1. Field of the Invention
The present invention relates to an electrophotographic image forming apparatus in which a cartridge is detachably mounted in an apparatus main body and which forms an image on a recording medium.
Here, the electrophotographic image forming apparatus is an apparatus that forms an image on a recording medium using an electrophotographic image forming process. Examples of the electrophotographic image forming apparatus include an electrophotographic copying machine, an electrophotographic printer (for example, a laser beam printer and an LED printer), a facsimile machine, and a word processor. The recording medium is a medium on which an image is formed by the electrophotographic image forming apparatus, examples of which include paper and an OHT (overhead transparency) sheet.
2. Description of the Related Art
A known image forming apparatus (electrophotographic image forming apparatus) using an electrophotographic image forming process in the related art employs a process cartridge system. The process cartridge system is such that a process cartridge in which a photosensitive drum (electrophotographic photosensitive drum), a developing roller that acts on the photosensitive drum, and a developing unit that accommodates toner for use in image formation are integrated to form a single unit is detachably mounted in an apparatus main body. The process cartridge system allows a user to perform maintenance of the apparatus by himself or herself without the help of a serviceman. Therefore, the process cartridge system is widely used in electrophotographic image forming apparatuses. In addition to the foregoing process cartridge system, there are various kinds of cartridge system. For example, there are a developing cartridge system in which a developing roller and toner are accommodated and a toner cartridge system in which only toner is accommodated. An optimum system is selected from them in consideration of the apparatus configuration, cost, etc.
An example of known electrophotographic image forming apparatuses has a configuration in which a scanner unit serving as an exposing unit is mounted to a covering member that opens and closes an opening for mounting and demounting a plurality of cartridges (U.S. Pat. No. 7,356,283). With this configuration, when the covering member is opened to mount or demount the cartridges, the scanner unit retracts, and thus, the ease of operation for mounting and demounting the cartridges can be improved.
U.S. Pat. No. 7,356,283 discloses an image forming apparatus capable of color image formation. In this image forming apparatus, a plurality of cartridges are disposed next to each other diagonally above and below.
The present invention is developed from the related art described above.
The present invention provides an image forming apparatus capable of high-accuracy positioning of an exposing unit relative to a photosensitive member to be exposed to light so as to form high-quality images.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
Embodiments of the present invention will be described in detail hereinbelow with reference to the drawings. It is to be understood that the scope of the present invention is not limited to the sizes, materials, shapes, the relative positions, etc. of components described in the embodiments unless otherwise stated.
Overall Schematic Configuration of Example of Electrophotographic Image Forming Apparatus
Specifically, the image forming apparatus 100 forms a full color image on a recording medium (sheet) S on the basis of an electrical image signal input from an external host unit 400, such as a personal computer, an image reader, and a sending-side facsimile machine, to a control circuit unit 300.
In the description below, for the image forming apparatus 100, “front” is a direction in which a feeding cassette 19 that accommodates the stacked recording medium S is drawn outward from the interior of an apparatus main body 100A; “rear” is opposite thereto; “above” is a direction in which the recording medium S is output; “front-to-back direction” includes a direction in which the image forming apparatus 100 is viewed from the rear to the front (forward direction) and a direction opposite thereto (backward); “left and right” are the sides of the image forming apparatus 100 as viewed from the front; “lateral direction” includes a right-to-left direction (leftward) and a direction opposite thereto (rightward); and “longitudinal direction” is the axial direction of an electrophotographic photosensitive drum or a developing roller. An apparatus main body 100A is part of the image forming apparatus 100 excluding cartridges 33 (33Y, 33M, 33C, and 33K) and an image forming unit 200. The right side of the image forming apparatus 100 of this embodiment is a drive side and the left side is a non-drive side.
The image forming apparatus 100 is placed on a substantially horizontal installation surface F of a table, a desk, a floor, etc. At the center in the apparatus main body 100A is disposed the image forming unit 200.
