TWI639023B - a method of applying an anti-reflective coating to an optical surface of a mold, a mold having an optical surface transferable to an anti-reflective coating of the lens, and an optical lens manufactured - Google Patents
a method of applying an anti-reflective coating to an optical surface of a mold, a mold having an optical surface transferable to an anti-reflective coating of the lens, and an optical lens manufactured Download PDFInfo
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- TWI639023B TWI639023B TW103124225A TW103124225A TWI639023B TW I639023 B TWI639023 B TW I639023B TW 103124225 A TW103124225 A TW 103124225A TW 103124225 A TW103124225 A TW 103124225A TW I639023 B TWI639023 B TW I639023B
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- B—PERFORMING OPERATIONS; TRANSPORTING
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- B29D—PRODUCING PARTICULAR ARTICLES FROM PLASTICS OR FROM SUBSTANCES IN A PLASTIC STATE
- B29D11/00—Producing optical elements, e.g. lenses or prisms
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- G02B1/00—Optical elements characterised by the material of which they are made; Optical coatings for optical elements
- G02B1/10—Optical coatings produced by application to, or surface treatment of, optical elements
- G02B1/11—Anti-reflection coatings
- G02B1/113—Anti-reflection coatings using inorganic layer materials only
- G02B1/115—Multilayers
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- G—PHYSICS
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- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B1/00—Optical elements characterised by the material of which they are made; Optical coatings for optical elements
- G02B1/10—Optical coatings produced by application to, or surface treatment of, optical elements
- G02B1/14—Protective coatings, e.g. hard coatings
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Abstract
本發明係關於一種將抗反射塗層塗覆於模具之光學表面上之方法。在一個實施例中,該方法包括以下步驟:提供具有光學表面之鏡片模具;在該光學表面上形成超疏水性材料層,其中該超疏水性材料含有一定量之雙臂矽烷,該量為該超疏水性材料之相對百分比;在該超疏水性材料層上形成抗反射塗層層狀結構;及在該抗反射塗層層狀結構上形成以單層厚度沈積之偶合劑層,該形成係在非質子性條件下使用氣相沈積或藉由使用偶合劑於非質子性溶劑中之溶液進行浸塗或旋塗來實現。 This invention relates to a method of applying an anti-reflective coating to an optical surface of a mold. In one embodiment, the method comprises the steps of: providing a lens mold having an optical surface; forming a layer of superhydrophobic material on the optical surface, wherein the superhydrophobic material contains a quantity of arms decane, the amount being a relative percentage of the superhydrophobic material; forming an antireflective coating layered structure on the superhydrophobic material layer; and forming a coupling layer deposited in a single layer thickness on the antireflective coating layer structure, the forming system This is accomplished by a vapor deposition or a dip coating or spin coating using a solution of a coupling agent in an aprotic solvent under aprotic conditions.
Description
本申請案為2011年4月15日由Kai C.Su,Leslie F.Stebbins,Bill Mantch及Eugene C.Letter申請之標題為「ANTI-REFLECTIVE LENSES AND METHODS FOR MANUFACTURING THE SAME」之美國專利申請案第13/088,199號的部分接續申請案。上文確定之同在申請中之申請案的揭示內容以全文引用的方式併入本文中。 This application is filed on April 15, 2011, to the patent application entitled "ANTI-REFLECTIVE LENSES AND METHODS FOR MANUFACTURING THE SAME" by Kai C. Su, Leslie F. Stebbins, Bill Mantch and Eugene C. Letter. Partial application for 13/088, 199. The disclosure of the above-identified application in the application is hereby incorporated by reference in its entirety.
本申請案亦為2012年10月10日由Kai C.Su,Leslie F.Stebbins,Bill Mantch及Eugene C.Letter申請之標題為「ANTI-REFLECTIVE LENSES AND METHODS FOR MANUFACTURING THE SAME」之美國專利申請案第13/648,642號的部分接續申請案。上文確定之同在申請中之申請案的揭示內容以全文引用的方式併入本文中。 This application is also filed on October 10, 2012 by Kai C. Su, Leslie F. Stebbins, Bill Mantch and Eugene C. Letter, entitled "ANTI-REFLECTIVE LENSES AND METHODS FOR MANUFACTURING THE SAME" Part of the continuation of application No. 13/648,642. The disclosure of the above-identified application in the application is hereby incorporated by reference in its entirety.
在本發明之描述中引用並論述了一些參考文獻,其可包括專利、專利申請案及各種公開案。提供此類參考文獻之引用及/或論述以僅闡明本發明之描述,且並不承認任何此類參考文獻為本文中所描述之本發明的「先前技術」。本說明書中所引用並論述之所有參考文獻以全文引用的方式併入本文中且其引用的程度就如同已個別地將各參考文獻以 引用的方式併入一般。 Some references are cited and discussed in the description of the present invention, which may include patents, patent applications, and various publications. The citation and/or discussion of such references is provided to clarify the description of the invention and is not to be construed as a "prior art" of the invention described herein. All references cited and discussed in this specification are hereby incorporated by reference in their entirety in their entirety herein in The manner of citation is incorporated into the general.
本發明一般係關於一種光學表面,且更特定言之係關於一種抗反射鏡片及其製造方法。 The present invention relates generally to an optical surface, and more particularly to an antireflective lens and method of making the same.
抗反射鏡片通常由使抗反射塗層處於塑膠眼鏡片上而形成。將抗反射(AR)塗層塗覆於眼鏡片及其他光學裝置之表面上以減少反射。尤其對於眼鏡片而言,減少反射使其不僅看起來較佳,而更重要的是用起來較佳,因為其藉由消除多次反射從而產生較少眩光,在夜晚駕駛或電腦監測器前工作時此情況尤其顯而易見。較少眩光意謂佩戴者通常發現尤其在一天結束時其眼睛不怎麼疲倦。AR塗層亦使更多光穿過鏡片,由此增加對比度且因此增加視覺敏銳度。 Antireflective lenses are typically formed by placing an antireflective coating on a plastic ophthalmic lens. An anti-reflective (AR) coating is applied to the surface of the ophthalmic lens and other optical devices to reduce reflection. Especially for ophthalmic lenses, reducing reflections not only looks better, but more importantly, it is better to use because it produces less glare by eliminating multiple reflections, working at night or computer monitors. This is especially true when this is the case. Less glare means that the wearer often finds that his eyes are not very tired, especially at the end of the day. The AR coating also allows more light to pass through the lens, thereby increasing contrast and thus increasing visual acuity.
鑄造塑膠眼鏡片領域涉及將鏡片形成物質材料引入兩個模具之間,且接著使鏡片形成材料聚合成為固體。將諸如CR39單體之液體塑膠調配物注入由前及後模具形成之腔室中,該等模具對於鏡片之加工面具有內部拋光之模具表面。塑膠在該模具中固化,且接著分離該模具以產生符合所選處方之完成之眼鏡片。接著圍繞邊緣對鏡片進行研磨以裝入所選框架中。可將塗層塗覆於加工鏡片或前或後模具之內側,因此在固化時其將結合於鏡片。 The field of cast plastic ophthalmic lenses involves introducing a lens forming material between two molds and then polymerizing the lens forming material into a solid. A liquid plastic formulation, such as a CR39 monomer, is injected into a chamber formed by the front and back molds having an internally polished mold surface for the machined face of the lens. The plastic is cured in the mold and the mold is then separated to produce a finished ophthalmic lens that meets the selected prescription. The lens is then ground around the edge to fit into the selected frame. The coating can be applied to the inside of the processing lens or the front or back mold so that it will bond to the lens when cured.
一些驗光師提供現場眼鏡服務。若干公司已研發可在辦公室中現場鑄造鏡片之方法。然而,因AR塗層必須經由真空氣相沈積塗覆,故當前將AR塗層塗覆於眼鏡上之方法仍需要將眼鏡運送至不同設施。當然此舉意謂額外之時間及 費用。因此,需要現場製造具有AR塗層之眼鏡的方法。 Some optometrists provide on-site eyewear services. Several companies have developed methods for casting lenses in the office. However, because AR coatings must be applied via vacuum vapor deposition, current methods of applying AR coatings to spectacles still require shipping the spectacles to different facilities. Of course, this means extra time and cost. Therefore, there is a need for a method of fabricating glasses with AR coatings on site.
一類用於眼鏡片之AR塗層為交替堆疊高折射率材料及低折射率材料。最常用低折射率材料為二氧化矽;二氧化鋯及/或二氧化鈦通常用作高折射率材料。 One type of AR coating for ophthalmic lenses is to alternately stack high refractive index materials and low refractive index materials. The most commonly used low refractive index material is ceria; zirconium dioxide and/or titanium dioxide is commonly used as a high refractive index material.
尤其在塗覆於塑膠眼鏡片上時,AR塗層之一個問題為黏著性。AR塗層一般經由真空沈積塗覆。熟知真空沈積塗層與其基底之黏著性一般成問題。有機塑膠鏡片材料及無機AR材料不容易彼此黏著,從而導致剝離或刮傷。因此,需要新穎方法將AR塗層以較大黏著性塗覆於塑膠鏡片上。 One problem with AR coatings, especially when applied to plastic ophthalmic lenses, is adhesion. The AR coating is typically applied via vacuum deposition. It is well known that the adhesion of vacuum deposited coatings to their substrates is generally problematic. Organic plastic lens materials and inorganic AR materials do not easily adhere to each other, resulting in peeling or scratching. Therefore, there is a need for a novel method of applying an AR coating to a plastic lens with greater adhesion.
應注意的是,若干專利揭露使用矽烷使無機基質結合於有機基質。Soane等人之美國專利第5,733,483號揭示使用偶合層將由氧化矽製成之AR多層與含丙烯酸酯之鏡片結合於一起。偶合劑具有矽烷氧基頭及丙烯酸酯基尾。其中所用之矽烷之實例為甲基丙烯醯氧基丙基三甲氧基矽烷。 It should be noted that several patents disclose the use of decane to bind an inorganic matrix to an organic matrix. No. 5,733,483 to Soane et al. discloses the use of a coupling layer to bond an AR multilayer made of yttria with an acrylate-containing lens. The coupling agent has a decyloxy head and an acrylate tail. An example of a decane used therein is methacryloxypropyltrimethoxydecane.
