The present application claims priority under 35 U.S.C § 119(e) to Japanese patent application No. 2017-230476, filed on Nov. 30, 2017, is incorporated herein by reference in its entirety.
The present invention relates to an optical writing device and an image forming apparatus.
A full color image forming apparatus of an electrophotographying system includes photoconductor drums corresponding to respective colors of Y (yellow), M (magenta), C (cyanogen), and K (black), forms latent images on the respective photoconductor drums with exposure by an optical writing device, and forms toner images by developing the latent images. Then, the toner images are superimposed one after another on an intermediate transfer belt, and thereafter, the superimposed toner images are transferred onto a sheet, thereby forming a color image.
In the above image forming apparatus, from the demands for miniaturization, without providing an independent optical writing device for each of the colors, an optical writing device has been known that performs scanning by deflecting light beams from a plurality of light sources by a single polygon mirror. In such an optical writing device, also in order to prevent color misalignment, it is necessary to make the image formation positions of respective colors coincident with each other with high accuracy. Therefore, it is necessary to set a holding method of optical elements, such as a lens and a reflective mirror, in consideration of the influence of vibration or thermal expansion due to a temperature change in an optical writing device.
Patent Literature 1 (JP 2008-26410A) discloses an optical writing device in which a pair of scanning optical systems and light sources are disposed to face each other across a polygon mirror and the center of a writing width of a surface to be scanned by each of the pair of scanning optical systems and the center of rotation of the polygon mirror are disposed to be on a straight line.
Moreover, Patent Literature 2 (JP 2006-184650A) discloses an optical writing device in which a pair of scanning optical systems and light sources are disposed to face each other across a polygon mirror plane-symmetrically, and a scanning lens of one scanning optical system is brought in contact with a writing start side and a scanning lens of the other scanning optical system is brought in contact with a writing end side.
In the case of the constitution as disclosed in Patent Literature 1, the light sources and the optical systems are arranged point symmetrically relative to the rotation axis of the polygon mirror. In such a constitution, it is easy to align the writing start positions of respective colors, and then, effects for jitter correction can be expected. On the other hand, in the case where the optical elements have twisted due to the influence of vibration etc., it becomes easy to visually recognize pitch unevenness caused by differences in the image formation positions (registration) of the respective colors, and there arises a problem that a high quality image cannot be acquired.
On the other hand, in the constitution as disclosed in Patent Literature 2, in the case where the light sources and the optical systems are arranged plane symmetrically relative to the rotation axis of the polygon mirror, since the profiles of deviations in the sub-scanning direction at positions in the main scanning direction are aligned, the effects for the visibility of the above-mentioned pitch unevenness can be expected. On the other hand, in the case where the optical elements have twisted due to the influence of vibration etc., there arises a problem that the jitter correction to align the image formation positions in the main scanning direction cannot be performed with high accuracy.
The present invention has been achieved in view of the above-described circumstances, and an object is to provide an optical writing device, and an image forming apparatus capable of achieving both jitter correction with high accuracy and suppression of pitch unevenness.
To achieve the above-mentioned object, according to an aspect of the present invention, an optical writing device reflecting one aspect of the present invention is an optical writing device includes first and second light source units each of which includes one or more light sources; a single polygon mirror that deflects a light beam emitted from each of the first and second light source units; a first scanning optical system that includes one or more reflective optical elements to reflect a light beam and one or more transmissive optical elements to transmit a light beam and forms an image with a light beam emitted from the first light source unit and deflected by the polygon mirror; a second scanning optical system that includes one or more reflective optical elements to reflect a light beam and one or more transmissive optical elements to transmit a light beam and forms an image with a light beam emitted from the second light source unit and deflected by the polygon mirror; and a plurality of first light detecting sensors that are disposed so as to correspond to respective light beams emitted from the first and second light source units and are used for controlling a writing start timing; wherein the first and second light source units, the first and second scanning optical systems, and a housing for holding these components are constituted plane symmetrically relative to a plane including a rotation axis of the polygon mirror and being parallel to a scanning line, in the reflective optical elements held at both end sides in the main scanning direction in the first and second scanning optical systems, a number of hold points for positioning is different between a writing start side and a writing end side in scanning of a light beam, in the reflective optical elements of the first and second scanning optical systems disposed in the optical axis direction from after the polygon mirror to before a separation mirror to guide a light beam to the first light detecting sensor, a number of hold points on each of a writing start side and a writing end side in scanning is same, and in the reflective optical elements disposed from after the separation mirror up to a surface to be scanned, a number of hold points on the writing start side of the first scanning optical system is same with a number of hold points on the writing end side of the second scanning optical system, and a number of hold points on the writing end side of the first scanning optical system is set to same with a number of hold points on the writing start side of the second scanning optical system.
