KR20100011246U - Miniature stacked glass lens module - Google Patents

Abstract

A compact laminated glass lens module is disclosed. The compact laminated glass lens module includes at least one laminated optical glass lens element, lens holder and other optical elements. The laminated optical glass lens element is formed by cutting along alignment notches in a laminated bonded optical glass lens array. The laminated optical glass lens element and other optical elements are then mounted in the lens holder to form a compact laminated glass lens module. This achieves accurate alignment of the optical axis of the lens in the lens module. The manufacturing processes of the lens module can be greatly simplified, and the manufacturing cost thereof is greatly reduced.

Description

Miniature laminated glass lens module {MINIATURE STACKED GLASS LENS MODULE}

The present invention relates to a compact laminated glass lens module, and more particularly, to a laminated glass lens module applied to small optical lenses of cameras such as mobile phones, notebook computers, personal digital assistants (PDAs) and the like. Laminated optical glass lenses are fabricated by cutting alignment notches of laminated and bonded optical glass lens arrays.

Glass precision molding technology, like the lenses disclosed in US 2006/0107695, US 2007/0043463, TW 095101830, TW 095133807 and JP 63-295448, etc., has high resolution, high stability and low cost. Dew has been widely applied to make aspherical molded glass lenses. A glass preform (or glass material) is placed in a mold having an upper mold and a lower mold, which is heated and softened. Thereafter, the upper mold and the lower mold are correspondingly clamped, and pressure is applied to the upper mold and the lower mold so that the glass preform has the same optical surfaces. After cooling, a molded glass lens is made by the molding surfaces of the upper mold and the lower mold. To reduce manufacturing costs, the prior art JP 63-304201 and US 2005/041215 provide a lens array formed by glass molding. Regarding a single lens, JP 02-044033 reveals that a lens blank with multiple lenses is produced by the movement of glass materials and by multiple molding processes. The lens array is then cut out into a plurality of lens elements.

Optical lenses formed by glass molding are widely applied to assembled lenses of LED light sources, lenses of solar energy conversion systems and optical lenses of cameras for mobile phones. The assembled lens or optical lens is formed by a plurality of optical lenses having different lens lens powers arranged to have a specific distance from each other with respect to the optical axis. Therefore, during assembly, the optical axis of each optical lens must be exactly aligned in order to avoid deterioration of resolution. In addition, the distance between the two adjacent optical lenses (the spacing to the optical axis) is fixed. As a result, complex and precise alignment processes are required for assembly. Therefore, it is impossible to improve the yield rate, and it is difficult to lower the cost. For this reason, when the assembly has an alignment off the optical axis, optical resolution (such as impact on the MTF) is affected. Therefore, lens alignment of the optical lens array is more complicated and important. Regarding the manufacture of an optical lens array, JP 2001-194508 discloses a method of making a plastic optical lens array. TWM 343166 discloses a method for manufacturing a glass optical lens array. After fabrication, the optical lens array can be cut and assembled into a lens module to form a single optical lens element. Alternatively, the optical lens array is assembled with other optical elements to form a lens submodule array which is later cropped to form a lens submodule. The lens submodule is assembled with lens holders, image sensors or other optical elements to form a lens module.

In the fabrication of lens module arrays, wafer level lens modules are disclosed in US 7,183,643, US 2007/0070511, WO 2008/011003 and the like. Referring to FIG. 1, a lens module array generally includes an aperture 711, a cover glass 712, a plurality of optical lenses, and an IR-cut lens 717. As shown in FIG. 1, a plurality of optical lenses form a set of three piece types of optical lenses. The optical lens set includes a first optical lens 714, a second optical lens 715, and a third optical lens 716. Two adjacent optical lenses are divided by a spacer 713. After assembly, a lens module array is formed, which is then cut into multiple lens modules. In addition, as shown in FIG. 2, the lens module disclosed in WO 2008/063528 is formed by a lamination method. Aperture 711, first optical lens 714, spacer 713, second optical lens 715, spacer 713, third optical lens 716, image sensor 717 and circuit board : 718 is packaged in an encapsulant 719 to form a lens module.

