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JPH0635212Y2 - Optical scanning device - Google Patents

Optical scanning device

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Publication number
JPH0635212Y2
JPH0635212Y2 JP1987052120U JP5212087U JPH0635212Y2 JP H0635212 Y2 JPH0635212 Y2 JP H0635212Y2 JP 1987052120 U JP1987052120 U JP 1987052120U JP 5212087 U JP5212087 U JP 5212087U JP H0635212 Y2 JPH0635212 Y2 JP H0635212Y2
Authority
JP
Japan
Prior art keywords
light
reflected
lens
scanning device
optical scanning
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Lifetime
Application number
JP1987052120U
Other languages
Japanese (ja)
Other versions
JPS63160525U (en
Inventor
義人 関川
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Fujifilm Business Innovation Corp
Original Assignee
Fuji Xerox Co Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Fuji Xerox Co Ltd filed Critical Fuji Xerox Co Ltd
Priority to JP1987052120U priority Critical patent/JPH0635212Y2/en
Publication of JPS63160525U publication Critical patent/JPS63160525U/ja
Application granted granted Critical
Publication of JPH0635212Y2 publication Critical patent/JPH0635212Y2/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

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Description

【考案の詳細な説明】 産業上の利用分野 本考案は光ビームをfθレンズを介して回転多面鏡に正
面入射させ、偏向後再び前記fθレンズを通過して感光
体表面を走査するようにしたダブルパス光学走査装置に
関するものである。
DETAILED DESCRIPTION OF THE INVENTION Industrial Field of the Invention According to the present invention, a light beam is incident on a rotary polygon mirror frontally through an fθ lens, and after deflecting, the light beam passes through the fθ lens again to scan the surface of the photoconductor. The present invention relates to a double-pass optical scanning device.

従来技術 従来のダブルパス光学走査装置の例を第4図および第5
図に図示し説明する。
Prior Art Examples of a conventional double-pass optical scanning device are shown in FIGS.
It is shown in the figure and explained.

第4図は同装置の要部縦断面図であり、第5図はその横
断面図である。
FIG. 4 is a longitudinal sectional view of the main part of the device, and FIG. 5 is a lateral sectional view thereof.

レーザビーム発生装置1は記録信号に応じて変調された
レーザビームを発生するレーザビーム発生装置であり、
同レーザビーム発生装置1から斜め下方に向けて入射レ
ーザビームb1が出力され、fθレンズ2に入射され、さ
らにfθレンズ2を透過して窓ガラス3に入射される。
The laser beam generator 1 is a laser beam generator that generates a laser beam modulated according to a recording signal,
An incident laser beam b 1 is output obliquely downward from the laser beam generator 1, is incident on the fθ lens 2, is further transmitted through the fθ lens 2, and is incident on the window glass 3.

窓ガラス3は回転多面鏡5および多面鏡駆動モーター8
を覆うモーターカバー4の一部に設けられた防音,防塵
用のガラス窓であり、モーターカバー4の内部は完全密
封され、class 100〜1000の清浄なガス9が封入されて
いる。
The window glass 3 is a rotary polygon mirror 5 and a polygon mirror drive motor 8
It is a glass window for soundproofing and dustproofing provided in a part of the motor cover 4 that covers the inside of the motor cover 4. The inside of the motor cover 4 is completely sealed and a clean gas 9 of class 100 to 1000 is enclosed.

窓ガラス3に入射された入射レーザビームb1は、窓ガラ
ス3を透過して回転する回転多面鏡5の一反射面で反射
され、走査レーザビームb2,b3として斜め下方に進行
し、窓ガラス3およびfθレンズ2を透過してシリンド
リカルミラー6に至り、同シリンドリカルミラー6で反
射してドラム状態光体7に到達し、ドラム状態光体7の
表面に静電潜像として記録される。
The incident laser beam b 1 incident on the window glass 3 is reflected by one reflecting surface of the rotating polygon mirror 5 which passes through the window glass 3 and rotates, and travels obliquely downward as scanning laser beams b 2 and b 3 , The light passes through the window glass 3 and the fθ lens 2, reaches the cylindrical mirror 6, is reflected by the cylindrical mirror 6, reaches the drum state optical body 7, and is recorded on the surface of the drum state optical body 7 as an electrostatic latent image. .

