JP2007072156A - Optical scanner and image forming system using same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To perform light beam scanning having high scanning efficiency on a plurality of scanning lines in an optical scanner and an image forming system using the optical scanner. <P>SOLUTION: The optical scanner comprises: a rocking deflector 7 having a rocking mirror in which mirror faces 11A and 11B are formed on both faces; laser light sources 2A and 2B which make laser beams 30A and 30B incident on the mirror faces 11A and 11B, respectively; polarized light control means 5A and 5B which selectively switch the optical characteristics of the laser beams 30A and 30B emitted from the laser light sources; and polarized light beam splitters 9A and 9B which divide the optical paths of the laser beams 30A and 30B deflected with the mirror faces 11A and 11B according to the optical characteristics. The optical paths are switched by switching the optical characteristics of the laser beams 30A and 30B according to the rocking directions of the mirror faces 11A and 11B. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an optical scanning device and an image forming system using the same.

2. Description of the Related Art Conventionally, for example, in an image forming system such as a copying machine or a laser printer, based on color-separated image signals, a plurality of scanning beams are modulated to perform exposure scanning, and a plurality of color images are formed and superimposed. Thus, there is known one that forms a full-color image.
The optical scanning device that forms a plurality of scanning beams is equipped with a number of beam light sources corresponding to the scanning beams, and after deflecting them by entering a common deflector, the optical path is bent by a mirror or the like and scanned at different positions. What you can do is known.
For example, in Patent Document 1, two laser beams are incident on the front and back surfaces of one galvanometer mirror, respectively, are deflected and scanned, and after two laser beams are incident on one scanning lens in parallel, the optical path is changed by the mirror. A multi-beam scanning optical device is described that bends and scans four photosensitive drums.
Japanese Patent Laid-Open No. 10-148775 (FIG. 1)

However, the conventional optical scanning apparatus as described above and the image forming system using the same have the following problems.
In the technique described in Patent Document 1, when using reciprocating oscillating scanning of a galvanometer mirror, an image forming system that needs to form scanning lines in parallel can use only one oscillating direction. There is a problem of being bad.
In addition, two laser beams are incident on one scanning lens in parallel, and then one of them is deflected by a mirror and separated into different optical paths, so that the interval in the sub-scanning direction of the laser beam is separated to such an extent that it can be separated by the mirror. There is a need. Therefore, there is a problem that the scanning lens becomes large in the sub-scanning direction and the manufacturing cost becomes expensive. In addition, since the laser beam transmitted through the scanning lens becomes off-axis light, there is a problem that aberrations are deteriorated.

  The present invention has been made in view of the above problems, and an optical scanning apparatus capable of performing light beam scanning with high scanning efficiency for performing light beam scanning on a plurality of scanning lines, and image formation using the same. The purpose is to provide a system.

In order to solve the above problems, an optical scanning device of the present invention includes a swing deflector having a swing mirror,
An optical device that selectively switches the optical characteristics of the light beam incident on the reflecting surface of the oscillating mirror and the optical characteristics of the light beam incident on the reflecting surface of the oscillating mirror according to the oscillating direction of the oscillating mirror. The apparatus includes a characteristic switching unit and an optical path branching unit that branches the optical path of the light beam deflected by the oscillating mirror according to the optical characteristic of the light beam.
According to this invention, a state in which the optical characteristic of the light beam from the beam light source is selectively switched by the optical characteristic switching means according to the swing direction with respect to the reflection surface of the swing mirror of the swing deflector. Is incident and scanned by deflection. The optical path of the light beam deflected by the oscillating mirror is switched by the optical path branching unit according to the optical characteristics. Therefore, every time the swing direction is switched, one light beam from the beam light source is scanned on a different optical path to alternately form two scanning lines per one light beam. Therefore, two light beam scans per one beam light source can be performed in the reciprocating direction of oscillation.

In the present invention, it is preferable that the oscillating mirror has a reflecting surface on the front and back, and that the beam light source is provided with at least one light beam incident on the reflecting surface on the front and back.
In this case, since the oscillating mirror can also be used in each scan, the number of parts can be reduced.

The image forming system of the present invention is configured to perform exposure scanning using the optical scanning device of the present invention to form an image.
According to this invention, since the optical scanning device of the present invention is used, the same effects as the optical scanning device of the present invention are provided.

  According to the optical scanning device and the image forming system using the optical scanning device of the present invention, each time the swinging direction of the swing deflector is switched, the light beam from the beam light source is scanned on a different optical path. Since the two-beam light beam scanning can be performed in the reciprocating direction of oscillation, the light beam scanning with high scanning efficiency can be performed.

  Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. In all the drawings, even if the embodiments are different, the same or corresponding members are denoted by the same reference numerals, and common description is omitted.

[First Embodiment]
An optical scanning device according to a first embodiment of the present invention will be described together with an image forming system using the same.
1 and 2 are a schematic front explanatory view and a plan explanatory view, respectively, for explaining the schematic configuration of the optical scanning device according to the first embodiment of the present invention. FIG. 3 is a schematic perspective view for explaining a schematic optical path of the optical scanning device according to the first embodiment of the present invention. FIGS. 4A and 4B are a plane explanatory view and a cross-sectional view taken along line AA for explaining the swing deflector used in the optical scanning device according to the first embodiment of the present invention. FIG. 5 is a functional block diagram for explaining the control unit of the optical scanning device and the image forming system according to the first embodiment of the present invention.

  As shown in FIGS. 1 and 2, the optical scanning device 1 of the present embodiment is a device for forming four scanning lines arranged substantially parallel to each other using two laser light sources 2A and 2B. Hereinafter, an example in which the image forming system 100 is configured in combination with the image forming apparatus 50 will be described. The image forming system 100 can be suitably used for, for example, a laser printer or a digital copying machine that forms a four-color full-color image.

