The present invention relates to a lens unit suitable for imaging lenses and the like.
Compact and extremely thin type imaging devices (hereafter, also called a camera module) are employed for mobile terminals such as mobile telephones and PDA, which are compact and thin electric devices, such as mobile telephones and PDA (Personal Digital Assistant). As imaging elements used for these imaging devices, solid state imaging elements such as CCD image sensors and CMOS image sensors are known. In recent years, the imaging elements have been improved to increase the number of pixels, and to attain higher image resolution and higher performance. Further, an imaging lens to form an image of an object on these imaging elements is required to become compact more in response to the miniaturization of imaging elements, and such requirement tends to become stronger from year to year.
As an imaging lens used for the imaging device built in such a mobile terminal, an optical system constituted by resin lenses has been known. Incidentally, in the imaging lens, due to unnecessary reflection, glare, and diffusion in a lens barrel or on a lens end face, ghost and flare may take place. In order to prevent such ghost and flare, there is a technique to dispose between lenses a light shielding member (stop) including an opening to restrict a range to allow light rays to pass through. The positioning of the light shielding member is important, because, if it enters an effective diameter, it itself causes ghost or flare.
PTL (Patent Literature) 1 discloses a technique to utilize a black metal ring as a light shielding member. The advantages of this conventional technique are to make it easy to obtain the positioning accuracy and dimensional accuracy of a light shielding member, and to make it possible to shield light up to a position as near as the end of an effective diameter. However, since a guide for positioning such as a taper and a light shielding member are not likely to deform, a release portion to avoid interference is needed. Accordingly, there is a defect that it is to be disposed only at a limited portion of a lens.
PTL1: Japanese Unexamined Patent Application Publication No. 2006-79073 Official Report
PTL2: Japanese Unexamined Patent Application Publication No. 2010-217279 Official Report
On the other hand, there is also a technique to use a material other than a solid material such as a black adhesive agent as another light shielding member. According to such a technique, since a light shielding member deforms unlike the above technique, there is an advantage that restrictions in arrangement are few. However, it is difficult to control a position and a thickness due to the fluidity of an adhesive agent. Accordingly, such an adhesive agent tends to invade an effective diameter, which cause poor products. There is a defect that the yield tends to become low.
There is also a technique to avoid such a defect.
PTL2 discloses a technique to form a groove at a position where a light shielding adhesive agent is filled us and to fill the adhesive agent at the groove, thereby making it possible to control the position of the adhesive agent and preventing the lowering of the yield. Further, the height of the adhesive agent filled in the groove is made lower than a surface to come in contact with a lens, whereby dispersion in the thickness of the adhesive agent is made not to influence the accuracy of a position coming in contact with a lens.
Then, the present invention has been achieved in view of the problems of the conventional techniques, and an object of the present invention is to provide a lens unit capable of shielding light effectively in spite of having been produced through simple processes.
A lens unit described in claim 1 includes a first lens, a second lens, an annular light shielding member disposed between the first lens and the second lens, wherein the outer periphery of the light shielding member is disposed at an inside than the outer periphery of the first lens or the second lens, and a non-transmissive filler material is filled up and solidified over a space (region) between the outer periphery of the light shielding member and the outer periphery of the first lens or the second lens.
Here, when external light rays OL have invaded the lens unit LU′ from the outside, the external light rays OL are reflected on the image side surface of the first lens L1, then, reflected on the outer periphery of the lens unit LU′, penetrate the flange portions FL1 and FL2, so as to pass through the second lens L2, and escape to the image side. Accordingly, there is a fear that these rays may become ghost and may reduce imaging quality.
On the other hand, in the case of the present invention, a non-transmissive filler material is filled up and solidified over a space between the outer periphery of the light shielding member and the outer periphery of each of the first lens and the second lens. Here, an important thing is that, as shown with hatching in
In the case of the present invention, when external light rays OL have invaded from the outside, as shown in
Further, in the constitution shown in
In addition, in the constitution of
The lens unit described in claim 2 in the invention described in claim 1 is characterized in that the filler material is an adhesive agent to bond the first lens and the second lens.
If a light shielding function can be given to an adhesive agent, the reduction of the number of processes can be attained more.
The lens unit described in claim 3 in the invention described in claim 2 is characterized in that as the adhesive agent, an adhesive agent in which an energy hardenable adhesive agent serving as a base material and carbon black or a metal powder are mixed is used.
When an energy hardenable adhesive agent is used, since it becomes unnecessary to care about the hardening time, handling characteristics becomes excellent. Examples of the energy hardenable adhesive agent include a UV hardenable adhesive agent which is solidified by being irradiating with UV light rays and a heat hardenable adhesive agent which hardens by being heated. Here, an adhesive agent in which a UV hardenable adhesive agent is mixed with carbon etc., becomes difficult to be hardened due to its light shielding properties. However, a heat hardenable adhesive agent has no problem that hardening is obstructed by the light shielding properties, which is desirable. Further, at the time of joining three lenses, even if light shielding portions overlap with each other, it becomes possible to harden them by heating the entire body.