Photosensitive Drum
The individual photosensitive drums 32a are fixed to the subframe 31 of the image forming unit 200. The subframe 31 is further provided with the charging rollers 32b and the cleaning blades 32c for removing developers remaining on the surfaces of the drums 32a, which serve as processing units for the drums 32a. The drums 32a, the charging rollers 32b, and the cleaning blades 32c are mounted in a predetermined placement relationship.
Cartridge
As shown in
The cartridge 33Y has the developing roller 33b at the distal end thereof in the mounting direction. A gear 50 is provided at the right end of the developing roller 33b. The gear 50 receives a driving force from a drum gear 32a1 (
Guided portions 33e1 and 33e2 and guided portions 33e3 and 33e4 for the cartridge 33Y to be guided to the unit 200 are provided at the right and left sides of cartridge 33Y, respectively. The guided portions 33e1, 33e2, 33e3, and 33e4 each have a cylindrical shape projecting outwards from the right and left sides of the cartridge 33Y.
A grip 39 (see
As shown in
Urging of Cartridges
The apparatus main body 100A has cartridge urging members 51a to 51d (
The developing rollers 33b accommodated in the cartridges 33 come into contact with the drums 32a with a fixed urging force by bringing control rollers (not shown) provided at both ends thereof into contact with the drums 32a. The urging forces of the urging members 51a to 51d suitably maintain the contact state (or the spaced-apart state) between the developing rollers 33b and the drums 32a.
Scanner Unit
As shown in
The scanner unit 11 is mounted in the cover unit 10 which is a covering member for opening and closing an opening 100B for mounting and demounting the cartridges 33.
The details of the mounting and positioning of the scanner unit 11 of this embodiment will be described later.
Recording-Medium Conveying Mechanism
As shown in
The cover unit 10 is an opening and closing member that can open and close the opening 100B provided at the front of the apparatus main body 100A. The cover unit 10 is fitted with the scanner unit 11. As will be described below, the opening 100B is an opening for mounting and demounting the cartridges 33 to/from the unit 200. Thus, the cartridges 33 can be mounted and demounted by bringing the cover unit 10 that holds the scanner unit 11 to an opening position.
In this state, the cover unit 10 is in a closing position at which the opening 100B is closed. The unit 200 is at an image forming position in the apparatus main body 100A in which the cartridges 3 are mounted, and image formation is performed. A gear 34b (
An operation for forming a full-color image will be described with reference to
The drums 32a are rotationally driven counterclockwise in the direction of the arrows at a predetermined speed. The charging rollers 32b are rotated as the drums 32a are rotationally driven. The intermediate transfer member 34 is also rotationally driven clockwise in the direction of the arrow (reverse direction to the rotation of the drums 32a) at a speed corresponding to the speed of the drums 32a. The developing rollers 33b and the supply rollers 33d are individually rotationally driven clockwise in the direction of the arrows at predetermined speeds. The scanner unit 11 is also driven. In synchronization with the driving, a predetermined charging bias is applied to the individual charging rollers 32b at a predetermined control timing.
Thus, the surfaces of the drums 32a are uniformly charged to a predetermined polarity and potential by the charging rollers 32b. The scanner unit 11 exposes the surfaces of the drums 32a to laser light beams L (LY, LM, LC, and LK) modulated in response to the Y-, M-, C-, and K-color image signals, respectively. Thus, electrostatic latent images corresponding to the corresponding color image signals are formed on the surfaces of the drums 32a. The electrostatic latent images formed on the surfaces of the drums 32a are developed as developer images by the developing rollers 33b of the corresponding cartridges 33. A predetermined developing bias is applied to the developing rollers 33b at a predetermined control timing.
