JP2003050369A - Light beam scanner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a light beam scanner constituted so that an optical box for storing a polygon motor and an optical element, etc., is provided with at least four fixation parts with reference to the main body frame, and also, the four fixing parts are made to differ in terms of height, and then, the box has the vibration characteristics having the characteristic frequency of the storing positions in a high frequency band. SOLUTION: The light beam scanner is provided with the optical box for storing a light beam emitting means for emitting the light beam, a light beam deflecting/scanning means constituted of a polygon mirror for deflecting the light beam emitted from the light beam emitting means and the polygon motor for rotating the polygon mirror so as to deflect/scan the light, a light beam image forming means for forming the image of the deflected/scanned light beam, a light beam reflecting means for reflecting the optical path of the light beam, and fixed to the main body frame. The optical box is provided with at least four fixation parts with reference to the main body frame, and also, the fixation parts are made to differ in terms of height.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a light beam scanning device, and more particularly to a structure of an optical box for housing optical elements of a light beam scanning device such as a copying machine, a printer and a facsimile.

[0002]

2. Description of the Related Art In a light beam scanning device used in a digital copying machine, a laser beam printer, a laser facsimile, etc., it is important to keep the positional relationship of optical elements at a predetermined accuracy in order to obtain good image quality. ing.
However, even when the positional relationship of the optical elements can be maintained at a predetermined accuracy, the optical path of the light beam fluctuates due to the vibration of the optical box that houses the optical elements and the like, or the vibration of the optical elements themselves, and thus the main scanning direction Is a factor causing image density unevenness in the sub-scanning direction, and good image quality cannot be obtained.

For this reason, various proposals have been made so far for the light beam scanning device to cope with further speeding up and image quality improvement. Especially, due to the vibrations generated from the vibration sources such as the polygon mirror and the drive motor,
Proposals have been made to prevent deterioration of image quality. For example, in Japanese Unexamined Patent Publication No. 5-103164 (hereinafter referred to as "conventional example 1"), the frequency of vibration generated by a laser beam scanner device (rotation frequency of a polygon motor) and the natural frequency of a support frame that supports this device are described. Are separated by a predetermined value. In Conventional Example 1, since the frequency of vibration generated by the laser beam scanner device and the natural frequency of the support frame are apart from each other to some extent, the support frame is prevented from resonating due to the vibration generated by the laser beam scanner device. be able to. Therefore, it is possible to form a good image on the photoconductor without uneven density.

However, in the prior art example 1, since the laser beam scanner device is mounted on the supporting frame, the damping property of the supporting frame itself is lowered, and there is a clear anti-resonance peak between the natural frequencies of the supporting frame. May not exist. For this reason, even if the natural frequencies are apart from each other by a predetermined value, it is impossible to suppress the vibration at the frequency of the vibration generating optical component.

Further, in Japanese Patent Laid-Open No. 9-33844 (hereinafter referred to as "conventional example 2"), the rigidity of a supporting plate having holes for arranging a vibration generating optical component such as a polygon motor is improved by a rib arrangement. I am raising. In this prior art example 2, since a vibration generating optical component such as a polygon motor is mounted on a support plate having a rib arrangement for enhancing rigidity, and this support plate is attached to the optical box and the frame, the polygon motor etc. Vibration caused by the vibration generating optical component can be suppressed. Therefore, it is possible to form a good image on the photoconductor without uneven density.

