JP6135987B2 - Light source device, optical scanning device, and image forming apparatus - Google Patents

Description

  The present invention relates to a light source device, an optical scanning device, and an image forming apparatus.

  As an image forming apparatus such as a copying machine, a printer, or a facsimile, a latent image is formed on a latent image carrier by irradiating the latent image carrier with writing light according to image information by deflecting scanning. It is known that an image is developed to obtain an image. In an optical scanning apparatus that deflects and scans writing light, light emitted from a light source is generally shaped into a predetermined shape by an optical system component such as a collimating lens and is incident on a polygon mirror. The light incident on the polygon mirror is deflected and scanned, and passes through an optical system component such as a scanning lens and a reflection mirror, and is irradiated onto the latent image carrier.

  In recent years, a light source device mounted on an optical scanning device has a plurality of light emitting units arranged such as an LD (Laser Diode) array or a vertical cavity surface emitting laser (VCSEL). Light sources are used, and the quality and image quality are increasing with the increase in the number of channels in the light emitting section.

  Patent Document 1 discloses an optical scanning device having a light source device having a light source of a surface emitting laser array in which 32 light emitting units are arranged two-dimensionally (8 × 4 columns) on the same substrate. ing.

FIG. 11 is a perspective view of the light source device described in Patent Document 1. FIG.
A light source device 370 described in Patent Document 1 includes a light source of a vertical cavity surface emitting laser (VCSEL) (not shown) and a light amount detection unit (not shown) that detects the light amount of a light beam emitted from the light source. A circuit board 375 is provided. Further, an optical element holder 372 that holds optical elements such as a collimating lens 311 (see FIG. 11A), a temperature correction lens 312, and an aperture mirror 313 is provided. The optical element holder 372 is attached to the circuit board 375 via the intermediate holder 371.

  In addition to the collimating lens 311, the temperature correction lens 312, and the aperture mirror 313, the optical element holder 372, as shown in FIG. 11B, the light reflected by the aperture mirror 313 is mounted on a circuit board 375 (not shown). It also holds optical system parts for guiding light to the light quantity detection unit. Specifically, a folding mirror 314, a detection aperture (not shown), and a condenser lens 316 are held.

  A light beam emitted from a light source (not shown) mounted on the circuit board 375 passes through the collimator lens 311 and the temperature correction lens 312 and then enters the aperture mirror 313. A part of the light beam incident on the aperture mirror 313 is emitted from the aperture of the aperture mirror 313 toward the polygon mirror, and the remaining light beam is reflected by the reflection surface of the aperture mirror 313 and enters the folding mirror 314. . Then, the light beam folded back by the folding mirror 314 is narrowed down to a predetermined beam diameter by a detection aperture (not shown) and a condensing lens 316, and to a light quantity detection unit (not shown) mounted on the circuit board 375. Incident.

  In the light source device 370, the light amount control of the light beam is performed based on the light amount detected by the light amount detection unit.

  In the light source device 370 described in Patent Document 1, the optical element holder 372 is formed of an aluminum alloy. The optical element holder 372 having a complicated structure as shown in FIG. 11 is manufactured by casting. However, since casting does not provide sufficient accuracy, it is necessary to perform accuracy by performing secondary processing such as cutting on the portion of the optical element holder 372 to which the optical element is attached. Therefore, there is a problem that the manufacturing cost is high. Also, the weight of the optical scanning device is increased.

  Therefore, the present applicant is developing a light source device in which the optical element holder 372 is made of resin. By using the optical element holder 372 as a resin, it can be accurately manufactured by injection molding or the like, secondary processing such as cutting can be omitted, and manufacturing cost can be expected to be reduced. Further, the weight of the apparatus can be reduced.

  However, this light source device under development has the following problems. That is, the optical element holder 372 needs to be provided with the following parts. That is, a holding unit for holding a plurality of optical elements (collimator lens 311, temperature correction lens 312, aperture mirror 313, etc.), and light emitted from the light source is incident on the light amount detection unit as reflected from the aperture mirror 313. It is necessary to provide a partition wall 372a for preventing the light from entering the optical path. Further, it is necessary to provide a through hole for allowing the light of the aperture mirror 313 to enter the reflection mirror 314 in the partition wall 372a. Thus, since the optical element holder 372 has many functional parts, the structure of the optical element holder 372 is complicated. When the optical element holder 372 having such a complicated structure is injection-molded, there arises a problem that the molded optical element holder 372 is difficult to release. It has been found that in order to remove the optical element holder 372 from the mold, it is necessary to provide a draft at the following locations of the mold due to the mold configuration. That is, it is a place where a surface to which the aperture mirror 313 of the mold is attached and a surface to which the reflection mirror 314 is attached are molded. However, in this case, the surface to which the aperture mirror 313 to be molded and the surface to which the reflection mirror 314 is attached are inclined. Therefore, in order to correct this inclination, it is necessary to perform secondary processing such as cutting on the mounting surfaces, and it has not been possible to sufficiently reduce the manufacturing cost.

  The present invention has been made in view of the above problems, and an object thereof is to provide a light source device, an optical scanning device, and an image forming apparatus that can simplify the structure of an optical element holding member.

In order to achieve the above object, an invention according to claim 1 is a light source device comprising: a light source; and an optical element holding means for holding a plurality of optical elements arranged on an optical path of light emitted from the light source. The optical element holding means includes: a light splitting element that splits light from the light source; an optical element that guides one light split by the light splitting element to a light quantity detection unit that detects the light quantity; A transparent wall that holds a partition wall that blocks an incident path of the other light split by the light splitting element to the light quantity detection unit, the light splitting element, and an optical element that guides the light quantity detection unit that detects the light quantity A first optical element holding member made of a resin material, and a second optical element holding member made of a non-transparent resin material on which the partition wall is formed, and at least of the optical elements held by the first optical element holding member One is by photo-curing resin And it is characterized in that it is bonded and fixed to the first optical element holding member.

