Optical: systems and elements – Mirror – Plural mirrors or reflecting surfaces
Reexamination Certificate
2001-10-24
2003-11-18
Phan, James (Department: 2872)
Optical: systems and elements
Mirror
Plural mirrors or reflecting surfaces
C359S850000, C359S900000, C359S216100, C427S162000
Reexamination Certificate
active
06648482
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a reflecting polygon mirror to be mounted on the optical scanner used for electrophotographic equipment or the like, and more specifically, to a film formed on the reflecting surface of the polygon mirror. The present invention also relates to an optical scanner and electrophotographic equipment.
2. Description of the Related Art
Hitherto, in the optical scanner such as a laser beam printer or the like, writing or reading of image information is made by scanning on the surface of an image carrier optically with optically modulated luminous flux (laser luminous flux) via a rotating polygon mirror as is disclosed in Japanese Patent Publication No. 62-36210.
FIG. 8
is a schematic drawing showing an example of the construction of the principal portion of an optical scanner. In
FIG. 8
, a luminous flux emitted from the light source
1
such as a semiconductor laser or the like is collimated by a collimator lens
2
, is condensed by a cylindrical lens
83
that has a reflective power only in the vertical scanning direction, and is linearly projected on the deflecting/reflecting surface
4
a
of the light deflector
4
constructed of a polygon mirror or the like. The collimator lens
2
and the cylindrical lens
83
constitute an image forming optical system. The luminous flux deflected and reflected on the deflecting/reflecting surface
4
a
is introduced through a scanning lens
87
comprising a lens
87
a
having a spherical surface and a negative reflective power and a lens
87
b
having different reflective powers between two directions orthogonal with each other and a toric surface onto the scanned surface
89
to form a spot. Then, the deflector
4
is rotated about the axis of rotation
82
by means of a motor
85
in the direction shown by an arrow
86
to scan the deflecting scanning surface on the scanned surface
89
optically in the direction shown by an arrow
90
(horizontal scanning direction).
Materials used in the polygon mirror are in many cases aluminum, plastic, glass. Then, the reflecting surface is coated with a vapor deposited film or an oxide film on anode for increasing the reflectance, eliminating the angle dependence, and preventing oxidation.
Since the reflecting surface of the polygon mirror that is used as a light deflector is coated with a reflection increasing film or the like by vacuum deposition, the difference of film thickness due to errors in manufacture or the uneven film thickness due to the method of manufacture results in variations in reflecting characteristics, and thus it requires an evaporation apparatus of high accuracy, an increase in the basic reflectance by employing a multilayer structure for alleviating the impact therefrom, or a special method of evaporating is necessary, which results in increase in cost or decrease in the possibility of film design.
In a technique to apply an amorphous fluorochemical resin film coating over the oxide film on anode, the oxide film on anode decreases the angle dependence of the reflectance and the amorphous fluorochemical resin film increases the durability for dew condensation. This anodic oxidation coating step requires a large apparatus for washing of the polygon mirror sufficiently, which presents a problem in terms of cost.
In order to solve the problem described above, a rotating wet film-forming method in which a single layer film can be formed at lower cost than two exampled above is proposed. However, when a film is formed on the polygon mirror according to the rotating wet film-forming method, the entire reflecting surface is immersed in the coating liquid, and thus the surfaces other than the reflecting surface are also coated with the coating liquid. As a consequent, there are tendencies where the coating liquid applied on the surfaces other than the reflecting surface gathers on the reflecting surface at the time of the rotating film-forming operation, and resulting in significant variations in film thickness or accidental occurrence of irregular film configurations. Therefore, improvement of productivity and decrease in cost of the rotating wet film-forming method has been problems to be solved.
Recently, the range of the angles of incident of the light being projected on the polygon mirror tends to be widened due to the increased requirement of miniaturization of the optical scanner. On the other hand, various optical films are formed on the reflecting surface of the polygon mirror for obtaining angle-independent uniformity of reflectance, and those optical films have an angle at which light of P-polarization is completely transmitted (Brewster's angle), in other words, when the range of the angles of incident is set to the range including Brewster's angle, an angle that coincides with the reflectance of the lower layer exists absolutely. In the polygon mirror that is desired to have a constant reflectance for the range of the angles of incident, presupposing that a film having a uniform thickness is formed, when the angle of incident is wider than Brewster's angle, the range of variations in reflectance increases, and thus angle-independent uniformity of reflectance can hardly be obtained. Therefore, in the related art, it is difficult to obtain a polygon mirror that can accommodate wide range of angles of incident and thus it is difficult to obtain a miniaturized optical scanner.
SUMMARY OF THE INVENTION
Accordingly, it is an object of the present invention to provide a polygon mirror that can be manufactured at low cost and high productivity, and to provide a polygon mirror in which variations in reflectance is small over a wide range of angles of incident, and a method of manufacturing the same.
It is another object of the present invention to provide an optical scanner and electrophotographic equipment of compact size at low cost.
The present invention provides a polygon mirror having a plurality of reflecting surfaces for reflecting light, wherein the reflecting surfaces are provided by forming a single-layer film of a substance having an index of refraction of not more than 1.45 on the base member.
With the reflecting polygon mirror to be mounted on the optical scanner used in electrophotographic equipment or the like according to the present invention, the polygon mirror can be manufactured at lower cost in comparison with vacuum deposition or anodic oxidation coating by forming a single layer of material having an index of refraction of not more than 1.45, more specifically of amorphous fluorochemical resin that is a substance for a film having a low index of refraction on the reflecting surfaces of the polygon mirror according to the rotating wet film-forming method.
With the rotating wet film-forming method for polygon mirrors according to the present invention, variations in film thickness and accidentally occurred irregular film configurations can be prevented by applying the coating liquid only in the area of the polygon mirror of which the distance from the axis of rotation is larger than Ri, where Ri is the shortest distance between the reflecting surface and the axis of rotation for the coating operation, thereby increasing productivity of the polygon mirror and thus decreasing cost of the polygon mirror.
Therefore, the optical scanner of the present invention comprising such a polygon mirror and thus the electrophotographic equipment comprising such an optical scanner can be manufactured at low cost.
In addition, a constant reflectance is ensured over a wide range of angles of incident by realizing suitable distribution of thickness in the film formed on the reflecting surface of the polygon mirror, which contributes to miniaturization of the optical scanner and enables manufacture of the optical scanner at low cost. Accordingly, the electrophotographic equipment of the present invention comprising such an optical scanner can be miniaturized, and manufactured at low cost.
Further objects, features and advantages of the present invention will become apparent from
Hatakeyama Hideyuki
Matsuo Yasuhiro
Canon Kabushiki Kaisha
Fitzpatrick ,Cella, Harper & Scinto
Phan James
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