In the lens module array, the alignment of the lens array in the process of assembling the lens array having a plurality of optical lenses affects the resolution of the lens module. In US 2006/0249859, imaging techniques are used to determine whether stacked wafers are correctly aligned. Fiducial marks, a pattern pre-engraved on each wafer, are revealed in the image created by infrared light. In the assembly of plastic optical lens arrays, JP 2000-321526 and JP 2000-227505 disclose bi-convex type optical lens arrays formed by a combination of convex portions and concave portions. US 7,187,501 discloses a resin lens in which cone-shaped protrusions are provided on an outer circumferential surface thereof. The plastic resin lens array is formed by laminating resin lens plates by fitting the protrusions and corresponding holes. However, in the conventional method of assembling the protrusions and holes to form a plastic optical lens array, after plastic injection molding, shrinkage of the plastic material causes the size of the protrusions and holes to change. As a result, positional accuracy is affected, and alignment of the optical axis becomes difficult. Thus, the application of plastic optical lens arrays is limited, especially the complicated processes in the manufacture of small lens modules cause an increase in cost. Molded glass lenses have a larger refractive index than plastic lenses and also have better thermal stability, and have been applied to various optical systems. In addition, optical lens arrays made of molded glass exhibit less shrinkage.

In order to produce lens modules that meet the requirements of compact design and mass production, the development of an optical glass lens array with simple structure and high precision is required.

It is therefore an object of the present invention to provide a compact laminated glass lens module having a single optical lens applied to small optical lenses of cameras such as mobile phones, notebook computers, personal digital assistants (PDAs) and the like. Another object of the present invention is to provide a compact laminated glass lens module having at least two optical lenses applied to small optical lenses of cameras such as mobile phones, notebook computers, personal digital assistants (PDAs) and the like.

A compact laminated glass lens module according to an embodiment of the present invention for achieving the above object includes a laminated optical glass lens element, a lens holder and other optical elements. The module features are as follows: The laminated optical glass lens element is obtained by cutting along the alignment marks formed by the intersection of the alignment notches of the laminated optical glass lens array. The laminated optical glass lens array is fabricated by laminating an optical glass lens array using a slide through a curable adhesive in adhesive grooves, the optical glass lens array having adhesive grooves and alignment notches. At this time, the laminated optical glass lens element and other optical elements are mounted in the lens holder to form a compact laminated glass lens module.

The compact laminated glass lens module according to another embodiment of the present invention includes a laminated optical glass lens element, a lens holder and other optical elements. The module features are as follows: The laminated optical glass lens element is obtained by cutting along the alignment marks formed by the intersection of the alignment notches of the laminated optical glass lens array. The laminated optical glass lens array is formed by laminating and adhering a first optical glass lens array, a second optical glass lens array and / or another optical glass lens array. At least one optical glass lens array is provided with alignment notches, and the at least one optical glass lens array is provided with adhesive grooves filled with adhesive for bonding the optical glass lens arrays. The laminated optical glass lens element and other optical elements are mounted in the lens holder to form a compact laminated glass lens module.

The other optical element may be any one or a combination of an optical lens, a spacer, an iris, a cover glass, an infrared blocking glass, and an image sensor. The adhesive is a thermosetting resin adhesive or a UV curable adhesive.

The compact laminated glass lens module is formed by the laminated optical glass lens element and other optical elements that need to be mounted in the lens holder. Since the laminated optical glass lens element can be accurately assembled and suitable for mass production, the lens module can be minimized and easily mass produced.

According to the present invention, since the optical axis of the lens can be accurately and quickly aligned, and the manufacturing process of the lens module can be greatly simplified, the lens module can be manufactured easily and quickly and conveniently, thus mass production of the lens module. This is possible and there is an advantage that the manufacturing cost can be greatly reduced.