Goosens之美國專利第4,615,947號揭示與有機聚矽氧烷混合以增加有機矽氧烷硬塗層與熱塑性基底之黏著性的丙烯酸系物。Takarada等人之美國專利第5,025,049號亦揭示增加有機聚矽氧烷層與熱塑性基底之黏著性的底塗劑。底塗劑為包括烷氧基矽烷基化單體之有機共聚物與其他成分之混合物。 No. 4,615,947 to Goosens discloses an acrylic compound which is mixed with an organopolyoxane to increase the adhesion of the organodecane hard coat to the thermoplastic substrate. U.S. Patent No. 5,025,049 to Takarada et al. also discloses a primer which increases the adhesion of an organic polyoxyalkylene layer to a thermoplastic substrate. The primer is a mixture of an organic copolymer comprising an alkoxyquinone alkylated monomer and other ingredients.
其他專利論述使用矽烷使有機基質與另一有機基質結合。Walters等人之美國專利第6,150,430號揭示使用有機官能性矽烷改良有機聚合層與有機聚合基底之黏著性。 Other patents discuss the use of decane to combine an organic matrix with another organic matrix. U.S. Patent No. 6,150,430 to Walters et al. discloses the use of organofunctional decane to improve the adhesion of an organic polymeric layer to an organic polymeric substrate.
Takamizawa等人之美國專利第5,096,626號揭示具有AR塗層及/或硬塗層之塑膠鏡片。該專利論述先前技術 方法之不良黏著性,且指示其藉由使用一組模具形成鏡片來獲得極佳黏著性,其中首先將AR塗層塗覆於一個模具上,且接著將鏡片單體傾倒於該等模具之間並進行聚合。諸如甲基丙烯醯氧基丙基三甲氧基矽烷之矽烷偶合劑可包括於硬塗層/AR塗層溶液中,其可含有膠態二氧化矽、膠態氧化銻或膠態二氧化鈦。 A plastic lens having an AR coating and/or a hard coat layer is disclosed in U.S. Patent No. 5,096,626 to the name of U.S. Pat. This patent discusses prior art The method has poor adhesion and indicates that it achieves excellent adhesion by forming a lens using a set of molds, wherein the AR coating is first applied to a mold and then the lens unit is poured between the molds And carry out the polymerization. A decane coupling agent such as methacryloxypropyltrimethoxydecane may be included in the hard coat layer/AR coating solution, which may contain colloidal cerium oxide, colloidal cerium oxide or colloidal titanium dioxide.
Klemm等人之美國專利第6,986,857號揭示用頂塗層、AR塗層、抗刮傷塗層、抗衝擊底塗劑及鏡片基底組裝鏡片之方法。Klemm對頂塗層與AR塗層之不良黏著性問題之解決方案為塗覆第一層AR塗層(其包含四層之堆疊)作為兩個SiO2子層。將另一SiO2薄層塗覆於AR堆疊與抗刮傷塗層之間以改良兩者之間的黏著性。 U.S. Patent No. 6,986,857 to Klemm et al. discloses a method of assembling a lens using a topcoat, an AR coating, an anti-scratch coating, an impact primer, and a lens substrate. Klemm the solution and the poor topcoat adhesion of the AR coating is a problem of a first coating layer AR coating layer (comprising a stack of four layers) as two sub-layer SiO. Another thin layer of SiO 2 was applied between the AR stack and the scratch resistant coating to improve the adhesion between the two.
以上參考文獻一般使用溶膠凝膠化學反應且需要高熱(80℃)。然而,加熱至高溫不適於用塑膠模具鑄造及固化鏡片,因為模具之光學表面將發生變形。 The above references generally use sol-gel chemical reactions and require high heat ( 80 ° C). However, heating to a high temperature is not suitable for casting and curing the lens with a plastic mold because the optical surface of the mold will be deformed.
因此,此項技術中存在有對解決前述缺點及不足之處而至今仍未解決之需要。 Therefore, there is a need in the art for solving the aforementioned shortcomings and deficiencies that have not yet been solved.
一方面,本發明係關於一種將抗反射(AR)塗層塗覆於諸如塑膠眼鏡片之塑膠基底上之方法,其中AR塗層展示與基底之良好黏著性,其中該方法消除初始SiO2或MgF2層與脫模劑層。目前可將超疏水性材料直接塗覆於模具表面上。 In one aspect, the invention relates to a method of applying an anti-reflective (AR) coating to a plastic substrate such as a plastic ophthalmic lens, wherein the AR coating exhibits good adhesion to the substrate, wherein the method eliminates initial SiO 2 or The MgF 2 layer and the release agent layer. Superhydrophobic materials can now be applied directly to the surface of the mold.
在一個實施例中,該方法包括以下步驟:提供具有光學表面之鏡片模具;於該光學表面上形成超疏水性材料 層,該形成係藉由將與一或多個含有超疏水性材料之坩堝接觸之熱舟加熱至約200℃與約500℃之間的溫度來實現,其中該超疏水性材料含有一定量之雙臂矽烷,該量為超疏水性材料之相對百分比;於該超疏水性材料層上形成AR塗層層狀結構;及在該AR塗層層狀結構上形成以單層厚度沈積之偶合劑層,該形成係在非質子性條件下使用氣相沈積或藉由使用偶合劑於非質子性溶劑中之溶液進行浸塗或旋塗來實現。在一個實施例中,藉由低電壓高安培數電流加熱熱舟。在另一個實施例中,藉由電子束加熱熱舟。在其他實施例中,使用加熱方法之組合。在一些實施例中,與熱舟接觸之坩堝含有吸附有超疏水性材料之陶瓷或金屬丸。 In one embodiment, the method comprises the steps of: providing a lens mold having an optical surface; forming a superhydrophobic material on the optical surface a layer formed by heating a hot boat in contact with one or more crucibles containing a superhydrophobic material to a temperature between about 200 ° C and about 500 ° C, wherein the superhydrophobic material contains a certain amount a double-armed decane, the amount being a relative percentage of the superhydrophobic material; forming an AR coating layered structure on the superhydrophobic material layer; and forming a coupling agent deposited on the AR coating layer structure in a single layer thickness The formation is carried out under aprotic conditions using vapor deposition or by dip coating or spin coating using a solution of a coupling agent in an aprotic solvent. In one embodiment, the hot boat is heated by a low voltage high amperage current. In another embodiment, the hot boat is heated by an electron beam. In other embodiments, a combination of heating methods is used. In some embodiments, the crucible in contact with the hot boat contains ceramic or metal pellets that are adsorbed with a superhydrophobic material.
在一個實施例中,雙臂矽烷之量為超疏水性材料之約1.7重量%-8.3重量%。 In one embodiment, the amount of the arms decane is from about 1.7 wt% to 8.3% wt% of the superhydrophobic material.
在一個實施例中,雙臂矽烷包含雙(三甲氧基矽烷基丙基)胺。 In one embodiment, the dual-arm decane comprises bis(trimethoxydecylpropyl)amine.
在一個實施例中,偶合劑層由包含環狀氮雜矽烷之組合物形成,其中偶合劑層由N-正丁基-氮雜-2,2-二甲氧基-矽雜環戊烷形成。在另一個實施例中,偶合劑層由包含雙臂矽烷之組合物形成。 In one embodiment, the coupler layer is formed from a composition comprising a cyclic azanonane wherein the coupler layer is formed from N-n-butyl-aza-2,2-dimethoxy-hydrazine heterocyclopentane . In another embodiment, the coupler layer is formed from a composition comprising dual-arm decane.
在一個實施例中,於層上形成AR塗層層狀結構之步驟進一步包含以下步驟:在超疏水性材料層上形成具有第一折射率且厚度為約5至100nm之第一材料之第一層;在第一層上形成具有高於第一折射率之第二折射率且厚度為約40至50nm之第二材料之第二層;在第二層上形成具有第一折射率且厚度為約10至20nm之第一材料之第三層;在第三 層上形成具有第二折射率且厚度為約50至70nm之第二材料之第四層;在第四層上形成具有第一折射率且厚度為約25至40nm之第一材料之第五層;在第五層上形成具有第二折射率且厚度為約10至25nm之第二材料之第六層;及在第六層上形成具有第一折射率且厚度為約5至15nm之第一材料之第七層,其中具有第一折射率之第一材料為SiO2,且具有第二折射率之第二材料為ZrO2。在一個實施例中,各SiO2層使用離子輔助或不使用離子輔助進行沈積。 In one embodiment, the step of forming an AR coating layer structure on the layer further comprises the step of forming a first material having a first refractive index and a thickness of about 5 to 100 nm on the superhydrophobic material layer. a second layer of a second material having a second refractive index higher than the first refractive index and having a thickness of about 40 to 50 nm is formed on the first layer; the first refractive index is formed on the second layer and the thickness is a third layer of a first material of about 10 to 20 nm; a fourth layer of a second material having a second refractive index and a thickness of about 50 to 70 nm formed on the third layer; and a first refraction formed on the fourth layer a fifth layer of a first material having a thickness of about 25 to 40 nm; a sixth layer having a second material having a second refractive index and a thickness of about 10 to 25 nm on the fifth layer; and a sixth layer A seventh layer having a first refractive index and a first material having a thickness of about 5 to 15 nm is formed, wherein the first material having the first refractive index is SiO 2 and the second material having the second refractive index is ZrO 2 . In one embodiment, each SiO 2 layer is deposited using ion assist or without ion assist.
在一個實施例中,該方法進一步包括在AR塗層層狀結構與超疏水性材料層之間形成SiO2層之步驟。 In one embodiment, the method further includes the step of forming a SiO 2 layer between the AR coating layer structure and the superhydrophobic material layer.
