TW200825446A - Method for producing lens coated film - Google Patents

Abstract

A method for producing lens coated a film comprises the steps of: providing a plurality of raw lenses, wherein each raw lens includes a lens body and a stub bar; providing a clamping apparatus, wherein the clamping apparatus includes an upper tray and a lower tray, and the upper and lower trays define a plurality of corresponding through holes therein; attaching the upper tray to the lower tray to thereby jointly clamp the stub bar of each lens, wherein the lens body of each lens aligns with the through hole of the lower tray and the corresponding through hole of the upper tray; coating a film on the lens body of each lens; cutting the stub bar of each lens to thereby obtain finished lens with a film coated.

Description

200825446 IX. Description of the Invention: [Technical Field] The present invention relates to a method for fabricating a coated lens, and more particularly to a method for producing a coated lens which can completely cover a region to be plated of a lens. [Prior Art] With the development of optical products, the application range of optical lenses has become wider and wider. Accordingly, in order to reduce costs and increase efficiency, mass production is performed to meet the demand for optical lenses. However, optical lenses produced in batches by various methods can be applied to optical equipment after subsequent processing. For example, a lens manufactured by injection molding technology needs to be machined by cutting, polishing, etc. to remove the waste edge to improve the lens fineness; and then physical or chemical method is applied to the surface of the optical lens by plating a single or multi-layer film, using incident, reflected and transmitted light. The interference generated by the interface of the thin film layer achieves effects such as focusing, collimation, filtering, reflection, and refraction. Considering that a single lens cannot meet the actual requirements, multiple lenses can be assembled to achieve different refraction or diffraction effects, and finally meet the optical properties of the product. The conventional coated lens is manufactured as shown in Figs. 1 to 3, and the tray device includes a lower tray 10 and an upper tray 20. The lower tray 10 is provided with a plurality of through holes 12 arranged in an array, and a positioning post 14 is protruded from the four corners of the lower tray. The diameter of the through hole 12 gradually becomes smaller from the top to the bottom, and the longitudinal section thereof is an inverted trapezoid. The upper tray 20 is similar in shape to the lower tray 1 and has a comparable size. The upper tray 20 is also provided with a plurality of through holes 22 arranged in an array. The diameter of the through hole 22 gradually increases from the top to the bottom, and the longitudinal section thereof is trapezoidal. The through hole 22 of the upper tray 20 and the through hole 12 of the lower tray 1 are the same size as the 200825446. Positioning holes 24 are formed at the four corners of the upper tray 20 to cooperate with the positioning posts 14 of the lower tray 10. Each of the to-be-keyed lenses 30 is placed in the corresponding through hole 12 of the lower tray 1 and then the upper tray 2 is closed to pass the positioning posts 14 through the corresponding positioning holes 24. Each of the ore mirrors 30 is clamped between the through hole 12 of the lower tray 1 and the through hole 22 of the upper tray 2. Then, the tray device holding the waiting plated lens 3 is placed in a coating device for coating. In the case of the bell film, the waiting mirror lens 30 is carried by the inner surface of the through holes 12, 22. Since the longitudinal cross section of the through holes 12, 22 is trapezoidal, the coated portion 36 cannot completely cover the waiting plated lens 3, which waits The edge of the plated lens 3', that is, the inner surface of the lens 30 to be plated close to the through holes 12, 22 cannot be coated with a film, which results in uneven film thickness distribution. When light passes through an uncoated area, it causes reflections that result in poor image quality. The traditional solution is to increase the size of the lens so that the uneven distribution is outside the optically effective area. However, for today's requirements for miniaturized lenses, other solutions are needed. SUMMARY OF THE INVENTION In view of the above, it is necessary to provide a method of fabricating a coated lens that allows the film layer to completely cover the area to be plated of the lens. To achieve the above, a method for fabricating a coated lens is provided, comprising the steps of: providing a lens preliminary product, the lens preliminary product comprising a lens body and a material head connected to the lens body; and providing a tray device, the tray device comprising An upper tray and a lower tray, wherein the upper tray and the lower tray are respectively provided with opposite through holes; the upper tray and the lower tray are matched to jointly hold the head of the lens of the lens, the lens body and the upper tray Corresponding to the through hole of the lower tray; coating the lens main body; removing the material head connected to the lens main body to obtain the finished coated lens. According to the conventional technology, in the method of manufacturing the film lens, since the lens initial product is provided with a material head, the upper tray and the lower tray jointly hold the material head of the lens preliminary product, thereby avoiding the lens The body applies pressure so as not to leave unnecessary indentations on the lens body; the lens body corresponds to the through holes of the upper tray and the lower tray, thereby increasing the coating area of the lens body to realize the lens body once Completely mineral film, improve efficiency and save a lot of cost. [Embodiment] Hereinafter, embodiments of the present invention will be further described in detail with reference to the accompanying drawings. Referring to FIG. 4 to FIG. 4 together, the method for manufacturing a coated lens of the present invention comprises the following steps: Step 1: providing a lens preliminary product 300, the lens initial product 3〇Q package I includes a lens body 310 and is connected to the lens body 31〇 The head 32 〇 is shown in Figure 4. The lens preliminary product 300 is produced by injection molding from an injection machine. The lens preform 300 includes two lens bodies 31 and a head 320 that is coupled to the two lens bodies 310. The material head 32 is connected to both ends of the two lens bodies 3iq at a shearing portion 33A connected to the two lens bodies 310. It can be understood that the structure of the lens preliminary product 300 formed by injection molding can also be separately connected by the structure of the material head 320 and the lens main body 31. The structure of the lens preliminary product 300 can also be borrowed from the plurality of lens main bodies 31. 8 200825446 • The structure in which the plurality of material heads 320 are connected in series, the structure of the lens elementary product 3〇0 can also be formed by the plurality of lens bodies 310 being connected to each other by the reduction head 320. Step 2: A tray device is provided. The tray device includes an upper tray 200 and a lower tray 10, and the upper tray 2 and the lower tray 1 have opposite through holes. As shown in FIG. 4 to FIG. 6 , the tray f device for loading a lens provided in this embodiment is substantially square, and includes a lower tray 100 and an upper tray 200. The upper tray 200 and the lower tray 1 〇〇 cooperate with each other. The lower tray 1 and the upper tray 200 may be made of a metal material or a plastic material. The metal material may be used; the plastic material may be a modified polyphenylene ether (M〇dified)