As shown in FIGS. 1 and 2, the schematic configuration of the optical scanning device 1 includes laser light sources 2A and 2B, collimating lenses 3A and 3B, apertures 4A and 4B, polarization control means 5A and 5B, a swing deflector 7, and a scanning lens. 8A, 8B, polarizing beam splitters 9A, 9B, mirrors 10A, 10B, 23A, 23B, 24A, 24B, folding mirrors 14A, 14B, synchronization lenses 18A, 18B, synchronization detection sensors 19A, 19B, folding mirrors 15A, 15B, synchronization It consists of lenses 21A and 21B, synchronization detection sensors 22A and 22B, and a controller 300 (see FIG. 5) for performing these controls.
Here, the member with the subscript B is the same as the member with the subscript A unless otherwise specified, and is arranged at a rotationally symmetric position rotated by 180 ° with respect to the swing center of the swing deflector 7. Only the differences are different. Also, subscripts A and B are attached to the functional blocks and signals shown in FIG. 5 according to the corresponding members.

The laser light source 2A (2B) generates laser light 30A (30B) having an appropriate wavelength as divergent light, and is composed of, for example, a semiconductor laser having a wavelength of 780 nm. For this reason, the laser light source 2A (2B) is linearly polarized light.
The laser light source 2A (2B) can modulate the laser light 30A (30B) by a laser drive signal 340A (340B) sent from the control unit 300 described later.

The collimating lens 3A (3B) is an optical element that condenses the laser light 30A (30B) to make it substantially parallel light.
The aperture 4A (4B) is used to change the laser beam 30A (30B), which has been made substantially parallel by the collimating lens 3A (3B), to an appropriate imaging spot diameter in the main scanning direction and the sub-scanning direction on the image plane. A member that shapes the beam shape of the laser beam 30A (30B) and that has an oval, rectangular, or oval opening having an appropriate size on the light shielding plate can be employed. . The size of the aperture is appropriately set according to the size of the spot diameter required on the image plane and the optical characteristics of the scanning lens 8A (8B) described later.

  In the following, unless there is a risk of misunderstanding, the main scanning direction and the sub-scanning direction are used in a broad sense, that is, not only in the direction at the scanning position but also when referring to two directions of a cross section orthogonal to each optical path. I will decide. That is, when advancing along the optical path and reaching the image plane, directions corresponding to the main scanning direction and the sub scanning direction on the image plane are referred to as a main scanning direction and a sub scanning direction, respectively, at any position on the optical path.

The polarization control means 5A (5B) selectively switches the polarization direction of the laser light 30A (30B) emitted from the aperture 4A (4B) and shaped in beam shape between two linearly polarized light beams orthogonal to each other. It is.
In the present embodiment, a half-wave plate that is held on the optical path of the laser beam 30A (30B) so that the angle of the main shaft can be varied by a motor (not shown) or the like is employed. The angle of the principal axis of the half-wave plate is varied so that the polarization direction of the transmitted light can be switched between two polarization directions orthogonal to each other.
For example, as a configuration in which s-polarized light and p-polarized light can be switched with respect to a mirror surface 11A (11B) of the swing deflector 7 described later, as shown in FIG. It is possible to adopt a configuration in which the s-polarization forming unit 5s and the p-polarization forming unit 5p are sequentially formed alternately in a region divided into four in the direction and rotated by 90 ° in the direction of the arrow shown in the drawing.
The switching operation of the polarization control means 5A (5B) is performed according to an optical characteristic switching signal 330 sent from an optical characteristic switching means 305A (305B) described later.

The oscillating deflector 7 includes an oscillating mirror having reflection surfaces formed on the front and back sides. For example, a galvano mirror having a reflection surface formed on the front and back surfaces and a MEMS resonance manufactured by MEMS (Micro Electro Mechanical Systems) technology. A mirror or the like can be used.
In the present embodiment, since a MEMS resonant mirror as shown in FIG. 4 is employed, the configuration in this case will be described.

The schematic configuration of the oscillating deflector 7 is such that a plate-like deflector body 11 formed by the MEMS technology is opposed to the deflector body 11 with a magnet portion that forms a constant magnetic field penetrating the deflector body 11. 12 and 13.
The deflector body 11 includes a support frame portion 11d having a rectangular frame shape when viewed from the front, and a beam-like torsion bar portion 11c extending on the same straight line from the two opposite sides of the support frame portion 11d to the inside of the support frame portion 11d. , 11c and a torsion bar portion 11c, 11c and a rectangular plate-like swinging portion 11b in which the center portions of the two sides are held.
On the front and back surfaces of the oscillating portion 11b, mirror surfaces 11A and 11B are formed in which a reflective film coating is applied to a rectangular region at the center by, for example, metal vapor deposition.
A substantially rectangular drive coil portion 11e surrounding the outer peripheries of the mirror surfaces 11A and 11B is formed on or between any surface of the oscillating portion 11b, and the conductive wire at the end thereof is passed through the torsion bar portion 11c. Thus, the coil current can be supplied to the drive coil portion 11e.

According to such a configuration, when a current is passed through the drive coil portion 11e, the drive coil portion 11e of the swing portion 11b receives Lorentz force from the static magnetic field formed by the magnet portions 12 and 13, and the swing portion 11b It rotates around the torsion bar portion 11c. Then, the torsion bar portion 11c is distorted to generate a torsion torque, and a restoring force acts on the swinging portion 11b. Therefore, for example, switching is performed by turning ON / OFF a current flowing through the drive coil unit 11e at a predetermined frequency, or an alternating current of a predetermined frequency is flowed to configure the swing unit 11b and the torsion bar unit 11c. This causes the torsional vibration system to resonate, and the swinging portion 11b swings and vibrates around the swing center axis where the torsion bar portion 11c extends at a predetermined frequency.
Since the oscillating portion 11b can be formed with a small size with low inertia by MEMS technology, the oscillating deflector 7 can perform high-speed and stable oscillating oscillation.

As shown in FIG. 2, the oscillating deflector 7 has a mirror surface 11A (11B) obliquely arranged with respect to the laser beam 30A (30B) emitted from the polarization control means 5A (5B), and the mirror surface 11A. (11B) is arranged so that the oscillation central axis is perpendicular to the paper surface.
For this reason, the laser beam 30A (30B) incident on the mirror surface 11A (11B) is deflected according to the inclination angle of the mirror surface 11A (11B) around the oscillation center axis. That is, the laser beam 30 </ b> A (30 </ b> B) is reciprocally scanned in a certain scanning angle range by the swing deflector 7.

