JP2005215369A - Solid-state imaging device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a solid-state imaging device constituted of a plurality of lenses and inexpensively ensuring the performance of a product and the stability of quality by eliminating the influence of the fine variance in dimension and material density when molded and the influence of deviation in an optical axis. <P>SOLUTION: The solid-state imaging device has a plurality of lenses A and B for forming an image on a solid-state imaging device, a lens holder 14 with which the lenses A and B are covered, a spacer 16 or a diaphragm put between the lenses A and B, and a lens cap 18 for fixing the lenses A and B, and is fixed by screwing a screw part 12b formed on the outside of the lens holder 14 with a screw part formed on the inside of a base 12. In the solid-state imaging device, by arranging a slit part on the lens holder 14 and utilizing a D-cut shape part, a gate part or a shape part recessed more than an outer periphery diameter at the outer periphery part of the edge of the lens B, the movement of the lens B in a rotating direction centering on an optical axis is adjusted through the slit part 14c from the outside of the lens holder 14. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a solid-state imaging device including a solid-state imaging element and a lens.

  In conventional imaging equipment such as a digital camera, a casing (base) that holds an image sensor such as a CCD and a lens barrel (lens holder) that holds an optical lens are provided as separate parts. The tube portion is screwed with a screw mechanism, and the lens is moved to adjust the focus.

  The solid-state imaging device having the above configuration is disclosed in many documents. (For example, see Patent Document 1, Patent Document 2, and Patent Document 3)

FIG. 7 is a cross-sectional view of a conventional solid-state imaging device. A solid-state imaging device 81 is mounted on the printed wiring board 80, and a base 82 is disposed so as to cover the outer periphery thereof. The base 82 is positioned and fixed so that the central axis A of the cylindrical portion 82 a at the upper portion of the base 82 matches the light receiving portion center of the solid-state imaging device 81. An optical filter 83 is bonded and fixed to the base 82. A screw portion 82 b is formed coaxially with the central axis A on the inner periphery of the cylindrical portion 82 a of the base 82. A first lens 85 for forming an image on the solid-state imaging device 81 is incorporated so that the optical axis is aligned with the central axis B of the opening 84a of the lens holder 84, and then a spacer 86 is inserted. A second lens 87 for forming an image on the solid-state imaging device 81 is incorporated so that the optical axis is aligned with the central axis B of the opening 84 a of 84. The spacer 86 is for determining the distance between the lens 85 and the lens 87. The lens 85 and the lens 87 are held by a lens cap 88, and the lens cap 88 is bonded and fixed to the lens holder 84. On the outer side of the lens holder 84, a screw portion 84b is formed coaxially with the central axis B of the opening 84a. The screw portion 84b of the lens holder 84 and the screw portion 82b of the base 82 are screwed together, and the lens holder 84 is assembled while the central axis B of the opening 84a and the central axis A of the base 82 are aligned. 85, the optical axis of the lens 86 coincides with the center of the light receiving unit of the solid-state image sensor 81. The lens holder 84 is screwed and moved to adjust the focus, and the lens holder 84 is bonded and fixed at an appropriate position.
JP 2000-196925 A (pages 2-4, 3 and 6) JP 2002006378 A (Page 2-5, Fig. 1-2) JP 2003-234927 A (page 2-4, FIG. 1)

  However, in the structure as described above, it is difficult to eliminate slight variations in the size and material density of the lens 85 and the lens 87 and the optical axis misalignment, the yield is poor, and defective products need to be reassembled or replaced. It becomes. This is very disadvantageous as a product in which stability of product performance and quality is indispensable. Solving these problems at a low cost is an important issue.

  At least a substrate to which a solid-state image sensor is attached; an optical element that improves image performance; a base that covers the outside of the solid-state image sensor; and a first lens A that forms an image on the solid-state image sensor; A similar second lens B, a lens holder that covers the lens A and the lens B, a spacer or a diaphragm that is inserted between the lens A and the lens B, and a lens that fixes the lens A and the lens B In a solid-state imaging device having a cap and screwing and fixing a screw portion formed outside the lens holder and a screw portion formed inside the base, the lens holder is provided with a slit portion, and the lens B Use the outer edge of the edge (preferably, the shape part that is recessed from the outer diameter (for example, the D-cut shape part, the gate part, the recessed part, etc. on the outer periphery of the lens B edge)) , The lens B through the slit portion from the outside of the lens holder, a solid state imaging device, characterized in that it is moved and adjusted in the rotational direction around the optical axis.

