1. Field of the Invention
The present invention relates to an image forming apparatus such as a copier or a printer that uses an electrophotographic method and includes an optical scanning apparatus that performs optical writing with respect to a photosensitive member.
2. Description of the Related Art
Normally, an image output portion of an image forming apparatus such as a copier or a printer that uses an electrophotographic method carries out image formation by an electrophotographic process that forms a toner image by scanning the surface of a photosensitive member with a laser beam that flickers in accordance with print data, and developing an electrostatic latent image formed on the photosensitive member. In general, an optical scanning apparatus is used for scanning a photosensitive member with a laser beam. An optical scanning apparatus converts luminous flux from a semiconductor laser that is a light source into substantially parallel luminous flux, deflects the luminous flux using a rotating polygonal mirror that rotates, and thereafter causes the luminous flux to imaged in the form of a spot on a photosensitive member through an element of an imaging optical system such as a lens or a mirror.
In the following description, the term “main-scanning direction” refers to a direction that is perpendicular to a rotation axis of a rotary polygon mirror and an optical axis of an imaging optical system (direction in which a laser beam deflected by the rotary polygon mirror scans a photosensitive member). The term “sub-scanning direction” corresponds to a direction that is parallel to the rotation axis of the rotary polygon mirror or a rotational direction of a photosensitive member. The term “main-scanning cross section” refers to a plane that includes the main-scanning direction and the optical axis of the imaging optical system. The term “sub-scanning cross section” refers to a cross section that is perpendicular to the main-scanning cross section.
In recent years, in response to demands to increase the speed of image formation, image forming apparatuses are known that use a light source that emits a plurality of laser beams in an optical scanning apparatus. In particular, since a vertical cavity surface emitting laser (hereunder, referred to as “VCSEL”) facilitates formation of a large number of light emitting points into an array, a large number of optical scanning apparatuses that use a VCSEL have been proposed.
The aforementioned kinds of optical scanning apparatuses have a configuration that controls a light amount of a laser beam that is emitted from a VCSEL. Unlike an edge emitting laser, the emission direction of laser beams emitted from a VCSEL is a single direction. As a configuration for detecting the light amount of a laser beam emitted from the VCSEL, a configuration is known that splits a laser beam emitted from the VCSEL into a plurality of laser beams using a beam splitter or the like that is disposed between the VCSEL and a rotary polygon mirror, and in which an optical sensor receives a laser beam obtained by the aforementioned splitting of the laser beam by the beam splitter. The image forming apparatus controls the light amount of a laser beam that the VCSEL emits based on the light amount of the laser beam received by the optical sensor.
A VCSEL has a characteristic such that a spreading angle (FFP) of a laser beam emitted from the VCSEL changes with a change in the driving current. Therefore, if an aperture is provided between a beam splitter and a rotary polygon mirror, a ratio between a light amount of a laser beam obtained when a laser beam is split by a beam splitter that is detected using an optical sensor and a light amount of a laser beam that passes through the aperture and is irradiated onto the photosensitive member changes, and highly accurate light amount control cannot be performed.
For example, in Japanese Patent Application Laid-Open No. 2002-040350, an optical scanning apparatus is proposed that, after shaping a laser beam using an aperture, splits the light beam with a beam splitter and guides a laser beam obtained by the aforementioned splitting to an optical sensor to detect the light amount. According to this configuration, even if a spreading angle at which light is emitted changes due to a change in the driving current, because the laser beam is split at the beam splitter after the laser beam has been shaped by the aperture, a ratio between a light amount that is reflected by the beam splitter and detected by the optical sensor and a light amount that arrives at the photosensitive member is constant. As a result, light amount control can be performed with high accuracy.
For example, in Japanese Patent Application Laid-Open No. 2006-259098, an optical scanning apparatus is proposed in which an aperture and a beam splitter are integrally formed with each other. According to this configuration, a risk of the positional relationship between the aperture and the beam splitter changing is eliminated, and the positional accuracy can be improved and the number of components can be reduced.