回転多面鏡5の反射面で反射された走査レーザビーム
b2,b3は略扇状に走査され、シリンドリカルミラー6で
反射してドラム状感光体7の表面においてその円筒軸に
略平行な直線上を走査することになる。
Scanning laser beam reflected by the reflecting surface of the rotating polygon mirror 5
b 2 and b 3 are scanned in a substantially fan shape, reflected by the cylindrical mirror 6, and scanned on the surface of the drum-shaped photoreceptor 7 on a straight line substantially parallel to the cylindrical axis thereof.

そこで回転多面鏡5が等角速度運動であることに起因し
て生じる走査歪はfθレンズ2が補償してドラム状感光
体7の表面上で等速直線運動を得るようにしており、ま
た回転多面鏡5の回転にともなう入射光に回転多面鏡5
の面倒れで生じる走査ピッチムラをシリンドリカルミラ
ー6が補償している。
Therefore, the fθ lens 2 compensates for the scanning distortion caused by the rotary polygonal mirror 5 having a constant angular velocity motion so as to obtain a constant linear velocity motion on the surface of the drum-shaped photoconductor 7, and the rotary polygonal facet is also used. Rotating polygonal mirror 5 for incident light accompanying rotation of mirror 5
The cylindrical mirror 6 compensates the scanning pitch unevenness caused by the surface tilt.

以上のような構造の光学走査装置はコリメータレンズを
省くことができ、fθレンズ2および窓ガラス3が入射
レーザビームb1のみならず走査レーザビームb2,b3を透
過するようにしているので、面サイズひいては回転多面
鏡5の外径を小さくして多面鏡駆動モーター8の負荷を
小さくできる等の利点がある。
In the optical scanning device having the above structure, the collimator lens can be omitted, and the fθ lens 2 and the window glass 3 transmit not only the incident laser beam b 1 but also the scanning laser beams b 2 and b 3 . There is an advantage in that the surface size and hence the outer diameter of the rotary polygon mirror 5 can be reduced to reduce the load on the polygon mirror drive motor 8.

考案が解決しようとする問題点 しかし、本装置はfθレンズ2および窓ガラス3がレー
ザビームを2度透過するダブルパス方式なので、わずか
ではあるがfθレンズ2および窓ガラス3の表面におい
て反射した光がドラム状感光体7の表面に至り期待され
ない光信号が記録されるおそれがある。
However, since the present device is a double-pass system in which the fθ lens 2 and the window glass 3 transmit the laser beam twice, the light reflected on the surfaces of the fθ lens 2 and the window glass 3 is small. There is a possibility that an unexpected optical signal may be recorded on the surface of the drum-shaped photoconductor 7.

すなわちfθレンズ2の外表面2aでの反射ビームb4およ
びfθレンズ2の内表面2bでの反射ビームb5は破線で示
す如く斜め下方に反射されて、さらにシリンドリカルミ
ラー6で反射されてドラム状感光体7の表面に至る。
That is, the reflected beam b 4 on the outer surface 2a of the fθ lens 2 and the reflected beam b 5 on the inner surface 2b of the fθ lens 2 are reflected obliquely downward as indicated by the broken line, and further reflected by the cylindrical mirror 6 to form a drum shape. The surface of the photoconductor 7 is reached.

かかる反射ビームb4,b5は回転多面鏡5による走査を受
ける前に反射される光であるので常に光路を同じくし、
ドラム状感光体7の中央の同じ位置に照射され光量はわ
ずかではあるが潜像が形成され、画像の鮮明度を妨げ
る。
Since the reflected beams b 4 and b 5 are the lights reflected before being scanned by the rotary polygon mirror 5, they always have the same optical path,
A latent image is formed by irradiating the same position in the center of the drum-shaped photoconductor 7 with a slight amount of light, which hinders the sharpness of the image.