  The configuration of the lens A and the lens B is three or more, and a spacer or an aperture inserted between the lens A and the lens B is also increased in accordance with the number of lenses, and the slits provided in the lens holder are also provided on the lens. The solid-state imaging device is characterized in that the number of lenses can be increased in accordance with the number of the lenses, and the movement of the plurality of lenses in the rotation direction about the optical axis can be adjusted.

  At least a substrate to which a solid-state image sensor is attached; an optical element that improves image performance; a base that covers the outside of the solid-state image sensor; and a first lens A that forms an image on the solid-state image sensor; A similar second lens B, a lens holder that covers the lens A and the lens B, a spacer or a diaphragm that is inserted between the lens A and the lens B, and a lens that fixes the lens A and the lens B In a solid-state imaging device having a cap and screwing and fixing a screw portion formed outside the lens holder and a screw portion formed inside the base, a slit portion is provided in the lens holder, and the lens A window is provided in a part of the screw portion of the base facing the holder slit portion, and the lens holder slit portion is fixed to the base when the lens holder is screwed. A solid-state imaging device characterized in that the lens B can be moved and adjusted in the rotational direction around the optical axis using the outer periphery of the lens B edge. And

  The configuration of the lens A and the lens B is three or more, and a spacer or an aperture inserted between the lens A and the lens B is also increased in accordance with the number of lenses, and the slits provided in the lens holder are also provided on the lens. In addition, the same number of windows are provided in the screw portion of the base corresponding to the lens holder slit portion, and each slit portion of the lens holder opens the respective window of the base when the lens holder is screwed and fixed. A solid-state imaging device characterized in that a plurality of lenses can be moved and adjusted in the rotational direction around the optical axis by using the outer peripheral edge of each of the lenses. To do.

  According to the present invention, slight variations in lens dimensions and material density and optical axis misalignment can be adjusted to the best after assembly to improve product performance and quality stability. Will do.

  The time required for re-installation can be shortened and the yield can be improved, which is very advantageous in terms of cost.

  The base and / or lens holder is provided with a slit that matches the lens position.

  FIG. 1 is a cross-sectional view of a solid-state imaging device according to the present invention. A solid-state imaging device 11 is mounted on a printed wiring board 10 (the board is not limited to a printed wiring board, but is a printed board in the following embodiments), and a base 12 is provided so as to cover the outer periphery thereof. Has been placed. The base 12 is positioned and fixed so that the central axis A of the cylindrical portion 12a at the upper part of the base 12 coincides with the light receiving portion center of the solid-state imaging device 11. An optical filter 13 is bonded and fixed to the base 12. A screw portion 12b is formed coaxially with the central axis A on the inner periphery of the base 12 cylinder portion 12a.

  A lens 15 is incorporated so that the optical axis is aligned with the central axis B of the opening 14a of the lens holder 14, and then a spacer 16 is inserted so that the optical axis is aligned with the central axis B of the opening 14a of the lens holder 14. A lens 17 is incorporated. The spacer 16 is for determining the distance between the lens 15 and the lens 17. The lens 15 and the lens 17 are held by a lens cap 18, and the lens cap 18 is bonded and fixed to the lens holder 14. A screw portion 14b is formed on the outer side of the lens holder 14 coaxially with the central axis B of the opening 14a. The screw portion 14b of the lens holder 14 and the screw portion 12b of the base 12 are screwed together, and the center axis B of the opening portion 14a of the lens holder 14 and the center axis A of the base 12 are combined while being assembled, The optical axes of the lens 15 and the lens 17 coincide with the light receiving portion center of the solid-state imaging device 11. The lens holder 14 is screwed and moved to adjust the focus, and the lens holder 14 is bonded and fixed at an appropriate position. The lens holder 14 is formed with a slit portion 14 c and is opposed to a D-cut shape portion 17 a provided on the outer periphery of the edge of the lens 17. Further, a window portion 12c is formed in the cylindrical portion 12a of the base 12 at a position opposite to the slit portion 14c of the lens holder 14, and the elongated adjustment treatment is performed via the window portion 12c and the slit portion 14c. The tool 19 is hooked on the D-cut shape portion 17a and rotated around the optical axis. At this time, adjustments are made while viewing the actual image to further adjust the image performance. Finally, the window 12c of the base 12 is closed with a black adhesive (not shown) or a black fitting part (not shown) and shielded.

