TW201722697A - Method for manufacturing microlens array and mold thereof - Google Patents

Abstract

A method for manufacturing microlens array is provided. The steps include: A first mold is manufactured in a precision machining technology for forming a flexible body with a film array assembly; Combining the flexible body and a substrate, wherein at least a cavity having a predetermined pressure be formed between the film array assembly and the substrate; A curable material layer is formed on the film array assembly; Making the outside pressure of the flexible body be different from the predetermined pressure, and the film array assembly is deformed and be with a deforming surface; Curing the curable material layer; Removing the assembly of the flexible body and the substrate; And the cured material layer be as a second mold and be used to manufacture the microlens array with the deforming surface.

Description

Method for manufacturing microlens array structure and microlens array structure and mold thereof

The present invention relates to a method for fabricating a microlens array structure and a method for fabricating a mold for a microlens array structure, and more particularly to a method for fabricating a microlens array structure using a thin film deformation technique and a method for fabricating a mold of the microlens array structure.

The microlens array structure is a very important micro-optical component, and the micro-optical component is a key component for manufacturing a small photoelectric subsystem to enhance light intensity focusing, etc., and has the advantages of small size, light weight, low cost, and the like, and realizes a small, array. , imaging changes and other functions, it is expected to reduce the cost of rapid production, but have complete transparency and accuracy, and the microlens array is widely used.

Conventional microlens array structures have a variety of fabrication methods. In general, most of these manufacturing methods use a lithography process to make a mold. However, the production of molds by the lithography process has problems of high cost and difficulty in controlling the size. In particular, when the microlens array structure needs to have a plurality of lens curvatures, the processing and process difficulty thereof is greatly improved, and the overall process is also unstable. Therefore, how to improve is an important issue.

An object of the present invention is to provide a method for fabricating a microlens array structure which has the advantages of low cost, easy size control, and convenient and quick modification of the structure.

Another object of the present invention is to provide a method for fabricating a mold of a microlens array structure which has the advantages of low cost, easy size control, and convenient and quick modification of the structure.

In order to achieve the above object, the present invention provides a method for fabricating a microlens array structure, comprising the steps of: fabricating a first mold by a precision machining; forming a flexible body on the first mold, the flexible body Having a body, a plurality of recesses, and a passage connecting the recesses, wherein the recesses and the passages are formed in the body, and the recesses form a film layer array combination on one side of the body; In combination with a substrate, wherein the film layer array combination and the substrate form a plurality of chambers, wherein the chambers have a predetermined pressure; forming a layer of curable material on the film layer array combination; The external pressure in combination with the substrate is different from the predetermined pressure, driving the film layer array to be combined and deformed, and having a deformed surface; curing the layer of the curable material on the film layer array combination; removing the flexible body and the a combination of the substrate, wherein the layer of the curable material after curing has the deformed surface; and the cured layer of the curable material having the deformed surface is a second mold, and Molding the structure of the microlens array, the microlens array in which the structure having the modified surface.

The present invention further provides a method for fabricating a mold of a microlens array structure, comprising: fabricating a first mold by a precision machining; forming a flexible body having a body and a plurality of recesses in the first mold And a channel connecting the recesses, wherein the recesses and the channel are formed in the body, and the recesses form a film layer array combination on one side of the body; the flexible body is combined with a substrate, wherein the Forming a plurality of chambers between the film layer array assembly and the substrate, wherein the chambers have a predetermined pressure; forming a layer of curable material on the film layer array combination; and externally combining the flexible body and the substrate The pressure is different from the predetermined pressure, driving the film layer array to be combined and deformed, and having a deformed surface; curing the layer of the curable material on the film layer array combination; and removing the combination of the flexible body and the substrate to be cured The layer of curable material is then provided with the deformed surface to form a mold of the microlens array structure.

According to an embodiment of the invention, the precision machining is milling or electrical discharge machining.

According to an embodiment of the invention, the method of fabricating the first mold includes: providing a mold body; and performing the precision machining on the surface of the mold body to form the first mold.

According to an embodiment of the invention, the material of the mold body is Polymethy Mathacrylate (PMMA).

According to an embodiment of the invention, the substrate is made of polymethythmium (PMMA) or polycarbonate (PC), and the substrate is an electronic wafer. The material of the flexible body is It is a flexible polymer material or Poly-Dimethyl Siloxane (PDMS), and the material of the curable material layer is a photocurable adhesive.

In accordance with an embodiment of the present invention, a method of differentiating an external pressure of the combination of the flexible body and the substrate from the predetermined pressure includes injecting a fluid into the passage to generate the predetermined pressure.