また以上の反射ビームb4,b5のほかに、一度回転多面鏡
5で反射した走査ビームb2,b3の一部がfθレンズ2の
外表面2aで反射するものもあり、同反射ビームb6は再び
窓ガラス3を透過して回転多面鏡5の反射面で反射して
窓ガラス3,fθレンズ2を透過してシリンドリカルミラ
ー6で反射した後、ドラム状感光体7に至り(破線で示
す)、期待されぬ信号が記録されるおそれがある。
In addition to the reflected beams b 4 and b 5 described above , there is also one in which a part of the scanning beams b 2 and b 3 once reflected by the rotating polygon mirror 5 is reflected by the outer surface 2a of the fθ lens 2. b 6 again passes through the window glass 3, is reflected by the reflecting surface of the rotary polygon mirror 5, passes through the window glass 3, fθ lens 2 and is reflected by the cylindrical mirror 6, and then reaches the drum-shaped photosensitive member 7 (broken line). , The unexpected signal may be recorded.

この反射ビームb6は一度ならず回転多面鏡5で反射され
た光なので、ドラム状態光体7に到達したときの位置は
感光体表面の幅方向全体に亘り不要な潜像が形成される
ことになり、画像が不鮮明にする。
Since this reflected beam b 6 is the light reflected by the rotating polygon mirror 5 more than once, an unnecessary latent image is formed at the position when it reaches the drum state light body 7 over the entire width direction of the surface of the photoconductor. And the image becomes unclear.

さらに回転多面鏡5の反射面で反射した走査ビームb2,b
3の一部はfθレンズ2の内表面2bでも反射して同反射
ビームb7が装置内部で反射を繰り返してドラム状感光体
7に至る場合もあり、かかる二次障害の問題がある。
Further, the scanning beams b 2 , b reflected by the reflecting surface of the rotary polygon mirror 5
A part of 3 may also be reflected by the inner surface 2b of the fθ lens 2 and the reflected beam b 7 may be repeatedly reflected inside the device to reach the drum-shaped photoconductor 7, which causes a problem of such a secondary obstacle.

以上の不具合を少なくするためfθレンズ2の表面に多
層膜等の高価な反射防止コーティングを施す場合がある
が極めて高価なものとなる。
In order to reduce the above problems, an expensive antireflection coating such as a multilayer film may be applied to the surface of the fθ lens 2, but it is extremely expensive.

問題点を解決するための手段および作用 本考案はかかる点に鑑みなされたもので、その目的とす
る処は、遮光部材を適当な位置に配置することで余計な
反射光を遮って感光体に至らないようにし、鮮明な画像
を得ることができる安価な光学走査装置を供する点にあ
る。
Means and Actions for Solving Problems The present invention has been made in view of the above points, and an object of the present invention is to block an unnecessary reflected light by arranging a light shielding member at an appropriate position to prevent the photosensitive member from being exposed. The point is to provide an inexpensive optical scanning device capable of obtaining a clear image while avoiding reaching the target.

すなわち本考案はレーザー光等の光ビームを光軸とある
角度をもってfθレンズに入射させ、出射光を回転多面
鏡で偏向した後、再び前記fθレンズを通過させ、シリ
ンドリカルミラー等の面倒れ補正光学系を介して感光体
表面に走査して露光するダブルパス光学走査装置におい
て、前記回転多面鏡の反射面と前記面倒れ補正光学系と
の間にあって入射光および走査光を妨げない所要位置に
前記fθタレンズからの反射光を遮光する1個または複
数個の遮光部材を配置した光学走査装置である。
That is, the present invention makes a light beam such as a laser beam incident on an fθ lens at an angle to the optical axis, deflects the emitted light by a rotary polygon mirror, and then passes the light beam again through the fθ lens to correct a surface tilt correction optics such as a cylindrical mirror. In a double-pass optical scanning device that scans and exposes the surface of a photoconductor through a system, the fθ is provided at a required position between the reflecting surface of the rotary polygon mirror and the surface tilt correction optical system so as not to interfere with incident light and scanning light. It is an optical scanning device in which one or a plurality of light blocking members for blocking the reflected light from the lens are arranged.

前記遮光部材を上記fθレンズからの反射光を遮光する
所要位置に配置することでfθレンズの内外表面で一部
反射する光を遮光して感光体に到達しないようにし感光
体に余計な潜像を形成することを回避することができ
る。
By disposing the light shielding member at a required position for shielding the reflected light from the fθ lens, the light partially reflected on the inner and outer surfaces of the fθ lens is shielded so as not to reach the photoconductor, and an unnecessary latent image is formed on the photoconductor. Can be avoided.

