The present application claims priority to and incorporates by reference the entire contents of Japanese priority document 2007-246938 filed in Japan on Sep. 25, 2007.
1. Field of the Invention
The present invention relates to an image forming apparatus such as a copier, a facsimile apparatus, a printer that can retract a latent image writing unit to a retracted position from an operating position.
2. Description of the Related Art
In typical electrophotographic image forming apparatuses, a configuration in which a latent image is written on a uniformly charged latent image carrier with a latent image writing unit has been widely adopted. The latent image carrier is generally a photosensitive body and the latent image writing unit is generally a laser writing device. In such image forming apparatuses, depending on a layout of the apparatus, maintainability of the latent image carrier and various types of peripheral devices such as a developing device disposed at the periphery of the latent image carrier may degrade because the optical writing unit comes in the way as an obstacle.
In Japanese Patent Application Laid-open No. 2007-164141, an image forming apparatus that includes an optical writing unit is disclosed. The optical writing unit moves between an operating position where a writing operation to write a latent image on a latent image carrier is carried out, and a retracted position where the writing operation is not carried out. With such a configuration, the latent image carrier and the peripheral devices can be exposed outside, by retracting the optical writing unit to the retracted position from the operating position opposed to the latent image carrier. Accordingly, the maintainability thereof can be improved.
A first holding plate 232 of the holding frame 230 includes a first opening 232a and a second opening 232b arranged with a predetermined distance therebetween. A left side first alignment axis 271a protruding from a left side surface of the casing 271 is inserted through the first opening 232a, while allowing a certain degree of freedom therein. On the other hand, a left side second alignment axis 271b protruding from the left side surface of the casing 271 is inserted through the second opening 232b, while allowing a certain degree of freedom therein.
A second holding plate 233 of the holding frame 230 includes a first opening 233a and a second opening 233b arranged with a predetermined distance therebetween. A right side first alignment axis 271c protruding from a right side surface of the casing 271 is inserted through the first opening 233a, while allowing a certain degree of freedom therein. On the other hand, a right side second alignment axis 271d protruding from the right side surface of the casing 271 is inserted through the second opening 233b, while allowing a certain degree of freedom therein.
The first holding plate 232 and the second holding plate 233 are rotatably supported by a rotation axis 200 laid across a first support plate 280 and a second support plate 290 of the apparatus main body. By rotating the holding frame 230 around the rotation axis 200, it is possible to retract the optical writing unit 270 to a retracted position from an operating position. A left side first optical alignment groove 281a and a left side second optical alignment groove 281b recessed by a predetermined depth are arranged with a predetermined distance therebetween, at an upper end of the first support plate 280. On the other hand, a right side first optical alignment groove 291a and a right side second optical alignment groove 291b recessed by a predetermined depth are arranged with a predetermined distance therebetween, at an upper end of the second support plate 290.
When the optical writing unit 270 is at the operating position, the optical writing unit 270 is supported by bringing each of the alignment axes 271a to 271d of the casing 271 pressed against the bottom surfaces of the corresponding optical alignment grooves 281a, 281b, 291a, and 291b, respectively. Accordingly, the optical writing unit 270 is aligned in a vertical direction.
In the Japanese Patent Application Laid-open No. 2007-164141, as shown in
When the optical writing unit 270 is supported at four points as shown in
However, in the image forming apparatus shown in
It is an object of the present invention to at least partially solve the problems in the conventional technology.
According to an aspect of the present invention, there is provided an image forming apparatus including a latent image carrier that carries a latent image; a latent image writing unit that carries out a writing operation to writ the latent image on the latent image carrier; and a holding mechanism that holds the latent image writing unit, the holding mechanism being rotatable between an operating position and a retracted position around a rotation axis provided in an apparatus main body, the operating position being a position where the latent image writing unit carries out the writing operation and the retracted position being a position where the latent image writing unit does not carry out the writing operation. The holding mechanism, when at the operating position, holds the latent image writing unit such that the latent image writing unit is supported at three points with respect to the apparatus main body, and the latent image writing unit and the rotation axis are not in contact with each other.
The above and other objects, features, advantages and technical and industrial significance of this invention will be better understood by reading the following detailed description of presently preferred embodiments of the invention, when considered in connection with the accompanying drawings.
Exemplary embodiments of the present invention are described below with reference to the accompanying drawings.
The charger 4K uniformly charges the surface of the photosensitive body 2K that rotates in a clockwise direction in
The developing device 5K includes a hopper unit 6K in a longitudinal shape that houses the K toner, which is not shown, and a developing unit 7K. The hopper unit 6K includes an agitator 8K rotatably driven by the driving unit, which is not shown, a stirring paddle 9K rotatably driven by the driving unit, which is not shown, in a vertically downward direction from the agitator 8K, a toner supplying roller 10K rotatably driven by the driving unit, which is not shown, in a vertical direction from the stirring paddle 9K, and the like. The K toner in the hopper unit 6K moves towards the toner supplying roller 10K due to the own weight of the K toner, while being stirred by the rotational drive of the agitator 8K and the stirring paddle 9K. The toner supplying roller 10K includes a core metal made of metal, and a roller unit made of foamed resin and the like, being covered on the surface thereof, and rotates while adhering the K toner in the hopper unit 6K onto the surface of the roller unit.