  FIG. 2 is also a cross-sectional view of a lens unit of a solid-state imaging device according to another embodiment of the present invention. A lens 21 is incorporated so that the optical axis is aligned with the central axis B of the opening 20a of the lens holder 20, and then a spacer 22 is inserted so that the optical axis is aligned with the central axis B of the opening 20a of the lens holder 20. A lens 23 is incorporated. The spacer 22 is for determining the distance between the lens 21 and the lens 23. The lens 21 and the lens 23 are held by a lens cap 24, and the lens cap 24 is bonded and fixed to the lens holder 20. A screw portion 20b is formed on the outer side of the lens holder 20 coaxially with the central axis B of the opening 20a. The lens holder 20 has a slit portion 20 c, which is opposed to a D-cut shape portion 23 a provided on the outer periphery of the lens 23. An elongated adjusting jig 25 is hooked on the D-cut shape portion 23a through the slit portion 20c and rotated around the optical axis. At this time, the image can be adjusted while viewing an image of a resolution projector or an evaluation image of an MTF (Modulation Transfer Function) measuring device or the like.

  FIG. 3 is a cross-sectional view of a solid-state imaging device according to the present invention. A solid-state imaging device 31 is mounted on the printed wiring board 30, and a base 32 is disposed so as to cover the outer periphery thereof. The base 32 is positioned and fixed so that the central axis A of the cylindrical portion 32 a at the upper portion of the base 32 coincides with the light receiving portion center of the solid-state imaging device 31. An optical filter 33 is bonded and fixed to the base 32. A threaded portion 32b is formed coaxially with the central axis A on the inner periphery of the base 32 cylindrical portion 32a. 2, the screw portion 20b of the lens holder 20 and the screw portion 32b of the base 32 are screwed together, and the central axis B of the lens holder 20 and the opening portion 20a and the central axis of the base 32 are combined. By incorporating A while matching, the optical axes of the lens 21 and the lens 23 coincide with the center of the light receiving portion of the solid-state image sensor 31. The lens holder 20 is screwed and moved to adjust the focus, and the lens holder 20 is bonded and fixed at an appropriate position.

  FIG. 4 is also a cross-sectional view of a lens unit of a solid-state imaging device according to another embodiment of the present invention. The first lens 41 is incorporated so that the optical axis is aligned with the central axis B of the opening 40 a of the lens holder 40, and then a spacer 42 is inserted so that the optical axis is aligned with the central axis B of the opening 40 a of the lens holder 40. A second lens 43 is incorporated so as to match. The spacer 42 is for determining the distance between the lens 41 and the lens 43. Next, the lens 45 is assembled so that the optical axis is aligned with the central axis B of the opening 40a of the lens holder 40 with the spacer 44 inserted inside the rib 45a of the third lens 45. Yes. The lens 41, the lens 43, and the lens 45 are held by a lens cap 46, and the lens cap 46 is bonded and fixed to the lens holder 40. On the outer side of the lens holder 40, a screw portion 40b is formed coaxially with the central axis B of the opening 40a. The lens holder 40 is formed with slit portions 40c and 40d, which are respectively opposed to the lens 43 and the D-cut shape portion 43a and the D-cut shape portion 45b provided on the outer periphery of the edge of the lens 45. The elongated adjusting jigs 47 and 48 are hooked on the D-cut shape portion 43a and the D-cut shape portion 45b through the slit portions 40c and 40d, respectively, and are rotated about the optical axis. At this time, adjustment can be performed while viewing an image of a resolution projector or an evaluation image of an MTF measuring device or the like. The lens 43 and the lens 45 may be adjusted alternately or simultaneously.

