnet roller 133, that is, the longitudinal direction of the development roller 115, over the entire longitudinal length of the magnet roller 133, for example. The magnet roller 133 is contained inside the development sleeve 132.
One of the multiple fixed magnets (P5 in
Another magnet faces the photoconductor drum 108 and generates a development pole that exerts a magnetic force on the outer surface of the development sleeve 132 in the development area 131. Thus, a magnetic field for image development is formed between the development sleeve 132 and the photoconductor drum 108. The magnetic field formed by the development pole causes the developer to form magnetic brushes, thereby transferring the toner of the developer attracted to the surface of the development sleeve 132 to the photoconductor drum 108.
At least one more magnet is present between the magnet generating the attraction pole and that generating the development pole. The magnet or magnets positioned between the attraction pole and the development pole generate a developer conveyance pole that exerts a magnetic force on the development sleeve 132, that is, the outer surface of the development roller 115 for transporting the developer (developer before development) toward the photoconductor drum 108 upstream from the development area 131 and for transporting the developer (developer after development) collected from the photoconductor drum 108 toward the developer container 117.
More specifically, the developer conveyance pole attracts the developer to the outer surface of the development sleeve 132. Then, the magnetic carrier particles contained in the developer stand on end on the development sleeve 132 along the lines of magnetic force generated by the developer conveyance pole. Then, the toner particles are adsorbed to the magnetic carrier particles standing on end on the development sleeve 132. That is, the development sleeve 132 adsorbs the developer to the outer surface thereof with the magnetic force exerted by the magnet roller 133.
In the development device 113, the toner and the magnetic carrier are agitated sufficiently in the developer supply unit 114, and the developer is attracted to the surface of the development sleeve 132 by the magnetic force exerted by the attraction pole. The development sleeve 132 rotates and conveys the developer attracted to the surface thereof by the attraction pole and the conveyance pole to the development area 131. Then, the doctor blade 116 adjusts the amount of the developer carried on the development sleeve 132, and then the developer is attracted to the photoconductor drum 108. Thus, the development device 113 carries the developer on the development roller 115, transports it to the development area 131, and then develops the latent image formed on the photoconductor drum 108 into the toner image.
Further, the development device 113 separates the developer used in image development from the development roller 115 and returns it to the developer container 117. The used developer is agitated with the developer contained in the second compartment 121 of the developer container 117 and is again used to develop the latent image formed on the photoconductor drum 108. It is to be noted that, when the toner concentration detector TD1 detects that the concentration of toner in the developer supplied from the developer supply unit 114 to the photoconductor drum 108 has decreased, the toner supplier 201 supplies fresh toner to the development device 113.
The development sleeve 132 is described in further detail below.
As shown in
As the material of the development sleeve 132, aluminum alloy excels in its lightness and easiness in processing. A6063, A5056, and A3003 are preferable as aluminum alloy. When stainless steel is used, SUS303, SUS304, and SUS316 are preferable. In the configuration shown in the figures, the development sleeve 132 is formed of aluminum alloy.
In the present embodiment, the development sleeve 132 has an external diameter of about 18 mm. The axial length of the development sleeve 132 is within a range of from about 300 mm to 350 mm when the maximum sheet size that the image forming apparatus 101 accommodates is A3 size.