The scanning lens 8A (8B) is a scanning optical system for forming an image of the laser beam 30A (30B) deflected and scanned by the swing deflector 7 on a predetermined image plane and correcting the scanning speed on the image plane. .
In the present embodiment, an arc sine lens whose distortion characteristic has an arc sine characteristic is used as the scanning lens 8A (8B). Since the tilt angle of the mirror surface 11A (11B) is a single vibration, that is, a sine vibration, by employing such an arc sine lens, it is possible to realize constant speed scanning on the image plane.

  Note that the scanning lens 8A (8B) may use, for example, an fθ lens having fθ characteristics as a signal obtained by appropriately clock-correcting the laser drive signal 340A (340B). In this case, a general-purpose fθ lens of an optical scanning device using a polygon scanner can be shared, which is convenient.

The polarization beam splitter 9A (9B) branches the laser light 30A (30B) into transmitted light 31A (31B) and reflected light 32A (32B) over the range of the scanning angle of view of the effective image area according to the polarization state. It is a member to do.
In the present embodiment, a polarized beam that transmits approximately 100% of the s-polarized light to the mirror surface 11A (11B) and reflects approximately 100% of the p-polarized light to the mirror surface 11A (11B). It is composed of parallel plates with splitter coating.
Then, the reflected light 32A (32B) is arranged so as to be deflected downward in FIG. 1 across the scanning plane in a direction perpendicular to the optical axis of the scanning lens 8A (8B). 1 is a schematic diagram, the laser beam 30A is drawn as a solid line and a broken line, but the laser beam 30A (30B) until it is branched by the polarization beam splitter 9A (9B) has only a different polarization state. Thus, the light travels along the same optical path.
Although the polarization direction of the laser beam 30A (30B) with respect to the polarization beam splitter 9A (9B) varies depending on the scanning angle of view, only light in two polarization states whose polarization directions are orthogonal to each other are incident at any scanning position. A polarizing beam splitter surface such as can be formed.

The mirror 10A (10B) is a folding mirror that bends the transmitted light 31A (31B) transmitted through the polarization beam splitter 9A vertically downward in FIG.
The mirrors 23A (23B) and 24A (24B) are folding mirrors that fold the reflected light 32A (32B) reflected by the polarization beam splitter 9A (9B) and bend it vertically downward in FIG.
In the case of this embodiment, each folding mirror has the same optical path length from the scanning lens 8A (8B) to each image plane, so that the scanning lines on each image plane become parallel scanning line images during image formation. They are arranged slightly inclined in the scanning direction in the opposite directions. Therefore, the scanning lines recorded on the photosensitive drums 51Y (51K) and 51M (51C) described later can be made parallel. Note that an adjustment mechanism for adjusting the position of each folding mirror with reference to the output image may be provided for such adjustment of the scanning line.

As described above, the optical scanning device 1 according to the present embodiment has a configuration in which at least one of the optical paths branched by the optical path branching unit includes the mirror member that corrects the inclination of the scanning line in the optical path.
Therefore, when the scanning medium is sub-scanned, it is possible to draw a parallel scanning line on the scanned medium by correcting the inclination of the scanning line according to the swing direction.

The folding mirrors 14A (14B) and 15A (15B) are provided with a laser beam in an optical path between the scanning lens 8A (8B) and the polarization beam splitter 9A (9B) in order to acquire synchronous detection light at a predetermined image height. 30A (30B) is a member that folds back light outside the effective image area at both ends of the scanning area.
As shown in FIG. 2, the folding mirror 14A (14B) is arranged so as to obtain synchronization detection light at the image height on the side where the laser light source 2A (2B) is arranged, and the folding mirror 15A (15B) It arrange | positions so that the synchronous detection light of the image height of the other side can be acquired. Each arrangement position is symmetrical with respect to the optical axis.
In the following description, it is assumed that the image height on the side where the folding mirror 14A (14B) is arranged is positive and the image height on the side where the folding mirror 15A (15B) is arranged is negative.

  The synchronization lens 18A (18B) is for adjusting the imaging position and spot diameter of the laser beam 30A (30B) deflected by the folding mirror 14A so as to be optimal on the light receiving surface of the synchronization detection sensor 19A (19B). Is. For example, it is provided in order to adjust the imaging position in accordance with the layout in which the synchronization detection sensor 19A (19B) is arranged, or to make the synchronization accuracy better by making it a long and narrow spot covering the light receiving surface.

The synchronization detection sensor 19A (19B) detects that the laser beam 30A (30B) transmitted through the synchronization lens 18A (18B) has reached a predetermined positive image height, and detects the synchronization detection signal 310A (310B) (see FIG. 5). ) To generate synchronization detection means. For example, a PIN photodiode can be employed.
The predetermined positive image height is set to an image height that is in the non-image region and is smaller than the maximum image height on the positive side serving as a deflection limit.

In addition, the synchronization lens 21A (21B) and the synchronization detection sensor 22A (22B) are configured with the same members in the same positional relationship as the synchronization lens 18A (18B) and the synchronization detection sensor 19A (19B) with the folding mirror 15A (15B). It is arranged in the deflected optical path.
The synchronization detection sensor 22A (22B) is synchronization detection means for detecting that the laser beam 30A (30B) has reached a predetermined negative image height and generating a synchronization detection signal 320A (320B) (see FIG. 5). .
The predetermined negative image height is set to an image height that is smaller than the maximum image height on the negative side that is a deflection limit in the non-image region.

  As shown in FIG. 5, the schematic configuration of the control unit 300 includes horizontal synchronization control means 301A and 301B, laser drive signal generation means 304A and 304B, image processing means 303, swing deflector control means 302, and optical characteristic switching means. 305.

