TWM514469U - Molding device for lens array - Google Patents

Abstract

The invention relates to a molding device for lens array, and it's method thereof. The molding device comprises an upper molding unit, a lower molding unit, and a plate unit. The upper molding unit has a plurality of upper pressing areas, and the lower molding unit has a plurality of lower pressing areas. The plate unit has a plurality of through holes capable of engaging with glass element by each through hole, and corresponding to the upper and lower pressing areas. The glass element has a first cross-sectional width W1. The through hole has an up opening with width W2, and a down opening with width W3, in which W1>=W2 or W1>=W3 is complied for each through hole to receive the glass element.

Description

Lens array die equipment

The present invention relates to a lens apparatus for a lens array and a method of using the same, and more particularly to a mold apparatus for manufacturing a lens array of glass material and a method of using the same.

In recent years, with the advancement of electronic technology, people have gradually become accustomed to carrying miniature video camera modules on portable consumer electronic products such as mobile phones and cameras. The video camera module is generally provided with a CCD (Charge Coupled Device) image sensor or a CMOS (Complementary Metal Oxide Semiconductor) image sensor for capturing static or dynamic images and images, so that most people can pass through Simple handheld electronic devices for camera and video recording. In general, the image sensor described above is provided with an imaged lens (Lens) or a lens array (Lens Array) on the light receiving surface of the component for collecting and adjusting the light of the incident light source.

Traditionally, the lens surface required for imaging has a curved profile such that when light is incident from inside the lens into the interior of the lens, the path of travel of the source can be varied and the incident source can be focused. In addition, in order to maximize the utilization of the incident light source, a plurality of lenses are generally combined and arranged into a lens array.

In high-end photography, camera cameras, and video equipment, glass materials are generally used to achieve stable light focusing and easy control of incident light. Lens array. In addition, increasingly popular LEDs often require the use of a lens array to control the light path of the source. Therefore, with the widespread use of mobile phones, cameras, and LEDs, the demand for lens arrays is bound to increase.

In general, the lens array is manufactured by injecting a glass melt of up to several hundred degrees C into a mold, and after the glass is cooled, the mold is opened, and the glass is taken out, and the glass has a plurality of lenses to form a lens array. However, this molding method is limited by the extremely high viscosity relationship of the glass in the high-temperature molten state, and the glass material adheres to the inner mold surface of the mold, resulting in cracks on the surface of the taken lens array. Scratches, or irregular extrusion contours, or even stress concentration, irregularities in the crack scratches will affect the focus after the light is incident, and the stress concentration of the glass material will be irregularly distributed. This results in a decrease in the yield of the lens array. Another common method in the industry is to pressurize and shape the softened glass through a mold, but because the area of the lens array may be as high as tens of square centimeters, the required pressing force can reach tens or even hundreds. kPa, the mold design is difficult, and the strong pressure is also easy to cause the lens array to reduce the yield. Therefore, the conventional glass lens array still has technical bottlenecks that are difficult to overcome, resulting in an overall improvement in overall yield or productivity.

Therefore, how to overcome the current technical bottleneck and improve the manufacturing yield or productivity of the glass lens array is the goal of those skilled in the art.

The main purpose of this creation is to improve the manufacturing yield or productivity of glass lens arrays.

Another purpose of this creation is to reinforce the curvature of the surface profile of a glass lens array. Control, and the effect of homogenizing the internal refractive index of the lens array.

In order to solve the above and other problems, the present invention provides a mold apparatus for a lens array including an upper mold, a lower mold, and a plate structure. The upper die includes a plurality of upper die abutting regions, the lower die includes a plurality of lower die abutting regions, and the plate structure is movably disposed between the upper stamper and the lower stamper, The plate structure includes a plurality of through holes penetrating the plate member, the through holes are for receiving a plurality of glass members, the glass member has a first cross-sectional width W1, and the through holes include an upper opening and a lower opening The upper opening and the upper die correspond to each other, the lower opening and the lower die correspond to each other, the upper opening has a second cross-sectional width W2, and the lower opening has a third cross-sectional width W3, wherein W1≧W2 Or W1≧W3; when the upper die and the lower die are close to each other, the upper die abutment region is located at the periphery of the upper opening to abut the glass member, and the lower die abutment region is located at the periphery of the lower opening Top the glass piece.

The mold apparatus of the lens array as described above, wherein at least one of the upper mold abutting area and the lower mold abutting area have different shapes or different areas; wherein the upper mold abutting area or the lower mold is abutted The top region is a structure of a convex structure, a concave structure or a Fresnel lens.

The mold apparatus of the lens array, wherein the upper opening of the through hole and the shape of the lower opening are different from each other or the areas are different from each other; wherein the shape of the upper opening or the lower opening is circular, elliptical, Polygon or irregular shape. In a further embodiment, the through hole includes an inner hole wall connecting the upper opening and the lower opening, the upper opening being greater than, equal to or smaller than the lower opening, and the cross section of the inner hole wall is presented as A straight line or a curve.

a mold apparatus for a lens array as described above, wherein the panel structure includes At least one first through hole and at least one second through hole, the volume and shape of the first through hole and the second through hole are different from each other, and the first through hole and the second through hole are sequentially arranged, Interactive or regular arrangement.

A mold apparatus for a lens array as described above, wherein the plurality of glass members have different volumes, different shapes, or different refractive indices. In a further embodiment, the plurality of glass members comprise at least a first configuration and at least a second configuration, the first configuration of the glass member and the second configuration of the glass member being in phase or shape And the glass member of the first configuration and the glass member of the second configuration are sequentially arranged, alternately arranged or regularly arranged.