The developing unit 7K of the developing device 5K includes a developing roller 11K that rotates while coming into contact with the photosensitive body 2K and the toner supplying roller 10K, and a thinning blade 12K of which the tip comes into contact with the surface of the developing roller 11K. The K toner adhered onto the toner supplying roller 10K in the hopper unit 6K is supplied on the surface of the developing roller 11K at an abutment portion between the developing roller 11K and the toner supplying roller 10K. The layer thickness of the supplied K toner on the surface of the roller is regulated, when the K toner passes through the abutment position between the roller and the thinning blade 12K with the rotation of the developing roller 11K. The K toner, after the layer thickness is being regulated, is adhered on the electrostatic latent image for K on the surface of the photosensitive body 2K, at a developing region that is an abutment portion between the developing roller 11K and the photosensitive body 2K. With the adhesion, the electrostatic latent image for K is developed into the K toner image.
The process unit for K is explained with reference to
Referring back to
A transferring unit 15 that stretches and endlessly moves the endless intermediate transfer belt 16 in an anti-clockwise direction in
The intermediate transfer belt 16 is stretched by the driving roller 18, the driven roller 17, the cleaning backup roller 22, and the four primary transfer rollers 19Y, 19M, 19C, and 19K disposed in the loop thereof. With the rotational force of the driving roller 18 rotated and driven in the anti-clockwise direction in
The four primary transfer rollers 19Y, 19M, 19C, and 19K hold the intermediate transfer belt 16 endlessly moved in this manner, between the photosensitive bodies 2Y, 2M, 2C, and 2K. Being held therebetween, primary transfer nips for Y, M, C, K, that allow the face of the intermediate transfer belt 16 to come into contact with the photosensitive bodies 2Y, 2M, 2C, and 2K are formed.
The primary transfer rollers 19Y, 19M, 19C, and 19K, are applied with a primary transfer bias, by a transfer bias supply, which is not shown, respectively. Accordingly, a transfer electric field is formed between the electrostatic latent images of the photosensitive bodies 2Y, 2M, 2C, and 2K, and the primary transfer rollers 19Y, 19M, 19C, and 19K. A transfer charger or a transfer brush may be adopted, instead of using the primary transfer rollers 19Y, 19M, 19C, and 19K.
When the Y toner formed on the surface of the photosensitive body 2Y of the process unit 1Y for Y enters the primary transfer nip for Y with the rotation of the photosensitive body 2Y, the Y toner is primarily transferred on the intermediate transfer belt 16 from the photosensitive body 2Y due to a transfer electric field and a nip pressure. When the intermediate transfer belt 16 that the Y toner image is primarily transferred thereto in this manner, passes through the primary transfer nips for M, C, and K with the endless movement, the toner images of M, C, and K on the photosensitive bodies 2M, 2C, and 2K are sequentially superimposed and primarily transferred onto the Y toner image. With the superimposition at the primary transfer, four toner images are formed on the intermediate transfer belt 16.
The secondary transfer roller 20 of the transferring unit 15 holds the intermediate transfer belt 16 with the driven roller 17 in the loop, while being disposed outside the loop of the intermediate transfer belt 16. Being held therebetween, a secondary transfer nip that allows the face of the intermediate transfer belt 16 to come into contact with the secondary transfer roller 20 is formed. The secondary transfer roller 20 is applied with a secondary transfer bias, by the transfer bias supply, which is not shown. Being applied with the secondary transfer bias, a secondary transfer electric field is formed between the secondary transfer roller 20 and the driven roller connected to ground.
A paper supply cassette 30 that houses recording paper P of a plurality of stacked sheets is slidably and attachably/detachably disposed with respect to a casing of the printer 100, in a vertically downward direction from the transferring unit 15. In the paper supply cassette 30, a paper supplying roller 30a comes into contact with the recording paper P at the top of the stacked sheets, and the recording paper P is fed towards a paper supply path 31, by rotating the paper supplying roller 30a in the anti-clockwise direction in
Near the end of the paper supply path 31, a pair of registration rollers 32 is disposed. The pair of registration rollers 32 stops rotating, as soon as the recording paper P fed from the paper supply cassette 30 is held between the rollers. Then, at the timing that the recording paper P held therebetween can be synchronized with the toner images of four colors on the intermediate transfer belt 16, in the secondary transfer nip, the pair of registration rollers 32 resumes the rotational drive, and feeds the recording paper P towards the secondary transfer nip.
The toner images of four colors on the intermediate transfer belt 16 that come in close contact with the recording paper P in the secondary transfer nip, are secondarily transferred onto the recording paper P collectively, being affected by the secondary transfer electric field and a nip pressure. Combined with the white of the recording paper P, the toner images of four colors become a full color toner image. The recording paper P on which surface the full color toner image is formed in this manner, is curvature-separated from the secondary transfer roller 20 and the intermediate transfer belt 16, when being passed through the secondary transfer nip. The recording paper P is then fed into a fixing device 34, which will be explained later, via a post-transfer conveying path 33.
