Title of Invention	A METHOD OF MANUFACTURING A CELL ARRAY STRUCTURE AND A METHOD OF MANUFACTURING MINUTE COMPOSITE MATERIAL
Abstract	A method of manufacturing a cell array structure includes.a first step of laminating a deformable layer capable of causing plastic deformation on a substrate, the substrate being formed with plural, mutually separated depressions on a top surface thereof, such that the deformable layer forms a mutually isolated space in each of the plural depressions; and a second step of extending the space in each of the plural depressions by causing plastic deformation in the deformable layer, such that there are formed plural columnar cells respectively in correspondence to the plural depressions.

Title of Invention

A METHOD OF MANUFACTURING A CELL ARRAY STRUCTURE AND A METHOD OF MANUFACTURING MINUTE COMPOSITE MATERIAL

Abstract

A method of manufacturing a cell array structure includes.a first step of laminating a deformable layer capable of causing plastic deformation on a substrate, the substrate being formed with plural, mutually separated depressions on a top surface thereof, such that the deformable layer forms a mutually isolated space in each of the plural depressions; and a second step of extending the space in each of the plural depressions by causing plastic deformation in the deformable layer, such that there are formed plural columnar cells respectively in correspondence to the plural depressions.

Full Text	- 1 - DESCRIPTION MINIATURE CELL ARRAY STRUCTURE AND MANUFACTURING METHOD OF MINIATURIZED COMPOSITE. COMPONENT USING SUCH A MINIATURE CELL ARRAY STRUCTURE TECHNICAL FIELD The present invention generally relates to molding technology of plastic components and more particularly to the high-precision molding technology of highly miniaturized plastic composites formed of plural parts. The technology of the present invention is applicable to the production of miniature plastic lens arrays for use in optical scanning system of copying machines, facsimile machines, solid-state scanning type printers, and the like, or optical waveguides having built-in miniature lens array designed for optical transmission, production of lenses of digital cameras, production of optical fiber array used for projector screens, touch panels, photosensitive bodies for electron photography process, display devices, and the like. BACKGROUND ART Conventionally, there is a technology of forming high-precision plastic products formed of plural miniaturized components by way of molding. - 2 - More specifically, there is a technology of forming: (1) miniature lens arrays; and (2) minute optical fiber arrays. (1) Conventional Technology related to Miniature Lens Arrays For the conventional technology related to miniature lens arrays or microlens arrays, Japanese Laid-Open Patent Application 1-107202 (Patent Reference 1), Japanese Laid-Open Patent Application 2004-341474 (Patent Reference 2); Japanese Laid-Open Patent Application 2004-45586 (Patent Reference 3) are cited. More specifically, Patent Reference 1 discloses a manufacturing method of a lens array according to the steps of: arraying GRIN (graded index) cylindrical lenses in a mold such that the optical axes thereof are aligned in a predetermined direction; and injecting a molten resin into the mold to form a molding in which the lens array and the resin are integrated. Further, Patent Reference 2 describes the method for producing an optical component by an extrusion molding-process. More specifically, the technology of Patent Reference 2 aims for a production method of an optical component - 3 - characterized by long lifetime of the mold, capability of forming the lenses without distortion or optical defects and capability of integrating the lenses easily into a main apparatus with high precision. Thus, a lens holding member is placed on a lower mold in such a manner that the lens holding member is formed with a large number of lens holes, and lenses are placed on the respective lens holes of the lens holding member. Thereby, the lower mold and the upper mold are formed respectively with a lower lens mold surface and an upper lens mold surface with the diameter smaller than the diameter of the lens holes, and lenses are formed by pressing the lower mold and the upper mold with each other. By using different materials for the lens and the lens holding member, it becomes possible to suppress optical noise of the lens. Particularly, by using a metal for the lens holding member, it becomes possible to mount the lens array to a main apparatus easily by way of soldering. Further, Patent Reference 4 provides the method of manufacturing a high-precision composite - molding having a thin optical shielding part. The reference eliminates the problem of misalignment - 4 - between a molded product and a molding apparatus applying a secondary molding process to the molded product and enables manufacturing of a composite by molding process with high precision in terms of dimensions and pattern transfer precision. With this prior art, reference positions are defined respectively to the molded product produced by the first molding process and to the mold used for the secondary molding process for mutual alignment at the time of initial setup of the secondary molding process. Further, adjustment of dimensions is achieved by way of expanding or shrinking the primary molding or the mold or by way of mechanical dimensional adjustment. Further, the start timing of holding the primary molding in the secondary molding apparatus is controlled by detecting the mutual positional relationship therebetween or by evaluating the mutual positional relationship based on the linear thermal expansion coefficients by detecting the temperature. Alternatively, the start timing may be controlled based on the time calculated from the temperature and the dimension. Thereby, the start timing of the secondary molding is defined as the timing in which the temperature of the primary - 5 - molding has reached a temperature higher than the glass transition point by 3 - 25°C. Japanese Patent 3,521,469 (Patent Reference 5) describes a manufacturing method of resin lens array according to the process steps of: forming a resin layer on one side of a flat substrate by applying a transparent resin with a uniform thickness; urging the resin layer against an optical shielding plate of an optically shielding material formed with plural through-holes; forming lenses by extruding a part of the resin layer into the through- holes of the optical shielding plate; curing the resin layer to form a lens array sheet; and fixing the substrate and the optical shielding plate by way of the resin layer. Further, Japanese Laid-Open Patent Application 2004-45586 provides a method of manufacturing a microlens array sheet having an optical shielding layer comprising the steps of: irradiating a ultraviolet radiation to a microlens array sheet comprising a consecutive lamination of: a transparent support substrate carrying microlenses at one side and a transparent a photosensitive layer or a thermoplastic resin layer at the other side; a UV- cure adhesive resin layer colored in black; and a - 6 - protective film layer, such that the ultraviolet radiation is applied to the side where the lenses are formed; curing the UV-cure resin layer at the parts where the UV radiation is focused by the microlenses to cause transfer of the cured resin layer corresponding to the focused parts to the protective film layer; peeling off the cured resin layer of the focused parts from the transparent photosensitive layer or the thermoplastic layer by peeling the protective film layer therefrom and forming an optical shielding pattern of the UV-cure resin layer in correspondence to the parts not exposed to the UV radiation and remaining in intimate contact with the transparent photosensitive layer. (2) Conventional Technology related to Optical Fiber Arrays There are various conventional arts related to manufacture of optical fiber arrays. Japanese Laid-Open Patent Application 2004- 118119 (Patent Reference 6) discloses a technology related to plastic optical fiber arrays and manufacturing method thereof. This prior art technology enables manufacturing of optical fiber array characterized by smooth core surface and reduced optical transmission loss with low cost in - 7 - short time while using a simple manufacturing apparatus, and comprises the steps of: lowering a comb-shaped molding that includes plural bar-shaped fingers extending parallel with each other toward a UV-cure molten resin of liquid state such that end parts of the bar-shaped fingers contact with the molten resin simultaneously; pulling up the bar- shaped fingers; curing the resin pulled up from the molten resin with the foregoing end parts to form plural core parts simultaneously; forming a cladding layer by dipping the entire core parts into a molten UV-cure resin (cladding resin solution) to form a cladding layer composite; placing the cladding layer composite thus formed into a vessel together with a molten thermoplastic resin of low viscosity; forming the entire thermoplastic resin by heating the vessel together with the molten resin and the cladding layer composite to form a protective part; cutting the molding thus formed including therein the comb-shaped part at the end parts of the bar-shaped fingers; and polishing the cross-section of the end parts thus formed. Japanese Laid-Open Patent Application 8- 112873 (Patent Reference 7) discloses the technology - 8 - related to a porous body and manufacturing process thereof. More specifically, this reference aims for a light weight porous body of excellent thermal insulation and compressive strength and provides a sheet-shaped porous body comprising: square-shaped cells forming a lattice patern in a thermoplastic resin body; and a highly expandable thermoplastic resin composition formed in each cell, the highly expandable thermoplastic resin composition having an expansion ratio of 20 times as large as the thermoplastic resin forming the cells. Further, Japanese Laid-Open Patent Application 10-80964 (Patent Reference 8) discloses a honeycomb structure and manufacturing technology thereof. More specifically, the reference teaches a strong transparent honeycomb structure of stable quality over a long period of time and the manufacturing method thereof, wherein the honeycomb structure includes three-dimensional packing of columnar cells of polygonal cross-sectional shape in a resin with high density. Thereby, the cells are formed without providing a junction part between the cell walls, and the cells are formed by placing an - 9 - expandable substance in a resin with a three- dimensionally regular arrangement and by inducing expansion of the expandable substance. Patent Reference 1 Japanese Laid-Open Patent Application 1-107202 official gazette Patent Reference 2 Japanese Laid-Open Patent Application 2004-341474 official gazette Patent Reference 3 Japanese Laid-Open Patent Application 2004-45586 official gazette Patent Reference 4 Japanese Laid Open Patent Application 2003-80543 official gazette Patent Reference 5 Japanese Patent 3,521,469 Patent Reference 6 Japanese Laid-Open Patent Application 2004-118119 official gazette Patent Reference 7 Japanese Laid-Open Patent Application 8-112873 official gazette Patent Reference 8 Japanese Laid-Open Patent Application 10-80964 official gazette Patent Reference 9 Japanese Patent Publication 56-34780 official gazette DISCLOSURE OF THE INVENTION. . . [Problem with Manufacture of Lens Array] - 10 - When manufacturing a miniature composite honeycomb structure, a typical example of which being the one shown in Figure 1, more than one hundred lenses 72 are assembled to form a microlens array in an optical shielding part 71 in the form of lattice by way of molding process. With such a honeycomb structure, there is a need of solving, the problems that: (a) forming the optical shielding part as thin as possible; and (b) maintaining high precision after formation of the composite. In the case of the technology of Patent Reference 1, in which the optical shielding part is injected after arraying the lenses, there arises no problem with regard to the foregoing point (a) . On the other hand, there is a possibility with this technology to form the lenses after formation of the optical shielding part. In such a case, however, the optical shielding part may be damaged at the time of removing the composite from the mold. Further, in the case the microlens array is miniaturized and the thickness of the optical shielding part is reduced to about 20um, it is not possible to fill such a small space with ordinary - 11 - injection molding process because of the too large viscosity of the resin, and it is not possible to form the optical shielding part by way of the molding process. In order to attend to the problem (b) noted above, Patent Reference 2 describes the process of forming a lens array by injecting the lenses to the holes formed in the optical shielding part, followed by pressing. However, this process of Patent Reference 2 has a drawback in that it requires high precision for the dimension of the optical shielding part and high precision for the alignment of the optical shielding part. In order to attend to the foregoing problem of Patent Reference 2, Patent Reference 4 proposes a dimension control by way of the temperature control. However, this process of Patent Reference 4 suffers from the problem of high cost in view of the need of using expensive apparatus and long cycle time for the forming process. Further, Patent Reference 5 proposes the solution of the foregoing problems. More specifically, the process of Patent Reference 5 forms the lens part by urging a transparent sheet to the optical shielding part and causing plastic deformation in the - 12 - sheet material. While this process is effective for eliminating the misalignment between the lenses and the optical shielding part, there is a problem that - the lens shape cannot be controlled because of the absence of lens mold. Patent Reference 3, on the other hand, teaches the method of forming a microlens array by forming the optical shielding pattern after formation of the microlenses, by disposing an adhesive UV-cure resin layer behind the lenses and causing focusing of UV radiation to the UV-cure resin through the lenses. While this method is effective for eliminating the misalignment between the lenses and the optical shielding part, the size and/or shape of the optical shielding part is restricted by the form of the lenses. More particularly, this process has a drawback in that the optical shielding pattern inevitably takes a tapered shape because of the curing taking place with the focusing of the UV radiation. [Problem with Manufacture of Optical Fiber Array] - With, regard, to. the method of forming the— plastic optical fiber array, it takes a very long time when the optical fibers are laid one by one to - 13 - form the optical fiber array. Such an approach is hardly efficient. Thus, there is a proposal shown in Figure 19A to form a comb-shaped molding 1 having plural bar-shaped fingers lb extending parallel from a bridging part la and cause the bar-shaped fingers lb to make a contact substantially simultaneously with the a molten resin 2 by lowering the comb-shaped molding 1 toward the molten resin 2. Thereafter, the comb-shaped molding 1 is pulled up in the step of Figure 19B gently in the upward direction while irradiating a weak UV radiation, and with this, the molten resin 2 is pulled up with the bar-shaped fingers lb to form cores 4 extending parallel with each other in correspondence to the fingers lb of the comb shaped member 1. Further, in the step of Figure 19C, a resin member 3 is attached to the distal end parts of the cores 4 to hold the cores 4 in the respective positions, and ultraviolet radiation is applied for fully curing the cores 4 thus formed. Next, in the step of Figure 19D, the. cores 4 thus formed are dipped in a resin 6 held in a vessel in the state that the cores 4 are held between - 14 - the comb-shaped molding 1 and the resin member 3, and with this, a cladding layer is formed on each of the cores 4. . . .. Further, in the step of Figure 19E, the member including the cores 4 carrying thereon the cladding layer and held between the comb-shaped molding 1 and the resin member 3 is dipped in a thermosetting resin 8 held in a vessel 9. After curing the thermosetting resin 8, the comb-shaped molding 1 and the resin member 3 are disconnected in the step of Figure 19F. This is the technology disclosed in Patent Reference 6. With the technology of Patent Reference 6, on the other hand, there arises a problem, associated with its principle of forming the cores by pulling up the comb-shaped member 1, in that the cores 4 inevitably have a tapered shape. Thus, the optical fiber array formed with such a process suffers from the problem of low efficiency of light utilization. The present invention addresses the foregoing problem by forming the cladding layer at first by an extension process, followed, by injection- of core material into the hollow space inside the cladding layer to form a plastic optical fiber array. - 15 - With such a process of forming the cladding layer part at first, there is a need of providing the technology of forming a cell array structure in which columnar cells are formed side-by-side. Conventionally, there is a process of forming a honeycomb structure according to Japanese Patent Publication 56-34780 (Patent Reference 9) comprising the steps of holding a plastic material between heating platens having an escaping holes of the plastic material; pressing and heating the resin between the platens; and pulling apart the platens from each other to expand the plastic material. This conventional process, which uses a plastic material for the honeycomb structure, however, has a drawback in that the honeycomb structure has a thick cell wall. Further, similar problem arises also in the technology described in Patent Reference 7 or Patent Reference 8 because of the use of thermoplastic resin. Meanwhile, it is known to form a cell of very thin cell wall by expanding water containing surfactant as in the case of soap bubble. With this process, it is possible to form a cell having a wall thickness of several nanometers to several microns. On the other hand, soap bubbles use the effects of electrostatic repulsion, interaction between - 16 - hydrophobic groups, Marangoni effect, and the like, wherein such effects become insignificant with drying of the film and the soap bubble -is-collapsed in due course. Further, in the case of plastic, none of these effects are available. In the bubbling process for forming a honeycomb structure or cell array structure of elongated columnar shape, it is important to cause the bubbling at the same time. When the bubbled are formed one by one without relationship, the bubbles take a spherical form and the desired honeycomb structure is not formed. It should be noted that Patent Reference 7 and Patent Reference 8 attempts the bubbling by way of heating, while such formation of bubbles by heating cannot form the desired honeycomb structure unless the heating is achieved with uniform temperature. Further, the technology of Patent Reference 9 forms the honeycomb structure by the operation of separating the platens from each other as noted before, while it is very important with such a process to control the viscosity of the plastic to be uniform. Thus, formation of honeycomb structure with this process is also difficult. - 17 - In an aspect, the present invention provides a method of forming a cellular array structure in which plural columnar cells are disposed adjacent to each other, comprising: a first step of laminating a deformable layer on a substrate formed with plural depressions, said plural depressions being formed in said substrate in a manner isolated from each other, said deformable layer being laminated on said substrate such that said depressions define respective spaces isolated from each other; and a second step of causing said space to expand in said plural depressions by causing plastic deformation in said deformable layer, such that said plural columnar cells are formed in said deformable layer respectively in correspondence to said depressions. According to the present invention, it becomes possible to form a cellular array structure in which plural columnar cells defined by a cell wall of very small thickness are disposed adjacent with each other, by a simple and reliable process. In another -aspect, the present invention provides a method for manufacturing a miniature - 18 - composite component in which plural columnar members are disposed in a matrix, comprising: a first step of laminating a-deformable layer on a substrate formed with plural depressions, said plural depressions being formed in said substrate in a manner isolated from each other, said deformable layer being laminated on said substrate such that said depressions define respective spaces isolated from each other; a second step of causing said space to expand in said plural depressions by causing plastic deformation in said deformable layer, such that plural columnar cells are formed in said deformable layer respectively in correspondence to said depressions; and forming said plural columnar members respectively in said plural columnar cells, said deformable member forming said matrix. According to the present invention, it becomes possible to form a miniature composite component in which plural columnar members are disposed in a matrix in the form or array. Particularly, it becomes possible with the present invention to form the columnar members in the form