A mold apparatus for a lens array as described above, wherein the plurality of glass members have different volumes, different shapes, or different refractive indices. In a further embodiment, the plurality of glass members include a first refractive index and a second refractive index, the first refractive index and the second refractive index are different from each other, and the glass member having the first refractive index and the The second refractive index glass members are arranged, alternately arranged or regularly arranged; or, the plurality of different glass members (8) include at least a first glass transition temperature (Tg) and a second glass transition temperature, The first glass transition temperature and the second glass transition temperature are different from each other, and the glass member (8) having the first glass transition temperature and the glass member (8) having the second glass transition temperature are sequentially arranged and arranged. Or regular arrangement.

The mold apparatus of the lens array as described above, wherein the sheet structure is curved.

A mold apparatus for a lens array as described above, wherein the sheet structure is opaque.

A mold apparatus for a lens array as described above, wherein the glass member is spherical, elliptical, columnar, or tapered.

A mold apparatus for a lens array as described above, wherein at least a portion of the glass member is contained or located within the through hole.

The mold apparatus of the lens array as described above, wherein the volume of the glass member is greater than or equal to the volume of the space occupied by the through hole.

a mold apparatus for a lens array as described above, wherein, when the upper stamper and the lower stamper are close to each other, the upper mold abutment region covers at least a portion of the upper opening, or the lower die abutment region covers At least part of the lower opening.

Thereby, the mold device of the lens array of the present invention and the operation and use method thereof have the beneficial effects that the curvature control of the surface contour of the glass lens array can be strengthened, and the surface contour of each lens manufactured is required to reach a perfect curve. And to achieve the effect of homogenizing the internal refractive index of the lens array, thereby improving the manufacturing yield or productivity of the glass lens array.

In order to further understand the features and technical contents of the present invention, please refer to the following detailed description and drawings of the present invention. However, the drawings are only for reference and explanation, and are not intended to limit the creation. In order to further understand the features and technical contents of the present invention, please refer to the following detailed description and drawings of the present invention. However, the drawings are only for reference and description, and are not intended to limit the creation.

1‧‧‧Mold equipment

11‧‧‧Upper stamper

113‧‧‧Round extension

115‧‧‧Upper to the top

12‧‧‧lower die

123‧‧‧Round extension

125‧‧‧The lower die area

13‧‧‧Piece structure

131‧‧‧Opening

132‧‧‧ opening

135‧‧‧through hole

135A‧‧‧ first through hole

135B‧‧‧second through hole

135C‧‧‧ third through hole

135D‧‧‧4th through hole

136‧‧‧ inner hole wall

8‧‧‧glassware

81‧‧‧ upper part

82‧‧‧ lower end

83‧‧‧ body parts

85‧‧‧Extensions

86‧‧‧Extensions

8A‧‧‧First configuration

8B‧‧‧Second configuration

9‧‧‧ lens array

H1, H2‧‧‧ lateral width

W1‧‧‧ first section width

W2‧‧‧Second section width

W3‧‧‧Three section width

FIG. 1A is a schematic view of a mold apparatus for creating a lens array before clamping.

FIG. 1B is a schematic view of the mold apparatus of the lens array after the mold clamping.

2 is a flow chart of a method of using a mold apparatus for creating a lens array.

3A-3E are diagrams showing steps of a method for using different embodiments of a mold apparatus for creating a lens array.

Figure 4 is a corresponding schematic view of the structure of the glass piece and the plate member.

Figure 5 is a schematic view of the finished product of the lens array.

6 to FIG. 9 are schematic views showing other embodiments of the mold apparatus of the lens array after the mold clamping.

10 to 13 are schematic views showing other embodiments in which the glass member and the panel member correspond to each other.

Figure 14 is a schematic illustration of a glazing unit of different configurations.

15A-16B are schematic views of other embodiments of the mold apparatus of the lens array after the mold clamping.

17 to 25 are schematic views of different embodiments of the panel structure of the lens array and the glass member after being combined.

26 to 31 are schematic views showing the structure of a plate member of different configurations.

Figure 32 is a schematic view showing the structure of a mold apparatus according to another embodiment of the present invention.

33 to 36 are schematic structural views of a plate member having a curved configuration.

37 to 38 are schematic views of finished products of lens arrays of different configurations.

39 to 41 are schematic views showing the structure of a non-transparent panel.

42A to 42B are process diagrams showing a method of using another embodiment of a mold apparatus for creating a lens array.