On the intermediate transfer belt 16 that has passed through the secondary transfer nip, the transfer residual toner not transferred onto the recording paper P is adhered. The transfer residual toner is cleaned from the surface of the belt, by the belt cleaning device 21 that comes into contact with the face of the intermediate transfer belt 16. The cleaning backup roller 22 disposed in the loop of the intermediate transfer belt 16 backs up the cleaning of the belt performed by the belt cleaning device 21 from inside the loop.
The fixing device 34 forms a fixing nip with a fixing roller 34a that includes a heating source such as a halogen lamp, which is not shown, and a pressure roller 34b that rotates while coming into contact with the fixing roller 34a at a predetermined pressure. The recording paper P fed into the fixing device 34 is held by the fixing nip, so that the surface that carries the unfixed toner image comes in close contact with the fixing roller 34a. Being affected by the heat and the pressure, the toner in the toner image is softened, thereby fixing the full color image.
The recording paper P discharged from the fixing device 34 comes to a branch point between a paper discharge path 36 and a pre-reverse conveying path 41, after passing through a post-fixing conveying path 35. At the side of the post-fixing conveying path 35, a switch pawl 42 rotationally driven around a rotation axis 42a is disposed, and an area near the end of the post-fixing conveying path 35 is closed and opened due to the rotation. At the timing that the recording paper P is fed out from the fixing device 34, as shown in
When a single-sided print mode is being set, the recording paper P held between the pair of paper discharging rollers 37 is discharged directly outside the machine. The single-sided print mode may be set by an input operation with respect to an operating unit formed by a numeric keypad and the like, which are not shown, and by a controlling signal and the like sent from a personal computer and the like, which are not shown. The recording paper P is then stacked in a stacking unit at the top surface of an upper cover 50 of the casing.
When a double-sided print mode is being set, after the rear edge side of the recording paper P, of which the tip edge side is conveyed in the paper discharge path 36 by being held between the pair of paper discharging rollers 37, passes through the post-fixing conveying path 35, the switch pawl 42 rotates to the position of a broken line in
The reversing unit 40 includes an outside cover 45 and an oscillating body 46. More specifically, the outside cover 45 of the reversing unit 40 is supported so as to rotate around the rotation axis 40a disposed in the casing of the printer main body. With this rotation, the outside cover 45 opens and closes with respect to the casing, along with the oscillating body 46 included therein. As shown in the broken line in
The oscillating body 46 is supported by the outside cover 45 so as to rotate around an oscillating axis, which is not shown, included in the outside cover 45, while the outside cover 45 is being opened. With this rotation, when the oscillating body 46 is opened with respect to the outside cover 45, the pre-reverse conveying path 41 and the reverse conveying path 44 are vertically halved and are exposed to outside. Accordingly, the paper jammed in the pre-reverse conveying path 41 and the reverse conveying path 44 can easily be removed therefrom.
The upper cover 50 of the casing of the printer 100, as shown by an arrow in
Characteristic configurations of the printer 100 will now be explained.
Referring back to
Accordingly, with the printer 100, the optical writing unit 70 is held in a holding frame 130, and as required, the holding frame is retracted from an operating position, which is immediately above the four process units 1Y, 1M, 1C, and 1K, along with the optical writing unit 70, thereby exposing the process units.
As shown in
The left side plate 80, the right side plate 90, and the beam plate 110 may be an integral structure integrally formed of resin. The number of components can be reduced by being integrally formed.
Between the left side plate 80 and the right side plate 90 facing each other with a predetermined distance, the transfer unit, which is not shown, there is a room for disposing the four process units, the optical writing unit 70 that is a latent image writing unit, the holding frame 130 that is a holder, and the like.
At the upper end portion of the left side plate 80, a left side optical alignment groove 81 with a predetermined depth is formed. At the upper end portion of the right side plate 90, a right side optical alignment groove 91 recessed by a predetermined depth is formed. The right side optical alignment groove 91 of the right side plate 90 includes a leaf spring 94.
To the right side plate 90, at the surface facing the left side plate 80, a right side image forming support unit 93 is being protruded. The right side image forming support unit 93 is integrally formed with the main body of the right side plate 90, and the main body and the right side image forming support unit 93 are both made of resin. Four right side image forming alignment grooves 93Y, 93M, 93C, and 93Y extended to the lower end from the upper end are formed in the right side image forming support unit 93. Although not shown in
The photosensitive bodies 2Y, 2M, 2C, and 2K, which are not shown, of the four process units 1Y, 1M, 1C, and 1K include a drum unit, which is a cylinder, and a left drum axis and a right drum axis that are axes protruded from the both end surfaces in a direction of the axis of the drum unit, respectively. The process units 1Y, 1M, 1C, and 1K, protrude the left drum axis and the right drum axis outside the casing, through an axis hole, which is not shown, provided in the casing. While engaging the left drum axis of each of the process units in the left side image forming alignment grooves, which are not shown, in the left side image forming support unit of the left side plate 80 of the main body frame, the right drum axis is engaged in the right side image forming alignment grooves 93Y, 93M, 93C, and 93K in the right side image forming support unit of the right side plate 90 of the main body frame. With these engagements, each of the process units 1Y, 1M, 1C, and 1K is aligned in a front-rear direction. The process units 1Y, 1M, 1C, and 1K are supported by the left side plate 80 and the right side plate 90, and aligned in the vertical direction, because the left drum axis comes into contact with bottom surfaces of the left side image forming alignment grooves, and the right drum axis comes into contact with bottom surfaces of the right side image forming alignment grooves 93Y, 93M, 93C, and 93K.