of - 19 - microlens array defined with thin shells forming an optical shielding part. -- In another aspect, the present invention provides a microlens array, comprising: plural optically transparent parts each carrying a microlens at least on one end part thereof; and a boundary part provided to each of said optically transparent parts, said plural optically transparent parts being disposed adjacent to each other across said boundary part to form a microlens array. According to the present invention, it becomes possible to form a microlens array such that each microlens forming the array carries an opaque thin film having a thickness of several microns or less on the sidewall surface thereof. Because the thickness of the opaque thin film is small, the microlens array of the present invention provides a large aperture while suppressing the stray light at the same time. Other objects and further features of the present invention will be come apparent from the following detailed description when read in conjunction with the attached drawings. - 20 - BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is an oblique view diagram showing an example of a lens array of the present invention; Figures 2A - 2F are diagrams showing the manufacturing method of the lens array according to Embodiment 1 of the present invention; Figures 3A - 3G are diagrams showing the manufacturing method of the lens array according to Embodiment 2 of the present invention; Figures 4A and 4B are diagrams showing a lens array of the present invention in a cross- sectional view; Figure 5 is an oblique view diagram showing the lens array of the present invention; Figure 6 is a diagram explaining the effect of the present invention; Figure 7 is a side view diagram showing the manufacturing method of an optical fiber array according to Example 3 of the present invention; Figure 8 is an enlarged side view diagram showing a process of forming a columnar cell array structure according to Example 3 of Figure 7; - 21 - Figure 9 is an oblique diagram showing the honeycomb structure formed according to Example 3 of Figure 7 in an enlarged scale; Figure 10 is a side view diagram showing the manufacturing process of an optical fiber array according to Embodiment 4 of the present invention; Figures 11A and 11B are diagrams explaining the problem that arises when a material of the deformable layer is applied to the substrate formed with semi-spherical depressions; Figure 12A is another side view diagram showing a substrate formed with spherical depressions; Figure 12B is another side view diagram showing a substrate formed with depressions of comb- tooth shape formed by photolithography; Figures 13A - 13D are diagrams showing the manufacturing process of optical fiber array according to a molding process; Figures 14A and 14B are diagrams explaining the process of filling a core material in a cell array structure by using a centrifugal separator in the embodiment of manufacturing an optical- fiber array; - 22 - Figure 15 is a diagram showing an optical fiber array manufactured according to the molding process of the present invention; Figures 16A - 16C are diagrams showing further modifications of the present invention; Figure 17 is a diagram showing the construction of an electronic reusable paper according to an embodiment of the present invention; Figures 18A - 18H are diagrams showing the manufacturing process of the electronic reusable paper of Figure 17; Figures 19A - 19F are diagrams explaining the manufacturing method of an optical fiber array according to a related art. BEST MODE FOR CARRYING OUT THE INVENTION [OVERVIEW OF THE INVENTION] In view of the prior art noted heretofore, the present invention has its main objective of: (1) providing a method of manufacturing a miniature cell array structure including therein an array of miniature columnar cells comprising the steps of: expanding plural, mutually isolated cells in a common direction with mutually identical expansion time and expansion amount such that the - 23 - miniature columnar cells are formed adjacent with each other across a thin shell wall; and fixing the expanded columnar cells promptly while maintaining respective shapes thereof. Further, the present invention has a first subsidiary objective of: (1.1) providing a simple and easy method of manufacturing a miniature lens array in which individual miniature lenses forming the array have high precision and formed in a manner that the individual lenses are isolated from each other by a thin optical shielding part. Further, the present invention has a second subsidiary objective of: (1.2) providing a simple and easy method of manufacturing an optical fiber array capable of forming an optical fiber array with high precision and with high efficiency of utilization of light. The main objective of the present invention is attained by the method of manufacturing a miniature cell array structure comprising: a first step of covering a first substrate formed with plural, mutually.independent depressions-at respective locations with a first material having a function of plastic deformation such that spaces are formed in - 24 - the respective depressions; and a second step of forming elongated columnar cells isolated by a thin cell wall by causing to expand the foregoing spaces simultaneously in a predetermined direction by a gas pressure in the foregoing spaces. According to the foregoing manufacturing method of the present invention, it becomes possible to cause the expansion of the first material with the gas pressure of the spaced by decreasing the pressure at the side of the substrate covered with the first material. Here, it should be noted that "mutually independent depressions" noted above means that individual depressions form a respective, mutually isolated spaces not communicating with the rear side of the first material or communicating with other depressions. The first subsidiary objective of the present invention is attained by the method of manufacturing a miniature composite component, comprising: a first step of covering a first substrate formed with plural, mutually independent depressions at respective locations with, a first ... _ material having a function of plastic deformation such that spaces are formed in the respective - 25 - depressions; a second step of expanding the first material at plural locations simultaneously by the gas pressure of the spaces to form elongated cells having thin cell walls such that the cells are elongated in a predetermined, common direction; and third step of forming the cellular shape and the depressions by injecting a second material without departing the first material from the first substrate. The foregoing depressions may have the shape of a lens. In this case, the present invention provides a method of manufacturing a lens array as the miniature composite component, by forming the lenses by using the miniature cell array structure of the first material as the optical shielding part and injecting the material of lens into the miniature cell array structure without separating the lens mold and the miniature cell array structure (optical shielding part) from each other. The second subsidiary objective of the present invention is attained by the method of manufacturing an optical fiber plate in which the cell array structure is injected with a core member having a refractive index larger than the refractive.. index of the cell array structure. With this process, the cell array structure is removed subsequently, and - 26 - the gap formed with such removal of the cell array is filled with a cladding material. In order .to solve the second- subsidiary objective and to obtain a miniature cell array structure including therein elongated columnar cells defined with thin cell walls, the present invention discloses a method of arraying a number of bubbles or cells in an aqueous solution added with a surfactant and solidifying the bubbles after causing simultaneous dilatation in such a manner that the shape of the bubbles is maintained during the solidification process. Particularly, the present invention provides the independent depressed spaces (depressions) on the top surface of the substrate and uses the means of controlling the pressure of the ambient in which the substrate is placed. Further, in order to dry the cellular array structure without causing disintegration in the shape thereof, the present invention discloses a method of using a gelatin solution that causes a sol-gel transition with temperature change for the deformable material. With this,, the gelatin solution .Is...changed to gel for increasing the rigidity thereof before conducting the drying process. Here, it should be - 27 - noted that the "deformable material" noted above means the material that forms the cellular array structure therein when it is processed according, to the present invention. According to the present invention, the method of manufacturing the cellular array structure comprises the steps of: covering a top surface of a substrate (A) formed with minute depressions with high density with a deformable material (B) having the function of ductile deformation under a predetermined condition by applying the deformable material (B) on the top surface of the substrate (A); causing expansion in the deformable material (B) ..by the gas pressure in the closed spaces formed between the depressions and the deformable material (B) such that the plural spaces are elongated simultaneously and such that there are formed a number of elongated cells extending in a predetermined direction in the state separated from each other by thin walls having a micrometer thickness, wherein the depressions on the substrate (A) are formed in a manner isolated from each other. With regard to the manufacturing method, of, the cellular array structure, it becomes possible to extend the deformable material (B) by lowering the - 28 - pressure at the side of the substrate (A) covered by the deformable material (B). With-the foregoing method of manufacturing . the cellular array structure, it is possible to use a gelatin aqueous solution added with a surfactant for the deformable material (B). Further, the method of manufacturing the cellular array structure may be conducted by providing a ventilation space behind the deformable material (B) such that the deformable material (B) is dried from this side. With regard to the method of manufacturing the cellular array structure, it is preferable to form the ventilation space behind the deformable material (B) provided on the substrate (A) and causes a member to make contact with the deformable cell array structure (B) from the behind such that the member is formed with penetrating holes with a pitch smaller than the pitch of the columnar cells formed in the deformable material (B). Thereby, drying of the deformable material (B) is conducted via such through-holes. Further, it is preferable, to process the _ .. depressions such that the depressions have a water- repellant surface. Further, it is preferable to form - 29 - the depressions such that the depressions have a large diameter in the interior of the substrate (A) as compared with at the top surface. Next, the means of solution of the second subsidiary objective will be explained. 1) The means for expanding the cellular array structure For the means of expanding the cellular array structure such that plural columnar cells are formed side by side therein, there is provided a substrate structure in which plural depressions are formed on the surface of a substrate, in combination with the means for applying the deformable material such that there are formed spaces between the respective depressions and the deformable material formed on the substrate. 2) The means for forming thin cell walls (1) In order to form the columnar cells with thin cell walls, the present invention uses an aqueous solution containing a surfactant and dissolved with a gelatin that causes a sol-gel transition upon temperature change for the means for forming the thin cell walls. (2) Further, the present invention uses the means for causing dry shrinking. Here, it - 30 - should be noted that this means for causing dry- shrinking means a depressurizing process conducted by using a pressure control apparatus. Therein, evaporation of water content contained in the gelatin is accelerated, and with this, thinning of the cell wall caused by shrinkage of the volume of the material forming the cell wall, which in turn is caused by the water evaporation, is facilitated. 3) The means for solidifying the cell walls while maintaining the columnar cell array structure (1) For solidifying the cell walls while maintaining the columnar cell array structure, the present invention uses an aqueous solution added with a surfactant and dissolved with a gelatin that causes a sol-gel transition with temperature, for the material of the deformable material. (2) Further, the present invention controls the temperature to the state of sols during the phase of expansion and control the temperature to the state of gels after the expansion has been completed. (3) Further, the present invention secures a space for facilitating drying of the deformable material while not restricting the expansion thereof. With this, there is facilitated - 31 - evaporation of water as a result of decompression, and the cell array structure formed as a result of the expansion o.f the deformable material is solidified as a result of the drying. 4) Other means Further, the present invention attains the simultaneous expansion of the cells and high speed drying of the deformable material at the same time by depressurizing by way of depressurizing means. [The method of manufacturing optical fiber array] Further, the present invention provides a method of manufacturing an optical fiber array based on the foregoing method of manufacturing miniature cellular array structure. Thus, the present invention forms an optical fiber array in which a large number of optical fibers are disposed in the form of high- density array, by injecting core material of a refractive index higher than the refractive index of the deformable material (B), into the cells in the miniature cell array structure formed of the deformable material (B) now forming the cell walls. Further, the present invention provides a "method of manufacturing an optical fiber array", comprising the steps of: injecting a core material into the cells of a miniature cell array structure - 32 - formed by the "method of manufacturing a miniature cellular array structure"; removing the deformable material (B) ; and forming a. large number ..of optical fibers in the form of an array in the spaces formed as a result of the step of removing the deformable material (B) by filling the spaces thus formed simultaneously with a cladding material. (1) First aspect of the invention According to a first aspect, the present invention provides a method of manufacturing a miniature cell array structure, comprising: a first step of covering a surface of a first substrate formed with a large number of mutually independent depressions (depressions not communicating to the outside or other depressions) at respective, predetermined locations, with a first material that has a function of ductile deformation under a predetermined condition, such that there are formed spaces in the foregoing depressions on the first substrate; and a second step of expanding and extending the first material by the gas pressure in the foregoing plural spaces simultaneously to form a miniature array of cells in the ..first material such . that the plural cells extend parallel in a predetermined direction. - 33 - According to the first aspect, it becomes possible to form a number of mutually isolated cells in the manner that.the cells are isolated by cell walls formed of the first material with high density and high precision at the same time. (2) Second aspect of the invention According to a second aspect of the present invention, the first material is subjected to the expansion and extension by the gas pressure inside the spaces, while the gas pressure is caused by depressurizing the side of the first substrate covered with the first material. According to the present invention, it becomes possible to form a large number of mutually independent cells separated with each other by the cell walls of the first material and formed with very high density, by a simple and quick process. (3) Third aspect of the invention According to a third aspect, the present invention provides a method of manufacturing a miniature composite component, comprising: a first step of covering a surface of a first substrate formed with a large number of mutually independent depressions at respective, predetermined locations, with a first material that has a function of ductile - 34 - deformation under a predetermined condition, such that there are formed spaces in the foregoing depressions on the first substrate-; a second step of expanding and extending the first material by the gas pressure in the foregoing plural spaces simultaneously to form a miniature array of cells in the first material such that the plural cells extend parallel in a predetermined direction; and a third step of injecting a second material to the plural cells without separating the first material and the first substrate from each other to form the cells such that the cells have respective end parts corresponding to the depressions on the first substrate According to the third aspect of the present invention, the spaces are formed in the depressions in the first step and the first material is expanded and extended in the second step, and thus, it becomes possible to form the plural cells simultaneously. Further, by injecting the second material to the cells in a third step, it becomes possible to form the plural cells simultaneously, such that each cell includes an end part corresponding to the depression on the first substrate. - 35 - Particularly, it becomes possible to manufacture the cells without misalignment between the part formed in the first and second steps., and the part formed in the third step, by conducting the third step continuously to the first and second steps, without separating the first material and the first substrate from each other. (4) Fourth aspect of the invention According to a fourth aspect, the present invention provides a method of manufacturing a miniature composite component, comprising: a first step of covering a surface of a first substrate formed with a large number of mutually independent depressions (depressions not communicating to the outside or other depressions) at respective, predetermined locations, with a first material that has a function of ductile deformation under a predetermined condition, such that there are formed spaces in the foregoing depressions on the first substrate; a second step of expanding and extending the first material by the gas pressure in the foregoing plural spaces simultaneously to form a miniature array.of cells in the first material such that the plural cells extend parallel in a predetermined direction; a third step of adhering a - 36 - third material to a cell wall of the plural cells without separating the first material and the first substrate form each other; and a fourth step of injecting a second material to the plural cells without separating the first material and the first substrate from each other to form the cells such that the cells have respective end parts corresponding to the depressions on the first substrate. According to the present invention, it becomes possible to form the miniature composite component with high precision similarly to the third aspect of the present invention in view of the fact that the third and fourth steps are conducted without separating the first material and the first substrate from each other. (5) Fifth aspect of the invention According to a fifth aspect, the present invention carries out the expansion and the extension of the first material in the state that the first material is sandwiched between the first substrate and a second substrate. According to the fifth aspect, it becomes possible to achieve high precision in the shape of the cells with the use of the second substrate. By- using a flat slab for the second substrate, it - 37 - becomes possible to form the cells to have a uniform length. (6) Sixth aspect of the invention According to a sixth aspect, it becomes possible to generate the gas pressure in the spaces corresponding to the depressions in the first step by causing depressurizing. With the use of depressurizing, the gas pressure becomes uniform in all the spaces corresponding to the foregoing plural depressions at any time, and it becomes possible to form the cells to have a uniform volume and shape. (7) Seventh aspect of the invention According to a seventh aspect, the second material is applied to the opening parts of the cells in a depressurized state, and the second material thus applied is injected into the cells by increasing the pressure beyond the atmospheric pressure. According to the present invention, there is formed a uniform static pressure because of the use of the difference of gas pressure, the injection of the second material is conducted uniformly, without variation. Further, the first and second steps can be conducted in continuation in the same apparatus at the time of manufacturing, and it - 38 - becomes possible to lower the cost of manufacturing the miniature composite component. (8) Eighth aspect of the invention According to an eighth aspect, it becomes possible to inject the second material into the cells by applying the second material at the opening parts of the cells in a depressurized state