AU2020202771B2 - Cartridge, and electrophotographic image forming apparatus which uses cartridge - Google Patents

Cartridge, and electrophotographic image forming apparatus which uses cartridge Download PDF

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AU2020202771B2
AU2020202771B2 AU2020202771A AU2020202771A AU2020202771B2 AU 2020202771 B2 AU2020202771 B2 AU 2020202771B2 AU 2020202771 A AU2020202771 A AU 2020202771A AU 2020202771 A AU2020202771 A AU 2020202771A AU 2020202771 B2 AU2020202771 B2 AU 2020202771B2
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Prior art keywords
coupling
cartridge
rotational force
main assembly
irn
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AU2020202771A
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AU2020202771A1 (en
Inventor
Shigeo Miyabe
Masanari Morioka
Takahito Ueno
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Canon Inc
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Canon Inc
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Priority claimed from AU2009258530A external-priority patent/AU2009258530A1/en
Priority claimed from AU2013200114A external-priority patent/AU2013200114A1/en
Application filed by Canon Inc filed Critical Canon Inc
Priority to AU2020202771A priority Critical patent/AU2020202771B2/en
Publication of AU2020202771A1 publication Critical patent/AU2020202771A1/en
Priority to AU2021229186A priority patent/AU2021229186B2/en
Application granted granted Critical
Publication of AU2020202771B2 publication Critical patent/AU2020202771B2/en
Priority to AU2024200278A priority patent/AU2024200278A1/en
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Abstract

CARTRIDGE, AND ELECTROPHOTOGRAPHIC IMAGE FORMING APPARATUS WHICH USES CARTRIDGE ABSTRACT A process cartridge (B9) for an electrophotographic image forming apparatus (100) having first and second main assembly engaging portions, wherein said process cartridge is dismountable from the main assembly in a dismounting direction substantially perpendicular to axial directions of the driving shaft, said process cartridge comprising: i) an electrophotographic photosensitive drum, for bearing a latent image, ii) a first coupling member (150) rotatable about the first coupling axis by a first rotational force received from the first main assembly engaging portion, iii) a developing roller, rotatable about a roller axis thereof, for developing the latent image formed on said electrophotographic photosensitive drum, and iv) a second coupling member rotatable about a second coupling axis by a rotational force received from the second main assembly engaging portion, wherein said second coupling member is disengageable from the second main assembly engaging portion by the pivoting movement.

Description

DESCRIPTION CARTRIDGE, AND ELECTROPHOTOGRAPHIC IMAGE FORMING APPARATUS WHICH USES CARTRIDGE
[REFERENCE TO RELATED PATENT APPLICATIONS] This application is a divisional application of Australian Application No. 2019200918 which was filed on 8 February 2019, which is a divisional application of Australian Application No. 2017228653 which was filed on 14 September 2017, which is a divisional application of Australian Application No. 2015203439 which was filed on 22 June 2015, which is a divisional of Australian Application No. 2013200114 which was filed on 10 January 2013, which is a divisional of application of Australian Application No. 2009258530 which entered the National Phase in Australia on 2 November 2010 from International Application No. PCT/JP2009/060822 which was filed on 9 June 2009 and which claims priority from Japanese Patent Application No. 2008-151824 which was filed on 10 June 2008, all of which applications are herein incorporated by reference in their entirety as if fully set forth herein, for all purposes.
[TECHNICAL FIELD] The present invention relates to a cartridge, and an electrophotographic image forming apparatus in which a cartridge is removably mountable. Here, an electrophotographic image forming apparatus means an electrophotographic copying machine, an electrophotographic printer (laser beam printer, LED printer, etc.), and the like. A cartridge means a development cartridge as well as a process cartridge. Here, a development cartridge means a cartridge which has a development roller for developing an electrostatic latent image formed on an electrophotographic photosensitive member, and which is removably mountable in the main assembly of an electrophotographic image forming apparatus. Some electrophotographic image forming apparatuses are structured so that the electrophotographic photosensitive member is a part of the main assembly of the image forming apparatus, whereas some electrophotographic image forming apparatuses are structured so that they employ a process cartridge (processing unit) made up of an electrophotographic photosensitive member and a development roller. A process cartridge is a cartridge in which an electrophotographic photosensitive member and one or more processing means, that is, a charging means, a development roller (developing means), and a cleaning means, are integrally disposed, and which is removably mountable in the main assembly of an electrophotographic image forming apparatus. More specifically, a process cartridge means a cartridge in which an electrophotographic photosensitive member, and at least a development roller (developing means) are integrally disposed so that they can be removably mounted in the main assembly of an electrophotographic image forming apparatus, or a cartridge in which an electrophotographic photosensitive member, a development roller (charging means), and a charging means, are integrally disposed so that they can be removably mounted in the main assembly of an electrophotographic image forming apparatus. It also means a cartridge in which an electrophotographic photosensitive member, a development roller (developing means) and a cleaning means, are integrally disposed so that they can be removably mounted in the main assembly of the electrophotographic image forming apparatus. Further, it means a cartridge in which an electrophotographic photosensitive member, a development roller (developing means), a cleaning means, and a charging means, are integrally disposed so that they can be removably mounted in the main assembly of an electrophotographic image forming apparatus.
A development cartridge or a process cartridge can be removably mounted in the main assembly of an electrophotographic image forming apparatus by a user himself or herself, making it possible for a user to maintain an image forming apparatus by himself or herself, that is, without relying on a service person. Thus, a development cartridge or a process cartridge can significantly improve an electrophotographic image forming apparatus in terms of operability, in particular, in terms of its maintenance.
[BACKGROUND ART]
An electrophotographic image forming apparatus uses a developing apparatus (development roller) to develop an electrostatic latent image formed on an electrophotographic photosensitive member, which is in the form of a drum (which hereafter will be referred to as photosensitive drum). Conventionally, electrophotographic image forming apparatuses are structured as follows:
In the case of some conventional electrophotographic image forming apparatuses, a cartridge (development cartridge or process cartridge) is provided with a gear. It is mounted in the main assembly of an image forming apparatus, in such a manner that the gear of the cartridge meshes with a gear with which the main assembly is provided. Thus, the development roller in the cartridge can be rotated by the rotational force transmitted to the development roller from a motor, with which the main assembly is provided, through the gear of the main assembly and the gear of the cartridge (U.S. Patent No. 7,027,754).
In the case of the conventional electrophotographic image forming apparatuses of the other type, a cartridge is provided with the cartridge portion of the development roller coupling, whereas the main assembly is provided with the main assembly portion of the development roller coupling. Further, the main assembly is provided with a member for moving (forward or backward) the main assembly portion of the development roller coupling so that the main assembly portion of the development roller coupling can be moved forward (toward cartridge) in the axial direction of the coupling to engage the main assembly portion of the coupling with the cartridge portion of the coupling, or backward (away from cartridge) in the axial direction of the coupling to disengage the main assembly portion of the coupling from the cartridge portion of the coupling.
Thus, as the main assembly portion of the development roller coupling is rotated after the proper mounting of the cartridge into the main assembly, the rotational force of the main assembly portion of the development roller coupling is transmitted to the cartridge portion of the development roller coupling, rotating thereby the development roller (U.S. Patent No. 2007/0,160,384).
However, the conventional structural arrangements described above make it necessary that when a cartridge is mounted into, or removed from, the main assembly of an image forming apparatus in the direction which is practically perpendicular to the axial line of the development roller in the cartridge, the main assembly portion of the developer coupling is moved in its axial direction. That is, when a cartridge is mounted or dismounted, the main assembly portion of the development roller coupling has to be moved in the horizontal direction by the opening or closing movement of the cover, with which the main assembly is provided. That is, the opening movement of the cover main assembly has to move the main assembly portion of the development roller coupling in the direction to separate from the cartridge portion of the development roller coupling, whereas the closing movement of the main assembly cover has to move the main assembly portion of the development roller coupling in the direction to engage with the cartridge portion of the development roller coupling.
In other words, one of the conventional technologies described above makes it necessary for the main assembly of an image forming apparatus to be structured so that the abovementioned rotational member (movable member) is moved in the direction parallel to its axial line by the opening or closing movement of the cartridge cover of the main- assembly.
In the case of another conventional structural arrangement, it is unnecessary to move the cartridge driving gear of the main assembly forward or backward in the direction parallel to the axial line of the driving gear at the time of mounting a cartridge into the main assembly of an image forming apparatus, or dismounting the cartridge from the main assembly. Thus, this structural arrangement makes it possible to mount or dismount a cartridge in the direction which is practically perpendicular to the axial line of the cartridge driving gear of the main assembly. In the case of this structural arrangement, however, the portion through which driving force is transmitted from the main assembly to the cartridge is the interface (point of meshing) between the driving force transmitting gear of the main assembly, and the driving force receiving gear of the cartridge, making it difficult to prevent the problem that the development roller fluctuates in its rotational speed.
[DISCLOSURE OF THE INVENTION]
It is an object of the present invention to substantially overcome, or at least ameliorate, one or more disadvantages of existing arrangement.
One or more arrangements disclosed herein seek to provide a cartridge which does not suffer from the above-described problems of the conventional technologies, and also, an electrophotographic image forming apparatus compatible with a cartridge in accordance with the present invention.
One or more of the disclosed arrangements seek to provide a cartridge, the development roller of which smoothly rotates even if the cartridge is mounted in an electrophotographic image forming apparatus which is not provided with a mechanism for moving the main assembly portion of the coupling for transmitting rotational force to the development, in the direction parallel to the axial line of the coupling, and also, to provide an electrophotographic image forming apparatus in which the above described cartridge is removably mountable.
One or more of the disclosed arrangements seek to provide a cartridge which can be removed from the main assembly of an electrophotographic image forming apparatus, which is provided with a cartridge driving shaft, in the direction which is practically perpendicular to the axial line of the cartridge driving shaft, and also, an electrophotographic image forming apparatus in which the cartridge described above is removably mountable.
One or more of the disclosed arrangements seek to provide a cartridge which can be mounted into the main assembly of an electrophotographic image forming apparatus, which is provided with a cartridge driving shaft, in the direction which is practically perpendicular to the axial line of the cartridge driving shaft, and also, an electrophotographic image forming apparatus in which the cartridge described above is removably mountable.
One or more of the disclosed arrangements seek to provide a cartridge which can be mounted into, or dismounted from, the main assembly of an electrophotographic image forming apparatus, which is provided with a cartridge driving shaft, in the direction which is practically perpendicular to the axial line of the cartridge driving shaft, and also, an electrophotographic image forming apparatus in which the above described cartridge is removably mountable.
One or more of the disclosed arrangements seek to provide a cartridge which is removable from the main assembly of an electrophotographic image forming apparatus having a cartridge driving shaft, in the direction which is practically perpendicular to the axial line of the cartridge driving shaft, and the development roller of which smoothly rotates, and also, to provide an electrophotographic image forming apparatus in which the above described cartridge is removably mountable.
One or more of the disclosed arrangements seek to provide a process cartridge which is mountable in an electrophotographic image forming apparatus having a cartridge driving shaft, in the direction which is practically perpendicular to the axial line of the cartridge driving shaft, and the development roller of which smoothly rotates, and also, to provide an electrophotographic image forming apparatus in which the above described cartridge is removably mountable.
One or more of the disclosed arrangements seek to provide is a cartridge which can be mounted into, or removed from, the main assembly of an electrophotographic image forming apparatus having a cartridge driving shaft, in the direction which is practically perpendicular to the axial line of the cartridge driving shaft, and the development roller of which smoothly rotates, and also, to provide an electrophotographic image forming apparatus in which the above described cartridge is removably mountable.
One or more of the disclosed arrangements seek to provide a cartridge, the development roller of which rotates more smoothly than the development roller in a cartridge, which receives rotational force from the main assembly of an electrophotographic image forming apparatus by the meshing of its gear with the gear of the main assembly, and also, to provide an electrophotographic image forming apparatus in which the above described cartridge is removably mountable.
One or more of the disclosed arrangements seek to provide a development cartridge (developing device of process cartridge), which reliably transmits rotational force to its development roller having been precisely positioned relative to the photosensitive drum, and can smoothly rotate the development roller, and also, an electrophotographic image forming apparatus in which the process cartridge is removably mountable.
There has been known the so-called contact developing method, which places a development roller in contact with a photosensitive drum to develop an electrostatic latent image on a photosensitive drum.
One or more of the disclosed arrangements seek to provide a cartridge which can smoothly rotates its development roller even if the development roller is moved in the direction to be separated from the photosensitive drum while it is in contact with the photosensitive drum, and also, an electrophotographic image forming apparatus in which the cartridge is removably mountable.
There has been known a combination of an electrophotographic image forming apparatus and a cartridge therefor, which is structured so that the rotational force for rotating the photosensitive drum, and the rotational force for rotating the development roller, are separately received from the main assembly of the image forming apparatus.
One or more of the disclosed arrangements seek to provide a cartridge structured so that the coupling through which the rotational force for rotating the photosensitive drum is moved forward or backward in the direction parallel to its axial line, and also, an electrophotographic image forming apparatus in which the cartridge is removably mountable.
According to an aspect of the present disclosure, there is provided a cartridge for use with a main assembly of an electrophotographic image forming apparatus, said main assembly including a driving shaft having a rotational force applying portion, wherein said cartridge is dismountable from the main assembly in a direction substantially perpendicular to an axial direction of the driving shaft, said cartridge comprising i) a developing roller for developing an electrostatic latent image formed on an electrophotographic photosensitive drum, said developing roller being rotatable about an axis thereof; and ii) a coupling member engageable with said rotational force applying portion to receive a rotational force for rotating said developing roller, said coupling member being capable of taking a rotational force transmitting angular position for transmitting the rotational force for rotating said developing roller to said developing roller and a disengaging angular position in which said coupling member is inclined away from said rotational force transmitting angular position, wherein when said cartridge is dismounted from the main assembly of the electrophotographic image forming apparatus in a direction substantially perpendicular to the axis of said developing roller, said coupling member moves from said rotational force transmitting angular position to said disengaging angular position.
According to another aspect of the present disclosure, there is provided an electrophotographic image forming apparatus to which a cartridge is detachably mountable, said apparatus comprising i) a driving shaft having a rotating force applying portion; and ii) a cartridge including a developing roller for developing an electrostatic latent image formed on an electrophotographic photosensitive drum, said developing roller being rotatable about an axis thereof; and a coupling member engageable with said rotational force applying portion to receive a rotational force for rotating said developing roller, said coupling member being capable of taking a rotational force transmitting angular position for transmitting the rotational force for rotating said developing roller to said developing roller and a disengaging angular position in which said coupling member is inclined away from said rotational force transmitting angular position, wherein when said cartridge is dismounted from the main assembly of the electrophotographic image forming apparatus in a direction substantially perpendicular to the axis of said developing roller, said coupling member moves from said rotational force transmitting angular position to said disengaging angular position.
According to another aspect of the present disclosure, there is provided a cartridge for an electrophotographic image forming apparatus, wherein a main assembly of said apparatus includes a main assembly engaging portion, to be driven by a motor, having a driving shaft and a rotational force applying portion provided on the driving shaft, and an electrophotographic photosensitive drum, wherein said cartridge is dismountable from the main assembly in a dismounting direction substantially perpendicular to an axial direction of the driving shaft, said cartridge comprising: i) a developing roller, for developing a latent image of the electrophotographic photosensitive drum, rotatable about a roller axis thereof; ii) a coupling member rotatable about a coupling axis by a rotational force received from the main assembly engaging portion, said coupling member including a rotational force receiving portion engageable with the rotational force applying portion to receive a rotational force to be transmitted to said developing roller from the main assembly engaging portion, and a rotational force transmitting portion for transmitting the rotational force to said developing roller through said rotational force receiving portion, wherein said coupling member is capable of pivoting movement such that a rotational force receiving portion side of said coupling axis is positioned upstream from a rotational force transmitting portion side of said coupling axis with respect to the dismounting direction, and said coupling member is disengageable from the main assembly engaging portion by the pivoting movement.
According to another aspect of the present disclosure, there is provided a cartridge for an electrophotographic image forming apparatus, wherein a main assembly of said apparatus includes a main assembly engaging portion, to be driven by a motor, having a driving shaft and a rotational force applying portion provided on the driving shaft, and an electrophotographic photosensitive drum, wherein said cartridge is dismountable from the main assembly in a dismounting direction substantially perpendicular to an axial direction of the driving shaft, said cartridge comprising: i) a developing roller, for developing a latent image of the electrophotographic photosensitive drum, rotatable about a roller axis thereof; ii) a coupling member rotatable about a coupling axis by a rotational force received from the main assembly engaging portion, said coupling member including a rotational force receiving portion engageable with the rotational force applying portion to receive a rotational force to be transmitted to said developing roller from the main assembly engaging portion, and a rotational force transmitting portion for transmitting the rotational force to said developing roller through said rotational force receiving portion, wherein said coupling member is capable of pivoting movement so that said coupling axis inclines relative to the roller axis, wherein when said rotational force receiving portion is behind the rotational force applying portion with respect to the dismounting direction, said rotational force receiving portion is retractable from behind the rotational force applying portion by the pivoting movement, by which said coupling member is disengageable from the main assembly engaging portion.
According to another aspect of the present disclosure, there is provided a cartridge for an electrophotographic image forming apparatus, wherein a main assembly of said apparatus includes a main assembly engaging portion, to be driven by a motor, having a driving shaft and a rotational force applying portion provided on the driving shaft, and an electrophotographic photosensitive drum, wherein said cartridge is dismountable from the main assembly in a dismounting direction substantially perpendicular to an axial direction of the driving shaft of the electrophotographic photosensitive drum, said cartridge comprising: i) a developing roller, for developing a latent image, rotatable about a roller axis thereof; ii) a coupling member rotatable about a coupling axis by a rotational force received from the main assembly engaging portion, said coupling member including a rotational force receiving portion engageable with the rotational force applying portion to receive a rotational force to be transmitted to said developing roller from the main assembly engaging portion, and a rotational force transmitting portion for transmitting the rotational force to said developing roller through said rotational force receiving portion, wherein said coupling member is capable of pivoting movement so that said coupling axis inclines relative to the roller axis, wherein when said rotational force receiving portion is behind the rotational force applying portion with respect to the dismounting direction, said rotational force receiving portion is retractable from behind the rotational force applying portion by such pivoting movement of said coupling member that a rotational force receiving portion side of said coupling axis is positioned upstream from a rotational force transmitting portion side of said coupling axis with respect to the dismounting direction, by which said coupling member is disengageable from the main assembly engaging portion.
According to another aspect of the present disclosure, there is provided a cartridge for an electrophotographic image forming apparatus, wherein a main assembly of said apparatus includes a main assembly engaging portion, to be driven by a motor, having a driving shaft and a rotational force applying portion provided on the driving shaft, and an electrophotographic photosensitive drum, wherein said cartridge is dismountable from the main assembly in a dismounting direction substantially perpendicular to an axial direction of the driving shaft, said cartridge comprising: i) a developing roller, for developing a latent image of the electrophotographic photosensitive drum, rotatable about a roller axis thereof; ii) a coupling member rotatable about a coupling axis to transmit a rotational force for rotating said developing roller, said coupling member including a plurality of rotational force receiving portions provided on a phantom circle about the coupling axis at diametrically opposite positions, and a rotational force transmitting portion for transmitting the rotational force to said developing roller through said rotational force receiving portion, wherein said coupling member is pivotable so that said coupling axis inclines relative to the roller axis; iii) a rotational force receiving member for receiving the rotational force from the rotational force transmitting portion, wherein said coupling member is pivotably connected with said rotational force receiving member, wherein said coupling member is capable of pivoting movement such that with movement of said cartridge in the dismounting direction, a rotational force receiving portion side of the coupling axis is positioned upstream from a rotational force transmitting portion side of the coupling axis with respect to the dismounting direction, wherein when said rotational force receiving portion is behind the rotational force applying portion with respect to the dismounting direction, said rotational force receiving portion is retractable from behind the rotational force applying portion by the pivoting movement of said coupling member, by which said coupling member is disengageable from the main assembly engaging portion.
According to another aspect of the present disclosure, there is provided an electrophotographic image forming apparatus for forming an image on a recording material, said apparatus comprising: a main assembly including a main assembly engaging portion, to be driven by a motor, having a driving shaft and a rotational force applying portion provided on the driving shaft, and an electrophotographic photosensitive drum; a cartridge dismountable from the main assembly in a dismounting direction substantially perpendicular to an axial direction of the driving shaft, said cartridge including, i) a developing roller, for developing a latent image of the electrophotographic photosensitive drum, rotatable about a roller axis thereof; ii) a coupling member rotatable about a coupling axis thereof by a rotational force received from the main assembly engaging portion, said coupling member including a rotational force receiving portion engageable with the rotational force applying portion to receive a rotational force to be transmitted to said developing roller from the main assembly engaging portion, and a rotational force transmitting portion for transmitting the rotational force to said developing roller through said rotational force receiving portion, wherein said coupling member is capable of pivoting movement such that a rotational force receiving portion side of said coupling axis is positioned upstream from a rotational force transmitting portion side of said coupling axis with respect to the dismounting direction, and said coupling member is disengageable from the main assembly engaging portion by the pivoting movement.
According to another aspect of the present disclosure, there is provided an electrophotographic image forming apparatus for forming an image on a recording material, said apparatus comprising: a main assembly including a main assembly engaging portion, to be driven by a motor, having a driving shaft and a rotational force applying portion provided on the driving shaft, and an electrophotographic photosensitive drum; a cartridge dismountable from the main assembly in a dismounting direction substantially perpendicular to an axial direction of the driving shaft, said cartridge including, i) a developing roller, for developing a latent image of the electrophotographic photosensitive drum, rotatable about a roller axis thereof, and ii) a coupling member rotatable about a coupling axis by a rotational force received from the main assembly engaging portion, said coupling member including a rotational force receiving portion engageable with the rotational force applying portion to receive a rotational force to be transmitted to said developing roller from the main assembly engaging portion, and a rotational force transmitting portion for transmitting the rotational force to said developing roller through said rotational force receiving portion, wherein said coupling member is capable of pivoting movement so that said coupling axis inclines relative to the roller axis, wherein when said rotational force receiving portion is behind the rotational force applying portion with respect to the dismounting direction, said rotational force receiving portion retractable from behind the rotational force applying portion by the pivoting movement, by which said coupling member is disengageable from the main assembly engaging portion.
According to another aspect of the present disclosure, there is provided an electrophotographic image forming apparatus for forming an image on a recording material, said apparatus comprising: a main assembly including a main assembly engaging portion, to be driven by a motor, having a driving shaft and a rotational force applying portion provided on the driving shaft, and an electrophotographic photosensitive drum; a cartridge dismountable from the main assembly in a dismounting direction substantially perpendicular to an axial direction of the driving shaft, said cartridge including, i) a developing roller, for developing a latent image of the electrophotographic photosensitive drum, rotatable about a roller axis thereof, and ii) a coupling member rotatable about a coupling axis by a rotational force received from the main assembly engaging portion, said coupling member including a rotational force receiving portion engageable with the rotational force applying portion to receive a rotational force to be transmitted to said developing roller from the main assembly engaging portion, and a rotational force transmitting portion for transmitting the rotational force to said developing roller through said rotational force receiving portion, wherein said coupling member is capable of pivoting movement so that said coupling axis inclines relative to the roller axis, wherein when said rotational force receiving portion is behind the rotational force applying portion with respect to the dismounting direction, said rotational force receiving portion is retractable from behind the rotational force applying portion by such pivoting movement of said coupling member that a rotational force receiving portion side of said coupling axis is positioned upstream from a rotational force transmitting portion side of said coupling axis with respect to the dismounting direction, by which said coupling member is disengageable from the main assembly engaging portion.
According to another aspect of the present disclosure, there is provided an electrophotographic image forming apparatus for forming an image on a recording material, said apparatus comprising: a main assembly including a main assembly engaging portion, to be driven by a motor, having a driving shaft and a rotational force applying portion provided on the driving shaft, and an electrophotographic photosensitive drum; a cartridge dismountable from the main assembly in a dismounting direction substantially perpendicular to an axial direction of the driving shaft, said cartridge including, i) a developing roller, for developing a latent image of the electrophotographic photosensitive drum, rotatable about a roller axis thereof; a coupling member rotatable about a coupling axis to transmit a rotational force for rotating said developing roller, said coupling member including a plurality of rotational force receiving portions provided on a phantom circle about the coupling axis at diametrically opposite positions, and a rotational force transmitting portion for transmitting the rotational force to said developing roller through said rotational force receiving portion, wherein said coupling member is pivotable so that said coupling axis inclines relative to the roller axis; iii) a rotational force receiving member for receiving the rotational force from the main assembly engaging portion, wherein said coupling member is pivotably connected with said rotational force receiving member, wherein said coupling member is capable of pivoting such that with movement of said drum unit in the dismounting direction, a rotational force receiving portion side of the coupling axis is positioned upstream from a rotational force transmitting portion side of the coupling axis with respect to the dismounting direction, wherein when said rotational force receiving portion is behind the rotational force applying portion with respect to the dismounting direction, said rotational force receiving portion is retractable from behind the rotational force applying portion by the pivoting of said coupling member, by which said coupling member is disengageable from the main assembly engaging portion. According to another aspect of the present disclosure, there is provided a process cartridge for an electrophotographic image forming apparatus, wherein a main assembly of said apparatus includes first and second main assembly engaging portions, wherein the first main assembly engaging portion having a recess, wherein the second main assembly engaging portion having a driving shaft, and a rotational force applying portion provided on the driving shaft, wherein said process cartridge is mountable to the main assembly in a mounting direction substantially perpendicular to axial directions of the driving shaft, said process cartridge comprising: i) an electrophotographic photosensitive drum, rotatable about a drum axis thereof, for bearing a latent image, and ii) a first coupling member rotatable about the first coupling axis by a first rotational force received from the first main assembly engaging portion, for receiving the first rotational force to be transmitted to said electrophotographic photosensitive drum from the first main assembly engaging portion, wherein said first coupling member is in a form of a projection engageable with the recess of the first main assembly engaging portion; and iii) a developing roller, rotatable about a roller axis thereof, for developing the latent image formed on said electrophotographic photosensitive drum, and iv) a second coupling member rotatable about a second coupling axis by a second rotational force received from the second main assembly engaging portion, said second coupling member including a rotational force receiving portion engageable with the rotational force applying portion to receive a second rotational force to be transmitted to said developing roller from the second main assembly engaging portion, and a rotational force transmitting portion for transmitting the second rotational force to said developing roller from said rotational force receiving portion, wherein said second coupling member is capable of moving between a rotational force transmitting position in which said second coupling axis is parallel to said roller axis and a pre-engagement position in which a rotational force receiving portion side of said second coupling axis is positioned downstream of a rotational force transmitting portion side of said second coupling axis with respect to the mounting direction, and said second coupling member is engageable with the second main assembly engaging portion by moving from the pre-engagement position to the rotational force transmitting position. According to another aspect of the present disclosure, there is provided a process cartridge for an electrophotographic image forming apparatus, wherein a main assembly of said apparatus includes first and second main assembly engaging portions having first and second driving shafts, respectively and first and second rotational force applying portions provided on
13a
the driving shafts, respectively, wherein said process cartridge is dismountable from the main assembly in a dismounting direction substantially perpendicular to axial directions of the driving shafts, said process cartridge comprising: i) an electrophotographic photosensitive drum, rotatable about a drum axis thereof, for bearing a latent image, and ii) a first coupling member rotatable about the first coupling axis by a rotational force received from the first main assembly engaging portion, said first coupling member including a first rotational force receiving portion engageable with the first rotational force applying portion to receive the first rotational force to be transmitted to said electrophotographic photosensitive drum from the first main assembly engaging portion, and the first rotational force transmitting portion for transmitting the first rotational force to said electrophotographic photosensitive drum from said first rotational force receiving portion; and iii) a developing roller, rotatable about a roller axis thereof, for developing the latent image formed on said electrophotographic photosensitive drum, and iv) a second coupling member rotatable about a second coupling axis by a rotational force received from the second main assembly engaging portion, said second coupling member including a second rotational force receiving portion engageable with the second rotational force applying portion to receive a second rotational force to be transmitted to said developing roller from the second main assembly engaging portion, and a second rotational force transmitting portion for transmitting the second rotational force to said developing roller from said second rotational force receiving portion, wherein said first coupling member is capable of first pivoting movement such that a first rotational force receiving portion side of said first coupling axis is positioned upstream of a first rotational force transmitting portion side of said first coupling axis with respect to the dismounting direction, and said first coupling member is disengageable from the first main assembly engaging portion by the first pivoting movement, and wherein said second coupling member is capable of second pivoting movement such that a second rotational force receiving portion side of said second coupling axis is positioned upstream of a second rotational force transmitting portion side of said second coupling axis with respect to the dismounting direction, and said second coupling member is disengageable from the second main assembly engaging portion by the second pivoting movement. In another arrangement there is provided a cartridge which can be removed from the main assembly of an electrophotographic image forming apparatus, which is provided with a cartridge driving shaft, in the direction which is practically perpendicular to the axial line of the cartridge driving shaft, and also, an electrophotographic image forming apparatus in which the cartridge described above is removably mountable.
