JP2020187176A - Optical scanning device and image forming device having the same - Google Patents

Abstract

To provide an optical scanning device which can be reduced in size and thickness, and an image forming device having the same.SOLUTION: An optical scanning device 10 is provided, comprising a polygon mirror 53 for deflecting a light beam 52, and a plurality of reflective mirrors configured to reflect and direct the light beam 52 to respective photosensitive drums 13. A first fθ lens 71 is provided in a path of the light beam 52 from the polygon mirror 53 to a first reflective mirror 61. A path of the light beam 52 reflected by a third reflective mirror 63 crosses a light path between the first reflective mirror 61 and a second reflective mirror 62.SELECTED DRAWING: Figure 5

Description

The present invention relates to an optical scanning apparatus that scans an object to be scanned by an optical beam, and an image forming apparatus including the optical scanning apparatus.

In an electrophotographic color image forming apparatus, the surface of each photoconductor (each object to be scanned) corresponding to a plurality of colors is uniformly charged, and then each photoconductor surface is scanned by each light beam to scan each photoconductor. Each electrostatic latent image is formed on the surface, the electrostatic latent image on the surface of each photoconductor is developed with the toner of each color, the toner image of each color is formed on the surface of each photoconductor, and the toner image of each color is each photosensitive. A color toner image is formed on the intermediate transfer body by superimposing and transferring from the body to the intermediate transfer body, and the toner image of this color is transferred from the intermediate transfer body to the recording paper. The scanning of each photoconductor by the light beam is performed by an optical scanning device, and generally, four photoconductors are scanned by at least four light beams using four color toners of black, cyan, magenta, and yellow. Need to scan.

In recent years, there has been a demand for miniaturization and thinning of image forming apparatus, and there is a demand for miniaturization and thinning of optical scanning apparatus. For example, in the optical scanning apparatus described in Patent Document 1, a plurality of reflection mirrors are arranged in the optical path of the light beam from the deflection portion, and an fθ lens is provided in the optical path of the light beam from the reflection mirror. Further, each light beam emitted from the light source is reflected by a deflection unit and distributed to each optical system, and each optical system is configured to make each light beam incident on each photoconductor.

Japanese Unexamined Patent Publication No. 2001-201707

In the conventional optical scanning device, a plurality of reflection mirrors that separate an integrated light beam into each color are arranged at intervals in the sub-scanning direction, and are arranged at intervals in the rotation axis direction of the deflection portion. It is arranged so that it does not overlap. Then, the light beam folded back by such an arrangement form is configured to be distributed to each optical system. Therefore, the arrangement of the plurality of reflection mirrors requires a thickness in the height direction of the optical scanning device, which is an adverse effect on the miniaturization and thinning of the optical scanning device.

The present invention has been made in view of the above circumstances, and an object of the present invention is to satisfactorily distribute a light beam to each optical system by a plurality of reflection mirrors, and to further reduce the size and thickness. It is an object of the present invention to provide an optical scanning apparatus capable of the present invention and an image forming apparatus including the optical scanning apparatus.

The solution of the present invention for achieving the above object is premised on an optical scanning device that deflects a light beam emitted from a light source to scan an object to be scanned, and the light source and the light beam emitted from the light source. A deflecting portion that deflects the light, at least three reflecting mirrors that reflect the light beam deflected by the deflecting portion and guide the light beam to a specific object to be scanned, and reflection of one of the reflecting mirrors from the deflecting portion. A first optical member provided on the optical path of the light beam to the mirror and having a light-collecting characteristic is provided, and the reflection mirror is mounted on the first, second, and second in order from the upstream side of the optical path of the light beam. Assuming that the reflection mirror of No. 3, the optical path of the light beam reflected by the third reflection mirror crosses the optical path between the first reflection mirror and the second reflection mirror. It is characterized in that the second and third reflection mirrors are arranged.

Due to this specific matter, in the optical path in which the light beam deflected by the deflection portion is reflected by a plurality of reflection mirrors and guided to the object to be scanned, the reflection mirrors are collectively arranged while ensuring a sufficient optical path length. It is possible to make it compact.

More specific configurations of the optical scanning apparatus include the following. That is, on the optical path, the first reflection mirror on which the light beam is incident through the first optical member and the second reflection that receives the light beam reflected by the first reflection mirror. It is preferable that the mirror and the third reflection mirror that receives the light beam reflected by the second reflection mirror are arranged.

Further, in the optical scanning apparatus of the present invention, the optical path of the light beam reflected by the third reflection mirror crosses the optical path of the light beam from the first optical member to the first reflection mirror. It is preferably configured.

