JP6825898B2 - Laminated lens and camera module - Google Patents

Description

The present invention relates to a bonded lens in which lenses are bonded to each other with an adhesive, and a camera module including the bonded lens.

In order to correct chromatic aberration and the like with a smaller number of lenses, a bonded lens in which the lens surfaces of different lenses are bonded with an adhesive may be used (see, for example, Patent Document 1). For bonded lenses, a sufficient amount (thickness) of adhesive is required so that gaps and peeling between lenses do not occur.
Further, in such a bonded lens, by fitting the flange portions provided on the outer peripheral portion of the lens, the lenses are bonded to each other so that their optical axes are aligned with each other.

Japanese Unexamined Patent Publication No. 2014-19707

By the way, if a sufficient amount of adhesive is used in the bonded lens so as not to cause a gap or peeling between the lenses, the adhesive exceeds the adhesive surface between the lenses and the fitting portion between the flange portions on the outer peripheral portion. There is a risk of overflowing.
When the adhesive overflows to the fitting portion in this way, the adhesive often intervenes in the fitting portion and the desired optical characteristics cannot be obtained in many cases. For example, if the adhesive intervenes unevenly in the fitting portion, the lens is tilted and adhered, and even if the adhesive intervenes uniformly in the fitting portion, the thickness of the bonded lens changes. The accuracy at the time of installation deteriorates, and as a result, the desired optical characteristics cannot be obtained.

The present invention has been made in view of the above circumstances, and is a bonding lens capable of preventing the adhesive from overflowing into the fitting portion when the lenses are bonded to each other with an adhesive, and a camera including the bonding lens. The purpose is to provide a module.

In order to solve the above problems, the bonded lens of the present invention is a bonded lens in which upper and lower lenses are bonded to each other with an adhesive, and flange portions on the outer peripheral portion of these lenses are fitted to each other at a fitting portion. hand,
The surface of the upper lens facing the lower lens is a convex surface, and the surface of the lower lens facing the upper lens is a concave surface.
The fitting portion is provided on the flange portion of the lower lens and is provided on the flange portion of the upper lens so as to be inclined downward toward the outer side in the radial direction. It is composed of fitting with a fitting surface that inclines downward as it goes toward it.
An adhesive pool is annularly formed on the flange portion of the lower lens on the radial outer side of the adhesive layer between the bonded upper lens and the lower lens and on the radial inner side of the fitting portion. Provided in
The outer peripheral portion of the adhesive reservoir is provided with an ascending wall extending upward from the bottom surface of the adhesive reservoir.

Here, the upper and lower lenses refer to the lens arranged on the lower side as the lower lens and the lens arranged on the upper side as the upper side when the lenses are bonded together with their optical axes directed in the vertical direction. It is defined as the lens of. Therefore, the adhesive injected between the lenses flows from upward (including diagonally upward) to downward (including diagonally downward) due to gravity.

In the present invention, when the adhesive crosses the adhesive layer between the lenses, the adhesive flows into the adhesive reservoir, and an ascending wall from the bottom surface of the adhesive reservoir to the upper side is provided on the outer peripheral portion of the adhesive reservoir. Therefore, the adhesive that has flowed into the adhesive pool is blocked by the ascending wall. Therefore, when the lenses are bonded to each other with the adhesive, it is possible to prevent the adhesive from overflowing to the fitting portion.

In the configuration of the present invention, the fitting portion may be configured by fitting the upper portion of the ascending wall and the flange portion of the lens on the upper side.

According to such a configuration, since the fitting portion can be formed by using the upper portion of the ascending wall, it is not necessary to form another fitting shape forming the fitting portion on the lower flange portion.

Further, in the configuration of the present invention, the distance between the facing surfaces outside the effective diameter of the upper and lower lenses is wider than the distance between the lens surfaces of the upper and lower lenses within the effective diameter of the upper and lower lenses. It is preferable to have.
In particular, it is preferable that the distance between the lens surfaces and the distance between the facing surfaces become wider toward the outer side in the radial direction.

According to such a configuration, when the lenses are joined to each other, the adhesive flows outward in the radial direction from the lens surface side to the facing surface side, but the facing surfaces are separated from each other due to the distance between the lens surfaces. Since the distance between the lenses is widened, the air bubbles in the adhesive move so as to be pushed out from between the lens surfaces to between the facing surfaces as the lenses to be bonded approach each other, and become an adhesive pool. Since it flows in, it is easily discharged to the outside of the effective diameter. Therefore, it becomes easy to remove air bubbles between the lens surfaces.

Further, in the configuration of the present invention, of the upper and lower flange portions of the lens, the outer peripheral surface of one flange portion may protrude radially outward from the outer peripheral surface of the other flange portion.

According to such a configuration, when the bonded lens is inserted into a cylindrical lens frame (lens barrel) and fixed, the outer peripheral surface of one flange portion is brought into contact with the inner peripheral surface of the lens frame. Therefore, the laminating lens can be positioned in the radial direction. Further, since the outer peripheral surface of the other flange portion does not abut on the inner peripheral surface of the lens frame, no force acts on the other lens from the lens frame. Therefore, it is possible to prevent the lenses from peeling off due to this force.

The camera module of the present invention is characterized by including the laminated lens.
According to such a configuration, the action and effect of the above-mentioned laminated lens can be obtained by the camera module.

According to the present invention, when the lenses are bonded to each other with an adhesive, the adhesive can be prevented from overflowing to the fitting portion.

