JP2005352516A - Multibeam scanning optical system and image forming apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To obtain a multibeam scanning optical system in which the displacement between dot positions of a plurality of scanning lines in the direction corresponding to a subscanning is reduced with a simple structure. <P>SOLUTION: In a multi beam scanning optical system in which an optical element group which focuses beams emitted from a plurality of laser light sources onto corresponding image carriers, respectively, is provided for every beam, a prism 7 is disposed between a coupling lens 2 and an optical deflector 5 which compose the optical element group, and the prism 7 is movable in the corresponding subscanning direction. The prism 7 may be turned around the incident luminous flux serving as a turning axis. The prism 7 may be tilted in the corresponding subscanning direction and turned. The multibeam scanning optical system is used as a scanning optical system of an image forming apparatus. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a laser beam scanning apparatus and an image forming apparatus for scanning a laser beam emitted from a plurality of laser light sources onto an image carrier by an optical deflector, and relates to a digital copying machine, a printer, a laser facsimile, and a laser printing machine. It can be applied to a laser plotter or the like.

  In recent years, optical means for emitting laser beams emitted from a plurality of light sources as scanning beams are integrally formed in one housing, and a plurality of scanning beams emitted from the housing are provided corresponding to the respective scanning beams. Color image forming apparatuses that form images of a plurality of colors by forming images on the surface of each image carrier and obtain a color image by superimposing and transferring the image on each image carrier onto a recording sheet have been known. .

  For example, four photosensitive drums are arranged in the conveyance direction of the recording paper, and a latent image is formed by simultaneously exposing with a scanning beam corresponding to each of the photosensitive drums. These latent images are yellow, magenta, cyan, and black. A digital copier, laser printer, etc. that obtains a color image by visualizing these images with a developer using different color developers such as Multicolor image forming apparatuses have been put into practical use.

  When scanning light with such a multicolor image forming apparatus, a plurality of scanning means are used. However, a large space is required to arrange the scanning means, and the entire apparatus becomes large. There has been proposed a system in which a beam is incident on a single deflector for scanning, and optical elements are superposed in the sub-scanning direction (see, for example, Patent Document 1). As disclosed in Patent Document 1, a plurality of light beams are incident on a single deflector, and each scanning unit is configured in a hierarchical manner, so that the optical scanning device is configured with an integral housing, and the configuration is simplified. Attempts have been made.

Here, an outline of a conventional general multi-beam scanning optical system will be described. In FIG. 9, reference numeral 1 is a light source, 2 is a coupling lens, 3 is an aperture, 4 is a first imaging optical system that forms a long line image in the main scanning direction in the vicinity of the deflection reflection surface, 5 is an optical deflector, 6 Denotes a writing scanning optical system comprising a second imaging optical system for forming a light spot on the surface to be scanned of an image carrier made of a photoconductor, and 7 denotes a photoconductor as an image carrier.
The light beam emitted from the light source 1 is shaped by the coupling lens 2, and after passing through the aperture 3, a first image forming optical system 4 forms a line image in the vicinity of the deflecting reflection surface of the optical deflector 5 in the main scanning direction. . The light beam that is changed in a predetermined angle range by the rotation of the optical deflector 5 is imaged on the surface of the photoconductor 7 by the second imaging optical system 6 and scans the surface of the photoconductor 7. Scanning optical systems are arranged on the left and right, and are laid out so as to share a single optical deflector 5.

FIG. 10 is a cross-sectional view of the multi-beam scanning optical system in the sub-scanning direction. The second imaging optical system 6 includes optical elements 8 stacked in the sub-scanning direction.
FIG. 8A is a schematic diagram showing the configuration from the laser light source 1 to the optical deflector 5 from the sub-scanning corresponding direction. The light beam emitted from the laser light source 1 is coupled by the coupling lens 2 and passes through the first imaging optical system that forms a long line image in the main scanning direction in the vicinity of the deflection reflection surface of the optical deflector 5 to deflect the light. A line image long in the main scanning direction is formed in the vicinity of the device 5.

