JP2015200853A - Optical scanner, and image forming apparatus including optical scanner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent thermal deformation of imaging lenses 45L and 45R resulting from an increase in temperature inside a housing 43 associated with the operation of a polygon motor 42.SOLUTION: Between a polygon motor 42 and imaging lenses 45L and 45R inside a housing 43, a partition wall 60 is provided to block the air stream induced by the rotation of the polygon motor 42 and directed from the motor 42 to the imaging lenses 45R and 45L, and the partition wall 60 has openings 47L and 47R formed therein through which light made incident on a rotary polygon mirror 41 and light reflected thereon can pass.

Description

  The present invention relates to an optical scanning device and an image forming apparatus including the optical scanning device.

  2. Description of the Related Art Conventionally, an optical scanning device mounted on, for example, an electrophotographic image forming apparatus is known (see, for example, Patent Document 1). This optical scanning device has a polygon mirror that deflects and scans a light beam emitted from a light source, and an fθ lens that forms an image on the scanning object by the light beam deflected and scanned by the polygon mirror. The polygon mirror is fixed to the rotation shaft of the polygon motor. The polygon motor is attached to the IC board. The fθ lens, the polygon mirror, the polygon motor, and the IC substrate are accommodated in a resin housing. The fθ lens and the IC substrate are fixed to the bottom wall portion of the housing with an adhesive or a bolt.

JP 2007-78999 A

  However, in recent years, with the progress of miniaturization of the optical scanning device, the space volume in the housing has to be reduced. Therefore, there is a problem that the temperature in the housing rapidly rises in a short time due to heat generated by the polygon motor, and the fθ lens (imaging lens) is thermally deformed. As a result, an image forming apparatus equipped with the optical scanning device has a problem that image defects such as color misregistration occur.

  The present invention has been made in view of such a point, and an object of the present invention is to heat the imaging lens housed in the housing by heat generated by the driving motor of the rotary polygon mirror housed in the housing. Prevent deformation.

  An optical scanning device according to the present invention includes a motor having a rotating shaft extending in the vertical direction, a rotating polygon mirror fixed to the rotating shaft of the motor for deflecting and scanning a light beam emitted from a light source, and the rotating polygon mirror. An imaging lens that forms an image of the light beam deflected and scanned on the surface to be scanned, and a housing that houses the motor, the rotary polygon mirror, and the imaging lens.

  In the housing, a hollow ring formed so as to surround the motor in a plan view so as to partition a space in which the motor and the rotary polygon mirror side are accommodated and a space in which the imaging lens is accommodated. The annular wall is formed with a light passage opening through which incident light and reflected light to the rotary polygon mirror can pass, and the annular wall has a predetermined height from the lower end. While the cross-sectional area of the hollow portion is constant in the portion below the height, the cross-sectional area of the hollow portion is increased toward the upper side in the portion where the height from the lower end exceeds the predetermined height. .

  According to this configuration, the air flow from the motor side toward the imaging lens side with the rotation of the motor can be prevented by the annular wall. Therefore, it is possible to suppress the high-temperature air flow warmed by the heat generated by the motor from moving toward the imaging lens side. As a result, it is possible to suppress thermal deformation of the imaging lens due to heat generated by the motor. In addition, since an opening through which light can pass is formed in the annular wall, the optical path of incident light and reflected light to the rotating polygon mirror is not obstructed.

  Here, when the volume of the hollow portion in the annular wall is small, the temperature of the hollow portion rises excessively. Therefore, even if the air flow from the motor side toward the imaging lens side is blocked by the folding wall or the annular wall, the imaging lens may be thermally deformed due to heat transfer from the wall surface of the annular wall. In addition, since the temperature of the air flow leaking from the light passage opening increases, the imaging lens is likely to be thermally deformed.

  On the other hand, in the above configuration, in a portion where the height from the lower end of the annular wall exceeds a predetermined height, the horizontal sectional area of the hollow portion is increased toward the upper side (that is, the annular wall is expanded toward the upper side). ) Thereby, the volume of a hollow part can be taken as much as possible, and the temperature rise of the hollow part by the heat_generation | fever of a motor can be suppressed. As a result, it is possible to suppress thermal deformation of the imaging lens due to heat transfer from the wall surface of the annular wall or an air flow leaking from the light passage opening.

