Abstract:
A lens-mounting structure according to the present invention is a lens mounting structure that glues a lens and a mounting surface of a support portion that supports the lens using an adhesive agent applied there between, to mount the lens to the support portion, characterized by setting a gluing surface area of the mounting surface of the support portion and the adhesive agent to be smaller than a gluing surface area of the lens and the adhesive agent.

Description:
This application is based on and claims the benefit of priority from Japanese Patent Application No. 2010-103012, filed on 28 Apr. 2010, the content of which is incorporated herein by reference. 
     BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates to a lens-mounting structure that mounts a lens to a support portion using an adhesive agent, an optical-scanning apparatus that optically scans an image carrier, and an image-forming apparatus such as a copier, or printer and the like. 
     2. Related Art 
     In an image-forming apparatus such as a copier or printer and the like, an image carrier uniformly electrostatically charged by a charging device is optically scanned by an optical-scanning apparatus to form on a surface of the image carrier an electrostatic latent image that corresponds to image information. 
     Here, the optical-scanning apparatus is composed of a scanning optical system, installed in a frame, equipped with a deflector, such as a polygon mirror that deflects a light beam radiated from a light source, a scanning lens such as an fθ lens that converts the light beam deflected by the deflector into constant speed scanning light, and a plurality of reflective mirrors that guide the constant speed scanning light back onto a photoreceptor. 
     In this optical-scanning apparatus, a scanning lens is attached and installed in a housing support portion by adhesive. However, a problem existed in that desired optical characteristics could not be attained because of changes in a lens position caused by lens displacement associated with shrinkage that occurs because of adhesive agent hardening. 
     A lens-mounting structure has been proposed to reduce lens mounting direction displacement that occurs when the adhesive agent contracts, by forming a projection on a top surface of a support column of a mounting base and supporting the lens on the projection, and gluing a surface of the projection, and the peripheral portion of the contact portion with the top surface of the support column post and projection on the lens. 
     SUMMARY OF THE INVENTION 
     However, with the lens-mounting structure described above, attention was only paid to changes in lens orientation; measures were not implemented for stress that develops in the lens caused by contraction associated with adhesive agent hardening. For that reason, when the adhesive agent hardens, stress is generated in locations where the projection of the support column and the lens touch, so it is not possible to prevent the problem of changes in lens refractive index caused by hardening of optical elasticity. Localized changes in the lens refractive index occur only near the locations where the projection of the support column and lens touch. For that reason, localized changes occur in the imaging position of the light beam on the image carrier, so high-precision exposure scanning on the image carrier is not attained. This results in the problem of the system not obtaining high-quality images. 
     An object of the present invention is to provide a lens-mounting structure that reduces changes in lens orientation and stress developed with a lens, and maintains high-optical lens characteristics, an optical-scanning apparatus capable of attaining high-precision optical scanning and an image-forming apparatus that attains stable, and high-quality images. 
     The present invention includes; a lens mounting structure that glues a lens and a mounting surface of a support portion that supports the lens using an adhesive agent applied therebetween, to mount the lens to the support portion, characterized by setting a gluing surface area of the mounting surface of the support portion and the adhesive agent to be smaller than a gluing surface area of the lens and the adhesive agent. 
     The present invention sets a gluing surface area for the support portion mounting surface and adhesive agent to be smaller than the gluing surface area of a lens and adhesive agent. For that reason, it is possible to reduce stress that develops near the lens support portion mounting surface that is caused by adhesive contraction that is associated with adhesive agent hardening. Furthermore, the present invention prevents localized changes in the lens refractive index caused by optical elasticity and changes in lens orientation, which ensures high-optical characteristics of the lens. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a lateral sectional view of an image-forming apparatus (color-laser printer) according to an embodiment of the present invention; 
         FIG. 2  is a plan view showing a cover of the optical-scanning apparatus according to the present invention, removed; 
         FIG. 3  is a fragmentary perspective view of an optical-scanning apparatus frame that composes a lens-mounting structure according to a first embodiment of the present invention; 
         FIG. 4  is a lateral view showing the lens-mounting structure according to the first embodiment of the present invention; 
         FIG. 5  is a plan view of a first-imaging lens that composes the lens-mounting structure according to the first embodiment of the present invention; 
         FIG. 6  is a perspective view showing a different configuration of the support portion that composes the lens-mounting structure according to the first embodiment of the present invention; 
         FIG. 7A  is a graph showing changes in a light beam diameter, before and after gluing, that passes near a lens base level, in a conventional lens-mounting structure, with regard to a position in a light axis direction; 
         FIG. 7B  is a graph showing changes in an light beam diameter, before and after gluing, that passes near a lens base level, in the lens-mounting structure according to the present invention, with regard to a position in a light axis direction; 
         FIG. 8  is a fragmentary perspective view of an optical-scanning apparatus frame that composes a lens-mounting structure according to a second embodiment of the present invention; 
         FIG. 9  is a lateral view showing the lens-mounting structure according to the second embodiment of the present invention; 
         FIG. 10  is a plan view of a first-imaging lens that composes the lens-mounting structure according to the second embodiment of the present invention; 
         FIGS. 11A and 11B  are perspective views showing different configurations of the support portion that composes the lens-mounting structure according to the second embodiment of the present invention; and 
         FIG. 12  is a graph showing changes of a light beam diameter that passes near a lens base level, in a lens-mounting structure according to the second embodiment of the present invention, in an light axis direction position. 
