KR20200001229U - Integrated optical lens mold and optical lens made by the same - Google Patents

Abstract

The optical lens mold according to the present invention includes a base, a lower mold, an upper mold, and an injector head. The base has at least three injector pins, the lower mold has a lower mold base and a lower mold core, and the lower mold core is formed in an integral structure while having a lower cavity and at least three through holes, and at least three Each ejector pin is inserted into the lower cavity through the through hole. The upper mold has an upper mold base and an upper mold core, the upper mold core has an upper cavity, and when two mold cores are adjacent to each other, a mold cavity is formed between the lower cavity and the upper cavity.

Description

INTEGRATED OPTICAL LENS MOLD AND OPTICAL LENS MADE BY THE SAME

The present invention relates to an optical lens mold and an optical lens manufactured using the same, and more particularly, to an optical lens mold that is integrated into a single component, improves accuracy, and protects the optical lens from tilting.

Referring to FIG. 7, a conventional optical lens mold has a base 70, a lower mold 80 and an upper mold 90. The base 70 has an upper surface and an ejector pin 71 disposed on the upper surface of the base. The lower mold 80 is disposed above the base 70, and the lower mold 80 can move up and down relative to the base 70. The lower mold 80 has a lower mold base 81 and a lower mold core 82. The lower mold base 81 is disposed horizontally above the base 70. The lower mold core 82 is installed on the lower mold base 81, and has a sleeve 821 and a lens mold core 822. The sleeve 821 has an opening, and the opening of the sleeve 821 is directed downward.

The lens mold core 822 is detachably installed in the sleeve 821 through the opening of the sleeve 821.

The upper mold 90 is disposed above the lower mold 80, and the upper mold 90 can move up and down relative to the lower mold 80. The upper mold 90 has an upper mold base 91 and an upper mold core 92. The upper mold base 91 is disposed horizontally above the lower mold base 81. The upper mold core 92 is disposed in the upper mold base 91. The bottom surface of the upper mold core 92 is flush with the bottom surface of the upper mold base 91.

However, in the case of the conventional lower mold base 81, it is inevitable that a gap is formed between the sleeve 821 and the lens mold core 822, which causes the optical surface of the lens mold core 822 to be 0.005 to 0.02 degrees. As inclined, the lens mold core 822 is tilted. And, the gap causes the sleeve 821 and the lens mold core 822 to have a non-coaxial core. The core abnormality between the sleeve 821 and the lens mold 822 is about 0.001 to 0.003 mm. The above-mentioned optical surface tilt and core abnormality of the sleeve 821 and the lens mold 822 cause manufacturing errors (defects) in the high-accuracy lens manufacturing process.

In order to overcome the disadvantages of the conventional optical lens mold, the present invention provides an integrated optical lens mold to alleviate or prevent the aforementioned problems.

The main object of the present invention is to provide an optical lens mold of an optical lens, and more specifically, to provide an optical lens mold that is integrated, improves accuracy, and protects the optical lens from tilting.

In order to achieve the above object, the optical lens mold according to the present invention has a base, a lower mold, an upper mold, and an injector head. The base has at least three injector pins, the lower mold has a lower mold base and a lower mold core, the lower mold core has a lower cavity and at least three through holes, and is formed in an integral structure, each of at least three ejector pins Is inserted into the lower cavity through the through hole. The upper mold has an upper mold base and an upper mold core, the upper mold core has an upper cavity, and when two mold cores are adjacent to each other, a mold cavity is formed between the lower cavity and the upper cavity.

Other objects, advantages, and novel features of the present invention will become more apparent from the following detailed description by referring to the accompanying drawings.

1 is a cross-sectional view of an integrated optical lens mold according to the present invention.
FIG. 2 is an enlarged cross-sectional view of the integral optical lens mold of FIG. 1.
3 is an exploded perspective view of the integral optical lens mold of FIG. 1.
4 is a partially operational perspective view of the optical lens mold of FIG. 1.
5 is an operational cross-sectional view of the optical lens mold of FIG. 1.
6 is another enlarged operation cross-sectional view of the optical lens mold of FIG. 1.
7 is an operational cross-sectional view of a conventional optical lens mold.

1 to 5, the integral mold for manufacturing the optical lens according to the present invention has a base 10, a lower mold 20, an upper mold 30, and an injector head 40.

The base 10 has an upper surface and at least three injector pins 11. At least three injector pins 11 are installed upright on the top surface of the base 10 at spaced apart intervals. Moreover, at least three ejector pins 11 are arranged in a circle at equal intervals.

The lower mold 20 is disposed above the base 10 and has a lower mold base 21 and a lower mold core 22. The lower mold base 21 has an upper surface and can be moved upward and downward with respect to each one of at least three ejector pins 11.

The lower mold core 22 is installed in the lower mold base 21, and has an upper surface, an outer surface, a lower cavity 221, at least three through holes 222, and sprues 223 and sprues. The upper surface of the lower mold core 22 is laid horizontally, and the lower mold core 22 is an integrated structure. The lower cavity 221 is formed in the upper surface of the lower mold core 22. At least three through-holes 222 are vertically formed in the lower mold core 22 at spaced intervals. Tanggu 223 is formed radially through the outer surface of the lower mold core 22, the boundary is defined into the upper surface of the lower mold core 22, and communicates with the lower cavity 221.