  Since the cross-sectional area of the hollow portion is constant in the portion of the annular wall below the predetermined height, the space for arranging lenses (for example, an imaging lens) disposed on the bottom wall portion of the case body is limited by the annular wall. There is no hindrance.

  The housing has a case body that opens to the upper side and accommodates the motor, the rotary polygon mirror, and the imaging lens, and a lid that covers the upper side of the case body. The portion that is in contact with the lid and that is on the inner side of the portion of the lid that is in contact with the annular wall is configured to have higher heat dissipation than the outer portion of the contact portion. preferable.

  According to this structure, the heat of the air inside the annular wall warmed by the heat generated by the motor can be efficiently radiated. Thereby, the temperature of the air inside the annular wall can be suppressed as low as possible. As a result, it is possible to reliably suppress thermal deformation of the imaging lens due to heat transfer from the wall surface of the annular wall or air heat leaking from the light passage opening.

  The lid portion has a duct portion that passes over the annular wall and through which cooling air flows, and an upper end portion of the annular wall is in contact with the duct portion of the lid portion, It is preferable that the inner portion of the duct portion than the portion where the upper end of the annular wall abuts is configured to have higher heat dissipation than the outer portion of the contact portion.

  According to this configuration, the heat of the air inside the annular wall warmed by the heat generated by the motor can be efficiently radiated from the inner portion of the duct portion than the portion where the annular wall abuts. In addition, since the cooling air flows in the duct portion, the heat of the air inside the annular wall can be radiated more efficiently than when no duct portion is provided.

  It is preferable that the inner portion of the lid portion than the portion where the upper end of the annular wall abuts is formed by fitting a thin plate member into the opening.

  According to this configuration, the heat of the air inside the annular wall warmed by the heat generated by the motor can be efficiently radiated through the thin plate member fitted in the opening of the lid.

  The thin plate member is preferably made of a polyethylene phthalate resin or an aluminum material.

  According to this configuration, by using the polyethylene phthalate resin as the thin plate member, the heat dissipation of the lid can be enhanced with an inexpensive configuration. Moreover, the heat of the air inside an annular wall can be efficiently radiated by using aluminum excellent in heat dissipation as a thin plate member.

  The predetermined height is preferably larger than the height at which the upper surface of the rotary polygon mirror is positioned.

  According to this configuration, the enlarged portion of the annular wall can be formed above the height at which the upper surface of the rotary polygon mirror is located. Therefore, the installation space for the lenses provided around the rotary polygon mirror is not obstructed by the annular wall.

  An image forming apparatus according to the present invention includes the optical scanning device.

  According to this configuration, thermal deformation of the imaging lens can be suppressed. As a result, the image quality of the printed image by the image forming apparatus can be improved.

  According to the present invention, it is possible to prevent the imaging lens accommodated in the housing from being thermally deformed due to heat generated by the driving motor for the rotary polygon mirror accommodated in the housing.

FIG. 1 is a schematic longitudinal sectional view showing an image forming apparatus including an optical scanning device according to the embodiment. FIG. 2 is a perspective view showing a state in which the cover of the housing of the optical scanning device is removed. FIG. 3 is a perspective view showing a lid portion of the housing. FIG. 4 is a longitudinal sectional view showing the internal structure of the optical scanning device. FIG. 5 is an enlarged perspective view showing the periphery of the light passage opening of the annular wall. FIG. 6 is a perspective view illustrating a lid portion of the optical scanning device according to the second embodiment. FIG. 7 is a perspective view illustrating a lid portion of the optical scanning device according to the second embodiment.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The present invention is not limited to the following embodiment.
<Embodiment>

  FIG. 1 shows an image forming apparatus 1 according to the first embodiment. The image forming apparatus 1 is a tandem color printer, and includes an intermediate transfer belt 7, a primary transfer unit 8 and a secondary transfer unit 9, a fixing unit 11, two optical scanning devices 4, and four Image forming units 16a to 16d and first to fourth paper transport units 21 to 24 are provided.

