This application is related to Japanese patent application No. 2010-116489 filed on May 20, 2010 whose priority is claimed under 35 USC §119, the disclosure of which is incorporated by reference in its entirety.
1. Field of the Invention
The present invention relates to a developing device using a dual-component developer and an image forming apparatus including the same.
2. Description of the Background Art
In recent years, for electrophotographic image forming apparatuses supporting full-color and high-quality images, a dual-component developer (hereinafter simply referred to as the “developer”) which exhibits an excellent charge performance stability as to a toner is in widespread use.
The developer is made up of the toner and a carrier, which are agitated in a developing device and frictionally rubbed with each other to produce an appropriately electrified toner.
In the developing device, the electrified toner is supplied onto a surface of a developing roller. The toner is moved by an electrostatic attraction from the developing roller to an electrostatic latent image formed on a surface of a photoconductor drum.
Thus, a toner image based on the electrostatic latent image is formed on the photoconductor drum.
Further, there has been an increasing demand for the image forming apparatuses that operate faster and that are miniaturized, which is associated with the necessity to electrify the developer quickly and sufficiently and to convey the developer quickly.
To this end, Prior Art 1 proposes a circulative developing device including first and second developer conveying passages divided by a partitioning plate provided in a developer vessel, first and second communicating paths that allow the first developer conveying passage and the second developer conveying passage to communicate with each other at opposite ends, and first and second auger screws that are arranged in the first and second developer conveying passages to convey a developer in directions opposite to each other (for example, see Japanese Unexamined Patent Publication No. 2001-255723).
In the developing device described above, the developer in the first developer conveying passage is conveyed by the first auger screw to an interior wall of the developer vessel located at the most downstream side of the first developer conveying passage, and is pushed toward the first communicating path due to a pressure from the developer conveyed from the upstream side, thereby transferring to the second developer conveying passage.
On the other hand, the developer in the second developer conveying passage is conveyed by the second auger screw to the interior wall of the developer vessel at the downstream side of the second developer conveying passage, and is pushed toward the second communicating path due to a pressure of the developer conveyed from the upstream side, thereby transferring to the first developer conveying passage.
In this manner, the developer is circulated between the first developer conveying passage and the second developer conveying passage.
Prior Art 2 proposes a circulative developing device same as that in the Prior Art 1 except that, on helical blades of first and second auger screws, helical directions of helical blades at an end of the downstream side in a conveying direction of a developer are opposite (for example, see Japanese Unexamined Patent Publication No. 2009-109741).
In the developing device described above, the developer in the first developer conveying passage is conveyed to the helical blade, having the reverse helical direction, of the first auger screw, and then, pushed toward the first communicating path due to a pressure caused between the conveyed developer and a developer conveyed from the upstream side of the first developer conveying passage, thereby transferring to the second developer conveying passage.
On the other hand, the developer in the second developer conveying passage is conveyed to the helical blade, having the reverse helical direction, of the second auger screw, and then, pushed toward the second communicating path due to a pressure caused between the conveyed developer and a developer conveyed from the upstream side of the second developer conveying passage, thereby transferring to the first developer conveying passage.
In this manner, the developer is circulated between the first developer conveying passage and the second developer conveying passage.
However, in the developing devices described in Prior Art 1 and Prior Art 2, the developer receives a violent pressure in an advancing direction, and receives a shear force in such a pressurized state, at the position, facing the communicating path, at the end of the downstream side of the auger screw.
Due to a generation of heat and the shear force caused by a stress, a flow improver, which is an external additive of a toner, is unfavorably be embedded into a particle of a resin constituting the toner, which might cause an extreme deterioration in a flow property of the developer, and hence, a phenomenon in which the conveyance of the developer becomes difficult might be produced.
Consequently, it becomes difficult to supply the developer in a sufficient amount to a photoconductor drum through a developing roller, which might cause a problem that a density of an image printed on a recording medium is reduced.
The present invention has been made in consideration of the problem described in the foregoing, and an object thereof is to provide a developing device that can suppress a sharp pressure rise to a developer during a circulating conveyance in order to reduce a stress to the developer for preventing a deterioration in an image density, and an image forming apparatus including the same.
In order to achieve the above object, the present invention provides a developing device to be installed in an electrophotographic image forming apparatus including a photoconductor drum that is to have an electrostatic latent image formed on a surface thereof, the developing device including:
a developer vessel that accommodates a developer containing a toner and a carrier; a toner supply port for supplying the toner into the developer vessel; a developing roller that is disposed in the developer vessel and that rotates while carrying the developer to supply the toner onto the surface of the photoconductor drum having the electrostatic latent image formed thereon; a developer conveying passage that is disposed between a position in the developer vessel where the toner is supplied and the developing roller; a developer conveying helical member that is rotatably disposed in the developer conveying passage to convey the developer in the developer conveying passage to the developing roller, wherein
the developer conveying passage includes: a first developer conveying passage associated with the toner supply port and a second developer conveying passage associated with the developing roller, the first developer conveying passage and the second developer conveying passage being defined by a partitioning plate extending in parallel to an axial direction of the developing roller; and a pair of communicating paths that establish a communication between the first developer conveying passage and the second developer conveying passage at opposite sides in the axial direction, and
the developer conveying helical member includes a first developer conveying helical member disposed in the first developer conveying passage and a second developer conveying helical member disposed in the second developer conveying passage, wherein
the first and second developer conveying helical members include a rotary shaft and a helical blade fixed to an outer peripheral surface of the rotary shaft, and at least one of the first and second developer conveying helical members includes an end blade at one end of the rotary shaft at a downstream side in a conveying direction of the developer, wherein
the end blade includes a circumferential-direction agitating blade portion whose radial projecting size gradually increases toward the downstream side in the conveying direction; and a helical blade portion integrally wound around an outer periphery of the circumferential-direction agitating blade portion in the same helical direction as that of the helical blade, wherein,
in the first and second developer conveying passages, the first and second developer conveying helical members convey the developer in directions opposite to each other, and the end blade agitates the developer in a circumferential direction of the rotary shaft at the downstream side in the conveying direction, such that the developer circulates through the first and second developer conveying passages.
