JP2004287077A - Optical scanner - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce the number of installations of a synchronizing detection sensor by guiding a plurality of light beams to one synchronizing detection sensor, without expanding a lens size for introducing synchronizing beams in an optical scanner that is applied to a tandem type image forming apparatus. <P>SOLUTION: In the case where a cylinder array-like lens 83 in Fig.(C) is used as an SOS lens for the synchronization detection of optical beams L in the main scanning direction, in comparison with the case where a regular array lens 530 in Fig.(A) is used as an SOS lens, four light beams L can be fully condensed in a narrow area. Consequently, if the optical path fluctuation of the light beams L is within a desired tolerance relative to the incident position to the lens (e.g., deviation in a subscanning direction is within ±2.5 mm before the lens), the beams can be always kept in line with an SOS sensor 38. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an optical scanning device, and more particularly to a tandem-type digital color copying machine that reproduces a color image in one pass, and an optical scanning device such as a color laser printer.
[0002]
[Prior art]
Conventionally, a digital copying machine that forms an electrostatic latent image by scanning and exposing a light beam modulated in accordance with image information on a charged photoconductor to form an electrostatic latent image, and develops, transfers, and fixes the image by an electrophotographic process, Printers are widely used.
[0003]
Similarly, an electrostatic latent image is formed on a photoconductor in accordance with image signals corresponding to yellow (Y), magenta (M), cyan (C), and black (K), and charged, exposed, and developed. Full-color copying machines and color printers that form a full-color image by superimposing and transferring images are also widely used.
[0004]
Many such full-color image forming apparatuses include a plurality of developing devices corresponding to a plurality of colors (Y, M, C, and K) in a rotary developing device, and rotate the developing device for each image forming process of each color. In this case, a method of forming images of different colors and superimposing and transferring the images to form a full-color image (hereinafter, referred to as a “four-cycle method”) is employed.
[0005]
However, in this four-cycle system, the process is repeated four times in order to obtain a full-color image, so that there is a disadvantage that productivity is reduced to one-fourth or less as compared with the formation of a single-color (monochrome) image. Therefore, a so-called tandem-type image forming apparatus has been devised in which image forming apparatuses corresponding to respective colors are arranged in series and transfer images are sequentially superimposed to form a full-color image in one pass.
[0006]
The following technology is disclosed as a method for detecting synchronization of a plurality of lights with a single sensor in a tandem image forming apparatus.
[0007]
Patent Document 1 discloses a single optical scanning device having a plurality of independent light sources, which has at least one or more mirrors in an optical system in front of a deflector, and which is a light beam group that has passed at least one of the Fθ lenses. Is described for detecting all-color synchronization. Specifically, it has the same number of SOS mirrors as the number of beams (synchronous detection pickup mirrors, SOS is an abbreviation for START OF SCAN), and the angles and directions of these mirrors are different from each other.
[0008]
This is because, in a single optical scanning device having a plurality of independent light sources, the optical system in front of the deflector detects at least one or more mirrors and at least a part of the light beam group that has passed through one Fθ lens in all-color synchronous detection. Are indispensable, and it cannot be detected unless there are substantially the same number of SOS mirrors as the beam and mirror configurations having different angles and directions. In other words, the ray group indicates a state before the ray bundle is separated, and it is extremely difficult to arrange an independent reflecting surface without interfering with other beams in the state of the bundle.
[0009]
FIGS. 15A, 15B and 15C show the configuration of the optical scanning device described in Patent Document 1 and the configuration of an SOS mirror block applied to the optical scanning device, respectively. The optical scanning device 500 shown in FIG. 15A includes scanning optical systems 504Y to 504K corresponding to Y, M, C, and K LD light sources 502Y to 502K, polygon mirrors 506, Y, M, C, and K, respectively. , A common optical system 508, an SOS mirror block 510 (512), and an SOS sensor 522 are arranged.
[0010]
The SOS mirror block 510 shown in FIG. 15B is molded by, for example, glass-containing PC (polycarbonate), and each of the mirrors 512 (Y, M, C, and B) is a block 512A molded at a predetermined angle. Are formed by evaporating a metal such as aluminum, for example. In the SOS mirror block 512 shown in FIG. 15C, four mirrors 514Y, 514M, 514C, and 514K are sequentially bonded to a fixing member 512B integrally formed at a predetermined position of the intermediate base 512A. It is configured.
[0011]
As far as the SOS mirror blocks 510 and 512 shown in FIGS. 15B and 15C are concerned, it is inevitable that a high-quality mirror configuration is obtained. In particular, it is unlikely that the total width of the light beam bundle will be 20 mm or more as judged from the embodiment. Assuming that the entire width is 21 mm, it is 7 mm if it is used evenly at the ends and evenly spaced, but it is extremely difficult to install a 7 mm wide mirror close to the mirror at a predetermined angle. That is, there is a problem that implementation is a configuration that is extremely difficult to achieve.
