Image forming apparatus with plural color image forming units moveable into image forming position

BACKGROUND OF THE INVENTION

The present invention relates to an image forming apparatus that is applicable, for example, as a color printer, a color copying machine or a color facsimile. More specifically, the present invention relates to a color electrophotographic apparatus for forming color images by electrophotography, and to an image forming unit used in the same.

DESCRIPTION OF THE PRIOR ART

A conventional image forming apparatus is disclosed, for example, in Publication of Unexamined Patent Application (Tokkai) No. Hei 7-36246.

The following is an explanation of a conventional color image forming apparatus as disclosed in the same publication, with reference to FIG.

43

. As shown in

FIG. 43

, an intermediate transfer belt unit

101

includes an intermediate transfer belt

102

, a primary transfer roller

103

, a secondary transfer roller

104

, a cleaner roller

105

, and a waste toner reservoir

106

. Color images can be superimposed on the transfer belt

102

. In the middle of the main body of this image forming apparatus, a group of image forming units

108

is provided. Four image forming units

107

Bk,

107

Y,

107

M and

107

C for black, yellow, magenta and cyan, each unit being of sector shape in cross section, are arranged circularly to form the group of image forming units

108

. When an image forming unit

107

Bk,

107

Y,

107

M or

107

C is installed properly in the color image forming apparatus, mechanical driving systems and electrical connection systems are coupled between the image forming units

107

Bk,

107

Y,

107

M and

107

C and other portions of the color image forming apparatus via mutual coupling members, so that both sides are mechanically and electrically connected. The image forming units

107

Bk,

107

Y,

107

M and

107

C are supported by a supporter and collectively rotated by a motor, so that they can revolve around a non-rotatable cylindrical shaft

109

. For image formation, the image forming units

107

Bk,

107

Y,

107

M and

107

C are successively moved by rotation to an image forming position

110

, where they oppose the primary transfer roller

103

spanning the intermediate transfer belt

102

. The image forming position

110

is also the exposure position for exposure with a laser signal beam

111

.

Inside this image forming apparatus, a laser exposing device

112

is arranged horizontally below the group of image forming units

108

. The laser signal beam

111

passes through a light path opening

113

between the image forming units

207

M and

207

C, and through an opening provided in the shaft

119

, and enters a mirror

114

, which is fixed inside the shaft

119

. The laser signal beam

111

reflected by the mirror

114

enters the black image forming unit

107

Bk positioned at the image forming position

110

through an exposure opening

115

. Then, the laser signal beam

111

passes through a light path between a developing device

116

and a cleaner

117

, arranged on the upper and the lower side in the image forming unit

107

Bk, enters an exposure portion on the left side of a photosensitive member

118

, and scans for exposure along the direction of the axis of the photosensitive member

118

. The toner image formed on the photosensitive member

118

is transferred to the intermediate transfer belt

102

. Then, the group of image forming units

108

rotates 90 degrees, so that the yellow image forming unit

107

Y moves into the image forming position

110

. An operation similar to the above formation of the black image is performed to form a yellow toner image overlaying the black toner image previously formed on the intermediate transfer belt

102

. Similar operations as explained above are performed using the magenta and cyan image forming units

107

M and

107

C to compose a full color image on the intermediate transfer belt

102

. After the full color image on the intermediate transfer belt

102

is completed, a recording paper is conveyed by a secondary transfer roller

104

and a tertiary transfer roller

119

, and the color image is simultaneously transferred onto the recording paper. The recording paper onto which the color image has been transferred is conveyed to a fuser

120

, which fuses the color image on the recording paper.

The above relates to an image forming apparatus as disclosed in Tokkai Hei 7-36246 etc., but these prior art examples do not disclose particular structures for retaining the image forming units precisely and reliably in the image forming apparatus, so that there is a need for the realization of such technological means.

Moreover, a color image forming apparatus for forming a color image with four image forming units by superimposing toner images on an intermediate transfer belt is known from Tokkai Hei 9-304996.

The following is an explanation of the conventional color image forming apparatus disclosed in this publication, with reference to

FIGS. 44 and 45

.

FIG. 44

is a cross sectional view showing a positioning and driving mechanism for a photosensitive member in a conventional color image forming apparatus.

FIG. 45

is a perspective view of the same.

As shown in

FIGS. 44 and 45

, flanges

402

are attached to both end portions of a drum-shaped photosensitive member

401

, and one photosensitive member shaft

403

is attached to both flanges

402

. A concave tapered surface

404

is formed on the right end of the photosensitive member shaft

403

, and a coupling plate

406

having eight tongues

405

is attached around the photosensitive member shaft

403

forming the concave tapered surface

404

. Thus, the photosensitive member

401

can be rotated by rotating the coupling plate

406

.

The photosensitive member driving mechanism, which is provided at the apparatus main body, comprises a driving shaft

411

, a coupling plate

412

rotating together with the driving shaft

411

, a driving gear

413

, and a driving motor. On the tip of the driving shaft

411

, a convex tapered surface

414

is formed, which mates with the convex tapered surface

404

formed on the right end of the photosensitive member shaft

403

.

The coupling plate

412

is provided with eight coupling tongues

418

, which mesh with the coupling plate

406

on the side of the photosensitive member

401

. The coupling plate

412

is fixed in rotation direction to the driving shaft

411

by a pin

415

, but the coupling plate

412

is movable in the axial direction within a predetermined distance. Thus, the coupling plate

412

retreats temporarily when the tips of the coupling tongues

418

abut the tips of the coupling tongues

405

. The coupling plate

412

is forced by a compression spring

416

to abut a tip stopper

417

, which holds it in a certain position.

The driving shaft

411

is supported rotatably and displaceably in the thrust direction by bearings

422

that are fixed to a hosing-side plate

420

and a driving base plate

421

. A driving shaft gear

413

meshing with a motor-side gear

423

is attached to the driving shaft

411

between the housing-side plate

420

and the driving base plate

421

. A compression spring

424

is inserted between the bearing

422

and the driving shaft gear

413

, and this compression spring

424

biases the driving shaft

411

in a direction separating it from the photosensitive member

401

. By moving a thrust bearing

425

, the driving shaft

411

can be moved against the force of the compression spring between a separated position and a coupling position

When the image forming unit in the image forming position is being changed, the driving shaft

411

is positioned in a separated position, where it is separated from the photosensitive member shaft

403

. Then, during the image forming operation, the driving shaft

411

is positioned in a coupling position, where the concave tapered surface

401

is coupled with the convex tapered surface

414

, as shown in FIG.

44

. In this coupling position, the coupling tongues

405

mesh with the coupling tongues

418

, so that a driving force can be transmitted.

The above relates to a color image forming apparatus as disclosed for example in Tokkai Hei 9-304996, but in order to suppress relative positional misalignments in such a color image forming apparatus, there is a need for reliability and reproducibility of the positioning of the photosensitive member in this image forming apparatus as well as the matching of rotational speed variations. Moreover, there is also a need for making the apparatus smaller.

However, in such conventional configurations, the coupling portions are easily misaligned, and the retention of the photosensitive member is unreliable, which causes the problem that the precision of the positioning of the photosensitive member is low, and there are variations in the position of the photosensitive member due to external forces such as the driving force for the photosensitive member and the developing device.

The reason for these problems is that the concave tapered surface

404

and the convex tapered surface

414

have the same shape and mate with each other. It is difficult to make the photosensitive member

401

and the driving shaft

411

completely coaxial at the image forming position. As is shown in

FIG. 46

, if the central axes of the driving shaft

411

and the photosensitive member shaft

403

are tilted against each other, their two cone-shaped surfaces cannot be contacted over the entire peripheral direction. In this case, the concave tapered surface

404

and the convex tapered surface

414

contact each other only at the two points P

1

and P

2

, of which P

1

is on a surface including the two tilting center axes. If the concave tapered surface

404

and the convex tapered surface

414

contact each other only at two points like this, the contact area is small, so that the coupling portion easily shifts away, and the retention of the photosensitive member

401

becomes unreliable. Moreover, the rotation center of the photosensitive member

401

cannot be positioned with good reproducibility.

Moreover, in order to press the long convex tapered surface

414

against the concave tapered surface

404

, the stroke over which the driving shaft

411

is shifted becomes long. As a result, a large waiting space has to be provided in the width direction inside the apparatus, which causes the problem that the width of the apparatus housing becomes larger, so that the apparatus main body becomes undesirably large.

Moreover, when the driving shaft

411

rotates the photosensitive member

401

, a counterforce against the rotation driving acts on the tapered coupling portion. Thus, an unreliable coupling portion will shift away, and the rotation center of the photosensitive member

401

shifts undesirably. Moreover, when the coupling portions of the photosensitive member shaft

403

and the driving shaft

411

are misaligned, the rotation speed of the photosensitive member

401

changes, which causes the problem that the positions at which the colors are superimposed on the intermediate transfer belt vary for each color.

Moreover, when the center axes of the photosensitive member shaft

403

and the driving shaft

411

are misaligned, the difference in the angular speed that is transmitted from the driving shaft

411

to the photosensitive member shaft

403

increases, which causes the problem that the positions at which the colors are superimposed on the intermediate transfer belt vary for each color.

Moreover, when the center axes of the photosensitive member shaft

403

and the driving shaft

411

are misaligned, the contact points between the coupling tongues

405

and

418

cannot be adjusted precisely, which causes the problem that the difference in the shapes of the contacting surfaces causes variations in the rotation speed for the photosensitive member

401

, and the speed variations are different for each color.

Moreover, since the coupling tongues

405

and

418

that establish contact during the rotation driving change, there is the problem that variations in the pitch between the coupling tongues

405

and

418

cause variations in the angular speed of the photosensitive member

401

, and as a result, different rotation variations are caused for each color, and relative positional misalignments occur for each color.

Moreover, while the driving shaft

411

is being moved toward the photosensitive member

401

, when the tips of the coupling tongues

405

hit the tips of the coupling tongues

418

, the photosensitive member

401

is moved in a direction that is perpendicular to the rotation axis so that the concave tapered surface

404

moves, and the driving shaft

411

cannot be coupled with the concave tapered surface

404

, and as a result, there is the problem that it becomes impossible to position the photosensitive member

401

and to rotate

Moreover, since the angle of the concave tapered surface

404

and the convex tapered surface

414

is large, there is the problem that their coupling becomes incomplete and unreliable. Furthermore, since the aperture circle at the end portion of the concave tapered surface

404

is small, sometimes it becomes impossible to insert the driving shaft

411

into the concave tapered surface

404

.

Moreover, in order to make the coupling plate

412

movable on the driving shaft, a clearance is provided between the coupling plate

412

and the driving shaft

411

, but to suppress too much play between the coupling plate

412

and the driving shaft

411

, the sliding fitting portion between the coupling plate

412

and the driving shaft

411

has to be made long. As a result, there is the problem that the distance from the bearing

422

of the driving shaft

411

to the tip becomes longer, and the width of the apparatus housing becomes larger, so that the apparatus main body becomes undesirably large.

Moreover, when the driving shaft

411

moves in the direction of the photosensitive member

401

, the inner peripheral surface of the coupling tongues

418

on the side of the driving shaft

411

may abut the outer peripheral surface of the coupling tongues

405

on the side of the photosensitive member

401

, which causes the problem that the photosensitive member

401

cannot be moved in a direction perpendicular to the rotation axis. Moreover, conversely, the outer peripheral surface of the coupling tongues

418

on the side of the driving shaft

411

may abut the inner peripheral surface of the coupling tongues

405

on the side of the photosensitive member

401

, which causes the problem that the photosensitive member

401

cannot be positioned in its proper position, even if pressure is applied to the driving shaft

411

.

Moreover, load variations due to the meshing of the coupling tongues

405

and

418

bring about speed variations of the intermediate transfer belt, which causes the problem that the positions of the images that are superimposed on the intermediate transfer belt become misaligned.

SUMMARY OF THE INVENTION

It is an object of the present invention to solve the problems of the prior art, and to provide an image forming apparatus for outputting color images that successively changes a plurality of image forming units, wherein the image forming units can be retained precisely and reliably at their proper position within the image forming apparatus main body, and which can output high-quality images, and to provide an image forming unit for the same.

Moreover, it is an object of the present invention to provide a small image forming apparatus and image forming unit used in the same, wherein the reproducibility of the positioning of the photosensitive member in the image forming position as well as the conformance of the rotation speed variations for each color are improved, and with which relative positional misalignments for each color can be suppressed.

In order to achieve these objects, a first configuration of an image forming apparatus in accordance with the present invention comprises a plurality of image forming units having a rotator; image forming unit conveying means for switching the plurality of image forming units by moving them successively between an image forming position and a waiting position; a rotator support member for positioning the rotator that is in the image forming position in a proper position in an apparatus main body by coupling with at least one axial end portion of the rotator in the axial direction of the rotator and supporting the image forming units in a freely rotatable manner; and a rotation stop portion for positioning the rotational orientation of an axis of the rotator of the image forming units.

Examples of suitable rotators include a photosensitive member or a developing roller.

With this first configuration of an image forming apparatus, it is possible to precisely and reliably retain image forming units at their proper position in the apparatus main body with a simple configuration, even when a plurality of different image forming units is used. As a result, it is possible to realize an image forming apparatus that can output high-quality color images.

Moreover, it is preferable that the image forming apparatus according to the first configuration further comprises a rotator driving means for driving the rotator, the rotation stop portion being provided on the same side of the rotator in the axial direction as the rotator driving means. With this preferable configuration, it is possible to concentrate the parts on which loads act close to each other, so that by raising the precision and the robustness of these parts, the positioning can be made more reliable. As a result, it is possible to realize an image forming apparatus that can output high-quality color images. Moreover, it is preferable that one supporting position of the rotator axis, a driving force transmission position for driving force transmission with the driving means, and a rotation stop position for stopping rotation with the rotation stop portion are substantially on the same plane, which is perpendicular to the axis of the rotator. With this preferable configuration, the torque on one support position of the axis is cancelled, and the driving force due to the driving means hardly influences the other support position of the axis, so that it is possible to precisely and reliably retain image forming units at their proper position in the apparatus main body with a simple configuration. As a result, it is possible to realize an image forming apparatus that can output high-quality color images.

Moreover, it is preferable that in the image forming apparatus according to the first configuration, the rotator is a photosensitive member; the image forming units further comprise a developer, which is driven by a developer driving means; and the rotation stop portion is provided on the same side of the rotator in an axial direction as the developer driving means. With this preferable configuration, it is possible to concentrate the parts on which loads act even closer to each other, so that by raising the precision and the robustness of these parts, the positioning can be made more reliable. As a result, it is impossible to realize an image forming apparatus that can output high-quality color images. Moreover, in this case, it is preferable that one supporting position of the rotator axis, a driving force transmission position for driving force transmission with the driving means, and a rotation stop position for stopping rotation with the rotation stop portion are substantially on the same plane, which is perpendicular to the axis of the rotator.

Moreover, it is preferable that in the image forming apparatus according to the first configuration, the rotation stop portion stops the rotation of the image forming units on a surface that is substantially parallel to a line connecting the axis of the rotator and a rotation stop position. With this preferable configuration, no excessive counter-forces act on the support portion of the rotator axis, so that the rotator can be retained even more reliably.

Moreover, it is preferable that in the image forming apparatus according to the first configuration, the rotator is a photosensitive member; the image forming apparatus further comprises a developer and a developer driving means for driving the developer; and the rotation stop portion stops the rotation of the image forming units on a surface that is substantially parallel to a direction of a driving force exerted by the developer driving means. With this preferable configuration, no excessive counter-forces act on the support portion of the rotator axis, so that the rotator can be retained even more reliably. Moreover, in this case, it is preferable that the rotation stop portion stops the rotation of the image forming units near an action line of the driving force exerted by the developer driving means. With this preferable configuration, there are almost no excessive counter-forces on the support portion of the rotator axis, so that the rotator can be retained even more reliably.

Moreover, it is preferable that in the image forming apparatus according to the first configuration, the rotation stop portion is provided in the image forming unit conveying means. With this preferable configuration, a rotation stop portion can be provided at a position close to the image forming unit, so that the rotation of the image forming unit can be stopped reliably without providing, for example, a large protrusion in the image forming unit or the apparatus main body.

Moreover, it is preferable that in the image forming apparatus according to the first configuration, the rotator is a photosensitive member; the image forming apparatus further comprises a developer, a developer driving means for driving the developer, and a photosensitive member driving means for driving the photosensitive member; and at the time of image formation, the developer driving means starts to drive the developer after the photosensitive member driving means has started to drive the photosensitive member. With this preferable configuration, it is possible to precisely and reliably retain image forming units at their proper position in the apparatus main body with a simple configuration, even when the rotator axis is not sufficiently supported. As a result, it is possible to realize an image forming apparatus that can output high-quality color images.

Moreover, it is preferable that the image forming apparatus according to the first configuration further comprises a thrust stop portion for positioning the axial direction of the rotator of the image forming units, which is provided near the axis of the rotator. With this preferable configuration, the torque on the support position of the rotator axis becomes small, so that it is possible to smoothly support the axis, even when the image forming unit is tilted. Moreover, in this case, it is preferable that the rotation stop portion and the thrust stop portion are provided on the same side of the rotator in the axial direction. With this preferable configuration, the members relating to the positioning can be concentrated close to each other, so that the positioning precision can be improved.

Moreover, it is preferable that in the image forming apparatus according to the first configuration, the rotator is a photosensitive member; the image forming apparatus further comprises a developer, a developer driving means for driving the developer, and a photosensitive member driving means for driving the photosensitive member; and the direction of the torque on the axis of the photosensitive member due to the gravitational force of the image forming unit acting on the image forming unit is opposite to the direction of the torque on the axis of the photosensitive member due to the developer driving means, and the size of the torque due to the gravitational force of the image forming unit is smaller than the size of the torque due to the driving gear for the developer. With this preferable configuration, the rotation stop force of the image forming unit on the rotation stop portion is reduced, and the influence of gravity is reduced, so that a more reliable positioning becomes possible.

A first configuration of an image forming unit in accordance with the present invention comprises a rotator. The image forming unit is retained in a manner that it can be installed in or removed from an apparatus main body; a rotator support member on an apparatus main body side is coupled with at least one axial end portion of the rotator positioned in an image forming position, in the axial direction of the rotator to position the rotator in a proper position in an apparatus main body; and positioning of the rotational orientation of an axis of the rotator is performed with a rotation stop portion on the side of the apparatus main body. With this first configuration of an image forming unit, it is possible to realize an image forming unit that can be retained precisely and reliably at a proper position in the apparatus main body.

A second configuration of an image forming apparatus in accordance with the present invention comprises a plurality of image forming units having a rotator with flanges on both ends; a unit retaining member, which retains the plurality of image forming units, and switches the plurality of image forming units by moving them successively between an image forming position and a waiting position; an intermediate transfer member, which contacts the image forming unit positioned in the image forming position and successively accepts toner images of various colors from the image forming units, so as to form a colored toner image on its surface; and a positioning member for coupling with at least one of the flanges of the rotator by advancing and receding in the axial direction when being substantially coaxial with the rotator of the image forming unit that is positioned in the image forming position; wherein a coupling part for coupling with the positioning member is provided at the center of end surfaces of the flanges; wherein the coupling part is a concave tapered surface with a circular cross section having the axis of the rotator as a center axis; and wherein a tip of the positioning member is a convex spherical surface, whose rotation center is the center axis. With this second configuration of an image forming apparatus, it is possible even when the positioning member and the rotator are coupled while their axes are tilted against each other, the contact portions of the coupling portions are circles formed by the intersection between a plane perpendicular to the axis of the rotator and the concave tapered surface. Consequently, the rotator can be held and controlled over the entire periphery. As a result, it is possible to hold and position the rotator reliably.