As shown in
Additionally, each recess 139 is positioned with its long axis along the longitudinal direction of the development sleeve 132. That is, the long axis of each recess 139 is in parallel or substantially parallel to the longitudinal direction of the development sleeve 132. In the configuration shown in
As shown in
Additionally, the recesses 139 are V-shaped in its width direction or the circumferential direction of the development sleeve 132 as shown in the cross-sectional view shown in
In the present embodiment, the recesses 139 have a longitudinal length of from 1.0 mm to 2.3 mm (1.0 mm and 2.3 mm included), a width of from 0.3 mm to 0.7 mm (0.3 and 0.7 mm included), and a depth of from 0.05 mm to 0.15 mm (0.05 mm and 0.15 mm included). The number of the recesses 139 is from 50 to 250 per an area of 100 mm2 of the surface of the development roller 132. In other words, the cubic capacity (dimension) of the multiple recesses 139 in total is from 0.5 mm3 to 7.0 mm3 per an area of 100 mm2 of the surface of the development roller 132. The number of the recesses 139 is 1.0 to 3.0 per 1 mm in the circumferential direction of the photoconductor drum 108 that rotates together with the development roller 132. It is to be noted that the longitudinal direction of the development sleeve 132 is in the lateral direction in
Although, typically, the developer conveyance ability of the development sleeve 132 increases as the depth of the recesses 139 increases, the amount of developer carried thereon is more likely to become uneven cyclically due to the pitch of the recesses 139 (hereinafter “pitch unevenness in the amount of developer”) as the depth of the recesses 139 increases, similarly to grooved development sleeves. By contrast, although unevenness in the amount of developer is alleviated as the depth of the recesses 139 decreases, the developer conveyance ability of the development sleeve 132 also degreases. In particular, at present, pitch unevenness in the amount of developer can occur more frequently since image reproducibility is improved owing to progress in image formation technology, such as introduction of smaller toner particles and magnetic carrier particles and close development. Therefore, in the above-described development sleeve 132, while the depth of the recesses 139 is relatively small, the distribution density of the recesses 139 is increased to balance the developer conveyance ability and prevention of pitch unevenness in the amount of developer carried on the development sleeve 132.
Next, the surface processing device 1 for forming the recesses 139 in the surface of the development sleeve 132 is described below.
The base 3 is planar and placed on the floor or a table. An upper face of the base 3 is in parallel to a horizontal direction. The base 3 may be rectangular in a plane view.
The holder 4 includes a fixed holding portion 7 and a slidable holding portion 8. The fixed holding portion 7 includes a fixed pillar 9 standing on an end portion in the longitudinal direction of the base 3 and a rotary chuck 10 provided at an upper end portion of the fixed pillar 9. The rotary chuck 10 is shaped like a thick circular plate and supported by the upper end portion of the fixed pillar 9 rotatably about its center portion. The axis of rotation of the rotary chuck 10 is in parallel to the surface of the base 3, and a columnar chuck pin 11 is positioned in the center portion of the rotary chuck 10 (on the right side of the rotary chuck 10 in
The slidable holding portion 8 includes a slider 12, a slide pillar 13, and a rotary chuck 14 provided at an upper end portion of the slide pillar 13. The slider 12 is slidable along the surface of the base 3, that is, the axis of the chuck pin 11 of the rotary chuck 11. The position of the slider 12 can be fixed in the axial direction of the chuck pin 11 relative to the chuck pin 11 as required.
The slide pillar 13 stands on the slider 12. The rotary chuck 14 is shaped like a thick circular plate and attached to an output shaft of the motor 2 attached to the upper end portion of the slide pillar 13. The center of rotation of the rotary chuck 14 is coaxial with that of the chuck pin 11 of the rotary chuck 10 of the fixed holding portion 7. A columnar chuck pin 15 is provided on a center portion of the rotary chuck 14 (on the left side of the rotary chuck 14 in
In the holder 4, the development sleeve 132 before the recesses 139 are formed is supported between the chuck pins 11 and 15 in a state in which the slidable holding portion 8 is away from the fixed holding portion 7. As the slidable holding portion 8 approaches the fixed holding portion 7, leading edge portions of the chuck pins 11 and 15 enter the end portion of the development sleeve 132. Then, the slider 12 is fixed in position relative to the development sleeve 132 clamped between the chuck pins 11 and 15. Thus, the holder 4 holds the development sleeve 132 between the chuck pins 11 and 15.
The motor 2 is attached to the upper end portion of the slide pillar 13 of the slidable holding portion 8. The motor 2 rotates the rotary chuck 14 about its center portion, thereby rotating the development sleeve 132 supported between the chuck pins 11 and 15 around its axis of rotation.
The tool transport unit 5 includes a linear guide 16 and an actuator (not shown) for transportation. The linear guide 16 includes a rail 17 and a slider 18. The rail 17 is provided on the base 3. The rail 17 is linear. The longitudinal direction of the rail 17 is in parallel to the longitudinal direction of the base 3 as well as the chuck pins 11 and 15, that is, the axial direction of the development sleeve 132 supported between the chuck pins 11 and 15. The slider 18 is supported by the rail 17 slidably in the longitudinal direction of the rail 17.