Please refer to FIG. 1A and FIG. 1B . FIG. 1A is a schematic view of the mold device of the lens array before the mold clamping, and FIG. 1B is a schematic view of the mold device of the lens array after the mold clamping. As shown in FIG. 1A, the mold apparatus 1 of the present lens array 9 includes an upper stamper 11, a lower stamper 12, and a plate structure 13. The upper die 11 includes a plurality of upper die abutment regions 115, and the lower die 12 includes a plurality of lower die abutment regions 125. The plate structure 13 is movably disposed on the upper die 11 and the lower die 11 Between the stampers 12, that is, the panel structure 13 can be placed between the upper stamper 11 and the lower stamper 12, or can be removed between the upper stamper 11 and the lower stamper 12. . The plate structure 13 includes a plurality of through holes 135 penetrating the plate structure 13 up and down. The through holes 135 are for receiving a plurality of glass members 8. The glass member 8 has a first cross-sectional width W1; the first cross-sectional width W1 is the maximum horizontal intercept of the glass member 8 in the view of FIG. 1A. In the embodiment, the glass member 8 is a sphere. Therefore, the first section width W1 of the glass member 8 is equal to the diameter of the glass member 8. The through hole 135 includes an upper opening 131 and a lower opening 132. The upper opening 131 and the upper die 11 correspond to each other, and the lower opening 132 and the lower die 12 correspond to each other. The upper opening 131 of the through hole 135 has a second cross-sectional width W2 which is a horizontal intercept of the upper opening 131 presented in the view of FIG. 1A. The lower opening 132 of the through hole 135 has a third cross-sectional width W3 which is the horizontal intercept of the lower opening 132 as shown in the view of FIG. 1A. Here, as shown in FIG. 4, W1≧W2 or W1≧W3, so when the glass member 8 is rolled or placed around the periphery of the through hole 135 of the panel structure 13, the glass member 8 can be located at or It is stuck around the through hole 135, so that a part of the glass member 8 is accommodated or located in the through hole 135 of the plate structure 13. The material of the plate structure 13 includes, but is not limited to, metal, alloy, ceramic, glass, polymer composite material, etc., and the plate structure 13 is movably disposed between the upper die 11 and the lower die 12 Therefore, the panel structure 13 can It is selectively taken out or taken out in conjunction with other process steps to perform the front or back processing of the panel structure 13 or the plurality of glass members 8.

Please refer to FIG. 2 and FIG. 3A simultaneously. FIG. 2 is a flow chart of the method for using the mold device of the lens array, and FIG. 3A is a step diagram of one of the use methods of the mold device. As shown in FIG. 2 and FIG. 3A, in the method of using the present invention, the mold apparatus 1 and the plurality of glass pieces 8 of the lens array 9 are first provided (step S01), and then the plurality of glass pieces 8 are heated and heated (step Tb). Then, at least a part of the volume of the plurality of glass members 8 is accommodated in the plurality of through holes 135 (step S02). Here, the method of placing the plurality of glass members 8 in the through hole 135 or the periphery of the through hole 135 may be that the glass member 8 is clamped and placed one by one by a robot arm (not shown), or The glass member 8 is rolled, slid or moved into the through hole 135, so that a part of the volume of the glass member 8 (or the entire volume of the glass member 8) is accommodated or located in the plate member 13 Inside the hole 135. As shown in FIG. 4, only the lower and lower halves of the glass member 8 are located in the through hole 135, and the upper and upper halves of the glass member 8 are located outside the through hole 135; in other embodiments, The first cross-sectional width W1 of the glass member 8 is approximately equal to the second cross-sectional width W2 or the third cross-sectional width W3, and the glass member 8 can be entirely accommodated or disposed within the through-hole 135. In addition, the glass member 8 of the step Tb is heated before the glass member 8 of the step S02 is placed and set. The purpose of the glass member 8 is to heat the plurality of glass members 8 to 200 to 1500 ° C (depending on the composition of the glass member 8). As a result, the glass member 8 is softened to a temperature that is easy to shape; thus, it is not necessary to place the entire mold device 1 in a high-temperature heating device, thereby simplifying the heating control device.

Next, the upper stamper 11 is closed with the lower stamper 12 (step S03), and the mold clamping step is to use the upper stamper 11 to approach the panel structure 13 to abut the plurality of glassware 8 (step S04). And the lower stamper 12 is brought close to the panel structure 13 to abut a plurality of glass The glass member 8 (step S05); that is, when the upper stamper 11 and the lower stamper 12 are close to each other, the upper mold abutting portion 115 of the upper stamper 11 is located at the periphery of the upper opening 131 to abut the glass. Above the piece 8, the lower die abutment region 125 of the lower die 12 is located at the periphery of the lower opening 132 to abut against the glass member 8. Then, the glass member 8 is pressed through the upper die 11 and the lower die 12 to deform the plurality of glass members 8 (step S06, plastic deformation occurs). As shown in FIG. 1B, after the glass member 8 is clamped, since the glass member 8 is in a high temperature state, its material is softened, so that it is plastically deformed by the action of pressure. The deformed glass member 8 is plastically deformed to produce an upper end portion 81, a body portion 83 and a lower end portion 82. The upper end portion 81 and the lower end portion 82 are respectively located at upper and lower ends of the through hole 135. The portion 83 is located in the through hole 135; that is, after the glass member 8 is clamped and pressed, the contour of the upper end portion 81 is pressed by the upper mold abutting portion 115 of the upper stamper 11. To be deformed, the contoured appearance of the lower end portion 82 of the glass member 8 is deformed by being pressed by the lower mold abutting portion 125 of the lower stamper 12. Therefore, the upper end portion 81 has the same appearance as the upper mold abutment region 115, and the lower end portion 82 has the same outer shape as the lower mold abutment region 125. In addition, after the glass member 8 is pressed and deformed, the body portion 83 of the glass member 8 can be closely coupled with the through hole 135 of the plate member 13 (step S07), so that the glass member 8 can be ensured. The panel structure 13 does not come loose, fall or shake. In practice, the mold clamping operation of step S03 may change the step S04 and the step S05 in a prioritized manner, or perform step S04 and step S05 simultaneously.

In the embodiment of FIG. 1A, the volume of the glass member 8 is greater than or equal to the volume of the space occupied by the through hole 135. Therefore, as shown in FIG. 1B, after the glass member 8 is deformed, the upper end portion 81 thereof protrudes therefrom. Outside the upper opening 131 of the through hole 135, the lower end portion 82 also protrudes beyond the lower opening 132 of the through hole 135 such that the upper end portion 81 The lateral width H1 is greater than the second cross-sectional width W2 of the upper opening 131, and the lateral width H2 of the lower end portion 82 is greater than the third cross-sectional width W3 of the lower opening 132. In this way, the combination of the glass member 8 and the panel structure 13 is more stable and is not easy to loosen and shake.

