The present invention relates to a photosensitive drum unit, an assembling method for the photosensitive drum unit, and a disassembling method for the photosensitive drum unit.
Conventionally, in an electrophotographic image forming apparatus using an electrophotographic image forming process, a photosensitive drum and process means actable on the drum is unified into a cartridge. The cartridge is detachably mountable to a main assembly of the electrophotographic image forming apparatus (process cartridge type). According to the process cartridge type, a maintenance operation for the image forming apparatus can be carried out by the user without relying on a service person, and therefore, an operationality of the maintenance operation can be improved remarkably.
A method is known in which a coupling member is provided at an end portion of the drum to rotation the drum, and a driving force is inputted to the coupling member from the main assembly of the apparatus. With such a structure, it is known that the coupling member is movable relative to the drum so that even if a positional relation between the cartridge and the main assembly of the apparatus is deviated, the drive can be transmitted to the drum with high accuracy (Japanese Laid-open Patent Application 2008-233867).
The present invention provides a further development of the above-described prior-art.
It is an object of the present invention to provide a photosensitive drum unit in which the coupling member can be easily mounted.
It is an object of the present invention to provide a photosensitive drum unit in which the coupling member can be easily dismounted.
It is an object of the present invention to provide a photosensitive drum unit disassembling method in which the coupling member can be easily mounted.
It is an object of the present invention to provide a photosensitive drum unit disassembling method in which the coupling member can be easily dismounted.
It is an object of the present invention to provide a photosensitive drum unit to which a coupling member is mountable, the coupling member including a rotational force receiving portion for receiving a rotational force at one end portion side thereof and a spherical portion at another end portion side, and including a projected portion projected from the spherical portion, said photosensitive drum unit comprising a cylinder provided with a photosensitive portion at a peripheral surface thereof; a drum flange provided at one end portion of said cylinder and including a hole portion which opens outwardly in a longitudinal direction of said cylinder and which has a opening capable of accommodating said spherical portion, a plurality of groove portions which continue from said hole portion and which is capable of accommodating said projected portion, and a regulating portion for limiting inward movement of said spherical portion in the longitudinal direction of said cylinder; and a closing member capable of partially covering said opening of said hole portion and mounted to said drum flange to limit outward movement of said spherical portion in the longitudinal direction of said cylinder.
It is another object of the present invention to provide an assembling method for a photosensitive drum unit, said assembling method comprising i) a drum flange mounting step of mounting a drum flange to one end portion of a cylinder having a photosensitive portion at a peripheral surface thereof, said drum flange including a hole portion having an opening which opens outwardly in the longitudinal direction of said cylinder, and a plurality of groove portions continuing from said hole portion; ii) a coupling member mounting step of mounting said coupling member, said coupling member including a rotational force receiving portion for receiving a rotational force at one end portion side thereof and a spherical portion at another end portion side, and including a projected portion projected from the spherical portion, and said coupling member mounting step inserting said spherical portion into said hole portion through said opening and inserting said projected portion into said groove portion; and iii) a closing member mounting step of mounting a closing member for partially covering said opening of said hole portion to said drum flange.
It is a further object of the present invention to provide a photosensitive drum unit disassembling method for disassembling a photosensitive drum unit, said photosensitive drum unit including a coupling member for receiving a rotational force for rotating a photosensitive drum having a cylinder provided with a photosensitive portion at a peripheral surface thereof, said coupling member including a rotational force receiving portion for receiving a rotational force at one end portion side thereof and a spherical portion at another end portion side, and including a projected portion projected from the spherical portion, said photosensitive drum, a drum flange provided at one end portion of said cylinder and including a hole portion which opens outwardly in a longitudinal direction of said cylinder and which has a opening capable of accommodating said spherical portion, a plurality of groove portions which continue from said hole portion and which is capable of accommodating said projected portion, and a closing member covering said opening of said hole portion and mounted to said drum flange to limit outward movement of said spherical portion in the longitudinal direction of said cylinder, said disassembling method being for removing said coupling member from said photosensitive drum unit and comprising i) a closing member dismounting step of dismounting said closing member from said drum flange; and ii) a coupling member dismounting step of dismounting said coupling member from said drum flange.