By the foregoing electrophotographic image forming process, a Y-color developer image corresponding to the Y-color component of the full-color image is formed on the drum 32a that the cartridge 33Y faces. The developer image is primarily transferred onto the intermediate transfer member 34 at a primary-transfer nip portion, which is a contact portion between the drum 32a and the intermediate transfer member 34; an M-color developer image corresponding to the M-color component of the full-color image is formed on the drum 32a that the cartridge 33M faces. The developer image is superimposed, that is, primarily transferred, onto the Y-color developer image that has already been transferred onto the intermediate transfer member 34 at a primary-transfer nip portion, which is a contact portion between the drum 32a and the intermediate transfer member 34. A C-color developer image corresponding to the C-color component of the full-color image is formed on the drum 32a that the cartridge 33C faces. The developer image is superimposed, that is, primarily transferred, onto the Y-color+M-color developer image that has already been transferred onto the intermediate transfer member 34 at a primary-transfer nip portion, which is a contact portion between the drum 32a and the intermediate transfer member 34. A K-color developer image corresponding to the K-color component of the full-color image is formed on the drum 32a that the cartridge 33K faces. The developer image is superimposed, that is, primarily transferred, onto the Y-color+M-color+C-color developer image that has already been transferred onto the intermediate transfer member 34 at a primary-transfer nip portion, which is a contact portion between the drum 32a and the intermediate transfer member 34. In this way, an unfixed developer image in which the four full colors, Y+M+C+K, are combined, is formed on the intermediate transfer member 34.
The order of the colors of developer images transferred onto the intermediate transfer member 34 is not limited to the above. Transferred developers remaining on the surfaces of the drums 32a after developer images are transferred to the intermediate transfer member 34 are removed by the cleaning blades 32c and are pooled in individual waste-developer accommodating portions.
On the other hand, the feeding roller 20 is driven at a predetermined control timing. Thus, the sheet-like recording mediums S stacked in the feeding cassette 19 are separated and fed one by one in cooperation with the feeding roller 20 and the separation pad 21. The recording mediums S are introduced to a secondary transfer nip portion, which is a contact portion between the intermediate transfer member 34 and the secondary transfer roller 22, by the registration roller pair 18a at a predetermined control timing. The secondary transfer roller 22 is subjected to a secondary transfer bias with an opposite polarity to the developer charging polarity and a predetermined potential at a predetermined control timing. Thus, the four-color-superimposed developer image on the intermediate transfer member 34 is secondarily transferred onto the surface of the recording medium S in the process in which the recording medium S is conveyed through the secondary transfer nip portion. The recording medium S that has passed through the secondary transfer nip portion is separated from the surface of the intermediate transfer member 34 and is introduced to the fixing unit 23, where it is heated and pressed in a fixing nip portion. Thus, the colors of the developer images are combined and fixed to the recording medium S. The recording medium S exits from the fixing unit 23 and is ejected as a full-color-image formed medium onto the output tray 100c by the discharge roller pair 24. Secondary-transferred toner remaining on the surface of the intermediate transfer member 34 is removed after the recording medium S is separated from the intermediate transfer member 34. In the case of this embodiment, the remaining toner electrostatically adheres to the surfaces of the drums 32a at the primary-transfer nip portion between the drums 32a and the intermediate transfer member 34 and is removed by the cleaning blades 32c.
The intermediate transfer member 34 is a drum-shaped rotational body, as described above. Developer images of different colors formed on the drums 32a are transferred one on another onto the intermediate transfer member 34. The intermediate transfer member 34 transfers the transferred developer images together to the recording medium S. Thus, a color image is formed on the recording medium S.
In the case where a monochrome image is to be formed, a K-color developer image formed on the drum 32a that the cartridge 33K faces is transferred to the intermediate transfer member 34. The intermediate transfer member 34 transfers the transferred K-color developer image to the recording medium S, so that a K-color image is formed on the recording medium S.
The secondary transfer roller 22 in this embodiment can be moved by a shift mechanism (not shown) to a first position at which it is in contact with the intermediate transfer member 34 to form the secondary transfer nip portion and a second position at which it is separate from, that is, out of contact with, the intermediate transfer member 34. When the forming apparatus 100 is in an image forming operation, the secondary transfer roller 22 is moved to the first position, and not in an image forming operation, it is moved to the second position. The secondary transfer roller 22 may also be configured to be normally in contact with the intermediate transfer member 34.