However, in this prior art example 2, since the laser scanning unit is mounted on the optical box, the relative position of the polygon mirror and the optical parts such as mirrors arranged in the optical box other than the laser scanning unit. The relationship depends largely on the natural frequency of the optical box. Although the rigidity of the optical box is secondarily enhanced by the support plate with a devised rib arrangement, it limits the amount of movement of the natural frequency of the optical box after the laser scanning unit is mounted to the high frequency side. Then, when the initial rigidity of the optical box is lowered, that is, when the primary natural frequency of the optical box is considerably lower than the frequency of the vibration generated by the vibration generating optical component, the rib arrangement of the support plate is devised. Even in such a case, there arises a problem that the vibration at the frequency of the vibration generating optical component cannot be suppressed. Also, in order to solve this problem, if the support plate is directly attached to the main body frame, it has the effect of reducing the dependence on the optical box, but the main body frame feeds and discharges the photosensitive drums and recording paper. Vibrations generated by a motor for driving the laser are directly transmitted to the laser scanning unit. Therefore, not only the vibration of the vibration-generating optical component itself but also the vibrations from a plurality of vibration sources are received, and the vibration is suppressed by simply shifting the primary natural frequency of the diaphragm to the high frequency side. The problem arises that you cannot do it.

Further, in Japanese Utility Model Laid-Open No. 5-11161 (hereinafter referred to as "conventional example 3"), in an optical box, a polygon motor arrangement area and an optical element arrangement area are formed in a stepped manner via a vertical wall, It has a structure in which a laser beam passage hole is formed in the vertical wall. In this Conventional Example 3, since the rigidity of the optical box is increased by the above structure, the vibration generated by the vibration generating optical parts such as the polygon motor causes
It is possible to prevent the optical box from resonating. Therefore, it is possible to form a good image on the photoconductor without uneven density.

However, in the prior art example 3, since the polygon motor arranging area and the optical element arranging area are formed in a stepped manner with the vertical wall interposed therebetween, the mounting surfaces of the polygon motor and the optical element are opposed to each other. There is. Therefore, the parallelism between the mounting surfaces of the polygon motor and the optical element is required to be high in accuracy, and the cost is high, and the mounting surfaces of the polygon motor and the optical element are reversed, so that there is a problem that the assembling property is deteriorated.

[0009]

However, even if only the vibration generated by the polygon motor is dealt with, as in the above-mentioned conventional examples 1 to 3, it is impossible to avoid the density unevenness on the photosensitive member caused by the vibration. This is because the vibrations generated from the polygon motor, the photoconductor drum, and the motor that drives the recording paper feeding / discharging system cause the optical box that houses the polygon motor, the optical elements, and the optical elements themselves to vibrate. This is because the optical path of the light beam changes. Therefore, the optical box that houses the polygon motor, the optical element, and the like needs to have a vibration characteristic that has a natural frequency in a high frequency range having a vibration shape that vibrates them.

The present invention is intended to solve these problems, and an optical box for housing a polygon motor, optical elements, etc. has at least four fixing portions to the main body frame, and its height is high. By having different fixing parts,
It is an object of the present invention to provide a light beam scanning device having a vibration characteristic having a natural frequency in a high frequency range in which the storage positions thereof vibrate.

[0011]

In order to solve the above-mentioned problems, a light beam scanning device of the present invention deflects a light beam generating means for generating a light beam and a light beam emitted from the light beam generating means. A polygon mirror and a polygon motor for rotating the polygon mirror, and a light beam deflection scanning means for deflecting and scanning the light beam, a light beam imaging means for forming the deflected and scanned light beam, and an optical path of the light beam is reflected. And an optical box that houses the light beam reflecting means and is fixed to the body frame. The optical box is characterized in that it has at least four fixing parts to the body frame, and the fixing parts have different heights. Therefore, at the first natural frequency of the optical box bending in the longitudinal direction, it is possible to greatly change the vibration deformation shape and form, and to shift the natural frequency of the optical box to the high frequency range side. Further, it is possible to suppress local vibration of the optical box in the high frequency range. Therefore, it is possible to avoid density unevenness on the photoconductor that is caused by vibrations generated by the polygon motor, the photoconductor drum, the motor that drives the recording paper feed / discharge system, and the like.

Further, since the optical box has a space formed by the outer wall and the rib, the optical box bends in the longitudinal direction.
At the next natural frequency, the vibrational deformation shape can be greatly changed to shift the natural frequency of the optical box to the high frequency range side. Further, it is possible to suppress local vibration of the optical box in the high frequency range. Therefore, it is possible to avoid density unevenness on the photoconductor that is caused by vibrations generated by the polygon motor, the photoconductor drum, the motor that drives the recording paper feed / discharge system, and the like.