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Referring to the drawings, the preferred embodiments of the invention will be described.
(General Arrangement)
Part (a) of
The image forming apparatus is a laser beam printer using an electrophotographic technique in which the cartridge 2 is detachably mountable to the main assembly 1 of the apparatus. An exposure device (laser scanner unit) 3 is provided at a position above the cartridge 2 when the cartridge 2 is mounted to the main assembly 1 of the apparatus. A sheet tray 4 accommodating recording materials (sheet materials) P on which images are to be formed, is provided at a position below the cartridge 2.
Furthermore, the main assembly 1 of the apparatus includes a pick-up roller 5a, a feeding roller 5b, a pair of feeding rollers 5c, a transfer guide 6, a transfer roller 7, a feeding guide 8, a fixing device 9, a pair of discharging rollers 10, a discharge tray 11 and so on, which are provided in the order named along a feeding direction of the sheet material P.
(Image Forming Process)
An image forming process will be described. In response to printing instructions of the main assembly 1 of the apparatus, the electrophotographic photosensitive drum (drum) 20 is rotated in a direction of an arrow R1 at a predetermined peripheral speed (process speed). The drum 20 includes a cylinder 20A on which a photosensitive layer (photosensitive portion) is provided. To an outer surface of the drum 20, a charging roller 12 supplied with a bias voltage is contacted so that the outer surface of the drum 20 is charged uniformly by the roller 12.
From the exposure device 3, a laser beam L modulated corresponding to a time series electrical digital pixel signal of the image information is outputted. The laser beam L enters the cartridge 2 through an exposure window 53 provided in an upper surface of the cartridge 2 to scanningly expose the outer surface of the drum 20. By this, an electrostatic latent image corresponding to the image information is formed on the outer surface of the drum 20. The electrostatic latent image is visualized by a developer T (toner) in a developing device unit 40 into a toner image.
More particularly, the roller 12 is contacted to the drum 20 to charge the drum 20. The roller 12 is driven by the drum 20 to rotate. The unit 40 supplies the toner to a developing zone of the drum 20 to develop the latent image formed on the drum 20. The unit 40 delivers the toner T from the toner chamber 45 into a toner supply chamber 44 by rotation of the stirring member 43. A developing roller 41 which is a developer carrying member containing a magnet roller (fixed magnet) 41a is rotated, and a layer of toner triboelectric charged by a developing blade 42 is formed a surface of the roller 41.
The toner is transferred onto the drum 20 in accordance with the latent image so that a toner image is formed to visualize the latent image. The blade 42 functions to regulate an amount of the toner on the peripheral surface of the roller 41 and to apply the triboelectric charge to the toner. On the other hand, in timed relation with output of the laser beam L, the sheet material P is fed from the tray 4 below the main assembly 1 of the apparatus by the roller 5a, the roller 5b and the roller pair 5c. The sheet material P is supplied via a guide 6 to a transfer position between the drum 20 and a roller 7 in timed relation.
In the transfer position, the toner image is transferred sequentially onto the sheet material P from the drum 20. The sheet material P having the transferred toner image is separated from the drum 20 and is fed to a device 9 along a guide 8. The sheet material P passes through a nip between a fixing roller 9a and a pressing roller 9b which constitutes a device 9. The toner image is subjected to a pressing and heat-fixing process and is fixed on the sheet material P.
The sheet material P having subjected to the toner image fixing process is fed to the roller pair 10, and is discharged to the tray 11. On the other hand, after the transfer, residual toner on the outer surface of the drum 20 is removed by a blade 52 to be prepared for the next image formation starting with the charging. The residual toner removed from the drum 20 is stored in a residual toner chamber 52a of a cleaning unit (photosensitive member unit) 50.
In the foregoing, the roller 12, the roller 41, the blade 52 and so on constitutes process means actable on the drum 20.