Image Forming Unit
The configuration of the image forming unit 200 will be described with reference to
The unit 200 includes the subframe 31 that can be mounted and demounted to/from the main frame 110 of the apparatus main body 100A. The subframe 31 rotatably supports the intermediate transfer member 34 formed by coating the circumferential surface of a cylinder with an elastic member. The intermediate transfer member 34 is supported such that the left end and the right end of the central shaft (rotation center) 34a are rotatably supported between a left side plate 31L and a right side plate 31R of the subframe 31. The intermediate transfer member 34 has the gear 34b, at the right end, that transmits a driving force to the individual drums 32a. The gear 34b transmits a driving force transmitted from the apparatus-main-body driving source (not shown) to the drum gears 32a1. The drums 32a are disposed around the intermediate transfer member 34 in a state in which they are in contact with the intermediate transfer member 34. The drums 32a are positioned relative to the subframe 31 with a positioning configuration (not shown) so as to be rotatable about the axes of the drums 32a. This allows the drums 32a and the intermediate transfer member 34 to be positioned relative to each other with high accuracy. The drums 32a are in contact with the intermediate transfer member 34 under a predetermined pressure.
A left shaft 45L and a right shaft 45R are fixed integrally with the outer surfaces of the left side plate 31L and the right side plate 31R, respectively, coaxially with the central axis 34a of the intermediate transfer member 34. The right side plate 31R of the subframe 31 is provided with a restricted portion 311 that restricts the inclination of the unit 200 in the apparatus main body 100A. The projection of the restricted portion 311 from the side surface of the subframe 31 is smaller than that of the right shaft 45R, as shown in
The unit 200 is located in the apparatus main body 100A by the left shaft 45L, the right shaft 45R, and the restricted portion 311, the details of which will be described later. Since the left shaft 45L, the right shaft 45R, and the inclination restricted portion 311, which are positioning portions for the intermediate transfer member 34 in the apparatus main body 100A, are provided on one subframe 31, the intermediate transfer member 34 is located in the apparatus main body 100A with high accuracy. As described above, the subframe 31 is provided with the cartridge mount portions 321 for detachably mounting the cartridges 33. The function of the mount portions 321 will be described later.
Image-Forming-Unit Mount Portion
As shown in
As shown in
Mounting of Image Forming Unit
Next, the mounting of the unit 200 into the apparatus main body 100A will be described with reference to
The lower end of the cover unit 10 is rotatably connected to the apparatus main body 100A via a hinge shaft 10a and can be located at a closing position (
As shown in
The mounting of the unit 200 into the apparatus main body 100A will be described.
First, as shown in
Next, the image forming unit 200 is inserted into the apparatus main body 100A through the openings 100B and 100C. First, the left and right shafts 45L and 45R of the subframe 31 are brought into engagement with the opposing guide portions 80b provided at the left and right guides 80L and 80R of the apparatus main body 100A, respectively (
As the mounting proceeds, the right shaft 45R reaches the rotation restricting portion 80c inside in the longitudinal direction (
As the mounting further proceeds, the left and right shafts 45L and 45R reach the positioning portions 80a (
At that time, the gear 34b (
When the unit 200 is to be removed, the procedure is opposite to the foregoing mounting procedure. Specifically, the upper cover unit 301 is moved to the opening position; the unit 200 is rotated until the inclination restricted portion 311 comes to a position at which it comes into contact with the ceiling surface of the guide portion 80b; and the unit 200 is extracted along the guide portion 80b.
After the unit 200 is mounted by the foregoing procedure, the four cartridges 33 (33Y, 33M, 33C, and 33K) are mounted to the mount portions 321 (321Y, 321M, 321C, and 321K) provided in the subframe 31.
Cover Unit
The cover unit 10, which is a covering member that opens and closes the opening 100B, will be described with reference to
The image forming apparatus 100 of this embodiment is provided with the cover unit 10 for opening and closing the opening 100B.
Cartridge Urging Unit
The cover unit 10 is provided with the urging members 51a to 51d that urge the individual developing cartridges 33, as shown in
As shown in
Scanner Mount Configuration
On the other hand, the cover unit 10 is equipped with the scanner unit 11, which is an exposing unit, as described above.