The lens unit described in claim 4 in the invention described in claim 3 is characterized in that the energy hardenable adhesive agent is a UV hardenable adhesive, and when the UV hardenable adhesive is hardened, UV light rays are irradiated from both sides of the optical axis to the UV hardenable adhesive provided between the first lens and the second lens.
As mentioned above, although an adhesive agent in which a UV hardenable adhesive agent is mixed with carbon etc., becomes difficult to be hardened due to its light shielding properties, when UV light rays are irradiated from both sides of the optical axis, it becomes possible to harden the adhesive agent effectively.
The lens unit described in claim 5 in the invention described in claim 3 is characterized in that the energy hardenable adhesive agent is a heat hardenable adhesive. In the case where UV light rays are difficult to reach a portion between lenses, the heat hardenable adhesive is effective.
The lens unit described in claim 5 in the invention described in any one of claims 1 to 4 is characterized in that the first lens and the second lens are bonded each other while a distance between the first lens and the second lens is kept at a predetermined distance.
Even if a filler material is non-transmissive for light, if its thickness is made thin, light tends to permeate through the filler material. In particular, in the state that the first lens and the second lens comes in contact with each other, the thickness of the filler material between them becomes near zero. Then, a distance between the first lens and the second lens is kept at a predetermined distance, whereby the thickness of the filler material filled up between them can be made to a thickness not to allow light to permeate through.
The lens unit described in claim 6 in the invention described in any one of claims 1 to 5 is characterized in that a first lens array including a plurality of the first lenses and a second lens array including a plurality of the second lenses are arranged to face each other and pasted to each other while interposing the light shielding member and the filler material between the first lens and the second lens, and thereafter, the pasted first lens array and second lens array are cut out for each pair of the first lens and the second lens.
With this, a plurality of lens units can be produced in large quantities at low cost.
The lens unit described in claim 7 in the invention described in any one of claims 1 to 6 is characterized in that the lens unit further includes a third lens and an another annular light shielding member disposed between the second lens and the third lens, the outer periphery of the another light shielding member is disposed at an inside than the outer periphery of the second lens or the third lens, and the filler material is filled and solidified over a space between the outer periphery of the light shielding member and the outer periphery of the second lens or the third lens.
With this, it becomes possible to provide a lens unit in which three or more lenses are superimposed in the optical axis direction.
According to the present invention, it becomes possible to provide a lens unit capable of shielding light effectively in spite of having been produced through simple processes.
Hereafter, the embodiments of the present invention will be described with reference to drawings.
On the other hand, on the top surface 21 of the lower molding die 20, an approximately square-shaped land portion 22 is formed, and on the flat top surface 23 of the land portion 22, four optical surface transferring surfaces 24 are formed so as to become concave in an arrangement of two rows and two lines. On each of the four sides of the land portion 22, a flat surface portion 25 is formed so as to incline at a predetermined angle relative to the respective optical axes of the optical surface transferring surfaces 24. The two flat surface portions 25 which neighbor on each other so as to make the respective axes orthogonal to each other are connected via a corner portion 26 (refer to
The multiple optical surface transferring surfaces of the molding die can be formed through grinding with a grinding stone by using an ultra-precision processing machine. After the grinding, in order to remove grinding traces, the optical surface transferring surfaces are subjected to polishing so that each of them can be finished into a mirror surface. The positional accuracy of each of optical surfaces can be confirmed such that a distance from the flat surface portion 25 to the optical surface transferring surface 24 and a distance between the two optical surface transferring surfaces 24 are measured with the use of a three-dimensional measuring instrument and the resulting measurements are checked whether to fall within a predetermined specification.
Next, description will be given to the molding of a lens array with reference to
In the first method (1), as with the conventional glass lens molding, a preform is preliminarily prepared so as to be shaped in an approximate form of a lens portion. A plurality of such preforms are separately arranged on the respective molding surfaces of a molding die and molded by heating and cooling.
In the second method (2), a liquefied molten glass is dropped from an upper portion onto the molding surface and molded by cooling without heating.
In this embodiment, in view of a constitution configured to mold a glass lens array, it is preferable to employ the second method (2). The reason is that the second method (2) makes it possible to enlarge a difference in thickness between a lens portion and a non-lens portion (a portion between two lenses in a plurality of lenses or a portion forming an end portion of an intermediate fabrication component). Further, according to a preferable method, it is preferable to drop collectively a large glass droplet, i.e., a molten glass droplet with a volume capable of being filled sufficiently into at least two molding surfaces without dropping a glass droplet separately into each molding surface. Furthermore, according to a more preferable method, a dropping position is determined so as to drop a large molten glass droplet at a position located with an equal distance from each of a plurality of molding surfaces expected to be filled with a glass droplet. With the employment of the above methods, it becomes possible to minimize a time difference among the respective time periods of the molding surfaces to take for being filled separately with a glass droplet. Accordingly, it becomes possible to minimize a shape difference among the molded lens shapes and a bad influence to optical performance. Naturally, in consideration of the above time difference, small glass droplets may be dropped separately simultaneously into respective molding surfaces, thereby attaining the similar effects. However, in order to make glass into such small glass droplets, an apparatus becomes large and complicate in terms of constitution. Accordingly, the former is more preferable.