(Process Cartridge)
Part (a) of
On the other hand, the unit 40 comprises a toner chamber 45 for accommodating the toner and a toner accommodating container 40a having a toner supply chamber 44, and a lid 40b. The container 40a and the lid 40b are connected integrally by means of welding or the like. As shown in part (a) of
When the arm portion 55a is inserted into the frame 51 to a predetermined position, it enters a fitting hole 51a provided in a frame 51 coaxially with the rotation hole 55b (left side fitting hole is not shown in part (a) of
At this time, a compression coil spring 46 mounted to the base portion of the arm portion 55a abuts to the frame 51 to urge the unit 40 downwardly. By this, the roller 41 (part (b) of
(Rotational Force Transmission Method to Process Cartridge)
Part (b) of
At this time, in interrelation with the mounting operation of the cartridge 2, a coupling member 200 (part (a) of
(Driving Shaft)
Part (a) of
(Coupling Member)
Part (b) of
Opposite ends of the pin 155 project out of the spherical portion 160, thus providing projected portions 155a, 155b. In this embodiment, the coupling member 200 is constituted by the rotational force receiving member 150 having the rotational force receiving portion 150e, the spherical portion 160 and the pin 155, which are integral with each other. The material of the rotational force receiving member 150 is resin material such as polyacetal, polycarbonate or PPS, for example.
In order to enhance a rigid of the rotational force receiving member 150, glass fibers carbon fibers may be mixed in the resin material depending on the load torque. With the use of the material thus mixed, the rigid of the rotational force receiving member 150 can be enhanced. In addition, the rigid can be further enhanced by inserting a metal member into the resin material, or the entirety of the rotational force receiving member 150 can be made of metal or the like. The spherical portion 160 is made of a resin material such as polyacetal, polycarbonate, PPS, for example. In this embodiment, the rotational force receiving member 150 is made of a zinc alloy, and the spherical portion 160 is made of polyacetal, and the pin is made of stainless steel.
Therefore, the coupling member 200 per se is reusable beyond a lifetime of the cartridge 2. The free end of the rotational force receiving member 150 is provided with a plurality of drive receiving projections 150d (150d1 to 150d4) (part (c) of
Part (d) of
As shown in part (e) of
As shown in parts (b) and (c) of
Between the rotational force receiving portion 150e and the spherical portion 160, there is provided a cylindrical portion 150c having a diameter smaller than that of the spherical portion 160. When the rotational force is received from the driving shaft 100, the rotational force receiving member 150 rotates about the axis L150 so that the pin 155 engages with the through-hole 150r. Thus, the rotational force from the main assembly 1 of the apparatus is converted to a rotational force to the pin 155 about the rotational axis L150 through the rotational force receiving member 150.
(Description of Connection State Between Driving Shaft and Coupling Member)
Part (a) of
The rotational force transmitting pin (rotational force applying portion) 100b of the driving shaft 100 is engaged with the rotational force receiving portion 150e (150e1 to 150e4). The rotational force transmitting pin 100b in the back side is also engaged with the rotational force receiving portion 150e although it is not shown in part (a). In addition, a free end portion 100a of the driving shaft 100 contacts to the recess 150f of the rotational force receiving member 150. By the rotation of the driving shaft 100, the rotational force is transmitted from the rotational force transmitting pin 100b to the rotational force receiving portion 150e.
Because the rotational force receiving portion 150e is inclined relative to the axis L150 of the rotational force receiving member 150, the rotational force receiving member 150 and the driving shaft 100 attracts each other, so that the contact between the free end portion 100a and the recess 150f is assured, thus accomplishing a stabilized rotational force transmission.
(Description of Drum Flange)
The opening 250a1 extends, keeping its size (diametrical size), toward the other end portion of the drum flange 250 (in the longitudinal direction of the cylinder 20A, toward the bottom) to the bottom portion (regulating portion) 250a2, thus forming a hole portion 250a. That is, the hole portion 250a extends toward the inside in the longitudinal direction while keeping the size of the opening 250a1. The length over which the size of the opening 250a1 is kept to the position contacted by the spherical portion 160 of the coupling member 200 accommodated in the opening 250a.