  In recent years, plastic materials are often used for optical elements of scanning optical systems. While plastic is excellent in mass productivity, its shape may deviate from the ideal due to the distribution of the temperature inside the mold during molding and cooling after removal from the mold. There are also many. In scanning optical systems, there are many optical elements that are long in the main scanning direction, and the optical elements may be bent in the sub-scanning direction. Depending on the holding method, the dot position shifts in the direction corresponding to sub-scanning, such as scanning line bending. It becomes. 12A shows a state of dot position deviation in the sub-scanning direction between the scanning lines, and FIG. 12B shows a state in which the dot position deviation in the sub-scanning direction is corrected.

  In addition, the mounting error of the optical element to the housing is also a dot position shift in the sub-scanning corresponding direction on the scanning surface, and often has a size that cannot be ignored. This is particularly a problem for tandem full-color copiers. The tandem type full-color copying machine has four photosensitive drums as image carriers corresponding to the cyan (C), magenta (M), yellow (Y), and black (K) colors along the transfer belt conveyance surface. The beam scanning device scans the beam provided corresponding to each photosensitive drum to form an electrostatic latent image on the peripheral surface of the photosensitive drum and develops it with the toner of the corresponding color. An image is formed and sequentially transferred onto a sheet conveyed by a conveyance belt to form a multicolor image. Therefore, if a dot position shift in the sub-scanning corresponding direction occurs for each color, a color shift or the like occurs and the image quality deteriorates.

  The point of improving the quality of the color image formed by the multicolor image forming apparatus as described above is how to accurately superimpose the position of the scanning line by each light beam at a predetermined position. As the form of the overlay error of each scanning line, there are a sub-scanning position shift, a tilt shift, and a curve. In recent years, when plastic lenses are used from the viewpoint of low cost and ease of handling, the plastic lenses are distorted due to environmental changes such as temperature fluctuations, and the scanning line by the light beam transmitted through the plastic lenses is bent. There's a problem. Therefore, the applicant of the present invention uses one of the lenses constituting the lens group corresponding to each light beam as a slit-like plastic lens, and scans the plastic lens by forcibly bending it in the sub-scanning direction. It has been proposed to provide a curve adjusting means for adjusting the bending of the line (see, for example, Patent Document 2).

JP-A-4-127115 Japanese Patent Laid-Open No. 10-268217

  The invention described in the above-mentioned Patent Document 2 adjusts by paying attention to the bending of the scanning line. Regarding the relative positional relationship of each scanning line in the sub-scanning corresponding direction, that is, the dot position deviation in the sub-scanning direction. Not considered.

  Accordingly, the invention described in claims 1 to 3 of the present application is a multi-beam scanning optical system capable of reducing the dot position deviation in the sub-scanning corresponding direction on the surface to be scanned between the plurality of scanning lines with a simple configuration. The purpose is to provide.

  A fourth aspect of the present invention is to provide an image forming apparatus using the multi-beam scanning optical system according to any one of the first to third aspects.

  According to the first aspect of the present invention, in the multi-beam scanning optical system in which an optical element group for forming images of beams emitted from a plurality of laser light sources on the corresponding image carriers is provided for each beam, the optical element group A prism is disposed between the coupling lens and the optical deflector, and the prism is movable in the sub-scanning corresponding direction.

  According to a second aspect of the present invention, there is provided a multi-beam scanning optical system in which an optical element group for forming images of beams emitted from a plurality of laser light sources on a corresponding image carrier is provided for each beam. A prism is disposed between the coupling lens constituting the optical deflector and the optical deflector, and this prism is rotatable about its incident light beam as a rotation axis.

  According to a third aspect of the present invention, there is provided a multi-beam scanning optical system in which an optical element group for forming images of beams emitted from a plurality of laser light sources on a corresponding image carrier is provided for each beam. A prism is disposed between the coupling lens and the optical deflector, and the prism is tiltable and rotatable in the sub-scanning corresponding direction.

  According to a fourth aspect of the present invention, there is provided an image forming apparatus for forming a latent image by performing optical scanning with an optical scanning device on a surface to be scanned of an image carrier, and obtaining the image by visualizing the latent image. The multi-beam scanning optical system according to any one of claims 1 to 3 is used as an optical scanning optical system that performs optical scanning on a surface to be scanned of a body.