  According to the present invention, the optical element holding means is constituted by a plurality of optical element holding members, so that the structure of each optical element holding member is compared with the case where the optical element holding means is constituted by one optical element holding member. Can be simplified.

1 is a schematic diagram illustrating a main configuration of a color printer according to an embodiment. FIG. 3 is a schematic diagram showing a layout of an incident optical system of a Bk-C unit that is an optical scanning device in the color printer. Explanatory drawing of the prism beam splitter in the same incident optical system. The schematic diagram which shows the layout of the scanning optical system of the Bk-C unit. The schematic diagram which shows the structure of the deflector seen from the rotating shaft direction of the rotary polygon mirror in the Bk-C unit. The perspective view which looked at the light source unit in the Bk-C unit from the lower side. The schematic diagram which looked at the optical path in the light source unit from the upper side. The perspective view of the 1st holder in the light source unit. The perspective view which looked at the light source unit from the upper side. The figure which shows an example of a surface emitting light source. The perspective view of the conventional light source device.

Hereinafter, an embodiment of a color printer as an image forming apparatus using an optical scanning device according to the present invention will be described.
FIG. 1 is a schematic diagram illustrating a main configuration of a color printer 500 according to the present embodiment.
The color printer 500 is a tandem multicolor printer that can form a full color image by superimposing four color toner images of black, cyan, magenta, and yellow. The color printer 500 includes an optical scanning device 100 and four photosensitive drums 501, 502, 503, and 504. In addition, four cleaning units 605Y, 605M, 605C, and 605Bk and four charging devices 602Y, 602M, 602C, and 602Bk are provided. Further, four developing devices 604Y, 604M, 604C, and 604Bk including developing rollers 603Y, 603M, 603C, and 603Bk are also provided. Further, an intermediate transfer belt 606 that is an intermediate transfer member, a secondary transfer roller 613, a fixing device 610, a paper feed roller 608, a pair of registration rollers 609, a paper discharge roller 612, a paper discharge tray 611, and the like are also provided.

  The photosensitive drum 501, the cleaning unit 605Y, the charging device 602Y, the developing roller 603Y, and the developing device 604Y constitute an image station (hereinafter referred to as “Y station”) that forms a yellow image. The photosensitive drum 502, the cleaning unit 605M, the charging device 602M, the developing roller 603M, and the developing device 604M constitute an image station (hereinafter referred to as “M station”) that forms a magenta image. The photosensitive drum 503, the cleaning unit 605C, the charging device 602C, the developing roller 603C, and the developing device 604C constitute an image station (hereinafter referred to as “C station”) that forms a cyan image. The photosensitive drum 504, the cleaning unit 605Bk, the charging device 602Bk, the developing roller 603Bk, and the developing device 604Bk constitute an image station (hereinafter referred to as “K station”) that forms a black image.

  Each of the photosensitive drums 501, 502, 503, and 504 has a photosensitive layer on its peripheral surface, and is driven to rotate in the direction of the arrow in FIG. 1 by a rotating mechanism (not shown). Each charging device 602Y, 602M, 602C, 602Bk uniformly charges the surface of the corresponding photosensitive drum 501, 502, 503, 504.

  The optical scanning apparatus 100 exposes and scans the yellow photosensitive drum 501 and the magenta photosensitive drum 502 by exposure, and the cyan photosensitive drum 503 and the black photosensitive drum 504 by exposure scanning Bk-C. It consists of unit 100B. The optical scanning device 100 irradiates scanning light with lighting control based on image information using the corresponding photosensitive drum surface as a scanning surface, and forms an electrostatic latent image on the photosensitive drum surface. The electrostatic latent image formed here is conveyed to the developing area facing the developing roller of the developing devices 604Y, 604M, 604C, and 604Bk as the photosensitive drums 501, 502, 503, and 504 rotate.

  Each developing device 604Y, 604M, 604C, 604Bk is provided with a developing roller for carrying charged toner. A predetermined developing bias is applied to the developing roller, and the toner on the developing roller adheres to the electrostatic latent image on the photosensitive drum by the action of the developing electric field formed thereby. As a result, an image (hereinafter referred to as “toner image”) with toner attached thereto is formed on the photosensitive drums 501, 502, 503, and 504.

  The toner image formed in this way is conveyed to a primary transfer region facing the intermediate transfer belt 606 as the photosensitive drums 501, 502, 503, and 504 rotate. The yellow, magenta, cyan, and black toner images on the photosensitive drums 501, 502, 503, and 504 are sequentially primarily transferred onto the intermediate transfer belt 606 at the timing of overlapping each other. As a result, a multicolor image is formed on the intermediate transfer belt 606. Each of the cleaning units 605Y, 605M, 605C, and 605Bk removes transfer residual toner that remains without being transferred to the surface of the corresponding photosensitive drum 501, 502, 503, or 504.

  On the other hand, the recording paper 510 as a recording material is conveyed to the registration roller pair 609 one by one by the paper feeding roller 608. The registration roller pair 609 sends the recording paper 510 to the secondary transfer area where the intermediate transfer belt 606 and the secondary transfer roller 613 face each other at a predetermined timing. In this secondary transfer area, the multicolor toner image on the intermediate transfer belt 606 is secondarily transferred to the recording paper 510. The recording paper 510 on which the multicolor toner image is transferred is then sent to the fixing device 610. The fixing device 610 fixes the toner image on the recording paper 510 to the recording paper with heat and pressure. The fixed recording paper 510 is discharged onto a paper discharge tray 611 via a paper discharge roller 612.