It is known that in an image forming apparatus that forms an electrostatic latent image on a photosensitive member using a plurality of laser beams, the imaging positions of respective laser beams on the photosensitive member deviate in the main-scanning direction, and main scanning jitter arises whereby the amount of deviation thereof differs according to a position in the main-scanning direction.
If the photosensitive member 82 has an eccentric component, in some cases the photosensitive member 82 becomes decentered during rotation and moves from a position 82 indicated by a solid line to a position 82′ indicated by a dashed line. The misalignment amount in the main-scanning direction in this case is, for example, an interval La′ at the position corresponding to the interval La, and thus the misalignment amount increases relative to the interval La that is the misalignment amount when there is no decentering.
The present invention has been conceived on the basis of the above described situation, and an object to the present invention is to provide an image forming apparatus that reduces main scanning jitter with a simple configuration and performs highly accurate light amount control.
To solve the above described problems, an image forming apparatus according to the present invention includes: a light source configured to emit a laser beam; an aperture configured to shape the laser beam that is emitted from the light source; a beam splitter configured to split the laser beam into a first laser beam that is a reflected beam and a second laser beam that is a transmitted beam; a deflection unit configured to deflect the second laser beam so that the second laser beam deflected scans a photosensitive member; a lens configured to guide the second laser beam deflected by the deflection unit to the photosensitive member, wherein the lens is disposed at a closest position to the deflection unit in a plurality of optical elements, which includes the lens, on an optical path of the second laser beam deflected by the deflection unit; a light-receiving unit configured to receive the first laser beam; and a control unit configured to control a light amount of the laser beam that the light source emits based on a light amount of the first laser beam received by the light-receiving unit; wherein the aperture is provided between a scanning region of the second laser beam deflected by the deflection unit between the deflection unit and the lens, and the light-receiving unit; and wherein the beam splitter is disposed between the deflection unit and the aperture and is positioned by abutting against the aperture.
According to the image forming apparatus of the present invention, main scanning jitter can be reduced with a simple configuration, and highly accurate light amount control can be performed.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
Preferred embodiments of the present invention will now be described in detail in accordance with the accompanying drawings.
[Exemplary Embodiment]
[Overview of Image Forming Apparatus]
An image forming apparatus 100 includes four image forming portions, namely, an image forming portion 81Bk that forms a black image, an image forming portion 81C that forms a cyan image, an image forming portion 81M that forms a magenta image, and an image forming portion 81Y that forms a yellow image that are disposed in a line with a fixed interval between each image forming portion. In
Black toner, cyan toner, magenta toner and yellow toner are contained in the developing apparatuses 84Bk, 84C, 84M and 84Y, respectively. Each photosensitive drum 82 is a negatively charged OPC photosensitive member and has a photoconductive layer on a drum base made of aluminum, and is rotatively driven at a predetermined process speed in the direction of an arrow (a clockwise direction in
The intermediate transfer belt 87 is suspended around a pair of belt conveying rollers 88 and 89, and is rotated (moved) in the direction of arrow A (counterclockwise direction in
Recording media are stored in a paper feed cassette 92. The recording media (hereunder, referred to as “sheets”) include paper and OHP sheets. The sheets stored in the paper feed cassette 92 are fed, sheet by sheet, by a paper feed roller 93 and conveyed to a pair of registration rollers 94. When the sheet reaches the pair of registration rollers 94, the conveying operation stops temporarily. The conveying operation is resumed in a manner that adjusts the timing thereof so that toner images are transferred onto a predetermined position of the sheet at the secondary transfer portion. The toner images which were transferred onto the sheet at the secondary transfer portion are fixed to the sheet by heating and pressurization at a fixing device 95. Thereafter, the sheet is conveyed by a pair of conveying rollers 96 and a pair of discharge rollers 97, and discharged onto a discharge tray 98.