Further, in the optical scanning apparatus of the present invention, it is preferable that the reflection mirrors are provided so that the angle formed by the incident light and the reflected light of the light beam on the reflection mirror is an acute angle.

Further, in the optical scanning apparatus of the present invention, a second optical member having a condensing characteristic is provided on the optical path of the light beam from the third reflecting mirror to the scanned object, and the second optical is provided. The optical path of the light beam incident on the member is the optical path of the light beam from the first optical member to the first reflection mirror and the optical path between the first reflection mirror and the second reflection mirror. It is preferably configured to cross.

Further, in the optical scanning device having the above configuration, when a plane orthogonal to the rotation center axis of the deflection portion and equally dividing the reflection surface of the deflection portion is used as a reference plane, or orthogonal to the rotation center axis of the deflection portion. When the plane including the optical path of the light beam between the deflection portion and the reflection mirror most distant from the deflection portion is used as a reference plane, the second reflection mirror is arranged on the side to be scanned of the reference plane. It is preferable that the first reflection mirror and the third reflection mirror are arranged on the opposite side of the reference plane to the object to be scanned.

Further, in the optical scanning apparatus having the above configuration, a fourth reflection mirror that receives the light beam reflected by the third reflection mirror may be further provided on the optical path of the light beam. In that case, the first reflection mirror and the third reflection mirror are arranged on the side of the reference surface to be scanned, and the second reflection mirror and the fourth reflection mirror are on the side of the reference surface to be scanned. It is preferably disposed on the opposite side.

In order to achieve the above object, even an image forming apparatus provided with an optical scanning apparatus having the above configuration is within the scope of the technical idea of the present invention. That is, the optical scanning device is provided as the image forming apparatus, a latent image is formed on the scanned object by the optical scanning device, and the latent image on the scanned object is developed into a visible image. It is characterized in that a visible image is transferred and formed on paper from the object to be scanned.

According to the present invention, in an optical path in which a deflected light beam is reflected by a plurality of reflection mirrors and guided to an object to be scanned, a plurality of the reflection mirrors are integrated and provided while ensuring a sufficient optical path length. Therefore, it is possible to realize miniaturization and thinning as an optical scanning device and an image forming device.

It is sectional drawing which shows the image forming apparatus provided with the optical scanning apparatus which concerns on this invention. It is a top view which shows the optical scanning apparatus which concerns on this invention. FIG. 5 is a perspective view showing the inside of a housing from which the upper lid of the optical scanning device according to the first embodiment of the present invention has been removed when viewed from diagonally above. It is explanatory drawing which shows the arrangement position of each optical member in the optical scanning apparatus which concerns on Embodiment 1 by the cross section. It is explanatory drawing which extracts and shows a plurality of optical members of the optical scanning apparatus which concerns on Embodiment 1. FIG. It is explanatory drawing which extracts and shows a plurality of optical members of the optical scanning apparatus which concerns on Embodiment 2. FIG.

Hereinafter, the optical scanning apparatus 10 and the image forming apparatus 1 according to the embodiment of the present invention will be described with reference to the drawings.

FIG. 1 is a cross-sectional view showing an image forming apparatus 1 provided with an optical scanning apparatus 10 according to the present invention. The image data handled in the image forming apparatus 1 corresponds to a color image using each color of black (K), cyan (C), magenta (M), and yellow (Y), or a single color (for example, black). It corresponds to the monochrome image used. Therefore, four developing devices 12, a photoconductor drum 13, a drum cleaning device 14, a charging device 15, and the like are provided in order to form four types of toner images according to each color, and each of them is black and cyan. , Magenta, and yellow, and four image stations Pa, Pb, Pc, and Pd are configured.

In each of the image stations Pa, Pb, Pc, and Pd, after removing and recovering the residual toner on the surface of the photoconductor drum 13 by the drum cleaning device 14, the surface of the photoconductor drum 13 is brought to a predetermined potential by the charger 15. It is uniformly charged, the surface of the photoconductor drum 13 is exposed by the optical scanning device 11, an electrostatic latent image is formed on the surface, and the electrostatic latent image on the surface of the photoconductor drum 13 is developed by the developing device 12. A toner image is formed on the surface of the photoconductor drum 13. As a result, toner images of each color are formed on the surface of each photoconductor drum 13.

Subsequently, while moving the intermediate transfer belt 21 orbiting, the residual toner of the intermediate transfer belt 21 is removed and recovered by the belt cleaning device 22, and then the toner images of each color on the surface of each photoconductor drum 13 are sequentially transferred to the intermediate transfer belt 21. It is transferred and superposed to form a color toner image on the intermediate transfer belt 21.