The horizontal synchronization control unit 301A (301B) synchronizes the writing position by delaying the synchronization detection signals 310A (310B) and 320A (320B) sent from the synchronization detection sensors 19A (19B) and 22A (22B) for a predetermined time. A writing start signal 350A (350B) is generated, and a scanning direction determination signal 351A (351B) for determining the scanning direction is generated and sent to the laser drive signal generation means 304A (304B).
The writing start signal 350A (350B) can be set with a different delay time depending on whether the original signal is the synchronization detection signal 310A (310B) or the synchronization detection signal 320A (320B). It can be adjusted according to.
Further, the scanning direction determination signal 351A (351B) is, for example, a signal having a binary level. When the synchronization detection signal 310A (310B) is received, scanning (from the positive image height toward the negative image height) For example, when the signal level is set to high and the synchronization detection signal 320A (320B) is received, scanning from the negative image height to the positive image height (hereinafter, referred to as forward scan). The signal level is set to low.

The laser drive signal generation means 304A (304B) performs selection of an image signal and conversion into a laser drive signal 340A (340B) in accordance with the scanning direction determination signal 351A (351B), and a writing start signal 350A (350B). Accordingly, the laser drive signal 340A (340B) is sent to the laser light source 2A (2B).
The conversion means for converting the image signal into the laser drive signal 340A (340B) includes conversion for inverting the data order according to at least the forward scanning or the backward scanning. In this embodiment, since the forward scan (return scan in the configuration of suffix B) is a normal scanning direction from the left to the right of the image, the data of the image data during the backward scan (forward scan in the configuration of suffix B). The order is reversed.
Further, lighting control of the laser light source 2A (2B) in the non-image area is also performed based on the clock information of the swing deflector control means 302. In this lighting control, the laser light source 2A (2B) is completely turned on at the scanning start timing of the forward scanning and the backward scanning based on the clock information of the swing deflector control means 302.

  The image processing unit 303 outputs image signals 360Y, 360M, 360C, and 360K, which are color-separated into four colors for forming a full-color image, for example, yellow, magenta, cyan, and black, based on externally input information. Is to be generated.

The oscillating deflector control means 302 supplies a switching current or an alternating current to the oscillating deflector 7 based on a clock having a predetermined frequency, and resonates the oscillating portion 11b of the oscillating deflector 7 at a predetermined frequency. It excites oscillation vibration. This clock information also includes phase information of the current supplied to the oscillating deflector 7 so that at least the timing at which the forward scanning and the backward scanning are switched, that is, the start timing of each scanning can be acquired.
Such clock information is supplied to the optical characteristic switching unit 305 and the laser drive signal generation unit 304A (304B), and the scanning start timings of the forward scanning and the backward scanning can be acquired respectively.
This timing acquisition is performed so that the laser light 30A (30B) is not lit on the side where the scanning ends with respect to the synchronization detection sensors 19A (19B) and 22A (22B). Thereafter, it is only necessary to obtain the timing until immediately before reaching each synchronization detecting means, and it is not necessary to strictly give the timing to start scanning.

The optical characteristic switching unit 305 is a unit for switching the optical characteristic of the laser beam 30A (30B) between the forward scanning and the backward scanning based on the clock information of the swing deflector control unit 302.
In this embodiment, the rotation angle of the rotating disk of the polarization control means 5A (5B) is switched, and the s-polarization forming unit 5s and the p-polarization forming unit 5p are alternately inserted into the optical path.

  The sequence operation control means 306 starts a print operation by receiving a print start signal, and controls the sequence operations of the optical scanning device 1 and the image forming apparatus 50 in a coordinated manner. For example, control is performed to coordinate the operation of each device in synchronization with the transfer of the transfer paper. Since this detail is well known, a description thereof will be omitted.

Next, a schematic configuration of the image forming apparatus 50 will be described.
As shown in FIG. 1, the image forming apparatus 50 is disposed below the optical scanning device 1, and transmits transmitted light 31 </ b> A, reflected light 32 </ b> A, and reflected light that are scanned on substantially parallel lines by the optical scanning device 1. This is an electrophotographic tandem type apparatus that uses 32B and transmitted light 31B for exposure.
That is, the axial direction is aligned in parallel at a predetermined interval on a transfer conveyance belt 52 for conveying a transfer sheet (not shown) that is driven in the horizontal direction in the figure by the drive roller 53 and is tensioned by the tension roller 54. The photosensitive drums 51Y, 51M, 51C, 51K thus arranged are arranged.
Although not shown in the drawing, in the circumferential direction of each photosensitive drum, a charger for uniformly charging the photosensitive drum, and charged toner are attached in accordance with the potential of the electrostatic latent image formed after exposure. A developer that visualizes the electrostatic latent image, a transfer device that transfers the visualized toner image onto the transfer paper conveyed by the transfer conveying belt 52, a cleaner that removes residual toner to reuse the photosensitive drum, and the like. Known components relating to electrophotography are arranged in this order.
Developers including yellow, magenta, cyan, and black toners are arranged corresponding to the photosensitive drums 51Y, 51M, 51C, and 51K, respectively. The development method is not particularly limited, but the following description will be made assuming that a reversal development method in which the exposed portion is developed is adopted.
Although not particularly shown, a paper feeding unit for feeding the transfer paper and a fixing device for thermally fixing the toner image transferred to the transfer paper on the transfer paper are provided upstream and downstream of the transfer conveyance belt 52.

Next, the operation of the image forming system 100 will be described focusing on the operation of the optical scanning device 1. Since the operation of the image forming apparatus 50 is well known, detailed description thereof is omitted.
In the image forming system 100, the configuration of the subscript A and the configuration of the subscript B simultaneously perform substantially the same operation. Therefore, if the operation of the configuration of the subscript A is described, the operation of the configuration of the subscript B simply reads the subscript. Can be easily understood. Therefore, in the following, the operation of the subscript A configuration will be mainly described.
FIG. 6 is a schematic operation explanatory diagram for explaining deflection scanning of the optical scanning device according to the first embodiment of the present invention. FIGS. 7A and 7B are schematic explanatory diagrams for explaining the scanning line image when the inclination of the scanning line is not adjusted and when the inclination of the scanning line is adjusted, respectively.

  In the image forming system 100, when the print start signal is received, the swing deflector 7 is driven by the swing deflector control means 302, and the swing portion 11b moves around the torsion bar portion 11c that is the swing center axis at a predetermined frequency. Oscillates and oscillates.

