JP2006003379A - Lens holder, lens block, and imaging apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a lens holder which stably holds a plurality of lenses and realizes the improvement in the machining accuracy of a metallic mold, and where an adhesive is prevented from being wasted and the lens is completely attached, and a recessed part being a path of a nozzle is surely formed for every lens holding part, and to provide a lens block and an imaging apparatus. <P>SOLUTION: Each lens holding part of the lens holder 44 includes a lens receiving part 50a for receiving the lens in an optical axis direction, a lens fitting part 50b for holding the outer circumferential surface of the lens in a state where the lens is fit in the optical axis direction. The lens receiving part 50a is constituted of three plane receiving parts arranged at three spots around the optical axis of the lens which it holds and having a plane perpendicular to the optical axis of the lens. Meanwhile, the lens fitting part 50b is constituted of three plane fitting parts arranged at three spots around the optical axis of the lens which it holds and having a plane parallel with the optical axis of the lens. The lens receiving part 50a and the lens fitting part 50b are arranged to be deviated around the optical axis, and the lens receiving parts 50a and 50a in the lens holding parts adjacent in the optical axis direction are arranged to be deviated around the optical axis. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a lens holding body that holds a plurality of lenses, a lens block that holds a lens by the lens holding body, and an imaging device that includes the lens block. It is.

  Conventionally, as a lens holder (lens mount) for holding a plurality of lenses, for example, there is one disclosed in Patent Document 1. FIG. 10 is a perspective view showing a schematic configuration of the lens holder described in Patent Document 1. As shown in FIG. The lens holder includes a first lens holding portion 101 that holds the first lens, a second lens holding portion 102 that holds the second lens, and an adhesive escape portion 103.

  The first lens holding unit 101 includes a flat surface portion 101a and a peripheral surface portion 101b. The plane part 101a is configured by an annular plane perpendicular to the optical axis of the first lens, and receives the first lens in the optical axis direction. The peripheral surface portion 101b is configured by a curved surface along the entire outer peripheral surface of the first lens, and holds the outer peripheral surface of the first lens when the first lens is fitted.

  On the other hand, the second lens holding unit 102 includes a flat surface portion 102a and a peripheral surface portion 102b. The plane part 102a is configured by a plane perpendicular to the optical axis of the second lens, and receives the second lens in the optical axis direction. The flat portion 102a is formed at three locations around the optical axis of the second lens. The peripheral surface portion 102b is configured by a curved surface along the outer peripheral surface of the second lens, and holds the outer peripheral surface of the second lens when the second lens is fitted. The peripheral surface portion 102b is formed at three positions around the optical axis of the second lens, and is formed at the same position as the flat portion 102a around the optical axis.

  The adhesive escape portion 103 is a recess for allowing the first adhesive applied to the flat surface portion 101 a of the first lens holding portion 101 to escape, and is provided in the second lens holding portion 102. More specifically, in the second lens holding portion 102, the adhesive escape portion 103 is formed between the plane portions 102a and 102a adjacent to each other around the optical axis and between the peripheral surface portions 102b and 102b adjacent to each other around the optical axis. Has been.

  In the above configuration, when the first lens and the second lens are incorporated into the lens holder, first, the first adhesive is applied to the flat surface portion 101a of the first lens holding portion 101. Then, the first lens is incorporated into the first lens holding unit 101. The first adhesive overflowing from between the first lens and the flat surface portion 101 a flows into the adhesive escape portion 103. In this state, the first adhesive is irradiated with ultraviolet rays to cure the first adhesive.

Subsequently, a second adhesive is applied to the flat surface portion 102 a of the second lens holding portion 102. Then, the second lens is incorporated into the second lens holding portion 102, and in this state, the second adhesive is irradiated with ultraviolet rays to cure the second adhesive. At this time, since the first adhesive that protrudes from the first lens holding portion 101 flows into the adhesive escape portion 103 and is cured, the second lens does not contact the first adhesive and does not contact the second adhesive. It is held by the lens holding unit 102.
Japanese Patent No. 3442507 (see FIG. 1)

However, the configuration of the conventional lens holder described above has the following problems.
(1) In the first lens holding unit 101, the flat surface portion 101a is configured by an annular flat surface perpendicular to the optical axis of the first lens, and the peripheral surface portion 101b is the entire circumference of the outer peripheral surface of the first lens. It is formed to contact. In this case, if the first lens holding portion 101 is distorted during molding of the lens holding body, the first lens is held at two points with respect to the flat portion 101a and the peripheral surface portion 101b, and the holding of the first lens is performed. It becomes unstable.

  (2) Since the first lens holding part 101 is composed of the plane part 101a and the peripheral surface part 101b, metal processing of the mold used for molding the lens holding body can be performed in one process without changing the setup. The processing accuracy is very good. However, for the second lens holding portion 102, the die has a complicated uneven shape for the sake of convenience of forming the flat portion 102a, the peripheral surface portion 102b, and the adhesive escape portion 103. It seems to be necessary.

  That is, the convex portion of the second lens holding portion 102 corresponds to a concave portion in the mold, but a part (tool) used for grinding cannot enter the concave portion. It is thought that this machining must be electrical discharge machining. For this reason, the machining accuracy of the mold tends to deteriorate.

  In addition, it is possible to divide the mold into a plurality of parts and individually produce the molded products, and then combine them later. However, this method causes positioning errors during synthesis, so it is possible to obtain molded products with high accuracy. I can't.

  (3) For example, when the second lens is incorporated into the second lens holding portion 102, the second lens is first applied to the flat portion 102a, and then the second lens is incorporated into the second lens holding portion 102. . In this case, depending on the amount of the second adhesive, the second lens tilts in the second lens holding portion 102 (causes an optical axis shift), so there is a concern that the position accuracy of the second lens may be lowered. Therefore, it can be said that a method in which the second lens is first incorporated into the second lens holding portion 102 and then the second adhesive is poured into a desired position is desirable.