Antistatic materials such as Poylphenylene Ether (MPPE) may also be used as non-antistatic materials such as a mixture of polycarbonate and glass fibers containing 1 〇 to 3 〇% of glass fiber (Glass Fiber) in total weight. The lower tray 100 includes an upper surface 11 〇 and a lower surface 150. In this case, a plurality of first through holes 120 are opened in the middle of the tray 100. The first through holes 120 may be distributed on the lower tray 1 in a regular or irregular arrangement. Preferably, the first through holes 120 are arranged in an array on the lower tray 100 in this embodiment. The diameter of the first through hole 120 gradually decreases from the top to the bottom, and the longitudinal section thereof is an inverted trapezoid (see Fig. 6). A clamping portion 130 is formed between each of the two first through holes 120 (see Fig. 6). A clamp post 140 is protruded from the four corners of the lower tray 100. In order to facilitate the confirmation of the mating direction, a chamfer 160 is preferably provided at one corner of the lower tray. The upper tray 200 is similar in shape to the lower tray 100 and has a comparable size. 9 200825446 The upper tray 200 includes an upper surface 210 and a lower surface 250. The upper tray 200 is also provided with a plurality of second through holes 220 arranged in an array according to the first through holes 12 of the lower tray 100. The diameter of the second through hole 220 gradually increases from top to bottom, and the longitudinal section thereof is also trapezoidal (see Fig. 6). The second through hole 220 of the upper tray 200 corresponds to the first through hole 12 of the lower tray 100 and has the same size. A clamping portion 230 is formed between each of the two second through holes 22' (see Fig. 6). A positioning hole 24A is formed at a corner of the upper tray 200 to cooperate with the positioning post 140 of the lower tray 100. The diameter of the positioning hole 240 is slightly larger than the diameter of the positioning post 14〇. In use, in order to facilitate alignment of the upper tray 200 and the lower tray 1 〇〇, the upper tray 2 最 is preferably provided with a chamfer 26 〇 corresponding to the chamfer 16 该 of the lower tray 1 〇〇 at one corner. The tray unit can also be used alone to load the lens to preserve the lens intact. When loading the lens, continuous operation is achieved without the need for additional carrier tools and without moving the lens, which simplifies the process and avoids damage to the lens caused by conventional work. Step 3: Cooperating with the upper tray 200 and the lower tray 100 to jointly hold the head 320 of the lens blank 300, the lens body 310 corresponds to the through holes of the upper tray 200 and the lower tray 1 . When the lens initial product 300 is fixed, the lower tray 1〇〇 can be first placed at the discharge position of the lens injection automatic cutting machine, and the lens main body 310 of the lens preliminary product is arranged in the first through hole 12 by the automatic arm. Upper, and the lens body 310 is aligned with the first through hole 12 and is aligned with the first through hole 12, the head 320 of the lens preliminary product 300 is placed on the two first through holes 12 The interposed portion 130 is for supporting the two lens bodies 31A. Then, 200825446 aligns the chamfer 160 of the upper tray 200 with the chamfer 160 of the lower tray 100, and then covers the upper tray 200, and the positioning post 140 and the upper tray 2 of the lower tray 1 The upper positioning hole 24 is matched and the upper tray 2 is positioned and fixed. At this time, the head 320 is sandwiched between the grip portion 230 of the upper tray 200 and the grip portion 130 of the lower tray 100. The lens body 300, the first through hole 12A and the second through hole 220 are substantially on the same axis. The minimum diameter of the first through hole 120 and the second through hole 220 is greater than or equal to the diameter of the lens body 310. Step 4: The lens body 310 is coated. The tray device for fixing the lens initial product 3〇〇 containing the film to be bonded is fed into the coating device, and the film device 310 is coated by the physical vapor deposition method until the lens body 31 is plated with a film of a predetermined thickness. . Since the minimum diameter of the first through hole 120 and the second through hole 220 is greater than or equal to the diameter of the tomograph lens body 31, the film recording area 360 can completely cover the lens body to be plated 310, that is, the The coated lens main body 31 is completely coated, and does not require secondary processing, thereby saving processing costs. Step 5: The head mo connected to the lens body 31 is removed to obtain a finished coated lens. After the coating process is completed, the tray device is sent to the machine of the automatic assembly machine. 'The upper tray 2 is opened by the jig, so that the automatic arm of the automatic assembly machine can remove the already coated lens from the lower tray 100. The product 300 is placed in the shearing machine to cut the material head 320 connected to the lens main body from the shearing portion 33, thereby obtaining the already coated lens main body 31, that is, the coated lens finished product. 11 200825446 As an optional step, this step may further include the steps of grinding the coated lens body 310, then washing with a detergent such as water, drying the lens body 310, and the like. In the method for manufacturing a coated lens of the present invention, since the lens initial product 3 is provided with a material head 320, the clamping portion 230 of the upper tray 200 and the clamping portion 130 of the lower tray 1 are clamped together to position the lens. The product head 320 is so as to avoid applying pressure to the lens main body 31 从而 so as not to leave unnecessary indentation on the lens main body 310; the lens main body 31 〇 and the first through hole of the lower tray 100 12〇 corresponds to the second through hole 22〇 of the upper tray 200, so that the coating area of the lens main body 31 is increased, so that the lens main body 310 is completely coated, the efficiency is improved, and a large cost is saved. It can be understood that, in the embodiment of the present invention, the aperture and the depth of the first through hole 120 of the lower tray 100 can be determined according to the size of the lens body 31, the first through hole 12 of the lower tray 100 and the upper portion thereof. The aperture of the second through hole 220 of the tray 2 can also be determined according to the size of the lens body 31 to be plated. The first through hole 120 and the second through hole 220 can be symmetrically arranged, or can be set according to actual needs. Different combinations. It can be understood that the first through hole 120 of the lower tray 100 and the second through hole 22 of the upper tray 200 in the embodiment of the present invention may also adopt other arrangements. It can be understood that, in the embodiment of the present invention, the lower tray 100 is also provided with a plurality of positioning holes, and the upper tray can also form a positioning column that cooperates with the positioning hole of the lower tray, and the position and the number thereof can be determined according to actual needs. As long as the positioning effect is achieved. The present invention is in accordance with the requirements of the invention patent, and is proposed according to law. 12 200825446 'Patent declaration Huaihuai, the above is only the preferred embodiment of the present invention, since and (4) this limitation is turned over in this case. _. Any equivalent modifications or variations made by those who are familiar with the skill of the present invention in accordance with this is applicable to the following patents. BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is an exploded view of a conventional tray device. Figure 2 is a top plan view of a conventional tray device. Figure 3 is an enlarged view taken along line of the dish of Figure 2; Figure 4 is an exploded view of the tray apparatus of the embodiment of the present invention. Figure 5 is a perspective view of the tray device of the embodiment of the present invention after assembly. Fig. 6 is a partially enlarged view taken along line VI-VI of Fig. 5. [Main component symbol description] Lower tray 10, 100 through hole 12, 22 positioning post 14, 140 upper tray 20, 200 positioning hole 24, 240 lens 30 iron film area 36, 360 upper surface 110, 210 first/through hole 120 Surface 150, 250 chamfer 160, 260 second through hole 220 iron sheet preliminary product 300 lens body 310 head 320 shearing portion 330 13