On the other hand, based on the clock information of the swing deflector control means 302, the laser light source 2A is turned on at the timing when the swing direction of the swing vibration is switched, and the laser light 30A is generated.
As shown in FIG. 3, the laser light 30A is made into substantially parallel light by the collimating lens 3A, shaped into a beam shape by the aperture 4A, and incident on the polarization control means 5A.

Similarly, based on the clock information of the swing deflector control means 302, the swing direction of the swing portion 11b is determined by the optical characteristic switching means 305.
The optical characteristic switching unit 305 sends an optical characteristic switching signal 330 corresponding to the swing direction to the polarization control unit 5A. That is, the optical characteristic switching signal 330 rotates the polarization controller 5A at the timing when the mirror surface 11A is switched from the backward scan to the forward scan, inserts the s-polarization forming unit 5s into the optical path, and switches to the scan from the forward scan to the backward scan. Thus, the polarization control means 5A is rotated, and the control signal is such that the p-polarization forming portion 5p is inserted into the optical path.
At this time, since the optical system of the subscript A and the optical system of the subscript B are arranged point-symmetrically with respect to the oscillation center axis, the timings of the forward scanning and the backward scanning are completely coincident with each other.

Therefore, the laser light 30A emitted from the polarization control means 5A is in the s-polarized state with respect to the mirror surface 11A when the mirror surface 11A performs forward scanning, and similarly when p-polarized when performing backward scanning. It is in a state.
The laser beam 30A is deflected by the mirror surface 11A, is incident on the scanning lens 8A, and is condensed so as to have an appropriate spot diameter on the image plane, and the traveling direction of the principal ray in the scanning plane is the scanning lens. It is bent in the direction corresponding to the arc sine characteristic of 8A.

  Since the laser beam 30A that is turned on at the timing when the swinging direction is switched is in the non-image area at that time, it is reflected by the folding mirror 14A or the folding mirror 15A before being scanned into the effective image area.

Here, if the laser light 30A is turned on at the timing when the backward scanning is switched to the forward scanning, the laser light 30A enters the folding mirror 14A as s-polarized light. Then, the light is received by the synchronization detection sensor 19A via the synchronization lens 18A. Then, a synchronization detection signal 310A is generated and sent to the horizontal synchronization control means 301A.
In the horizontal synchronization control unit 301A, the writing start signal 350A is set high in response to the synchronization detection signal 310A, and the writing start signal 350A delayed by a predetermined time according to the synchronization detection signal 310A is generated as a laser drive signal. Send to means 304A.
The laser drive signal generator 304A temporarily turns off the laser light source 2A, and sends a laser drive signal 340A that modulates the laser light source 2A according to the image signal to the laser light source 2A at the timing of the writing start signal 350A.
At this time, since the scanning direction determination signal 351A is high, the image processing unit 303 reads the image signal 360Y for one line while maintaining the data order.

At the timing when the laser drive signal 340A is supplied by the writing start signal 350A, the mirror surface 11A rotates to deflect the laser light 30A toward the effective image area. That is, the laser beam 30A modulated by the laser drive signal 340A is deflected by the mirror surface 11A, and is condensed by the scanning lens 8A while the optical path of the principal ray is bent, and reaches the polarization beam splitter 9A.
Then, as shown in FIG. 1, the light is transmitted through the polarizing beam splitter 9A, deflected by the mirror 10A, and exposed by scanning the photosensitive drum 51Y in the forward direction at a constant speed.
At this time, in the image forming apparatus 50, the uniformly charged photosensitive drum 51Y has reached the exposure position, and exposure scanning for one line is performed by this forward scanning, thereby electrostatic latent for one line. An image is formed on the photosensitive drum 51Y.
The laser beam 30A is turned off when scanning for one line is completed.

Then, at the timing when the oscillating portion 11b is switched from the forward scanning to the backward scanning based on the clock information of the oscillating deflector control means 302, the laser light source 2A is turned on by the laser drive signal generating means 304A, and the laser light 30A is turned on. Is done. In this backward scan, synchronization detection is performed by the folding mirror 15A, the synchronization lens 21A, and the synchronization detection sensor 22A instead of the folding mirror 14A, the synchronization lens 18A, and the synchronization detection sensor 19A, and instead of the synchronization detection signal 310A, A synchronization detection signal 320A is sent to the horizontal synchronization control means 301A, and the same operation as described above is performed except for the following points.
That is, since the polarization control means 5A inserts the p-polarization forming unit 5p in the optical path, the laser light 30A becomes p-polarized with respect to the mirror surface 11A, and is reflected by the polarization beam splitter 9A to be mirrors 23A, 24A. And is guided onto the photosensitive drum 51M.
In addition, since the scanning direction determination signal 351A is set to low by the horizontal synchronization control unit 301A according to the synchronization detection signal 320A, the laser drive signal 340A is a signal obtained by inverting the data order of the image signal 360M.
The delay time of the writing start signal 350A is set to a timing at which the writing position of the laser drive signal 340A is aligned with the final pixel position written by the forward scanning.

  In this way, in the forward scanning, an electrostatic latent image for one line corresponding to the image signal 360Y is formed on the photosensitive drum 51Y, and in the backward scanning, the pixel position in the main scanning direction on the photosensitive drum 51M. One line of electrostatic latent images corresponding to the image signals 360M aligned with each other are formed.