Next, the configuration and operation of the optical scanning device 100 will be described.
Since the basic configuration of the MY unit 100A and the Bk-C unit 100B constituting the optical scanning device 100 is the same, in the following description, the configuration and operation of the optical scanning device 100 using the Bk-C unit 100B. Will be explained. In the following description, Y, M, C, and Bk that are color-coded codes are omitted as appropriate.

FIG. 2 is a schematic diagram showing the layout of the incident optical system of the Bk-C unit 100B.
A light source unit 101 that is a light source device includes a light source 102 that emits laser light with linearly polarized light, and a quarter-wave plate 105 that converts the laser light emitted from the light source 102 into circularly polarized light. In addition, a collimator lens 106 that converts the laser light converted into circularly polarized light by the quarter-wave plate 105 into parallel light, and an aperture mirror 107 that cuts out the laser light parallelized by the collimator lens 106 are provided. These optical components 102, 105, 106, and 107 are positioned at a predetermined position and assembled integrally with a light source holder 103 (see FIG. 6, FIG. 7, etc.) described later. Laser light emitted from the light source unit 101 is incident on a deflector 202 as light deflecting means via an incident optical system.

  The incident optical system includes a prism beam splitter (PBS) 203 that splits the laser light emitted from the light source unit 101 into two in the sub-scanning direction (the front-rear direction in FIG. 2). In addition, a quarter-wave plate 204 that converts the polarization characteristics of the laser beams L1 and L2 divided into two into linearly polarized light is provided. Further, a cylindrical lens 205 is provided for imaging the laser beams L1 and L2 converted into circularly polarized light on the mirror surfaces of the two rotary polygon mirrors 202a and 202b mounted on the deflector 202. The cylindrical lens 205 has a function of condensing laser light converted into circularly polarized light only in the sub-scanning direction.

  The laser beams L1 and L2 formed in a predetermined laser profile by such an incident optical system are imaged on the mirror surfaces of the rotary polygon mirrors 202a and 202b of the deflector 202, respectively. The deflector 202 stably drives the rotary polygon mirrors 202a and 202b integrally at a predetermined rotation number around a rotation axis parallel to the sub-scanning direction. When the laser beams L1 and L2 are incident on the mirror surfaces of the rotating polygon mirrors 202a and 202b rotating in this way, the laser beams L1 and L2 are scanned in the main scanning direction as shown in FIG.

FIG. 3 is an explanatory diagram of the prism beam splitter 203.
The laser light L0 emitted from the light source unit 101 is converted from linearly polarized light to circularly polarized light by the quarter wavelength plate 105 in the light source unit 101. Thus, when the laser beam L0 having circular polarization characteristics reaches the polarization separation surface of the deflecting beam splitter 203, the component perpendicular to the incident surface with respect to the mirror surfaces of the rotary polygon mirrors 202a and 202b (of the polarization components of circular polarization) ( Only the s-polarized component) is transmitted through the polarization separation surface. Then, the laser beam L2 having only the s-polarized component goes to the lower rotary polygon mirror 202b. On the other hand, of the circularly polarized light components, the component parallel to the incident surface with respect to the mirror surfaces of the rotary polygon mirrors 202a and 202b (p-polarized component) is reflected by the polarization separation surface. Thereafter, the laser beam L1 having only the p-polarized component is reflected by the reflecting surface of the deflecting beam splitter 203 and travels toward the upper rotating polygon mirror 202a. At this time, the two separated laser beams L1 and L2 have different polarization characteristics, respectively. Thereafter, each laser beam L1 and L2 is again circularly polarized by the quarter wavelength plate 204. Is converted to

FIG. 4 is a schematic diagram showing the layout of the scanning optical system of the Bk-C unit 100B.
One of the laser beams L1 scanned by the deflector 202 (laser beam scanned by the mirror surface of the upper rotary polygon mirror 202a) passes through the first exit lens 301 and the second exit lens 302, and is dust-proof. The glass 305 is transmitted. Then, the surface of the photosensitive drum 504 is scanned at a constant speed. On this optical path, mirrors 303a, 303b, and 303c for returning the laser beam L1 are installed. The other laser beam L2 (the laser beam scanned by the mirror surface of the lower rotating polygon mirror 202b) passes through the first exit lens 301 and the second exit lens 302, passes through the dust-proof glass 305, and is the photosensitive drum. A constant speed scan is performed on the surface 504. On this optical path, a mirror 304 for turning back the laser beam L2 is installed.

  All of the incident optical system, the deflector 202, and the scanning optical system described above are integrally fixed to the optical housing 400 shown in FIG. 4 as a light source support, and characteristics as an optical scanning device are secured. .

FIG. 5 is a schematic diagram showing the configuration of the deflector 202 viewed from the direction of the rotation axis of the rotary polygon mirrors 202a and 202b.
In the deflector 202, the two rotary polygon mirrors 202a and 202b have an integral shape and are assembled on the motor substrate 202C. The rotary polygon mirrors 202a and 202b each have four mirror surfaces, and the mirror surface of the upper rotary polygon mirror 202a and the mirror surface of the lower rotary polygon mirror 202b are arranged so as to be shifted by an angle θ in the rotation direction. . In the present embodiment, θ = 45 °. The upper rotating polygon mirror 202a is used for scanning the photosensitive drum 504, and the lower rotating polygon mirror 202b is used for scanning the photosensitive drum 503. However, the upper rotating polygon mirror 202a is not geometrically scanned simultaneously by the above arrangement.