The actuator for transportation is attached to the base 3 and moves the slider 18 in the longitudinal direction of the base 3 as well as the chuck pins 11 and 15, that is, the axial direction of the development sleeve 132 supported between the chuck pins 11 and 15.
The tool unit 6 includes a tool body 19, a motor 20 serving as a tool rotator, and an end mill 21 serving as a rotary tool. The tool body 19 is shaped like a pillar standing on the slider 18.
The motor 20 is attached to an upper end portion of the tool body 19. As shown in
The end mill 21 is columnar generally and is attached to an end portion of the output shaft 22 of the motor 20. Therefore, the axial direction of the end mill 21 is in parallel to the surface of the base 3 and crosses (in
As shown in
In the above-described tool unit 6, the motor 20 rotates the end mill 21 around the axis of rotation, thereby forming the recesses 139 in the surface of the development sleeve 132.
The controller 140 of the surface processing device 1 is a computer including a known CPU, a random access memory (RAM), and a read only memory (ROM), for example. The controller 140 is operatively connected to the motor 2, the actuator for transportation of the tool transport unit 5, the motor 20 of the tool unit 6, and controls the surface processing device 1 entirely.
When multiple recesses 139 are formed in the surface of the development sleeve 132, the controller 140 of the surface processing device 1 rotates the development sleeve 132 around its axis of rotation with the motor 2 and moves the tool unit 6 in the axial direction of the development sleeve 132 with the actuator for transportation while rotating the end mill 21 around its axis of rotation with the motor 20. Further, the controller 140 causes the cutting blades 24 to mill, that is, to chip the surface of the development sleeve 132 intermittently as the end mill 21 rotates, thereby forming the multiple recesses 139.
At this time, the radius of the curvature of each recess 139 is determined by the radius of the curvature of the outer rim of the cutting blades 24, and the depth of each recesses 139 is determined by the depth by which the cutting blades 24 chip the surface of the development sleeve 132 (hereinafter “milling amount”). The interval between the recesses 139 in the longitudinal direction of the development sleeve 132 is determined by the velocity at which the tool unit 6 moves. Further, the controller 140 controls the motor 2 serving as the driving source for rotation, the actuator for transportation of the tool transport unit 5, and the motor 20 of the tool unit 6 so that the following formula 1 can be satisfied.
N2=N1×{[m/(n/2)−0.5]} (1)
wherein N1 represents the rotational number of the development sleeve 132, m represents the number of the cutting blades 24 of the end mill 21.
The controller 140 adjusts those factors as required so as to change the size or arrangement density of the recesses 139. Thus, the surface processing device 1 mills the surface of the development sleeve 132.
Additionally, an input device 141 such as a keyboard and a display device 142 such as a display screen are connected to the controller 140.
Descriptions are given below of a sequence of processes for milling the surface of the development sleeve 132 by the above-described surface processing device 1 for forming the recesses 139.
Initially, an operator inputs the product number of the development sleeve 132 to be processed to the controller 140 via the input device 141. The controller 140 sets the end mill 21 serving as the rotary tool of the tool unit 6 at an initial position, that is, an end portion of the development sleeve 132 in its longitudinal direction, and then holds the development sleeve 132 with the holder 4. At that time, the development sleeve 132 and chuck pins 11 and 15 are positioned coaxially.
Then, the operator instructs the surface processing device 1 to initiate the processing via the input device 141, and the controller 140 drives the motor 2, the actuator of the tool transport unit 5, and the motor 20 of the tool unit 6 based on the above-described formula 1. Then, the cutting blades 24 of the end mill 21 rotate around the axis of rotation and chip the surface of the development sleeve 132 intermittently, thus forming the recesses 139 in the surface of the development sleeve 132. In other words, the recesses 139 are formed in the surface of the development sleeve 132 through milling performed by the tool unit 6 that rotates around its axis of rotation.
