JP2002267989A - Optical deflection scanner - Google Patents

Abstract

(57) Abstract: Provided is an optical deflecting scanning device which improves contamination of a scanning lens caused by an air flow generated by rotation of a rotating body and obtains a high-quality recorded image. A shielding member (1) is provided at at least one location on an optical box (10) containing a polygon motor (20) and a scanning lens (30). For this reason, the airflow containing dust and dust is blocked by the shielding member 1 as a barrier, and the dust and dust contained in the airflow collide with the shielding member 1 and adhere to the surface of the shielding member. As a result, the sucked dust and dust can be reduced before reaching the scanning lens 30, and the adhesion of dirt to the effective surface of the scanning lens can be reduced.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a light deflection scanning device used for a laser beam printer, a laser facsimile or the like.

[0002]

2. Description of the Related Art Conventionally, an image forming apparatus such as a laser beam printer or a laser facsimile using an optical deflection scanning device reflects a light beam such as a laser beam by a rotating polygon mirror which rotates at a high speed. Is deflected and scanned, and the obtained scanning light is focused on a photosensitive member to form an electrostatic latent image. Next, the electrostatic latent image on the photoreceptor is visualized into a toner image by a developing device, transferred to a recording medium such as recording paper and sent to a fixing device, and the toner on the recording medium is heated and fixed to print ( Print) is performed.

An optical deflection scanning device used in such a conventional image forming apparatus is configured as shown in FIG. A laser light beam emitted from a beam light source unit 40 composed of a beam light source, a laser holder, and a lens barrel is converted into a parallel light beam or a convergent light beam by a collimator lens (not shown). To form a line image. The laser beam is deflected by rotating the polygon mirror 20a (rotation direction T), and is image-formed and scanned on a photoconductor (not shown) by a scanning lens 30 as an image-forming lens.

[0004] The scanning lens 30 is a polygon mirror 20a.
The light flux reflected at is focused so as to form a spot on a photoreceptor (not shown), and the scanning speed of the spot is designed to be kept constant. In order to obtain such lens characteristics, the scanning lens 30 includes two lenses, a spherical lens and a toric lens.

[0005] By rotation of the polygon mirror 20a, main scanning by a light beam is performed on a photosensitive member (not shown), and sub-scanning is performed by rotating the photosensitive member (not shown) around the axis of the cylinder. Done. Thus, an electrostatic latent image is formed on the surface of the photoconductor.

The optical box 10 includes a beam light source unit 40, a cylindrical lens 50, a polygon motor 20 (a structure including a polygon mirror 20a as a rotating polygon mirror and a rotor 20b as a rotating body and a built-in driving source), and a scanning lens 30. The photoconductor (not shown) is built in the optical box 1
0. The bottom wall of the optical box 10 is provided with a window for taking out scanning light from the optical box toward a photoconductor (not shown).

[0007]

However, in the above-described prior art, as shown in FIG. 8, the direction U of the arrow in FIG. 8 is the upper direction (height direction). close to the motor 20, which may circumradius r ₁ of the polygon mirror 20a rotor 20b radius r ₂ is smaller than the polygon motor 20 is used.

The rotor 20b is provided with a portion 20d for balancing rotation with a diameter larger than the diameter of the rotor 20b. Therefore, there were the following disadvantages.

[0009] The apparatus having the above-described configuration uses the polygon motor 2.
0, the maximum diameter portion 2 of the outer portion of the rotor 20b
0d has the largest radius of the rotor, so that the rotor 20b
The peripheral speed at the maximum diameter portion 20d of the outer portion is the fastest.

Then, since the pressure decreases at a place where the speed is faster than Bernoulli's theorem, a negative pressure is generated at the maximum diameter portion 20d of the outer part of the rotor 20b, and air is generated by the polygon motor 20.
Of the outer diameter of the rotor 20b from above the axis of rotation of the rotor 2
Od is drawn down to generate a descending air flow.

Then, the descending air flow is generated by the polygon motor 20.
Is released from the polygon motor 20 and released to the outside. The airflow generated by this causes the optical box to
At 0a, it rebounds and rises, so that it flows in the direction shown by the arrow P in FIG. 8 and passes through the scanning lens effective surface 30a.