After the plurality of glass members 8 are combined with the plate structure 13, the mold structure 13 can be opened, and the plate structure 13 is taken out to form a lens array 9 (step S08), which is a finished product diagram of FIG. As shown, the plurality of through holes 135 in the panel structure 13 have been filled and filled with the deformed glass member 8. The glazing unit 8 is of a transparent structure so that light can be allowed to pass through the glazing unit 8. Generally, the plurality of glass members 8 of one lens array 9 are made of the same material and thus have the same refractive index, or a plurality of glass members 8 of one lens array 9 have the same glass transition temperature (Glass transition temperature, Tg). However, in other embodiments, the plurality of glass members 8 of one lens array 9 may also use different materials, or use different compositions of glass, or even use multiple glass members 8 of different refractive indices, or use multiple Different Tg glass pieces 8.

After the fabrication of the lens array 9 is completed, the surface or the interior of the panel structure 13 can be selectively opaque (step Ta); that is, the panel structure 13 can be surface-coated, surface-coated, The method of surface blasting, surface atomization, surface attachment or internal doping of the plate structure achieves the purpose of non-transparency. Here, the step structure 13 of the step Ta is not transparent, and can be performed as needed or ignored, or placed before any of the above steps.

Therefore, the method of using the mold apparatus 1 of the lens array 9 disclosed in FIG. 3A utilizes the contour design of the upper mold abutment region 115 and the lower mold abutment region 125, that is, the glass member 8 of the glass material lens array 9 can be controlled. Shape and deformation, making each one finished The surface profile or surface curvature of the lens (ie, the glass member 8) meets the requirements of a perfect curve. In addition, since the glass member 8 can be preselected, the internal refractive index of the lens array 9 can also be uniformized, and the manufacturing yield or productivity of the glass lens array 9 can be improved. Further, the glass member 8 of the embodiment of FIG. 3A is heated by the step Tb and slowly cooled in the mold apparatus 1. Therefore, it is possible to prevent the temperature from being lowered too quickly and to cause a temperature gradient to cause residual glass thermal stress. Further, since the glass member 8 is clamped, pressed, and deformed at a high temperature, the stress concentration of the mechanical stress can be minimized. Therefore, the mold apparatus 1 of the lens array 9 of the present invention and the method of its operation have commercial potential for popularization and application.

There are other embodiments of the present invention for the method of using the mold apparatus 1 of the lens array 9. Please refer to the schematic diagram of the process steps of FIG. 3B; compared with FIG. 3A, the difference is that the heating operation of the glass member 8 of the step Tb is after the glazing unit 8 of the step S02 is placed and set; the effect is that when the glass is The piece 8 is located on or disposed on the through hole 135 of the plate structure 13, so that all the workpieces (ie, the glass member 8 and the plate structure 13) can be conveniently taken and transported. This method is particularly suitable for a plurality of glass members 8 having different volumes, different contours, or different refractive indices, and still ensures that all the glass members 8 can be simultaneously heated and maintained at the same temperature. Avoiding the temperature difference caused by the multiple glass members 8 being separately heated, affecting the yield.

Further, as shown in FIG. 3C, the temperature rising step Tb of the present embodiment is performed after the mold clamping in step S03, and the effect is that the temperature is raised and the temperature is raised while the mold is being heated, and the temperature and the pressure are gradually gradually decreased. The lifting causes the plurality of glass members 8 to achieve the homogenization effect as much as possible, contributing to a reduction in the uneven distribution of the refractive index of the glass member 8.

As shown in FIG. 3D, the method of using the mold apparatus 1 of the lens array 9 of the present embodiment The opaque action of the plate structure of the step Ta can be adjusted until the mold clamping and shaping of the glass member 8 (ie, before step S03 and step S06), that is, the mold is provided at the beginning of step S01. After the device 1 and the panel structure 13, the panel structure 13 is subjected to surface coating, surface coating, surface blasting, surface atomization, surface attachment or internal doping of the panel structure 13. Here, the non-transparent action of the panel structure 13 of the step Ta may be performed before the step Tb, or may be performed after the step Tb, or may be performed simultaneously with the step Tb; thus, the mold apparatus 1 of the present invention can be made. The method of use has more variations and is suitable for a wider range of applications.

There are other configurations of the present invention for the mold apparatus 1 of the lens array 9. Please refer to FIG. 6 to FIG. 9 . FIG. 6 to FIG. 9 are schematic diagrams of other embodiments of the mold device of the lens array after the mold clamping. As shown in FIG. 6, when the upper die 11 and the lower die 12 are adjacent to the plate structure 13 and the glass member 8, the upper die abutment region 115 covers all of the upper openings 131 (ie, the through holes). The lower die area 125 also covers all of the lower openings 132 (ie, the lower positions of the through holes 135). Further, the volume of the glass member 8 is larger than the volume occupied by the through hole 135, so that after the mold apparatus 1 is clamped, the glass member 8 is shaped by pressure so that the upper end portion 81 of the glass member 8 is 81. Projecting beyond the through hole 135. As such, the lateral width H1 of the upper end portion 81 is greater than the second cross-sectional width W2 of the through hole 135. In the present embodiment, the lateral width H2 of the lower end portion 82 of the molded glass member 8 is almost the same as the third cross-sectional width W3 of the through hole 135. In addition, the shape of the upper die abutment region 115 and the lower die abutment region 125 are different from each other, and the area is different; the upper die abutment region 115 of the upper die 11 is concave, so the glass member 8 The upper end portion 81 is correspondingly convex, and the lower mold abutting portion 125 of the lower mold 12 is flat. Therefore, the lower end portion 82 of the glass member 8 is correspondingly flat. In other embodiments The upper mold abutting portion 115 of the upper stamper 11 may be disposed in a convex shape or a flat shape, or the lower mold abutting portion 125 of the lower stamper 12 may be disposed in a convex shape or a concave shape; Of course, the contour shape of the upper mold abutment region 115 can also be interchanged with the contour contour of the lower mold abutment region 125.