It is sectional drawing which shows the lens unit which concerns on 1st Embodiment of this invention. It is sectional drawing which shows the laminated lens which concerns on 1st Embodiment of this invention. It is sectional drawing which shows the laminated lens which concerns on 2nd Embodiment of this invention. It is sectional drawing which shows the laminated lens which concerns on 3rd Embodiment of this invention. It is sectional drawing which shows the laminated lens which concerns on 4th Embodiment of this invention. It is the schematic sectional drawing which shows the camera module which concerns on embodiment of this invention.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
(First Embodiment)
FIG. 1 shows a lens unit 11 having a bonded lens 18 according to the first embodiment. The lens unit 11 is, for example, for an in-vehicle camera, and is installed on the outside of an automobile with at least the end portion (upper end portion in FIG. 1) of the lens unit 11 on the object side exposed.

The lens unit 11 includes a cylindrical lens barrel 12, a plurality of (for example, four) lenses 13, 14, 15, 18 arranged in the lens barrel 12, and two diaphragm members 21 and 22. There is. An in-vehicle camera including the lens unit 11 includes a lens unit 11, a substrate having an image sensor (not shown), and an installation member (not shown) for installing the substrate in a vehicle such as an automobile.

The plurality of lenses 13, 14, 15, and 18 fixedly supported by the lens barrel 12 are arranged in a state in which their respective optical axes are aligned with each other, and the respective lenses 13, 14 are arranged along one optical axis. , 15 and 18 are arranged side by side to form one group of lenses used for imaging. Further, the lens 18 is a bonded lens 18, and the lens 16 and the lens 17 are bonded to each other with an adhesive.

The first aperture member 21 of the two aperture members 21 and 22 from the object side (one end of the lens barrel 12) is arranged between the second lens 14 and the third lens 15 from the object side. Has been done. The second aperture member 22 from the object side is arranged between the third lens 15 and the fourth lens 16 from the object side. The diaphragm members 21 and 22 are an "aperture diaphragm" that limits the amount of transmitted light and determines an F value that is an index of brightness, or a "light-shielding diaphragm" that blocks light rays that cause ghosts and light rays that cause aberrations. ..

The inner diameter of the lens barrel 12 is reduced by caulking one end (upper end in FIG. 1) on the object side, and the lens barrel is smaller than the outer diameter of the lens 13 on the most object side housed inside. The inner diameter of the end portion of the 12 on the object side is reduced, whereby the frame portion 23 is provided.
Further, a frame portion 24 having an opening having a diameter smaller than that of the bonded lens 18 is provided at the other end portion (lower end portion in FIG. 1) of the lens barrel 12 on the image side. A plurality of lenses 13, 14, 15, 18 and aperture members 21 and 22 forming a lens group are held in the lens barrel 12 by the frame portions 23 and 24. The frame portion 23 may be attached to the end portion of the lens barrel 12 on the object side after the lenses 13, 14, 15, and 18 are housed in the lens barrel 12.

On the outer peripheral surface of the lens 13 on the most object side, a reduced diameter portion having a smaller diameter is provided on the image side portion of the lens 13, and an O ring 26 as a sealing member is provided on the reduced diameter portion. The outer peripheral surface of the lens barrel 12 and the inner peripheral surface of the lens barrel 12 are sealed by the object-side end of the lens barrel 12. This prevents fine particles such as water and dust from entering the lens barrel 12 from the end of the lens unit 11 on the object side.

The inner diameter of the lens barrel 12 gradually decreases from the object side to the image side. Correspondingly, the outer diameters of the lenses 13, 14, 15, and 18 become smaller as their arrangement positions move from the object side to the image side. Basically, the outer diameters of the lenses 13, 14, 15 and 18 are substantially equal to the inner diameters of the portions of the lens barrel 12 on which the lenses 13, 14, 15 and 18 are supported. On the outer peripheral surface of the lens barrel 12, a flange portion 25 used for installing the lens barrel 12 on an in-vehicle camera is provided on the outer peripheral surface of the lens barrel 12 in a flange shape.

Further, among the lenses 13, 14, 15 and 18, the lens 13 exposed to the outside of the vehicle (outside the lens barrel 12) on the most object side is a glass lens, and the lenses 14, 15 and 18 are resin lenses.
The image-side bonded lens 18 has a surface (lower surface in FIG. 1) on the image side of the outer peripheral portion that is orthogonal to the optical axis as a reference surface. The reference surface of the bonded lens 18 is in contact with the reference surface on the inner surface side of the frame portion 23 having an opening having an inner diameter smaller than the outer diameter of the bonded lens 18.

In the present embodiment, as shown in FIG. 2, the bonded lens 18 is formed by bonding a concave lens 16 on the object side and a convex lens 17 on the image side with an adhesive, and the lenses 16 and 17 are made of resin. It consists of a lens. In the following, the concave lens 16 may be simply referred to as a lens 16 and the convex lens 17 may be simply referred to as a lens 17.
Further, when the concave lens 16 and the convex lens 17 are bonded together, the concave lens 16 is on the bottom and the convex lens 17 is on the top. Therefore, in FIG. 2, the concave lens 16 is on the bottom and the convex lens 17 is on the top. These are illustrated. The top and bottom in the following description are based on the above-mentioned vertical relationship at the time of bonding.
When incorporating the bonded lens 18 into the lens barrel 12, the bonded lens 18 shown in FIG. 2 is installed upside down.