  Therefore, in the configuration of the lens holder, if the second adhesive is poured later, it is conceivable that the second adhesive is poured into the adhesive escape portion 103 of the second lens holding portion 102, for example. However, since the adhesive escape portion 103 does not receive the second adhesive in the optical axis direction in the vicinity of the second lens to be held, a large amount of the second adhesive is used when the second lens is bonded. And waste of the second adhesive occurs. Further, since the second adhesive flows in the direction of the first lens, the second lens is not sufficiently adhered by the second adhesive.

  (4) In the second lens holding portion 102, the plane portion 102a and the peripheral surface portion 102b are formed at the same position around the optical axis of the second lens, and therefore between the plane portions 102a and 102a adjacent to each other around the optical axis. A space for the adhesive escape portion 103 is formed between the peripheral surface portions 102b and 102b adjacent to each other around the optical axis. Therefore, when filling the adhesive escape portion 103 with the second adhesive, a large amount of the second adhesive is required.

  (5) In the above lens holder, it is considered that the planar portion 102a that receives the second lens in the optical axis direction is provided at three positions around the optical axis, and the second lens can be stably held. In order to hold the lens stably, a configuration in which the flat portion 101a that receives the first lens in the optical axis direction is provided at three positions around the optical axis can be considered. At this time, if the flat portion 101a and the flat portion 102a are formed at the same position around the optical axis, the respective flat portions 101a are formed along the optical axis direction in the recesses serving as nozzle passages for filling the adhesive. -Even if it is desired to form it toward 102a, the concave portions interfere with each other, so that they cannot be formed.

  The present invention has been made in order to solve the above-described problems, and the object thereof is to stably hold a plurality of lenses, to improve the processing accuracy of a mold, and to adhere It is an object of the present invention to provide a lens holder, a lens block, and an imaging device that can sufficiently adhere a lens without waste of an agent, and can reliably form a concave portion serving as a nozzle passage for each lens holding portion.

  The lens holding body of the present invention includes a lens receiving portion that receives the lens in the optical axis direction, and a lens fitting portion that holds the outer peripheral surface of the lens in a state where the lens is fitted in the optical axis direction. A lens holder that includes a plurality of holding portions and holds a plurality of lenses that are incorporated from the same direction along the optical axis, and when m and n are natural numbers of 3 or more, the lens receiving portion in each lens holding portion is , Arranged at m positions around the optical axis of the lens to be held, and is composed of m plane receiving portions having a plane perpendicular to the optical axis of the lens, and the lens fitting portion in each lens holding portion holds It is arranged at n places around the optical axis of the lens and is composed of n plane fitting portions having a plane parallel to the optical axis of the lens. The lens receiving portion and the lens fitting portion in the same lens holding portion are , Shifted around the optical axis Are, the lens receiving portions of the lens holding portion adjacent to the optical axis direction is characterized by being arranged offset about the optical axis.

  According to the above configuration, the m plane receiving portions constituting the lens receiving portion of each lens holding portion come into contact with the lens in a plane perpendicular to the optical axis (point contact or line contact), thereby causing the lens to light. Receive in the axial direction. In addition, the n plane fitting portions constituting the lens fitting portion hold the outer peripheral surface of the lens by contacting the lens outer peripheral surface with a plane parallel to the optical axis.

  At this time, m plane receiving portions are provided at m places around the optical axis, and n plane fitting portions are provided at n places around the optical axis. Even when deformation (distortion) occurs in the holding body, the lens can be received at three or more points in the optical axis direction in each lens holding portion, and the lens can be held at three or more locations on the outer peripheral surface thereof. Thereby, in each lens holding part, a some lens can be hold | maintained stably.

  In addition, since the lens receiving portion and the lens fitting portion of each lens holding portion are constituted by a flat receiving portion and a flat fitting portion, grinding processing suitable for flat surface processing is possible as processing of a mold for forming a lens holding body. Can sufficiently cope with this, and electric discharge machining can be made unnecessary. As a result, the machining correction accuracy of the mold can be improved.

  Moreover, since the lens fitting part of each lens holding part is supposed to hold | maintain a lens outer peripheral surface in n places by n plane fitting parts, it is between the lens fitting parts adjacent to the periphery of an optical axis. A gap that can be filled with an adhesive can be formed between the outer peripheral surface of the lens and the inner surface of the holding body. On the other hand, since the lens receiving portion and the lens fitting portion in the same lens holding portion are shifted around the optical axis, when the adhesive is poured into the gap, the adhesive is blocked by the lens receiving portion. Can do. Accordingly, it is possible to sufficiently adhere the lens inside the holding body while suppressing adhesive leakage (adhesive waste). In addition, compared to the case where the lens receiving portion and the lens fitting portion are not shifted around the optical axis (when the lens receiving portion and the lens fitting portion are formed at the same position around the optical axis), the above-described gap filled with the adhesive can be formed small. it can. As a result, the lens can be bonded to the lens holding portion without using a large amount of adhesive.

  In addition, since the lens receiving portions in the lens holding portions adjacent to each other in the optical axis direction are shifted from each other around the optical axis, for example, a concave portion serving as a nozzle passage for filling the adhesive is provided in each lens receiving portion. It can be formed on the inner surface of the lens holder almost along the optical axis so as to go to the portion. In other words, the concave portions corresponding to the respective lenses can be shifted around the optical axis, and the concave portions can be reliably ensured for each lens (the concave portions do not interfere with each other).

  In the lens holding body of the present invention, the m plane receiving portions in the lens receiving portion may be formed in a shape in line contact with the surface of the lens to be held around the optical axis. In this case, the lens can be held more stably than when receiving the lens in the optical axis direction by point contact.