As shown in FIG. 7, the area of the upper mold abutment region 115 is approximately equal to the area of the upper opening 131 of the through hole 135, so that the upper mold abutment region 115 completely covers the upper opening 131. The area of the abutment region 125 is also approximately equal to the area of the lower opening 132 of the through hole 135, so that the lower die abutment region 125 completely covers the lower opening 132. In this embodiment, the upper mold abutment region 115 has a convex shape. Therefore, after the glass member 8 is compression molded, the upper end portion 81 has a concave structure; the lower mold abutment region 125 is concave. Therefore, after the glass member 8 is compression molded, the lower end portion 82 has a convex structure. In addition, the through hole 135 of the embodiment has a columnar shape, so the second cross-sectional width W2 of the upper opening 131 is equal to the third cross-sectional width W3 of the lower opening 132, and the lateral width H1 of the upper end portion 81 is also equal to the lower end portion 82. The lateral width is H2.

In the mold apparatus 1 shown in FIG. 8, the upper upper mold abutment area 115 can completely cover the upper opening 131 of the through hole 135, and the middle lower mold abutment area 125 can cover only a part of the lower opening 132 area. That is, the area of the upper mold abutment region 115 of the intermediate portion is larger than the corresponding area of the lower mold abutment region 125. In this way, after the intermediate glass member 8 is compressed and shaped, the lateral width H1 of the upper end portion 81 is approximately equal to the second cross-sectional width W2 of the upper opening 131, and the lateral width H2 of the lower end portion 82 is smaller than the lower opening. The third cross-sectional width W3 of 132. The upper mold abutment region 115 on both sides of FIG. 8 has the same area as the lower mold abutment region 125, but the contour shape is a convex and a concave shape. Therefore, after the glass member 8 is shaped, the outer contour of the glass member 8 is different from the outer contour of the glass members 8 on both sides.

As shown in the mold apparatus 1 of FIG. 8, the second cross-sectional width W2 of the through hole 135 is not equal to the third cross-sectional width W3, and therefore, the through-hole 135 is tapered. In this embodiment, after the glass member 8 is compression molded, the lateral width H1 of the upper end portion 81 may be greater than, equal to, or smaller than the lateral width H2 of the lower end portion 82; in fact, the lateral width H1, H2 It will depend entirely on the contour of the upper die abutment zone 115 and the lower die abutment zone 125.

The corresponding position of the plurality of glazing elements 8 to the plate structure 13 is additionally described here in step S02 (ie before clamping, press forming). Please refer to FIG. 10 to FIG. 13 . FIG. 10 to FIG. 13 are schematic diagrams of other embodiments in which the glass member and the panel structure correspond to each other. As shown in FIG. 10, the glass member 8 is a sphere, and the first section width W1 of the glass member 8 (ie, the diameter of the sphere) is greater than the second section width W2 of the opening 131 in the through hole 135, so the glass The lower half of the member 8 can be disposed in the through hole 135, so that the entire glass member 8 is stuck around the upper opening 131 of the through hole 135, and the plate member structure 13 and the plurality of glass members 8 can be conveniently moved. , moving, for subsequent processing steps. In this embodiment, the shape of the upper opening 131 and the lower opening 132 of the through hole 135 may be different from each other, and the area of the upper opening 131 is smaller than the area of the lower opening 132 (because the second section width W2 is smaller than the third section Width W3). Further, the through hole 135 includes an inner hole wall 136 connecting the upper opening 131 and the lower opening 132. The upper opening 131 is smaller than the lower opening 132, and the cross section of the inner hole wall 136 is presented. It is a straight line, so the through hole 135 is a tapered space. As shown in FIG. 11, the glass member 8 is a columnar structure, and the first section width W1 of the glass member 8 is larger than the third section width W3 of the lower opening 132 of the through hole 135, so that the lower half of the glass member 8 is It can be disposed in the through hole 135 so that the entire glass member 8 is stuck inside the through hole 135, and the plate member structure 13 and the plurality of glass members 8 can be easily moved and moved. In this embodiment, the through hole The area of the upper opening 131 of the 135 is larger than the area of the lower opening 132 (because the second section width W2 is greater than the third section width W3), and the through hole 135 is an inverted tapered space. As shown in FIG. 12 and FIG. 13 , the through hole 135 of the embodiment is also an inverted tapered space. The area of the upper opening 131 of the through hole 135 is larger than the area of the lower opening 132 , so the glass member 8 is large. A portion of the volume can be received and disposed inside the through hole 135. In addition, the cross section of the inner hole wall 136 of FIGS. 12 and 13 assumes a curve in which the bending direction (the vector of the curved surface) of the hole wall 136 is different from each other.

The mold device 1 of the present invention, the glass member 8 can also have a variety of different configurations. Please refer to FIG. 14, which is a schematic view of a glass member of different configurations. The cross section or section of the glazing unit 8 may be elliptical, tapered, rectangular (e.g., square cylinder, hexagonal cylinder, cylinder), square, or even irregular configuration.