FIG. 6 is a perspective view of the light source unit 101 as viewed from below.
FIG. 7 is a schematic view of the optical path in the light source unit 101 as viewed from above.
In the following description, for convenience, the direction in which the laser light is emitted (optical axis direction) is the X axis, the main scanning direction is the Y axis, and the sub scanning direction is the Z axis. As shown in FIG. 7, the light source unit 101 as a light source device includes a light source 102, a quarter-wave plate 105 constituting an incident optical system, a collimating lens 106, and an aperture mirror 107.

  The aperture mirror 107 has a mirror configuration on the incident surface on which the laser light is incident. Therefore, part of the laser light incident on the aperture mirror 107 passes through the opening 107a (see FIG. 8) of the aperture mirror 107, is shaped and heads toward the deflector 202, and the rest is on the incident surface that is a mirror. Reflected.

  The light source unit 101 includes a detection optical system 108 that guides the laser light L <b> 0 ′ reflected by the aperture mirror 107 to a photodiode 109 as a light amount detection unit mounted on the laser modulation substrate 104. The detection optical system 108 includes a detection reflection mirror 108 </ b> A that reflects the laser light L <b> 0 ′ dispersed by the aperture mirror 107 toward the photodiode 109. Further, it has a detection collimator lens 108B that condenses the laser light L0 'reflected by the detection reflection mirror 108A.

  The laser beam L0 'reflected from the incident surface of the aperture mirror 107 travels to the detection reflection mirror 108A. Then, the laser beam is reflected by the detection reflection mirror 108A, passes through the opening D formed in the light source holder 103, and only necessary laser light is cut out and then collected by the detection collimator lens 108B. Thereafter, the laser beam L0 'is received by the photodiode 109, which is a light amount detector mounted on the laser modulation substrate 104, and the light amount is detected. This detection result is sent to a control unit that performs power control of the light source 102 (not shown), and is used for power adjustment of laser light emitted from the light source 102.

  As shown in FIG. 6, the light source holder 103 includes a first holder 103a and a second holder 103b. The first holder 103a holds the aperture mirror 107 and the detection reflection mirror 108A. The second holder 103b holds the laser modulation substrate 104, the quarter wavelength plate 105, the collimating lens 106, and the detection collimating lens 108B on which the light source 102 and the photodiode 109 are mounted.

  The first holder 103a is made of a transparent resin material, and the second holder 103b is made of an impermeable resin. In the present embodiment, the first holder 103a is made of a PC (polycarbonate) resin material. For the second holder 103b, a resin material having a lower thermal expansion coefficient by adding a material having a lower thermal expansion coefficient than a resin such as glass or mica to the PC / ABS alloy was used.

  The modulation IC of the control unit that performs power control of the light source 102 mounted on the laser modulation substrate 104 generates heat. For this reason, the second holder 103 b close to the light source 102 is more affected by heat than the first holder 103 a farther than the light source 102. Therefore, when the second holder 103b is made of the same PC resin as that of the first holder 103a, the portion that holds the optical system such as the collimating lens is deformed due to the thermal expansion of the second holder 103a, and the optical system is inclined. Will occur. Therefore, the resin material of the second holder 103b and the resin material of the first holder are made different from each other, and the second holder 103b resin material has a lower thermal expansion coefficient than the resin material of the first holder 103a. . Thereby, the thermal expansion of the 2nd holder 103b can be suppressed, and malfunctions, such as a collimating lens etc. inclining by the thermal expansion of the 2nd holder 103b, can be suppressed.

  Further, it is preferable to use a transparent resin having a low thermal expansion coefficient, such as PC (polycarbonate), as the resin material of the first holder 103a. Thereby, it is possible to prevent the aperture mirror 107 and the detection reflection mirror 108A from being inclined about the Y axis or the Z axis due to the thermal expansion of the first holder 103a.

  Moreover, it is preferable to use a resin material having a thermal expansion coefficient close to that of the second holder 103b as much as possible as the resin material of the first holder 103a. If the thermal expansion coefficients of the first holder 103a and the second holder 103b are greatly different, when thermal expansion occurs, stress is generated in the fixing portion between the first holder 103a and the second holder 103b, and the first holder 103a and the second holder 103b There is a possibility that the two holders 103b are distorted and deformed. By making the thermal expansion coefficient of the first holder 103a close to the thermal expansion coefficient of the second holder 103b, it is possible to suppress the occurrence of stress in the fixing portion between the first holder 103a and the second holder 103b. Thereby, it can suppress that distortion deformation arises in the 1st holder 103a or the 2nd holder 103b.

  By forming each holder 103a, 103b with resin, the light source unit 101 can be reduced in weight as compared with the case where each holder 103a, 103b is made of metal such as aluminum. Moreover, a holder with high accuracy can be formed only by forming each holder 103a, 103b by injection molding, and secondary processing for improving accuracy can be made unnecessary.

  When the light source holder 103 is made of resin, the thermal conductivity of the light source holder 103 is inferior to that of metal. When a vertical cavity surface emitting laser (VCSEL) having a low operating environment temperature is used as the light source 102, the heat of the modulation IC included in the control unit that performs power control of the light source 102 passes through the laser modulation substrate 104, and the light source There is a risk of heating 102 above the ambient temperature. When the light source holder 103 is made of a metal such as aluminum, the heat of the modulation IC can be radiated by the light source holder 103, and the temperature rise of the light source 102 can be suppressed. However, when the light source holder 103 is made of resin, heat radiation from the light source holder 103 cannot be expected. For this reason, in the present embodiment, the modulation IC is cooled by a cooling mechanism such as a fan (not shown). Thereby, even if the light source holder 103 is made of resin, the temperature rise of the light source 102 can be suppressed.