It is preferable that in the image forming apparatus according to the second configuration, the tip of the concave tapered surface at the coupling part contacting the positioning member during positioning and coupling is provided with a tapered surface with circular cross section, whose tip angle is larger than that of the concave tapered surface, and which is in close opposition to a tip of the positioning member. With this preferable configuration, even when the concave tapered surface is deformed and the positioning member attempts to enter the concave tapered surface beyond a certain position, the tip of the positioning member abuts the tapered surface, which has a large tip angle. Consequently, it can be prevented that the positioning member enters much beyond a certain position into the tapered portion. Therefore, it is possible to set a small moving stroke in the axial direction for the positioning member. As a result, even when the moving stroke for the positioning member in the axial direction is small, the rotator is pressed securely by the positioning member, and the rotator can be retained securely.

It is preferable that in the image forming apparatus according to the second configuration, the tip of the concave tapered surface at the coupling part contacting the positioning member during positioning and coupling is provided with a flat surface, which is in close opposition to a tip of the positioning member. With this configuration, even when the concave tapered surface is deformed and the positioning member attempts to enter the concave tapered surface beyond a certain position, the tip of the positioning member abuts the flat surface. Consequently, it can be prevented that the positioning member enters much beyond a certain position into the tapered portion. Therefore, it is possible to set an even smaller moving stroke in the axial direction for the positioning member. As a result, the moving stroke for the positioning member in the axial direction can be set to be short while retaining the rotator securely, so that the apparatus main body can be made smaller.

It is preferable that in the image forming apparatus according to the second configuration, the positioning member is made of a conductive material and is electrically grounded; the flange coupling with the positioning member is made of an insulating material; a center of a coupling part of the flange is provided with a through hole connecting an inner portion of the rotator with an outer portion thereof; and an electrode member is provided inside the through hole, which is retained while being biased in the direction of the positioning member, and which establishes conduction between the rotator and the positioning member by contacting the positioning member. With this preferable configuration, the electrode member contacts the positioning member at the rotation center of the coupling portion where the relative displacement amount is the smallest, so that a secure electrical conduction can be established also during rotation. In addition, the flange and the positioning member rotate together, and there is no relative movement in the rotation direction between the two, so that an even more secure electrical conduction can be established.

It is preferable that in the image forming apparatus according to the second configuration, the convex spherical tip of the positioning member is provided with a flat portion that is perpendicular to the rotation axis. With this preferable configuration, the contact between the electrode member and the positioning member, which contact each other elastically, can be made more reliable, so that electrical conduction can be established more securely. Furthermore, even when the stroke in the axial direction of the positioning member is short, it is possible to pull out the positioning member from the concave tapered surface of the flange. Moreover, since the concave tapered surface of the flange contacts the spherical surface of the positioning member over the entire perimeter of a circle, it is possible to retain the photosensitive member securely, even when the spherical surface of the positioning member is short. As a result, the apparatus main body can be made smaller, since the moving stroke of the positioning member can be made short.

It is preferable that the image forming apparatus according to the second configuration further comprises a driving motor for generating a rotation force for the rotator; and a rotation transmission member provided in one piece with one positioning member, wherein transmission and disconnection of the rotation force is performed by substantially coaxial rotation with that rotator that is positioned in the image forming position, and advancing and receding in the axial direction of the rotator; wherein the flange opposing the rotation transmission member has, on an end surface, a rotation follower portion to which a rotation force is transmitted when it contacts the rotation transmission member. With this preferable embodiment, the coupling portion on the driving side for transmitting the angular speed does not vary, and the rotation center of the rotator can be defined reliably. As a result, variations of the rotation speed of the rotator can be suppressed, and it is possible to obtain a good image without color misalignments. Moreover, in this case, it is preferable that a contact portion for contact between the rotation transmission member and the rotation follower portion extends through a center of the convex spherical surface of the tip of the positioning member, and is at a position perpendicular to a rotation center axis of the rotation transmission member. With this preferable embodiment, positional misalignments due to speed variations are suppressed, and a high-quality image can be obtained. Moreover, in this case, it is preferable that at least one of the contact faces where the rotation transmission member contacts the rotation follower portions is provided with a protrusion. With this configuration, the contact point is usually the tip of the protrusion and does not change, so that rotation speed variations of the rotator, which are caused by the contact portion where the rotation transmission member contacts the rotation follower portion, can be suppressed. As a result, positional misalignments for each color due to speed variations can be suppressed, and it is possible to obtain a high-quality image.

A third configuration of an image forming apparatus in accordance with the present invention comprises a plurality of image forming units having a rotator with flanges on both ends; a unit retaining member, which retains the plurality of image forming units, and switches the plurality of image forming units by moving them successively between an image forming position and a waiting position; an intermediate transfer member, which contacts the image forming unit positioned in the image forming position and successively accepts toner images of various colors from the image forming units, so as to form a colored toner image on its surface; a positioning member for coupling at a coupling part at a center of an end surface of at least one of the flanges of the rotator by advancing and receding in the axial direction when being substantially coaxial with the rotator of the image forming unit that is positioned in the image forming position; a driving motor for generating a rotation force for the rotator; and a rotation transmission member provided in one piece with one positioning member, for which transmission and disconnection of the rotation force is performed by substantially coaxial rotation with the rotator that is positioned in the image forming position, and advancing and receding in the axial direction of the rotator; wherein an end surface of the flange opposing the rotation transmission member is provided with rotation follower portions made of a plurality of concave and convex portions; and wherein the rotation transmission member is provided with one transmission tongue for transmitting a rotation force by meshing with the rotation follower portions. With this third configuration of an image forming apparatus, the angular speed is always transmitted by the same tongue, so that there are no variations in the angular speed transmitted to the photosensitive member.

It is preferable that in the image forming apparatus according to the third configuration, the rotation transmission member is provided with at least one protrusion portion of the same height as the transmission tongue; and during rotation, the at least one protrusion portion enters a concave portion of the rotation follower portions, but does not contact the rotation follower portions. With this preferable configuration, there is no resulting counter-force on the rotation transmission member when the transmission tongue hits the tips of the tongues on the flange. Thus, it is possible to move the rotation transmission member smoothly in the axial direction. As a result, the transmission tongue can be meshed securely with the rotation follower portions when the rotation starts.

A fourth configuration of an image forming apparatus in accordance with the present invention comprises a plurality of image forming units having a rotator with flanges on both ends; a unit retaining member, which retains the plurality of image forming units, and switches the plurality of image forming units by moving them successively between an image forming position and a waiting position; an intermediate transfer member, which contacts the image forming unit positioned in the image forming position and successively accepts toner images of various colors from the image forming units, so as to form a colored toner image on its surface; a positioning member for coupling at a coupling part at a center of an end surface of at least one of the flanges of the rotator by advancing and receding in the axial direction when being substantially coaxial with the rotator of the image forming unit that is positioned in the image forming position; a driving motor for generating a rotation force for the rotator; and a rotation transmission member provided in one piece with one positioning member, for which transmission and disconnection of the rotation force is performed by substantially coaxial rotation with the rotator that is positioned in the image forming position, and advancing and receding in the axial direction of the rotator; wherein an end surface of the flange opposing the rotation transmission member is provided with rotation follower portions made of a plurality of concave and convex portions; wherein the rotation transmission member is provided with a transmission tongue for transmitting a rotation force by meshing with the rotation follower portions; and wherein, when a tip of the transmission tongue reaches a tip position of the rotation follower portions during the transition from a disconnected state to a connected state for the rotation force, the positioning member has advanced inside beyond an edge portion of the coupling part. With this fourth configuration of an image forming apparatus, when the transmission tongue reaches the tip position of the rotation follower portions, the tip of the positioning member enters beyond an edge portion of the coupling part of the flange, so that at the portion where the tongue abuts, the rotator can be moved in a radial direction, and the positioning member can be coupled securely with a coupling part of the flange.

It is preferable that in the image forming apparatus according to the fourth configuration, the coupling part comprises a concave tapered surface with circular cross section, which contacts the positioning member during positioning and coupling; and a tapered surface with circular cross section, which is provided at a tip of the concave tapered surface, and whose tip angle is greater than that of the concave tapered surface.

It is preferable that in the image forming apparatus according to the fourth configuration, at least a tip of the transmission tongue of the rotation transmission member is movable in a rotation direction with respect to the positioning member and biased toward the rotator. With this preferable configuration, the radial movement of the rotator is not hindered when the positioning member abuts the coupling part. Consequently, the rotator can be positioned even more securely in the image forming position, and the rotation speed can be transmitted precisely. Moreover, in this case, it is preferable that the transmission tongue of the rotation transmission member is formed only in a portion in a rotation circumferential direction, and the rotation transmission member is retained rotatably with respect to the positioning member around a rotation shaft that is provided perpendicularly to the rotation center axis at a peripheral portion where the transmission tongue is not formed. With this preferable configuration, it does not become long in the rotation axial direction, even when the coupling and sliding portion between the rotation center and the rotation transmission member is set to be long. As a result, the length from the bearing of the positioning member to its tip can be set short and without clearance, so that the apparatus main body can be made smaller. In this case, it is furthermore preferable that the rotation transmission member is provided with a posture defining means for defining a posture of the rotation orientation of the rotation transmission member. With this preferable configuration, the tip of the transmission tongue does not hit the bottom of the rotation follower portions of the flange, and the transmission tongue and the rotation follower portions of the flange usually mesh at the proper position. Moreover, in this case, it is furthermore preferable that the rotation shaft is provided at a position directly near an end surface of the flange that opposes the rotation transmission member during positioning and coupling. With this configuration, even when there is an intersection angle θ between the center axis of the driving shaft and the center axis of the rotator, the distance between the contact point where the transmission tongue contacts the rotation follower portions and the center axis of the driving shaft can be maintained substantially constant.

It is preferable that in the image forming apparatus according to the fourth configuration, a surface that opposes in the circumferential direction a surface where the transmission tongue and at least one of the rotation follower portions contact during rotation and driving is oblique in the circumferential direction. With this preferable configuration, the impact at the time of coupling during the moving in the axial direction can be reduced, and as a result, collision noise can be avoided.

It is preferable that in the image forming apparatus according to the fourth configuration, when a tip of the rotation transmission member reaches a tip position of the rotation follower portions while being moved toward the rotator, coupling between the positioning member and the coupling part is incomplete; and that at least one portion of the transmission tongue of the rotation transmission member is normally positioned between an outermost peripheral portion and an innermost peripheral portion of the rotation follower portions. With this preferable configuration, when the positioning member is moved toward the rotator and the rotator is being positioned, the inner peripheral surface of the tongues on the side of the positioning member cannot abut the outer peripheral surfaces of the tongues on the side of the rotator. Furthermore, the inner peripheral surface of the tongues on the side of the rotator cannot abut the outer peripheral surfaces of the tongues on the side of the positioning member. As a result, the rotator is moved securely in a radial direction, and the rotator can be positioned at its correct position.

A fifth configuration of an image forming apparatus in accordance with the present invention comprises a plurality of image forming units having a rotator with flanges on both ends; a unit retaining member, which retains the plurality of image forming units, and switches the plurality of image forming units by moving them successively between an image forming position and a waiting position; an intermediate transfer member, which contacts the image forming unit positioned in the image forming position and successively accepts toner images of various colors from the image forming units, so as to form a colored toner image on its surface; a driving motor for generating a rotation force for the rotator and the intermediate transfer member, which stops when the unit retaining member is being moved; a detection means for detecting a reference position of the intermediate transfer member after the driving motor has started; an exposure means for forming a latent image on the rotator, based on a detection signal from the detection means; a rotation transmission member for which transmission and disconnection of the rotation force is performed by substantially coaxial rotation with the rotator that is positioned in the image forming position, and advancing and receding in the axial direction of the photosensitive member; wherein an end surface of one of the flanges is provided in the circumferential direction with rotation follower portions made of a plurality of concave and convex portions, which transmit a rotation force by meshing with the rotation transmission member; wherein a pitch between neighboring concave and concave portions of the rotation follower portions is smaller than a rotation angle of the driving transmission member from the start of the driving motor until the generation of the detection signal. With this fifth configuration of an image forming apparatus, the reference position of the intermediate transfer member is detected after the driving tongue has meshed with the rotation follower portions, and after the speed of the intermediate transfer member has stabilized. As a result, the position of the image can be aligned precisely on the intermediate transfer member, because anomalous speed variations do not occur after the reference position has been detected.

It is preferable that in the image forming apparatus according to the fifth configuration, the pitch between neighboring concave and concave portions of the rotation follower portions is smaller than a rotation angle of the driving transmission member from the start of the driving motor until the acceleration of the driving motor to a predetermined speed. With this preferable configuration, the driving tongue and the rotation follower portions mesh while the driving motor is being accelerated. Therefore, the time from the meshing of the driving tongue and the rotation follower portions until the speed variations due to load variations have subsided becomes short. As a result, after the meshing of the driving tongue and the rotation follower portions, the speed of the intermediate transfer member stabilizes in a short time. As a result, if the reference position of the intermediate transfer member is detected after the driving motor is started, anomalous speed variations do not occur after the position has been detected, so that the positions of the images on the intermediate transfer member can be aligned precisely.

A second configuration of an image forming unit in accordance with the present invention comprises a rotator with flanges on both ends, and can be installed in and removed from an image forming apparatus comprising a unit retaining member, which retains a plurality of image forming units, and switches the plurality of image forming units by moving them successively between an image forming position and a waiting position; an intermediate transfer member, which contacts the image forming unit positioned in the image forming position and successively accepts toner images of various colors from the image forming units, so as to form a colored toner image on its surface; and a positioning member for coupling with at least one of the flanges of the rotator by advancing and receding in the axial direction when being substantially coaxial with the rotator of the image forming unit that is positioned in the image forming position, the tip of the positioning member being a convex spherical surface whose rotation center is the center axis; wherein a coupling part for coupling with the positioning member of the image forming apparatus is provided at the center of an end surface of the flanges; and wherein the coupling part is a concave tapered surface with a circular cross section having the axis of the rotator as a center axis.

It is preferable that in the image forming unit according to the second configuration, the tip of the concave tapered surface at the coupling part contacting the positioning member of the image forming apparatus during positioning and coupling is provided with a tapered surface with circular cross section, whose tip angle is larger than that of the concave tapered surface, and which is in close opposition to a tip of the positioning member.

It is preferable that in the image forming unit according to the second configuration, the tip of the concave tapered surface at the coupling part contacting the positioning member of the image forming apparatus during positioning and coupling is provided with a flat surface, which is in close opposition to a tip of the positioning member.

It is preferable that in the image forming unit according to the second configuration, the flange is made of an insulating material; a center of a coupling part of the flange is provided with a through hole connecting an inner portion of the rotator with an outer portion thereof; and an electrode member is provided inside the through hole, which is retained while being biased in the direction of the positioning member of the image forming apparatus, and which establishes conduction between the rotator and the positioning member by contacting the positioning member.

It is preferable that the image forming unit according to the second configuration further comprises a driving motor for generating a rotation force for the rotator; and a rotation transmission member provided in one piece with one positioning member, wherein transmission and disconnection of the rotation force is performed by substantially coaxial rotation with the rotator that is positioned in the image forming position, and advancing and receding in the axial direction of the rotator; and that the flange opposing the rotation transmission member has, on an end surface, a rotation follower portion to which a rotation force is transmitted when it contacts the rotation transmission member. Moreover, in this case, it is preferable that the contact portion between the rotation transmission member and the rotation follower portion goes through a center of the convex spherical portion of the tip of the positioning member at a coupling position, and is at a position perpendicular to a rotation center axis of the rotation transmission member. In this case, it is even more preferable that at least one of the contact faces where the rotation transmission member contacts the rotation follower portions is provided with a protrusion.

A third configuration of an image forming unit in accordance with the present invention comprises a rotator with flanges on both ends, and the image forming unit can be installed in and removed from an image forming apparatus comprising a unit retaining member, which retains a plurality of image forming units and switches the plurality of image forming units by moving them successively between an image forming position and a waiting position; an intermediate transfer member, which contacts the image forming unit positioned in the image forming position and successively accepts toner images of various colors from the image forming units, so as to form a colored toner image on its surface; a positioning member for coupling with at least one of the flanges of the rotator by advancing and receding in the axial direction when being substantially coaxial with the rotator of the image forming unit that is positioned in the image forming position; a driving motor for generating a rotation force for the rotator; and a rotation transmission member provided in one piece with one positioning member, and which has a transmission tongue for performing transmission and disconnection of the rotation force by substantially coaxial rotation with the rotator that is positioned in the image forming position, and advancing and receding in the axial direction of the rotator; wherein a coupling part for coupling with the positioning member of the image forming apparatus is provided at the center of an end surface of the flanges; wherein an end surface of the flange that opposes the rotation transmission member is provided with rotation follower portions made of a plurality of concave and convex portions; and wherein, when a tip of the transmission tongue reaches a tip position of the rotation follower portions during the transition from a disconnected state to a transmission state of the rotation force, the positioning member has advanced inside beyond an edge portion of the coupling part.

It is preferable that in the image forming unit according to the third configuration, the coupling part comprises a concave tapered surface with circular cross section, which contacts the positioning member during positioning and coupling; and a tapered surface with circular cross section, which is provided at the tip of the concave tapered surface, and whose tip angle is greater than that of the concave tapered surface.

It is preferable that in the image forming unit according to the third configuration, a surface that opposes in a circumferential direction a surface of the rotation follower portion that contacts the transmission tongue during rotation and driving is oblique in a circumferential direction.

It is preferable that in the image forming unit according to the third configuration, when a tip of the transmission tongue reaches a tip position of the rotation follower portions while being moved toward the rotator, coupling between the positioning member and the coupling part is incomplete; and that at least one portion of the transmission tongue of the rotation transmission member is normally positioned between an outermost peripheral portion and an innermost peripheral portion of the rotation follower portions.

A fourth configuration of an image forming unit in accordance with the present invention comprises a rotator with flanges on both ends, and the image forming unit can be installed in and removed from an image forming apparatus comprising a unit retaining member, which retains the plurality of image forming units and switches the plurality of image forming units by moving them successively between an image forming position and a waiting position; an intermediate transfer member, which contacts the image forming unit positioned in the image forming position and successively accepts toner images of various colors from the image forming units, so as to form a colored toner image on its surface; a driving motor for generating a rotation force for the rotator and the intermediate transfer member, which stops when the unit retaining member is being moved; a detection means for detecting a reference position of the intermediate transfer member after the driving motor has started; an exposure means for forming a latent image on the image forming unit, based on a detection signal from the detection means; a rotation transmission member for which transmission and disconnection of the rotation force is performed by substantially coaxial rotation with the rotator that is positioned in the image forming position, and advancing and receding in the axial direction of the photosensitive member; wherein an end surface of one of the flanges is provided in circumferential direction with rotation follower portions made of a plurality of concave and convex portions, which transmit a rotation force by meshing with the rotation transmission member; wherein a pitch between neighboring concave and concave portions of the rotation follower portions is smaller than a rotation angle of the driving transmission member from the start of the driving motor until the generation of the detection signal.

It is preferable that in the image forming unit according to the fourth configuration, a pitch between neighboring concave and concave portions of the rotation follower portions is smaller than a rotation angle of the driving transmission member from the start of the driving motor until the acceleration of the driving motor to a predetermined speed.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1

is a diagrammatic cross sectional view illustrating the configuration of a first embodiment of an image forming apparatus according to the present invention.