The air flow passing through the effective surface 30a contains dust and dirt, and contaminates the effective surface 30a of the scanning lens. As a result, the amount of laser light passing through the contaminated part locally decreases, causing density unevenness in the image. If the contamination progresses over time, the amount of laser light until reaching the photoconductor is insufficient. And the image becomes unclear.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems of the prior art.
An object of the present invention is to provide an optical deflection scanning device which can improve the contamination of a scanning lens caused by an air flow generated by the rotation of a rotating body.

[0014]

According to the present invention, there is provided a rotating polygon mirror for deflecting and scanning a light beam, a rotating body rotating together with the rotating polygon mirror, the rotating polygon mirror, and the rotating polygon mirror. Light deflection scanning comprising an optical box containing a rotation driving source for rotating the rotating body, and a scanning lens for forming a scanning light scanned in a predetermined scanning direction by the rotating polygon mirror on a photosensitive body. In the apparatus, at least one shielding member that blocks an air flow generated by rotation of the rotating body is provided between the rotating body and a wall of the optical box, and the shielding member has a part of the shielding member. When the minimum radius of a concentric circle centered on the rotation axis of the rotation drive source is y and the maximum radius of the outer shape of the rotating body is r, 1.1r <y <1.8r is provided. It is characterized by having.

The shielding member has a surface against which an air flow generated by the rotation of the rotating body collides, and the surface is provided so that the air flow is directed toward a wall of the optical box. In the optical box provided with the shielding member, the member includes a plane X including a part of the shielding member, and a point A at which the plane X intersects the wall of the optical box. A and a part of the shielding member is provided so as to be inclined in a direction opposite to a rotation direction side of the plane Y of the rotation drive source with respect to a plane Y including a center line C of a rotation axis of the rotation drive source. It is preferable that it is performed.

Further, it is preferable that the shielding member is provided on a wall of the optical box.

It is preferable that the shielding member has a portion that opens toward the upstream side in the rotation direction of the rotary drive source.

It is preferable that the height of the shielding member is lower than the mounting surface of the rotary polygon mirror for the rotary drive source.

Therefore, according to the present invention, the air flow generated by the rotation of the polygon motor is obstructed by the shielding member acting as a barrier. For this reason, dust and dirt contained in the airflow collide with the shielding member and adhere to the surface of the shielding member. As a result, the sucked dust and dirt can be reduced before reaching the scanning lens, and the adhesion of dirt to the effective surface of the scanning lens can be reduced.

[0020]

Preferred embodiments of the present invention will be described in detail below with reference to the accompanying drawings. However, the dimensions of the components described in this embodiment,
The materials, shapes, relative arrangements, and the like are not intended to limit the scope of the present invention only to them unless otherwise specified.

(First Embodiment) A first embodiment will be described with reference to FIGS.

FIG. 1 is a plan view of the light deflection scanning device according to the first embodiment, and FIG. 2 is a plan view of the light deflection scanning device of FIG.
It is -B partial sectional view. In FIG. 2, the direction U of the arrow is defined as the upper direction (height direction). The same or similar parts as in the conventional example are denoted by the same reference numerals, and description thereof is omitted.

As shown in FIGS. 1 and 2, the optical box 10 contains a polygon motor 20, a scanning lens 30, a beam light source unit 40, and a cylindrical lens 50. The polygon motor 20 includes a polygon mirror 20a as a rotating polygon mirror and a rotor 20b as a rotating body and has a built-in drive source.

The radius r ₁ of the circumscribed circle of the polygon mirror 20a is smaller than the radius r _{2 of the} rotor 20b.
The rotor 20b is provided with a portion 20d for balancing rotation with a diameter larger than the diameter of the rotor 20b.

The scanning lens 30 is a polygon mirror 20b
Are arranged in the direction of reflection of laser light (not shown). On the optical box 10 surrounding the polygon motor 20, the shielding member 1 is provided in contact with the wall of the optical box 10.

When the plane including a part of the shielding member 1 is defined as a plane X, and the point where the plane X intersects the wall of the optical box is defined as A, the point A and the rotation of the polygon motor 20 are defined. It is provided to be inclined with respect to a plane Y including the center line C of the shaft.

Let T be the rotation direction of the polygon motor 20,
Assuming that the tangential direction of the rotation direction T of the polygon motor 20 at the intersection of the plane Y and the rotor 20b is R, the shielding member 1 is inclined with respect to the plane Y in a direction opposite to the tangential direction R of the rotation direction T. It can be said that. This is called that the shielding member 1 is inclined in the direction opposite to the rotation direction T with respect to the plane Y.