Further, because the motor 2, the actuator of the tool transport unit 5, and the motor 20 of the tool unit 6 are driven simultaneously, the development sleeve 132 positioned crossing (in
When the end mill 21 is positioned at a processing completion opposition, that is, the end portion of the development sleeve 132 opposite the initial position and thus milling of the development sleeve 132 is completed, the motor 2, the actuator of the tool transport unit 5, and the motor 20 of the tool unit 6 are stopped. The slidable holding portion 8 is disengaged from the fixed holding portion 7, and the development sleeve 132 in which the multiple recesses 139 are formed is released from the chuck pins 11 and 15, after which another development sleeve 132 is held by the holder 4. Thus, the surface of the development sleeve 132 is processed to form the recesses 139, and the development sleeve 132 shown in
Although blasted (e.g., sandblasted) development sleeve includes projections on their surfaces, on projections are formed on the surface of the development sleeve produced though the above-described process. Further, the recesses 139 formed in the above-described process are relatively large. These features has advantages. For example, the recesses 139 are less likely to wear over time, and accordingly the decrease in the developer conveyance ability can be reduced.
Additionally, the developer can accumulate in the recesses 139 that are positioned regularly not to overlap each other in the surface of the development sleeve 132. That is, the portions where the developer accumulates are arranged regularly, which can prevent or reduce unevenness in the image density. Further, the amount of developer carried on the development sleeve 132 can be increased for maintaining high image quality in high speed image forming apparatuses.
Moreover, the regular arrangement of the recesses 139 can attain the following advantages. The processing conditions can be adjusted easily for balancing expansion of useful life of the development sleeve 132 and increasing the amount of developer carried thereon. The recesses 139 can be formed reliably with the set conditions and processing can be easier.
Further, a sufficient developer conveyance ability can be attained because the multiple recesses 139 are arranged regularly with the long axes of the recesses 139 along the longitudinal direction of the development sleeve 132 and the cubic capacity of the recesses 139 in total is equal to or greater than 0.5 mm3 per an area of 100 mm2 of the surface of the development roller 132.
Since two of the multiple recesses 139 adjacent to each other in the circumferential direction of the development sleeve 132 are shifted from each other in the longitudinal direction thereof, the recesses 139 can extend or be distributed entirely and uniformly. That is, there are no portions where no recesses 139 are present or portions where the recesses 139 are denser than other portions. Therefore, unevenness in the amount of developer attracted to the surface of the development sleeve 132 can be prevented or reduced, thus preventing or reducing unevenness in the image density.
Next, variations of the recesses 139 are described below with reference to
Although the recesses 139 are V-shaped in cross section in the circumferential direction of the development sleeve 132 as shown in
In the case shown in
Additionally, although the recesses 139 are V-shaped in cross section in the circumferential direction of the development sleeve 132 as shown in
Additionally, although, in the description above regarding
Further, although the recesses 139 are oval in the description above regarding
As described above, the image forming apparatus 101 shown in
Next, the magnetic poles of the development device 113 according to the present embodiment are described in further detail below.
The development sleeve 132 rotates in the direction indicated by arrow A1 shown in
A predetermined gap is provided between an inner wall of the casing 125 and the outer circumferential surface of the development sleeve 132 at a position downstream form the opening 125a and upstream from the developer release portion 137 in the rotational direction of the development sleeve 132. This gap, that is, the distance between the inner wall of the casing 125 and the outer circumferential surface of the development sleeve 132 is hereinafter referred to as a casing gap GP. The magnetic force exerted by at least one of the developer conveyance poles P2 and P3 acts in the casing gap GP.
The casing gap GP is allowed between the development sleeve 132 and the inner wall (i.e., the casing 125) of the development device 113 to prevent scattering of toner. More specifically, the casing gap GP is positioned adjacent to the opening 125a, between a surface of the development sleeve 132 and the inner wall where the developer passes after passing through the development area 131. The casing gap GP faces one of the multiple magnetic poles of the magnet roller 133.
The casing gap GP is described in further detail below with reference to
In
Providing the above-described casing gap GP can cause an airflow, flowing into the development device 113 (hereinafter “sucking-in airflow”), that transports the developer in the rotational direction of the development sleeve 132 when the developer on the development sleeve 132 passes through the casing gap GP between the inner wall of the casing 125 and the outer circumferential surface of the development sleeve 132. In other words, because the developer stands on end on the development sleeve 132 along the lines of magnetic force generated by the magnet roller 133, an airflow flowing into the development device 113 is caused when the developer standing on end on the development roller 132 passes through the casing gap GP as the development sleeve 132 rotates. The sucking-in airflow can prevent or reduce scattering of toner outside the device.