Referring to FIG. 3, the compact laminated glass lens module 30 according to the present invention includes at least one laminated optical glass lens element 100, at least one lens holder 301, and a plurality of optical elements 311 and 312. , 314, 315, 316). The lens element 100 is composed of first and second optical glass lens elements 141 and 142. The lens element 100 is shown in FIG. 7 in accordance with an alignment mark 122 (as shown in FIG. 8) formed by alignment notches 121 (121a, 121b,...). And the like, by cutting the laminated optical glass lens array 10. The lens array 10 includes glue grooves 111 and alignment notches 121 (121a, 121b,...), And is bonded to each other by an adhesive 13 coated in the adhesive grooves 111. It is made by the optical glass lens arrays 11 and 12 to be assembled. 3, but not limited to the embodiment shown in FIG. 3, cover glass 311, aperture 312, IR-cut glass 314, image sensor Optical elements such as 315 and circuit board 316 and the lens element 100 are mounted in the lens holder 301 to form the lens module 30.

Referring to FIG. 7, the lens array 10 includes two lens arrays 11 and 12 assembled and fixed by the adhesive 13 to have a predetermined interval. The lens arrays 11, 12 are made by multi-cavity glass molding and have an optical area and a non-optical area. The first lens array 11 has adhesive grooves 111 filled with the adhesive 13 along the outer circumferential surface of the non-optical area of the second optical surfaces 102 (102a, 102b,...). The shape and pattern of the adhesive groove 111 is not limited. That is, it may be a circular groove. After the adhesive 13 in the adhesive groove 111 is cured, the two assembled lens arrays 11 and 12 are laminated and fixed to form the laminated optical glass lens array 10.

Referring to FIG. 8, the second lens array 12 includes alignment notches 121 (121a, 121b,...) Provided on the outer circumferential surface of the non-optical area of the fourth optical surfaces 104 (104a, 104b,...). It includes. The shape and pattern of each alignment notch 121 is not limited. The alignment notch 121 may be an annular groove having a V-shaped cross section whose center is at the optical axis 14 of the fourth optical surfaces 104 (104a, 104b,...). In addition, the diameter of each alignment notch 121 may be the same. At this time, the intersections of two adjacent alignment notches 121 (121a, 121b,...) Form two alignment marks 122, as shown in FIG. 8. Thus, according to the alignment mark 122, the lens array 10 is accurately cut out, resulting in a plurality of single stacked optical lens elements 100, as in step S8 shown in FIG.

As shown in FIG. 9, the method of manufacturing the lens module 30 according to the present invention includes the following steps:

S1: providing a glass blank 21;

S2: providing a first optical surface mold 51 and a second optical surface mold 52 of the lens array; Here, each optical surface mold has a first optical surface molding surface 511 (511a, 511b, ...) and a second optical surface molding surface 521 (521a, 521b, ...) 2 the optical surface mold 52 further includes an adhesive groove molding surface 524 (524a, 524b, ...),

S3: The molds 51 and 52 are heated through the heater 225 to put the glass blank 21 into the molds 51 and 52 to form the first lens array 11 through molding processes. Pressing the molds (51, 52); Here, the first lens array 11 has a corresponding 16 (4 × 4) having 16 (4 × 4) first optical surfaces and 16 (4 × 4) adhesive grooves 111 in a non-optical area. ) Second optical surfaces,

S4: manufacturing a second lens array 12 according to the step S3; The second lens array 12 has annular alignment notches 121 (121a, 121b,...) Having 16 (4 × 4) third optical surfaces and 16 (4 × 4) V-shaped cross sections. A corresponding 16 (4 × 4) fourth optical planes provided in this non-optical region,

S5: applying the adhesive 13 to the adhesive groove 111 between two adjacent lens arrays 11, 12;

S6: using the laser beam (140) for the alignment of the optical axes (14, 14 ') of the two lens arrays (11, 12); Here, the laser beam 140 is aligned with the optical axis 14, 14 ', as shown in FIG.

