KR20170001668U - Optical lens and optical lens mold - Google Patents

Abstract

The optical lens includes a base, a lower module, an upper module and an ejector head. Wherein the base includes at least three ejector pins, the lower module includes a lower mold base and a lower mold core, wherein the lower mold core includes a lower cavity and at least three through holes, To the lower cavity. The upper module includes an upper mold base and an upper mold core, wherein the upper mold core includes an upper cavity, and a mold cavity is formed between the lower cavity and the upper cavity when the two mold cores are adjacent to each other. Liquid plastic is formed in the mold cavity in the optical lens and each ejector pin applies pressure to the bottom surface of the optical lens such that the force acts uniformly on the optical lens to release the optical lens from the bottom cavity.

Description

[0001] OPTICAL LENS AND OPTICAL LENS MOLD [0002]

The present invention relates to an optical lens and an optical lens mold, and more particularly, an optical lens mold uniformly applies an optical force to an optical lens to prevent lens deformation and increase the yield.

Conventional optical lens molds include a base, a lower module and an upper module. The base includes a top surface and an ejector pin, and the ejector pin is erectly mounted directly on the top surface of the base. The lower module is mounted on the base and can be moved up or down relative to the base. The lower module includes a lower mold base, a lower mold core, and a through hole. The lower mold base is mounted transversely on the base and includes a top surface and a lower runner. The lower runner is formed in the top surface of the lower mold base.

The lower mold core is mounted in the lower mold base and includes a top surface, an outer surface, a lower cavity and an upper sprue. The top surface of the bottom mold core is aligned with the top surface of the bottom mold base. The lower cavity is formed in the top surface of the lower mold and communicates with the lower runner. The upper sprue is formed in a radial direction through an outer surface adjacent the top surface of the lower mold core. The through hole is vertically formed on the side of the lower mold core through the lower mold base, and communicates with the runner. The through hole is mounted to surround the rounded edge of the ejector pin of the base.

The upper module is mounted on the lower module and can be moved toward or away from the lower module. The upper module includes an upper mold base and an upper mold core. The upper mold base includes a bottom surface and an upper runner, wherein an upper runner is formed within the lower surface of the upper mold base, and the shape and position of the upper runner corresponds to the shape and position of the lower runner. The upper mold may be adjacent to the lower mold base. The upper mold core is mounted in the upper mold base and includes a bottom surface, an outer surface, an upper cavity and an upper sprue. The bottom surface of the upper mold core is aligned with the bottom surface of the upper mold base. The upper cavity is formed in the bottom surface of the upper mold core and communicates with the upper runner. The upper sprue is formed in a radial direction through an outer surface adjacent the bottom surface of the upper mold core. The lower sprue of the lower mold core and the upper sprue of the upper mold core form an annular injecting hole.

When the conventional optical lens mold is used, a mold cavity is formed between the lower cavity of the lower mold core and the upper cavity of the upper mold core by moving the lower module upwards so as to be adjacent to the upper module. Liquid plastic is injected into the molar cavity from the optical lens through the ejecting hole. The liquid plastic in the molar cavity flows into the lower runner and the upper runner to seal the through hole. When the optical lens in the mold cavity is cooled and plasticized, the lower module moves down and separates from the upper module. The ejector pin of the base extends through the through hole to the lower runner of the lower module and pushes the plastic in the lower runner so that the optical lens in the lower cavity is released from the lower mold core along with the plastic in the lower runner.

Conventional optical lens molds are applied to manufacture optical lenses. However, when a conventional mold is used, the ejector pin indirectly pushes the optical lens out of the lower mold core. Due to the ejector pin pressing on the lateral edge of the optical lens, a biased force in the process of pressing the optical lens can cause stress concentration on the optical lens, thereby deforming the optical lens and reducing the yield of the optical lens.

When a modified optical lens is used, the aspheric surface accuracy of the optical lens has a large peak-to-valley (PV) deviation due to deformation, thereby affecting the imaging effect of the optical lens. Furthermore, since the lower mold core or the upper mold core of the conventional optical lens mold is formed by a plurality of separate components, a gap can be formed between a plurality of separated components, and a tolerance ) Is accumulated. The accumulated resistivity affects the precision and yield of the optical lens. Therefore, the optical lens and the conventional optical lens mold must be improved.

In order to overcome the deficiencies of the conventional optical lens and the optical lens mold, the present invention provides an optical lens and an optical lens mold for alleviating or eliminating the aforementioned problems.

The main object of the present invention is to provide an optical lens and an optical lens mold capable of releasing an optical lens by exerting a uniform force on the optical lens. Such an optical lens is not susceptible to deformation and has a high yield.