[0012]
Also, if the total width of the light beam bundle is 20 mm or more, it means that the width in the height direction of the reflecting surface of the deflector also increases, and it becomes difficult to balance the rotating body, and it is inevitable to increase the vibration. is there.
[0013]
Patent Document 2 discloses a technique in which a plurality of light beams scanned by the same reflection surface of a deflector are detected by the same sensor. However, although Patent Document 2 includes a timing chart and the like, it cannot be achieved without a specific configuration. That is, only the concept is disclosed in Patent Literature 2, and there is a problem that a large-sized cylinder lens that covers the beam pitch is required if the conventional technology is used to guide the lens to the generatrix. .
[0014]
[Patent Document 1]
JP-A-7-256926
[Patent Document 2]
JP-A-5-19586
[0015]
[Problems to be solved by the invention]
In view of the above, it is an object of the present invention to combine a plurality of light beams into one light beam without increasing a lens size for introducing a synchronous beam in an optical scanning device applied to a tandem type image forming apparatus. An object of the present invention is to provide an optical scanning device that can reduce the number of installations of the synchronization detection sensor by leading to the synchronization detection sensor.
[0016]
[Means for Solving the Problems]
In order to achieve the above object, an optical scanning device according to claim 1 irradiates a plurality of light beams to a plurality of photoconductors to form an image on the photoconductor. The beams are made incident on an array-shaped lens having no power in the main scanning direction, the plurality of light beams are guided to one synchronization detection sensor by the array-shaped lens, and a plurality of light beams are detected by the one synchronization detection sensor. Is detected.
[0017]
In the optical scanning device according to the first aspect, it is possible to cope with a pickup using a single mirror in a bundled beam portion of a single housing type, and it is possible to introduce the sensor into the sensor without increasing the size of the lens. That is, in the SOS mirror configuration as disclosed in Patent Document 1, good detection is possible even when each beam is displaced in the sub-scanning direction.
[0018]
Here, the exposure method of the tandem-type image forming apparatus may be any of a four-chassis optical scanning device, a facing spray tandem, a Q-BeT optical scanning device, and the like. Note that the opposing spray tandem is a single-chassis optical scanning device having a scanning optical system on both sides facing each other via one deflector, and the Q-BeT tandem is Refers to an optical scanning device of one housing having one scanning optical system. As the details of the Q-BeT type, there are known a beam combining type and a single package multiple light source type.
[0019]
An optical scanning device according to a second aspect of the present invention is the optical scanning device according to the first aspect, wherein a cylinder array lens is used as the array lens.
[0020]
The optical scanning device described in claim 2 shows a specific shape (cylinder) of the array-shaped lens according to claim 1, and the lens shape includes both a simple array-shaped lens and a modified array-shaped lens.
[0021]
4. The optical scanning device according to claim 1, wherein the plurality of light beams are arranged after the last optical element when the synchronization of the plurality of light beams is detected. And the light is guided to the one synchronous detection sensor by the array-shaped lens.
[0022]
According to the optical scanning device of the third aspect, it is possible to detect a beam fluctuation closer to scanning of the photoconductor by the post-reflection of the final optical element excluding the aperture member, so that information closer to the writing image information of the photoconductor is obtained. There is a merit that can be obtained.
[0023]
An optical scanning device according to claim 4, wherein the plurality of scanning optical systems are arranged so as to face each other via a light beam deflector. When detecting the synchronization of a plurality of light beams passing therethrough, the plurality of light beams are deflected by a folding mirror disposed after the last optical element and are incident on the array-shaped lens, and one of the synchronized light beams is synchronized by the array-shaped lens. The method is characterized by leading to a detection sensor.
[0024]
In the optical scanning device according to claim 4, in the opposed spray tandem type optical scanning device, two beams scanned by the same reflecting surface of the deflector are turned by a mirror after the last optical element, and a cylinder array lens is formed. To detect the introduction into the sensor.
[0025]
In the optical scanning device according to claim 5, in the optical scanning device according to claim 4, a reflection mirror is provided as the final optical element, and the reflection mirror is disposed so as to be conjugate with the synchronization detection sensor. In addition, a cylinder array-shaped lens is used as the array-shaped lens, and the sub-scanning deviation of the synchronous detection light with respect to the light beam is corrected by the cylinder array-shaped lens.
[0026]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, an optical scanning device according to an embodiment of the present invention will be described with reference to the drawings.