実施例 以下第1図ないし第3図に図示した本考案にかかる一実
施例について説明する。
Embodiment An embodiment according to the present invention shown in FIGS. 1 to 3 will be described below.

同実施例は前記第4図および第5図に図示した従来例の
光学走査装置と略同様の構成をしており、したがって共
通に使用する部材は同じ符号を用いることとする。
This embodiment has substantially the same structure as the optical scanning device of the conventional example shown in FIGS. 4 and 5, so that the same reference numerals are used for commonly used members.

本実施例では回転多面鏡5とシリンドリカルミラー6と
の間でfθレンズ2を挟む両側にそれぞれ遮光板20,21
を配置している。
In this embodiment, the light shielding plates 20 and 21 are provided on both sides of the rotary polygonal mirror 5 and the cylindrical mirror 6 with the fθ lens 2 interposed therebetween.
Are arranged.

遮光板20,21ともに表面に黒色クロメート処理が施され
ている。
The surfaces of both the light shielding plates 20 and 21 are black chromated.

遮光板20はfθレンズ2の外表面2a側にあって入射レー
ザビームb1より下方でかつfθレンズ2の外表面2aでの
反射ビームb4および内表面2bでの反射ビームb5を遮る位
置に配置されている。
Shielding plate 20 is positioned to intercept the reflected beam b 5 in the reflected beam b 4 and the inner surface 2b of the outer surface 2a of the fθ lens 2 of the outer surface 2a incident laser In the side beams b 1 from and a lower fθ lens 2 It is located in.

したがって遮光板20は入射レーザビームb1の妨げとなら
ずに反射ビームb4,b5を遮光して同反射ビームがシリン
ドリカルミラー6およびドラム状感光体7に達するのを
避けることができる。
Therefore, the light shielding plate 20 shields the reflected beams b 4 and b 5 without obstructing the incident laser beam b 1 and can prevent the reflected beams from reaching the cylindrical mirror 6 and the drum-shaped photoreceptor 7.

しかも遮光板20の表面は黒色クロメート処理がなされて
いるので反射ビームb4,b5は遮光板20の表面で略吸収さ
れて極めて低い反射率を示し以後の二次的障害を考慮す
る必要はない。
Moreover, since the surface of the shading plate 20 is subjected to the black chromate treatment, the reflected beams b 4 and b 5 are substantially absorbed by the surface of the shading plate 20 and show an extremely low reflectance, so that it is not necessary to consider the subsequent secondary obstacles. Absent.

なお該反射ビームb4,b5は動くことはなく固定された光
線なので遮光板20に点として照射される。
Since the reflected beams b 4 and b 5 are fixed light beams that do not move, they are applied to the light shielding plate 20 as points.

したがって遮光板20自体はかかる反射ビームb4,b5を遮
光すればよいので小面積のものですむ。
Therefore, the light shield plate 20 itself needs only to shield the reflected beams b 4 and b 5 , so that it has a small area.

また一方の遮光板21はfθレンズ2の内表面2b側にあっ
て走査レーザビームb2,b3より下方でかつfθレンズ2
の外表面2aでの反射ビームb6および内表面2bでの反射ビ
ームb7を遮る位置に配置されている。
The one light shield plate 21 is on the inner surface 2b side of the fθ lens 2 and below the scanning laser beams b 2 and b 3 and at the fθ lens 2
It is arranged at a position to intercept the reflected beam b 7 in the reflected beam b 6 and an inner surface 2b in the outer surface 2a.

反射ビームb6,b7は走査ビームb2,b3の一部が反射した光
なので左右に移動する。
The reflected beams b 6 and b 7 move to the left and right because the scanning beams b 2 and b 3 are part of the reflected light.

したがって遮光板21は移動する反射ビームb6,b7を遮光
するため左右方向に長尺であるとともに上下にある程度
の幅を有している。
Therefore, the light blocking plate 21 is long in the left-right direction and has a certain width in the vertical direction for blocking the moving reflected beams b 6 and b 7 .