  According to the first, second, and third aspects of the invention, it is possible to provide a multi-beam scanning optical system capable of reducing dot position deviation in the sub-scanning corresponding direction on the surface to be scanned with a simple configuration. . In addition, it is possible to provide a multi-beam scanning optical system that can effectively relax the tolerance for the shape tolerance and assembly tolerance of a single optical element.

  According to a fourth aspect of the present invention, an image forming apparatus is configured using the multi-beam scanning optical system according to the first, second, and third aspects. The effect similar to the effect acquired by can be acquired. In particular, color misregistration can be reduced in a full-color image forming apparatus.

Hereinafter, embodiments of a multi-beam scanning optical system and an image forming apparatus according to the present invention will be described with reference to the drawings.
1 and 2 show an embodiment of a multi-beam scanning optical system according to the present invention, and are optical arrangement diagrams of a multi-beam scanning apparatus in which a plurality of pairs of light sources and coupling lenses are arranged. 1 and 2, the two light emitting sources are semiconductor lasers 301 and 302, respectively, and there are coupling lenses 303 and 304 corresponding to the respective semiconductor lasers. The semiconductor lasers 301 and 302 are arranged so that the optical axes of the coupling lasers 303 and 304 coincide with each other and have an emission angle symmetrical to the main scanning direction, and the emission axes intersect at the reflection point of the polygon mirror 307 as an optical deflector. Has been.

The light beams emitted from the respective semiconductor lasers 301 and 302 are made into substantially parallel light beams by the coupling lenses 303 and 304, pass through the beam shaping means, and then converged only in the sub-scanning direction by one cylinder lens 308 to be polygon mirror 307. A line image that is long in the main scanning direction is formed in the vicinity of the deflection reflection surface. Each light beam is further scanned collectively by a polygon mirror 307 and formed on a photoconductor 312 as an image carrier by an f-θ lens 310 and a toroidal lens 311.
The buffer memory 321 stores print data for one line for each of the light emission sources 301 and 302, and the print data corresponding to each deflection reflection surface of the polygon mirror 307 is read by the control of the writing control unit 322. The semiconductor lasers 301 and 302 are driven by the semiconductor laser driving unit 323 to simultaneously scan the photoconductor 312 line by line, and optical recording is performed line by line.

At this time, the following expression is satisfied.
12.7 <(D × β ₀ × m ₀ × dpi) / (2 × NA) <38.1 (1)
Here, β ₀ = (β ₊ -β ₋ ) / (n−1)
β ₊ : Of the two beams that have passed through the coupling lens, of the two beams having the largest difference in the tilt angle of the principal ray in the sub-scanning direction, the principal beam of the beam positioned more positive in the sub-scanning direction Ray tilt amount: Unit is rad (radian)
β ₋ : Of the two beams that have passed through the coupling lens, the main beam of the two beams that have the largest difference in the tilt angle of the principal ray in the sub-scanning direction and that is positioned more negative in the sub-scanning direction. Ray tilt amount: Unit is rad (radian)
D: Aperture diameter in the main scanning direction NA: Effective NA (numerical aperture) for D
m ₀ : Sub-scanning lateral magnification of the entire system dpi: Number of dots per inch n: Number of pairs of light source and coupling lens

  The above formula represents the relationship between the sub-scanning direction light source side pitch of a plurality of beams and the scanning line pitch in the sub-scanning direction that forms an image on the surface to be scanned. An abnormal image is generated and a good image cannot be obtained.

The above expression (1) is an expression that defines an appropriate value of the sub-scanning lateral magnification of the entire scanning optical system, and it is desirable that m ₀ satisfies the following expression.
1 ≦ m ₀ ≦ 15 (2)
When m ₀ is smaller than 1, the optical element forming the scanning lens becomes large and a light amount loss occurs. When m ₀ is larger than 15, the beam flux incident on the optical element forming the scanning lens becomes large, so that the wavefront aberration is deteriorated and the beam spot diameter is likely to be thickened.