  In the lens holder of the present invention, the m plane receiving portions may be arranged at equal intervals around the optical axis. According to this configuration, the lens can be reliably and stably held in the optical axis direction.

  In the lens holder of the present invention, m = n = 3 may be satisfied. In this case, each lens holding portion can have a minimum configuration necessary for stably holding the lens (the number of plane receiving portions and plane fitting portions is the minimum required number). The configuration can be simplified most.

  On the inner surface of the lens holder of the present invention, a concave portion serving as a nozzle passage for filling an adhesive is formed between the lens fitting portions adjacent to each other around the optical axis in the lens receiving portion corresponding to the lens to be held. It may be formed to face.

  If such a recess is formed on the inner surface of the holder, an adhesive can be filled between the outer peripheral surface of the lens to be held and the inner surface of the holder by inserting a nozzle along the recess. Moreover, since the filled adhesive is dammed by the lens receiving portion in the optical axis direction, the lens outer peripheral surface and the inner surface of the holding body are bonded while eliminating leakage of the adhesive (waste of the adhesive). Can do.

  In the lens holder of the present invention, the inner surface of the holder between the lens receiving portions adjacent to each other around the optical axis may be formed in a shape in which the optical axis side is concave.

  In the case of this configuration, for example, if the first lens is a first lens and the subsequent lens is a second lens, the lens receiver adjacent to the optical axis in the lens receiver corresponding to the second lens. A space for forming a concave portion for filling the adhesive toward the lens receiving portion corresponding to the first lens can be secured between the portions. Accordingly, the concave portion can be formed without increasing the diameter of the second lens (without limiting the diameter of the second lens).

  The lens block of the present invention may have a configuration in which a plurality of lenses are held by the lens holder of the present invention described above. In addition, an imaging apparatus according to the present invention includes at least one lens block described above so that an optical image of a subject is formed, and an imaging device that converts the optical image into an electrical signal. Also good.

  According to the present invention, in each lens holding portion, m plane receiving portions are provided at m locations around the optical axis, and n plane fitting portions are provided at n locations around the optical axis. Even if deformation (distortion) occurs in the lens holder during molding of the lens holder, each lens holder can receive the lens at three or more points in the optical axis direction. Can be held at three or more locations. As a result, a plurality of lenses can be stably held in each lens holding portion.

  In addition, since the lens receiving part of each lens holding part is constituted by a flat receiving part, and the lens fitting part is constituted by a flat fitting part, as a machining of a mold for molding a lens holding body, it is possible to process a flat surface. A suitable grinding process is sufficient. As a result, the machining correction accuracy of the mold can be improved.

  In addition, since the lens receiving portion and the lens fitting portion in the same lens holding portion are shifted around the optical axis, when the adhesive is poured into the gap between the lens outer peripheral surface and the inner surface of the holding body, the bonding is performed. The agent can be dammed up at the lens receiving portion. Accordingly, it is possible to sufficiently adhere the lens inside the holding body while suppressing adhesive leakage (adhesive waste). Moreover, since the gap filled with the adhesive can be formed small, the lens can be bonded to the lens holding portion without using a large amount of adhesive.

  In addition, since the lens receiving portions in the lens holding portions adjacent to each other in the optical axis direction are shifted from each other around the optical axis, for example, a concave portion serving as a nozzle passage for filling the adhesive is provided in each lens receiving portion. It can be formed on the inner surface of the holding body while being shifted around the optical axis so as to be directed to the portion, and the above-mentioned concave portion can be reliably ensured for each lens.

An embodiment of the present invention will be described below with reference to the drawings.
FIG. 2A is a front view showing a schematic configuration of the digital camera 1 to which the lens holder of the present invention is applied, and FIG. 2B is a rear view of the digital camera 1.

  The digital camera 1 has a substantially rectangular parallelepiped housing 2 with the shortest side being a fraction of the size of the other side. During normal shooting, the direction of the shortest side of the housing 2 ( 2 (a) and 2 (b) are directions in the front-rear direction, the direction of the longest side (the left-right direction in FIGS. 2A and 2B) is the left-right direction, and the length of the side between them is It is set to be held by the user with the direction (vertical direction in FIGS. 2A and 2B) facing the vertical direction. Hereinafter, the front and rear, left and right, and top and bottom directions are determined based on this state. Note that the range captured by the digital camera 1 is a rectangle, and normal shooting means that an erect user shoots a long rectangular range on the side of the front and horizontally.

  The digital camera 1 includes an objective window 3, a finder front window 4, a flash light emitting unit 5, and a self-timer lamp 6 on the front surface of the housing 2, and a finder rear window 7 and a display unit 8 on the rear surface of the housing 2. , A mode setting switch 9, a cursor button 10, and a plurality of operation keys 11, and a release button 12 on the upper surface of the housing 2.

  The objective window 3 can be opened and closed. When the objective window 3 is opened, a first lens group 31 included in an imaging optical system 22 (see FIG. 3) described later appears. The front viewfinder window 4 and the rear viewfinder window 7 are windows for providing a user with an optical image to be photographed. The flash light emitting unit 5 emits flash light that illuminates the subject to be photographed. The self-timer lamp 6 is lit to indicate that preparation for self-timer shooting is in progress.

  The display unit 8 displays various information such as the setting status of the digital camera 1 and operation guidance in addition to the photographed image, and is configured by a liquid crystal display device, for example. The mode setting switch 9 is used to set the operation mode of the digital camera 1 and is configured by a slide type switch.