A nip area is formed between the intermediate transfer belt 21 and the transfer roller 23a of the secondary transfer device 23, and the recording paper conveyed through the paper transfer path 31 is sandwiched between the nip areas and transferred while being transferred. The color toner image on the surface of the belt 21 is transferred onto the recording paper. Then, the recording paper is sandwiched between the heating roller 24 and the pressurizing roller 25 of the fixing device 17 to heat and pressurize, and the color toner image on the recording paper is fixed.

The recording paper is pulled out from the paper cassette 18 by the pickup roller 33, conveyed through the paper transport path 31, passes through the secondary transfer device 23 and the fixing device 17, and reaches the paper output tray 39 via the paper output roller 36. Is carried out. In the paper transport path 31, the recording paper is temporarily stopped, the tips of the recording paper are aligned, and then the recording paper is aligned with the transfer timing of the toner image in the nip area between the intermediate transfer belt 21 and the transfer roller 23a. A resist roller 34 for starting the transfer, a transfer roller 35 for promoting the transfer of recording paper, and the like are arranged.

(Embodiment 1)
Next, the first embodiment of the optical scanning apparatus 10 of the present invention provided in the image forming apparatus 1 will be described with reference to FIGS. 2 to 5.

FIG. 2 is a top view showing the optical scanning device 10, FIG. 3 is a perspective view showing the optical scanning device 10 with the upper lid 42 removed and viewed from diagonally above, and FIG. 4 is a perspective view of each of the optical scanning devices 10. It is explanatory drawing which shows the arrangement form of the optical member by the cross section, and FIG. 5 is the explanatory view which shows by extracting a plurality of optical members of an optical scanning apparatus 10. As shown in FIG. 3 and the like, the direction orthogonal to the main scanning direction Y is defined as the sub-scanning direction X, and the direction orthogonal to the main scanning direction Y and the sub-scanning direction X (longitudinal direction of the rotation center axis G of the polygon mirror 53). ) Is the height direction Z, which will be described below.

As shown in FIGS. 2 and 3, the housing 41 of the optical scanning device 10 has a rectangular upper lid 42, a bottom plate 43, and four side plates 44 surrounding the bottom plate 43. The housing 41 is blocked by the upper lid 42 to prevent dust. The optical scanning device 10 guides the light beam 52 emitted from a plurality of light emitting elements (semiconductor lasers) 51 as a light source to the reflecting surface of the polygon mirror 53, and reflects the light beam 52 on the reflecting surface of the polygon mirror 53. To deflect.

The reflected light beam 52 is guided to the photoconductor drum 13 as the object to be scanned by each optical member provided in the housing 41. The optical scanning device 10 is configured to scan each corresponding photoconductor drum 13 with such an optical beam 52.

As shown in FIG. 2, from each light emitting element 51 to the polygon mirror 53, four collimator lenses 54, four first mirrors 55a, 55b, and a cylindrical lens 56, in the order from each light emitting element 51 to the polygon mirror 53, And the second mirror 57 is arranged.

The collimator lens 54 converts the light beam 52 emitted from the light emitting element 51 into parallel light. The three first mirrors 55b reflect the light beam 52 incident from the three light emitting elements 51 through the respective collimator lenses 54 onto the one first mirror 55a. One first mirror 55a reflects each light beam 52 reflected by the three first mirrors 55b to the cylindrical lens 56. Further, the light beam 52 transmitted from the other one light emitting element 51 through the collimator lens 54 passes above the first mirror 55a and is incident on the cylindrical lens 56.

The cylindrical lens 56 concentrates the light beam 52 in the sub-scanning direction X and substantially converges on the reflecting surface of the polygon mirror 53 or in the vicinity of the reflecting surface, and the spot of the light beam 52 is focused on the reflecting surface of the polygon mirror 53 or in the vicinity of the reflecting surface. The light beam 52 is emitted as parallel light as it is in the main scanning direction Y which is narrowed down in the vicinity of the reflecting surface and is orthogonal to the sub-scanning direction X.

The polygon mirror 53 corresponds to a deflection portion (rotational polymorphic mirror), rotates at high speed about the rotation center axis G, reflects a light beam 52 on each reflection surface, and repeatedly deflects the light beam 52 in the main scanning direction Y. A plurality of reflection mirrors 6 are provided in the optical path of the light beam 52 from the polygon mirror 53 in order to guide the light beam 52 deflected by the polygon mirror 53 to each photoconductor drum 13.