Further, according to another aspect of the present invention, there is provided an image forming apparatus including: a photoconductor drum that is to have an electrostatic latent image formed on a surface thereof; a charging device that electrifies the surface of the photoconductor drum; an exposure device that forms the electrostatic latent image on the surface of the photoconductor drum; the developing device which supplies a toner to the electrostatic latent image on the surface of the photoconductor drum to form a toner image; a toner supplying device that supplies the toner to the developing device; a transferring device that transfers the toner image on the surface of the photoconductor drum to a recording medium; and a fusing device that fuses the toner image on the recording medium.
According to the developing device of the present invention, when the first developer conveying helical member has the end blade, for example, not only a force in the conveying direction by the helical blade portion of the end blade but also an agitating force in the circumferential direction of the rotary shaft by the circumferential-direction agitating blade portion are applied to the developer conveyed toward the downstream side of the first developer conveying passage by the first developer conveying helical member.
Therefore, the developing device according to the present invention can ease the pressure, which is applied to the developer conveyed toward the most downstream side of the first developer conveying passage because the developer is pressed against the interior wall of the developer vessel at the downstream side, so as to reduce a stress. As a result, the developing device of the present invention can smoothly transfer the developer toward the communicating path without being stayed, while reducing the deterioration in the flow property of the developer, at the downstream side of the first developer conveying passage.
This is also applied to the case in which the second developer conveying helical member includes the end blade.
Accordingly, the image forming apparatus provided with the developing device according to the present invention can allow the developer to smoothly circulate through the first developer conveying passage and the second developer conveying passage, whereby the developer in a sufficient amount is supplied to the photoconductor drum through the developing roller. Consequently, an image can be printed on a recording medium with a satisfactory image density.
The developing device of the present invention is a circulative developing device including the developer vessel, the toner supply port, the developing roller, the first and second developer conveying passages, and the first and second developer conveying helical members, and is installed in the electrophotographic image forming apparatus such as a monochrome or full-color copier, printer, facsimile machine, or multi function peripheral possessing the functions of the foregoing apparatuses.
In the developing device described above, the first and second developer conveying helical members include the rotary shaft, and the helical blade mounted to the outer peripheral surface of the rotary shaft.
At least one of the first and second developer conveying helical members includes the end blade at one end of the rotary shaft at the downstream side in the conveying direction of the developer. From the viewpoint of further reducing the deterioration in the flow property of the developer, it is preferable that the end blade is mounted to both the first and second developer conveying helical members.
Hereinafter, the mere description of the “developer conveying helical member” indicates one or both of the first and second developer conveying helical members, and the mere description of the “developer conveying passage” indicates one or both of the first and second developer conveying passages.
The end blade of the developer conveying helical member includes the circumferential-direction agitating blade portion whose radial projecting size gradually increases toward the downstream side in the conveying direction; and the helical blade portion integrally wound around the outer periphery of the circumferential-direction agitating blade portion in the same helical direction as that of the helical blade. Specifically, the end blade can be configured as end blades A and B described below. The end blades A and B correspond to a first embodiment and a second embodiment described later.
<End Blade A>
The circumferential-direction agitating blade portion of the end blade A has plural projecting pieces provided on the rotary shaft with a predetermined space in the circumferential direction. A radial projecting size of each of these projecting pieces gradually increases toward the downstream side in the conveying direction. In other words, each of the projecting pieces is formed such that an area of a face arranged in the circumferential direction of the rotary shaft increases toward the downstream side.
With the structure of the end blade A described above, an agitating force (mainly, a force in the rotating direction) in the circumferential direction by the projecting pieces increases toward the downstream side at the position of the end blade A.
As a result, the pressure and stress applied to the developer because of the developer being pressed against the interior wall face of the developer conveying passage at the downstream side are decreased to reduce the deterioration in the flow property of the developer, whereby the developer can smoothly be transferred to the communicating path without being stayed at the downstream side of the developer conveying passage.
In this case, the projecting piece is formed into a right-angled triangle, or into a shape in which a long side of a right-angled triangle is in a step-like form.
The number of the projecting pieces is not particularly limited. It is preferable that two to four projecting pieces are equally spaced from the viewpoint of preventing the stay of the developer and of acquiring a sufficient agitating force in the circumferential direction of the rotary shaft.
When the number of the projecting pieces exceeds four, the gap formed between the adjacent projecting pieces becomes small, so that the developer is easy to be accumulated and stayed in the gap. On the other hand, when the number of the projecting pieces is less than two, the agitating force in the circumferential direction of the rotary shaft is significantly lowered.
It is suffice that the projecting pieces are arranged on a radial line with the center of the rotary shaft being defined as a center. The projecting pieces may tilt at an angle of up to about 15° with respect to the radial line in the circumferential direction (rotating direction or reverse rotating direction). Alternatively, the projecting pieces may totally be curved in the circumferential direction, wherein a base end thereof near the rotary shaft may be arranged on the radial line, and a tip end thereof may tilt at an angle of up to about 15° in the circumferential direction.
When the developer vessel includes the semicylindrical interior wall faces, each constituting the first and second developer conveying passages, a maximum radial projecting size of the projecting piece from the center of the rotary shaft is set to be 0.8 to 0.9 times the distance from the center of the rotary shaft to the semicylindrical interior wall face.
With this structure, the maximum radial projecting size of the projecting piece has an appropriate length, whereby the agitating force for the developer can sufficiently be acquired, while suppressing the stress to the developer.
When the maximum radial projecting size of the projecting piece from the center of the rotary shaft exceeds 0.9 times the distance from the center of the rotary shaft to the semicylindrical interior wall face, a shear force caused between the semicylindrical interior wall face and the projecting piece increases, which might increase the stress to the developer. When the maximum radial projecting size of the projecting piece from the center of the rotary shaft is less than 0.8 times, the agitating force applied to the developer cannot sufficiently be acquired.