[Overview of Optical Scanning Apparatus]
Next, the configuration of the optical scanning apparatus 50 is described. In
In
A cylindrical lens 6 has a predetermined refractive power in the sub-scanning direction, and condenses the parallel luminous flux from the collimator lens 5 into a substantially linear shape. The main-scanning aperture portion 7 shapes the luminous flux transmitted through the cylindrical lens 6 into a desired optimal beam shape in the main-scanning direction. A beam splitter 8 is a beam splitting unit. A laser beam incident on the beam splitter 8 is split into a laser beam (first laser beam) that is reflected by the incident surface of the beam splitter 8, and a laser beam (second laser beam) that passes through the incident surface and is incident on a reflection surface of a rotary polygon mirror 10. A light amount of the first laser beam formed by splitting of the laser beam at the beam splitter 8 is measured by an optical sensor 9 (light-receiving unit) in order to perform APC (auto power control). The optical sensor 9 outputs the measured light amount to a system control portion 101. The system control portion 101 controls a driving current that is supplied to the light emitting points of the VCSEL 2 based on the light amount of the first laser beam measured by the optical sensor 9, to thereby stabilize the light amount of the laser beam emitted from the VCSEL 2. Note that the term “APC” refers to control that, in order to maintain the light amount of a laser beam at a constant amount during a single scanning operation, detects the output of the laser beam in a beam detection section during a single scanning operation and maintains the driving current of the semiconductor laser during the single scanning operation. The APC is executed for the respective light emitting points.
Although according to the present exemplary embodiment a configuration is exemplified in which the first laser beam obtained by splitting of the laser beam by the beam splitter 8 is directly incident on the optical sensor 9, an exemplary embodiment of the present invention is not limited thereto. For example, a configuration may be adopted in which the first laser beam obtained by splitting of the laser beam by the beam splitter 8 is caused to be incident on an optical sensor via a reflection mirror that reflects the first laser beam. In this case, the light-receiving unit is assumed to include the optical sensor and the reflection mirror.
The rotary polygon mirror 10 is rotated at a constant speed in the direction of an arrow (counterclockwise direction) in
An alternate long and short dash line 23 and an alternate long and short dash line 24 in
A BD sensor 30 is a synchronization detection unit. The BD sensor 30 is provided outside an exposure region of the photosensitive drum 82 at a substantially conjugate position with respect to the photosensitive drum 82. When the BD sensor 30 receives the second laser beam that is reflected by the rotary polygon mirror 10, the BD sensor 30 outputs a synchronizing signal to the system control portion 101. The system control portion 101 controls the emission timing of laser beams from the VCSEL 2 based on the synchronizing signal from the BD sensor 30.
[Overview of Main-Scanning Aperture Portion and Beam Splitter]
The main-scanning aperture portion 7 includes a first light blocking portion and a second light blocking portion. The first light blocking portion includes an incident side surface 7b (first incident side surface) that is on a side on which a laser beam is incident, a facing surface 7f (first facing surface) that is a surface on a side from which the second laser beam is emitted and that faces the beam splitter 8 that is described later, and an edge portion 7d (first connecting surface) that connects the first incident side surface 7b and the facing surface 7f. The second light blocking portion includes an incident side surface 7a (second incident side surface) that is on a side on which a laser beam is incident, a facing surface 7e (second facing surface) that is a surface on a side from which the second laser beam is emitted and that faces the beam splitter 8 that is described later, and an edge portion 7c (second connecting surface) that connects the second incident side surface 7a and the facing surface 7e.
In
Since an incident beam on the beam splitter 8 is completely reflected when an incident angle of the incident beam is greater than or equal to approximately 42° (degrees), according to the present exemplary embodiment, for example, a configuration is adopted in which the incident angle is less than or equal to 40°, and the angles c and d of the edge portions 7c and 7d of the main-scanning aperture portion 7 are 45°. The housing 40 of the present exemplary embodiment is formed by injection molding in which pressure is applied to inject fluidized resin into a metal mold to perform molding, and the main-scanning aperture portion 7 is formed integrally with the housing. Therefore, if the angles c and d of the edge portions 7c and 7d are too large, the edge distal end portions of the edge portion 7c and the edge portion 7d become narrow, and in some cases the resin forming the housing does not spread as far as the edge distal end portions when performing injection molding of the housing 40. As a result, in some cases projections and depressions arise at the edge distal end portions, and sufficient accuracy is not obtained with respect to the main-scanning adjustment. Therefore, it is appropriate to make the angles c and d less than or equal to 45°.