13b
In another arrangement there is provided a cartridge which can be mounted into the main assembly of an electrophotographic image forming apparatus, which is provided with a cartridge driving shaft, in the direction which is practically perpendicular to the axial line of the cartridge driving shaft, and also, an electrophotographicimage forming apparatus in which the cartridge described above is removably mountable.
In another arrangement there is provided a cartridge which can be mounted into, or
dismounted from, the main assembly of an electrophotographic image forming apparatus,
which is provided with a cartridge driving shaft, in the direction which is practically
perpendicular to the axial line of the cartridge driving shaft, and also, an
electrophotographic image forming apparatus in which the above described cartridge is
removablymountable.
In another arrangement there is provided a cartridge which is to be mounted in the
main assembly of an electrophotographic image forming apparatus having no mechanism
for moving its coupling for transmitting rotational force to the development roller in the
cartridge, in the axial direction of the coupling, and yet, smoothly rotate itsdevelopment
roller.
In another arrangement there is provided a cartridge which smoothly rotates its
development roller even though it is structured so that the direction in which it is to be
moved to be removed from the main assembly of an electrophotographicimage forming
apparatus is practically perpendicular to the axial line of the drive shaft with which themain
assembly is provided.
In another arrangement there is provided a cartridge which smoothly rotates its
development roller even though it is structured so that the direction in which it is to be
moved to be attachedto the main assembly of an electrophotographic image forming
apparatus is practically perpendicular to the axial line of the drive shaft with which the main
assembly is provided.
In another arrangement there is provided a cartridge which smoothly rotates its
development roller even though it is structured so that the direction in which it is to be
moved to be attached to, or removed from, the main assembly of an electrophotographic
image forming apparatus is practically perpendicular to the axial line of the drive shaft with
which the main assembly is provided.
In another arrangement there is provided a combination of an electrophotographic
image forming apparatus and a cartridge therefor, which rotates its development roller more
smoothly than a combinationof an electrophotographic image forming apparatus and a
cartridge therefor, which uses a set of gears to transmit rotational force from the main
assemblyof the image forming apparatus to the cartridge.
In another arrangement there is provided a combination of an electrophotographic
imageforming apparatus and a cartridge therefor, which reliably transmits rotational force
to the development roller in the cartridge and smoothly rotates thedevelopment roller, even
though the combination is structured so that the development roller is positioned relativeto
the photosensitive drum with which the mainassembly of the apparatus is provided.
In another arrangement there is provided a combination of an electrophotographic
image forming apparatus and a cartridge therefor, which smoothly rotates the development
roller in the cartridge, even if the development roller which is in contact withthe
photosensitive drum is moved to be separated from the photosensitive drum.
In another arrangement there is provided a combination of an electrophotographic
image forming apparatus and a cartridge therefor, the mechanism of which for the
photosensitive drum to receive rotational force is structured so that the couplingof the
mechanism is moved in the axial direction of the coupling.
These and other objects, features, andadvantages of the present invention will become
more apparent upon consideration of the following description ofthe preferred
embodiments of the present invention, taken in conjunction with the accompanying
drawings.
[BRIEF DESCRIPTION OF THE DRAWINGS]
Figure 1 is a side sectional view of a
cartridge according to an embodiment of the present
invention.
Figure 2 is a perspective view of the cartridge
according to the embodiment of the present invention.
Figure 3 is a perspective view of the cartridge
according to the embodiment of the present invention.
Figure 4 is a side sectional view of a main
assembly according to the embodiment of the present
invention.
Figure 5 is a perspective view of a developing
roller according to the embodiment of the present
invention.
Figure 6 is a perspective view and a
longitudinal sectional view of the coupling according
to the embodiment of the present invention.
Figure 7 is a side view and a longitudinal
sectional view of the driving gear according to the
embodiment of the present invention.
Figure 8 is a view which shows the assembling
process of the coupling and the driving gear according
to the embodiment of the present invention.
Figure 9 is an exploded perspective view of the
cartridge according to the embodiment of the present
invention.
Figure 10 is a longitudinal sectional view
after the assembling of the cartridge according to an
embodiment of the present invention.
Figure 11 is a perspective view illustrating
the connection state of the development gear and the
coupling.
Figure 12 is a perspective view showing the
state that the coupling inclines.
Figure 13 is a perspective view and a
longitudinal sectional view showing the driving
structure of the main assembly according to an
embodiment of the present invention.
Figure 14 is a perspective view showing the
driving structure of the developing roller according
to an embodiment of the present invention.
Figure 15 is a perspective view of the
cartridge set portion of the main assembly according
to an embodiment of the present invention.
Figure 16 is a sectional view illustrating the
process that the cartridge is mounted to the main
assembly according to an embodiment of the present
invention.
Figure 17 is a perspective view illustrating
the process that the drive shaft and the coupling
engage with each other according to an embodiment of
the present invention.
Figure 18 is a perspective view illustrating the process that the coupling is mounted to the drive shaft according to an embodiment of the present invention.
Figure 19 is a perspective view of the coupling
provided in the main assembly and the coupling
provided in the cartridge according to an embodiment
of the present invention.
Figure 20 is a perspective view illustrating
the process that the coupling is mounted to the drive
shaft according to an embodiment of the present
invention.
Figure 21 is an exploded perspective view
illustrating the drive shaft, the driving gear, the
coupling, and the development shaft according to an
embodiment of the present invention.
Figure 22 is a perspective view illustrating
the process that the coupling disengages from the
drive shaft according to an embodiment of the present
invention.
Figure 23 is a perspective view illustrating
the coupling according to a modified example according
to an embodiment of the present invention.
Figure 24 is a perspective view illustrating
the coupling according to a modified example according
to an embodiment of the present invention.
Figure 25 is an exploded perspective view
illustrating the drive shaft according to a modified example of an embodiment of the present invention.
Figure 26 is a perspective view illustrating
the coupling according to the modified example of the
present invention.
Figure 27 is an exploded perspective view
illustrating the drive shaft, the development shaft
and the coupling only according to the embodiment of
the present invention.
Figure 28 is a side view and a longitudinal
section of the cartridge side according to the
embodiment of the present invention.
Figure 29 is a perspective view of the
cartridge set portion of the main assembly, and a view,
as seen from the device, according to the embodiment
of the present invention.
Figure 30 is a longitudinal sectional view
illustrating the take-out process in which the
cartridge according to the embodiment of the present
invention is taken out of the main assembly.
Figure 31 is a longitudinal sectional view
illustrating the mounting process in which the
cartridge according to the embodiment of the present
invention is mounted to the main assembly.
Figure 32 is a perspective view and a top plan
view of the coupling according to a second embodiment
of the present invention.
Figure 33 is a perspective view illustrating the mounting operation of the cartridge according to the second embodiment of the present invention.
Figure 34 is a top plan view of the cartridge,
as seen in the mounting direction, in the state of
mounting the cartridge according to the second
embodiment of the present invention.
Figure 35 is a perspective view illustrating
the cartridge in the state that the drive of the
cartridge according to the second embodiment of the
present invention stops.
Figure 36 is a longitudinal sectional view and
a perspective view illustrating the operation of
taking out the process cartridge according to the
second embodiment of the present invention.
Figure 37 is a sectional view illustrating the
state of opening the door provided in the main
assembly according to an embodiment of the present
invention.
Figure 38 is a perspective view illustrating a
mounting guide of the driving side of the main
assembly according to an embodiment of the present
invention.
Figure 39 is a side view of the driving side of
the cartridge according to an embodiment of the
present invention.
Figure 40 is a perspective view of the
cartridge as seen from the driving side according to
.22
an embodiment of the present invention.
Figure 41 is a side view illustrating the state
of inserting the cartridge into the main assembly
according to an embodiment of the present invention.
Figure 42 is an exploded perspective view
illustrating the state of mounting the pressing member
(peculiar to the present embodiment) to the
development supporting member according to an
embodiment of the present invention.
Figure 43 is an exploded perspective view
illustrating a development supporting member, a
coupling, and a development shaft according to an
embodiment of the present invention.
Figure 44 is a perspective view illustrating
the driving side of the cartridge according to an
embodiment of the present invention.
Figure 45 is a longitudinal sectional view
illustrating the engaged state between the drive shaft
and the coupling according to an embodiment of the
present invention.
Figure 46 is a side view illustrating the
driving side of the cartridge according to an
embodiment of the present invention.
Figure 47 is a perspective view illustrating
the driving side of the main assembly guide according
to an embodiment of the present invention.
Figure 48 is a side view illustrating the relation between the cartridge and the main assembly guide according to an embodiment of the present invention.
Figure 49 is a side view and a perspective view
illustrating the relation between the main assembly
guide and the coupling according to an embodiment of
the present invention.
Figure 50 is a side view, as seen from the
driving side, of the process in which the cartridge
according to an embodiment of the present invention is
mounted to the main assembly.
Figure 51 is a side sectional view of the
cartridge according to an embodiment of the present
invention.
Figure 52 is a perspective view of the
cartridge according to an embodiment of the present
invention.
Figure 53 is a longitudinal sectional view of
the cartridge according to an embodiment of the
present invention.
Figure 54 is a side sectional view of the
cartridge according to an embodiment of the present
invention.
Figure 55 is a longitudinal sectional view of
the cartridge according to an embodiment of the
present invention.
Figure 56 is a perspective view of the cartridge according to an embodiment of the present invention.
Figure 57 is a perspective view illustrating a
state that the development supporting member of the
cartridge according to an embodiment of the present
invention is omitted.
Figure 58 is a side sectional view of the
cartridge according to an embodiment of the present
invention.
Figure 59 is a perspective view of the
cartridge according to an embodiment of the present
invention.
Figure 60 is a side sectional view of the main
assembly according to an embodiment of the present
invention.
Figure 61 is a perspective view of the
cartridge set portion of the main assembly according
to an embodiment of the present invention.
Figure 62 is a schematic illustration, as seen
from the upper part of the device, of the process in
which the process cartridge according to an embodiment
of the present invention is mounted to the main
assembly.
Figure 63 is a perspective view of the process
cartridge according to an embodiment of the present
invention.
[BEST MODE FOR CARRYING OUT THE INVENTION]
(Embodiment 1)
To begin with, the present invention will be
described with reference to one of the examples of a
development cartridge compatible-with the present
invention.
It should be noted here that a development
cartridge is an example of a process cartridge.
(1) Description of Development Cartridge
First, referring to Figures 1 - 4, a development
cartridge B (which hereafter will be referred to
simply as cartridge), which is one of the embodiments
of the present invention, will be described. Figure 1
is a sectional view of the cartridge B. Figures 2 and
3 are perspective views of the cartridge B. Further,
Figure 4 is a sectional view of the main assembly A of
an electrophotographic image forming apparatus (which
hereafter will be referred to simply as main assembly
A). The cartridge B is attachable to, or detachable
from, the main assembly A by a user.
Referring to Figures 1 - 4, the cartridge B has a
development roller 110. Referring to Figure 4, the
cartridge B is mounted in the main assembly A. It
rotates by receiving rotational force from the main
assembly A through a coupling mechanism (which will be described later) while the cartridge B is properly situated in its image forming position in the main assembly A.
The development roller 110 supplies the portion
of an electrophotographic photosensitive drum 107
(which hereafter will be referred to simply as
photosensitive drum) (Figure 4), which is in the
development area of the apparatus main assembly A,
with developer t. It develops an electrostatic latent
image on the peripheral surface of the photosensitive
drum 107, with the use of the developer t. There is a
magnetic roller 111 (stationary magnet) in the
development roller 110.
The cartridge B is provided with a development
blade 112, which is in contact with the development
roller 110. The development blade 112 regulates the
amount by which the developer t is allowed to remain
on the peripheral surface of the development roller
110. It also frictionally charges the developer t.
The developer t is stored in the developer
storage portion 114 of the cartridge B, and is sent
into the development chamber 113a of the cartridge B,
by the rotation of the toner stirring members 115 and
116 of the cartridge B. The development roller 110 is
rotated while voltage is applied to the development
roller 110. As a result, a layer of the frictionally
charged developer t is formed on the peripheral surface of the development roller 110 by the development roller 110. The charged toner particles in this layer of the frictionally charged developer are transferred onto the photosensitive drum 107 in the pattern of the abovementioned electrostatic latent image; the development roller 110 develops the latent image.
The developed image on the photosensitive drum
107, that is, the image formed of the developer t, is
transferred onto a sheet of recording medium 102 by a
transfer roller 104. The recording medium may be any
medium on which an image can be formed (onto which
image formed of developer (toner) can be transferred).
For example, it may be an ordinary piece of paper, OHP
sheet, and the like.
The cartridge B has a development unit 119, which
is made up of a developing means holding frame 113 and
a developer storing frame 114. More specifically, the
development unit 119 has the development roller 110,
development blade 112, developing means frame portion,
development chamber 113a, developer storing frame
portion 114, and stirring members 115 and 116.
The development roller 110 is rotatable about its
axial line Li.
The apparatus main assembly A is provided with a
cartridge compartment 130a, into which a user is to
mount the cartridge B by holding the cartridge B by the handhold T of the cartridge B. As the cartridge B is mounted, the coupling 150 (rotational force transmitting member, which will be described later) of the cartridge B becomes connected to the drive shaft
180 (Figure 17), with which the apparatus main
assembly A is provided, making it possible for the
development roller 110, etc., to rotate by receiving
rotational force from the apparatus main assembly A.
In a case where a user wants to take the cartridge B
out of the cartridge compartment 130a of the apparatus
main assembly A, the user is to pull the cartridge B
by grasping the handhold T. As the cartridge B is
moved in the direction to be moved out of the
apparatus main assembly A, the coupling 150 of the
cartridge B becomes disengaged from the driving shaft
180.
The direction in which the cartridge B is to be
moved to attach the cartridge B to the apparatus main
assembly A (to mount cartridge into cartridge
compartment 130a), or detach the cartridge B from the
apparatus main assembly A (to dismount cartridge from
cartridge compartment 130a), is practically
perpendicular to the axial line L3 of the drive shaft
180. This subject will be described later in detail.
(2) Description of Electrophotographic Image Forming
Apparatus
Next, referring to Figure 4, the
electrophotographic image forming apparatus which uses
the cartridge B will be described. The image forming
apparatus 100 in this embodiment is a laser beam
printer.
Designated by a referential letter A is the main
assembly of the image forming apparatus 100.
Incidentally, the apparatus main assembly A is what
remains after the removal of the cartridge B from the
image forming apparatus 100.
The apparatus main assembly A is provided with a
charge roller 108 (charging member), which is parallel
to the photosensitive drum 107. The charge roller 108
charges the photosensitive drum 107 with the voltage
applied to the charge roller 108 from apparatus main
assembly A. It is in contact with the photosensitive
drum 107, and is rotated by the rotation of the
photosensitive drum 107.
A drum unit 120 has the photosensitive drum 107
and a cleaning blade 117a (cleaning means). The drum
unit 120 has also a storage bin 117b for removed
developer, a screw 117c for conveying the removed
developer to a box (unshown) with which the apparatus
main assembly A is provided to store the removed
developer, and the charge roller 108. These components
are integrally disposed in the apparatus main assembly
A. That is, the unit 120 (cartridge B) and the apparatus main assembly A are structured so that as the cartridge B is mounted into the apparatus main assembly A, the photosensitive drum 107 is precisely positioned in its preset position (cartridge position) in the apparatus main assembly A. More specifically, the unit 120 is provided with a pair of bearings
(unshown), which protrude outward from the lengthwise
ends of the cartridge B, one for one, and the axial
line of each of which coincides with the axial line of
the photosensitive drum 107. Thus, when the cartridge
B is in the abovementioned preset image forming
position in the apparatus main assembly A, the
cartridge B is supported by the pair of bearings,
which are in a pair of grooves (unshown), one for one,
with which the apparatus main assembly A is provided.
The removed developer mentioned above is the
developer which was removed from the photosensitive
drum 107 by the blade 117a.
The unit 120 may be made solidly attachable to,
or removably mountable in, the apparatus main assembly
A. As for the structural arrangement for positioning
the unit 120 in the apparatus main assembly A so that
the photosensitive drum 107 in the unit 120 is
precisely positioned for image formation, relative to
the main assembly A, any one of the known structural
arrangements may be employed.
The cartridge B is mounted in the apparatus main assembly A (cartridge compartment 130a). Then, a user is to close the cartridge compartment door 109 with which the apparatus main assembly A is provided. As the cartridge door 109 is closed, the cartridge B is pressed toward the photosensitive drum 107 by the resiliency of a pair of spring 192 which are on the inward side of the door 109 is provided. Therefore, the development roller 110 is kept pressed toward surface of the photosensitive drum 107, in such a manner that a proper amount of distance is maintained between the development roller 110 and photosensitive drum 107 (Figure 4). That is, the cartridge B is precisely positioned relative to the photosensitive drum 107. Thus, the development roller 110 is precisely positioned relative to the photosensitive drum 107. More concretely, the lengthwise ends of the drum shaft (unshown) of the photosensitive drum 107 are fitted with the pair of bearings 107a, one for one, which are coaxial with the drum shaft. Further, the pair of bearings 107a are supported by a pair of bearing positioning portions 150, with which the apparatus main assembly A is provided. Thus, the photosensitive drum 107 is rotatable while remaining precisely positioned relative to the apparatus main assembly A (Figures 4 and 5).
The door 109 is to be opened by a user when the
cartridge B needs to be attached to the apparatus main
. 32
assembly A by the user, or when the cartridge B needs
to be taken out the apparatus main assembly A by the
user.
The image forming operation to be carried out by
this electrophotographic image forming apparatus is as
follows: The rotating photosensitive drum 107 is
uniformly charged by the charge roller 108, across the
portion of its peripheral surface, which is moving in
contact with the charge roller 108. Then, a beam of
laser light is projected, while being modulated with
the information regarding the image to be formed, upon
the charged portion of the peripheral surface of the
photosensitive drum 107, by an optical means 101
having laser diodes, polygon mirror, lenses, and
deflective mirrors (which are not shown). As a result,
an electrostatic latent image, which reflects the
information regarding the image to be made, on the
peripheral surface of the photosensitive drum 107.
This latent image is developed by the abovementioned
development roller 110.
Meanwhile, in synchronism with the development of
the electrostatic latent image, a sheet of recording
medium 102 in a cassette 103a is sent out of the
cassette 103, and then, is conveyed to the image
transferring position by pairs 103c, 103d, and 103e,
of recording medium conveyance rollers. There is a
transfer roller 104 (transferring means) in the transferring position. To the transfer roller 104, voltage is applied from the apparatus main assembly A.
As a result, the image formed on the photosensitive
drum 107, of the developer, transfers onto the sheet
of recording medium 102.
The apparatus main assembly A is provided with a
cleaning blade 117a, which extends from one lengthwise
end of the photosensitive drum 107 to the other, and
the cleaning edge of which is elastically in contact
with the peripheral surface of the photosensitive drum
107. The cleaning blade 117a is for removing the
developer t remaining on the peripheral surface of the
photosensitive drum 107 after the transfer of the
developer image onto the recording medium 102. After
the removal of the developer t from the peripheral
surface of the photosensitive drum 107 by the blade
117a, the developer t is temporarily stored in the
developer bin 117b. Then, the removed developer t in
the developer bin 117b is conveyed to abovementioned
box (unshown) for removed developer, by a developer
conveying screw 117c in the developer bin 117b, and
then, is accumulated in the box.
After the transfer of the developer image onto
the recording medium 102, the recording medium 102 is
conveyed to a fixing means 105 by a guide 103f. The
fixing means 105 is provided with a driving roller
105c, and a fixing roller 105 which contains a heater
105a. The fixing means 105 fixes the developer image
to the recording medium 102 by applying heat and
pressure to the recording medium while the recording
medium 102 is conveyed through the fixing means 105.
After the formation of the image on the recording
medium 102 (after the fixation of the developer image
on recording medium 102), the recording medium 102 is
conveyed further, and then, is discharged into a tray
106, by a pair of rollers 103g and a pair of rollers
103h. The pairs of rollers 103c, 103d, and 103e, guide
103f, and pairs of rollers 103g and 103h, etc., make
up the recording medium conveying means 103.
The cartridge compartment 130a is the room
(space) in which the cartridge B is to be set. As the
cartridge B is mounted into this room, the coupling
150 of the cartridge B (which will be described later)
becomes connected to the drive shaft 180 with which
the apparatus main assembly A is provided. In this
embodiment, the placement of the cartridge B in the
cartridge compartment 130a is synonymous to the
attachment of the cartridge B to the apparatus main
assembly A. Further, the removal of the cartridge B
from the cartridge compartment 130a is synonymous to
the detachment of the cartridge B from the apparatus
main assembly A.
(3) Structure of Development Roller
Next, referring to Figure 5, the development
roller 110 will be described about its structure.
Figure 5(a) is a perspective view of the development
roller 110 as seen from its rotational force receiving
side (which hereafter may be referred to as driving
force receiving side). Figure 5(b) is a perspective
view of the development roller 110 as seen from the
opposite side from the driving force receiving side
(which hereafter may be referred to simply as opposite
side).
The development roller 110 is made up of a
development roller cylinder 110a, a development roller
flange 151 (which is at driving force receiving end),
a development roller flange 152 (which is at opposite
end), and a magnetic roller 111.
The development roller cylinder 110a is made up
of a cylinder made of an electrically conductive
cylinder, such as an aluminum cylinder, and a coated
layer. The cylinder 110a bears the developer on its
peripheral surface. The developer borne on the
cylinder 110a is charged. The lengthwise ends of the
cylinder 110a are provided with openings 110al and
110a2, one for one, which are roughly the same in
diameter as the cylinder 110a, and are fitted with the
abovementioned flanges 151 and 152, respectively.
The flange 151 is formed of a metallic substance,
such as aluminum, stainless steel, etc. However, it may be formed of a resinous substance, as long as it can withstand the amount of torque necessary to rotate the development roller 110.
The flange 151 is provided with a gear fitting
portion 151c, around which the development roller gear
153 (Figure 8(b)) for driving the developer stirring
members 115 and 116 (Figure 1), etc., is fitted. It is
also provided with a bearing fitting portion 151d,
around which the development roller bearing 138 is
fitted to rotatably support the development roller 110.
The gear fitting portion 151c and bearing fitting
portion 151d are coaxial with the flange 151. The
flange 151 is also provided with an internal cavity
for supporting the magnetic roller 111, which will be
described later. The development roller gear 153, with
which the flange 151 is fitted, is fitted with the
coupling 150 (which will be described later) in such a
manner that the coupling 150 can be tilted relative to
the axial line of the development roller 110 even
while being moved.
The flange 152 is made of a metallic substance,
such as aluminum or stainless steel, as is the flange
151. The flange 152 also may be made of a resinous
substance as long as it can withstand the amount of
load to which the development roller 110 is subjected.
Further, the axial line of the cylinder fitting
portion 152b roughly coincides with that of the bearing 152a. Further, one of the lengthwise end portions of the magnetic roller 111 is made to extend beyond the corresponding lengthwise end of the development roller 110, and is supported by the bearing 152a.
The magnetic roller 111 is formed of a magnetic
substance, or a resinous substance into which magnetic
particles have been mixed. The magnetic roller 111 is
provided with two to six magnetic poles, which are
distributed in its circumferential direction. It
contributes to the conveyance of the developer, by
holding the developer on the peripheral surface of the
development roller 110.
The above-described magnetic roller 111 is placed
in the development roller cylinder 110a, and the
fitting portion 151a of the flange 151 is fitted in
the opening 110al of the development roller cylinder
110a. Further, the fitting portion 152b of the flange
152 is fitted in the opening 110a2 of the other
lengthwise end of the development roller cylinder 110a.
The method for solidly attaching the flanges 151 and
152 to the development roller cylinder 110a is
adhesion, crimping, etc. Further, a spacer 136, the
development roller bearing 138, and the development
roller gear (unshown) are fitted from the driving
force receiving side of the development roller 110.
Further, a spacer 137 and development roller contact
156 is fitted from the opposite side of the
development roller 110.
The spacers 136 and 137 are the members for
regulating the gap between the development roller 110
and photosensitive drum 107. There are cylindrical
members formed of a resinous substance, and are
roughly 200 - 400 pm in thickness. The spacer 136 is
fitted around one of the lengthwise end portions of
the development roller cylinder 110a, and the spacer
137 is fitted around the other lengthwise end portion
of the development roller cylinder 110a. With the
fitting of the development roller 110 with the spacers
136 and 137, a gap of roughly 200 - 400 pm is
maintained between the development roller 110 and
photosensitive drum 107.
The bearing 138 is the bearing for rotatably
supporting the development roller 110 by the
development unit frame 113 (Figure 1).
The development voltage contact 156 is formed of
an electrically conductive substance (primarily,
metallic substance), and is in the form of a coil. The
internal surface of the electrically conductive
development roller cylinder 110a, or the flange 152,
is provided with the development voltage contact 156b.
In this embodiment, the image forming apparatus is
structured so that the development voltage contact 156
contacts the flange 152. Thus, as the cartridge B is mounted in the apparatus main assembly A, electrical connection is established between the apparatus main assembly A and cartridge B through the external electrical contact (unshown) of the cartridge B and the electrical contact 156a of the apparatus main assembly A. That is, while the cartridge B is in its image forming position in the apparatus main assembly
A, the electrical contacts (unshown), with which the
apparatus main assembly A is provided, remain in
contact with the external electrical contacts of the
cartridge B, making it possible for the cartridge B to
receive electrical voltage from the apparatus main
assembly A. The voltage received by the external
electrical contact of the cartridge B is supplied to
the development roller 110 through the electrical
contact 156.
(5) Rotational force transmitting portions (coupling
member)
Then, referring to Figure 6, an example of the
coupling member which is the rotational force
transmitting portion will be described. Figure 6 (a)
is a perspective view of a coupling member, as seen
from the main assembly side, figure 6 (b) is a
perspective view of the coupling member, as seen from
the developing roller side. Figure 6 (c) is a view, as
seen in a direction perpendicular to a direction of the coupling axis L2. Figure 6 (d) is a side view of the coupling member, as seen from the main assembly side, figure 6 (e) is a view, as seen from a developing roller side. Figure 6 (f) is a sectional view taken along the line S3 in Figure 6 (d).
In the state that the cartridge B is set in the
set portion 130a the coupling member (coupling) 150
engages with the drive shaft 180 (Figure 17) of the
main assembly A. The coupling 150 is disengaged from
the drive shaft 180 by taking the cartridge B out of
the main assembly A. In this case, the cartridge B is
moved in a direction substantially perpendicular to a
direction of the axis L3 of the drive shaft 180 from
the set portion in the main assembly A. At the time of
the mounting, the cartridge B is moved to the set
portion of the main assembly A in the direction
substantially perpendicular to the direction of the
axis L3 of the drive shaft 180. In the state of being
in engagement with the drive shaft 180 the coupling
150 receives a rotational force from the motor 186
(Figure 14) provided in the main assembly A through
the drive shaft 180. In addition, the coupling 150
transmits the rotational force to the developing
roller 110. By this, the developing roller 110 is
rotated. Here, the material of the coupling 150 is the
resin material of polyacetal, polycarbonate PPS, or
the like. However, in order to raise the rigidity of the coupling 150, the glass fiber, the carbon fiber, or the like may be mixed in the resin material in accordance with the required load torque. When such material is mixed, a rigidity of the coupling 150 can be raised. In addition, in the resin material, the rigidity may further be raised by inserting a metal member. In addition, the whole coupling 150 may be manufactured from metal or the like. In addition, the material of the coupling is similar also in the embodiments as will be described hereinafter. The coupling 150 has three main parts (Figure 6 (c)).