At this time, in the optical scanning device 1, as shown in FIG. 6, the forward scanning line 60 and the backward scanning line 61 are continuously formed and sub-scanned on the image plane, so that the zigzag scanning line is formed on the recording medium. Is obtained. Therefore, for example, if continuous exposure is performed on one photosensitive drum and the electrostatic latent image is visualized, the forward scanning line image 62 and the backward scanning line image 63 are zigzag as shown in FIG. As a result, the pixel arrangement in the sub-scanning direction is disturbed. For this reason, in a normal image forming system, for example, exposure scanning is performed only by forward scanning.
In the present embodiment, since scanning on different photosensitive drums is performed in the forward scanning and the backward scanning, the scanning lines are parallel to each other, and the same exposure scanning is performed.
However, if the forward scanning line image 62 and the backward scanning line image 63 are developed with different color toners and overlapped, a color shift occurs due to crossing each other, so that each scanning line image is as shown in FIG. The forward scanning line image 62 and the backward scanning line image 63a that are scanned in parallel to each other are required.
In this embodiment, as shown in FIG. 1, the polarization beam splitter 9A splits the scanning light as transmitted light 31A and reflected light 32A in forward scanning and backward scanning, and mirrors 10A and 23A arranged after branching. Since the inclination of the scanning line is adjusted by adjusting the arrangement position of 24A, scanning lines parallel to each other are formed as schematically shown in FIG.

In parallel with the above operation, the same exposure scanning is performed by the configuration of the subscript B. That is, in the forward scan, an electrostatic latent image for one line corresponding to the image signal 360K is formed on the photosensitive drum 51K, and in the backward scan, the pixel positions in the main scanning direction are mutually positioned on the photosensitive drum 51C. An electrostatic latent image for one line corresponding to the combined image signal 360C is formed. These writing positions in the main scanning direction are also aligned with the writing positions of the scanning lines on the photosensitive drums 51Y and 51M having the structure of the suffix A.
However, in the configuration of the subscript B, the scanning direction is reversed with respect to the configuration of the subscript A, so that the laser drive signal generation unit 304B reverses the data order of the image signal 360K during forward scanning.

As described above, according to the optical scanning device 1 of the present embodiment, on the photosensitive drums 51Y, 51M, 51C, and 51K arranged in parallel in the image forming apparatus 50, according to the image signals 360Y, 360M, 360C, and 360K, respectively. Since the electrostatic latent image can be formed with scanning lines that are parallel and aligned in the main scanning direction, a full color image can be formed by superimposing four colors using two laser light sources 2A and 2B. The image forming system 100 to be formed can be configured.
In other words, in the conventional optical scanning device that shares the galvanometer mirror with four beams and scans two beams by one scanning lens, it is necessary to separately provide a beam light source for every four beams, which increases the number of parts. However, in the present embodiment, the two beam light sources are selectively switched according to the swinging direction and scanned on different optical paths to perform scanning of two beams per beam light source. Since the number of light sources could be halved, it has the further effect that it can be solved.

In addition, since it is possible to perform scanning at different positions for the forward scanning and the backward scanning, it is possible to use the swing deflector 7 more efficiently than when only one scanning is performed. Compared with the case where only one scanning is performed, it is possible to perform high-speed image formation.
Further, since the scanning direction for each color is constant, data inversion can be performed for each color, and data conversion is simplified, so that a simple configuration can be achieved.

  In the present embodiment, the polarization beam splitters 9A and 9B branch the light beam by utilizing the difference in polarization characteristics. Therefore, in order to branch the light beam, it is necessary to form multiple beams separated in the sub-scanning direction. There is no. For this reason, since the center of the lens can be passed in the sub-scanning direction, it is possible to prevent the imaging performance from being deteriorated by passing the light beam off the axis. Further, it is possible to reduce the thickness of the scanning lens 8A (8B) in the sub-scanning direction and prevent the apparatus from becoming large.

In the optical scanning device 1 of the present embodiment, in the optical scanning device of the present invention, the optical characteristic switching means selectively switches the light beam between two linearly polarized lights whose polarization directions are orthogonal to each other. The optical path branching means is a polarization beam splitter.
Therefore, by switching the polarization direction of the light beam emitted from one beam light source, the scanning position can be guided to two different scanning positions, and each is switched according to the swing direction of the swing deflector. 2 beam scanning can be performed. At that time, by optimizing the polarization beam splitter characteristics of the polarization beam splitter in accordance with the polarization direction of the incident light beam, the light beam can be efficiently branched while reducing the light amount loss.

Next, a modification of this embodiment will be described.
FIG. 8 is a schematic plan view for explaining a schematic configuration of an optical scanning device according to a modification of the first embodiment of the present invention.

  The optical scanning device 70 of the present modification is the same as the optical scanning device 1 of the first embodiment except that the synchronization detection sensor 22A (22B) is deleted, a folding mirror 16A (16B) is added, and the synchronization lens 21A (21B) is added. The arrangement has been changed. Hereinafter, a description will be given focusing on differences from the above embodiment.

The folding mirror 16A (16B) deflects the laser light 30A (30B) in the non-image area deflected by the folding mirror 15A (15B) toward the synchronization detection sensor 19A (19B). The synchronous lens 21A (21B) is disposed on the optical path of the folding mirror 16A (16B) and the synchronous detection sensor 19A (19B).
The optical path lengths of the laser beam 30A (30B) deflected by the folding mirror 14A (14B) and the laser beam 30A (30B) deflected by the folding mirror 15A (15B) are preferably set to be the same.

With this configuration, the synchronization detection sensor 19A (19B) can also use the synchronization detection on the side where the backward scanning is started, which is performed by the synchronization detection sensor 22A (22B) in the first embodiment.
That is, in this modification, the laser light 30A (30B) deflected by the folding mirror 15A (15B) is incident on the synchronization detection sensor 19A (19B), and the synchronization detection signal 19A is generated by the synchronization detection sensor 19A (19B). .
In this case, since the synchronization detection signals 310A (310B) and 320A (320B) sent from the synchronization detection sensor 19A (19B) cannot be distinguished as signals, for example, the clock information of the swing deflector control means 302 is used. The signal is input to the horizontal synchronization control unit 301A (see the two-dot chain line in FIG. 5), and is determined by the horizontal synchronization control unit 301A (301B).
Therefore, the writing start signal 350A (350B) and the scanning direction determination signal 351A (351B) can be transmitted from the horizontal synchronization control unit 301A (301B) as in the above embodiment.

  According to the present modification, the forward scanning and the backward scanning can be used as the synchronization detection unit, so that there is an advantage that the number of parts can be reduced.