If the beam splitter 8 is disposed as illustrated by a beam splitter 8′ that is shown by a dashed line in
Even if a laser beam that passed through the incident surface of the beam splitter 8 is reflected at the inner face side of the emission surface of the beam splitter 8, since the incident surface and the emission surface of the beam splitter 8 are not parallel, the reflection angles at the incident surface and the emission surface are different. Consequently, since a reflected beam that is reflected at the emission surface of the beam splitter 8 is not incident on the optical sensor 9, the optical sensor 9 can detect a reflected beam that is reflected at the incident surface of the beam splitter 8 and can perform light amount detection with high accuracy.
As shown in
As shown in
[Overview of APC]
[Exposure of Photosensitive Drum]
Next, the flow of the process until luminous flux emitted from the surface emitting laser 2 by the optical scanning apparatus 50Bk is exposed as a scanning beam E1 on the photosensitive drum is described using
Next, the size of the main-scanning cross section of the luminous flux is limited by the main-scanning aperture portion 7 so that the luminous flux is shaped to have a predetermined beam diameter on the photosensitive drum 82Bk, and one portion of the luminous flux is reflected at the incident surface side of the beam splitter and is incident on the optical sensor 9. The second laser beam that passed through the beam splitter 8 is deflected by the rotary polygon mirror 10. After the second laser beam that has been deflected by the rotary polygon mirror 10 passes through the first imaging lens 21, the second laser beam passes through the second imaging lens 22 and is exposed as the scanning beam E1 on the photosensitive drum 82Bk. The BD sensor 30 detects the second laser beam emitted from the surface emitting laser 2, and outputs a BD synchronizing signal to the system control portion 101. Based on the BD synchronizing signal from the BD sensor 30, the system control portion 101 adjusts a timing with respect to a position for starting scanning at an image end portion by the surface emitting laser 2. According to the present exemplary embodiment, the beam splitter 8 can be disposed close to the rotary polygon mirror 10 without interfering with the scanning beam. Consequently, it is possible to also dispose the main-scanning aperture portion 7 that abuts against the beam splitter 8 close to the rotary polygon mirror 10, and the occurrence of main scanning jitter can be reduced. The optical scanning apparatuses 50C, 50M and 50Y have the same configuration as the optical scanning apparatus 50Bk, and the respective laser beam emitted therefrom are exposed as scanning beams E2, E3 and E4 on the photosensitive drums 82C, 82M and 82Y, respectively.
[Overview of Image Formation Operations]
Next, operations when performing image formation with the image forming apparatus 100 are described. If a signal to start printing is inputted to a control portion (not shown) of the image forming apparatus 100, the respective optical scanning apparatuses 50 emit laser luminous flux based on image information, and each emitted laser luminous flux is irradiated as a scanning beam E onto the surface of the corresponding photosensitive drum 82 to thereby expose the photosensitive drum 82.
The respective photosensitive drums 82 that have been uniformly charged by the corresponding primary charging devices 83 are exposed by the corresponding optical scanning apparatuses 50 to thereby form an electrostatic latent image on each of the photosensitive drums 82. Developing rollers of each of the developing apparatus 84 cause toner of each color within the respective developing apparatuses 84 to adhere to the electrostatic latent images to form toner images of each color on the respective photosensitive drums 82. The toner images of each color on the respective photosensitive drums 82 are transferred onto the intermediate transfer belt 87 at the primary transfer nip portion and thereby superimposed on each other. One sheet at a time is fed from the paper feed cassette 92 by the paper feed roller 93. When the sheet is conveyed to the pair of registration rollers 94, conveying of the sheet stops temporarily. The pair of registration rollers 94 resume conveying of the sheet in a manner that adjusts the timing thereof relative to the toner images on the intermediate transfer belt 87 so that the toner images are transferred onto a predetermined position on the sheet at the secondary transfer portion. At the secondary transfer portion, the toner images on the intermediate transfer belt 87 are transferred onto the sheet. The sheet onto which the toner images have been transferred is conveyed to the fixing device 95. At the fixing device 95, the toner images on the sheet are fixed to the sheet by heating and pressurization. The sheet to which the toner images have been fixed is conveyed by the pair of conveying rollers 96 and the pair of discharge rollers 97, and discharged onto the discharge tray 98. According to the present exemplary embodiment, the beam splitter 8 can be disposed close to the rotary polygon mirror 10 without interfering with a scanning beam, and it is also possible for the main-scanning aperture portion 7 that abuts against the beam splitter 8 to be disposed close to the rotary polygon mirror 10. As a result, main scanning jitter can be reduced and highly accurate image formation can be performed.