According to an embodiment of the invention, the recesses have different sizes such that the chambers have different spatial sizes, and the film layer array combination has a plurality of film layers having different thicknesses.

According to an embodiment of the invention, the film layers have different shape variables when the external pressure of the combination of the flexible body and the substrate is different from the predetermined pressure.

According to an embodiment of the present invention, a method for fabricating a mold of a microlens array structure further includes forming a metal layer on the second mold.

According to an embodiment of the present invention, the channel communicates with the recesses, and the other channel communicates with the recesses of the other portions, the channels are not in communication with each other, and have different predetermined pressures, and the film layer array combination has at least Two film layer array structures.

According to one embodiment of the invention, the precision machining is performed by turning or milling a diamond knife.

According to an embodiment of the invention, the first mold is produced by chemical processing.

Based on the above, the present invention utilizes a technique for controlling the deformation of a film to cause the film layer array to be deformed in combination, and has a deformed surface. In detail, the present invention can inject fluid into the channel to generate the predetermined pressure, so that the external pressure of the combination of the flexible body and the substrate is different from the predetermined pressure, so as to produce a plurality of lens curvatures in subsequent processes. Lens array structure.

In addition, the present invention can also apply precision machining to replace the yellow lithography process with higher cost, more complicated process and longer time to manufacture the microlens array structure. In this way, the present invention is a method for fabricating a microlens array structure with better efficiency and a lower manufacturing cost. On the other hand, the manufacturing method of the microlens array structure of the present invention and the manufacturing method of the mold of the microlens array structure are relatively simple, and therefore have better process stability.

Furthermore, in the flexible body formed by the first mold, since the film layer array combination has a plurality of film layers, and the film layers have different thicknesses, a plurality of lens curvatures are required in the microlens array structure. At this time, by controlling the film layers of different thicknesses to produce different degrees of curvature deformation under the same pressure environment, a microlens array structure having a plurality of lens curvatures can be fabricated in a subsequent process.

Compared with the conventional technology, the microlens array structure process with multiple lens curvatures can not be effectively controlled, or the application is complicated and the processing difficulty is high. The present invention is applied to control the film deformation technology and apply precision machining technology to quickly stabilize. A low cost microlens array structure and a low cost microlens array structure mold are fabricated.

In order to enable the reviewing committee to better understand the technical contents of the present invention, the preferred embodiments are described below.

1 is a flow chart showing the structure of a microlens array according to an embodiment of the present invention, and FIG. 2A to FIG. 2H are cross-sectional views showing the structure of the microlens array of FIG. 1. Referring to FIG. 2A to 2H. The manufacturing method of the microlens array structure of this embodiment includes the following steps. First, as shown in step S110 and FIG. 2A, a first mold 210 is fabricated. In the present embodiment, the method of making the first mold 210 is, for example, precision machining or chemical processing. Precision machining is, for example, ultra-precision machining technology, which can be diamond knife turning or milling. The chemical processing is, for example, reactive-ion etching or deep reactive-ion etching. When the manufacturing method of the first mold 210 is precision machining, the first mold 210 is manufactured by, for example, providing a mold body in advance and performing precision machining on the surface of the mold body to form the first mold 210. In a preferred embodiment, precision machining is, for example, milling or electrical discharge machining. Further, the material of the above-mentioned mold body can be selected, for example, according to a process of precision machining, and the present invention is not limited thereto. In this embodiment, the material of the mold body is, for example, polymethyl methacrylate (PMMA).

Next, as shown in steps S120-S130 and FIG. 2B, a flexible body 220 having a film layer array combination 224 is formed in the first mold 210 (step S120), and the flexible body 220 is combined with a substrate 230 to A plurality of chambers having a predetermined pressure are formed (step S130). In detail, the flexible body 220 of the present embodiment has, for example, a body 221, a plurality of recesses 222, and a passage 223 communicating with the recesses 222, wherein the recesses 222 and the passages 223 are formed in the body 221, and the recesses 222 One side 221a of the body 221 is formed with a film layer array combination 224. In addition, after the flexible body 220 is bonded to the substrate 230, a plurality of chambers 225 having a predetermined pressure are formed between the film layer array assembly 224 and the substrate 230. In the present embodiment, the material of the flexible body 220 is, for example, a flexible polymer material, and is, for example, a poly-dimethyl Siloxane (PDMS). In addition, the material of the substrate 230 is, for example, Polymethy Mathacrylate (PMMA) or Polycarbonate (PC), and the substrate 230 can also be any form of electronic wafer. No restrictions.