[0027]
(1st Embodiment)
FIG. 1 shows an optical scanning device according to a first embodiment of the present invention, and FIG. 2 shows a tandem image forming apparatus to which the optical scanning device according to the present embodiment is applied. The image forming apparatus 12 is capable of forming a full-color image. In the optical scanning apparatus 10 in the image forming apparatus 12, usually, each color component of yellow = Y, magenta = M, cyan = C and black = K Since four sets of various types of devices for forming an image for each color component corresponding to each of Y, M, C, and K and four types of image data which are color-separated are used, Y after each reference code is used. , M, C, and K, the image data for each color component and the corresponding device portion are identified.
[0028]
The optical scanning device 10 according to the present embodiment is of a so-called spray tandem type. In order to reduce the number of synchronization detection sensors from four to two in the related art, one synchronization detection sensor is used. Are made to enter two color light beams. Specifically, two light beams scanned in the same direction are incident on one synchronization detection sensor.
[0029]
As shown in FIG. 1, in the optical scanning device 10, the first light beam emitted from the single light emitting source 14Y (here, the first light beam is a yellow light beam LY) changes the light beam. The light passes through a first lens (not shown) for generating a gentle divergent light, passes through an opening member (not shown) having an H-shaped opening for preventing a decrease in the amount of light at the scanning end, and moves in the sub-scanning direction. After passing through a convex and flat cylinder lens 16YM which has only power and converges in the sub-scanning direction, it is reflected in the main scanning direction by the first folding mirror 18YM, and is reflected in the main scanning direction and in the sub scanning direction by the second folding mirror 20YM. And enters the cylinder lens 24YM which is the second scanning image forming lens. The cylinder lens 24YM is a plano-convex cylinder lens having power only in the scanning direction. Then, the light enters the cylinder lens 22YM that is the first scanning image forming lens. The cylinder lens 22YM is a concave cylinder lens having power only in the main scanning direction.
[0030]
The light beam LY emitted from the pair of cylinder lenses 22, 24YM enters a polygon mirror 26, which is a common deflector for four colors (Y, M, C, K). This light beam LY includes a reflecting surface in the main scanning direction and forms an image in the sub-scanning direction, and has an incident angle inclined by 1.25 ° with respect to the scanning optical axis after reflection. The light beam LY reflected by the polygon mirror 26 passes through the cylinder lens 22YM and the cylinder lens 24YM again, and then enters the third folding mirror 28YM.
[0031]
The light beam LY reflected by the third turning mirror 28 is incident on the fourth turning mirror 30Y and then on the fifth turning mirror 32Y. Thereafter, the synchronization light is reflected by the SOS mirror 34Y, which is the sixth folding mirror, passes through the SOS lens 36YM that corrects the positional deviation in the sub-scanning direction, and reaches the synchronization detection sensor (hereinafter, referred to as “SOS sensor”) 38YM. Be guided.
[0032]
Further, in the optical scanning device 10, the second light beam emitted from the single light emitting source 14M disposed on the same scanning direction side as the single light emitting source 14Y via the polygon mirror 26 (here, the second light beam is a magenta light beam). A first lens (not shown) for converting the light beam into gentle divergent light, an aperture member having an H-shaped opening (not shown), and a cylinder lens having power only in the sub-scanning direction. After passing through the light beam LY, it is incident on the first turning mirror 18YM common to the light beam LY at an angle in the sub-scanning direction, and is reflected by the second turning mirror 20YM common to the light beam LY. This light beam LM passes through the same cylinder lens 24YM and cylinder lens 22YM as the light beam LY, and enters the polygon mirror 26. At this time, the light beam LM has an incident angle that is symmetric with the light beam LY in the scanning optical axis.
[0033]
The light beam LM reflected by the polygon mirror 26 again passes through the cylinder lens 22YM and the cylinder lens 24YM, and then enters the third folding mirror 28YM common to the light beam LY, and is provided independently of the fourth light source. The light enters the folding mirror 30M and the fifth folding mirror 32M. The light beam LM is reflected as synchronous light by the SOS mirror 34M, which is the sixth folding mirror, passes through the common SOS lens 36YM that corrects positional deviation in the sub-scanning direction, and is guided to the common SOS sensor 38YM.
[0034]
Here, the fifth folding mirror 32Y and the fifth folding mirror 32M are cylinder mirrors each having power only in the sub-scanning direction, and apply the light beam LY and the light beam LM on the photoconductors 46Y and 46M in the sub-scanning direction. It has the function to form an image. Between the folding mirrors 32Y and 32M and the photoconductors 46Y and 46M, transmission plane glasses 48Y and 48M are disposed for dust protection, respectively. The final optical element referred to in the present invention is a fifth optical element. It points to folding mirrors 42Y and 42M. Here, the fifth folding mirrors 32Y and 32M and the SOS sensor 38YM are in a conjugate relationship.