When the end blade A is used, it is preferable that the rotary shaft rotates such that the projecting pieces direct toward the communicating path from above. With this structure, the developer on the outer periphery of the developer conveying helical member moves in the rotating direction, whereby the pressure caused at the downstream side of the developer conveying passage is easy to escape in the space in the communicating path. Therefore, a local pressure rise can effectively be suppressed.
It may be configured such that the helical directions of helical blade 112a and the helical blade portion 112db are made opposite to each other, and the rotary shaft may rotate in order that a projecting piece 112da1 directs toward the communicating path from below. However, with this structure, the helical blade portion 112db that integrally rotates with the projecting piece 112da1 applies a force to the developer in the vicinity of a terminal of the helical blade portion 112db in the direction in which the helical blade portion 112db pushes the developer into a corner of the developer vessel 111. As a result, the developer, which is pushed into the corner of the developer vessel 111 and has nowhere to go, is liable to be susceptible to an excessive stress. Accordingly, it is preferable that the rotary shaft rotates in such a manner that the projecting piece 112da1 directs toward the communicating path from above.
<End Blade B>
The circumferential-direction agitating blade portion of the end blade B has a conic part provided to the rotary shaft in such a manner that the outer diameter thereof gradually increases toward the downstream side in the conveying direction; and has plural notches that are formed on the outer peripheral surface of the conic part with a prescribed space in the circumferential direction so as to extend in the axial direction of the rotary shaft.
Even with the structure of the end blade B described above, the agitating force in the circumferential direction by the projecting pieces increases toward the downstream side at the position of the end blade B, like the end blade A. In this case, the outer peripheral surface of the conic part expands in the radial direction toward the downstream side, so that the developer also receives a force in the direction of moving the developer in the radial direction along the outer peripheral surface of the conic part.
As a result, the pressure and stress applied to the developer because of the developer being pressed against the interior wall face of the developer conveying passage at the downstream side are decreased to reduce the deterioration in the flow property of the developer, whereby the developer can smoothly be transferred to the communicating path without being stayed at the downstream side of the developer conveying passage.
In this case, the conic part can be formed into a shape of a frustum of cone or frustum of pyramid such as a frustum of triangular pyramid, or a frustum of square pyramid. When the conic part is formed into a truncated pyramid, it is preferable that the notch is formed at the position of the surrounding corner portions of the truncated pyramid, because this structure easily applies the agitating force in the circumferential direction to the developer.
The shape of the cross-section of the notch, i.e., the shape of the cross-section parallel to the vertical surface with respect to the axial direction of the rotary shaft, is not particularly limited. However, a shape having a vertical internal face vertical with respect to the rotating direction of the rotary shaft is preferable. Examples of the shape described above include a V-shaped cross-section, L-shaped cross-section, or U-shaped cross-section.
With this structure, the developer can be pressed by the internal face of the notch through the rotation of the rotary shaft, whereby the agitating force in the circumferential direction can easily be applied to the developer.
The number of the notches is not particularly limited. However, it is preferable that two to four notches are equally spaced on the conic part from the viewpoint of preventing the stay of the developer and of acquiring a sufficient agitating force in the circumferential direction of the rotary shaft.
When the number of the notches exceeds four, the space between the adjacent notches becomes small, so that the developer is easy to be accumulated and stayed in the notches. On the other hand, when the number of the notches is less than two, the agitating force in the circumferential direction of the rotary shaft is significantly lowered.
When the developer vessel includes the semicylindrical interior wall faces, each constituting the first and second developer conveying passages, the maximum radial projecting size of the conic part from the center of the rotary shaft is set to be 0.8 to 0.9 times the distance from the center of the rotary shaft to the semicylindrical interior wall face.
With this structure, the maximum radial projecting size of the conic part has an appropriate length, whereby the agitating force for the developer can sufficiently be acquired, while suppressing the stress to the developer.
When the maximum radial projecting size of the conic part from the center of the rotary shaft exceeds 0.9 times the distance from the center of the rotary shaft to the semicylindrical interior wall face, a shear force caused between the semicylindrical interior wall face and the conic part increases, which might increase the stress to the developer. When the maximum radial projecting size of the conic part from the center of the rotary shaft is less than 0.8 times, the agitating force in the circumferential direction applied to the developer cannot sufficiently be acquired.
When the end blade B is used, it is also preferable that the rotary shaft rotates such that the notches direct toward the communicating path from above. With this structure, the developer on the outer periphery of the developer conveying helical member moves in the rotating direction, whereby the pressure caused at the downstream side of the developer conveying passage is easy to escape in the space in the communicating path. Therefore, a local pressure rise can effectively be suppressed.
It may be configured such that the helical directions of a helical blade 212a and a helical blade portion 212db are made opposite to each other, and the rotary shaft may rotate in order that notches 212da22 direct toward the communicating path from below. However, with this structure, the helical blade portion 212db that integrally rotates with the notches 212da22 applies a force to the developer in the vicinity of a terminal of the helical blade portion 212db in the direction in which the helical blade portion 212db pushes the developer into a corner of the developer vessel 111. As a result, the developer, which is pushed into the corner of the developer vessel 111 and has nowhere to go, is liable to be susceptible to an excessive stress. Accordingly, it is preferable that the rotary shaft rotates in such a manner that the notches 212da22 direct toward the communicating path from above.
<Helical Blade Portion>
The helical blade portion of the end blade has a constant outer diameter, and has a width in the radial direction that gradually decreases toward the downstream side in the conveying direction.
With this structure, a conveying capability of the helical blade portion in the conveying direction gradually decreases toward the downstream side in the conveying direction, and the agitating force in the circumferential direction by the circumferential-direction agitating blade portion relatively increases. Accordingly, the stress to the developer can effectively be eased, while preventing the stay of the developer at the downstream side of the developer conveying passage.
In the following, with reference to the drawings, embodiments of a developing device of the present invention and an image forming apparatus including the same will be described in detail.
