The present invention relates to a drive transmission mechanism for transmitting a rotational force from a driving device to a driven side, the drive transmission mechanism being suitable for use in a drive transmission coupling the driving force from a main assembly side of the apparatus to a cartridge of cartridge type image forming apparatus, for example. In addition, the present invention relates to an image forming apparatus provided with such a drive transmission mechanism.
Japanese Laid-open Patent Application 2010-262056 discloses the following structure as a coupling structure of a drive transmitting portion for drive transmission from the main assembly side of the image forming apparatus to the process cartridge. By opening and closing operations of a main assembly cover provided on a main assembly A, a coupling member of the main assembly side of the apparatus is retracted in the rotational axis direction.
The present invention provides a further improvement to such a prior-art. It is another object of the present invention to provide a drive transmission mechanism having easy assembling property and an image forming apparatus provided with the same.
According to an aspect of the present invention, there is provided a drive transmission mechanism comprising a driving side coupling member for transmitting a rotational force; a holder member for holding said driving side coupling member; said driving side coupling member being provided with a first engaging portion; said holder member being provided with a second engaging portion which is capable of engaging with said first engaging portion when said driving side coupling member is in a first rotation angular position relative to said holder member; said driving side coupling member being further provided with a first operating portion; and said holder member being further provided with a second operating portion for rotating said driving side coupling member when contacting to said first operating portion, and said driving side coupling member being movable along a rotational axial direction thereof between (1) a projected position projected from said holder member, (2) a retracted position retracted toward said holder member and (3) a middle position between the projected position and the retracted position, wherein when said first engaging portion and said second engaging portion are engaged with each other, said driving side coupling member is held in the middle position to be prevented from moving from the middle position to the projected position, wherein when said driving side coupling member is moved from the middle position toward the retracted position, the first operating portion and the second operating portion contact to each other so that said driving side coupling member rotates relative to said holder member to a second rotation angular position where said first engaging portion and said second engaging portion are disengaged from each other, and wherein by said driving side coupling member rotating from the first rotation angular position to the second rotation angular position, said driving side coupling member is enabled to move to the projected position.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
(General Arrangement of Image Forming Apparatus)
In the following description, a front side of the image forming apparatus (main assembly A) is a side provided with an apparatus door (openable member) 31 as a main assembly cover. The rear side is an opposite side. The front and rear directions are the direction from the rear side toward the front side of the main assembly A (frontward direction), and a direction opposite therefrom (backward direction). Left and right are left-hand and right-hand, respectively when the apparatus is seen from the front side. Left-right directions are the directions from the right side toward the left side (leftward direction), and the direction opposite therefrom (rightward direction).
Referring to
Each cartridge P in this embodiment is a so-called integral type process cartridge. More particularly, each of the cartridges comprises an electrophotographic photosensitive drum as a first image bearing member, and process means actable on the drum 1 (charger 2, developing device 3 and a cleaning device 4), which are provided integrally in a cartridge frame 5. The charger 2 is a contact type charging roller in this embodiment. The developing device 3 includes a developing roller (developing member) 3a, and the developer (toner) is accommodated in the developer container. The cleaning device 4 is a blade equation device in this embodiment.
The first cartridge PY includes the developing device 3 containing yellow (Y) toner to form a yellow (Y) chromatic toner image on the drum 1. The second cartridge PM includes the developing device 3 containing magenta (M) to form a magenta (M) chromatic toner image on the surface of the drum 1. The third cartridge PC includes the developing device 3 containing cyan (C) chromatic toner to form a cyan (C) toner image on the drum 1. The fourth cartridge PK includes the developing device 3 containing black (K) toner to form a black (K) chromatic toner image on the drum 1.
Above the cartridges PY, PM, PC, PK, there is provided a laser scanner unit 11. The scanner unit 11 produces a laser beam L modulated in accordance with image information of each color supplied from an external host apparatus and scanningly projects the laser beam onto the surface of the drum 1 of the cartridge P through the exposure window 6 provided on the top side of the cartridge frame 5.