FIG. 2

is a diagram showing how the image units can be installed in and removed from the first embodiment of an image forming apparatus according to the present invention.

FIG. 3

is a cross sectional view illustrating the configuration of the intermediate transfer belt unit used in the first embodiment of an image forming apparatus according to the present invention.

FIG. 4

is a perspective view illustrating the configuration of the intermediate transfer belt used in the first embodiment of an image forming apparatus according to the present invention.

FIG. 5

is an exploded perspective view showing the positioning mechanism and the driving mechanism for the carriage and the photosensitive members of the image forming units in the first embodiment of an image forming apparatus according to the present invention.

FIG. 6

is a cross sectional view of the carriage of the first embodiment of an image forming apparatus according to the present invention, taken along the plane through the image forming position.

FIG. 7

is a lateral view of an image forming unit and the carriage in the first embodiment of an image forming apparatus according to the present invention, seen from the right.

FIG. 8

is a perspective view showing a photosensitive member driving mechanism in the first embodiment of an image forming apparatus according to the present invention, which is a photosensitive member driving means for driving the photosensitive member positioned in the image forming position.

FIG. 9

is a lateral view showing a mechanism for positioning the shaft of the photosensitive member at an end surface opposite from the driving mechanism in the first embodiment of an image forming apparatus according to the present invention.

FIG. 10

is a diagrammatic cross sectional view illustrating the configuration of a first embodiment of an image forming unit according to the present invention.

FIG. 11

is a cross sectional view of the carriage of a second embodiment of an image forming apparatus according to the present invention, taken along the plane through the image forming position.

FIG. 12

is a perspective view showing the photosensitive member driving mechanism, which is a photosensitive member driving means for driving the photosensitive member positioned in the image forming position, and the developer driving mechanism, which is a developer driving means for driving the developer in the second embodiment of an image forming apparatus according to the present invention.

FIG. 13

is a lateral view of an image forming unit and a portion of the carriage in the second embodiment of an image forming apparatus according to the present invention, taken from the right side.

FIG. 14

is a lateral view of an image forming unit and a portion of the carriage in a third embodiment of an image forming apparatus according to the present invention, taken from the right side.

FIG. 15

is a cross sectional view of a fourth embodiment of an image forming unit according to the present invention.

FIG. 16

is a cross sectional view of a fourth embodiment of an image forming apparatus according to the present invention.

FIG. 17

is a cross sectional view showing a position detection portion for detecting the position of the intermediate transfer belt in the fourth embodiment of the present invention, including a position detection hole provided in the intermediate transfer belt and an optical position detection sensor.

FIG. 18

is a perspective view showing a first flange on the right side of the photosensitive member and a driving shaft provided on the right side of the main body in the fourth embodiment of the present invention.

FIG. 19

is a cross sectional view taken at the rotation center of the first flange on the right side of the photosensitive member and the driving shaft provided on the right side of the main body in the fourth embodiment of the present invention.

FIG. 20

is a diagram illustrating the driving mechanism on the main body side for driving the photosensitive member and the intermediate transfer belt in the fourth embodiment of the present invention.

FIG. 21

is a perspective view showing a second flange on the left side of the photosensitive member and a positioning shaft provided on the left side of the main body in the fourth embodiment of the present invention.

FIG. 22

is a cross sectional view taken at the rotation center of the second flange on the left side of the photosensitive member and the positioning shaft provided on the left side of the main body in the fourth embodiment of the present invention.

FIG. 23

is a cross sectional view of the first flange and the driving shaft in the fourth embodiment of the present invention, seen from the direction of the driving shaft.

FIG. 24

is a cross sectional view through the rotation center of the first flange and the driving shaft in the fourth embodiment of the present invention, when the driving shaft is moving from the separation position to the coupling position.

FIG. 25

is a graph illustrating the speed of the driving motor at the beginning of the image formation in the fourth embodiment of the present invention.

FIG. 26

is a cross sectional view of a fifth embodiment of the present invention, taken at the rotation center of the coupling portion of the first flange on the driving side and the driving shaft.

FIG. 27

is a lateral view of the first flange in the fifth embodiment of the present invention, seen from the direction of the end surface.

FIG. 28

is a cross sectional view of a sixth embodiment of the present invention, taken at the rotation center of the coupling portion of the first flange on the driving side and the driving shaft.

FIG. 29

is a lateral view of the driving shaft in a seventh embodiment of the present invention, seen from the tip direction.

FIG. 30

is a perspective view showing an end portion of the first flange of the photosensitive member in the seventh embodiment of the present invention.

FIG. 31

is a cross sectional view of the seventh embodiment of the present invention, taken at the rotation center of the coupling portion of the first flange on the driving side and the driving shaft.

FIG. 32

is a cross sectional view of the seventh embodiment of the present invention, taken at the rotation center of the coupling portion during the coupling operation.

FIG. 33

is a diagram illustrating the effect of the seventh embodiment of the present invention.

FIG. 34

is a front view showing the driving shaft in an eighth embodiment of the present invention.

FIG. 35

is a lateral view of the driving shaft in the eighth embodiment of the present invention, seen from its axial direction.

FIG. 36

is a lateral view of the driving shaft in an ninth embodiment of the present invention, seen from its axial direction.

FIG. 37

is a cross sectional view of the ninth embodiment of the present invention, taken at the rotation center of the coupling position of the first flange and the driving shaft.

FIG. 38

is a lateral view of a driving shaft having a transmission member in a tenth embodiment in accordance with the present invention, seen from the axial direction.

FIG. 39

is a cross sectional view of the transmission tongue that the transmission member in the tenth embodiment of the present invention is provided with, seen from a radial direction.

FIG. 40

is a lateral view showing the configuration of the end surface of the first flange in the tenth embodiment of the present invention.

FIG. 41

is a cross sectional view of the follower tongue that a peripheral portion of the end surface of the first flange in this tenth embodiment of the present invention is provided with, seen from the radial direction.

FIG. 42

is cross sectional view of the coupling position in the tenth embodiment of the present invention, taken at the rotation center of the first flange.

FIG. 43

is a cross sectional view showing the configuration of a conventional image forming apparatus.

FIG. 44

is a cross sectional view showing the configuration of a positioning and driving mechanism in a conventional image forming apparatus.

FIG. 45

is a cross sectional view of a conventional image forming apparatus, taken at the rotation axis of the coupling portion.

FIG. 46

is a diagram illustrating the problems with the conventional image forming apparatus.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

The following is a detailed explanation of the invention with reference to the preferred embodiments.

First Embodiment

The following is an explanation of a first embodiment of an image forming apparatus in accordance with the present invention, with reference to

FIGS. 1

to

4

.

In

FIG. 1

, numeral

1

denotes the printer main body of an image forming apparatus, with the right-hand face being the front face of the apparatus. Numeral

1

A denotes a printer front panel. The printer front panel is hinged on a hinge axis

1

B on the lower side of an outer printer housing

1

D, and can be tilted and opened toward the front.

FIG. 2

shows the situation when the printer front panel

1

A is tilted and opened. For maintenance of the printer internal parts, such as during the removal of paper jams, the printer front panel

1

A is opened, and the internal parts of the printer are laid open.

FIG. 3

shows an intermediate transfer belt unit. As is shown in

FIG. 3

, the intermediate transfer belt unit

2

includes a unit case

3

, an intermediate transfer belt

4

, a transfer guide roller

9

, a retransfer backup roller

6

, a driving roller

8

, and a tension roller

5

for suspending the intermediate transfer belt

4

, a waste toner reservoir

10

for collecting waste toner, a waste toner overflow detector

11

, a position detector

12

, and a cleaner unit

15

. The driving roller

8

receives its driving power from a driving means (not shown in the drawings) in the printer main body

1

, and drives the intermediate transfer belt

4

in the arrow direction Y. The cleaning unit

15

includes a cleaning blade

7

, a toner catcher

17

, and a cam follower

16

, and is attached rockably around a rocking axis

18

. The cleaning unit

15

is biased against the driving roller

8

by means of, for example, a spring (not shown in the drawings), so that the cleaning blade

7

abuts the driving roller

8

through the intermediate transfer belt. A disjunction cam is provided in the printer main body

1

(see FIGS.

1

and

2

), and this disjunction cam is coupled with the cam follower

16

when the intermediate transfer belt unit

2

is installed in the printer main body. The cleaner unit

15

and the waste toner reservoir

10

are connected via a communicating hole

19

, and waste toner that a cleaning blade

7

has scraped off by a known means, such as a screw shaft, is transported into the waste toner reservoir

10

, which is arranged inside the intermediate transfer belt

4

.

The intermediate transfer belt

4

has a thickness of 100-500 μm and is made of a urethane film of a semiconducting (medium electrical resistance) endless belt, which is coated with a fluororesin such as PFA or PTFE.

The perimeter of the intermediate transfer belt

4

is 377 millimeters, which corresponds to the length of the maximally acceptable A

4

recording paper size (297 mm) plus a little bit more (80 mm) than half the perimeter of the photosensitive member (30 mm diameter), so that A

4

size and letter size recording paper sheets can be used for full color printing. With this arrangement, the perimeter of the intermediate transfer belt

4

from the retransfer position of the retransfer backup roller

6

to position where the cleaning blade

7

abuts the driving roller

8

is set to 75 mm, thus a little shorter than 80 mm.

The travel speed of the intermediate transfer belt

4

is about 1.5% faster than the image forming speed of the image forming units (100 mm/s, which is equal to the circumferential speed of the photosensitive member), which prevents the thinning out of the toner image in the middle.

During the transfer of the toner image onto the photosensitive member, a high voltage source, which is not shown in the drawings, applies a voltage of about +2.5 kV (about 100 μA) to the transfer guide roller

9

and the tension roller

5

. Sometimes when the transfer guide roller

9

abuts against the photosensitive member, and the toner image is being transferred onto the intermediate transfer belt

4

, the intermediate transfer belt

4

“jumps forward” before it contacts the photosensitive member, thereby corrupting the image, and it is difficult to adjust the contact pressure between the transfer guide roller

9

and the photosensitive member to be constant. However, with the configuration of the present embodiment, in which the intermediate transfer belt

4

is suspended between the transfer guide roller

9

and the tension roller

5

and contacts the photosensitive member, such problems do not occur.

The diameter of the driving roller

8

and the retransfer backup roller

6

is 30 mm. Moreover, the diameter of the tension roller

5

and the transfer guide roller

9

is 15 mm. The perimeter of the intermediate transfer belt

4

is set to be an integer multiple of the outer perimeter of each roller. This way, misalignments of the colors can be prevented. Numeral

20

in

FIG. 4

denotes a detection hole for detecting the position of the intermediate transfer belt

4

. A position detector

12

optically detects the passing of this detection hole

20

to determine the start position of the toner image. Thus, it is possible to align the position of the color images on the intermediate transfer belt

4

.

Here, an optical position detection means is used for the position detection means, but there is no limitation to this, and it is also possible to use a position detection means that does not use an optical detection method, but for example a mechanical, electrical, magnetic or any other method. carriage

22

and a transport motor

23

, constituting an image forming unit conveying means, are arranged on the center left side of the printer main body

1

. Four image forming units

21

Y,

21

M,

21

C and

21

Bk for yellow, magenta, cyan, and black, each unit being substantially of sector shape in cross section, are arranged and retained circularly in the carriage

22

. The image forming units

21

are mounted removably in certain positions in the carriage

22

, and when one of the image forming units

21

needs to be replaced, it easily can be replaced with a new unit after rotating the carriage

22

so that the image forming unit

21

to be exchanged is located directly under the printer top panel

1

C, and opening the printer top panel

1

C to exchange the image forming unit

21

through the insertion port, as shown in FIG.

2

. As will be explained below, when the image forming units

21

are set properly in the printer main body

1

, mechanical driving systems and electrical connection systems are established between the image forming units

21

and the other parts in the printer main body

1

via mutual coupling members, so that both sides are mechanically and electrically connected. The carriage

22

is driven by the transport motor

23

, and can be rotated around the fixed non-rotating cylindrical shaft

24

, while retaining the image forming units. At the time of image formation, each image forming unit is successively rotated to an image forming position

25

, where it opposes a transfer position between a transfer guide roller

9

and a tension roller

5

, supporting the intermediate transfer belt

4

. The image forming position

25

is also the exposure position for exposure by a pixel laser signal beam

26

. The image forming units

21

perform the image forming operation only in this position, and do not operate at other positions (waiting positions).

FIG. 10

shows an image forming unit. The image forming units differ only with respect to the developer they contain, and all other structural aspects are the same, so that the following explanations only relate to the image forming unit

21

Bk for black, and the explanation for all other colors have been omitted for brevity. The same parts have the same numbers for all colors, and where it is necessary to make a distinction, letters indicating the color are supplemented to the number. In

FIG. 10

, numeral

26

denotes the pixel laser signal beam also shown in

FIG. 1

, numeral

27

denotes an organic photosensitive member using phtalocyanine as the photosensitive material and having a polycarbonate binder resin as a main component, numeral

28

denotes a corona charger for charging the photosensitive member

27

with a negative charge, numeral

29

denotes a grid for keeping the charge potential of the photosensitive member

27

constant, numeral

30

denotes an exposure window that is opened so that the pixel laser signal beam

26

can enter the image forming unit

21

, and numeral

31

Bk denotes a black developer. The developer

31

includes a toner hopper

32

, a developing roller

33

, a magnet

34

, and a doctor blade

35

. Negatively charged black toner

36

Bk, including a polyester resin in which a black pigment has been dispersed, is filled into the toner hopper

32

. This black toner

36

Bk is mixed with a ferrite carrier of 50 μm particle size, whose surface is coated with a silicon resin, and is supported by the surface of the developing roller

33

as a two-component developer

37

Bk, where it develops the photosensitive member

27

. Numeral

38

denotes a cleaner for cleaning off toner that remains on the surface of the photosensitive member

27

after the transfer. This cleaner

38

includes a cleaning blade

39

made of rubber, and a waste toner reservoir

40

for collecting waste toner. The diameter of the photosensitive member

27

is 30 mm, and it rotates with a speed of 100 mm/s in the direction indicated by the arrow. The diameter of the developing roller

33

is 16 mm, and it rotates with a speed of 140 mm/s. The sector angle of the image forming units

21

is 90°, which breaks down into about 30° for the cleaner

38

and about 60° for the developer

31

.

The following is a further explanation of FIG.

1

. In

FIG. 1

, numeral

41

denotes a discharging needle, which prevents the toner image on the recording paper

42

from being corrupted when the recording paper

42

is separated from the intermediate transfer belt

4

(see FIG.

3

). Numeral

43

denotes a retransfer roller, serving as a retransfer means, which abuts the retransfer backup roller

6

(see

FIG. 3

) through the intermediate transfer belt

4

. This retransfer roller

43

rotates 1.5% faster than the intermediate transfer belt

4

, in order to prevent the thinning out of the toner image in the middle.

Numeral

53

denotes a paper feed unit for storing recording paper

42

. This paper feed unit

53

is installed in the lower part of the printer main body

1

. Numeral

54

denotes a paper guide, which serves as a paper conveying path for conveying the recording paper

42

from the paper feed unit

53

to the retransfer roller

43

. Numeral

50

denotes a feeding roller.

Numeral

44

denotes a laser exposure device, which includes a semiconductor laser (not shown in the drawings), a polygon mirror

45

, a lens system

46

, an intermediate mirror

47

, and a laser beam emission window

55

. The laser exposure device

44

is arranged in the space within the outer printer housing

1

D that is enclosed by the carriage

22

, the intermediate transfer belt unit

2

, the paper feed unit

53

, and the paper guide

54

. Numeral

49

denotes a center mirror, whose reflective surface is fixed within a shaft

24

, so that it is less than

30

from the horizontal plane. The laser exposure device

44

irradiates a pixel laser signal beam

26

corresponding to a transient serial electrical pixel signal of image information onto the intermediate mirror

47

. The pixel laser signal beam

26

reflected at the intermediate mirror

47

is irradiated into the beam path window

48

that is formed between the cleaner

38

Y of the yellow image forming unit

21

Y and the developer

31

M of the magenta image forming unit

21

M, through a window that is opened in one portion of the shaft

24

, and onto the center mirror

49

at an elevation angle of 18°, where it is reflected and enters the image forming unit

21

Y, which is positioned at the image forming position

25

, through an exposure window

30

of the image forming unit

21

Y. Then, this pixel laser signal beam

26

is irradiated through a path between the developer

31

Y and the cleaner

38

Y located in an upper and a lower portion in the image forming unit

21

Y, and at an elevation angle of 12° onto an exposure portion of the left side surface of the photosensitive member

27

Y, so as to scan and expose the photosensitive member

27

Y in a main the axial direction.

Since the gap between the wall surfaces of the image forming units

21

Y and

21

M is used for the beam path from the beam path window

48

to the center mirror

49

, almost no space in the carriage

22

is wasted. Moreover, since the center mirror

49

is employed in the center of the carriage

22

, it can be made of a fixed single mirror, which allows a simple configuration with easy alignment etc. Moreover, since the laser exposure device

44

is arranged in the space enclosed by the carriage

22

, the intermediate transfer belt unit

2

, the paper feed unit

53

, and the paper guide

54

, and the rotation plane of the polygon mirror

45

is tilted with respect to the horizontal plane, the space inside the device is used efficiently, which facilitates its miniaturization.

It is preferable that the angle of incidence of the pixel laser signal beam

26

onto the intermediate mirror

47

and the center mirror

49

is not more than 30°. If it is 30° or more, the aberrations of the laser beam in the reflection plane become large, which may lead to a deterioration of the image quality. Moreover, since the image forming position

25

and the laser exposure device

44

have to be arranged so as to be separated from each other, miniaturization becomes difficult.

There is no particular restriction with regard to the orientation of the reflection planes of the intermediate mirror

47

and the center mirror

49

, but it is preferable that they are tilted downward with respect to the horizontal plane, so as to minimize possible staining with toner.

The pixel laser signal beam

26

is irradiated onto the center mirror

49

through the gap between the wall faces of the image forming units

21

Y and

21

M. In other words, sandwiching the beam path of the pixel laser signal beam

26

(i.e. the path between the developer

31

Y and the cleaner

38

Y), which is reflected at the center mirror

49

and irradiated onto the photosensitive member

27

Y, the pixel laser signal beam

26

is irradiated onto the center mirror

49

from the opposite side of the developer

31

Y of the image forming unit

21

Y. With this arrangement, it is also possible to increase the capacity of the toner hopper

32

Bk of the black image forming unit

21

Bk without changing the arrangement of the other structural elements, which can be useful to make the capacity of the black image forming unit, which is used more frequently, larger than that of the other image forming units. For example, the sector angle of the black image forming unit

21

Bk can be 120°, and that of the yellow, magenta, and cyan image forming units

21

Y,

21

M, and

21

C can be 80° each, breaking down into 90° for the developer

31

Bk, 30° for the cleaner

38

Bk, 50° for the developers

31

Y,

31

M, and

31

C, and 30° for the cleaners

38

Y,

38

M, and

38

C.

Numeral

51

denotes a fixing device, which is arranged in an upper portion within the printer main body.

The following is an explanation of a positioning mechanism and a driving mechanism for performing precise color alignment of all colors in the image forming position, with reference to

FIGS. 5

to

9

.