[0035]
As shown in FIG. 3, the SOS mirror 34 is positioned by a resin holder 50 which is fastened and fixed to a side wall of a casing (not shown) by a screw, and is fixed to the resin holder 50 by an ultraviolet curable adhesive. . The resin holder 50 also holds an independent fourth folding mirror 30. The light beam L reflected by the SOS mirror 34 is directed to the inside of the scan, which contributes to downsizing of the housing of the optical scanning device 10.
[0036]
As shown in FIG. 4, the SOS lens 36 and the SOS sensor 38 for correcting the displacement in the sub-scanning direction are fastened and fixed by screws 54 to a sheet metal holder 52 formed by processing a metal plate. A light-shielding member for preventing reflection from the sensor edge surface is attached to a surface end of the SOS sensor 38. The angles of incidence of the two light beams LY and LM on the polygon mirror 26 are each inclined by 1.25 ° with respect to the scanning optical axis, and there is a relative difference of 2.5 °. This angle difference is the difference between the incident times of the light beam LY and the light beam LM. In the case of the present embodiment, the time difference is about 28 mm in terms of the position of the photoconductor 46.
[0037]
The configuration of the portions corresponding to the light beam LY and the light beam LM in the optical scanning device 10 has been described above. However, the light beam which is the third light beam disposed on the opposite side to these portions via the polygon mirror 26 is described. The portions corresponding to the LC and the light beam LK also have the same configuration as the portions corresponding to the light beam LY and the light beam LM except that they are arranged symmetrically with respect to the rotation axis of the polygon mirror 26. I have.
[0038]
FIG. 5 shows a four-cylinder array lens used as an SOS lens according to the embodiment of the present invention and an array lens used as a conventional SOS lens, respectively. Here, FIGS. 5A and 5B show a cross-sectional shape of an array lens 530 used as a conventional SOS lens, and FIG. 5C shows a cross-sectional shape used as an SOS lens according to an embodiment of the present invention. An example of a cross-sectional shape of a four-cylinder array lens is shown. 6 and 7 show examples of various types of cylinder array lenses applicable as the SOS lens according to the embodiment of the present invention.
[0039]
The conventional array lens 530 shown in FIG. 5A is formed by using acrylic as a material, and has a cylinder surface shape of 5.5 mm in thickness and a radius of 14.5 mm. When this array lens 530 is used as an SOS lens, and four light beams L are deflected by the array lens 530 and are detected by one SOS sensor 38, the correction power of the lens against the optical path fluctuation in the sub-scanning direction is obtained. Is insufficient, the light beam L may deviate from the sensor light receiving portion even if the SOS sensor 38 is manufactured within a desired tolerance. When the array lens 530 is used as an SOS lens, as shown in FIG. 5A, the width of the SOS sensor 38 for detecting the four light beams L is the width of the SOS lens 530. It is necessary to use the same thing as.
[0040]
Further, as shown in FIG. 5B, when four light beams L are incident on the array lens 530 while being deviated from each generatrix, the four light beams L are Although it can be collected in a narrower range, when a two-element silicon PIN photodiode described later is used as the SOS sensor 38, it is necessary to collect four light beams L in a narrower range.
[0041]
On the other hand, when the four-cylinder array lens 83 according to the present invention shown in FIG. 5C is used as an SOS lens, four light beams L are used as compared with the case where the array lens 530 is used as an SOS lens. Can be collected in a sufficiently narrow range.
[0042]
Further, in the optical scanning device 10 according to the present embodiment, any of the two-cylinder array-shaped lenses 84, 86, and 88 shown in FIGS. 6A to 6C can be used as the SOS lens 36. The two-cylinder array lenses 84, 86, and 88 have a generatrix pitch of 4 mm, a thickness of 6.5 mm, and a radius of 6.5 mm. One of the two-cylinder array lenses 84, 86, and 88 is used as the SOS lens 36. Thus, if the optical path variation of the two light beams L is within a desired tolerance with respect to the lens incident position (the deviation in the sub-scanning direction before the lens is within ± 2.5 mm), the SOS sensor 38 is not detached. be able to. As the SOS sensor 38 of the present embodiment, a two-element silicon PIN photodiode is used. The two-element silicon PIN photodiode has a longitudinal size of about 2.4 mm, and two light beams within this range. Need to be surely incident. The condition of the light beam incident on the SOS lens 36 of the cylinder array lens must be incident not parallel to the lens normal.