An image forming apparatus 100 is a printer capable of forming a multi-color or single-color image on a sheet-like recording medium (recording sheet) based on image data externally received, the image forming apparatus 100 including: a developing device housing 100A in which a plurality of developing devices 2a to 2d are each accommodated in a casing; a fusing device housing 100B in which a fusing device 12 is accommodated above the developing device housing 100A inside the casing; and a partition wall 30 disposed between the developing device housing 100A and the fusing device housing 100B for insulating the heat generated by the fusing device 12.
A top face of the developing device housing 100A positioned beside the fusing device housing 100B serves as a sheet exit tray 15.
In the present embodiment, the printer is shown as an example of the image forming apparatus. On the other hand, the image forming apparatus can be a copier, a facsimile machine or a multi function peripheral possessing functions of the foregoing apparatuses, that can form a multi-color or single-color image on a recording medium based on image data externally received and/or image data read from an original by use of a scanner.
[Developing Device Housing]
As shown in
The developing device housing 100A further includes: a sheet feeding tray 10 disposed at a bottommost position in the developing device housing 100A to store a plurality of recording media; a manual sheet feeding tray 20 disposed on one side of the developing device housing 100A such that a recording medium of an arbitrary size is set thereon; and a sheet conveying path S for conveying a recording medium from the sheet feeding tray 10 or the manual sheet feeding tray 20 to the intermediate transfer belt unit (transferring device) 8.
As used herein, as to members denoted by reference character associated with “a” to “d”, “a” refers to those members for forming a black image, “b” refers to those members for forming a cyan image, “c” refers to those members for forming a magenta image, and “d” refers to those members for forming a yellow image.
That is, the image forming apparatus 100 is structured such that, based on image data for each of black, cyan, magenta, and yellow color components, a black toner image, a cyan toner image, a magenta toner image and a yellow toner image are selectively formed on the surfaces of the photoconductor drums 3a to 3d, and the formed toner images are overlaid one over another on the intermediate transfer belt unit 8, so as to form a full-color image on the recording medium.
Because the photoconductor drums 3a to 3d corresponding to respective colors are of the same structure, the description thereof will collectively be given employing a unified reference character “3”. Similarly, the description will collectively be given employing a unified reference character “2” as to the developing devices; a unified reference character “5” as to the chargers; a unified reference character “4” as to the cleaner units; and a unified reference character “22” as to the toner supplying devices.
(Photoconductor Drum and Peripheral Members Thereof)
The photoconductor drum 3 is structured with an electrically conductive base and a photosensitive layer formed on a surface of the base. The photoconductor drum 3 is a cylindrical member that forms a latent image by electrification and exposure. The photoconductor drum 3 exhibits electrical conduction as being illuminated by a light beam, whereby an electrical image called an electrostatic latent image is formed on the surface of the photoconductor drum 3.
The photoconductor drum 3 is supported by not-shown drive means such that it can rotate about its axis.
As the charger 5, a contact roller-type charger, a contact brush-type charger or a non-contact discharging type charger is used, to uniformly electrify the surface of the photoconductor drum 3 to a prescribed potential.
The exposure unit 1 allows a light beam corresponding to image data to pass between the charger 5 and the developing device 2, to illuminate the electrified surface of the photoconductor drum 3 to expose it thereby, such that an electrostatic latent image corresponding to the image data is formed on the surface of the photoconductor drum 3.
In the present embodiment, an exemplary case in which a laser scanning unit (LSU) provided with a laser emitter and reflection mirrors is shown as the exposure unit 1. On the other hand, arrays of light emitting elements such as EL (electroluminescence) or LED writing heads may also be used as the exposure unit 1.
(Developing Device)
As shown in
The developer vessel 111 has its interior partitioned into two chambers by a partitioning plate 117 arranged in parallel to an axial direction of the developing roller 114. One of the two chambers associated with the toner supply port 115a is the first developer conveying passage P, and the other associated with the developing roller 114 is the second developer conveying passage Q. The first developer conveying passage P and the second developer conveying passage Q communicate each other by the first communicating path (a) and the second communicating path (b) at opposite ends in the axial direction. Thus, the first and second developer conveying passages P and Q and the first and second communicating paths (a) and (b) form one annular developer conveying passage.
The developer vessel 111 has semicylindrical interior wall faces 111a and 111b respectively constituting the first and second developer conveying passages P and Q.
The developer vessel 111 further includes a removable developer vessel cover 115 that forms a top wall of the developer vessel 111. The developer vessel cover 115 is provided with a toner supply port 115a upstream in a developer conveying direction (a direction of an arrow X) in the first developer conveying passage P for the purpose of supplying an unused toner.
The developer vessel 111 has an opening between a sidewall facing the second developer conveying passage Q and a bottom edge of the developer vessel cover 115. At the opening, the developing roller 114 is rotatably disposed so as to form a prescribed developing nip portion N with the photoconductor drum 3.
The developing roller 114 is a magnet roller that is rotated about its axis by not-shown drive means. The developing roller 114 carries the developer in the developer vessel 111 on its surface to supply the toner to the photoconductor drum 3. An application of a developing bias voltage from a not-shown power supply allows the toner to be supplied from the developer on the surface of the developing roller 114 to an electrostatic latent image on the surface of the photoconductor drum 3.
The doctor blade 116 is a rectangular plate-like member extending in parallel to the axial direction of the developing roller 114. A bottom end 116b is fixed to a bottom edge of the opening of the developer vessel 111, while its top end 116a is away from the surface of the developing roller 114 by a prescribed gap. The doctor blade 116 may be made of stainless steel, aluminum, synthetic resin or the like, for example.
<First Developer Conveying Helical Member>
The first developer conveying helical member (hereinafter sometimes referred to as the “first helical member”) 112 is structured with a rotary shaft 112b disposed rotatably in the first developer conveying passage P and in parallel thereto, a helical blade 112a fixed to an outer circumferential surface of the rotary shaft 112b, an end blade 112d disposed on the rotary shaft 112b at one end of the helical blade 112a, and a gear 112c disposed at one end of the rotary shaft 112b, which penetrates one sidewall 111c of the developer vessel 111 in the longitudinal direction.