In this case, the airflow that has collided with the shielding member is directed to the wall of the optical box, and more dust and dirt can adhere to the shielding member and the wall surface of the optical box. As a result, the sucked dust and dirt can be reduced before reaching the scanning lens, and the adhesion of dirt to the effective surface of the scanning lens can be reduced.

Further, the tip of the shielding member 1 (a portion close to the polygon motor 20) is located at the maximum diameter portion 2 of the outer portion of the rotor 20b.
On a concentric circle whose radius is 1.2 times the radius of 0d,
Since the base of the shielding member 1 intersecting with the optical box 10 is provided on a concentric circle having a radius of 1.8 times, the length of the shielding member 1 in the linear direction is approximately 8.4 mm.

The inclination angle is 10 degrees with respect to the plane Y.
The shielding member 1 of the present embodiment is provided under these conditions. Note that the height of the shielding member 1 is
a is lower than the mounting seat surface 20c.

Next, the operation of this embodiment will be described. When the polygon motor 20 is rotated in the apparatus having such a configuration, since the maximum diameter portion 20d of the outer portion of the rotor 20b has the maximum radius portion of the rotor, the peripheral speed at the maximum diameter portion 20d of the outer portion of the rotor 20b is reduced by one. The fastest.

Then, since the pressure drops at a place where the speed is higher than the Bernoulli's theorem, a negative pressure is generated at the maximum diameter portion 20d of the outer shape of the rotor 20b, and air is generated from the upper side of the polygon motor rotating shaft. Maximum diameter 2
Od is drawn down to generate a descending air flow.

Then, the descending air flow is generated by the polygon motor 20.
Is released from the polygon motor 20 and released to the outside. In addition, even when the optical box 10 is closed by a lid (not shown), a gap is formed between the optical box 10 and the lid (not shown) on the scanning lens. In this case, there occurs a flow that sucks in from the left side as in T1.

Since the shielding member 1 is provided on the optical box 10, the airflow generated by the rotation of the polygon motor 20 is obstructed by the shielding member acting as a barrier. Therefore, dust and dust contained in the air flow collide with the shielding member 1 and adhere to the surface of the shielding member 1.

As a specific numerical value of this embodiment, the maximum diameter portion 20d of the outer portion of the rotor 20b has a radius of 13.6 mm.
It is. A radius of 14.8 mm, which is approximately 1.2 mm radially away from the maximum diameter portion 20d of the outer shape portion of the rotor 20b and approximately 1.1 times the radius of the maximum diameter portion 20d of the outer shape portion of the rotor 20b.
When the shielding member 1 is within the concentric circle of
Experiments have confirmed that the sound of the collision caused by a collision with the vehicle suddenly becomes loud.

In addition, even in consideration of the assemblability when attaching the polygon motor 20 to the optical box 10, it is necessary that the diameter is approximately 1.0 mm from the maximum diameter portion 20d of the outer shape of the rotor 20b. Further, a radius of 23.6 m, which is approximately 10 mm radially away from the maximum diameter portion 20d of the outer shape portion of the rotor 20b and is approximately 1.8 times the radius of the maximum diameter portion 20d of the outer shape portion of the rotor 20b.
It has also been confirmed that the presence of a part of the shielding member 1 within the concentric circle of m has a sufficient effect of adhering dust and dirt.

Taking these into consideration, it is preferable that a part of the shielding member 1 be in a concentric circle having a radius of about 1.1 to 1.8 times the radius of the maximum diameter portion 20d of the outer diameter portion of the rotor 20b. .

As a result, the sucked dust and dirt can be reduced before reaching the scanning lens 30, and the adhesion of dirt to the scanning lens effective surface 30a can be reduced.

As a result, dirt on the scanning lens 30 due to dirt such as dust or dirt is greatly improved, and a decrease in transmittance of the scanning lens 30 can be prevented, so that a high-quality recorded image can be obtained.

In this embodiment, the shielding member 1 is provided to be inclined with respect to the plane Y, but may be provided on the plane Y.

In the present embodiment, the height of the shielding member 1 is made lower than the mounting seat surface 20c of the polygon mirror 20a in order to avoid generation of wind noise of the polygon motor 20.