and subsequently applying a centrifugal force. By using the centrifugal force, the substances of different specific gravity are separated easily, and thus, it becomes possible to easily evacuate the gas in the cells and inject the second material in the liquid state into the cells. (9) Ninth aspect of the invention According to a ninth aspect, the present invention can manufacture a miniature lens array (microlens array) for the miniature composite component. (10) Tenth aspect of the invention According to a tenth aspect, the present invention uses a slab of hydrophobic nature for the second substrate. With this, the first material is easily.separated from the second substrate in the second step, and thus, it becomes possible to form the penetrating cells easily. - 39 - (11) Eleventh aspect of the invention According to an eleventh aspect, the depressions formed on .the first substrate have the shape of a lens. Thus, according to the present invention, it becomes possible to transfer the lens shape to the cells in the third step of the third aspect or in the fourth step of the fourth aspect with the dilatation of the gas caused in the first step. Thus, transfer of the lens shape is achieved at the same time to the formation of the cells, and it becomes possible with the eleventh aspect to form a lens array for the miniature composite component. (12) Twelfth aspect of the invention According to a twelfth aspect, the present invention provides a miniature lens array in which the lenses forming the lens array are separated from each other by the first material having the function of optical shielding, by using a transparent material for the second material and an opaque or optical shielding material for the first material. With this, flare or stray light is eliminated in the lens array. (13) Thirteen aspect of the invention According to a thirteen aspect, the miniature lens array (microlens array) of the present invention is formed of the first material at least - 40 - having the function of isolation, the second material having the function of optical transmission, and the third material having the function of optical shielding. With this, it becomes possible to obtain a miniature lens array (microlens array) free from stray light or flare. Because the miniature lens array of the thirteen aspect attains the foregoing three functions by three different materials, it becomes possible to enhance the respective functions as compared with the invention of the twelfth aspect. Further, there is attained increased degree of freedom at the time of manufacture of the miniature lens array. (14) Fourteenth aspect of the invention According to a fourteenth aspect, the present invention provides a method of manufacturing a miniature cell array structure, comprising the steps of: covering a top surface of a substrate (A) formed with minute depressions with high density with a deformable material (B) having a function of ductile deformation under a predetermined condition; extending the deformable material (B) by a gas pressure in plural spaces formed by the plural depressions and the deformable material, such that the plural spaces are expanded and elongated in a - 41 - predetermined direction to form plural cells separated from each other by thin cell walls of a micron thickness, wherein the depressions are formed independently on the substrate (A). According to the present invention, the depressions on the substrate (A) are formed independently to each other, and thus, the expansion time and the expansion amount become identical between the plural depressions when depressurization is applied. Thereby, the elongated, columnar cells are formed uniformly in a manner separated form each other by the cell walls formed of the deformable material. (15) Fifteenth aspect of the invention According to a fifteen aspect, the present invention depressurizes the side of the substrate (A) covered with the deformable material (B), and thus, the expansion time and expansion amount become identical between the adjacent depressions. Thereby, it becomes possible to grow a cell array formed of plural, mutually independent columnar cells uniformly. (16) Sixteenth aspect of the invention According to a sixteenth aspect, the present invention uses a gelatin aqueous solution added with a surfactant for the deformable material - 42 - (B). Thus, the cells are grown like soap bubbles having a very thin cell wall, wherein the cells thus grown undergo transition to. a.gel thereafter. Thereby the cells are dried while maintaining the shape thereof. Further, because the temperature of sol-gel transition is about 40°C, it becomes possible to increase the amount of expansion at low temperatures while suppressing the boiling of water, and it becomes possible to use a high degree of depressurization for the growth of the cell array structure. (17) Seventeenth aspect of the invention According to a seventeenth aspect, the present invention provided a ventilation space at the side of the substrate (A) covered with the deformable material (B). With this, it is possible to dry the deformable material (B) form this side. (18) Eighteenth aspect of the invention According to an eighteenth aspect, the present invention causes a structural body formed with penetrating holes with a pitch smaller than the pitch of the cells in the cell array structure to make a contact with the deformable material (B) covering the top surface of the substrate (A) where the depressions are formed. With this, it becomes - 43 - possible to control the relationship between the spaces formed in the structural body in the penetrating holes and the substrate (A), and the thickness of the deformable material (B) applied to the substrate (A) becomes uniform. Further, because the penetrating holes are formed with the pitch smaller than the pith of the cells in the deformable material (B), the cells can grow without losing their shapes. Further, by ventilating the space behind the deformable material (B) through the penetrating holes, the cells are solidified promptly. (6) Nineteenth aspect of the invention According to a nineteenth aspect, the present invention applies a process to make the depressions hydrophobic. With this, the deformable material (B) does not enter to the depressions at the time of application of the deformable material (B) upon the surface of the substrate (A). (20) Twentieth aspect of the invention According to a twelfth aspect of the present invention, the depressions are formed in the substrate (A) such that a diameter thereof is larger than a diameter of an opening part formed on the surface of the substrate (A) by the depressions. - 44 - According to the twentieth aspect, it becomes possible to apply the deformable material (B) on the surface of the substrate (A) without causing the deformable material (B) to invade substantially into the depressions on the substrate (A). Further, because of the reduced contact area of the opening parts, degassing from the depressions after the application of the deformable material (B) is reduced, and it becomes possible to cause maximum expansion for the cells at the time of the depressurizing. (21) Twenty first aspect of the invention According to a twenty first aspect, the present invention injects a core material having a refractive index larger than the refractive index of the deformable material (B) into the cells formed in the deformable material (B). Thus, it becomes possible to manufacture an optical fiber array with high dimensional precision and high efficiency of utilization of light, with low cost and high production efficiency. (22) Twenty second aspect of the invention According to a twenty second aspect, the present invention removes the deformable material (B, after injecting the core material into the cells formed in the deformable material (B), and fills the - 45 - gaps formed with the removal of the deformable material (B) , with a cladding material. As a result, it becomes possible to manufacture an optical fiber array having resistance to water while using various materials for the cores. Working Examples of the Invention Next, description will be made with regard to (1) "manufacturing of lens array", and (2) "manufacturing of an optical fiber plate (optical fiber array)". 1. Manufacturing of Lens Array [Example 1] First, processing method pertinent to the third aspect of the invention will be explained with reference to Figure 1 and Figures 2A - 2F. Lens Mold (First Substrate) Referring to Figures 2A, it should be noted that a lens mold 80 (first substrate) is a mold that determines the pitch of the lens elements of a lens array to be formed. Further, the lens mold 80 determines the basic structure of the cell array formed by expanding a deformable opaque material 82 provided thereon so as to form voids therein in the form of columnar cells and used for holding the lens - 46 - elements of the lens array. Further, the lens mold 80 is used for the mold of the lens elements in the process conducted after formation of the cell array. In Example 1, the lens mold 8 0 is formed of a silicone rubber having a water-repellent surface, and lens parts 80a are formed in the lens mold 80 in a lattice pattern with a pitch of 200pm. Each lens part 80a has a semispherical surface of the radius of 180um, wherein one hundred and sixty nine such lens parts 80a are formed on the lens mold 80 in thirteen rows and thirteen columns. Opaque Material (First Material) The opaque material 82 is a deformable material forming the cellular array structure including the elongated, columnar cells defined by cell walls. The opaque material 82 thereby functions to suppress flares or stray light when optical elements are formed in the cells. In the Example 1, an UV-cure acrylic resin of the refractive index of 1.56 is used for the opaque material 82. Thereby, in order to function as an opaque optical shield, the opaque material 82 is added with carbon black particles with the amount of 0.5wt%. Because the opaque material 82 has the same refractive index to - 47 - the lenses to be formed in the cells, there is caused no total reflection of light, and optical absorption is attained efficiently. Lens Material (Second Material) With Example 1, an UV-cure acrylic resin of the refractive index of 1.56 is used for lenses 83 that are formed in the opaque material 82 in correspondence to the columnar cells therein. Pressure Control Apparatus A pressure control apparatus 100 compresses and/or evacuating gases and is used for controlling the dimension, primarily the height, of the cell array structure forming the cellular walls in the opaque material 82. [Function] The process of Example 1 proceeds as shown in Figures 2B - 2F. (1) In the step of Figure 2B, the opaque material 82 is spin-coated on a flat glass substrate 81 transparent to ultraviolet lights and having a high degree of flatness, with a film thickness 0.1 - lOOum in the state that the glass substrate 81 is - 48 - placed upon the lens mold 80. In Example 1, the opaque material is spin-coated with the thickness of 20um (First Step).. . The pressure control apparatus 100 is the apparatus capable of controlling the ambient pressure therein to a predetermined pressure. In Example 1, the ambient pressure is controlled usually to O.lMPa. It should be noted that this pressure is chosen for controlling the gas dilatation caused in the subsequent steps. (2) The structure of Figure 2B obtained in the first step is incorporated into the pressure control apparatus 100 and the ambient pressure therein is reduced to 0.003MPa. With this process of depressurization, there starts expansion or dilatation of gas in the spaces corresponding to the lens parts 80a, and thus, there is caused expansion of the spaces in the lens parts 80a with the expansion of the gas therein by causing deformation in the opaque material 82. Here, it should be noted that the expansion takes.place in all of the lens parts 80a on the lens mold 80 simultaneously, and thus, lateral expansion of the spaces is restricted because of the - 49 - interference of the adjacent spaces. Thus, the expansion takes place solely in the direction upward, leading to formation of a cell.._a.rr.ay structure in which plural columnar cells are formed adjacent with each other in the deformed opaque material 82 in correspondence to the lens parts 80a in such a manner that the plural cells extend parallel with each other in the upward direction from the substrate 80. Thereby, the opaque material 82 forms opaque cell walls 84 defining the columnar cells formed therein. In the state of Figure 2C, ultraviolet radiation is applied for about ten seconds for curing the opaque material 82 thus deformed, and with this, the opaque cell walls 84 thus formed are solidified and the cellular array structure is fixed (Second Step). Next, in the step of Figure 2D, the substrate 80 thus carrying thereon the cellular array structure is taken away from the pressure control apparatus 100. Further, after removing the glass substrate 81, the cells forming the cell array in the opaque material 82 are injected with a resin forming the lens, wherein this injection of the resin is conducted in a centrifugal separator under a centrifugal force of 3000G for 30 seconds (Third Step). - 50 - Here, it is important to note that the lens mold 80 and the cell walls 84 are not separated from each other during this, process. Next, in the step of Figure 2E, a reflector plate 85 transparent to the ultraviolet radiations is placed is placed upon the structure of Figure 2D and ultraviolet radiation is applied for about 10 seconds for curing the lens material 83. With this, lens elements 86 are formed in the cells of the cellular array structure in the form of lens array (Fourth Step). Finally, the lens mold 80 and the reflector plate.85 are removed, and the lens array is obtained such that microlens elements 86 are held in the elongated, columnar cells defined with the opaque cell walls 84. While not illustrated, it is preferable to anneal the structure thus obtained such that the curing proceeds thoroughly in the lens elements 86 and also in the cell walls 84 and such that there remains no uncured site, especially in the opaque cell walls 84. [Example 2] - 51 - Example 2 is an embodiment corresponding to the second aspect of the invention and forms the opaque part in two. steps as. will be explained with reference to Figures 3A - 3G. Therein, it will be noted that the process of Example 2 is different from the process of Example 1 in the following aspects: (a) a cell wall 94 corresponding to the opaque cell wall 8 4 of Example 1 includes an opaque film 94a covering a cell wall 94b; and (b) an acrylic UV-cure resin is used for the material of the cell wall 94b (first material), while the opaque film (third material) 94a is formed by applying carbon black particles to the cell wall 94b. Otherwise, Example 2 is identical to Example 1. [Function] The process of Example 3 is shown in Figures 3A - 3G, wherein there is no difference to the process of Example 1 except that an opaque liquid in which carbon black particles are dispersed in a volatile solvent is injected into the cells in the step of Figure 3D after formation of the cell walls 94b. In Figures 3A - 3G, it should be noted that - 52 - those parts corresponding to the parts described previously with reference to Example 1 are designated by the same reference numerals and the description thereof will be omitted. Thereby, because the lens mold 80 has water-repellency, the opaque liquid adheres selectively to the cell walls 94b, and the carbon black particles thus adhered to the cell wall 94 form the foregoing opaque film 94a (Third Step). Because the material 92 corresponding to the material 82 of Example 1 is free from the opaque material with Example 2, the UV curing process of Figure 3C proceeds efficiently, and curing of the cell walls 94b is attained in short time. Further, because it becomes possible to use the opaque material in large amount, the effect of eliminating stray light or flares is enhanced with Example 2, and it becomes possible to suppress the leakage of light in the lens array effectively. [Example 3] Example 3 shown in Figures 4A and 4B provides an optical fiber array (optical fiber plate) formed by using the process of Example 1 and Example 2. - 53 - Thus, with the construction of Figure 4A, a cladding layer 101 forms a cell array structure holding cores 102 in the cells of the cell array structure, wherein Example 3 forms the cladding layer 101 by using a UV-cure methacrylate resin of the refractive index of 1.45 for the first material forming the cell walls while using a UV-cure acrylic resin of the refractive index of 1.56 for the second material used for the core 102. Thereby, it is possible to provide lens effect to the optical fiber elements by forming the optical fiber elements to have a semi-spherical as shown in Figure 4A. Alternatively, it is possible to form the optical fiber elements to have an end part of conical shape for diffusing the light as shown in Figure 4B. [Example 4] In contrast to the microlens array of Figure 1 in which the lens elements are arranged in the form of a lattice, Example 4 shown in Figure 5 provides a lens array in which the lens elements are arranged in a staggered array. Thus, it is possible with the present invention to manufacture a miniature lens array of - 54 - staggered arrangement for the lens element shown in Figure 5 while using a similar process explained heretofore. In this case, it should be noted that the opaque cell walls forming the cladding layer 101 form therein cells of hexagonal pillar shape as shown in Figure 5, and the cores 102 filling the cells have the corresponding shape of hexagonal pillar. Next, the eighth aspect of the present invention that uses the second substrate of hydrophobic nature will be explained with reference to Figure 6. (Case 1) Second substrate is not water-repellent In the case the second substrate 81 lacks water-repellency, the cells are formed in the cell array structure of a second material 112 corresponding to the deformable material 82 of Figures 2A - 2F as shown in Figure 6, wherein it will be noted that each cell has a closed end at the side facing the second substrate 81. This is because the film of the material 112 remained in contact with the second substrate 81 at the end part of the cells because of the high wetness between the second material 112 and the second substrate 81. (Case 2) Second substrate is water-repellent - 55 - In the case the second substrate 81 is repellent to water, there appears a cellular array structure similar to the case of Examples 1 and 2 shown in Figures 2A - 2F or 3A - 3G in which each cell has opened ends. Such a structure is caused because the film of the second material 112 has moved elsewhere because of the poor wetting between the second material 112 and the second substrate 81. From Cases 1 and 2 noted above, it will be understood that control of the cell array structure is possible by the water-repellent nature of the first substrate 80. 2. Examples of manufacturing optical fiber plate [Example 5] - Method of forming a cell array structure of columnar elongated cells Figures 7-9 show the process of manufacturing an optical fiber plate (optical fiber array) according to Example 5. Referring to the drawings, there is provided a temperature control apparatus 22 on a coater machine 21, and a substrate (A) carrying a large number of depressions on a top surface thereof with high density is mounted upon the temperature control apparatus 22. - 56 - With this embodiment, a cell array structure including therein fine columnar cells with high density is formed on such a substrate (A). The construction and operation of Example 5 will be explained hereinafter. 