The concave lens 16 has a concave surface 31 on the image side and a convex surface 36 on the object side. Further, the concave lens 16 includes a lens portion 16b having a desired lens function and an annular flange portion 16a formed on the outer periphery of the outer peripheral edge thereof. Further, when the concave lens 16 and the convex lens 17 are attached to each other, the adhesive is injected into the concave surface 31 with the concave surface 31 of the concave lens 16 facing up.

The convex lens 17 includes a convex surface 41 on the object side through which light passes and a convex surface 46 on the image side. Further, the convex lens 17 includes a lens portion 17b having a desired lens function and an annular flange portion 17a formed on the outer periphery thereof. The concave surface 31 on the image side of the concave lens 16 and the convex surface 41 on the object side of the convex lens 17 have an effective diameter r as a range having a lens function.
When the concave lens 16 and the convex lens 17 are bonded to each other, the convex surface 41 on the object side of the convex lens 17 is bonded to the concave surface 31 on the image side of the concave lens 16 with an adhesive.
In this case, the adhesive layer 51 is formed between the concave surface 31 of the concave lens 16 and the convex surface 41 of the convex lens 17. Although the adhesive is not shown in FIG. 2, the adhesive layer 51 is filled with the adhesive. Further, the range of the adhesive layer 51 is wider than the range of the effective diameter r, and extends to the space between the facing surfaces 54 and 55, which will be described later.

An adhesive reservoir 53 is provided in an annular shape on the flange portion 16a on the outer side of the effective diameter r of the lens 16. The adhesive reservoir 53 is formed in a substantially inverted trapezoidal cross section, and has an annular bottom surface 53a and an annular inclined surface continuously provided on the inner peripheral side of the bottom surface 53a. It is composed of 53b and an annular inclined surface 53c provided continuously with the bottom surface 53a on the outer peripheral side of the bottom surface 53a.
The inclined surface 53c is an ascending wall 53c that extends diagonally upward from the outer peripheral edge of the bottom surface 53a of the adhesive reservoir 53 toward the outside in the radial direction. On the outer peripheral side of the ascending wall 53c, a flat surface 53d having a height equal to the upper edge of the ascending wall 53c is provided continuously with the ascending wall 53c.
Further, a flat facing surface 54 is provided in an annular shape between the inclined surface 53b and the concave surface 31. The facing surface 54 is provided outside the effective diameter of the concave lens 16 and is continuous with the lens surface (concave surface) 31 within the effective diameter. Actually, there is a surface forming the outer peripheral side of the lens surface 31 on the outer peripheral side of the effective diameter of the lens surface 31, and the facing surface 54 is continuous with this surface. Further, the facing surface 54 is located above the flat surface 53d (image side).

On the other hand, on the outer peripheral side of the lens surface (convex surface) 41 of the lens 17, a flat facing surface 55 is provided in an annular shape and at a predetermined distance from the facing surface 54. The radial width of the facing surface 55 is substantially equal to or slightly wider than the radial width of the facing surface 54. The facing surface 56 is provided outside the effective diameter of the convex lens 17 and outside the facing surface 55, and is continuous with the facing surface 55. Actually, there is a surface forming the outer peripheral side of the lens surface 41 on the outer peripheral side of the effective diameter of the lens surface 41, and the facing surface 55 is continuous with this surface.

Further, on the outer peripheral side of the facing surface 55, an inclined surface 56 that inclines downward in the radial direction is provided continuously with the facing surface 55. The inclined surface (opposing surface) 56 is arranged to face the inclined surface (opposing surface) 53b at a predetermined interval, and is shorter in the inclined direction than the inclined surface 53b.
Further, on the outer peripheral side of the inclined surface 56, a flat surface 57 is provided continuously with the inclined surface 56, and the flat surface 57 is parallel to the bottom surface 53a of the adhesive reservoir 53. Further, the flat surface 57 faces the bottom surface 53a and the flat surface 53d at a predetermined interval.

The adhesive potted on the bottom surface of the concave surface 31 of the concave lens 16 fills the space between the concave surface 31 and the convex surface by bonding the concave surface 31 of the concave lens 16 and the convex surface of the convex lens 17, and a part of the adhesive is formed with the facing surface 54 and the facing surface 55. Spreads through the gaps between the two, is filled between the gaps, and excess adhesive descends between the slope (opposing surface) 53b and the slope (opposing surface) 56 along the slope 53b. It flows into the adhesive reservoir 53. Therefore, the height of the ascending wall 53c that functions as a damming portion of the adhesive reservoir 53 is set to a height so that excess adhesive does not exceed the upper end of the ascending wall 53c.

Further, from the distance between the lens surfaces 41 and 31 of the upper and lower lenses 17 and 16 within the effective diameter of the upper and lower lenses 17 and 16, the distance between the facing surfaces 55 and 54 outside the effective diameter of the upper and lower lenses 17 and 16 is increased. And the distance between the inclined surfaces (opposing surfaces) 56 and 53b is wide. As a result, air bubbles mixed or generated in the adhesive are easily discharged to the outside of the lens portion.
Further, the distance between the lens surfaces 41 and 31 becomes wider toward the outer side in the radial direction, and air bubbles are more easily discharged.
Specifically, the distance between the lens surfaces 41 and 31 is smaller than the distance between the central portion of the lens surfaces 41 and 31 (the portion where the lens surfaces 41 and 31 and the optical axis intersect and the vicinity thereof). The distance between the outer peripheral sides of the surfaces 41 and 31 is gradually increasing. That is, the lens surface (concave surface) 31 and the lens surface (convex surface) 41 are different in concave and convex, but have substantially the same shape, unlike conventional laminated lenses, which have different shapes. The concave surface 31 and the convex surface 41 are aspherical surfaces, but the curvature of the convex surface 41 is generally larger than the curvature of the concave surface 31. As a result, the distance between the concave surface 31 and the convex surface 41 gradually increases from the center toward the peripheral edge. The concave surface 31 and the convex surface 41 may be spherical surfaces.
Further, the distance between the facing surface (inclined surface) 53b and the facing surface (inclined surface) 56 is wider than the distance between the facing surface 54 and the facing surface 55.