  A paper feed cassette 3 is disposed below the inside of the main body 2 of the image forming apparatus 1. The paper feed cassette 3 stores and accommodates paper (not shown) such as cut paper before printing. The sheets are separated and sent one by one toward the upper left of the sheet feeding cassette 3 in FIG.

  The first paper transport unit 21 is provided on the side of the paper feed cassette 3. The first paper transport unit 21 is disposed along the left side surface of the main body 2. The first paper transport unit 21 receives the paper sent from the paper feed cassette 3 and transports the paper along the left side surface of the main body 2 to the upper secondary transfer unit 9.

  A manual paper feed unit 5 is provided on the right side of the paper feed cassette 3. In the manual sheet feeder 5, paper of a size that is not in the paper cassette 3, thick paper, an OHP sheet, or the like is placed. A second paper transport unit 22 is provided on the left side of the manual paper feed unit 5. The second paper transport unit 22 extends substantially horizontally from the manual paper feed unit 5 to the first paper transport unit 21 and joins the first paper transport unit 21. Then, the second paper transport unit 22 receives the paper sent from the manual paper feed unit 5 and transports it to the first paper transport unit 21.

  Each optical scanning device 4 is arranged above the second paper transport unit 22. Here, the image forming apparatus 1 receives image data transmitted from the outside. The image data is stored in a temporary storage unit (not shown) and then sent to each optical scanning device 4 as necessary. Each of the optical scanning devices 4 irradiates laser light controlled based on the image data toward the image forming units 16a and 16b for cyan and magenta or the image forming units 16c and 16d for yellow and black.

  The image forming units 16 a to 16 d are provided above the two optical scanning devices 4. Each of the image forming units 16a to 16d has photosensitive drums 10a to 10d, respectively. Chargers 20a to 20d, developing devices 30a to 30d, and cleaning devices 40a to 40d are provided for the respective photosensitive drums 10a to 10d. The cleaning devices 40a to 40d are provided for cleaning the peripheral surfaces of the photosensitive drums 10a to 10d.

  An endless intermediate transfer belt 7 is provided above each of the image forming units 16a to 16d. The intermediate transfer belt 7 is wound around a plurality of rollers and is rotationally driven by a driving device (not shown).

  As shown in FIG. 1, the four image forming units 16a to 16d are arranged in a line along the intermediate transfer belt 7, and respectively form cyan, magenta, yellow, or black toner images. That is, in each of the image forming units 16a to 16d, the optical scanning device 4 irradiates the peripheral surface 10 of the photosensitive drums 10a to 10d with laser light to form an electrostatic latent image of the original image, and the developing devices 30a to 30d By developing this electrostatic latent image, a toner image of each color is formed.

  The primary transfer portions 8a to 8d are respectively disposed above the image forming units 16a to 16d. The primary transfer portions 8 a to 8 d include primary transfer rollers 80 a to 80 d that primarily transfer the toner images formed by the image forming units 16 a to 16 d to the surface of the intermediate transfer belt 7. A transfer bias is applied to the primary transfer rollers 80a to 80d from a transfer bias power source (not shown). The toner images of the image forming units 16a to 16d are transferred to the intermediate transfer belt 7 at a predetermined timing by a transfer bias applied to the primary transfer rollers 80a to 80d. Thus, a color toner image is formed on the surface of the intermediate transfer belt 7 by superposing four color toner images of yellow, magenta, cyan, and black.

  The secondary transfer unit 9 has a secondary transfer roller 18 disposed on the left side of the intermediate transfer belt 7. A transfer bias is applied to the secondary transfer roller 18 by a transfer bias power source. The secondary transfer roller 18 sandwiches the paper P with the intermediate transfer belt 7. Thus, the toner image on the intermediate transfer belt 7 is transferred onto the paper P by the transfer bias applied to the secondary transfer roller 18.

  The fixing unit 11 is provided above the secondary transfer unit 9. Between the secondary transfer unit 9 and the fixing unit 11, a third paper transport unit 23 that transports the paper P onto which the toner image has been secondarily transferred to the fixing unit 11 is formed.

  The fixing unit 11 includes a heating roller 182 and a pressure roller 181 that rotate. The fixing unit 11 holds the paper P between the heating roller 182 and the pressure roller 181 so that the toner image transferred to the paper P is heated and pressed to be fixed on the paper P.