1. Construction of Example 5 (1) Substrate (A) The substrate (A) of Figure 7 serves for the mold for growing a cell array structure thereon and determines the pitch of the cells in the cell array structure thus formed. More specifically, the substrate (A) is formed of a silicon rubber and is formed with depressions 23 having a semispherical shape of the diameter of 25um in a staggered pattern with a pitch of 38um. (2) Cellular structure material (B) The cell array structure material (B) of Figure 7 forms the body of the cell array structure formed with a number of columnar, elongated cells. For the cell array structure material (B) , it is possible to use an aqueous solution of commercially available gelatin (trade name Jellice) diluted by five times in purified water and added with a surfactant (dodecyl sodium sulfate) by lwt%. In this - 57 - case, the sol-gel transition takes place for the material of the cell array structure at about 38°C. (3) Temperature control apparatus The temperature control apparatus 22 control the viscosity (sol-gel transition) by controlling the temperature of the cellular structural material (B). (4) Pressure control apparatus A pressure control apparatus 24 of Figure 7 is an apparatus that compresses and evacuates gases and controls the dimension, particularly the height of the cell array structure. Further, the pressure control apparatus facilitates drying of the cellular structural material (B). (5) Ejector An ejector 25 of Figure 7 is a device for ejecting the cellular structural material (B) on the substrate (A) with a predetermined amount. (6) Coater machine The coater machine 21 of Figure 7 is an apparatus that spreads the cellular structural - 58 - material (B) ejected on the top surface of the substrate (A) from the ejector 25 to form a film of a predetermined thickness. In the illustrated example, the coater machine 21 is a spin-coater that utilizes a centrifugal force. Operation of Example 1 (1) First, the ambient pressure of the coater machine 21 is controlled to a predetermined pressure such as 0.IMPa by using the pressure control apparatus 24. This process is conducted for controlling the amount of gas dilation in the later process. (2) The temperature of the substrate (A) is controlled by using the temperature control apparatus 22. Thereby, heating may be conducted by any of heater, infrared light, microwave, and the like. In the case of Example 1, an electric cartridge heater is used for the temperature control apparatus 22. The temperature may be set close to the sol-gel transition temperature such as 38°C. This temperature is chosen for controlling the viscosity, and hence sol-gel transition of the cellular structural material (B). - 59 - (B) Eject the cellular structural material (B) on the substrate (A) by using the ejector 25. Almost simultaneously, the cellular structural material (B) thus ejected is spread over the substrate (A) by squeezing or spin-coating, such that there are formed vacant spaces in the depressions 23. In this step of coating, the cellular structural material (B) may form a film having a film thickness of 1 - lOOum. In the example of Embodiment 5, the cellular structural material (B) forms a film of the thickness of lOum. Ejection of the cellular structural material (B) from the ejector 25 is attained at the temperature of 45°C, and hence in the state of sol of low viscosity. (4) Lower the ambient pressure of the coater machine 21, after lowering the temperature of the substrate (A) such that there is caused gel transition in the cellular structural material (B). With Example 5, the control temperature of the temperature control apparatus 22 is reduced to 20°C and the ambient pressure is lowered thereafter to 0.03MPa by using the pressure control apparatus 24. With this, the gas in the spaces of the depressions starts dilatation and the spaces cause extension as represented in Figure 8. - 60 - Thereby, because of the simultaneous dilatations in the adjacent depressions 23, lateral expansion of the spaces is restricted and the dilatation of the spaces takes place only in the direction upward from the substrate (A). Thus, there are formed a number of cells 31 simultaneously in the cellular structural material (B) in the form of mutually independent elongated bubbles, while the bubbles or cells 31 thus formed form a columnar cell array structure 30. Thereafter, the temperature of the substrate (A) is lowered by the temperature control apparatus 22, and the cellular structural material (B) thus formed with a cell array structure is solidified and dried while maintaining the shape thereof. Thereby, the time for the solidification is reduced greatly by evacuating the ambient by using the pressure control apparatus 24. (5) Next, the processing chamber of the pressure control apparatus 24 is opened and the work corresponding to the cell array structure thus formed is taken out to the outside. Figure 8 shows the cell array structure thus formed in an enlarged scale in the state that the cell array structure is taken out from the - 61 - pressure control apparatus 24 after 10 minutes elapsed from the dilatation process and in the state that the substrate (A) is removed. It was confirmed that the cell array structure thus obtained is sufficiently dried and has a mechanical strength maintaining its shape. In the illustrated example, each cell 31 in the cell array structure 30 has a diameter of '35um and a length of 120um, with the wall thickness of 3um. [Example 6] - Embodiment corresponding to eighteen aspect of the invention Next, the embodiment corresponding to the eighteenth aspect of the invention will be explained. The eighteen aspect of the invention corresponds to the construction shown in Figure 10 in which a flat slab structure 26 formed with a number of penetrating holes is contacted to the deformable material (B) on the substrate (A). Thereby, the penetrating holes are formed with a pitch smaller than the pitch of the cells in the cell array structure. It should be noted that such minute penetrating holes can be formed easily with a diameter of 0.lum or less by causing anode oxidation - 62 - in an aluminum plate of the thickness of 200um. Because the penetrating holes are formed with a pitch smaller than the pitch of the cells in the cell array structure, it becomes possible to cause dilatation in the deformable material (B) without damaging the shape of the individual cells 31 by contacting the slab structure 26 to the backside of the deformable material (B). [Example 7] - Embodiment corresponding to twentieth aspect of the invention Figure 11A schematically shows the problem that may arise when a deformable material (B) is applied to a surface of the substrate (A) formed with semispherical depressions 23. More specifically, Figure 11A shows the situation in which the gas in the depression 23 is dissolved into the deformable material (B) or escapes to the outside by passing through the deformable member (B) as shown at the left part of the drawing. Associated with such degassing, it can be seen in Figure 11A that the deformable material (B) invades into the depressions in some of the depressions 23. Figure 11B illustrates the Young-Laplace equation. - 63 - According to the Young-Laplace equation, a pressure difference AP between a gas pressure Pi and a liquid pressure PL is represented for a bubble of elliptical shape formed in a liquid as AP=Pi-PL = a( 1 /Ri+1 /R2) , wherein Rl and R2 respectively represent the radius of the bubble measured along a minor axis thereof and the radius of the bubble measured along a major axis thereof. Thus, the foregoing equation represents that the pressure difference AP is increased when the radius Ri and the radius R2 are decreased. Here, a represents the surface tension of the liquid. Thus, when the diameter of the depression 23 has become 30um or less, the pressure of the bubble is increased according to the Young-Laplace equation, resulting in absorption of the gas by the liquid. Alternatively, the gas escapes from the depression 23 to the outside by passing through the deformable material (B). In any of these cases, there arises the problem that the deformable material invades into the depression 23 as shown in Figure 11A. Thus, Example 7 reduces this problem by decreasing the area of the depression 23 opened at the surface of the substrate (A) as represented in - 64 - Figure 12A, in which it will be noted that there are formed a number of spherical voids in the substrate (A) such that each spherical void is exposed at the surface of the substrate (A) at an opening having a diameter much smaller than the diameter of the void itself. It should be noted that the structure of Figure 12A is obtained easily by the steps of: arraying polystyrene microspheres on the surface of the substrate (A); covering the microspheres by an UV-cure resin layer; and removing the polystyrene microspheres by an organic solvent such as acetone. Figure 12B shows another example of the substrate (A) in which there are formed a number of deep depressions 23b in the substrate (A). The structure of Figure 12B can be formed by photolithography. [Example 8] - Embodiment corresponding to twentieth aspect Figures 13A - 13D, 14A and 14B show the process of manufacturing an optical fiber array according to the twentieth aspect of the invention. With the twentieth aspect, there is formed a cell array structure 30 in which the cells have a - 65 - closed end at the side of the substrate (A) while the other, opposite end is opened. (1) The cell array structure 30 obtained with the process of Example 5 is turned over upside down as shown in Figure 13A, and a transparent core material 41 is injected to the cells therein in this state. In the illustrated example, an uncured UV-cure resin is used for the core material 41. More specifically, the illustrated example uses an acrylic UV-cure resin of the refractive index of 1.56 for the core material 41. In order to ensure positive injection of the more material 41 into the miniature cells 31 without voids, the present embodiment uses a centrifugal separator 50 shown in Figures 14A, and the core material 41 is injected in the step of Figure 14B with a pressure of 3000G for the duration of 30 seconds by operating the centrifugal separator 50. Thus, in the step of Figure 14A, the cell array structure 30 is mounted upon a rotary drum 51 of the centrifugal separator 50 and the core material 41 is poured upon the cell array structure 30. Next, in the step of Figure 14B, the drum 51 is rotated at high speed and the core material 41 - 66 - is pressed into the cells 3 by the centrifugal force acting upon the core material 41. Thereby, any air bubble 52 in the cell 41 is separated and the cells 31 are fully loaded with the core material 41. (2) Next, in the step of Figure 13B, the UV-cure resin forming the core material 41 is cured by irradiating UV light. (3) Next, the cell array 30 of gelatin is replaced with other, preferably opaque material capable of performing optical shielding function, in view of the fact that gelatin forming the cell array 30 has poor resistance to water and relatively high refractive index. Thus, the optical fiber array of Figure 13B is dipped into water for removal of the cell walls formed of gelatin in the step of Figure 13C, and with this, there are formed gaps 42 between the cores 41 in correspondence to the gelatin cell walls. (4) Further, in the step of Figure 13C, a cladding material 43 is injected into the gaps 42 thus formed by using the centrifugal separator 50 of Figures 14A and 14B similarly to the case of the cores 41. In the illustrated example, a PMMA solution in which polymethacrylate (PMMA) having a refractive index of 1.49 dissolved into a volatile solvent and - 67 - added with carbon black with the amount of 0.5wt% is used. After the injection of the cladding material 43, the cladding structure 44 is formed after drying as shown in Figure 13D. (5) With the foregoing process, it is possible to manufacture a miniature optical fiber plate or optical fiber array 40 shown in Figure 13D or 15 with simple process and short time period, such that optical fibers 45 having a diameter of 35um and carrying a cladding layer of 3um thickness are arranged in the form of array of the height of 120um. It should be noted that the efficiency of utilization of light of such an optical fiber plate 40 reaches as large as 22% in the case the distance to the optical source is set to 15um or less. [Example 9] While the substrate or "mold" used in the preceding embodiments have a flat top surface formed with the depressions, the present invention is not limited to such a flat substrate and it is also possible to use a cylindrical substrate 201 as shown in Figure 16A. In each of Figures 16A - 16C, it should be noted that the right drawing shows the - 68 - cylindrical substrate 201 and the components formed thereon in an oblique view while the left drawing shows the cross-section taken along a plane L. As represented in Figure 16A, the cylindrical substrate 201 is formed with a number of depressions 202 corresponding to the depressions 80a of Figure 2A, and a deformable material 203 is coated upon the cylindrical surface of the substrate 202 in correspondence to the deformable material 82 of Figure 2B. Thereby, there are formed isolated spaces on the surface of the cylindrical substrate 201 in correspondence to the depressions 202. Further, in the step of Figure 16C, the ambient pressure is decreased and there is caused dilatation in the gas filling the depressions 202, and there are formed elongated cells 203A in the deformable material 203 now forming a cell array structure, such that the cells 203A are aligned in the direction perpendicular to the cylindrical surface of the substrate. [Example 10] Figure 17 shows an electronic reusable paper 400 according to Example 10 of the present invention. - 69 - Referring to Figure 17, the electronic reusable paper 400 is includes a back plane 401 formed of a substrate 401A carrying thereon an electrode layer 401B including various electrodes and active elements, and a front plane 402 is adhered upon the back plane 401 by an adhesive layer 403. The front plane 401 includes a transparent substrate 402A and a transparent electrode layer 402B formed thereon, wherein the transparent electrode layer 402B is adhered to a cell structure 402D including therein mutually isolated cells 402c in such a manner that the cells 402c are separated by cell walls 402d. The cells 402c are filled with an electrophoretic substance 402e and covered with a sealing layer 402E, wherein the transparent electrode layer 402B is adhered to a sealing .layer 402E by way of an adhesive layer 402C. Thus, by applying a voltage across the electrode pattern in the electrode layer 401B of the backplane 401 and the transparent electrode layer 402B of the front plane 402, there is caused electrophoretic migration in the electrophoretic substance 402c filling the cells 402c, and images are displayed by the electrophoretic migration thus inducted. - 70 - In an example, the cell structure 402D has a thickness t of 50um, and each cell 402c may have a width W of 150um. Further, the cell wall 402d may have a thickness of 8um or less. Figures 18A - 18G show the•fabrication process of the electronic reusable paper 400 of Figure 18. Referring to Figure 18A, a mold 501 of a silicone rubber is provided such that the mold 501 is formed with depressions 501A in a staggered pattern, similarly to the step of Figure 2A, except that the depressions 501A are formed in a cylindrical pit having a diameter of lOOum and with a pitch of 150um. Further, a UV-cure acrylic resin admixed with carbon black particles with a concentration of 0.5wt% is applied to the substrate 501 by a coating process to form a deformable layer 502 in the step of Figure 18A, and in the step of Figure 18B, the ambient behind the deformable layer 502 is evacuated to the pressure of 0.03MPa to cause expansion of the gas filling the spaces 501A. After curing the deformable material 502 by UV irradiation, the substrate 501 is removed, and the cell structure 402D of the structure of Figure 17 is obtained by the cured material 502 such that the - 71 - cells 402c are formed in the cell structure 402D in the form isolated with each other by the cell walls 402d. The cell structure thus formed has an A5 size (148mm> cell pitch A of 150um, and the cell wall thickness d of 8um. Next, in the step of Figure 18D, the cells 402c are filled with an electrophoretic substance, typically formed of titanium oxide particles, carbon black particles and isoparaffin, and in the step of Figure 18E, the seal layer 402E of a urethane resin is provided so as to cover the opened cells 402c such that there remains no air bubbles. Next, in the step of Figure 18F, the adhesive layer 402 is applied to the seal layer 402E, and in the step of Figure 18E, the transparent substrate 402A carrying thereon the transparent electrode 402B of ITO, or the like, is adhered to the adhesive layer 402C in the upside down state. Further, in the step of Figure 18G, the structure of Figure 18E is adhered to the backplane 401 via the adhesive layer 403, and the electronic reusable paper 400 of Figure 17 is obtained. Further, the present invention is by no - 72 - means limited to the embodiments described heretofore, but various variations and modifications may be made without departing from the scope of the invention. The present invention is based on Japanese priority applications No2005-262202 and 2005-322493 respectively filed on September 9, 2005 and November 7, 2005, which are incorporated herein as reference. - 73 - CLAIMS 1. A method of manufacturing a cell array- structure, comprising: a first step of laminating a deformable layer capable of causing plastic deformation on a substrate, said substrate being formed with plural, mutually separated depressions on a top surface thereof, such that said deformable layer forms a mutually isolated space in each of said plural depressions; and a second step of extending said space in each of said plural depressions by causing plastic deformation in said deformable layer, such that there are formed plural columnar cells respectively in correspondence to said plural depressions. 2. The method as claimed in claim 1, wherein said second step comprises a step of lowering a pressure of a space outside said deformable layer laminated on said substrate, said plastic deformation of said material layer being induced by a gas pressure in said plural depressions. - 74 - 3. The method as claimed in claim 1, wherein said plural cells extend in a direction generally perpendicular to said top surface of said substrate. 4. A method of manufacturing a minute composite material, comprising: a first step of laminating a deformable layer capable of causing plastic deformation on a substrate, said substrate being formed with plural, mutually separated depressions on a top surface thereof, such that said deformable layer forms a mutually isolated space in each of said plural depressions; a second step of extending said space in each of said plural depressions by causing plastic deformation in said deformable layer, such that there are formed plural columnar cells respectively in ' correspondence to said plural depressions; and a third step of forming plural columnar components in said respective columnar cells. 5. The method as claimed in claim 4, wherein said third step comprises: a first sub-step of solidifying said deformable layer to form cell - 75 - walls in a state formed with said plural columnar cells; and a second sub-step of injecting a material of said columnar components, into- said plural cells in a state in which said cell walls are attached to said substrate. 6. The method as claimed in claim 4, wherein said third step comprises: a first sub-step of solidifying said deformable layer to form cell walls in a state formed with said plural columnar cells; a second sub-step of adhering a first material to said cell walls to form a layer of said first material covering said cell walls; and a third sub- step of injecting a second material of said columnar component into said cells after said cell walls are covered with said first material. 7. The method as claimed in claim 6, wherein said first material is a material adhering selectively to said cell walls, said third sub-step being conducted such that said second material makes a direct contact with said substrate at said depression in each of said plural cells. - 76 - 8. The method as claimed in claim 4, wherein said third step comprises: a first sub-step of solidifying said deformable layer to form cell walls in a state formed with said plural columnar cells; a second sub-step of injecting a material of said columnar component into said cells as a first material; solidifying said first material to form said columnar components in said respective plural cells; removing said cell walls selectively to said columnar components; and filling a second material to a gap formed between said plural columnar components. 9. The method as claimed in claim 8, wherein said deformable layer comprises a material that causes sol-gel transition, and wherein said first sub-step of solidifying said deformable layer comprises a step of causing transition from a sol state to a gel state in said deformable layer. 10. The method as claimed in claim 9, wherein said deformable layer comprises a gelatin solution added with a surfactant. - 77 - 11. The method as claimed in claim 8, wherein said second material contains an opaque substance.- ... 12. The method as claimed in claim 4, wherein said deformable layer comprises a UV-cure resin. 13. The method as claimed in claim 12, wherein said deformable layer contains an opaque substance. 14. The method as claimed in claim 4, wherein said third step comprises the steps of: filling said cells with a material of said columnar components; and applying a pressure to said material of said columnar components. 15. The method as claimed in claim 4, wherein said third step comprises the steps of filling said cells with a material of said columnar components; and applying a centrifugal force to said material of said columnar components. - 78 - 16. The method as claimed in claim 4, wherein said second step comprises the steps of: attaching a slab to said deformable layer at a side away from said substrate; and evacuating a region behind said slab. 17. The method as claimed in claim 16, wherein said slab comprises a glass slab transparent to ultraviolet radiation. 18. The method as claimed in claim 16, wherein said slab includes penetrating holes formed with a pitch smaller than a pitch of said depressions on said substrate. 19. The method as claimed in claim 18, wherein said second step comprises a step of ventilating said region via said slab. 20. The method as claimed in claim 4, wherein said depressions on said substrate form an opening at said top surface of said substrate with an opening width such that a size of a width across walls inside said depression is larger than said opening width. A method of manufacturing a cell array structure includes.a first step of laminating a deformable layer capable of causing plastic deformation on a substrate, the substrate being formed with plural, mutually separated depressions on a top surface thereof, such that the deformable layer forms a mutually isolated space in each of the plural depressions; and a second step of extending the space in each of the plural depressions by causing plastic deformation in the deformable layer, such that there are formed plural columnar cells respectively in correspondence to the plural depressions.