FIG. 5

is an exploded perspective view of the carriage, the positioning mechanism and the driving mechanism for the photosensitive member of the image forming unit.

FIG. 6

is a cross sectional view of the carriage, taken at a plane through the image forming position.

FIG. 7

is a lateral view of an image forming unit and the carriage, taken from the right.

FIG. 8

is a perspective view showing a photosensitive member driving mechanism, which is a photosensitive member driving means for driving the photosensitive member positioned in the image forming position.

FIG. 9

is a lateral view showing a mechanism for positioning the shaft of the photosensitive member at an end surface opposite from the driving mechanism.

As can be seen in

FIGS. 5 and 6

, the carriage

22

has a right wall

520

R and a left wall

520

L, which are fixed to the central shaft

24

. Partition plates

523

for partitioning the carriage

22

into four sections are provided at four places between these walls

520

R and

520

L. An image forming unit

21

for each color is installed in each space in the carriage

22

, which is partitioned with the partition plates

523

. Two partition plates

523

each are fixed in four places inside the carriage

22

. Between each pair of partition plates

523

, a light path is formed, through which the pixel laser signal beam

26

passes. The shaft

24

has a total of eight exposure windows

522

, at positions corresponding to the light path, and at positions where the pixel laser signal beam

26

leaves the shaft

24

after being reflected by the center mirror

49

.

A coupling plate

542

is fixed to the photosensitive member

27

of the image forming unit

21

, and right cutouts

526

for accepting the coupling plate

542

are provided on a portion of the right wall

520

R. A gap is provided between the coupling plate

542

and the right wall

520

R, so that the coupling plate

542

and the right wall

520

R are not in contact at a regular position. The periphery of the left wall

520

L is provided with left cutouts

529

for receiving a collar

543

that is provided at the left end of the photosensitive member shaft. The left cutouts

529

are larger than the outer diameter of the collar

543

, so that the collar

543

and the left cutouts

529

are not in contact at a regular position.

Numeral

525

denotes guide grooves formed on the inner side of the right and left walls

520

R and

520

L. These guide grooves

525

guide the guide pins

545

R and

545

L provided on both side walls of the image forming unit

21

, which is thus positioned roughly in the carriage

22

.

Numeral

530

denotes rotation stop portions, which are connected to the right cutouts

526

in the right wall

520

R of the carriage

22

on the side of the photosensitive member driving mechanism in the axial direction of the photosensitive member

27

. These rotation stop portions

530

couple with the rotation stop pins

531

provided in the right wall of the image forming units

21

, and perform the rotational positioning around the axis of the photosensitive member

27

of the image forming unit

21

at the time of image formation.

The rotation stop portions

530

have a surface that is substantially parallel to the line that connects the axis of the photosensitive member

27

when it is supported at the proper position in the image forming position

25

and the center of the rotation stop pin

531

, and this surface stops the rotation stop pin

531

.

Moreover, when the image forming unit

21

is in the image forming position

25

and performs image formation, clearances are provided between the image forming unit

21

and the carriage

22

, between the coupling board

542

and the right cutout

526

, between the collar

543

and the left cutout

529

, between the guide pins

545

R and

545

L and the guide grooves

525

, and between the outer surface of the image forming unit

21

and all parts of the carriage

22

, as shown in FIG.

7

. In other words, the image forming unit

21

and the carriage

22

do not contact each other except with the rotation stop portion

530

and the rotation stop pin

531

.

Not shown in the drawings are protrusions for preventing the image forming units

21

from dropping out in the centrifugal direction, which are provided at the outer peripheral surface of the right and left walls

520

R and

520

L and which can be advanced and retracted.

Numeral

528

denotes a carriage gear, which is fixed to the left wall

520

L, and which can be connected to a carriage driving mechanism

86

on the main body side, which constitutes a unit conveying means. This carriage driving mechanism

86

comprises a worm gear

89

connected to a driving motor, a worm wheel

88

, and a gear

87

that is formed in one piece with the worm wheel

88

and meshes with the carriage gear

528

.

The carriage

22

is rotatably mounted on the right and left main walls

1

R and

1

L with bearings

546

so that it is parallel to the laser exposing device

44

and the center mirror

49

. The center mirror

49

is fixed to the right and left main walls

1

R and

1

L by supporting members (not shown in the drawings).

The photosensitive member

27

of the image forming unit

21

shown in

FIG. 6

comprises flanges

541

, which are rigidly fixed to each end of the photosensitive member shaft

540

. The photosensitive member shaft

540

is rotatably mounted to the side walls of the image forming unit

21

. A concave tapered surface

548

is formed on the right side of the photosensitive member shaft

540

. The coupling plate

542

is fixed to the photosensitive member shaft

540

and has eight tongues

547

(see

FIG. 5

) that are disposed around the tapered surface

548

. When the coupling plate

542

with this configuration rotates, the photosensitive member shaft

540

is caused to rotate, and at the same time the flanges

541

and the photosensitive member

27

are rotated as well. The collar

543

, which serves as a radial bearing, is attached rotatably on the left edge of the photosensitive member shaft

540

.

A photosensitive member driving mechanism

60

and a detent mechanism

80

, which are both photosensitive member driving means, are employed at the side walls

1

R and

1

L of the printer main body

1

, as shown in

FIGS. 5-8

, to position the photosensitive member

27

precisely at the image forming position

25

.

The photosensitive member driving mechanism

60

, which is attached to the right main wall

1

R, includes an output shaft

70

, which is a photosensitive member supporting member, a coupling plate

61

that rotates together as one piece with the output shaft

70

, an output shaft driving gear

71

, and a driving mechanism for driving these elements. The output shaft

70

is supported rotatably and displaceably in the thrust direction by bearings

77

that are fixed between the right main wall

1

R and a base plate

67

fixed thereto.

One end of the output shaft

70

has a tip-tapered portion

75

, which has a convex tapered surface matching the tapered surface

548

of the photosensitive member shaft

540

. The other end of the output shaft

70

has a spherical shape so as to abut on a thrust bearing

69

with little area. The output shaft driving gear

71

, which is fixed to the output shaft

70

, is a left-handed helical gear, having the same direction as the rotation direction. This output shaft driving gear

71

meshes with a motor-side gear

72

.

Numeral

74

denotes a compression spring

74

, which is inserted between the bearing

77

and the output shaft driving gear

71

. This compression spring

74

is steadily energized toward the position where the output shaft

70

and the coupling plate

61

are separated from the coupling plate

542

of the photosensitive member

27

(position indicated in FIG.

8

). The output shaft

70

can be moved axially against the spring force by the driving means that moves the thrust bearing

69

, between a separated position shown in

FIG. 8 and a

coupling position shown in

FIG. 6

where the tapered surface

548

is coupled with the tip-tapered portion

75

. The motor-side gear

72

has a sufficient length in the axial direction so that the output shaft driving gear

71

engages the motor-side gear

72

in both positions. When the output shaft

70

is moved along the thrust direction, the output shaft driving gear

71

and the motor-side gear

72

slide against each other on the tooth faces.

The coupling plate

61

meshes with the coupling plate

542

on the side of the photosensitive member

27

for the transmission of motive power. The coupling plate

61

has eight coupling tongues

65

, as does the coupling plate

542

, that are disposed on its end. A pin

64

impedes rotation of the coupling plate

61

with respect to the output shaft

70

, but the coupling plate

61

is movable in the thrust direction within a predetermined distance. This way, the coupling plate

61

can retreat temporarily when the tips of the coupling tongues

65

hit the tips of the coupling tongues

547

of the coupling plate

542

. Moreover, this way, the meshing action of the tip-tapered surfaces is not impeded. The compression spring

62

forces the coupling plate

61

against a tip stopper

63

.

Next, the detent mechanism

80

, which is attached to the left main wall

1

L, is explained.

The detent mechanism

80

comprises a guide plate

81

, a detent lever

82

, and a solenoid

85

for moving the detent lever

82

. The guide plate

81

, which is fixed to the left main wall

1

L, guides the collar

543

arranged at the left end of the photosensitive member shaft

540

to position the collar

543

at a proper centrifugal distance from the center of the carriage

22

when the photosensitive member is located near the image forming position

25

. The detent lever

82

is pivoted rotatably on the left main wall

1

L by a stop pin

83

and pushes the collar

543

to the guide plate

81

with a frontal V-groove so as to position the collar

543

correctly in the image forming position

25

.

The detent lever

82

is connected to a plunger of the solenoid

85

via a lever

84

. With this configuration, the solenoid actuates the detent lever

82

by magnetic attraction and the V-groove of the detent lever

82

forces the collar

543

strongly against guide plate

81

.

The output shaft

70

of the photosensitive member driving mechanism

60

and the position of the V-groove of the detent mechanism

80

are kept precisely parallel to the laser exposing device

44

and the center mirror

49

. For this reason, play of the bearings is minimized, so that the photosensitive member

27

is usually located precisely at the image forming position

25

when the photosensitive member driving mechanism

60

and the detent mechanism

80

are actuated.

The following is an explanation of the operation of an image forming apparatus with the above configuration.

First, a full-color image forming process is explained.

FIG. 1

shows an image forming apparatus as it is forming an image. First, a yellow image is formed. The operation of the image forming unit

21

Y is explained with reference to FIG.

10

. At the time of image formation, a voltage of −450V is applied to the grid

29

of the charger

28

, which charges the photosensitive member

27

to −450V. When the pixel laser signal beam

26

is irradiated onto the photosensitive member

27

, a static latent image is formed. After the pixel laser signal beam

26

has passed a lens system

46

, it is reflected twice, once at the intermediate mirror

47

and once at the center mirror

49

, thereby defining a Z-shape (seen in reverse in FIG.

1

), and reaches the photosensitive member

27

. At this time, the exposure potential of the photosensitive member

27

is −50V. The photosensitive member

27

is developed with a developing roller

33

carrying a yellow two-component developer

37

Y. A DC voltage of −250V is applied from a high-voltage source to the developing roller

33

when it passes a region of the photosensitive member

27

that is not yet charged. Thus, a negative-positive reversed yellow toner image is formed only at an image portion on the photosensitive member

27

. At this time, the carriage

22

is in the position shown in

FIG. 1

, the yellow image forming unit

21

Y is in the image forming position

25

, and the photosensitive member

27

is in contact with the intermediate transfer belt

4

. With this image forming process with the image forming unit explained above, an image is formed with yellow toner. The transfer speed of the intermediate transfer belt

4

is set to be about 1.5% faster than the speed of the photosensitive member

27

, which prevents the thinning out of the toner image in the middle. Thus, a yellow toner image is transferred to the intermediate transfer belt

4

simultaneously with the image formation. Moreover, at this time, a DC voltage of +1.0 kV is applied to the transfer guide roller

9

and the tension roller

5

.

After the yellow toner image has been transferred completely onto the intermediate transfer belt

4

, the entire carriage

22

is driven by the transport motor

23

, rotated for 90° in arrow direction Q, and stopped when the image forming unit

21

M has reached the image forming position

25

.

When the carriage

22

stops rotating and the image forming unit

21

M reaches the image forming position

25

, the laser exposure device

44

irradiates a signal beam into the image forming unit

21

M, as before but this time with a magenta signal, so that a magenta toner image is formed and transferred. Up to this point, the intermediate transfer belt

4

has rotated once, and the signal from the position detector

12

controls the timing with which the writing of the magenta signal beam is started, so that the magenta toner image is superimposed onto the previously transferred yellow toner image with positional alignment. During that time, the retransfer roller

43

is retracted to a position where it is not in contact with the intermediate transfer belt

4

, so that the toner image on the intermediate transfer belt

4

is not corrupted.

As is shown in

FIGS. 1 and 3

, the disjunction cam

52

of the printer main body

1

presses down the cam follower

16

, and the cleaning unit

15

rotates in the direction of the arrow P with the rocking axis

15

as the fulcrum, whereby the cleaning blade

7

and the toner catcher

17

are separated from the intermediate transfer belt

4

, so that the toner image on the intermediate transfer belt

4

is not corrupted. Moreover, the cleaning blade

7

contacts an overhanging portion

4

A of the intermediate transfer belt

4

and during the separation of the cleaning blade

7

the toner catcher

17

is further on the side of the intermediate transfer belt

4

than the tip of the cleaning blade

7

, so that when the cleaning blade is separated, waste toner adhering to the cleaning blade

7

does not spill and fall down.

Then, the entire carriage

22

is again driven by the transport motor

23

, rotated 90° in the arrow direction Q in

FIG. 1

, and stopped when the image forming unit

21

C reaches the image forming position

25

. Then, the same operation as for yellow and magenta is repeated for cyan.

Finally, the entire carriage

22

is driven by the transport motor

23

, rotated 90° in the arrow direction Q in

FIG. 1

, and stopped when the image forming unit

21

Bk reaches the image forming position

25

, and image formation is performed with black toner. Superimposing the four color toner images on the intermediate transfer belt

4

with positional alignment, a full-color image is formed. After the final black toner image has been transferred onto the intermediate transfer belt

4

, the retransfer roller

43

is pressed against the retransfer backup roller

6

, a voltage of +3 kV is applied to it, and the four-color toner image is transferred in one piece onto the recording paper

42

, which has been conveyed from the paper feed unit

53

, guided by the paper guide

54

. The recording paper

42

onto which the toner image has been transferred is fixed by passing the fixing device

51

, and ejected from the apparatus.

Then, the entire carriage

22

is driven by the transport motor

23

, rotated 90° in the arrow direction Q in

FIG. 1

, until the image forming unit

21

Y reaches the image forming position

25

again, and the process for forming a new full-color image can be started.

In this manner, 2.5 full-color A

4

-sized print-outs can be obtained per minute.

The following is an explanation of how the intermediate transfer belt unit and the image forming unit can be installed and removed.

As is shown in

FIG. 2

, when the printer front panel

1

A is tilted and opened, an aperture portion is opened. When an intermediate transfer belt unit

2

is inserted into this aperture portion, the intermediate transfer belt unit

2

is guided into a predetermined storage position by a guide member, which is not shown in the drawings, in the direction of the arrow R.

The aperture portion for the removal of paper jams is also an insertion port for inserting the intermediate transfer belt unit

2

, so that there is no need to provide a separate insertion port for the intermediate transfer belt unit

2

, which has a large projected upper surface, in the upper surface of the printer main body

1

. The guiding direction is obliquely downwards, seen from the user, and the intermediate transfer belt unit

2

can be mounted in a natural posture without difficulty. Moreover, since the insertion direction is toward the center mirror

49

, the photosensitive member

27

and the intermediate transfer belt

4

are not damaged, even if it comes to an orthogonal contact between the intermediate transfer belt

4

and the photosensitive member

27

, and the photosensitive member

27

is not retracted while the intermediate transfer belt unit is installed or removed. The intermediate transfer belt unit

2

has a cross-sectional shape that becomes narrower toward the center mirror

49

, so that it can be easily inserted through the aperture portion. Moreover, while reducing the axial distance between the transfer guide roller

9

and the tension roller

5

, so that the positioning of the intermediate transfer belt

4

and the contact pressure with regard to the photosensitive member

27

can be adjusted easily, the capacity of the waste toner reservoir

10

can be enlarged.

In conjunction with the insertion of the intermediate transfer belt unit

2

, the disjunction cam

52

of the printer main body

1

is coupled with the cam follower

16

, and the cleaning blade

7

is separated from the intermediate transfer belt

4

. Therefore, when being stopped or retracted, the cleaning blade

7

is separated from the intermediate transfer belt

4

, so that a deformation of the cleaning blade

7

can be prevented. Only when cleaning is necessary is the disjunction cam

52

rotated, and the cleaning blade

7

contacts the intermediate transfer belt

4

.

When the intermediate transfer belt unit

2

is removed, the coupling between the disjunction cam

52

and the cam follower

16

is released, the cleaning blade

7

contacts the intermediate transfer belt

4

, and the scattering of waste toner is prevented. The angle defined by the removing direction (direction opposite to arrow R) and the direction in which the disjunction cam

52

is pressed, as indicated by the arrow V, is less than 90°, so that the intermediate transfer belt unit

2

can be removed smoothly and without applying unnecessary resistance.

Moreover, to install or remove an image forming unit

21

, the printer top panel

1

C is opened, and a unit other than that in the image forming position

25

(here, the black image forming unit

21

Bk positioned above) can be installed or removed. Therefore, the photosensitive member

27

and the intermediate transfer belt

4

are not damaged, even if the photosensitive member

27

is not retracted while an image forming unit is installed or removed. In this embodiment, the image forming units are inserted substantially in the direction of gravity. Since their projected upper surface area is smaller than that of the intermediate transfer belt unit

2

, they also can be operated easily from the front of the apparatus. It is preferable that this direction of installation and removal is at least 30° and at most 90° with the respect to the direction of installation and removal of the intermediate transfer belt unit

2

. If it is less than 30°, the capacity of the toner hopper

32

of the developer

31

in the image forming position

25

cannot be sufficiently ensured, and if it is more than 90°, then the user has to insert from the back toward the front, which is very inconvenient.

The following is an explanation of the operation of the device with the driving mechanism.

When all image units

21

are installed in the carriage

22

, the worm gear

89

is rotated by actuating the transport motor

23

, and the carriage

22

is rotated in the arrow direction to position the yellow image forming unit

21

Y in the image forming position

25

. When the carriage

22

rotates, the output shaft

70

of the photosensitive member driving mechanism

60

retreats due to the energization of the spring

74

, so that the tip-tapered portion

75

and the coupling board

61

are separated from the coupling board

542

on the photosensitive member side. Furthermore, in this situation, the solenoid

85

of the detent mechanism

80

is turned off, and the detent lever

82

recedes to the position indicated by the dashed line in FIG.

9

. Furthermore, in this situation, the motor driving the photosensitive member driving mechanism

60

, which is not shown in the drawings, stops. The yellow photosensitive member

27

Y slides and moves along the surface of the intermediate transfer belt

4

, and when it comes near the image forming position

25

, the transport motor

23

stops, the worm gear

89

stops, and the carriage

22

is locked in this position.

When the carriage

22

stops, the solenoid

85

of the detent mechanism

80

is immediately turned on, so that the detent lever

82

forces the collar

543

of the photosensitive member shaft

540

against the guide plate

81

. A specified position is assumed while holding the collar

543

with the V-groove of the detent lever

82

.

Simultaneously, the thrust bearing

69

pushes the output shaft

70

against the resistance of the spring force to the left in FIG.

6

. As the output shaft

70

is pushed to the left in

FIG. 6

, the tip-tapered portion

75

of the output shaft

70

starts to couple with the tapered surface

548

of the photosensitive member shaft

540

and advances while shifting the photosensitive member shaft

540

so as to align it with the center of the output shaft

70

. When the thrust bearing

69

pushes the output shaft

70

further to the left in

FIG. 6

, the tip-tapered portion

75

engages the tapered surface

548

, and the center of the photosensitive member shaft

540

aligns completely with the center of the output shaft

70

. Thus, the photosensitive member

27

Y is positioned precisely in the image forming position

25

. In this situation, the thrust from the output shaft

70

pushes the end of the flange

541

against the side wall bearings of the image forming unit

21

Y, and abuts on the left side wall

520

L of the carriage

22

, so that it is stopped by the left side wall

520

L. Furthermore, when the tip-tapered portion

75

engages the tapered surface

548

, the coupling plates

542

and

61

engage each other, so that a rotational force can be transmitted between the two.