[0043]
FIG. 8 shows a case where two light beams L are guided to the SOS sensor 38 using the two-cylinder array lenses 84, 86 and 88 according to the present invention as the SOS lens 36, and a case where the conventional cylinder lens 530 is used as the SOS lens. In this case, two light beams L are used to guide the light beam L to the SOS sensor 38. In FIG. 8, the conventional cylinder lens 530 is indicated by a two-dot chain line, and the two-cylinder array lenses 84, 86, 88 according to the present invention are indicated by solid lines.
[0044]
As is apparent from FIG. 8, in order to obtain the same performance as the cylinder array lenses 84, 86, and 88 using the conventional cylinder lens 530, it is necessary to extend the distance between the cylinder lens 530, the SOS sensor 38, and the lens. In addition, since the width of the cylinder lens 530 needs to be longer than the distance between the two light beams L at the installation position, the lens size of the cylinder lens 530 naturally increases. Accordingly, it is difficult to avoid interference with the scanning light of the cylinder lens 530 and interference with other components, and there is a concern about deterioration of moldability and an increase in cost due to material costs.
[0045]
Further, as shown in FIG. 9A, when the cylinder lens 530 is arranged at the same position as the cylinder array lenses 84, 86 and 88 with respect to the sensor surface 38A of the SOS sensor 38, two light beams are emitted. It becomes difficult to guide the beam L within the range of the sensor surface 38A. On the other hand, as shown in FIG. 9B, according to the two-cylinder array lenses 84, 86, and 88 of the present invention, the two light beams L can be guided to a sufficiently narrow range on the sensor surface 38A. .
[0046]
Further, in the case of the optical spray device 10 of the opposed spray tandem type as shown in FIG. 1, the light beam L opposed via the polygon mirror 26 scans the photosensitive member 46 in the opposite direction. It is known that the displacement due to the above-mentioned causes. This displacement can be controlled and corrected by installing a sensor (EOS sensor) 64 at least at one of the EOS (END OF SCAN) positions and monitoring the synchronization. In other words, the shift can be corrected by a change in the time difference between the detection timing of the EOS sensor 64 of the light beam L to be reversely scanned and the detection timing of the SOS sensor 38 of the light beam L to be the forward direction. In this case, it is necessary to arrange two SOS sensors 38 and one EOS sensor 64 in the optical scanning device 10.
[0047]
Further, in the image forming apparatus 12 according to the present embodiment, as illustrated in FIG. 2, four photoconductors 46 </ b> Y to 46 </ b> K are arranged to face the housing 70 of the optical scanning device 10, and An intermediate transfer drum 72YM and an intermediate transfer drum 72CK are arranged so as to be in contact with 46Y, 6M and the photoconductors 46C, 46K. Developing units 76Y to 76K are arranged close to the photoconductors 46Y to 46K. One transfer drum 74 is in contact with the two intermediate transfer drums 72.
[0048]
In the image forming apparatus 12, the four photoconductors 46Y to 46K are scanned by the light beams LY to LK emitted from the optical scanning device 10, respectively, so that Y, M, and An electrostatic latent image corresponding to C and K is formed. These electrostatic latent images are developed into toner images by the developing units 76Y to 76K. Thereafter, the Y and M toner images are transferred and superimposed on the intermediate transfer drum 72YM, and the C and K toner images are transferred and superimposed on the intermediate transfer drum 72CK. The toner image on the intermediate transfer drum 72YM and the toner image on the intermediate transfer drum 72CK are further superimposed on the transfer drum 74 to form a full-color image. The color image on the transfer drum 74 is transferred to the recording paper fed from the tray 80 by the transfer device 78, and is thermally fixed on the recording paper by the fixing device 82.
[0049]
(Second embodiment)
FIG. 10 shows a tandem-type image forming apparatus to which an example of the optical scanning device according to the second embodiment of the present invention is applied. The optical scanning device 110 of the present embodiment is a four-housing type having four independent housings 114Y to 114K, and each of the housings 114Y to 114K has a single light emitting source of the light beam L, an optical system, and the like. Is arranged.
[0050]
Normally, the four-chassis optical scanning device 110 individually has a synchronous sensor such as an SOS sensor inside the housing 114. It is also known that a single-casing type optical scanning device has a synchronization sensor outside the housing. However, the optical scanning device 110 of the present embodiment uses four light beams LY for one SOS sensor 116. By making 入射 LK incident, the number of SOS sensors 116 to be installed is reduced.
[0051]
Note that the scanning optical systems arranged in the four housings 114Y to 114K basically have a common configuration, so that ones corresponding to Y, M, C, and K are distinguished. If it is necessary to do so, one of the symbols Y, M, C, and K is appended to the end of the reference number.
