JP3166437B2 - Optical deflector - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention scans an original image or a photoreceptor with a light beam emitted from a laser light source in an image reading system such as a digital copying machine or a facsimile or an image writing system such as a laser beam printer. To an optical deflector for

[0002]

2. Description of the Related Art Conventionally, as a reading system of a document image, there has been known a method of exposing and scanning a document image with a light beam to obtain density information for each pixel from reflected light thereof. There is known a method of exposing and scanning a photosensitive member with a light beam modulated according to information to form an electrostatic latent image. As a method of scanning a document image or a photoreceptor with a light beam emitted from a laser light source in any system, a scanning method using an optical deflector provided with a polygon mirror is known.

FIG. 5 is a schematic diagram showing an image writing system using this scanning method.
01 is a collimator lens, and 102 is a polygon mirror 102a
, An optical deflector having a reference numeral 104, an f-θ lens, and a reference numeral 1
Reference numeral 05 denotes each photosensitive drum. Laser light source 1
The light beam emitted from 00 is reflected by the reflecting mirror surface of the polygon mirror 102a and enters the photosensitive drum 105. At this time, the light beam is deflected by the rotation of the polygon mirror 102a in the direction of arrow A, and Along the line B direction
Scan 5 In addition, the photosensitive drum 105 rotates in the direction of the arrow C along with this, and a two-dimensional electrostatic latent image is formed on the photosensitive drum 105.

Conventionally, an optical deflector used for such a purpose is disclosed in JP-A-59-23324,
The one disclosed in -194513 is known. Specifically, a rotating sleeve is rotatably supported on a fixed shaft erected on a housing, and a polygon mirror is fixed on a mirror flange formed on the rotating sleeve, and a motor unit incorporated in the housing is provided. To rotate the polygon mirror together with the rotating sleeve. In these conventional techniques, the polygon mirror is pressed against the mirror flange by a mirror cap (holding plate), and is held and fixed by the mirror cap and the mirror flange.

[0005]

However, in the case where the polygon mirror is pressed against the mirror flange by the mirror cap and fixed as described above, if the polygon mirror is firmly pressed by the mirror cap, the mirror cap may be mounted in accordance with the mounting accuracy of the mirror cap. As a result, uneven stress is generated in the polygon mirror, and the reflection mirror surface of the polygon mirror is distorted. On the other hand, if the pressing force exerted on the polygon mirror by the mirror cap is reduced, such a problem is solved, but on the other hand, since the polygon mirror is not securely fixed, heat generated during rotation and centrifugal force are generated. As a result, the polygon mirror is displaced with respect to the mirror flange, and there is a problem that vibration occurs in the rotation of the polygon mirror.

As described above, in the conventional optical deflector, the reflection mirror surface is distorted or the polygon mirror vibrates, so that an error occurs in the reflection angle of the incident light beam, and the light beam is accurately deflected. Could not.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and has as its object to hold a polygon mirror between a mirror cap and a mirror flange without distorting a reflecting mirror surface, and to attach the polygon mirror to the polygon mirror. Can be fixed securely,
An object of the present invention is to provide an optical deflector capable of deflecting a light beam incident on a reflecting mirror surface at an accurate reflection angle.

[0008]

In order to achieve the above object, an optical deflector according to the present invention comprises a polygon mirror having a plurality of reflecting mirror surfaces formed on an outer periphery thereof, and an annular mirror flange to which the polygon mirror is fixed. In a light deflector comprising a rotating member that rotates at a predetermined speed and a mirror cap that presses the polygon mirror against a mirror flange, between the mirror cap and the polygon mirror, a mirror cap and a rotating member Characterized in that an adhering means is arranged between them.

In such a technical means, the shape of the rotating member may be appropriately designed and deviated as long as the rotating member holds the polygon mirror and rotates smoothly. It may be a sleeve that rotates around, or a rotating shaft that rotates at the center of the fixed sleeve via a bearing.

The mirror flange may be formed integrally with the rotating member as long as the mirror flange projects from the outer periphery of the rotating member and supports the polygon mirror, or may be formed as a separate member. May be fitted to the outer periphery of the.

Further, as long as the polygonal mirror is sandwiched between the mirror flange and the mirror flange, the fixing method may be changed in design as appropriate. For example, a male screw engraved on a rotating member may be used. May be directly screwed and fixed, or may be fixed by a screw which penetrates the polygon mirror and is screwed to the mirror flange.