It is to be noted that, when development sleeves having multiple recesses formed in its surface, such as the development sleeve 132 according to the present embodiment, are used, the intervals between the recesses 139 in the circumferential direction of the development sleeve 132 should be set properly to prevent scatting of toner outside the development device 113. More specifically, retained in the recesses 139, the developer particles stand on end one on another. Therefore, if the interval between the recesses 139 in the circumferential direction of the development sleeve 132 is relatively large, air might leak through gaps between the developer particles standing on end one on another in the recesses 139, thus making it difficult to generate the sucking-in airflow. As a result, toner scatters outside the development device 113.
Additionally, the developer particles stand on end on the surface of the development sleeve 132 along the lines of magnetic force generated by the developer conveyance poles P2 and P3 of the magnet roller 133, and this phenomenon can occur reliably on the surface of the development sleeve 132 corresponding to half a width of the magnetic flux density of the developer conveyance poles P2 and P3 in the direction perpendicular to the longitudinal direction. Therefore, in the present embodiment, an arrangement pitch (interval) Pc of the recesses 139 in the circumferential direction thereof is smaller than a circumferential length of the development sleeve corresponding to the half width of the magnetic flux density of the developer conveyance poles P2 and P3 (hereinafter “the casing gap width”).
For example, regarding the developer conveyance pole P3, the arrangement pitch Pc of the recesses 139 in the circumferential direction of the development sleeve 132 is as follows. Referring to
It is to be noted that, although the arrangement pitch Pc of the recesses 139 in the circumferential direction of the development sleeve 132 is set based on the half width of the magnetic flux density of the developer conveyance pole P3 in the direction perpendicular to the longitudinal direction in the description above, alternatively, it can be set based on the half width of the magnetic flux density of the developer conveyance pole P2 in the direction perpendicular to the longitudinal direction. The arrangement pitch of the recesses 139 can be changed by adjusting the variables of the surface processing device 1 shown in
Additionally, it is preferred that an arrangement pitch Pa between the recesses 139 in the axial direction of the development sleeve 132 be equal to or shorter than a length L of each recess 139 in the axial direction of the development sleeve 132. In other words, adjacent two recesses 139 in the circumferential direction of the development sleeve 132 are shifted from each other in the axial direction of the development sleeve 132, and the amount by which the adjacent recesses 139 are shifted from each other is equal to or shorter than the length L of the recess 139 in the axial direction of the development sleeve 132. With this arrangement, no gap is present in the axial direction of the development sleeve 132 between end portions of two recesses 139 adjacent to each other in the circumferential direction of the development sleeve 132. Therefore, when the development sleeve 132 rotates, in the end portions of two recesses 139 adjacent to each other in the axial direction, no air or little air leak through the gaps between the developer particles standing on end on the recesses 139. Accordingly, an adequate amount of sucking-in airflow can be generated.
Additionally, in the present embodiment, the development device 113 is removably installable in the main body 102 of the image forming apparatus 101, and an airflow flowing from the front side to the back side in the direction in which the development device 113 is installable in the apparatus (hereinafter “installation direction of the development device 113”) is generated in the above-described gap between the inner wall of the casing 125 and the outer circumferential surface of the development sleeve 132.
As shown in
Additionally, in the present embodiment, to generate the airflow flowing from the front side to the back side in the installation direction of the development device 113 in the gap between the inner wall of the casing 125 and the outer circumferential surface of the development sleeve 132, the oval recesses 139 may be positioned with their long axes oblique to the axial direction of the development sleeve 132.
As shown in
Additionally, shown in
As described above, an effect of the first embodiment is to reliably generate the airflow to prevent or reduce scattering of toner that occurs when the developer standing on end on the development sleeve passes through the casing gap in a configuration in which multiple recesses are formed at intervals in the surface of the development sleeve.