As shown in
Of the three positioning projection 11a1 to 11a3, the upper two positioning projections 11a1 and 11a2 are cylindrical in shape and are located on the same axis. The two projections 11a1 and 11a2 have longitudinal-position restricting portions 11b1 and 11b2, respectively. As shown in
The housing 10c of the cover unit 10 is a hollow housing, as shown in
As shown in
As shown in
As described above, the scanner unit 11 is mounted in the cover unit 10 via the compressing springs 111 and 112 which are elastic members. The scanner unit 11 is mounted so as to be moved relative to the cover unit housing 10c in any direction if a predetermined force or more is applied thereto.
Positioning of Scanner Unit
Next, the positioning of the scanner unit 11 when the cover unit 10 is located at the closing position at which the opening 100B is closed will be described with reference to
Configuration of Scanner Unit and Subframe
As described above, the scanner unit 11 is mounted in the cover unit 10 via the compressing springs 111 and 112. On the other hand, the subframe 31 of the image forming unit 200 is provided with scanner guides 312a, 312b, and 312c, which are engaged portions corresponding to the positioning projections 11a1 to 11a3 which are engaging portions of the scanner unit 11.
As shown in
As shown in
The portions of the scanner guides 312a and 312b inside the subframe 31 are slopes 312a4 and 312b4 (
The lower scanner guide 312c is a square groove whose corners are R-shaped, as shown in
Behavior of Scanner Unit in Cover-Unit Closing Operation
The scanner unit 11 is mounted in the cover unit 10 via the elastic members, and thus has a certain degree of flexibility. Therefore, when the cover unit 10 is moved close to the closing position, the positioning projections 11a1 and 11a2 are guided to the straight line portions 312a2 and 312b2 of the scanner guides 312a and 312b by the introductory portions 312a3 and 312b3 of the scanner guides 312a and 312b, respectively, as shown in
The closing operation further proceeds, and the cover unit 10 reaches the closing position, the positioning projections 11a1 and 11a2 are guided to the positioning portions 312a1 and 312b1 of the scanner guides 312a and 312b by the straight line portions 312a2 and 312b2 of the scanner guides 312a and 312b, respectively. At that time, the positioning projections 11a1 and 11a2 are located and held at positions coaxial with the positioning portions 312a1 and 312b1 of the scanner guides 312a and 312b, shown in
For the lower positioning projection 11a3, when the cover unit 10 is brought close to the closing position, first a bent portion 11a3A comes into contact with the scanner guide 312c, as shown in
As the closing operation proceeds, the longitudinal-position restricting portion 11b2 of the positioning projection 11a2 of the scanner unit 11 is guided along the slope 312b4 against the urging force of the compressing spring 112. When the cover unit 10 reaches the closing position, the longitudinal-position restricting portion 11b2 is urged to an inner wall 312b5 by the compressing spring 112 to come into the contact position, as shown in
Positioning of Scanner Unit
As described above, when the cover unit 10 is located at the closing position at which the opening 100B is closed, the scanner unit 11 is positioned relative to the subframe 31, as shown in
When the cover unit 10 reaches the closing position, the cover unit 10 is located such that the positioning projections 11a1 and 11a2 are fitted in the positioning portions 312a1 and 312a2 of the scanner guides 312a and 312b, respectively, as shown in
In this state, since the scanner unit 11 is urged in the direction of E1b by the compressing springs 111, the positioning projections 11a1 and 11a2 are pushed against the positioning portions 312a1 and 312a2 of the scanner guides 312a and 312b, respectively.
Therefore, the positioning projections 11a1 and 11a2 in the directions of E1 and E3 are positioned and held at a position in the directions of E1 and E3 at which the positioning projections 11a and 11a2 and the positioning portions 312a1 and 312a2 of the scanner guides 312a and 312b are coaxial. Even if the positions of the positioning projections 11a and 11a2 are determined in the directions of E1 and E3, the scanner unit 11 has flexibility in the direction in which it rotates about the positioning projections 11a1 and 11a2, and thus, it is not completely positioned. Thus, as shown in
With the above positioning configuration, the position of the scanner unit 11 relative to the subframe 31 in the directions of E1 and E3 can be determined.