  Here, the operation modes of the digital camera 1 include a still image shooting mode for shooting and recording still images, a moving image shooting mode for shooting and recording moving images, and a playback mode for playing back and displaying recorded images. There is. By sliding the mode setting switch 9 to a position corresponding to each operation mode, the user can operate the digital camera 1 in a desired operation mode. In addition, in the vicinity of the mode setting switch 9, marks representing each operation mode are written along the sliding direction of the mode setting switch 9, so that the user can easily recognize the correspondence between the slide position and the operation mode. It is like that.

  The cursor button 10 has four contacts on the top, bottom, left, and right, and is used for moving the cursor displayed on the display unit 8. The digital camera 1 also includes a zoom lens as an imaging optical system, and the cursor button 10 is also used for adjusting the focal length. The operation keys 11 are used for settings related to functions of the digital camera 1 such as switching of items displayed on the display unit 8 and selection of displayed items. The release button 12 operates in two stages and is used for an instruction for preparing to shoot an image to be recorded and an instruction to shoot an image to be recorded. The digital camera 1 has functions of automatic focus adjustment (AF) and automatic exposure control (AE), and performs AF and AE in preparation for photographing.

  The digital camera 1 also has an imaging device 21 inside the housing 2. Hereinafter, a specific configuration of the imaging device 21 will be described.

  FIG. 3 is a cross-sectional view illustrating a schematic configuration of the imaging device 21. The imaging device 21 includes an imaging optical system 22, an imaging element 23, and an optical low-pass filter 24. In the present embodiment, the imaging device 21 is arranged horizontally in the housing 2, but may of course be arranged vertically.

  The imaging optical system 22 includes a plurality of lens groups to be described later, and forms an image of light from the imaging target on the imaging element 23. The image sensor 23 is configured by, for example, a CCD area sensor, and is fixed to a support substrate 23 a in the housing 2. The low-pass filter 24 is disposed in the optical path between the imaging optical system 22 and the image sensor 23.

  Light from the imaging target is imaged on the image sensor 23 by the imaging optical system 22 via the optical low-pass filter 24, and the optical image is converted into an electrical signal by the image sensor 23. A signal output from the image sensor 23 is processed by a circuit (not shown) to be image data representing a captured image. This image data is recorded on, for example, a removable recording medium (not shown).

Next, details of the imaging optical system 22 will be described.
The imaging optical system 22 includes a prism unit 25 and an imaging optical unit 26. The prism unit 25 includes a first lens group 31, a prism 35, and a prism holding frame 36.

  The first lens group 31 includes a lens 31a and a lens 31b in this order along the traveling direction of incident light. The lens 31a is arranged so that the optical axis faces the front-rear direction, and the lens 31b is arranged so that the optical axis is orthogonal to the optical axis of the lens 31a and faces the left-right direction.

  The prism 35 is a triangular prism having a right-angled isosceles triangle, and is disposed between the lens 31a and the lens 31b. More specifically, in the prism 35, one of two surfaces orthogonal to each other faces the lens 31a, the other faces the lens 31b, and a slope is formed between the optical axis of the lens 31a and the optical axis of the lens 31b. It is located on the intersection and is arranged at 45 degrees with respect to the optical axis of the lens 31a and the optical axis of the lens 31b. The slope of the prism 35 is provided with a reflective coating, and the prism 35 reflects the light from the object to be photographed through the lens 31a and guides it to the lens 31b by the slope.

  The prism holding frame 36 holds the first lens group 31 and the prism 35, and is obtained, for example, by molding a resin material with a mold.

  On the other hand, the imaging optical unit 26 includes a second lens group 32, a third lens group 33, a fourth lens group 34, and a lens barrel 37.

  The second lens group 32, the third lens group 33, and the fourth lens group 34 each have at least one lens, and each optical axis is the light of the lens 31b of the first lens group 31. The lens barrel 37 is arranged in this order along the traveling direction of the light incident through the first lens group 31 so as to coincide with the axis. Therefore, the optical axis of the imaging optical system 22 as a whole is bent 90 degrees from the front-rear direction of the housing 2 to the left-right direction by the prism 35, and most of the optical axis is set to face the left-right direction.

  The present invention has the greatest feature in the lens holder constituting the second lens group 32, which will be described later.

  The lens barrel 37 holds the second lens group 32, the third lens group 33, and the fourth lens group 34. Like the prism holding frame 36, for example, a resin material is molded with a mold. Obtained. The lens barrel 37 is fixed to the prism holding frame 36 by adhesion.

  In the imaging optical system 22, the first lens group 31 and the fourth lens group 34 are fixed, and both the second lens group 32 and the third lens group 33 are movable in the optical axis direction. is there. The movement of the second lens group 32 performs zooming, that is, the change of the focal length, and the movement of the third lens group 33 performs focusing, that is, the adjustment of the focus on the object to be imaged.

Next, details of the second lens group 32 will be described.
FIG. 4 is a cross-sectional view showing a detailed configuration of the second lens group 32. The second lens group 32 is a lens block disposed in the lens barrel 37 so that an optical image of a subject (photographing target) is formed on the image sensor 23. The second lens group 32 includes a first lens 41, a second lens 42, a third lens 43, and a lens holder 44.

  The first lens 41, the second lens 42, and the third lens 43 are incorporated in the lens holder 44 in this order from the same direction along the optical axis (from the third lens group 33 side in this embodiment). The surface of the first lens 41 on the first lens group 31 side is formed as a curved surface that is convex from the center of the optical axis to the radially outer end and convex toward the first lens group 31 side. The second lens 42 is a plane whose outermost end in the radial direction is perpendicular to the optical axis. The third lens 43 is formed in a shape in which the surfaces on the first lens group 31 side and the third lens group 33 side are convex on the third lens group 33 side, and is the outermost end in the radial direction. Is a plane perpendicular to the optical axis. The first lens 41, the second lens 42, and the third lens 43 are formed so that their diameters increase in this order.