In the multi-beam scanning optical system, it is desirable to define the inclination of the light beam emitted from the coupling lenses 303 and 304 within the main scanning section, and therefore it is desirable to satisfy the following equation.
0 <θ ₀ ≦ (10/180) × π (3)
Here, θ ₀ = θ ₊ −θ ₋
θ ₀ : Opening angle in the main scanning direction of a plurality of beams passing through the coupling lens: unit is deg (degrees)
θ ₊ : The principal ray tilt amount of a beam positioned more positive in the main scanning direction among the two beams having the largest difference in tilt angle in the main scanning direction among the plurality of beams passing through the coupling lens : Unit is deg (degrees)
θ ₋ : The principal ray tilt amount of the beam positioned more negative in the main scanning direction among the two beams having the largest difference in tilt angle in the main scanning direction among the plurality of beams passing through the coupling lens. : Unit is deg (degrees)
If θ ₀ exceeds the upper limit, the curvature of field on the scanned surface 312 deteriorates due to the sag of the deflection reflection point of the polygon scanner 307.

In the multi-beam scanning optical system that satisfies the above expression (3), it is desirable to satisfy the following expression in order to keep the scanning positions in the main scanning direction and the sub-scanning direction appropriate.
0 <| β ₀ × θ ₀ | <0.00002 (4)
If the range of the above expression (4) is not satisfied, the beam pitch on the scanned surface 312 will not be stable, the resolution at the time of adjustment will be low, and high image quality will not be obtained.

In a multi-beam scanning optical system that satisfies the expression (1), it is preferable that the following expression is satisfied.
0.3 <(D × β ₀ × m ₀ ) / (2 × NA × W) <1.5 (5)
Here, W: 1 / e ² beam spot diameter in the sub-scanning direction on the surface to be scanned 312.
In the above formula (5), if it is smaller than 0.3, the overlapping of adjacent dots is too large, and the resolution and gradation are deteriorated. If it is larger than 1.5, a solid image cannot be reproduced.

In the multi-beam scanning optical system satisfying the expression (1), the relationship between the sub-scanning lateral magnification m ₁ by the optical system before the polygon mirror 307 and the sub-scanning lateral magnification m ₂ by the optical system after the polygon mirror 307 is as follows. It is desirable to satisfy the following formula.
2 <m ₁ ² × m ₂ <85 (6)
If the lower limit of the above expression (6) is exceeded, the outer dimension of the scanning lens increases, and if the upper limit is exceeded, the fluctuation of the beam pitch on the scanned surface 312 increases.

Next, another embodiment will be described. This embodiment is characterized in that the following equation is satisfied in a multi-beam scanning optical system comprising a plurality of light sources and a number of coupling lenses smaller than the number of light sources.
12.7 <(D × β ₀ × m ₀ × dpi) / (2 × NA) <38.1 (7)
Here, β ₀ (rad) = (β ₊ −β ₋ ) / (n−1)
D: Aperture diameter in the main scanning direction NA: Effective NA (numerical aperture) for D
m ₀ : Sub-scanning lateral magnification of the entire system n: Indicates the number of pairs of light source and coupling lens.
The above formula (7) is a formula that expresses the relationship between the sub-scanning direction light source side pitch of a plurality of beams and the scanning line pitch in the sub-scanning direction that forms an image on the surface to be scanned. An abnormal image such as density unevenness is generated, and a good image cannot be obtained.

In a multi-beam scanning optical system that satisfies the above equation (7), it is desirable to define an appropriate value for the sub-scanning lateral magnification of the entire system, and for this reason, m ₀ desirably satisfies the following equation.
0.5 ≦ m ₀ ≦ 15 (8)
When m ₀ is smaller than 0.5, the optical element forming the scanning lens becomes large, and a light amount loss occurs. When m ₀ is larger than 15, the beam flux incident on the optical element forming the scanning lens becomes large, so that the wavefront aberration is deteriorated and the beam spot diameter is likely to be thickened.