  A branch portion 27 is provided above the fixing portion 11. The sheet P discharged from the fixing unit 11 is discharged from the branching unit 27 to the sheet discharging unit 28 formed on the upper part of the image forming apparatus 1 when double-sided printing is not performed. The discharge port portion from which the paper P is discharged from the branch portion 27 toward the paper discharge portion 28 functions as a switchback portion 29. When performing duplex printing, the switchback unit 29 switches the transport direction of the paper P discharged from the fixing unit 11.

  -Details of optical scanning device-

  The optical scanning device 4 for cyan and magenta and the optical scanning device 4 for yellow and black have the same structure. As shown in FIG. 2, each optical scanning device 4 includes a polygon mirror 41, a polygon mirror, and the like. A pair of light sources 44 </ b> L and 44 </ b> R that emit laser light toward 41. The polygon mirror 41 has a regular hexagonal column shape having six reflecting surfaces on the side surface. The polygon mirror 41 deflects and scans the light beams emitted from the light sources 44L and 44R. In the following description, the main scanning direction of the light beam is defined as the front-rear direction of the optical scanning device 4, the sub-scanning direction of the light beam is defined as the height direction of the optical scanning device 4, and the main scanning direction and the sub-scanning direction are defined. The direction orthogonal to both is defined as the left-right direction of the optical scanning device 4.

  The polygon mirror 41 is accommodated in a rectangular box-shaped housing 43. The housing 43 has a bottomed case body 43a (see FIG. 2) that opens upward, and a lid portion 43b (see FIG. 3) that covers the upper side of the case body 43a. The pair of light sources 44L and 44R are attached to the front side wall of the case body 43a. The pair of light sources 44L and 44R are arranged with an interval in the left-right direction.

  A pair of engaging projections 43t are formed on the outer wall surfaces of the four side wall portions of the case body 43a. Each of the four sides of the lid portion 43b is formed with a pair of protruding pieces 43u protruding downward, and each protruding piece 43u has an engaging hole 43f that engages with the engaging protrusion 43t. Is formed. The lid portion 43b is attached to the case body 43a by engaging the engagement hole 43f with the engagement protrusion 43t of the case body 43a.

  As shown in FIG. 4, the polygon mirror 41 is fixed to the tip of the output shaft of the polygon motor 42. The polygon mirror 41 is rotationally driven by a polygon motor 42. The polygon motor 42 is attached to the bottom wall portion of the case body 43 a via the substrate 49 and the heat sink 50. The substrate 49 has a rectangular plate shape that is long in the front-rear direction. A driving IC 48 is mounted on the upper surface of the substrate 49. A heat sink 50 is provided on the lower surface side of the substrate 49. The heat sink 50 includes a horizontal plate portion 50a, a protruding boss portion 50b, and a fin portion 50c. The horizontal flat plate portion 50a has a long plate shape in the front-rear direction. The horizontal flat plate portion 50a is attached to the case body 43a so as to close an opening 43v formed at the center of the bottom wall portion of the case body 43a from below. The protruding boss portion 50 b protrudes from the upper surface of the horizontal plate portion 50 a and is in contact with the lower surface of the substrate 49. The fin portion 50c is formed on the lower surface of the horizontal plate portion 50a. The fin portion 50c is configured by a plurality of vertical plate portions arranged at intervals in the left-right direction.

  Returning to FIG. 2, first fθ lenses 45L and 45R and second fθ lenses 46L and 46R are attached to the left and right sides of the polygon mirror 41 on the bottom wall of the case body 43a. The second fθ lenses 46L and 46R are disposed outside the first fθ lenses 45L and 45R when viewed from the axial center position of the polygon mirror 41.

  A hollow annular wall 47 is provided around the polygon mirror 41. The annular wall 47 is formed so as to surround the polygon motor 42 and the polygon mirror 41 in a plan view (as viewed from the rotation axis direction of the polygon motor 42). The annular wall 47 partitions the space in the housing 43 into a space S1 and a space S2. In the space S1, the polygon mirror 41, the polygon motor 42, the substrate 49, and the like are accommodated. In the space S2, optical systems such as the first fθ lenses 45R and 45L and the second fθ lenses 46R and 46L are accommodated. .