As shown in FIG. 4, in the optical scanning apparatus 10 according to the present embodiment, the first optical is in the optical path from the polygon mirror 53 to each photoconductor drum 13 in the order from the polygon mirror 53 to each photoconductor drum 13. A first fθ lens 71 as a member, a plurality of reflection mirrors 6, and four second fθ lenses 72 as a second optical member are arranged respectively.

The plurality of reflection mirrors 6 reflect the incident light beam 52 toward each of the photoconductor drums 13. The upper lid 42 is formed with a dustproof window 421 through which the reflected light beam 52 passes. The dustproof window 421 is configured to close the opening of the upper lid 42 with, for example, transparent glass. The light beam 52 that has passed through the dustproof window 421 forms an image on the photoconductor drum 13.

The first fθ lens 71 condenses and emits an optical beam 52 on the surface of each photoconductor drum 13 so as to have a predetermined beam diameter in both the main scanning direction Y and the sub-scanning direction X, and emits a polygon. The light beam 52 deflected by the mirror 53 in the main scanning direction Y at a uniform velocity is converted so as to move at a uniform velocity along the main scanning lines on the respective photoconductor drums 13. As a result, the light beam 52 repeatedly scans the surface of each photoconductor drum 13 in the main scanning direction Y.

The plurality of reflection mirrors 6 provided in the optical path reflect the light beam 52 transmitted through the first fθ lens 71 and make it incident on each of the second fθ lenses 72. The second fθ lens 72 mainly collects a light beam 52 of parallel light in the sub-scanning direction X and squeezes the light beam 52 so as to have a predetermined beam diameter (spot diameter) on the surface of each photoconductor drum 13. In the main scanning direction Y, the focused light beam 52 is emitted to the respective photoconductor drums 13.

In the optical scanning device 10, each light beam 52 is reflected and deflected by the reflecting surface of the polygon mirror 53, enters each photoconductor drum 13 through each optical path, and repeats the surface of each photoconductor drum 13. Main scan. By rotationally driving each photoconductor drum 13, the two-dimensional surface (peripheral surface) of each photoconductor drum 13 is scanned by each light beam 52, and an electrostatic latent image is formed on the surface of each photoconductor drum 13. To.

Among these optical paths, the optical path of the light beam 52 to the magenta (M) photoconductor drum 13 m will be described. As shown in FIG. 5, in the optical path of the light beam 52 to the magenta photoconductor drum 13 m, as a plurality of reflection mirrors 6 between the polygon mirror 53 and the magenta photoconductor drum 13 m, the polygon mirror 53 to the magenta The first reflection mirror 61, the second reflection mirror 62 that receives the light beam 52 reflected by the first reflection mirror 61, and the second reflection mirror 62 reflect the light beam 52 from the upstream side of the optical path in the order toward the photoconductor drum 13m. A third reflection mirror 63 that receives the light beam 52 is provided.

A first fθ lens 71 is provided in the optical path of the light beam 52 from the polygon mirror 53 to the first reflection mirror 61 on the upstream side in the front stage. A second fθ lens 72 is provided in the optical path of the light beam 52 from the third reflection mirror 63 on the downstream side to the magenta photoconductor drum 13 m in the final stage.

As shown in FIG. 4, in the optical scanning device 10, when the plane perpendicular to the rotation center axis G of the polygon mirror 53 and equally dividing the reflection surface of the polygon mirror 53 is set as the reference plane L, the first reflection mirror 61 is It is arranged on the opposite side of the reference surface L on the 13 m side of the photoconductor drum for magenta. Alternatively, the reference plane L is a plane orthogonal to the rotation center axis G of the polygon mirror 53, and the light beam 52 is incident on the black (K) photoconductor drum 13 from the polygon mirror 53 to the K reflection mirror 65. It may be a plane including the optical path of the light beam 52 of. The K reflection mirror 65 is arranged at the position farthest from the polygon mirror 53.

The second reflection mirror 62 is arranged on the magenta photoconductor drum 13 m side with respect to such a reference surface L. Further, the third reflection mirror 63 is arranged on the side opposite to the reference surface L on the magenta photoconductor drum 13 m side.

As shown in FIG. 5, the optical path of the light beam 52 to the third reflection mirror 63 in the last stage crosses the optical path to the first reflection mirror 61 in the front stage, and these first reflection mirrors 61 and 2 A reflection mirror 62 and a third reflection mirror 63 are arranged. The light beam 52 deflected by the polygon mirror 53 is incident on the first reflection mirror 61 via the first fθ lens 71. The light beam 52 reflected by the first reflection mirror 61 is reflected by the second reflection mirror 62 and the third reflection mirror 63, and is incident on the magenta photoconductor drum 13m via the second fθ lens 72.