Below the cartridges PY, PM, PC, PK, there is provided an intermediary transfer belt unit 12. The belt unit 12 functions as an intermediary transfer member (second image bearing member) and includes an endless flexible intermediary transfer belt 13 made of dielectric member, and a driving roller 14, a tension roller 15 and a turning roller 16 which stretch and rotate the belt 13. The driving roller 14 and the turning roller 16 are disposed in a rear side of the main assembly A. The tension roller 15 is disposed in the front side of the main assembly.
Lower surfaces of the drums 1 of the cartridges P are in contact with an upper traveling side of the belt 13. Inside the belt 13, there are provided four primary transfer rollers 17 opposed to the drums 1 of the respective cartridges P through the upper traveling side of the belt. To the driving roller 14, a secondary transfer roller 22 is urged with the belt 13 sandwiched therebetween.
Below the belt unit 12, a sheet feeding unit 18 is provided. The sheet feeding unit 18 comprises a sheet feeding tray 19, a sheet feeding roller 80, a feeding roller 20 and a separation roller 21. The sheet feeding tray 19 is loadable from the front side of the main assembly (front loading).
In an upper portion of the rear side in the main assembly, there are provided a fixing device 23 and a pair of sheet discharging rollers 24. The top surface of the main assembly functions as a sheet discharge tray 25. The fixing device 23 includes a fixing film assembly 23a and a pressing roller 23b. The pair of sheet discharging rollers 24 comprises a sheet discharge roller 24a and a sheet discharging roller 24b.
Each cartridge P mounted to the mounting position in the main assembly is fixed at the predetermined position. A drive inputting portion of the cartridge P which will be described hereinafter is coupled with a drive outputting portion of the main assembly which will be described hereinafter. By this arrangement, a driving force (rotational force) can be transmitted from a driving device (unshown) of the main assembly to each cartridge P. The cartridge P is provided with an electrical contact (unshown) which is connected with an electric energy supply line (unshown) of the main assembly. By this, predetermined bias voltages such as a charging bias voltage or developing bias voltage can be applied to each cartridge P from the voltage source device (unshown) of the main assembly.
The operation for forming a full-color image is as follows. The drums 1 of the first-fourth cartridges PY, PM, PC, PK are rotated at the predetermined control timing in the counterclockwise direction indicated by the arrow at a predetermined control speed. In addition, the developing rollers 3a and so on of the cartridges P are also rotated. The belt 13 is rotated in the clockwise direction indicated by the arrow at a predetermined speed corresponding to the speed of the drum 1. Also, the scanner unit 11 is driven.
In synchronism with the driving, the charging rollers 2 charge the surfaces of the drums 1 of the cartridges P at the respective predetermined control timings. The scanner unit 11 scans the surfaces of the drums 1 with the laser beams L modulated in accordance with respective color image signals. By doing so, electrostatic latent images are formed on the surfaces of the respective drums 1 in accordance with the respective color image signals. The electrostatic latent images thus formed are developed into toner images by the respective developing devices 3.
By the above-described electrophotographic image forming process operations, a Y color toner image corresponding to a yellow component of the full-color image is formed on the drum 1 of the first cartridge PY, and the toner image is primary-transferred onto the belt 13.
An M color toner image corresponding to a magenta component of the full-color image is formed on the drum 1 of the second cartridge PM, and the toner image is primary-transferred onto the belt 13 superimposedly on the Y color toner image.
A C color toner image corresponding to a cyan component of the full-color image is formed on the drum 1 of the third cartridge PC, and the toner image is primary-transferred onto the belt 13 superimposedly on the Y+M color toner image.
A K color toner image corresponding to a black component of the full-color image is formed on the drum 1 of the fourth cartridge PK, and the toner image is primary-transferred onto the belt 13 superimposedly on the Y+M+C color toner image.
In this manner, unfixed four full-color toner image (Y+M+C+K) is formed synthetically on the belt 13. In each of the cartridges P, untransferred toner remaining on the surface of the drum 1 after the primary-image transfer of the toner image onto the belt 13 is removed by the cleaning device 4.