  FIG. 5 is also a cross-sectional view of the solid-state imaging device according to the present invention. A solid-state imaging device 51 is mounted on the printed wiring board 50, and a base 52 is disposed so as to cover the outer periphery thereof. The base 52 is positioned and fixed so that the central axis A of the cylindrical portion 52 a at the upper part of the base 52 coincides with the light receiving portion center of the solid-state image sensor 51. An optical filter 53 is bonded and fixed to the base 52. A threaded portion 52b is formed coaxially with the central axis A on the inner periphery of the base 52 cylindrical portion 52a. In the lens unit adjusted in FIG. 4, the screw portion 40b of the lens holder 40 and the screw portion 52b of the base 52 are screwed together, and the central axis B of the lens holder 40 and the opening portion 40a and the central axis of the base 52 are combined. By incorporating A while matching, the optical axes of the lens 41, the lens 43, and the lens 45 coincide with the center of the light receiving unit of the solid-state imaging device 51. The lens holder 40 is screwed and moved to adjust the focus, and the lens holder 40 is bonded and fixed at an appropriate position.

  FIG. 6 is also a cross-sectional view of a solid-state imaging device according to another embodiment of the present invention. A solid-state imaging device 61 is mounted on the printed wiring board 60, and a base 62 is disposed so as to cover the outer periphery thereof. The base 62 is positioned and fixed so that the central axis A of the cylindrical portion 62 a at the upper part of the base 62 coincides with the light receiving portion center of the solid-state image sensor 61. An optical filter 63 is bonded and fixed to the base 62. A screw portion 62b is formed coaxially with the central axis A on the inner periphery of the base 62 cylindrical portion 62a.

  A first lens 65 is incorporated so that the optical axis is aligned with the central axis B of the opening 64 a of the lens holder 64, and then a spacer 66 is inserted so that the optical axis is aligned with the central axis B of the opening 64 a of the lens holder 64. A second lens 67 is incorporated so as to match. The spacer 66 is for determining the distance between the lens 65 and the lens 67. Next, the lens 69 is assembled so that the optical axis is aligned with the central axis B of the opening 64 a of the lens holder 64 with the spacer 68 inserted inside the rib 69 a of the third lens 69. ing. The lens 65, the lens 67, and the lens 69 are held by a lens cap 70, and the lens cap 70 is bonded and fixed to the lens holder 64. On the outer side of the lens holder 64, a screw part 64b is formed coaxially with the central axis B of the opening 64a. The screw portion 64b of the lens holder 64 and the screw portion 62b of the base 62 are screwed together, and the lens holder 64 is assembled while the central axis B of the opening 64a and the central axis A of the base 62 are aligned. 65, the optical axes of the lens 67 and the lens 69 coincide with the center of the light receiving unit of the solid-state image sensor 61. The lens holder 64 is screwed and moved to adjust the focus, and the lens holder 64 is bonded and fixed at an appropriate position. The lens holder 64 is formed with slit portions 64c and 64d, which are opposed to the lens 67 and the D-cut shape portion 67a and the D-cut shape portion 69b provided on the outer periphery of the edge of the lens 69, respectively. Further, the cylindrical portion 62a of the base 62 is formed with a window portion 62c and a window portion 62d at positions corresponding to the slit portions 64c and 64d of the lens holder 64. The window portion 62c, the slit portion 64c, The elongated adjustment jigs 71 and 72 are hooked on the D-cut shape portion 67a and the D-cut shape portion 69b through the window portion 62d and the slit portion 64d, and are rotated about the optical axis. At this time, adjustments are made while viewing the actual image to further adjust the image performance. Finally, the window part 62c and the window part 62d of the base 62 are respectively closed with black adhesive (not shown) or black fitting parts (not shown) and shielded.