Further, the flange portion 16a of the lens 16 and the flange portion 17a of the lens 17 are fitted to each other. That is, the flange portion 16a is provided with a fitting surface 58 that is inclined downward (object side) from the outer peripheral edge of the flat surface 53 toward the outer side in the radial direction on the outer peripheral side of the flat surface 53d.
Further, the flange portion 17a is provided with a fitting surface 59 on the outer peripheral side of the flat surface 57, which is inclined downward (object side) from the outer peripheral edge of the flat surface 57 toward the outer side in the radial direction.
The fitting portion 60 is formed by fitting the fitting surfaces 58 and 59. When the lens 16 and the lens 17 are bonded together, the fitting surfaces 58 and 59 position the lenses 16 and 17 in the radial direction (orthogonal direction of the optical axis). That is, the optical axes of the lenses 16 and 17 are aligned.
Since the fitting surfaces 58 and 59 constituting the fitting portion 60 have a function of guiding the lenses so that the optical axes coincide with each other, the inclination angles of the fitting surfaces 58 and 59 are set. There is no need to match. However, the angle of the fitting surface 58 with respect to the optical axis is preferably smaller than the angle of the fitting surface 59 with respect to the optical axis. That is, it is preferable that the fitting surfaces 58 and 59 are separated from each other as the distance from the contact surface of the flange portion 16a and the flange portion 17a for positioning in the optical axis direction increases. Compared to the opposite, there is an advantage that it is easier to attract the other lens in manufacturing.
Further, the fitting surfaces 58 and 59 do not necessarily have to be in contact with each other when the bonding is completed, and may be separated from each other as long as they are within a predetermined tolerance range. When the fitting surfaces 58 and 59 come into contact with each other, it may be difficult to position the fitting surfaces 58 and 59 in the optical axis direction by the flange portion 17a and the flange portion 16a, which will be described later. When the minimum value of the gap amount when looking at the gap amount of the above and the gap amount on the other side of the optical axis in the optical axis direction is Δ, the range of 0 <Δ≤20 μm is satisfied. preferable. The minimum clearance amount Δ is applied to a lens having a lens portion diameter (diameter at the boundary with a flange surface whose lens surface shape is clearly changed) of 1.5 to 3.0 mm as a premise. Is the value of.
Further, on the outside (outer peripheral side) of the fitting portion 60, the surface 16c on the upper side (image side) of the flange portion 16a and the surface 17c on the lower side (object side) of the flange portion 17a are in contact with each other. , The lenses 16 and 17 are positioned in the optical axis direction.

Further, the outer peripheral surface of the flange portion 16a of the lens 16 projects outward in the radial direction from the outer peripheral surface of the flange portion 17a of the lens 17. That is, the lens 16 has a larger diameter than the lens 17.

With such a configuration, when the lenses 16 and 17 are joined, the adhesive that overflows from the disk-shaped adhesive layer 51 to the outside along the substantially radial direction is the outer facing surface of the adhesive layer 51 in a plan view. It reaches between 54 and 55 (adhesive passage) and between facing surfaces 53b and 56 (adhesive passage), and further flows out so that the adhesive spreads outward in the radial direction, and an adhesive pool provided on the outside of the adhesive passage. It is designed to flow into 53. Since an ascending wall 53c extending upward from the bottom surface 53a of the adhesive reservoir 53 is provided on the outer peripheral portion of the adhesive reservoir 53, excess adhesive flowing into the adhesive reservoir 53 is blocked by the ascending wall 53c. Therefore, it does not overflow to the fitting portion 60 side.

As described above, according to the present embodiment, the flange portion of the lower lens 16 is radially outside the adhesive layer 51 between the bonded lenses 16 and 17 and radially inside the fitting portion 60. An adhesive reservoir 53 is provided in an annular shape in 16a, and an ascending wall 53c extending upward from the bottom surface 53a of the adhesive reservoir 53 is provided on the outer peripheral portion of the adhesive reservoir 53, so that the adhesive can be applied to the adhesive layer 51. When the amount exceeds, the adhesive flows into the adhesive reservoir 53, and the inflowing adhesive is blocked by the ascending wall 53c. Therefore, when the lenses 16 and 17 are bonded to each other with the adhesive, it is possible to prevent the adhesive from overflowing to the fitting portion 60.

Further, the distance between the facing surfaces 55 and 54 and the facing surfaces 56 and 53b outside the effective diameter of the lenses 17 and 16 is larger than the distance between the lens surfaces 41 and 31 within the effective diameter of the upper and lower lenses 17 and 16. The interval between them is wide. Therefore, when the lenses 17 and 16 are joined to each other, the adhesive flows outward in the radial direction from the lens surfaces 41 and 31 to the facing surfaces 55 and 54, but the bubbles in the adhesive are attached. As the lenses 17 and 16 to be combined approach each other, they move so as to be pushed out from between the lens surfaces 41 and 31 to between the facing surfaces 55 and 54 and between the facing surfaces (inclined surfaces) 56 and 53b. Since it flows into the adhesive reservoir 53, it is easily discharged to the outside of the effective diameter. Therefore, it becomes easy to remove air bubbles between the lens surfaces 41 and 31.