[0052]
In each housing 114 of the optical scanning device 110, the light beam L emitted from the single light emitting source passes through the first lens, which is substantially collimated light, passes through the aperture member, and has power only in the sub-scanning direction, After passing through a cylinder lens that converges in the sub-scanning direction, the light enters a polygon mirror serving as a deflector. At this time, the light beam L is included in the reflection surface of the polygon mirror in the main scanning direction, and forms an image in the sub scanning direction. The light beam L reflected by the polygon mirror is emitted to the outside of the housing 114 through the dustproof transmission member after passing through the imaging lens.
[0053]
The light beam L emitted to the outside of the housing 114 scans (main-scans) on the photoconductor 46, is reflected as synchronous light by the SOS mirror 120 installed at the SOS position outside the scanning range for the photoconductor 46, The light passes through the SOS lens 122 that corrects the positional deviation in the scanning direction, and is guided to the SOS sensor 116. The four SOS mirrors 120Y to 120K respectively corresponding to Y to K are arranged outside the housings 114Y to 114K, respectively, and the housings 114Y to 114K or the main body frame supporting the housings 114Y to 114K ( (Not shown).
[0054]
Each of the SOS mirrors 120Y to 120K has a different reflection angle along the main scanning direction, and the timing of incidence of the light beams LY to LK emitted from the housings 114Y to 114K on the SOS sensor 116 is slightly different. The setting is shifted. The SOS lens 122 and the SOS sensor 116 are arranged between the housing 114M and the housing 114K.
[0055]
As shown in FIGS. 7A to 7F, any of the four-cylinder array lenses 90 to 100 can be used as the SOS lens 122. In the optical scanning device 110, for example, four light beams LY to LK are guided to one SOS sensor 116 using the SOS lens 92.
FIG. 11 shows a tandem image forming apparatus 132 to which a modification of the optical scanning device according to the second embodiment of the present invention is applied. The optical scanning device 130 shown in FIG. 11 is also a four-housing type having four independent housings 134Y to 134K, and each of the housings 134Y to 134K has a single light emitting source of the light beam L and an optical system. Etc. are arranged.
[0056]
In the optical scanning device 130, the SOS lens 136YM and the SOS sensor 138YM are arranged between the housing 134Y and the housing 134M, and the SOS lens 136YM and the SOS sensor 138YM are installed between the housing 134C and the housing 134K. Are located. The configuration of the optical scanning system in each of the casings 134Y to 134K is common to the optical scanning device shown in FIG.
[0057]
In the optical scanning device 130, the light beam LY emitted from the housing 134Y is reflected by the SOS mirror 140Y, enters the SOS lens 136YM, and is guided to the SOS sensor 138YM by the SOS lens 136YM. The light beam LM emitted from the housing 134M is reflected by the SOS mirror 140Y, enters the SOS lens 136YM, and is guided to the SOS sensor 138YM by the SOS lens 136YM. Therefore, the two light beams LY and LM emitted from the housing 134Y and the housing 134M are guided to the SOS sensor 138YM by the common SOS lens 136YM. At this time, the SOS mirror 140Y and the SOS mirror 140M have different reflection angles along the main scanning direction, respectively. It is set so that the incident timing to the light is slightly shifted.
[0058]
As in the case of the light beams LY and LM emitted from the housings 134Y and 134M, the two light beams LC and LK emitted from the housings 134C and 134K are common. The light is guided to the SOS sensor 138CK by the SOS lens 136CK, and enters the SOS sensor 138CK at slightly different timings.
[0059]
Here, as the SOS lens 136YM and the SOS lens 136CK, two-cylinder array lenses 84 to 88 shown in FIGS. 6A to 6C can be used.
[0060]
(Third embodiment)
FIG. 12 shows an image forming apparatus to which an example of the optical scanning device according to the third embodiment of the present invention is applied. FIG. 13 shows a configuration of a scanning optical system in the optical scanning device shown in FIG. The optical scanning device 150 according to the present embodiment is of a four-beam, same-deflection surface scanning type, and is applied to a tandem-type image forming device 152 capable of forming a full-color image.
[0061]
As shown in FIG. 13, the optical scanning device 150 includes, as a light source, a one-chip semiconductor laser array 154 that emits four light beams L including image information of Y, M, C, and K, respectively. A collimator lens 156 that converts divergent light into parallel light is disposed in the emission direction of the semiconductor laser array 154. The light beam L that has been weakly divergent by the collimator lens 156 is corrected by an opening member 158 having an H-shaped opening so that the light amount at the scanning end becomes uniform. This H-shaped opening is particularly effective when combined with an overfilled optical system. Note that the overfilled optical system is one in which a light beam wider than the entire width of the reflection surface of the polygon mirror 160 is incident. Although the light beam line shown in the figure actually has a certain width as a light beam, only the chief ray is displayed to clearly show the arrangement of the optical components.