The first portion is a driven portion 150a
which has a rotational force reception surface
(rotational force receiving portion) 150e (150e1 to
150e4) for receiving the rotational force from the pin
182 by engaging with the drive shaft 180. The second
portion is a driving portion 150b for transmitting the
rotational force by engaging with the development gear
153. In addition, the third portion is an intermediate
part 150c between the driven portion 150a and the
driving portion 150b. The development gear 153
transmits the rotational force received by the
coupling 150 from the main assembly A to a developer
supply roller, for example (as will be described
hereinafter).
As shown in Figure 6 (f), the driven portion
150a has a drive shaft insertion opening 150m which is an expanded part which expands in the shape of conic away from the axis L2. As shown in the Figure, the opening 150m constitutes a recess 150z. The recess
150z is co-axial with the rotation axis L2 of the
coupling 150.
The driving portion 150b has a spherical
driving shaft receiving surface 150i. By the receiving
surface 150i, the coupling 150 can substantially pivot
(move) between a rotational force transmitting angular
position and a pre-engagement angular position (or a
disengaging angular position) relative to the axis L1.
By this, the coupling 150 engages with the drive shaft
180 without being obstructed by a free end portion
180b of the drive shaft 180, irrespective of a
rotational phase of the developing roller 110. As
shown in the Figure, the driving portion 150b has a
projecting configuration.
And, a plurality of drive receiving projections
150dl-d4 are provided on the circumference (Figure 6
(d), phantom circle Cl) of an end surface of the
driven portion 150a. In addition, the drive receiving
stand-by portions 150kl, 150k2, 150k3, 150k4 is
provided between the adjacent projections 150d 1 or
150d 2 or 150d3, 150d4. The intervals of the adjacent
projections 150dl-d4 are larger than an outer diameter
of the pins 182 so that the pins (the rotational force
applying portions) 182 can enter the intervals. These clearance portions of the intervals are standing-by portions 150kl-k4. Furthermore, in Figure 6 (d), the clockwise downstream side of the projection 150d is provided with a rotational force reception surface
(the rotational force receiving portion) 150e crossing
with the rotational direction of coupling 150, and
(150el-e4). When the drive shaft 180 rotates, the pins
182 abut to one of the receiving surfaces 150el-e4.
And, the receiving surfaces 150el-e4 are pushed by the
peripheries of the pins 182, so that the coupling 150
rotates about the axis L2.
The driving portion 150b has a spherical
surface. For this reason, in the cartridge B,
irrespective of the rotational phase of the developing
roller 110, the coupling 150 can substantially pivot
(move) between the rotational force transmitting
angular position and the pre-engagement angular
position (or the disengaging angular position). In the
illustrated example, the driving portion 150b is
constituted by the spherical developing shaft
receiving surface 150i which has the axis L2 as the
axis thereof. And, at the position passing through the
center thereof, a fixing hole 150g penetrated by the
pin (the rotational force transmitting portion) 155 is
provided.
As has been described hereinbefore, the
coupling 150 has the recess 150z co-axial with the rotation axis L2 of the coupling 150. In the state that the coupling 150 is in the rotational force transmitting angular position, the recess 1.50z covers the free end of the drive shaft 180. And, the rotational force reception surface 150e (150el to
150e4) engages with the rotational force transmitting
pins (rotational force applying portion) 182 which
project in the direction perpendicular to the axis L3
of the drive shaft 180 in the free end portion of the
drive shaft 180 in the rotational direction of the
coupling 150. The rotational force reception surface
150e is the rotational force receiving portion. The
pin 182 is the rotational force applying portion. In
this manner, the coupling 150 receives the rotational
force from the drive shaft 180 to rotate. In
dismounting the cartridge B from the main assembly A
the cartridge B is moved, so that the coupling 150
moves in the direction substantially perpendicular to
the axis Li of the developing roller 110, in the
cartridge In response to the movement of the cartridge
B, the coupling 150 pivots (moves) to the disengaging
angular position from the rotational force
transmitting angular position, so that a part of
recess 150z (free end position 150A1) circumvents the
drive shaft 180. By this, the coupling 150 can
disengage from the drive shaft 180.
The rotational force receiving surfaces
(rotational force receiving portions) 150e (150el to
150e4) are positioned, interposing the center S, on
the phantom circle which has a center S on the
rotation axis L2 of the coupling 150 Cl (Figure 6 (d)).
In this embodiment, the rotational force receiving
surfaces 150e are disposed at four places.
Here, the force is uniformly applied to the
coupling 150 by the opposing arrangement of the
rotational force reception surfaces 150e. Accordingly,
the rotational accuracy of the coupling 150 can be
improved.
In the state of being in the rotational force
transmitting angular position the axis L2 of the
coupling 150 is substantially co-axial with the axis
Ll of the developing roller 110. In the state that the
coupling 150 is in the disengaging angular position,
it inclines relative to the axis Ll so that in the
removing direction X6 of dismounting the cartridge B,
the upstream side (free end portion 150 A3) can pass
by the free end of the drive shaft 180 from the main
assembly A.
(6) Development gear
Referring to Figure 7, an example of a
development gear 153 which supports the coupling 150
will be described. Figure 7 (a) is a view, as seen
from the drive shaft side, and Figure 7 (b) is a sectional view taken along a line S4-S4 in Figure 7
(a).
The openings 153g 1 or 153g2 shown in Figure 7
(a) are the grooves extended in a rotational axis
direction of the development gear 153. A space portion
153f is provided between the openings 153g 1, 153g2.
In mounting the coupling 150 to the development gear
153 the pins 155 are received in the opening 153g 1,
153g2. In addition, the developing shaft receiving
surface 150i is accepted in the space portion 153f.
By the above-described structure, in the
cartridge B, irrespective of the rotational phase
(stop position of the pin 155) of the developing
roller 110, the coupling 150 is pivotable (movable)
between the rotational force transmitting angular
position and the pre-engagement angular position (or
the disengaging angular position).
In Figure 7 (a), the clockwisely upstream side
of the openings 153g 1, 153g2 is provided with the
rotational force transmitting surfaces (rotational
force transmitted portions) 153h 1, 153h2. The sides
of the rotational force transmitting pin (rotational
force transmitting portion) 155 of coupling 150
contact to the transmitting surfaces 153h 1 or 153h2.
By this, the rotational force is transmitted to the
developing roller 110 from the coupling 150. Here, the
transmitting surface 153h 1-153h2 is the surface which faces in the rotational direction of the development gear 153. Therefore, the transmitting surfaces 153h 1
153h2 are pushed by the sides of the pin 15155. In the
state in which the axis Li and the axis L2 are
substantially co-axial with each other the coupling
150 rotates about the axis L2.
The development gear 153 has transmitted
portions 153h 1 or 153h2 here, and therefore, they
function as a rotational force transmitted member.
Similarly to the projection 15150d, it is
desirable to dispose the rotational force transmitting
surfaces 15150h 1, 15150h2 diametrically opposed on a
circumference.
(7) Assembling of t coupling
Figure 8 is a sectional view illustrating the
process in which the coupling 150 is assembled into
the development gear 153.
Figure 8 (a) is a view illustrating the state
of assembling the drive transmission pin and the
retaining member 156 to the coupling 150 which
comprises two parts. Figure 8 (b) is a view
illustrating the process in which the structure thus
assembled is assembled to the development gear.
The retaining member 156 is locked with the
development gear 153. By this, the coupling 150 is
mounted so that they are pivotable (movable) between the rotational force transmitting angular position and the pre-engagement angular position (or the disengaging angular position). And, the movement, in the direction of the axis L2, of the coupling 150 is restricted. For this reason, the opening 156j has a diameter D15 smaller than the diameter of the shaft receiving surface 150i. More particularly, the movement of the coupling 150 is regulated by the development gear 153 and a retaining member 156. By this, the coupling 150 does not separate from the developing roller (the cartridge).
As shown in Figure 8, the driving portion 150b
of the coupling 150 is in engagement with the recess
(space portion 153f) of the development gear 153.
A specific mounting method of the coupling will
be described.
As shown in Figure 8 (a), the driven portion
150a and the intermediate part 150c are inserted in
the direction X33 relative to the positioning member
150q which has the shaft receiving surface 150i
(driving portion 150c). At this time, the retaining
member 156 is placed between the driven portion 150c
and the positioning member 150q beforehand. In this
state, the pin 155 penetrates the fixing hole 150g of
the positioning member 150q and the fixing hole 150r
of the intermediate portion 150c. By this, the
positioning member 150q is fixed to the intermediate portion 150c.
As shown in Figure 8 (b)., then, the coupling
150 is moved in the direction X33. By this, the
coupling 150 is inserted into the development gear 153.
Then, the retaining member 156 is inserted in the
direction of an arrow X33. And, the retaining member
156 is fixed to the development gear 153. By this
mounting method, the coupling 150 can be mounted with
play (gap) between the positioning member 150q and the
development gear 153. By this, the coupling 150 can
change the orientation thereof (inclination and/or
movement relative to the axis L2).
The mounting method of the coupling is not
limited to these mounting methods. For example, what
is required is that the coupling not movable in the
axial direction relative to the development gear 153,
and that inclinable relative to the axis of the
development gear 153 (developing roller 110).
In view of this, for example the coupling is
formed integrally. And, a flexible locking claw is
provided on the development gear 153, and the shaft
receiving surface 150i is locked by this. In this
manner the retention may be accomplished. In addition,
even in this case the retaining member may also be
used.
(8) Assembling of cartridge (developing cartridge)
Referring to Figure 9 and Figure 10, the
mounting of the cartridge will be described. Figure 9
is an exploded perspective view illustrating the
driving side of the cartridge. Figure 10 (a) is the
sectional view taken along the line S4-S4 in Figure 2
wherein the axis L2 is co-axial with the axis Li.
Figure 10 (b) is a sectional view taken along the line
S5-S5 in Figure 2.
The development gear 153 which has the coupling
150 is fixed to the one-end portion (developing roller
flange 151) of the developing roller 110 so that the
driving portion 150a is exposed.
The driving side of the integral structure
(developing roller 110, development gear 153, coupling
150) is supported by the bearing member 157, and the
non-driving side is supported by the development
supporting pin (unshown). And, in this state, the
integral structure is rotatably supported on the
developing device frame 119. By this, they are unified
into the cartridge B (Figure 2 and Figure 3).
In this state, the rotational force received
from the drive shaft 180 is transmitted to the
developing roller 110 through the coupling 150 and the
development gear 153.
In addition, in this state, the axis L2 of the
coupling 150 can be in the state of being
substantially co-axial with the axis Li of the developing roller 110 (Figure 10 (a)), and also can be in the state of inclining relative to the axis Li
(Figure 10 (b)).
As shown in Figure 11, here, the coupling 150
is mounted to the developing device frame 119 so that
the axis L2 can incline in any directions relative to
the axis Li. Figure 11 (al) - (a5) is views as seen in
the direction of the drive shaft 180, and is
perspective views of the elements shown in Figure 11
(bl) - (b5). Here, figure 11 (bl) - (b5) illustrates a
substantial entirety of the coupling 150 with the
development gear 153 exploded partially.
In Figure 11 (al) and (bl), the axis L2 is co
axial relative to the axis Li. The state when the
coupling 150 has been inclined upward from this state
is shown in Figure 11 (a2) and (b2). As shown in this
view, when the coupling 150 inclines toward the
opening 153g, the pin 155 is moved along the opening
153g. As a result, the coupling 150 inclines about an
axis AX perpendicular to the opening 153g.
In Figure 11 (a3) and (b3), the coupling 150
inclines rightward. As shown in this view, when the
coupling 150 inclines in the direction perpendicular
to the opening 153g, the pin 155 rotates in the
opening 153g. The pin 155 rotates about the central
axis AY of the pin 155.
In Figure 11 (a4), (b4), and Figure 11 (a5) and
(b5), the state that the coupling 150 is inclined
downward and the state of being inclined leftward are
shown. The description of the rotation axes AX, AY is
omitted for the sake of simplicity.
In the direction different from the described
inclining direction i.g. in the direction shown in
Figure 11 (al) 45 degrees, the rotations in the
direction of the rotation axis AX and in the rotation
axis AY are combined together, and therefore, such an
inclination (the movement) is possible.
In this manner, according to this embodiment,
the axis L2 can incline in the all directions relative
to the axis L1.
In this embodiment, the opening 151g extends in
the direction crossing with the projecting direction
of the pin 155.
In addition, a gap as shown in the Figure
between the development gear (rotational force
transmitted member) 153 and the coupling 150 is
provided. As has been described hereinbefore, the
coupling 150 is inclinable (movable) in all the
directions.
More particularly, the transmitting surface
(rotational force transmitted portion) 153h, (153hl,
h2) is movable relative to the pin 155 (rotational
force transmitting portion). The pin 155 is movable
relative to the transmitting surface 153h. In the rotational direction of the coupling, the transmitting surface 153h and the pin 155 are engaged to each other.
In order to accomplish this, the gap is provided
between the pin 155 and the transmitting surface 153h.
By this, the coupling 150 is pivotable over
substantially all directions relative to the axis Li.
In this manner, the coupling 150 is mounted to the end
of the developing roller 110.
It has been described that the axis L2 is
inclinable in all the directions relative to the axis
Li. However, the coupling 150 does not necessarily 360
degrees need to be inclinable linearly to the
predetermined angle in any direction. In this case,
the opening 150g, for example is more widely set in
the circumferential direction. If it is set in this
manner, it can be rotated to a slight degree by the
coupling 150 relative to the axis L2, even in the case
where the axis L2 cannot linearly incline by the
predetermined angle, when the axis L2 inclines
relative to the axis L1. By this, it can incline to
the predetermined angle. In other words, the amount of
the play of the rotational direction of the opening
150g can be selected properly if necessary.
This point applies to all of the embodiments
described in this specification.
In this manner, the coupling 150 is pivotably
mounted in any direction substantially. For this reason, the coupling 150 is revolvable (movable) over the full-circumference substantially relative to the development gear 153 (axis Li of the developing roller
110). As has been described hereinbefore (Figure 10),
the spherical surface 150i of the coupling 150
contacts to the retaining portion (a part of recess)
156i. For this reason, the coupling 150 is mounted
concentrically with the center P2 of the spherical
surface 150i (Figure 10). More particularly,
irrespective of the phase of the development gear 153
(developing roller 110), the axis L2 of the coupling
150 is inclinable.
In order for the coupling 150 to engage with
the drive shaft 180, the axis L2 inclines toward the
downstream side with respect to the mounting direction
of the cartridge B relative to the axis Li,
immediately before the engagement. As shown in Figure
10 (b), more particularly, the axis L2 is inclined so
that the driven portion 150a is the downstream of the
axis Li with respect to the mounting direction X4. In
Figure 12 (a) - (c), the position of the driven
portion 150a is downstream relative to the mounting
direction X4 in any case.
By the structure described heretofore, as shown
in Figure 10, the shift to the state that the axis L2
is substantially parallel to the axis Li from the
state that the axis L2 inclines, is possible. The maximum possible inclination angle a4 (Figure 10 (b)) between the axis Li and the axis L2 is the inclination angle at which the driven portion 15150a or the intermediate portion 15150c contacts to the development gear 153 or the bearing member 157. This inclination angle is the angle which permits the engagement and disengagement of the coupling 150 relative to the drive shaft 180 at the time of mounting and demounting the cartridge B to the main assembly A.
(9) Drive shaft and driving structure of main assembly
Then, referring to Figure 13 and Figure 14, a
developing roller driving structure of the main
assembly A will be described. Figure 13 is a
perspective view of the main assembly in the state
that the cartridge B is not inserted, wherein the side
plate of the driving side is omitted partially. Figure
14 is a perspective view illustrating only the
developing roller driving structure.
The free end portion 180b of the drive shaft
180 is a semispherical surface. It has a rotational
force transmitting pin 182 as a rotational force
applying portion which penetrates substantially the
center of the cylindrical main part 180a. The
rotational force is transmitted to the coupling 150 by
this pin 182.
The longitudinally opposite side from the free
end portion 180b is provided with a development drive
gear 181 substantially co-axial with the axis L3. The
gear 181 is fixed non-rotatably on the drive shaft 180.
For this reason, when the gear 181 rotates, the drive
shaft 180 also rotates.
The gear 181 receives the rotational force
through a pinion gear (motor pinion) 187, an idler
gear 191, and a photosensitive drum driving gear 190
from the motor 186. For this reason, when the motor
186 rotates, the drive shaft 180 also rotates.
The gear 181 is supported rotatably by the main
assembly A by through bearing member (unshown). At
this time, the gear 181 is not moved in the direction
of the axis Li. For this reason, the gear 181 and the
bearing member (unshown) can be disposed closely
relative to each other.
It has been described that the gear 181
receives the transmission of the rotational force
through the gears from the gear 187. This is not
inevitable. For example, proper modification is
possible from the viewpoint of the convenience of the
disposition of the motor 186. The rotational force may
be transmitted by belt or the like.
In addition, the drive shaft 180 is not moved
in the direction thereof of the axis L3. For this
reason, the gap between the drive shafts 180 and the bearing members 183, 184 is a gap for permitting the rotation of the drive shaft 180. Therefore, the position of the gear 181 relative to the gear 187 can also accurately be determined with respect to the diametrical direction.
However, because of the unavoidable dimensional
tolerance, the drive shaft 180 may have play (gap) in
the direction of the axis L3. In this case, in order
to remove the play, the drive shaft 180 or the gear
181 may elastically be urged by a spring or the like
in the direction of the axis L3.
(10) Structure of Cartridge Guide of Main Assembly
Referring to Figures 15 and 16, the cartridge
mounting means 130 in this embodiment has a pair of
cartridge guides 130R1 and 130L1, with which the main
assembly A is provided.
These guides 130R1 and 130L are in the space
(cartridge compartment 130a) in which the cartridge B
is to be mounted. That is, the cartridge compartment
130a is provided with the cartridge mounting means 130,
the cartridge guides 130R1 and 130L1 of which are
located next to its end walls (left and right walls),
one for one, and extend in the direction in which the
cartridge B is inserted (mounted) into the cartridge
compartment 130a. The two guides 130R1 and 130L1 of
the cartridge mounting means 130 are disposed next to the left and right walls of the cartridge compartment
130a, in such a manner that they squarely oppose each
other across the cartridge compartment 130a (Figure 15
shows side from which cartridge is driven, and Figure
16 shows opposite side from which cartridge is driven).
The cartridge mounting means 130 is provided with the
pair of cartridge guiding portions 130R1 and 130L1,
which guide the cartridge B when the cartridge is
mounted into the cartridge compartment 130a. In terms
of the direction in which the cartridge B is mounted
into the main assembly A, the guiding portion 130R1 is
located at one end (right end, as seen from direction
from which cartridge B is inserted) of the cartridge
compartment 130a, and the guiding portion 130L1 is
located at the other end. They are positioned so that
they oppose each other across the cartridge
compartment 130a. When a user mounts the cartridge B
into the cartridge compartment 130a, the user is to
insert the cartridge B in such a manner that a pair of
portions (bosses, which will be described later)
projecting from the lengthwise ends of the external
portion of the cartridge frame are guided by the
guiding portions 130R1 and 130L1. The procedure for
mounting the cartridge B in the apparatus main
assembly A is as follows: First, a user is to open the
door 109, which can be opened or closed about the
shaft 109a. Then, the user is to insert the cartridge
B into the cartridge compartment 130a while allowing
the abovementioned bosses to be guided by the guiding
portions 130R1 and 130L1. Then, the user is to close
the door 109. The closing of the door 109 ends the
mounting of the cartridge B into the apparatus main
assembly A. Incidentally, the user is to open the door
9 also when the user takes the cartridge B out of the
apparatus main assembly A.
A groove 130R2, which is on the cartridge
driving side of the cartridge compartment 130a,
functions as a clearance for the coupling 150, until
the coupling 150 engages with the drive shaft 180.
The door 109 is provided with a spring 192,
which is on the inward side of the door 109. When the
door 109 is in the closed position, the spring 192
keeps the cartridge B elastically pressed so that a
preset amount of distance is maintained between the
development roller 110 and photosensitive drum 107.
That is, the spring 102 keeps the cartridge B
elastically pressed so that the development roller 110
is kept pressed toward the photosensitive drum 107.
(11) Structural Arrangement for Guiding and
Positioning Development Cartridge
Referring to Figures 2 and 3, the cartridge B
is provided with a pair of cartridge guides 140R1 and
140R2, and a pair of cartridge guides 140L1 and 140L2.
In terms of the axial (lengthwise) direction of the development roller 110, the cartridge guides 140R1 and
140R2 are at one of the lengthwise ends of the
cartridge B, and the cartridge guides 140L1 and 140L2
are at the other lengthwise end.
In this embodiment, the guides 140R1, 140R2,
140L1 and 140L2 are integral parts of the development
unit frame 119, development roller supporting members
157, or development roller bearings 139, and are
integrally molded therewith. They protrude outward of
the cartridge B.
(12) Development Cartridge Mounting Operation
Next, referring to Figure 17, the operation for
mounting the cartridge B into the apparatus main
assembly A will be describe. Figures 17(a) - 17(c) are
cross sectional views of the cartridge B and cartridge
compartment portion of the apparatus main assembly A,
at a plane S6-S6 in Figure 15.
Referring to Figure 17(a), a user is to open
the door 109 of the apparatus main assembly A, and to
mount the cartridge B into the cartridge mounting
means 130 (cartridge compartment 130a).
More specifically, referring to Figure 17(b),
the cartridge B is to be mounted into the cartridge
compartment 130a by inserting the cartridge B into the
apparatus main assembly A in such a manner that the
cartridge guides 140R1 and 140R2, which are on the
driving force receiving side, follow the cartridge guide 130R1 of the apparatus main assembly A, and also, so that the cartridge guides 140L1 and 140L2 (Figure
3), which are on the opposite side from the driving
force receiving side, follow the cartridge guide 130L1
(Figure 16) of the apparatus main assembly A. As the
cartridge B is inserted as described above, the
coupling 150, which is on the driving force receiving
side, and the cylindrical portion 157c of the
development roller supporting member 157, which
surrounds the coupling 150, follow the groove 130R2 of
the guide 130R1, with no contact between the
cylindrical portion 157c and the walls of the groove
130R2.
Then, the cartridge B is to be inserted further
in the direction indicated by an arrow mark X. As the
cartridge B is inserted as described above, the
coupling 150 engages with the drive shaft 180,
allowing the cartridge B to properly settle in the
cartridge compartment 130a (preset position in
'cartridge compartment 130a), as will be described
later in more detail. More specifically, referring to
Figure 17(c), the guide 140R1 comes into contact with
the cartridge positioning portion 130Rla of the guide
130R1. Further, the guide 140L1 comes into contact
with the cartridge positioning portion 130Lla (Figure
16) of the guide 130L1. As described above, the
cartridge B is removably mounted into the cartridge compartment 130a while being assisted by the cartridge mounting means 130. The coupling 150 engages with the driving shaft 180 toward the end of the mounting
(insertion) of the cartridge B into the cartridge
compartment 130a. While the cartridge B remains
properly positioned in the image forming position in
the cartridge compartment 130a, the coupling 150
remains engaged with the drive shaft 180 so that the
cartridge B can perform a part of an image forming
operation. Incidentally, the cartridge compartment
130a is the space in the apparatus main assembly A,
which the cartridge B occupies while the cartridge B
remains in the apparatus main assembly A after being
mounted into the apparatus main assembly A by the user
while being assisted by the cartridge mounting means
130.
As described above, the cartridge B is provided
with the pair of guides 140R1 and 140R2, which
protrude from one of the lengthwise ends of the
cartridge B (Figure 2). In terms of the direction X4
in which the cartridge B is mounted into the apparatus
main assembly A, there is provided a preset amount of
distance (gap) between the guides 140R1 and 140R2.
Further, the cartridge B is also provided with the
pair of guides 140L1 and 140L2, which protrude from
the other lengthwise end of the cartridge B (Figure 3).
In terms of the direction X4 in which the cartridge B is mounted into the apparatus main assembly A, a preset amount of distance (gap) is provided between the guides 140L1 and 140L2.
As for the apparatus main assembly A, one end
of its cartridge compartment 130a, in terms of the
direction perpendicular to the cartridge mounting
direction X4, is provided with the guide 130R1 and
130R2, which align with each other in the direction
parallel to the cartridge mounting direction X4, with
the guide 130R1 positioned higher than the guide 130R2
(Figure 15). The other end of the cartridge
compartment 130a is provided with the guides 130L1 and
130L2, which align with each other in the direction
parallel to the cartridge mounting direction X4
(Figure 16).
Thus, when the cartridge B is mounted into the
cartridge compartment 130a, it is to be inserted into
the cartridge compartment 130a in such a manner that
the guides 140R1 and guide 140R2 are guided by the
guide 130R1, and the bottom surface of the cartridge B
is guided by the guide 130R2 (Figure 17). As for the
opposite side from the guides 140R1 and 140R2, the
guide 140L1 and guide 140L2 are guided by the guide
130L1.
Further, the guides 140R1 (Figure 17) and 140L1
(Figure 16) are precisely positioned relative to the
cartridge compartment 130a by the cartridge positioning portions 130Rla and 130Lla, respectively, after the engagement of the coupling 150 with the drive shaft 180. That is, the cartridge B is precisely positioned in the cartridge compartment 130a after the engagement of the coupling 150 with the drive shaft
180.
How the coupling 150 engages with the drive
shaft 180, and how the coupling 150 disengages from
the drive shaft 180, will be described later.
If it is necessary to remove the cartridge B
from the cartridge compartment 130a, the cartridge B
can be taken out of the cartridge compartment 130a
simply by carrying out in reverse the above described
cartridge mounting operation.
The above described structural arrangement for
the cartridge B and apparatus main assembly A makes it
possible to remove the cartridge B from the cartridge
compartment 130a by moving the cartridge B in the
direction which is practically perpendicular to the
axial line of the drive shaft 180. That is, the
cartridge B can be mounted into, or removed from, the
cartridge compartment 130a, by moving the cartridge B
in the direction which is practically perpendicular to
the axial line of the drive shaft 180.
After the proper positioning of the cartridge B
in the image forming position in the cartridge
compartment 130a of the apparatus main assembly A, the guide 140R1 remains under the pressure from the resiliency of the spring 188R, with which the apparatus main assembly A is provided (Figure 2 as well as Figure 15), whereas the guide 140L1 remains under the pressure from the resiliency of the spring
188L, with which the apparatus main assembly A is
provided (Figure 3 as well as Figure 16). Then, after
the closing of the door 109, the cartridge B is kept
pressed upon the cartridge seat 114a (Figure 4) by the
resiliency of the spring 192R (as for spring 192L,
that is, spring on opposite side from driving force
receiving side, see Figure 16) attached to the inward
surface of the color 109. Thus, the spacers 136 and
137 (Figure 2) fitted around the lengthwise end
portions of the development roller 110, one for one,
are kept in contact with the lengthwise end portions
of the photosensitive drum 107, whereby the preset
amount of distance is maintained between the
development roller 110 and photosensitive drum 107.
In addition, the closing of the cover 109
causes a switching means (unshown) to be turned on,
making it possible for the development roller 110 to
receive the rotational force for rotating the
development roller 110, from the apparatus main
assembly A through the drive shaft 180 and coupling
150.
As described above, the cartridge B is removably mounted in the cartridge compartment 130a by a user while being guided by the cartridge mounting means 130. That is, the cartridge B is mounted into the cartridge compartment 130a while remaining precisely positioned relative to the apparatus main assembly A and photosensitive drum 107. Further, the drive shaft 180 and coupling 150 becomes fully engaged after the precise positioning of the cartridge B in the cartridge compartment 130a.
That is, the coupling 150 is made to take its
rotational force receiving attitude.
That is, the electrophotographic image forming
apparatus in this embodiment is enabled to form an
image, by the mounting of the cartridge B into the
cartridge compartment 130a of the image forming
apparatus.