Next, the configuration of the present mold device 1 will be described. Please refer to FIG. 15A to FIG. 16B . FIG. 15A to FIG. 16B are schematic diagrams of other embodiments of the mold apparatus of the lens array after the mold clamping. As shown in FIG. 15A, the area of the upper mold abutment region 115 of the present embodiment is larger than that of the lower mold abutment region 125. Therefore, after the glass member 8 is compression molded, the surface area of the upper end portion 81 is larger than that of the lower end portion 82. Surface area. In addition, the upper mold abutment region 115 covers all of the upper openings 131, and the lower mold abutment region 125 covers only a portion of the lower opening 132. Further, the upper mold abutting portion 115 has a convex structure, so that the upper end portion 81 has a concave structure, and the lower mold abutting portion 125 has a concave structure, so that the lower end portion 82 has a convex structure. As shown in FIG. 15B, the upper mold abutment region 115 is a Fresnel lens structure. Therefore, after the glass member 8 is compression molded, the upper end portion 81 of the glass member 8 also exhibits Fresnel. The structure of the lens. The upper end portion 81 and the lower end portion 82 of the glass member 8 of the present embodiment have a convex structure, and therefore, the glass member 8 is a "lenticular lens". In other embodiments, the structure of the Fresnel lens can also be set The lower die of the lower die 12 abuts the top region 125. As shown in FIG. 16A, the upper mold abutment region 115 covers all of the upper openings 131, and the lower mold abutment region 125 covers only a portion of the lower opening 132. The upper end portion 81 and the lower end portion 82 of the glass member 8 are each concave. Therefore, the glass member 8 is a "double concave lens". As shown in FIG. 16B, the periphery of the upper mold abutment region 115 further includes an abutting extension region 113. The periphery of the lower mold abutment region 125 further includes an abutting extension region 123. The extension regions 113 and 123 are not directly adjacent to the through hole 135, that is, the abutment extension regions 113 and 123 are spaced apart from the through hole 135 by a small distance. In this way, an extension portion 85 can be formed around the upper end portion 81 of the glass member 8, and an extension portion 86 can be formed around the lower end portion 82 of the glass member 8. The extension portions 85, 86 can make the glass member 8 The combination with the panel structure 13 is more stable, avoiding the occurrence of looseness and shaking.

Please refer to FIG. 17 to FIG. 25. FIG. 17 to FIG. 25 are schematic diagrams showing different embodiments of the panel structure of the lens array and the glass member. As shown in Fig. 17, the periphery of the upper end portion 81 of the glass member 8 includes an extended portion 85, and the lower end portion 82 is absent, and the lower end portion 82 is flush with the lower edge of the panel structure 13. In addition, the glass member 8 of FIG. 18 forms a "upwardly convex and flat" lens structure, and the upper end portion 81 includes an extending portion 85 alongside, so that the lateral width H1 of the upper end portion 81 is greater than the second cross-sectional width W2 of the through hole 135. . The glazing unit 8 of Fig. 19 forms an upper and lower biconvex "lenticular lens" structure, and the glazing unit 8 includes extensions 85, 86 for enhancing the effectiveness of the fixation. The glazing unit 8 of Fig. 20 forms a double-concave "double concave lens" structure. The glazing unit 8 of Fig. 21 forms a "upper, lower flat" lens structure. The glazing unit 8 of Fig. 22 forms a concave-convex "concave-convex lens" structure. The glazing unit 8 of Fig. 23 also forms a double lenticular "lenticular lens" configuration, but the glazing unit 8 does not include extensions 85, 86. The glazing member 8 of Fig. 24 also forms a "upwardly convex and flat" lens structure, but adjacent to the upper end portion 81 The extension 85 is not included in the side. The glass member 8 of Fig. 25 forms a concave-convex "concave-convex lens" structure, but the area of the concave lens is smaller than the area of the convex lens.

Please refer to FIG. 26 to FIG. 31, and FIG. 26 to FIG. 31 are schematic structural views of the plates of different configurations. As shown in FIG. 26, the through hole 135 of the plate structure 13 has a circular opening 131 and a lower opening 132 of a hexagonal shape, that is, an upper opening 131 and a lower opening 132 of the through hole 135. The shapes are different from each other. In addition, the shape of the upper opening 131 may be a circle, an ellipse, a polygon (for example, a triangle, a quadrangle, a pentagon, etc.) or other irregular shape, and the shape of the lower opening 132 may of course be a circle, an ellipse, a polygon or the like. The irregular shape; the upper opening 131 of the through hole 135 and the lower opening 132 may have the same area or different. As shown in FIG. 27 and FIG. 28, the upper opening 131 of the through hole 135 is larger than the lower opening 132, and the cross section of the inner hole wall 136 is a straight line or a curve. As shown in FIG. 29, the plate structure 13 includes a plurality of first through holes 135A and a plurality of second through holes 135B. The volume or shape of the first through holes 135A and the second through holes 135B are different from each other. The first through hole 135A and the second through hole 135B are arranged in a regular manner, that is, the through holes of the same configuration are arranged in a circle, and the through holes of the plurality of different configurations sequentially form concentric circles. As shown in FIG. 30, the plurality of first through holes 135A and the plurality of second through holes 135B of the plate structure 13 are also arranged in a regular manner, and the through holes of the same configuration are arranged in a straight line (vertical Arranged or arranged horizontally, a plurality of through holes of different configurations are sequentially arranged in a staggered arrangement. As shown in FIG. 31, the plate structure 13 includes a first through hole 135A, a second through hole 135B, a third through hole 135C, and a fourth through hole 135D. The configuration or volume of each through hole is different, and the same structure The through holes of the type form a concentric arrangement.