在另一個態樣中,本發明係關於一種具有有可轉移至鏡片之AR塗層之光學表面的模具。在一個實施例中,模具具有藉由將與一或多個含有超疏水性材料之坩堝接觸之熱舟加熱至約200℃與約500℃之間的溫度而於光學表面上所形成之超疏水性材料層,其中該超疏水性材料含有一定量之雙臂矽烷,該量為超疏水性材料之相對百分比;於該超疏水性材料層上所形成之AR塗層層狀結構;及在非質子性條件下使用氣相沈積或藉由浸塗或旋塗使用偶合劑於非質子性溶劑中之溶液以單層厚沈積於抗反射塗層層狀結構上之偶合劑層。 In another aspect, the invention is directed to a mold having an optical surface that can be transferred to an AR coating of a lens. In one embodiment, the mold has a superhydrophobic formation on the optical surface by heating a hot boat in contact with one or more crucibles containing the superhydrophobic material to a temperature between about 200 ° C and about 500 ° C. a layer of a material, wherein the superhydrophobic material contains a certain amount of double-arm decane, the amount being a relative percentage of the superhydrophobic material; an AR coating layered structure formed on the superhydrophobic material layer; A coupler layer deposited on the antireflective coating layer structure by a vapor deposition or a solution of a coupling agent in an aprotic solvent by dip coating or spin coating under proton conditions.
在一個實施例中,模具進一步包括在AR塗層層狀結構與超疏水性材料層之間所形成之SiO2層。 In one embodiment, the mold further includes a SiO 2 layer formed between the AR coating layered structure and the superhydrophobic material layer.
在一個實施例中,雙臂矽烷之量為超疏水性材料之約1.7重量%-8.3重量%。 In one embodiment, the amount of the arms decane is from about 1.7 wt% to 8.3% wt% of the superhydrophobic material.
在一個實施例中,AR塗層層狀結構包含在超疏水性材料層上所形成之具有第一折射率且厚度為約5至100 nm之第一材料之第一層;在第一層上所形成之具有高於第一折射率之第二折射率且厚度為約40至50nm之第二材料之第二層;在第二層上所形成之具有第一折射率且厚度為約10至20nm之第一材料之第三層;在第三層上所形成之具有第二折射率且厚度為約50至70nm之第二材料之第四層;在第四層上所形成之具有第一折射率且厚度為約25至40nm之第一材料之第五層;在第五層上所形成之具有第二折射率且厚度為約10至25nm之第二材料之第六層;及在第六層上所形成之具有第一折射率且厚度為約5至15nm之第一材料之第七層。在一個實施例中,具有第一折射率之第一材料為SiO2,且具有第二折射率之第二材料為ZrO2。在一個實施例中,各SiO2層使用離子輔助或不使用離子輔助進行沈積。 In one embodiment, the AR coating layered structure comprises a first layer of a first material having a first index of refraction and a thickness of between about 5 and 100 nm formed on the layer of superhydrophobic material; on the first layer a second layer formed of a second material having a second refractive index higher than the first refractive index and having a thickness of about 40 to 50 nm; having a first refractive index formed on the second layer and having a thickness of about 10 to a third layer of a first material of 20 nm; a fourth layer of a second material having a second refractive index and having a thickness of about 50 to 70 nm formed on the third layer; and having a first layer formed on the fourth layer a fifth layer of a first material having a refractive index and a thickness of about 25 to 40 nm; a sixth layer of a second material having a second refractive index and having a thickness of about 10 to 25 nm formed on the fifth layer; A seventh layer of the first material having a first refractive index and a thickness of about 5 to 15 nm formed on the six layers. In one embodiment, the first material having a first index of refraction is SiO 2 and the second material having a second index of refraction is ZrO 2 . In one embodiment, each SiO 2 layer is deposited using ion assist or without ion assist.
在一個實施例中,雙臂矽烷包含雙(三甲氧基矽烷基丙基)胺。 In one embodiment, the dual-arm decane comprises bis(trimethoxydecylpropyl)amine.
在一個實施例中,偶合劑層由包含環狀氮雜矽烷之組合物形成。在一個實施例中,偶合劑層由N-正丁基-氮雜-2,2-二甲氧基-矽雜環戊烷形成。 In one embodiment, the coupler layer is formed from a composition comprising a cyclic azanonane. In one embodiment, the coupler layer is formed from N-n-butyl-aza-2,2-dimethoxy-hydrazine heterocyclopentane.
在另一個態樣中,本發明係關於一種由具有光學表面之模具製造之光學鏡片。在一個實施例中,光學鏡片具有有光學表面之鏡片主體;處於鏡片主體之光學表面上之硬塗層;及AR塗層。AR塗層包括藉由將與一或多個含有超疏水性材料之坩堝接觸之熱舟加熱至約200℃與約500℃之間的溫度於模具之光學表面上所形成之超疏水性材料層,其中該超疏水性材料含有一定量之雙臂矽烷,該量為超疏水性材料之相對百分比;於該超疏水性材料層上所形成之抗反射塗層 層狀結構;及在該抗反射塗層層狀結構上以單層厚度沈積之偶合劑層。硬塗層實質上與抗反射塗層之偶合劑層接觸。 In another aspect, the invention is directed to an optical lens made from a mold having an optical surface. In one embodiment, the optical lens has a lens body having an optical surface; a hard coating on the optical surface of the lens body; and an AR coating. The AR coating comprises a layer of superhydrophobic material formed by heating a hot boat in contact with one or more crucibles containing a superhydrophobic material to a temperature between about 200 ° C and about 500 ° C on the optical surface of the mold. Wherein the superhydrophobic material contains a quantity of double-armed decane, the amount being a relative percentage of the superhydrophobic material; an anti-reflective coating formed on the superhydrophobic material layer a layered structure; and a coupler layer deposited on the antireflective coating layer structure in a single layer thickness. The hard coat layer is in substantial contact with the coupler layer of the anti-reflective coating.
在一個實施例中,AR塗層層狀結構包含在超疏水性材料層上所形成之具有第一折射率且厚度為約5至100nm之第一材料之第一層;在第一層上所形成之具有高於第一折射率之第二折射率且厚度為約40至50nm之第二材料之第二層;在第二層上所形成之具有第一折射率且厚度為約10至20nm之第一材料之第三層;在第三層上所形成之具有第二折射率且厚度為約50至70nm之第二材料之第四層;在第四層上所形成之具有第一折射率且厚度為約25至40nm之第一材料之第五層;在第五層上所形成之具有第二折射率且厚度為約10至25nm之第二材料之第六層;及在第六層上所形成之具有第一折射率且厚度為約5至15nm之第一材料之第七層。在一個實施例中,具有第一折射率之第一材料為SiO2,且具有第二折射率之第二材料為ZrO2。在一個實施例中,各SiO2層使用離子輔助或不使用離子輔助進行沈積。 In one embodiment, the AR coating layered structure comprises a first layer of a first material having a first index of refraction and a thickness of between about 5 and 100 nm formed on the layer of superhydrophobic material; Forming a second layer of a second material having a second refractive index higher than the first refractive index and having a thickness of about 40 to 50 nm; forming the first refractive index on the second layer and having a thickness of about 10 to 20 nm a third layer of the first material; a fourth layer of a second material having a second refractive index and a thickness of about 50 to 70 nm formed on the third layer; and a first refraction formed on the fourth layer a fifth layer of a first material having a thickness of about 25 to 40 nm; a sixth layer of a second material having a second refractive index and having a thickness of about 10 to 25 nm formed on the fifth layer; and A seventh layer of the first material having a first refractive index and a thickness of about 5 to 15 nm formed on the layer. In one embodiment, the first material having a first index of refraction is SiO 2 and the second material having a second index of refraction is ZrO 2 . In one embodiment, each SiO 2 layer is deposited using ion assist or without ion assist.
在一個實施例中,雙臂矽烷之量為超疏水性材料之約1.7重量%-8.3重量%。 In one embodiment, the amount of the arms decane is from about 1.7 wt% to 8.3% wt% of the superhydrophobic material.
在一個實施例中,雙臂矽烷包含雙(三甲氧基矽烷基丙基)胺。 In one embodiment, the dual-arm decane comprises bis(trimethoxydecylpropyl)amine.
在一個實施例中,偶合劑層由包含環狀氮雜矽烷之組合物形成。在一個實施例中,偶合劑層由N-正丁基-氮雜-2,2-二甲氧基-矽雜環戊烷形成。 In one embodiment, the coupler layer is formed from a composition comprising a cyclic azanonane. In one embodiment, the coupler layer is formed from N-n-butyl-aza-2,2-dimethoxy-hydrazine heterocyclopentane.
在一個實施例中,光學鏡片進一步包含在AR塗層層狀結構與超疏水性材料層之間所形成之SiO2層。 In one embodiment, the optical lens further comprises an SiO 2 layer formed between the AR coating layer structure and the superhydrophobic material layer.
在另一個態樣中,本發明係關於一種將AR塗層塗覆於模具之光學表面上之方法。在一個實施例中,該方法包括以下步驟:提供具有光學表面之鏡片模具;於該光學表面上形成超疏水性材料層,其中該超疏水性材料含有一定量之雙臂矽烷,該量為超疏水性材料之相對百分比;於該超疏水性材料層上形成AR塗層層狀結構;及在該AR塗層層狀結構上形成以單層厚度沈積之偶合劑層,該形成係在非質子性條件下使用氣相沈積或藉由使用偶合劑於非質子性溶劑中之溶液進行浸塗或旋塗來實現。在一個實施例中,雙臂矽烷之量為超疏水性材料之約1.7重量%-8.3重量%。 In another aspect, the invention is directed to a method of applying an AR coating to an optical surface of a mold. In one embodiment, the method comprises the steps of: providing a lens mold having an optical surface; forming a layer of superhydrophobic material on the optical surface, wherein the superhydrophobic material contains a quantity of arms decane, the amount being super a relative percentage of the hydrophobic material; forming an AR coating layered structure on the superhydrophobic material layer; and forming a coupling layer deposited on the AR coating layer structure in a single layer thickness, the formation being in the aprotic This is accomplished by dip coating or spin coating using a vapor deposition or a solution using a coupling agent in an aprotic solvent. In one embodiment, the amount of the arms decane is from about 1.7 wt% to 8.3% wt% of the superhydrophobic material.