Incidentally, regarding how the cartridge B is
to be mounted, the apparatus main assembly A and
cartridge B may be structured so that the cartridge B
is to be inserted all the way into the cartridge
compartment 130a by a user himself or herself, or the
cartridge B is to be inserted partway by the user to
make it possible for the cartridge B to be mounted the
rest of the way by another means. For example, the
apparatus main assembly A may be structured so that as
the door 109 is closed, a part of the door 109 comes
into contact with the cartridge B, which has been inserted partway, and then, the cartridge B is pushed into its final position in the cartridge compartment
130a by the rest of the closing movement of the door
109. Or, the cartridge B and apparatus main assembly A
may be structured so that the cartridge B is to be
pushed partway into the cartridge compartment 130a by
a user, and then, the cartridge B is advanced into its
final the position in the cartridge compartment 130a
by its own weight.
As shown in Figure 17, the cartridge B is
mounted and demounted relative to the main assembly A
by moving in the direction substantially perpendicular
to the direction of the axis L3 of the drive shaft 180
(Figure 18). And, the drive shaft 180 and the coupling
150 are in the engaged state or the disengaged state.
The " substantial perpendicularity" will be
described here.
In order to mount and demount the cartridge B
smoothly between the cartridge B and the main assembly
A, the small gap is given between they. More
specifically, small gaps are provided between the
longitudinal directions of the guide 140R1 and the
guide 130R1, between the longitudinal directions of
the guide 140R2 and the guide 130R1, between the
longitudinal directions of the guide 140L1 and the
guide 130L1, and between the longitudinal directions
of the guide 140L2 and the guide 130L2. Therefore, in mounting and demounting the cartridge B relative to the main assembly A, the whole cartridge B may sometimes slightly be slanting within the limits of the gap thereof. Therefore, strictly speaking, the mounting and demounting is sometimes not in the orthogonality direction. However, even in such a case, the functional effect of the present invention is implementable. Therefore, the "substantial perpendicularity" includes the case where the cartridge slightly slanted.
(13) engaging operation and rotational force
transmission between coupling and drive shaft
As has been described in the foregoing, the
coupling 150 of the cartridge B engages with the drive
shaft 180 immediately before being positioned in the
mounting portion 130a (predetermined position), or,
simultaneously with the positioning to the
predetermined position. More particularly, the
coupling 150 is in the rotational force transmitting
angular position. Here, the predetermined position is
the set portion 130a.
Referring to Figure 18 and Figure 19, the
description will be made as to the engaging operation
between the coupling 150 and the drive shaft 180.
Figure 18 is a perspective view illustrating the drive
shaft and the major part of the driving side of the cartridge. Figure 19 is a longitudinal sectional view, as seen from below the main assembly. Here, the engagement means the state in which the axis L2 and the axis L3 are substantially co-axial with each other, and in which the transmission of the rotational force is possible.
As shown in Figure 19, the cartridge B is
mounted to the main assembly A in the direction
(direction of arrow X4) substantially perpendicular to
the axis L3 of the drive shaft 180. Or, it is
dismounted from the main assembly A. The coupling 150
is in the pre-engagement angular position, wherein the
axis L2 (Figure 19 (a)) inclines toward the mounting
direction X4 relative to the axis Li (Figure 19 (a))
of the developing roller 110 beforehand (Figure 18 (a)
and Figure 19 (a)).
As for the structure for inclining the coupling
to the pre-engagement angular position, the structures
of the embodiment 4 as will be described hereinafter
or the embodiment 5 are used for example. However, the
present invention cannot be limited to these, but the
other proper structure can be used.
By the coupling 150 inclining in the direction
described above, the downstream free end position
150Al of the coupling 150 with respect to the mounting
direction X4 is nearer, than the free end 180b3 of the
drive shaft, to the position that the developing roller 110 is provided with respect to the direction of the axis Ll. In addition, the upstream free end position 150A2 is nearer, than the free end 180b3 of the shaft, to the position that the pin 182 is provided with respect to the mounting direction X4
(Figure 19 (a), (b)). Here, the free end position
means the position which is remotest from the axis L2
at position closest to the drive shaft with respect to
the direction of the axis L2 in the driven portion
150a shown in Figure 6 (a), (c). In other words, it is
one of an edge line of the driven portion 150a or an
edge line of the projection 150d of the coupling 150
depending on the rotational phase of the coupling 150,
(Figure 6 (a), (c), 150A).
First, the free end position (a part of
coupling 150) 150A1 of the coupling 150 passes by the
free end 180b3 of the shaft. And, after the coupling
150 passes the free end 180b3 of the shaft, the
receiving surface 150f or the projection 150d contacts
to the free end portion 180b or the pin 182 of the
drive shaft 180 (Figure 19 (b)). The receiving surface
150f and the projection 150d are the cartridge side
contact portions. The drive shaft 180 is the main
assembly side engaging portion. , the pins 182 are the
main assembly side engaging portion and the rotational
force applying portion. In the coupling 150, in
response to the mounting operation of the cartridge B, the coupling 150 inclines (Figure 19 (c)) so that the axis L2 becomes coaxial with the axis L1. The coupling
150 inclines from the pre-engagement angular position,
it pivots (moves) to the rotational force transmitting
angular position at which the axis L2 thereof is
substantially co-axial with the axis L1. Finally, the
position of the cartridge B is determined relative to
the main assembly A. At this time, the drive shaft 180
and the developing roller 110 are substantially co
axial with each other. Furthermore, in this state, the
receiving surface 150f opposes to the spherical
surface free end portion 180b of the drive shaft 180.
And, the coupling 150 and the drive shaft 180 are
engaged with each other (Figure 18 (b) and Figure 19
(d)). In addition, at this time, the pin 155 (unshown)
is positioned in the opening 150g (Figure 6 (b)). In
addition, the pin 182 is positioned in the standing-by
portion 150k. Here, the coupling 150 covers the free
end portion 180b.
As has been described hereinbefore, when the
cartridge B is mounted to the main assembly A, the
coupling 150 makes the following motion. More
particularly, while a downstream part of coupling 150
(free end position 150A1) with respect to the mounting
direction X4 circumvents the drive shaft 180, the
coupling 150 inclines moves toward the rotational
force transmitting angular position from the pre- engagement angular position. The receiving surface
150f constitutes the recess 150z. The recess 150z has
a conical shape. The mounting direction X4 is the
direction for mounting the cartridge B to the main
assembly A.
As has been described hereinbefore, the
coupling 150 is mounted for inclining motion relative
to the axis Ll. And, in response to the movement of
the cartridge B, the a part of coupling 150 (receiving
surface 150f and/or projection 150d) which is the
cartridge side contact portion contacts to the main
assembly side engaging portion (drive shaft 180 and/or
pin 182). By this, the pivoting motion of the coupling
150 is carried out. As shown in Figure 19, the
coupling 150 is mounted in the state that it overlaps,
with respect to the direction of the axis Li, with the
drive shaft 180. However, by the pivoting motion of
the coupling s as described above, the coupling 150
can be engaged with the drive shaft 180 in the
overlapping state.
Furthermore, the engaging operation of the
coupling 150 described above can be carried out
regardless of the phase difference between the drive
shaft 180 and the coupling 150. Referring to Figures
11 and 20, this reason will be described. Figure 20 is
a view showing the respective phases of the coupling
150 and the drive shaft 180. Figure 20 (a) is a view showing the state that the pin 182 and the receiving surface -150f oppose to each other in the downstream side, with respect to the mounting direction X4, of the cartridge. Figure 20 (b) is a view showing the state that the pin 182 and the projection 150d oppose to each other. Figure 20 (c) is a view showing the state that the free end portion 180b and the projection 150d oppose to each other. Figure 20 (d) is a view showing the state that the free end portion
180b and the receiving surface 150f oppose to each
other.
As shown in Figure 11, the coupling 150 is
inclinable in all directions relative to the axis Li
of the developing roller 110. More particularly, the
coupling 150 is revolvable. As shown in Figure 20, for
this reason, in the mounting direction X4 of the
cartridge B, it is inclinable irrespective of the
phase of the development gear 153 (developing roller).
Regardless of the phases of the drive shaft 180 and
the coupling 150, the free end position 150A1 is
inclinable in a set range of the inclination angle of
the coupling 150 so that it is in the developing
roller side beyond the free end 180b3 of the shaft in
the direction of the axis Li. In addition, the range
of the inclination angle of the coupling 150 is set so
that the free end position 150A2 is positioned in the
pin 182 side with respect to the free end 180b3 of the shaft. With such a setting, in response to the mounting operation of the cartridge B, the free end position 150Al with respect to the mounting direction
X4 is passed by the free end 180b3 of the shaft. And,
in the case shown in Figure 20 (a), the receiving
surface 150f contacts to the pin 182. In the case
shown in Figure 20 (b), the projection (engaging
portion) 150d contacts to the pin (rotational force
applying portion) 182. In the case shown in Figure 20
(c), the projection 150d contacts to the free end
portion 180b. In the case shown in Figure 20 (d), the
receiving surface 150f contacts to the free end
portion 180b. Furthermore, by the contact force
between the coupling 150 and the drive shaft 180 at
the time of mounting the cartridge B, the coupling 150
is moved so that the axis L2 is substantially co-axial
with the axis Ll. More particularly, after the
coupling 150 -starts the contact to the drive shaft 180,
the cartridge B is moved, until the axis L2 becomes
substantially co-axial with the axis L1. And, in the
state in which the axis L2 is substantially co-axial
with the axis L1, the cartridge B is positioned in the
main assembly A as described above. By this, the
coupling 150 engages with the drive shaft 180. More
particularly, the recess 150z covers the free end
portion 180b. Therefore, the coupling 150 can be
engaged with the drive shaft 180 (pin 182) irrespective of the phases of the drive shaft 180 and the coupling 150 or the development gear 153
(developing roller).
In addition, as shown in Figure 20, the gap is
provided between the development gear 153 and the
coupling 150, the inclination (movement) is permitted
as described above.
In this embodiment, the case where the coupling
150 pivots in the plane of the sheet of the drawing of
Figure 20 has been described. However, since the
coupling 150 can also revolve as described above, the
pivoting in the direction other than the in of plane
of Figure 20 may be included. Also in such a case, it
results in reaching, from the state of Figure 20 (a),
the state of Figure 20 (d). This applies to the
following embodiments unless otherwise described.
Referring to Figure 21, the rotational force
transmitting operation at the time of rotating the
developing roller 110 will be described. By the
rotational force received from the driving source
(motor 186), the drive shaft 180 rotates with the gear
181 in the direction X8 in the Figure. And, the pin
182 (182al, 182a2) integral with the drive shaft 180
contacts to one of the rotational force receiving
surfaces (rotational force receiving portions) 150el
to 150e4. More particularly, the pin 182al contacts to
one of the rotational force receiving surfaces 150el to 150e4. In addition, the pin 182a2 contacts to one of the rotational force receiving surfaces 150el to
150e4. By this, the rotational force of the drive
shaft 180 is transmitted to the coupling 150 to rotate
the coupling 150. Furthermore, by the rotation of the
coupling 150, the pin 155 (rotational force
transmitting portion) of the coupling 150 contacts to
the development gear 153. By this, the rotational
force of the drive shaft 180 is transmitted to the
developing roller 110 through the coupling 150, the
pin 155, the development gear 153, and the developing
roller flange 151. By this, the developing roller 110
is rotated.
In addition, in the rotational force
transmitting angular position, the free end portion
153b is contacted to the receiving surface 150i. And,
the free end portion (positioning portion) 180b of the
drive shaft 180 is contacted to the receiving surface
(portion to be positioned) 150f. By this, the coupling
150 is, in the state of hanging over the drive shaft
180, positioned relative to the drive shaft 180 (19d
of Figures).
Here, in this embodiment, the developing roller
110 is positioned relative to the photosensitive drum
107 through a spacer member. On the contrary, the
drive shaft 180 is positioned in the side plate of the
main assembly A or the like. In other words, the axis
Li is positioned through the photosensitive drum to
the axis L3. For this reason, the dimensional
tolerance tends to become large. Therefore, the axis
L3 and the axis Li deviate from the co-axial state
easily. In such a case, by inclining to a slight
degree, the coupling 150 can properly transmit the
rotational force. Even in such a case, the coupling
150 can rotate without applying the large load to the
development gear 153 (developing roller 110) and the
drive shaft 180. For this reason, at the time of the
assembling mounting of the drive shaft 180 and the
developing roller 110 (the developing cartridge), the
accuracy required to the positioning adjustment can be
reduced. Therefore, the assembling operativity can be
improved.
This is one of the advantageous effects
according to an embodiment of the present invention in
addition to the effects described above as the effect
of the present invention.
In addition, as it has been described with
Figure 14, the drive shaft 180 and the gear 181 are
positioned, with respect to the diametrical direction
and the axial direction, in the predetermined position
(mounting portion 130a) of the main assembly A. In
addition, the cartridge B is positioned to mounting
portion 130a as described above. And, the drive shaft
180 positioned in the mounting portion 130a and the cartridge B positioned in the mounting portion 130a are coupled with each other by the coupling 150. The coupling 150 is swingable pivotable relative to the developing roller 110). Therefore, as has been described hereinbefore, between the drive shaft 180 positioned in the predetermined position and the cartridge B positioned in the predetermined position, the coupling 150 can transmit the rotational force smoothly. In other words, even when a slight deviation exists between the driving shaft 180 and the developing roller 110, the coupling 150 can transmit the rotational force smoothly.
This is also one of the effects of the present
embodiment according to the present invention.
The coupling 150 contacts to the drive shaft
180. By this, it has been described that the coupling
150 swings to the rotational force transmitting
angular position from the pre-engagement angular
position, but this is not inevitable. For example, an
abutting portion as the main assembly side engaging
portion may be provided in the position other than the
drive shaft of the main assembly. And, in the mounting
process of the cartridge B, after the free end
position 150Al passes by the free end 180b3 of the
drive shaft, a part of coupling 150 (cartridge side
contact portion) contacts to the abutting portion. By
this, the coupling receives the force in the swinging directions (pivoting direction), and it swings
(pivots) so that the axes L2 is substantially coaxial
with the axis L3. In other words, any other means are
usable if the axis Li is able to become substantially
co-axial with the axis L3 in interrelation with the
mounting operation of the cartridge B.
(14) disengaging operation between coupling and drive
shaft and operation for taking out cartridge
Referring to Figure 22, the operation for
disengaging the coupling 150 from the drive shaft 180
In taking out the cartridge B from the main assembly A
will be described. Figure 22 is a sectional view, as
seen from below of the main assembly.
As shown in Figure 22, at the time of
dismounting from the main assembly A, the cartridge B
is dismounted in the direction perpendicular to the
direction substantially to the axis L3 (direction of
the arrow X6).
In the state that the development gear 153
(developing roller 110) does not rotate, the axis L2
of the coupling 150 is substantially co-axial relative
to the axis Li in the rotational force transmitting
angular position (Figure 22 (a)). And, in response to
the user taking the cartridge B out of the mounting
portion 130a, the development gear 153 moves in a
take-out direction X6 with the cartridge B. And, the receiving surface 150f or the projection 150d which is in the upstream side of the coupling 150 with respect to the take-out direction X6 contacts to at least the free end portion 180b of the drive shaft 180 (Figure
22 (a)). And, the axis L2 of the coupling 150 begins
to incline to the upstream side of the take-out
direction X6 (Figure 22 (b)). The direction of the
inclination start of the coupling 150 is the same as
the inclining direction of the coupling 150 (pre
engagement angular position) at the time of the
mounting of the cartridge B. By the operation taking
the cartridge B out of the main assembly A, the
coupling 150 is moved while the upstream side free end
portion 150 A3 with respect to the take-out direction
X6 contacts to the free end portion 180b. In more
detail, the coupling 150 makes the following motion in
response to the movement of the cartridge B in the
take-out direction X6. More particularly, while a part
of coupling 150 (receiving surface 150f and/or
projection 150d) which is the cartridge side contact
portion contacts to the main assembly side engaging
portion (drive shaft 180 and/or pin 182) the coupling
150 is moved. And, in the disengaging angular position,
the axis L2 inclines until the free end portion 150 A3
reaches the free end 180b3 (Figure 22 (c)). And, in
this state, the coupling 150 is passed by the drive
shaft 180, and while contacting to the free end 180b3, it disengages from the drive shaft 180 (Figure 22 (d)).
Thereafter, the cartridge B is taken out of the main
assembly A through the process opposite from the
mounting process described with Figure 17.
As will be apparent from the foregoing
description, the angle of the pre-engagement angular
position relative to the axis Li is larger than the
angle of the disengaging angular position relative to
the axis Li. By this, in consideration of the
dimensional tolerance of the parts, at the time of the
engagement of the coupling, the free end position (a
part of coupling 150) 150A1 can pass assuredly by the
free end portion 180b3 in the pre-engagement angular
position. This is because, in the pre-engagement
angular position, the gap is between the coupling 150
and the free end portion 180b3 (Figure 19 (b)). On the
contrary, at the time of the coupling disengagement,
the axis L2 inclines toward the disengaging angular
position in interrelation with the removal of the
cartridge B. For this reason, the free end portion 150
A3 of the coupling 150 is along the free end portion
180b3. In other words, the upstream side of the
coupling 150 with respect to the cartridge take-out
direction X6 and the free end portion 180b of the
drive shaft 180 are substantially in the same position
(Figure 22 (c)). Therefore, the angle at the pre
engagement angular position relative to the axis Li is larger than the angle at the disengaging angular position relative to the axis Li.
In addition, similarly to the case where the
cartridge B is mounted to the main assembly A, the
cartridge B can be taken out of the main assembly A
irrespective of the phases of the coupling 150 and the
pin 182.
As has been described hereinbefore, in the
state that the cartridge B is set to the main assembly
A, a part of coupling 150 (free end position 150A1) as
seen in the opposite direction to the removing
direction X6 is behind the drive shaft 180 (Figure 19
(d)). And, in dismounting the cartridge B from the
main assembly A the coupling 150 makes the following
motion. In response to moving the cartridge B in the
direction substantially perpendicular to the axis Li,
the coupling 150 is moved inclined to the disengaging
angular position from the rotational force
transmitting angular position so that a part of
coupling 150 (free end position 150Al) circumvents the
drive shaft 180. In the state in which the cartridge B
is mounted to the main assembly A the coupling 150
receives the rotational force from the drive shaft 180
in the rotational force transmitting angular position
of the coupling 150 to rotate. More particularly, the
rotational force transmitting angular position is an
angular position for transmitting the rotational force for rotating the developing roller 110 to the developing roller 110. Figure 21 shows the state that the coupling 150 is in the rotational force transmitting angular position.
The pre-engagement angular position of the
coupling 150 is the angular position of the coupling
150 relative to the axis Li immediately before the
coupling 150 engages with the drive shaft 180 at the
time of mounting the cartridge B to the main assembly
A. More particularly, it is an angular position
relative to the axis Li at which the downstream side
free end portion 150A1 of the coupling 150 can pass by
the drive shaft 180 in the mounting direction of the
cartridge B.
The disengaging angular position of the
coupling 150 is the angular position of the coupling
150 relative to the axis Li when the coupling 150
disengages from the drive shaft 180 in the case where
the cartridge B is removed from the main assembly A.
More particularly, as shown in Figure 22, it is an
angular position relative to the axis Li at which the
free end portion 150 A3 of the coupling 150 can pass
by the drive shaft 180 in the removing direction of
the cartridge B.
In the pre-engagement angular position or the
disengaging angular position, an angle 02 between the
axis L2 and the axis Ll is larger than an angle 01 between the axis L2 and the axis Li in the rotational force transmitting angular position. The angle 91 is preferably zero. However, according to this embodiment, if the angle 91 is below approx. 15 degrees, the smooth transmission of the rotational force is accomplished. It is preferable that the angle 02 is approx. 20-60 degrees.
As has been described hereinbefore, the
coupling is mounted so that it is inclinable relative
to the axis Li. And, in response to the removing
operation of the cartridge B, the coupling 150
inclines. By this, the coupling 150 in the state of
overlapping with the drive shaft 180 with respect to
the direction of the axis Li can be disengaged from
the drive shaft 180. More particularly, the cartridge
B is moved in the direction substantially
perpendicular to the axial direction L3 of the drive
shaft 180. By this, the coupling 150 of the state of
covering the drive shaft 180 can be disengaged from
the drive shaft 180.
In the foregoing description, in interrelation
with the cartridge B moving in the take-out removing
direction X6, the receiving surface 150f or the
projection 150d of the coupling 150 contacts to the
free end portion 180b. By this, the axis L2 starts the
inclination (movement) to the upstream side with
respect to the take-out direction. However, in this embodiment, this is not inevitable. For example, a structure may be employed so that the urging force
(elastic force) is applied beforehand to the upstream
side of the coupling 150 with respect to the take-out
direction. And, in response to the movement of the
cartridge B, by the urging force relative to the
coupling 150, the axis L2 starts the inclination to
the downstream side with respect to the take-out
direction (the movement). The free end 150 A3 passes
by the free end 180b3, and the coupling 150 disengages
from the drive shaft 180. In other words, the coupling
can be disengaged from the drive shaft 180, without
the contact between the upstream (with respect to the
take-out direction of the coupling 150) receiving
surface 150f or projection 150d and the free end
portion 180b. Therefore, if the axis L2 can be
inclined in interrelation with the take-out operation
of the cartridge B, any structure can be applied.
By the time immediately before the coupling 150
is mounted to the drive shaft 180, the driven portion
of the coupling 150 is inclined toward the downstream
side with respect to the mounting direction. In other
words, the coupling 150 is moved to the pre-engagement
angular position beforehand.
The pivoting in the plane of the sheet of the
drawing of Figure 22 has been described, but, the
revolution may be included, similarly to the case of
Figure 19.
As has been described hereinbefore, the axis L2
of the coupling 150 can incline in all directions
relative to the axis Li of the developing roller 110
(Figure 11).
More particularly, the axis L2 is inclinable in
any direction relative to the axis L1. However, as for
the coupling 150, the axis L2 is not necessarily
inclinable linearly to the predetermined angle in any
direction over 360 degrees range. In this case, for
example the opening 150g is more widely formed in the
circumferential direction. With such an opening, when
the axis L2 incline relative to the axis L1, the
coupling 150 can be rotated to a slight degree about
the axis L2 even in the case where it cannot incline
to the predetermined angle linearly. By this, the
coupling 150 can incline to the predetermined angle.
In other words, the amount of the play in the
rotational direction of the opening 150g can be
selected properly if necessary.
In this manner, the coupling 150 is revolvable
(swingable) over the full-circumference thereof
substantially relative to the axis Li of the
developing roller 110. More particularly, the coupling
150 is pivotable substantially over the full
circumference thereof relative to the developing
roller 110.
As will be apparent from the foregoing
description, the coupling 150 is revolvable
substantially over the full-circumference thereof
relative to the axis Li.
Here, the revolution of the coupling does not
mean that the coupling itself rotates about the axis
L2 of the coupling, but means that the inclined axis
L2 rotates about the axis Li of the developing roller
110. However, it does not exclude that the coupling
150 itself rotates about the axis L2 in the range of
the play or the gap provided positively.
More particularly, the coupling 150 is
revolvable so that in the state of positioning the
developing roller 110 side end of the driving portion
150b on the axis L2, the free end of the driven side
150a draws a circle having the center thereof on the
axis L2.
In addition, the coupling 150 is provided to
the end of the developing roller 110 pivotably
substantially in all directions relative to the axis
L1. By this, the coupling 150 can be smoothly pivoted
between the pre-engagement angular position, the
rotational force transmitting angular position, and
the disengaging angular position.
Here, the pivotability substantially in all
directions is as follows. More particularly, when the
user mounts the cartridge B to the main assembly A, the coupling 150 can pivot to the rotational force transmitting angular position irrespective of the stoppage phase of the drive shaft 180 which has the rotational force applying portion.
In addition, when the user dismounts the
cartridge B from the main assembly A, the coupling 150
can pivot to the disengaging angular position
irrespective of the stoppage phase of the drive shaft
180.
In addition, the coupling 150 has the gap
between the rotational force transmitting portion (pin
155, for example), and the rotational force
transmitted portion (rotational force transmitting
surface 153hl, 153h2, for example) which is in
engagement with the rotational force transmitting
portion so that it is inclinable substantially in all
directions relative to the axis L1. In this manner,
the coupling 150 is mounted to the end of the
developing roller 110. Therefore, the coupling 150 is
inclinable substantially in all directions relative to
the axis Ll. As has been described hereinbefore the
coupling of the present embodiment is mounted so that
the axis L2 thereof can incline move in any direction
relative to the axis Ll of the developing roller 110.
Here, the inclination (movement) includes the pivoting,
the swinging, and the revolution described above, for
example.
Referring to Figures 23 - 24, a modified
example of the coupling will be described.
Figure 23 shows a first modified example. A
driving portion 1150b of a coupling 1150 of this
modified example has the expanding shape similarly to
a driven portion 1150a. A development shaft 1153 is
provided co-axially with the developing roller.
The development shaft 1153 has a circular
column portion 1153a, and it has a diameter approx. 5
15mm in consideration of the material, the load, and
the spacing. The circular column portion 1153a is
fixed, by press-fitting, bonding, insert molding, and
so on, to an engaging portion of a developing roller
flange (unshown). By this, the development shaft 1153
transmits the rotational force from the main assembly
A to the developing roller 110 through the coupling
1150 as will be described hereinafter. The circular
column portion 1153a thereof is provided with a free
end portion 1153b. The free end portion 1153b has a
spherical configuration so that when the axis L2 of
the coupling 1150 inclines, it can incline smoothly.
In the neighborhood of a free end of the development
shaft 1153, in order to receive the rotational force
from the coupling 1150, the drive transmission pin
(rotational force transmitting portion, rotational
force receiving portion) 1155 extends in the direction
crossing with an axis Li of the development shaft 153.
The pin 1155 is made of metal, and is fixed by
the press-fitting, bonding, and so on relative to the
development shaft 1153. The position thereof may be
any, if it is such a position that the rotational
force is transmitted (direction crossing with the axis
Li of development shaft 153 (developing roller 110)).
Preferably, it passes through the spherical surface
center of the free end portion 1153b of the
development shaft 1153.
The driven portion 1150a of the coupling 1150.
has the configuration the same as the configuration
described above, and therefore, the description is
omitted for simplicity.
An opening 1150g is provided with a rotational
force transmitting surface (rotational force
transmitting portion) 1150i. In the state of the
coupling is set in the cartridge B, an opening 11501
has a conical shape as an expanded part which expands
toward the side which has the development shaft 153.
By the coupling 1150 rotating, the rotational force
transmitting surface 1150i pushes the pin 1155 to
transmit the rotational force to the developing roller
110.
By this, irrespective of the rotational phase
of the developing roller 110 in the cartridge B, the
coupling 1150 can pivot (move) between the rotational
force transmitting angular position, the pre- engagement angular position, and the disengaging angular position relative to the axis Li without being prevented by the free end portion of the development shaft 1153. In the illustrated example, the receiving surface 1150i is provided with a stand-by opening
1150g (1150gl, 1150g2). The coupling 1150 is mounted
to the development shaft 1153 so that the pin 1155 is
received in the opening 1150g 1 or 1150g2. The size of
the opening 1150g 1 or 1150g2 is larger than the outer
diameter of the pin 1155. By this, irrespective of the
rotational phase of the developing roller 110 in the
cartridge B, the coupling 1150 is pivotable (movable)
between the rotational force transmitting angular
position and the pre-engagement angular position (or
the disengaging angular position), without being
prevented by the pin 1155.
And, the rotational force transmitting surface
1150i pushes the pin 1155 by the rotation of the
coupling 1150 to transmit the rotational force to the
developing roller 110.
Referring to Figure 24, a second modified
example will be described.
In the embodiments described above, the driving
shaft receiving surface or the developing shaft
receiving surface of coupling is conical. In this
embodiment, the different configuration is employed.
A coupling 12150 shown in Figure 24 has three main parts similarly to the coupling 150 shown in
Figure 6. More particularly, the coupling 12150 has a
driven portion 12150a for receiving the rotational
force from the drive shaft 180, a driving portion
12150b for transmitting the rotation to the
development shaft 153, and an intermediate portion
12150c for connecting a driven portion 12150a and a
driving portion 12150b (Figure 24 (b)).
The driven portion 12150a and the driving
portion 12150b are provided with a drive shaft
insertion opening 12150m which expands toward the
drive shaft 180 relative.to the axis L2 and a
development shaft insertion opening 12150v which
expands toward the direction of the development shaft
153, respectively ( Figure 24 (b)). The opening 12150m
and the opening 12150v constitute the expanded parts.