The opening 250a1 is at the most outside position, with respect to the longitudinal direction, of the hole portion 250a having substantially the same diameter as the spherical portion 160 of the coupling member 200.
The hole portion 250a comprises the opening 250a1, the bottom portion 250a2 and a side wall portion 250a3 continuously extending from the bottom portion 250a2 and is generally cylindrical. In this embodiment, it is circular-cylindrical, but this is not limiting, and may be another such as a circular-columnar or polygonal-columnar shape, if the spherical portion of the coupling member 200 can be accommodated. The circular-cylindrical shape is most easy to machine and manufacture.
Here, a size of the bottom portion 250a2 is substantially the same as or smaller than the size of the opening 250a1. In other words, as seen from a longitudinally outside position of the cylinder 20A, the bottom portion 250a2 at least partly overlapping the opening 250a1. That is, the bottom of the hole portion 250a of the drum flange 250 has a bottom portion 250a2 which at least partly overlaps the opening 250a1 as seen from an outside with respect to the longitudinal direction.
As will be described hereinafter, the coupling member 200 can be inserted into the drum flange 250 through an opening 250a1 from an outside of the cylinder 20A with respect to the longitudinal direction. And, since the bottom portion 250a2 at least part overlaps the opening 250a1, the spherical portion 160 of the coupling member 200 passed through the opening 250a1 is stopped by the bottom portion 250a2. Therefore, the coupling member 200 is not disengaged from the drum flange 250.
Here, the bottom portion (regulating portion) 250a2 has been described as being integral with the drum flange 250, but may be an additional member mounted to the drum flange 250. In addition, the bottom portion (regulating portion) 250a2 has been described as having one flat surface, but this is not inevitable, and the surface may be a curved surface, a spherical surface, an inclined surface or a surface having pits and projections if the coupling member 200 is not dislodged from the drum flange 250. Or, the bottom portion (regulating portion) 250a2 can be formed by a projection or the like if the movement of the coupling member 200 can be limited. Furthermore, in
A radially outside portion of the hole portion 250a is provided with groove portions 250b, 250c, 250d, 250e continuously extending from the hole portion 250a (groove portions formed continuously from the hole portion). As shown in
The groove portion 250b and the groove portion 250d, and the groove portion 250c and the groove portion 250e, are in opposite side with respect to a center O (a rotational axis L1 of the cylinder 20A which will be described hereinafter) of the hole portion 250a and are opposed to each other. Therefore, the projected portions 155a, 155b of the coupling member 200 can be accommodated smoothly. In this embodiment, the number of the groove portions 250b to 250e is four. Since the groove portions accommodate the projected portions 155a, 155b of the coupling member 200, the number thereof is preferably a multiple of 2. Furthermore, clockwisely upstream of the groove portions 250b to 250e, there are provided rotational force transmission surfaces (rotational force receiving portions) 250b1 to 250e1 which will be described in detail hereinafter.
In addition, between the groove portions 250b to 250e, and radially outside of the opening 250a1, there is provided a flat surface portion 250m. In addition, in the neighborhood of a center portion of the flat surface portion 250m, there are provided fixing hole portions 250f to 250i. The fixing hole portions 250f to 250i are disposed concentrically with respect to the center O of the hole portion 250a, and are radially equidistant from adjacent groove portion. Closing members 230 which will be described hereinafter (
As shown in part (a) of
Here, as shown in part (a) of
(Assembling Method of Photosensitive Drum Unit U1)
Referring to parts (b) and (c) of
First, the drum flange (second drum flange) 350 is inserted into the opening 20b of the cylinder 20A. The drum flange 350 is provided therein with a grounding metal plate 351 for grounding, which contacts an inner surface of the cylinder 20A. Then, the drum flange 250 is inserted into another opening 20a of the cylinder 20A. The drum flange 250 is inserted while aligning the engaging portion 250l with the opening 20a. Thereafter, the drum flange 250 is fixed to the cylinder 20A [i) drum flange mounting step]. The fixed method may be bonding, press-fitting or the like.