Claims (1)

200825446 X. Patent Application No. 1. A method for manufacturing a coated lens, comprising the steps of: providing a lens preliminary product, the lens preliminary product comprising a lens body and a material head connected to the lens body, and providing a tray device, the tray device The utility model comprises an upper tray and a lower tray, wherein the upper tray and the lower tray are respectively provided with opposite through holes; the upper tray and the lower tray are matched to jointly hold the head of the lens preliminary product, the lens body and the upper The tray and the through hole of the lower tray correspond to each other; the mineral film is applied to the lens body; and the material head connected to the lens body is removed to obtain the finished coated lens. 2. The method for producing a coated lens according to claim 1, wherein the axis of the through hole of the lower tray coincides with the axis of the main body of the lens to be plated. 3. The method of manufacturing a coated lens according to claim 2, wherein an axis of the through hole of the upper tray coincides with an axis of the through hole of the lower tray and an axis of the main body of the lens to be plated. 4. The method for producing a coated lens according to claim 3, wherein the diameter of the through hole of the upper tray and the through hole of the lower tray are larger or larger than the diameter of the main body of the lens to be inspected. 5. The method for producing a lens according to the fourth aspect of the invention, wherein the through hole of the upper tray and the through hole of the lower tray have a trapezoidal shape. The method for producing a coated lens according to claim 1, wherein the main body of the lens to be coated is coated by physical vapor deposition. 7. The method of producing a coated lens according to claim 6, wherein the lens preliminary product is formed by injection molding. 15