The opening 12150m and the opening 12150v is
constituted by the horn-like driving shaft receiving
surface 12150f and the developing shaft receiving
surface 12150i. The receiving surface 12150f and the
receiving surface 12150i are provided with recesses
12150x, 12150z (Figure 24). At the time of the
rotational force transmission, the recess 12150z
opposes to the free end of the drive shaft 180. More
particularly, the recess 12150z covers the free end of
the drive shaft 180.
As has been described hereinbefore, the developing shaft receiving surface of the coupling has the expanding shape, and therefore, the coupling can be mounted for inclining motion relative to the axis of the development shaft. Furthermore, the driving shaft receiving surface of the coupling has the expanding shape, and therefore, the coupling can be inclined, without interfering with the drive shaft in response to the mounting operation or take-out operation of the cartridge B. By this, in this embodiment, the effects similar to the first embodiment or the second embodiment can be provided.
Each the configurations of the openings 12150m,
12250m and the openings 12150v, 12250v may be a
combination of a horn-like shape and a bell-like shape
or the like.
Referring to Figure 25, a further embodiment of
the drive shaft will be described. Figure 25 is
perspective views of a drive shaft and a development
drive gear.
As shown in Figure 25, the free end of the
drive shaft 1180 has a flat surface 1180b. In this
case, the configuration of the shaft is simple, and
therefore, the manufacturing cost can be reduced.
As shown in Figure 25 (b), a rotational force
applying portion (drive transmitting portion) 1280,
(1280c1, 1280c2) may be integrally molded with a drive
shaft 1280. In the case of the drive shaft 1280 being a molded resin part, the rotational force applying portion may be molded integrally. In this case, the cost reduction can be accomplished. In addition, designated by 1280b is a flat surface portion.
a positioning method of the developing roller
110 in the direction of the axis -Ll will be described.
Here, for example, the description will be made as to
the coupling expanded toward the developing roller in
the axial direction (Figure 24) similarly to the
coupling of the first modified example. However, the
present embodiment can be applied also to the coupling
of the first embodiment.
A coupling 1350 is provided with a tapered
surface (inclinded surface) 1350e, 1350h. The tapered
surface 1350e, 1350h produces a thrust force at the
time of the rotation of the drive shaft 181. By this
thrust force, the coupling 1350 and the developing
roller 110 are correctly positioned in the direction
of the axis Li. Referring to Figure 26 and Figure 27,
a further description is made. Figure 26 is a
perspective view and a top plan view of the coupling
alone. Figure 27 is an exploded perspective view
illustrating a drive shaft, a development shaft, a
coupling.
As shown in Figure 26 (b), the rotational force
reception surface 1350e (1350el to 1350e4, inclinded
surface, rotational force receiving portion) is tapered at the angle a5 relative to the axis L2. When the drive shaft 180 rotates in a direction Ti, the pin
182 and the rotational force reception surface 1350e
contact with each other. Then, a component force is
applied in the direction T2 to the coupling 1350 to
move it in the direction. And, until the driving shaft
receiving surface 1350f (Figure 27a) contacts to the
free end 180b of the drive shaft 180, the coupling
1350 moves in the direction of the axis L2. By this,
the position of the coupling 1350 is determined with
respect to the direction of the axis L2. In addition,
the free end 180b of the drive shaft 180 is spherical.
The receiving surface 1350f is conical. For this
reason, the position of the driven portion 1350a
relative to the drive shaft 180 is determined in the
orthogonal direction to the axis L2. In addition, in
the case of the coupling 1350 set to the developing
roller 110, the developing roller 110 is also moved in
the axial direction by a force applied in the
direction T2. In this case, the position of the
developing roller 110 relative to the main assembly A
in the longitudinal direction is also determined. The
developing roller 110 is mounted with play in the
longitudinal direction in the cartridge frame.
As shown in Figure 26 (c), in addition, the
rotational force transmitting surface (rotational
force transmitting portion) 1350h is tapered at a angle a6 relative to the axis L2 (inclinded surface).
When the coupling 1350 rotates in the direction Tl,
the transmitting surface 1350h and the pin 1155
contact to each other. And, the transmitting surface
1350h pushes the pin 1155. Then, a component force is
applied in the direction T2 to the pin 1155 to move in
the direction T2. Until the free end 1153b of the
development shaft 1153 contacts to the developing
shaft receiving surface 1350i (Figure 27 (b)) of the
coupling 1350, the development shaft 1153 moves. By
this, the position of the development shaft 1153 (the
developing roller) is determined in the direction of
the axis L2. The developing shaft receiving surface
1350i is conical and free end 1153b of the development
shaft 1153 is spherical. In the orthogonal direction
to the axis L2, the position of the driving portion
1350b relative to the development shaft 1153 is
determined.
The taper angles a5, o6 are selected so that
the sufficient force to move the coupling and the
developing roller in the thrust direction is produced.
Such a force is different depending on the torque
required by the developing roller 110. However, if
another means for positioning it in the thrust
direction is employed, the taper angles a5, a6 may be
small.
As has been described hereinbefore, the coupling 1350 is provided with a tapered portion for producing retraction thrust in the direction of the axis L2 and a conic surface for the positioning in the orthogonal direction to the axis L2. By this, the coupling 1350 can simultaneously be determined in the position and the axis Li in the direction of the axis
Li, the position in the orthogonality direction. In
addition, the coupling 1350 can transmit the
rotational force assuredly. As compared with the case
where the rotational force reception surface (the
rotational force receiving portion) or the rotational
force transmitting surface (the rotational force
transmitting portion) of the coupling 1350 does not
have the taper angle described above, the following
effects are provided. In the present embodiment, the
contact between the pin 182 (rotational force applying
portion) of the drive shaft 180 and the rotational
force reception surface 1350e of the coupling 1350 can
be stabilized. In addition, the contact between the
pin 8 (rotational force transmitted portion) 1155 of
the development shaft 1153 and the transmitting
surface (rotational force transmitting portion) 1350h
of the coupling 1350 can be stabilized.
However, the tapered surface (inclinded
surface) described above and conic surface described
above of the coupling 1350 is not inevitable. For
example, in place of the taper described above, a part for applying the urging force in the direction of the axis L2 may be added.
Referring to Figure 28, the description will be
made as to the regulating means for regulating the
inclining direction of the coupling relative to the
cartridge B. Figure 28 (a) is a side view illustrating
a major part of the driving side of the cartridge.
Figure 28 (b) is a sectional view taken along a line
S7-S7 of Figure 28 (a). For example, the description
will be made as to the coupling (Figure 24) of the
first modified example. The driving portion expands
toward the developing roller in the axial direction in
the coupling of the first modified example. However,
the present embodiment is applicable also to the
coupling of the first embodiment. The coupling of the
first embodiment has the spherical driving portion.
In this embodiment by employing the regulating
means, the coupling 1150 and the drive shaft 180 can
be engaged further assuredly.
In this embodiment, a development supporting
member 1557 is provided with a regulating portion
1557h 1, 1557h2 as a regulating means. The swinging
directions of the coupling 1150 relative to the
cartridge B can be regulated by this regulating means.
The regulating portions 1557h 1 or 1557h2 are
contacted to the flange portion 1150j to regulate the
swinging directions of the coupling 1150. The regulating portions 1557h 1 and 1557h2 are provided so that immediately before the coupling 1150 engages with the drive shaft 180, it is parallel to the mounting direction X4 of the cartridge B. In addition, the intervals D6 between them is slightly larger than the outer diameter D7 of the driving portion 1150b of the coupling 1150 (Figure 28 (d)). By this, the coupling
1150 is inclinable only toward the mounting direction
X4 of the cartridge B. In addition, the coupling 1150
is inclinable in the all directions relative to the
development shaft 1153. For this reason, irrespective
of the phase of the development shaft 1153, the
coupling 1150 can incline in the regulated direction.
Accordingly, the drive shaft 180 is further assuredly
acceptable in the opening 1150m of the coupling 1150.
By this, the coupling 1150 is engageable further
assuredly with the drive shaft 180.
Referring to Figure 29, another structure for
regulating the inclining direction of the coupling
will be described. Figure 29 (a) is a perspective view
showing an inside of a driving side of the main
assembly. Figure 29 (b) is a side view of the
cartridge seen from the upstream side of the mounting
direction X4.
In the foregoing description, the regulating
portions 1557h 1, 1557h2 are provided in the cartridge
B. In this embodiment, a part of a mounting guide
1630R1 of the driving side of the main assembly A is a
rib-like regulating portion 1630Rla. By this, the
regulating portion 1630Rla is the regulating means for
regulating the swinging directions of the coupling
1150. And, when the user inserts the cartridge B, the
outer periphery of the intermediate portion 1150c of
the coupling 1150 is contacted to the upper surface
1630Rla-1 of the regulating portion 1630Rla. By this,
the coupling 1150 is guided by the upper surface
1630Rla-1. Therefore, the inclining direction of the
coupling 1150 is regulated. Similarly to the
embodiment described above, in addition, irrespective
of the phase of the development shaft 1153, the
coupling 1150 can incline in the regulated direction.
In the embodiment shown in Figure 29 (a), the
regulating portion 1630R1a is provided below the
coupling 1150. Similarly to the regulating portion
1557h2 shown in Figure 28, however, the more assured
regulation can be performed when the regulating
portion is added to the upper side.
As has been described hereinbefore, it may be
combined with the structure which provides the
regulating portion in the cartridge B. In this case,
even further assured regulation even can be carried
out.
In addition, a shaft is provided substantially
co-axial with the axis of the coupling 150 (Figure 6) of the first embodiment, the shaft may be regulated by another part (bearing member, for example) of a cartridge.
However, in this embodiment, the means for
regulating the inclining direction of the coupling may
not be provided. For example, the coupling 1150
inclines toward the downstream side of the cartridge B
with respect to the mounting direction. The driving
shaft receiving surface 1150f of the coupling is
increased. By this, the drive shaft 180 and the
coupling 150 can be engaged with each other.
In the foregoing description, the angle of the
pre-engagement angular position of the coupling 150
relative to the axis Li is larger than the angle of
the disengaging angular position. However, this is not
inevitable.
Referring to Figure 30, this will be described.
Figure 30 is a longitudinal sectional view
illustrating a process in which the cartridge B is
taken out of the main assembly A. For example, the
coupling of the first modified example is taken.
However, this is applicable also to the coupling of
the first embodiment.
In the process in which the cartridge B is
taken out of the main assembly A, the angle of the
disengaging angular position (Figure 30c) of the
coupling 1750 with respect to the axis L1 may be as follows. The angle may be equivalent to the angle of the coupling 1150 at the pre-engagement angular position relative to the axis Li at the time of the coupling 1150 engaging with the drive shaft 180. Here, the disengagement process of the coupling 1150 will be described with Figure 30 (a) - (b) - (c) - (d).
More particularly, when the free end portion
1150 A3 passes by the free end portion 180b3 of the
drive shaft 180 with respect to the upstream side in
the take-out direction X6 of the coupling 1150, the
distance between the free end portion 1150 A3 and the
free end portion 180b3 is equivalent to that in the
pre-engagement angular position. The coupling 1150 can
be disengaged from the drive shaft 180 with such a
setting.
As to the other operations when the cartridge B
is taken out, the same as that of the operation
described above applies. For this reason, the
description is omitted for simplicity.
In the foregoing description, at the time of
mounting the cartridge B to the main assembly A, the
downstream side free end with respect to the mounting
direction of the coupling is nearer, than the free end
of the drive shaft 180, to the development shaft.
However, this is not inevitable.
Referring to Figure 31, the description will be
made as to this point. For example, the coupling of the first modified example is taken. However, it is applicable also to the coupling of the first embodiment.
Figure 31 is a longitudinal sectional view
illustrating a mounting process of the cartridge B.
The mounting of the cartridge B is carried out in
order of (a) - (b) - (c) - (d). In the state shown in
Figure 31 (a), in the direction of the axis Ll, the
downstream free end position 1150A1 with respect to
the mounting direction X4 is nearer, than a free end
180b3 of the shaft, to the pin 182 (rotational force
applying portion). In the state shown in Figure 31 (b),
the free end position 1150A1 is contacted to the free
end portion 180b. At this time, the free end position
1150A1 is moved toward the development shaft 1153
along the free end portion 180b. The free end position
1150A1 is passed by the free end portion 180b3 (at
this time, the coupling 1150 is in the pre-engagement
angular position) (Figure 31 (c)). Finally, the
coupling 1150 and the drive shaft 180 engage with each
other (rotational force transmitting angular position)
(Figure 31 (d)).
In the developing cartridge in which such a
coupling is used, the following effects are provided
in addition to the effects described heretofore.
(1) An external force is applied to the
cartridge by the engagement force between the gears.
In the case that the direction of the external force
is such that the developing roller and the
photosensitive drum are separated from each other,
there is a possibility that the image quality may
deteriorate. Therefore, the position of a center of
swinging or the gear of the cartridge is restricted so
that that the moment in the direction of the
developing roller approaching to the photosensitive
drum is produced. For this reason, the design latitude
is narrow. Therefore, there is a possibility that the
main assembly or the cartridge may become bulky.
However, according to this embodiment, the latitude
about the driving input position is wide. Therefore,
the main assembly or the cartridge can be downsized.
(2) In the case of the operative connection
gear between cartridge s and the main assembly: in
order to prevent the tooth tip bearing between a gear
and a gear at the time of the mounting of the
cartridge, it is required to consider the positions of
the gears so that the gears approach beyond the
tangential direction. For this reason, there is a
possibility that the design latitude may be narrow and
the main assembly or the cartridge may be become to
bulky. However, according to this embodiment, the
latitude of the driving input position is high.
Therefore, it is possible to downsize the main
assembly or the cartridge.
An example according to the present embodiment
will be described.
The maximum outer diameter of the driven
portion 150a of the coupling 150 is Z4, the diameter
of a phantom circle Cl contacting the end surface of
the inside of the projections 150d 1, 150d 2, 150d3,
150d4 is Z5, and the maximum outer diameter of the
driving portion 150b is Z6 (Figure 6 (d), (f)). The
angle of the receiving surface 150f of the coupling
150 is a2. The shaft diameter of the drive shaft 180
is Z7, the shaft diameter of the pin 182 is Z8, and
the length thereof is Z9 (Figure 19). Relative to the
axis Ll, the angle at the rotational force
transmitting angular position is @1, and the angle at
the pre-engagement angular position is P2, and the
angle at the disengaging angular position is P3. At
this time, for example,
z4=13mm, z5=8mm, z6=10mm, z7=6mm, z8=2mm,
z9=14mm, al=70 degree, Pl=0 degree, P2=35 degree, B3=30 degree. It has been confirmed that the coupling 150 can
engage with the drive shaft 180 with the above
described setting. However, the similar operation is
possible with the other settings. The coupling 150 can
transmit the rotational force to the developing roller
110 with high precision. The values described above
are examples and, the present invention is not limited to these values.
In this embodiment, the pin (rotational force
applying portion) 182 is disposed at a position in a
range of 5mm from the free end of the drive shaft 180.
The rotational force reception surface (rotational
force receiving portion) 150e provided in the
projection 150d is disposed at a position in the range
of 4mm from the free end of the coupling 150. In this
manner, the pin 182 is provided on the free end
portion of the drive shaft 180. The rotational force
reception surface 150e is disposed on the free end
portion of the coupling 150.
By this, in mounting the cartridge B to the
main assembly A, the drive shaft 180 and the coupling
150 can engage with each other smoothly. More
particularly, the pin 182 and the rotational force
reception surface 150e can engage with each other
smoothly.
In dismounting the cartridge B from the main
assembly A, the drive shaft 180 and the coupling 150
can disengage from each other smoothly. More
particularly, the pin 182 and the rotational force
reception surface 150e can disengage from each other
smoothly.
These values are examples and the present
invention is not limited to the values. However, the
effects described above are effectively provided by disposing the pin (rotational force applying portion)
182 and the rotational force reception surface 150e in
the ranges of the values.
As has been described in the foregoing,
according to the embodiment of the present invention,
the coupling 150 can take the rotational force
transmitting angular position and the pre-engagement
angular position. Here, the rotational force
transmitting angular position is an angular position
for transmitting the rotational force for rotating the
developing roller 110 to the developing roller 110.
The pre-engagement angular position is the angular
position which is the position inclined, in the
direction away from the axis Li of the developing
roller 110, from the rotational force transmitting
angular position. The coupling 150 can take a
disengaging angular position which is the position
inclined, in the direction away from the axis Li of
the developing roller 110, from the rotational force
transmitting angular position. In dismounting the
cartridge B, in the direction substantially
perpendicular to the axis L1, from the main assembly A,
the coupling 150 moves to the disengaging angular
position from the rotational force transmitting
angular position. By this, the cartridge B can be
dismounted from the main assembly A. In mounting the
cartridge B to the main assembly A in the direction substantially perpendicular to the axis Li, the coupling 150 moves to the rotational force transmitting angular position from the pre-engagement angular position. By this, the cartridge B can be mounted to the main assembly A. This applies to the following embodiments. However, in the embodiment 2 only the case where it dismounts the cartridge B from the main assembly A will be described.
(Embodiment 2)
Referring to Figures 32 - 36, the second
embodiment of the present invention will be described.
For example, the coupling of the first modified
example is taken. However, the present embodiment is
applicable also to the coupling of the first
embodiment, for example. As for the structure of the
coupling, the proper structure is selected by the
person skilled in the art.
In the description of this embodiment, the same
reference numerals as in Embodiment 1 are assigned to
the elements having the corresponding functions in
this embodiment, and the detailed description thereof
is omitted for simplicity The same applies all the
subsequent embodiments.
The present embodiment may be applied only for
the case of dismounting the cartridge B from the main
assembly A.
In the case of stopping the drive shaft 180 by
the controlling operations of the main assembly A, the
drive shaft 180 is stopped in the predetermined phase
(A predetermined orientation of the pin 182). The
phase of the coupling 14150 (150) is set in alignment
with the phase of the drive shaft 180. For example,
the position of the standing-by portion 14150k (150k)
aligns with the stop position of the pin 182. With
such a setting, in mounting the cartridge B to the
main assembly A the coupling 14150 (150) is in the
state of opposing to the drive shaft 180, without the
pivoting (swinging, revolving). By the rotation of the
drive shaft 180, the rotational force is transmitted
from the drive shaft 180 to the coupling 14150 (150).
By this, the coupling 14150 (150) can be rotated with
high precision.
However, in the case of dismounting the
cartridge B, in the direction substantially
perpendicular to the direction of the axis L3, from
the main assembly A, the structure of the embodiment 2
of the present invention is effective. Here, the pin
182 and the rotational force reception surface 14150el,
14150e2 (150e) are in engagement with each other. This
is because, in order for the coupling 14150 (150) to
disengage from the drive shaft 180, the coupling 14150
(150) must be pivoted.
In the embodiment 1 described above, in the case of mounting and dismounting relative to the main assembly A of the cartridge B, the coupling 14150
(150) inclines (move). Therefore, it is not necessary
to align the phase of the coupling 14150 (150) with
the phase of the stopped drive shaft 180 beforehand,
at the time of mounting the cartridge B to the main
assembly A with the control of the main assembly A
described above.
Referring to the drawing, the description is
made.
Figure 32 is a perspective view and a top plan
view of the coupling. Figure 33 is a perspective view
showing a mounting operation of the cartridge. Figure
34 is a top plan view, as seen in the mounting
direction in the state at the time of the cartridge
mounting. Figure 35 is a perspective view illustrating
the state that the drive of the cartridge (developing
roller) stops. Figure 36 is a longitudinal sectional
view and a perspective view illustrating the operation
for taking out the cartridge.
In this embodiment, the cartridge detachably
mountable to the main assembly A provided with the
control means for controlling the phase of the stop
position of the pin 182 (unshown) will be described.
Referring to Figure 32, the coupling used for
the present embodiment will be described.
The coupling 14150 comprises three main parts.
As shown in Figure 32 (c), they are a driven portion
14150a for receiving the rotational force from the
drive shaft 180, a driving portion 14150b for
transmitting the rotational force to the development
shaft 153, and an intermediate portion 14150c for
connecting the driven portion 14150a and the driving
portion 14150b.
The driven portion 14150a has a drive shaft
inserting portion 14150m which comprises two surfaces
which expand from the axis L2. The driving portion
14150b has a development shaft insertion part 14150v
which comprises two surfaces which expand from the
axis L2.
The inserting portion 14150m has a tapered
shape driving shaft receiving surfaces 14150f 1,
14150f2. The respective end surface is provided with
projections 14150d 1, 14150d2. The projections 14150d
1, 14150d2 are disposed on the circumference having,
as the center thereof, the axis L2 of the coupling
14150. As shown in the Figure, the receiving surfaces
14150f 1 or 14150f2 constitute the recesses 14150z. As
shown in Figure 32 (d), the downstream side of the
projections 14150d 1, 14150d2 with respect to the
clockwise direction is provided with a rotational
force reception surface (rotational force receiving
portion) 14150e (14150el, 14150e2). The pin
(rotational force applying portion) 182 contacts to this receiving surface 14150el, 14150e2. By this, the rotational force is transmitted to the coupling 14150.
An interval W between the adjacent projections
14150d1-d2 is larger than an outer diameter of the pin
182 so that the pin 182 can be received. This interval
functions as a standing-by portion 14150k.
An inserting portion 14150v is constituted by
the two surfaces 14150il, 14150 i2. Stand-by openings
14150g 1 or 14150g2 are provided in the surface
14150il, 14150 i2 thereof (Figure 32 (a) and Figure 32
(e)). In Figure 32 (e), the clockwisely upstream side
of the opening 14150g 1, 14150g2 is provided with a
rotational force transmitting surface (rotational
force transmitting portion) 14150h (14150h 1, 14150h2)
(Figure 32 (b), (e)). As has been described
hereinbefore, the pins (rotational force transmitted
portions) 155a contact to the rotational force
transmitting surfaces 14150h 1, 14150h2. By this, the
rotational force is transmitted to the developing
roller 110 from the coupling 14150.
With such a configuration of the coupling 14150,
in the state that the cartridge is mounted to the main
assembly the coupling covers the free end of the drive
shaft. By this, the effects as will be described
hereinafter are provided.
The coupling 14150 has the structure similar to
the structure of the first modified example, and is inclinable (movable) in all directions relative to the development shaft 153.
Referring to Figure 33 and Figure 34, the
mounting operation of the coupling will be described.
Figure 33 (a) is a perspective view illustrating the
state before the mounting of the coupling. Figure 33
(b) is a perspective view illustrating the state that
the coupling is in engagement. Figure 34 (a) is a top
plan view as seen in the mounting direction. Figure 34
(b) is a top plan view.
The axis L3 of the pins (rotational force
applying portion) 182 is parallel to the mounting
direction X4 by the control means described above. As
for the cartridge, the phase is aligned (Figure 33
(a)) so that the receiving surfaces 14150f 1, 14150f2
oppose to each other in the direction perpendicular to
the mounting direction X4. As shown in the Figure, for
example, as a structure for aligning the phase, one of
the receiving surfaces 14150f 1, 14150f2 is aligned
with a register mark 14157z provided on a bearing
member 14157. This is carried out when the cartridge
is shipped from the plant. However, the user may carry
out this, before mounting the cartridge B to the main
assembly. In addition, another phase aligning means
may be used. By doing so, the coupling 14150 and the
drive shaft 180 (pin 182) do not interfere with each
other, as shown in Figure 34 (a). For this reason, the coupling 14150 and the drive shaft 180 are in the engageable positional relation (Figure 33 (b)). The drive shaft 180 rotates in the direction X8, the pin
182 contacts to the receiving surfaces 14150el,
14150e2. By this, the rotational force is transmitted
to the developing roller 110.
Referring to Figure 35 and Figure 36, the
description will be made as to the operation of
disengaging the coupling 14150 from the drive shaft
180 in interrelation with the operation of taking out
the cartridge B from the main assembly A. The control
means (unshown) stops the pin 182 at the predetermined
phase relative to the drive shaft 180. From the
standpoint of easiness of the mounting of the
cartridge B, it is desirable to stop the pin 182 in
the position parallel to the cartridge take-out
direction X6 (Figure 35 (b)). The operation at the
time of taking out the cartridge B is shown in Figure
36. In this state (Figure 36 (al) and (bl)), the axis
L2 of the coupling 14150 is substantially co-axial
relative to the axis Ll in the rotational force
transmitting angular position. Similarly to the case
of mounting the cartridge B, at this time, the
coupling 14150 is inclinable (movable) in the all
directions relative to the development shaft 153
(Figure 36 (al) and Figure 36 (bl)). For this reason,
the axis L2 inclines, in the opposite direction to the take-out direction, relative to the axis Li in interrelation with the take-out operation of the cartridge B. More particularly, the cartridge B is dismounted in the direction substantially perpendicular to the axis L3 (the direction of the arrow X6). In the take-out process of the cartridge, the axis L2 inclines to the position that the free end
14150 A3 of the coupling 14150 is along at the free
end 180b of the drive shaft 180 (disengaging angular
position). Or, it inclines until it is positioned in
the side of the axis L2 to the development shaft 153
with respect to the free end portion 180b3 (Figure 36
(a2) and Figure 36 (b2)). In this state, the coupling
14150 is passed adjacent to the free end portion 180b3.
By doing so, the coupling 14150 is dismounted from the
drive shaft 180.
In the state that the cartridge B is mounted to
the main assembly A, a part of coupling 14150 (free
end 14150 A3) is behind the drive shaft 180 (Figure 36
(al)), as seen in the opposite direction to.the
removing direction X6 of dismounting the cartridge B
from the main assembly A. And, in dismounting the
cartridge B from the main assembly A, in response to
moving the cartridge B in the direction substantially
perpendicular to the axis Li of the developing roller
110, the coupling 14150 makes the following motion.
More particularly, the coupling 150 is moved to the disengaging angular position from the rotational force transmitting angular position so that said portion
(free end 14150 A3) of the coupling 150 circumvents
the drive shaft 180.
As shown in Figure 35 (a), the axis of the pin
182 may stop with the direction perpendicular to the
cartridge take-out direction X6. In other words, the
pin 182 is normally stopped at the position shown in
Figure 35 (b) by the control operation of the control
means (unshown). However, when the voltage source of
the device (the printer) is OFF, and the control means
(unshown) does not work, the pin 182 may be stopped at
the position shown in Figure 35 (a). However, even in
such a case, the axis L2 inclines relative to the axis
Li to permit the dismounting. In the rest state of the
device, the pin 182 is downstream of the projection
14150d2 in the take-out direction X6. For this reason,
by the inclination of the axis L2, the free end 14150
A3 of the projection 14150dl of the coupling passes by
the side nearer, than the pin 182, to the development
shaft 153. By this, the coupling 14150 can be
dismounted from the drive shaft 180.
In the case that the coupling 14150 is engaged
with the drive shaft 180 by a certain method in the
mounting of the cartridge B, and there is no means for
controlling the phase of the drive shaft, the
cartridge can be removed by the inclination of the axis L2 relative to the axis Li. By this, the coupling
14150 can be dismounted from the drive shaft 180 only
by take-out operation of the cartridge.
As has been described hereinbefore, Embodiment
2 is effective, even when only the case where the
cartridge B is dismounted from the main assembly A is
considered.
As has been described hereinbefore, Embodiment
2 has the following structures.
The cartridge B is dismounted by being moved in
the direction substantially perpendicular to the
direction of the axis L3 of the drive shaft 180 from
the main assembly A provided with the drive shaft 180
which has the pin (the rotational force applying
portion) 182. The cartridge B has the developing
roller 110 and the coupling 14150.
I>> The developing roller 110 is rotatable
about the axis Li thereof, and develops the
electrostatic latent image formed on the
photosensitive drum 7. Ii>> The coupling 14150 engages
with the pin 182 to receive the rotational force for
rotating the developing roller 110. The coupling 14150
can take the rotational force transmitting angular
position for transmitting the rotational force for
rotating the developing roller 110 to the developing
roller 110 and the disengaging angular position for
disengaging the coupling 14150 from the drive shaft
180 in which it inclined from the rotational force
transmitting angular position.
In dismounting the cartridge B in the direction
substantially perpendicular to the axis Li of the
developing roller 110 from the main assembly A the
coupling 14150 is moved to the disengaging angular
position from the rotational force transmitting
angular position.