  The annular wall 47 is formed separately from the housing 43 (that is, the case body 43a and the lid portion 43b). As shown in FIG. 4, the annular wall 47 is formed so that the horizontal cross-sectional area and the cross-sectional shape of the hollow portion (space S <b> 1) are constant in a portion whose height from the lower end is a predetermined height H or less. ing. On the other hand, the annular wall 47 is configured so that the cross-sectional area of the hollow portion increases toward the upper side at a portion where the height from the lower end exceeds the predetermined height H. That is, the upper end portion of the annular wall 47 is expanded in diameter toward the upper side. In the present embodiment, the predetermined height H is larger than the height at which the upper surface of the polygon mirror 42 is located.

  The upper end portion of the annular wall 47 is in contact with the peripheral edge of the opening 43g (see FIG. 4) formed in the lid portion 43b. The opening 43g is formed in a rectangular shape extending in the front-rear direction in plan view. A thin plate member 55 is fitted in the opening 43g. The thin plate member 55 constitutes a part of the lid portion 43b. The thickness of the thin plate member 55 is smaller than the thickness of the outer portion of the opening 43g in the lid portion 43b. By doing so, the heat radiation property of the inner portion of the lid portion 43b than the contact portion with the annular wall 47 is made higher than that of the outer portion of the corresponding contact portion. In the present embodiment, the thin plate member 55 is made of PET (polyethylene terephthalate) resin.

  The lower end portion of the annular wall 47 is in contact with the upper surface of the horizontal plate portion 50a of the heat sink 50 (see FIG. 4). The annular wall 47 is formed so as to surround the polygon mirror 41, the polygon motor 42, and the substrate 49 in a plan view (as viewed from the direction of the rotation axis of the polygon motor 42).

As shown in FIGS. 2 and 5, slit-shaped light passage openings 47f _L and 47f _R (in FIG. 5, only the left light passage opening 47f _L is shown at the left and right corners of the front end portion of the annular wall 47. ) Is formed. Both the light passage openings 47 f _L and 47 f _R are formed in the intermediate portion in the height direction of the annular wall 47. The left light passage opening 47f _L is formed from the left end of the front side wall 47c of the annular wall 47 to the front end of the left side wall 47a. Right light passage opening 47f _R is formed from the right end portion of the front wall 47c of the annular wall 47 over the front end of the right side wall 47b. The light passage openings 47f _L and 47f _R are configured to allow incident light and reflected light to the polygon mirror 41 to pass therethrough.

The operation of the optical scanning device 4 configured as described above will be described. At the time of image formation, the polygon mirror 41 is rotationally driven by the polygon motor 42. Then, light beams are emitted from the light sources 44L and 44R toward the rotating polygon mirror 41. The two light beams pass through an incident optical system (not shown) and enter the reflecting surface of the polygon mirror 41 through the light passage openings 47f _L and 47f _R , and are deflected and scanned by the polygon mirror 41. The deflected and scanned light beams pass through the light passage openings 47f _L and 47f _R, and then pass through the first fθ lenses 45L and 45R and the second fθ lenses 46L and 46R. The light beam is converted into a constant velocity motion by the first fθ lenses 45L and 45R and the second fθ lenses 46L and 46R, and then folded back by a reflection mirror (not shown) to form an image on the peripheral surfaces of the photosensitive drums 10a to 10d. Is done.

  Thus, since the polygon motor 42 operates during image formation, the polygon motor 42 and the drive IC 48 generate heat. The high-temperature air warmed by the heat generation flows from the motor 42 side toward the first fθ lenses 45L and 45R side by the rotation of the polygon motor 42. For this reason, in the conventional optical scanning device 4 that does not have the annular wall 47, there is a possibility that the first fθ lenses 45L and 45R and the second fθ lenses 46L and 46R are thermally deformed by this high-temperature air flow.

On the other hand, in the above embodiment, the annular wall 47 can block the high-temperature air flow from the motor 42 side toward the first fθ lenses 45L and 45R as the polygon motor 42 rotates. Therefore, thermal deformation of the first fθ lenses 45L and 45R and the second fθ lenses 46L and 46R due to heat generated by the polygon motor 42 and the drive IC 48 can be suppressed. Further, since the light passage openings 47f _L and 47f _R are formed in the annular wall 47, the optical path of the incident light beam and the reflected light beam to the polygon motor 42 is not obstructed by the annular wall 47.