Further, since the outer peripheral surface of the flange portion 16a of the lens 16 projects radially outward from the outer peripheral surface of the flange portion 17a of the lens 17, the bonded lens 18 formed by bonding the lenses 16 and 17 is inside the lens barrel 12. When the lens 16 is inserted into the lens 16 and fixed to the lens 16, the flange portion 16a of the lens 16 comes into contact with the inner peripheral surface of the lens barrel 12, so that the lens 18 can be positioned in the radial direction. Further, since the outer peripheral surface of the flange portion 17a of the lens 17 does not abut on the inner peripheral surface of the lens barrel 12, no force acts on the lens 17 from the inner peripheral surface of the lens barrel 12. Therefore, it is possible to prevent the lenses 16 and 17 from peeling off due to this force.

(Second Embodiment)
FIG. 3 is a cross-sectional view showing the bonded lens 18A of the second embodiment.
The main difference between the bonded lens 18A and the bonded lens 18 of the first embodiment is the shape of the joint surface of the upper lens 17, so this point will be described below, and the first embodiment will be described. The same reference numerals are given to the configurations common to the forms, and the description thereof will be omitted or simplified.

The bonding lens 18A of the second embodiment is formed by bonding the lens 16 on the object side and the lens 17 on the image side with an adhesive.
When incorporating the bonded lens 18A into the lens barrel 12, the bonded lens 18A shown in FIG. 3 is installed upside down.

The inclined surface 56a of the lens 17 is longer in the inclined direction than the inclined surface 56 of the lens 17 in the first embodiment, and the outer peripheral edge of the inclined surface 56a is in the vicinity of the bottom surface 53a of the adhesive reservoir 53. Is located in. A flat surface 61 is provided in an annular shape on the outer peripheral side of the inclined surface 56a, and a slight gap is provided between the flat surface 61 and the bottom surface 53a. Further, an inclined surface 62 is provided in an annular shape on the outer peripheral side of the flat surface 61. The inclined surface 62 is inclined upward (image side) toward the outer side in the radial direction, and a flat surface 63 is provided in an annular shape on the outer peripheral side of the inclined surface 62. A fitting surface 59 is provided on the outer peripheral side of the flat surface 63, and the fitting surface 59 is fitted with the fitting surface 58 of the lens 16.

Further, in the present embodiment, the distance on the outer peripheral side between the lens surfaces 41 and 31 of the upper and lower lenses 17 and 15 within the effective diameter of the upper and lower lenses 17 and 16 and the effective diameter of the upper and lower lenses 17 and 16 The distance between the facing surfaces 55 and 54 on the outside and the distance between the inclined surfaces 56a and 53b are equal.
Further, the distance between the lens surfaces 41 and 31 is wider on the central side than on the outer peripheral side.

In the present embodiment, the inclined surface 56a has substantially the same length as the inclined surface 53b of the adhesive reservoir 53, and the distance between the inclined surface 56a and the inclined surface 53b is the same as that of the first embodiment. Since it is narrower than the distance between the inclined surface 56 and the inclined surface 53b, the amount of adhesive required for adhering the lenses 16 and 17 including the adhesive accumulated in the adhesive reservoir 53 is smaller than that in the first embodiment. There is an advantage that it can be done. Therefore, the volume of the adhesive reservoir 53 is smaller than the volume of the adhesive reservoir 53 of the first embodiment. Further, since the area of the adhesive layer outside the effective diameter is larger than that of the first embodiment, there is an advantage that the adhesive strength is increased accordingly.
Further, in the present embodiment, since the outer peripheral surface of the flange portion 17a of the lens 17 projects outward in the radial direction from the outer peripheral surface of the flange portion 16a of the lens 16, the laminated lens formed by laminating the lenses 16 and 17 is formed. When the 18A is inserted into the lens barrel 12 and fixed, the flange portion 17a of the lens 17 comes into contact with the inner peripheral surface of the lens barrel 12.

Further, also in the present embodiment, as in the first embodiment, the adhesive flowing into the adhesive reservoir 53 is blocked by the ascending wall 53c, so that when the lenses 16 and 17 are bonded to each other with the adhesive. , It is possible to prevent the adhesive from overflowing to the fitting portion 60.
Further, when the bonded lens 18A is inserted into the lens barrel 12 and fixed, the flange portion 17a of the lens 17 comes into contact with the inner peripheral surface of the lens barrel 12 to position the bonded lens 18A in the radial direction. It can be carried out. Further, since the outer peripheral surface of the flange portion 16a of the lens 16 does not abut on the inner peripheral surface of the lens barrel 12, no force acts on the lens 16 from the inner peripheral surface of the lens barrel 12. Therefore, it is possible to prevent the lenses 16 and 17 from peeling off due to this force.

(Third Embodiment)
FIG. 4 is a cross-sectional view showing the bonded lens 18B of the third embodiment.
The main difference between the bonded lens 18B and the bonded lens 18A of the second embodiment is the distance between the joint surfaces of the lens 16 and the lens 17, and this point will be described below. The same reference numerals are given to the configurations common to those of the embodiment, and the description thereof will be omitted or simplified.