S7: curing the adhesive (13) to form a laminated optical glass lens array (10) accurately aligned with the optical axis (14);

S8: After connecting the two alignment notches 121 (121a, 121b) of the lens array 10 to form two alignment marks 122, the above to form a cutting line 15 Connecting two alignment marks 122 to cut the lens array 10 into 16 stacked optical lens elements 100 through a diamond grinding wheel along the cutting line 15. ;

S9: mounting the lens element 100 and other optical elements to the lens holder 301 in turn to form a lens module 30.

<First Embodiment>

Referring to FIG. 4, this embodiment is a compact laminated glass lens module 30 having a single optical lens applied to web cameras. The compact laminated glass lens module 30 includes a laminated optical lens element 100, a lens holder 301 and other optical elements, the other optical elements being an IR-cut glass 314, an image. Sensor 315 and circuit board 316. The laminated optical lens element 100 is formed by a first optical glass lens element 141 and a shade 143, and their optical parameters are shown in [Table 1].

Optical plane Radius (mm) Distance to optical axis (mm) Diameter of the optical surface (mm) material  101 ＊ 1.061 10.6 0.35 L-BSL7  102 ＊ 0.097 0.099 0.95  143 infinity 0.30 1.09 BK7  314 infinity 0.51 1.23 -  315 infinity - 1.65 -

＊ aspherical surface

The laminated optical lens element 100 is manufactured by cutting the laminated optical glass lens array 10. Referring to FIG. 11, the 4 × 4 laminated optical glass lens array 10 includes a first lens array 11 and a shade array 12 ′ fixed to each other by an adhesive 13. The first lens array 11 has 4 × 4 first optical surfaces 101 (101a, 101b,...) And corresponding 4 × 4 second optical surfaces 102 (102a, 102b,...) It is provided. The shade array 12 'is an opaque compatible plastic piece for blocking light and has a 4x4 penetration corresponding to the second optical surfaces 102 (102a, 102b, ...). With through holes. 4 × 4 annular alignment notches 121 (121a, 121b,...) Having a V-shaped cross section are arranged around the non-optical area of the first optical surfaces 101 (101a, 101b,...). The center of each alignment notch is in the optical axis 14 of the corresponding first optical surfaces 101 (101a, 101b,...), Respectively. The second optical surface 102 has annular 4 × 4 glue grooves 111 having a trapezoidal cross section. In assembly, each adhesive groove 111 is filled with an adhesive 13, such as UV curing adhesives, after which the shade array 12 ′ is stacked thereon. Next, the first lens array 11 and the shade array 12 'are mounted in an assembly fixture, not shown, to apply the adhesive 13 to form the laminated optical glass lens array 10. It is sent to a UV curing oven to cure.

Referring to FIG. 8, two adjacent alignment notches 121a and 121b form two alignment marks 122. The two alignment marks 122 together form a cutting line 15. By cutting along the cutting line 15 using a diamond grinding wheel, 16 laminated optical lens elements 100 having the same shape and size are obtained.

As shown in FIG. 4, when assembling the lens module 30, a lens holder 301 is prepared. The lens element 100 is mounted in the lens holder 301, and then the infrared ray blocking glass is assembled into the lens holder 301. A fixed ring 302 is used to position the components. Next, a pre-installed circuit board 316 having an image sensor 315 is disposed in the lens holder 301. Thus, the lens module 30 is obtained. Thus, the lens module 30 according to the present invention is easily and quickly manufactured, the lens module 30 can be mass-produced, and the manufacturing cost thereof can be greatly reduced.