On the other hand, the sheet feeding rollers 80 are operated at a predetermined control timing. By this, a sheet S (recording material) of the sheets S stacked on the sheet feeding tray 19 is separated and fed out to a nip (secondary transfer nip) between the secondary transfer roller 22 and in the belt 13 by the feeding roller 20, the separation roller 21 and pairs 81a, 81b of the feeding rollers. And, the sheet S is nipped and fed by the nip, during which four color superimposing toner image is sequentially transferred onto a surface of the sheet S from the belt 13.
The sheet S is separated from the surface of the belt 13 and is introduced into the fixing device 23, and is pressed and heated by a fixing nip. In this manner, the color mixture of the toner images and the fixing thereof on the sheet are effected. Then, the sheet S is discharged from the fixing device 23 onto the sheet discharge tray 25 by the sheet discharging roller pair 24 as a full-color print. Secondary-untransferred toner remaining on the surface of the belt 13 after the separation of the sheet therefrom are electrostatically attracted onto the surface of the drum 1 at the primary transfer portion of the first process cartridge PY, for example, in this embodiment, and is removed by the cleaning device 4.
(Cartridge Exchanging Type)
In the image forming apparatus 100 of this embodiment, the four cartridges PY, PM, PC, PK are carried on a drawer type tray 35 and can be changed at the front side of the apparatus (front access), for improvement of usability. The exchanging type is known, and therefore, will be described briefly.
As shown in
The door 31 is movable between a closed state for closing the opening 30 and an opened state for opening the opening 30. The opening is provided for the purpose of permitting demounting and dismounting of the cartridge P, exchange of the intermediary transfer belt unit 12, jam paper clearance operation and so on.
By the operation of the interrelating mechanism (unshown) in interrelation with a moving operation of the door 31 from the closing position to the opening position, the coupling between the drive outputting portions of the main assembly and the drive inputting portions of the cartridges P is broken. In addition, the electrical conduction between the electric energy supply line of the main assembly and the electrical contacts of the cartridges P is disconnected. Furthermore, the positioning urging of the cartridges P to the main assembly is released.
Then, a tray grip portion 35a in the opening 30 is gripped, and the tray 35 is drawn out to the front side. By gripping the grip portion 35a, the locking of the tray 35 relative to the main assembly A is released, and the tray 35 is drawn out through the opening 30. The tray 35 is supported substantially horizontally by a guiding member (unshown) extending in the front-rear direction in the main assembly so as to be movable between the inside and outside of the main assembly.
When the tray 35 is drawn out sufficiently to a predetermined extent, a further drawing in the outward direction is prevented by a stopper member (unshown). In the state, all of the cartridges PY, PM, PC, PK supported and arranged along the moving direction of the tray 35 are exposed outside (
After the completion of the replacement, the tray 35 is inserted back into the main assembly (from the state of
By the operation of the interrelating mechanism (unshown) interrelated with the moving operation of the door 31 from the opening position to the closing position, the cartridge P is urged and positioned to the main assembly. In addition, the connection between the drive outputting portions of the main assembly and the drive inputting portions of the cartridges P is established. In addition and the electrical conduction between the electric energy supply line of the main assembly and in the electrical contact of the cartridges P is established. By doing so, the image forming apparatus 100 is reset into the state capable of the image forming operation.
(Drive Transmission Mechanism)
At the driven sides of the cartridges P mounted and positioned in the mounting position in the main assembly, driving forces (rotational forces) of the motor (driving device) of the main assembly can be transmitted through the drive transmission mechanism to the drums 1 and the developing rollers 3a, respectively.
As will be described hereinafter, a driving side of the coupling (drive inputting portion) is provided in the cartridge P. On the other hand, a driving unit (drive outputting portion), of the drive transmission mechanism, which includes a driving side of the coupling capable of engaging with and disengaging from the driven side of the coupling is provided in the main assembly of the apparatus.
In addition, as to the driving roller 14 for rotating the intermediary transfer belt 13, a driving force is transmitted from the motor of the main assembly A to a driving roller driven side coupling provided at one end portion side of the driving roller 14 through a reduction gear train (unshown). The belt 13 is contacted with the surface of the drum 1, and during the image forming operation, the surface of the drum 1 and the surface of the belt 13 move in the same direction substantially at the same speed at the contact portion therebetween.