     
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     Preferred embodiments of the present invention will now be described based on the drawings provided. 
     [Image-Forming Apparatus] 
       FIG. 1  is a lateral sectional view of a color-laser printer as one embodiment of an image-forming apparatus according to the present invention. The color-laser printer depicted in the drawing is a tandem-type apparatus. A magenta-image-forming unit  1 M, a cyan-image-forming unit  1 C, a yellow-image-forming unit  1 Y, and a black-image-forming unit  1 BK are disposed in tandem at regular spacings in a central location of a main unit  100  of the color-laser printer. 
     Photosensitive drums  2   a ,  2   b ,  2   c , and  2   d  that are image carriers are each disposed at each image-forming units  1 M,  1 C,  1 Y, and  1 BK. Charging devices  3   a ,  3   b ,  3   c , and  3   d , developing devices  4   a ,  4   b ,  4   c , and  4   d , transfer rollers  5   a ,  5   b ,  5   c , and  5   d , and drum cleaning devices  6   a ,  6   b ,  6   c , and  6   d  are each disposed in areas around each of the photosensitive drums  2   a ,  2   b ,  2   c  and  2   d.    
     Here, the photosensitive drums  2   a ,  2   b ,  2   c  and  2   d  are drum-shaped photoreceptors. They are rotationally driven by a drive motor, not shown, at a predetermined processing speed in a direction of arrows (clockwise direction) in the drawing. Also, the charging devices  3   a - 3   d  uniformly charge a surface of the photosensitive drums  2   a - 2   d  to a predetermined potential using a charged bias charged from charging bias power supply, not shown. 
     Furthermore, the developers  4   a - 4   d  contain magenta (M) toner, cyan (C) toner, yellow (Y) toner, and black (BK) toner. The developers  4   a - 4   d  adhere a toner of each color to each electrostatic latent image formed onto each of the photosensitive drums  2   a - 2   d  to visually develop each electrostatic latent image as a toner image of each color. 
     Also, the transfer rollers  5   a - 5   d  are disposed to be able to touch the photosensitive drums  2   a - 2   d  interposed by an intermediate transfer belt  7 , at each primary transfer unit. The intermediate transfer belt  7  is trained between a drive roller  8  and tension roller  9 , and disposed to be able to travel at an upper surface side of photosensitive drums  2   a - 2   d . The drive roller  8  is disposed to be able to touch a secondary transfer roller  10  interposed by an intermediate transfer belt  7 , at a secondary transfer unit. Also, a belt cleaning device  11  is established near the tension roller  9 . 
     Toner containers  12   a ,  12   b ,  12   c , and  12   d  are disposed in parallel in a line to refill toner to each developer  4   a - 4   d , above each image-forming unit  1 M,  1 C,  1 Y, and  1 BK in the printer main unit  100 . 
     Also, two optical scanning apparatuses  13  are disposed in parallel to a paper conveyance direction below each image-forming unit  1 M,  1 C,  1 Y, and  1 BK in the printer main unit  100 . A paper cassette  14  is detachably disposed in the printer main unit  100 , at a bottom portion of the printer main unit  100  which is a bottom side of the optical scanning apparatus  13 . A plurality of sheets of paper, not shown, is stacked and stored in the paper cassette  14 . A pickup roller  15  that kicks out paper from the paper cassette  14 , a feed roller  16  and a retard roller  17  that separate kicked out paper and feed one sheet of paper at a time to a conveyance path L are disposed near the paper cassette  14 . 