The end blade 112d includes a circumferential-direction agitating blade portion 112da having four projecting pieces 112da1, and a helical blade portion 112db that is wound integral with the outer circumference of the circumferential-direction agitating blade portion 112da in the helical direction same as the helical direction of the helical blade 112a.
The circumferential-direction agitating blade portion 112da includes four projecting pieces 112da1, each having a shape of a right-angled triangle.
Each of the projecting pieces 112da1 is arranged such that a long side of two sides making a right angle is attached along the rotary shaft 112b. The projecting pieces 112da1 are arranged 90 degrees apart in the circumferential direction.
As shown in
The maximum radial projecting size L1 (see
As illustrated in
Therefore, a gap is formed at the portion enclosed by the two adjacent projecting pieces 112da1, the rotary shaft 112b, and the helical blade portion 112db. This gap may be closed by the helical blade portion 112db.
The helical blade portion 112db has the outer diameter, thickness and helical pitch, same as those of the helical blade 112a, and is continuously formed with the helical blade 112a.
The first helical member 112 is driven by not-shown drive means (e.g., a motor) through the gear 112c. The rotation of the helical blade 112a in a direction of an arrow J (see
In this case, the end blade 112d rotates in the same direction, wherein the projecting pieces 112da1 of the circumferential-direction agitating blade portion 112da rotate toward the first communicating path (a) from above so as to agitate the developer in the circumferential direction, and the helical blade portion 112db conveys the developer toward one sidewall 111c of the developer vessel 111.
On the end blade 112d, the width W of the helical blade portion 112da in the radial direction gradually decreases, while the projecting size L1 of the projecting piece 112da1 gradually increases. Accordingly, the developer moving in the circumferential direction (in the direction of the arrow J) along the semicylindrical interior wall face 111a of the first developer conveying passage P increases more than the developer that is transferred toward one sidewall 111c of the developer vessel 111 to be pressed against the sidewall 111c.
Accordingly, the developing device according to the first embodiment can prevent the deterioration in the flow property of the developer, which deterioration is caused because the developer is pushed toward one sidewall 111c of the developer vessel 111 and receives a violent pressure as in the conventional case.
The developer around the rotating end blade 112d is pushed out to the first communicating path (a) by the developer sequentially conveyed from the upstream side of the first developer conveying passage P, and moves to the second developer conveying passage Q.
<Second Developer Conveying Helical Member>
The second developer conveying helical member (hereinafter sometimes referred to as the “second helical member”) 113 has substantially the same structure as the first helical member 112, except that an end blade 113d same as the end blade 112d of the first helical member 112 is arranged at the downstream side (at the side of the second communicating path (b)) of the second developer conveying passage Q, and a helical blade 113a is arranged from the end blade 113d to the most upstream side of the second developer conveying passage Q (at the side of the first communicating path (a)).
The end blade 113 includes a circumferential-direction agitating blade portion 113da having four projecting pieces 113da1, each of which has a projecting size increases toward the downstream side of the second developer conveying passage Q, and a helical blade portion 113db that is integrally wound around the outer circumference of the circumferential-direction agitating blade portion 113da in the helical direction same as that of the helical blade 113a.
The rotary shaft 113b penetrates through one sidewall 111c of the developer vessel 111 in terms of the longitudinal direction, and a gear 113c is attached to one end thereof so as to be adjacent to the gear 112c.
The helical direction of the helical blade 113a is the same as that of the helical blade 112a.
Therefore, when the helical blade 112a rotates in the direction of the arrow J through the gear 112c and the rotary shaft 112b, and the helical blade 113a synchronously rotates in a direction of an arrow K, which is reverse to the direction of the arrow J, through the gear 113c and the rotary shaft 113b by the not-shown drive means, the developer conveyed to the most upstream side of the second developer conveying passage Q from the first developer conveying passage P through the first communicating path (a) is conveyed to the end blade 113d in the direction of an arrow Y in the second developer conveying passage Q as shown in
On the rotating end blade 113d, the projecting pieces 113da1 of the circumferential-direction agitating blade portion 113da rotate toward the second communicating path (b) from above to agitate the developer in the circumferential direction, while the helical blade portion 113db conveys the developer toward the other sidewall 111d of the developer vessel 111.
In this case, the width in the radial direction of the helical blade portion 113da gradually decreases toward the downstream side of the second developer conveying passage Q, while the projecting size of the projecting piece 113da1 gradually increases, whereby the developer moving in the circumferential direction (in the direction of the arrow K) along the semicylindrical interior wall face 111b of the second developer conveying passage Q increases more than the developer that moves to the other sidewall face 111d of the developer vessel 111 to be pressed against the sidewall face 111d.
Accordingly, the developing device according to the first embodiment can also prevent the deterioration in the flow property of the developer, which deterioration is caused because the developer is pushed toward the other sidewall 111d of the developer vessel 111 and receives a violent pressure as in the conventional case.
The developer around the rotating end blade 113d is pushed out to the second communicating path (b) by the developer sequentially conveyed from the upstream side of the second developer conveying passage Q, and moves to the first developer conveying passage P.
Thus, the developer circulates through the first developer conveying passage P and the second developer conveying passage Q.
A toner concentration detecting sensor 119 is mounted at a substantially central portion of the second developer conveying passage Q at the semicylindrical interior wall face 111b of the developer vessel 111 right below the second helical member 113, having its sensor face exposed inside the second developer conveying passage Q.
The toner concentration detecting sensor 119 is electrically connected to not-shown toner concentration control means.
The toner concentration control means exerts control in accordance with a toner concentration measurement value detected by the toner concentration detecting sensor 119, so as to rotate a toner discharging member 122 of a toner supplying device 22 (see
When the toner concentration control means determines that the toner concentration measurement value is lower than a toner concentration set value, a control signal is transmitted to drive means that rotates the toner discharging member 122, whereby the toner discharging member 122 rotates.
The toner concentration detecting sensor 119 may be a general toner concentration detecting sensor, such as a transmitted light detecting sensor, a reflected light detecting sensor, a permeability detecting sensor or the like. Of these, the permeability detecting sensor is preferable.