Further, as the above-mentioned bonding means, an adhesive such as an epoxy-based or acrylic-based adhesive, or an adhesive sheet having these adhesives applied to both surfaces of a substrate can be used.

Further, from the viewpoint of preventing local deformation of the polygon mirror due to the pressing force exerted on the polygon mirror by the mirror cap, adjustment of the compression force having an elastic coefficient equal to or less than that of the polygon mirror. It is preferable that the member be sandwiched between the mirror cap and the polygon mirror to disperse the pressing force of the mirror cap. When the pressing force adjusting member is provided in this manner, the bonding means is disposed on both surfaces of the pressing force adjusting member. At this time, if the elastic modulus of the bonding means is larger than that of the pressing force adjusting member. In addition, the unevenness of the bonding means generates a local stress on the pressing force adjusting member, and this stress also distorts the polygon mirror. Therefore,
It is preferable that the elasticity coefficient of the bonding means is lower than that of the pressing force adjusting member.

[0014]

According to the above technical means, since the mirror cap and the polygon mirror are fixed by the bonding means, and the mirror cap and the rotating member are also fixed by the bonding means, the polygon mirror is fixed to the rotating member via the mirror cap. Will be fixed. Therefore, even if the pressing force exerted on the polygon mirror by the mirror cap is reduced, the polygon mirror is securely fixed to the mirror flange, and the polygon mirror does not shift with respect to the mirror flange. Further, even if the mirror cap does not exert a large pressing force, the polygon mirror can be securely fixed to the mirror flange, so that the distortion of the reflecting mirror surface of the polygon mirror is suppressed by the reduced pressing force.

[0015]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An optical deflector according to the present invention will be described below in detail with reference to the accompanying drawings. FIG. 1 shows a first embodiment of an optical deflector to which the present invention is applied. In the figure, reference numeral 1 denotes a polygon mirror having eight reflecting mirror surfaces 1a on the outer periphery, reference numeral 2 denotes a rotating sleeve which holds and rotates the polygon mirror 1, and reference numeral 3 denotes a mirror flange protruded from the rotating sleeve 2. , Reference numeral 4 denotes a screwing member fitted to the outer periphery of the rotating sleeve 2, reference numeral 5
Is screwed into the screwing member 4 and the mirror flange 3
Respectively show mirror caps that sandwich the polygon mirror 1 between them.

The rotary sleeve 2 has a predetermined clearance (hereinafter referred to as a bearing clearance) with respect to a fixed shaft 7 erected on the housing 6.
The rotary sleeve 2 and the fixed shaft 7 constitute an air dynamic pressure bearing in the radial direction. That is, the grooves 7 for generating dynamic pressure are formed on the outer peripheral surface of the fixed shaft 7.
a is formed in a herringbone pattern, and when the rotary sleeve 2 rotates, air dynamic pressure is generated in the bearing gap,
The rotating sleeve 2 is supported by the high-pressure air lubricating film and rotates around the fixed shaft 7 in a non-contact state. In this embodiment, the dynamic pressure generating groove 7a is formed on the outer peripheral surface of the fixed shaft 7. However, a dynamic pressure generating groove may be formed on the inner peripheral surface of the rotary sleeve 2 instead.

In FIG. 1, reference numeral 8 denotes a motor for driving the rotary sleeve 2 to rotate. The motor 8 includes a rotor portion 8a fixed to the outer periphery of the rotary sleeve 2 and a stator portion 8b fixed to the housing 6. It is configured.

The rotor section 8a has an annular inner magnet 9 and an outer magnet 10, and these magnets 9 and 10 are fixed in a magnet yoke 11. As shown in FIG. 2, the outer magnet 10 and the inner magnet 9 are arranged on an outer periphery and an inner periphery of a stator core 12, which will be described later, and are respectively magnetized to four poles so as to divide the circumference. Also, the stator core 1
The magnetic poles of the magnets 9 and 10 facing each other across the same 2 are the same magnetic pole.