     Also, a conveyance roller pair  18  that conveys paper and a resist roller pair  19  are disposed in the conveyance path L that extends in up and down directions of the printer main unit  100 . The resist roller pair  19  supplies paper at a predetermined timing after having made the paper to temporarily standby, to the secondary transfer unit which is a touching portion of the secondary transfer roller pair  8  and secondary transfer roller  10 . A separate conveyance path L′ is formed next to the conveyance path L, to be used when forming images on both sides of paper. A plurality of turn-over roller pairs  20  is disposed at appropriate intervals in a conveyance path L′. 
     However, the conveyance path L disposed in a longitudinal direction at one side of the printer main unit  100  extends up to a discharge tray  21  established at a top surface of the printer main unit  100 . A fixing device  22  and discharge roller pair  23 ,  24  are established partway in the conveyance path L. 
     Image-forming operations using a color-laser printer having the configuration above will now be described. 
     When an image-forming starting signal is issued, each photosensitive drum  2   a - 2   d  is rotationally driven at a predetermined processing speed in a direction of arrows (clockwise direction) shown in the drawing, in each image-forming unit  1 M,  1 C,  1 Y, and  1 BK. These photosensitive drums  2   a - 2   d  are uniformly charged by the charging devices  3   a - 3   d . Furthermore, each optical-scanning apparatus  13  emits a light beam modulated according to a color image signal of each color to irradiate the light beams onto a surface of each photosensitive drum  2   a - 2   d  thereby forming on each photosensitive drum  2   a - 2   d  an electrostatic latent image that corresponds to a color-image signal of each color. 
     First, the developer  4   a  charged with a developer bias having the same polarity as the charged polarity of the photosensitive drum  2   a  attaches magenta toner to an electrostatic latent image formed on the photosensitive drum  2   a  in the magenta image-forming unit  1 M. This visually develops the electrostatic latent image as a magenta toner image. This magenta toner image is primarily transferred at the primary transfer unit (transfer nipping portion) between the photosensitive drum  2   a  and transfer roller  5   a  onto the intermediate transfer belt  7  rotationally driven in a direction of the arrows in the drawing, by an action of the transfer roller  5   a  charged with a primary transfer bias of a polarity opposite to that of the toner. 
     Next, the intermediate transfer belt  7  onto which the magenta toner image is primarily transferred as described above moves to the cyan image-forming unit  1 C. Then, at the cyan image-forming unit  1 C, in the same way as described above, the cyan toner image formed on the photosensitive drum  2   b  is transferred onto the intermediate transfer belt  7  overlapping the magenta toner image at the primary transfer unit. 
     Below, in the same way, yellow and black toner images each formed on photosensitive drums  2   c  and  2   d  of the yellow and black image-forming units  1 Y and  1 BK are formed sequentially overlapping magenta and cyan toner images on the intermediate transfer belt  7 . In this way, a full-color toner image is formed on the intermediate transfer belt  7 . Residual transfer toner on each photosensitive drum  2   a - 2   d  that is not transferred to the intermediate transfer belt  7  is removed by each drum cleaning device  6   a - 6   d . Then, each photosensitive drum  2   a - 2   d  is ready for forming a next image. 
     Paper is then fed from the paper cassette  14  to the conveyance path L by the pickup roller  15 , the feed roller  16  and the retard roller  17 , to match a timing for the leading edge of a full-color toner image on the intermediate transfer belt  7  to reach the secondary transfer position (the nipping portion) between the drive roller  8  and the secondary transfer roller  10 . Also, paper is conveyed by the resist roller pair  19  to the secondary transfer portion. Then, the full-color toner image is secondarily transferred at one time from the intermediate transfer belt  7  to the paper conveyed to the secondary transfer position, by secondary transfer roller  10  that is charged with a secondary transfer bias having a polarity opposite to that of the toner. 
     In this way, paper transferred with the full-color toner image is conveyed to the fixing device  22 . The full-color toner image is heated and compressed thereby being heat-fused to a surface of the paper. Paper onto which the toner image is fixed is then discharged by discharge roller pair  23 ,  24  to the discharge tray  21 . This completes a series of image-forming operations. Residual transfer toner on the intermediate transfer belt  7  that is not transferred to paper is removed by the belt cleaning device  11 . With this, the intermediate transfer belt  7  is ready for forming a next image. 