Full Text

- 1 -
DESCRIPTION
MINIATURE CELL ARRAY STRUCTURE AND MANUFACTURING
METHOD OF MINIATURIZED COMPOSITE. COMPONENT USING SUCH
A MINIATURE CELL ARRAY STRUCTURE
TECHNICAL FIELD
The present invention generally relates to
molding technology of plastic components and more
particularly to the high-precision molding technology
of highly miniaturized plastic composites formed of
plural parts. The technology of the present invention
is applicable to the production of miniature plastic
lens arrays for use in optical scanning system of
copying machines, facsimile machines, solid-state
scanning type printers, and the like, or optical
waveguides having built-in miniature lens array
designed for optical transmission, production of
lenses of digital cameras, production of optical
fiber array used for projector screens, touch panels,
photosensitive bodies for electron photography
process, display devices, and the like.
BACKGROUND ART
Conventionally, there is a technology of
forming high-precision plastic products formed of
plural miniaturized components by way of molding.

- 2 -
More specifically, there is a technology of forming:
(1) miniature lens arrays; and (2) minute optical
fiber arrays.
(1) Conventional Technology related to Miniature
Lens Arrays
For the conventional technology related to
miniature lens arrays or microlens arrays, Japanese
Laid-Open Patent Application 1-107202 (Patent
Reference 1), Japanese Laid-Open Patent Application
2004-341474 (Patent Reference 2); Japanese Laid-Open
Patent Application 2004-45586 (Patent Reference 3)
are cited.
More specifically, Patent Reference 1
discloses a manufacturing method of a lens array
according to the steps of: arraying GRIN (graded
index) cylindrical lenses in a mold such that the
optical axes thereof are aligned in a predetermined
direction; and injecting a molten resin into the mold
to form a molding in which the lens array and the
resin are integrated.
Further, Patent Reference 2 describes the
method for producing an optical component by an
extrusion molding-process. More specifically, the
technology of Patent Reference 2 aims for a
production method of an optical component

- 3 -
characterized by long lifetime of the mold,
capability of forming the lenses without distortion
or optical defects and capability of integrating the
lenses easily into a main apparatus with high
precision.
Thus, a lens holding member is placed on a
lower mold in such a manner that the lens holding
member is formed with a large number of lens holes,
and lenses are placed on the respective lens holes of
the lens holding member. Thereby, the lower mold and
the upper mold are formed respectively with a lower
lens mold surface and an upper lens mold surface with
the diameter smaller than the diameter of the lens
holes, and lenses are formed by pressing the lower
mold and the upper mold with each other. By using
different materials for the lens and the lens holding
member, it becomes possible to suppress optical noise
of the lens. Particularly, by using a metal for the
lens holding member, it becomes possible to mount the
lens array to a main apparatus easily by way of
soldering.
Further, Patent Reference 4 provides the
method of manufacturing a high-precision composite -
molding having a thin optical shielding part. The
reference eliminates the problem of misalignment

- 4 -
between a molded product and a molding apparatus
applying a secondary molding process to the molded
product and enables manufacturing of a composite by
molding process with high precision in terms of
dimensions and pattern transfer precision. With this
prior art, reference positions are defined
respectively to the molded product produced by the
first molding process and to the mold used for the
secondary molding process for mutual alignment at the
time of initial setup of the secondary molding
process. Further, adjustment of dimensions is
achieved by way of expanding or shrinking the primary
molding or the mold or by way of mechanical
dimensional adjustment. Further, the start timing of
holding the primary molding in the secondary molding
apparatus is controlled by detecting the mutual
positional relationship therebetween or by evaluating
the mutual positional relationship based on the
linear thermal expansion coefficients by detecting
the temperature. Alternatively, the start timing may
be controlled based on the time calculated from the
temperature and the dimension. Thereby, the start
timing of the secondary molding is defined as the
timing in which the temperature of the primary

- 5 -
molding has reached a temperature higher than the
glass transition point by 3 - 25°C.
Japanese Patent 3,521,469 (Patent Reference
5) describes a manufacturing method of resin lens
array according to the process steps of: forming a
resin layer on one side of a flat substrate by
applying a transparent resin with a uniform
thickness; urging the resin layer against an optical
shielding plate of an optically shielding material
formed with plural through-holes; forming lenses by
extruding a part of the resin layer into the through-
holes of the optical shielding plate; curing the
resin layer to form a lens array sheet; and fixing
the substrate and the optical shielding plate by way
of the resin layer.
Further, Japanese Laid-Open Patent
Application 2004-45586 provides a method of
manufacturing a microlens array sheet having an
optical shielding layer comprising the steps of:
irradiating a ultraviolet radiation to a microlens
array sheet comprising a consecutive lamination of: a
transparent support substrate carrying microlenses at
one side and a transparent a photosensitive layer or
a thermoplastic resin layer at the other side; a UV-
cure adhesive resin layer colored in black; and a

- 6 -
protective film layer, such that the ultraviolet
radiation is applied to the side where the lenses are
formed; curing the UV-cure resin layer at the parts
where the UV radiation is focused by the microlenses
to cause transfer of the cured resin layer
corresponding to the focused parts to the protective
film layer; peeling off the cured resin layer of the
focused parts from the transparent photosensitive
layer or the thermoplastic layer by peeling the
protective film layer therefrom and forming an
optical shielding pattern of the UV-cure resin layer
in correspondence to the parts not exposed to the UV
radiation and remaining in intimate contact with the
transparent photosensitive layer.
(2) Conventional Technology related to Optical Fiber
Arrays
There are various conventional arts related
to manufacture of optical fiber arrays.
Japanese Laid-Open Patent Application 2004-
118119 (Patent Reference 6) discloses a technology
related to plastic optical fiber arrays and
manufacturing method thereof. This prior art
technology enables manufacturing of optical fiber
array characterized by smooth core surface and
reduced optical transmission loss with low cost in

- 7 -
short time while using a simple manufacturing
apparatus, and comprises the steps of: lowering a
comb-shaped molding that includes plural bar-shaped
fingers extending parallel with each other toward a
UV-cure molten resin of liquid state such that end
parts of the bar-shaped fingers contact with the
molten resin simultaneously; pulling up the bar-
shaped fingers; curing the resin pulled up from the
molten resin with the foregoing end parts to form
plural core parts simultaneously; forming a cladding
layer by dipping the entire core parts into a molten
UV-cure resin (cladding resin solution) to form a
cladding layer composite; placing the cladding layer
composite thus formed into a vessel together with a
molten thermoplastic resin of low viscosity; forming
the entire thermoplastic resin by heating the vessel
together with the molten resin and the cladding layer
composite to form a protective part; cutting the
molding thus formed including therein the comb-shaped
part at the end parts of the bar-shaped fingers; and
polishing the cross-section of the end parts thus
formed.
Japanese Laid-Open Patent Application 8-
112873 (Patent Reference 7) discloses the technology

- 8 -
related to a porous body and manufacturing process
thereof.
More specifically, this reference aims for
a light weight porous body of excellent thermal
insulation and compressive strength and provides a
sheet-shaped porous body comprising: square-shaped
cells forming a lattice patern in a thermoplastic
resin body; and a highly expandable thermoplastic
resin composition formed in each cell, the highly
expandable thermoplastic resin composition having an
expansion ratio of 20 times as large as the
thermoplastic resin forming the cells.
Further, Japanese Laid-Open Patent
Application 10-80964 (Patent Reference 8) discloses a
honeycomb structure and manufacturing technology
thereof.
More specifically, the reference teaches a
strong transparent honeycomb structure of stable
quality over a long period of time and the
manufacturing method thereof, wherein the honeycomb
structure includes three-dimensional packing of
columnar cells of polygonal cross-sectional shape in
a resin with high density. Thereby, the cells are
formed without providing a junction part between the
cell walls, and the cells are formed by placing an

- 9 -
expandable substance in a resin with a three-
dimensionally regular arrangement and by inducing
expansion of the expandable substance.
Patent Reference 1 Japanese Laid-Open Patent
Application 1-107202 official gazette
Patent Reference 2 Japanese Laid-Open Patent
Application 2004-341474 official gazette
Patent Reference 3 Japanese Laid-Open Patent
Application 2004-45586 official gazette
Patent Reference 4 Japanese Laid Open Patent
Application 2003-80543 official gazette
Patent Reference 5 Japanese Patent 3,521,469
Patent Reference 6 Japanese Laid-Open Patent
Application 2004-118119 official gazette
Patent Reference 7 Japanese Laid-Open Patent
Application 8-112873 official gazette
Patent Reference 8 Japanese Laid-Open Patent
Application 10-80964 official gazette
Patent Reference 9 Japanese Patent Publication
56-34780 official gazette
DISCLOSURE OF THE INVENTION. . .
[Problem with Manufacture of Lens Array]

- 10 -
When manufacturing a miniature composite
honeycomb structure, a typical example of which being
the one shown in Figure 1, more than one hundred
lenses 72 are assembled to form a microlens array in
an optical shielding part 71 in the form of lattice
by way of molding process.
With such a honeycomb structure, there is a
need of solving, the problems that:
(a) forming the optical shielding part as
thin as possible; and
(b) maintaining high precision after
formation of the composite.
In the case of the technology of Patent
Reference 1, in which the optical shielding part is
injected after arraying the lenses, there arises no
problem with regard to the foregoing point (a) . On
the other hand, there is a possibility with this
technology to form the lenses after formation of the
optical shielding part. In such a case, however, the
optical shielding part may be damaged at the time of
removing the composite from the mold.
Further, in the case the microlens array is
miniaturized and the thickness of the optical
shielding part is reduced to about 20um, it is not
possible to fill such a small space with ordinary

- 11 -
injection molding process because of the too large
viscosity of the resin, and it is not possible to
form the optical shielding part by way of the molding
process.
In order to attend to the problem (b) noted
above, Patent Reference 2 describes the process of
forming a lens array by injecting the lenses to the
holes formed in the optical shielding part, followed
by pressing. However, this process of Patent
Reference 2 has a drawback in that it requires high
precision for the dimension of the optical shielding
part and high precision for the alignment of the
optical shielding part.
In order to attend to the foregoing problem
of Patent Reference 2, Patent Reference 4 proposes a
dimension control by way of the temperature control.
However, this process of Patent Reference 4 suffers
from the problem of high cost in view of the need of
using expensive apparatus and long cycle time for the
forming process.
Further, Patent Reference 5 proposes the
solution of the foregoing problems. More specifically,
the process of Patent Reference 5 forms the lens part
by urging a transparent sheet to the optical
shielding part and causing plastic deformation in the

- 12 -
sheet material. While this process is effective for
eliminating the misalignment between the lenses and
the optical shielding part, there is a problem that -
the lens shape cannot be controlled because of the
absence of lens mold.
Patent Reference 3, on the other hand,
teaches the method of forming a microlens array by
forming the optical shielding pattern after formation
of the microlenses, by disposing an adhesive UV-cure
resin layer behind the lenses and causing focusing of
UV radiation to the UV-cure resin through the lenses.
While this method is effective for eliminating the
misalignment between the lenses and the optical
shielding part, the size and/or shape of the optical
shielding part is restricted by the form of the
lenses. More particularly, this process has a
drawback in that the optical shielding pattern
inevitably takes a tapered shape because of the
curing taking place with the focusing of the UV
radiation.
[Problem with Manufacture of Optical Fiber Array]
- With, regard, to. the method of forming the—
plastic optical fiber array, it takes a very long
time when the optical fibers are laid one by one to

- 13 -
form the optical fiber array. Such an approach is
hardly efficient.
Thus, there is a proposal shown in Figure
19A to form a comb-shaped molding 1 having plural
bar-shaped fingers lb extending parallel from a
bridging part la and cause the bar-shaped fingers lb
to make a contact substantially simultaneously with
the a molten resin 2 by lowering the comb-shaped
molding 1 toward the molten resin 2.
Thereafter, the comb-shaped molding 1 is
pulled up in the step of Figure 19B gently in the
upward direction while irradiating a weak UV
radiation, and with this, the molten resin 2 is
pulled up with the bar-shaped fingers lb to form
cores 4 extending parallel with each other in
correspondence to the fingers lb of the comb shaped
member 1.
Further, in the step of Figure 19C, a resin
member 3 is attached to the distal end parts of the
cores 4 to hold the cores 4 in the respective
positions, and ultraviolet radiation is applied for
fully curing the cores 4 thus formed.
Next, in the step of Figure 19D, the. cores
4 thus formed are dipped in a resin 6 held in a
vessel in the state that the cores 4 are held between

- 14 -
the comb-shaped molding 1 and the resin member 3, and
with this, a cladding layer is formed on each of the
cores 4. . . ..
Further, in the step of Figure 19E, the
member including the cores 4 carrying thereon the
cladding layer and held between the comb-shaped
molding 1 and the resin member 3 is dipped in a
thermosetting resin 8 held in a vessel 9. After
curing the thermosetting resin 8, the comb-shaped
molding 1 and the resin member 3 are disconnected in
the step of Figure 19F.
This is the technology disclosed in Patent
Reference 6.
With the technology of Patent Reference 6,
on the other hand, there arises a problem, associated
with its principle of forming the cores by pulling up
the comb-shaped member 1, in that the cores 4
inevitably have a tapered shape. Thus, the optical
fiber array formed with such a process suffers from
the problem of low efficiency of light utilization.
The present invention addresses the
foregoing problem by forming the cladding layer at
first by an extension process, followed, by injection-
of core material into the hollow space inside the
cladding layer to form a plastic optical fiber array.

- 15 -
With such a process of forming the cladding
layer part at first, there is a need of providing the
technology of forming a cell array structure in which
columnar cells are formed side-by-side.
Conventionally, there is a process of
forming a honeycomb structure according to Japanese
Patent Publication 56-34780 (Patent Reference 9)
comprising the steps of holding a plastic material
between heating platens having an escaping holes of
the plastic material; pressing and heating the resin
between the platens; and pulling apart the platens
from each other to expand the plastic material. This
conventional process, which uses a plastic material
for the honeycomb structure, however, has a drawback
in that the honeycomb structure has a thick cell wall.
Further, similar problem arises also in the
technology described in Patent Reference 7 or Patent
Reference 8 because of the use of thermoplastic resin.
Meanwhile, it is known to form a cell of
very thin cell wall by expanding water containing
surfactant as in the case of soap bubble. With this
process, it is possible to form a cell having a wall
thickness of several nanometers to several microns.
On the other hand, soap bubbles use the effects of
electrostatic repulsion, interaction between

- 16 -
hydrophobic groups, Marangoni effect, and the like,
wherein such effects become insignificant with drying
of the film and the soap bubble -is-collapsed in due
course. Further, in the case of plastic, none of
these effects are available.
In the bubbling process for forming a
honeycomb structure or cell array structure of
elongated columnar shape, it is important to cause
the bubbling at the same time. When the bubbled are
formed one by one without relationship, the bubbles
take a spherical form and the desired honeycomb
structure is not formed.
It should be noted that Patent Reference 7
and Patent Reference 8 attempts the bubbling by way
of heating, while such formation of bubbles by
heating cannot form the desired honeycomb structure
unless the heating is achieved with uniform
temperature.
Further, the technology of Patent Reference
9 forms the honeycomb structure by the operation of
separating the platens from each other as noted
before, while it is very important with such a
process to control the viscosity of the plastic to be
uniform. Thus, formation of honeycomb structure with
this process is also difficult.

- 17 -
In an aspect, the present invention
provides a method of forming a cellular array
structure in which plural columnar cells are disposed
adjacent to each other, comprising:
a first step of laminating a deformable
layer on a substrate formed with plural depressions,
said plural depressions being formed in said
substrate in a manner isolated from each other, said
deformable layer being laminated on said substrate
such that said depressions define respective spaces
isolated from each other; and
a second step of causing said space to
expand in said plural depressions by causing plastic
deformation in said deformable layer, such that said
plural columnar cells are formed in said deformable
layer respectively in correspondence to said
depressions.
According to the present invention, it
becomes possible to form a cellular array structure
in which plural columnar cells defined by a cell wall
of very small thickness are disposed adjacent with
each other, by a simple and reliable process.
In another -aspect, the present invention
provides a method for manufacturing a miniature

- 18 -
composite component in which plural columnar members
are disposed in a matrix, comprising:
a first step of laminating a-deformable
layer on a substrate formed with plural depressions,
said plural depressions being formed in said
substrate in a manner isolated from each other, said
deformable layer being laminated on said substrate
such that said depressions define respective spaces
isolated from each other;
a second step of causing said space to
expand in said plural depressions by causing plastic
deformation in said deformable layer, such that
plural columnar cells are formed in said deformable
layer respectively in correspondence to said
depressions; and
forming said plural columnar members
respectively in said plural columnar cells,
said deformable member forming said matrix.
According to the present invention, it
becomes possible to form a miniature composite
component in which plural columnar members are
disposed in a matrix in the form or array.
Particularly, it becomes possible with the present
invention to form the columnar members in the form of

- 19 -
microlens array defined with thin shells forming an
optical shielding part.
-- In another aspect, the present invention
provides a microlens array, comprising:
plural optically transparent parts each
carrying a microlens at least on one end part
thereof; and
a boundary part provided to each of said
optically transparent parts,
said plural optically transparent parts
being disposed adjacent to each other across said
boundary part to form a microlens array.
According to the present invention, it
becomes possible to form a microlens array such that
each microlens forming the array carries an opaque
thin film having a thickness of several microns or
less on the sidewall surface thereof. Because the
thickness of the opaque thin film is small, the
microlens array of the present invention provides a
large aperture while suppressing the stray light at
the same time.
Other objects and further features of the
present invention will be come apparent from the
following detailed description when read in
conjunction with the attached drawings.