Second Embodiment

Referring to Fig. 3, this embodiment is a compact laminated glass lens module 30 having two optical lenses applied to lenses for high precision mobile phones. The compact laminated glass lens module 30 includes a laminated optical lens element 100, a lens holder 301 and other optical elements, the other optical elements comprising a cover glass 311, an aperture. 312) and an infrared cut glass (314). The laminated optical lens element 100 is composed of a first optical glass lens element 141 and a second optical glass lens element 142, and their optical parameters are shown in [Table 2].

Optical plane Radius (mm) Distance to optical axis (mm) Diameter of the optical surface (mm) material  101 ＊ 0.871 0.69 1.023 L-BAL42  102 ＊ 1.534 0.51 0.91  103 ＊ -4.741 1.13 1.3 L-BAL42  104 ＊ -19.042 0.10 2.57  314 infinity 0.70 2.97 BK7  302 infinity 0.22 3.32 -  315 infinity - 3.55 -

＊ aspherical surface

The lens element 100 is manufactured by cutting the laminated optical glass lens array 10. Referring to FIG. 7, the 4 × 4 lens array 10 includes a first optical glass lens array 11 and a second optical glass lens array 12 laminated and fixed by an adhesive 13. The first optical glass lens array 11 has 4 × 4 first optical surfaces 101 (101a, 101b,...) And corresponding 4 × 4 second optical surfaces 102 (102a, 102b,...). )). The second optical surface 102 is arranged with annular 4 × 4 glue grooves 111 having a trapezoidal cross section. The second optical glass lens array 12 has 4x4 third optical surfaces 103 (103a, 103b, ...) and corresponding 4x4 fourth optical surfaces 104 (104a, 104b,...). )). 4 × 4 annular alignment notches 121 (121a, 121b,...) Having a V-shaped cross section are arranged around the non-optical area of the fourth optical surface 104, with the centers of each alignment notch respectively corresponding. In the optical axis 14 of the fourth optical surfaces 104 (104a, 104b,...).

Since the present embodiment is applied to the high precision lens module 30, not only the optical axis of the second lens array 12 but also the optical axis of the first lens array 11 must satisfy the requirements of tolerance. Should be ordered. Referring to FIG. 10, when assembling the first lens array 11 and the second lens array 12, the second lens array 12 is disposed in an assembly fixture not shown. After the adhesive 13 is filled in the adhesive groove 111 of the first lens array 11, the adhesive 13 is stacked on the second lens array 12 to be disposed in the assembly fixture. Next, the laser beam 140 is used for the alignment of the optical axes. When the laser beam 140 passes through the optical axis 14 'of the second lens array 12, it is aligned along the optical axis 14'. Thereafter, in order to align the laser beam 140 along the optical axis 14 of the first lens array 11, the first lens array 11 may be aligned with an arrow A shown in FIG. 10. , Move horizontally. This completes the alignment of the two optical axes 14 ', 14. The alignment is only performed on a 4 × 4 diagonal surface.

In this embodiment, the adhesive 13 is a UV curing adhesive. After the alignment of the optical axes 14 ′, 14, the first and second lens arrays 11, 12 are fixed in an assembly fixture to cure and stack the optical glass lens array 10 of adhesive 13. For the formation of a, it is sent to a UV curing oven.

4 × 4 annular alignment notches 121 (121a, 121b,...) Having a V-shaped cross section are arranged in the fourth optical surface 104. By two adjacent alignment notches 121a and 121b, two alignment marks 122 are formed. As in <First Embodiment>, the two alignment marks 122 are connected to form the cutting line 15. By cutting along the cutting line 15 using a diamond grinding wheel, 16 laminated optical lens elements 100 having the same shape and size are obtained. In addition, the optical axes of the first, second, third and fourth optical surfaces are aligned to be applied to the lenses for the mobile phone.