[0062]
The light beam L that has passed through the cylinder lens 162 enters the first turning mirror 164. The light beam L reflected by the first turning mirror 164 enters the second turning mirror 166. The second folding mirror 166 has an angle in the sub-scanning direction, and the reflected light beam L is inclined in the sub-scanning direction in front of the cylinder lenses 168 and 170 constituting the fθ lens (in the optical axis direction of the optical system). To make the light incident on the reflection surface of the polygon mirror 160 which is a deflector.
[0063]
The width of the beam incident on the polygon mirror 160 in the main scanning direction is wider than the entire width of the deflection surface including the width of the rotation angle corresponding to the scanning and the scanning angle for synchronization detection. It is a beam that is substantially imaged in the sub-scanning direction. The light beam L deflected by the polygon mirror 160 again passes through the cylinder lenses 168 and 170 and enters the plane mirrors 172 and 174.
[0064]
Further, the plane mirrors 172 and 174 are disposed so that the center portion is located substantially on the optical axis of the optical system (on the radial direction of the polygon mirror 160). The reflection surface faces the polygon mirror 160 at an angle, with the top of the long side of the plane mirror 172 and the top of the long side of the plane mirror 174 abutting each other.
[0065]
In this configuration, four light beams LY to LK respectively enter the space surrounded by the plane mirrors 172 and 174, and the light beams L reflected by the reflecting surface intersect and are separated. The collimator lens 156 and the cylinder are arranged such that the two light beams L are incident on the plane mirrors 172 and 174 at substantially equal angles, respectively, on the optical paths that are symmetrical with respect to the optical axis of the optical system. Lens 162 has been adjusted.
[0066]
The light beam L reflected by the plane mirror 172 is reflected inward by the plane mirror 176, and travels to the first cylinder mirror 178 disposed closer to the polygon mirror 160 than the plane mirror 176. The light beam L reflected by the plane mirror 172 is directed to a second cylinder mirror 180 disposed outside the first cylinder mirror 178.
[0067]
The light beam L reflected by the plane mirror 174 is reflected inward by the plane mirror 182, and travels toward the third cylinder mirror 184 disposed closer to the polygon mirror 160 than the plane mirror 182. The light beam L reflected by the plane mirror 174 is directed to a fourth cylinder mirror 186 disposed outside the third cylinder mirror 184.
[0068]
Then, the light beams L reflected by the first to fourth cylinder mirrors 178, 180, 184, 186 are emitted to the outside from the housing 190 and are respectively directed to the photoconductors 46Y to 46K, as shown in FIG. Incident light forms an electrostatic latent image on its surface.
[0069]
As shown in FIG. 12, in the housing 190, four SOS mirrors 192Y to 192K are provided at the ends on the emission side of the light beam L outside the scanning region of the light beams LY to LK (SOS mirrors). Position). These SOS mirrors 192Y to 192K reflect the light beams LY to LK, respectively, and make the light beams enter the SOS lens 194 disposed closer to the polygon mirror 160 than the plane mirrors 172 and 174. As the SOS lens 194, any of the four cylinder array lenses 90 to 100 shown in FIG. 7 can be used. The SOS lens 194 guides the light beams LY to LK to one SOS sensor 196. At this time, the SOS sensor 196 has different reflection angles set for the light beams LY to LK, respectively, and causes the light beams LY to LK to enter the SOS sensor 196 at slightly different timings.
[0070]
FIG. 14 shows an image forming apparatus to which a modification of the optical scanning device according to the third embodiment of the present invention is applied. The optical scanning device 200 according to this modification differs from the optical scanning device 150 shown in FIG. 12 in the configuration of the scanning optical system. Specifically, the optical scanning device 150 uses two plane mirrors 172 and 174 for separating the light beam L, but instead of these planar mirrors, the optical scanning device 200 has a rectangular cross section. The light beam L is separated by using a mirror block 204 having a shape. In other respects, the optical scanning device 200 guides the light beams LY to LK to the SOS lens 194 by four SOS mirrors 192Y to 192K arranged in the housing 202, similarly to the optical scanning device 150. The SOS lens 194 causes the four light beams LY to LK to enter the SOS sensor 196 at slightly different timings.
[0071]
【The invention's effect】
As described above, according to the optical scanning device of the present invention, a plurality of optical scanning devices can be used without increasing the size of an SOS sensor for introducing a synchronous beam in an optical scanning device applied to a tandem-type image forming apparatus. By guiding the beam to one synchronization detection sensor, the number of the synchronization detection sensors to be installed can be reduced.