  Although the resin has a larger thermal expansion coefficient than the metal, the laser modulation substrate 114 is assembled outside the optical housing, and further cooled by a cooling mechanism. The impact is small. Therefore, even if the light source holder is made of resin, adverse effects due to thermal expansion (such as tilting the optical element being held) can be suppressed. Moreover, regarding the 2nd holder 103a, as mentioned above, glass and mica are added and the thermal expansion coefficient is suppressed more than general resin. Therefore, even if affected by the heat of the modulation IC, there is no problem that the held optical element is tilted so that desired optical characteristics cannot be obtained.

  Further, the second holder 103a may be made of a resin material having a higher thermal conductivity than that of the first holder by adding a material having a higher thermal conductivity than that of the resin. Thereby, a part of the heat of the modulation IC can be moved to the second holder 103a, and the temperature rise of the light source 102 can be suppressed.

FIG. 8 is a perspective view of the first holder 103a.
As shown in FIG. 8, the 1st holder 103a has the fixed surface part 113a for fixing to the 2nd holder 103b. Moreover, it has the aperture attachment surface part 113b to which the aperture mirror 107 is attached, and the mirror attachment surface part 113c to which the reflective mirror 108A for detection is attached. A screw hole 114 into which a screw is inserted is provided at the center of the fixed surface portion 113a. Two positioning holes 115a and 115b are provided across the screw holes. One positioning hole 115b is a main reference for positioning and is a round hole, and the other positioning hole 115a is a secondary reference for positioning and is a long hole extending in the Y-axis direction.

  The aperture mounting surface portion 113b is formed to be inclined by 45 ° with respect to the optical axis (X-axis direction), and the mirror mounting surface portion 113c is formed to be orthogonal to the aperture mounting surface portion 113b.

  The aperture mirror 107 is bonded and fixed to the light source side surface (aperture mounting surface) of the aperture mounting surface portion 113b. The detection reflection mirror 108A is bonded and fixed to the surface (mirror mounting surface) of the mirror mounting surface portion 113c on the photodiode 109 side. Specifically, an ultraviolet curable resin is applied between the four corners of the rectangular aperture mirror 107 and the aperture mounting surface. The aperture mirror 107 is bonded and fixed to the aperture mounting surface 113b by irradiating the ultraviolet curable resin with ultraviolet rays. Similarly, an ultraviolet curable resin is applied between the four corners of the rectangular detection reflection mirror 108A and the mirror mounting surface, and the ultraviolet light is applied to bond the detection reflection mirror 108A to the mirror mounting surface 113c. To do.

  When the first holder 103a is formed of the same non-permeable resin material as the second holder (PC / ABS alloy to which glass or mica is added), an ultraviolet curable resin is used to bond the aperture mirror 107 and the detection reflecting mirror 108A. Cannot be used. This is because the aperture mirror 107 and the detection reflection mirror 108A are not components such as a lens that transmit light. Therefore, when the first holder 103a is formed of a non-permeable resin, the aperture mirror 107 and the detection reflecting mirror 108A are bonded and fixed to the first holder 103a with a general-purpose adhesive. For this reason, it was necessary to consume as much as 1 hour for drying. Therefore, it is conceivable to fix the aperture mirror 107 and the detection reflection mirror 108A by pressing the aperture mirror 107 and the detection reflection mirror 108A against the first holder 103a using a fixing member such as a leaf spring. However, in this case, the cost may increase due to an increase in the number of parts.

  On the other hand, in the present embodiment, the first holder 103a is made of a PC (polycarbonate) resin different from the second holder 103b and is made transparent, so that the ultraviolet curable resin is irradiated with ultraviolet rays through the first holder 103a. Can be irradiated. Accordingly, the aperture mirror 107 and the detection reflection mirror 108A can be bonded and fixed to the first holder 103a in several tens of seconds. As a result, the working time (tact time) for bonding and fixing the aperture mirror 107 and the detection reflection mirror 108A to the first holder 103a can be reduced. In addition, the aperture mirror 107 and the detection reflecting mirror 108A can be fixed to the first holder 103a by bonding, and the number of parts can be reduced compared to the case of fixing by using a leaf spring or the like, and the cost can be reduced. Can be achieved.

FIG. 9 is a perspective view of the light source unit 101 as viewed from above.
To fix the first holder 103a to the second holder 103b, first, the two positioning protrusions 117a and 117b provided on the upper surface of the second holder 103b are inserted into the positioning holes provided in the fixing surface portion 113a of the first holder 103a. Insert and position the first holder 103a to the second holder 103b. Next, a screw is inserted into a screw insertion hole provided in the fixed surface portion 113a of the first holder 103a, a screw is screwed into a screw hole (not shown) provided in the second holder 103b, and the first holder 103a is attached to the second holder 103a. It fixes to the holder 103b.

  A fixing member 110 is fixed to the second holder 103b of the light source holder 103, and the light source unit 101 is fixed to the optical housing via the fixing member 110.

In the present embodiment, the light source holder 103 is composed of two members, a first holder 103a and a second holder 103b.
This is because the following problems occur when the light source holder 103 is formed of a single member. That is, as shown in FIG. 6, the light source holder 103 includes a partition wall 118 for preventing the light emitted from the light source 102 from entering the optical path for allowing the light reflected from the aperture mirror 107 to enter the photodiode 109, and an opening. Part D (see FIG. 7) and the like are provided. For this reason, the structure of the light source holder 103 is complicated. As described above, since the light source holder 103 has a complicated structure, there has been a problem that when the molding is performed by injection molding, the molded product cannot be removed. In order to solve this problem, it is necessary to form a draft angle at a location where a mounting surface on which the aperture mirror 107 is mounted and a mounting surface on which the detection reflecting mirror 108A is mounted are formed on the mold. It has been found. As a result, the attachment surface to which the aperture mirror 107 of the light source holder 103 is attached and the attachment surface to which the reflection mirror 108A is attached are inclined about the Y axis direction and the Z axis direction. When the aperture mirror 107 and the reflection mirror 108A are attached to such an inclined surface, the following problems occur. That is, there is a problem that the laser beam L0 directed to the deflector 202 cannot be shaped into a desired shape. Another problem is that laser light cannot be incident on the photodiode 109. For this reason, in this embodiment, the light source holder 103 is composed of two members, the first holder 103a and the second holder 103b.