Thus, the photosensitive drum unit U1 is completed (part (c) of
(Assembling Method of Photosensitive Drum Unit U2)
Referring to
As described hereinbefore, the size of the opening 250a1 is substantially the same as the diameter of the spherical portion 160, and therefore, the coupling member 200 can pass through the opening 250a1. In addition, the size of the bottom portion 250a2 of the drum flange 250 is equivalent to or smaller than the size of the opening 250a1, and therefore, the spherical portion 160 can not pass through the bottom portion (regulating portion) 250a2. In other words, the bottom portion 250a2 limits movement of the spherical portion 160.
The projected portions 155a, 155b (part (c) of
The two closing members 230 have the same configurations. Part (b) of
The closing member 230 is semicircular, and a radius D of an inner surface portion (regulating portion) 230a is larger than a radius of the cylindrical portion 150c of the coupling member 150 shown in part (c) of
As shown in parts (a) and (b) of
As shown in part (a) of
As another fixing method of the closing member 230 to the drum flange 250, a double coated tape may be fixed to the back side of the closing member 230, and may be fixed to the flat surface portion 250m of the drum flange 250 by an adhesion thereof. Or, a snap fit mechanism may be provided on the closing member 230 and the drum flange 250, and the closing member 230 may be fixed to the flat surface portion 250m by an elastic force of the snap fit.
Part (b) of
Therefore, the inner surface portion (regulating portion) 230a limits the movement of the spherical portion 160 of the coupling member 200 longitudinally outwardly (outward in the direction of the rotational axis L1). Thus, the coupling member 150 is supported by the drum flange 250 and is not dislodged from the photosensitive drum unit U2. In addition, in the side opposite from the closing member 230 with respect to the longitudinal direction of the drum flange 250, the bottom portion (regulating portion) 250a2 of the drum flange 250 is provided, and therefore, the coupling member 200 limits the longitudinally inward (inward in the direction of the rotational axis L1) movement.
When two closing members 230 are assembled into the drum flange 250, the closing members 230 are positioned so as not to cover the groove portions 250b, 250d as seen from the outside in the direction of the rotational axis L1 of the drum flange. By doing so, the rotation of the pins 155 of the coupling member 200 about the spherical portion 160 is not prevented. Part (a) of
Since the closing members 230 do not cover the groove portions 250b, 250d, the pin 155 can move in the direction perpendicular to the sheet of the drawing about the spherical portion 160. In other words, it is rotatable center is spherical portion 160. The drum flange 250 is provided with a plurality of closing members 230, and the groove portions 250b, 250d accommodating the projected portions 155a, 155b are not covered by the closing members 230.
Part (b) of
Thereafter, the unit U2 is supported by the frame 51 together with the drum bearing 158 (part (a) of
As described in the foregoing, it is not necessary to assemble the coupling, the spherical member and the drive transmission pin into the flange, respectively, as required in the patent specification 1. In other words, the coupling member 200 can be assembled into the drum flange 250, integrally with the spherical portion 160, the rotational force receiving member 150 and the pin 155. The pin can be manufactured integrally with the spherical member or the rotational force receiving member.
The unit U1 is a unit which can be simply and easily assembled into the unit U2 only by using the closing member 230 for mounting the coupling member 200. Therefore, if the drum unit U1 is prepared, the coupling member 200 or the closing member 230 is procured separately, and it is assembled in the unit U2. At this time, the coupling member 200 or the closing member 230 may be a new part or a recycled part. The unit U2 is a unit provided by mounting the coupling member 200 by the simple and easy method.
The unit U1 has been described as a unit not including the closing member 230. However, it may be a photosensitive drum unit U3 including the closing member 230.
Here, unit U3 includes the screws 61 to 64, but this is not inevitable. The closing member 230 is not fixed to the drum flange 250, but it may be fixed beforehand. In such a case, after the procurement of the coupling member 200, the coupling member 250 may be mounted.