A not-shown power supply is connected to the permeability detecting sensor (toner concentration detecting sensor 119).
The power supply applies, to the permeability detecting sensor, a drive voltage for driving the permeability detecting sensor and a control voltage as an output of a detection result of the toner concentration to the control means.
The application of the voltages to the permeability detecting sensor by the power supply is controlled by the control means.
The permeability detecting sensor is of a type that receives the control voltage and outputs the detection result of the toner concentration as an output voltage value. Basically, the sensor exhibits an excellent sensitivity about the output center voltage value, and hence a control voltage capable of providing the output voltage around such a value is applied when used.
The permeability detecting sensor of such a type is commercially available. Examples thereof include those marketed under trade names TS-L, TS-A, and TS-K by TDK Corporation.
(Toner Supplying Device)
As shown in
The toner supplying device 22 is disposed above the developer vessel 111 (see
The toner container 121 is a hollow substantially semicylindrical container. The toner discharge port 123 is disposed beside the circumference of the semicylindrical part.
The toner agitating member 125 is rotatably disposed at a substantially central position of the semicylindrical part of the toner container 121, and the toner discharging member 122 is rotatably disposed at a position above and near the toner discharge port 123.
The toner agitating member 125 is a plate-like member that rotates about a rotary shaft 125a, and has a sheet-like toner draw-up member 125b made of an elastic resin (e.g., polyethylene terephthalate) at each opposite tip away from the rotary shaft 125a. In this case, the rotary shaft 125a is rotatably supported at opposite sidewalls of the toner container 121 in terms of the longitudinal direction. One end of the rotary shaft 125a penetrates through the sidewall. A gear meshing with a drive gear of not-shown drive means is fixed to the one end.
As the toner draw-up member 125b of the toner agitating member 125 rotates from the bottom toward the top relative to the toner discharge port 123, the toner accommodated in the toner container 121 is drawn up while being agitated, and conveyed to the toner discharging member 122.
In this case, the elasticity of the toner draw-up member 125b allows the toner draw-up member 125b to slidably rotate as being deformed along the interior wall of the toner container 121, to thereby supply the toner toward the toner discharging member 122.
It is to be noted that a partition wall 124 is provided between the toner discharging member 122 and the toner agitating member 125, such that the toner drawn up by the toner agitating member 125 can be retained by an appropriate amount around the toner discharging member 122.
The toner discharging member 122 is structured with a rotary shaft 122b having its opposite ends rotatably supported at opposite sidewalls of the toner container 121 in terms of the longitudinal direction, a helical blade 122a fixed to an outer circumferential surface of the rotary shaft 122b, and a gear 122c fixed to one end of the rotary shaft 122b penetrating through the sidewall of the toner container 121.
The gear 122c meshes with a drive gear of not-shown drive means.
The toner discharge port 123 of the toner container 121 is arranged at one end opposite to the gear 122c of the helical blade 122a.
A rotation of the toner discharging member 122 allows the toner supplied around the toner discharging member 122 to be conveyed by the helical blade 122a toward the toner discharge port 123, and to be supplied from the toner discharge port 123 into the developer vessel 111 via the toner conveying pipe 102.
<Operation of Developing Device>
In a developing step with the image forming apparatus, as shown in
In this case, the developer in the first developer conveying passage P is conveyed in the arrow X direction by the first helical member 112, while the developer in the second developer conveying passage Q is conveyed in the arrow Y direction by the second helical member 113.
Simultaneously, the developer at the downstream side in the first developer conveying passage P is conveyed to the second developer conveying passage Q through the first communicating path (a), while the developer at the downstream side in the second developer conveying passage Q is conveyed to the first developer conveying passage P through the second communicating path (b).
In this manner, the developer in the developer vessel 111 circulates through the first developer conveying passage P and the second developer conveying passage Q, whereby the toner in the developer is sufficiently electrified through a frictional rub with the carrier.
The developer moving in the second developer conveying passage Q is partially supplied to the developing roller 114.
The developer supplied to the developing roller 114 is sent to the photoconductor drum 3 by the doctor blade 116 in a form of a uniform developer layer having a prescribed thickness on the outer circumferential surface of the developing roller 114. From the developer layer, the toner is partially supplied to the photoconductor drum 3. Thereafter, the developer whose toner concentration is lowered on the developing roller 114 is blended with the developer in the second developer conveying passage Q.
Accordingly, the toner concentration of the developer in the second developer conveying passage Q gradually becomes low.
Because the toner concentration of the developer in the second developer conveying passage Q is detected by the toner concentration detecting sensor 119, when the toner concentration becomes smaller than a prescribed value, the unused toner is supplied from the toner supplying device 22 onto the developer (existing developer) in the first developer conveying passage P. The supplied toner is blended with the existing developer, and dispersed by the rotation of the first helical member 112.
(Intermediate Transfer Belt Unit and Intermediate Transfer Belt Cleaner Unit)
As shown in
It is to be noted that the intermediate transfer rollers 6 are each rotatably supported by a roller mounting portion of the belt tensioning mechanism.
Further, the intermediate transfer belt cleaner unit 9 is disposed next to the driven roller 72 of the intermediate transfer belt unit 8.
The drive roller 71 and the driven roller 72 are disposed externally to the outmost photoconductor drums 3, respectively, out of the four photoconductor drums 3, so that the intermediate transfer belt 7 is brought into contact with the photoconductor drums 3.
The intermediate transfer belt 7 is formed in an endless manner using a film having a thickness of about 100 to 150 μm, for example. The toner images of different color components formed on respective photoconductor drums 3 are successively transferred one over another on the external face of the intermediate transfer belt 7, to form a full-color toner image (multi-color toner image).
A transfer operation of the toner image from the photoconductor drums 3 to the intermediate transfer belt 7 is carried out by the intermediate transfer rollers 6 which are in contact with an internal face of the intermediate transfer belt 7.
Each intermediate transfer roller 6 is made up of a metal shaft (e.g., made of stainless steel) having a diameter of, e.g., 8 to 10 mm, and a conductive elastic material layer coating the outer circumferential surface of the metal shaft.