In this manner, the yellow photosensitive member

27

Y is positioned precisely by the detent mechanism

80

and the photosensitive member driving mechanism

60

. Then, the image forming unit

21

Y, which includes the photosensitive member

27

Y, is moved with the photosensitive member

27

Y in the carriage

22

. Since the image forming unit

21

Y is retained freely inside the carriage

22

, the carriage

22

does not hinder the movement of the image forming unit

21

Y when it is being positioned. Although the carriage

22

has some clearance in the rotation direction such as a backlash between the spur gear

528

and the gear

87

, this does not affect the precise positioning of the photosensitive member

27

Y, since the photosensitive member

27

Y is positioned by the positioning mechanism on the main body side and not with the carriage

22

.

In this situation, the image forming unit

21

Y is supported to be freely rotatable with the photosensitive member

27

Y in the center.

After the positioning of the photosensitive member

27

Y is completed, the motor for driving the photosensitive member starts to rotate the photosensitive member

27

Y. As the motor and the photosensitive member start to move, all process elements start to operate, and subsequently a yellow toner image is formed on the photosensitive member

27

Y, which is subsequently transferred onto the intermediate transfer belt

4

.

During this image forming operation, the output shaft

70

is still pushed by the thrust bearing

69

to the left, and the solenoid

85

is still actuated, so that the detent lever

82

retains the collar

543

. Moreover, the rotation load of the photosensitive member

27

Y tends to rotate the image forming unit

21

Y counterclockwise around the photosensitive member shaft

540

, but the coupling between the rotation stop portion

530

and the rotation stop pin

531

determines the rotational orientation of the image forming unit

21

Y. At this time, the image forming unit

21

and the carriage

22

are retained in a manner that they do not contact each other at other places than the rotation stop portion

530

and the rotation stop pin

531

. The rotation stop portion

530

couples with the rotation stop pin

531

in a plane that is parallel to the line connecting the axis of the photosensitive member

27

Y and the center of the rotation stop pin

531

, so that no excessive reactive force acts on the coupling portion of the tip-tapered portion

75

and the tapered surface

548

.

It is also preferable that the rotation stop portion

530

and the rotation stop pin

531

do not contact each other while the image forming unit

21

Y is being positioned, and that they are devised so as not to disturb the positioning operation.

When the intermediate transfer belt

4

has performed one full rotation (while the photosensitive member

27

Y rotates four times), the yellow image formation is complete, the motor stops, and the intermediate transfer belt

4

stops at its initial position.

When the intermediate transfer belt

4

and the photosensitive member

27

Y have stopped, the solenoid

85

is turned off, thus releasing the detent lever

82

. Simultaneously, the thrust bearing

69

retreats to the right. The driving shaft

70

recedes due to the force of the spring

74

, and the coupling plate

61

and the tip-tapered portion

75

are separated from the coupling plate

542

and the photosensitive member shaft

540

. Thus, the positioning of the photosensitive member

27

Y is released and it becomes possible to rotate the carriage

22

.

The output shaft

70

is rotated counterclockwise when facing the photosensitive member

27

Y, but when the motor stops and the photosensitive member

27

Y is stopped, there is a rotation load on the photosensitive member

27

Y, so that in some cases there is still a pressure force on the side faces of the coupling tongues

65

and the coupling tongues

547

on the photosensitive member side. In this situation, friction forces act on the side faces of the tongues, and it becomes difficult to pull out the coupling plate

61

from the coupling plate

542

. In this embodiment, the output shaft driving gear

71

is made of a helical gear, which is left-handed, the same as the rotation direction, so that the coupling plate

61

is pulled out while rotating by only the twisting amount of the tooth faces in a direction that is opposite to the driving direction of the photosensitive member

27

. As a result, there are no friction forces on the side faces of the tongues, so that the coupling plate

61

can be pulled out easily from the coupling plate

542

.

Moreover, in this embodiment, the coupling operations of the detent mechanism

80

and the output shaft

70

in the thrust direction are performed simultaneously, but when a force acts in the lateral direction on the coupling tongues

65

and the coupling tongues

547

on the photosensitive member side, a friction force acts between the tongues, and attaching and removing it becomes a little bit difficult. Consequently, it is preferable that the axes of the output shaft

70

and the photosensitive member shaft

540

are aligned as good as possible at the time of coupling. Therefore, at the time of attachment, the detent mechanism

80

is operated first to position the photosensitive member shaft

540

, and then the output shaft

70

is moved, and the attaching and removing operation can be performed more precisely and smoothly than when the output shaft

70

is operated before the detent mechanism

80

. Especially in a configuration where at the time of removing the output shaft

70

is separated by the force of the spring

74

, it is difficult to separate the tongues when there is a load on the coupling portion, so that it is effective to have the operation of the detent mechanism

80

performed after the operation the output shaft

70

.

Moreover, in this embodiment, the output shaft

70

is returned with the force of the spring

74

, but it is also possible to force it back with a driving mechanism on the side of the thrust bearing

69

.

After the coupling between the photosensitive member shaft

540

and the output shaft

70

is released, the worm gear

89

is rotated again, and the carriage

22

is rotated 90° in the arrow direction indicated in FIG.

1

. This moves the next, magenta image forming unit

21

M near the image forming position

25

, where it is stopped. Then, the photosensitive member driving mechanism

60

and the detent mechanism

80

are actuated, and the magenta photosensitive member

27

M is positioned. After this, the photosensitive member shaft

540

and the output shaft

70

are coupled, and the image forming operation for the second color begins.

In this manner, the switching operation and the image forming operation are repeated in sequence, so that a four-color image is formed on the intermediate transfer belt

4

, which is then transferred onto the recording paper

42

.

In the present embodiment, a 90 degree rotation of the carriage

22

takes about 0.6 sec, and the attach and the detach operation for coupling and decoupling the output shaft

70

take 0.2 sec each.

Thus, in this embodiment, the tip-tapered portion

75

of the output shaft

70

is coupled with the tapered surface

548

of the photosensitive member

27

, and the photosensitive member

27

is positioned at the proper position inside the printer main body

1

. Moreover the image forming units

21

are supported freely rotatably, and the rotation stop portion

530

couples with the rotation stop pin

531

, which determines the rotational orientation of the image forming unit

21

, whereby it is possible to precisely and reliably retain photosensitive members

27

and image forming units

21

at their correct position in the printer main body with a simple configuration, even when a plurality of different photosensitive members

27

is used. As a result, it is possible to realize an image forming apparatus that can output high-quality color images.

Moreover, by providing rotation stop portions

530

on the photosensitive member driving mechanism side, the parts where loads act can be concentrated in the vicinity thereof, so that by raising the precision and the robustness of this part, the positioning can be made more reliable. As a result, it is possible to realize an image forming apparatus that can output high-quality color images.

Moreover, the rotation stop portion

530

couples with the rotation stop pin

531

in a plane that is parallel to the line connecting the axis of the photosensitive member

27

and the center of the rotation stop pin

531

, so that no excessive reactive forces act on the output shaft

70

and the tip-tapered portion

75

, and the photosensitive member

27

can be retained even more reliably.

Moreover, since the rotation stop portions

530

are arranged in the carriage

22

, the rotation stop portions can be provided in a position near to the image forming units

21

. As a result, it is possible to stop the rotation of the image forming units

21

reliably and without providing large protrusions or the like in the image forming units

21

or the apparatus main body.

Second Embodiment

The following is an explanation of a second embodiment of an image forming apparatus in accordance with the present invention, with reference to

FIGS. 11

to

13

.

FIG. 11

is a cross sectional view of the carriage, taken through the image forming position.

FIG. 12

is a perspective view showing the photosensitive member driving mechanism, which is a photosensitive member driving means for driving the photosensitive member positioned in the image forming position, and the developer driving mechanism, which is a developer driving means for driving the developer.

FIG. 13

is a lateral view of an image forming unit and the carriage, taken from the right side.

Numeral

550

denotes a developer driving input gear for inputting from the apparatus main body a motive force that drives the developer

31

. This developer driving input gear

550

is attached to an input shaft

551

, which protrudes from the right surface of the image forming unit

21

. The right cutout

526

(see

FIG. 5

) provides a cutout shape, which ensures that the coupling plate

542

and the developer driving input gear

550

are not in contact at the correctly positioned position. Numeral

552

denotes a developer driving gear, which, together with the remaining developing driving mechanism, constitutes a developer driving means. Numeral

554

denotes a bearing fixed to the right main wall

1

R, which rotatably supports the driving shaft

553

. The developer driving gear

552

is attached to a driving shaft

553

, is driven by a driving motor not shown in the drawings, and meshes with the developer driving input gear

550

of the image forming unit

21

positioned in the image forming position

25

.

As shown in

FIG. 11

, the rotation stop pin

531

, which is on the side of the developer driving means, is a little bit more elongated than in the first embodiment, and the tapered surface

548

, which is at the supporting position in the axis of the photosensitive member

27

, the position where the developer driving input gear

550

, which is in the driving force transmission position, meshes with the developer driving gear

552

, and the position where the rotation stop portion

530

stops the rotation are arranged on substantially the same plane, which is perpendicular to the axis of the photosensitive member

27

.

The arrow F in

FIG. 13

indicates the direction of the driving force of the developer driving gear

552

when the developer driving input gear

550

in the image forming position

25

meshes with the developer driving gear

552

, and numeral

555

indicates the action line in which this driving force F acts. The rotation stop portion

530

stops the rotation stop pin

531

substantially perpendicularly to the action line

555

and near the action line

555

.

Numeral

556

denotes a thrust guide, which is a thrust stop portion, and this thrust guide

556

is provided at the right wall

520

R near the axis of the photosensitive member

27

.

Moreover, at the left end of the photosensitive member shaft

540

, which forms the axis of the photosensitive member

27

, a tapered surface

561

is formed, similar to the tapered surface

548

on the right end.

Numeral

557

denotes a detent mechanism provided in the left main wall

1

L. The detent mechanism

557

includes a detent shaft

558

, which is a photosensitive member supporting member, and a driving mechanism for driving the same. A bearing

560

, which is fixed between the left main wall

1

L and the panel

559

attached thereto supports the detent shaft

558

so that it is movable in the thrust direction. A tip-tapered portion

562

having a convex tapered surface that matches the tapered surface

561

is formed on one end of the detent shaft

558

, whereas the other end has a spherical shape so as to abut on a thrust bearing

563

with little area. Numeral

564

denotes a compression spring that is inserted between the bearing

560

and a stop ring

565

. The compression spring

564

is steadily energized in the position where the detent shaft

558

is separated from the tapered surface

561

on the left end of the photosensitive member shaft

540

. A driving means for moving the thrust bearing

563

can move the detent shaft

558

into a coupling position shown in

FIG. 11

where the tapered surface

561

engages the tip-tapered portion

562

and a position where it is separated by the compression spring

564

.

The following is an explanation of the operation of an image formation apparatus configured as above. Explanations for parts that are the same as in the first embodiment have been omitted.

The carriage

22

rotates and carries the yellow image forming unit

21

Y into the image forming position

25

. At this time, the output shaft

70

of the photosensitive member driving mechanism

60

and the detent shaft

558

of the detent mechanism

557

are receded due to the energization of the springs

74

and

564

, and the tip-tapered portion

75

with the coupling plate

61

is separated from the coupling plate

54

on the photosensitive member side. Also the tip-tapered portion

562

of the detent shaft

558

and the tapered surface

561

of the photosensitive member shaft

540

are separated. The motor for driving the photosensitive member driving mechanism

60

, which is not shown in the drawings, is stopped. The yellow photosensitive member

27

Y slides and moves along the surface of the intermediate transfer belt

4

, and when it comes near the image forming position

25

, the transport motor

23

stops, the worm gear

89

stops, and the carriage

22

is locked in this position.

When the carriage

22

stops, the thrust bearings

69

and

563

immediately push the output shaft

70

and the detent shaft

558

against the spring forces toward the photosensitive member shaft

540

. As the output shaft

70

and the detent shaft

558

are pushed toward the photosensitive member shaft

540

, the tip-tapered portions

75

and

562

start to engage the tapered surfaces

548

and

561

of the photosensitive member shaft

540

and advance while the output shaft

70

and the detent shaft

558

align the photosensitive member shaft

540

with the axes of the output shaft

70

and the detent shaft

558

. This aligns the tip-tapered portions

75

and

562

with the tapered surfaces

548

and

561

. As the thrust bearings

69

and

563

push the output shaft

70

and the detent shaft

558

further toward the photosensitive member shaft

540

, the axis of the photosensitive member. shaft

540

aligns completely with the axis of the output shaft

70

and the detent shaft

558

, so that the photosensitive member

27

Y is positioned precisely in the image forming position

25

. In this situation, the thrust force exerted by the detent shaft

558

is set to be larger than the thrust force exerted by the output shaft

70

, whereby the side wall bearing portion of the image forming unit

21

Y is pushed and received by the thrust guide

556

provided in the right wall

520

R of the carriage

22

. Furthermore, when the tip-tapered portion

75

couples with the tapered surface

548

, the coupling plates

542

and

61

couple with each other, so that a rotational force can be transmitted between the two.

Incidentally, the strength of the force pushing into the thrust direction should take into account not only the pushing forces of the output shaft

70

and the detent shaft

55

, but also the pushing forces in the thrust direction due to spring-shaped electrical contacts etc.

By operating the detent mechanism

557

and the photosensitive member driving mechanism

60

in this manner, the yellow photosensitive member

27

Y is positioned precisely. Since the thrust guide

556

is provided near the photosensitive member shaft

540

, the torque around the coupling portion between the tip-tapered portion

75

and the tapered surface

548

becomes small, and the tip-tapered portions

75

and

562

can be aligned smoothly with the tapered surfaces

548

and

561

, even when for example a difference in the timing for the positioning of the image forming unit

21

Y inside the carriage

22

and the aligning of the tip-tapered portions

75

and

562

with the tapered surfaces

548

and

561

tilts the image forming unit

21

Y inside the carriage

22

during the positioning of the photosensitive member

27

Y.

It is preferable that the thrust guide

556

is ring-shaped with the photosensitive member shaft

540

at its center. Moreover, it is advantageous if the coupling of the tip-tapered portion

75

and the tapered surface

548

is completed prior to the coupling of the tip-tapered portion

562

and the tapered surface

561

, so that the thrust guide

556

receives the image forming unit

21

Y before the tapered portion

75

is sufficiently aligned with the tapered surface

548

.

Moreover, in this situation, the image forming unit

21

Y is supported to be freely rotatable around the axis of the photosensitive member

27

Y.

After the positioning of the photosensitive member

27

Y is completed, the motor for driving the photosensitive member starts to rotate, whereby the photosensitive member

27

Y starts to rotate. A very short time thereafter, the motor for driving the developer starts to rotate. As these motors start to move, all process elements start to operate, and a yellow toner image is formed subsequently on the photosensitive member

27

Y, which is then transferred subsequently onto the intermediate transfer belt

4

.

During this image forming operation, the output shaft

70

and the detent shaft

558

are pushed by the thrust bearings

69

and

563

. Moreover, the driving force F of the developer driving gear

552

exerts a torque on the image forming unit

21

Y with the axis of the photosensitive member

27

Y in the center, but since the rotation stop portion

530

stops the rotation stop pin

531

on a surface that is at a position near the action line

555

of the driving force F and substantially perpendicular to it, the driving force F is cancelled by the counter-force of the rotation stop portion

530

, so that it hardly influences the coupling portion between the tip-tapered portion

75

and the tapered surface

548

.

Moreover, since the position where the tip-tapered portion

75

couples with the tapered surface

548

, the position where the developer driving input gear

550

couples with the developer driving gear

552

, and the rotation stop position of the rotation stop portion

530

are all substantially in one plane that is perpendicular to the axis of the photosensitive member

27

, the torque around the position where the tip-tapered portion

75

is coupled with the tapered surface

548

is cancelled, so that it hardly influences the coupling portion between the tip-tapered portion

562

and the tapered surface

561

.

In rare cases, the pushing force of the thrust bearings

69

and

563

is not enough to align the tip-tapered portions

75

and

562

with the tapered surfaces

548

and

561

, but when the motor for driving the photosensitive member starts to rotate, all parts move relatively to each other, so that the tip-tapered portions

75

and

562

are sufficiently aligned with the tapered surfaces

548

and

561

. Also in this case, since the motor for driving the developer starts to turn within a short time after the motor for driving the photosensitive member, this movement is not impeded.

When the intermediate transfer belt

4

has rotated once, the yellow image forming is finished, the motor stops, and the intermediate transfer belt

4

stops in its initial position.

When the intermediate transfer belt

4

and the photosensitive member

27

Y have stopped, the thrust bearings

69

and

563

recede to the left and right, the springs

74

and

564

retract the output shaft

70

and the detent shaft

558

, the coupling plate

61

and the tip-tapered portion

75

are separated from the coupling plate

542

and the photosensitive member shaft

540

, while the tip-tapered portion

562

is separated from the tapered surface

561

, and the carriage

22

becomes rotatable and shiftable.

In this embodiment, the output shaft

70

and the detent shaft

558

are returned by the force of the springs

74

and

564

, but it is also possible that a driving mechanism on the side of the thrust bearings

69

and

563

forces them back.

When the coupling and the detention are released, the worm gear

89

rotates again, and the carriage

22

rotates 90°. This moves the next, magenta image forming unit

21

M near the image forming position

25

, where it is stopped. Then, the detent mechanism

80

and the photosensitive member driving mechanism are actuated, and the magenta photosensitive member

27

M is positioned. After this, the photosensitive member shaft

540

is coupled with the output shaft

70

and the detent shaft

558

, and the image forming operation for the second color begins.

In this manner, the switching operation and the image forming operation are repeated in sequence, so that a four-color image is formed on the intermediate transfer belt

4

, which is then transferred onto the recording paper.

With this configuration, providing a rotation stop portion

530

on the developer driving mechanism side makes it possible to concentrate the parts on which loads act in the vicinity thereof, so that by increasing the precision and the robustness of this part, the positioning can be made more reliable. As a result, it is possible to realize an image forming apparatus that can output high-quality color images.

Moreover, letting the position where the tip-tapered portion

75

couples with the tapered surface

548

, the position where the developer driving input gear

550

couples with the developer driving gear

552

, and the rotation stop position of the rotation stop portion

530

be all substantially in one plane that is perpendicular to the axis of the photosensitive member

27

cancels the torque around the position where the tip-tapered portion

75

couples with the tapered surface

548

, so that the driving force of the developer driving gear

225

hardly influences the coupling portion between the tip-tapered portion

562

and the tapered surface

561

, and it is possible to precisely and reliably retain the photosensitive members

27

and the image forming units

21

at their correct position in the printer main body with a simple configuration. As a result, it is possible to realize an image forming apparatus that can output high-quality color images.

Moreover, employing a configuration in which the rotation stop portion

530

stops the rotation stop pin

531

at a surface that is perpendicular to the action line

555

makes it possible to retain the photosensitive members

27

more reliably and without exerting excessive counter-forces on the detent shaft

558

and the tip-tapered portion

562

.

In addition, employing a configuration in which the rotation stop portion

530

stops the rotation stop pin

531

near the action line

555

, makes it possible to retain the photosensitive members

27

more reliably and almost without exerting counter-forces on the detent shaft

558

and the tip-tapered portion

562

.

In addition, employing a configuration in which the motor for driving the developer starts to rotate a short time after the motor for driving the photosensitive member, all parts move relatively to each other even when the pushing force of the thrust bearings

69

and

563

is not enough to align the tip-tapered portions

75

and

562

with the tapered surfaces

548

and

561

, so that the tip-tapered portions

75

and

562

are sufficiently aligned with the tapered surfaces

548

and

561

. Thus, it is possible to precisely and reliably retain the photosensitive members

27

and the image forming units

21

at their correct position in the printer main body

1

with a simple configuration. As a result, it is possible to realize an image forming apparatus that can output high quality color images.