Further, since the optical box has a fixing hole for fixing it to the body frame in a predetermined space, the optical box is bent in the longitudinal direction as compared with the case where the fixing hole is outside the shape of the optical box. With respect to the natural frequency, it is possible to greatly change the vibration deformation shape and form and to shift the natural frequency of the optical box to the high frequency range side. Therefore, it is possible to avoid density unevenness on the photoconductor that is caused by vibrations generated by the polygon motor, the photoconductor drum, the motor that drives the recording paper feed / discharge system, and the like.

Further, since the ribs are formed along the outer wall, the vibrational deformation shape is greatly changed at the primary natural frequency of the optical box bending in the longitudinal direction, and the natural frequency of the optical box is changed to a high frequency. It can be shifted to the zone side. Therefore, it is possible to avoid density unevenness on the photoconductor that is caused by vibrations generated by the polygon motor, the photoconductor drum, the motor that drives the recording paper feed / discharge system, and the like.

Further, the ribs are also formed between the outer wall and the ribs along the outer shape, so that the shape of vibration deformation is greatly changed at the primary natural frequency at which the optical box bends in the longitudinal direction. The natural frequency of can be shifted to the high frequency side. Further, it is possible to suppress local vibration of the optical box in the high frequency range. Therefore, the polygon motor,
It is possible to avoid uneven density on the photoconductor that is caused by vibrations generated by a motor or the like that drives the photoconductor drum and the recording / paper feeding system.

Further, since the rib has the same height as the height of the outer wall from the bottom surface, the shape of vibration deformation is greatly changed at the primary natural frequency at which the optical box bends in the longitudinal direction. The natural frequency can be shifted to the high frequency range side. Therefore, it is possible to avoid density unevenness on the photoconductor that is caused by vibrations generated by the polygon motor, the photoconductor drum, the motor that drives the recording paper feed / discharge system, and the like.

Further, since the rib has the same thickness as the outer wall, when the optical box is made of resin, the thickness of the optical box can be made uniform and the molding becomes easy. For this reason, die manufacturing costs and production costs can be reduced.

Further, since the heights of the bottoms of the adjacent spaces are different, the vibrational deformation shape is greatly changed at the primary natural frequency of the optical box bending in the longitudinal direction, and the natural frequency of the optical box is increased. It can be shifted to the frequency range side. Further, it is possible to suppress local vibration of the optical box in the high frequency range. Therefore, it is possible to avoid density unevenness on the photoconductor that is caused by vibrations generated by the polygon motor, the photoconductor drum, the motor that drives the recording paper feed / discharge system, and the like.

Further, by making the height of the bottom surface of the space larger than the wall thickness of the bottom surface, the vibrational deformation shape is greatly changed at the primary natural frequency at which the optical box bends in the longitudinal direction. The natural frequency can be shifted to the high frequency range side. Further, it is possible to suppress local vibration of the optical box in the high frequency range. Therefore, it is possible to avoid density unevenness on the photoconductor that is caused by vibrations generated by the polygon motor, the photoconductor drum, the motor that drives the recording paper feed / discharge system, and the like.

Further, by making the thickness of the bottom portion having the fixing hole in the space larger than the thickness of the bottom portion of the space having no fixing hole, the rigidity in the vicinity of the fixing hole is improved and the characteristic of the optical box is improved. The frequency can be shifted to the high frequency side. Therefore, it is possible to avoid density unevenness on the photoconductor that is caused by vibrations generated by the polygon motor, the photoconductor drum, the motor that drives the recording paper feed / discharge system, and the like.

[0021]

BEST MODE FOR CARRYING OUT THE INVENTION The light beam scanning device of the present invention comprises a light beam generating means for generating a light beam, a polygon mirror for deflecting the light beam emitted from the light beam generating means, a polygon motor for rotating the polygon mirror, and the like. And a light beam deflecting and scanning means for deflecting and scanning a light beam, a light beam imaging means for forming an image of the deflected and scanned light beam, and a light beam reflecting means for reflecting the optical path of the light beam. An optical box fixed to the frame is provided. The optical box has at least four fixing portions to the body frame, and the fixing portions have different heights.