Next, as shown in steps S140-S160 and FIG. 2C (or FIG. 2D), a curable material layer 240 is formed on the thin film layer array assembly 224 (step S140), and the outer portion of the combination of the flexible body 220 and the substrate 230 is combined. The pressure is different from the predetermined pressure of the chamber 225 (step S150), thereby driving the film layer array assembly 224 to deform to have a deformed surface S, followed by re-curing the curable material layer 240 on the film layer array assembly 224 (step S160). Wherein, in FIG. 2C, the external pressure of the combination of the flexible body 220 and the substrate 230 is less than the predetermined pressure of the chamber 225, and thus the cured film layer array combination 224 is convexly deformed. Conversely, in FIG. 2D, the external pressure of the combination of the flexible body 220 and the substrate 230 is greater than the predetermined pressure of the chamber 225, and thus the cured film layer array combination 224 will undergo a concave deformation. Whether the film layer array combination 224 is convexly deformed or concavely deformed, the curable material layer 240 can be cured in a state of having a deformed surface S. In a preferred embodiment, the method of causing the external pressure of the combination of the flexible body 220 and the substrate 230 to differ from the predetermined pressure includes injecting fluid into the passage 223 to generate the predetermined pressure, the predetermined pressure being different from the ambient pressure.

In addition, although the above embodiment first performs step S140 (forming a curable material layer 240 on the thin film layer array assembly 224), and then performing step S150 (the external pressure of the combination of the flexible body 220 and the substrate 230 is different from the cavity). The predetermined pressure of the chamber 225), however, in other preferred embodiments, the step S150 may be performed first (the external pressure of the combination of the flexible body 220 and the substrate 230 is different from the predetermined pressure of the chamber 225), and then the steps are performed. S140 (forming a layer of curable material 240 on the film layer array assembly 224). The present invention does not limit the order of execution of step S140 and step S150 herein. In addition, in the embodiment, the material of the curable material layer 240 is, for example, a photocurable adhesive (or resin), which may be a UV curable adhesive.

After performing steps S140-S160, the combination of the flexible body 220 and the substrate 230 is then removed as shown in step S170 and FIG. 2E (or FIG. 2F). That is, the method for fabricating the microlens array structure of the present embodiment performs a demolding process, and after the demolding process, the cured curable material layer 240 has a deformed surface S, and the cured curable material layer 240 is It is a manufacturing mold for a microlens array structure. The curable material layer 240 shown in FIG. 2E is generated corresponding to the combination of the flexible body 220 and the substrate 230 shown in FIG. 2C, and the curable material layer 240 shown in FIG. 2F corresponds to the scratch shown in FIG. 2D. The combination of the body 220 and the substrate 230 is produced.

Finally, as shown in step S180 and FIG. 2G (or FIG. 2H), the cured curable material layer 240 having the deformed surface S is a second mold, and the microlens array structure 250 is formed in the second mold. The microlens array structure 250 has a deformed surface S. The microlens array structure 250 shown in FIG. 2G is generated corresponding to the curable material layer 240 (second mold) shown in FIG. 2E, and the microlens array structure 250 shown in FIG. 2H corresponds to the one shown in FIG. 2F. A layer of curable material 240 (second mold) is produced.

In particular, in the present embodiment, the recesses 222 may have different sizes and configurations depending on the lens size and arrangement position of the microlens array structure. The lens size design according to the microlens array structure will, in conjunction, cause these chambers 225 to have different spatial sizes. On the other hand, the thin film layer array combination 224 of the present embodiment is composed of, for example, a plurality of thin film layers to achieve subsequent fabrication of the lens array. Among them, these thin film layers can have different curvature designs according to the lens curvature requirements of the microlens array. Briefly, when the curvature of a plurality of lenses in a microlens array structure is required to be uniform, the film layers may have the same thickness. Therefore, when the external pressure of the combination of the flexible body 220 and the substrate 230 is different from the predetermined pressure of the chamber 225, the shape variables of the film layers are uniform, and the lens array having the same curvature of the deformed surface S can be produced subsequently.

Alternatively, in a preferred embodiment, the film layers can be designed to have different thicknesses. Therefore, when the external pressure of the combination of the flexible body 220 and the substrate 230 is different from the predetermined pressure of the chamber 225, since these thin film layers have different thicknesses, the deformation of these thin film layers even under the same pressure difference environment Also inconsistent. Therefore, in the lens array produced subsequently, the curvature of each deformed surface S is inconsistent. Regarding the control of the above pressure difference, the present invention is, for example, that an injection pump (not shown) is connected to the inlet end of the channel, and a pressure sensor (not shown) is connected to the outlet end of the channel, so that The pressure change of the chamber is controlled to change the shape of the film layer to form, for example, a spherical surface, an aspheric surface, or various shapes.

