JPH10138290A - Manufacture of optical plastic article - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a manufacture of an optical plastic article with superior dimensional accuracy by shortening the molding period of time in a conventional injection molding method and realize a sure melt-integration of resin. SOLUTION: The method of manufacturing an optical plastic article comprises the steps of a process A for molding a primary molded article 1 by injection molten resin in the cavity of a mold and a process B for injecting the same resin as in the process A in a part or entire part of the primary molded article 1 and melt-integrating the primary article 1 and injected resin. Here, the primary molded article 1 is made smooth in its surface prior to shielding the primary molded article with resin in the process B.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical plastic product, for example, a visual optical system (a loupe, various finders, etc.), an ophthalmic optical system (a lens for eyeglasses, a contact lens), an illumination / light receiving system (a condenser) , Infrared projector,
Radiation thermometer, solar furnace, vehicle lamp, etc., photography system (various lenses, etc.), laser optical system (interferometer, scanner, etc.)
And the like.

[0002]

2. Description of the Related Art Generally, glass is used as a material for optical products. The reason for this is that there are advantages such as a wide variety of glasses, good stability of optical physical properties, excellent heat resistance, and little change in physical properties due to temperature change. However, this optical glass is not without its drawbacks, it is heavy, hard and brittle, and requires man-hours to grind, resulting in poor productivity.Products with an aspherical shape have poor reproducibility of the polishing process and productivity. There was also a disadvantage that it was inferior. Some types of glass have problems such as poor weather resistance depending on the type of glass used.

In view of these drawbacks, recently, the use of plastic as a material for optical products has been studied. The advantages of this optical plastic product are its lightness and high impact resistance, and it is currently used as a material for eyeglass lenses. Another advantage is that
It can be easily made into any shape, and mass production can be done according to injection molding, reducing man-hours.
And excellent reproducibility.

[0004] In addition to the injection molding method, a cutting and polishing method is known as a method for producing an optical plastic product.

[0005]

The conventional injection molding method has drawbacks such as shrinkage as the temperature of the product decreases after being removed from the mold, and the product differs from the mold size. This phenomenon becomes more remarkable as the thickness of the product increases. In addition, the cutting and polishing method requires a procedure in which a cast plastic block is formed into a target lens shape by machining and then polished. For a flat surface or a spherical surface, surface accuracy is easily obtained. There are disadvantages such as difficulty in obtaining accuracy and requiring a large number of man-hours.

Therefore, the present inventors have previously described a step A of molding a primary molded article by injecting a molten resin into a cavity of a mold, and a part or the whole of the primary molded article is the same as the step A. A resin molding method for producing an optical plastic product including a step B of injecting a resin and forming a secondary molded product obtained by fusing and integrating the primary molded product and the injected resin, with high productivity and surface precision of the product. It is reported that a good optical plastic product can be obtained (Japanese Patent Application No. 7-350437). However, when the maximum thickness of the product is 30 mm or more, and an attempt is made to obtain an optical plastic product with good surface accuracy of the product, the manufacturing method proposed by the present inventors delicately adjusts the manufacturing conditions. Otherwise, shrinkage, depression, etc. may occur on the surface of the product. Therefore, an object of the present invention is to provide an optical plastic product having a high surface precision without causing shrinkage or depression on the surface of the optical plastic product even when the product has a large thickness or an aspherical surface. An object of the present invention is to provide a method of manufacturing a plastic product for a business.

[0007]

In order to achieve the above-mentioned object, the present invention comprises a step A of molding a primary molded product by injecting a molten resin into a cavity of a mold; Injecting the same resin as in step A into part or the entirety, and molding a secondary molded product obtained by fusing and integrating the primary molded product and the injected resin, and B. Before the resin is coated on the primary molded product, the surface of the primary molded product is smoothed.

[0008]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 shows a state in which the primary molded article 1 is set in a mold 10 and the same resin as the molding resin of the primary molded article 1 is injected into a part of the primary molded article 1, that is, the gates 11, 1.
2 shows an example of a cross section immediately before injection from the cavity 2 into the cavity 13. The primary molded article 1 is molded by injecting a molten resin into a cavity of a mold (not shown).