Four leaf springs 95Y, 95M, 95C, and 95K are provided on the right side image forming support unit 93 (only leaf spring 95Y is shown in
The optical writing unit 70 includes a casing 71 containing an optical system including a polygon motor, a polygon mirror, a reflecting mirror, a lens, and the like, which are not shown, and the casing 71 is held in the holding frame 130.
The holding frame 130 includes a left holding plate 72, a right holding plate 73, a front coupling rod 74, and a tension coil spring 75.
The area near the front end portion of the left holding plate 72 and the right holding plate 73 of the holding frame 130 are connected by the front coupling rod 74, so that the left holding plate 72 and the right holding plate 73 face each other with a predetermined distance therebetween, in the front-rear direction of the printer 100. The left holding plate 72 and the right holding plate 73 are rotatably fitted to the rotation axis 51. At the lower surfaces of the left holding plate 72 and the right holding plate 73 of the holding frame 130, four coil springs that correspond to the process units are fixed thereto, although not shown. When the holding frame 130 is at the operating position, each of the coil springs comes into contact with the upper surface of the corresponding process unit, and urges each of the process units downwards.
A left side alignment axis 71a protrudes from the left side surface of the casing 71 of the optical writing unit 70. A right side alignment axis 71c protrudes from the right side surface of the casing 71. A rotation axis engaging unit 71e is provided at the center of the rear wall of the casing 71, in a direction that the side plates are opposed to each other (left-right direction). The rotation axis engaging unit 71e, as shown in
A support protrusion 71b is provided at the lower surface of the engaging unit 71e, and as shown in
As shown in
The left holding plate 72 includes an opening 72a, and the left side alignment axis 71a protruded from the left side surface of the casing 71 is penetrated through the opening 72a. The right holding plate 73 includes an opening 73a, and the right side alignment axis 71c protruded from the right side surface of the casing 71 is penetrated therethrough.
The optical writing unit 70 is held in the holding frame 130, by having each of the alignment axes 71a and 71c of the casing 71 of the optical writing unit 70 penetrated through the openings in the left holding plate 72 and the right holding plate 73 of the holding frame 130, while allowing a certain degree of freedom therein. The opening 72a of the left holding plate 72 and the opening 73a of the right holding plate 73 are opened in an oval shape, because the end of the U-shaped notch portion provided on the holding plates 72 and 73 is closed by a notch end closing member. The notch end closing member is screwed onto each of the holding plates 72 and 73, and may be removed from the holding plates by being unscrewed. The optical writing unit 70 can be set between the left holding plate 72 and the right holding plate 73, by removing the notch end closing member from the holding plates 72 and 73, thereby forming the opening into the U-shaped notch portion. After inserting each of the alignment axes of the optical writing unit 70 into the U-shaped notch portion of the holding plates 72 and 73, each notch is opened by fitting the notch end closing member therein. In this manner, the optical writing unit 70 is held in the holding frame 130.
Before the optical writing unit 70 held in the holding frame 130 is set in the printer 100, the rotation axis 51 shown in
After putting the optical writing unit 70 in between the right side plate 90 and the left side plate 80 in this manner, the rotation axis 51 is inserted therein. More specifically, the rotation axis 51 is inserted into a hole provided in the left side plate 80, which is not shown, a hole provided in the left holding plate 72 of the holding frame 130, which is not shown, a hole in the upper cover 50, which is not shown, a hole provided in the right holding plate 73, which is not shown, and a hole provided in the right side plate 90, which is not shown. The left end portion of the rotation axis 51 is fixed to the left side plate 80 by a flange, an E-ring, an insert pin, and the like, and the right end portion is fixed to the right side plate 90.
The alignment axes 71a and 71c of the casing 71 of the optical writing unit 70 are brought into contact with the bottom surfaces of the corresponding optical alignment grooves 81 and 91, and the support protrusion 71b provided on the engaging unit 71e of the casing 71 is brought into contact with the upper surface of the rear side plate 120. Accordingly, the optical writing unit 70 is supported at three points of the left side plate 80 (the first support plate), the right side plate 90 (the second support plate), and the rear side plate 120 (the perpendicular plate) of the apparatus main body, and also aligned in the vertical direction.