It is worth mentioning that the forming thickness of the plurality of film layers is based on the design of the first mold 210 shown in step S110 and FIG. 2A. Since the first mold 210 of the present invention is manufactured by precision machining, the first mold 210 has a simple manufacturing process and better production efficiency, and can effectively control the forming position and the state of the film layer. In order to make the subsequent microlens array structure in production or in the fabrication of the mold (second mold) of the microlens array structure, the microlens of different sizes, different curvatures and different positions can be simultaneously fabricated and combined. On the same substrate, a variety of microlens arrays can be reproduced, and at the same time, better process stability can be achieved.

In an embodiment of the invention, a metal layer (not shown) may also be formed on the second mold. Further, the present invention can apply a layer of metal to a second mold of a material such as a photocurable adhesive (resin), and then use an electroplating technique to produce a metal mold required for industrial mass production, thereby mass producing a microlens array. structure.

Further, in step S120, in the present embodiment, for example, a flexible polymer material is injected into the first mold 210, and then, for example, a heating process is performed to cure the flexible polymer material. It is bonded to a substrate 230, such as an electronic wafer, after demolding. In other words, the present invention is to fabricate a microfluidic wafer by precision machining, which is formed by the recess 222 and the passage 223 of the communicating recess 222 herein. By arranging, for example, a wafer material of a flexible polymer in the upper layer of the microchannel, and utilizing a pressure change (air pressure or hydraulic pressure) of the microchannel to deform a wafer material such as a flexible polymer, and then bonding An upper cover is subjected to a second over-molding to produce lenses of various shapes (for example, spherical or non-spherical) for subsequent processes. Wherein, the mold for the second overturning is the second mold described herein, and a metal material can be plated thereon as a metal mold for mass production in the future, and using techniques such as injection molding and roll forming. Mass production of microlens arrays.

In a preferred embodiment (as shown in FIG. 3, which is a cross-sectional view of a combination of a flexible body and a substrate according to another embodiment of the present invention), the passage 223 is only connected to the partial recess 222, and has another passage. 223' comes to connect the recess 222' of the other portion. Here, the passage 223 and the passage 223' are, for example, not in communication with each other, and for example, may be set to have different predetermined pressures. The film layer array combination 224 has at least two film layer array structures 224, 224' on the regions corresponding to the recess 222 and the recess 222'. Therefore, when the external pressure of the combination of the flexible body and the substrate is different from the predetermined pressure of the channel 223 and the channel 223', the film layer array combination 224, 224' has different deformation forms, thereby allowing the microlens array. The fabrication method of the structure and the manufacturing method of the mold of the microlens array structure have more variability.

In summary, the present invention utilizes a technique for controlling film deformation to cause the film layer array to be combined and deformed to have a deformed surface. In detail, the present invention can inject fluid into the channel to generate the predetermined pressure, so that the external pressure of the combination of the flexible body and the substrate is different from the predetermined pressure, so as to produce a plurality of lens curvatures in subsequent processes. Lens array structure.

In addition, the present invention can also apply precision machining to replace the conventional process with higher cost, complicated process, and longer time to manufacture a microlens array structure. In other words, the present invention has the advantages of high efficiency, low cost, easy size control, and convenient and quick modification of the structure. On the other hand, the manufacturing method of the microlens array structure of the present invention and the manufacturing method of the mold of the microlens array structure are relatively simple, and therefore have better process stability. On the other hand, the design of the present invention can easily make the plurality of film layers in the film layer array combination have different thicknesses or sizes, so that when the microlens array structure needs to have various lens curvatures or lens specifications, By controlling the film layers of different thicknesses to produce different degrees of curvature deformation under the same pressure environment, a microlens array structure having a plurality of lens curvatures can be fabricated in a subsequent process.

Compared with the conventional technology, the microlens array structure process with multiple lens curvatures cannot be effectively controlled, or the application is complicated and the processing difficulty is high. The present invention is applied to control the film deformation technology and apply precision machining technology to quickly. A low-cost microlens array structure is stably produced.

The present invention is a breakthrough in terms of its purpose, means, and efficacy, both of which are distinct from the characteristics of conventional techniques. It is to be noted that the above-described embodiments are merely illustrative of the principles of the invention and its advantages, and are not intended to limit the scope of the invention. Modifications and variations of the embodiments can be made by those skilled in the art without departing from the spirit and scope of the invention. The scope of protection of the present invention should be as described in the scope of the patent application to be described later.