Here, the first reflection mirror 61, the second reflection mirror 62, and the third reflection mirror 63 are provided in the housing 41 so that the angle formed by the incident light and the reflected light of the light beam 52 is an acute angle. For example, in the example shown in FIG. 5, the angle formed by the incident light and the reflected light of the light beam 52 is 10 degrees (α1) for the first reflection mirror 61, 17 degrees (α2) for the second reflection mirror 62, and the third reflection. In the mirror 63, it is set to 53 degrees (α3).

Similarly, in the reflection mirrors 6 for yellow (Y), cyan (C), and black (B), the angle formed by the incident light and the reflected light of the light beam 52 is an acute angle, which is 13 respectively. The degrees (α4), 74 degrees (α5), 14 degrees (α6), 76 degrees (α7), and 89 degrees (α8) are set.

Further, as shown in FIG. 5, the third reflection mirror 63 is arranged on an extension of an optical path connecting the magenta photoconductor drum 13 m and the second fθ lens 72. As a result, the third reflection mirror 63 is arranged so that the position of the second fθ lens 72 and the optical scanning device 10 in the housing 41 overlap each other when viewed from above. That is, the third reflection mirror 63 and the second fθ lens 72 are arranged so as to have overlapping portions when viewed from the height direction Z along the rotation center axis G.

The first reflection mirror 61 guides the light beam 52 to the second reflection mirror 62. Further, the second reflection mirror 62 guides the light beam 52 to the third reflection mirror 63. In the optical scanning device 10, in the first reflection mirror 61 and the second reflection mirror 62, the optical path of the light beam 52 formed between the first reflection mirror 61 and the second reflection mirror 62 is from the third reflection mirror 63. It is provided so as to cross the optical path to the second fθ lens 72. Further, the optical path from the third reflection mirror 63 to the second fθ lens 72 is provided so as to cross the optical path of the light beam 52 from the first fθ lens 71 to the first reflection mirror 61.

In these first reflection mirror 61 and second reflection mirror 62, the optical path of the light beam 52 formed between the first reflection mirror 61 and the second reflection mirror 62 is from the third reflection mirror 63 to the second fθ lens 72. It is provided so as to cross the optical path of the light beam 52 of.

Further, in the second reflection mirror 62 and the third reflection mirror 63, the optical path of the light beam 52 formed between the second reflection mirror 62 and the third reflection mirror 63 is from the first fθ lens 71 to the first reflection mirror 61. It is provided so as to cross the optical path of the light beam 52 to. These optical paths intersect each other.

In the optical scanning device 10, the first reflection mirror 61 is arranged in the sub-scanning direction X from the polygon mirror 53 so as to be separated from the second reflection mirror 62. Further, in the sub-scanning direction X, the first reflection mirror 61 is arranged so as to be further separated from the polygon mirror 53 in the sub-scanning direction X from the position of the magenta (M) photoconductor drum 13 m.

In the height direction Z orthogonal to the main scanning direction Y and the sub-scanning direction X, the second reflection mirror 62 is arranged at a height position having a portion overlapping the second fθ lens 72. In the exemplary embodiment, the second reflection mirror 62 is provided so as to partially overlap the second fθ lens 72 in the height direction Z, for example, on the photoconductor drum 13 side with respect to the reference plane L (for example, It is arranged on the magenta photoconductor drum 13 m side).

In the optical scanning device 10, the first reflection mirror 61, the second reflection mirror 62, and the third reflection mirror 63 that reflect the light beam 52 deflected by the polygon mirror 53 are arranged based on the regularity as described above. As a result, the folded optical path can be formed a plurality of times, and the optical path length of the light beam 52 from the first fθ lens 71 to the second fθ lens 72 can be sufficiently secured. Moreover, as shown in FIGS. 4 and 5, these plurality of reflection mirrors 6 are widely spaced from each other in the direction along the rotation center axis G of the polygon mirror 53 (the height direction Z of the optical scanning device 10). Since it can be arranged without being provided, it is possible to sufficiently cope with the miniaturization and thinning of the optical scanning apparatus 10 as compared with the conventional case.

Further, it is already known that when the optical path is shaken due to vibration, density unevenness (jitter or banding) occurs in the formed image. On the other hand, in the present embodiment, by arranging a plurality of reflecting mirrors 6 so that the angle formed by the incident light and the reflected light is an acute angle, the occurrence of vibration is suppressed and banding and the like are reduced. , It is possible to reduce the curvature (bow) of the scanning line.