すなわち第3図に第1図および第2図におけるIII−III
矢視図を示すが、同図において入射レーザビームb1,走
査レーザビームb2,b3,反射ビームb6,b7の軌跡と遮光板
21との位置関係が図示されている。
That is, FIG. 3 shows III-III in FIGS. 1 and 2.
As shown in the figure, the loci of the incident laser beam b 1 , the scanning laser beams b 2 and b 3 , and the reflected beams b 6 and b 7 and the light shield plate are shown.
The positional relationship with 21 is shown.

遮光板21の中央上方に入射レーザビームb1が点で示さ
れ、遮光板21の上端縁より距離χだけ上方に走査レーザ
ビームb2,b3が左から右へ走査している。
The incident laser beam b 1 is indicated by a dot above the center of the light shield plate 21, and the scanning laser beams b 2 and b 3 scan from the left to the right above the upper edge of the light shield plate 21 by a distance χ.

fθレンズ2の外表面2aで反射された反射ビームb6は遮
光板21の表面上半分に照射され、その軌跡は初めに左側
において一度左方向へ向う光線として現われたのち、そ
の上下方にUターンして右方へ向い、右側において再び
上方にUターンして一走査を終了する。
The reflected beam b 6 reflected by the outer surface 2a of the fθ lens 2 is irradiated to the upper half of the surface of the light shielding plate 21, and its locus first appears once as a light beam heading leftward on the left side, and then on the upper and lower sides thereof. Turn to face right, and make another U-turn upward on the right side to end one scan.

これはfθレンズ2の外表面2aが曲率を有するからで、
この全ての軌跡は遮光板21の表面内に納まる。
This is because the outer surface 2a of the fθ lens 2 has a curvature,
All of these loci fit within the surface of the shading plate 21.

さらにfθレンズ2の内表面2bで反射された反射ビーム
b7は遮光板21の下半分に照射され、左から右へ向う略直
線状の軌跡を示しており、これはfθレンズ2の内表面
2bが平面であるからで、全軌跡は遮光板21の表面に含ま
れる。
Further, the reflected beam reflected by the inner surface 2b of the fθ lens 2
b 7 is irradiated on the lower half of the light shielding plate 21 and shows a substantially linear locus from left to right, which is the inner surface of the fθ lens 2.
Since 2b is a plane, the entire locus is included in the surface of the light shielding plate 21.

以上のように遮光板21は入射レーザビームb1,走査レー
ザビームb2,b3は妨げることなく反射ビームb6,b7のみ完
全に遮光して該反射ビームがドラム状感光体7にまで至
るのを回避することができる。
As described above, the light blocking plate 21 completely blocks only the reflected beams b 6 and b 7 without disturbing the incident laser beam b 1 and the scanning laser beams b 2 and b 3 , and the reflected beam reaches the drum-shaped photoconductor 7. It can be avoided.

また同遮光板21も表面に黒色クロメート処理が施されて
おり、遮光板21の表面での反射率は極めて低く二次障害
のおそれはない。
The surface of the shading plate 21 is also subjected to black chromate treatment, so that the reflectance on the surface of the shading plate 21 is extremely low and there is no risk of secondary damage.

なお走査レーザビームb2,b3の軌跡と遮光板21の上端縁
との間の距離χは、走査ビームのビーム径(1/e2エネル
ギーの位置)を2ωとした場合、χ>4ωを満たすこと
により本体ドラム状態光体7に露光されるべき走査光の
エネルギーを損することがなく、適正な露光が可能であ
る。
The distance χ between the loci of the scanning laser beams b 2 and b 3 and the upper edge of the light shielding plate 21 is χ> 4ω when the beam diameter of the scanning beam (position of 1 / e 2 energy) is 2ω. By satisfying the condition, proper exposure is possible without deteriorating the energy of the scanning light to be exposed on the main body drum state light body 7.

ただ、χ>4ωを満たすことにより反射ビームb7の一部
が遮光板21からはみ出し、ドラム状態光体7に至るおそ
れがあるがかかる反射ビームのエネルギーは非常に小さ
いため、印字品質に対し殆ど影響を与えない。
However, if χ> 4ω is satisfied, a part of the reflected beam b 7 may protrude from the light shielding plate 21 and reach the drum state light body 7. However, since the energy of the reflected beam is very small, the reflected beam b 7 is almost unclear to the print quality. It has no effect.