  By using the light source holder 103 as the first holder 103a and the second holder 103b, the structure of each holder can be simplified. Thereby, each holder 103a, 103b can be extracted from a metal mold | die, without providing a draft in a metal mold | die. Therefore, it is possible to accurately form the surface to which the aperture mirror 107 of the first holder 103a is attached and the surface to which the detection reflection mirror is attached. In addition, the molded first holder 103a can be extracted from the mold without providing a draft at the portion where the fixed surface portion of the mold for molding the first holder 103a is formed. Further, the molded second holder 103b can be removed from the mold without forming a draft at a portion where the fixed surface portion 113a of the first holder 103a of the mold for molding the second holder 103b is pressed. Can be extracted. Therefore, it is possible to accurately mold the surfaces that the fixed surface portion 113a of the first holder 103a and the fixed surface portion 113a of the first holder 103b of the second holder 103a are pressed against. Accordingly, it is possible to suppress the first holder 103a from being attached to the second holder 103b by being inclined about the Z-axis direction or the Y-axis direction. Thereby, it is possible to suppress the aperture mirror 107 and the detection reflection mirror 108A from being inclined around the Z-axis direction and the Y-axis direction. As a result, the laser beam L0 directed to the deflector 202 can be shaped into a desired shape, and the laser beam L0 'can be incident on the photodiode 109.

  Further, the partition wall 118 of the light source holder 103 must be impermeable. Therefore, when the light source holder 103 is formed of a single member, the aperture mirror mounting surface portion and the mirror mounting surface portion are also non-transparent resin. Therefore, when the light source holder 103 is formed of a single member, the aperture mirror 107 and the detection reflection mirror 108A cannot be bonded with an ultraviolet curable resin. Further, as described above, the laser modulation substrate 114 has a heat generating portion such as a modulation IC, and the temperature of the light source side of the light source holder 103 is likely to rise. For this reason, when the light source holder 103 is formed of a resin, it is necessary to add glass, mica, or the like to suppress thermal expansion in order to suppress thermal expansion, resulting in an impermeable resin. Therefore, when the light source holder 103 is formed of a single member, the aperture mirror 107 and the detection reflection mirror 108A cannot be bonded with an ultraviolet curable resin.

  On the other hand, by using the light source holder 103 as the first holder 103a and the second holder 103b, the first holder 103a that does not require the function of blocking light can be formed of a transparent resin. In addition, since the first holder 103a is far from the light source and does not easily rise in temperature, thermal expansion can be suppressed without adding glass or mica, so that the first holder 103a can be made of a transparent resin. Thereby, the aperture mirror 107 and the detection reflecting mirror 108A can be bonded with the ultraviolet curable resin.

  Thus, by using the light source holder 103 as the first holder 103a and the second holder 103b, the thermal expansion of the light source holder 103 is suppressed, and the aperture mirror 107 and the detection reflection mirror 108A can be easily bonded. One function can be satisfied.

  Furthermore, when the light source holder 103 is formed of a single member, the aperture mirror 107 and the detection mirror 108A can be mounted in a narrow space surrounded by four sides in order to attach the aperture mirror 107 and the detection reflection mirror 108A as shown in FIG. The reflection mirror 108A is inserted and attached. For this reason, the assembling workability of the aperture mirror 107 and the detection reflecting mirror 108A is poor. On the other hand, in the present embodiment, as shown in FIG. 8, the aperture mirror 107 and the detection reflection mirror 108A are assembled with the periphery of the surface to which the aperture mirror 107 is attached and the surface to which the detection reflection mirror is attached opened. be able to. Therefore, there are no restrictions on the direction in which the aperture mirror 107 and the detection reflection mirror 108A are assembled. As a result, the aperture mirror 107 and the detection reflection mirror 108 </ b> A can be assembled from a direction in which they can be easily assembled, and the aperture mirror 107 and the detection reflection mirror 108 </ b> A can be easily assembled to the first holder 103. Thereby, the workability of assembling the aperture mirror 107 and the reflection mirror for detection 108A can be improved.

  In the present embodiment, as the light source 102, a surface-emitting light source in which a plurality of light-emitting portions as shown in FIG. 10 are arranged in a 4 × 4 arrangement in a plane orthogonal to the light beam emission direction is used. It was. By using the light source 102 as a surface-emitting light source, high-resolution printing is possible. Further, instead of the surface emitting light source, an LD (Laser Diode) having a single light emitting portion, or an LD array in which LDs having a plurality of light emitting portions are arranged linearly or two-dimensionally may be used. . Even with such a light source, high-resolution printing is possible. Note that the surface-emitting light source is preferable because the cost reduction effect is large.

What has been described above is an example, and the present invention has a specific effect for each of the following aspects.
(Aspect 1)
A light source 102 and a plurality of optical elements arranged on the optical path of the light emitted from the light source 102 (in this embodiment, a quarter-wave plate 105, a collimating lens 106, an aperture mirror 107, a detection reflection mirror 108A, detection Optical element holding means such as the light source holder 103 that holds the collimating lens 108B), the optical element holding means includes a plurality of optical element holding members made of a resin material that holds at least one optical element. Including.
With this configuration, as described in the embodiment, the structure can be simplified as compared with the case where the optical element holding means as the light source holder 103 is formed by a single member. Thereby, the location which holds the optical element of each optical element holding member can be manufactured with high accuracy, and the manufacturing cost can be reduced.