The advantages and features provided by one or more embodiments of the invention will become more fully understood from the detailed description given hereinbelow and the appended drawings which are given by way of illustration only, and thus are not intended as a definition of the limits of the present invention.
Hereinafter, with reference to attached drawings, embodiments of the present invention will be described in detail. However, the scope of the invention is not limited to the disclosed embodiments. In the description for the drawings, the same constitutional element is provided with the same reference symbol, and the overlapping description is omitted. Moreover, the dimensional ratios in the drawings are exaggerated on account of description, and, may be different from the actual ratios. In the drawings, the vertical direction is defined as the Z direction, the front-to-rear direction in the image forming system is defined as the Y direction, and a direction orthogonal to each of the Z and Y directions is defined as the X direction. Furthermore, in the optical writing device described in the below, a scanning direction (scanning line direction or main scanning direction) is set to the Y direction, the optical axis direction is located on an XZ flat surface, and a part of it is the same as the X direction.
Hereinafter, with reference to
As shown in
(Image Former 20)
The image former 20 includes an image creating unit 21, an intermediate transfer belt 22, a primary transfer roller 23, and a secondary transfer roller 24.
The image creating units 21 includes a plurality of image creating units corresponding to respective colors of Y (yellow), M (magenta), C (cyanogen), and K (black), each of which has the same constitution except that the color of toner used for developing is different.
The image creating unit 21 of each of the colors includes a photoconductor drum 211 being a drum-shaped photoconductor, an electrifying electrode 212, a developer 213, and a cleaner 214.
The photoconductor drum 211 that rotates counterclockwise is electrified with the electrifying electrode 212, and thereafter, on its surface, an electrostatic latent image is formed by exposure with light beams B (indicated with an arrow of a broken line in the illustration) emitted from the optical writing device 10 on the basis of image signals. In this connection, each of the two right and left optical writing devices 10 shown in
The electrostatic latent image formed on the surface of the photoconductor drum 211 is developed by the developer 213, whereby a mono-color toner image is formed. The mono-color toner image formed by each of the image creating units 21 is superimposed sequentially on the intermediate transfer belt 22 by the primary transfer roller 23 of a corresponding color among the colors, and thereafter, a color toner image composed of the superimposed toner images is transferred by the secondary transfer roller 24 onto a sheet. The color toner image transferred on the sheet is heated and pressed by a fixing device (not shown) located at a downstream side, whereby the color toner image is fused and fixed on the surface of the sheet. On the other hand, the remaining toner remaining on the photoconductor drum 211 without being transferred is cleaned by the cleaner 214.
(Optical Writing Device 10)
As mentioned in the above, the optical writing device 10 for C and K colors and the optical writing device 10 for Y and M colors are equipped with the same constitution. In
The optical writing device 10 includes a first light source unit 11a, a second light source unit 11b, a polygon mirror (deflector) 124, a first scanning optical system 13, a second scanning optical system 14, an SOS (Start Of Scan) sensor 15, a housing 19, and so on. The first scanning optical system 13 is a scanning optical system for C, and the second scanning optical system 14 is a scanning optical system for K, and each of them forms an image on a surface (photoconductor drum 211) to be scanned with a light beams B deflected by the polygon mirror 124.
Each of the first light source unit 11a and the second light source unit 11b includes a light control board 111 and a light source 112. Each of the first light source unit 11a and the second light source unit 11b may include a plurality of light sources 112 (for example, two or four light sources 112) so as to be able to perform exposure along a plurality of lines simultaneously on a surface to be scanned by scanning of one time.
In
As shown in
The first scanning optical system 13 includes a first scanning lens 131, a first mirror 132, a second mirror 133, a second scanning lens 134, a third mirror 135, and a separation mirror 136. Similarly, the second scanning optical system 14 includes a first scanning lens 141, a first mirror 142, a second mirror 143, a second scanning lens 144, a third mirror 145, and a separation mirror 146. Each scanning lens functions as a “transmissive optical element”, and each mirror functions as a “reflective optical element”. In this connection, in each illustration, the reflective optical element is indicated with a gray color.