在一個實施例中,於層上形成AR塗層層狀結構之步驟進一步包含以下步驟:在超疏水性材料層上形成具有第一折射率之第一材料之第一層;在第一層上形成具有第二折射率之第二材料之第二層;在第二層上形成具有第一折射率之第一材料之第三層;在第三層上形成具有第二折射率之第二材料之第四層;在第四層上形成具有第一折射率之第一材料之第五層;在第五層上形成具有第二折射率之第二材料之第六層;及在第六層上形成具有第一折射率之第一材料之第七層。在一個實施例中,第一折射率及第二折射率滿足H/L之比率>1,其中L及H分別為第一及第二折射率之值。在一個實施例中,具有第一折射率之第一材料為SiO2,且具有第二折射率之第二材料為ZrO2。 In one embodiment, the step of forming an AR coating layered structure on the layer further comprises the steps of: forming a first layer of a first material having a first index of refraction on the layer of superhydrophobic material; Forming a second layer of a second material having a second index of refraction; forming a third layer of a first material having a first index of refraction on the second layer; forming a second material having a second index of refraction on the third layer a fourth layer; a fifth layer of a first material having a first refractive index formed on the fourth layer; a sixth layer of a second material having a second refractive index formed on the fifth layer; and a sixth layer A seventh layer of a first material having a first refractive index is formed thereon. In one embodiment, the first index of refraction and the second index of refraction satisfy a ratio of H/L > 1, wherein L and H are values of the first and second indices of refraction, respectively. In one embodiment, the first material having a first index of refraction is SiO 2 and the second material having a second index of refraction is ZrO 2 .
在一個實施例中,偶合劑層由包含環狀氮雜矽烷之組合物形成。 In one embodiment, the coupler layer is formed from a composition comprising a cyclic azanonane.
在一個實施例中,於光學表面上形成超疏水性材 料層之步驟包含加熱與一或多個含有超疏水性材料之坩堝接觸之熱舟。在一個實施例中,加熱步驟包含將熱舟加熱至約200℃與約500℃之間的溫度。 In one embodiment, a superhydrophobic material is formed on the optical surface The step of layering comprises heating a hot boat in contact with one or more crucibles containing a superhydrophobic material. In one embodiment, the heating step comprises heating the hot boat to a temperature between about 200 ° C and about 500 ° C.
在又一態樣中,本發明係關於一種具有有可轉移至鏡片之AR塗層之光學表面的模具。在一個實施例中,模具具有於光學表面上所形成之超疏水性材料層,其中該超疏水性材料含有一定量之雙臂矽烷,該量為超疏水性材料之相對百分比;於該超疏水性材料層上所形成之AR塗層層狀結構;及在非質子性條件下使用氣相沈積或藉由浸塗或旋塗使用偶合劑於非質子性溶劑中之溶液在該AR塗層層狀結構上以單層厚度沈積之偶合劑層。在一個實施例中,雙臂矽烷之量為超疏水性材料之約1.7重量%-8.3重量%。 In yet another aspect, the present invention is directed to a mold having an optical surface that can be transferred to an AR coating of a lens. In one embodiment, the mold has a layer of superhydrophobic material formed on the optical surface, wherein the superhydrophobic material contains a quantity of double-armed decane, the amount being a relative percentage of the superhydrophobic material; An AR coating layered structure formed on a layer of a material; and a solution of a coupling agent in an aprotic solvent using a vapor deposition or a dip coating or spin coating under aprotic conditions in the AR coating layer A layer of coupler deposited in a single layer thickness. In one embodiment, the amount of the arms decane is from about 1.7 wt% to 8.3% wt% of the superhydrophobic material.
在一個實施例中,藉由在一定溫度下加熱與一或多個含有超疏水性材料之坩堝接觸之熱舟於光學表面上形成超疏水性材料層,其中該溫度在約200℃與約500℃之間。 In one embodiment, the superhydrophobic material layer is formed on the optical surface by heating a hot boat in contact with one or more crucibles containing a superhydrophobic material at a temperature, wherein the temperature is between about 200 ° C and about 500. Between °C.
在一個實施例中,AR塗層層狀結構包含在超疏水性材料層上所形成之具有第一折射率之第一材料之第一層;在第一層上所形成之具有第二折射率之第二材料之第二層;在第二層上所形成之具有第一折射率之第一材料之第三層;在第三層上所形成之具有第二折射率之第二材料之第四層;在第四層上所形成之具有第一折射率之第一材料之第五層;在第五層上所形成之具有第二折射率之第二材料之第六層;及在第六層上所形成之具有第一折射率之第一材料之第七層。在一個實施例中,第一折射率及第二折射率滿足H/L之比率>1,其中L及H分別為第一及第二折射率之值。在一 個實施例中,具有第一折射率之第一材料為SiO2,且具有第二折射率之第二材料為ZrO2。 In one embodiment, the AR coating layered structure comprises a first layer of a first material having a first index of refraction formed on the layer of superhydrophobic material; a second index of refraction formed on the first layer a second layer of the second material; a third layer of the first material having the first refractive index formed on the second layer; and a second material having the second refractive index formed on the third layer a fourth layer; a fifth layer of a first material having a first refractive index formed on the fourth layer; a sixth layer of a second material having a second refractive index formed on the fifth layer; and A seventh layer of the first material having a first refractive index formed on the six layers. In one embodiment, the first index of refraction and the second index of refraction satisfy a ratio of H/L > 1, wherein L and H are values of the first and second indices of refraction, respectively. In one embodiment, the first material having a first index of refraction is SiO 2 and the second material having a second index of refraction is ZrO 2 .
在一個實施例中,偶合劑層由包含環狀氮雜矽烷之組合物形成。 In one embodiment, the coupler layer is formed from a composition comprising a cyclic azanonane.
一方面,本發明係關於一種由具有光學表面之模具製造之光學鏡片。在一個實施例中,光學鏡片具有有光學表面之鏡片主體;處於鏡片主體之光學表面上之硬塗層;及AR塗層。AR塗層包括於模具之光學表面上所形成之超疏水性材料層,其中該超疏水性材料含有一定量之雙臂矽烷,該量為超疏水性材料之相對百分比;於該超疏水性材料層上所形成之抗反射塗層層狀結構;及在該抗反射塗層層狀結構上以單層厚度沈積之偶合劑層。硬塗層實質上與抗反射塗層之偶合劑層接觸。 In one aspect, the invention relates to an optical lens made from a mold having an optical surface. In one embodiment, the optical lens has a lens body having an optical surface; a hard coating on the optical surface of the lens body; and an AR coating. The AR coating comprises a layer of superhydrophobic material formed on the optical surface of the mold, wherein the superhydrophobic material contains a quantity of double-arm decane, the amount being a relative percentage of the superhydrophobic material; and the superhydrophobic material An anti-reflective coating layered structure formed on the layer; and a coupler layer deposited on the anti-reflective coating layer structure in a single layer thickness. The hard coat layer is in substantial contact with the coupler layer of the anti-reflective coating.
在一個實施例中,藉由在一定溫度下加熱與一或多個含有超疏水性材料之坩堝接觸之熱舟於鏡片模具之光學表面上形成超疏水性材料層。在一個實施例中,溫度在約200℃與約500℃之間。 In one embodiment, a layer of superhydrophobic material is formed on the optical surface of the lens mold by heating a heated boat in contact with one or more crucibles containing a superhydrophobic material at a temperature. In one embodiment, the temperature is between about 200 ° C and about 500 ° C.
在一個實施例中,雙臂矽烷之量為超疏水性材料之約1.7重量%-8.3重量%。 In one embodiment, the amount of the arms decane is from about 1.7 wt% to 8.3% wt% of the superhydrophobic material.
在一個實施例中,AR塗層層狀結構包含在超疏水性材料層上所形成之具有第一折射率之第一材料之第一層;在第一層上所形成之具有第二折射率之第二材料之第二層;在第二層上所形成之具有第一折射率之第一材料之第三層;在第三層上所形成之具有第二折射率之第二材料之第四層;在第四層上所形成之具有第一折射率之第一材料之第五 層;在第五層上所形成之具有第二折射率之第二材料之第六層;及在第六層上所形成之具有第一折射率之第一材料之第七層。在一個實施例中,第一折射率及第二折射率滿足H/L之比率>1,其中L及H分別為第一及第二折射率之值。在一個實施例中,具有第一折射率之第一材料為SiO2,且具有第二折射率之第二材料為ZrO2。 In one embodiment, the AR coating layered structure comprises a first layer of a first material having a first index of refraction formed on the layer of superhydrophobic material; a second index of refraction formed on the first layer a second layer of the second material; a third layer of the first material having the first refractive index formed on the second layer; and a second material having the second refractive index formed on the third layer a fourth layer; a fifth layer of a first material having a first refractive index formed on the fourth layer; a sixth layer of a second material having a second refractive index formed on the fifth layer; and A seventh layer of the first material having a first refractive index formed on the six layers. In one embodiment, the first index of refraction and the second index of refraction satisfy a ratio of H/L > 1, wherein L and H are values of the first and second indices of refraction, respectively. In one embodiment, the first material having a first index of refraction is SiO 2 and the second material having a second index of refraction is ZrO 2 .
在一個實施例中,偶合劑層由包含環狀氮雜矽烷之組合物形成。 In one embodiment, the coupler layer is formed from a composition comprising a cyclic azanonane.
由結合以下圖式獲得之以下較佳實施例之描述,本發明之此等及其他態樣將顯而易知,但可在不背離本發明之新穎概念的精神及範疇之情況下實現其中之變化及修改。 These and other aspects of the present invention will be apparent from the following description of the preferred embodiments of the invention. Changes and modifications.