Here, in the image forming apparatus (main assembly) 100 of this embodiment, the longitudinal direction is the direction substantially parallel with the rotational axis directions of the rotatable members such as the rotatable image bearing member or the rotatable developer carrying member. A widthwise direction is a direction substantially perpendicular to the longitudinal direction. One end portion side in the longitudinal direction is the driving side, and the other end portion side is the non-driving side. In this embodiment, the right-hand end side with respect to the longitudinal direction is the driving side and the left-hand end side is the non-driving side.
As shown in
On the other hand, as shown in
In
The development driving unit 40 is provided with developing drive side coupling 43 as the driving side coupling member. The developing drive side coupling 43 has a recess 43b having a triangular shape cross-section, and a free end portion. The recess 43b is also twisted about the axis.
As will be described hereinafter, the developing drive side coupling 43 advances and retracts in the rotational axis direction in interrelation with the opening and closing operation of the opening and closing door 31. More particularly, when the door 31 is in the closed state, the developing drive side coupling 43 is in the advanced position in which it is projected from a coupling gear 44 of the development driving unit 40 toward the cartridge P, as shown in
In this state, the developing drive side coupling 43 is coupled with the development driven side coupling 45 of the cartridge P situated and positioned in the mounting position of the main assembly, more particularly, the projection 45a and the recess 43b are engaged with each other.
And, by the developing drive side coupling 43 being driven, the development driven side coupling 45 receives the driving force (rotational force) through the engagement between the projection 45a and the recess 43b, and in addition a force is produced in the direction of attracting each other. To the developing roller 3a, the driving force is transmitted from the development driven side coupling 45 through the gear train in the cartridge P.
When the door 31 is in the opened state, the developing drive side coupling 43 is in the retracted position toward the inside of the development driving unit 40 (coupling gear 44), as shown in
The operations of the drum driving unit (50) of the main assembly relative to the drum driven coupling 55 of the cartridge P are similar to those of the development driving unit 40.
As regards the projection and the recess, the driving side coupling may be provided with a projection having a triangular shape section, and such a case, the driven side coupling is provided with a recess having a triangular shape section. The triangular configuration is not inevitable in the present invention, and it may be rectangular configuration, and a combination of parallel pins and grooves, a D-cut configuration keyway is usable.
(Detail Structure of the Development Driving Unit)
The rotation from the motor (M) is used by a deceleration gear train (G), and is transmitted to the coupling gear 44 provided on the driving shaft 42 on the drive plate 41, so that the coupling gear 44 is rotated about the driving shaft 42. Then, the drive (rotational force) is transmitted from a surface (second transmitting portion, claw portion) 44a of the coupling gear 44 to a surface (first transmitting portion, claw portion) 43a of the developing drive side coupling 43. The developing drive side coupling 43 (drive coupling member) and the coupling gear 44 (holder member) are provided with claw portions 43a, 44a which are engaged with each other within a predetermined rotational angle range.
At this time, in this embodiment, the driving force is transmitted to each of three positions (three first transmitting portions 43a and three second transmitting portions 44a), but the number is not limiting to the present invention. The holder supporting the developing drive side coupling 43 may not be a gear, but a belt-drive or direct-drive structure is usable.
As shown in
More particularly, in the closed state of the door 31, the developing drive side coupling 43 is urged in the direction indicated by an arrow A (toward the developing drive side coupling 43 projected position) by the spring 47 provided between the coupling gear 44 and itself, as shown in part (a) and part (b) of
As shown in part (a) and part (b) of
By a second surface 49b of the second spacing member 49 urging a flange portion 43c of the developing drive side coupling 43, the developing drive side coupling 43 moves in the direction indicated by an arrow B (against the urging force of the spring 47), as shown in part (b) of
That is, in the rotation axial direction, the projected position (first position) 43A is where the developing drive side coupling 43 is engaged with the development driven side coupling 45 and the retracted position (second position) 43B is where it is retracted from the development driven side coupling 45. The contact spacing mechanism comprising the spacing members 48, 49 and the spring 47 translates the developing drive side coupling 43 between the projected position (first position) 43A and the retracted position (second position) 43B. The translating motion by the contact spacing mechanism (moving mechanism) is effected in interrelation with the opening and closing operation of the door 31 of the main assembly provided with the drive transmission mechanism.