The mold apparatus 1 of the present invention can also use a curved or curved plate structure 13. Please refer to FIG. 32 to FIG. 36. FIG. 32 is a mold device according to another embodiment of the present invention. Schematic diagram of the structure, Figure 33 ~ Figure 36 is a schematic diagram of the structure of the curved surface. As shown in FIG. 32 to FIG. 36, the plate structure 13 is curved or curved. Correspondingly, the upper die 11 and the lower die 12 are also in contact with or in contact with the plate structure 13 or Arc shape.

After the processing of the mold apparatus 1 of the present invention, the lens array 9 formed can be as shown in FIGS. 37 to 38, and FIGS. 37 to 38 are schematic views of the finished lens arrays of different configurations. The lens array 9 of FIG. 37 and FIG. 38 includes a plurality of glass members 8 of different volumes or different configurations, that is, the glass member 8 includes a first configuration 8A and a second configuration 8B, the first The volume or shape of the glass member 8 of the configuration 8A and the glass member 8 of the second configuration 8B are different from each other, and the glass member 8 of the first configuration 8A and the glass member 8 of the second configuration 8B are The rules are regularly interactive and staggered. In other embodiments, the glass member 8 may further include a third configuration, a fourth configuration, etc., or a plurality of different glass members 8 having a plurality of different refractive indices, for example, The glass member 8 has a first refractive index, a second refractive index, a third refractive index, ..., and then a plurality of different refractive index glass members 8 are sequentially arranged, alternately arranged or regularly arranged; or alternatively, the plurality of glass members 8 have a plurality of different glass transition temperatures (Tg), for example, the glass member 8 has a first glass transition temperature, a second glass transition temperature, a third glass transition temperature, ..., and then a plurality of different glass transition temperatures of the glass The pieces 8 are arranged in order, interactively arranged or regularly arranged. Here, the panel structure 13 of FIG. 37 is a flat plate structure, and the panel structure 13 of FIG. 38 is a curved plate structure.

The plate structure 13 of the mould device 1 can of course also be varied. Please refer to FIG. 39 to FIG. 41, and FIG. 39 to FIG. 41 are schematic diagrams showing the structure of the non-transparent plate. As shown in FIG. 39, the interior of the panel structure 13 can be made to be non-transparent by adding a coloring agent or doping. As shown in FIG. 40, the panel structure 13 The step of surface blasting or surface atomization may be applied to the surface (including the periphery of the through hole 135 or the inner hole wall 136) to render the panel structure 13 in a non-transparent state. As shown in FIG. 41, the panel structure 13 can be subjected to a surface coating and a surface coating step to make the panel structure 13 appear in a non-transparent state.

Please refer to FIG. 42A to FIG. 42B. FIG. 42A to FIG. 42B are diagrams showing the steps of using the mold device of the lens array according to still another embodiment. As shown in FIG. 42A, the method step diagram of the present embodiment differs from that of FIG. 3A in that the panel structure 13 can use a plurality of different glass members 8, that is, the plurality of glass members 8 have different glass transition temperatures (Glass transition). Temperature, Tg), that is, have different Tg values. Here, in order to place a plurality of different glass transition temperature glass members 8 on the plate structure 13, it is necessary to first install a glass member 8 having a high Tg value on the plate structure 13, and then to lower the glass of the Tg value. The piece 8 is mounted on the plate structure 13, so that the glass member 8 having a low Tg value is prevented from being softened at an excessively high temperature (the glass which is softened at a high temperature may stick to the mold and damage the mold). Therefore, in the first cycle of FIG. 42A, step Tb, step S02, step S03, step S06, and step S07 are sequentially performed for mounting and shaping the glass member 8 of the first glass transition temperature, and then, Then, the second step Tb, step S02, step S03, step S06, and step S07 are performed to perform the mounting and shaping of the glass member 8 at the second glass transition temperature. And so on, if there is a third glass transition temperature, the fourth glass transition temperature of the glass member 8, repeating the third cycle, the fourth cycle of the step Tb, the step S02, the step S03, the step S06, the step S07, Glass members 8 of different Tg values are mounted on the panel structure 13. As a result, the glass transition temperature (Tg value) of the glass member 8 that is accommodated in the through hole 135 is lower than that of the glass member 8 that has been shaped in the through hole 135. Glass transition temperature.

As shown in FIG. 42B, this embodiment is also a step of clamping and shaping the glass member 8 of different Tg values repeatedly; however, the difference between the embodiment and the embodiment of FIG. 42A is that the glass member of FIG. 42A 8 heating and heating, the glass member 8 with different Tg values is separately heated, and the glass member 8 of FIG. 42B is heated and heated, then all the glass members 8 are heated together, waiting for their individual cooling to different temperatures, and then proceeding to step S02 Steps S03, S06, and S07 are used to set the glass members 8 of different temperatures in the through holes 135 (step S02). In Fig. 42B, the glass transition temperature (Tg value) of the glass member 8 which is accommodated in the through hole 135 for the next time must also be lower than the previous time to be accommodated in the through hole 135. The glass transition temperature of the glass member 8. Thereby, the glass members 8 of different Tg values can be placed on the plate structure 13 through the mold clamping and shaping action, and the glass members 8 of different Tg values are arranged, alternately arranged or regularly arranged. .