402‧‧‧模具 402‧‧‧Mold
404‧‧‧光學表面 404‧‧‧Optical surface
406‧‧‧超疏水性材料層 406‧‧‧Superhydrophobic material layer
410‧‧‧SiO2層 410‧‧‧SiO 2 layer
411‧‧‧抗反射塗層層狀結構 411‧‧‧Anti-reflective coating layered structure
412‧‧‧SiO2層/第一層 412‧‧‧SiO 2 layer / first layer
414‧‧‧ZrO2層/第二層 414‧‧‧ZrO 2nd floor / second floor
416‧‧‧SiO2層/第三層 416‧‧‧SiO 2 layer / third layer
418‧‧‧ZrO2層/第四層 418‧‧‧ZrO 2nd /4th Floor
420‧‧‧SiO2層/第五層 420‧‧‧SiO 2 layer / 5th floor
422‧‧‧ZrO2層/第六層 422‧‧‧ZrO 2 /6th Floor
424‧‧‧SiO2層/第七層 424‧‧‧SiO 2 / seventh
426‧‧‧偶合劑層 426‧‧‧ coupling layer
502‧‧‧模具 502‧‧‧Mold
504‧‧‧光學表面 504‧‧‧Optical surface
506‧‧‧超疏水性材料層 506‧‧‧Superhydrophobic material layer
510‧‧‧SiO2層 510‧‧‧SiO 2 layer
511‧‧‧抗反射塗層層狀結構 511‧‧‧Anti-reflective coating layered structure
512‧‧‧SiO2層/第一層 512‧‧‧SiO 2 layer / first layer
514‧‧‧ZrO2層/第二層 514‧‧‧ZrO 2 /Second
516‧‧‧SiO2層/第三層 516‧‧‧SiO 2 / third layer
518‧‧‧ZrO2層/第四層 518‧‧‧ZrO 2nd /4th floor
520‧‧‧SiO2層/第五層 520‧‧‧SiO 2 / 5th floor
522‧‧‧ZrO2層/第六層 522‧‧‧ZrO 2 /6th Floor
524‧‧‧SiO2層/第七層 524‧‧‧SiO 2 / seventh
526‧‧‧偶合劑層 526‧‧‧ coupling layer
隨附圖式說明本發明之一或多個實施例,且連同書面描述一起用以解釋本發明之原理。只要有可能,整個圖式中使用相同元件符號指示實施例之相同或類似元件。 One or more embodiments of the present invention are described with reference to the accompanying drawings, and, Wherever possible, the same reference numerals are in the
圖1展示先前技術中用於製造抗反射塗佈之鏡片之偶合劑相關化學反應的示意圖。 BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a schematic illustration of a coupling agent related chemical reaction used in the manufacture of antireflective coated lenses of the prior art.
圖2展示根據本發明之一個實施例中用於製造抗反射塗佈之鏡片之偶合劑相關化學反應的示意圖。 2 shows a schematic diagram of a coupling-related chemical reaction for making an anti-reflective coated lens in accordance with one embodiment of the present invention.
圖3展示根據本發明之實施例中AR塗層及所得鏡片對塗覆超疏水性層之溫度依賴性的示意圖。 Figure 3 shows a schematic representation of the temperature dependence of the AR coating and the resulting lens on the coating of the superhydrophobic layer in accordance with an embodiment of the present invention.
圖4展示根據本發明之一個實施例之抗反射塗佈之鏡片模具製備的示意圖。 4 shows a schematic diagram of the preparation of an anti-reflective coated lens mold in accordance with one embodiment of the present invention.
圖5展示根據本發明之一個實施例之抗反射塗佈之鏡片 模具製備的示意圖。 Figure 5 shows an anti-reflective coated lens in accordance with one embodiment of the present invention. Schematic diagram of mold preparation.
以下參考隨附圖式充分地描述本發明,在該等隨附圖式中展示本發明之例示性實施例。然而,本發明可以許多不同形式加以體現,不應視為限於本文中所闡述之實施例。相反地,提供此等實施例係用以便於本發明詳盡且完整,且向熟習此技藝人士充分傳達本發明之範疇。通篇中相似元件符號係指相似元件。 The invention is described in the following with reference to the accompanying drawings, in which, FIG. However, the invention may be embodied in many different forms and should not be construed as being limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete. Similar component symbols throughout the specification refer to similar components.
本說明書所使用之術語一般具有其在此項技術中、在本發明之內容內及在使用每一術語之特定內容中之普通意義。用以描述本發明之某些術語在以下或本說明書中之其他處論述以對實踐者提供關於本發明之描述之額外指導。為方便起見,本說明書中可例如使用斜體字及/或引號突出某些術語。使用突出與否對術語範疇及含義沒有影響;在相同內容中不論術語是否突出,其範疇及含義均相同。應注意的是,相同特徵或情況可以一種以上方式表達。因此,本文所討論之任一或多個術語,均可使用替代術語及同義詞進行描述,且無論術語在本文中是否詳細描述或討論,使用替代術語及同義詞均不具有任何特殊含義。某些術語提供同義詞,敍述一或多個同義詞並不排除使用其他同義詞。本說明書中任一實例(包括本文中論述的任一術語之實例)之使用僅為說明性質,且並非用以限制本發明或任一例示術語之範疇及意義。同樣地,本發明並不限於本說明書中給出之各種實施例。 The terms used in the specification generally have their ordinary meaning in the art, within the scope of the invention, and in the specific content of each term. Certain terms used to describe the invention are discussed below or elsewhere in this specification to provide additional guidance to the practitioner regarding the description of the invention. For convenience, certain terms may be highlighted in this specification, for example, in italics and/or quotation marks. The use of highlighting has no effect on the terminology and meaning of the term; in the same content, regardless of whether the term is prominent, its scope and meaning are the same. It should be noted that the same features or circumstances may be expressed in more than one manner. Thus, any one or more of the terms discussed herein may be described using alternative terms and synonyms, and no matter whether the terms are described or discussed in detail herein, the use of alternative terms and synonyms does not have any particular meaning. Certain terms are provided synonymously, and the use of one or more synonyms does not exclude the use of other synonyms. The use of any of the examples in this specification, including examples of any of the terms discussed herein, is merely illustrative and is not intended to limit the scope and meaning of the invention or any exemplified term. As such, the invention is not limited to the various embodiments presented in this specification.
應注意的是,當一元件被稱為「在另一元件上」 時,其可直接位於其他元件之上或其間可存在介入元件。相反地,當一元件被稱為「直接在另一元件上」時,不存在介入元件。如本文中所使用,術語「及/或」包括關聯列出項目中之一或多者的任何及所有組合。 It should be noted that when one component is called "on another component" In this case, the intervening elements may be present directly on or between other components. Conversely, when an element is referred to as "directly on the other element," the intervening element is absent. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.
應理解,儘管本說明書中可使用術語「第一」、「第二」、「第三」等等來描述各種元件、組件、區域、層及/或區段,但此等元件、組件、區域、層及/或區段不應受此等術語限制。此等術語僅用以區分一個元件、組件、區域、層或區段與另一元件、組件、區域、層或區段。因此,在不背離本發明之揭示之情況下,下文所論述之第一元件、組件、區域、層或區段可稱為第二元件、組件、區域、層或區段。 It will be understood that, although the terms "first", "second", "third", etc. may be used in the specification to describe various elements, components, regions, layers and/or sections, such elements, components, and regions , layers and/or sections are not limited by these terms. The terms are only used to distinguish one element, component, region, layer or section from another element, component, region, layer or section. Thus, a first element, component, region, layer or section discussed hereinafter may be referred to as a second element, component, region, layer or section, without departing from the disclosure.
本說明書所使用之術語僅係出於描述特定實施例之目的,且不意欲限制本發明。除非上下文另外明確指示,否則如本文所用之單數形式「一(a/an)」及「該(the)」意欲亦包括複數形式。進一步將理解,術語「包含(comprises/comprising)」或「包括(includes/including)」或「具有(has/having)」在用於本說明書中時表示存在所述特徵、區域、整數、步驟、操作、元件及/或組件,但不妨礙存在或添加一或多個其他特徵、區域、整數、步驟、操作、元件、組件及/或其群組。 The terminology used in the description is for the purpose of describing particular embodiments, and is not intended to limit the invention. The singular forms "a", "the" and "the" are intended to include the plural. It will be further understood that the terms "comprises/comprising" or "includes/including" or "has/having" when used in this specification means that the features, regions, integers, steps, The operation, the components, and/or the components, but do not preclude the presence or addition of one or more other features, regions, integers, steps, operations, components, components and/or groups thereof.
此外,相對術語,諸如「下」或「底」、「上」或「頂」及「左」及「右」本文中可用以描述如圖所示一個元件與另一個元件之關係。應理解,除了圖式中所描述之取向以外,相對術語意欲亦涵蓋裝置之不同取向。舉例而言,若將一個圖式中之裝置翻過來,則描述為在其他元件之「下」側 上之元件將取向於其他元件之「上」側上。因此,根據圖式之特定取向,例示性術語「下」可涵蓋「下」及「上」取向。類似地,若一個圖式中之裝置翻過來,則描述為「在其他元件以下」或「在其他元件之下」的元件將取向為「在其他元件之上」。因此,例示性術語「在......以下」或「在......之下」可涵蓋在......之上與在......以下之取向。 In addition, relative terms such as "lower" or "bottom", "upper" or "top" and "left" and "right" may be used herein to describe the relationship of one element to another. It will be understood that the relative terms are intended to encompass different orientations of the device in addition to the orientations described in the drawings. For example, if the device in one figure is turned over, it is described as being on the "lower" side of the other components. The components above will be oriented on the "upper" side of the other components. Therefore, the exemplary term "lower" can encompass the "lower" and "upper" orientations, depending on the particular orientation of the drawings. Similarly, if the device in one of the figures is turned over, the element described as "below the other elements" or "under the other elements" will be oriented "above the other elements." Thus, the exemplified terms "below" or "under" can encompass the <RTIgt;
除非另外定義,否則本說明書所使用之所有術語(包括技術及科學術語)具均有與一般本發明所屬技術之熟習此技藝人士通常所理解之含義相同的含義。應進一步理解,術語(諸如常用辭典中所定義之術語)應被解釋為具有與其在相關技術及本發明之內容中之含義一致的含義,且不應在理想化或過度形式化之意義上加以解釋,除非本文中明確地如此定義。 Unless otherwise defined, all terms (including technical and scientific terms) used in the specification have the same meaning meaning meaning It should be further understood that terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with their meaning in the relevant art and the teachings of the present invention, and should not be construed in the sense of idealization or over-formalization. Explain, unless explicitly defined as such herein.