また遮光板21はわずかではあるが窓ガラス3で反射する
反射光をも遮断する場合もある。
Further, the light shielding plate 21 may block the reflected light reflected by the window glass 3 although it is small.

以上のように本実施例においては遮光板20,21がfθレ
ンズ2の表面で反射する光をほぼ遮断してしまうので、
残りのわずかに漏れた光がドラム状態光体7に至って
も、エネルギーが非常に小さいので潜像を形成するおれ
はない。
As described above, in the present embodiment, since the light shielding plates 20 and 21 almost block the light reflected on the surface of the fθ lens 2,
Even if the remaining slightly leaked light reaches the drum state light body 7, since the energy is very small, it is not easy to form a latent image.

したがってfθレンズ2の表面には安価な反射防止コー
ティングを施すか、もしくはかかるコーティングを省く
ことができ、コスト低減を図ることができる。
Therefore, an inexpensive antireflection coating can be applied to the surface of the fθ lens 2, or the coating can be omitted, and the cost can be reduced.

なお本実施例のほか、入射レーザビームb1,走査レーザ
ビームb2,b3を妨げない適当な位置に遮光板を設けるこ
とで窓ガラス3の反射光などを遮光することが考えられ
る。
In addition to the present embodiment, it is conceivable to shield the reflected light from the window glass 3 by providing a light shielding plate at an appropriate position that does not interfere with the incident laser beam b 1 and the scanning laser beams b 2 and b 3 .

また遮光板表面に施す反射防止処理としては、前記黒色
クロメート処理のほか黒色硫酸陽極酸化等の方法が考え
られる。
As the antireflection treatment applied to the surface of the light shielding plate, a method such as black sulfuric acid anodic oxidation in addition to the above black chromate treatment can be considered.

考案の効果 本考案は遮光部材を適当な位置に配置することで余計な
反遮光を遮光して感光体に至らないようにし、鮮明な画
像を得ることができる。
EFFECTS OF THE INVENTION The present invention can provide a clear image by arranging the light shielding member at an appropriate position so as to shield unnecessary anti-light shielding so as not to reach the photoconductor.

またfθレンズ等に高価な反射防止コーティングを施す
必要はなく、コストの低減を図ることができる。
Further, it is not necessary to apply an expensive antireflection coating to the fθ lens or the like, and the cost can be reduced.

【図面の簡単な説明】[Brief description of drawings]

第1図は本考案に係る一実施例の光学走査装置の縦断面
図、第2図は同光学走査装置の横断面図、第3図は第1
図におけるIII−III矢視図、第4図は従来の光学走査装
置の縦断面図、第5図は同光学走査装置の横断面図であ
る。 1…レーザビーム発生装置、2…fθレンズ、3…窓ガ
ラス、4…モーターカバー、5…回転多面鏡、6…シリ
ンドリカルミラー、7…ドラム状態光体、8…多面鏡駆
動モータ、9…ガス、 20,21…遮光板、 b1…入射レーザビーム、b2,3…走査レーザビーム、b4
7…反射ビーム。
FIG. 1 is a vertical sectional view of an optical scanning device according to an embodiment of the present invention, FIG. 2 is a horizontal sectional view of the optical scanning device, and FIG.
FIG. 3 is a view in the direction of arrow III-III, FIG. 4 is a vertical sectional view of a conventional optical scanning device, and FIG. 5 is a transverse sectional view of the same optical scanning device. DESCRIPTION OF SYMBOLS 1 ... Laser beam generator, 2 ... fθ lens, 3 ... Window glass, 4 ... Motor cover, 5 ... Rotating polygon mirror, 6 ... Cylindrical mirror, 7 ... Drum state optical body, 8 ... Polyhedral drive motor, 9 ... Gas , 20, 21 ... Shading plate, b 1 ... Incident laser beam, b 2 , 3 ... Scanning laser beam, b 4 ~
7 … Reflected beam.