The distance between the cavity 13 of the mold 10 shown in FIG. 1 and the primary molded product 1 is in the range of 1 to 15 mm. Therefore, the thickness of the resin coated on the primary molded article 1 is also 1 to 15
mm. The unit of φ50 and φ20 in FIG. 1 is mm. If the thickness of the resin to be coated (injected later) is too thin, the flow resistance of the resin will be too large, and the resin will not flow into the details sufficiently. If it is too thick, defective phenomena such as sink marks and voids will occur with thick molded products It's easy to do.
The coating resin thickness varies depending on the type and grade of the resin,
1 to 15 mm, preferably 3 to 10 mm is suitable.

FIG. 2 shows a final molded product, that is, an optical plastic product 20, in which a part of the primary molded product 1 is covered with a secondary molded product 2, and the resins of the molded products 1 and 2 are melted and integrated. The maximum thickness of this optical plastic product 20 is 50
mm.

FIG. 3 shows a molded primary molded article 1 having a diameter φ
The unit of 10, φ20 is mm. The coating resin thickness of the spherical portion of the primary molded product 1 is 15 mm if the secondary molded product is to be molded as shown in FIG. Primary molded product 1
Becomes the core of the final molded product and is inserted into the secondary molded product 2. The primary molded article 1 serves as a core of the final molded article. Therefore, the dimensional accuracy of the primary molded article 1 is not required unless there is a serious failure phenomenon such as a void or a surface depression. This means that the dimensional accuracy of the mold for molding the primary molded article 1 is unnecessary. The mold for molding the secondary molded product 2 is required to have dimensional accuracy.

[0013] The surface of the injection-molded primary molded article 1 is polished to a mirror surface with a diamond paste to make the surface smooth, and then the surface is preferably washed with ethanol or hexane. Mold 1 as shown
Set within 0, and inject coating resin to recommended minimum temperature of + 5 ° C
Injection is performed at the recommended maximum resin temperature of -5 ° C.

The primary molded article 1 is molded so as to cover the secondary molded article 2, that is, the molded article shown in FIG. 2 is not used as the final molded article, but the same resin is injected so as to further cover the molded article. To form a final molded product. That is, three layers are partially formed. Of course, four or more layers may be used. The present invention relates to a step A of molding a primary molded article 1 by injecting a molten resin into a cavity of a mold, and injecting the same resin as in step A into a part or the whole of the primary molded article 1 to form a primary molded article. Step B of molding a molded article 1 and a secondary molded article 2 in which the injected resin is melted and integrated.
May be repeated multiple times.

Example <Molding of Primary Molded Product ... Step A> Injection molding machine: M-100A-TS resin, Meiki Seisakusho Co., Ltd. Resin: Delpet 80N (PMMA manufactured by Asahi Chemical Industry Co., Ltd.)
Pre-drying 80 ° C x 4 hours Injection molding condition: barrel (cylinder) temperature setting Nozzle temperature 230 ° C barrel temperature 245 ° C Hopper side temperature 230 ° C Mold temperature setting: 90 ° C by water circulation Molding time: 120 seconds or more The primary molded article 1 shown in FIG. 3 was obtained. In Example 1, the primary molded product using the primary molded product 1 in which the molded product surface was freely shrunk without holding pressure was used, and the surface of the primary molded product 1 was polished to a mirror surface with a diamond paste. Example 2 was used. <Molding of Secondary Molded Article: Step B> Next, the surface of the obtained primary molded article 1 is washed and preheated, and then set in a mold 10 as shown in FIG. The molding material (PMMA resin) of the product was injection-molded to form the secondary molded product 2 shown in FIG. The secondary molded article 2 was subjected to the secondary molding including the defective dimension of the primary molded article 1. In any case, the injection molding conditions such as the injection secondary to tertiary pressure (holding pressure) conditions are appropriately set for the secondary molded article 2. As a result, it was possible to mold the product to the desired dimensions without occurrence of defective phenomena such as sink marks and voids. In particular, it was confirmed by three-dimensional shape measurement that the sphere of φ50 (mm) shown in FIG. The molding time in the secondary molding step was 150 seconds. Therefore, the total molding time of the primary and secondary molded products 1 and 2 according to the present embodiment was 270 seconds, including the molding time of the primary molded product 1 of 120 seconds.