Inner magnet 9 and stator core 12
, Magnetic attraction always acts between the outer magnet 10 and the stator core 12, and these magnets 9, 10 and the stator core 12 constitute a magnetic thrust bearing. That is, when the rotating sleeve 2 moves from the predetermined position in the thrust direction (axial direction of the fixed shaft), the rotating sleeve 2 is returned to the predetermined position where the magnets 9 and 10 and the stator core 12 face each other by the magnetic attraction. The rotating sleeve 2 is always held at a predetermined position in the thrust direction.

On the other hand, the stator portion 8b is
The stator core 12 is supported by a stud 13 which is provided upright. An electromagnetic coil (not shown) is wound around the stator core 12 in a toroidal shape. A circuit board 15 is fixed to the stator core 12 via studs 14, and the electromagnetic coil is connected to wiring printed on the circuit board 15. And this circuit board 1
Reference numeral 5 is connected to a control circuit unit (not shown) via a wire 16 and a connector 17.

The direction of the current flowing through the electromagnetic coil is determined based on a detection signal of a magnetic detection sensor 18 erected on the circuit board 15. That is, the magnetic detection sensor 18 detects the leakage magnetic flux of the magnets 9 and 10 of the rotor unit 8a and transmits a detection signal to the control circuit unit, while the control circuit unit detects the magnetic flux based on the detection signal. Are determined as to whether the magnetic poles of the magnets 9 and 10 passing through the vicinity of the stator core are N-poles or S-poles.
Then, the direction of the current flowing through the electromagnetic coil wound around each position is determined. As a result, the electromagnetic coil and the magnets 9, 1
Between 0 and 0, a force in the direction of maintaining the rotation of the rotary sleeve 2 always acts, and a predetermined number of rotations is given to the rotary sleeve 2.

Next, the mounting of the polygon mirror 1 on the rotating sleeve 2 will be described. The polygonal mirror 1 has the screwing member 4
A center hole having an inner diameter slightly larger than the outer diameter of the polygon mirror is formed, and the polygon mirror 1 is mounted on the mirror flange 3 so that the screw member 4 is inserted through the center hole. A mirror cap 5 screwed to the screw member 4 is in contact with the polygon mirror 1 to press the polygon mirror 1 against the mirror flange 3.

The screw member 4 to which the mirror cap 5 is screwed is fixed to the outer periphery of the rotary sleeve 2 by press-fitting or bonding. As shown in FIG. 3, a male screw 21 with which the mirror cap 5 is screwed is provided on the outer periphery. Is formed. The male screw 21 has cutout grooves 22 for filling the adhesive in several places.

On the other hand, an annular balance adjusting groove 23 is formed in the upper part of the mirror cap 5, and a ballast is appropriately fixed in the balance adjusting groove 23 so as to prevent the rotation of the polygon mirror 1 from being unbalanced. Have been. A connection hole 24 into which a dedicated jig (not shown) is fitted is formed at an upper portion of the mirror cap 5, and the mirror cap 5 is screwed by the jig fitted into the connection hole 24.
To be tightened.

When the mirror cap 5 is screwed into the screwing member 4, the upper end of the fixed shaft 7 and the mirror cap 5
An air pool 19 is formed between them to suppress damping in the thrust direction. The air pool 19 is communicated with the outside air by the fine holes 20 to stabilize the above-described damping effect. A damper 25 is provided on the housing 6 below the rotating sleeve 2 to prevent the rotating sleeve 2 from contacting the housing 6 when the rotating sleeve 2 is stopped.

As described above, in this embodiment, the mirror cap 5
Is fastened to the screw member 4 to hold and fix the polygon mirror 1 between the mirror flange 3 and the mirror cap 5. At this time, a disc-shaped mirror cap 5 and the polygon mirror 1 are provided between the mirror cap 5 and the polygon mirror 1. The pressing force adjusting member 26 is sandwiched. The pressing force adjusting member 26 is formed of polyethylene terephthalate having a thickness of 0.1 mm, and has an elastic coefficient substantially equal to that of the polygon mirror 1 formed of aluminum. For this reason, when the polygon mirror 1 is fixed by tightening the mirror cap 5, even if the pressing force acts locally on the polygon mirror 1, the pressing force adjusting member 26 is not used. Since the pressure is dispersed and absorbed, local uneven stress is not generated in the polygon mirror 1 and the polygon mirror 1
Of the reflecting mirror surface 1a can be suppressed.