[0022]

1 is a schematic sectional view showing an outline of an image forming apparatus using a light beam scanning device of the present invention. FIG. 2 is a perspective view showing a schematic configuration of an optical box of the light beam scanning device of the present invention. Further, FIG. 3 is a schematic diagram showing a configuration of an optical box of the light beam scanning device of the present invention. Further, FIG. 4 is a sectional view showing the structure of the optical box of the light beam scanning device of the present invention.
FIG. 5 is a perspective view showing the structure of the optical box of the light beam scanning device of the present invention. 1 and 2, the image forming apparatus using the light beam device of the present invention mainly has a main body frame 11 and an optical box 12. A photoconductor drum 13 is mainly provided in the main body frame 11. Further, in the optical box 12, a light beam deflection scanning means 14 for deflecting and scanning a light beam composed of a polygon mirror for deflecting the light beam emitted from the light beam generating means 17 and a polygon motor for rotating the polygon mirror, An optical system such as a light beam image forming means 15 for forming an image of the scanned light beam and a light beam reflecting means 16 for reflecting the optical path of the light beam is provided at predetermined positions. Also, the optical box 12
As shown in FIG. 3, it has a fixing portion provided with fixing holes 21 to 24 for fixing to the main body frame 11. The arrangement of the fixing holes 21 to 24 is such that the light beam deflection scanning means 1
4, the light beam image forming means 15 and the light beam reflecting means 16 are arranged so as to be included therein. Further, as shown in FIG. 4, the fixing holes 21 and 22 and the fixing holes 23 and 24 in the main body frame 11 in the direction perpendicular to the scanning direction of the light beam have a height H (for example, 29.5 (mm)). It has a height difference. The heights of the fixing holes 21 and 22 and the fixing holes 23 and 24 in the body frame 11 in the direction parallel to the scanning direction of the light beam are the same.

Further, as shown in FIGS. 3 and 5, the optical box 12 of the light beam scanning device of this embodiment has outer walls 41 to 4.
3 and spaces 31 to 38 formed by the ribs 51 to 59. Optical systems such as the light beam imaging unit 15 and the light beam reflecting unit 16 are arranged in the space 31. Space 31
Although not shown, is sealed with a cover to prevent dust on the optical element surface and thermal deformation of the optical element. The cover is preferably made of resin from the viewpoint of production cost and the like. The light beam deflection scanning means 14 is arranged in the space 35. Although not shown, the space 35 is also sealed with a cover in order to prevent dust on the polygon mirror surface. This cover is preferably made of metal from the viewpoint of soundproofing, heat dissipation and the like. However, it may be made of resin from the viewpoint of production cost and the like. On the other hand, since the optical elements and the like are not arranged in the spaces 32 to 34 and 36 to 38, they need not be hermetically sealed.

The optical box 12 of the light beam scanning device of this embodiment has a fixing hole 2 for fixing it to the body frame 11.
1 to 24 are included in the space. In the example shown in FIG. 3, of the four fixing holes for fixing to the body frame 11, 2
One fixing hole is arranged in each of the spaces 33 and 36.

Further, in the optical box 12 of the light beam scanning device of this embodiment, the ribs 51 to 53 have outer walls 41 to 43.
It is formed along. And these ribs 51-53
Has the same effect as the outer shape walls 41 to 43 in terms of bending rigidity.
As a result, the bending deformation shape of the optical box in the longitudinal direction is significantly different from that in the case where the ribs 51 to 53 are not provided.