The assembly method of the present embodiment is as follows: the cover glass 311, the iris 312, the lens element 100 and the infrared blocking glass 314 are sequentially arranged in the lens holder 301 to fix the ring (fixed ring) (302) to be fixed. Thereafter, a pre-installed circuit board 316 having an image sensor 315 is assembled with the lens holder 301 to form the lens module 30. Thus, the lens module 30 can be manufactured quickly and conveniently, the lens module 30 can be mass-produced, and the manufacturing cost thereof can be greatly reduced.

Third Embodiment

Referring to Fig. 5, this embodiment is a compact laminated glass lens module 30 having two optical lenses and spacers, which is applied to high precision mobile phone cameras, similar to the embodiments described above. The compact laminated glass lens module 30 includes a laminated optical lens element 100, a lens holder 301 and other optical elements, the other optical elements comprising a cover glass 311, an aperture 312, a spacer ( spacer: 313) and infrared cut glass (314). The laminated optical lens element 100 is composed of a first optical glass lens element 141 and a second optical glass lens element 142, and their optical parameters are shown in [Table 3].

Optical plane Radius (mm) Distance to optical axis (mm) Diameter of the optical surface (mm) material  101 ＊ 0.442 0.35 0.47 L-BSL7  102 ＊ 0.914 0.17 0.52  103 ＊ -2.178 0.39 0.58
L-LAM69
 104 ＊ -1.690 0.20 0.97  313 infinity 0.45 1.12  314 infinity 0.25 1.22 BK7  302 infinity 0.05 1.68 -  315 infinity - 1.76 -

＊ aspherical surface

The adhesive 13 used in this embodiment is a thermoset adhesive. The manufacturing method of the lens element 100 is the same as the above-described <second embodiment>.

The assembly method of this embodiment is as follows: The cover glass 311, the iris 312, the lens element 100, the spacer 313 and the infrared blocking glass 314 are sequentially placed in the lens holder 301 To be fixed by the retaining ring 302. Thereafter, a pre-installed circuit board 316 having an image sensor 315 is assembled with the lens holder 301 to form the lens module 30. Thus, the lens module 30 can be manufactured quickly and conveniently, the lens module 30 can be mass-produced, and the manufacturing cost thereof can be greatly reduced.

<Fourth Embodiment>

Referring to FIG. 6, the present embodiment is a compact laminated glass lens module 30 having three optical lenses and spacers, which is applied to cameras for mobile phones having high pixels. The compact laminated glass lens module 30 includes a laminated optical lens element 100, a lens holder 301 and other optical elements, the other optical elements comprising a cover glass 311, an aperture 312, a spacer ( 313, optical glass lens 303 and IR-cut glass 314. The laminated optical lens element 100 is composed of a first optical glass lens element 141 and a second optical glass lens element 142, and their optical parameters are shown in [Table 4].

Optical plane Radius (mm) Distance to optical axis (mm) Diameter of the optical surface (mm) material  101 ＊ 1.015 0.64 1.52 L-BAL35  102 ＊ 2.746 0.30 0.97  103 ＊ -2.265 0.95 1.07 S-NPH1  104 ＊ -6.781 0.40 1.90  105 ＊ 2.312 0.89 3.03 L-BSL7  106 ＊ 1.784 0.22 3.92  302 infinity 0.70 4.29 -  315 infinity - 4.56 -

＊ aspherical surface

The adhesive 13 used in this embodiment is a thermoset adhesive. The manufacturing method of the lens element 100 is the same as the above-described <second embodiment>.

The assembly method of this embodiment is as follows: The cover glass 311, the aperture 312, the lens element 100, and the spacer 313 are sequentially disposed in the lens holder 301. Thereafter, the optical glass lens 303 is arranged below the spacer 313, and an optical system is used to align the optical axis of the optical glass lens 303. The fixing ring 302 is used to fix the components. Next, a pre-installed circuit board 316 having an image sensor 315 is assembled with the lens holder 301 to form the lens module 30. Thus, the lens module 30 can be manufactured quickly and conveniently, the lens module 30 can be mass-produced, and the manufacturing cost thereof can be greatly reduced.