In the present embodiment, the facing surface 55 outside the effective diameter of the upper and lower lenses 17 and 16 is increased by the distance between the lens surfaces 41 and 31 of the upper and lower lenses 17 and 15 within the effective diameter of the upper and lower lenses 17 and 16. , 54 The distance between the inclined surfaces 56a and 53b and the distance between the bottom surface 53a and the flat surface 61 are wider.
Further, the distance between the facing surfaces 55 and 54, the distance between the inclined surfaces (opposing surfaces) 56a and 53b, and the distance between the bottom surface 53a and the flat surface 61 are equal.
Further, the distance between the lens surfaces 41 and 31 becomes wider toward the outer side in the radial direction.

As described above, in the present embodiment, the effective diameter of the upper and lower lenses 17 and 16 is out of the effective diameter of the upper and lower lenses 17 and 16 due to the distance between the lens surfaces 41 and 31 of the upper and lower lenses 17 and 15. The distance between the facing surfaces 55 and 54, the distance between the inclined surfaces (opposing surfaces) 56a and 53b, and the distance between the bottom surface 53a and the flat surface 61 are wider.
Therefore, when the lenses 17 and 16 are joined to each other, the adhesive flows outward in the radial direction from the lens surfaces 41 and 31 to the facing surfaces 54 and 53, but the bubbles in the adhesive are attached. As the lenses 17 and 16 to be combined approach each other, between the lens surfaces 41 and 31, between the facing surfaces 55 and 54, between the facing surfaces (inclined surfaces) 56a and 53b, and between the bottom surface 53a and the flat surface 61. Since it moves so as to be pushed out between them and flows into the adhesive reservoir 53, it is easily discharged to the outside of the effective diameter. Therefore, it becomes easy to remove air bubbles between the lens surfaces 41 and 31.

Further, also in the present embodiment, as in the second embodiment, the adhesive flowing into the adhesive reservoir 53 is blocked by the ascending wall 53c, so that when the lenses 16 and 17 are bonded to each other with the adhesive. , It is possible to prevent the adhesive from overflowing to the fitting portion 60.
Further, when the bonded lens 18B is inserted into the lens barrel 12 and fixed, the flange portion 17a of the lens 17 comes into contact with the inner peripheral surface of the lens barrel 12 to position the bonded lens 18A in the radial direction. It can be carried out. Further, since the outer peripheral surface of the flange portion 16a of the lens 16 does not abut on the inner peripheral surface of the lens barrel 12, no force acts on the lens 16 from the inner peripheral surface of the lens barrel 12. Therefore, it is possible to prevent the lenses 16 and 17 from peeling off due to this force.

(Fourth Embodiment)
FIG. 5 is a cross-sectional view showing the bonded lens 18C of the fourth embodiment.
As shown in FIG. 5, the bonded lens 18C is formed by bonding a concave lens 66 on the object side and a convex lens 67 on the image side with an adhesive.
When the concave lens 66 and the convex lens 67 are bonded together, the bonding operation is performed with the concave lens 66 facing down and the convex lens 67 facing up. When the bonding lens 18C is incorporated in the lens barrel 12, FIG. The laminated lens 18C shown in the above is installed upside down.

The concave lens 66 has a concave surface 31 on the image side and a convex surface 36 on the object side. Further, the concave lens 66 includes a lens portion 66b that is within the range of its optical effective diameter and an annular flange portion 66a formed on the outside of the outer peripheral edge thereof. Further, when the concave lens 66 and the convex lens 67 are attached to each other, the adhesive is injected into the concave surface 31 with the concave surface 31 of the concave lens 66 facing up.

The convex lens 67 includes a convex surface 41 on the object side through which light passes and a convex surface 46 on the image side. Further, the convex lens 67 includes a lens portion 67b within the range of its effective diameter r and an annular flange portion 67a formed on the outer periphery of the outer peripheral edge thereof.
When the concave lens 66 and the convex lens 67 are bonded to each other, the convex surface 41 on the object side of the convex lens 67 is bonded to the concave surface 31 on the image side of the concave lens 66 with an adhesive.
In this case, the adhesive layer 51 is formed between the concave surface 31 of the concave lens 66 and the convex surface 41 of the convex lens 67. Although the adhesive is not shown in FIG. 5, the adhesive layer 51 is filled with the adhesive. Further, the range of the adhesive layer 51 is wider than the range of the effective diameter r, and extends between the facing surfaces 54 and 55.

An adhesive reservoir 73 is provided in an annular shape on the flange portion 66a on the outer side of the effective diameter r of the lens 66. The adhesive reservoir 73 is formed to have a substantially L-shaped cross section, and has a flat annular bottom surface 73a and a cylindrical inclined surface 73c provided continuously with the bottom surface 73a on the outer peripheral side of the bottom surface 73a. It is composed of.
The inclined surface 73c is an ascending wall 73c that extends diagonally upward from the outer peripheral edge of the bottom surface 73a of the adhesive reservoir 73 toward the outside in the radial direction. A flat surface 73d having a height equal to the upper edge of the ascending wall 73c is provided on the outer peripheral side of the ascending wall 73c.
Further, an inclined surface 73b is provided on the inner peripheral side of the bottom surface 73a of the adhesive reservoir 73, and a flat facing surface 54 is provided in an annular shape between the inclined surface 73b and the concave surface 31. The facing surface 54 is provided outside the effective diameter of the concave lens 66, and is continuous with the lens surface (concave surface) 31 within the effective diameter. Actually, there is a surface continuous with the lens surface 31 on the outer peripheral side of the effective diameter of the lens surface 31, and the facing surface 54 is adjacent to this surface. Further, the facing surface 54 is located above the flat surface 73d (image side).