Further, in the optical box 12 of the light beam scanning device of this embodiment, ribs 54 to 59 are formed between the outer walls 41 to 43 and the ribs 51 to 53 along the outer shape. Ribs 54 and 55 are formed between the outer shape wall 41 and the rib 51, ribs 56 and 57 are formed so as to connect both ends of the outer shape wall 42 and the rib 52, and a rib 58 is formed between the outer shape wall 43 and the rib 53. , 59 are formed. Ribs 54 and 55 are formed so as to sandwich the fixing hole 22 in the space 33. Further, when the fixing hole 21 in the space 36 is separated from the rib 57, the ribs 58 and 59 are formed so as to sandwich the fixing hole 22 like the fixing hole 22 in the space 33, although not shown. You may.

Further, in the optical box of the light beam scanning device of the present embodiment, as shown in FIG. 6 which is a sectional view taken along the line AA 'showing the external wall and the partial configuration of the rib, the rib 51 has a bottom portion 61.
It has the same height as the height of the outer wall 41. The height H ₁ of the outer wall 41 from the bottom surface portion 61 of the optical box and the height H ₂ of the rib 51 from the bottom surface portion 61 of the optical box are such that H ₁ = H ₂ , for example, H ₁ = H ₂ = 37.1 (mm) is set. Further, in the optical box of the light beam scanning device of the present embodiment, as shown in FIG. 6, the rib 51 has the same thickness as the outer wall 41. External wall 41 wall thickness T ₁
The thickness _{T 2} of the ribs 51 _is set thick so that T 1 = _{T 2,} for example, _T 1 _{= T} 2 ₌ 2.5 and (mm).

Further, in the optical box of the light beam scanning device of this embodiment, as shown in FIG. 7 which is a sectional view taken along the line BB 'showing the external wall and the partial configuration of the ribs, the spaces 31 to 33 are adjacent to each other. The height of the bottom of the matching space is different. The height of the bottom surface portion 61 of the space 31 is H with respect to the bottom surface portion 62 of the space 32.
₃ , the height of the bottom surface portion 63 of the space 33 is set to have a difference of H ₄ . Here, H ₃ ≠ H ₄ . Also,
When H ₃ = H ₄ = 0, the bottoms of the spaces 31 and 33 are on the same plane. In the present embodiment, the height H ₃ of the bottom surface portion 61 of the space 31 is 19.7 (m) with respect to the bottom surface portion 63 of the space 33.
m), and the height H ₄ of the bottom of the space 32 is 16.2 (mm).

Further, the optics of the light beam scanning device of this embodiment
In the box, the height of the bottom of the space is greater than the thickness of the bottom.
Kii. In FIG. 7, the bottom portion 61 of the space 31 and the bottom of the space 32 are
Height difference H in the face portion 62_ThreeIs the bottom of the space 31, 32
Thickness D of the surface portions 61 and 62₁, D _TwoAgainst D₁, D_Two
≤H_ThreeAnd the space between the bottom portion 62 of the space 32 and the space
Height difference H at bottom surface 63 of 33_FourBut the space 32,
Thickness D of bottom surface portions 62 and 63 of 33_Two, D_ThreeAgainst D
_Two, D_Three≤H_FourIs set to be Example
Then, with respect to the bottom surface portion 62 of the space 32, the bottom surface portion of the space 31
Height difference H at 61_ThreeIs 3.5 (mm) and is empty
Bottom portions 61 and 62 of the spaces 31 and 32, thickness D₁, D_TwoAnd
It is 2.5 (mm).

Further, in the optical box of the light beam scanning device of the present embodiment, the wall thickness of the bottom portion having the fixing hole for fixing the body frame in the space is larger than the wall thickness of the bottom portion. In FIG. 7, for example, when a fixing hole is provided in the space 32, the thickness D ₂ of the bottom surface portion 62 of the space 32 is larger than the thicknesses D ₁ and D ₃ of the bottom surface portions 61 and 63 of the spaces 31 and 33. Thus, D ₁ and D ₃ ≦ D ₂ are set. In this embodiment shown in FIG. 3, the thickness of the bottom surface of the spaces 32 and 34 is 2.5 (m).
m), and the thickness of the bottom of the space 33 is 3.0 (mm).

It is needless to say that the present invention is not limited to the above embodiments, and various modifications and substitutions can be made within the scope of the claims.