- 20 -
BRIEF DESCRIPTION OF THE DRAWINGS
Figure 1 is an oblique view diagram showing
an example of a lens array of the present invention;
Figures 2A - 2F are diagrams showing the
manufacturing method of the lens array according to
Embodiment 1 of the present invention;
Figures 3A - 3G are diagrams showing the
manufacturing method of the lens array according to
Embodiment 2 of the present invention;
Figures 4A and 4B are diagrams showing a
lens array of the present invention in a cross-
sectional view;
Figure 5 is an oblique view diagram showing
the lens array of the present invention;
Figure 6 is a diagram explaining the effect
of the present invention;
Figure 7 is a side view diagram showing the
manufacturing method of an optical fiber array
according to Example 3 of the present invention;
Figure 8 is an enlarged side view diagram
showing a process of forming a columnar cell array
structure according to Example 3 of Figure 7;

- 21 -
Figure 9 is an oblique diagram showing the
honeycomb structure formed according to Example 3 of
Figure 7 in an enlarged scale;
Figure 10 is a side view diagram showing
the manufacturing process of an optical fiber array
according to Embodiment 4 of the present invention;
Figures 11A and 11B are diagrams explaining
the problem that arises when a material of the
deformable layer is applied to the substrate formed
with semi-spherical depressions;
Figure 12A is another side view diagram
showing a substrate formed with spherical
depressions;
Figure 12B is another side view diagram
showing a substrate formed with depressions of comb-
tooth shape formed by photolithography;
Figures 13A - 13D are diagrams showing the
manufacturing process of optical fiber array
according to a molding process;
Figures 14A and 14B are diagrams explaining
the process of filling a core material in a cell
array structure by using a centrifugal separator in
the embodiment of manufacturing an optical- fiber
array;

- 22 -
Figure 15 is a diagram showing an optical
fiber array manufactured according to the molding
process of the present invention;
Figures 16A - 16C are diagrams showing
further modifications of the present invention;
Figure 17 is a diagram showing the
construction of an electronic reusable paper
according to an embodiment of the present invention;
Figures 18A - 18H are diagrams showing the
manufacturing process of the electronic reusable
paper of Figure 17;
Figures 19A - 19F are diagrams explaining
the manufacturing method of an optical fiber array
according to a related art.
BEST MODE FOR CARRYING OUT THE INVENTION
[OVERVIEW OF THE INVENTION]
In view of the prior art noted heretofore,
the present invention has its main objective of:
(1) providing a method of manufacturing a
miniature cell array structure including therein an
array of miniature columnar cells comprising the
steps of: expanding plural, mutually isolated cells
in a common direction with mutually identical
expansion time and expansion amount such that the

- 23 -
miniature columnar cells are formed adjacent with
each other across a thin shell wall; and fixing the
expanded columnar cells promptly while maintaining
respective shapes thereof.
Further, the present invention has a first
subsidiary objective of:
(1.1) providing a simple and easy method of
manufacturing a miniature lens array in which
individual miniature lenses forming the array have
high precision and formed in a manner that the
individual lenses are isolated from each other by a
thin optical shielding part.
Further, the present invention has a second
subsidiary objective of:
(1.2) providing a simple and easy method of
manufacturing an optical fiber array capable of
forming an optical fiber array with high precision
and with high efficiency of utilization of light.
The main objective of the present invention
is attained by the method of manufacturing a
miniature cell array structure comprising: a first
step of covering a first substrate formed with plural,
mutually.independent depressions-at respective
locations with a first material having a function of
plastic deformation such that spaces are formed in

- 24 -
the respective depressions; and a second step of
forming elongated columnar cells isolated by a thin
cell wall by causing to expand the foregoing spaces
simultaneously in a predetermined direction by a gas
pressure in the foregoing spaces.
According to the foregoing manufacturing
method of the present invention, it becomes possible
to cause the expansion of the first material with the
gas pressure of the spaced by decreasing the pressure
at the side of the substrate covered with the first
material.
Here, it should be noted that "mutually
independent depressions" noted above means that
individual depressions form a respective, mutually
isolated spaces not communicating with the rear side
of the first material or communicating with other
depressions.
The first subsidiary objective of the
present invention is attained by the method of
manufacturing a miniature composite component,
comprising: a first step of covering a first
substrate formed with plural, mutually independent
depressions at respective locations with, a first ... _
material having a function of plastic deformation
such that spaces are formed in the respective

- 25 -
depressions; a second step of expanding the first
material at plural locations simultaneously by the
gas pressure of the spaces to form elongated cells
having thin cell walls such that the cells are
elongated in a predetermined, common direction; and
third step of forming the cellular shape and the
depressions by injecting a second material without
departing the first material from the first substrate.
The foregoing depressions may have the
shape of a lens. In this case, the present invention
provides a method of manufacturing a lens array as
the miniature composite component, by forming the
lenses by using the miniature cell array structure of
the first material as the optical shielding part and
injecting the material of lens into the miniature
cell array structure without separating the lens mold
and the miniature cell array structure (optical
shielding part) from each other.
The second subsidiary objective of the
present invention is attained by the method of
manufacturing an optical fiber plate in which the
cell array structure is injected with a core member
having a refractive index larger than the refractive..
index of the cell array structure. With this process,
the cell array structure is removed subsequently, and

- 26 -
the gap formed with such removal of the cell array is
filled with a cladding material.
In order .to solve the second- subsidiary
objective and to obtain a miniature cell array
structure including therein elongated columnar cells
defined with thin cell walls, the present invention
discloses a method of arraying a number of bubbles or
cells in an aqueous solution added with a surfactant
and solidifying the bubbles after causing
simultaneous dilatation in such a manner that the
shape of the bubbles is maintained during the
solidification process.
Particularly, the present invention
provides the independent depressed spaces
(depressions) on the top surface of the substrate and
uses the means of controlling the pressure of the
ambient in which the substrate is placed.
Further, in order to dry the cellular array
structure without causing disintegration in the shape
thereof, the present invention discloses a method of
using a gelatin solution that causes a sol-gel
transition with temperature change for the deformable
material. With this,, the gelatin solution .Is...changed
to gel for increasing the rigidity thereof before
conducting the drying process. Here, it should be

- 27 -
noted that the "deformable material" noted above
means the material that forms the cellular array
structure therein when it is processed according, to
the present invention.
According to the present invention, the
method of manufacturing the cellular array structure
comprises the steps of: covering a top surface of a
substrate (A) formed with minute depressions with
high density with a deformable material (B) having
the function of ductile deformation under a
predetermined condition by applying the deformable
material (B) on the top surface of the substrate (A);
causing expansion in the deformable material (B) ..by
the gas pressure in the closed spaces formed between
the depressions and the deformable material (B) such
that the plural spaces are elongated simultaneously
and such that there are formed a number of elongated
cells extending in a predetermined direction in the
state separated from each other by thin walls having
a micrometer thickness, wherein the depressions on
the substrate (A) are formed in a manner isolated
from each other.
With regard to the manufacturing method, of,
the cellular array structure, it becomes possible to
extend the deformable material (B) by lowering the

- 28 -
pressure at the side of the substrate (A) covered by
the deformable material (B).
With-the foregoing method of manufacturing .
the cellular array structure, it is possible to use a
gelatin aqueous solution added with a surfactant for
the deformable material (B).
Further, the method of manufacturing the
cellular array structure may be conducted by
providing a ventilation space behind the deformable
material (B) such that the deformable material (B) is
dried from this side.
With regard to the method of manufacturing
the cellular array structure, it is preferable to
form the ventilation space behind the deformable
material (B) provided on the substrate (A) and causes
a member to make contact with the deformable cell
array structure (B) from the behind such that the
member is formed with penetrating holes with a pitch
smaller than the pitch of the columnar cells formed
in the deformable material (B). Thereby, drying of
the deformable material (B) is conducted via such
through-holes.
Further, it is preferable, to process the _ ..
depressions such that the depressions have a water-
repellant surface. Further, it is preferable to form

- 29 -
the depressions such that the depressions have a
large diameter in the interior of the substrate (A)
as compared with at the top surface.
Next, the means of solution of the second
subsidiary objective will be explained.
1) The means for expanding the cellular
array structure
For the means of expanding the
cellular array structure such that plural columnar
cells are formed side by side therein, there is
provided a substrate structure in which plural
depressions are formed on the surface of a substrate,
in combination with the means for applying the
deformable material such that there are formed spaces
between the respective depressions and the deformable
material formed on the substrate.
2) The means for forming thin cell walls
(1) In order to form the columnar
cells with thin cell walls, the present invention
uses an aqueous solution containing a surfactant and
dissolved with a gelatin that causes a sol-gel
transition upon temperature change for the means for
forming the thin cell walls.
(2) Further, the present invention
uses the means for causing dry shrinking. Here, it

- 30 -
should be noted that this means for causing dry-
shrinking means a depressurizing process conducted by
using a pressure control apparatus. Therein,
evaporation of water content contained in the gelatin
is accelerated, and with this, thinning of the cell
wall caused by shrinkage of the volume of the
material forming the cell wall, which in turn is
caused by the water evaporation, is facilitated.
3) The means for solidifying the cell walls
while maintaining the columnar cell array structure
(1) For solidifying the cell walls
while maintaining the columnar cell array structure,
the present invention uses an aqueous solution added
with a surfactant and dissolved with a gelatin that
causes a sol-gel transition with temperature, for the
material of the deformable material.
(2) Further, the present invention
controls the temperature to the state of sols during
the phase of expansion and control the temperature to
the state of gels after the expansion has been
completed.
(3) Further, the present invention
secures a space for facilitating drying of the
deformable material while not restricting the
expansion thereof. With this, there is facilitated

- 31 -
evaporation of water as a result of decompression,
and the cell array structure formed as a result of
the expansion o.f the deformable material is
solidified as a result of the drying.
4) Other means
Further, the present invention attains
the simultaneous expansion of the cells and high
speed drying of the deformable material at the same
time by depressurizing by way of depressurizing means.
[The method of manufacturing optical fiber array]
Further, the present invention provides a
method of manufacturing an optical fiber array based
on the foregoing method of manufacturing miniature
cellular array structure. Thus, the present invention
forms an optical fiber array in which a large number
of optical fibers are disposed in the form of high-
density array, by injecting core material of a
refractive index higher than the refractive index of
the deformable material (B), into the cells in the
miniature cell array structure formed of the
deformable material (B) now forming the cell walls.
Further, the present invention provides a
"method of manufacturing an optical fiber array",
comprising the steps of: injecting a core material
into the cells of a miniature cell array structure

- 32 -
formed by the "method of manufacturing a miniature
cellular array structure"; removing the deformable
material (B) ; and forming a. large number ..of optical
fibers in the form of an array in the spaces formed
as a result of the step of removing the deformable
material (B) by filling the spaces thus formed
simultaneously with a cladding material.
(1) First aspect of the invention
According to a first aspect, the present
invention provides a method of manufacturing a
miniature cell array structure, comprising: a first
step of covering a surface of a first substrate
formed with a large number of mutually independent
depressions (depressions not communicating to the
outside or other depressions) at respective,
predetermined locations, with a first material that
has a function of ductile deformation under a
predetermined condition, such that there are formed
spaces in the foregoing depressions on the first
substrate; and a second step of expanding and
extending the first material by the gas pressure in
the foregoing plural spaces simultaneously to form a
miniature array of cells in the ..first material such .
that the plural cells extend parallel in a
predetermined direction.

- 33 -
According to the first aspect, it becomes
possible to form a number of mutually isolated cells
in the manner that.the cells are isolated by cell
walls formed of the first material with high density
and high precision at the same time.
(2) Second aspect of the invention
According to a second aspect of the present
invention, the first material is subjected to the
expansion and extension by the gas pressure inside
the spaces, while the gas pressure is caused by
depressurizing the side of the first substrate
covered with the first material. According to the
present invention, it becomes possible to form a
large number of mutually independent cells separated
with each other by the cell walls of the first
material and formed with very high density, by a
simple and quick process.
(3) Third aspect of the invention
According to a third aspect, the present
invention provides a method of manufacturing a
miniature composite component, comprising: a first
step of covering a surface of a first substrate
formed with a large number of mutually independent
depressions at respective, predetermined locations,
with a first material that has a function of ductile

- 34 -
deformation under a predetermined condition, such
that there are formed spaces in the foregoing
depressions on the first substrate-; a second step of
expanding and extending the first material by the gas
pressure in the foregoing plural spaces
simultaneously to form a miniature array of cells in
the first material such that the plural cells extend
parallel in a predetermined direction; and a third
step of injecting a second material to the plural
cells without separating the first material and the
first substrate from each other to form the cells
such that the cells have respective end parts
corresponding to the depressions on the first
substrate
According to the third aspect of the
present invention, the spaces are formed in the
depressions in the first step and the first material
is expanded and extended in the second step, and thus,
it becomes possible to form the plural cells
simultaneously.
Further, by injecting the second material
to the cells in a third step, it becomes possible to
form the plural cells simultaneously, such that each
cell includes an end part corresponding to the
depression on the first substrate.

- 35 -
Particularly, it becomes possible to
manufacture the cells without misalignment between
the part formed in the first and second steps., and the
part formed in the third step, by conducting the
third step continuously to the first and second steps,
without separating the first material and the first
substrate from each other.
(4) Fourth aspect of the invention
According to a fourth aspect, the present
invention provides a method of manufacturing a
miniature composite component, comprising: a first
step of covering a surface of a first substrate
formed with a large number of mutually independent
depressions (depressions not communicating to the
outside or other depressions) at respective,
predetermined locations, with a first material that
has a function of ductile deformation under a
predetermined condition, such that there are formed
spaces in the foregoing depressions on the first
substrate; a second step of expanding and extending
the first material by the gas pressure in the
foregoing plural spaces simultaneously to form a
miniature array.of cells in the first material such
that the plural cells extend parallel in a
predetermined direction; a third step of adhering a

- 36 -
third material to a cell wall of the plural cells
without separating the first material and the first
substrate form each other; and a fourth step of
injecting a second material to the plural cells
without separating the first material and the first
substrate from each other to form the cells such that
the cells have respective end parts corresponding to
the depressions on the first substrate.
According to the present invention, it
becomes possible to form the miniature composite
component with high precision similarly to the third
aspect of the present invention in view of the fact
that the third and fourth steps are conducted without
separating the first material and the first substrate
from each other.
(5) Fifth aspect of the invention
According to a fifth aspect, the present
invention carries out the expansion and the extension
of the first material in the state that the first
material is sandwiched between the first substrate
and a second substrate.
According to the fifth aspect, it becomes
possible to achieve high precision in the shape of
the cells with the use of the second substrate. By-
using a flat slab for the second substrate, it

- 37 -
becomes possible to form the cells to have a uniform
length.
(6) Sixth aspect of the invention
According to a sixth aspect, it becomes
possible to generate the gas pressure in the spaces
corresponding to the depressions in the first step by
causing depressurizing. With the use of
depressurizing, the gas pressure becomes uniform in
all the spaces corresponding to the foregoing plural
depressions at any time, and it becomes possible to
form the cells to have a uniform volume and shape.
(7) Seventh aspect of the invention
According to a seventh aspect, the second
material is applied to the opening parts of the cells
in a depressurized state, and the second material
thus applied is injected into the cells by increasing
the pressure beyond the atmospheric pressure.
According to the present invention, there
is formed a uniform static pressure because of the
use of the difference of gas pressure, the injection
of the second material is conducted uniformly,
without variation. Further, the first and second
steps can be conducted in continuation in the same
apparatus at the time of manufacturing, and it

- 38 -
becomes possible to lower the cost of manufacturing
the miniature composite component.
(8) Eighth aspect of the invention
According to an eighth aspect, it becomes
possible to inject the second material into the cells
by applying the second material at the opening parts
of the cells in a depressurized state and
subsequently applying a centrifugal force. By using
the centrifugal force, the substances of different
specific gravity are separated easily, and thus, it
becomes possible to easily evacuate the gas in the
cells and inject the second material in the liquid
state into the cells.
(9) Ninth aspect of the invention
According to a ninth aspect, the present
invention can manufacture a miniature lens array
(microlens array) for the miniature composite
component.
(10) Tenth aspect of the invention
According to a tenth aspect, the present
invention uses a slab of hydrophobic nature for the
second substrate. With this, the first material is
easily.separated from the second substrate in the
second step, and thus, it becomes possible to form
the penetrating cells easily.

- 39 -
(11) Eleventh aspect of the invention
According to an eleventh aspect, the
depressions formed on .the first substrate have the
shape of a lens. Thus, according to the present
invention, it becomes possible to transfer the lens
shape to the cells in the third step of the third
aspect or in the fourth step of the fourth aspect
with the dilatation of the gas caused in the first
step. Thus, transfer of the lens shape is achieved at
the same time to the formation of the cells, and it
becomes possible with the eleventh aspect to form a
lens array for the miniature composite component.
(12) Twelfth aspect of the invention
According to a twelfth aspect, the present
invention provides a miniature lens array in which
the lenses forming the lens array are separated from
each other by the first material having the function
of optical shielding, by using a transparent material
for the second material and an opaque or optical
shielding material for the first material. With this,
flare or stray light is eliminated in the lens array.
(13) Thirteen aspect of the invention
According to a thirteen aspect, the
miniature lens array (microlens array) of the present
invention is formed of the first material at least

- 40 -
having the function of isolation, the second material
having the function of optical transmission, and the
third material having the function of optical
shielding. With this, it becomes possible to obtain a
miniature lens array (microlens array) free from
stray light or flare. Because the miniature lens
array of the thirteen aspect attains the foregoing
three functions by three different materials, it
becomes possible to enhance the respective functions
as compared with the invention of the twelfth aspect.
Further, there is attained increased degree of
freedom at the time of manufacture of the miniature
lens array.
(14) Fourteenth aspect of the invention
According to a fourteenth aspect, the
present invention provides a method of manufacturing
a miniature cell array structure, comprising the
steps of: covering a top surface of a substrate (A)
formed with minute depressions with high density with
a deformable material (B) having a function of
ductile deformation under a predetermined condition;
extending the deformable material (B) by a gas
pressure in plural spaces formed by the plural
depressions and the deformable material, such that
the plural spaces are expanded and elongated in a

- 41 -
predetermined direction to form plural cells
separated from each other by thin cell walls of a
micron thickness, wherein the depressions are formed
independently on the substrate (A).
According to the present invention, the
depressions on the substrate (A) are formed
independently to each other, and thus, the expansion
time and the expansion amount become identical
between the plural depressions when depressurization
is applied. Thereby, the elongated, columnar cells
are formed uniformly in a manner separated form each
other by the cell walls formed of the deformable
material.
(15) Fifteenth aspect of the invention
According to a fifteen aspect, the present
invention depressurizes the side of the substrate (A)
covered with the deformable material (B), and thus,
the expansion time and expansion amount become
identical between the adjacent depressions. Thereby,
it becomes possible to grow a cell array formed of
plural, mutually independent columnar cells uniformly.
(16) Sixteenth aspect of the invention
According to a sixteenth aspect, the
present invention uses a gelatin aqueous solution
added with a surfactant for the deformable material

- 42 -
(B). Thus, the cells are grown like soap bubbles
having a very thin cell wall, wherein the cells thus
grown undergo transition to. a.gel thereafter. Thereby
the cells are dried while maintaining the shape
thereof. Further, because the temperature of sol-gel
transition is about 40°C, it becomes possible to
increase the amount of expansion at low temperatures
while suppressing the boiling of water, and it
becomes possible to use a high degree of
depressurization for the growth of the cell array
structure.
(17) Seventeenth aspect of the invention
According to a seventeenth aspect, the
present invention provided a ventilation space at the
side of the substrate (A) covered with the deformable
material (B). With this, it is possible to dry the
deformable material (B) form this side.
(18) Eighteenth aspect of the invention
According to an eighteenth aspect, the
present invention causes a structural body formed
with penetrating holes with a pitch smaller than the
pitch of the cells in the cell array structure to
make a contact with the deformable material (B)
covering the top surface of the substrate (A) where
the depressions are formed. With this, it becomes

- 43 -
possible to control the relationship between the
spaces formed in the structural body in the
penetrating holes and the substrate (A), and the
thickness of the deformable material (B) applied to
the substrate (A) becomes uniform. Further, because
the penetrating holes are formed with the pitch
smaller than the pith of the cells in the deformable
material (B), the cells can grow without losing their
shapes. Further, by ventilating the space behind the
deformable material (B) through the penetrating holes,
the cells are solidified promptly.
(6) Nineteenth aspect of the invention
According to a nineteenth aspect, the
present invention applies a process to make the
depressions hydrophobic. With this, the deformable
material (B) does not enter to the depressions at the
time of application of the deformable material (B)
upon the surface of the substrate (A).
(20) Twentieth aspect of the invention
According to a twelfth aspect of the
present invention, the depressions are formed in the
substrate (A) such that a diameter thereof is larger
than a diameter of an opening part formed on the
surface of the substrate (A) by the depressions.