(Embodiment 3)
Embodiment 3 to which the present invention is
applied will be described with reference to Figures 37
to 41. A structure of the coupling is as described in
Embodiment 2.
Figure 37 is a sectional view showing a state
in which a door of the apparatus main assembly A2 is
opened. Figure 38 is perspective view showing a
mounting guide in the state in which the door of the
apparatus main assembly 42 is opened. Figure 39 is an
enlarged view of a driving-side surface of the
cartridge. Figure 40 is a perspective view as seen
from the driving side of the cartridge. Figure 41 is a
schematic view for illustrating two states including a
state immediately before the cartridge is inserted
into the apparatus main assembly and a state after the
cartridge is mounted at a predetermined position in a
single drawing for simplicity.
In this embodiment, the case of mounting the
cartridge toward a vertically lower portion, e.g., as
a clamshell type image forming apparatus will be
described. A representative clamshell type image
forming apparatus is shown in Figure 37. The apparatus
main assembly A2 is capable of being divided into a
lower casing D2 and an upper casing E2. The upper
casing E2 is provided with a door 2109 and an exposure
device 2101 inside the door 2109. For that reason,
when the upper casing E2 is upwardly opened, the
exposure device 2101 is retracted. Then, an upper
portion of a cartridge mounting portion 2130a is
opened. Therefore, the user may only be required to
drop the cartridge B2 in a vertically downward
direction (a direction X42 in the figure) when the
user mounts the cartridge B2 in the mounting portion
2130a. Thus, the cartridge is more liable to be
mountable. Further, jam clearance in the neighborhood
of the fixing device 105 can be performed from above
the apparatus. Therefore, the jam clearance is readily
performed. Here, the jam clearance refers to an
operation for removing the recording material (medium)
102 jammed or stuck during conveyance.
Next, the mounting portion 2130a will be
described. As shown in Figure 38, the image forming
apparatus (apparatus main assembly) A2 includes, as a
mounting means 2130, a driving side mounting guide
2130R and a non-driving side mounting guide (not
shown) opposite to the driving side mounting guide
2130R. The mounting portion 2130a is a space enclosed
by the opposing guides. In a state in which the
cartridge B2 is mounted in the mounting portion 2130a,
a rotational force is transmitted from the apparatus
main assembly A2 to the coupling 150.
To the mounting guide 2130R, a groove 2130b is
provided with respect to a substantially vertical
direction. Further, at a lowermost portion of the
mounting guide 2130R, an abutting portion 2130Ra for
positioning the cartridge B2 at a predetermined
position is provided. Further, a driving shaft 180 is
projected from the groove 2130b in order to transmit
the rotational force from the apparatus main assembly
A2 to the coupling 150 in the state in which the
cartridge 32 is positioned at the predetermined
position. Further, in order to position the cartridge
B2 at the predetermined position with reliability, an
urging spring 2188R is provided at a lower portion of
the mounting guide 2130R. By the above-described
structure, the cartridge B2 is positioned at the
mounting portion 2130a.
As shown in Figures 39 and 40, to the
cartridge B2, cartridge side mounting guides 2140R1
and 2140R2 are provided. By these guides, an attitude
of the cartridge B2 is stabilized during the mounting.
The mounting guide 2140R1 is formed integrally with a
developing device supporting member 2157. Further, the
mounting guide 2140R2 is provided vertically above the
mounting guide 2140R1. The mounting guide 2140 R2 is
provided in a rib shape to the supporting member 2157.
Incidentally, the guides 2140R1 and 2140R2 of
the cartridge B2 and the mounting guide 2130R provided
to the apparatus main assembly A2 provide the
above-described guide structure. That is, the guide
structure in this embodiment is the same as the guide
structure described with reference to Figures 2 and 3.
Further, this is true for the guide structure on the
other end. Thus, the cartridge B2 is moved in a
direction substantially perpendicular to a direction
of an axis L3 of the driving shaft 180 and is mounted
to the apparatus main assembly A2 (the mounting
portion 2130a). Further, the cartridge B2 is demounted
from the apparatus main assembly A2 (the mounting
portion 2130a).
As shown in Figure 41, when the cartridge B is
mounted, the casing E2 is rotationally driven
clockwise about a shaft 2109a. Then, the user moves
the cartridge B2 toward above the casing D2. At this
time, the coupling 150 is inclined downwardly by its
own weight (see also Figure 39). That is, an axis L2
of the coupling 150 is inclined with respect to the
axis Ll so that a driven portion 150a of the coupling
150 is directed downwardly (an angular position before
engagement).
In this state, the user downwardly moves the
cartridge B2 by fitting the mounting guides 2140R1 and
2140R2 of the cartridge B2 to the mounting guide 2130R
of the apparatus main assembly A2. It is possible to
mount the cartridge B2 to the apparatus main assembly
A2 (the mounting portion 2130a) only by this operation.
In this mounting process, similarly as in Embodiment 1
(Figure 19), the coupling 150 is engageable with the
driving shaft 180. In this state, the coupling 150
takes a rotational force transmitting angular position.
That is, by moving the cartridge B2 in the direction
substantially perpendicular to the direction of the
axis L3 of the driving shaft 180, the coupling 150
engages with the driving shaft 180. Further, also when
the cartridge B2 is demounted, similarly as in
Embodiment 1, only by a demounting operation of the
cartridge, the coupling 150 is disengageable from the
driving shaft 180. That is, the coupling 150 is moved
from the rotational force transmitting angular
position to a disengagement angular position (Figure
22). Thus, the coupling 150 is disengaged from the
driving shaft 180 by moving the cartridge B2 in the
direction substantially perpendicular to the direction
of the axis L3 of the driving shaft 180.
As described above, in the case where the cartridge is downwardly mounted to the apparatus main assembly A2, the coupling 150 is downwardly inclined by its own weight. For that reason, the coupling 150 is engageable with the driving shaft 180.
In this embodiment, the clamshell type image
forming apparatus is described. However, the present
invention is not limited thereto. For example, this
embodiment is applicable when a mounting path of the
cartridge is directed downwardly. The mounting path
may also be downwardly non-linear. For example, the
cartridge mounting path may be obliquely downward at
an initial stage and be directed downwardly at a final
stage. In short, the mounting path may be only
required to be directed downwardly immediately before
the cartridge reaches the predetermined position (the
mounting portion 2130a).
(Embodiment 4)
Embodiment 4 to which the present invention is
applied will be described with reference to Figures 42
to 45. The structure of the coupling is as described
in Embodiment 2. In this embodiment, a means for
keeping the axis L2 in an inclined state with respect
to the axis Li will be described.
Figure 42 is an exploded perspective view
showing a state in which a coupling urging member
(peculiar to this embodiment) is mounted to the developing device supporting member. Figures 43(a) and
32(b) are exploded perspective views showing the
developing device supporting member, the coupling, and
a developing shaft. Figure 44 is an enlarged
perspective view showing a driving side principal
portion of the cartridge. Figures 45(a) to 45(d) are
longitudinal sectional views showing the process in
which the driving shaft engages with the coupling.
As shown in Figure 42, the developing device
supporting member 4157 is provided with a holding hole
4157j in a rib 4157e. In the holding hole 4157j,
coupling urging members 4159a and 4159b as a keeping
member for keeping the inclination of a coupling 4150
are mounted. The urging members 4159a and 4159b urge
the coupling 4150 so that the coupling 4150 is
inclined toward a downstream side with respect to the
mounting direction of the cartridge B2. The urging
members 4159a and 4159b are compression springs
(elastic members). As shown in Figures 43(a) and 43(b),
the urging members 4159a and 4159b urge a flange
portion 4150j of the coupling 4150 in the direction of
the axis Ll (in a direction indicated by an arrow X13
in Figure 43(a)). A contact position of the urging
members with the flange portion 4150j is set on a
downstream side of a center of the developing shaft
153 with respect to a mounting direction X4. For that
reason, the axis L2 is inclined with respect to the axis Li by an elastic force of the urging members
4159a and 4159b so that the driven portion 4150a side
is directed to the downstream side with respect to the
cartridge mounting direction X4 (Figure 44).
Further, as shown in Figure 42, at
coupling-side ends of the urging members 4159a and
4159b, contact members 4160a and 4160b are provided.
The contact members 4160a and 4160b contact the flange
portion 4150j. Therefore, a material for the contact
members 4160a and 4160b is selected from those having
good slidability. By using such a material, as
described later, the influence of the urging force
(elastic force) of the urging members 4159a and 4159b
on the rotation of the coupling 4150 during the
rotational force transmission. However, the contact
members 4160a and 4160b may also be omitted when a
load on the rotation is sufficiently small and the
coupling 4150 is satisfactorily rotated.
In this embodiment, two urging members are
used. However, the number of the urging members may be
changed when the axis L2 can be inclined with respect
to the axis L2 downwardly in the cartridge mounting
direction X4. For example, in the case of a single
urging member, it is urging position may desirably be
a lowermost-stream position of the cartridge mounting
position. As a result, the coupling 4150 can be stably
inclined toward the downstream direction in its mounting direction X4.
As the urging member, in this embodiment, the
compression coil spring is used. However, as the
urging member, any material such as a leaf spring, a
torsion spring, a rubber or a sponge may appropriately
be selected when the material generates the elastic
force. However, the urging member needs a stroke to
some extent in order to incline the axis L2. For that
purpose, it is desirable that the material for the
urging member is the coil spring or the like capable
of giving the stroke.
Next, with reference to Figures 43(a) and
43(b), a mounting method of the coupling 4150 will be
described.
As shown in Figures 43(a) and 43(b), a pin 155
is inserted into a stand-by space 4150g of the
coupling 4150. Then, a part of the coupling 4150 is
inserted into a space 4157b of the developing device
supporting member 4157. At this time, as described
above, the urging members 4157a and 4159b press the
predetermined portion of the flange portion 4157j
through the contact members 4160a and 4160b. Further,
the supporting member 4157 is fixed to a developing
device frame 118 with a screw or the like. As a result,
the urging members 4159a and 4159b can obtain a force
of urging the coupling 4150. Thus, the axis L2 is
inclined with respect to the axis Li (state of Figure
44)
Next, with reference to Figure 45, an
operation for engaging the coupling 4150 with the
driving shaft 180 (as a part of the cartridge mounting
operation) will be described. Figures 45(a) and 45(c)
show a state immediately before the engagement, and
Figure 45(d) shows an engaged state. In the state
shown in Figure 45(a), the axis L2 of the coupling
4150 is inclined in advance with respect to the axis
Ll in the mounting direction X4 (the angular position
before the engagement). By the inclination of the
coupling 4150, in the axis Li direction, a downstream
side end position 4150A1 with respect to the mounting
direction X4 is located at a position closer to the
developing roller 110 than an end 180b3. Further, an
upstream side end position 4150A2 with respect to the
mounting direction X4 is located at a position closer
to the pin 182 than the end 180b3. That is, as
described above, the flange portion 4150j of the
coupling 4150 is urged by the urging member 4159. For
that reason, the axis L2 is inclined with respect to
the axis Li by the urging force.
Therefore, by moving the cartridge B in the
mounting direction X4, an end surface 180b or an end
(a main assembly-side engaging portion) of the pin
(rotational force imparting portion) 182 contacts a
driving shaft receiving surface 4150f of the coupling
4150 or a projection (cartridge-side contact portion)
4150d. A contact state of the pin 182 with the
receiving surface 4150f is shown in Figure 45(c). Then,
by the contact force (a mounting force of the
cartridge), the axis L2 approaches a direction
parallel to the axis Ll. At the same time, the urging
portion 4150jl urged by the elastic force of the
spring 4159 provided to the flange portion 4150j is
moved in the direction in which the spring 4159 is
compressed. Then, finally, the axis Ll and the axis L2
are substantially in line with each other. Then, the
cartridge 4150 is placed in a stand-by state for
performing the transmission of the rotational force
(rotational force transmission angular position)
(Figure 45(d)).
Thereafter, similarly as in Embodiment 1, the
rotational force is transmitted from the motor 186 to
the developing roller 110 through the driving shaft
180, the coupling 4150, the pin 155, and the
developing shaft 4153. During the rotation, on the
coupling 4150, the urging force of the urging member
4159 is exerted. However, as described above, the
urging force of the urging member 4159 is exerted on
the coupling 4150 through the contact member 4160. For
that reason, the coupling 4150 can be rotated under
not much load. Further, when there is a margin of a
driving torque of the motor 186, the contact member
4160 may be omitted. In this case, the coupling 4150
can transmit the rotational force with accuracy even
when the contact member is not provided.
Further, in the process of demounting the
cartridge B from the apparatus main assembly A, steps
which are the reverse of the mounting steps are
pursued (Figure 45(d) - Figure 45(c) - Figure
45(b) - Figure 45(a)). That is, the cartridge 4150 is
urged always toward the downstream side with respect
to the mounting direction X4 by the urging member 4159.
For that reason, in the process of demounting the
cartridge B, on the upstream side with respect to the
mounting direction X4, the receiving surface 4150f
contacts the end portion 182A of the pin 182 (a state
between those shown in Figures 45(d) and 45(d)).
Further, on the downstream side with respect to the
mounting direction X4, a gap n50 is always created
between the transmitting (receiving) surface 4150f and
the end 180b of the driving shaft 180. In the
above-described Embodiments, in the cartridge
demounting process, the receiving surface 4150f or
projection 4150d which are located on the downstream
side with respect to the cartridge mounting direction
X4 is described as contacting at least the end 180b of
the driving shaft 180 (e.g., Figure 19). However, as
in this embodiment, even when the downstream-side
receiving surface 4150f or the projection 4150 does not contact the end 180b of the driving shaft 180, the coupling 4150 can be separated from the driving shaft
180 in accordance with the demounting operation of the
cartridge B. Then, also after the coupling 4150 comes
out of the driving shaft 180, by the urging force of
the urging member 4159, the axis L2 is inclined
downwardly with respect to the axis Li in the mounting
direction X4 (the demounting angular position). That
is, in this embodiment, an angle at the angular
position before the engagement with respect to the
axis Li and an angle at the demounting angular
position are equal to each other. This is because the
coupling 4150 is urged by the elastic force-of the
spring.
The urging member 4159 has the functions of
inclining the axis L2 and regulating the inclination
direction of the coupling 4150. That is, the urging
member 4159 also functions as a regulating means for
regulating the inclination direction of the coupling
4150.
As described above, in this embodiment, the
coupling 4150 is urged by the urging force of the
urging member 4159 provided to the supporting member
4157. As a result, with respect to the axis Li, the
axis L2 is inclined. Accordingly, the inclined state
of the coupling 4150 is retained. Therefore, the
coupling 4150 is engageable with the driving shaft 180 with reliability.
Incidentally, in this embodiment, the urging
member 4159 is provided to the rib 4157e of the
supporting member 4157 but is not limited thereto. For
example, the urging member 4159 may also be provided
to another portion of the supporting member 4157 or
provided to a member other than the supporting member
so long as the member is fixed to the cartridge B.
Further, in this embodiment, the urging
direction of the urging member 4159 is the direction
of the axis Ll. However, the urging direction may be
any direction in which the axis L2 can be inclined
(moved) toward the downstream side with respect to the
mounting direction X4 of the cartridge B.
Further, in this embodiment, at the urging
position of the urging member 4159, the flange portion
4150j is located. However, the urging position may
also be any position of the coupling so long as the
axis L2 is inclined toward the cartridge mounting
direction downstream side.
(Embodiment 5)
Embodiment 5 to which the present invention is
applied will be described with reference to Figures 46
to 50. The structure of the coupling is as described
above.
In this embodiment, another means for inclining the axis L2 with respect to the axis Ll will be described.
Figures 46(al), 46(a2), 46(bl) and 46(b2) are
enlarged side views of the driving side of the
cartridge. Figure 47 is a perspective view showing the
driving side of an apparatus main assembly guide.
Figures 48(a) and 48(b) are side views showing a
relationship between the cartridge and the apparatus
main assembly guide. Figures 49(a) and 49(b) are
schematic views showing a relationship between the
apparatus main assembly guide and the coupling as seen
from the mounting direction upstream side. Figures
50(a) to 50(f) are side views for illustrating the
mounting process.
Figure 46(al) and Figure 46(bl) are side views
of the cartridge as seen from the driving shaft side,
and Figure 46(a2) and Figure 46(b2) are side views of
the cartridge as seen from a side opposite from the
driving shaft side. As shown in these figures, a
coupling 7150 is mounted to a developing device
supporting member 7157 in a state in which the
coupling 7150 can be inclined toward the mounting
direction X4 downstream side. Further, with respect to
the inclination direction, the coupling 7150 can be
inclined only toward the mounting direction X4
downstream side. Further, the coupling 7150 has the
axis L2 inclined at an angle a60 with respect to the horizontal line in the state of Figure 46(al). The reason for the inclination of the coupling 7150 at the angle aY60 is as follows. A flange portion 7150j of the coupling 7150 is regulated by regulating portions
7157hl and 7157h2 as the regulating means (Figure
46(a2)). For that reason, the coupling 7150 can be
inclined upwardly at the angle a60 with respect to the
mounting direction downstream side.
Next, with reference to Figure 47, a main
assembly guide 7130R will be described. The main
assembly guide 7130R principally includes, through the
coupling 7150, a guide rib 7130Rla for guiding the
cartridge B and cartridge position portions 7130R1e
and 7130R1f. The rib 7130Rla is located on a mount
locus of the cartridge B. The rib 7130Rla extends to a
portion in front of the driving shaft 180 in the
mounting direction X4. Further, a rib 7130Rlb in the
neighborhood of the driving shaft 180 has a height
such that the rib 7130Rlb does not interfere with the
coupling 7150 when the coupling 7150 is engaged with
the driving shaft 180. A main assembly guide 7130 R2
principally includes a guide portion 7130R2a for
guiding a part of the cartridge frame to determine an
attitude of the cartridge during themounting and
includes a cartridge position portion 7130R2c.
Next, the relationship between the main
assembly guide 7130R and the cartridge at the time of mounting the cartridge will be described.
As shown in Figure 48(a), the cartridge B is
moved on the driving side in a state in which an
intermediary portion (a force receiving portion) 7150c
contacts the surface of the guide rib (fixed portion,
contact portion) 7130Rla. At this time, a cartridge
guide 7157a of the supporting member 7157 is distant
from the guide surface 7130Rlc by n59. For that reason,
on the coupling 7150, a self weight of the cartridge B
is exerted. On the other hand, as described above, the
coupling 7150 is set so that the mounting direction
downstream side portion thereof can be inclined
upwardly at the angle a60 with respect to the mounting
direction X4. For that reason, the coupling 7150 is
inclined toward the downstream side with respect to
the mounting direction X4 at the driven portion 7150a
(in the direction in which the driven portion 7150a is
inclined at the angle C60) (Figure 49(a)).
The reason that the coupling 7150 is inclined
is as follows. The intermediary portion 7150c receives
reaction force of the self weight of the cartridge B
from the guide rib 7130Rla. The reaction force acts on
the regulating portions 7157hl and 7157h2 for
regulating the inclination direction. As a result, the
coupling is inclined in a predeterm-ined direction.
When the intermediary portion 7150c moves on
the guide rib 7130Rla, a frictional force occurs between the intermediary portion 7150c and the guide rib 7130R1a. Accordingly, the coupling 7150 receives a force toward a direction opposite to the mounting direction X4 by the frictional force. However, the frictional force generated by friction coefficient between the intermediary portion 7150c and the guide rib 7130Rla is smaller than a force of inclining the coupling 7150 toward the downstream side with respect to the mounting direction X5 by the reaction force.
For that reason, the coupling 7150 is inclined and
moved downwardly with respect to the mounting
direction X4 by overcoming the frictional force.
Incidentally, a regulating portion 7157g of
the supporting member 7157 (Figures 46(al) and 46(bl))
can also be provided as the regulating means for
regulating the inclination. As a result, the
inclination direction of the coupling is regulated by
the regulating portions 7157hl and 7157h2 (Figures
46(a2) and 46(b2)) and the regulating portion 7157g at
different positions with respect to the direction of
the axis L2. Thus, the inclination direction of the
coupling 7150 can be regulated with reliability.
Further, the coupling 7150 can be inclined always at
the angle aY60. The regulation of the inclination
direction of the coupling 7150 may also be performed
by another means.
The guide rib 7130Rla is located in a space
7150s constituted by the driven portion 7150a, the
driving portion 7150b, and the intermediary portion
7150c. Therefore, in the mounting process, a
longitudinal position (with respect to the direction
of the axis L2) of the coupling 7150 in the apparatus
main assembly A is regulated (Figures 48(a) and 48(b)).
By regulating the longitudinal position of the
coupling 7150, the coupling 7150 is engageable with
the driving shaft 180 with reliability.
Next, the engaging operation for engaging the
coupling 7150 with the driving shaft 180 will be
described. The engaging operation is the substantially
same as that in Embodiment 1 (Figure 19). In this
embodiment, a relationship between the main assembly
guide 7130R2 and the supporting member 7157 and the
coupling 7150 in the engaging process of the coupling
7150 with the driving shaft 180 will be described with
reference to Figures 50(a) to 50(f). During the
contact of the intermediary portion 7150c with the rib
7130Rla, the cartridge guide 7157a is placed in a
separated state from the guide surface 7130Rlc. As a
result, the coupling 7150 is inclined (the angular
position between the engagement) (Figure 50(a) and
Figure 50(d)). Then, at the time when an end 7150Al of
the inclined coupling 7150 passes through a shaft end
180b3, the intermediary portion 7150c does not contact
the guide rib 7130Rla (Figure 50(b) and Figure 50(e)).
In this case, the cartridge guide 7157a passes through
the guide surface 7130Rlc and an inclined surface
7130Rld and is in a state in which the cartridge guide
7157a starts to contact the positioning surface
7130Rie (Figure 50(b) and Figure 50(e)). Thereafter, a
receiving surface 7150f or a projection 7150d contacts
the end portion 180b or the pin 182. Then, in
accordance with the cartridge mounting operation, the
axis L2 and the axis Li come near to the same line,
and the center position of the developing shaft and
the center position of the coupling come near to a
co-axial line. Then, finally, as shown in Figure 50(c)
and Figure 50(f), the axis Li and the.axis L2 are
substantially in line with each other. Thus, the
coupling 7150 is in a rotation stand-by state (the
rotational force transmission angular position).
In the process of demounting the cartridge B
from the apparatus main assembly A, steps which are
substantially the reverse of the engaging operation
are pursued. Specifically, the cartridge B is moved in
the demounting direction. As a result, the end portion
180b pushes the receiving surface 7150f. As a result,
the axis L2 starts to be inclined with respect to the
axis L1. By the demounting operation of the cartridge,
the upstream side end portion 7150A1 moves along the
surface of the end portion 180b in the demounting
direction X6, so that the axis L2 is inclined until the end portion Al reaches a shaft end 180b3. In this state, the coupling 7150 completely passes through the shaft end 180b3 (Figure 50(b)). Thereafter, the coupling 7150 contacts the surface of the rib 7130Rla at the intermediary portion 7150c. As a result, the coupling 7150 is demounted in a state in which the coupling 7150 is inclined toward the downstream side with respect to the mounting direction X4. That is, the coupling 7150 is inclined (swung) from the rotational force transmission angular position to the demounting angular position.
As described above, by the mounting operation
of the cartridge to the main assembly by the user, the
- coupling is swung to be engaged with the main assembly
driving shaft. Further, a means for keeping the
attitude of the coupling is not particularly required.
However, as described in Figure 4, the structure in
which the attitude of the coupling is kept in advance
can also be carried out in combination with the
structure of this embodiment.
In this embodiment, by applying the self
weight to the guide rib, the coupling is inclined in
the mounting direction X4. However, in addition to the
self weight, the elastic force of the spring or the
like may also be utilized.
In this embodiment, the intermediary portion
of the coupling receives the force to incline the coupling. However, the present invention is not limited thereto. For example, a portion other than the intermediary portion may also be brought into contact with the contact portion when the portion can receive the force from the contact portion of the main assembly to incline the coupling.
Further, this embodiment can also be carried
out in combination with any of Embodiments 2 to 4. In
this case, the engagement and disengagement of the
coupling with respect to the driving shaft can be
performed with further reliability.
(Embodiment 6)
Embodiment 6 will be described with reference
to Figures 51 to 55. In the above-described
Embodiments, the surface of the developing roller 6110
is held with a predetermined spacing with respect to
the photosensitive drum 107. In that state, the
developing roller 6110 develops the latent image
formed on the photosensitive drum 107. In the
above-described Embodiments, the cartridge employing
the so-called non-contact developing system is
described. In this embodiment, a cartridge employing a
so-called contact developing system in which
development is carried out in a state in which the
developing roller surface is in contact with the
latent image formed on the photosensitive drum. That is, the case where an embodiment of the present invention is applied to the cartridge employing the contact developing system will be described.
Figure 51 is a sectional view of the
developing cartridge of this embodiment. Figure 52 is
a perspective vie showing a developing device side of
the cartridge. Figure 53 is a sectional view of the
cartridge taken along S24 - S24 line indicated in
Figure 52. Figures 54(a) and 54(b) are sectional views
showing the case where the developing cartridge is in
a development enabled state and the case where the
developing cartridge is in a development disabled
state, respectively. Figures 55(a) and 55(b) are
longitudinal sectional views showing drive connection
in the states of Figures 54(a) and 54(b), respectively.
The development disabled state refers to a state in
which the developing roller 6110 is moved apart from
the photosensitive drum 107.
First, the structure of the developing
cartridge B6 employing the contact developing system
will be described with reference to Figures 51 and 52.
The cartridge B6 includes the developing
roller 6110. The developing roller 6110 rotates,
during a developing action, by receiving a rotational
force from the apparatus main assembly A through a
coupling mechanism described later.
In a developer accommodating frame (developer accommodating portion) 6114, developer t is accommodated. This developer is fed to a developing chamber 6113a by rotation of a stirring member 6116.
The fed developer is supplied to the surface of the
developing roller 6110 by rotation of a sponge-like a
developer supplying roller 6115 in the developing
chamber 6113a. Then, the developer is supplied with
electric charges by friction between a thin plate-like
developing blade 6112 and the developing roller 6110
to be formed in a thin layer. The developer formation
in the thin layer is fed to a developing position by
the-rotation. Then, to the developing roller 6110, a
predetermined developing bias is applied. As a result,
the developing roller 6110 develops the electrostatic
latent image formed on the photosensitive drum 107 in
a state in which the surface thereof contacts the
surface of the photosensitive drum 107. That is, the
electrostatic latent image is developed by the
developing roller 6110.
The developer which has not contributed to the
development of the electrostatic latent image, i.e.,
the developer t remaining on the surface of the
developing roller 6110 is removed by the developer
supplying roller 6115. At the same time, fresh
developer t is supplied to the surface of the
developing roller 6110 by the supplying roller 6115.
As a result, the developing operation is performed continuously.
The cartridge B6 includes a developing unit
6119. The developing unit 6119 includes a developing
device frame 6113 and the developer accommodating
frame 6114. Further, the developing unit 6119 includes
the developing roller 6110, the developing blade 6112,
the developer supplying roller 6115, the developing
chamber 6113a, the developer accommodating frame 6114,
and the stirring member 6116.
The developing roller 6110 rotates about the
axis Li.
The structure of the apparatus main assembly A
is the substantially same as that in Embodiment 1,
thus being omitted from the description. However, to
the apparatus main assembly A applied to Embodiment 6,
in addition to the structure of the main assembly A
described above, a lever (a force-imparting member
shown in Figures 54(a) and 54(b)) 300 for contact and
separation between the surface of the photosensitive
drum 107 and the surface of the developing roller 6110.
Incidentally, the lever 300 will be described later.
The developing cartridge B is, described in Embodiment
1, mounted to a mounting portion 130a (Figure 3) by
guiding cartridge guides 6140L1, 6140R2 and the like
to the apparatus main assembly A by the user.
Incidentally, the cartridge B6 is also, similarly as
in the above-described cartridge, mounted to the mounting portion 130a by being moved in the direction substantially perpendicular to the axial direction of the driving shaft 180. Further, the cartridge 6B is demounted from the mounting portion 130a.