如本說明書所用,「大約」、「約」或「大致」一般應意謂在給定值或範圍之20%內、較佳10%內且更佳5%內。本文中給出之數量為近似數量,意謂若未明確陳述,則可推斷術語「大約」、「約」或「大致」。 As used in this specification, "about", "about" or "substantially" shall generally mean within 20%, preferably within 10% and more preferably within 5% of a given value or range. The quantities given herein are approximate quantities, meaning that the term "about", "about" or "roughly" can be inferred if not explicitly stated.
如本說明書所用,術語「包含(comprise/comprising)」、「包括(include/including)」、「帶有(carry/carrying)」、「具有(has/have/having)」、「含有(contain/containing)」、「涉及(involve/involving)」及其類似術語應理解為開放的,亦即,意謂包括(但不限於)。 As used in this specification, the terms "comprise/comprising", "include/including", "carry/carrying", "having (has/have/having)", "containing (contain/) ""involved/involving" and the like should be understood to be open, that is, meant to include (but not limited to).
以下將根據圖1-5中之隨附圖式對本發明之實施例進行描述。根據本發明之目的,如本文所體現及大致描述, 本發明係關於塗佈AR之眼鏡鏡片、製造AR鏡片之模具、組合物及方法。 Embodiments of the present invention will be described below with reference to the accompanying drawings in FIGS. 1-5. In accordance with the purpose of the present invention, as embodied and broadly described herein, The present invention relates to an eyeglass lens for coating AR, a mold, a composition and a method for manufacturing an AR lens.
以全文引用的方式併入本文中之本源美國申請案第13/088,199號中所述之先前程序需要脫膜劑層(標準疏水性層)及處於疏水性材料與模具之間的SiO2或MgF2層。 Incorporated in its entirety by reference herein, the origin of U.S. Application No. 13 / 088,199 in the previous application requires the removal agent layer (standard hydrophobic layer) and a SiO is between the hydrophobic material and the mold 2 or MgF 2 layers.
然而,根據本發明之各種實施例,藉由控制塗覆超疏水性材料之溫度,可消除初始SiO2或MgF2層與脫模劑層。可將超疏水性材料直接塗覆於模具表面。說明書之實例中所用之超疏水性材料為(但不限於)Daikin Optool DSX。應注意的是,亦可利用其他超疏水性材料以實踐本發明。 However, according to various embodiments of the present invention, the initial SiO 2 or MgF 2 layer and the release agent layer can be eliminated by controlling the temperature at which the superhydrophobic material is applied. Superhydrophobic materials can be applied directly to the mold surface. The superhydrophobic material used in the examples of the specification is, but not limited to, Daikin Optool DSX. It should be noted that other superhydrophobic materials may also be utilized to practice the invention.
在一個實施例中,在小於540℃下(如在熱舟上所量測)塗覆超疏水性材料。較佳溫度範圍為約250-500℃。 In one embodiment, the superhydrophobic material is coated at less than 540 ° C (as measured on a hot boat). A preferred temperature range is from about 250 to 500 °C.
超疏水性層之厚度可為20nm至100nm中之任何值,較佳厚度為40nm。 The superhydrophobic layer may have any thickness from 20 nm to 100 nm, preferably 40 nm.
根據本發明之實施例,仍需要雙臂物以使超疏水性層穩定。將雙臂物以及超疏水性材料置於丸中,且將其一起塗覆。在一個實施例中,在Satis 1200腔室中,與超疏水性材料混合之雙臂物之量必須在每丸0.01g與0.1g之間。在單次運作中使用兩個丸。雙臂物之較佳重量(對40nm超疏水性層而言)為每丸0.04g。 According to embodiments of the invention, there is still a need for arms to stabilize the superhydrophobic layer. The arms and superhydrophobic material are placed in the pellets and coated together. In one embodiment, the amount of the arms that are mixed with the superhydrophobic material must be between 0.01 g and 0.1 g per pill in the Satis 1200 chamber. Use two pills in a single run. The preferred weight of the arms (for a 40 nm superhydrophobic layer) was 0.04 g per pill.
雙臂矽烷可購自Gelest,Inc。較佳雙臂矽烷可為具有下式之雙(三甲氧基矽烷基丙基)胺:
在一個實施例中,超疏水性材料含有以超疏水性材料計約1.7重量%-8.3重量%之雙臂矽烷。 In one embodiment, the superhydrophobic material contains from about 1.7% to about 8.3 weight percent of the cobine in terms of the superhydrophobic material.
模具上之超疏水性層並非脫模劑層。在鏡片鑄造及固化期間超疏水性層轉移鏡片至並變為鏡片之一部分。 The superhydrophobic layer on the mold is not a release agent layer. The superhydrophobic layer transfers the lens to and becomes part of the lens during lens casting and curing.
在超疏水性塗層之後,塗覆抗反射(AR)塗層。AR塗層為具有藉由真空沈積塗覆之多層介電材料之層狀結構(4至7層或甚至7層以上),以使得最後一層為離子輔助SiO2。較佳地,AR塗層為具有多層有三種或三種以上具有交替高及低折射率之介電材料的層狀結構。 After the superhydrophobic coating, an anti-reflective (AR) coating is applied. The AR coating is a layered structure (4 to 7 layers or even 7 or more layers) having a multilayer dielectric material coated by vacuum deposition such that the last layer is ion-assisted SiO 2 . Preferably, the AR coating is a layered structure having a plurality of layers of three or more dielectric materials having alternating high and low refractive indices.
將矽烷偶合劑層塗覆於塗佈AR之模具上以促進硬塗層之黏附。偶合劑層必須在非質子性條件下進行塗覆。此舉可使用現今常用於鏡片行業之方法(諸如旋塗、噴塗、浸塗、真空塗佈)進行。在室溫下塗覆偶合劑層。矽烷偶合劑可為雙臂矽烷。或者,矽烷偶合劑為環狀氮雜矽烷。分別地,來自環狀氮雜矽烷之矽烷將結合於AR塗層且官能基將與有機硬塗層結合。 A layer of decane coupling agent is applied to the AR coated mold to promote adhesion of the hard coat layer. The coupler layer must be coated under aprotic conditions. This can be done using methods commonly used in the lens industry today (such as spin coating, spray coating, dip coating, vacuum coating). The coupler layer was applied at room temperature. The decane coupling agent can be a double-arm decane. Alternatively, the decane coupling agent is a cyclic azanonane. Separately, the decane from the cyclic azanonane will bind to the AR coating and the functional groups will bond to the organic hardcoat.
下一個塗覆於模具之塗層為抗刮傷(硬)塗層。硬塗層可藉由鏡片行業中習用之方法進行塗覆,包括旋塗、噴塗或浸塗,之後進行固化。 The next coating applied to the mold is a scratch resistant (hard) coating. The hard coat layer can be applied by conventional methods in the lens industry, including spin coating, spray coating or dip coating, followed by curing.
可將上文所示之例示性製程反覆施用於含有前模具及後模具之光學模具總成之不同光學表面。在將塗層塗覆於前及後模具之後,用墊圈組裝模具形成光學模具總成。接著總成之腔室充滿鏡片材料調配物並固化。在固化完成之後,自總成移除鏡片。將所有塗層轉移至鏡片使得鏡片塗覆有超疏水性、抗反射且抗刮傷塗層。亦可使用此製程製造偏 光及光色鏡片。 The exemplary process illustrated above can be applied over the different optical surfaces of the optical mold assembly containing the front and back molds. After the coating is applied to the front and back molds, the mold is assembled with a gasket to form an optical mold assembly. The chamber of the assembly is then filled with the lens material formulation and cured. After curing is complete, the lens is removed from the assembly. Transferring all of the coating to the lens allows the lens to be coated with a superhydrophobic, anti-reflective, and scratch resistant coating. Can also use this process to create partial Light and light color lenses.
因此,一方面,更特定言之,本發明係關於一種製造具有良好AR塗層黏著性之塗佈AR之塑膠基底之方法。在一個實施例中,塑膠基底為塑膠眼鏡鏡片。 Thus, in one aspect, more particularly, the present invention relates to a method of making a AR coated plastic substrate having good AR coating adhesion. In one embodiment, the plastic substrate is a plastic eyeglass lens.
在另一個態樣中,本發明係關於一種現場製造塗佈AR之塑膠眼鏡鏡片之方法。 In another aspect, the invention is directed to a method of fabricating an AR coated plastic spectacle lens in situ.
通常將AR塗層塗覆於鏡片表面以減少反射。通常,AR塗層由多個高折射率及低折射率材料(諸如ZrO2及SiO2)層製成。關於無機二氧化矽AR塗層之一個問題為其不易黏著於塑膠有機鏡片。本發明藉由尤其在無機二氧化矽AR塗層與鏡片之間使用偶合層成功地解決該問題。在本發明之一個實施例中,偶合層利用環狀氮雜矽烷形成。在另一個實施例中,偶合層利用雙臂矽烷形成。 The AR coating is typically applied to the lens surface to reduce reflection. Typically, the AR coating is made of a plurality of layers of high refractive index and low refractive index materials such as ZrO 2 and SiO 2 . One problem with inorganic ruthenium oxide AR coatings is that they are not easily adhered to plastic organic lenses. The present invention successfully solves this problem by using a coupling layer, inter alia, between the inorganic cerium oxide AR coating and the lens. In one embodiment of the invention, the coupling layer is formed using a cyclic azanonane. In another embodiment, the coupling layer is formed using double-armed decane.
一般而言,形成其上具有AR塗層之眼鏡片之方法包含製備光學表面彼此面對之第一及第二模具步驟。在一個較佳實施例中,使用模具及密封墊,諸如美國專利第7,114,696號中所述,其以全文引用的方式併入本文中。將各種所需塗層塗覆於一個或兩個模具之內部。將其上具有塗層之模具置於在模具之間提供間隔之密封墊總成中。將液體單體置於間隔中且固化得到鏡片。 In general, a method of forming an ophthalmic lens having an AR coating thereon includes the steps of preparing first and second molds in which the optical surfaces face each other. In a preferred embodiment, a mold and a gasket are used, such as those described in U.S. Patent No. 7,114,696, which is incorporated herein in its entirety by reference. Various desired coatings are applied to the interior of one or both molds. A mold having a coating thereon is placed in a gasket assembly that provides spacing between the molds. The liquid monomer is placed in the compartment and cured to give the lens.