When the cartridge not inserted, no coupling engagement exists, and therefore, the position of the driving shaft 42 of the developing drive side coupling 43 in the axial direction is such that it is abutted to the main assembly frame through the spacing members 48, 49 by the force of the spring 47.
In the developing drive side coupling 43 and the coupling gear 44 are rotatably engaged with the driving shaft 42. The developing drive side coupling 43 is movable in the axial direction of the driving shaft 42, and the rotation of the coupling gear 44 can be transmitted to the developing drive side coupling 43 through the drive transmitting portions 43a, 44a.
The structures of the drum driving unit (50) of the main assembly and the structures of the contact spacing mechanism relative to the drum driven side coupling 55 of the cartridge P are similar to those of the development driving unit 40. The drive transmission mechanism and the contact spacing mechanism of the development coupling and the photosensitive drum are mountable to the main assembly as one driving unit or assembly.
(Temporary Holding and Releasing Structure)
In the free state of the assembly of the driving unit 40, the spacing members 48, 49 do not abut the main assembly frame, and therefore, the developing drive side coupling 43 is projected by the spring 47. When the driving unit 40 is mounted to the main assembly of the apparatus, the projected developing drive side coupling 43 may hit a part of the main assembly of the apparatus with the result of reduction of the assembling property. If a cover or the like is additionally provided to prevent the projection of the developing drive side coupling 43, it will result in the increase in cost or upsizing of the main assembly of the apparatus.
In view of this, in this embodiment, as shown in
First, during the assembling of the driving unit 40, the temporary holding claw (first engaging portion) 43d and the claw receiving surface (second engaging portion) 44b are engaged with each other at a predetermined rotation angular position (first rotation angular position).
Then, the driving unit 40 is mounted to the main assembly 100 of the apparatus while the door 31 is kept open, and thereafter, the door 31 is closed. By doing so, the developing drive side coupling 43 moves to the retracted position (movement in the direction of an arrow D (part (b) of
Once they are disengaged, the developing drive side coupling 43 is movable only in the axial direction in the normal operations, and therefore, the temporary holding state does not occur even when the contacting and spacing operations are repeated (parts (c) and (d)). More particularly, when the developing drive side coupling 43 rotates to the second rotation angular position, the developing drive side coupling 43 is enabled to move to a projected position 43A by the contact spacing mechanism (spacing members 48, 49).
The temporary holding and release structures of the developing drive side coupling 43 which is the drive coupling member are summarized as follows.
The developing drive side coupling 43 and the coupling gear 44 as the holder member are provided with the temporary holding claw 43d and the claw receiving surface 44b as the first engaging portion and the second engaging portion, respectively, which are engaged with each other at the predetermined first rotational angular position. In addition, the developing drive side coupling 43 and the coupling gear 44 are provided with the cam receiving surface 43e and the cam surface 44c as the first operating portion and the second operating portion, respectively, which are actable on each other. The cam surface 44c is an inclined portion which is inclined relative to the rotational axis of the developing drive side coupling 43, and the cam receiving surface 43e slides on the cam surface 44c. When the temporary holding claw 43d and the claw receiving surface 44b are engaged with each other, the development drive side coupling 43 is held at the middle position (third position) 43c wherein it is engaged with the developing driven side coupling 45. This is the temporary holding state of the developing drive side coupling 43. Here, the middle position is a position between the projected position 43A and the retracted position 43B with respect to the rotational axis direction.
In the retracting operation of the developing drive side coupling 43 by the spacing members 48, 49, the developing drive side coupling 43 moves toward the coupling gear 44 so that the cam receiving surface 43e and the cam surface 44c are engaged to each other. And, the cam receiving surface 43e slides on the cam surface 44c. By this, the developing drive side coupling 43 rotates relative to the coupling gear 44 to such a position that the temporary holding claw 43d and the claw receiving surface 44b are not overlapped with each other. This state (the developing drive side coupling 43 has been moved to the second rotation angular position) is the temporary holding released state of the developing drive side coupling 43. In the temporary holding released state, the developing drive side coupling 43 is capable of moving to the projected position 43A.