Here, the lower die 12, the lower die 12, the upper die abutment region 115, the lower die abutment region 125, the upper opening 131, the lower opening 132, the inner hole wall 136, the plate structure 13, and the cross section disclosed above are disclosed. The widths W1, W2, W3 and their corresponding spatial/structural relationships, or features such as the contour, shape, material, refractive index or arrangement of the glass members 8, may be individually matched or combined to any of the above embodiments. Thereby, the mold apparatus 1 of the lens array 9 and the method of its operation can enhance the curvature control of the surface contour of the glass material lens array 9, so that the surface contour of each lens manufactured is perfect. And the effect of homogenizing the internal refractive index of the lens array 9 is achieved, thereby improving the manufacturing yield or productivity of the lens array 9 made of glass. Therefore, it has great commercial application potential.

The present invention is described above by way of example, but it is not intended to limit the scope of patent rights claimed herein. The scope of patent protection is attached to the scope of the patent application and its scope Depending on the field. Any changes or modifications made by those skilled in the art without departing from the spirit or scope of this patent are subject to the equivalent changes or designs made in the spirit of the present disclosure and should be included in the scope of the patent application below. Inside.

1‧‧‧Mold equipment

11‧‧‧Upper stamper

115‧‧‧Upper to the top

12‧‧‧lower die

125‧‧‧The lower die area

13‧‧‧Piece structure

131‧‧‧Opening

132‧‧‧ opening

135‧‧‧through hole

136‧‧‧ inner hole wall

8‧‧‧glassware

W1‧‧‧ first section width

W2‧‧‧Second section width

W3‧‧‧Three section width

Claims (12)

A mold apparatus for a lens array, comprising: an upper stamper (11) comprising a plurality of upper mold abutment regions (115); a lower stamper (12) comprising a plurality of lower mold abutment regions (125) a plate structure (13) movably disposed between the upper die (11) and the lower die (12), the plate structure (13) comprising a plurality of structures penetrating the plate ( a through hole (135) for receiving a plurality of glass members (8), the glass member (8) having a first cross-sectional width W1, the through hole (135) including an upper portion An opening (131) and a lower opening (132) corresponding to the upper die (11), the lower opening (132) and the lower die (12) corresponding to each other, the upper opening (131) Having a second cross-sectional width W2, the lower opening (132) having a third cross-sectional width W3, wherein W1≧W2 or W1≧W3; when the upper stamper (11) and the lower stamper (12) are mutually When approaching, the upper mold abutment region (115) is located at the periphery of the upper opening (131) to abut the glass member (8), and the lower mold abutment region (125) is located at the periphery of the lower opening (132) to be abutted. The glass piece (8). The mold apparatus of the lens array according to claim 1, wherein at least one of the upper mold abutting area (115) and the lower mold abutting area (125) have different shapes or different areas; wherein the upper mold The abutment region (115) or the lower die abutment region (125) is a structure of a convex structure, a concave structure or a Fresnel lens. The mold apparatus of the lens array of claim 1, wherein the upper opening (131) of the through hole (135) and the lower opening (132) are different in shape or different in area; wherein the upper opening (131) or the shape of the lower opening (132) is circular, elliptical, Polygon or irregular shape. The mold apparatus of the lens array of claim 3, wherein the through hole (135) includes an inner hole wall (136) connecting the upper opening (131) and the lower opening (132) The upper opening (131) is larger than, equal to, or smaller than the lower opening (132), and the cross section of the inner hole wall (136) appears as a straight line or a curve. The mold device of the lens array of claim 1, wherein the plate structure (13) comprises at least one first through hole (135A) and at least one second through hole (135B), the first through hole (135A) The volume or shape of the second through hole (135B) is different from each other, and the first through hole (135A) and the second through hole (135B) are sequentially arranged, alternately arranged or regularly arranged. The mold apparatus of the lens array according to claim 1, wherein the plurality of glass members (8) have different volumes or different shapes, and the plurality of glass members (8) include at least one first configuration (8A) and at least one a second configuration (8B), the glass member (8) of the first configuration (8A) and the glass member (8) of the second configuration (8B) are different in volume or shape, and the first The glass member (8) of the configuration (8A) and the glass member (8) of the second configuration (8B) are sequentially arranged, alternately arranged or regularly arranged. The mold apparatus of the lens array according to claim 1, wherein the plurality of different glass members (8) include at least a first refractive index and a second refractive index, the first refractive index and the second refractive index being mutually phased The glass member (8) having the first refractive index and the glass member (8) having the second refractive index are sequentially arranged, alternately arranged or regularly arranged; or, the plurality of different glass members (8) include at least a first glass transition temperature (Tg) and a second glass transition temperature, the first glass transition temperature and the second glass transition temperature are different from each other, and the glass member having the first glass transition temperature (8) The glass members (8) with the second glass transition temperature are arranged in sequence, alternately arranged or regularly arranged. The mold apparatus of the lens array according to claim 1, wherein the panel structure (13) is opaque or the outer shape of the panel structure (13) is curved. The mold apparatus of the lens array according to claim 1, wherein the glass member (8) is spherical, elliptical, columnar, or tapered. The mold apparatus of the lens array of claim 1, wherein at least a portion of the glass member (8) is accommodating or located within the through hole (135). The mold apparatus of the lens array according to claim 1, wherein the volume of the glass member (8) is greater than or equal to the volume of the space occupied by the through hole (135). The mold apparatus of the lens array according to claim 1, wherein when the upper stamper (11) and the lower stamper (12) are close to each other, the upper mold abutting region (115) covers at least a portion of the upper opening (131), or the lower mold abutment region (125) covers at least a portion of the lower opening (132).