(Removing Method of Coupling Member)
Dismounting method for dismounting the coupling member 200 from the unit U2 (disassembling method of the photosensitive drum unit of dismounting the coupling member from the photosensitive drum unit) will be described. The removing method (disassembling method) is generally reverse of the assembling method of the unit U2. An exhausted cartridge 2 is collected by the printer maker or by a specialized collector. Then, reusable parts are taken out of the cartridge.
First, the unit U2 is taken out of the cartridge 2. The cylinder 20A of the unit U2 has a coated photosensitive layer at its peripheral surface, but since the photosensitive layer is scraped by the blade 52 or the like, the photosensitive layer is non-reusable in most cases at the end of the lifetime of the cartridge. On the other hand, the coupling member 200 is reusable in many cases because it does not have many sliding positions. Therefore, as regards the unit U2, the cylinder 20A, the drum flange 250, the drum flange 350 and so on connected cylinder 20A by clamping or the like are abolished, and the coupling member 200 is reused in many cases.
First, the closing members 230 are dismounted from the drum flange 250 shown in part (a) of
Thereafter, the coupling member 200 is taken out of the drum flange 250 outwardly of the cylinder 20A in the direction of the axis L1 [ii) coupling member dismounting step]. The closing members 230 have limited the movement of the coupling member 200, and therefore, later the closing members 230 are dismounted, the coupling member 200 can be taken out smoothly from the drum flange 250. As described in the foregoing, the coupling member 200 can be dismounted from the unit U2 easily. In other words, a photosensitive drum unit U2 from which the coupling member 200 can be easily dismounted.
A second embodiment of the present invention will be described. In the description of this embodiment, the same reference numerals as in the foregoing embodiment are assigned to the elements having the corresponding functions in this embodiment, and the detailed description thereof is omitted for simplicity, and the description will be made as to the structures and operations different from the foregoing embodiment.
The points of this embodiment significantly different from Embodiment 1 will be described. In Embodiment 1, the coupling member 200 comprises the rotational force receiving member 150, the spherical portion 160 and the pin 155. In this embodiment, the coupling member comprises a spherical portion and a pin which are unified. Part (a) of
Part (b) of
Part (a) of
A surface-to-be-positioned 401b of the rotational force receiving member 401 abuts to a flat positioning surface 402e of the spherical member 402 so that the rotational force receiving member 401 is positioned to the spherical member 402. The male screw portion 401a and the female screw portion 402d are threaded such that when the rotational force receiving member 401 receives a rotational force from the main assembly of the apparatus, they are tightened. Therefore, in operation of the coupling member 400, the rotational force receiving member 401 does not drop off the spherical member 402.
In this example, the rotational force receiving member 401 has the male screw portion 401a, and the spherical member 402 has the female screw portion 402d, but the male and female may be interchanged. In other words, the rotational force receiving member may have a female screw portion, and the spherical member may have a male screw portion. The material of the spherical member 160 is desirably a metal since the projected portions 402b, 402c transmit the drive. However, if the diameter of the projected portion is large enough, it may be made of a resin material.
As described in the foregoing, the coupling member 400 comprises the rotational force receiving member 401 and the spherical member 402, so that the number of the parts can be reduced. The assembling is also simple since what is required is substantially only to engage the rotational force receiving member 401 with the spherical member 402.
The rotational force receiving member 401 may be a new part or may be manufactured by machining the rotational force receiving member 150 of embodiment 1. In other words, by providing the rotational force receiving member 150 with a male screw portion 401a to manufacture the rotational force receiving member 401.
(Photosensitive Drum Unit U4)
Part (b) of
(Photosensitive Drum Unit U5)
Part (a) of
As described in the foregoing, the unit U5 is a unit which can be assembled simply and easily only by preparing the rotational force receiving member 401.
(Photosensitive Drum Unit U6)
Part (b) of
On the other hand, in the unit U6, in order to limit the outward movement of the spherical portion 402a in the longitudinal direction of the cylinder 20A, the use is made with a regulating portion 410a provided on the drum flange 410. A radius E of the regulating portion 410a is smaller than a radius of the spherical portion 402a of the spherical member 402. And, in the longitudinal direction (rotational axis L1 direction) of the drum flange 410, the position of the regulating portion 410a is outside of the center R of the spherical portion 402a.