  The lens holder 44 is a lens frame that holds the first lens 41, the second lens 42, and the third lens 43, and has a substantially cylindrical shape. More specifically, the lens holding body 44 has a first lens holding portion 51 that holds the first lens 41, a second lens holding portion 52 that holds the second lens 42, and a third lens 43 that holds the third lens 43. 3 lens holding portion 53. The inner diameter of the cylindrical portion of the first lens holding portion 51 is larger than the outer diameter of the first lens 41, the inner diameter of the cylindrical portion of the second lens holding portion 52 is larger than the outer diameter of the second lens 42, and the third The inner diameter of the cylindrical portion of the lens holding portion 53 is formed larger than the outer diameter of the third lens 43. In the following, for convenience of explanation, when the first lens holding unit 51, the second lens holding unit 52, and the third lens holding unit 53 are not particularly distinguished, each of them is also referred to as a lens holding unit 50.

  In addition, the outer wall of the peripheral surface of the lens holding body 44 is formed in a shape that expands in a stepped manner from the first lens group 31 side toward the third lens group 33 side. This is because the first lens holding portion 51, the second lens holding portion 52, and the third lens holding portion 53 of the lens holding body 44 are formed in a shape corresponding to the outer diameter of the lens to be held. In the lens holder 44, the opening 45 on the first lens group 31 side has a smaller inner diameter than the opening 46 on the third lens group 33 side.

Hereinafter, a detailed configuration of the lens holder 44 will be described.
FIG. 1 is a plan view showing a schematic configuration of the lens holding body 44 when viewed from the third lens group 33 side, and FIG. 5 is a lens holding body when viewed from the first lens group 31 side. 44 is a plan view showing a schematic configuration of 44. FIG. The cross-sectional view of the lens holder 44 in FIG. 4 also corresponds to a cross-sectional view taken along the line AA ′ of the lens holder 44 in FIGS. 1 and 5.

  The lens holding body 44 has a lens receiving portion and a lens fitting portion in at least two of the lens holding portions 50 adjacent in the optical axis direction. The lens receiving portion receives the lens to be held in the optical axis direction, and the lens fitting portion holds the outer peripheral surface of the lens in a state in which the lens to be held is fitted in the optical axis direction.

  More specifically, the first lens holding part 51 has a lens receiving part 51a and a lens fitting part 51b, and the second lens holding part 52 adjacent to the first lens holding part 51 in the optical axis direction is The lens receiving portion 52a and the lens fitting portion 52b are provided. Further, the third lens holding portion 53 has only the lens receiving portion 53a and does not have a lens fitting portion. This is because the eccentricity of the third lens 43 can be adjusted when the third lens 43 is incorporated into the third lens holding portion 53.

  In the following, for convenience of explanation, when the lens receiving portions 51a, 52a, and 53a are not particularly distinguished, each of them is also referred to as a lens receiving portion 50a. Similarly, when the lens fitting portions 51b and 52b are not particularly distinguished, each of them is also referred to as a lens fitting portion 50b.

  The lens receiving portions 50a are arranged at three locations around the optical axis of the lens to be held, and are composed of three flat receiving portions having a plane perpendicular to the optical axis of the lens. In the present embodiment, the lens receiving portion 50a is formed in an arcuate shape in plan view, a portion corresponding to the arc (arc portion) coincides with the cylindrical inner surface of the lens holding portion 50, and a portion corresponding to the string (string) Part) is formed on the optical axis side. And the part enclosed by the arc part and the chord part is the said plane perpendicular | vertical to an optical axis. Further, the lens receiving portions 50a in the same lens holding portion 50 are disposed at positions where the distances from the optical axis are substantially equal.

  The lens receiving portions 51a, 52a, and 53a are formed so that the area of the plane perpendicular to the optical axis increases in this order, and the distance from the optical axis increases in this order. Is provided.

  By configuring the lens receiving portion 50a with three plane receiving portions, when the lens is incorporated in the lens holding portion 50, the lens surface and the plane (particularly the chord portion) of the lens receiving portion 50a are around the optical axis. It is possible to contact the lens in the optical axis direction by contacting in three different places in the optical axis direction. The contact at this time is a point contact when the lens receiving portion 50a receives the curved surface of the lens, and the lens receiving portion 50a is a flat surface of the lens (at the radially outer ends of the second lens 42 and the third lens 43). When receiving a flat surface, it becomes surface contact. In the lens receiving portion 50a, the string portion may be slightly rounded in order to soften the receiving in the optical axis direction.

  Further, the three lens receiving portions 50a in the same lens holding portion 50 are arranged at equal intervals (shifted by 120 degrees) around the optical axis. This makes it possible to reliably and stably receive the lens to be held in the optical axis direction.

  On the other hand, the lens receiving portions 50a of the lens holding portions 50 adjacent to each other in the optical axis direction are arranged so as to be shifted around the optical axis. For example, the lens receiving portion 51 a of the first lens holding portion 51 and the lens receiving portion 52 a of the second lens holding portion 52 are arranged so as to be shifted by 60 degrees around the optical axis, and the lenses of the second lens holding portion 52 are arranged. The receiving portion 52a and the lens receiving portion 53a of the third lens holding portion 53 are arranged so as to be shifted by 60 degrees around the optical axis. The effect of this configuration will be described later.

  On the other hand, the lens fitting portions 50b are arranged at three places around the optical axis of the lens to be held, and are composed of three plane fitting portions having a plane parallel to the optical axis of the lens. In the present embodiment, the lens fitting portion 50b is formed in an arc shape smaller than the lens receiving portion 50a in plan view, and a portion corresponding to the arc (arc portion) coincides with the cylindrical inner surface of the lens holding portion 50, A portion corresponding to the string (string portion) is formed on the optical axis side. And a part of plane parallel to the optical axis in the lens fitting part 50b becomes said string part.