In the present embodiment, the shielding member 1 is
0, the shielding member 1 is an optical box 1
0 It may be away from the wall. In this case, the shielding member 1 has a plane X including a part of the shielding member 1 as a plane X, and the plane X
Assuming that a point at which the optical box intersects with the wall of the optical box is A, the point may be inclined with respect to the plane A including the point A and the center line C of the rotation axis of the polygon motor 20. The direction of the inclination is the same as described above.

Although only one shielding member is provided in this embodiment, a plurality of shielding members may be provided as shown in FIG. The effect can be enhanced by providing a plurality of locations.

As shown in FIG. 4, only a part of the shielding member 1 may satisfy the above condition.

(Second Embodiment) FIGS. 5 and 6 show a second embodiment. FIG. 5 is a plan view of the light deflection scanning device according to the second embodiment, and FIG. 6 is a partial cross-sectional view taken along line BB of the light deflection scanning device of FIG. In FIG. 6, a direction U indicated by an arrow is an upper direction (height direction). The same or similar parts as those in the related art are denoted by the same reference numerals, and description thereof is omitted.

As shown in FIGS. 5 and 6, the optical box 10 houses a polygon motor 20, a scanning lens 30, a beam light source unit 40, and a cylindrical lens 50.
The polygon motor 20 includes a polygon mirror 20a as a rotating polygon mirror and a rotor 20b as a rotating body and has a built-in drive source.

The radius r ₁ of the circumscribed circle of the polygon mirror 20a is smaller than the radius r _{2 of the} rotor 20b.
The rotor 20b is provided with a portion 20d for balancing rotation with a diameter larger than the diameter of the rotor 20b.

The scanning lens 30 is a polygon mirror 20b
Are arranged in the direction of reflection of laser light (not shown).

In the optical box 10 surrounding the polygon motor 20, the shielding member 1 having an opening is integrally formed.
The polygon motor 20 passes through an arbitrary position A 'of this opening.
When a circle T2 centering on the rotation axis is drawn, the tangent direction of the rotation direction T of the polygon motor 20 at an arbitrary position A 'of the opening is R. At this time, the tangential direction R side with respect to the rotation direction T of the polygon motor 20 is called a downstream side, and the opposite direction is called an upstream side.

At this time, the shielding member 1 is a polygon motor 2
It can be said that it opens toward the upstream side in the zero rotation direction T. A part of the shielding member 1 is included in a concentric circle whose radius is 1.3 times the radius of the maximum diameter portion 20d of the outer portion of the rotor 20b with the rotation axis of the polygon motor 20 as the center. .

The shielding member 1 in the present embodiment is provided under this condition. The height of the shielding member 1 is
It is lower than the mounting seat surface 20c of the polygon mirror 20a.

Next, the operation of this embodiment will be described. In the case of the apparatus having the configuration of the present embodiment, when the polygon motor 20 is rotated, the maximum diameter portion 2
0d has the maximum radius of the rotor, so that the rotor 20b
The peripheral speed at the maximum diameter portion 20d of the outer portion is the fastest.

Then, since the pressure drops at a place where the speed is higher than the Bernoulli's theorem, a negative pressure is generated at the maximum diameter portion 20d of the outer part of the rotor 20b, and air flows from the upper side of the polygon motor rotating shaft to the maximum of the outer part of the rotor 20b. The air is drawn to the diameter portion 20d, and a descending air flow is generated. Then, the descending air flow is generated by the rotation of the polygon motor 20.
It is released more and released outside.

Further, as for the flow of air in the entire optical box 10, even when the optical box 10 is closed by a lid (not shown), a gap is formed on the scanning lens with the lid (not shown). In FIG. 5, there is a flow such as T1 that sucks in from the left side.

Since the shielding member 1 is provided on the optical box 10, the airflow generated by the rotation of the polygon motor 20 is obstructed by the shielding member acting as a barrier. Therefore, dust and dirt contained in the air flow collide with the shielding member 1 and adhere to the surface of the shielding member 1.

Accordingly, it is possible to reduce the sucked dust and dirt before the dust reaches the scanning lens 30, and it is possible to reduce the adhesion of dirt to the scanning lens effective surface 30a.

As a result, dirt on the scanning lens 30 due to dirt such as dust or dirt is greatly improved, and a decrease in transmittance of the scanning lens 30 can be prevented, so that a high-quality recorded image can be obtained. As described above, the same effects as those of the above embodiment can be obtained.

In this embodiment, the height of the shielding member 1 is made lower than the mounting seat surface 20c of the polygon mirror 20a in order to avoid the generation of wind noise of the polygon motor 20.