Moreover, providing the thrust guide

556

near the photosensitive member shaft

540

reduces the torque around the coupling portion between the tip-tapered portion

75

and the tapered surface

548

, and the tip-tapered portions

75

and

562

can be aligned smoothly with the tapered surfaces

548

and

561

, even when the image forming unit

21

Y is tilted inside the carriage

22

.

Moreover, providing the rotation stop portion

530

and the thrust guide

556

on the same side with respect to the axis of the photosensitive member

27

makes it possible to concentrate members related to positioning in the vicinity thereof, and to increase the positioning precision.

It is also possible to provide either the developer driving input gear

550

or the developer driving gear

552

of this embodiment with play, so that they are not damaged when their teeth abut each other when meshing.

Moreover, “substantially the same plane” means to an extent where no excessive counter-force acts on the detent shaft

558

and the tip-tapered portion

562

, and there is no problem in practice if it is within a distance not more than {fraction (1/20)} of the distance of the supporting positions on both sides of the photosensitive member

540

.

Moreover, it is also possible to provide the thrust guide

556

on the side of the image forming units

21

, and it also can be provided directly in the apparatus main body.

Third Embodiment

FIG. 14

is a lateral view of an image forming unit and a part of a carriage in accordance with a third embodiment of the present invention.

In

FIG. 14

, numeral

566

denotes the center of gravity of the image forming unit

21

positioned in the image forming position, and arrow G indicates the direction of the gravitational force acting in the center of gravity

566

. In this configuration, the torque that the gravitational force G exerts on the image forming unit

21

with respect to the axis of the photosensitive member

27

is opposite to the direction of the torque on the axis of the photosensitive member

27

caused by the developer driving gear

552

. Moreover, in this configuration, the size of the torque due to the gravitational force G is smaller than the size of the torque due to the developer driving gear

552

. Other configurational and operational aspects are the same as in the second embodiment, so that their explanation has been omitted.

When the motor for driving the developer starts to rotate, the driving force F exerts a torque in arrow direction H on the image forming unit

2

. The gravitational force G exerts a torque around the photosensitive member

27

that acts in the direction opposite to the arrow H. In this situation, since the size of the torque caused by the gravitational force G is smaller than the size of the torque caused by the developer driving gear

552

, the image forming unit

21

receives a torque in the direction of arrow H that corresponds to the difference between these torques. The rotation stop force of the image forming unit

21

acting on the rotation stop portion

530

is reduced by this difference, and the danger that the position of the image forming unit

21

is displaced in the rotational orientation becomes smaller than if it receives only the driving force F, so that reliable positioning in the rotational orientation becomes possible. The center of gravity

566

changes with time, as it depends on the amount of toner in the toner hopper

32

and the amount of waste toner in the waste toner reservoir

40

, and a configuration is preferable where the above-noted relation stays established during this temporal change. Moreover, it is preferable that the line running vertically through the center of gravity passes between the axis of the photosensitive member

27

and the contact point

590

where the rotation stop portion

530

contacts the rotation stop pin

531

, because this way the temporal change of the torque due to the gravitational force G can be reduced.

With this embodiment, the torque around the photosensitive member

27

caused by the gravitational force G acts in the direction opposite to the direction of the torque around the photosensitive member caused by the developer driving gear

552

, and the size of the torque caused by the gravitational force G is smaller than the size of the torque caused by the developer driving gear

552

, whereby the rotation stop force of the image forming unit

21

on the rotation stop portion

530

can be reduced, and positioning can be performed reliably, because the rotation stop portion is not separated due to the torque around the axis of the photosensitive member

27

caused by the gravitational force G.

The above examples have been explained by way of examples relating to the case of four image forming units

21

of the colors black, yellow, magenta and cyan, but there is no limitation on the type of colors and their number. Moreover, it is also possible to use image forming units with different capacities.

The diameter of the photosensitive members

27

has been given as 30 mm and its circumferential speed as 100 mm/s, but there is no limitation on the diameter and the peripheral speed of the photosensitive members

27

. Moreover, the process conditions, such as the developing method, the applied voltages, the circumferential speed of the intermediate transfer belt

4

, are not limited to those given as examples in the above embodiments. For example, it is also possible to use a non-magnetic one-component developing process.

Moreover, the configuration of the intermediate transfer belt unit

2

is also not limited to the configuration shown in the above embodiments. There are no limitations on the number of rollers spanning the intermediate transfer belt

4

, or their diameters. Moreover, a cleaning blade

7

is used for the belt cleaning means, but the belt cleaning means and its position are arbitrary. Moreover, if the life-expectancy of the intermediate transfer belt

4

is more or less the same as the life-expectancy of the printer main body

1

, and there is no need to exchange the intermediate transfer belt

4

, a configuration is also possible to have the intermediate transfer belt unit

2

is not removable from the printer main body

1

.

Moreover, a retransfer roller

43

is used as a retransfer means, but it is also possible to use another transfer means, such as a coroner charger.

Moreover, the photosensitive member shaft

540

does not have to be a pierced shaft. For example, it is also possible that it is provided as one piece with the left and right flanges

541

.

Moreover, the tapered surfaces

548

and

561

do not have to be provided at the ends of the protruding photosensitive member shaft

540

. For example, it is also possible that tapered surfaces are provided as holes in the left and right flanges

541

or in the coupling plate

542

.

Moreover, the above-noted embodiments have been explained by way of examples relating to cases in which the rotator of the positioned image forming units

21

is the photosensitive member

27

, but the rotator is not limited to the photosensitive member

27

, and also can be, for example, the developing roller

33

, which is a structural member of the image forming unit

21

.

Fourth Embodiment

The following is an explanation of the entire configuration and operation of a fourth embodiment of an image forming apparatus in accordance with the present invention, with reference to

FIGS. 15

to

21

.

Image Forming Units

In

FIG. 15

, numeral

201

denotes an image forming unit, integrating the process elements that are arranged around each of the various photosensitive members

202

of the colors yellow, magenta, cyan, and black. Each image forming unit is made of the following parts.

The photosensitive member

202

is made of a cylinder of aluminum, onto whose surface an organic photosensitive layer is formed. Numeral

203

denotes a corona charger for evenly charging the photosensitive member

202

with a negative charge. Numeral

204

denotes a developer including a developing roller

205

for carrying toner. Numeral

206

denotes a toner hopper. The toner hopper

206

contains a toner

207

that can be negatively charged and is made of polyester resin and a pigment dispersed in the resin.

While contacting the photosensitive member

202

, the developing roller

205

rotates at a higher speed than the photosensitive member

202

. In the contact portion, latent images on the photosensitive member

202

are developed. Numeral

208

denotes a cleaning blade made of rubber for cleaning off toner remaining on the surface of the photosensitive member

202

after the transfer. Numeral

209

denotes a waste toner reservoir for collecting waste toner. Numeral

210

denotes an exposure window, which is opened so that a laser beam can enter the image forming unit

201

. The photosensitive member

202

has a diameter of 30 mm, and the developing roller

205

has a diameter of about 16 mm. The photosensitive member

202

and the developing roller

205

are mounted rotatably on side walls of the image forming unit

201

.

Structure of the Entire Apparatus

As shown in

FIG. 16

, the right side of which corresponds to the front side of the apparatus, a carriage

211

is provided in the back, a front door

212

is provided in the front and a top door

213

is provided at the top of the apparatus main body.

The carriage

211

carries four color image forming units

201

Y,

201

M,

201

C, and

210

Bk for yellow, magenta, cyan, and black. The carriage

211

is mounted so as to be rotatable around a cylindrical shaft

214

. Thus, each image forming unit

201

can be rotated successively between the image forming position P and waiting positions, so as to switch the image forming units

201

. The image forming units

201

operate only when they are located at the image forming position P, where the intermediate transfer belt unit

215

and the photosensitive member

202

are in contact. All other positions are waiting positions, where the image forming units

201

do not operate.

A clearance of about 2 mm is provided in the radial direction and the in circumferential direction between the image forming units

201

and the carriage

211

, whereby the image forming units

201

are retained movably in the carriage

211

. Consequently, the carriage

211

moves the image forming units

201

near the image forming position, but it does not perform the precise positioning of the image forming units

201

.

The image forming units

201

are mounted removably in the apparatus main body. When an image forming units

201

needs to be replaced, it can be replaced by a new unit after rotating the carriage

211

so that the image forming unit

201

to be exchanged is located underneath the top door

213

, and opening the door

213

.

The transfer belt unit

215

includes an intermediate transfer belt

216

, a driving roller

217

A, a tension roller

217

B, and a supporting roller

217

C for suspending the intermediate transfer belt

216

, a cleaner

218

, and a waste toner case

219

for collecting waste toner. When the transfer belt unit

215

is mounted in the apparatus main body, the intermediate transfer belt

216

contacts the photosensitive member

202

that is positioned in the image forming position P. At the same time, each portion of the transfer belt unit

215

is electrically connected to the main body and the driving roller

217

A is connected to a driving means on the main body side, so that the intermediate transfer belt

216

can rotate.

Numeral

220

denotes an exposure device for emitting a laser signal beam

221

in correspondence with the image information. The laser signal beam

221

passes through the light path formed between the yellow image forming unit

201

Y and the magenta image forming unit

201

M. Then, the laser signal beam

221

passes a window (not shown in the drawing) in a portion of the cylindrical shaft

214

, and is irradiated onto a mirror

222

(fixed to the apparatus main body) inside the cylindrical shaft

214

, where it is reflected, and enters the image forming unit

201

Y that is positioned in the image forming position P through an exposure window

210

of the yellow image forming unit

201

Y. Thereby, the laser signal beam

221

is irradiated onto an exposure portion on the left side of the photosensitive member

202

and scans in the axial direction to expose the photosensitive member

202

.

Numeral

223

denotes a paper feed unit. Numeral

224

denotes a paper feed roller, numeral

225

denotes a resist roller, and numeral

226

denotes a paper eject roller. These rollers form a paper path together with the contact point where the intermediate transfer belt

216

contacts the secondary transfer roller

227

, and a fixing device

228

.

Operation of the Apparatus

The following is an explanation of the color image forming process.

When the transfer belt unit

215

and all image forming units

201

are installed in their predetermined locations, the power for the apparatus main body is turned on, and the fixing device

228

is heated up, while the polygon mirror of the exposing device

220

starts to revolve, thus completing the preparations.

After these preparations are completed, first, an initialization operation is performed to move the image forming unit

201

of the color to be recorded to the image forming position P. In this initialization operation, the carriage

211

, which retains all image forming units

201

, rotates, and the image forming unit

201

of the color to be recorded first (in the present embodiment the yellow image forming unit

201

Y) is moved into the image forming position P in the apparatus main body, where it stops. Thereafter, the positioning and driving mechanism, which will be explained in more detail later, engages the photosensitive member

202

, which positions the photosensitive member

202

precisely, while the photosensitive member

202

is rotatable.

First of all, the image formation process of the yellow image forming unit

201

Y, which is positioned in the image forming position P, begins. The motor (not shown in the drawing) that is the driving motor at the apparatus main body, starts to rotate the yellow photosensitive member

202

in the image forming position P, and at the same time, the driving roller

217

A is driven from the main body, and friction forces rotate the intermediate transfer belt

216

in the arrow direction. At the same time, the charger

203

and the developer

204

start to operate as well. On the other hand, the secondary transfer roller

227

and a fur brush

230

of the cleaner are separated from the intermediate transfer belt

216

.

FIG. 17

is a cross sectional view showing a position detection portion for detecting the position of the intermediate transfer belt, including a position detection hole provided in the intermediate transfer belt and an optical position detection sensor. After the intermediate transfer belt

216

has been started and has reached a certain speed, the position detection hole

231

provided in the intermediate transfer belt

216

passes the detection sensor

232

. At this time, the position sensor

232

generates a timing reference signal. The laser signal beam

221

emitted from the exposing device

220

forms the static latent image on the photosensitive member

202

in synchronization with this reference signal.

This static latent image is subsequently made manifest by the developing device

204

, and a toner image is formed. At a primary transfer position where the photosensitive member

202

contacts the intermediate transfer belt

216

, this toner image is transferred onto the intermediate transfer belt

216

. When the end of the image has been copied onto the intermediate transfer belt

216

, the yellow image formation is finished, and the intermediate transfer belt

216

stops in the initialization position.

At the time of image formation, the charger

203

charges the photosensitive member

202

at −450V. The exposing potential of the photosensitive member

202

is −50 volts. A DC voltage of +100V is applied from a high-voltage source to the developing roller

205

, when it passes a region of the photosensitive member

202

that is not yet charged. Then, when the surface of the photosensitive member

202

, onto which a static latent image has been inscribed, passes the developing roller, a DC voltage of −250V is applied from a high-voltage source to the developing roller

205

. A DC voltage of +1.0 kV is applied to the driving roller

217

A and the tension roller

217

B of the intermediate transfer belt

216

, and the supporting roller

217

C is maintained at ground potential.

When yellow image formation is finished and the photosensitive member

202

and the intermediate transfer belt

216

stop, the coupling between the yellow photosensitive member

202

and the positioning and driving mechanism is released, and the carriage

211

rotates 90° in the arrow direction shown in FIG.

16

. This moves the yellow image forming unit

201

Y away from the image forming position P, and the next, magenta image forming unit

201

M is positioned and stopped in the image forming position P. Below, this operation is referred to as “switching operation” for switching the image forming units.

When the magenta image forming unit

201

M stops in the image forming position P, the positioning and driving mechanism couples with the magenta photosensitive member

202

. After this, the image forming unit

201

M and the transfer belt unit

215

start to operate, and an image forming operation is performed, similarly as for yellow. Thus, a magenta toner image are formed overlapping a yellow toner image on the intermediate transfer belt

216

.

Thus, sequential switching operations and image forming operations are repeated for cyan and black, so that four toner images are formed on the intermediate transfer belt

216

. When the top of the black toner image, transferred by primary transfer, comes to the position of the secondary transfer roller

227

, the secondary transfer roller

227

is moved. Then, recording paper, which is fed from the paper feed unit

223

, is sandwiched and conveyed between the secondary transfer roller

227

and the intermediate transfer belt

216

, and the four-color toner image is transferred in one batch onto the recording paper. During this time, a voltage of +800V is applied to the secondary transfer roller

227

. The toner image transferred onto the recording paper is fixed on the recording paper by passing a fixing device

228

, and is ejected out of the apparatus with the paper eject rollers

226

.

During the secondary transfer, a fur brush

230

of the cleaner

218

contacts the intermediate transfer belt

216

, and any toner that has remained on the intermediate transfer belt

216

is scraped off. A screw

233

collects the scraped-off toner into the waste toner case

219

. During this time, a voltage of +800V is applied to the fur brush

230

.

When the secondary transfer is finished, the intermediate transfer belt

216

and the image forming unit

201

are stopped again, and the carriage

211

rotates 90°. Then, the yellow image forming unit

201

Y is again positioned and stopped in the image forming position P, and the color image forming operation is completed.

Positioning and Driving Mechanism

The following is an explanation of the photosensitive member

202

and the mechanism for positioning and driving the photosensitive member

202

.

FIG. 18

is a perspective view showing a first flange on the right side of the photosensitive member and a driving shaft provided on the right side of the main body.

FIG. 19

is a cross sectional view taken at the rotation center thereof.

FIG. 20

is a diagram illustrating the driving mechanism on the main body side for driving the photosensitive member and the intermediate transfer belt.

FIG. 21

is a perspective view showing a second flange on the left side of the photosensitive member and a positioning shaft provided on the left side of the main body.

FIG. 22

is a cross sectional view taken at the rotation center thereof.

As is shown in

FIGS. 18

,

19

,

21

, and

22

, a first flange

240

is attached to the photosensitive member

202

on the side where it is rotated and driven by the apparatus main body, and a second flange

245

is attached to the photosensitive member

202

on the opposite side thereof. A bearing surface

240

A of the first flange

240

and a bearing surface

245

A of the second flange

245

support the photosensitive member

202

freely rotatably in the housing

243

. Here, the first flange

240

is made of a conductive resin.

A first concave tapered surface

240

B is formed at the center of the end face of the first flange

240

of the photosensitive member

202

, and twelve follower tongues made of convex and concave portions are arranged at equal intervals around the first concave tapered surface

240

B. The first concave tapered surface

240

B is coaxial with the center axis of the photosensitive member

202

. Its tip angle is about 20°, and its diameter at the edge is set at about 9 mm.

Moreover, in a center portion of the end surface of the second flange

245

on the opposite side of the photosensitive member

202

, a second concave tapered portion

245

B is formed, which is similar to the first concave tapered portion

240

B.

The following is an explanation of the positioning and driving mechanism of the photosensitive member.

As is shown in

FIGS. 18 and 19

, the positioning and driving mechanism

251

includes a driving shaft

250

, a pin-shaped transmission tongue

252

, a driving shaft gear

253

, and driving mechanism for driving the same.

The driving shaft

250

is supported by bearings

256

fixed to a right panel

254

of the main body and a driving panel

255

, and is rotatable and movable in a thrust direction. The diameter of the driving shaft

250

is 8 mm, and a spherical surface

250

A is formed at its tip. When it is pushed into the first concave tapered surface

240

B of the first flange

240

, the spherical surface

250

A enters the first concave tapered surface

240

B. In the following, the position where the spherical surface

250

A enters the first concave tapered surface

240

b

and the two are coupled is referred to as “coupling position”.

The transmission tongues

252

mesh with the follower tongues

240

C, to which they transmit a motive force. The transmission tongues

252

are fixed to the driving shaft

250

, and rotate together with the driving shaft

250

. The driving shaft gear

253

is fixed to the driving shaft

250

, and this driving shaft gear

253

meshes with a motor-side gear

257

supported by the right panel

254

of the main body and the driving panel

255

. Numeral

258

denotes a compression spring, which is inserted between the bearing

256

of the main body-side panel

254

and driving shaft gear

253

. This compression spring

258

is steadily energized toward the position where the driving shaft

250

and the transmission tongues

252

are separated from the photosensitive member

202

. The driving shaft

250

can be moved against the force of the spring with the thrust bearing

259

, between a separation position and the coupling position. The motor-side gear

257

has a sufficient broad teeth width so that the driving shaft gear

253

meshes with the motor-side gear

257

in the separated position as well as in the coupling position.

As is shown in

FIG. 20

, the motor-side gear

257

meshes with a motor gear

260

of the driving motor, and this motor gear

260

transmits a driving force to a belt driving shaft gear

263

, which is attached to the driving roller

217

A of the intermediate transfer belt

216

, via a belt transmission gear

261

and a belt driving gear

262

.

The following is an explanation of a positioning mechanism

271

for positioning the photosensitive member

202

on the left side of the main body, referring to

FIGS. 21 and 22

.

The positioning mechanism

271

includes a positioning shaft

270

and a mechanism for shifting the positioning shaft

270

into a thrust direction.

The positioning shaft

270

is supported by a bearing

274

fixed to a left panel

272

of the main body and a support panel

273

, and is rotatable and movable in a thrust direction. Same as for the driving shaft

250

, the diameter of the positioning shaft

250

is 8 mm, and a spherical surface

270

A is formed at its tip. When it is pushed into the second concave tapered surface

245

B of the second flange

245

, the spherical surface

270

A enters the second concave tapered surface

245

B. In the following, the position where the spherical surface

270

A enters the second concave tapered surface

245

B and the two engage is referred to as “coupling position”.