[0032]

As described above, the light beam scanning device of the present invention comprises a light beam generating means for generating a light beam,
A light beam deflecting and scanning means for deflecting and scanning the light beam comprising a polygon mirror for deflecting the light beam emitted from the light beam generating means and a polygon motor for rotating the light beam, and a light beam for forming an image of the deflected and scanned light beam. An optical box is provided which houses the image forming means and the light beam reflecting means for reflecting the optical path of the light beam and is fixed to the main body frame. The optical box is characterized in that it has at least four fixing parts to the body frame, and the fixing parts have different heights. Therefore, the optical box bends in the longitudinal direction 1
At the next natural frequency, the vibrational deformation shape can be greatly changed to shift the natural frequency of the optical box to the high frequency range side. Further, it is possible to suppress local vibration of the optical box in the high frequency range. Therefore, it is possible to avoid density unevenness on the photoconductor that is caused by vibrations generated by the polygon motor, the photoconductor drum, the motor that drives the recording paper feed / discharge system, and the like.

Further, since the optical box has a space formed by the outer wall and the rib, the optical box bends in the longitudinal direction.
At the next natural frequency, the vibrational deformation shape can be greatly changed to shift the natural frequency of the optical box to the high frequency range side. Further, it is possible to suppress local vibration of the optical box in the high frequency range. Therefore, it is possible to avoid density unevenness on the photoconductor that is caused by vibrations generated by the polygon motor, the photoconductor drum, the motor that drives the recording paper feed / discharge system, and the like.

Further, since the optical box has a fixing hole for fixing it to the body frame in a predetermined space, the optical box is bent in the longitudinal direction as compared with the case where the fixing hole is outside the shape of the optical box. With respect to the natural frequency, it is possible to greatly change the vibration deformation shape and form and to shift the natural frequency of the optical box to the high frequency range side. Therefore, it is possible to avoid density unevenness on the photoconductor that is caused by vibrations generated by the polygon motor, the photoconductor drum, the motor that drives the recording paper feed / discharge system, and the like.

Further, since the rib is formed along the outer wall, the vibrational deformation shape is greatly changed at the primary natural frequency of the optical box bending in the longitudinal direction, and the natural frequency of the optical box is changed to a high frequency. It can be shifted to the zone side. Therefore, it is possible to avoid density unevenness on the photoconductor that is caused by vibrations generated by the polygon motor, the photoconductor drum, the motor that drives the recording paper feed / discharge system, and the like.

Further, the ribs are also formed between the outer wall and the ribs along the outer shape, so that the vibrational deformation shape is greatly changed at the primary natural frequency at which the optical box bends in the longitudinal direction. The natural frequency of can be shifted to the high frequency side. Further, it is possible to suppress local vibration of the optical box in the high frequency range. Therefore, the polygon motor,
It is possible to avoid uneven density on the photoconductor that is caused by vibrations generated by a motor or the like that drives the photoconductor drum and the recording / paper feeding system.

Further, since the rib has the same height as the height of the outer wall from the bottom surface, the shape of vibration deformation is greatly changed at the primary natural frequency at which the optical box bends in the longitudinal direction. The natural frequency can be shifted to the high frequency range side. Therefore, it is possible to avoid density unevenness on the photoconductor that is caused by vibrations generated by the polygon motor, the photoconductor drum, the motor that drives the recording paper feed / discharge system, and the like.

Further, since the rib has the same thickness as the outer wall, when the optical box is made of resin, the thickness of the optical box can be made uniform, which facilitates molding. For this reason, die manufacturing costs and production costs can be reduced.

Further, since the heights of the bottoms of the adjacent spaces are different, the vibrational deformation shape is greatly changed at the primary natural frequency of the optical box bending in the longitudinal direction, and the natural frequency of the optical box is increased. It can be shifted to the frequency range side. Further, it is possible to suppress local vibration of the optical box in the high frequency range. Therefore, it is possible to avoid density unevenness on the photoconductor that is caused by vibrations generated by the polygon motor, the photoconductor drum, the motor that drives the recording paper feed / discharge system, and the like.