Namely, in the case of a large droplet in the former, as shown in
Successively, before the glass GL cools, the lower molding die 20 is made approach a position which is located beneath the upper molding die 10 shown in
Subsequently, as shown in
As shown in the drawings, the glass lens array LA1 is shaped in a thin square (or octagon) plate as a whole. The glass lens array LA1 includes a top surface LA1a which is transferred and molded from the underside surface 11 of the upper molding die 10 and is a highly precise flat surface; four concave optical surfaces LA1b which are transferred from the optical surface transferring surfaces 12 onto the top surface LA1a; and shallow circular grooves LA1c which are transferred from the circular step portions 13 to the respective peripheries of the concave optical surfaces LA1b. The circular grooves LA1c are used, for example, to accommodate respective light shielding members SH (refer to
Further, the glass lens array LA1 includes a bottom surface LA1d which is transferred from the top surface 23 of the land portion 22 of the lower molding die 20 and is a highly precise flat surface; four convex optical surfaces LA1e which are transferred and molded from the optical surface transferring surface 24 onto the bottom surface LA1d, and first flat surfaces LA1f and corner connecting portions LA1g which are transferred respectively from the flat surface portions 25 and the corner portions 26 of the land portion 22. A reference symbol LA1h represents a mark which is transferred simultaneously and indicates a direction. The first flat surfaces LA1f and the corner connecting portions LA1g constitute an inner peripheral surface.
In
Next, description will be given to a process of forming an intermediate fabrication component 1M by pasting a glass lens array molded separately in the similar manner to that of the glass lens array LA1 onto the glass lens array LA1.
The holder HLD and HLD′ each shaped in a rectangular barrel includes tapered surfaces HLD1 on its external periphery at the holding side and end surfaces HLD2 which intersects with the respective tapered surfaces HLD1. The tapered surfaces HLD1 each of which serves as a second flat surface are provided by four in response to the number of the first flat surfaces LA1f of the glass lens array LA1, and each of the tapered surfaces HLD1 is made incline by 45° with respect to the axis of the central opening HLD3 of the holder HLD. The central opening HLD3 has a size capable of surrounding the optical surfaces LA1e of the glass lens array LA1. Therefore, the end surfaces HLD2 are enabled to come in contact with the bottom surface LA1d of the glass lens array LA1. The back surface side of the central opening HLD3 is connected to a negative pressure source P. Here, the two tapered surfaces HLD1 neighboring on each other are connected via a corner tapered surface HLD5. The tapered surfaces HLD1 and the corner tapered surfaces HLD5 constitute an outer peripheral surface. It may be preferable to form an escape portion (concave portion) E configured to receive the mark LA1h at a part from one of the end faces HLD2 to one of the corner tapered surfaces HLD5.
It is preferable that each of the holders HLD and HLD′ is made of a stainless material, and subjected to quenching treatment in order to suppress abrasion and deformation, whereby hardness is made HRC 56 or more. Further with regard to a distance between the two tapered surfaces HLD1 facing each other, an amount of shrinkage at the time of molding of a lens array is calculated, and then the distance is preferably determined in consideration of the amount of shrinkage as a feedback value.
From the state shown in
When the first flat surfaces LA1f come in contact with the respective tapered surfaces HLD1, the glass lens array LA1 cannot rotate more than that for the holder HLD. Meanwhile, since the tapered surfaces HLD1 are regulated by the respective opposite first flat surface LA1f, the glass lens array LA1 cannot move more than that relatively to the holder HLD. That is, by holding the glass lens array LA1 with the holder HLD, the glass lens array LA1 can be positioned with high precision for the holder HLD. Therefore, by positioning the two holders HLD to each other with high precision with the XYZ table TBL, the two glass lens arrays LA1 held respectively by the two holders HLD can be positioned to each other with high precision while facing each other. As a result, with this positioning, all the four optical surfaces can be aligned with high precision.
When the bolt BT is rotated relatively to the shifting XYZ table TBL, the lower end of Bolt BT moves vertically, whereby a distance between the holder HLD and the HLD′ changes. Accordingly, a distance between the first glass lens array LA1 and the second glass lens array LA1′ can be maintained at a predetermined distance. A lock nut NT is used to secure the bolt BT with a set pushed-out length to the shifting XYZ table TBL. With the above constitution, the film thickness of a light-shielding adhesive agent BD (later-mentioned) can be managed.
First, as shown in
Subsequently, as shown in
Subsequently, as shown in
After the adhesive agent was solidified, as shown in
Since
Subsequently, as shown in
Subsequently, as shown in
After the adhesive agent was solidified, as shown in
It is clear for a person skilled in the art from the embodiment and technical concept described in this description that the present invention should not be limited to the embodiments described in the description and includes other modified embodiments.
Number | Date | Country | Kind |
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2012-091544 | Apr 2012 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2013/060780 | 4/10/2013 | WO | 00 |