Claims (2)

【実用新案登録請求の範囲】[Scope of utility model registration request] 【請求項1】光ビームを光軸とある角度をもってfθレ
ンズに入射させ、出射光を回転多面鏡で偏向した後、再
び前記fθレンズを通過させ、面倒れ補正光学系を介し
て感光体表面に走査して露光するダブルパス光学走査装
置において、前記回転多面鏡の反射面と前記面倒れ補正
光学系との間にあって入射光および走査光を妨げない所
要位置に前記fθレンズからの反射光を遮光する1個ま
たは複数個の遮光部材を配置したことを特徴とする光学
走査装置。
1. A light beam is made incident on an f.theta. Lens at an angle with respect to the optical axis, emitted light is deflected by a rotary polygon mirror, and then passed through the f.theta. In a double-pass optical scanning device that scans and exposes the light, the reflected light from the fθ lens is shielded at a required position between the reflecting surface of the rotary polygon mirror and the surface tilt correction optical system so as not to interfere with incident light and scanning light. An optical scanning device characterized in that one or a plurality of light blocking members are arranged.
【請求項2】前記遮光部材の片面又は両面に反射防止処
理を施したことを特徴とする実用新案登録請求の範囲第
1項記載の光学走査装置。
2. The optical scanning device according to claim 1, wherein one or both surfaces of the light shielding member are subjected to antireflection treatment.
JP1987052120U 1987-04-08 1987-04-08 Optical scanning device Expired - Lifetime JPH0635212Y2 (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
JP1987052120U JPH0635212Y2 (en) 1987-04-08 1987-04-08 Optical scanning device

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP1987052120U JPH0635212Y2 (en) 1987-04-08 1987-04-08 Optical scanning device

Publications (2)

Publication Number Publication Date
JPS63160525U JPS63160525U (en) 1988-10-20
JPH0635212Y2 true JPH0635212Y2 (en) 1994-09-14

Family

ID=30877007

Family Applications (1)

Application Number Title Priority Date Filing Date
JP1987052120U Expired - Lifetime JPH0635212Y2 (en) 1987-04-08 1987-04-08 Optical scanning device

Country Status (1)

Country Link
JP (1) JPH0635212Y2 (en)

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2006014023A1 (en) * 2004-08-05 2006-02-09 Canon Kabushiki Kaisha Optical scanning device
JP2006078576A (en) * 2004-09-07 2006-03-23 Canon Inc Optical scanner and image forming apparatus using the same

Families Citing this family (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP5013652B2 (en) * 2003-06-13 2012-08-29 キヤノン株式会社 Scanning optical device
JP4649222B2 (en) * 2004-03-31 2011-03-09 キヤノン株式会社 Manufacturing method of imaging lens

Citations (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPS62269925A (en) * 1986-05-19 1987-11-24 Toshiba Corp Light beam scanning optical system

Patent Citations (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPS62269925A (en) * 1986-05-19 1987-11-24 Toshiba Corp Light beam scanning optical system

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2006014023A1 (en) * 2004-08-05 2006-02-09 Canon Kabushiki Kaisha Optical scanning device
JP2006078576A (en) * 2004-09-07 2006-03-23 Canon Inc Optical scanner and image forming apparatus using the same
US7453616B2 (en) 2004-09-07 2008-11-18 Canon Kabushiki Kaisha Optical scanner configured so a principal ray of an incident beam from a light source to a deflector and a principal ray of a scanning beam from the deflector to a scanned surface travel on same side (or opposite sides) of an optical axis of an optical element(s) having transmissive surfaces both convex (or both concave) toward the deflector in sub-scanning section respectively, and image forming apparatus using the same
US7679802B2 (en) 2004-09-07 2010-03-16 Canon Kabushiki Kaisha Optical scanner configured so a principal ray of an incident beam from a light source to a deflector and a principal ray of a scanning beam from the deflector to a scanned surface travel on opposite sides of an optical axis of optical element(s) having transmissive surfaces both concave toward the deflector in sub-scanning section, and image forming apparatus using the same
JP4500633B2 (en) * 2004-09-07 2010-07-14 キヤノン株式会社 Optical scanning device and image forming apparatus using the same

Also Published As

Publication number Publication date
JPS63160525U (en) 1988-10-20

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