The opening and closing operation of the door 31 is necessarily carried out during the assembling operation, for the purpose of insertion of the cartridge P into the main assembly 100 of the apparatus, for example, and therefore, it is unnecessary to manually release the developing drive side coupling 43. Therefore, there arises no such a trouble that the temporary holding releasing is inadvertently not carried out with the result of image defect.
The drive, the coupling member temporary holding and the release structures with the drum driving unit (50) of the main assembly relative to the drum driven side coupling 55 of the cartridge P are the same as with the development driving unit 40.
As described in the foregoing, according to the structures of the embodiments of the present invention, there are provided a coupling structure for the drive transmitting portion and an image forming apparatus having the same, with which the assembling property can be improved without additional cost increase.
[Others]
(a) the drive transmission mechanism according to the present invention is usable with the intermediary transfer belt unit 12 and the other drive transmission mechanism for various units and devices with the same advantageous effects.
(b) the cartridge P is not limited to a process cartridge of the above-described embodiment, which comprises an image bearing member on which a latent image is formed and a developing means for developing the latent image with a developer, as a unit.
The cartridge P may be a separable type process cartridge comprising a image bearing member on which a latent image is formed and an image forming process means other than such a developing means.
The cartridge P may be a developing cartridge comprising a developing means for developing a latent image formed on an image bearing member and a developer accommodating portion for accommodating a developer to be used for developing the latent image.
In such a case, the cartridge supported on the tray 35 is a pair of the separable type process cartridge and the developing cartridge (combination). Alternatively, at least one of the process cartridge and the developing cartridge may be supported dismountably relative to the tray 35.
The cartridge includes a unit which is contributable to the image forming process for forming a image on a recording material and which is detachably mountable to the main assembly of the apparatus.
(c) in the foregoing embodiments, the full-color electrophotographic image forming apparatus is taken as an exemplary example, to which four cartridges containing different color developers are detachably mountable. However, the number of the cartridges mountable to the apparatus is not limited to this, and the number may be properly selected by one skilled in the art. For example, the number may be one, two, three or not less than five. The present invention is applicable to a monochromatic image forming apparatus using only one cartridge.
(d) in the foregoing embodiments, the tray 35 is movable linearly in the horizontal direction. However, the tray (cartridge supporting member) 35 is not limited to such an example. For example, the tray 35 may be moved in a linear direction inclined from the horizontal direction and crossing with the studio direction of the drum, and the inclination may be ascending or descending. The tray 35 may be such that it can be dismounted from the main assembly of the apparatus by releasing from a stopper.
(e) in the image forming apparatus 100 of the foregoing embodiments, the intermediary transfer unit 12 may be replaced with a recording material feeding transfer belt device which carries the sheet S. More particularly, in such a case, the recording material feeding transfer belt device (recording material feeding transferring means) includes a recording material feeding member for feeding the sheet S to cause the sheet S to directly receive the developed image from the drum.
(f) the image forming apparatus is not limited to the printer as described in the foregoing. For example, it may be a copying machine, a facsimile machine or another image forming apparatus, or a multifunction machine or the like having the functions of such machines.
(g) the image forming process of the image forming apparatus is not limited to the electrophotographic process. For example, it may be an electrostatic recording process using a dielectric member for electrostatic recording as the image bearing member, a magnetic recording process using a magnetic member for magnetic recording as the image bearing member.
According to the foregoing embodiments, the driving side coupling member and the holder member are provided with respective claw portions (temporary holding mechanism) which are engageable with each other at the predetermined rotation angular position, and therefore, the pop out of the coupling member is prevented so that the assembling property is improved without significant increase in cost.
In the retracting operation by the contact spacing mechanism, the temporary holding state of the claw portions (temporary holding mechanism) is released.
While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
This application claims priority from Japanese Patent Application No. 255915/2013 filed Dec. 11, 2013, which is hereby incorporated by reference.
Number | Date | Country | Kind |
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2013-255915 | Dec 2013 | JP | national |
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Number | Date | Country |
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2010-262056 | Nov 2010 | JP |
Number | Date | Country | |
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20150160608 A1 | Jun 2015 | US |