The optical path of the light beam 52 to the yellow (Y) photoconductor drum 13 (13y) among the plurality of optical paths in the optical scanning device 10 will be described. As shown in FIG. 5, the light to the yellow photoconductor drum 13y In the optical path of the beam 52, a first reflection mirror 66 and a second reflection mirror 67 that receives the light beam 52 reflected by the first reflection mirror 66 are provided between the polygon mirror 53 and the yellow photoconductor drum 13y. Is provided. The first fθ lens 71 is arranged in the optical path of the light beam 52 from the polygon mirror 53 to the first reflection mirror 66 in the previous stage. A second fθ lens 72 is arranged in the optical path of the light beam 52 from the second reflection mirror 67 to the yellow photoconductor drum 13y in the subsequent stage.

When the plane perpendicular to the rotation center axis G of the polygon mirror 53 and equally dividing the reflection surface of the polygon mirror 53 is set as the reference plane L, the first reflection mirror 66 has the yellow photoconductor drum 13y with respect to the reference plane L. The second reflection mirror 67 is arranged on the side (above the reference surface L in the height direction Z), and is arranged on the opposite side of the reference surface L on the yellow photoconductor drum 13y side. The first fθ lens 71 is arranged substantially on the reference plane L.

In the first reflection mirror 66 and the second reflection mirror 67, the optical path of the light beam 52 that reaches the yellow photoconductor drum 13y from the second reflection mirror 67 via the second fθ lens 72 is from the polygon mirror 53 to the first fθ lens. It is arranged in the housing 41 so as to cross the optical path of the light beam 52 to 71. Further, these first reflection mirror 66 and second reflection mirror 67 are provided in the housing 41 so that the angle formed by the incident light and the reflected light of the light beam 52 is an acute angle.

Regarding the optical path of the light beam 52 to the yellow (Y) photoconductor drum 13 (13y), the first reflection mirror 66 and the second reflection mirror 67 are arranged based on such regularity, so that a plurality of light beams 52 are arranged. The folded optical path can be formed, and the optical path length of the light beam 52 from the first fθ lens 71 to the second fθ lens 72 can be sufficiently secured. Moreover, the first reflection mirror 66 and the second reflection mirror 67 are arranged in the direction along the rotation center axis G of the polygon mirror 53 (the height direction Z of the optical scanning device 10) without providing a wide space between them. Therefore, it is possible to sufficiently cope with the miniaturization and thinning of the optical scanning apparatus 10 as compared with the conventional case.

In this embodiment, the optical path of the light beam 52 guided to the magenta photoconductor drum 13 m has been described, but the arrangement of the plurality of reflection mirrors 6 shall be similarly applied to the other photoconductor drums 13. However, it is not limited to the magenta photoconductor drum 13 m.

(Embodiment 2)
FIG. 6 is an explanatory view showing by extracting a plurality of optical members in the optical scanning apparatus 10 according to the second embodiment of the present invention. The optical scanning apparatus 10 and the image forming apparatus 1 provided with the optical scanning apparatus 10 according to the second embodiment described below are characterized by the arrangement of a plurality of reflection mirrors 6, and the other basic configurations are the same as those of the first embodiment. Since the same is true, the reflection mirror 6 will be described in detail, and the other configurations will be omitted by using the same reference numerals as those in the first embodiment.

As shown in the figure, in the optical path of the light beam 52 to the magenta photoconductor drum 13 m, as a plurality of reflection mirrors 6 from the polygon mirror 53 to the magenta photoconductor drum 13 m, the polygon mirror 53 to the magenta photoconductor drum 13 m From the upstream side of the optical path, the first reflection mirror 61, the second reflection mirror 62 that receives the light beam 52 reflected by the first reflection mirror 61, and the light beam reflected by the second reflection mirror 62. A third reflection mirror 63 that receives 52 is provided. In the present embodiment, a fourth reflection mirror 64 that receives the light beam 52 reflected by the third reflection mirror 63 is further provided.

In this case, assuming that a plane orthogonal to the rotation center axis G of the polygon mirror 53 and equally dividing the reflection surface of the polygon mirror 53 is used as a reference plane, the first reflection mirror 61 and the third reflection mirror 63 are magenta of the reference plane. It is arranged on the 13m side of the photoconductor drum. Further, the second reflection mirror 62 and the fourth reflection mirror 64 are arranged on the opposite side of the reference surface on the magenta photoconductor drum 13 m side.

The light beam 52 deflected by the polygon mirror 53 is incident on the first reflection mirror 61 via the first fθ lens 71. These plurality of reflection mirrors 6 are provided so that the optical path of the light beam 52 to the fourth reflection mirror 64 in the final stage crosses the optical path to the first reflection mirror 61 in the front stage. The light beam 52 reflected by the fourth reflection mirror 64 is incident on the magenta photoconductor drum 13 m via the second fθ lens 72.