As shown in
As shown in
The light beams B (C) and B (K) having been guided to the lower housing 192 pass through these optical elements, and thereafter, expose the surfaces, being the surface to be scanned, of the photoconductor drum 211 (C) and 211 (K) through dustproof windows w (refer to
Moreover, the light beams B enter the separation mirrors 136 and 146 each disposed at the end of the upper stream side in the main scanning direction, are reflected thereon, and are guided to the respective SOS sensors 15. The SOS sensor 15 is constituted by a photodiode, and functions as “a first light detecting sensor”. The SOS sensor 15 is used for a writing start timing control. In concrete terms, the writing start timing on a main scanning line is controlled by detecting the incident timing of the light beam B with the SOS sensor 15. The position of this SOS sensor 15 is arranged at a position equivalent to a surface to be scanned in the optical axis direction.
(Number and Position of Hold Point of Reflective Optical Element)
The third mirror 135 is a plate-shaped member, and as shown in
As shown in
Moreover, in the first embodiment, as can be understood from
(i) In the first scanning optical system 13 and the second scanning optical system 14, in all the reflective optical elements held at both ends, the number of hold points is different on the writing start side and on the writing end side. In concrete terms, as shown in
(ii) In the reflective optical elements disposed in the optical axis direction from after the polygon mirror 124 to before the separation mirrors 136 and 146, i.e., in the mirrors 132 and 133 of the first scanning optical system 13 and the mirrors 142 and 143 of the second scanning optical system 14, the number of hold points is the same on the writing start side and on the writing end side. That is, the number of hold points on the writing start side is one together, and the number of hold points on the writing end side is two together. In this way, the reflective optical elements and the hold points disposed from after the polygon mirror 124 to before the separation mirrors 136 and 146 are arranged point symmetrically relative to the axis x1 of the polygon mirror 124.
(iii) Moreover, in the reflective optical elements disposed from after the separation mirrors 136 and 146 up to the surface to be scanned, i.e., in the third mirror 135 of the first scanning optical system 13 and the third mirror 145 of the second scanning optical system 14, the number of hold points on the writing start side of the third mirror 135 and the number of hold points on the writing end side of the third mirror 145 are the same one, and the number of hold points on the writing end side of the third mirror 135 and the number of hold points on the writing start side of the third mirror 145 are set to the same two. That is, the reflective optical elements and hold points disposed from after the separation mirrors 136 and 146 up to the surface to be scanned are arranged plane symmetrically relative to a plane including the axis x1 of the polygon mirror 124 and parallel to the scanning line.
(Effect)
Hereinafter, the effects of the first embodiment are described with reference to
As shown in the comparative example of
Moreover, as shown in the comparative example in
On the other hand, as shown in
Namely, in the present embodiment, in the optical writing device that deflects light beams from the first and second light source units by a single polygon mirror, the first and second light source units, the first and second scanning optical systems, and the housing holding these components are constituted plane symmetrically relative to a plane including the rotation axis of the polygon mirror and being parallel to a scanning line; in the reflective optical elements held at both end sides in the main scanning direction in the first and second scanning optical systems, the number of hold points for positioning is different between the writing start side and the writing end side in scanning of a light beam; in the reflective optical elements of the first and second scanning optical systems disposed in the optical axis direction from after the polygon mirror to before the separation mirror to guide a light beam to the first light detecting sensor for controlling a writing start timing, the number of hold points on each of the writing start side and the writing end side in scanning is the same; and in the reflective optical elements disposed from after the separation mirror up to a surface to be scanned, the number of hold points on the writing start side of the first scanning optical system is the same with the number of hold points on the writing end side of the second scanning optical system, and the number of hold points on the writing end side of the first scanning optical system is set to the same with the number of hold points on the writing start side of the second scanning optical system. Since the optical writing device is constituted in the above arrangement, it becomes possible to perform both of the jitter correction with high accuracy and the suppression of pitch unevenness.
(Other Effect)
Moreover, as shown in
Furthermore, as shown in
In this connection, as a further modified example, for the constitution shown with
The EOS sensor 16 includes the constitution similar to that of the SOS sensor 15, and functions as “a second light detecting sensor”. The EOS sensor 16 is used for controlling a writing end timing, and in addition, by cooperating with the SOS sensor 15, is also used for adjusting a magnification in the main scanning direction. In concrete terms, a light beam B having entered the separation mirror 137 (and separation mirror 147) is reflected thereon, and is guided to EOS sensor 16. The writing end timing of the main scanning line is adjusted by detecting the incident timing of the light beam B by the EOS sensor 16, whereby the magnification of the main scanning direction is adjusted. In the optical axis direction, the separation mirrors 137 and 147 are disposed at the positions corresponding to the separation mirrors 136 and 146 for the SOS sensor 15, respectively. Moreover, the position of the EOS sensor 16 is arranged at a position equivalent to a surface to be scanned in the optical axis direction.