     [Optical-Scanning Apparatus] 
     The optical-scanning apparatus  13  according to the present invention will now be explained with reference to  FIG. 2 . 
       FIG. 2  is a plan view showing a cover of the optical-scanning apparatus according to the present invention, removed. As shown in  FIG. 1 , two optical-scanning apparatuses  13 , shown in  FIG. 2 , are juxtaposed in the color-laser printer shown in  FIG. 1 . However, because both apparatuses have the same configuration, only one optical-scanning apparatus  13  will be described. 
     The optical-scanning apparatus  13  has a frame  25  formed into one body using resin. An inside of the frame  25  is sectioned into a top and a bottom by a horizontal partition plate  25 A. Also, a polygon mirror  26 , which is a deflector, is disposed at a central portion in a width direction (left and right directions of  FIG. 2 ) of a top surface of the partition plate  25 A of the frame  25 . Two scanning-optical systems  30 ,  40 , are disposed in the frame  25  symmetrically on both sides thereof, centering on the polygon mirror  26 . Also, a pair of laser diodes  31 ,  41  that is a light source that corresponds to the scanning-optical systems  30 ,  40 , and a pair of cylindrical lenses  32 ,  42  are each disposed at a left and a right side of a top portion of the partition plate  25 A of the frame  25 , with a central line in a width direction as a boundary. 
     At a top surface of the partition plate  25 A of the frame  25 , each of the scanning-optical systems  30 ,  40  is equipped with first-imaging lenses  33 ,  43 , second-imaging lenses  34 ,  44  and first-reflective mirrors  35 ,  45 , disposed along a light beam advancing direction. At a bottom surface of the partition plate  25 A, each of the scanning-optical systems  30 ,  40  is equipped with a second reflective mirror and a third reflective mirror, not shown, disposed along the light beam advancing direction. 
     Also, light beam that is emitted from laser diodes  31 ,  41  disposed in each scanning-optical system  30 ,  40 , in one optical-scanning apparatus  13  is incident from two symmetrical directions onto the polygon mirror  26  that is rotationally driven, after being converged into a linear luminous flux by cylindrical lenses  32 ,  42 . 
     Each light beam incident to the polygon mirror  26  as described above is converted into constant speed scanning light by passing through the first-imaging lenses  33 ,  43  and the second-imaging lenses  34 ,  44 , after being deflected by the polygon mirror  26 . Also, the constant speed scanning light is reflected back at a right angle toward a downward direction by the first reflective mirrors  35 ,  45 , reaches the second reflective mirror, not shown, passing through an aperture, not shown, formed in partition plate  25 A; the constant speed scanning light is then reflected back at a right angle by the second reflective mirror to advance horizontally along a bottom surface of the partition plate  25 A. Then, the constant speed scanning light is reflected back at a right angle by the third reflective mirror, not shown, and passes through an aperture, not shown, formed in a cover that covers a top surface of the partition plate  25 A and the frame  25 . Also, the constant speed scanning light is directed toward the photosensitive drums  2   a ,  2   b  (see  FIG. 1 ) and scans to expose the photosensitive drums  2   a ,  2   b.    
     As shown in  FIG. 2 , one optical-scanning apparatus  13  scans to expose the photosensitive drum  2   a  of the magenta-image forming unit  1 M and the photosensitive drum  2   b  of the cyan-image forming unit  1 C shown in  FIG. 1 . Two optical-scanning apparatuses  13  having the same configuration as that described above are juxtaposed in the color-laser printer main unit  100  shown in  FIG. 1 . These two optical-scanning apparatuses  13  scan to expose all four photosensitive drums  2   a - 2   d  including the photosensitive drum  2   c  of the yellow-image forming unit  1 Y and the photosensitive drum  2   d  of the black-image forming unit  1 BK to a light beam. 
     [Lens-Mounting Structure] 
     Next, an embodiment of a mounting structure for the first-imaging lens  33  as the lens-mounting structure according to the present invention will be explained. Note that the mounting structures for both first-imaging lens  33 ,  43  are the same. Therefore, only the first-imaging lens  33  mounting structure will be explained. 
     First Embodiment 
       FIG. 3  is a fragmentary perspective view of an optical-scanning apparatus frame that composes a lens-mounting structure according to a first embodiment of the present invention.  FIG. 4  is a lateral view showing the lens-mounting structure according to the first embodiment of the present invention.  FIG. 5  is a plan view of the first-imaging lens that composes the lens-mounting structure according to the first embodiment of the present invention.  FIG. 6  is a perspective view showing different configurations of the support portion that composes the lens-mounting structure according to the first embodiment of the present invention. 