Incidentally, when the cartridge B6 is mounted
to the mounting portion 130a as described above, a
guide (projection) 6140R1 of the cartridge B6 is
subjected to pressure application by the elastic force
of the urging spring (elastic member) 188R as shown in
Figures 15 and 16. Further, by the elastic force of
the urging spring 188L, a guide (dowel) 6140L1 (Figure
52) of the cartridge B6 is subjected to pressure
application. As a result, the cartridge B6 is
rotatably held about the guides 6140R1 and 6140L1 by
the apparatus main assembly A. That is, the guide
6140R1 is rotatably supported by the main assembly
guide 130R1 and the guide 6140L1 is rotatably
supported by the main assembly guide 130L1. Then, when
the door 109 (Figure 3) is closed, by the elastic
force of the urging spring 192R provided to the door
109 (and the urging spring 192L on the non-drive side
shown in Figure 16), the urging portion 6114a of the
cartridge B6 (Figures 51 and 52) is subjected to
pressure application. As a result, the cartridge B6 is
subjected to rotation moment about the guide 6140.
Then, nip width regulating members (spacing regulating
members) 6136 and 6137 (Figure 52) disposed at end portions of the developing roller 6110 of the cartridge 6B contact the end portions of the photosensitive drum 107. For that reason, the developing roller 6110 and the photosensitive drum 107 are kept with a constant contact nip. That is, the developing roller 6110 includes the developing shaft
6151 and a rubber portion (elastic member) 6110a
(Figures 52 and 53). The developing roller 6110
contacts the photosensitive drum 107 in a state in
which the rubber portion 6110a is bent. In this state,
the developing roller develops the electrostatic
latent image formed on the photosensitive drum 107
with the toner t.
Next, with reference to Figures 52 and 53, the
structure of the developing roller 6110 and the
mounting structure (supporting structure) of the
coupling 6150 will be described.
The developing shaft 6151 is an elongated
member of an electroconductive material such as iron
or the like. The developing shaft 6151 is rotatably
supported by the developing device frame 6113 through
a shaft supporting member 6152. Further, the
developing gear 6150b is fixedly positioned to the
developing shaft 6151 in a non-rotatable manner. The
coupling 6150 is mounted in an inclinable member to
the developing gear 6150b with the same structure as
described in Embodiment 1. That is, the coupling 6150 is mounted so that the axis L2 is inclinable with respect to the axis L1. The rotational force of the coupling 6150 received from the apparatus main assembly A is transmitted to the developing roller
6110 through the drive transmitting pin (rotational
force transmitting portion) 6155, the developing gear
6153, and the developing shaft 6151. As a result, the
developing roller 6110 is rotated.
The rubber portion 6110a is coated on the
developing shaft 6151 so as to be co-axial with the
developing shaft 6151. The rubber portion 6110a
carries the developer (toner) t at its peripheral
surface and to the developing shaft 6151, a bias is
applied. As a result, the rubber portion 6110a
develops the electrostatic latent image with the
developer t carried thereon.
The regulating members 6136 and 6137 are
members for regulating the nip width at a constant
level when the surface of the developing roller 6110
contacts the surface of the photosensitive drum 107.
That is, the regulating members 6136 and 6137 regulate
an amount of depression of the surface of the
developing roller 6110.
In the case of the contact developing system
as in this embodiment, when the state in which the
developing roller 6110 always contacts the
photosensitive drum 107 is kept, there is a possibility of deformation of the rubber portion 6110a of the developing roller 6110. For this reason, during the non-development, it is preferable that the developing roller 6110 is moved apart from the photosensitive drum 107. That is, *as shown in Figures
54(a) and 54(b), it is preferable that a state in
which the developing roller 6110 contacts the
photosensitive drum 107 (Figure 54(a)) and a state in
which the developing roller 6110 is moved apart from
the photosensitive drum 107 (Figure 54(b)) are created.
In the state in which the cartridge B6 is
mounted to the mounting portion 130a, an upper surface
(force receiving portion) 6114a of the developer
accommodating frame 6114 of the cartridge B6 is urged
by the elastic force of the springs 192R and 192L.
Thus, the cartridge B6 is rotated about the guides
(supporting points) 6140R and 6140L of the cartridge
B6 (in the clockwise direction X67 in Figure 54(a)).
Therefore, the surface of the developing roller 6110
contacts the surface of the photosensitive drum 107
(the state shown in Figure 54(a)).
Then, in this embodiment, the lever (urging
member, force-imparting member) 300 provided to the
apparatus main assembly A is rotated by a force of a
motor (not shown) rotated by a developing device
separation signal (i.e., rotated in the
counterclockwise direction (direction indicated by an arrow X45 in Figure 54(b))). Then, the lever 300 urges the bottom (force receiving portion) 6114a of the cartridge B6 (the developer accommodating frame 6114).
As a result, the cartridge B6 rotates about the guide
6140 against the elastic force of the springs 192R and
192L (i.e., rotates in the counterclockwise direction
X47). Therefore, the surface of the developing roller
6110 is placed in a separated state from the surface
of the photosensitive drum 107 (the state shown in
Figure 54 (b)). That is, the cartridge B6 rotates about
the guides (supporting points) 6140R and 6140L to move
in the direction X66.
The lever 300 is rotated to the stand-by
position by the force of a motor (not shown) rotated
in an opposite direction by a developing device
contact signal (i.e., rotated in the clockwise
direction (the direction indicated by an arrow X44
shown in Figure 54(b))). Then, the cartridge B6
returns to the developing device contact portion by
the elastic force of the springs 192R and 192L (the
state shown in Figure 54(a)). That is, the cartridge
B6 rotates about the guides (supporting points) 6140R
and 6140L to move in the direction X46.
Here, the stand-by position of the lever 300
refers to a state (position) in which the lever 300 is
separated from the cartridge B6 (the position shown in
Figure 54(a)).
According to this embodiment, while the
developing roller 6110 is left to rotate, it is
possible to move the cartridge B6 from the state of
Figure 54(b) to the state of Figure 54(a) and from the
state of Figure 54(a) to the state of Figure 54(b).
This operation will be described. The
rotation of the developing roller 6110 may preferably
be started immediately before the state of the
cartridge B6 is changed from the state of Figure 54(b)
to the state of Figure 54(a). That is, the developing
roller 6110 may preferably contact the photosensitive
drum 107 while rotating. In this way, by bringing the
developing roller 6110 into contact with the
photosensitive drum 107 while rotating the developing
roller 6110, it is possible to damage the
photosensitive drum 107 and the developing roller 6110.
This is true for the case where the developing roller
6110 is moved apart from the photosensitive drum 107,
so that the developing roller 6110 may preferably be
separated from the photosensitive drum 107.
With reference to Figures 55(a) and 55(b), an
example, of a drive input structure in this embodiment
will be described.
A state of Figure 55(a) corresponds to the
state of Figure 54(a), i.e., the state in which the
developing roller 6110 contacts the photosensitive
drum 107 and is rotatable. That is, the axis Ll of the developing roller 6110 and the axis L2 of the coupling
6150 are substantially in the same line, so that the
coupling 6150 is in a state in which it can receive
the rotational force from the driving shaft 180. When
the development is completed, the cartridge B6 is
moved from this state in the direction X66 (see also
Figure 54(a) in combination). At this time, the
developing shaft 6153 is gradually moved in the
direction X66, so that the axis L2 is gradually
inclined. When the cartridge B6 is placed in the state
of Figure 55(b), the developing roller 6110 is
completed moved away from the photosensitive drum 107.
Thereafter, the rotation of the motor 186 is stopped.
That is, even in the state of Figure 55(b), the motor
186 is rotated for a time. According to this
embodiment, the cartridge B6 can transmit the
rotational force even in the state in which the axis
L2 is inclined. Accordingly, even in the state shown
in Figure 55(b), the cartridge B6 can transmit the
rotational force to the developing roller 6110.
Therefore, according to the present invention, while
rotating the developing roller 6110, the developing
roller 6110 can be moved away from the photosensitive
drum 107.
A similar operation is performed in the case
where the state of the cartridge B6 is changed from
the state of Figure 55(b) to the state of Figure 55(a).
That is, the rotation of the motor 186 is started from
the state of Figure 55(b), so that the developing
roller 6110 can be rotated. That is, according to this
embodiment, the developing roller 6110 can be brought
into contact with the photosensitive drum 107 while
rotating the developing roller 6110.
Incidentally, the engaging operation and
disengaging operation of the coupling 6150 with
respect to the driving shaft 180 are the same as those
described in Embodiment 1, thus being omitted from the
description.
The structure described in Embodiment 6 is as
follows.
The apparatus main assembly A described in
Embodiment 6 is provided with the lever (urging
member) 300 in addition to the above-described
structure of the apparatus main assembly A.
The cartridge B6 in Embodiment 6 includes the
bottom (force receiving portion) 6114b. The bottom
6114b receives the urging force for moving the
developing roller 6110 away from the photosensitive
drum 107 in the state in which the cartridge B6 is
mounted to 'the apparatus main assembly A.
The cartridge B6 is urged by the elastic force
of the springs 192R and 192L at the upper surface
(force receiving portion) 6114a of the developer
accommodating frame 6114. As a result, the developing roller 6110 of the cartridge B6 presses against the photosensitive drum 107 rotatably positioned to the apparatus main assembly A. Therefore, the cartridge B6 is placed in the contact state in which the developing roller 6110 contacts the photosensitive drum 107.
When the upper surface (force receiving
portion) 6114a of the cartridge B6 is urged by the
lever 300, the cartridge B6 is placed in the
separation state in which the developing roller 6110
is separated from the photosensitive drum 107.
The cartridge B6 placed in either of the
contact state and the separation state can transmit
the rotational force from the coupling 6150 to the
developing roller 6110 since the coupling 6150 is
located at the above-described rotational force
transmission angular position. When the cartridge B6
is demounted from the apparatus main assembly A in the
direction substantially perpendicular to the axis Li,
the coupling 6150 is moved from the above-described
rotational force transmission angular position to the
above-described disengagement angular position. As a
result, the coupling 6150 can be disengaged from the
driving shaft 180.
Thus, even when the cartridge B6 is in the
above-described disengagement state and the axis L3
and the axis Li deviate from each other, according to
the coupling 6150 to which the present invention is applied, it is possible to smoothly transmit the rotational force from the driving shaft 180 to the developing roller 6110.
Incidentally, the axis Li represents the
rotational axis of the developing roller 6110 and the
axis L3 represents the rotational axis of the driving
shaft 180.
Thus, in Embodiment 6, the effects of the
embodiment to which the present invention is applied
are effectively utilized.
As described above, even when the drive input
position is not located at the swing center, in the
state in which the developing cartridge is moved away
from the photosensitive drum, it is possible to
transmit the rotational force to the developing roller.
For that reason, it is possible to allow latitude for
the drive input position, so that the cartridge and
the apparatus main assembly can be downsized.
Incidentally, in this embodiment, the drive
input position is located so as to be co-axial with
the developing roller. However, as described in a
subsequent embodiment, a similar effect can be
achieved also in the case where the drive input
position is located so as not to be co-axial with the
developing roller.
In this embodiment, the engagement and
disengagement of the coupling during the developing device separation are described. However, also in this embodiment, the engagement and disengagement of the coupling can also be applicable to those as described in Embodiment 1. As a result, in this embodiment, it is possible to perform mounting/demounting of the cartridge without particularly providing the driving connection mechanism and the releasing mechanism to the apparatus main assembly. Further, it is possible to the driving connection and release during contact/separation of the developing roller of the cartridge with respect to the photosensitive drum.
That is, according to the cartridge B6 to
which this embodiment is applied, the cartridge B6 can
be mounted to and demounted from the apparatus main
assembly A by being moved in the direction
substantially perpendicular to the axis L3 of the
driving shaft 180. In addition, according to the
cartridge B6, even during the developing device
separation, the transmission of the rotational force
from the apparatus main assembly A to the developing
roller 6110 can be performed smoothly.
Here, "during the developing device
separation" refers to a state in which the
photosensitive drum 107 and the developing roller 6110
which have contacted each other at their surfaces are
separated (moved away) from each other.
Figure 6 is described by taking the so-called developing cartridge as an example of the cartridge but the present invention is also applicable to the so-called process cartridge as the cartridge.
The structure of the cartridge is not limited
to that in Embodiment 6 but may also be appropriately
changed to other structures.
Embodiment 6 is also applicable to other
embodiments.
(Embodiment 7)
Embodiment 7 will be described with reference
to Figures 56 and 57.
Embodiment 7 is different from Embodiment 6 in
drive input position (coupling position) and structure
for transmitting the rotational force from the
coupling to the developing roller and the developer
feeding roller. Specifically, a coupling 8150 is not
located on the axis Ll of a developing roller 8110 but
is located at a position deviating from the axis Ll.
. Figure 56 is a perspective view of a cartridge
B8. Figure 57 is a perspective view showing a driving
portion of the cartridge B8.
A developing roller gear 8145 and a developer
feeding roller gear 8146 are disposed at driving-side
end portions of the developing roller 8110 and the
developer feeding roller 6115 (Figure 51),
respectively. The gears 8145 and 8146 are fixed to shafts (not shown). These gears transmit the rotational force, received from the apparatus main assembly A by the coupling 8150, to other rotatable members (the developing roller 8110, the developer feeding roller 6115, a toner stirring member (not shown) and the like) of the cartridge B8.
Next, a drive input gear 8147 to which the
coupling 8150 is mounted (by which the coupling 8150
is supported) will be described.
As shown in Figure 57, the gear 8147 is
rotatably fixed at a position in which the gear 8147
engages with the developing roller gear 8145 and the
developer feeding roller gear 8146. The gear 8147
includes a coupling accommodating portion 8147j
similarly as in the developing roller gear 151
described in Embodiment 1. The coupling 8150 is
mounted to the gear 8147 in an inclinable manner by a
retaining member 8156. That is, the coupling 8150 is
disposed on the axis Li of the developing roller 8110
but is disposed at a position deviated from the axis
Ll. The rotational force received from the driving
shaft 180 by the coupling 8150 is transmitted to the
developing roller 8110 through the gears 8147 and 8145.
The rotational force is further transmitted to the
developer feeding roller 6115 through the gears 8147
and 8146.
A supporting member 8157 is provided with a hole which defines an inner peripheral surface 8157i engageable with the gear 8147. The description on the engagement, drive, and disengagement of the coupling by the mounting and demounting operations of the cartridge is the same as that in Embodiment 1, thus being omitted.
Further, as the structure for inclining the
axis L2 of the coupling 8150 to the angular position
before the engagement immediately before the coupling
8150 engages with the driving shaft, any of those in
Embodiment 2 to Embodiment 5 may be employed.
As described above, the coupling 8150 is not
required to be disposed at the end portion co-axial
with the developing roller 8110. According to this
embodiment, it is possible to improve design latitude
of the image forming apparatus main assembly and the
cartridge.
(Embodiment 8)
Embodiment 8 will be described with reference
to Figures 58 to 62.
Figure 58 is a principal sectional view of a
process cartridge B9 of this embodiment and Figure 59
is a perspective view of the process cartridge B9.
Figure 60 is a principal sectional view of the
apparatus main assembly and Figure 61 is a perspective
view showing a mounting guide (drive side) of the apparatus main assembly and a driving connection portion. Figures 62(a) to 62(c) are schematic views for illustrating a process of mounting the process cartridge to the apparatus main assembly as seen from above the apparatus. The process cartridge is an example of the above-described cartridge.
In this embodiment, the present invention is
applied to the process cartridge which is prepared by
integrally supporting the photosensitive drum and the
developing roller as a unit and is detachably
mountable to the apparatus main assembly. That is,
this embodiment relates to the process cartridge
mountable to and demountable from the apparatus main
assembly A provided with the driving shaft by moving
the process cartridge in a direction substantially
perpendicular to an axial direction of the driving
shaft. According to this embodiment, the process
cartridge (hereinafter simply referred to as the
cartridge) includes two portions for receiving the
rotational force from the apparatus main assembly.
That is, the cartridge to which the present
invention is applied separately receives the
rotational force for rotating the photosensitive drum
from the apparatus main assembly and the rotational
force for rotating the developing roller from the
apparatus main assembly.
Also to such a structure, the present invention is applicable, and it is possible to achieve effects described later. In contact with a photosensitive drum 9107, a charging roller 9108 as the charging means (process means).
Further, the cartridge B9 includes the
developing roller 9110 as the developing means
(process means). The developing roller 9110 feeds the
developer t to a developing area of the photosensitive
drum 9107. The developing roller 9110 develops the
electrostatic latent image formed on the
photosensitive drum 9107 by using the developer t. The
developing roller 9110 contains a magnet roller (fixed
magnet) 9111.
In contact with the developing roller 9110, a
developing blade 9112 is provided. The developing
blade 9112 determines an amount of the developer t to
be deposited on the peripheral surface of the
developing roller 9110.
The developer accommodated in a developer
accommodating container 9114 is fed by rotation of
stirring members 9115 and 9116. Then, a developer
layer to which electric charges are imparted by the
developing blade 9112 is formed on the surface of the
developing roller 9110. Then, the developer t is
transferred onto the photosensitive drum 9107
depending on the latent image. As a result, the latent
image is developed.
In contact with the photosensitive drum 9107,
an elastic cleaning blade 9117a as the cleaning means
(process means) is disposed. The blade 9117a removes
the developer t remaining on the photosensitive drum
9107 after the developer image is transferred onto a
recording material 9102. The developer t removed from
the surface of the photosensitive drum 9107 by the
blade 9117a is collected in a removed developer
container 9117b.
The cartridge B9 includes a first frame unit
9119 and a second frame unit 9120 which are swingably
(rotatably) connected with each other.
The first frame unit (developing device) 9119
is constituted by a first frame 9113 as a part of a
cartridge frame. The unit 9119 includes the developing
roller 9110, the developing blade 9112, a developing
chamber 9113a, the developer accommodating container
(developer accommodating portion) 9114, and the
stirring members 9115 and 9116.
The second frame unit 9120 is constituted by a
second frame 9118 as a part of the cartridge frame.
The unit 9120 includes the photosensitive drum 9107,
the cleaning blade 9117a, the removed developer
container (removed developer accommodating portion)
9117b, and the charging roller 9108.
The first frame unit (developing device) 9119
and the second frame unit 9120 are rotatably connected by a pin P. By an elastic member (not shown) provided between the units 9119 and 9120, the developing roller
9110 is pressed against the photosensitive drum 9107.
That is, the first frame unit (developing device) 9119
determines the position of the second frame unit 9120.
The user grips a handle T and mounts the
cartridge B9 to a cartridge mounting portion 9130a
provided to an apparatus main assembly A9. At this
time, as described later, in interrelation with the
mounting operation of the cartridge B9, the driving
shaft 9180 provided to the apparatus main assembly A9
and a cartridge-side developing roller coupling
(rotational force transmitting part) 9150 of the
cartridge B9 are connected with each other. The
developing roller 9110 and the like are rotated by
receiving the rotational force from the apparatus main
assembly A9.
After the completion of the cartridge B9 to
the apparatus main assembly A9, the door 109 is closed.
In interrelation with the closing operation of the
door 109, a main assembly-side drum coupling 9190 and
a cartridge-side drum coupling (rotational force
transmitting part) 9145 are connected with each other.
Thus, the photosensitive drum 9107 is rotated by
receiving the rotational force from the apparatus main
assembly A9. The main assembly-side drum coupling 9190
is a non-circular twisted hole having a plurality of corners in cross section. This coupling 9190 is provided at a central portion of a rotatable drive member 9191. At a peripheral surface of the rotatable drive member 9191, a gear (helical gear) 9191a is provided. To the gear 9191a, the rotational force from the motor 196 is transmitted.
Further, the cartridge-side drum coupling 9145
is a non-circular twisted projection having a
plurality of corners in cross section. The coupling
9145 engages with the coupling 9190 to receive the
rotational force from the motor 186. That is, the
rotatable member 9191 is rotated in a state in which
the hole of the coupling 9145 and the projection of
the coupling 9190 are engaged with each other. As a
result, in a state in which the projection receives a
drawing force into the hole, the rotational force of
the rotatable drive member 9191 is transmitted to the
photosensitive drum 9107 through the projection.
The shape of the projection may appropriately
be changed so long as the projection can receive the
rotational force from the hole in the engaged state
with the hole. In this embodiment, the hole shape is a
substantially equilateral triangle and the projection
shape is a substantially twisted equilateral
triangular column. As a result, according to the
present invention, it is possible to transmit the
rotational force from the hole to the projection in a state in which the axis of the hole and the axis of the projection are aligned with each other (center alignment) and in a state in which the projection receives the drawing force into the hole. Therefore, the photosensitive drum 9107 can be rotated accurately and smoothly. Further, the hole is provided co-axially with the axis of a shaft portion 9107a of the photosensitive drum 9107. The shaft portion 9107a is provided at one end portion of the photosensitive drum
9107 and is rotatably supported by the unit 9120.
The main assembly-side drum coupling 9190 (the
rotatable drive member 9191) is, as described later,
moved by a moving member (a retractable mechanism)
9195 moved in interrelation with the closing operation
of the door 109. That is, the coupling 9190 is moved
by the moving member 9195 in a direction along a
rotational axis X70 of the coupling 9190 and in a
direction X93 in which the coupling 9145 is provided.
As a result, the coupling 9190 and the coupling 9145
are engaged with each other. Then, the rotational
force of the coupling 9190 is transmitted to the
coupling 9145 (Figure 62(b)).
The coupling 9190 (the rotatable drive member
9191) is moved by the moving member 9195, moved in
interrelation with the opening operation of the door
109, in the direction along the rotational axis X70
and in a direction X95 in which the coupling 9190 is moved apart from the coupling 9145. As a result, the coupling 9190 and the coupling 9145 are separated from each other (Figure 62(c)).
That is, the coupling 9190 is moved toward and
away from the coupling 9145 in the direction along the
rotational axis X70 by the moving member (retractable
member) 9195 as described later (in the directions
indicated by the arrows X93 and X95 in Figures 62(b)
and 62(c)). Incidentally, details of the structure of
the moving member 9195 will -be omitted from
explanation since a known structure may appropriately
be used as the structure of the moving member 9195.
For example, the structures of the coupling 9145, the
coupling 9190, and the moving member 9195 are
described in Japanese Patent No. 2875203.
As shown in Figure 61, a mounting means 9130
in this embodiment includes main assembly guides
9130R1 and 9130R2 provided in the apparatus main
assembly A9.
These guides are oppositely provided in the
cartridge mounting portion 9130a (cartridge mounting
space) provided in the apparatus main assembly A9.
Figure 61 shows the drive-side surface and a non-drive
side has a symmetrical shape with respect to the drive
side, thus being omitted from explanation. The guides
9130R1 and 9130R2 are provided along the mounting
direction of the cartridge B9.
When the cartridge B9 is mounted to the
apparatus main assembly A9, a cartridge guide
described later is inserted while being guided by the
guides 9130R1 and 9130R2. The mounting of the
cartridge B9 to the apparatus main assembly A9 is
performed in a state in which the cartridge door 109
openable about a shaft 9109a with respect to the
apparatus main assembly A9. By closing the door 109,
the mounting of the cartridge B9 to the apparatus main
assembly A9 is completed. Incidentally, also when the
cartridge B9 is demounted from the apparatus main
assembly A9, the demounting operation is performed in
the state in which the door 109 is opened. These
operations are performed by the user.
In this embodiment, as shown in Figure 59, an
outer end peripheral portion 9159a of the shaft
supporting member 9195 also functions as a cartridge
guide 9140R1. That is, the shaft supporting member
9159 is outwardly projected, so that its outer
peripheral surface has a guiding function.
At a longitudinal end (drive side) of the
second frame unit 9120, cartridge guides 9140R2 are
provided above the cartridge guide 9140R1.
When the cartridge B9 is mounted to the
apparatus main assembly A9 and when the cartridge B9
is demounted from the apparatus main assembly A9, the
guide 9140R1 is guided by the guide 9130R1 and the guides 9140R2 are guided by the guide 9130R2.
The guide structure on the other end-side of
the apparatus main assembly and the guide structure on
the other end-side of the cartridge are the same as
those described above, thus being omitted from the
description. In the above-described manner, the
cartridge B9 is moved in the direction substantially
perpendicular to the direction of the axis L3 of the
driving shaft 9180 to be mounted to and be demounted
from the apparatus main assembly A9.
When such a cartridge B9 is mounted to the
apparatus main assembly A9, similarly as in
Embodiments described above, the coupling 9150 is
engaged with the driving shaft 9180 of the apparatus
main assembly A9. Then, by rotating the motor 186, the
driving shaft 9180 is rotated. By the rotational force
transmitted to the developing roller 9110 through the
coupling 9150, the developing roller 9110 is rotated.
Incidentally, with respect to the drive transmitting
path in the cartridge, as described in Embodiment 1,
the coupling may be disposed co-axially with the
developing roller 9110 or disposed at the position
deviated from the axis of the developing roller 9110.
The engagement and disengagement operations between
the coupling 9150 and the driving shaft 9180 are the
same as those described above, thus being omitted from
the description.
As the structure of the cartridge-side
developing roller coupling 9150, those of the
above-described couplings may appropriately be
employed.
Here, with reference to Figures 62(a) to 62(c),
the process in which the above-described process
cartridge B9 is mounted to the mounting portion 9130a
to establish the drive connection between the
apparatus main assembly A9 and the cartridge B9 will
be described.
In Figure 62(a), the cartridge B9 is being
mounted to the apparatus main assembly A9. At this
time, the axis L2 of the coupling 9150 is, as
described above, inclined toward the downstream side
with respect to the mounting direction (X92). Further,
the apparatus main assembly-side drum coupling 9190 to
be engaged with the drum coupling 9145 is retracted so
as not to obstruct the mounting path of the cartridge
B9. An amount of retraction is indicated by X91 in
Figure 62(a). In this figure, the driving shaft 9180
seems to be located in the mounting (demounting) path
of the cartridge B9. However, as is apparent from
Figure 61, the drum coupling 9145 and the developing
roller coupling 9150 are deviated from each other with
respect to the moving path in the cross-sectional
direction (the vertical direction). Therefore, the
driving shaft 9180 does not obstruct the mounting and demounting of the cartridge B9.
Then, from this state, when the user inserts
the cartridge B9 into the apparatus main assembly A9,
the cartridge B9 is mounted to the mounting portion
9130a. Similarly as in the aforementioned description,
the coupling 9150 is engaged with the driving shaft
9180 by this operation. Thus, the coupling 9150 is
placed in the state in which it can transmit the
rotational force to the developing roller 9110.
Then, by the moving member 9195 interrelated
with the closing operation of the door 109 (Figure 61)
by the user, the drum coupling 9190 on the apparatus
main assembly A9 side is moved in the direction X93
(Figure 62(b)). Then, the coupling 9190 engages with
the drum coupling 9145 of the cartridge B9 to be
placed in a rotational force transmittable state.
Thereafter, by the image forming operation, the
rotational force from the motor 186 is transmitted to
the drum gear 9190 fixed to the drum coupling 9190.
Further, the rotational force is transmitted to a
developing gear 9181 fixed to the driving shaft 9180
for receiving the rotational force from the coupling
9150. As a result, the rotational force from the motor
196 is transmitted to the photosensitive drum 9107
through the drum coupling 9190 and the drum gear 9190.
Further, the rotational force from the motor 196 is
transmitted to the developing roller 9110 through the coupling 9150, the rotational force-receiving driving shaft 9180, and the developing gear 9181. Incidentally, details of the transmission path from the coupling
9150 in the developing unit 9114 to the developing
roller 9110 through the supporting member 9147 are
same as those described above, thus being omitted from
explanation. When the cartridge B9 is demounted from
the apparatus main assembly A9, the user opens the
door 109 (Figure 61). By the moving member 9195
interrelated with the opening operation of the door
109, the drum coupling 9190 on the apparatus main
assembly A9 side.is moved in the direction X95
opposite from the direction X93 (Figure 62(c)). As a
result, the drum coupling 9190 is moved apart from the
drum coupling 9145. Thus, the cartridge B9 can be
demounted from the apparatus main assembly A9.
As descried above, the apparatus main assembly
A9 in Embodiment 8 includes, in addition to the
above-described structure of the apparatus main
assembly A, the moving member (retractable mechanism)
9195 for moving the main assembly-side drum coupling
9190 and the coupling 9145 in their axis direction
(the rotational axis direction X70).
In Embodiment 8, the cartridge (process
cartridge) B9 integrally includes the photosensitive
drum 9107 and the developing roller 9110.