On the other hand, on the outer peripheral side of the lens surface (convex surface) 41 of the lens 67, a flat facing surface 55 is provided in an annular shape and at a predetermined distance from the facing surface 54. The radial width of the facing surface 55 is substantially equal to or slightly wider than the radial width of the facing surface 54.
Further, on the outer peripheral side of the facing surface 55, an inclined surface 76 that inclines downward toward the outer side in the radial direction is provided. The inclined surface (opposing surface) 76 is arranged to face the inclined surface (opposing surface) 73b at a predetermined interval, and has substantially the same length in the inclined direction as the inclined surface 73b.
Further, a flat surface 77 is provided in an annular shape on the outer peripheral side of the inclined surface 76, and the flat surface 77 is parallel to the bottom surface 73a of the adhesive reservoir 73, and the flat surface 77 is the bottom surface 73a. And face each other at a predetermined interval.

A part of the adhesive injected between the concave surface 31 of the concave lens 66 and the convex surface 41 of the convex lens 67 spreads between the facing surface 54 and the facing surface 55 so as to pass between them, and is filled between them. Further, excess adhesive flows down between the inclined surface 73b and the inclined surface 76 along the inclined surface 73b and flows into the adhesive reservoir 73. Therefore, the height of the ascending wall 73c that functions as a damming portion of the adhesive reservoir 73 is set to a height so that excess adhesive does not exceed the upper end of the ascending wall 73c.

Further, from the distance between the lens surfaces 41 and 31 of the upper and lower lenses 67 and 66 within the effective diameter of the upper and lower lenses 67 and 66, the distance between the facing surfaces 55 and 54 outside the effective diameter of the upper and lower lenses 67 and 66. And the distance between the inclined surfaces 76 and 73b is wide.
Further, the distance between the facing surface (inclined surface) 73b and the facing surface (inclined surface) 76 is wider than the distance between the facing surface 54 and the facing surface 55.
As for the distance between the lens surfaces 41 and 31, the distance on the outer peripheral side of the lens surfaces 41 and 31 is closer to the center of the lens surfaces 41 and 31 (the lens surfaces 41 and 31 and the optical axis intersect). It is wider than the distance between the part to be used and its vicinity.

Further, the flange portion 66a of the lens 66 and the flange portion 67a of the lens 67 are fitted to each other. That is, an inclined surface 78 is provided on the outer peripheral side of the flat surface 77 of the lens 67. The inclined surface 78 is formed so as to be obliquely upward from the outer peripheral edge of the flat surface 77 toward the outer side in the radial direction, and the inclination angle with respect to the optical axis is equal to that of the ascending wall 73c.
Then, the fitting portion 60A is formed by fitting the inclined surface 78 and the upper portion 73e of the ascending wall 73c. That is, substantially the upper half of the ascending wall 73c is the fitting surface 73e, the entire inclined surface 78 is the fitting surface 78, and these fitting surfaces 73e and 78 are fitted together to form the fitting portion 60A. It is configured. The fitting portion 60 positions the lenses 66 and 67 in the radial direction. That is, the optical axes of the lenses 66 and 67 are aligned.
Further, a flat surface 79 is provided in an annular shape on the outer peripheral side of the inclined surface 78 of the lens 67. The flat surface 79 is formed on the lower surface (object side surface) of the flange portion 67a, and the flat surface 73d is formed on the upper surface (image side surface) of the flange portion 66a.
On the outside (outer peripheral side) of the fitting portion 60A, the flat surface 73d on the upper side (image side) of the flange portion 66a and the flat surface 79c on the lower side (object side) of the flange portion 67a are in contact with each other. As a result, the lenses 66 and 67 are positioned in the optical axis direction.

Further, the outer peripheral surface of the flange portion 66a of the lens 66 projects outward in the radial direction from the outer peripheral surface of the flange portion 67a of the lens 67. That is, the lens 66 has a larger diameter than the lens 67.

With such a configuration, when the lenses 66 and 67 are joined, the adhesive that overflows from the disk-shaped adhesive layer 51 to the outside along the substantially radial direction is the outer facing surface of the adhesive layer 51 in a plan view. An adhesive provided on the outside of the adhesive passage, reaching between 54 and 55 (adhesive passage) and between the inclined surfaces 73b and 76 (adhesive passage), and further flowing out so that the adhesive spreads radially outward. It is designed to flow into the sump 73. Since an ascending wall 73c extending upward from the bottom surface 73a of the adhesive reservoir 73 is provided on the outer peripheral portion of the adhesive reservoir 73, excess adhesive flowing into the adhesive reservoir 73 is blocked by the ascending wall 73c. Therefore, it does not overflow to the fitting portion 60A side.

FIG. 6 is a schematic cross-sectional view of the camera module 300 of the present embodiment. As shown in FIG. 6, the camera module 300 includes a lens unit 11 to which the filter 100 is mounted. The lens unit 11 has a bonded lens 18 as described above. Therefore, the camera module 300 is provided with the bonded lens 18. In the camera module 300, the laminated lenses 18A, 18B, and 18C may be incorporated in the lens unit 11 instead of the bonded lens 18.

The camera module 300 includes an upper case (camera case) 301, which is an exterior component, and a mount (flange, pedestal) 302 that holds the lens unit 11. Further, the camera module 300 includes a seal member 303 and a package sensor (imaging element) 304.