The optical writing unit 70 is aligned in the front-rear direction, by pulling the optical writing unit 70 forward by the tension coil spring 75, and bringing each of the alignment axes 71a and 71c pressed against the front inner walls of the optical alignment grooves 81 and 91. In other words, in the present embodiment, a first alignment unit that aligns the optical writing unit 70 in a direction substantially perpendicular (front-rear direction) with respect to the rear side plate 120 (the perpendicular plate) includes each of the alignment axes 71a and 71c of the casing 71, the front inner walls of the optical alignment grooves 81 and 91, and the tension coil spring 75.
The optical writing unit 70 is aligned in the left-right direction, by moving the optical writing unit 70 to the side of the left side plate where the photosensitive body is supported. This is enabled by urging the right side alignment axis 71c of the casing 71 towards the side of the left side plate 80 using the leaf spring 94, and bringing the optical writing unit 70 pressed against the left holding plate 72. In other words, in the present embodiment, a second alignment unit that aligns the optical writing unit in a direction substantially perpendicular (left-right direction) with respect to the left side plate 80 (the first support plate) or the right side plate 90 (the second support plate) includes the right side alignment axis 71c of the casing 71, the leaf spring 94, and the left holding plate 72 of the holding frame 130.
The holding frame 130 set between the left side plate 80 and the right side plate 90 can slide and rotate with the optical writing unit 70, around the rotation axis 51 laid across the left side plate 80 (the first support plate) and the right side plate 90 (the second support plate). More specifically, each of the alignment axes 71a and 71c of the casing 71 of the optical writing unit 70 is formed smaller than the width of the corresponding optical alignment grooves 81 and 91, thereby moving in a direction of the groove width within the groove. However, when the optical writing unit 70 is being set at the operating position as shown in
As shown in
In the printer 100, the optical writing unit 70 is supported at three points. Thus, it is possible to accurately align the optical writing unit 70 in the vertical direction, by only performing alignment of six locations. Those locations are the bottom surfaces of the optical alignment grooves 81 and 91, the upper surface of the rear side plate, the alignment axes 71a and 71c of the optical writing unit 70, and the support protrusion 71b. Therefore, compared with an optical writing unit supported at four points, the number of support points is reduced, thereby reducing the locations to perform accurate alignment. Accordingly, it is possible to manufacture the apparatus at a low cost.
The alignment of the optical writing unit 70 in the rotating direction around a virtual axis that extends in the front-rear direction can be carried out, by supporting the optical writing unit 70 with the left side plate 80 and the right side plate 90. The alignment of the optical writing unit 70 in the rotating direction around a virtual axis that extends in the left-right direction can be carried out, by supporting the optical writing unit 70 with the rear side plate 120.
In the printer 100, when the optical writing unit 70 is at the operating position, the notch portion of the engaging unit 71e is set so as not to come into contact with the rotation axis 51. Accordingly, even if a user bumps into the upper cover 50 while an image is being formed, and makes the rotation axis 51 bent and vibrated, the vibration of the rotation axis is not directly transmitted to the optical writing unit 70. Accordingly, it is possible to prevent the optical writing unit 70 from vibrating, thereby preventing the writing position from shifting. As a result, it is possible to prevent occurrence of abnormal images such as color shifts and banding.
As shown in
If the distance between the support protrusion 71b and the engaging unit 71e is close, it is possible to reduce the displacement of the engaging unit 71e in the vertical direction, when the optical writing unit 70 is obliquely supported. Accordingly, even if the distance A of the notch portion of the engaging unit 71e in the vertical direction is small, it is possible to prevent the rotation axis 51 and the engaging unit 71e from coming into contact with each other, at the operating position. As a result, it is possible to set the distance A of the notch portion of the engaging unit 71e in the vertical direction, in a range that the optical writing unit 70 does not wobble in the holding frame, while being rotated to the retracted position from the operating position. By disposing the rotation axis 51 so that a part of the projected shape in the vertical direction is overlapped with the rear side plate 120, above the upper surface of the rear side plate 120 (the perpendicular plate), the support protrusion 71b and the engaging unit 71e can be disposed close to each other. Accordingly, even if the optical writing unit 70 is obliquely supported, it is possible to prevent the rotation axis 51 and the engaging unit 71e from coming into contact with each other, at the operating position.
In the printer 100, the left side plate 80 is formed so that the left drum axes of the photosensitive bodies 2Y, 2M, 2C, and 2K are slidably and movably engaged towards the operating position of the optical writing unit 70, with respect to their respective left side image forming alignment grooves of the printer 100, which are not shown, and the engagement with the left drum axes is cancelled by removing the left drum axes that slidably moved a predetermined distance towards the operating position, from the upper end portions of the left side image forming alignment grooves. The right side plate 90 is formed so that the right drum axes of the photosensitive bodies 2Y, 2M, 2C, and 2K are slidably and movably engaged towards the operating position of the optical writing unit 70, with respect to their respective right side image forming alignment grooves 93Y, 93M, 93C, and 93K of the printer 100, and the engagement with the right drum axes is cancelled by removing the right drum axes that slidably moved a predetermined distance towards the operating position, from the upper end portions of the right side image forming alignment grooves 93Y, 93M, 93C, and 93K. In such a configuration, the photosensitive bodies 2Y, 2M, 2C, and 2K can be easily attached and detached with respect to the left side plate 80 and the right side plate 90, by slidably moving each of the photosensitive bodies 2Y, 2M, 2C, and 2K toward the operating position where the optical writing unit 70 being an obstacle is rotationally moved and removed, or by slidably moving thereof in the reverse direction.