- 44 -
According to the twentieth aspect, it
becomes possible to apply the deformable material (B)
on the surface of the substrate (A) without causing
the deformable material (B) to invade substantially
into the depressions on the substrate (A). Further,
because of the reduced contact area of the opening
parts, degassing from the depressions after the
application of the deformable material (B) is reduced,
and it becomes possible to cause maximum expansion
for the cells at the time of the depressurizing.
(21) Twenty first aspect of the invention
According to a twenty first aspect, the
present invention injects a core material having a
refractive index larger than the refractive index of
the deformable material (B) into the cells formed in
the deformable material (B). Thus, it becomes
possible to manufacture an optical fiber array with
high dimensional precision and high efficiency of
utilization of light, with low cost and high
production efficiency.
(22) Twenty second aspect of the invention
According to a twenty second aspect, the
present invention removes the deformable material (B,
after injecting the core material into the cells
formed in the deformable material (B), and fills the

- 45 -
gaps formed with the removal of the deformable
material (B) , with a cladding material. As a result,
it becomes possible to manufacture an optical fiber
array having resistance to water while using various
materials for the cores.
Working Examples of the Invention
Next, description will be made with regard
to (1) "manufacturing of lens array", and (2)
"manufacturing of an optical fiber plate (optical
fiber array)".
1. Manufacturing of Lens Array
[Example 1]
First, processing method pertinent to the
third aspect of the invention will be explained with
reference to Figure 1 and Figures 2A - 2F.
Lens Mold (First Substrate)
Referring to Figures 2A, it should be noted
that a lens mold 80 (first substrate) is a mold that
determines the pitch of the lens elements of a lens
array to be formed. Further, the lens mold 80
determines the basic structure of the cell array
formed by expanding a deformable opaque material 82
provided thereon so as to form voids therein in the
form of columnar cells and used for holding the lens

- 46 -
elements of the lens array. Further, the lens mold 80
is used for the mold of the lens elements in the
process conducted after formation of the cell array.
In Example 1, the lens mold 8 0 is formed of
a silicone rubber having a water-repellent surface,
and lens parts 80a are formed in the lens mold 80 in
a lattice pattern with a pitch of 200pm. Each lens
part 80a has a semispherical surface of the radius of
180um, wherein one hundred and sixty nine such lens
parts 80a are formed on the lens mold 80 in thirteen
rows and thirteen columns.
Opaque Material (First Material)
The opaque material 82 is a deformable
material forming the cellular array structure
including the elongated, columnar cells defined by
cell walls. The opaque material 82 thereby functions
to suppress flares or stray light when optical
elements are formed in the cells. In the Example 1,
an UV-cure acrylic resin of the refractive index of
1.56 is used for the opaque material 82. Thereby, in
order to function as an opaque optical shield, the
opaque material 82 is added with carbon black
particles with the amount of 0.5wt%. Because the
opaque material 82 has the same refractive index to

- 47 -
the lenses to be formed in the cells, there is caused
no total reflection of light, and optical absorption
is attained efficiently.
Lens Material (Second Material)
With Example 1, an UV-cure acrylic resin of
the refractive index of 1.56 is used for lenses 83
that are formed in the opaque material 82 in
correspondence to the columnar cells therein.
Pressure Control Apparatus
A pressure control apparatus 100 compresses
and/or evacuating gases and is used for controlling
the dimension, primarily the height, of the cell
array structure forming the cellular walls in the
opaque material 82.
[Function]
The process of Example 1 proceeds as shown
in Figures 2B - 2F.
(1) In the step of Figure 2B, the opaque
material 82 is spin-coated on a flat glass substrate
81 transparent to ultraviolet lights and having a
high degree of flatness, with a film thickness 0.1 -
lOOum in the state that the glass substrate 81 is

- 48 -
placed upon the lens mold 80. In Example 1, the
opaque material is spin-coated with the thickness of
20um (First Step).. .
The pressure control apparatus 100 is the
apparatus capable of controlling the ambient pressure
therein to a predetermined pressure. In Example 1,
the ambient pressure is controlled usually to O.lMPa.
It should be noted that this pressure is chosen for
controlling the gas dilatation caused in the
subsequent steps.
(2) The structure of Figure 2B obtained in
the first step is incorporated into the pressure
control apparatus 100 and the ambient pressure
therein is reduced to 0.003MPa.
With this process of depressurization,
there starts expansion or dilatation of gas in the
spaces corresponding to the lens parts 80a, and thus,
there is caused expansion of the spaces in the lens
parts 80a with the expansion of the gas therein by
causing deformation in the opaque material 82.
Here, it should be noted that the expansion
takes.place in all of the lens parts 80a on the lens
mold 80 simultaneously, and thus, lateral expansion
of the spaces is restricted because of the

- 49 -
interference of the adjacent spaces. Thus, the
expansion takes place solely in the direction upward,
leading to formation of a cell.._a.rr.ay structure in
which plural columnar cells are formed adjacent with
each other in the deformed opaque material 82 in
correspondence to the lens parts 80a in such a manner
that the plural cells extend parallel with each other
in the upward direction from the substrate 80.
Thereby, the opaque material 82 forms opaque cell
walls 84 defining the columnar cells formed therein.
In the state of Figure 2C, ultraviolet radiation is
applied for about ten seconds for curing the opaque
material 82 thus deformed, and with this, the opaque
cell walls 84 thus formed are solidified and the
cellular array structure is fixed (Second Step).
Next, in the step of Figure 2D, the
substrate 80 thus carrying thereon the cellular array
structure is taken away from the pressure control
apparatus 100. Further, after removing the glass
substrate 81, the cells forming the cell array in the
opaque material 82 are injected with a resin forming
the lens, wherein this injection of the resin is
conducted in a centrifugal separator under a
centrifugal force of 3000G for 30 seconds (Third
Step).

- 50 -
Here, it is important to note that the lens
mold 80 and the cell walls 84 are not separated from
each other during this, process.
Next, in the step of Figure 2E, a reflector
plate 85 transparent to the ultraviolet radiations is
placed is placed upon the structure of Figure 2D and
ultraviolet radiation is applied for about 10 seconds
for curing the lens material 83. With this, lens
elements 86 are formed in the cells of the cellular
array structure in the form of lens array (Fourth
Step).
Finally, the lens mold 80 and the reflector
plate.85 are removed, and the lens array is obtained
such that microlens elements 86 are held in the
elongated, columnar cells defined with the opaque
cell walls 84.
While not illustrated, it is preferable to
anneal the structure thus obtained such that the
curing proceeds thoroughly in the lens elements 86
and also in the cell walls 84 and such that there
remains no uncured site, especially in the opaque
cell walls 84.
[Example 2]

- 51 -
Example 2 is an embodiment corresponding to
the second aspect of the invention and forms the
opaque part in two. steps as. will be explained with
reference to Figures 3A - 3G. Therein, it will be
noted that the process of Example 2 is different from
the process of Example 1 in the following aspects:
(a) a cell wall 94 corresponding to the
opaque cell wall 8 4 of Example 1 includes an opaque
film 94a covering a cell wall 94b; and
(b) an acrylic UV-cure resin is used for
the material of the cell wall 94b (first material),
while the opaque film (third material) 94a is formed
by applying carbon black particles to the cell wall
94b.
Otherwise, Example 2 is identical to
Example 1.
[Function]
The process of Example 3 is shown in
Figures 3A - 3G, wherein there is no difference to
the process of Example 1 except that an opaque liquid
in which carbon black particles are dispersed in a
volatile solvent is injected into the cells in the
step of Figure 3D after formation of the cell walls
94b. In Figures 3A - 3G, it should be noted that

- 52 -
those parts corresponding to the parts described
previously with reference to Example 1 are designated
by the same reference numerals and the description
thereof will be omitted.
Thereby, because the lens mold 80 has
water-repellency, the opaque liquid adheres
selectively to the cell walls 94b, and the carbon
black particles thus adhered to the cell wall 94 form
the foregoing opaque film 94a (Third Step).
Because the material 92 corresponding to
the material 82 of Example 1 is free from the opaque
material with Example 2, the UV curing process of
Figure 3C proceeds efficiently, and curing of the
cell walls 94b is attained in short time. Further,
because it becomes possible to use the opaque
material in large amount, the effect of eliminating
stray light or flares is enhanced with Example 2, and
it becomes possible to suppress the leakage of light
in the lens array effectively.
[Example 3]
Example 3 shown in Figures 4A and 4B
provides an optical fiber array (optical fiber plate)
formed by using the process of Example 1 and Example
2.

- 53 -
Thus, with the construction of Figure 4A, a
cladding layer 101 forms a cell array structure
holding cores 102 in the cells of the cell array
structure, wherein Example 3 forms the cladding layer
101 by using a UV-cure methacrylate resin of the
refractive index of 1.45 for the first material
forming the cell walls while using a UV-cure acrylic
resin of the refractive index of 1.56 for the second
material used for the core 102.
Thereby, it is possible to provide lens
effect to the optical fiber elements by forming the
optical fiber elements to have a semi-spherical as
shown in Figure 4A.
Alternatively, it is possible to form the
optical fiber elements to have an end part of conical
shape for diffusing the light as shown in Figure 4B.
[Example 4]
In contrast to the microlens array of
Figure 1 in which the lens elements are arranged in
the form of a lattice, Example 4 shown in Figure 5
provides a lens array in which the lens elements are
arranged in a staggered array.
Thus, it is possible with the present
invention to manufacture a miniature lens array of

- 54 -
staggered arrangement for the lens element shown in
Figure 5 while using a similar process explained
heretofore. In this case, it should be noted that the
opaque cell walls forming the cladding layer 101 form
therein cells of hexagonal pillar shape as shown in
Figure 5, and the cores 102 filling the cells have
the corresponding shape of hexagonal pillar.
Next, the eighth aspect of the present
invention that uses the second substrate of
hydrophobic nature will be explained with reference
to Figure 6.
(Case 1) Second substrate is not water-repellent
In the case the second substrate 81 lacks
water-repellency, the cells are formed in the cell
array structure of a second material 112
corresponding to the deformable material 82 of
Figures 2A - 2F as shown in Figure 6, wherein it will
be noted that each cell has a closed end at the side
facing the second substrate 81. This is because the
film of the material 112 remained in contact with the
second substrate 81 at the end part of the cells
because of the high wetness between the second
material 112 and the second substrate 81.
(Case 2) Second substrate is water-repellent

- 55 -
In the case the second substrate 81 is
repellent to water, there appears a cellular array
structure similar to the case of Examples 1 and 2
shown in Figures 2A - 2F or 3A - 3G in which each
cell has opened ends. Such a structure is caused
because the film of the second material 112 has moved
elsewhere because of the poor wetting between the
second material 112 and the second substrate 81.
From Cases 1 and 2 noted above, it will be
understood that control of the cell array structure
is possible by the water-repellent nature of the
first substrate 80.
2. Examples of manufacturing optical fiber plate
[Example 5] - Method of forming a cell array
structure of columnar elongated cells
Figures 7-9 show the process of
manufacturing an optical fiber plate (optical fiber
array) according to Example 5.
Referring to the drawings, there is
provided a temperature control apparatus 22 on a
coater machine 21, and a substrate (A) carrying a
large number of depressions on a top surface thereof
with high density is mounted upon the temperature
control apparatus 22.

- 56 -
With this embodiment, a cell array
structure including therein fine columnar cells with
high density is formed on such a substrate (A).
The construction and operation of Example 5
will be explained hereinafter.
1. Construction of Example 5
(1) Substrate (A)
The substrate (A) of Figure 7 serves for
the mold for growing a cell array structure thereon
and determines the pitch of the cells in the cell
array structure thus formed. More specifically, the
substrate (A) is formed of a silicon rubber and is
formed with depressions 23 having a semispherical
shape of the diameter of 25um in a staggered pattern
with a pitch of 38um.
(2) Cellular structure material (B)
The cell array structure material (B) of
Figure 7 forms the body of the cell array structure
formed with a number of columnar, elongated cells.
For the cell array structure material (B) , it is
possible to use an aqueous solution of commercially
available gelatin (trade name Jellice) diluted by
five times in purified water and added with a
surfactant (dodecyl sodium sulfate) by lwt%. In this

- 57 -
case, the sol-gel transition takes place for the
material of the cell array structure at about 38°C.
(3) Temperature control apparatus
The temperature control apparatus 22
control the viscosity (sol-gel transition) by
controlling the temperature of the cellular
structural material (B).
(4) Pressure control apparatus
A pressure control apparatus 24 of Figure 7
is an apparatus that compresses and evacuates gases
and controls the dimension, particularly the height
of the cell array structure. Further, the pressure
control apparatus facilitates drying of the cellular
structural material (B).
(5) Ejector
An ejector 25 of Figure 7 is a device for
ejecting the cellular structural material (B) on the
substrate (A) with a predetermined amount.
(6) Coater machine
The coater machine 21 of Figure 7 is an
apparatus that spreads the cellular structural

- 58 -
material (B) ejected on the top surface of the
substrate (A) from the ejector 25 to form a film of a
predetermined thickness. In the illustrated example,
the coater machine 21 is a spin-coater that utilizes
a centrifugal force.
Operation of Example 1
(1) First, the ambient pressure of the
coater machine 21 is controlled to a predetermined
pressure such as 0.IMPa by using the pressure control
apparatus 24. This process is conducted for
controlling the amount of gas dilation in the later
process.
(2) The temperature of the substrate (A) is
controlled by using the temperature control apparatus
22. Thereby, heating may be conducted by any of
heater, infrared light, microwave, and the like. In
the case of Example 1, an electric cartridge heater
is used for the temperature control apparatus 22. The
temperature may be set close to the sol-gel
transition temperature such as 38°C. This temperature
is chosen for controlling the viscosity, and hence
sol-gel transition of the cellular structural
material (B).

- 59 -
(B) Eject the cellular structural material
(B) on the substrate (A) by using the ejector 25.
Almost simultaneously, the cellular structural
material (B) thus ejected is spread over the
substrate (A) by squeezing or spin-coating, such that
there are formed vacant spaces in the depressions 23.
In this step of coating, the cellular structural
material (B) may form a film having a film thickness
of 1 - lOOum. In the example of Embodiment 5, the
cellular structural material (B) forms a film of the
thickness of lOum. Ejection of the cellular
structural material (B) from the ejector 25 is
attained at the temperature of 45°C, and hence in the
state of sol of low viscosity.
(4) Lower the ambient pressure of the
coater machine 21, after lowering the temperature of
the substrate (A) such that there is caused gel
transition in the cellular structural material (B).
With Example 5, the control temperature of
the temperature control apparatus 22 is reduced to
20°C and the ambient pressure is lowered thereafter
to 0.03MPa by using the pressure control apparatus 24.
With this, the gas in the spaces of the depressions
starts dilatation and the spaces cause extension as
represented in Figure 8.