Additional modifications and effects other than the configurations and effects specific to the present invention described so far will be apparent to those skilled in the art. Accordingly, the scope of the present invention should not be limited to only those shown in the specific examples disclosed in the specification and the accompanying drawings, but the claims in the Utility Model Registration Claims attached thereto and equivalents thereto. It should be understood that various modifications may be made without departing from the scope of the present invention as defined by.

1 is a schematic diagram of a conventional optical glass lens module array.

2 shows the packaging of a conventional lens module.

3 is an embodiment of a lens module according to the present invention.

4 is another embodiment of a lens module according to the present invention.

5 is another embodiment of a lens module according to the present invention.

6 is another embodiment of a lens module according to the present invention.

7 is an embodiment of a laminated optical glass lens array according to the present invention.

8 is a partial bottom view of one embodiment of a laminated optical glass lens array according to the present invention.

9 is a manufacturing process chart for manufacturing a laminated optical glass lens array and laminated lens module according to the present invention.

10 is a schematic view showing the alignment of the optical axis of the laminated optical glass lens array according to the present invention.

FIG. 11 is a laminated optical glass lens array of the embodiment shown in FIG. 4.

Claims (10)

At least one laminated optical glass lens element, a lens holder and at least one optical element; The laminated optical glass lens element is obtained by cutting along alignment marks formed by the intersection of alignment notches of the laminated optical glass lens array; The laminated optical glass lens array comprises at least one optical glass lens array comprising a non-optical region with adhesive grooves and alignment notches; The adhesive groove is filled with an adhesive for bonding the optical glass lens array and the shade array with a predetermined distance with respect to the optical axis to cure and to form a laminated optical glass lens array; And the lens holder is used to mount the laminated optical glass lens element and the optical element. At least one laminated optical glass lens element, a lens holder and at least one optical element; The laminated optical glass lens element is obtained by cutting along alignment marks formed by the intersection of alignment notches of the laminated optical glass lens array; The laminated optical glass lens array includes a plurality of optical glass lens arrays, wherein at least one of the optical glass lens arrays is provided with adhesive grooves filled with adhesive, at least one of the optical glass lens arrays Alignment notches are arranged in the non-optical region of; The optical glass lens arrays are arranged at a predetermined interval with respect to the optical axis, and after curing, are assembled by an adhesive to form a laminated optical glass lens array; And the lens holder is used to mount the laminated optical glass lens element and the optical element. The method of claim 1, And said optical element is an optical lens, an aperture, a spacer, a cover glass, an infrared cut lens, an image sensor, a circuit board or a combination thereof. The method of claim 2, And said optical element is an optical lens, an aperture, a spacer, a cover glass, an infrared cut lens, an image sensor, a circuit board or a combination thereof. The method of claim 1, And the adhesive for laminating the optical glass lens array and the shade array is a thermosetting resin adhesive cured by heat. The method of claim 2, And the adhesive for laminating the optical glass lens array and the shade array is a thermosetting resin adhesive cured by heat. The method of claim 1, And the adhesive for laminating the optical glass lens array and the shade array is a UV curable adhesive cured by ultraviolet rays. The method of claim 2, And the adhesive for laminating the optical glass lens array and the shade array is a UV curable adhesive cured by ultraviolet rays. The method of claim 1, The alignment notches are annular alignment notches having a V-shaped cross section arranged around the non-optical area of the optical glass lens array and the annular of the alignment notches such that two alignment marks are formed by the intersection of two adjacent alignment notches. A miniature laminated glass lens module, wherein the center is located on the optical axis of each optical surface. The method of claim 2, The alignment notches are annular alignment notches having a V-shaped cross section arranged around the non-optical area of the optical glass lens array and the annular of the alignment notches such that two alignment marks are formed by the intersection of two adjacent alignment notches. A miniature laminated glass lens module, wherein the center is located on the optical axis of each optical surface.

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