Therefore, the development device 113 according to the present embodiment includes the development roller 115 serving as the developer carrier, the developer container 117 that contains two-component developer to be carried on the surface of the development roller 115, the doctor blade 116 serving as the developer regulator that adjusts the layer thickness of the developer carried on the development roller 115, and the casing 125 in which the development roller 115, the developer container 117, and the doctor blade 116 are housed. The development roller 115 includes the development sleeve 132 that is a nonmagnetic rotatable hollow cylinder and the magnet roller 133 serving as the magnetic field generator, disposed inside the development sleeve 132. The development roller 115 transports the developer carried on the circumferential surface of the development sleeve 132 due to the magnetic force exerted by the magnet roller 133. The developer in the developer container 117 is attracted onto the development roller 115 due the magnetic force exerted by the magnet roller 133, and then the doctor blade 116 adjusts the amount of the developer carried on the development roller 115. Subsequently, the developer passes through the development area, where the circumferential surface of the development sleeve 132 is partly exposed through the opening 125a of the casing 125 and faces the photoconductor drum 108 serving as the latent image carrier, and then in returned to the developer container 117. The magnet roller 133 has the developer conveyance poles P2 and P3 serving as the magnetic field generator for generating the magnetic field that exerts the force for transporting the developer that has passed through the development area 131 to the developer release portion 137, where the developer is separated from the development sleeve 132. The predetermined gap is provided between the inner wall of the casing 125 and the outer circumferential surface of the development sleeve 132 downstream form the opening 125a and upstream from the developer release portion 137 in the rotational direction of the development sleeve 132. Further, the multiple recesses 139 are formed in the surface of the development sleeve 132 at intervals. The arrangement pitch Pc of the recesses 139 in the circumferential direction of the development sleeve 132 is shorter than the length WGP3 that is equal to half the width of the magnetic flux density of the developer conveyance pole P3 in the direction perpendicular to the longitudinal direction. With the pitch Pc of the recesses 139 in the circumferential direction thus set, at least two recesses 139 are present in the portion of the development sleeve 132 having a length equal to half the width of the magnetic flux density, and the developer particles contained in the recesses 139 stand on end one on another therein. The developer particles are thus piled one on another in the recesses 139, dividing the casing gap positioned between the circumferential surface of the development sleeve 132 and the inner surface of the casing 125. Accordingly, as the development sleeve 132 rotates, the air held in the divided casing gaps can be transported to the developer container 117. When the air is transported to the developer container 117, a negative pressure is generated in the casing gap, thus generating the sucking-in airflow that flows from the outside the development device 113 through the opening 125a into the device, which can prevent or reduce scattering of toner out side the device.
Additionally, adjacent two recesses 139 in the circumferential direction of the development sleeve 132 are shifted from each other in the axial direction of the development sleeve 132, and the amount by which the adjacent recesses 139 are shifted from each other is equal to or shorter than the length L of the recess 139 in the axial direction of the development sleeve 132. With this arrangement, no gap is present in the axial direction of the development sleeve 133 between end portions of two recesses 139 adjacent to each other in the circumferential direction of the development sleeve 132. Therefore, when the development sleeve 132 rotates, air is less likely to leak through the gaps between the developer particles standing on end one on another in the recesses 139 in the end portions of two adjacent recesses 139 in the axial direction. Accordingly, an adequate amount of sucking-in airflow can be generated.
Further, the development device 113 is removably installable in the main body 102 of the image forming apparatus 101 in the axial direction of the development sleeve 132, and the airflow flowing from the front side to the back side in the installation direction of the development device 113 is generated. Therefore, even when toner that is not adsorbed to the carrier but floats in the air adjacent to the opening 125a on the front side in the installation direction of the development device 113, the toner can be transported by the airflow flowing to the back side portion of the development device 113, thus preventing or reducing scattering of toner outside the development device 113.
Moreover, the arrangement pitch Pc of the recesses 139 in the circumferential direction is smaller on the back side than the front side in the installation direction of the development device 113. In the configuration shown in
Additionally, in the present embodiment, each recess 139 is ellipsoidal or oval, and the long axis of the recess 139 is oblique to the axial direction of the development sleeve 132. In particular, the angle of the recess 139 relative to the axial direction of the development sleeve 132 is determined so as to generate the airflow flowing from the front to the back in the installation direction of the development device 113. More specifically, as shown in
As the development sleeve 132 rotate, the air flows from the front to the back in the installation direction of the development device 113 by the developer particles standing on end one on another in the recesses 139. In the developer release portion 137, the developer is separated from the development sleeve 132 toward the back side in the installation direction of the development device 113. Thus, as the development sleeve 132 rotates, the airflow flowing toward the back side in the installation direction of the development device 113 can be generated.