Numeral

275

denotes a compression spring, which is inserted between the bearing

274

and a thrust plate

276

. This compression spring

275

is steadily energized in the position where the positioning shaft

270

is separated from the second flange

245

. The positioning shaft

270

can be moved against the force of the spring with the thrust bearing

277

, between a separation position and a coupling position.

Driving Operation for Positioning and Rotation

The following is an explanation of the driving operation for positioning and rotation of the photosensitive member.

FIG. 23

is a cross sectional view of the first flange and the driving shaft, seen from the direction of the driving shaft.

FIG. 24

is a cross sectional view through the rotation center of the first flange and the driving shaft, when the driving shaft is moving from the separation position to the coupling position.

FIG. 25

is a graph illustrating the speed of the driving motor at the beginning of the image formation.

When the image forming unit

201

has been shifted to the image forming position P in the apparatus main body, the thrust bearing

277

moves the positioning shaft

270

of the main body side in the thrust direction, and the spherical surface

270

A at the tip of the positioning shaft

270

is coupled with the second concave tapered surface

245

B of the second flange

245

, thereby positioning the photosensitive member. In this coupling position, the center of the spherical surface

270

A has entered the second concave tapered surface

245

B. When the photosensitive member

202

rotates, the second flange

245

and the positioning shaft

270

rotate together due to friction forces.

At the same time, the thrust bearing

259

shifts the driving shaft

250

with the transmission tongues

252

into the thrust direction. In this situation, if the transmission tongues

252

and the follower tongues

240

C mesh with each other as shown by the solid line in

FIG. 23

, the follower tongues

240

C and the transmission tongues

252

engage. Then, the spherical surface

250

A at the tip of the driving shaft

250

engages the first concave tapered surface

240

B of the first flange

240

, thereby positioning the photosensitive member

202

. In this coupling position, the center of the spherical surface

250

A has entered the first concave tapered surface

240

B.

The driving shaft

250

is rotated by the driving motor of the apparatus main body. This rotational force is transmitted onto the follower tongues

240

C of the first flange

240

via the transmission tongues

252

, and rotates the photosensitive member

202

. As a result, the line that connects the spherical surface

250

A at the tip of the driving shaft

250

with the spherical surface at the tip of the positioning shaft

270

becomes the rotation center of the photosensitive member

202

.

The dashed line in

FIG. 23

shows the situation when the transmission tongues

252

abut the follower tongues

240

C of the first flange

240

while the driving shaft

250

is shifted in the engagement direction (direction of the photosensitive member). In this case, the driving shaft

250

temporarily stops in a position where the transmission tongues

252

abut the follower tongues

240

C, as shown in FIG.

24

. The transmission tongues

252

are provided at a position 5 mm away from the tip of the driving shaft

250

, and the height of the follower tongues

20

C is set to 3.5 mm, so that the tip of the driving shaft

250

still can enter the first concave tapered surface

240

B even in this case.

If the driving motor in the apparatus main body rotates the driving shaft

250

in this situation where the follower tongues

240

C and the transmission tongues

252

do not mesh with each other, at first the transmission tongues

252

rotate, but the photosensitive member

202

does not rotate. Then, as the transmission tongues

252

rotate and come into the position between the follower tongues

240

C, the transmission tongues enter and mesh with the follower tongues

240

C. This makes it possible to transmit a rotation force from the driving shaft

250

to the photosensitive member

202

. At the same time, the positioning shaft

270

enters the second concave tapered surface

245

B, and positions the photosensitive member

202

. As a result, the line that connects the centers of the spherical surfaces

270

A and

250

A on the left and right becomes the rotation center of the photosensitive member

202

.

With this operation, the positioning shaft

270

and the driving shaft

250

position the photosensitive member

202

of the image forming unit

201

that the carriage

211

has moved near the image forming position P precisely in the image forming position P. Since a clearance is provided between the carriage

211

and the image forming unit

201

, the carriage

211

does not disturb the movement of the image forming unit

201

containing the photosensitive member

202

.

The pitch between the follower tongues

240

C is set to 30° with the rotation shaft at the center. On the other hand, the interval BP between the position detection hole

231

and the detection sensor

232

at the time when the intermediate transfer belt

216

stops, as shown in

FIG. 17

, is set to 30 mm. Moreover, the rotation angle of the driving axis

250

while the intermediate transfer belt

216

travels 30 mm is 120°. Consequently, even in the slowest possible meshing between the follower tongues

240

C and the transmission tongues

252

, the detection hole

231

passes the detection sensor

232

after a rotation of 90° after the meshing. In this case, the load variation due to the meshing of the follower tongues

240

C with the transmission tongues

252

brings about a speed variation of the driving motor as shown by CA in FIG.

25

. While the driving motor settles these speed variations, the driving shaft

250

rotates only about 30°. Consequently, a detection signal for the reference position of the intermediate transfer belt

216

is generated after the speed variations brought about by the load variations due to the meshing have settled down.

As described above, the tip of the driving shaft

250

is spherical, and the coupling portion of the first flange

240

is conical. Similarly, the tip of the positioning shaft

270

is spherical, and the coupling portion of the second flange

245

is conical. Therefore, even when the driving shaft

250

, the positioning shaft

270

and the photosensitive member

202

are coupled while their axes are tilted against each other, the contact portions of the coupling portions are circles formed by the intersection between a plane perpendicular to the axis of the photosensitive member

202

and the conical surface. Consequently, the photosensitive member

202

can be held and controlled over the entire periphery. As a result, it is possible to hold and position the photosensitive member

202

reliably. Moreover, since the line that connects the centers of the left and right spherical surfaces

270

A and

250

A usually becomes the rotation center of the photosensitive member

202

, the rotation center of the photosensitive member

202

can be positioned with good reproducibility.

Moreover, since the first and second concave tapered surfaces

240

B and

245

B contact the spherical surfaces

250

A and

270

A in a circle extending around the entire periphery, the coupling portion does not misalign. Thus, the rotation center of the photosensitive member

202

can be controlled reliably. As a result, variations in the rotation speed of the photosensitive member can be prevented, and a favorable image can be obtained without positional misalignments.

Moreover, when the transmission tongues

252

reach the tip position of the follower tongues

240

C as shown in

FIG. 24

, the tip of the driving shaft

250

enters the first concave tapered surface

240

B of the first flange

240

, so that the driving shaft

250

can be coupled securely with the first concave tapered surface

240

B of the photosensitive member

202

even when a force acts in the radial direction of the photosensitive member

202

where the transmission tongues

252

abut the follower tongues

240

C. Moreover, when the transmission tongues

252

are moved toward the photosensitive member

202

, and when the tips of the transmission tongues

252

reach the tip position of the follower tongues

240

C, the inner peripheral surface of the convex portions of the follower tongues

240

C are closer to the rotation center than the outermost peripheral portion of the transmission tongues

252

. Therefore, when the driving shaft

250

is moved toward the photosensitive member

202

and the photosensitive member

202

is being positioned, the inner peripheral surface of the follower tongues

240

C on the side of the photosensitive member

202

cannot abut the outer peripheral surfaces of the transmission tongues

252

on the side of the driving shaft

250

. As a result, the photosensitive member

202

is moved securely in a radial direction, and the photosensitive member

202

can be positioned at its correct position.

Moreover, the pitch between the convex and concave portions of the follower tongues

240

C is smaller than the rotation angle of the driving shaft

250

from the time when the motor is started until the reference position detection signal for the intermediate transfer belt

216

is generated. Therefore, the speed variations brought about by the meshing between the transmission tongues

252

and the follower tongues

240

C have settled down when the reference position of the intermediate transfer belt

216

is detected. As a result, the reference position of the intermediate transfer belt

216

is detected after the speed of the intermediate transfer belt

216

has been stabilized, and anomalous speed variations do not occur after the reference position has been detected, so that the positions of the images on the intermediate transfer belt

216

can be aligned precisely.

In this embodiment, the positioning shaft

270

rotates together with the second flange due to friction, but there is no necessary limitation to this configuration, and the same effect also can be attained if the positioning shaft

270

is fixed in the rotation direction. In this case, the positioning shaft is movable only in an axial direction, and the spherical surface

270

A at the end slides on the contact portion with the second concave tapered surface

245

B.

Fifth Embodiment

FIG. 26

is a cross sectional view of a fifth embodiment of the present invention, taken at the rotation center of the coupling portion of the first flange on the driving side and the driving shaft.

FIG. 27

is a lateral view of the first flange, seen from the direction of the end surface. Different from the above fourth embodiment, the first flange

240

is made of an insulating polycarbonate. Moreover, the tip of the first concave tapered surface

240

B is provided with a tapered surface

240

D with a tip angle that is larger than that of the tapered surface

240

B, which tapered surface

240

D is separated from but in close vicinity to the driving shaft

250

. Moreover, the follower tongues

240

C of the first flange

240

of the photosensitive member

202

are formed by

20

convex and concave portions arranged at equal intervals.

The center of the tapered surface

240

C is provided with a through hole

280

, leading into an inner portion of the photosensitive member

202

in the axial direction. An electrode member

281

made of metal is retained in the through hole

280

and is movable in the axial direction. A metal plate

282

is attached to the end surface of the side opposite to the first concave tapered surface

240

B of the first flange

240

, where it contacts the drum cylinder of the photosensitive member

202

. A pressure spring

283

is provided between the metal plate

282

and the electrode member

281

, and this pressure spring

283

biases the electrode member

281

toward the flange end surface (in the direction of the first concave tapered surface

240

B). As is shown in

FIG. 26

, when the photosensitive member

202

is being positioned, the tip of the driving shaft

250

abuts the electrode member

281

. At this time, the force of the pressure spring

283

is pressing the electrode member

281

in the direction of the tip of the driving shaft

250

. This establishes an electrical connection from the driving shaft

250

to the drum cylinder of the photosensitive member

202

through the electrical member

281

, the pressure spring

283

, and the metal plate

282

, so that the drum cylinder of the photosensitive member

202

can be drawn to ground potential. All other structural elements and operations are the same as in the fourth embodiment.

The following is an explanation of an image forming apparatus and the operation of the image forming units with such a configuration.

When the coupling between the driving shaft

250

and the first concave tapered surface

240

B is repeated in the fourth embodiment, there is the danger that the first concave tapered surface

240

B is deformed. Therefore, if the driving shaft

250

is not moved beyond its regular position to the tip of the first concave tapered surface

240

B the driving shaft

250

cannot press onto the first concave tapered surface

240

B anymore. If at this time the stroke of the driving shaft

250

in the axial direction is short, the driving shaft

250

does not press sufficiently onto the photosensitive member

202

, so that the driving shaft

250

cannot hold the photosensitive member

202

completely, and the danger arises that the position of the photosensitive member

202

varies.

In this embodiment, the tip of the first concave tapered surface

240

B is provided with a tapered surface

240

D whose tip angle that is larger than that of the tapered surface

240

B, which tapered surface

240

D contacts and separates from the driving shaft

250

, so that even when the first concave tapered surface

240

B is deformed and the driving shaft

250

attempts to enter the first concave tapered surface

240

B beyond a certain position, the tip of the driving shaft

250

abuts the tapered surface

240

D, which has a large tip angle. Consequently, it can be prevented that the driving shaft

250

enters much beyond a certain position into the tapered portion. As a result, it is possible to set a small moving stroke in the axial direction for the driving shaft

250

.

Moreover, in the fourth embodiment, a conductive resin is used for the material of the first flange

240

, but if a conductive resin is used, there is the problem that such a resin is brittle and may break. In addition, since an electrically conductive path is established through the first concave tapered surface

240

B with unreliable contact, there is the problem that a poor conduction may occur easily, which can lead to corruption of the image.

With this embodiment, however, the electrode member

281

contacts the driving shaft

250

at the rotation center of the coupling portion where the relative displacement amount is the smallest, so that a secure electrical conduction can be established also during rotation. In addition, the electrode member

281

and the driving shaft

250

rotate together, and do not slide at the contact face, so that an even more secure electrical conduction can be established.

Moreover, the pitch of the concave and convex portions of the follower tongues

240

C is 16° with the rotation axis as the center. On the other hand, the rotation angle of the driving shaft

250

is about 25° from the start of the driving motor for the photosensitive member

202

until a certain speed is reached. Therefore, even in the slowest possible case for the meshing of the follower tongues

240

C and the transmission tongues

252

C, load variations due to the meshing occur during the acceleration of the driving motor, as shown by CB in FIG.

25

. Since the motor of the driving motor is driven with the largest current during the acceleration, the speed variations are small even when a load is added. Consequently, after the occurrence of load variations, the time to settle down speed variations caused by the load variations is short.

This means that even in the slowest possible case for the meshing of the follower tongues

240

C and the transmission tongues

252

C, the speed of the intermediate transfer belt

216

can be stabilized in a short time. Consequently, after the motor that is the driving motor has been started, and the reference position of the intermediate transfer belt

216

is detected at a certain time, anomalous speed variations do not occur after this position detection. Thus, speed variations of the intermediate transfer belt

216

after the generation of the reference signal can be prevented. As a result, positional misalignments can be prevented for each color.

Thus, with this embodiment, providing the tip of the first concave tapered surface

240

B with a tapered surface

240

D whose tip angle that is larger than that of the tapered surface

240

B, the photosensitive member

202

can be pressed securely by the driving shaft

250

, even when the stroke of the driving shaft

250

in the axial direction is small, and as a result, the photosensitive member

202

can be held securely by the driving shaft

250

. Moreover, by providing an electrode member

281

at the center of the tapered surface

240

D, secure electrical conduction between the driving shaft

250

and the cylinder of the photosensitive member

202

can be established even during rotation. Moreover, it is possible to use for the first flange

240

a low-price molded product of a resin with high strength. In addition, since the tip angle of the tapered surface

240

D of the first flange

240

is large, it can hold the electrode member

281

, which moves in the axial direction, up to the vicinity of the point of contact with the driving axis

250

. Moreover, even in the slowest possible case for the meshing of the follower tongues

240

C and the transmission tongues

252

C, load variations due to the meshing occur during the acceleration of the driving motor, so that speed variations of the intermediate transfer belt

216

after the generation of the reference signal can be prevented. As a result, positional misalignments can be prevented for each color.

In this embodiment, the electrode member

281

is provided at the first flange

240

, which couples with the driving shaft

250

, but there is no limitation to this configuration, and the same effect can be obtained if the electrode member

281

is provided at the second flange

245

, which couples with the positioning shaft

270

.

Sixth Embodiment

FIG. 28

is a cross sectional view of a sixth embodiment of the present invention, taken at the rotation center of the coupling portion of the first flange on the driving side and the driving shaft. Different from the above-noted fifth embodiment, a flat surface

240

E that is perpendicular to the rotation axis is formed at the tip of the first concave tapered surface

240

B, and a flat surface

250

B that is perpendicular to the rotation axis is formed at the tip of the spherical surface

250

A of the driving shaft

250

. All other structural elements and operations are the same as in the fifth embodiment.

The following is an explanation of an image forming apparatus and the operation of the image forming units with such a configuration.

The flat surface

240

E perpendicular to the rotation axis is provided at the tip of the concave tapered surface

240

B, and is in close opposition to the driving shaft

250

. Therefore, even when the first concave tapered surface

240

B of the positioning contact portion is deformed and the driving shaft

250

attempts to enter the first concave tapered surface

240

B beyond a certain position, the tip of the driving shaft

250

abuts the flat surface

240

E. Consequently, it can be prevented that the driving shaft

250

enters much beyond a certain position into the tapered portion. As a result, it is possible to set a small moving stroke in the axial direction for the driving shaft

250

.

Moreover, during the switching and moving of the image forming units

1

, the driving shaft

250

has to be completely detached from the first concave tapered surface

240

B. On the other hand, during the image formation operation, it is necessary to press the driving shaft

250

against the first concave tapered surface

240

B to position the photosensitive member

202

. Therefore, it is necessary to move the driving shaft

250

into the axial direction over a distance that is longer than the distance from the tip of the first flange

240

to the contact portion between the driving shaft

250

and the first concave tapered surface

240

B. To ensure this moving distance, a waiting space for the driving shaft

250

has to be provided extending in the width direction inside the apparatus, and as a result, leads to the problem that the width of the apparatus main body increases and the apparatus turns out to be bigger.

In this embodiment, a flat surface

250

B is provided at the tip of the driving shaft

250

so that the distance that the driving shaft

250

moves in the axial direction is shortened, and the detaching and pressing of the driving shaft

250

from and against the first concave tapered surface

240

B of the first flange

240

can be performed reliably. Moreover, since the first concave tapered surface

240

B of the first flange

240

contacts the spherical surface

250

A over the entire periphery of a ring, the photosensitive member

202

can be held securely even when the spherical surface

250

A of the driving shaft

250

is short.

In this manner, with this embodiment, the electrode member

281

can be retained by the through hole

280

up to a position closer to the output shaft

250

by providing the tip of the first concave tapered surface

240

B with a flat surface

240

E perpendicular to the rotation axis. Moreover, providing the tip of the driving shaft

250

with a flat surface

250

B stabilizes the contact to the electrode member

281

, which the tip of the driving shaft

250

contacts elastically. Therefore, electrical conduction between the driving shaft

250

and the cylinder of the photosensitive member

202

can be established more securely. Moreover, providing the tip of the spherical surface

250

A of the driving shaft

250

with a flat surface

250

B makes it possible to set a shorter moving stroke of the driving shaft

250

while retaining the photosensitive member

202

securely. As a result, the apparatus main body can be made smaller.

Seventh Embodiment

FIG. 29

is a lateral view of the driving shaft in a seventh embodiment of the present invention, seen from the tip direction.

FIG. 30

is a perspective view showing an end portion of the first flange of the photosensitive member in the seventh embodiment of the present invention.

FIG. 31

is a cross sectional view of the seventh embodiment of the present invention, taken at the rotation center of the coupling portion of the first flange on the driving side and the driving shaft.

Different from the above-noted sixth embodiment, a disk-shaped transmission member

290

is attached to the driving shaft

250

, and the disk-shaped transmission member

290

is provided with a single transmission tongue

290

A, which is a rectangular convex portion. This transmission tongue

290

A is provided at the same axial position (on the line CL) as the center of the spherical surface

250

A of the tip of the driving shaft

250

. Moreover, the first flange

240

is provided with follower tongues

240

F by forming concave portions in the end portion of the first flange

240

. Here, the tips of the follower tongues

240

F of the first flange

240

are arranged in the same plane as the end portion of the first concave tapered portion. This makes it possible to arrange the contact portion of the transmission tongue

290

A and the follower tongues

240

F at the same axial position (on the line CL) as the center of the spherical surface

250

A. In addition, even if the tip of the driving shaft

250

abuts a peripheral portion of the first concave tapered surface

240

B as shown by the solid line in

FIG. 32

, the transmission tongue

290

A of the transmission member

290

does not protrude beyond an outermost peripheral portion of the follower tongues

240

F. Moreover, even if the tip of the driving shaft

250

abuts a peripheral portion on the opposite side of the first concave tapered surface

240

B as indicated by the dashed line in

FIG. 32

, the transmission tongue

290

A of the transmission member

290

does not protrude to the inside beyond an innermost peripheral portion of the follower tongues

240

F. All other structural elements and operations are the same as in the sixth embodiment.

In conventional configurations, when the photosensitive member

202

and the driving shaft

250

are misaligned and not concentric, the error in the angular speed transmitted by the driving shaft

250

to the photosensitive member

202

increases, and there is the problem that the positions for superimposing the colors on the intermediate transfer belt

216

are misaligned.