For the position in the direction of E2, the scanner unit 11 is positioned because the position restricting portion 11b2 of the positioning projection 11a2 is pushed against the inner wall 312b5 of the subframe 31 by the compressing spring 112.
With such a configuration, the scanner unit 11 can be positioned relative to the subframe 31 that supports the intermediate transfer member 34, the drums 32a, and the developing cartridges 33 simply by closing the cover unit 10. As described above, since the positioning of the scanner unit 11 relative to the subframe 31 is performed using the urging forces of the compressing springs 111 and 112 interposed between the scanner unit 11 and the cover unit 10, there is no need to provide a separate urging member only for positioning.
Summary
Thus, the image forming apparatus 100 can perform an image forming operation (printing operation), and thus, the image forming operation as described above is performed on the basis of an image-formation start signal (printing start signal). In other words, a drive output portion (not shown) at the apparatus main body 100A side is connected to the gear 34b serving as a driving input unit for the intermediate transfer member 34 of the unit 200 at the image forming position. The drum gears 32a1 of the individual photosensitive drums 32a are connected to the gear 34b. The gears 50 of the developing rollers 33b of the cartridges 33 are connected to the drum gears 32a1.
Contacts at the apparatus main body 100A side are electrically connected to the electrical contacts between the photosensitive drums 32a and the cartridges 33. This allows the image forming apparatus 100 to perform an image forming operation.
As shown in
This embodiment has been described taking the intermediate transfer member 34 for indirectly transferring images from the drums 32a to the recording medium S as an example of a transfer member; instead, a system of directly transferring images from the drums 32a to the recording medium S is also possible. In this case, the transfer member 34 plays the roll of directly transferring developer images on the drums 32a onto the recording medium S. This embodiment shows the configuration in which the replaceable cartridges are the developing cartridges 33; instead, it is also possible to have a configuration in which the replaceable cartridges are integrated process cartridges 133 in each of which the drum 32a, the charging roller 32b, the cleaning blade 32c, the developing roller 33b serving as a developing unit, etc. are integrated.
As described above, with the configuration of this embodiment, the urging of the cartridges 33 is performed by the urging members 51 attached to the housing 10c of the cover unit 10. On the other hand, the scanner unit 11 is mounted in the housing 10c of the cover unit 10 via the compressing springs 111 and 112 which are elastic members, and the positioned is performed relative to the subframe 31, which is a supporting member, of the image forming unit 200. Thus, this embodiment is configured such that the scanner unit 11 is positioned directly to the subframe 31.
Therefore, if the housing 10c of the cover unit 10 is slightly deformed by urging the cartridges 33, the positions of the compressing springs 111 and 112 may change correspondingly to exert an influence on the force of urging the scanner unit 11. However, such a change in urging force due to the slight positional change has no influence on the position of the scanner unit 11.
Accordingly, this configuration can significantly reduce the adverse influence on an exposing process due to the urging of the cartridges 33 as compared with a configuration in which the scanner unit 11 is fixed in the housing 10c of the cover unit 10.
Furthermore, the scanner unit 11 can be positioned directly to the subframe 31 of the image forming unit 200, which supports and positions the drums 32a to be exposed to light, the cartridges 33, or cartridges each including the drum 32a. Therefore, this can achieve high-accuracy images and can reliably prevent the laser light beams L of the scanner unit 11 from being blocked by the cases 33a of the cartridges 33 or the like to cause underexposure. Here, the direct positioning of the scanner unit to the subframe is that the scanner unit is positioned by part thereof coming into contact with part of the subframe.
While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
This application claims the benefit of Japanese Patent Application No. 2010-273911 filed on Dec. 8, 2010, which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | Kind |
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2010-273911 | Dec 2010 | JP | national |
Number | Name | Date | Kind |
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7356283 | Igarashi | Apr 2008 | B2 |
20090317128 | Jang | Dec 2009 | A1 |
20110142490 | Kikuchi et al. | Jun 2011 | A1 |
Number | Date | Country | |
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20120148293 A1 | Jun 2012 | US |