  Further, in the same lens holding part 50, the lens fitting parts 50b are respectively arranged at positions where the distances from the optical axis are substantially equal, and are more in the optical axis direction than the lens receiving part 50a of the same lens holding part 50. 3 on the lens group 33 side.

  The lens fitting portions 51b and 52b are formed so that the cross-sectional areas in the cross section perpendicular to the optical axis increase in this order, and the distance from the optical axis increases in this order. It has been.

  By configuring the lens fitting portion 50b with three plane fitting portions, when the lens is incorporated into the lens holding portion 50, the lens outer peripheral surface and the plane of the lens fitting portion 50b are different around the optical axis. Line contact is made in the optical axis direction at three locations, and the lens can be held on the outer peripheral surface thereof.

  These three lens fitting portions 50b are arranged at equal intervals (shifted by 120 degrees) around the optical axis, and the lens to be held can be reliably and stably held on the outer peripheral surface thereof. ing. Further, the lens receiving portion 50a and the lens fitting portion 50b in the same lens holding portion 50 are arranged so as to be shifted around the optical axis (for example, shifted by 60 degrees at equal intervals). It will be described later.

  Further, as shown in FIG. 4, with respect to the first lens holding part 51 and the second lens holding part 52, an adhesive filling part 54 is formed between the lens fitting parts 50b and 50b adjacent to each other around the optical axis. Has been. More specifically, an adhesive filling portion 54a is formed between the lens fitting portions 51b and 51b adjacent to each other around the optical axis. An adhesive filling portion 54b is formed between the lens fitting portions 52b and 52b adjacent to each other around the optical axis.

  The adhesive filling portion 54 is filled with an adhesive discharged from an adhesive filling nozzle 55 (see FIGS. 6 and 7), and the outer peripheral surface of the lens is applied to the inner surface of the lens holding portion 50 by the adhesive. Glued. On the other hand, since the lens fitting portion is not formed for the third lens holding portion 53, it is between the outer peripheral surface of the third lens 43 and the inner surface of the third lens holding portion 53, and on the lens receiving portion 53 a. The portion that can receive the adhesive is the adhesive filling portion.

  Further, as shown in FIGS. 1 and 4, on the inner surface of the lens holder 44, an adhesive filling nozzle 55 (see FIGS. 6 and 6) is provided between the lens fitting portions 50b and 50b adjacent to each other around the optical axis. A recess 56 serving as a passage in FIG. 7) is formed substantially along the optical axis direction so as to go to the lens receiving portion 50a corresponding to the lens to be held.

  More specifically, on the inner surface of the lens holding body 44, a concave portion 56a serving as a passage for the nozzle 55 is held between the lens fitting portions 51b and 51b adjacent to each other around the optical axis. A concave portion 56b serving as a passage for the nozzle 55 is held between the lens fitting portions 52b and 52b adjacent to each other around the optical axis. The concave portion 56b is formed along the optical axis direction so as to face the lens receiving portion 51a. It is formed substantially along the optical axis direction so as to go to the lens receiving portion 52a that receives the second lens 42.

  With this configuration, as shown in FIG. 6, after the first lens 41 is fitted into the lens fitting portion 51b, the nozzle 55 is inserted along the concave portion 56a from the third lens group 33 side. It becomes possible to fill the filling portion 54a with an adhesive. Further, as shown in FIG. 7, after the second lens 42 is fitted into the lens fitting portion 52b, the nozzle 55 is inserted along the concave portion 56b from the third lens group 33 side. 54b can be filled with an adhesive.

  Further, as shown in FIG. 1, the inner surface of the lens holder 44 between the lens receiving portions 50a and 50a adjacent to each other around the optical axis (for example, the lens receiving portions 52a and 52a) has a shape in which the optical axis side is concave. It is formed with. Thereby, the space for forming the recessed part 56a which goes to the lens receiving part 51a between the lens receiving parts 52a * 52a adjacent to the surroundings of an optical axis is securable. Thereby, the recessed part 56a can be formed, without enlarging the diameter of the 2nd lens 42 (without enlarging the lens holding body 44).

  In the configuration described above, when the first lens 41, the second lens 42, and the third lens 43 are incorporated into the lens holder 44, the following procedure may be used.

  First, as shown in FIG. 6, the first lens 41 is incorporated into the first lens holding portion 51 of the lens holding body 44 along the optical axis from the third lens group 33 side. After the first lens 41 comes into contact with the lens receiving portion 51a and the outer peripheral surface thereof is fitted into the lens fitting portion 51b, the nozzle 55 is inserted along the concave portion 56a, and the adhesive filling portion 54a is filled with the adhesive. , Cure it. Even if the amount of the filled adhesive is too large, there is no particular problem because an excessive amount of the adhesive flows out into the recess 56a.

  Subsequently, as shown in FIG. 7, the second lens 42 is incorporated into the second lens holding portion 52 along the optical axis from the third lens group 33 side. After the second lens 42 comes into contact with the lens receiving portion 52a and its outer peripheral surface is fitted into the lens fitting portion 52b, the nozzle 55 is inserted along the concave portion 56b, and the adhesive filling portion 54b is filled with the adhesive. , Cure it. Even if the amount of the filled adhesive is too large, there is no particular problem because an excessive amount of the adhesive flows out into the recess 56b.

  Finally, as shown in FIG. 4, the third lens 43 is incorporated into the third lens holding portion 53 along the optical axis from the third lens group 33 side. After the third lens 43 comes into contact with the lens receiving portion 53a, an adhesive is filled between the outer peripheral surface of the third lens 43 and the inner surface of the third lens holding portion 53 and at a position where the lens receiving portion 53a is located. And cure it. At this time, the third lens 43 is incorporated into the third lens holding portion 53 while adjusting the eccentricity of the third lens 43.