Example 1 The obtained molded article was visually observed under sunlight, but no interface between the primary and secondary molded articles was observed. In addition, when the laser beam was incident at a right angle and when the laser beam was incident at an angle of 45 degrees, the interface between the primary and secondary molded products was not visually recognized. Example 2 The obtained molded article was visually observed under sunlight, but no interface between the primary and secondary molded articles was observed. When the laser beam is incident at right angles, 4
The interface between the primary and secondary molded products was not visually recognized in any of the cases where the light was incident at an angle of 5 degrees.

Primary molded article 1 obtained by primary molding described above
In the case of a comparative example, the surface of which was polished with abrasive paper # 1000 and subjected to the above-mentioned secondary molding, the interface of the primary / secondary molded article was visually recognized under sunlight in the product of this comparative example. Was done. On the other hand, when laser light was incident, slight blurring of the laser light was observed at the interface between the primary and secondary molded products.

From the above results, if the surface of the primary molded article 1 is a smooth surface, the surface of the primary molded article 1 is completely wetted by the coating resin at the time of secondary molding, and the fusion of the primary / secondary molded resin occurs. However, if the surface of the primary molded article 1 is rough, the surface of the primary molded article 1 is not completely wetted by the coating resin at the time of secondary molding, so that fusion of the primary / secondary molded resin hardly occurs completely. It has been found.

If there is a corner on the outer periphery of the primary molded article 1 in the secondary molding, the resin is not easily wrapped around the corner, and voids and bubbles may be generated in the corner. It is preferable to design the shape so that there are no corners on the outer periphery.

When selecting an optical plastic, it is important to select a resin that is transparent to visible light. Further rationale is as follows. Do not absorb visible light inside the resin. That is, it has a light transmittance as high as possible. The tissue is dense, each size is smaller than the wavelength and does not cause scattering. It is better that spherulites do not exist. Be isotropic. This relates to the stability of optical properties such as the refractive index.

Suitable resins for use include methacrylic resins such as polymethyl methacrylate (PMMA), polystyrene resins (PS), AS, polycarbonate resins (P
C), polymethylpentene, styrene-butadiene copolymer and the like.

[0022]

As described above, according to the present invention, in the method for producing an optical plastic product, a step A of molding a primary molded product by injecting a molten resin into a cavity of a mold, and forming the primary molded product. Injecting the same resin as in step A into part or all of the article, and molding a primary molded article and a secondary molded article in which the injected resin is melted and integrated, and coating the primary molded article in step B When the thickness of the resin to be formed was set to 1 to 15 mm, a defective product such as sink marks did not occur on the outer peripheral portion of the final molded product, and a product having excellent surface accuracy was obtained. In addition, since molding is performed in a plurality of stages, each molding time is short, and as a result, the total molding time can be shortened.
Productivity is improved. Further, by making the thickness formed at the time of the final injection relatively thin, a target shape can be obtained with high accuracy.

[Brief description of the drawings]

FIG. 1 is an example of a cross-sectional view of a state where a primary molded product is set in a mold.

FIG. 2 is an example of a front view showing a final molded product.

FIG. 3 is an example of a front view of a primary molded product.

[Explanation of symbols]

 1 Primary molded product 2 Secondary molded product 20 Final molded product (optical plastic product)

Claims (2)

[Claims] 1. A step A of molding a primary molded article by injecting a molten resin into a cavity of a mold, and injecting the same resin as in the step A into a part or the whole of the primary molded article to form a primary molded article. Molding a secondary molded product obtained by melting and integrating the injected resin, and a step B of forming an optical plastic product, wherein the primary molded product is coated before the resin is coated on the primary molded product in the step B. A method for producing an optical plastic product, characterized in that the surface of the plastic is smoothed. 2. The method for producing an optical plastic product according to claim 1, wherein the surface of the primary molded article is smoothed by polishing or free-shrinking the surface of the primary molded article.