In the printer 100, the optical writing unit 70 is an optical writing unit that can serve as one unit to write a latent image with respect to the four photosensitive bodies 2Y, 2M, 2C, and 2K. With such a configuration, unlike when an exclusive optical writing device is provided for optically writing an image in the photosensitive bodies 2Y, 2M, 2C, and 2K, it is possible to determine the optical writing position with respect to each of the photosensitive bodies 2Y, 2M, 2C, and 2K, by aligning one unit. Accordingly, it is possible to further simplify the alignment operation and the setting operation of the optical writing device, thereby improving the maintainability.
In this manner, the optical writing unit 70 moves between the operating position opposed to the four process units 1Y, 1M, 1C, and 1K, and the retracted position not opposed thereto, by rotating around the rotation axis 51 laid across the left side plate 80 and the right side plate 90. With such a configuration, the optical writing unit 70 is moved between the operating position and the retracted position, by fixing the sliding position with the rotation axis 51 in the optical writing unit 70, at the same position with respect to the left side plate 80 and the right side plate 90. Accordingly, it is possible to easily align the optical writing unit 70, compared with when the unit is slidably moved.
As shown in
In this manner, by providing the elastic members 77a, 77b, and 77c, it is possible to absorb an impact when the engaging unit 71e is pressed against the rotation axis 51, or when the alignment axes 71a and 71c are pressed against the rear walls of the openings 72a and 73a of the holding plates 72 and 73. The impact is caused because the optical writing unit 70 is moved to the side of the rear side plate, due to the own weight of the optical writing unit 70, while being rotated to the retracted position from the operating position. Thus, it is possible to soften the impact to the optical writing unit 70, thereby preventing the breakage of the optical writing unit 70.
When the support protrusion 71b and the casing 71 are integrally formed, the height of the support protrusion 71b being high can be adjusted, for example, by scraping. However, when the height of the support protrusion 71b is low, the height cannot be adjusted.
In the printer 98 as shown in
The support protrusion 71b is preferably made of material different from the casing 71, and it is especially preferable to form the support protrusion 71b by a slidable material. A glass fiber reinforced resin is used for the casing 71, to enhance the stiffness. When the optical writing unit 70 is aligned using the leaf spring 94 and the tension coil spring 75, by rotating the optical writing unit 70 to the operating position from the retracted position, the support protrusion 71b slides on the rear side plate 120. At this time, if the support protrusion 71b is made of the same glass fiber reinforced resin as that of the casing 71, the rear side plate 120 is scraped and abraded by the glass fiber of the support protrusion 71b. As a result, the abutment position between the support protrusion 71b and the rear side plate 120 may be abraded and recessed, thereby degrading the alignment accuracy. If the support protrusion 71b is formed of the material different from the casing 71, it is possible to prevent the abrasion of the rear side plate 120, thereby preventing degradation of the alignment accuracy. Particularly, the support protrusion 71b can move smoothly on the upper surface of the rear side plate 120, if the support protrusion 71b is made of a slidable material, thereby further preventing the abrasion of the rear side plate 120.
As shown in
As shown in
As shown in
In the printer 97, the rotation axis 51 is laid across the left side plate 80 and the right side plate 90, and the rotation axis 51 is supported by the left side plate 80 and the right side plate 90. However, the rotation axis 51 may be supported by the rear side plate 120. By supporting the rotation axis 51 with the rear side plate 120, as shown in
For example, when the installation surface is uneven and the position of the right side plate 90 or the left side plate 80 is lowered, the rear side plate 120, the rotation axis 51, and the optical writing unit 70 are inclined at the same angle, thereby keeping the parallel relationship between the rotation axis 51 and the engaging unit 71e.
As shown in
In this manner, by placing the controller 103 on the rear side plate 120, a housing case to house the controller 103 is unnecessary, thereby reducing the number of components.
A harness clamp 105 is rotatably fitted on the rotation axis 51, and the harness 104 between the rotation axis 51 and the optical writing unit 70 is fixed by a clamping unit 105a of the harness clamp 105. As shown in
However, in the printer 96, the harness 104 between the rotation axis 51 and the optical writing unit 70 is fixed by the harness clamp 105. Accordingly, while being at the rotation position, at least the harness 104 between the clamping unit 105a and the optical writing unit 70 does not get loose. Thus, even if the optical writing unit 70 is rotated to the operating position from the retracted position, the harness 104 therebetween will not be caught on the other members in the apparatus. As a result, the harness 104 does not pull the optical writing unit 70 towards the side of the rear side plate. The harness 104 between the clamping unit 105a and the controller 103 gets loose while being at the retracted position. Even if the harness 104 gets caught on the other members while the optical writing unit 70 is rotated to the operating position, the pulling force of the harness 104 is intercepted by the clamping unit 105a, thereby not reaching the optical writing unit 70. As a result, it is possible to prevent the optical writing unit 70 from being pulled towards the side of the rear side plate, at the operating position, and the engaging unit 71e from coming into contact with the rotation axis 51.