Various functions are required for the optical element holding means such as the light source holder 103. For example, when the optical element holding unit is heated by the heat of the light source or the heat of the control unit that performs power control of the light source 102 and the optical element holding unit is thermally expanded, the optical element held by the optical holding unit is inclined, There is a possibility that desired optical characteristics cannot be obtained. Accordingly, the optical element holding means is required to have a function that hardly causes thermal expansion. The optical element holding means holds an optical element that does not transmit light, such as a reflection mirror. There is also a demand for a function capable of easily bonding the optical element that does not transmit light to the optical element holding means. In some cases, the optical holding means is also required to have heat dissipation. When the optical element holding means such as the light source holder 103 is formed by a single member, it is difficult to satisfy all these functions. For example, when the optical element holding member is required to have a function that is difficult to thermally expand, a resin material to which glass or mica is added is used as the resin material of the optical element holding member. It is not possible to obtain a function that can be easily bonded with an ultraviolet curable resin.
However, in (Aspect 1), by having a plurality of optical element holding members, the optical elements held by the optical element holding member and the functions required according to the place where they are arranged can be individually satisfied. Thereby, a plurality of functions required as an optical element holding means such as the light source holder 103 can be satisfied.

(Aspect 2)
In (Aspect 1), the resin materials of the optical element holding members were made different from each other.
As described in the embodiment, a resin material that satisfies the function required for each optical element holding member (in this embodiment, the second holder 103a that is required to have a function of suppressing thermal expansion is a resin having a low thermal expansion coefficient. The first holder 103a, which is required to have a function of easily bonding an optical element with an ultraviolet curable resin, is required to be used as an optical element holding means such as the optical holder 103. A plurality of functions can be satisfied.

(Aspect 3)
In (Aspect 1) or (Aspect 2), at least one of the plurality of optical element holding members is formed of a transparent resin, and is held by an optical element holding member such as the first holder 103a formed of a transparent resin. The optical elements (in this embodiment, the aperture mirror 107 and the detection reflection mirror 108A) are bonded and fixed to the optical element holding member with a photo-curing resin.
With such a configuration, as described in the embodiment, light such as ultraviolet rays can be irradiated to a photocurable resin such as an ultraviolet curable resin via an optical element holding member such as the first holder 103a. Accordingly, the optical element can be easily bonded and fixed to the optical element holding member with the photo-curing resin.

(Aspect 4)
In (Aspect 3), the photocurable resin is an ultraviolet curable resin.
With this configuration, as described in the embodiment, the optical element can be bonded and fixed to the optical element holding member by irradiating ultraviolet rays through the optical element holding member such as the first holder.

(Aspect 5)
In any one of (Aspect 1) to (Aspect 4), the plurality of optical elements held by the optical element holding means such as the light source holder 103 include a light splitting element such as an aperture mirror 107 that splits light from the light source 102, and An optical element such as a detection reflection mirror 108A for guiding one light split by the light splitting element to a light quantity detection unit such as a photodiode 109 that detects the light quantity. A first holding member such as a first holder 103a made of a transparent resin material that holds the light splitting element and an optical element that guides the light amount to a light amount detection unit that detects the amount of light, and a resin material that holds the remaining optical elements. A second optical element holding member.
With this configuration, the light splitting element such as the aperture mirror 107 held by the first holding member such as the first holder 103a, and the photodiode 109 that detects the amount of light of one light split by the light splitting element. An optical element such as the detection reflection mirror 108A for guiding the light amount to the light amount detection unit can be bonded and fixed with an ultraviolet curable resin or the like.

(Aspect 6)
In (Aspect 5), the light splitting element is an aperture mirror 107 that has a light incident surface on which light from the light source 102 is incident as a reflecting surface, shapes a part of the light from the light source 102, and reflects the rest. The optical element for guiding the light amount to the light amount detection unit such as the photodiode 109 that detects the light amount is a reflection mirror 108A that reflects the light reflected by the reflection surface of the aperture mirror 107 toward the light amount detection unit.
With this configuration, as described in the embodiment, the aperture mirror 107 and the reflection mirror 108A can be bonded and fixed with an ultraviolet curable resin or the like.

(Aspect 7)
In any one of (Aspect 1) to (Aspect 6), the optical element holding means such as the light source holder 103 includes a first optical element holding member such as the first holder 103a and a light source side from the first optical element holding member. The second optical element holding member such as the second holder 103b disposed in the second optical element holding member, and the thermal expansion coefficient of the second optical element holding member is lower than the thermal expansion coefficient of the first optical element holding member.
By providing such a configuration, as described in the embodiment, it is possible to suppress thermal expansion of the second optical element holding member such as the second holder 103b due to heat of the light source 102 or the like. Accordingly, it is possible to suppress problems such as the optical element held by the second optical element tilting due to the thermal expansion of the second optical element holding member, and desired optical characteristics cannot be obtained.

(Aspect 8)
In (Aspect 7), a material having a lower thermal expansion coefficient than that of the resin material is added to the second optical element holding member such as the second holder 103b.
With this configuration, as described in the embodiment, the coefficient of thermal expansion of the second optical element holding member such as the second holder 103b can be lowered.

(Aspect 9)
In (Aspect 1) to (Aspect 8), the optical element holding means such as the light source holder includes a first optical element holding member such as the first holder 103a and a first optical element holding member disposed closer to the light source than the first optical element holding member. The second optical element holding member such as the two holder 103b is provided, and the thermal conductivity of the second optical element holding member is higher than the thermal conductivity of the first optical element holding member.
By providing such a configuration, as described in the embodiment, the heat of the light source 102 can be moved to the second optical element holding member such as the second holder 103b, and the temperature rise of the light source 102 is suppressed. Can do. Thereby, it is possible to suppress the deterioration of the beam characteristics due to the temperature rise of the light source 102.