模具可由能夠耐受下文所用之加工溫度且可提供製備光學元件所要之類型的表面之任何適合材料形成。 The mold may be formed of any suitable material that is capable of withstanding the processing temperatures used below and that provides the surface of the type desired for the optical component.
在本發明之一個實施例中,作為第一步驟,藉由電子束沈積將塗層直接塗覆於塑膠模具光學表面上。在第一塗層之後,可塗覆第二塗層,之後以相反的順序塗覆多層AR 塗層。在本發明之一個實施例中,AR塗層為具有由兩種不同材料(低折射率材料及低折射率材料)形成之交替層之多層結構。在本發明之一個較佳實施例中,AR塗層為具有由比率H/L>1之兩種不同材料(高折射率材料及低折射率材料)形成之7個交替層之多層結構,其中L及H分別為第一及第二折射率之值。認為適於實踐本發明之材料為作為高折射率材料二氧化鋯(稱為「ZrO2」)及折射率為約1.46之作為低折射率材料二氧化矽。 In one embodiment of the invention, as a first step, the coating is applied directly to the optical surface of the plastic mold by electron beam deposition. After the first coating, a second coating can be applied, after which the multilayer AR coating is applied in the reverse order. In one embodiment of the invention, the AR coating is a multilayer structure having alternating layers of two different materials (low refractive index material and low refractive index material). In a preferred embodiment of the present invention, the AR coating is a multilayer structure having seven alternating layers formed of two different materials (high refractive index material and low refractive index material) having a ratio H/L>1, wherein L and H are the values of the first and second refractive indices, respectively. The material which is considered to be suitable for the practice of the present invention is a low refractive index material cerium oxide as a high refractive index material zirconium dioxide (referred to as "ZrO 2 ") and a refractive index of about 1.46.
在本發明之一個實施例中,藉由真空沈積塗覆各層使得第一及最後一層均為二氧化矽(SiO2)。 In one embodiment of the present invention, by a vacuum deposition coating layers such that the first and the last layer are silicon dioxide (SiO 2).
在AR塗層塗覆之後,藉由氣相沈積塗覆偶合劑層或薄膜。當偶合劑為環狀氮雜矽烷時,其將結合於二氧化矽層上之表面羥基,打開環且在表面上產生有機分子。此舉可在真空下在室溫下進行,且不需要水作為催化劑。 After the AR coating is applied, the coupler layer or film is applied by vapor deposition. When the coupling agent is a cyclic azanonane, it will bind to the surface hydroxyl groups on the ceria layer, opening the ring and creating organic molecules on the surface. This can be carried out under vacuum at room temperature and does not require water as a catalyst.
接下來,塗覆抗刮傷(硬)塗層。可作為AR塗層製程之延伸藉由真空沈積或藉由更習知之旋塗、噴塗或浸塗方法塗覆硬塗層,塗層塗覆之後進行固化。 Next, an anti-scratch (hard) coating is applied. The hard coat layer can be applied as a stretch of the AR coating process by vacuum deposition or by a more conventional spin coating, spray coating or dip coating method, after the coating is applied.
在將各種塗層塗覆於模具之後,組裝前及後模具。總成之腔室接著充滿鏡片材料調配物,該等鏡片材料調配物接著固化且結合於硬塗層在固化完成之後,自總成移除鏡片。將所有塗層轉移至鏡片使得鏡片塗覆有超疏水性、抗反射且抗刮傷塗層。 After applying the various coatings to the mold, the front and back molds are assembled. The chamber of the assembly is then filled with a lens material formulation that is then cured and bonded to the hard coat to remove the lens from the assembly after curing is complete. Transferring all of the coating to the lens allows the lens to be coated with a superhydrophobic, anti-reflective, and scratch resistant coating.
環狀氮雜矽烷可購自Gelest,Inc。通式包括具有下式之氮雜矽雜環戊烷:
其中R1及R2獨立地選自由分支鏈及直鏈、經取代及未經取代之烷基、烯基及烷氧基組成之群,且其中R3係選自由以下組成之群:經取代且未經取代之飽和及不飽和、分支鏈及直鏈脂族烴基;經取代及未經取代之分支鏈及直鏈芳烷基;經取代及未經取代之芳基;及氫。環狀氮雜矽烷亦包括具有下式之二氮雜矽環化合物:
其中R3係選自由以下組成之群:經取代且未經取代之飽和及不飽和、分支鏈及直鏈脂族烴基;經取代及未經取代之分支鏈及直鏈芳烷基;經取代及未經取代之芳基;及氫;且其中R4及R5獨立選自由經取代及未經取代之分支鏈及直鏈烷基及烷氧基組成之群。 Wherein R 3 is selected from the group consisting of substituted and unsubstituted saturated and unsaturated, branched and straight-chain aliphatic hydrocarbon groups; substituted and unsubstituted branched and linear aralkyl groups; And an unsubstituted aryl group; and hydrogen; and wherein R 4 and R 5 are independently selected from the group consisting of substituted and unsubstituted branched chains and linear alkyl groups and alkoxy groups.
較佳超疏水化合物為可購自Daikin之Optool DSX。此疏水性化合物不含通常包括於商業超疏水性製劑中以增加超疏水性材料與塑膠鏡片之黏著的添加劑。 Preferred superhydrophobic compounds are Optool DSX available from Daikin. This hydrophobic compound is free of additives typically included in commercial superhydrophobic formulations to increase the adhesion of superhydrophobic materials to plastic lenses.
更特定言之,下文描述本發明之此等及其他態樣。 More specifically, these and other aspects of the invention are described below.
在不欲限制本發明之範疇的情況下,下文給出本 發明實施例之其他例示性實施例及其相關結果。應注意,為了讀者之方便起見,可在實例中使用標題或副標題,其決不應限制本發明之範疇。此外,本文中提議且揭示了某些理論;然而,不管其正確或是錯誤,其決不應限制本發明之範疇,只要在不考慮動作之任何特定理論或方案之情況下根據本發明實踐本發明即可。 Without limiting the scope of the invention, the following is given Other illustrative embodiments of the inventive embodiments and their associated results. It should be noted that for the convenience of the reader, the title or subtitle may be used in the examples, which should in no way limit the scope of the invention. In addition, some of the theories are proposed and disclosed herein; however, regardless of their correctness or error, they should not limit the scope of the invention as long as it is practiced in accordance with the present invention without regard to any particular theory or The invention can be.
可使用各種類型之環狀氮雜矽烷實踐本發明,包括: The invention can be practiced using various types of cyclic azadecanes, including:
(a)SIB1932.4或N-正丁基-氮雜-2,2-二甲氧基矽雜環戊烷,C9H21NO2Si,具有下式:
(b)SID3543.0或2,2-二甲氧基-1,6-二氮雜-2-矽環辛烷,C7H18N2O2Si,具有下式:
(c)SIA0592.0或N-胺基乙基-氮雜-2,2,4-三甲基矽雜環戊烷,C8H21NSi,具有下式:
(d)SIA0380.0或N-烯丙基-氮雜-2,2-二甲氧基矽雜環戊烷,C8H17NO2Si,具有下式:
此實例展示用於根據本發明之各種實施例產生之塗層之結合的各種測試。 This example demonstrates various tests for the combination of coatings produced in accordance with various embodiments of the present invention.
交叉影線測試. 在交叉影線測試中,用刀片將間隔1mm之一系列10條線切入塗層中。將與第一者呈直角且重疊之間隔1mm之第二系列10條線切入塗層中。接著將一片塞璐芬帶(cellophane tape)施加於交叉影線圖案上且快速牽引遠離塗層。 Cross hatch test. In the cross hatch test, a series of 10 lines spaced 1 mm apart was cut into the coating with a blade. A second series of 10 lines spaced 1 mm apart from the first and at an interval of 1 mm were cut into the coating. A piece of cellophane tape is then applied to the cross hatch pattern and quickly pulled away from the coating.
裂紋測試. 在裂紋測試中,將鏡片去除模具,接著在80℃下退火20分鐘。將鏡片快速轉移至室溫水中且檢查裂紋。若無裂紋顯現,則AR/偶合劑系統可接受。 Crack test. In the crack test, the lens was removed from the mold and then annealed at 80 ° C for 20 minutes. The lenses were quickly transferred to room temperature water and cracks were examined. If no cracks appear, the AR/coupler system is acceptable.
沸騰鹽水測試. 在沸騰鹽水測試中,首先將鏡片 在含有4.5% NaCl及0.8% NaH2PO4.2H2O之沸騰鹽溶液中浸漬兩分鐘。接下來,將鏡片快速轉移至室溫(18-24℃)去離子水中。若在塗層中未注意到裂紋或分層,則AR/偶合劑系統可接受。 Boiling brine test. In the boiling brine test, the lens was first contained in 4.5% NaCl and 0.8% NaH 2 PO 4 . Immerse in a boiling salt solution of 2H 2 O for two minutes. Next, the lenses were quickly transferred to deionized water at room temperature (18-24 ° C). The AR/coupler system is acceptable if no cracks or delamination are noted in the coating.
在此實例中,尤其根據本發明之不同實施例提供製備超疏水性層之方法。 In this example, a method of making a superhydrophobic layer is provided, particularly in accordance with various embodiments of the present invention.
使用鋼熱舟,將厚度為約40nm之超疏水性材料層沈積於模具上。自兩個含有鋼絲絨之亦稱為銅「襯套」之銅坩堝蒸發超疏水性材料,各自含有0.04g雙臂矽烷及過量超疏水性材料。如以下實例中所示,AR塗層及所得鏡片之品質實質上視塗覆超疏水性層之鋼熱舟之溫度而定。藉由記錄沈積期間鋼熱舟之溫度獲得所有溫度量測值。 A layer of superhydrophobic material having a thickness of about 40 nm was deposited on the mold using a steel boat. The two copper-evaporated superhydrophobic materials, also known as copper "liners" containing steel wool, each contain 0.04 g of coke hexane and an excess of superhydrophobic material. As shown in the examples below, the quality of the AR coating and the resulting lens is substantially dependent on the temperature of the steel boat that coats the superhydrophobic layer. All temperature measurements were obtained by recording the temperature of the steel boat during deposition.