Examples of the conductive elastic material layer include ethylene propylene diene terpolymer (EPDM), foamed urethane or the like that contains a conductive material such as carbon black.
A high-voltage transfer bias (a high voltage whose polarity is opposite (+) to a polarity (−) of the electrostatic charge on the toner) is applied to the metal shaft of each of the intermediate transfer rollers 6 for transferring the toner images, whereby the intermediate transfer rollers 6 can uniformly apply a high voltage to the intermediate transfer belt 7.
While intermediate transfer rollers 6 are used as transfer electrodes in the present embodiment, brushes or the like can be used instead.
The toner image overlaid on the external surface of the intermediate transfer belt 7 shifts to a position of the transfer roller 11 (transfer portion) by the rotation of the intermediate transfer belt 7.
On the other hand, a recording medium is also conveyed through the sheet conveying path S to the transfer portion, where the recording medium is pressed against the intermediate transfer belt 7 by the transfer roller 11. Thus, the toner image on the intermediate transfer belt 7 is transferred onto the recording medium.
In this case, the intermediate transfer belt 7 and the transfer roller 11 are pressed against each other at a prescribed nip, while a high voltage is applied to the transfer roller 11 for transferring the toner image onto the recording medium. In this case, a polarity of the high voltage is opposite (+) to the polarity (−) of the electrostatic charge on the toner.
Further, in order to constantly obtain the nip between the intermediate transfer belt 7 and the transfer roller 11, one of the transfer roller 11 and the drive roller 71 is formed of a hard material such as metal, and the other is formed of a soft material such as rubber, foamed resin or the like.
The toner having not been transferred from the intermediate transfer belt 7 to the recording medium and remaining on the intermediate transfer belt 7 may cause undesired blend of toners of different colors when overlaying a new toner image on the intermediate transfer belt 7, and hence the remaining toner is removed and collected by the intermediate transfer belt cleaner unit 9.
The intermediate transfer belt cleaner unit 9 includes a cleaning blade in contact with the intermediate transfer belt 7 to remove the remaining toner, and a toner collector that collects the removed toner. It is noted that a portion in the intermediate transfer belt 7 which is brought into contact with the cleaning blade is supported by the driven roller 72.
(Sheet Conveying Path and Peripheral Member Thereof)
As shown in
The feed rollers 25 are small rollers for facilitating and assisting sheet conveyance, and paired along the sheet conveying path S.
The pickup roller 16a is disposed at an end portion of the sheet feeding tray 10, to pick up sheet-like recording media (recording sheets) one by one from the feed tray 10 and supplies it to the sheet conveying path S.
The pickup roller 16b is disposed near the manual sheet feeding tray 20, to pick up the recording media one by one from the manual sheet feeding tray 20 and supplies it to the sheet conveying path S.
The registration roller 14 temporarily holds the recording medium conveyed on the sheet conveying path S, and delivers the recording medium to the transfer portion at a timing intended to align a tip of the toner image on the intermediate transfer belt 7 with a tip of the recording medium.
[Fusing Device Housing]
As shown in
The heat roller 81 is controlled by a not-shown controller such that it reaches a prescribed fusing temperature. The controller controls the temperature of the heat roller 81 based on a detection signal received from a not-shown temperature detector.
The heat roller 81 having reached the fusing temperature and the pressure roller 82 press against the recording medium to melt the toner, whereby the toner image is fused on the recording medium.
The recording medium having the toner image fused thereon is conveyed by the feed rollers 25b and 25c to take a turn-over sheet exit route of the sheet conveying path S, and ejected on the sheet exit tray 15 as being turned over (i.e., the toner image facing down).
A developing device 202 according to the second embodiment is the same as the developing device according to the first embodiment, except for end blades 212d and 213d of a first developer conveying helical member 212 and a second developer conveying helical member 213. Therefore, a description will be given hereinafter mainly of the difference from the first embodiment.
<First Developer Conveying Helical Member>
The end blade 212 of the first developer conveying helical member 212 includes a circumferential-direction agitating blade portion 212da and a helical blade portion 212db, as in the first embodiment, but the structure of the circumferential-direction agitating blade portion 212da is different from the circumferential-direction agitating blade portion 112da in the first embodiment.
The circumferential-direction agitating blade portion 212da includes a conic part 212da1 that is mounted to the rotary shaft 212b in such a manner that its outer diameter gradually increases toward the downstream side in the conveying direction (in the direction of the arrow X), and plural notches 212da2 that are formed on the outer peripheral surface of the conic part 212da1 with a prescribed space so as to extend in an axial direction.
The conic part 212da1 has a structure in which four notches 212da2 are formed on the outer peripheral surface of a frustum of a cone so as to form a central angle of 90° between adjacent one of the notches 212da2. The central axis of the conic part 212da1 agrees with the center of the rotary shaft 212b.
Each of the notches 212da2 has a first internal face 212da21 that is vertical to the rotating direction (in the direction of an arrow in
In other words, the first internal face 212da21 is arranged on a radial line with the center of the rotary shaft 212 being defined as a center, while the second internal face 212da22 is arranged in the rotating direction of the rotary shaft 212b and is arranged as to be at right angles to the first internal face 212da21.
Therefore, an angle F of the first internal face 212da21 to a tangent line of an outer peripheral surface of the conic part 213da1 is 90°, while an angle G of the second internal face 212da1 to the tangent line of the outer peripheral surface of the conic part 213da1 is 45°.
The notch 212da2 may be formed to have a U-shaped cross-section in which the portion between the first internal face 212da21 and the second internal face 212da22 is formed into a curved face. Alternatively, the notch 212da2 may be formed to have a V-shaped cross-section in which an angle between the first internal face 212da21 and the second internal face 212da22 is decreased to about 45°.
A width W1 of the first internal face 212da21 in the radial direction is set to be narrower than a width W2 of the second internal face 212da22 in the radial direction with a prescribed ratio. These widths W1 and W2 increase, as the diameter of the conic part 212da1 increases. Specifically, the depth of the notch 212da2 increases, as the diameter of the conic part 212da1 increases.