- 60 -
Thereby, because of the simultaneous
dilatations in the adjacent depressions 23, lateral
expansion of the spaces is restricted and the
dilatation of the spaces takes place only in the
direction upward from the substrate (A). Thus, there
are formed a number of cells 31 simultaneously in the
cellular structural material (B) in the form of
mutually independent elongated bubbles, while the
bubbles or cells 31 thus formed form a columnar cell
array structure 30.
Thereafter, the temperature of the
substrate (A) is lowered by the temperature control
apparatus 22, and the cellular structural material
(B) thus formed with a cell array structure is
solidified and dried while maintaining the shape
thereof. Thereby, the time for the solidification is
reduced greatly by evacuating the ambient by using
the pressure control apparatus 24.
(5) Next, the processing chamber of the
pressure control apparatus 24 is opened and the work
corresponding to the cell array structure thus formed
is taken out to the outside.
Figure 8 shows the cell array structure
thus formed in an enlarged scale in the state that
the cell array structure is taken out from the

- 61 -
pressure control apparatus 24 after 10 minutes
elapsed from the dilatation process and in the state
that the substrate (A) is removed.
It was confirmed that the cell array
structure thus obtained is sufficiently dried and has
a mechanical strength maintaining its shape. In the
illustrated example, each cell 31 in the cell array
structure 30 has a diameter of '35um and a length of
120um, with the wall thickness of 3um.
[Example 6] - Embodiment corresponding to eighteen
aspect of the invention
Next, the embodiment corresponding to the
eighteenth aspect of the invention will be explained.
The eighteen aspect of the invention
corresponds to the construction shown in Figure 10 in
which a flat slab structure 26 formed with a number
of penetrating holes is contacted to the deformable
material (B) on the substrate (A). Thereby, the
penetrating holes are formed with a pitch smaller
than the pitch of the cells in the cell array
structure.
It should be noted that such minute
penetrating holes can be formed easily with a
diameter of 0.lum or less by causing anode oxidation

- 62 -
in an aluminum plate of the thickness of 200um.
Because the penetrating holes are formed with a pitch
smaller than the pitch of the cells in the cell array
structure, it becomes possible to cause dilatation in
the deformable material (B) without damaging the
shape of the individual cells 31 by contacting the
slab structure 26 to the backside of the deformable
material (B).
[Example 7] - Embodiment corresponding to twentieth
aspect of the invention
Figure 11A schematically shows the problem
that may arise when a deformable material (B) is
applied to a surface of the substrate (A) formed with
semispherical depressions 23.
More specifically, Figure 11A shows the
situation in which the gas in the depression 23 is
dissolved into the deformable material (B) or escapes
to the outside by passing through the deformable
member (B) as shown at the left part of the drawing.
Associated with such degassing, it can be seen in
Figure 11A that the deformable material (B) invades
into the depressions in some of the depressions 23.
Figure 11B illustrates the Young-Laplace
equation.

- 63 -
According to the Young-Laplace equation, a
pressure difference AP between a gas pressure Pi and
a liquid pressure PL is represented for a bubble of
elliptical shape formed in a liquid as
AP=Pi-PL = a( 1 /Ri+1 /R2) ,
wherein Rl and R2 respectively represent the radius
of the bubble measured along a minor axis thereof and
the radius of the bubble measured along a major axis
thereof.
Thus, the foregoing equation represents
that the pressure difference AP is increased when
the radius Ri and the radius R2 are decreased. Here,
a represents the surface tension of the liquid.
Thus, when the diameter of the depression
23 has become 30um or less, the pressure of the
bubble is increased according to the Young-Laplace
equation, resulting in absorption of the gas by the
liquid. Alternatively, the gas escapes from the
depression 23 to the outside by passing through the
deformable material (B). In any of these cases, there
arises the problem that the deformable material
invades into the depression 23 as shown in Figure 11A.
Thus, Example 7 reduces this problem by
decreasing the area of the depression 23 opened at
the surface of the substrate (A) as represented in

- 64 -
Figure 12A, in which it will be noted that there are
formed a number of spherical voids in the substrate
(A) such that each spherical void is exposed at the
surface of the substrate (A) at an opening having a
diameter much smaller than the diameter of the void
itself.
It should be noted that the structure of
Figure 12A is obtained easily by the steps of:
arraying polystyrene microspheres on the surface of
the substrate (A); covering the microspheres by an
UV-cure resin layer; and removing the polystyrene
microspheres by an organic solvent such as acetone.
Figure 12B shows another example of the
substrate (A) in which there are formed a number of
deep depressions 23b in the substrate (A). The
structure of Figure 12B can be formed by
photolithography.
[Example 8] - Embodiment corresponding to twentieth
aspect
Figures 13A - 13D, 14A and 14B show the
process of manufacturing an optical fiber array
according to the twentieth aspect of the invention.
With the twentieth aspect, there is formed
a cell array structure 30 in which the cells have a

- 65 -
closed end at the side of the substrate (A) while the
other, opposite end is opened.
(1) The cell array structure 30 obtained
with the process of Example 5 is turned over upside
down as shown in Figure 13A, and a transparent core
material 41 is injected to the cells therein in this
state. In the illustrated example, an uncured UV-cure
resin is used for the core material 41. More
specifically, the illustrated example uses an acrylic
UV-cure resin of the refractive index of 1.56 for the
core material 41.
In order to ensure positive injection of
the more material 41 into the miniature cells 31
without voids, the present embodiment uses a
centrifugal separator 50 shown in Figures 14A, and
the core material 41 is injected in the step of
Figure 14B with a pressure of 3000G for the duration
of 30 seconds by operating the centrifugal separator
50.
Thus, in the step of Figure 14A, the cell
array structure 30 is mounted upon a rotary drum 51
of the centrifugal separator 50 and the core material
41 is poured upon the cell array structure 30.
Next, in the step of Figure 14B, the drum
51 is rotated at high speed and the core material 41

- 66 -
is pressed into the cells 3 by the centrifugal force
acting upon the core material 41. Thereby, any air
bubble 52 in the cell 41 is separated and the cells
31 are fully loaded with the core material 41.
(2) Next, in the step of Figure 13B, the
UV-cure resin forming the core material 41 is cured
by irradiating UV light.
(3) Next, the cell array 30 of gelatin is
replaced with other, preferably opaque material
capable of performing optical shielding function, in
view of the fact that gelatin forming the cell array
30 has poor resistance to water and relatively high
refractive index.
Thus, the optical fiber array of Figure 13B
is dipped into water for removal of the cell walls
formed of gelatin in the step of Figure 13C, and with
this, there are formed gaps 42 between the cores 41
in correspondence to the gelatin cell walls.
(4) Further, in the step of Figure 13C, a
cladding material 43 is injected into the gaps 42
thus formed by using the centrifugal separator 50 of
Figures 14A and 14B similarly to the case of the
cores 41. In the illustrated example, a PMMA solution
in which polymethacrylate (PMMA) having a refractive
index of 1.49 dissolved into a volatile solvent and

- 67 -
added with carbon black with the amount of 0.5wt% is
used.
After the injection of the cladding
material 43, the cladding structure 44 is formed
after drying as shown in Figure 13D.
(5) With the foregoing process, it is
possible to manufacture a miniature optical fiber
plate or optical fiber array 40 shown in Figure 13D
or 15 with simple process and short time period, such
that optical fibers 45 having a diameter of 35um and
carrying a cladding layer of 3um thickness are
arranged in the form of array of the height of 120um.
It should be noted that the efficiency of
utilization of light of such an optical fiber plate
40 reaches as large as 22% in the case the distance
to the optical source is set to 15um or less.
[Example 9]
While the substrate or "mold" used in the
preceding embodiments have a flat top surface formed
with the depressions, the present invention is not
limited to such a flat substrate and it is also
possible to use a cylindrical substrate 201 as shown
in Figure 16A. In each of Figures 16A - 16C, it
should be noted that the right drawing shows the

- 68 -
cylindrical substrate 201 and the components formed
thereon in an oblique view while the left drawing
shows the cross-section taken along a plane L.
As represented in Figure 16A, the
cylindrical substrate 201 is formed with a number of
depressions 202 corresponding to the depressions 80a
of Figure 2A, and a deformable material 203 is coated
upon the cylindrical surface of the substrate 202 in
correspondence to the deformable material 82 of
Figure 2B. Thereby, there are formed isolated spaces
on the surface of the cylindrical substrate 201 in
correspondence to the depressions 202.
Further, in the step of Figure 16C, the
ambient pressure is decreased and there is caused
dilatation in the gas filling the depressions 202,
and there are formed elongated cells 203A in the
deformable material 203 now forming a cell array
structure, such that the cells 203A are aligned in
the direction perpendicular to the cylindrical
surface of the substrate.
[Example 10]
Figure 17 shows an electronic reusable
paper 400 according to Example 10 of the present
invention.

- 69 -
Referring to Figure 17, the electronic
reusable paper 400 is includes a back plane 401
formed of a substrate 401A carrying thereon an
electrode layer 401B including various electrodes and
active elements, and a front plane 402 is adhered
upon the back plane 401 by an adhesive layer 403.
The front plane 401 includes a transparent
substrate 402A and a transparent electrode layer 402B
formed thereon, wherein the transparent electrode
layer 402B is adhered to a cell structure 402D
including therein mutually isolated cells 402c in
such a manner that the cells 402c are separated by
cell walls 402d. The cells 402c are filled with an
electrophoretic substance 402e and covered with a
sealing layer 402E, wherein the transparent electrode
layer 402B is adhered to a sealing .layer 402E by way
of an adhesive layer 402C.
Thus, by applying a voltage across the
electrode pattern in the electrode layer 401B of the
backplane 401 and the transparent electrode layer
402B of the front plane 402, there is caused
electrophoretic migration in the electrophoretic
substance 402c filling the cells 402c, and images are
displayed by the electrophoretic migration thus
inducted.

- 70 -
In an example, the cell structure 402D has
a thickness t of 50um, and each cell 402c may have a
width W of 150um. Further, the cell wall 402d may
have a thickness of 8um or less.
Figures 18A - 18G show the•fabrication
process of the electronic reusable paper 400 of
Figure 18.
Referring to Figure 18A, a mold 501 of a
silicone rubber is provided such that the mold 501 is
formed with depressions 501A in a staggered pattern,
similarly to the step of Figure 2A, except that the
depressions 501A are formed in a cylindrical pit
having a diameter of lOOum and with a pitch of 150um.
Further, a UV-cure acrylic resin admixed
with carbon black particles with a concentration of
0.5wt% is applied to the substrate 501 by a coating
process to form a deformable layer 502 in the step of
Figure 18A, and in the step of Figure 18B, the
ambient behind the deformable layer 502 is evacuated
to the pressure of 0.03MPa to cause expansion of the
gas filling the spaces 501A.
After curing the deformable material 502 by
UV irradiation, the substrate 501 is removed, and the
cell structure 402D of the structure of Figure 17 is
obtained by the cured material 502 such that the

- 71 -
cells 402c are formed in the cell structure 402D in
the form isolated with each other by the cell walls
402d. The cell structure thus formed has an A5 size
(148mm> cell pitch A of 150um, and the cell wall thickness d
of 8um.
Next, in the step of Figure 18D, the cells
402c are filled with an electrophoretic substance,
typically formed of titanium oxide particles, carbon
black particles and isoparaffin, and in the step of
Figure 18E, the seal layer 402E of a urethane resin
is provided so as to cover the opened cells 402c such
that there remains no air bubbles.
Next, in the step of Figure 18F, the
adhesive layer 402 is applied to the seal layer 402E,
and in the step of Figure 18E, the transparent
substrate 402A carrying thereon the transparent
electrode 402B of ITO, or the like, is adhered to the
adhesive layer 402C in the upside down state.
Further, in the step of Figure 18G, the
structure of Figure 18E is adhered to the backplane
401 via the adhesive layer 403, and the electronic
reusable paper 400 of Figure 17 is obtained.
Further, the present invention is by no

- 72 -
means limited to the embodiments described heretofore,
but various variations and modifications may be made
without departing from the scope of the invention.
The present invention is based on Japanese
priority applications No2005-262202 and 2005-322493
respectively filed on September 9, 2005 and November
7, 2005, which are incorporated herein as reference.

- 73 -
CLAIMS
1. A method of manufacturing a cell array-
structure, comprising:
a first step of laminating a deformable
layer capable of causing plastic deformation on a
substrate, said substrate being formed with plural,
mutually separated depressions on a top surface
thereof, such that said deformable layer forms a
mutually isolated space in each of said plural
depressions; and
a second step of extending said space in
each of said plural depressions by causing plastic
deformation in said deformable layer, such that there
are formed plural columnar cells respectively in
correspondence to said plural depressions.
2. The method as claimed in claim 1,
wherein said second step comprises a step of lowering
a pressure of a space outside said deformable layer
laminated on said substrate, said plastic deformation
of said material layer being induced by a gas
pressure in said plural depressions.

- 74 -
3. The method as claimed in claim 1,
wherein said plural cells extend in a direction
generally perpendicular to said top surface of said
substrate.
4. A method of manufacturing a minute
composite material, comprising:
a first step of laminating a deformable
layer capable of causing plastic deformation on a
substrate, said substrate being formed with plural,
mutually separated depressions on a top surface
thereof, such that said deformable layer forms a
mutually isolated space in each of said plural
depressions;
a second step of extending said space in
each of said plural depressions by causing plastic
deformation in said deformable layer, such that there
are formed plural columnar cells respectively in '
correspondence to said plural depressions; and
a third step of forming plural columnar
components in said respective columnar cells.
5. The method as claimed in claim 4,
wherein said third step comprises: a first sub-step
of solidifying said deformable layer to form cell

- 75 -
walls in a state formed with said plural columnar
cells; and a second sub-step of injecting a material
of said columnar components, into- said plural cells in
a state in which said cell walls are attached to said
substrate.
6. The method as claimed in claim 4,
wherein said third step comprises: a first sub-step
of solidifying said deformable layer to form cell
walls in a state formed with said plural columnar
cells; a second sub-step of adhering a first material
to said cell walls to form a layer of said first
material covering said cell walls; and a third sub-
step of injecting a second material of said columnar
component into said cells after said cell walls are
covered with said first material.
7. The method as claimed in claim 6,
wherein said first material is a material adhering
selectively to said cell walls, said third sub-step
being conducted such that said second material makes
a direct contact with said substrate at said
depression in each of said plural cells.

- 76 -
8. The method as claimed in claim 4,
wherein said third step comprises: a first sub-step
of solidifying said deformable layer to form cell
walls in a state formed with said plural columnar
cells; a second sub-step of injecting a material of
said columnar component into said cells as a first
material; solidifying said first material to form
said columnar components in said respective plural
cells; removing said cell walls selectively to said
columnar components; and filling a second material to
a gap formed between said plural columnar components.
9. The method as claimed in claim 8,
wherein said deformable layer comprises a material
that causes sol-gel transition, and wherein said
first sub-step of solidifying said deformable layer
comprises a step of causing transition from a sol
state to a gel state in said deformable layer.
10. The method as claimed in claim 9,
wherein said deformable layer comprises a gelatin
solution added with a surfactant.

- 77 -
11. The method as claimed in claim 8,
wherein said second material contains an opaque
substance.- ...
12. The method as claimed in claim 4,
wherein said deformable layer comprises a UV-cure
resin.
13. The method as claimed in claim 12,
wherein said deformable layer contains an opaque
substance.
14. The method as claimed in claim 4,
wherein said third step comprises the steps of:
filling said cells with a material of said columnar
components; and applying a pressure to said material
of said columnar components.
15. The method as claimed in claim 4,
wherein said third step comprises the steps of
filling said cells with a material of said columnar
components; and applying a centrifugal force to said
material of said columnar components.

- 78 -
16. The method as claimed in claim 4,
wherein said second step comprises the steps of:
attaching a slab to said deformable layer at a side
away from said substrate; and evacuating a region
behind said slab.
17. The method as claimed in claim 16,
wherein said slab comprises a glass slab transparent
to ultraviolet radiation.
18. The method as claimed in claim 16,
wherein said slab includes penetrating holes formed
with a pitch smaller than a pitch of said depressions
on said substrate.
19. The method as claimed in claim 18,
wherein said second step comprises a step of
ventilating said region via said slab.
20. The method as claimed in claim 4,
wherein said depressions on said substrate form an
opening at said top surface of said substrate with an
opening width such that a size of a width across
walls inside said depression is larger than said
opening width.

A method of manufacturing a cell array
structure includes.a first step of laminating a
deformable layer capable of causing plastic
deformation on a substrate, the substrate being
formed with plural, mutually separated depressions on
a top surface thereof, such that the deformable layer
forms a mutually isolated space in each of the plural
depressions; and a second step of extending the space
in each of the plural depressions by causing plastic
deformation in the deformable layer, such that there
are formed plural columnar cells respectively in
correspondence to the plural depressions.

Documents:

http://ipindiaonline.gov.in/patentsearch/GrantedSearch/viewdoc.aspx?id=6v5NseWWb6GNhChei/bwrQ==&loc=wDBSZCsAt7zoiVrqcFJsRw==

« Previous Patent

Next Patent »

Patent Number

272930

Indian Patent Application Number

861/KOLNP/2008

PG Journal Number

19/2016

Publication Date

06-May-2016

Grant Date

03-May-2016

Date of Filing

27-Feb-2008

Name of Patentee

RICOH COMPANY, LTD.

Applicant Address

3-6, NAKAMAGOME 1-CHOME, OHTA-KU, TOKYO

Inventors:

#	Inventor's Name	Inventor's Address
1	KANEKATSU, TOSHIHIRO	17-36, TSUMADAMINAMI 1-CHOME, ATSUGI-SHI, KANAGAWA, 243-0814
2	HARADA, TOMOHIRO	7-31, TSUMADAMINAMI 1-CHOME, ATSUGI-SHI, KANAGAWA, 243-0814
3	SUTO, KATSUNORI	2623-18, SHIMOMIZO, SAGAMIHARA-SHI, KANAGAWA, 229-0015

PCT International Classification Number

B29C 44/00,B32B 3/12

PCT International Application Number

PCT/JP2006/318096

PCT International Filing date

2006-09-06

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	2005-262202	2005-09-09	Japan
2	2005-322493	2005-11-07	Japan