The printers 96 to 100, which are the image forming apparatuses, according to the present embodiment includes the photosensitive body 2, the optical writing unit 70, and the holding frame 130. The photosensitive body 2 is the latent image carrier that carries a latent image. The optical writing unit 70 is the latent image writing unit that writes the latent image on the photosensitive body. The holding frame 130 is the holder that can rotate between the operating position where the optical writing unit 70 carries out the writing operation to write a latent image on the surface of the photosensitive body, and the retracted position where the optical writing unit 70 does not carry out the writing operation, around the rotation axis 51 provided in the apparatus main body while holding the optical writing unit 70. When the holding frame 130 is at the operating position, the optical writing unit 70 is supported at three points with respect to the apparatus main body, and the optical writing unit 70 and the rotation axis 51 do not come into contact with each other.
Being configured in this manner, compared with the optical writing unit 70 supported at four points, the location to perform accurate alignment can be reduced, thereby manufacturing the printer at a low cost. Because the engaging unit does not come into contact with the rotation axis 51 at the operating position, it is possible to prevent the vibration of the rotation axis 51 from being directly transmitted to the optical writing unit 70. Accordingly, it is possible to prevent the abnormal images caused by vibration, such as color shifts and banding.
When the holding frame 130 is at the operating position, the optical writing unit 70 is supported by the left side plate 80, the right side plate 90, and the rear side plate 120. The left side plate 80 is the first support plate that supports one end of the photosensitive body 2 of the apparatus main body. The right side plate 90 is the second support plate that supports the other end of the photosensitive body 2. The rear side plate 120 is the perpendicular plate, perpendicular to the left side plate 80 and the right side plate 90. By supporting the optical writing unit 70 with the right side plate 90 and the left side plate 80, it is possible to carry out the alignment around a virtual axis that extends in the front-rear direction, in the rotation direction. By supporting the optical writing unit 70 with the rear side plate 120, it is possible to carry out the alignment around a virtual axis that extends in the left-right direction, in the rotation direction. Accordingly, it is possible to accurately align the optical writing unit 70 in the vertical direction.
The first alignment unit that aligns the left side plate 80 or the right side plate 90 of the optical writing unit 70 in the parallel direction is provided on the left side plate 80 and the right side plate 90. Accordingly, it is possible to align the optical writing unit 70 in the direction substantially perpendicular (front-rear direction) with respect to the rear side plate 120.
The second alignment unit that aligns the optical writing unit 70 at the operating position in the direction substantially perpendicular to the left side plate 80 or the right side plate 90 is provided, by moving the optical writing unit 70 close to the left side plate 80 or the right side plate 90. Accordingly, it is possible to align the optical writing unit in the direction substantially perpendicular (left-right direction) with respect to the left side plate 80 or the right side plate 90.
Particularly, it is preferable to configure the second alignment unit so that the optical writing unit 70 is aligned by moving the optical writing unit 70 close to the left side plate 80. The left side plate 80 is a support plate that supports the photosensitive body motor, which is a driving source, to rotate and drive the photosensitive body 2. The process unit including the photosensitive body 2 is aligned by being moved to the side of the left side plate 80 (the support plate), by which the photosensitive body motor is supported, so as not to be disengaged from the driving gear. Accordingly, by aligning the optical writing unit 70 by moving it close to the side of the left side plate 80, by which the photosensitive body motor is supported in the same direction as the direction that the process unit is being moved close to, it is possible to eliminate the shift between the photosensitive body and the optical writing unit 70, in the direction substantially perpendicular (left-right direction) with respect to the left side plate 80 or the right side plate 90.
The engaging unit 71e that is engaged to the rotation axis 51 is provided at least at the retracted position. The rotation axis 51 is disposed so that an upper portion of the rear side plate 120 and a part of the projected shape in the vertical direction are overlapped with the rear side plate 120. Being configured in this manner, the engaging unit 71e and the support protrusion 71b can be disposed close to each other, thereby preventing the positional fluctuation of the engaging unit 71e in the vertical direction, when the optical writing unit 70 is obliquely supported. Accordingly, even if the distance between the notch portion of the engaging unit 71e and the, rotation axis 51 is small, it is possible to prevent the engaging unit 71e and the rotation axis 51 from coming into contact with each other at the operating position, when the optical writing unit is obliquely supported. Thus, it is possible to at least prevent the optical writing unit from wobbling in the holding frame, when the optical writing unit 70 is at the retracted position.
With the printer 99, it is possible to soften the impact when the notch portion of the engaging unit 71e is pressed against the rotation axis 51, while being rotated to the rotating position from the operating position. This is enabled by providing the elastic member 77c in the notch portion that is an engaging unit abutment location of the rotation axis 51, or a rotation axis abutment location of the engaging unit 71e. Accordingly, it is possible to prevent the breakage of the optical writing unit 70.