Next, still another embodiment will be described. This embodiment is characterized in that the following equation is satisfied in a multi-beam scanning optical system having a plurality of light sources.
0.3 <(D × β ₀ × m ₀ ) / (2 × NA × W) <1.5 (9)
here,
β ₀ = (β ₊ -β ₋ ) / (n−1)
D: Aperture diameter in the main scanning direction NA: Effective NA (numerical aperture) for D
m ₀ : Sub-scanning lateral magnification of the entire system n: Number of pairs of light source and coupling lens W: Indicates the 1 / e ² beam spot diameter in the sub-scanning direction on the surface to be scanned.
In the above equation (9), if it is smaller than 0.3, the overlapping of adjacent dots is too large, resulting in degradation of resolution and gradation, and if it is larger than 1.5, a solid image cannot be reproduced.

  An image forming apparatus can be configured using the multi-beam scanning optical system described above. That is, it is configured such that a latent image is formed on the surface of an image carrier made of a photosensitive member by optical scanning using the multi-beam scanning optical system, and the latent image is visualized to obtain an image. This image forming apparatus obtains an image by executing a series of electrophotographic processes such as charging, exposure, development, transfer, fixing, cleaning, and charge removal on the surface of the image carrier.

  As a light source unit for forming a plurality of beams, as shown in FIG. 3, n = 2 semiconductor laser arrays 201 in which two light emitting sources are monolithically arranged at an interval ds = 25 μm are used. A configuration in which the axis C is symmetrically arranged in the sub-scanning direction is also conceivable. According to this configuration, as shown in FIG. 7, if the semiconductor laser array 201 is rotated about the optical axis C of the collimator lens 202, the light spot interval in the sub-scanning corresponding direction on the surface to be scanned is adjusted. can do.

  FIG. 5 shows a configuration example of a light source unit using the light source unit configured as described above. In FIG. 5, semiconductor laser arrays 403 and 404 are each fitted with a fitting hole (not shown) formed on the back side of a base member 405 inclined by a predetermined angle (a minute angle of about 1.5 ° in the example shown) in the main scanning direction. Respectively) are fitted with cylindrical heat sinks 403-1 and 404-1 individually. The protrusions 406-1 and 407-1 of the holding members 406 and 407 are aligned with the cut-out portions of the heat sink parts 403-1 and 404-1, and the arrangement direction of the light emitting sources is adjusted. It is fixed to.

Further, the collimating lenses 408 and 409 are respectively arranged along the semicircular mounting guide surfaces 405-4 and 405-5 of the base member 405, the optical axis direction is adjusted, and the light emitting point is adjusted. The emitted divergent beam is positioned and bonded so as to become a parallel light beam.
In the embodiment shown in FIG. 5, since the light beams from the semiconductor laser arrays 403 and 404 are set so as to intersect within the main scanning plane as described above, the fitting hole and the semicircular shape are formed along the light beams. The mounting guide surfaces 405-4 and 405-5 are inclined.
The base member 405 has a cylindrical engagement portion 405-3 integrally formed in a circular table shape and is engaged with the holder member 410, and the screw 413 that penetrates the through holes 410-2 and 410-3 of the holder member 410. Are fixed to the holder member 410 by screwing them into the screw holes 405-6 and 405-7 of the base member 405, thereby constituting a light source unit.

The cylindrical portion 410-1 of the holder member 410 is fitted into the reference hole 411-1 provided in the mounting wall 411 of the optical housing, the spring 611 is inserted from the front side, and the stopper member 612 is engaged with the cylindrical protrusion 410-3. By combining, the holder member 410 is held in close contact with the back side of the mounting wall 411, and the above-described light source unit is mounted on the mounting wall 411 of the optical housing. At this time, one end of the spring 611 is hooked on the protrusion 411-2 of the mounting wall 411, thereby generating a rotational force with the center of the cylindrical portion as the rotation axis. The entire unit can be rotated around the optical axis θ by the adjusting screw 613 provided to lock the rotational force. As shown in FIG. It can be adjusted so as to be arranged alternately by shifting.
The aperture 415 is provided with a slit corresponding to each semiconductor laser array, and is attached to the optical housing to define the emission diameter of the light beam.