As shown in FIG. 4, an epoxy adhesive 27 is applied between the polygon mirror 1 and the pressing force adjusting member 26, and between the pressing force adjusting member 26 and the mirror cap 5. The polygon mirror 1 is fixed to a mirror cap 5. On the other hand, the notch groove 22 of the screwing member 4 is also filled with an epoxy-based adhesive. For this reason, since the polygon mirror is bonded to the mirror cap 5 and the mirror cap 5 is bonded to the screw member 4, even if the pressing force exerted on the polygon mirror by the mirror cap 5 is small, the mirror flange 3 and the mirror flange 3 are not bonded. The polygon mirror held between the mirror cap 5 and the mirror cap 5 does not shift.

Accordingly, it is possible to prevent the balance of the rotating body such as the polygon mirror 1 and the rotating sleeve 2 from being lost and to generate vibration, and to accurately deflect the light beam incident on the reflecting mirror surface 1a of the polygon mirror 1. Things come. In addition, since the force for pressing the polygon mirror 1 against the mirror flange 3 can be reduced as compared with the related art, it is possible to prevent the occurrence of uneven stress in the polygon mirror 1 and the distortion of the reflection mirror surface 1.

Further, in this embodiment, since the elastic modulus of the adhesive 27 at the time of curing is lower than that of the pressing force adjusting member 26,
Even when the mirror cap 5 is tightened to exert a pressing force on the polygon mirror 1, unevenness caused by uneven application of the adhesive does not cause local stress on the pressing force adjusting member 26. Therefore, uneven stress is not generated in the polygon mirror 1 due to uneven application of the adhesive 27, and the reflection mirror surface 1 is not generated.
a can be prevented.

[0030]

As described above, according to the optical deflector of the present invention, the bonding means is arranged between the mirror cap and the polygon mirror, and between the mirror cap and the rotating member, and the mirror cap and the mirror are arranged. Since the polygonal mirror can be clamped between the flange and the flange with a small pressing force, the polygonal mirror can be securely fixed to the mirror flange without distorting the reflective mirror surface. The beam can be deflected at an accurate reflection angle.

The polygon mirror is bonded to the rotating member via the mirror cap to prevent the polygon mirror from being displaced from the mirror flange due to heat or centrifugal force generated during rotation. Occurrence of vibration can be prevented, and at this point, the light beam incident on the reflecting mirror surface can be deflected at an accurate reflection angle.

[Brief description of the drawings]

FIG. 1 is a schematic view showing an embodiment of an optical deflector according to the present invention.

FIG. 2 is a plan sectional view showing a motor of the optical deflector according to the embodiment.

FIG. 3 is a perspective view showing a screw fixing member of the optical deflector according to the embodiment.

FIG. 4 is a cross-sectional view illustrating a main part of the optical deflector according to the embodiment.

FIG. 5 is a perspective view showing an example of use during the light deflection period.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Polyhedral mirror, 1a ... Reflection mirror surface, 2 ... Rotating sleeve, 3 ...
Mirror flange, 4: screwing member, 5: mirror cap, 26: pressing force adjusting member, 27: adhesive (adhesion means)

Claims (2)

(57) [Claims] 1. A polygon mirror having a plurality of reflecting mirror surfaces formed on an outer periphery, a rotating member provided with an annular mirror flange to which the polygon mirror is fixed and rotating at a predetermined speed, and the polygon mirror being attached to the mirror flange. in light deflector composed of the pressing to the mirror cap, between said mirror cap and polygonal mirror, as well as placing the adhesive means between the mirror cap and the rotating member, the polygonal mirror equal to or less elastic Have a coefficient
Pressing force adjustment member sandwiched between polygon mirror and mirror cap
The elastic modulus of the bonding means to the pressing force adjusting member.
An optical deflector characterized by being less than that . 2. A multiple surface having a plurality of reflecting mirror surfaces formed on an outer periphery.
The mirror and the annular mirror flange to which this polygon mirror is fixed
A rotating member provided and rotating at a predetermined speed, and the polygon mirror
And a mirror cap that presses against the mirror flange.
In the optical deflector, the gap between the mirror cap and the polygon mirror, the mirror cap
Adhesive means is arranged between the rotating member and a screwing member having an external thread formed on the outer periphery of the rotating member.
And the above mirror cap is
An optical deflector, wherein the polygon mirror is screwed and pressed against a mirror flange .