Here, if the volume of the space S1 (hollow part) inside the annular wall 47 is small, the temperature of the space S1 rises excessively. Therefore, even if the air flow from the polygon motor 42 side to the first fθ lenses 45L and 45R side is blocked by the folding wall 47, the heat transfer from the side walls 47a to 47d of the annular wall 47 and the light passage openings 47f _L and 47f. There is a possibility that the first fθ lenses 45L and 45R and the second fθ lenses 46L and 46R are thermally deformed due to heat of the air flow leaking from _R.

On the other hand, in the above embodiment, in the portion where the height from the lower end of the annular wall 47 exceeds the predetermined height H, the horizontal sectional area of the space S1 is increased toward the upper side. Thereby, the volume of the space S1 inside the annular wall 47 can be made as large as possible, and the temperature rise of the space S1 due to the heat generated by the polygon motor 42 can be suppressed. As a result, the first fθ lenses 45L and 45R and the second fθ lenses 46L and 46R are thermally deformed by heat transfer from the side walls 47a to 47d of the annular wall 47 and heat of the air flow leaking from the light passage openings 47f _L and 47f _R. Can be reliably suppressed. On the other hand, since the horizontal cross-sectional area of the space S1 is constant in the portion of the annular wall 47 below the predetermined height H, the first fθ lenses 45L, 45R and the like attached to the bottom wall portion of the housing 43, etc. A sufficient installation space can be secured.

  Moreover, in the said embodiment, the part inside the contact part with the annular wall 47 in the cover part 43b is formed by fitting the thin plate-shaped member 55 in the opening part 43g. According to this, in the part inside the contact part with the annular wall 47 in the cover part 43b, since the thickness is thinner than the part outside the corresponding contact part, the heat dissipation becomes higher. Therefore, the heat of the air inside the annular wall 47 warmed by the heat generated by the polygon motor 42 can be efficiently radiated. As a result, the temperature of the air inside the annular wall 47 can be kept low, and the thermal deformation of the first fθ lenses 45L and 45R and the second fθ lenses 46L and 46R can be reliably suppressed.

  Moreover, in the said embodiment, since PET resin was used as the thin plate-shaped member 55, the heat dissipation of the cover part 43b can be improved with an inexpensive structure.

  In the above embodiment, the predetermined height H is larger than the height at which the upper surface of the polygon mirror 41 is located.

  According to this, the enlarged diameter portion of the annular wall 47 can be formed above the height at which the upper surface of the polygon mirror 41 is located. Therefore, the installation space for the lenses provided around the polygon mirror is not obstructed by the annular wall 47.

Since the image forming apparatus 1 includes the optical scanning device 4, it is possible to prevent image color shift due to thermal deformation of the first fθ lenses 45L and 45R and the second fθ lenses 46L and 46R. As a result, the image quality of the printed image can be improved.
<< Embodiment 2 >>

  6 and 7 show the second embodiment. The second embodiment is different from the first embodiment in that the lid portion 43 b includes a duct portion 56. In addition, the same code | symbol is attached | subjected to the same component as FIG. 3, and the detailed description is abbreviate | omitted.

  The duct portion 56 is formed so as to pass above the annular wall 47. The cooling flow path 51 in the duct portion 56 passes through the space S <b> 1 inside the annular wall 47 in a plan view (as viewed from the rotation axis direction of the polygon motor 42). An air flow (cooling air) from the front side to the rear side is formed in the cooling air passage 51 by the blower fan 53. An opening 43g is formed on the lower surface of the duct portion 56, and the upper end of the annular wall 47 is in contact with the peripheral edge of the opening 43g. A thin plate member 55 is fitted into the opening 43g. The thickness of the thin plate member 55 is smaller than the thickness of the outer portion of the duct portion 56 (part of the lid portion 43b) than the opening portion 43g in plan view. By doing so, the heat radiation property of the inner portion of the lid portion 43b than the contact portion with the annular wall 47 is made higher than that of the outer portion of the corresponding contact portion.