Referring to

FIG. 33

, the following is an explanation of the reason why the angular speed changes. In

FIG. 33

, the center axis PF of the photosensitive member

202

(first concave tapered surface

240

B) and the center axis DR of the driving shaft

250

intersect at point A at an intersection angle θ. The transmission tongue is at a position at a radius r

0

from the center axis of the driving shaft

250

, and the follower tongues on the side of the photosensitive member

202

are at a position that is perpendicular to the center axis PF from point B on the center axis PF of the photosensitive member

202

. The intersection A and the contact point where the transmission tongue contacts the follower tongues (passing through the positions S

1

and S

2

) are shifted by a distance d (segment AB) in the direction of the center axis PF of the photosensitive member

202

.

Because of the intersection angle θ, the transmission tongue and the follower tongue mesh obliquely. Consequently, during the meshing rotation, even when the radius of the contact points S with respect to the center axis DR of the driving shaft

250

is a constant r

0

, the radius with respect to the center axis PF of the photosensitive member

202

varies. In the plane including the center axis DR of the driving shaft

250

and the center axis PF of the photosensitive member

202

, this radius takes on a minimum value r

1

at the position of S

1

and a maximum value r

2

at the position of S

2

. The difference ΔR

1

between these radii can be expressed by Eq. 1:

Δ

R

1

=r

2

−r

1

=2

d

·tanθ

Since the radii for the contact points S of the transmission tongue and the follower tongues vary like this with respect to the center axis PF of the photosensitive member

202

, the angular speed of the photosensitive member

202

varies even though the angular speed of the driving shaft

250

is constant.

As becomes clear from Eq. 1, the amount of the speed variations depends on the distance d. Since the members constituting the tapered surface of the photosensitive member

202

differ for each color, this distance d also differs for each color. This can cause different speed variations for each color.

Moreover, in conventional configurations, since the coupling portion of the photosensitive member

202

and the driving shaft

250

is unstable, the distance d varies during the rotation. Therefore, even more anomalous speed variations are superimposed.

On the other hand, if the contact points S of the transmission tongue and the follower tongues are at positions perpendicular to the driving shaft

250

on a line through the intersection A between the center axis PF of the photosensitive member

202

and the center axis DR of the driving shaft

250

, the radius with respect to the center axis DR of the driving shaft

250

is constant, but the radius for the contact points S of the transmission tongue and the follower tongues with respect to the center axis PF of the photosensitive member

202

changes. In the plane including the center axis DR of the driving shaft

250

and the center axis PF of the photosensitive member

202

, this radius takes on a maximum value r

3

at the positions S

3

and S

4

, and a minimum value r

0

at positions perpendicular to this plane. The difference ΔR

2

between these radii can be expressed by Eq. 2:

Δ

R

2

=r

3

−r

0

=(1/cosθ−1)·

r

0

If r

0

=10 mm, d=1 mm, θ=1°, then ΔR

1

/ΔR

2

=229.

From this, it can be seen that if the follower tongues are at the position of point A, the speed variations are smaller than {fraction (1/200)} than if they are at the position of point B. Consequently, arranging the intersection between the rotation axis of the photosensitive member

202

and the rotation axis of the driving shaft

250

and the contact point where the transmission tongue contacts the follower tongues in the same plane perpendicular to the rotation axis of the driving shaft

250

suppresses positional misalignments due to speed variations and makes it possible to obtain a high-quality image.

Moreover, in conventional configurations, transmission tongues and follower tongues are arranged at substantially equal-spaced intervals in the circumferential direction. However, if the center axis DR of the driving shaft

250

is tilted against the center axis PF of the photosensitive member

202

, it is not possible to abut the transmission tongues uniformly against all follower tongues. The transmission tongues and the follower tongues come in contact only at the position S

1

in

FIG. 34

, where the photosensitive member

2

rotates the fastest (where the radius is the smallest). Consequently, since the tongues that contact at the time of rotation driving change, irregularities and form errors in the pitch of the transmission tongues and the follower tongues cause variations in the angular speed of the photosensitive member

202

. Then, when such angular speed variations occur, undesired positional misalignments are caused by different speed variations for each color.

On the other hand, in this embodiment, there is only one transmission tongue

290

A, so that the angular speed is always transmitted by the same tongue. Consequently, the angular speed transmitted from the driving shaft

250

to the photosensitive member

202

does not vary.

Moreover, when the driving shaft

250

is moved in the direction of the photosensitive member

202

, and the tip of the transmission tongue

290

A of the transmission member

290

has reached the tip of the follower tongues

240

F, the tip of the driving shaft

250

has entered the first concave tapered surface

240

B. And, even if the tip of the driving shaft

250

abuts a peripheral portion of the first concave tapered surface

240

B, the transmission tongue

290

A of the transmission member

290

does not protrude beyond an outermost peripheral portion of the follower tongues

240

F. Moreover, even if the tip of the driving shaft

250

abuts a peripheral portion on the opposite side of the first concave tapered surface

240

B, the transmission tongue

290

A of the transmission member

290

does not protrude to the inside beyond an innermost peripheral portion of the follower tongues

240

F. Therefore, when the photosensitive member is moved in the direction of the photosensitive member

202

for positioning, the inner peripheral surface of the transmission tongue

290

A on the side of the driving shaft

250

does not abut the outer peripheral surface of the follower tongue

240

F on the side of the photosensitive member

202

. As a result, the photosensitive member

202

can be moved securely in a radial direction to position the photosensitive member

202

in its correct position.

Eighth Embodiment

FIG. 34

is a front view showing the driving shaft in an eighth embodiment of the present invention.

FIG. 35

is a lateral view seen from its axial direction.

Different from the above-noted seventh embodiment, the surface of the transmission tongue

290

A abutting the follower tongues

240

F is provided with a spherical protrusion

290

B whose center is at the same axial position as the center of the spherical surface

250

A of the tip of the driving shaft

250

(on the line CL). Moreover, a rectangular protrusion portion

290

C of the same height as the transmission tongue

290

A but narrower is provided at a position symmetrical to the transmission tongue

290

A with respect to the rotation center. All other structural elements and operations are the same as in the seventh embodiment.

The following is an explanation of an image forming apparatus and the operation of the image forming units with such a configuration.

In the seventh embodiment, the contact face of the transmission tongue

290

A and the follower tongues

240

F is flat, so that it is not possible to precisely define the contact point between the tongues. This means, since there is a small tilt between the transmission tongue

290

A and the follower tongues

240

F, rotating the driving shaft

250

and the photosensitive member

202

changes the contact point where the transmission tongue

290

A contacts the follower tongues

240

F. Consequently, form errors of the contact surface cause variations in the rotation speed of the photosensitive member

202

. Then, when such rotation speed variations occur, undesired positional misalignments are caused by different speed variations for each color.

On the other hand, in this embodiment, the contact surface of the transmission tongue

290

A is provided with a spherical protrusion

290

B, so that the contact point is normally at the tip of this protrusion

290

B, even when the rotation is performed while the transmission tongue

290

A and the follower tongues

240

F are slightly tilted against each other. Therefore, it is possible to prevent variations of the rotation speed of the photosensitive member

202

, which are caused by the change of the contact portion between the transmission tongue

290

A and the follower tongues

240

F. As a result, positional misalignments due to speed variations can be suppressed and it is possible to obtain a high-quality image.

Moreover, in the seventh embodiment, there is one transmission tongue

290

A, so that when the transmission tongue

290

A hits the tip of the follower tongues

240

F, the counter force causes a bending moment in the driving shaft

250

. This can distort the coupling and moving portion of the bearing

256

, so that the driving shaft

250

cannot be moved in the axial direction anymore. Consequently, at the start of the rotation, the transmission tongue

290

A and the follower tongues

240

F cannot be meshed correctly, and as a result, there is the problem that the angular speed cannot be transmitted to the photosensitive member

202

.

On the other hand, in this embodiment, a protrusion portion

290

C of the same height as the transmission tongue

290

A is provided at a position that is symmetrical to the transmission tongue

290

A with respect to the rotation center, so that when the transmission tongue

290

A hits the follower tongues

240

F, the protrusion portion abuts a position symmetrical to the position abutted by the transmission tongue

290

A. Therefore, there is no counter force acting on the driving shaft

250

, so that the driving shaft

250

moves smoothly in the axial direction. As a result, the transmission tongue

290

A and the follower tongues

240

F can be meshed securely when the rotation starts. Since the protrusion portion

290

C is rectangular and narrower than the transmission tongue

290

A, it does not contact the follower tongues

240

F during the rotation driving.

In this embodiment, the transmission tongue

290

A is provided with a spherical protrusion

290

B, but there is no limitation to this configuration, and the same effect can be attained when the follower tongues

240

F are provided with spherical protrusions.

Moreover, in this embodiment, there is only one protrusion portion

290

C provided at a position that is symmetrical to the transmission tongue

290

A, but there is no limitation to this configuration. An even more stabilized effect can be attained if a plurality of protrusions are provided at the positions of the vertices of a regular polygon including the position of the transmission tongue

290

A and having the rotation center at its center.

Ninth Embodiment

FIG. 36

is a cross sectional view of the driving shaft in a ninth embodiment of the present invention, seen from the axial direction.

FIG. 37

is a cross sectional view of the ninth embodiment of the present invention, taken at the rotation center of the coupling portion of the first flange and the driving shaft.

Different from the eighth embodiment, a driving plate spring

295

having a transmission tongue

295

A for meshing with the follower tongues

240

F is attached to the transmission member

290

with a fixing pin

296

. Moreover, the end of the first concave tapered surface

240

B of the first flange

240

is provided with a tapered surface

240

G with a large tip angle. All other structural elements and operations are the same as in the eighth embodiment.

The following is an explanation of an image forming apparatus and the operation of the image forming units with such a configuration.

The smaller the tip angle of the first concave tapered surface

240

B, the more precisely can the position of the photosensitive member

202

be defined. However, if the taper angle is small, the driving shaft

250

cannot be inserted into the first concave tapered surface

240

B, unless the driving shaft

250

and the photosensitive member

202

are aligned almost completely concentrically at the image forming position P. If the driving shaft

250

cannot be inserted into the first concave tapered surface

240

B, the photosensitive member

202

cannot be positioned in the image forming position P.

Conversely, the larger the circle at the end of the first concave tapered surface

240

B is, the easier it is to insert the driving shaft

250

into the first concave tapered surface

240

B, even when the carriage

211

has positioned the photosensitive member

202

with misalignment. However, in this case, the distance from the end of the first concave tapered surface

240

B to the coupling contact portion with the driving shaft

250

becomes undesirably long, and because it is necessary to move the driving shaft

250

over this distance, the moving stroke for the driving shaft

250

becomes long. As a result, a large waiting space has to be provided extending in the width direction inside the apparatus, which leads to the problem that the width of the apparatus main body increases, and the apparatus turns out to be bigger.

In this embodiment, the end of the first concave tapered surface

240

of the first flange

240

is provided with a tapered surface

240

G with a large tip angle, so that not only the ring of the tapered end can be made larger, but also the distance from the end of the first concave tapered surface

240

B to the coupling contact portion with the driving shaft

250

can be shortened. As a result, the moving stroke of the driving shaft

250

in the axial direction can be set shorter, and the driving shaft

250

can be taken out completely from the first concave tapered surface

240

B, so that the apparatus main body can be made smaller.

Moreover, the transmission tongue

295

A is movable in the axial direction with respect to the driving shaft

250

and is elastically biased by the driving plate spring

295

, so that when the driving shaft

250

is moved in the coupling direction, the transmission tongue

295

can be accommodated even when the transmission tongue

295

A abuts the follower tongues

240

F. Thus, when the driving shaft

250

abuts the first concave tapered surface

240

B, it does not hinder the moving of the photosensitive member

202

in the radial direction. Since in this configuration only the transmission tongue

295

moves in the axial direction with respect to the driving shaft

250

, the transmission member

290

can be made shorter in the axial direction of the driving shaft

250

. As a result, it is possible to make the apparatus main body smaller, since the length from the bearing of the driving shaft

250

to the tip thereof can be shortened.

Tenth Embodiment

FIG. 38

is a lateral view of a tenth embodiment of a driving shaft having a transmission member in accordance with the present invention, seen from the axial direction.

FIG. 39

is a cross sectional view of the transmission tongue that the transmission member in this tenth embodiment of the present invention is provided with.

FIG. 40

is a lateral view showing the configuration of the end surface of the first flange in the tenth embodiment of the present invention.

FIG. 41

is a cross sectional view of the follower tongue that a peripheral portion of the end surface of the first flange in this tenth embodiment of the present invention is provided with, seen from the radial direction.

FIG. 42

is cross sectional view of the coupling position in the tenth embodiment of the present invention, taken at the rotation center of the first flange.

Different from the above-noted ninth embodiment, a transmission member

300

is supported rotatably around a rotation shaft

301

, which is attached to the driving shaft

250

and whose rotation center is perpendicular to the driving shaft

250

. The transmission member

300

is rotationally biased by a torsion spring

302

, so that the transmission tongue

300

A is rotatably forced into the tip direction of the driving shaft

250

. An arc-shaped stopper portion

300

C abuts the peripheral surface of the driving shaft

250

, which defines the posture of the transmission member

300

in the rotational orientation.

A clearance is ensured for the rotation shaft

301

, so that the strength and operation necessary for the transmission of the motive force can be applied. Moreover, the rotation shaft

301

is provided at a position directly near the end surface of the first flange opposing the transmission member

300

during the positioning and coupling. The side of the transmission member

300

that opposes the first flange

240

and which is opposite to the transmission tongue

300

A with respect to the rotation shaft

301

is provided with an oblique surface

242

, which gradually recedes from the first flange

240

.

Moreover, as in the above ninth embodiment, the face of the transmission tongue

300

A that abuts the follower tongues

240

H is provided with a spherical protrusion

300

B centered on the same position (on line CL) in the axial direction as the center of the spherical surface

250

A of the tip of the driving shaft

250

. Furthermore, an oblique surface is formed on the transmission tongue

300

A, on the surface in peripheral direction that is on the opposite side from the protrusion

300

B and that does not contact the follower tongue

240

H.

Moreover, an oblique surface is formed on the follower tongue

240

H of the first flange

240

, in the peripheral direction that does not contact the transmission tongue

300

A when being driven to rotate. All other structural elements and operations are the same as in the ninth embodiment.

Because in this embodiment the transmission member

300

is supported rotatably around the driving shaft

250

, it does not become long in the rotation axial direction, even when the coupling/sliding portion between the rotation center and the transmission member

300

is set to be long. As a result, the length from the bearing of the driving shaft

250

to its tip can be set short and without clearance, so that the apparatus main body can be made smaller.

Moreover, in the above-noted fourth embodiment, if the driving shaft

250

is rotated while the tip of the transmission tongue

252

abuts the tips of the follower tongues

240

C, only the side of the driving shaft

250

rotates at first. Then, when the convex and concave portions of the transmission tongue

252

and the follower tongues

240

C come into a meshing position, the driving shaft

250

moves toward the photosensitive member

202

. This causes the tongues to mesh, so that it becomes possible to transmit a motive force. During the meshing movement, the transmission tongue is moved impulsively, because the follower tongues

240

C are rectangular. Therefore, there is the problem that the tip of the driving shaft

250

collides with first concave tapered surface

240

B, which causes collision noise. Moreover, also in conventional configurations, there is the problem that when the coupling tongues

412

enter the photosensitive member side, the coupling tongues

412

move impulsively and collide with the stopper

417

, which causes collision noise.

In this embodiment, the faces of the transmission tongue

300

A and the follower tongues

240

H that are not in contact when driven for rotation are oblique surfaces in the peripheral direction, and the transmission tongue

300

A moves into the meshing position while sliding on the oblique surface when the rotation starts while the tips of the transmission tongue

300

A and the follower tongues

240

H abut each other. Consequently, during this controlled movement of the transmission tongue

300

A the impact when the stopper portion

300

C collides with the driving shaft

250

is small. As a result, the collision noise when the transmission member

300

is brought into its proper position can be suppressed.

Moreover, because the rotation radius of the stopper portion

300

C is smaller than that of the transmission tongue

300

A, the moving speed of the stopper portion

300

C is reduced. Therefore, when the transmission member

300

is brought into its proper position, the impact when the stopper portion

300

C collides with the driving shaft

250

is reduced. As a result, the collision noise can be suppressed even further.

Moreover, since the stopper portion

300

C brings the transmission member

300

into its proper position, the tip of the transmission tongue

300

A does not hit the bottom of the follower tongues

240

H, and the center of the protrusion

300

B is usually at the same position in the axial direction as the center of the spherical surface

250

A at the tip of the driving shaft

250

.

Moreover, the rotation shaft

301

is provided such that it is in a position directly near the end surface of the first flange

240

during the positioning and coupling, so that even when there is an intersection angle θ between the center axis of the driving shaft

250

and the center axis of the photosensitive member

202

the distance between the contact point where the transmission tongue

300

A contacts the follower tongues

240

H and the center axis of the driving shaft

250

can be maintained substantially constant.

Moreover, since the transmission member

300

is provided with an oblique surface

242

, the other portions of the transmission member

300

do not contact the follower tongues

240

H when the transmission tongue

300

A abuts the tips of the follower tongues

240

H as indicated by the dashed line in

FIG. 42

, and as a result, they do not impede the operation of the driving shaft

250

.

In this embodiment, the transmission tongue

300

A is provided with a spherical protrusion

300

B, but there is no limitation to this configuration, and the same effect also can be attained when the follower tongues

240

H are provided with spherical protrusions.

Moreover, the above explanations referred to examples of coupling between the driving shaft

250

and the first concave tapered surface

240

B of the first flange

240

, but the positioning of the photosensitive member

202

can be performed similarly by coupling between the positioning shaft

270

and the second concave tapered surface

245

B of the second flange

245

.

Moreover, in the above explanations, a convex spherical surface is formed at the tip of the driving shaft

250

on the main body side, and a concave tapered surface is formed on the side of the first flange

240

, but the same effect also can be attained, if contrarily a concave tapered surface is formed at the tip of the driving shaft

250

and a convex spherical surface is formed at the center on the side of the first flange

240

.

Moreover, the above explanations refer to examples in which the rotator of the image forming units

201

to be positioned is the photosensitive member

202

, but there is no necessary limitation to the photosensitive member

202

as the rotator, and it also can be the developing roller

205

, which is a structural member of the image forming units

201

.

The invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof The embodiments disclosed in this application are to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, all changes that come within the meaning and range of equivalency of the claims are intended to be embraced therein.

Number	Date	Country	Kind
10-244031	Aug 1998	JP
10-252955	Sep 1998	JP

Number	Name	Date	Kind
4839690	Onoda et al.	Jun 1989	A
5023660	Ebata et al.	Jun 1991	A
5128715	Furuyama et al.	Jul 1992	A
5132728	Suzaki et al.	Jul 1992	A
5313255	Taniguchi et al.	May 1994	A
5583630	Kimura et al.	Dec 1996	A
5610701	Terada et al.	Mar 1997	A
5669046	Yoshida et al.	Sep 1997	A
5809380	Katakabe et al.	Sep 1998	A
6157799	Asakura et al.	Dec 2000	A
6185396	Aizawa et al.	Feb 2001	B1
6249663	Aizawa et al.	Jun 2001	B1

Image forming apparatus with plural color image forming units moveable into image forming position

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