1 is a cross-sectional view of a solid-state imaging device showing an embodiment of the present invention. (Example 1) Sectional drawing of the lens unit of the solid-state imaging device which shows another embodiment of this invention. (Example 2) Sectional drawing of the solid-state imaging device which shows another embodiment of this invention. (Example 2) Sectional drawing of the lens unit of the solid-state imaging device which shows another embodiment of this invention. Example 3 Sectional drawing of the solid-state imaging device which shows another embodiment of this invention. Example 3 Sectional drawing of the solid-state imaging device which shows another embodiment of this invention. (Example 4) Sectional drawing of the solid-state imaging device by a prior art.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Printed wiring board 11 Solid-state image sensor 12 Base 12a Tube part 12b Screw part 12c Window part 13 Optical filter 14 Lens holder 14a Opening part 14b Screw part 14c Slit part 15 Lens 16 Spacer 17 Lens 17a D cut shape part 18 Lens cap 19 Adjustment Jig 20 Lens holder 20a Opening portion 20b Screw portion 20c Slit portion 21 Lens 22 Spacer 23 Lens 23a D-cut shape portion 24 Lens cap 25 Adjustment jig 30 Printed wiring board 31 Solid-state imaging device 32 Base 32a Tube portion 32b Screw portion 33 Optical Filter 40 Lens holder 40a Opening 40b Screw part 40c Slit part 40d Slit part 41 Lens 42 Spacer 43 Lens 43a D-cut shape part 44 Spacer 45 Lens 45a Rib 45b D Cut shape portion 46 Lens cap 47 Adjustment jig 48 Adjustment jig 50 Printed wiring board 51 Solid imaging device 52 Base 52a Tube portion 52b Screw portion 53 Optical filter 60 Printed wiring board 61 Solid imaging device 62 Base 62b Screw portion 62c Window portion 62d Window portion 63 Optical filter 64 Lens holder 64a Opening portion 64b Screw portion 64c Slit portion 64d Slit portion 65 Lens 66 Spacer 67 Lens 67a D cut shape portion 68 Spacer 69 Lens 69a Rib 69b D cut shape portion 70 Lens cap 71 Adjustment jig 72 Adjustment jig 80 Printed wiring board 81 Solid-state imaging device 82 Base 82a Tube portion 82b Screw portion 83 Optical filter 84 Lens holder 84a Opening portion 84b Screw portion 85 Lens 86 Spacer 87 Lens 88 Lens carrier Flop

Claims (5)

  At least a substrate to which a solid-state image sensor is attached; an optical element that improves image performance; a base that covers the outside of the solid-state image sensor; and a first lens A that forms an image on the solid-state image sensor; A similar second lens B, a lens holder that covers the lens A and the lens B, a spacer or a diaphragm that is inserted between the lens A and the lens B, and a lens that fixes the lens A and the lens B In a solid-state imaging device having a cap and screwing and fixing a screw portion formed outside the lens holder and a screw portion formed inside the base, the lens holder is provided with a slit portion, and the lens B Using the outer periphery of the edge, it is possible to adjust the movement of the lens B in the rotation direction about the optical axis from the outside of the lens holder through the slit portion. The solid-state imaging device according to claim.   The configuration of the lens A and the lens B is three or more, and a spacer or an aperture inserted between the lens A and the lens B is also increased in accordance with the number of lenses, and the slits provided in the lens holder are also provided on the lens. 2. The solid-state imaging device according to claim 1, wherein the number of lenses is increased in accordance with the number of the lenses, and the movement of the plurality of lenses in the rotation direction about the optical axis can be adjusted.   At least a substrate to which a solid-state image sensor is attached; an optical element that improves image performance; a base that covers the outside of the solid-state image sensor; and a first lens A that forms an image on the solid-state image sensor; A similar second lens B, a lens holder that covers the lens A and the lens B, a spacer or a diaphragm that is inserted between the lens A and the lens B, and a lens that fixes the lens A and the lens B In a solid-state imaging device having a cap and screwing and fixing a screw portion formed outside the lens holder and a screw portion formed inside the base, a slit portion is provided in the lens holder, and the lens A window is provided in a part of the screw portion of the base facing the holder slit portion, and the lens holder slit portion is fixed to the base when the lens holder is screwed. A solid-state imaging device characterized in that the lens B can be moved and adjusted in the rotational direction around the optical axis using the outer periphery of the lens B edge. .   The configuration of the lens A and the lens B is three or more, and a spacer or an aperture inserted between the lens A and the lens B is also increased in accordance with the number of lenses, and the slits provided in the lens holder are also provided on the lens. In addition, the same number of windows are provided in the screw portion of the base corresponding to the lens holder slit portion, and each slit portion of the lens holder opens the respective window of the base when the lens holder is screwed and fixed. 4. A positional relationship that can be confirmed through a plurality of lenses, wherein the movement of the plurality of lenses in the rotational direction about the optical axis can be adjusted using the outer peripheral edge of each of the lenses. Solid-state imaging device.   The solid-state imaging device according to any one of claims 1 to 4, wherein a shape portion that is recessed from the outer peripheral diameter is formed on the outer peripheral portion of the lens edge.

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