As described above, the lens holder 44 of the present invention particularly includes the following configurations (A), (B), and (C). Thereby, the following effects can be obtained.
(A) The lens receivers 50a in each lens holder 50 are arranged at three locations around the optical axis of the lens to be held, and are composed of three plane receivers having a plane perpendicular to the optical axis of the lens. The lens fitting portions 50b in each lens holding portion 50 are arranged at three locations around the optical axis of the lens to be held, and are composed of three plane fitting portions having planes parallel to the optical axis of the lens. .
(B) The lens receiving portion 50a and the lens fitting portion 50b in the same lens holding portion 50 are arranged so as to be shifted around the optical axis.
(C) The lens receiving portions 50a of the lens holding portions 50 adjacent to each other in the optical axis direction are arranged so as to be shifted around the optical axis.

  According to the configuration of (A), even if deformation such as distortion occurs in the lens holder 44 when the lens holder 44 is molded, each lens holder 50 has three or more lenses in the optical axis direction. The lens can be received by hitting, and the lens can be held at three or more locations on the outer peripheral surface thereof. Thereby, even if the lens holding body 44 is distorted at the time of molding, each lens holding portion 50 can stably hold a plurality of lenses.

  Moreover, since the lens receiving part 50a is comprised by the plane receiving part and the lens fitting part 50b is comprised by the plane fitting part, it is suitable for the process of a plane as a process of the metal mold | die which shape | molds the lens holding body 44. Grinding can be used. That is, it is possible to eliminate the need for electric discharge machining, which is considered to have been used when processing the mold of the conventional lens holder. As a result, the machining correction accuracy of the mold can be improved.

  According to the configuration of (B) above, in each lens holding part 50, a gap that becomes the above-described adhesive filling part 54 can be formed between the lens fitting parts 50b and 50b adjacent to each other around the optical axis. . On the other hand, since the lens receiving portion 50a and the lens fitting portion 50b in the same lens holding portion 50 are displaced around the optical axis, when the adhesive is poured into the adhesive filling portion 54 from the third lens group 33 side. In addition, the adhesive can be blocked by the lens receiver 50a. Accordingly, it is possible to sufficiently adhere the lens inside the holding body while suppressing adhesive leakage (adhesive waste).

  Moreover, the adhesive filling portion 54 can be formed smaller than when the lens receiving portion 50a and the lens fitting portion 50b are not shifted around the optical axis (when formed at the same position around the optical axis). As a result, the lens can be bonded to the lens holding unit 50 without using a large amount of adhesive. In addition, since the adhesive filling portion 54 can be formed small, the lens holder 44 and thus the lens barrel 37 can be easily downsized.

  According to the configuration of (C), the concave portion 56 serving as the passage of the nozzle 55 can be formed on the inner surface of the lens holding body 44 substantially along the optical axis so as to face each lens receiving portion 50a. That is, the concave portions 56 corresponding to the respective lenses can be reliably secured for each lens without interfering with each other.

  In the above, the configuration in which the lens receiving portion 51a of the first lens holding portion 51 is brought into point contact with the first lens 41 in a plane perpendicular to the optical axis has been described. However, the lens receiving portion 51a is limited to this configuration. However, for example, the following configuration is also possible.

  FIG. 8 is a plan view showing another configuration example of the lens holding body 44 as viewed from the third lens group 33 side. As shown in the figure, the lens receiving portion 51a is composed of three flat receiving portions having a plane perpendicular to the optical axis, and has a shape in line contact with the surface of the first lens 41 to be held around the optical axis. And may be formed respectively. If the lens receiving portion 51a is configured in this way, the first lens 41 can be stably held as compared with the case where the first lens 41 is received in the optical axis direction by point contact. Further, in this configuration, since the first lens 41 can be positioned by only three line contacts between the lens receiving portion 51a and the first lens 41, the outer peripheral surface of the first lens 41 is fitted to the lens fitting portion 51b. Even if not, the first lens 41 can be held by the first lens holding portion 51.

  If the lens surface to be held is a spherical surface or an aspheric surface, and the lens receiving portion 50a receives the lens surface in the optical axis direction, the configuration of the lens receiving portion 51a in FIG. Of course, the present invention can also be applied to the lens receiving portion 50a.

  In the above description, an example in which the lens receiving portions 50a of the lens holding portion 50 are arranged at equal intervals around the optical axis and the lens fitting portions 50a are arranged at equal intervals around the optical axis has been described. The lens holder 44 of the present invention is not limited to this configuration.

  FIG. 9 is a plan view showing still another configuration example of the lens holder 44 as viewed from the third lens group 33 side. In the figure, the third lens holding portion 53 is not shown for convenience of explanation. In this lens holding body 44, the lens fitting portions 52b of the second lens holding portion 52 that holds the second lens 42 are arranged around the optical axis at intervals of about 135 degrees, 135 degrees, and 90 degrees. The lens receiving portion 52a is disposed at a position that is substantially point-symmetric about the optical axis with respect to the lens receiving portion 52a.

  According to the above configuration of the second lens holding unit 52, an oval lens can be used as the second lens 42. The oval lens is a lens having surfaces parallel to each other, which are formed when the end of the second lens 42 is cut off at an equal distance from the optical axis by two planes parallel to the optical axis. If the second lens 42 is composed of an oval lens, the length in the opposing direction of the mutually parallel surfaces (lens width) of the oval lens is shorter than the diameter of the lens before the end portion is cut off. Therefore, in accordance with this, the width of the second lens holding portion 52 that holds the second lens 42 and thus the lens holding body 44 can be reduced. Thereby, the lens holding body 44 and the lens barrel 37 can be further thinned, and the digital camera 1 can be further thinned.