(Aspect 10)
In (Aspect 9), a material having a higher thermal conductivity than the resin material is added to the second optical element holding member such as the second holder 103b.
By providing this configuration, as described in the embodiment, the thermal conductivity of the second optical element holding member such as the second holder 103b can be increased.

(Aspect 11)
In any one of (Aspect 1) to (Aspect 10), a light source in which a plurality of light emitting units are two-dimensionally arranged is used as the light source 102.
With this configuration, high-resolution printing is possible as described in the embodiment.

(Aspect 12)
In any one of (Aspect 1) to (Aspect 10), a light source in which a plurality of light emitting units are linearly arranged is used as the light source 102.
Even with this configuration, high-resolution printing is possible.

(Aspect 13)
In any one of (Aspect 1) to (Aspect 12), the light source 102 includes a plurality of laser diodes waiting for one or more light emitting units.
With this configuration, as described in the embodiment, high-resolution printing is possible.

(Aspect 14)
In the optical scanning device 100 including the light source unit 101 and light deflecting means such as the deflector 202 that deflects and scans the light from the light source unit 101, the light source unit 101 is any one of (Aspect 1) to (Aspect 13). A light source device was used.
By providing such a configuration, an inexpensive optical scanning device can be realized.

(Aspect 15)
The optical scanning device scans a photosensitive member such as a photosensitive drum with scanning light according to the image information, forms a latent image on the photosensitive member, and finally develops the image obtained by developing the latent image on the recording material. In the image forming apparatus that forms an image on the recording material by transferring to the optical material, the optical scanning apparatus of (Aspect 14) was used as the optical scanning apparatus.
By providing such a configuration, an inexpensive image forming apparatus can be realized.

DESCRIPTION OF SYMBOLS 100 Optical scanning device 101 Light source unit 102 Light source 103 Light source holder 103a 1st holder 103b 2nd holder 104 Laser modulation board | substrate 105 1/4 wavelength plate 106 Collimating lens 107 Aperture mirror 108 Detection optical system 108A Detection reflective mirror 108B Detection collimating lens 109 Photodiode 110 Fixing member 113a Fixing surface portion 113b Aperture mounting surface portion 113c Mirror mounting surface portion 114 Screw insertion holes 115a and 115b Positioning hole 202 Deflector 202a Upper rotating polygon mirror 202b Lower rotating polygon mirror 203 Deflection beam splitter 204 1/4 wavelength plate 205 Cylindrical lenses 301 and 302 Exit lenses 303a, 303b, 303c, and 304 Mirror 305 Dust-proof glass 400 Optical housing 401 V-shaped recess 40 2 Arc-shaped concave portion 500 Color printer 501, 502, 503, 504 Photosensitive drum 510 Recording paper 606 Intermediate transfer belt

JP 2011-48222 A

Claims (12)

A light source;
In a light source device comprising an optical element holding means for holding a plurality of optical elements arranged on an optical path of light emitted from the light source,
The optical element holding means is
A light splitting element for splitting light from the light source;
An optical element for guiding one light split by the light splitting element to a light quantity detection unit for detecting the light quantity;
A partition wall that blocks an incident path to the light amount detection unit of the other light divided by the light splitting element;
A first optical element holding member made of a transparent resin material that holds the light splitting element and an optical element for guiding the light quantity to a light quantity detection unit that detects the light quantity;
A second optical element holding member made of a non-transparent resin material on which the partition wall is formed,
At least one of the optical elements held by the first optical element holding member is adhesively fixed to the first optical element holding member with a photo-curing resin. The light source device according to claim 1.
The light source device, wherein the photocurable resin is an ultraviolet curable resin. The light source device according to claim 1 or 2,
The light splitting element is an aperture mirror on which an incident surface on which light from the light source is incident is a reflective surface, and a part of the light from the light source is shaped and transmitted, and the rest is reflected.
The light source device , wherein the optical element for guiding the light amount to the light amount detection unit is a reflection mirror that reflects the light reflected by the reflection surface of the aperture mirror so as to travel toward the light amount detection unit. . The light source device according to any one of claims 1 to 3,
The second optical element holding member is disposed closer to the light source than the first optical element holding member,
The light source device, wherein a thermal expansion coefficient of the second optical element holding member is lower than a thermal expansion coefficient of the first optical element holding member. The light source device according to claim 4.
A light source device characterized in that a material having a lower thermal expansion coefficient than a resin material is added to the second optical element holding member. The light source device according to any one of claims 1 to 5,
The second optical element holding member is disposed closer to the light source than the first optical element holding member,
The light source device characterized in that the thermal conductivity of the second optical element holding member is higher than the thermal conductivity of the first optical element holding member. The light source device according to claim 6.
The light source device, wherein the second optical element holding member is added with a material having a higher thermal conductivity than a resin material. The light source device according to claim 1,
A light source device using a light source in which a plurality of light emitting units are two-dimensionally arranged as the light source. The light source device according to claim 1,
A light source device using a light source in which a plurality of light emitting portions are arranged in a straight line as the light source. The light source device according to claim 8 or 9,
The light source comprises a plurality of laser diodes waiting for one or more light emitting units. In an optical scanning device comprising a light source unit and light deflecting means for deflecting and scanning light from the light source unit,
An optical scanning device using the light source device according to claim 1 as the light source unit. The photosensitive member is scanned with scanning light according to the image information to form a latent image on the photosensitive member, and the latent image is developed to finally transfer the image onto the recording material. In an image forming apparatus for forming an image on the recording material,
An image forming apparatus using the optical scanning device according to claim 11 as the optical scanning device.

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