Further, the optical path of the light beam 52 from the third reflection mirror 63 to the fourth reflection mirror 64 crosses the optical path from the first reflection mirror 61 to the second reflection mirror 62. Further, the light beam 52 reflected by the fourth reflection mirror 64 crosses the optical path of the light beam 52 from the first reflection mirror 61 to the second reflection mirror 62.

Each of these reflection mirrors 61, 62, 63, 64 is provided in the housing 41 so that the angle formed by the incident light and the reflected light of the light beam 52 is an acute angle. For example, in the example shown in FIG. 6, the angle formed by the incident light and the reflected light of the light beam 52 is 21 degrees (β1) for the first reflection mirror 61, 48 degrees (β2) for the second reflection mirror 62, and the third reflection. It is 59 degrees (β3) for the mirror 63 and 41 degrees (β4) for the fourth reflection mirror 64.

Similarly, in the reflection mirrors 6 for yellow (Y), cyan (C), and black (B), the angle formed by the incident light and the reflected light of the light beam 52 is an acute angle, which is 5 respectively. The degrees (β5), 87 degrees (β6), 14 degrees (β7), 76 degrees (β8), and 89 degrees (β9) are set.

In the optical scanning apparatus 10 according to this embodiment, the fourth reflection mirror 64 is arranged on the extension of the optical path connecting the magenta photoconductor drum 13m and the second fθ lens 72. As a result, the fourth reflection mirror 64 is arranged so that the position of the second fθ lens 72 and the optical scanning device 10 in the housing 41 overlap each other when viewed from above. That is, the fourth reflection mirror 64 and the second fθ lens 72 are arranged so as to have overlapping portions when viewed from the height direction Z along the rotation center axis G.

Further, in the optical scanning device 10, in the second reflection mirror 62 and the third reflection mirror 63, the optical path of the light beam 52 formed between the second reflection mirror 62 and the third reflection mirror 63 is the first fθ lens 71. It is provided so as to cross the optical path of the light beam 52 from the light beam to the first reflection mirror 61. In the fourth reflection mirror 64, the optical path of the light beam 52 formed between the third reflection mirror 63 and the fourth reflection mirror 64 follows the optical path of the light beam 52 from the first fθ lens 71 to the first reflection mirror 61. It is provided to cross.

Further, in the first reflection mirror 61 and the second reflection mirror 62, the optical path of the light beam 52 formed between the first reflection mirror 61 and the second reflection mirror 62 is transferred from the fourth reflection mirror 64 to the second fθ lens 72. It is provided so as to cross the optical path of the light beam 52 of. These optical paths intersect each other.

In the height direction Z orthogonal to the main scanning direction Y and the sub-scanning direction X, the third reflection mirror 63 is arranged at a height position having a portion overlapping the second fθ lens 72. In the exemplary embodiment, the second reflection mirror 63 is provided so as to partially overlap with the second fθ lens 72 in the height direction Z, for example, on the photoconductor drum 13 side (for example, with respect to the reference plane L). It is arranged on the magenta photoconductor drum 13 m side).

In the optical scanning device 10, the light beam 52 is satisfactorily guided to each of the photoconductor drums 13 by the plurality of reflection mirrors 6 arranged in this way, and each of the photoconductor drums 13 is scanned. Then, the scanning timing of each photoconductor drum 13 by the light beam is set based on the detection timing of the light beam 52. In the optical scanning device 10 according to the second embodiment, as in the first embodiment, it is possible to compactly accommodate a plurality of reflection mirrors 6 in the housing 41 while ensuring a sufficient optical path length of the light beam 52. .. Therefore, the optical scanning apparatus 10 and the image forming apparatus 1 provided with the optical scanning apparatus 10 can be made smaller and thinner, and can form an image with high image quality.

In the optical scanning apparatus 10 according to the present invention, the plurality of reflection mirrors 6 that reflect the light beam 52 and guide them to the photoconductor drums 13 are not limited to the number of installations shown in the first and second embodiments. More reflective mirrors may be provided. Further, the arrangement of the reflection mirrors 6 is not limited to those illustrated in FIGS. 5 and 6, and the optical path of the light beam 52 reflected by the third reflection mirror 63 is the same as that of the first reflection mirror 61. Any form may be used as long as the first reflection mirror 61, the second reflection mirror 62, and the third reflection mirror 63 are provided so as to cross the optical path between the second reflection mirror 62 and the second reflection mirror 62. ..