In Embodiment 8, when the cartridge B9 is demounted from the apparatus main assembly A9 in the direction substantially perpendicular to the axis Ll of the developing roller 9110, the cartridge-side developing roller coupling 9150 is moved as follows.
That is, the coupling 9150 is moved from the
rotational force transmission angular position to the
disengagement angular position to be disengaged from
the driving shaft 9180. Then, by the moving member
9185, the main assembly-side drum coupling 9190 is
moved in its axis direction and also in the direction
in which the coupling 9190 is moved apart from the
cartridge-side drum coupling 9145. As a result, the
cartridge-side drum coupling 9145 is disengaged from
the main assembly-side drum coupling 9190.
According to Embodiment 8, with respect to the
coupling structure for transmitting the rotational
force from the apparatus main assembly A9 to the
photosensitive drum 9107 and the coupling structure
for transmitting the rotational force from the
apparatus main assembly A9 to the developing roller
9110, the number of the moving members can be reduced
as compared with those requiring the moving member for
each.
Therefore, according to Embodiment 8, the
apparatus main assembly can be downsized. Further,
when the apparatus main assembly is designed, it is
possible to allow increased design latitude.
Further, this embodiment can also be applied
to the case of the contact developing system as
described in Embodiment 6. In this case, this
embodiment is applicable to not only the mounting and
demounting of the cartridge but also the drive
connection during the developing device separation.
Further, in this embodiment, with respect to
the drive connection of the photosensitive drum, such
a manner as in this embodiment is not employed but the
couplings as in this embodiment may also be disposed.
As described above, according to this
embodiment, by applying the present invention to at
least the case where the developing roller is rotated
(i.e., the rotational force is transmitted to the
developing device), the number of the moving members
(retractable mechanisms) can be reduced by at lease
one. Therefore, according to this embodiment, it is
possible to realize the downsizing of the apparatus
main assembly and the increased design latitude.
Incidentally, in Embodiment 8,as the
cartridge-side drum coupling for receiving the
rotational force from the apparatus main assembly in
order to rotate the photosensitive drum, the twisted
projection is described as an example. However, the
present invention is not limited thereto. The present
invention is appropriately applicable to such a
coupling structure that the main assembly-side drum coupling is movable (retractable) in the rotational direction of the cartridge-side drum coupling. That is, in the present invention, such a coupling structure that the main assembly-side drum coupling approaches the cartridge-side drum coupling to engage therewith in the above-described movement direction and is moved apart from the cartridge-side drum coupling in the above-described movement direction. To the embodiment to which the present invention is applied, e.g., a so-called pin-drive coupling structure is applicable.
According to Embodiment 8, in the structure in
which the rotational forces for rotating the
photosensitive drum and the developing roller are
separately transmitted from the apparatus main
assembly, the moving structure for moving (retracting)
the coupling with respect to its rotational direction
can be reduced in number. That is, as the moving
structure, only the structure for transmitting the
rotational force to the photosensitive drum can be
used.
Therefore, according to Embodiment 8, it is
possible to achieve an effect of simplifying the
structure of the apparatus main assembly as compared
with the case where the moving structure is required
for both of the structure for transmitting the
rotational force to the photosensitive drum and the
structure for transmitting the rotational force to the developing roller.
(Embodiment 9)
Embodiment 9 will be described with reference
to Figure 63.
In Embodiment 9, the present invention is
applied to both of the coupling for receiving the
rotational force, from the apparatus main assembly,
for rotating the photosensitive drum and the coupling
for receiving the rotational force, from the apparatus
main assembly, for rotating the developing roller.
That is, a cartridge B10 to which the present
invention is applied and the cartridge B9 described in
Embodiment 8 are different in that the photosensitive
drum 9107 also receives the rotational force from the
apparatus main assembly by using the coupling
structure similar to that in Embodiment 8.
According to Embodiment 9, without using the
moving member (retractable mechanism) described in
Embodiment 8, the process cartridge B10 can be moved
in the direction substantially perpendicular to the
direction of the axis L3 of the driving shaft 180 to
be mounted to and demounted from the apparatus main
assembly.
The cartridge B10 in Embodiment 9 and the
cartridge B9 in Embodiment 8 are merely different in
the cartridge-side drum coupling structure and the structure for transmitting the rotational force received by the coupling to the photosensitive drum and are the same in other structures.
Further, with respect to the apparatus main
assembly-side structures, both cartridges are only
different in the main assembly side drum coupling
structure.
The apparatus main assembly to which
Embodiment 9 is applied includes the driving shaft
described in the above-described embodiments in place
of the main assembly-side drum coupling structure in
Embodiment 8, thus being omitted from the description.
To the apparatus main assembly in this embodiment
(Embodiment 9), a driving shaft (first driving shaft)
180 and a driving shaft (second driving shaft) (not
shown) having the same structure as the driving shaft
180 are provided. However, similarly as in Embodiment
8, the moving paths of a cartridge-side drum coupling
10150 and the cartridge-side developing roller
coupling 9150 are deviated from each other in the
cross-sectional direction (the vertical direction).
Therefore, the first driving shaft 180 and the second
driving shaft (not shown) do not obstruct the mounting
and demounting of the cartridge B10.
Similarly as in the case of the cartridge-side
developing roller coupling 9150, the cartridge-side
drum coupling 10150 of the cartridge B10 has the same structure as those in the above-described embodiments, thus being explained by making reference to the above-described coupling structures.
According to Embodiment 9, the cartridge B10
is moved in the direction substantially perpendicular
to the direction of the axis L3 of the first driving
shaft 180 and the second driving shaft (not shown) to
be mounted to and demounted from the apparatus main
assembly.
Further, in Embodiment 9, when the cartridge
B10 is mounted to the cartridge mounting portion 130a,
the first driving shaft 180 and the developing roller
coupling 9150 are engaged with each other, so that the
rotational force is transmitted from the driving shaft
180 to the coupling 9150. By the rotational force
received by the coupling 9150, the developing roller
9110 is rotated.
Further, the second driving shaft and the drum
coupling 10150 are engaged with each other, so that
the rotational force is transmitted from the second
driving shaft to the coupling 10150. By the rotational
force received by the coupling 10150, the
photosensitive drum 9107 is rotated.
To Embodiment 9, the structures described in
the above-described embodiments are appropriately
applicable.
According to this embodiment, without using the moving member (retractable mechanism) described in
Embodiment 8, the process cartridge B10 can be mounted
to and demounted from the apparatus main assembly by
being moved in the direction substantially
perpendicular to the direction of the axis of the
driving shaft.
As a result, the structure of the apparatus
main assembly can be simplified.
In the above-described embodiments, the
apparatus main assembly includes the driving shafts
(180, 1180, 9180) provided with the rotational force
transmitting pin (rotational force imparting portion)
182. Further, the cartridges (B, B2, B6, B8, B9, B10)
are moved in the direction substantially perpendicular
to the direction of the axis L3 of the driving shafts,
thus being mounted to and demounted from the apparatus
main assemblies (A, A2, A9). The above-described
respective cartridges include the developing rollers
(110, 6110, 8110, 9110) and the couplings (150, 1150,
4150, 6150, 7150, 8150, 9150, 10150, 12150, 14150).
i) The developing roller (110, 6110, 8110,
9110) is rotatable about the axis Li thereof, and
develops the electrostatic latent image formed on the
photosensitive drum (107, 9107).
ii) The coupling is engaged with the rotational
force transmitting pin (the rotational force applying
portion) (182, 1182, 9182) to receive the rotational force for rotating the developing roller from the pin.
The coupling may be one of the couplings 150, 1150,
4150, 6150, 7150, 8150, 9150, 10150, 12150, 14150. The
coupling can take the rotational force transmitting
angular position for transmitting the rotational force
for rotating the developing roller to the developing
roller. The coupling can take the pre-engagement
angular position which is a position inclined, in the
direction away from the axis Li of the developing
roller, from the rotational force transmitting angular
position and the disengaging angular position which is
a position inclined from the rotational force
transmitting angular position. In mounting the
cartridge (B, b-2, b6, b8, b9, blO) to the main
assembly in the direction substantially perpendicular
to the axis Li of the developing roller, the coupling
moves to the rotational force transmitting angular
position from the pre-engagement angular position. By
this, the coupling opposes to the drive shaft. In
dismounting the cartridge, in the direction
substantially perpendicular to the axis Li of the
developing roller, from the main assembly the coupling
moves to the disengaging angular position from the
rotational force transmitting angular position. By
this, the coupling disengages from the drive shaft.
In the state that the cartridge is set in the
main assembly, a part of the coupling is positioned behind the drive shaft as seen in the opposite direction to the removing direction X6 (Figure 19 (d), for example). A part of the coupling is one of the free end positions 150A1, 1150A1, 4150A1, 12150A1,
14150 A3. The removing direction X6 is the direction
for dismounting the cartridge from the main assembly.
In dismounting the cartridge B from the main assembly
A in response to moving the cartridge in the direction
substantially perpendicular to the axis Li of the
developing roller 110, the coupling makes the
following motion. The coupling is moved (inclined) to
the disengaging angular position from the rotational
force transmitting angular position so that the part
of the coupling circumvents the drive shaft.
In mounting the cartridge to the main assembly
the coupling makes the following motion. The coupling
is moved (inclined) to the rotational force
transmitting angular position from the pre-engagement
angular position so that the part of the coupling at
the downstream side with respect to the mounting
direction X4 circumvents the drive shaft. The mounting
direction X4 is the direction of for mounting the
cartridge to the main assembly.
In the state that the cartridge is mounted to
the main assembly the part or portion of the coupling
is behind the drive shaft as seen in the opposite
direction to the removing direction X6 for dismounting the cartridge from the main assembly. In dismounting the cartridge from the main assembly the coupling makes the following motion. In response to moving the cartridge in the direction substantially perpendicular to the axis Ll of the developing roller, the coupling is moved (inclined) to the disengaging angular position from the rotational force transmitting angular position so that the portion of the coupling circumvents the drive shaft.
In the embodiment described above, the coupling
has the recesses (150z, 1150z, 1350z, 4150z, 6150z,
7150z, 9150z, 12150z, 14150z) co-axial with the
rotation axis L2 of the coupling. In the state that
the coupling is in the rotational force transmitting
angular position, the recess covers the free end of
the drive shaft 180. The rotational force reception
surface (rotational force receiving portion) engages
in the rotational direction of the coupling with the
rotational force transmitting pin (rotational force
applying portion) (182, 1182, 9182) which projects in
the direction perpendicular to the axis L3 of the
drive shaft in the free end portion of the drive shaft.
The rotational force reception surface is one of the
rotational force receiving surfaces 150e, 1150e, 1350e,
4150e, 6150e, 7150e, 9150e, 12150e, 14150e. By this,
the coupling receives the rotational force from the
drive shaft to rotate. In dismounting the cartridge from the main assembly the coupling makes the following motion. In response to moving the cartridge in the direction substantially perpendicular to the axis Li of the developing roller, the coupling is pivoted (moved) to the disengaging angular position from the rotational force transmitting angular position so that the portion of the recess circumvents the drive shaft. By this, the coupling can disengage from the drive shaft. The portion is one of the free end positions 150A1, 1150A1, 4150A1, 12150A1, 14150 A3.
As has been described hereinbefore, the
coupling has the recess co-axially with the rotation
axis L2 thereof. In the state that the coupling is in
the rotational force transmitting angular position,
the recess covers the free end of the drive shaft. The
rotational force reception surface (rotational force
receiving portion) engages in the rotational direction
of the coupling with the rotational force transmitting
pin of the free end portion of the drive shaft. By this, the coupling receives the rotational force from
the drive shaft to rotate. In dismounting the
cartridge from the main assembly the coupling makes
the following motion. In response to moving the
cartridge B in the direction substantially
perpendicular to the axis Li of the developing roller,
the coupling is pivoted (moved) to the disengaging
angular position from the rotational force transmitting angular position so that the portion of the recess circumvents the drive shaft. By this, the coupling can disengage from the drive shaft.
The rotational force receiving surfaces
(rotational force receiving portions) are provided so
that they are positioned, interposing the center S, on
the phantom circle C1 which has the center S on the
rotation axis L2 of the coupling (Figure 6 (d), for
example). In this embodiment, the four rotational
force reception surfaces are provided. By this,
according to this embodiment, the coupling can
uniformly receive the force from the main assembly.
Accordingly, the coupling can be rotated smoothly.
In the state that the coupling is in the
rotational force transmitting angular position, the
axis L2 of the coupling is co-axial with the axis Li
of the developing roller substantially. In the state
that the coupling is in the disengaging angular
position, the coupling inclines relative to the axis
Li so that the upstream side thereof can pass by the
free end of the drive shaft in the removing direction
X6. The upstream side is one of the free end position
150A1, 1150A1, 4150A1, 12150A1, 14150 A3.
The cartridge described above is a developing
cartridge not containing the photosensitive drum. Or,
the cartridge is the process cartridge including the
photosensitive drum as a unit. By applying to these cartridges the present invention the effects as described above are provided.
(Other embodiments)
In the embodiments described above, the
cartridge is mounted and demounted downwardly or
angularly upwardly relative to the drive shaft of the
main assembly. However, the present invention is not
limited to the structure thereof. The present
invention can suitably be applied to the cartridge
which can be mounted and demounted in the direction
perpendicular to the axis of the drive shaft.
In the foregoing embodiments, the mounting path
is straight relative to the main assembly, but the
present invention is not limited to such a structure.
The present invention can suitably be applied also to
the case where the mounting path includes a path
provided as a combination of the straight lines or
curvilinear path.
The developing cartridge of the embodiments
forms a monochromatic image. However, the present
invention can suitably be applied also to the
cartridge having a plurality of developing means to
form a color image (two-color image, three-color image,
or full-color image).
The process cartridge of the embodiments forms
a monochromatic image. However, the present invention can suitably be applied also to the cartridge may contain a plurality of photosensitive drums, and developing means and charging means, respectively to form a color images such as two-color images, three color images, or full-color images.
The developing cartridge includes at least the
developing roller (developing means).
The process cartridge contains, as a unit, the
electrophotographic photosensitive member and the
process means which is actable on the
electrophotographic photosensitive member and is
detachably mountable to the main assembly of the
electrophotographic image forming apparatus. For
example, it contains at least the electrophotographic
photosensitive member and the developing means as the
process means.
This cartridge (developing cartridge and
process cartridge) is detachably mountable to the main
assembly by the user. In view of this, the maintenance
of the main assembly can be carried out in effect by
the user.
According to the foregoing embodiments, the
coupling can be mounted and demounted, in the
direction substantially perpendicular to the axis of
the drive shaft, relative to the main assembly which
is not provided with the mechanism for moving the main
assembly side coupling member for transmitting the rotational force in axial direction thereof. The developing roller can be rotated smoothly.
According to the embodiments described above,
the cartridge can be dismounted, in the direction
substantially perpendicular to the axis of the drive
shaft, from the main assembly of the
electrophotographic image forming apparatus provided
with the drive shaft.
According to the embodiments described above,
the cartridge can be mounted, in the direction
substantially perpendicular to the axis of the drive
shaft, to the main assembly of the electrophotographic
image forming apparatus provided with the drive shaft.
According to the embodiments described above,
the developing cartridge can be mounted and dismounted,
in the direction substantially perpendicular to the
axis of the drive shaft, relative to the main assembly
of the electrophotographic image forming apparatus
provided with the drive shaft.
According to the embodiments of coupling
described above, the developing cartridge is moved in
the direction substantially perpendicular to the axis
of the drive shaft to mount and demount the developing
cartridge relative to the main assembly, even if the
drive rotor (driving gear) provided in the main
assembly does not move in the axial direction thereof.
According to the embodiments described above, the developing roller can be rotated smoothly, as compared with the case in which the drive connecting portion between the main assembly and the cartridge employs the gear-gear engagement.
According to the embodiments described above,
both of the dismounting of the cartridge in the
direction substantially perpendicular to the axis of
the drive shaft provided in the main assembly and the
smooth rotation of the developing roller, can be
accomplished.
According to the embodiments described above,
both of the mounting of the cartridge in the direction
substantially perpendicular to the axis of the drive
shaft provided in the main assembly and the smooth
rotation of the developing roller, can be accomplished.
According to the embodiments described above,
both of the mounting and dismounting of the cartridge
in the direction substantially perpendicular to the
axis of the drive shaft provided in the main assembly
and the smooth rotation of the developing roller, can
be accomplished.
According to the embodiments described above,
in the developing cartridge (or developing device of
the process cartridge) positioned relative to the
photosensitive drum, the drive can be assuredly
applied to the developing roller, and the smooth
rotation can be accomplished.
[INDUSTRIAL APPLICABILITY]
As has been described hereinbefore, in the
present invention, the axis of the coupling member can
take the different angular positions relative to the
axis of the developing roller. With this structure in
the present invention, the coupling member can be
brought into engagement with the drive shaft in the
direction substantially perpendicular to the axis of
the drive shaft provided in the main assembly. Also,
the coupling member can be brought into disengagement
from the drive shaft in the direction substantially
perpendicular to the axis of the drive shaft. The
present invention can be applied to the developing
cartridge, the electrophotographic image forming
apparatus usable with the detachably mountable
developing cartridge, the process cartridge, and the
electrophotographic image forming apparatus usable
with the detachably mountable process cartridge.
The present invention can be applied to a so
called contact type developing system wherein in the
state in which the electrophotographic photosensitive
member and the developing roller contact to each other,
the electrostatic latent image formed on the
electrophotographic photosensitive member is developed.
The present invention can be applied to a so
called contact type developing system wherein in the
state in which the electrophotographic photosensitive member and the developing roller are spaced from each other, the electrostatic latent image formed on the electrophotographic photosensitive member is developed.
The developing roller can be rotated smoothly.
According to the embodiments of the present
invention, the rotational force for rotating the
photosensitive drum and the rotational force for
rotating the developing roller can be received
individually from the main assembly. According to the
embodiments of the present invention, the structure
for receiving the rotational force for rotating the
photosensitive drum can employ the structure for
making the coupling move in the axial direction
thereof.
While the invention has been described with
reference to the structures disclosed herein, it is
not confined to the details set forth and this
application is intended to cover such modifications or
changes as may come within the purpose of the
improvements or the scope of the following claims.

Claims (23)

  1. CLAIMS: 1. A process cartridge for an electrophotographic image forming apparatus, wherein a main assembly of said apparatus includes first and second main assembly engaging portions having first and second driving shafts, respectively and first and second rotational force applying portions provided on the driving shafts, respectively, wherein said process cartridge is dismountable from the main assembly in a dismounting direction substantially perpendicular to axial directions of the driving shafts, said process cartridge comprising: i) an electrophotographic photosensitive drum, rotatable about a drum axis thereof, for bearing a latent image, and ii) a first coupling member rotatable about the first coupling axis by a rotational force received from the first main assembly engaging portion, said first coupling member including a first rotational force receiving portion engageable with the first rotational force applying portion to receive the first rotational force to be transmitted to said electrophotographic photosensitive drum from the first main assembly engaging portion, and the first rotational force transmitting portion for transmitting the first rotational force to said electrophotographic photosensitive drum from said first rotational force receiving portion; and iii) a developing roller, rotatable about a roller axis thereof, for developing the latent image formed on said electrophotographic photosensitive drum, and iv) a second coupling member rotatable about a second coupling axis by a rotational force received from the second main assembly engaging portion, said second coupling member including a second rotational force receiving portion engageable with the second rotational force applying portion to receive a second rotational force to be transmitted to said developing roller from the second main assembly engaging portion, and a second rotational force transmitting portion for transmitting the second rotational force to said developing roller from said second rotational force receiving portion, wherein said first coupling member is capable of first pivoting movement such that a first rotational force receiving portion side of said first coupling axis is positioned upstream of a first rotational force transmitting portion side of said first coupling axis with respect to the dismounting direction, and said first coupling member is disengageable from the first main assembly engaging portion by the first pivoting movement, and wherein said second coupling member is capable of second pivoting movement such that a second rotational force receiving portion side of said second coupling axis is positioned upstream of a second rotational force transmitting portion side of said second coupling axis with respect to the dismounting direction, and said second coupling member is disengageable from the second main assembly engaging portion by the second pivoting movement.
  2. 2. A process cartridge according to Claim 1, wherein an upstream part of said first coupling member with respect to the dismounting direction circumvents the first main assembly engaging portion by inclining of in a direction opposite to the dismounting direction, wherein an upstream part of said second coupling member with respect to the dismounting direction circumvents the second main assembly engaging portion by inclining in the direction opposite to the dismounting direction.
  3. 3. A process cartridge according to Claim 1, wherein the dismounting of said process cartridge causes the inclining of said first and second coupling members in a direction opposite to the dismounting direction.
  4. 4. A process cartridge according to Claim 1, further comprising a first rotational force receiving member for receiving the first rotational force from said first coupling member and a second rotational force receiving member for receiving the second rotational force from said second coupling member, wherein said first and second coupling member are pivotably coupled with said first and second rotational force receiving members respectively.
  5. 5. A process cartridge according to Claim 4, wherein afirst rotational axis of said first rotational force receiving member is substantially coaxial with said drum axis, wherein a second rotational axis of said second rotational force receiving member is substantially coaxial with said roller axis.
  6. 6. A process cartridge according to Claim 5, wherein said first rotational force receiving member is provided on a longitudinal end of said photosensitive drum, wherein said second rotational force receiving member is provided on a longitudinal end of said developing roller.
  7. 7. A process cartridge according to Claim 4, wherein afirst rotational axis of said first rotational force receiving member is substantially coaxial with said drum axis, wherein a second rotational axis of said second rotational force receiving member is offset from and substantially parallel with said roller axis.
  8. 8. A process cartridge according to Claim 7, further comprising another second rotational force receiving member that is provided on a longitudinal end of said developing roller, wherein the rotational force is transmitted from said second rotational force receiving member to said developing roller through said another second rotational force receiving member, wherein said first rotational force receiving member is provided on a longitudinal end of said photosensitive drum.
  9. 9. A process cartridge according to Claim 8, wherein said second rotational force receiving member meshes with said another second rotational force receiving member.
  10. 10. A process cartridge according to Claim 1, wherein said first coupling members has a first recess and said second coupling members has a second recess, wherein said first recess is urged by a free end of thefirst main assembly engaging portion when said first coupling member receives said first rotational force from the first main assembly engaging portion, wherein said second recess is urged by a free end of the second main assembly engaging portion when said second coupling member receives said second rotational force from the second main assembly engaging portion.
  11. 11. A process cartridge according Claim 10, wherein the first recess is provided with a first expanding portion which expands away from said first coupling axis as the distance from said electrophotographic photosensitive drum along said first coupling axis increases, wherein said first expanding portion is urged to the free end of the first driving shaft, wherein the second recess is provided with an second expanding portion which expands away from said second coupling axis as the distance from said developing roller along said second coupling axis increases, wherein said second expanding portion is urged to the free end of the second driving shaft.
  12. 12. A process cartridge according to Claim 2, wherein said first coupling member inclines in a direction opposite to the dismounting direction by receiving a force from the first main assembly engaging portion as said cartridge is dismounted from the main assembly of the apparatus, wherein said second coupling member inclines in a direction opposite to the dismounting direction by receiving a force from the second main assembly engaging portion as said cartridge is dismounted from the main assembly of the apparatus.
  13. 13. A process cartridge according to Claim 1, further comprising a first urging member for urging said first coupling member in a direction opposite the dismounting direction, and a second urging member for urging said second coupling member in the direction opposite the dismounting direction.
  14. 14. A process cartridge according to Claim 13, wherein said first and second urging members include first and second elastic members, respectively.
  15. 15. A process cartridge according to Claim 14, wherein said first and second elastic members include first and second springs, respectively.
  16. 16. A process cartridge according to Claim 1, further comprising a casing that includes a first projection disposed in proximity to said first coupling member.
  17. 17. A process cartridge according to Claim 16, wherein said first projection has a positioning force receiving portion to receive a force from the main assembly to position said cartridge with respect to the main assembly.
  18. 18. A process cartridge according to Claim 16, wherein said first projection has a guide portion capable of guiding said first coupling member in a direction opposite to the dismounting direction.
  19. 19. A process cartridge according to any one of Claims 1-18, wherein said first coupling member is inclineable relative to said drum axis such that an angle between said first coupling axis and said drum axis is 20 - 60.
  20. 20. A process cartridge according to any one of Claims 1-18, wherein said second coupling member is inclineable relative to said roller axis such that an angle between said second coupling axis and said roller axis is 20 - 60.
  21. 21. A process cartridge according to any one of Claims 1 - 18, wherein said second coupling member is offset from said first coupling member with respect to a direction perpendicular to the dismounting direction.
  22. 22. A process cartridge according to any one of Claims 1-18, wherein said second coupling member is positioned downstream of said first coupling member with respect to the dismounting direction.
  23. 23. A process cartridge according to any one of Claims 1 - 18, wherein an angle between said first coupling axis and said drum axis is substantially the same as an angle between said second coupling axis and said roller axis when said first coupling member is disengaged from the first main assembly engaging portion and said second coupling member is disengaged from the second main assembly engaging portion.
    Canon Kabushiki Kaisha Patent Attorneys for the Applicant SPRUSON&FERGUSON
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    13619521 (IRN: 973200D3)
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    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
    13619521 (IRN: 973200D3)
AU2020202771A 2008-06-10 2020-04-27 Cartridge, and electrophotographic image forming apparatus which uses cartridge Active AU2020202771B2 (en)

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AU2020202771A AU2020202771B2 (en) 2008-06-10 2020-04-27 Cartridge, and electrophotographic image forming apparatus which uses cartridge
AU2021229186A AU2021229186B2 (en) 2008-06-10 2021-09-08 Cartridge, and electrophotographic image forming apparatus which uses cartridge
AU2024200278A AU2024200278A1 (en) 2008-06-10 2024-01-16 Cartridge, and electrophotographic image forming apparatus which uses cartridge

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JP2008-151824 2008-06-10
AU2009258530A AU2009258530A1 (en) 2008-06-10 2009-06-09 Cartri dge, and electrophotographic image forming apparatus which uses cartridge
AU2013200114A AU2013200114A1 (en) 2008-06-10 2013-01-10 Cartridge, and electrophotgraphic image forming apparatus which uses cartridge
AU2015203439A AU2015203439B2 (en) 2008-06-10 2015-06-22 Cartridge, and electrophotgraphic image forming apparatus which uses cartridge
AU2017228653A AU2017228653B2 (en) 2008-06-10 2017-09-14 Cartridge, and electrophotographic image forming apparatus which uses cartridge
AU2019200918A AU2019200918B2 (en) 2008-06-10 2019-02-08 Cartridge, and electrophotographic image forming apparatus which uses cartridge
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AU2019200918A Active AU2019200918B2 (en) 2008-06-10 2019-02-08 Cartridge, and electrophotographic image forming apparatus which uses cartridge
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Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US6240266B1 (en) * 1996-03-21 2001-05-29 Canon Kabushiki Kaisha Process cartridge and drum mount for photosensitive drum
US6285847B1 (en) * 1999-01-20 2001-09-04 Matsushita Electric Industrial Co., Ltd. Printer
US20070122188A1 (en) * 2005-11-25 2007-05-31 Brother Kogyo Kabushiki Kaisha Developer cartridge and image forming apparatus

Family Cites Families (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP4498407B2 (en) * 2006-12-22 2010-07-07 キヤノン株式会社 Process cartridge, electrophotographic image forming apparatus, and electrophotographic photosensitive drum unit

Patent Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US6240266B1 (en) * 1996-03-21 2001-05-29 Canon Kabushiki Kaisha Process cartridge and drum mount for photosensitive drum
US6285847B1 (en) * 1999-01-20 2001-09-04 Matsushita Electric Industrial Co., Ltd. Printer
US20070122188A1 (en) * 2005-11-25 2007-05-31 Brother Kogyo Kabushiki Kaisha Developer cartridge and image forming apparatus

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AU2017228653A1 (en) 2017-10-05
AU2019200918B2 (en) 2020-02-06
AU2015203439A1 (en) 2015-07-16
AU2015203439B2 (en) 2017-06-15
AU2021229186B2 (en) 2023-10-19
AU2017228653B2 (en) 2018-11-08
AU2019200918A1 (en) 2019-02-28
AU2020202771A1 (en) 2020-05-14

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