The optical lens includes a base, a lower module, an upper module and an ejector head. Wherein the base includes at least three ejector pins, the lower module includes a lower mold base and a lower mold core, wherein the lower mold core includes a lower cavity and at least three through holes, To the lower cavity. The upper module includes an upper mold base and an upper mold core, wherein the upper mold core includes an upper cavity, and a mold cavity is formed between the lower cavity and the upper cavity when the two mold cores are adjacent to each other. Liquid plastic is formed in the mold cavity in the optical lens, and each ejector pin applies pressure to the bottom surface of the optical lens, and the force acts uniformly on the optical lens to release the optical lens from the bottom cavity.

Other objects, advantages, and progressive features of the present invention will become more apparent from the following detailed description when taken in conjunction with the accompanying drawings.

1 is a transverse side view of the optical lens mold according to the present invention.
2 is an exploded perspective view of a partial section of the optical lens mold of Fig. 1;
3 is an operational cross-sectional view of the optical lens mold of FIG.
4 is an operational perspective view of a partial cross section of the optical lens mold of Fig.
Fig. 5 is an operation perspective view of a partial cross-section of the optical lens mold of Fig. 1;
FIG. 6 is an operational cross-sectional view of the optical lens mold of FIG. 1;
Figure 7 is an enlarged, operational, cross-sectional view of the optical lens mold of Figure 1;
Figure 8 is another operational cross-sectional view of the optical lens mold of Figure 1;
Figure 9 is another enlarged, operational, cross-sectional view of the optical lens mold of Figure 1;
10 is a further operational cross-sectional view of the optical lens mold of FIG.
Fig. 11 is an enlarged operation side view of a partial cross section of the optical lens mold of Fig. 1; Fig.
12 is an operation perspective view of a partial cross-section of the optical lens mold of Fig.

1, 2 and 6, a mold for manufacturing the optical lens according to the present invention comprises a base 10, a lower module 20, an upper module 30 and an injector head 40 ).

The base 10 includes a top surface and at least three ejector pins 11. At least three ejector pins 11 are mounted directly on the top surface of the base 1 at spaced intervals. Furthermore, at least three ejector pins 11 are arranged in the form of rings of equiangular spacing (arranged at angles of 120 °, 240 ° and 360 °). The base 10 also includes four ejectors 11 which are spaced apart on the top surface of the base 10.

The lower module 20 is mounted on the base 10 and includes a lower mold base 21 and a lower mold core 22. The lower mold base 21 includes a top surface and is movable upward or downward with respect to each of the at least three ejector pins 11. [

The lower mold core 22 is mounted to the lower mold base 21 and includes a top surface, an outer surface, a lower cavity 23, at least three through holes 24, (25). The top surface of the lower mold core (22) is aligned with the top surface of the lower mold base (21). The lower cavity 23 is formed on the top surface of the lower mold core 22. The lower cavity 23 includes a bottom surface, a lower convex surface 231 and at least three elongated arced recesses 232. The lower convex surface 231 is formed at the center of the bottom surface of the lower cavity 23. At least three long arcuate recesses 232 are formed at the outer peripheral edge of the lower convex surface 231 and at least three long arcuate recesses 232 are arranged in ring form at spacing. A stepped face is formed between the lower convex surface 231 and the at least three arcuate concave portions 232.

At least three through-holes 24 are formed in a radial direction passing through the lower mold core 22 at intervals so that each of the at least three through-holes 24 is formed by two adjacent long Shaped concave portions 232. [0064] Each of the at least three through holes 24 is disposed one by one along the outer edge of one of the at least three ejector pins 11. [ Further, the lower cavity 23 includes four long arcuate concave portions 232, and these four long arcuate concave portions 232 are arranged in a ring shape at intervals. The lower mold core 22 includes four through holes 24 and each of the four through holes 24 is engaged with each of the four ejector pins 11 of the base 10 one by one and four through holes 24 Are each located between adjacent long arcuate depressions 232. The sprue 25 is formed in a radial direction through an outer surface adjacent to the top surface of the lower mold core 22 and communicates with the lower cavity 23.