The technical scope of the present invention is not to be construed solely by the above-described embodiment, but is based on the scope of claims. In addition, the technical scope of the present invention includes all modifications within the meaning and scope equivalent to the claims.

1 Image forming device 10 Optical scanning device 12 Developing device 13 Photoreceptor drum (scanned object)
14 Drum cleaning device 34 Resist roller 35 Conveyor roller 36 Paper discharge roller 41 Housing 51 Light emitting element (light source)
52 Light beam 53 Polygon mirror (deflection part)
6 Reflective mirror 61 1st reflection mirror 62 2nd reflection mirror 63 3rd reflection mirror 64 4th reflection mirror 71 1st fθ lens 72 2nd fθ lens

Claims (11)

An optical scanning device that deflects a light beam emitted from a light source to scan an object to be scanned.
Light source and
A deflection unit that deflects the light beam emitted from the light source, and
At least three reflection mirrors that reflect the light beam deflected by the deflection portion and guide it to a specific object to be scanned.
It is provided with a first optical member provided on the optical path of the light beam from the deflection unit to one of the reflection mirrors and having a light-collecting characteristic.
Assuming that the reflection mirrors are the first, second, and third reflection mirrors in order from the upstream side of the optical path of the light beam,
The optical path of the light beam reflected by the third reflection mirror is the first, second and third reflections so as to cross the optical path between the first reflection mirror and the second reflection mirror. An optical scanning device characterized in that a mirror is arranged. In the optical scanning apparatus according to claim 1,
On the optical path, the first reflection mirror in which a light beam is incident through the first optical member and the second reflection mirror that receives the light beam reflected by the first reflection mirror. An optical scanning apparatus comprising the third reflective mirror that receives the light beam reflected by the second reflective mirror. In the optical scanning apparatus according to claim 1 or 2.
An optical scanning device characterized in that the optical path of the light beam reflected by the third reflection mirror crosses the optical path of the light beam from the first optical member to the first reflection mirror. The optical scanning apparatus according to any one of claims 1 to 3.
Each of the reflection mirrors is an optical scanning device provided so that the angle formed by the incident light of the light beam to the reflection mirror and the reflected light is an acute angle. The optical scanning apparatus according to any one of claims 1 to 4.
A second optical member having a condensing characteristic is provided on the optical path of the light beam from the third reflection mirror to the object to be scanned.
The optical path of the light beam incident on the second optical member includes the optical path of the light beam from the first optical member to the first reflection mirror, the first reflection mirror, and the second reflection mirror. An optical scanning device characterized by crossing an optical path between. In the optical scanning apparatus according to claim 5,
When a plane orthogonal to the rotation center axis of the deflection portion and equally dividing the reflection surface of the deflection portion is used as a reference plane, or orthogonal to the rotation center axis of the deflection portion, the deflection portion and the deflection portion When the plane containing the optical path of the light beam with the most distant reflection mirror is used as the reference plane.
The second reflection mirror is arranged on the side to be scanned of the reference surface, and the first reflection mirror and the third reflection mirror are arranged on the opposite side of the reference surface to the object to be scanned. An optical scanning device as a feature. In the optical scanning apparatus according to claim 5 or 6.
The optical scanning device is characterized in that the second reflecting mirror is arranged so as to have at least a portion overlapping the second optical member in a height direction orthogonal to a main scanning direction and a sub scanning direction. In the optical scanning apparatus according to claim 5,
An optical scanning apparatus characterized in that a fourth reflection mirror that receives the light beam reflected by the third reflection mirror is further provided on the optical path of the light beam. In the optical scanning apparatus according to claim 8,
When a plane orthogonal to the rotation center axis of the deflection portion and equally dividing the reflection surface of the deflection portion is used as a reference plane, or orthogonal to the rotation center axis of the deflection portion, the deflection portion and the deflection portion When the plane containing the optical path of the light beam with the most distant reflection mirror is used as the reference plane.
The first reflection mirror and the third reflection mirror are arranged on the side to be scanned of the reference surface, and the second reflection mirror and the fourth reflection mirror are on the opposite side of the reference surface to the object to be scanned. An optical scanning device characterized in that it is arranged. In the optical scanning apparatus according to claim 8 or 9.
The optical scanning device is characterized in that the third reflection mirror is arranged so as to have at least a portion overlapping the second optical member in a height direction orthogonal to a main scanning direction and a sub scanning direction. The optical scanning apparatus according to any one of claims 1 to 10 is provided.
A latent image is formed on the scanned object by the optical scanning device, the latent image on the scanned object is developed into a visible image, and the visible image is transferred from the scanned object to paper. An image forming apparatus characterized by.

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