  In FIG. 9, the second lens holding unit 52 is configured to be able to accommodate the oval second lens 42, but the first lens 41 and the third lens 43 are oval lenses, and It is of course possible to apply the configuration of the second lens holding unit 52 of FIG. 9 to the one lens holding unit 51 and the third lens holding unit 53. In this case, the lens holder 44, the lens barrel 37, and the digital camera 1 can be further reduced in thickness.

  As described above, in the present embodiment, the example in which the same number of the lens receiving portions 50a and the lens fitting portions 50b in the same lens holding portion 50 are provided is described. However, if the number is three or more, the same number is not necessary. . In particular, as in this embodiment, by providing the same number of three lens receiving portions 50a and three lens fitting portions 50b in the same lens holding portion 50, each lens holding portion 50 stably holds the lens. Therefore, the configuration of the lens holder 50 can be most simplified within a range that does not impair the effects of the present invention described above.

  In the present embodiment, the case where the lens holding body 44 has three lens holding portions 50 and holds three lenses (first lens 41, second lens 42, and third lens 43) has been described. Even when there are four or more lens holding portions 50 and four or more lenses are held, the configuration of this embodiment can be applied.

  In the present embodiment, the lens holding body 44 of the second lens group 32 has been described. However, as long as the lens holding body holds a plurality of lenses, the lens holding body of another lens group can also be used in the present embodiment. It is possible to apply a configuration.

  The lens holder 44 described in the present embodiment can also be expressed as follows.

  The lens holder 44 of the present invention is a lens holder that holds and holds a plurality of lenses (the first lens 41, the second lens 42, and the third lens 43) from the same direction, and the lens holder 50 of each lens. (I) a lens receiver in the optical axis direction, equally arranged in the circumferential direction, and composed of three planes perpendicular to the optical axis, and (ii) a phase with the lens receiver 50a Is disposed at a position shifted by 60 degrees, has a lens fitting portion 50b that faces the lens outer periphery and holds the lens outer periphery, and is configured by three planes parallel to the optical axis. The inner surface of the lens holding portion 50 between 50b is configured as a cylindrical inner surface having an inner diameter larger than the outer diameter of the lens, and has an adhesive filling portion 54 formed between the outer periphery of the lens and the inner surface of the cylinder. Between parts 50, Receiving unit 50a and the lens fitting portion 50b is configured offset 60 degrees out of phase.

FIG. 2 is a plan view of the lens holder when viewed from one direction along the optical axis of the lens to be held, showing a schematic configuration of the lens holder according to the embodiment of the present invention. (A) is a front view which shows the schematic structure of the digital camera provided with the said lens holding body, (b) is a rear view of the said digital camera. It is sectional drawing which shows the schematic structure of the imaging device provided in the inside of the said digital camera. It is sectional drawing which shows the detailed structure of the 2nd lens group in the said imaging device. It is a top view which shows the schematic structure of the said lens holding body when it sees from the opposite direction to the said direction. It is sectional drawing of the lens holding body incorporating the 1st lens. It is sectional drawing of the lens holding body incorporating the 2nd lens. It is a top view which shows the other structural example of the said lens holding body. It is a top view which shows other structure of the said lens holding body. It is a perspective view which shows the schematic structure of the conventional lens holding body.

Explanation of symbols

21 imaging device 23 imaging device 32 second lens group (lens block)
41 1st lens 42 2nd lens 43 3rd lens 44 Lens holding body 50 Lens holding part 50a Lens receiving part (plane receiving part)
50b Lens fitting part (plane fitting part)
51 Lens holding part 51a Lens receiving part (flat receiving part)
51b Lens fitting part (plane fitting part)
52 Lens holding part 52a Lens receiving part (plane receiving part)
52b Lens fitting part (plane fitting part)
53 Lens holding part 53a Lens receiving part (flat receiving part)
56 recess 56a recess 56b recess

Claims (8)

A plurality of lens holding portions each having a lens receiving portion that receives the lens in the optical axis direction and a lens fitting portion that holds the outer peripheral surface of the lens in a state in which the lens is fitted in the optical axis direction; A lens holder that holds a plurality of lenses assembled from the same direction along
If m and n are natural numbers of 3 or more,
The lens receiver in each lens holder is
It is arranged at m places around the optical axis of the lens to be held, and is composed of m plane receiving portions having a plane perpendicular to the optical axis of the lens,
The lens fitting part in each lens holding part is
It is arranged at n places around the optical axis of the lens to be held, and is composed of n plane fitting portions having a plane parallel to the optical axis of the lens,
The lens receiving portion and the lens fitting portion in the same lens holding portion are arranged around the optical axis,
A lens holder, wherein the lens receiving portions of the lens holding portions adjacent to each other in the optical axis direction are arranged so as to be shifted around the optical axis.   2. The lens holder according to claim 1, wherein the m planar receivers in the lens receiver are each formed in a shape in line contact with the surface of the lens to be held around the optical axis.   The lens holder according to claim 2, wherein the m planar receiving portions are arranged at equal intervals around the optical axis.   4. The lens holder according to claim 1, wherein m = n = 3.   On the inner surface of the holder, between the lens fitting portions adjacent to each other around the optical axis, a recess serving as a passage for the nozzle for filling the adhesive is formed so as to face the lens receiving portion corresponding to the lens to be held. The lens holder according to any one of claims 1 to 4, wherein the lens holder is provided.   6. The lens holder according to claim 1, wherein the inner surface of the holder between the lens receiving portions adjacent to each other around the optical axis is formed in a shape in which the optical axis side is concave.   A lens block comprising a plurality of lenses held by the lens holder according to claim 1. At least one lens block according to claim 7 so that an optical image of a subject is formed,
An image pickup apparatus comprising an image pickup element for converting the optical image into an electrical signal.

Images