The upper module 30 is mounted on the lower module 20 and can move toward or from the lower module 20. The upper module 30 includes an upper mold base 31 and an upper mold core 32. The upper mold base 31 is adjacent to the lower mold base 21 and includes a bottom surface. The upper mold core 32 is mounted to the upper mold base 31 and includes a bottom surface, an outer surface, an upper cavity 33, and a sprue 34. The bottom surface of the upper mold core 32 is aligned with the lower surface of the upper mold base 31. The upper cavity 33 is formed on the bottom surface of the upper mold core 32 and corresponds in shape to the lower cavity 23. The upper cavity 33 includes an upper convex surface 331 and an upper convex surface 331 is formed on the center of the upper cavity 33 and protrudes downward from the center of the upper cavity 33. The sprue 34 is formed in a radial direction through the outer surface of the upper mold core 32 adjacent the bottom surface of the upper mold core 32. 4 and 5, when the upper mold 30 is adjacent to the lower module 20, the lower mold core 22 is adjacent to the upper mold core 32, so that the lower cavity 23 And the upper cavity 33 are formed. The two sprubs 25 and 34 form an ejecting hole 60 and the ejecting hole 60 is annular in shape and communicates with the mold cavity 50.

The injector head 40 is disposed next to the lower module 20 and the upper module 30. The injector head 40 can be moved transversely with respect to the lower mold core 22 and the upper mold core 32 and the injector head 40 can be inserted into the ejecting hole 60. The injector head 40 may include liquid plastic in the interior of the injector head 40. The liquid plastic is a thermoplastic plastic such as polycarbonate polyester (PC) or polymethylmethacrylate (PMMA). The liquid plastic can flow into the mold cavity 50 through the injector head 40 and the ejecting hole 60.

3 to 6, when the above-described optical lens mold is applied to manufacture an optical lens, the upper module 30 is moved toward the lower module 20, so that the upper mold core 32 And the mold cavity 50 is formed between the upper cavity 33 and the lower cavity 32. [ The injector head 40 is inserted into the ejecting hole 60 to inject the liquid plastic into the mold cavity 50 and the liquid The plastic fills the mold cavity 50. When the liquid plastic fills the mold cavity 50, the injector head 40 is removed from the ejecting hole 60 and the liquid plastic in the mold cavity 50 begins to cool (holding pressure). Referring to FIGS. 7 to 9, the liquid plastic is plasticized to form the optical lens 70.

10, after the liquid plastic is cooled and plasticized to form the optical lens 70 in the mold cavity 50, the upper module 30 moves in the upper direction to move the lower module 20, And the upper cavity 33 is separated from the optical lens 70. [ The lower module 20 moves toward the base 10 and each of the at least three ejector pins 11 of the base 10 extend out of the lower cavity 23 through corresponding through holes 24, The normal ends of each of the at least three ejector pins 11 push out the bottom surface of the optical lens 70. Therefore, the force is uniformly applied to the optical lens 70 to release the optical lens 70 from the lower cavity 23, and the manufacturing process of the optical lens 70 is completed.

11 and 12, the bottom surface and the top surface of the optical lens 70 correspond to the shapes of the lower convex surface 231 and the upper convex surface 331, Two convex surfaces 72 are formed. The optical lens 70 includes a plurality of positioning convex surfaces 73 with a plurality of positioning convex surfaces 73 corresponding in shape to the arcuate concave portions 232 of the lower cavity 23, Are spaced apart.

The number of the through holes 24 of the lower cavity core 22 is equal to the number of the ejector pins 11 of the base 11 when the optical lens mold is used according to the above-described characteristics and structural relationship. When the lower mold base 21 moves toward the base 11 after the liquid plastic in the mold cavity 50 is cooled and plasticized to form the optical lens 70, Can extend through the hole 24 into the lower cavity 23 and each ejector pin 11 can be adjacent to the bottom surface of the optical lens 70. Force is uniformly applied to release the optical lens 70 from the lower cavity 23, and deformation is prevented because the optical lens 70 does not have stress concentration.

Therefore, the yield of the optical lens 70 can be remarkably improved, the possibility of PV deviation in the aspherical surface accuracy of the optical lens 70 is reduced, and the imaging effect of the optical lens 70 is improved. In addition, the long arcuate concave portions 232 are arranged in a ring shape at intervals in the lower cavity 23. After the liquid plastic is cooled and plasticized in the mold cavity 50, a plurality of positioning convex surfaces 73 are formed on the bottom surface of the optical lens 70, and the shape of the plurality of positioning convex surfaces 73 is And corresponds to the shape of the long arcuate concave portion 232 of the lower cavity 23. When the optical lens 70 is assembled with the associated optics, each of the plurality of positioning convex surfaces 73 can provide a positioning effect as a base plane. Furthermore, since the lower mold core 22 or the upper mold core 23 is a combined structure, resistance is prevented from accumulating during assembly, the force is uniformly applied to the optical lens, the optical lens is not susceptible to deformation, The yield of the optical lens and the optical lens mold is increased.