In this way, in the second embodiment, by disposing the EOS sensor 16, in addition to the effects similar to those in the first embodiment, it is possible to perform the magnification adjustment in the main scanning direction with high accuracy. Moreover, before the separation mirror, the number of hold points of a reflective optical element on the writing end side is set to two, and the number of hold points on the writing start side is set to one. In this way, by setting the number of hold points on the EOS sensor 16 side (the writing end side) to two, it is possible to suppress the deviation of a light beam entering the EOS sensor 16 and to perform the correction of the magnification in the main scanning direction with high accuracy.
Moreover, with regard to each of the transmissive optical elements (scanning lenses 131, 141, 134, and 144) before the separation mirror, they are held at their both ends, and the number of hold points is different between the writing start side and the writing end side (similarly to the above-mentioned constitution (i)). Moreover, in the transmissive optical elements of each of the first scanning optical system 13 and the second scanning optical system 14, the number of hold points on the writing start side and the number of hold points on the writing end side are the same (similarly to the above-mentioned constitution (ii)).
In this way, in the second embodiment, also with regard to the transmissive optical elements, since the one point holding side is more easily influenced by twist or vibration, not only the above-mentioned constitutions (i) to (iii) for the reflective optical elements, but also the similar constitution is adopted for the transmissive optical elements, whereby jitter correction can be performed with higher accuracy.
The optical writing device 10 in the third embodiment includes a first adjustment mechanism 17 and a second adjustment mechanism 18.
As shown in
As shown in
In this connection, in
Moreover, with regard to the transmissive optical elements from after the polygon mirror 124 to before the separation mirror, i.e., the second scanning lens 134 and the second scanning lens 144, the second adjustment mechanism 18 to move the hold point to hold the end portion side in the main scanning direction is disposed so as to make it possible to adjust the inclination of the optical axis direction. Among the first scanning optical system 13 and the second scanning optical system 14, in one scanning optical system of them, the second adjustment mechanism 18 is disposed on the writing start side, and in the other scanning optical system of them, the second adjustment mechanism 18 is disposed on the writing end side. For example, as shown in
In this connection, in the third embodiment, an example in which the second adjustment mechanism 18 is disposed on the second scanning lens 134 and 144, has been shown. However, in place of this example, or together with this example, the second adjustment mechanism 18 may be disposed on the first scanning lens 131 and 141.
In this way, in the third embodiment, the angle adjustment for the reflective optical element after the separation mirror, can be performed by the first adjustment mechanism 17. By doing in this way, it becomes possible to perform the registration adjustment in the sub-scanning direction without influencing a light beam B that enters the SOS sensor 15 or the SOS sensor 15 and the EOS sensor 16.
Moreover, in the third embodiment, among the first and second scanning optical systems 13 and 14, in one scanning optical system of them, the second adjustment mechanism 18 is disposed on the writing start side, and in the other scanning optical system of them, the second adjustment mechanism 18 is disposed on the writing end side. By doing in this way, the adjustment sides in the main scanning direction on an image can be aligned, and it becomes easy to align the registration position of each of the colors in the first and second scanning optical systems 13 and 14. That is, it becomes possible to perform the registration adjustment with high accuracy, and it becomes difficult to visually recognize color misalignment.
(Power of Transmissive Optical Element)
As shown in
With regard to the constitution of each of the optical writing device described in the above and the image forming apparatus equipped with this, the main constitution has been described for describing the feature of the above-described embodiment. Accordingly, the constitution is not limited to the above-described constitution, and within a scope of claims, various modification can be made. Moreover, the constitution equipped in a general optical writing device or an image forming apparatus is not excluded.
For example, in the embodiment shown in
Although embodiments of the present invention have been described and illustrated in detail, the disclosed embodiments are made for purpose of illustration and example only and not limitation The scope of the present invention should be interpreted by terms of the appended claims.
Number | Date | Country | Kind |
---|---|---|---|
2017-230476 | Nov 2017 | JP | national |