Therefore, the regulating portion 410a limits the outward movement of the spherical portion 402a of the spherical member 402 in the longitudinal direction (rotational axis L1 direction). In an opposite side of the drum flange 410 with respect to the regulating portion 410a, a bottom closing member (retaining portion) 420 is provided, and therefore, the inward movement of the spherical portion 402a in the longitudinal direction (rotational axis L1 direction) is also limited.
(Photosensitive Drum Unit U7)
When the rotational force receiving member 401 is dismounted and is reused, it can be dismounted easily only be disengaging the spherical member 402. Similarly to the unit U5, the unit U6 is a unit which can be assembled into a unit U7 simply and easily only by preparing the rotational force receiving member 401.
A third embodiment of the present invention will be described. In the description of this embodiment, the same reference numerals as in the foregoing embodiments are assigned to the elements having the corresponding functions in this embodiment, and the detailed description thereof is omitted for simplicity, and the description will be made as to the structures and operations different from the foregoing embodiment.
Part (a) of
As shown in
The length L1 of the female screw portion 502d and a total length L2 of the positioning portion 502f and the inclined surface 502h satisfy L1<L2. In a specific example, L1 is 3.5 mm, and L2 is 4.7 mm.
In addition, projected portions 502b, 502c are projected from a spherical portion 502a. The projected portions 502b, 502c transmits the driving force received by the rotational force receiving member 501 to a drum flange 250. When the spherical member 502 is manufactured from a resin material, a reinforcing portion 502g shown in
At an end portion of the male screw portion 501a, there is provided a portion-to-be-positioned 501d for positioning the rotational force receiving member 501 relative to the spherical member 502 by engagement with the positioning portion 502f. The other end portion of the rotational force receiving member 501 is provided with a rotational force receiving portion 501c. Between the portion-to-be-positioned 501d and the male screw portion 501a, an inclined surface 501h is provided. A length M1 of the male screw portion 501a and a total length M2 of the portion-to-be-positioned 501d and the inclined surface 501h satisfy M1<M2. In a specific example, M1 is 3.0 mm, and M2 is 4.45 mm.
Since the length L1 of the female screw portion 502d of the spherical member 502 and a total length L2 of the positioning portion 502f and inclined surface 502h satisfies L1<L2, the positioning between the spherical member 502 and the rotational force receiving member 501 is effected prior to engagement between the male screw portion 501a and the female screw portion 502d. The positioning portion 502f is cylindrical. A center of the positioning portion 502f is substantially aligned with the center of the spherical portion 502a.
Therefore, the screw engagement starts in the state that the rotational force receiving member 501 and the axis of the spherical member 502 are aligned (positioned state). In addition, the rotational force receiving member 501 and the spherical member 502 are easily aligned, and therefore, the rotational force transmission accuracy is improved. The threading directions of the screws are similar to those in embodiment 2. The inclined surface 502h is provided between the positioning portion 502f and the female screw portion 502d, and therefore, the portion-to-be-positioned 501d can be directed into the positioning portion 502f, by which the rotational force receiving member 501 and the spherical member 502 are easily assembled.
A fourth embodiment of the present invention will be described. 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.
Part (a) of
Part (a) of
The closing member 530 is provided with holes-to-be-positioned 530g1, 530g2 for engaging with the positioning projections 550n1 to 550n4. The hole-to-be-positioned 530g1 is a cylindrical hole having a diameter of 1.0 mm and a depth of 2.45 mm. Therefore, one of the positioning projections 550n1 to 550n4 can be inserted into the hole-to-be-positioned 530g1. The hole-to-be-positioned 530g2 has an elongated hole configuration, and another one of the positioning projections 550n1 to 550n4 is inserted into the hole-to-be-positioned 530g2. Thus, the position of the closing member 530 is determined relative to the drum flange 550.