[Second Embodiment]
An optical scanning device according to a second embodiment of the present invention will be described together with an image forming system using the same.
9 and 10 are a schematic front explanatory view and a plan explanatory view, respectively, for explaining the schematic configuration of the optical scanning device according to the second embodiment of the present invention. FIG. 11 is a functional block diagram for explaining a control unit of the optical scanning device and the image forming system according to the second embodiment of the present invention.

As shown in FIGS. 9 and 10, the optical scanning device 80 of this embodiment is a device for forming four scanning lines arranged substantially parallel to each other using two laser light sources 29A and 29B. As in the optical scanning device 1 of the first embodiment, the image forming system 200 that forms, for example, a four-color full-color image can be configured in combination with the image forming device 50.
The optical scanning device 80 deletes the polarization control means 5A, 5B of the optical scanning device 1 of the first embodiment, and laser light sources 2A, 2B, a polarizing beam splitter 9A, mirrors 10A, 10B, 23A, 23B, 24A, 24B. In place of the control unit 300, two-wavelength LDs 29A and 29B, dichroic mirrors 25A and 25B, mirrors 26A, 26B, 27A, 27B, 28A and 28B, and a control unit 400 (see FIG. 11) are provided. Hereinafter, a description will be given focusing on differences from the first embodiment.

In the two-wavelength LD 29A (29B), a two-wavelength LD element having a light emitting point close to each other is formed on one chip, and each of the laser beams having the wavelengths λ ₁ and λ ₂ is supplied by independently supplying a drive current. This is a beam light source that emits 33A (33B). Since the light emitting points are close to each other, they are substantially coaxial light.
Note that these two wavelengths of light may be emitted at the same time, but in the present embodiment, it is sufficient if either of them can be emitted selectively.
The two wavelengths can be appropriately selected as long as the photosensitive drum 51Y and the like have exposure sensitivity. In the present embodiment, λ ₁ = 780 nm and λ ₂ = 650 nm.

The dichroic mirror 25A (25B) is for branching the wavelength of the laser beam 33A (33B), for example, on a parallel plate transmits light having a wavelength lambda ₁ as transmitted light 34A (34B), the wavelength lambda ₂ It is the member which gave the dichroic mirror coating which has the wavelength characteristic which reflects this light as reflected light 35A (35B).

Mirror 26A (26B) is a deflecting means for directing the transmitted light 34A and (34B) on the photosensitive drum 51Y (51K), reflective film coating the reflectance is better is applied to the wavelength lambda _1.
Mirror 27A (27B), 28A (28B ) is a deflecting means for directing the reflected light 35A and (35B) on the respective photosensitive drums 51M (51C), reflective film coating that reflectance is improved with respect to the wavelength lambda ₂ Is given.
The mirrors 26A (26B), 27A (27B), and 28A (28B) are arranged in a positional relationship corresponding to the mirrors 10A (10B), 23A (23B), and 24A (24B) of the first embodiment, respectively. The tilt of is adjusted.

As shown in FIG. 11, the control unit 400 includes an optical characteristic switching unit 405 instead of the optical characteristic switching unit 305 of the control unit 300 of the first embodiment, and includes signal switch units 410A and 410B. is there.
The optical characteristic switching means 405 discriminates the scanning direction from the clock information of the oscillating deflector control means 302, and the wavelength switching for selectively switching the signal level between high and low according to the forward scanning or the backward scanning. The signal 406 is transmitted to the signal switch units 410A and 410B.
In response to the wavelength switching signal 406 from the optical characteristic switching unit 405, the signal switch unit 410A (410B) transmits the laser driving signal 340A (340B) transmitted from the laser driving signal generation unit 304A (304B) to the two-wavelength LD 29A ( 29B) is supplied to one of the two light emitting units. In the present embodiment, when the wavelength switching signal 406 is high and low, the light is supplied to the light emitting units having the wavelengths λ ₁ and λ ₂ , respectively.

With such a configuration, the wavelengths emitted from the two-wavelength LDs 29A and 29B can be selectively switched between the forward scanning and the backward scanning. Therefore, in the forward scanning, the wavelength λ ₁ modulated by the image signals 360Y and 360K. Transmitted light 34A and 34B on the photosensitive drums 51Y and 51K, respectively, and in the backward scanning, the reflected lights 35A and 35B having the wavelength λ ₂ modulated by the image signals 360M and 360C are applied on the photosensitive drums 51M and 51C. A full color image can be formed by scanning and superimposing the four colors.

At this time, since the two-wavelength light of the two-wavelength LD 29A (29B) is electrically switched by the optical characteristic switching means 405, a simple configuration without a movable part as in the case of changing the polarization direction can be achieved.
In addition, since the two-wavelength light source employs a two-wavelength LD 29A (29B) in which a two-wavelength light emitting section is formed on one chip, compared to a case where lights from a plurality of LD light sources are combined on the same axis, Since optical axis alignment is not required, assembly is easy, and the apparatus can be downsized.
In addition, since the two-wavelength LD 29A (29B) switches the light-emitting portion according to the forward scan and the backward scan, problems such as crosstalk occur when the two wavelengths are simultaneously emitted at a close position on one chip. Therefore, high-quality exposure scanning can be performed while being small.

That is, in the optical scanning device 80 of the present embodiment, in the optical scanning device of the present invention, the optical characteristic switching unit switches the wavelength characteristic of the light beam, and the optical path branching unit is a dichroic mirror. It has become.
Therefore, by switching the wavelength characteristics of the light beam emitted from one beam light source, the scanning position can be guided to two different scanning positions, and each is changed according to the swing direction of the swing deflector. 2 beam scanning can be performed. At that time, by optimizing the wavelength characteristics of the dichroic mirror according to the wavelength of the incident light beam, the light beam can be efficiently branched while reducing the light amount loss.

  In the above description, an example in which a four-beam scanning is performed by entering a light beam from one beam light source on each reflecting surface of the oscillating mirror has been described. However, the oscillating mirror is a single-sided mirror. Then, two-beam scanning may be performed by entering a light beam from one beam light source on the reflection surface. Alternatively, light beams from a plurality of beam light sources may be incident on one or both surfaces of the oscillating mirror, and beam scanning may be performed twice the number of beam light sources.