A maximum radial projecting size (maximum radius) L1 of the conic part 212da1 from the center of the rotary shaft 212b is set to be about 0.85 times a distance L2 from the center of the rotary shaft 212b to the semicylindrical interior wall face 111a of the first developer conveying passage P.
The helical blade portion 212db, which has the similar structure of the helical blade portion 112db in the first embodiment, is continuously wound and fixed on the outer peripheral surface of the conic part 212da1 thus configured. In this case, a gap is formed between the helical blade portion 212db and the notch 212da2. The helical blade part 212db may be formed so as to close this gap.
The rotating direction of the first helical member 212 is the same as the rotating direction of the first helical member 112 in the first embodiment, so that the rotary shaft 212b rotates such that the notches 212da2 direct toward the first communicating path (a) from below. Specifically, the rotary shaft 212b rotates in such a manner that the first internal face 212da21 of each of the notches 212da1 pushes the developer.
The first helical member 212 is driven by not-shown drive means (e.g., a motor) through a gear 212c. The rotation of the helical blade 212a in the direction of the arrow J (see
In this case, the end blade 212d rotates in the same direction, wherein each of the notches 212da2 of the circumferential-direction agitating blade portion 212da rotates toward the first communicating path (a) from above so as to agitate the developer in the circumferential direction, and the helical blade portion 212db conveys the developer toward one sidewall 111c of the developer vessel 111.
On the end blade 212d, the width W of the helical blade portion 212da in the radial direction gradually decreases toward the downstream side of the first developer conveying passage P, while the diameter of the conic part 212da1 gradually increases. Therefore, the developer moving in the circumferential direction (in the direction of the arrow J) along the semicylindrical interior wall face 111a of the first developer conveying passage P increases more than the developer that is moved toward one sidewall 111c of the developer vessel 111 to be pressed against the sidewall 111c.
Since the diameter of the conic part 212da1 increases toward the downstream side, the developer also receives a force in the direction of moving the developer in the radial direction along the outer peripheral surface of the conic part 212da1.
Accordingly, the developing device according to the second embodiment can also prevent the deterioration in the flow property of the developer, which deterioration is caused because the developer is pushed toward one sidewall 111c of the developer vessel 111 and receives a violent pressure as in the conventional case.
The developer around the rotating end blade 212d is pushed out to the first communicating path (a) by the developer sequentially conveyed from the upstream side of the first developer conveying passage P, and moves to the second developer conveying passage Q.
<Second Developer Conveying Helical Member>
The second developer conveying helical member 213 has substantially the same structure as the first helical member 212, except that an end blade 213b same as the end blade 212d of the first helical member 212 is arranged at the downstream side (facing the second communicating path (b)) of the second developer conveying passage Q, and a helical blade 213a is arranged from the end blade 213d to the most upstream side of the second developer conveying passage Q (facing the first communicating path (a)).
The end blade 213 includes a circumferential-direction agitating blade portion 213da having a conic part 213da1, whose diameter increases toward the downstream side of the second developer conveying passage Q, and four notches 213da2; and a helical blade portion 213db that is integrally wound around the outer circumference of the circumferential-direction agitating blade portion 213da.
The helical blade portion 213d is continuously formed in the helical direction same as that of the helical blade 213a.
The rotary shaft 213b penetrates through one sidewall 111c of the developer vessel 111 in terms of the longitudinal direction, and a gear 313c is attached to one end thereof so as to be adjacent to the gear 212c.
The helical direction of the helical blade 313a is the same as that of the helical blade 112a.
Therefore, when the helical blade 212a rotates in the direction of the arrow J through the gear 212c and the rotary shaft 112b, and the helical blade 213a synchronously rotates in the direction of the arrow K, which is reverse to the direction of the arrow J, through the gear 213c and the rotary shaft 213b by the not-shown drive means, the developer conveyed to the most upstream side of the second developer conveying passage Q from the first developer conveying passage P through the first communicating path (a) is conveyed to the end blade 213d in the direction of the arrow Y in the second developer conveying passage Q as shown in
On the rotating end blade 213d, the notches 212da2 of the circumferential-direction agitating blade portion 213da rotate toward the second communicating path (b) from above to agitate the developer in the circumferential direction, while the helical blade portion 213db conveys the developer toward the other sidewall 111d of the developer vessel 111.
In this case, the width in the radial direction of the helical blade portion 213da gradually decreases toward the downstream side of the second developer conveying passage Q, while the diameter of the conic part 213da1 increases, whereby the developer moving in the circumferential direction (in the direction of the arrow K) along the semicylindrical interior wall face 111b of the second developer conveying passage Q increases more than the developer that moves to the other sidewall face 111d of the developer vessel 111 to be pressed against the sidewall 111d.
Accordingly, the developing device according to the second embodiment can also prevent the deterioration in the flow property of the developer, which deterioration is caused because the developer is pushed toward the other sidewall 111d of the developer vessel 111 and receives a violent pressure as in the conventional case.
The developer around the rotating end blade 213d is pushed out to the second communicating path (b) by the developer sequentially conveyed from the upstream side of the second developer conveying passage Q, and moves to the first developer conveying passage P.
Thus, the developer circulates through the first developer conveying passage P and the second developer conveying passage Q.
Number | Date | Country | Kind |
---|---|---|---|
2010-116489 | May 2010 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
6615014 | Sugihara | Sep 2003 | B2 |
7035573 | Yamaguchi et al. | Apr 2006 | B2 |
7881638 | Noguchi et al. | Feb 2011 | B2 |
7881640 | Iwata et al. | Feb 2011 | B2 |
20100226688 | Soga | Sep 2010 | A1 |
Number | Date | Country |
---|---|---|
5-197283 | Aug 1993 | JP |
2009-109741 | May 2009 | JP |
2010-160411 | Jul 2010 | JP |
Number | Date | Country | |
---|---|---|---|
20110286770 A1 | Nov 2011 | US |