A development roller 115-1 according to a second embodiment and a development device 113-1 including it is described below.
It is to be noted that components of the development device 113-1 (shown in
The development roller 115-1 shown in
A right end portion 134a (second axial end portion) and a left end portion 134b (first axial end portion) of the magnet roller shaft 134-1 are provided with bearings 135a and 135b, respectively, and the bearings 135a and 135b rotatably support a right flange 132a and a left flange 132b, respectively. Since the right and left flanges 132a and 132b are fixed inside both axial end portions of the development sleeve 132, the development sleeve 132 can rotate around the axis of rotation of the magnet roller shaft 134-1 by rotating a rotary shaft 132c of the left flange 132b.
In
The magnet roller shaft 134-1 is formed of a magnetic metal material. Thus, the right end portion 134a and the left end portion 134b of the magnet roller shaft 134-1, positioned outside axial edge faces of a main body of the magnet roller 133-1 are different in length. In the configuration shown in
In the present embodiment, multiple recesses 139 are formed in the surface of the development sleeve 132, and each recess 139 is positioned oblique to the axial direction of the development sleeve 132 considering the effects of the right-end magnetic field T1 and the left-end magnetic field T2. More specifically, as shown in
Herein, when multiple oval recesses 139 each positioned oblique to the axial direction of the development sleeve 132 are formed in the surface of the development sleeve 132 as described above, the developer might accumulate on the downstream side (the left side in
In view of the foregoing, the second embodiment further includes a second magnetic field generator for preventing carry-over of developer, thus alleviating unevenness in the image density while keeping the apparatus relatively compact.
More specifically, as shown in
The magnet 149 is positioned facing the magnetic poles N2 and N3 of the magnet roller 133-1, serving as the developer release poles, via the development sleeve 132 with the north pole of the magnet 149 facing the development roller 115-1. Further, as shown in
Therefore, carry-over of developer in the left axial end portion of the development sleeve 132 can be reduced, and accordingly the longitudinal length of the development roller 115-1 can be reduced.
Referring to
It is to be noted that, in the comparative example shown in
The magnetic poles N2 and N3 serving as the developer release poles generate lines of magnetic force for separating the developer from the development sleeve 132, and the magnet 149 generates a magnetic field for deflecting the lines of magnetic force, among those generated by the magnetic poles N2 and N3 in the developer release portion 137, that pass through the axial end portion to the inner side in the axial direction of the development sleeve 132. More specifically, with its side whose polarity is identical to polarity (north) of the magnetic poles N2 and N3 facing the development sleeve 132, the magnet 149 is positioned, in the developer conveyance direction of the development sleeve 132 (rotational direction of the development sleeve 132), within a area from the normal line H1, passing through the maximum density point of the magnetic flux generated by the magnetic pole N2 on the surface of the development sleeve 132 in the normal direction, to the normal line H2, passing through the maximum density point of the magnetic flux generated by the magnetic pole N3 on the surface of the development sleeve 132 in the normal direction. The magnet 149 is positioned outside the body of the magnet roller 133-1 in the axial direction of the development sleeve 132. With this arrangement, as described above, in the release portion 137 on the development sleeve 132, in the area facing the magnet roller 133-1, the direction of the lines of magnetic force in the axial end portion can be deflected close to the direction perpendicular to the axial direction of the development sleeve 132, that is, to such a direction for dropping the developer from the development sleeve 132. Because the force for separating the developer from the development sleeve 132 in the axial end portion can be increased, the developer can be efficiently separated from the surface of the development sleeve 132 in the axial end portion. Consequently, the axial length (i.e., width) of area facing the magnet roller 133 in which the developer is likely to be carried over can be reduced. Therefore, even when the axial length of the area facing the magnet roller 133-1 is reduced, unevenness in image density caused by carry-over of developer can be smaller. Thus, development device can be more compact in the axial direction of the development sleeve 132.
Additionally, as shown in
It is to be noted that another magnet may be provided in the right end portion of the development device 113-1 in addition to the left end portion in the axial direction of the development sleeve 132.
Similarly to the development roller 115-1 shown in
It is to be noted that the magnetic force of the magnet 149 may be stronger than that of the magnet 150 because, in the left end portion, the force transporting the developer to the left is generated in the developer release portion 137 due to the recesses 139 formed in the surface of the development sleeve 132. The force transporting the developer to the left can be alleviated when the magnetic force of the magnet 149 in the left end portion is stronger than that of the magnet 150. Thus, releasability of the developer from the development sleeve 132 can be substantially equal in the both end portions.