  In the above description, the beam light source is a semiconductor laser. However, the present invention is not limited to this. For example, a gas laser may be used. For example, in the case of the first embodiment, a mechanism for changing the polarization direction by rotating a quarter wavelength plate that converts circularly polarized light into linearly polarized light can be employed as the optical characteristic switching means. In the case of the second embodiment, for example, a gas laser capable of oscillating a plurality of wavelengths by harmonics is used, and a mechanism for switching the wavelength selection filter can be employed as the optical characteristic switching means.

  In the above description, the optical characteristic of the light beam from one beam light source is switched according to the swing direction of the swing mirror to form two light beams that scan on different scanning lines. Alternatively, a configuration may be adopted in which light from two beam light sources having different optical characteristics such as a polarization state and a wavelength is incident on the oscillating mirror in a state of being coaxially synthesized. In this case, the optical characteristic switching means can be configured to switch light emission of beam light sources having different optical characteristics. For example, if these beam light sources are LD elements, they can be switched by electrical switching.

  In the above description, the optical scanning device is used in an image forming system such as a laser printer. However, the optical scanning device is used in other systems such as a multi-beam laser processing system for drawing a processing portion. Needless to say. In this case, the scanning positions of multiple beams may be drawn in a planar shape by forming a plurality of parallel scanning lines on the same processed portion.

  In the above description, an example using a scanning lens is used to perform constant speed scanning on the image plane. However, depending on the depth of field and the scanning angle of view, a lens that does not correct the scanning speed is used. May be. Further, depending on the required spot diameter and scanning accuracy, a configuration without using a scanning lens may be used.

Here, a case will be described where the names of the correspondence relationship between the terminology of the above embodiment and the terminology of the claims are different.
The laser light sources 2A and 2B and the two-wavelength LDs 29A and 29B are an embodiment of a beam light source. The polarization beam splitters 9A and 9B and the dichroic mirrors 25A and 25B are an embodiment of the optical path branching unit. The mirror surfaces 11A and 11B correspond to reflecting surfaces. The laser beams 30A, 30B, 33A, and 33B correspond to light beams. At least one of the mirrors 10A (10B), 23A (23B), and 24A (24B) is a mirror member that corrects the inclination of the scanning line. At least one of the mirrors 26A (26B), 27A (27B), and 28A (28B) is a mirror member that corrects the inclination of the scanning line.

FIG. 3 is a schematic front explanatory view for explaining a schematic configuration of the optical scanning device according to the first embodiment of the present invention. FIG. 2 is a schematic plan view for explaining a schematic configuration of the optical scanning device according to the first embodiment of the present invention. It is a typical perspective explanatory view for explaining a schematic optical path of an optical scanning device concerning a 1st embodiment of the present invention. It is a plane explanatory view for explaining an oscillation deflector used for an optical scanning device concerning a 1st embodiment of the present invention, and its AA sectional view. FIG. 2 is a functional block diagram for explaining a control unit of the optical scanning device and the image forming system according to the first embodiment of the present invention. FIG. 5 is a schematic operation explanatory diagram for explaining deflection scanning of the optical scanning device according to the first embodiment of the present invention. FIG. 5 is a schematic explanatory diagram for explaining a scanning line image when the adjustment of the inclination of the scanning line is not performed and when the adjustment of the inclination of the scanning line is performed. It is a typical plane explanatory view for explaining a schematic structure of an optical scanning device of a modification of the first embodiment of the present invention. FIG. 6 is a schematic front explanatory view for explaining a schematic configuration of an optical scanning device according to a second embodiment of the present invention. FIG. 5 is a schematic plan explanatory diagram for describing a schematic configuration of an optical scanning device according to a second embodiment of the present invention. It is a functional block diagram for demonstrating the control part of the optical scanning device and image forming system which concern on the 2nd Embodiment of this invention.

Explanation of symbols

1, 70, 80 Optical scanning device 2A, 2B Laser light source (beam light source)
5A, 5B Polarization control means 7 Oscillating deflectors 8A, 8B Scanning lenses 9A, 9B Polarization beam splitter (optical path branching means)
10A, 10B, 23A, 23B, 24A, 24B, 26A, 26B, 27A, 27B, 28A, 28B Mirror (mirror member that corrects the inclination of the scanning line)
11A, 11B Mirror surface (reflection surface)
11b Oscillating part (oscillating mirror)
50 Image forming apparatuses 51Y, 51C, 51M, 51K Photosensitive drums 25A, 25B Dichroic mirrors (optical path branching means)
29A, 29B 2 wavelength LD (beam light source)
30A, 30B, 33A, 33B Laser light (light beam)
31A, 31B, 34A, 34B Transmitted light 32A, 32B, 35A, 35B Reflected light 300, 400 Controllers 301A, 301B Horizontal synchronization control means 302 Oscillating deflector control means 304A, 304B Laser drive signal generation means 305, 405 Optical characteristics Switching means 310A, 310B, 320A, 320B Synchronization detection signals 351A, 351B Scan direction determination signals 410A, 410B Signal switch section

Claims (5)

A swing deflector having a swing mirror;
A beam light source that makes a light beam incident on the reflecting surface of the oscillating mirror;
Optical characteristic switching means for selectively switching the optical characteristics of the light beam incident on the reflecting surface of the oscillating mirror according to the oscillating direction of the oscillating mirror;
An optical scanning device comprising: an optical path branching unit that branches an optical path of the light beam deflected by the oscillating mirror according to an optical characteristic of the light beam.   2. The optical scanning device according to claim 1, wherein at least one of the optical paths branched by the optical path branching unit is provided with a mirror member that corrects the inclination of the scanning line in the optical path. The optical characteristic switching means selectively switches the light beam between two linearly polarized light beams whose polarization directions are orthogonal to each other;
The optical scanning apparatus according to claim 1, wherein the optical path branching unit is a polarization beam splitter. The optical characteristic switching means is for switching the wavelength characteristic of the light beam;
The optical scanning device according to claim 1, wherein the optical path branching unit is a dichroic mirror.   An image forming system that performs exposure scanning using the optical scanning device according to claim 1 to form an image.

Images