In this embodiment, only one shielding member is provided, but a plurality of shielding members may be provided. The effect can be enhanced by providing a plurality of locations. Although the shape of the opening of the shielding member 1 is concave, the same effect can be obtained even if the shape is a dead end shape such as a V shape or a U shape in which the downstream side in the rotation direction of the polygon motor 20 is dead end (closed). Can be obtained.

[0060]

As described above, according to the present invention,
The airflow generated by rotating the rotating body is obstructed by the shielding member acting as a barrier. For this reason,
Dust and dust contained in the airflow collide with the shielding member and adhere to the surface of the shielding member. As a result, dust and dirt can be reduced before reaching the scanning lens, and the adhesion of dirt to the effective surface of the scanning lens can be reduced. As a result, it is possible to realize a light deflection scanning device in which an image is clear and density is not uneven.

[Brief description of the drawings]

FIG. 1 is a diagram showing a plane of an optical deflection scanning device according to a first embodiment.

FIG. 2 is a diagram showing a partial cross section of the light deflection scanning device according to the first embodiment.

FIG. 3 is a diagram showing a plane of the light deflection scanning device according to the first embodiment.

FIG. 4 is a diagram showing a plane of the light deflection scanning device according to the first embodiment.

FIG. 5 is a diagram illustrating a plane of an optical deflection scanning device according to a second embodiment.

FIG. 6 is a diagram showing a partial cross section of the light deflection scanning device according to the first embodiment.

FIG. 7 is a diagram showing a plane of a light deflection scanning device showing a conventional example.

FIG. 8 is a diagram showing a cross section of a light deflection scanning device showing a conventional example.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Shielding member 10 Optical box 10a Optical box wall surface 20 Polygon motor 20a Polygon mirror 20b Rotor 20c Polygon mirror mounting seat surface 20d Maximum diameter portion of rotor outer part 30 Scanning lens 40 Beam light source unit 50 Cylindrical lens

 ────────────────────────────────────────────────── ─── Continuing on the front page (72) Inventor Yasutaka Narige 3-30-2 Shimomaruko, Ota-ku, Tokyo Inside Canon Inc. (72) Inventor Nobuo Nakajima 3-30-2 Shimomaruko, Ota-ku, Tokyo Canon F term in reference (reference) 2C362 AA42 AA45 BA90 DA03 EA17 2H045 AA34 DA41 5C051 AA02 CA07 DB02 DB05 DB22 DB24 DB30 DC01 DC07 5C072 AA03 BA20 DA02 DA21 HA02 HA09 HA13 XA05

Claims (7)

[Claims] A rotary polygon mirror that deflects and scans a light beam; a rotary body that rotates together with the rotary polygon mirror; a rotary drive source that drives the rotary polygon mirror and the rotary body to rotate; A scanning lens that forms an image on a photosensitive member with scanning light scanned in the scanning direction, and an optical deflection scanning device that includes an optical box that houses the scanning lens. One or more shielding members for preventing airflow generated by rotation of the rotating body are provided, and the shielding member has a minimum radius of a concentric circle centered on a rotation axis of the rotary drive source including a part of the shielding member. y, wherein r is the maximum radius of the outer shape of the rotating body, 1.1r <y <1.8r. 2. The optical system according to claim 2, wherein the shielding member has a surface against which an air flow generated by rotation of the rotating body collides, and the surface is provided so that the air flow is directed toward a wall of the optical box. The light deflection scanning device according to claim 1. 3. In the optical box provided with the shielding member, when a plane including a part of the shielding member is a plane X, and a point at which the plane X intersects a wall of the optical box is A, With respect to a plane Y including the point A and the center line C of the rotation axis of the rotary drive source, a part of the shielding member is inclined in a direction opposite to the rotation direction side of the plane Y of the rotary drive source. The light deflection scanning device according to claim 1, wherein the light deflection scanning device is provided. 4. The light deflection scanning device according to claim 1, wherein the shielding member is provided on a wall of the optical box. 5. The light deflection scanning device according to claim 1, wherein the shielding member has a portion that opens toward an upstream side in a rotation direction of the rotation drive source. 6. The light deflection scanning device according to claim 1, wherein a height of said shielding member is lower than a mounting surface of said rotary polygon mirror for said rotary drive source. 7. An optical deflection scanning device according to claim 1, wherein said shielding member is a rib-shaped member.