It is to be noted that the above-described features of the embodiments can adapt to other development devices than those shown in the figures.
A third embodiment is described below with reference to
As described above, an effect of the above-described second and third embodiments is to alleviate carry-over of developer on the surface of the development sleeve, thereby reducing unevenness in image density, while preventing an increase in the size of the device in a configuration in which the developer is moved to one end in the axial direction of the development sleeve due to the oblique recesses formed in the surface of the development sleeve as the development sleeve rotates.
More specifically, the development device according to the second and third embodiments includes the magnet roller shaft 134-1, serving as a magnetic support shaft, that projects outside the both axial ends of the body of the magnet roller 133-1. The magnet roller shaft 134-1 includes the right and left end portions 134a and 134b of the magnet roller shaft 134-1 of unequal axial length. The left end portion 134b on the downstream side in the direction in which the developer in the developer release portion 137 is moved due to the recesses 139 as the development sleeve 132 rotates is shorter than the right end portion 134a on the opposite side. With this configuration, in the left end portion of the development roller 115-1, the developer is directed inside the imaging area and falls from the development sleeve 132, affected by the left-end magnetic field T2 around the left end portion 134b. In the right end portion of the development roller 115-1, where the degree of margin for the occurrence of carry-over of developer is lower due to the effects of the right-end magnetic field T1 around the right end portion 134a, the developer falls from the development sleeve 132 toward inside the imaging area.
Additionally, in the above-described embodiments, toner particles included in the developer have a volume average particle diameter of within a range from 3 μm to 8 μm. Additionally, the ratio of the volume average particle diameter (Dv) to the number average particle diameter (Dn) is within a range of from 1.00 to 1.40 (Dv/Dn). To reproduce fine-dot image greater than 600 dpi, the ratio of the volume average particle diameter (Dv/Dn) is preferably closer to 1.00 for attaining a sharp particle diameter distribution. In the case of toner having such a small diameter and a narrow particle diameter distribution, the distribution of electrical charge can be uniform, and thus high-quality image with scattering of toner in the backgrounds reduced can be produced. Further, in electrostatic transfer methods, the transfer ratio can be improved.
Further, the toner used in the above-described embodiments has a first shape factor SF-1 within a range of from 100 to 180 and a second shape factor SF-2 within a range of from 100 to 180. The toner particle is a sphere when the first shape factor SF-1 is 100. The larger the SF-1 becomes, the more the toner particle becomes amorphous. The toner particle is flat when the first shape factor SF-2 is 100. The larger the first shape factor SF-2 is, the more irregular the toner particle is. When either or both of the first shape factor SF-1 and the second shape factor SF-2 exceed 180, fluidity and circularity of the developer and transfer efficiency may be deteriorated.
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 |
---|---|---|---|
2010-027208 | Feb 2010 | JP | national |
2010-036809 | Feb 2010 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
7043182 | Sakai et al. | May 2006 | B2 |
7599650 | Katoh et al. | Oct 2009 | B2 |
7813680 | Masuda et al. | Oct 2010 | B2 |
7925192 | Kojima et al. | Apr 2011 | B2 |
20070127952 | Terashima et al. | Jun 2007 | A1 |
20090060591 | Kojima et al. | Mar 2009 | A1 |
20090245889 | Koetsuka et al. | Oct 2009 | A1 |
Number | Date | Country |
---|---|---|
101382761 | Mar 2009 | CN |
2003-208027 | Jul 2003 | JP |
2009-80447 | Apr 2009 | JP |
2009-244611 | Oct 2009 | JP |
2009-251450 | Oct 2009 | JP |
Entry |
---|
Chinese Office Action issued Apr. 19, 2012, in Patent Application No. 201110035563.0. |
Japanese Office Action issued Oct. 25, 2013, in Japan Patent Application No. 2010-027208. |
Japanese Office Action issued Nov. 29, 2013, in Japan Patent Application No. 2010-036809. |
Number | Date | Country | |
---|---|---|---|
20110194874 A1 | Aug 2011 | US |