  FIG. 6 shows another embodiment of the light source unit. In this embodiment, light beams from two semiconductor laser arrays are combined using beam combining means. In FIG. 6, the semiconductor laser array and the collimating lens are supported by the base members 601 and 602 one by one, as in the embodiment shown in FIG. 5, and constitute the first and second light source sections. The first base member 601 and the second base member 602 are fixed with screws by engaging cylindrical engagement portions in holes 607-1 and 607-2 provided in a common flange member 607. An adjustment screw 606 is screwed onto the second base member 602. By adjusting the protruding amount of the adjustment screw 606 from the back side, both arms 602-1 are twisted to hold the semiconductor laser array and the collimating lens. Only the portion can be inclined in the sub-scanning direction β. As a result, the arrangement of the beam spots can be shifted by one line and adjusted so as to have the arrangement as shown in FIG.

The prism 608 composed of a parallelogram prism portion and a triangular prism portion reflects each beam of the second light source unit on the inclined surface 608-1, reflects on the beam splitter surface 608-2, and directly passes through the first light source. Injected close to each beam of the part. A plurality of adjacent beams are deflected and scanned at a time by a polygon mirror, and each beam spot forms an image on the image carrier.
The aperture 615 is similarly supported on the optical housing. In the illustrated embodiment, since the light beams from the respective semiconductor laser arrays are substantially overlapped, a common slit is provided.

  The flange member 607 is held by the holder member 609, and the cylindrical portion 609-1 of the holder member 609 is fitted into the reference hole 610-1 provided in the mounting wall 610 in the optical housing as in the embodiment shown in FIG. In addition, by rotating the entire unit, the inclination of the array of each beam spot can be corrected.

The dot position deviation of the plurality of light beams in the sub-scanning corresponding direction on the surface to be scanned can be reduced by the optical arrangement examples shown in FIGS. 8B, 8C, and 8D.
FIG. 8B shows a configuration of the optical element group in a multi-beam scanning apparatus in which an optical element group for forming images of beams emitted from a plurality of laser light sources on the corresponding image carriers is provided for each beam. A prism 7 that can be driven in the sub-scanning direction is disposed between the coupling lens 2 and the optical deflector 5 including a polygon mirror. By driving the prism 7 in the sub-scanning corresponding direction, the position of the light beam incident on the optical deflector 5 in the sub-scanning corresponding direction and the angle of the light beam are changed, and the sub-scanning corresponding direction on the surface to be scanned is changed. Dot position shift can be reduced.

  FIG. 8C shows a multi-beam scanning optical system in which an optical element group for forming images of beams emitted from a plurality of laser light sources on corresponding image carriers is provided for each beam. A prism 7 is disposed between the coupling lens 2 and the optical deflector 5 to be configured. The prism 7 is rotatable about the center of the incident light beam as a rotation axis. By rotating this prism 7, the position and angle of the light beam incident on the deflector 5 in the sub-scanning corresponding direction are changed, and the dot position deviation in the sub-scanning corresponding direction on the surface to be scanned is reduced. Can do.

  FIG. 8D shows a multi-beam scanning optical system in which an optical element group for forming beams emitted from a plurality of laser light sources on a corresponding image carrier is provided for each beam. Between the coupling lens 2 and the optical deflector 5 that constitutes, a prism 7 that can be tilted and rotated in the sub-scanning corresponding direction is disposed. By rotating the prism 7, the position of the light beam incident on the optical deflector 7 in the sub-scanning direction and the angle of the light beam are changed, and the dot position shift in the sub-scanning direction on the surface to be scanned is reduced. be able to.

  Each of the driving methods of the prism 7 shown in FIGS. 8B, 8C, and 8D may be used singly, or the same effect can be obtained by using any one of them in combination.

  The multi-beam scanning optical system having the beam pitch adjusting means in the sub-scanning direction shown in FIGS. 8B, 8C, and 8D can also be applied to a copying machine, a printer, and other image forming apparatuses. FIG. 11 shows an example of an image forming apparatus to which the multi-beam scanning optical system according to the present invention can be applied. The example shown in FIG. 11 is a tandem full-color image forming apparatus equipped with a multi-beam scanning optical system. Four photosensitive drums 7 forming an image carrier are arranged in parallel to correspond to four colors, and the scanning optical system is composed of two polygon mirrors that are rotated together by a common axis. And four scanning optical systems arranged symmetrically, two on each side with the optical deflector 5 in between. Reference numeral 8 denotes an optical element constituting a part of the scanning optical system.