     Three cylindrical positioning projections  50  are vertically arranged, as shown in  FIG. 3 , on a top surface of the partition plate  25 A on the frame  25  of the optical-scanning apparatus  13  shown in  FIG. 2 . Two sets of support portions  51 , one set thereof composed of three vertically arranged cylindrical projections  51 A, are disposed between these positioning projections  50 . 
     Also, as shown in  FIG. 4 , the first-imaging lens (hereinafter simply referred to as lens)  33  is placed horizontally on these three positioning projections  50 . The lens  33  is mounted to the frame  25  by gluing two locations of a bottom surface of the lens to a top surface of the two sets of support portions  51  using adhesive agent  52 . A top surface of each positioning projection  50  (surface that touches the lens) composes a reference surfaces  50   a . A top surface of each of the three cylindrical projections  51 A, which compose each support portion  51 , composes a mounting surface  51   a . Heights of these cylindrical projections  51 A are set to be lower than heights of each positioning projection  50 , by an application thickness (δ) of the adhesive agent  52 . Note that for the adhesive agent  52 , a photo-curable resin is used. 
     Here, as shown in  FIG. 5 , each of the three cylindrical projections  51 A that compose the two sets of support portions  51  is disposed at each apex of an equilateral triangle in a plan view. The gluing surface area (the sum of the surface areas of the mounting surfaces  51   a  of each of the three cylindrical projections  51 A) of the mounting surface  51   a  of each support portion  51  and the adhesive agent  52  is set to be smaller than the gluing surface area of the lens  33  and the adhesive agent  52 , shown with the dashed line in  FIG. 5 . More specifically, if a surface area of the mounting surface  51   a  of the three cylindrical projections  51 A of each support portion  51  is S 1 , and a gluing surface area of the lens  33  and adhesive agent  52  is S, the following relationship is established.
 
3× S 1 &lt;S   (1)
 
     Note that as another configuration that satisfies the above relationship (1), it is acceptable to compose each support portion  51  as one cylindrical projection  51 A, and to form a circular hole  53  in the mounting surface  51   a  of the cylindrical projection  51 A, as shown in  FIG. 6 . 
     In this way, with this embodiment, the gluing surface area of the mounting surface  51   a  of the support portion  51  and the adhesive agent, as described above, is set to be smaller than the gluing surface area of the lens  33  and adhesive agent  52 . For that reason, stress is reduced that developed near the mounting surfaces  51   a  of each support portion  51  (near each mounting surface  51   a  of the three cylindrical projections  51 ) of the lens caused by shrinkage associated with hardening of the adhesive agent  52 . Also, localized refractive index changes of the lens  33  and orientation changes of the lens  33  caused by optical elasticity are prevented and high-optical characteristics of the lens  33  are ensured. The result is that problems such as localized changes in the light beam imaging position on the photosensitive drums  2   a ,  2   b  (see  FIG. 1 ) using the optical-scanning apparatus  13  shown in  FIG. 2  do not occur. Furthermore, high-precision optical scanning of photosensitive drums  2   a ,  2   b  is possible. For that reason, problems such as an image being out of color registration do not occur in the color-laser printer shown in  FIG. 1  that is equipped with two of such optical-scanning apparatuses  13 . Therefore, high-quality, full-color images can be obtained in a stable manner. 
       FIG. 7A  is a graph showing changes in a light beam diameter [μm], before and after gluing, that passes near a lens base level, in a conventional lens-mounting structure, with regard to position [mm] in a light axis direction;  FIG. 7B  is a graph showing changes in an light beam diameter [μm], before and after gluing, that passes near a lens base level, in the lens-mounting structure according to the present invention, with regard to position [mm] in a light axis direction. 
     According to results, shown in  FIG. 7A , of using the conventional lens-mounting structure, lens stress caused by adhesive hardening and shrinkage is not reduced; changes occurred in the imaging position before and after the lens is glued. According to results, shown in  FIG. 7B , of using the lens-mounting structure according to the present invention, lens  33  stress caused by adhesive  52  hardening and shrinkage is adequately reduced, so no change occur in the imaging position before and after the lens is glued. In this way, the effect of this invention is verified. 
     Second Embodiment 
     Next, a second embodiment of the lens-mounting structure according to the present invention will now be described. 