  Therefore, the heat in the space S <b> 1 inside the annular wall 47 can be radiated from the thin plate-like portion 55 and released to the outside by the air flow in the cooling air passage 51. Therefore, the temperature of the space S1 inside the annular wall 47 can be kept low. Therefore, the same effect as the first embodiment can be obtained more reliably.

  << Other embodiments >>

  In each of the above embodiments, the predetermined height H is greater than the height of the upper surface of the polygon mirror 41, but is not limited to this. That is, the predetermined height H may be smaller than the height of the upper surface of the polygon mirror 41.

  In each said embodiment, although the said thin-plate-shaped member 55 is comprised with PET resin, it is not restricted to this, For example, you may be comprised with aluminum. Thereby, the heat dissipation of the thin plate-shaped member 55 can be improved and the temperature of the space S1 inside the annular wall 47 can be suppressed as low as possible.

  In each of the embodiments described above, the optical scanning device 4 employs a so-called counter scanning type in which scanning optical systems are arranged on both the left and right sides with the polygon mirror 42 interposed therebetween. The scanning optical system may be provided only on one side in the left-right direction.

  Further, the present invention includes a configuration in which the above embodiments are appropriately combined.

  As described above, the present invention is useful for an optical scanning device and an image forming apparatus including the optical scanning device.

H Predetermined height S1 Space S2 Space 1 Image forming device 4 Optical scanning device 10a Photosensitive drum (scanned body)
10b Photosensitive drum (scanned body)
10c Photosensitive drum (scanned body)
10d Photosensitive drum (scanned body)
41 Polygon mirror (rotating polygon mirror)
42 Polygon motor (motor)
43 housing 43a case body 43b lid 44 annular wall 45L first fθ lens (imaging lens)
45R 1st fθ lens (imaging lens)
47 annular wall 47L light passage opening (opening)
47R Light passage opening (opening)
51 Cooling air passage (first cooling air passage)

Claims (7)

A motor having a rotating shaft extending in the vertical direction, a rotating polygon mirror fixed to the rotating shaft of the motor for deflecting and scanning a light beam emitted from a light source, and a light beam deflected and scanned by the rotating polygon mirror An optical scanning apparatus comprising: an imaging lens that forms an image on a scanning body; and a housing that houses the motor, the rotary polygon mirror, and the imaging lens,
The housing has a hollow annular wall formed so as to surround the motor in a plan view so as to partition a space in which the motor and the rotary polygon mirror are accommodated and a space in which the imaging lens is accommodated. Is provided,
The annular wall is formed with a light passage opening through which incident light and reflected light to the rotary polygon mirror can pass.
The annular wall has a constant cross-sectional area in the hollow portion where the height from the lower end is equal to or lower than the predetermined height, whereas the annular wall is hollow toward the upper side in the portion where the height from the lower end exceeds the predetermined height. An optical scanning device configured to increase the cross-sectional area of the portion. The optical scanning device according to claim 1,
The housing has a case body that opens upward and accommodates the motor, the rotary polygon mirror, and the imaging lens, and a lid that covers the upper side of the case body,
The upper end of the annular wall is in contact with the lid,
The optical scanning device, wherein a portion inside the lid portion with respect to the portion where the annular wall abuts is configured to have higher heat dissipation than a portion outside the contact portion. The optical scanning device according to claim 2.
The lid portion has a duct portion that passes above the annular wall and through which cooling air flows.
The upper end portion of the annular wall is in contact with the side wall of the duct portion of the lid portion,
The optical scanning device configured such that a heat dissipating property is higher in a portion inside the duct portion of the lid portion than a portion where the upper end of the annular wall is in contact with a portion outside the corresponding contact portion. The optical scanning device according to claim 2 or 3,
The optical scanning device, wherein a portion inside the portion where the upper end of the annular wall contacts the lid portion is formed by fitting a thin plate member into the opening. The optical scanning device according to claim 4.
The thin plate member is an optical scanning device made of polyethylene terephthalate resin or aluminum. In the optical scanning device according to any one of claims 1 to 5,
The optical scanning device, wherein the predetermined height is greater than a height at which an upper surface of the rotary polygon mirror is positioned. An image forming apparatus comprising the optical scanning device according to claim 1.

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