Furthermore, by making the height of the bottom of the space larger than the thickness of the bottom, the vibrational deformation shape is greatly changed at the primary natural frequency at which the optical box bends in the longitudinal direction. The natural frequency can be shifted to the high frequency range side. Further, it is possible to suppress local vibration of the optical box in the high frequency range. Therefore, it is possible to avoid density unevenness on the photoconductor that is caused by vibrations generated by the polygon motor, the photoconductor drum, the motor that drives the recording paper feed / discharge system, and the like.

Further, by making the thickness of the bottom portion having the fixing hole in the space larger than the thickness of the bottom portion of the space having no fixing hole, the rigidity in the vicinity of the fixing hole is improved and the optical box is unique. The frequency can be shifted to the high frequency side. Therefore, it is possible to avoid density unevenness on the photoconductor that is caused by vibrations generated by the polygon motor, the photoconductor drum, the motor that drives the recording paper feed / discharge system, and the like.

[Brief description of drawings]

FIG. 1 is a schematic cross-sectional view showing an outline of an image forming apparatus using a light beam scanning device of the present invention.

FIG. 2 is a perspective view showing a schematic configuration of an optical box of the light beam scanning device of the present invention.

FIG. 3 is a schematic view showing a configuration of an optical box of the light beam scanning device of the present invention.

FIG. 4 is a cross-sectional view showing a configuration of an optical box of the light beam scanning device of the present invention.

FIG. 5 is a perspective view showing a configuration of an optical box of the light beam scanning device of the present invention.

6 is an AA ′ showing a partial configuration of the outer wall and the rib of FIG.
It is a line sectional view.

FIG. 7 is a BB ′ showing a partial configuration of the outer wall and the rib of FIG.
It is a line sectional view.

[Explanation of symbols]

11: body frame, 12; optical box, 13; photoconductor drum, 14; light beam deflection scanning means, 15; light beam image forming means, 16; light beam reflecting means, 17; light beam generating means, 21-24; Fixing holes 31-38; Spaces 41-4
3; external wall, 51-59; rib, 61; bottom part.

Continued front page    F-term (reference) 2C362 AA42 AA45 BA90 DA17                 2H045 AA01 DA02 DA04 DA44                 5C072 AA03 BA20 HA01 HA13 HA20                       XA01 XA04

Claims (10)

[Claims] 1. A light beam for deflecting and scanning a light beam comprising a light beam generating means for generating a light beam, a polygon mirror for deflecting the light beam emitted from the light beam generating means, and a polygon motor for rotating the polygon mirror. An optical box is provided which houses the deflection scanning means, the light beam imaging means for forming an image of the deflected and scanned light beam, and the light beam reflecting means for reflecting the optical path of the light beam, and which is fixed to the main body frame. In the light beam scanning device, the optical box has at least four fixing portions to the body frame, and the heights of the fixing portions are different from each other. 2. The light beam scanning device according to claim 1, wherein the optical box has a space formed by an outer wall and a rib. 3. The optical box has a fixing hole for fixing to the body frame in the predetermined space.
The described light beam scanning device. 4. The light beam scanning device according to claim 1, wherein the rib is formed along the outer wall. 5. The light beam scanning device according to claim 1, wherein the rib is also formed between the outer wall and the rib along the outer shape. 6. The light beam scanning device according to claim 4, wherein the rib has the same height as the height of the outer wall from the bottom surface portion. 7. The light beam scanning device according to claim 4, wherein the rib has the same wall thickness as the outer wall. 8. The light beam scanning device according to claim 1, wherein bottom surfaces of adjacent spaces have different heights. 9. The light beam scanning device according to claim 8, wherein the height of the bottom portion of the space is larger than the thickness of the bottom portion. 10. The light beam scanning device according to claim 8, wherein a thickness of a bottom surface portion having the fixing hole in the space is larger than a thickness of a bottom surface portion of the space having no fixing hole.