       FIG. 8  is a fragmentary perspective view of an optical-scanning apparatus frame that composes a lens-mounting structure according to a second embodiment of the present invention.  FIG. 9  is a lateral view showing the lens-mounting structure according to the second embodiment of the present invention.  FIG. 10  is a plan view of the first-imaging lens that composes the lens-mounting structure according to the second embodiment of the present invention.  FIGS. 11A and 11B  are perspective views showing different configurations of the support portion that composes the lens-mounting structure according to the second embodiment of the present invention. Elements in these drawings that are the same as those shown in  FIGS. 3-6  have the same symbols. Therefore, descriptions of those elements will be omitted from the description below. 
     With the second embodiment, two support portions  51  are composed as one cylindrical projection. Three round holes  54  are formed in each mounting surface  51   a  of each support portion  51 . In this way, by forming three round holes  54  in the mounting surface  51   a  of each support portion  51 , in the same way as described the first embodiment, the gluing surface area (S−S′) of the mounting surfaces  51   a  (excluding the three round holes  54 ) of each support portion  51  and adhesive agent  52  is set to be smaller than the gluing surface area (shaded surface area S in  FIG. 10 ) of the lens  33  and adhesive agent  52  ((S−S′)&lt;S). 
     Also, with the second embodiment, the sum of the peripheral length of each round hole  54  formed in the mounting surface  51   a  of the support portion  51  is set to be at least ½ of the outer peripheral length of the gluing surface of the lens  33  and adhesive agent  52 . More specifically, if the peripheral length of each round hole  54  is a 1 , and the outer peripheral length (outer peripheral length of the support portion  51 ) is a, the following relationship is established.
 
3× a 1 ≧a/ 2  (2)
 
     Note that as another configuration that satisfies the above relationship (2), it is acceptable to adopt a configuration that forms three round holes  54  of the mounting surface  51   a  of the support portions  51  composed of prismatic projections as shown in  FIG. 11A , or to adopt a configuration that forms three square holes  55  in the mounting surfaces  51   a  of the support portion  51  composed of cylindrical projections as shown in  FIG. 11B . 
     Also, with this embodiment, the gluing surface area of the adhesive agent  52  and mounting surface  51   a  of the support portion  51  described above is set to be smaller than the gluing surface area of the adhesive agent  52  and lens  33 , and the sum of the peripheral length of each round hole  54  formed in the mounting surface  51   a  of the support portion  51  is set to be at least ½ of the outer peripheral length of the gluing surface of the lens  33  and adhesive agent  52 . For that reason, stress is reduced that developed near the mounting surface  51   a  of each support portion  51  of the lens  33  caused by shrinkage associated with hardening of the adhesive agent  52 . Also, localized refractive index changes of the lens  33  and orientation changes of the lens  33  caused by optical elasticity are effectively prevented and high-optical characteristics of the lens  33  are ensured. The result is that problems such as localized changes in the light beam imaging position on the photosensitive drums  2   a ,  2   b  (see  FIG. 1 ) using the optical-scanning apparatus  13  shown in  FIG. 2  do not occur, and high-precision optical scanning of photosensitive drums  2   a ,  2   b  is possible. For that reason, problems such as an image being out of color registration do not occur in the color-laser printer shown in  FIG. 1  that is equipped with two of such optical-scanning apparatuses  13 , and high-quality full-color images can be obtained in a stable manner. 
     Here,  FIG. 12  is a graph showing changes in an light beam diameter [μm], before and after gluing, that passes near a base level of the lens  33 , when the sum of the peripheral length of each round hole  54  formed in the mounting surface  51   a  of each support portion  51 , and outer peripheral length of the gluing surface of the lens  33  and adhesive agent  52  are equal, with regard to an light axis direction position [mm]; According to results shown in  FIG. 12 , it is clear that stress caused to the lens  33  by adhesive  52  hardening and shrinkage is adequately reduced, and that no changes develop in the imaging position before and after the lens is glued. 
     The description of the present invention above related to an embodiment that is adopted for a first-imaging lens mounting structure in color-laser printer, and an optical-scanning apparatus equipped with the same, and an optical-scanning apparatus. However, the description is not to be construed as a limitation of the present invention. The present invention can also be applied to a lens-mounting structure equipped on any other color image forming apparatus, optical-scanning apparatus equipped with the same, and the optical-scanning apparatus described above. Furthermore, the present invention can also be applied to a lens-mounting structure equipped on any apparatus other than an optical-scanning apparatus.