210‧‧‧First mould
220‧‧‧Flexible body
221‧‧‧ Ontology
221a‧‧‧One side of the body
222, 222'‧‧‧ recess
223, 223'‧‧‧ channel
224, 224'‧‧‧ film layer array combination
225‧‧‧ chamber
230‧‧‧Substrate
240‧‧‧Curable material layer
250‧‧‧Microlens array structure
S‧‧‧ deformed surface
S110-S180‧‧‧Steps

FIG. 1 is a flow chart showing the fabrication of a microlens array structure according to an embodiment of the invention. 2A to 2H are cross-sectional views showing the structure of the microlens array structure of Fig. 1. 3 is a cross-sectional view showing a combination of a flexible body and a substrate according to another embodiment of the present invention.

S110-S180‧‧‧Steps

Claims (13)

A method for fabricating a microlens array structure, comprising: fabricating a first mold by a precision machining; forming a flexible body on the first mold, the flexible body having a body, a plurality of recesses, and connecting the recesses a channel, wherein the recesses and the channel are formed in the body, and the recesses form a film layer array combination on one side of the body; the flexible body is combined with a substrate, wherein the film layer array is combined with the Between the substrates, a plurality of chambers are formed, wherein the chambers have a predetermined pressure; a layer of curable material is formed on the film layer array combination; an external pressure of the combination of the flexible body and the substrate is different from the predetermined pressure Driving the film layer array to form a combination deformation, and having a deformed surface; curing the layer of the curable material on the film layer array combination; removing the combination of the flexible body and the substrate, and curing the curable material layer And forming the deformed surface; and forming the cured layer of the curable material having the deformed surface as a second mold, and molding the microlens array structure in the second mold, wherein A microlens array having a structure of the surface modification. A microlens array structure manufacturing method of the mold comprises: forming a first mold by a precision machining; forming a flexible body on the first mold, the flexible body having a body, a plurality of recesses, and connecting the plurality of a channel of the recess, wherein the recesses and the channel are formed in the body, and the recesses form a film layer array combination on one side of the body; the flexible body is combined with a substrate, wherein the film layer array is combined Forming a plurality of chambers with the substrate, wherein the chambers have a predetermined pressure; forming a layer of curable material on the film layer array combination; the external pressure of the combination of the flexible body and the substrate is different from the Predetermining the pressure to drive the film layer array to deform, and having a deformed surface; curing the layer of the curable material on the film layer array combination; and removing the combination of the flexible body and the substrate, and curing the The layer of cured material has the deformed surface to form a mold of the microlens array structure. The manufacturing method according to the first or the second aspect of the invention, wherein the precision machining is milling or electric discharge machining. The manufacturing method according to the first or the second aspect of the invention, wherein the method for manufacturing the first mold comprises: providing a mold body; and performing the precision machining on the surface of the mold body to form the first mold Mold. The manufacturing method according to claim 4, wherein the material of the mold body is polymethythmethane (PMMA). The manufacturing method according to the first or the second aspect of the invention, wherein the substrate is made of polymethyphate (PMMA) or polycarbonate (PC), and the substrate is an electronic chip. (wafer), the material of the flexible body is poly-dimethyl Siloxane (PDMS), and the material of the curable material layer is a photocurable adhesive. The manufacturing method of claim 1 or 2, wherein the method of making the external pressure of the combination of the flexible body and the substrate different from the predetermined pressure comprises: injecting a fluid into the channel to generate the predetermined pressure . The manufacturing method of claim 1 or 2, wherein the recesses have different sizes such that the chambers have different spatial sizes, and the film layer array combination has a plurality of film layers, These film layers have different thicknesses. The manufacturing method according to claim 8, wherein the film layers have different shape variables when the external pressure of the combination of the flexible body and the substrate is different from the predetermined pressure. The manufacturing method as described in claim 1 or 2, further comprising forming a metal layer on the second mold. The manufacturing method of claim 1 or 2, wherein the channel communicates with the recesses, and the other channel communicates with the recesses of the other portions, the channels are not in communication with each other, and have different predetermined Pressure, and the film layer array combination has at least two film layer array structures. The manufacturing method according to the first or the second aspect of the patent application, wherein the precision machining system is a diamond cutter turning or milling. The manufacturing method according to the first or the second aspect of the invention, wherein the first mold is produced by chemical processing.