With the printer 98, the support protrusion 71b, which is the support unit, of the optical writing unit 70 supported by the rear side plate 120 is formed by components different from the casing of the optical writing unit 70. Accordingly, it is possible to easily adjust the height of the support protrusion 71b, compared with the support protrusion 71b and the casing 71 being integrally formed. It is also possible to enhance the yield, compared with the support protrusion 71b and the casing 71 being integrally formed.
It is also possible to prevent the rear side plate 120 from being abraded by the support protrusion 71b, when the support protrusion 71b slides on the rear side plate 120. This is enabled by forming the support protrusion 71b by material different from the casing 71 of the optical writing unit 70. Accordingly, it is possible to prevent the degradation of the alignment accuracy, caused because the portion that supports the support protrusion 71b of the rear side plate 120 is recessed.
Particularly, by forming the support protrusion 71b with a slidable material, the support protrusion 71b can slide well on the rear side plate 120, thereby preventing the abrasion of the rear side plate 120. Accordingly, it is possible to prevent degradation of the alignment accuracy.
With the printer 96, the housing unit that houses the controller 103, which is the controlling unit, to control the optical writing unit 70, is provided on the rear side plate 120. Accordingly, it is possible to eliminate the housing case that houses the controller 103, thereby reducing the number of the components.
By fixing a part of the harness 104 that electrically connects the optical writing unit 70 and the controller 103, to the harness clamp 105, which is a harness holding member, rotatably fitted on the rotation axis 51, it is possible to limit the loosening of the harness 104 between the harness clamp 105 and the optical writing unit 70, at the retracted position. Accordingly, it is possible to prevent the optical writing unit 70 from being pulled towards the side of the rear side plate, caused because the harness 104 is caught on the other components in the apparatus, when the optical writing unit 70 is rotated to the operating position from the retracted position. As a result, it is possible to prevent the optical writing unit 70 from coming into contact with the rotation axis 51 at the operating position.
With the printer 97, the right and left side alignment bosses 115 and 114 to fit to the rear side plate 120 are provided at each location of the left side plate 80 and the right side plate 90, respectively. The height of the left side alignment boss 114 of the left side plate 80 from the installation surface, and the height of the right side alignment boss 115 of the right side plate 90 from the installation surface are the same. Accordingly, when an external force and the like is applied from the left and the right directions of the printer, the right side plate 90 and the left side plate 80 can be rotated in the same direction at the same angle. Thus, the parallel relationship between the rotation axis 51 and the notch portion of the engaging unit 71e can be maintained. Therefore, compared with an arrangement that the rotation axis 51 is inclined with respect to the notch portion of the engaging unit 71e, the clearance between the rotation axis 51 and the notch portion of the engaging unit 71e can be narrowed. As a result, it is possible to prevent the optical writing unit 70 from wobbling in the holding frame, while the optical writing unit is being rotated.
The rotation axis 51 is laid across the left side plate 80 and the right side plate 90, in parallel with the notch portion, which is a rotation axis engagement location, of the engaging unit 71e. Accordingly, even if the position of the rotation axis 51 fluctuates downwards with respect to the engaging unit 71e, when the right side plate 90 and the left side plate 80 are inclined, it is possible to prevent the rotation axis 51 from coming into contact with the engaging unit 71e, compared with the rotation axis 51 obliquely supported with respect to the notch portion of the engaging unit 71e. Accordingly, compared with the rotation axis 51 obliquely supported with respect to the notch portion of the engaging unit 71e, it is possible to narrow the clearance between the rotation axis 51 and the notch portion of the engaging unit 71e. It is also possible to prevent the optical writing unit 70 from wobbling in the holding frame, while the optical writing unit is being rotated.
The number of components can be reduced by integrally forming the left side plate 80 and the right side plate 90 into an integral structure with resin.
With the invention according an aspect of the present invention, when the holder is at the operating position, the latent image writing unit is supported at three points with respect to the apparatus main body. Accordingly, it is only necessary to perform accurate alignment of the latent image writing unit in the vertical direction at three points, thereby reducing the manufacturing cost, compared with an arrangement that the optical writing unit 70 is supported at four points.
When the holder is at the operating position, the latent image writing unit does not come into contact with the rotation axis. Accordingly, even if the rotation axis is vibrated by a disturbance, the vibration does not directly transmit to the latent image writing unit, compared with an arrangement that the latent image writing unit and the rotation axis come into contact with each other, when the holder is at the operating position. Thus, it is possible to prevent the vibration of the latent image writing unit caused by a disturbance, compared with an arrangement that the latent image writing unit and the rotation axis come into contact with each other, when the holder is at the operating position.
Although the invention has been described with respect to specific embodiments for a complete and clear disclosure, the appended claims are not to be thus limited but are to be construed as embodying all modifications and alternative constructions that may occur to one skilled in the art that fairly fall within the basic teaching herein set forth.
Number | Date | Country | Kind |
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2007-246938 | Sep 2007 | JP | national |