The closing member 530 is provided with holes 530h1, 530h2 through which screws 561 are penetrated. Finally, the coupling member 200 is fixed to the drum flange 550 by screws 561 through the holes 530h1, 530h2. The size of the screws 561 is M2, and the screws 561 are tap tight screws. A diameter head portions 561a of the screws 561 is 3.0 mm, and a height of the head portions 561a is 0.6 mm. Using the tap tight screws such dimensions, the head portions 561a of the screws 561 do not interfere the coupling member 200 even when the coupling member 200 are inclined relative to the drum flange 250.
Similarly to the Embodiment 1, a spherical surface portion 530d and an inclined surface 530f are provided. Similarly to Embodiment 1, two closing members 530 are used to fix the coupling member 200.
A fifth embodiment of the present invention will be described. In the description of this embodiment, the same reference numerals as in Embodiment 4 are assigned to the elements having the corresponding functions in this embodiment, and the detailed description thereof is omitted for simplicity.
Part (a) of
In Embodiment 1, two closing members 230 are using, but in this embodiment, one closing member 630 is used. The coupling member 200 is accommodated in the drum flange 550 by the closing member 630. In Embodiment 1, the closing member 230 does not cover the groove portions 250b, 250d so as to permit movement of the pin 155. Therefore, two closing members 230 are used in embodiment 1. In this embodiment, the closing member 630 has a recess 630a which is large enough to permit movement of the pin 155. An outside of the recesses 630a are connected by a connecting portion 630b to be unified. A thickness of the connecting portion 630b measured in the radial direction is approx. 1.35 mm.
Furthermore, the closing member 630 is provided with a hole-to-be-positioned 630g1 and an elongated hole-to-be-positioned 630g2, similarly to the embodiment 4. In addition, it is provided with holes 630h1, 630h2 for relief for those projections of the positioning projections 550n1 to 550n4 of the drum flange 550 which are not engaged with the hole-to-be-positioned 630g1, 630g2.
A diameter of the holes 630h1, 630h2 is 1.3 mm. Thus, the positioning projections 550n1 to 550n4 having a diameter of 1.0 mm do not contact the holes 630h1, 630h2. Therefore, the position of the closing member 630 relative to the drum flange 550 is determined correctly. Similarly to the Embodiment 4, an inclined surface 630f and holes 630j through which a screw is penetrated are provided.
Referring to parts (a) when (b) of
The unified coupling member 200 and closing member 630 is fixed to the drum flange 550 by a screw 561, thus forming a drum unit similarly to the embodiment 1.
According to this embodiment, the closing member 630 can be unified, and therefore, the number of parts can be reduced.
As described in the foregoing, according to the present invention, there are provided a photosensitive drum unit in which the coupling member can be easily mounted, a photosensitive drum unit in which the coupling member can be easily dismounted, an assembling method for the photosensitive drum unit in which the coupling member can be easily mounted, and a disassembling method for the photosensitive drum unit in which the coupling member can be easily dismounted.
Number | Date | Country | Kind |
---|---|---|---|
2010-021126 | Feb 2010 | JP | national |
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Entry |
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Office Action in Taiwanese Patent Application No. 100104066, dated Feb. 18, 2014. |
English translation of Office Action in Taiwanese Patent Application No. 100104066, dated Feb. 18, 2014. |
Number | Date | Country | |
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20200225611 A1 | Jul 2020 | US |
Number | Date | Country | |
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Parent | 16239696 | Jan 2019 | US |
Child | 16830492 | US | |
Parent | 15696528 | Sep 2017 | US |
Child | 16239696 | US | |
Parent | 14842964 | Sep 2015 | US |
Child | 15696528 | US | |
Parent | 14134513 | Dec 2013 | US |
Child | 14842964 | US | |
Parent | 13563044 | Jul 2012 | US |
Child | 14134513 | US |
Number | Date | Country | |
---|---|---|---|
Parent | PCT/JP2011/052679 | Feb 2011 | US |
Child | 13563044 | US |