As described above, according to the present exemplary embodiment, main scanning jitter can be reduced with a simple configuration, and highly accurate light amount control can be performed. More specifically, by narrowing the width of the end portion of the beam splitter on a side that is near to a scanning beam, the beam splitter can be disposed closer to the rotary polygon mirror without interfering with the scanning beam. As a result, the main-scanning aperture portion that abuts against the beam splitter can also be disposed close to the rotary polygon mirror and the occurrence of main scanning jitter can be reduced. In addition, since the main-scanning aperture portion is mounted in contact with the beam splitter, main-scanning adjustment is performed at the incident surface of the beam splitter. Therefore, an incident beam on the beam splitter can be split with high accuracy into a reflected beam that is reflected by the incident surface of the beam splitter and guided to an optical sensor, and a transmitted beam that is transmitted to an emission surface of the beam splitter. It is thus possible to detect a light amount with high accuracy at the optical sensor. As a result, even if the driving currents of respective lasers are changed, a ratio between a light amount that passes through the beam splitter and exposes the photosensitive drum and a light amount that is reflected by the beam splitter and guided to the optical sensor is fixed, and light amount measurement and light amount control can be performed with high accuracy.
The smaller that an angle that is formed between a scanning beam that exposes an endmost portion of the image region on the photosensitive drum and the emission surface of the beam splitter is, the closer to the rotary polygon mirror that the main-scanning aperture portion and the beam splitter can be disposed without interfering with the scanning beam, and the greater the extent to which the occurrence of main scanning jitter can be reduced. In addition, the angle can be made smaller by changing the configuration in the following manner based on the relationship between incident and exit angles with respect to the beam splitter that does not totally reflect incident light. That is, for example, the angle can be made smaller by decreasing the number of surfaces of the rotary polygon mirror to thereby increase the scanning angle as far as an end portion of an image region of a photosensitive drum or, without changing the number of surfaces of the rotary polygon mirror, by increasing the distance from the rotary polygon mirror to the photosensitive drum to thereby decrease the scanning angle to the image region end portion.
[Other Exemplary Embodiment]
According to the present exemplary embodiment, a configuration is adopted in which an aperture is separated into the sub-scanning aperture portion 1c and the main-scanning aperture portion 7. However, a configuration may also be adopted in which an integral opening portion is disposed immediately anterior to the beam splitter 8. In this case, if it is attempted to form an aperture portion that is the integral opening portion using a rib of the housing 40, the adopted configuration will be a slide-type configuration. The aperture portion may also be formed using a metal plate or the like, and not a rib of the housing 40.
As described above, according to another exemplary embodiment, main scanning jitter can be reduced with a simple configuration, and highly accurate light amount control can be performed.
While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
This application claims the benefit of Japanese Patent Applications No. 2012-100095, filed Apr. 25, 2012, and No. 2013-058260, filed Mar. 21, 2013, which are hereby incorporated by reference herein in their entirety.
Number | Date | Country | Kind |
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2012-100095 | Apr 2012 | JP | national |
2013-058260 | Mar 2013 | JP | national |
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Chinese Office Action dated Dec. 3, 2014 in counterpart Chinese Patent Application No. 201310146512.4, together with an English language translation. |
Number | Date | Country | |
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20130286141 A1 | Oct 2013 | US |