  Various units for executing a series of electrophotographic processes are arranged around each photosensitive drum 7. FIG. 11 shows the above-described scanning optical system for performing an exposure process and exposure with the scanning optical system. Thus, only the developing unit 20 for developing the electrostatic latent image formed on the surface of the photosensitive drum 7 is described. The electrostatic latent images on the respective photosensitive drums 7 are developed with magenta, cyan, yellow, and black developers (toners), and the images of these colors are aligned with the transfer paper conveyed by the conveyance roller 21. As a result, the images are superimposed and transferred to form a full-color image on the transfer paper. The image on the transfer paper is heat-fixed by a fixing unit to obtain a hard copy.

1 is a perspective view showing an embodiment of a multi-beam scanning optical system according to the present invention. It is an optical arrangement | positioning figure which shows the surface of the sub scanning corresponding | compatible direction of the said embodiment. It is a perspective view which shows the example of the light source part which can be used for the said embodiment. It is a front view which shows typically the light spot position on the to-be-scanned surface by a multi-beam scanning optical system, and the mode of the correction. It is a disassembled perspective view which shows the specific structural example of the light source part applicable to this invention. It is a disassembled perspective view which shows another specific structural example of the light source part applicable to this invention. It is a perspective view which shows the mode of the subscanning corresponding | compatible light spot space | interval adjustment on the to-be-scanned surface using the light source part shown in FIG. FIG. 2 is an optical arrangement diagram showing various configuration examples from a light source to an optical deflector in a scanning optical system, where (a) shows a conventional example, and (b) shows a sub-scanning direction between a coupling lens and an optical deflector. (C) shows an example in which a movable prism is arranged, (c) shows an example in which a prism that can rotate with an incident light beam as a rotation axis is arranged between a coupling lens and an optical deflector, and (d) shows a coupling. An example is shown in which a prism that can be tilted and rotated in the sub-scanning corresponding direction is disposed between the lens and the optical deflector. It is an optical arrangement diagram showing an example of a generally known multi-beam scanning optical system. FIG. 3 is an optical layout diagram when the multi-beam scanning optical system is viewed from the sub-scanning corresponding direction. 1 is a front view schematically showing an example of an image forming apparatus using a multi-beam scanning optical system. This shows the state of light dots in the sub-scanning corresponding direction on the surface to be scanned by the multi-beam scanning optical system. (A) shows a case where no positional deviation occurs, and (b) shows a case where the positional deviation is corrected. FIG.

Explanation of symbols

Reference Signs List 301 light source 302 light source 303 coupling lens 304 coupling lens 307 optical deflector 310 scanning lens 311 scanning lens 312 surface to be scanned

Claims (4)

In a multi-beam scanning device in which an optical element group for forming images emitted from a plurality of laser light sources on a corresponding image carrier is provided for each beam.
An optical scanning device, wherein a prism is disposed between a coupling lens and an optical deflector constituting the optical element group, and the prism is movable in a sub-scanning corresponding direction. In a multi-beam scanning device in which an optical element group for forming images emitted from a plurality of laser light sources on a corresponding image carrier is provided for each beam.
A multi-beam scanning device, wherein a prism is disposed between a coupling lens constituting the optical element group and an optical deflector, and the prism is rotatable about an incident light beam as a rotation axis. In a multi-beam scanning device in which an optical element group for forming images emitted from a plurality of laser light sources on a corresponding image carrier is provided for each beam.
A multi-beam scanning device, wherein a prism is disposed between a coupling lens constituting the optical element group and an optical deflector, and the prism is tiltable and rotatable in a sub-scanning corresponding direction. An image forming apparatus that forms a latent image by performing optical scanning with an optical scanning device on a surface to be scanned of an image carrier, and obtains an image by visualizing the latent image,
4. An image forming apparatus using the multi-beam scanning device according to claim 1 as an optical scanning device that performs optical scanning on a surface to be scanned of an image carrier.

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