[Brief description of the drawings]
FIG. 1 is a perspective view illustrating a configuration of an optical scanning device according to a first embodiment of the present invention.
FIG. 2 is a side view illustrating a configuration of an image forming apparatus to which the optical scanning device according to the first embodiment of the present invention is applied.
FIG. 3 is a perspective view illustrating a configuration of a resin holder that holds an SOS mirror in the optical scanning device illustrated in FIG.
FIG. 4 is a side view showing a configuration of a sheet metal holder for holding the SOS lens and the SOS sensor in the optical scanning device shown in FIG.
FIG. 5 is a side view showing a cross-sectional shape of a four-cylinder array lens used as an SOS lens according to an embodiment of the present invention and a cross-sectional shape of an array lens used as a conventional SOS lens.
FIG. 6 is a side view showing a cross-sectional shape of a two-cylinder array lens applicable as the SOS lens according to the embodiment of the present invention.
FIG. 7 is a side view showing a cross-sectional shape of a four-cylinder array lens applicable as the SOS lens according to the embodiment of the present invention.
FIG. 8 shows a case where two light beams are guided to an SOS sensor using a two-cylinder array lens according to the present invention as an SOS lens and a case where two light beams are used as SOS lenses using a conventional cylinder lens 0 as an SOS lens FIG. 7 is a plan view showing a comparison with a case where the sensor is led to a sensor.
FIG. 9 shows a case where two light beams are guided to an SOS sensor using a two-cylinder array lens according to the present invention as an SOS lens and a case where two light beams are used as SOS lenses using a conventional cylinder lens 0 as an SOS lens It is a side view which shows the comparison with the case where it led to the sensor 38.
FIG. 10 is a side view illustrating a configuration of an image forming apparatus to which an example of an optical scanning device according to a second embodiment of the present disclosure is applied.
FIG. 11 is a side view illustrating a configuration of an image forming apparatus to which a modified example of the optical scanning device according to the second embodiment of the present invention is applied.
FIG. 12 is a side view illustrating a configuration of an image forming apparatus to which an example of an optical scanning device according to a third embodiment of the present disclosure is applied.
13 is a perspective view showing a configuration of a scanning optical system in the optical scanning device shown in FIG.
FIG. 14 is a side view illustrating a configuration of an image forming apparatus to which a modified example of the optical scanning device according to the third embodiment of the present disclosure is applied.
FIG. 15 is a plan view and a perspective view showing a configuration of an optical scanning device described in Japanese Patent Application Laid-Open No. 7-256926 and an SOS mirror block applied to the optical scanning device.
[Explanation of symbols]
10 Optical scanning device
26 Polygon mirror
36 SOS lens
38 SOS sensor
40, 42 Folding mirror (final optical element)
46 Photoconductor
64 EOS sensor
83 cylinder array lens
84, 86, 88 Cylinder array lens
90, 92, 94, 96, 98, 100 Cylinder array lens
110 Optical Scanning Device
116 SOS sensor
120 SOS mirror
130 Optical Scanning Device
136 SOS lens
138 SOS sensor
140 SOS mirror
150 Optical scanning device
192 SOS mirror
194 SOS lens
196 SOS sensor
200 optical scanning device

Claims (5)

In an optical scanning device that forms an image on a photoconductor by irradiating a plurality of light beams to a plurality of photoconductors,
A plurality of light beams are made incident on an array-shaped lens having no power in the main scanning direction, and the plurality of light beams are guided to one synchronization detection sensor by the array-shaped lens, and the one synchronization detection sensor is used. An optical scanning device, wherein a plurality of beams are detected by a sensor. 2. The optical scanning device according to claim 1, wherein a cylinder array lens is used as the array lens. At the time of detecting the synchronization of the plurality of light beams, the plurality of light beams are deflected by a folding mirror disposed after the final optical element and are incident on the array-shaped lens, and the one synchronization beam is detected by the array-shaped lens. The optical scanning device according to claim 1, wherein the optical scanning device is guided to a detection sensor. In a counter-spray tandem-type optical scanning device in which a plurality of scanning optical systems are arranged to face each other via a light beam deflector,
At the time of synchronous detection of a plurality of light beams respectively passing through the plurality of scanning optical systems, the plurality of light beams are deflected by a folding mirror disposed after a final optical element and are incident on the array-like lens, An optical scanning device, wherein the light is guided to one synchronization detection sensor by an array lens. A reflection mirror is provided as the final optical element, and the reflection mirror is disposed so as to be conjugate with the synchronization detection sensor, and a cylinder array lens is used as the array lens, and the cylinder array lens is 5. The optical scanning device according to claim 4, wherein a sub-scanning deviation correction of the synchronization detection light with respect to the light beam is performed.

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