The upper mold 30 is disposed above the lower mold 20 and may be moved away from the lower mold 20 toward the lower mold 20. The upper mold 30 has an upper mold base 31 and an upper mold core 32. The upper mold base 31 may be adjacent to the lower mold base 21. The upper mold core 32 is installed in the upper mold base 31, and the bottom surface of the upper mold core 32 lies horizontally with the bottom surface of the upper mold base 31. The upper mold core 32 has an upper cavity 321 and a sprue 322. The upper cavity 321 is formed in the bottom surface of the upper mold core 32, and corresponds to the shape of the lower cavity 221. The sprue 322 is formed radially on the outer surface of the upper mold core 32, and is bounded into the bottom surface of the upper mold core 32.

4 and 5, when the upper mold 30 is adjacent to the lower mold 20, the lower mold core 22 is adjacent to the upper mold core 32, the lower cavity 221 and the upper cavity A closed mold cavity 50 is formed between 321. The two sprues 223 and 322 form an injecting hole 60, and the injecting hole 60 is formed in a round shape and communicates with the mold cavity 50.

The injector head 40 is disposed next to the lower mold 20 and the upper mold 30. The injector head 40 may move transversely to the lower mold core 22 and the upper mold core 32, and the injector head 40 may be inserted into the injection hole 60. The injector head 40 has liquid plastic contained inside the injector head 40. Moreover, the liquid plastic is a thermoplastic plastic such as polycarbonate polyester (PC) or polymethylmethacrylate (PMMA). Liquid plastic flows into the mold cavity 50 through the injector head 40 and the injecting hole 60.

3 to 6, the above-described optical lens mold is applied to manufacture the optical lens, the upper mold 30 is moved toward the lower mold 20, the upper mold core 32, the lower mold core 22 ), the mold cavity 50 is formed between the upper cavity 321 and the lower cavity 221. The sprues 223 and 322 are coupled to each other to form an injection hole 60, and the injector head 40 is inserted into the injection hole 60 to inject liquid plastic into the mold cavity 50, The liquid plastic fills the mold cavity 50 sufficiently. When the liquid plastic fills the mold cavity 50 sufficiently, the injector head 40 moves out of the injection hole 60, and the liquid plastic in the mold cavity 50 starts to cool. 5 and 6, the liquid plastic is plasticized to form the optical lens 65. Since the lower mold core 22 has an integral structure, problems of tilting of the optical surface and core abnormalities can be avoided, manufacturing variations in optical surface deformation can be reduced, and thereby, the yield of the optical lens 65 can be effectively improved. Can be.

5 and 6, when the liquid plastic is cooled to form the optical lens 65, the upper mold 30 moves upward to separate from the lower mold 20, and the upper cavity 321 is optical It is separated from the lens 65. The lower mold 20 is moved toward the base 10, and each of the at least three ejector pins 11 of the base 10 extends out of the lower cavity 221 through a corresponding through hole 222, The image side of each of the at least three ejector pins 11 pushes the underside of the optical lens 65. Therefore, the force is uniformly applied to the optical lens 65 to emit the optical lens 65 from the lower cavity 221, and the manufacturing process of the optical lens 65 is completed.

Compared to the conventional lower mold base 81, the gap between the sleeve 821 and the lens mold core 822 causes the lens mold core 822 to tilt. In addition, the gap between the sleeve 821 and the lens mold core 822 causes a core abnormality between the sleeve 821 and the lens mold core 822. The present design provides the lower mold core 22 in an integral structure, which can prevent the problem of the optical surface tilting and the core abnormality, and effectively increases the production amount of the optical lens 65. Moreover, since the lower mold core 22 does not need to be assembled in the manufacturing process, manufacturing efficiency is effectively increased.

10: base 11: ejector pin
20: lower mold 21: lower mold base
22: lower mold core 30: upper mold
31: upper mold base 32: upper mold core
40: injector head

Claims (3)

A base having at least two ejector pins installed upright and spaced apart;
A lower mold disposed on the base and movable upward and downward with respect to the base;
An upper mold installed on the lower mold and movable upward and downward with respect to the lower mold; And
And an injector head movably disposed next to the lower mold and the upper mold,
The lower mold,
Lower mold base; And
It is installed in the lower mold base and is provided with an integral molded lower mold core,
The lower mold core,
Top side;
A lower cavity formed on an upper surface of the lower mold core;
At least three through-holes formed through the lower mold core at spaced apart intervals and communicating with the lower cavity, each through-hole disposed around the outer edge of each of the at least three ejector pins; And
It is formed radially through the outer surface of the lower mold core, and includes a sprue through the lower cavity,
Upper mold,
Upper mold base; And
It has an upper mold core installed in the upper mold base,
The upper mold core,
Bottom surface;
A lower cavity formed in the bottom surface of the upper mold core and having a shape corresponding to the lower cavity; And
An integrated optical lens mold including a sprue formed radially through the outer surface of the upper mold core adjacent to the bottom surface of the upper mold core. The method according to claim 1,
The lower mold core is adjacent to the upper mold core, a closed mold cavity is formed between the lower cavity and the upper cavity, and the spout of the lower mold core and the spout of the upper mold core are adjacent to each other to form an injection hole, and an injector The head is inserted into the injection hole, characterized in that the integral optical lens mold. An optical lens made by the optical lens mold claimed in claim 1 or 2.

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