Claims (10)

As an optical lens mold,
A base comprising at least three ejector pins;
A lower module mounted on the base and capable of moving upward or downward with respect to the base;
An upper module mounted on the lower module and capable of moving upward or downward with respect to the lower module; And
An injector head disposed movably next to the lower module and the upper module and having liquid plastic therein;
Lt; / RTI >
Wherein the at least three ejector pins are erectly mounted on the base at spaced intervals,
Wherein the lower module includes a lower mold base and a lower mold core mounted on the lower mold base,
Wherein the lower mold core comprises:
Top surface;
A lower cavity formed on a top surface of the lower mold core;
At least three through holes formed through the lower mold core at an interval and communicating with the lower cavity, each of the at least three through holes having an outer edge of one of the at least three ejector pins ); ≪ / RTI > And
A sprue formed radially through the outer surface of the lower mold core and communicating with the lower cavity,
Lt; / RTI >
Wherein the upper module includes an upper mold base and an upper mold core mounted on the upper mold base,
Wherein the upper mold core comprises:
Floor surface;
An upper cavity formed in the bottom surface of the upper mold core, the upper cavity corresponding in shape to the lower cavity; And
A sprue extending through the outer surface of the upper mold core adjacent the bottom surface of the upper mold core and formed in the radial direction;
/ RTI >
Optical lens mold. The method according to claim 1,
The lower mold core is adjacent to the upper mold core, and a closed mold cavity is formed between the lower cavity and the upper cavity. The two sprues are adjacent to each other to form an injection hole And the injector head is inserted into the ejecting hole,
Optical lens mold. The method according to claim 1,
The lower cavity
A lower convex surface formed at the center of the bottom surface of the lower cavity; And
At least three elongated arced recesses formed in the outer edge of said lower convex surface,
Lt; / RTI >
Wherein the at least three long arcuate recesses are spaced apart in a ring shape and a stepped face is formed between the lower convex surface and the at least three arcuate recesses, Each of the through holes is located between two adjacent arcuate concave portions of the lower cavity,
Wherein the upper cavity includes an upper convex surface protruding downward from a center of the upper cavity,
Optical lens mold. 3. The method of claim 2,
The lower cavity
A lower convex surface formed at the center of the bottom surface of the lower cavity; And
At least three long arc-shaped concave portions formed on the outer edge of the lower convex surface
Lt; / RTI >
Wherein the at least three long arcuate concave portions are arranged in a ring shape with an interval therebetween and a stepped surface is formed between the lower convex surface and the at least three long arcuate concave portions, Wherein the lower cavity is located between adjacent two long arcuate recesses,
Wherein the upper cavity includes an upper convex surface protruding downward from a center of the upper cavity,
Optical lens mold. The method according to claim 1,
The base includes:
Normal surface; And
Four ejector pins mounted at intervals on the top surface of the base,
/ RTI >
Wherein the lower cavity includes four long arcuate recesses spaced apart in a ring shape,
Wherein the lower mold core includes four through holes each of which engages with each of the four ejector pins of the base one by one and each of the four through holes is located between the long circular arc recesses ,
Optical lens mold. 3. The method of claim 2,
The base includes:
Normal surface; And
Four ejector pins mounted at intervals on the top surface of the base,
/ RTI >
Wherein the lower cavity includes four long arcuate recesses spaced apart in a ring shape,
Wherein the lower mold core includes four through holes each of which engages with each of the four ejector pins of the base one by one and each of the four through holes is located between the long circular arc recesses ,
Optical lens mold. The method of claim 3,
The base includes:
Normal surface; And
Four ejector pins mounted at intervals on the top surface of the base,
/ RTI >
Wherein the lower cavity includes four long arcuate recesses spaced apart in a ring shape,
Wherein the lower mold core includes four through holes each of which engages with each of the four ejector pins of the base one by one and each of the four through holes is located between the long circular arc recesses ,
Optical lens mold. 5. The method of claim 4,
The base includes:
Normal surface; And
Four ejector pins mounted at intervals on the top surface of the base,
/ RTI >
Wherein the lower cavity includes four long arcuate recesses spaced apart in a ring shape,
Wherein the lower mold core includes four through holes each of which engages with each of the four ejector pins of the base one by one and each of the four through holes is located between the long circular arc recesses ,
Optical lens mold. An optical lens made by the optical lens mold according to any one of claims 1 to 8. An optical lens made by the optical lens mold according to any one of claims 3, 4, 7, and 8,
Floor surface;
Normal surface;
A first convex surface formed on a bottom surface of the optical lens and corresponding in shape to the bottom convex surface;
A second convex surface formed on a top surface of the optical lens and corresponding in shape to the top convex surface; And
A plurality of positioning convex surfaces corresponding in shape to the long arcuate concave portions of the lower cavity,
/ RTI >

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