The upper case 301 is a member that exposes the end portion of the lens unit 11 on the object side and covers the other portion. The mount 302 is arranged inside the upper case 301 and has a female screw 302a that is screwed with the male screw 11a of the lens unit 11. The seal member 303 is a member inserted between the inner surface of the upper case 301 and the outer peripheral surface of the lens barrel 1 of the lens unit 11, and is a member for maintaining the airtightness inside the upper case 301.

The package sensor 304 is arranged inside the upper case 301, and is arranged at a position where it receives an image of an object formed by the lens unit 11. Further, the package sensor 304 includes a CCD, CMOS, and the like, and converts the light collected through the lens unit 11 and reached into an electric signal. The converted electrical signal is converted into analog data or digital data, which are components of image data captured by the camera.

As described above, according to the present embodiment, the flange portion of the lower lens 66 is radially outside the adhesive layer 51 between the bonded lenses 66 and 67 and radially inside the fitting portion 60A. An adhesive reservoir 73 is provided in an annular shape on the 66a, and an ascending wall 73c extending upward from the bottom surface 73a of the adhesive reservoir 73 is provided on the outer peripheral portion of the adhesive reservoir 73, so that the adhesive can be applied to the adhesive layer 51. When the amount exceeds, the adhesive flows into the adhesive reservoir 73, and the inflowing adhesive is blocked by the ascending wall 73c. Therefore, when the lenses 66 and 67 are bonded to each other with the adhesive, it is possible to prevent the adhesive from overflowing to the fitting portion 60A.

Further, the distance between the facing surfaces 55 and 54 outside the effective diameter of the lenses 67 and 66 and the facing surface (inclined surface) are larger than the distance between the lens surfaces 41 and 31 within the effective diameter of the upper and lower lenses 67 and 66. The distance between 76 and 73b is wide. Therefore, when the lenses 67 and 66 are joined to each other, the adhesive flows outward in the radial direction from the lens surfaces 41 and 31 to the facing surfaces 55 and 54, but the bubbles in the adhesive are attached. As the lenses 67 and 66 to be combined approach each other, they move so as to be pushed out from between the lens surfaces 41 and 31 to between the facing surfaces 55 and 54 and between the facing surfaces (inclined surfaces) 76 and 73b. Since it flows into the adhesive reservoir 73, it is easily discharged to the outside of the effective diameter. Therefore, it becomes easy to remove air bubbles between the lens surfaces 41 and 31.

Further, since the outer peripheral surface of the flange portion 66a of the lens 66 protrudes outward in the radial direction from the outer peripheral surface of the flange portion 67a of the lens 67, the laminated lens 18C formed by bonding the lenses 66 and 67 is inside the lens barrel 12. When the lens 66 is inserted into and fixed to the lens 66, the flange portion 66a of the lens 66 comes into contact with the inner peripheral surface of the lens barrel 12, so that the bonded lens 68 can be positioned in the radial direction. Further, since the outer peripheral surface of the flange portion 67a of the lens 67 does not abut on the inner peripheral surface of the lens barrel 12, no force acts on the lens 67 from the inner peripheral surface of the lens barrel 12. Therefore, it is possible to prevent the lenses 66 and 67 from peeling off due to this force.
Further, the fitting portion 60A is formed by fitting the upper fitting surface 73d of the ascending wall 73c and the inclined surface 78 (fitting surface) provided on the flange portion 67a of the upper lens 67. Therefore, since the fitting portion 60A can be formed by using the upper portion of the ascending wall 73c, it is not necessary to form another fitting shape forming the fitting portion on the lower flange portion 66a.
Further, since the camera module 300 includes a lens unit 20 having the bonded lens 11, the effect of the bonded lens 11 described above can be obtained by the camera module 300.

In the first to fourth embodiments, the bonded lenses 18, 18A, 18B, and 18C are resin lenses, but the bonded lens of the present invention is not limited to the resin lens, but is a glass lens. May be good.

16,17,66,67 Lens 16a, 16b, 66a, 67a Flange part 18,18A, 18B, 18C Laminated lens 31,41 Lens surface 51 Adhesive layer 53,73 Adhesive pool 53a, 73a Bottom surface 53c, 73c Up wall 53b, 54-56, 56a, 73b, 76
60, 60A Fitting part 300 Camera module

Claims (4)

It is a bonded lens in which the upper and lower lenses are bonded to each other with an adhesive, and the flanges on the outer periphery of these lenses are fitted to each other at a fitting portion.
The surface of the upper lens facing the lower lens is a convex surface, and the surface of the lower lens facing the upper lens is a concave surface.
The fitting portion is provided on the flange portion of the lower lens and is provided on the flange portion of the upper lens so as to be inclined downward toward the outer side in the radial direction. It is composed of fitting with a fitting surface that inclines downward as it goes toward it.
An adhesive pool is annularly formed on the flange portion of the lower lens on the radial outer side of the adhesive layer between the bonded upper lens and the lower lens and on the radial inner side of the fitting portion. Provided in
A laminating lens characterized in that an ascending wall extending upward from the bottom surface of the adhesive reservoir is provided on the outer peripheral portion of the adhesive reservoir. The claim is characterized in that the distance between the facing surfaces outside the effective diameter of the upper and lower lenses is wider than the distance between the lens surfaces of the upper and lower lenses within the effective diameter of the upper and lower lenses. The bonded lens according to 1 . The bonded lens according to claim 1 or 2 , wherein the outer peripheral surface of one of the upper and lower flange portions of the lens projects radially outward from the outer peripheral surface of the other flange portion. A camera module including the bonded lens according to any one of claims 1 to 3 .

Images