實例(A):使鋼舟之溫度升至1350華氏度(約730攝氏度)。因此,在AR塗層中可以看到淡的脈樣標記。在所得鏡片上出現裂紋。 Example ( A ): Raise the temperature of the steel boat to 1350 degrees Fahrenheit (about 730 degrees Celsius). Therefore, a light pulse-like mark can be seen in the AR coating. Cracks appeared on the resulting lens.
實例(B):使鋼舟之溫度升至1200華氏度(約650攝氏度)。看不到脈樣標記,但在所得鏡片上出現裂紋。此外,鏡片未通過接觸角測試。 Example ( B ): Raise the temperature of the steel boat to 1200 degrees Fahrenheit (about 650 degrees Celsius). No pulse-like marks were visible, but cracks appeared on the resulting lenses. In addition, the lens did not pass the contact angle test.
實例(C):使鋼舟之溫度升至1000華氏度(約540攝氏度)。在鏡片上仍出現裂紋,且鏡片未通過接觸角測試。 Example ( C ): Raise the temperature of the steel boat to 1000 degrees Fahrenheit (about 540 degrees Celsius). Cracks still appear on the lens and the lens does not pass the contact angle test.
實例(D):使鋼舟之溫度升至900華氏度(約480攝氏度)。鏡片無裂紋,且接觸角改良。 Example ( D ): Raise the temperature of the steel boat to 900 degrees Fahrenheit (about 480 degrees Celsius). The lens has no cracks and the contact angle is improved.
實例(E):使鋼舟之溫度升至700華氏度(約370攝氏度)。鏡片無裂紋,且接觸角良好。 Example ( E ): Raise the temperature of the steel boat to 700 degrees Fahrenheit (about 370 degrees Celsius). The lens has no cracks and a good contact angle.
實例(F):使鋼舟之溫度升至500華氏度(約260攝氏度)。接觸角可接受,但並非如實例5中之結果般良好。在鑄造之後亦更難以分離模具與鏡片。無裂紋出現。 Example ( F ): Raise the temperature of the steel boat to 500 degrees Fahrenheit (about 260 degrees Celsius). The contact angle was acceptable but not as good as the results in Example 5. It is also more difficult to separate the mold and the lens after casting. No cracks appear.
實例(G):當舟之溫度升至400華氏度(約200攝氏度)時,塗佈機即不能持續偵測模具上超疏水性層之生長。 Example ( G ): When the temperature of the boat rises to 400 degrees Fahrenheit (about 200 degrees Celsius), the coater cannot continuously detect the growth of the superhydrophobic layer on the mold.
圖3展示AR塗層及所得鏡片對塗覆超疏水性層之鋼熱舟之溫度的依賴性。根據本發明,較佳溫度範圍為約200-500攝氏度。 Figure 3 shows the dependence of the AR coating and the resulting lens on the temperature of the steel boat coated with the superhydrophobic layer. According to the invention, a preferred temperature range is from about 200 to 500 degrees Celsius.
在此實例中,尤其根據本發明之又一實施例提供將AR塗層塗覆於拋棄式模具上之方法。應注意,在此實例中,在有或無離子輔助之情況下形成或沈積SiO2層。 In this example, a method of applying an AR coating to a disposable mold is provided, particularly in accordance with yet another embodiment of the present invention. It should be noted that in this example, the SiO 2 layer is formed or deposited with or without ion assist.
目前參考圖4,用標準箱式塗佈機及蒸發用電子束結合具有光學表面404之模具402進行以下所述製程。使用熟知真空實務進行該等製程。 Referring now to Figure 4, the following process is performed using a standard box coater and electron beam for evaporation in combination with a mold 402 having an optical surface 404. These processes are carried out using well-known vacuum practices.
程序:program:
(1)清潔模具402之光學表面404。在本發明之一個實施例中,對模具表面電漿清潔約2min。 (1) Cleaning the optical surface 404 of the mold 402. In one embodiment of the invention, the surface of the mold is plasma cleaned for about 2 minutes.
(2)於光學表面404上形成厚度為約30至40nm之超疏水性材料層406,其中超疏水性材料含有約1.7重量%-8.3重量%之雙臂矽烷。在一個實施例中,超疏水性材料含 在一或多個與金屬板或舟接觸之坩堝內。在某些實施例中,自一或多個坩堝中真空蒸發超疏水性材料,同時將金屬舟加熱至約200℃與約500℃之間的溫度。在一些實施例中,坩堝為銅材料且舟為不鏽鋼材料。 (2) Forming a superhydrophobic material layer 406 having a thickness of about 30 to 40 nm on the optical surface 404, wherein the superhydrophobic material contains from about 1.7% by weight to about 8.3% by weight of the cobine. In one embodiment, the superhydrophobic material comprises Within one or more of the contact with the metal plate or boat. In certain embodiments, the superhydrophobic material is vacuum evaporated from one or more crucibles while the metal boat is heated to a temperature between about 200 ° C and about 500 ° C. In some embodiments, the crucible is a copper material and the boat is a stainless steel material.
(3)在層406上形成在不使用離子輔助之情況下沈積且厚度為約5至40nm之SiO2層410。 (3) An SiO 2 layer 410 deposited on the layer 406 without using ion assist and having a thickness of about 5 to 40 nm is formed.
(4)在層410上形成使用離子輔助沈積且厚度為約5至100nm之SiO2層412。 (4) A SiO 2 layer 412 deposited using ion assisted deposition and having a thickness of about 5 to 100 nm is formed on the layer 410.
(5)在層412上形成厚度為約40至50nm之ZrO2層414。 (5) A ZrO 2 layer 414 having a thickness of about 40 to 50 nm is formed on the layer 412.
(6)在層414上形成在不使用離子輔助之情況下沈積且厚度為約10至20nm之SiO2層416。 (6) A SiO 2 layer 416 deposited on the layer 414 without using ion assist and having a thickness of about 10 to 20 nm is formed.
(7)在層416上形成厚度為約50至70nm之ZrO2層418。 (7) A ZrO 2 layer 418 having a thickness of about 50 to 70 nm is formed on the layer 416.
(8)在層418上形成在不使用離子輔助之情況下沈積且厚度為約25至40nm之SiO2層420。 (8) An SiO 2 layer 420 deposited on the layer 418 without using ion assist and having a thickness of about 25 to 40 nm is formed.
(9)在層420上形成厚度為約10至25nm之ZrO2層422。 (9) A ZrO 2 layer 422 having a thickness of about 10 to 25 nm is formed on the layer 420.
(10)在層422上形成使用離子輔助沈積且厚度為約5至15nm之SiO2層424。 (10) A SiO 2 layer 424 deposited using ion assisted deposition and having a thickness of about 5 to 15 nm is formed on the layer 422.
(11)在層424上形成使用浸塗或氣相沈積沈積且單層厚之偶合劑層426。 (11) A single layer of thick coupler layer 426 deposited using dip or vapor deposition is formed over layer 424.
應注意,在此實施例中,超疏水性材料層406含有以超疏水性材料計約1.7重量%-8.3重量%之雙臂矽烷使得AR塗層可為穩定的。超疏水性材料中雙臂矽烷之濃度之實例 為每0.6g超疏水性材料含有約0.01g至0.05g雙臂矽烷。若在超疏水性材料中不使用或使用極少雙臂矽烷,則AR塗層出現裂紋且與模具分離。此外,SiO2層410充當AR層狀結構411之保護密封件以及充當AR層狀結構411與超疏水性材料層406之間的自然結合表面或「連接物」。同樣地,SiO2層424提供AR層狀結構411與偶合劑層426之間的自然結合表面或「連接物」。應注意,儘管層410與層412皆由SiO2形成,但其由不同製程形成使得其彼此黏著但起不同作用。 It should be noted that in this embodiment, the superhydrophobic material layer 406 contains from about 1.7% to about 8.3 weight percent of the cobine in terms of the superhydrophobic material such that the AR coating can be stable. An example of the concentration of the arms hemane in the superhydrophobic material is from about 0.01 g to 0.05 g of cob hexane per 0.6 g of superhydrophobic material. If no very small arms decane is used or used in the superhydrophobic material, the AR coating cracks and separates from the mold. In addition, the SiO 2 layer 410 acts as a protective seal for the AR layered structure 411 and as a natural bonding surface or "linker" between the AR layered structure 411 and the superhydrophobic material layer 406. Likewise, the SiO 2 layer 424 provides a natural bonding surface or "linker" between the AR layer structure 411 and the coupler layer 426. It should be noted that although both layer 410 and layer 412 are formed of SiO 2 , they are formed by different processes such that they adhere to each other but function differently.
在此實例中,尤其根據本發明之另一個實施例提供將AR塗層塗覆於拋棄式模具上之方法。應注意,在此實例中,在有或無離子輔助之情況下形成或沈積SiO2層。 In this example, a method of applying an AR coating to a disposable mold is provided, particularly in accordance with another embodiment of the present invention. It should be noted that in this example, the SiO 2 layer is formed or deposited with or without ion assist.
目前參考圖5,用標準箱式塗佈機及蒸發用電子束結合具有光學表面504之模具502進行以下所述製程。使用熟知真空實務進行該等製程。 Referring now to Figure 5, the following process is performed using a standard box coater and electron beam for evaporation in combination with a mold 502 having an optical surface 504. These processes are carried out using well-known vacuum practices.
程序:program:
(1)清潔模具502之光學表面504。在本發明之一個實施例中,對模具表面電漿清潔約2min。 (1) Cleaning the optical surface 504 of the mold 502. In one embodiment of the invention, the surface of the mold is plasma cleaned for about 2 minutes.
(2)於光學表面504上形成厚度為約30至40nm之超疏水性材料層506,其中超疏水性材料含有以超疏水性材料計約1.7重量%-8.3重量%之雙臂矽烷。在一個實施例中,超疏水性材料含在一或多個與金屬板或舟接觸之坩堝內。在某些實施例中,自一或多個坩堝中真空蒸發超疏水性材料,同時將金屬舟加熱至約200℃與約500℃之間的溫度。在一些 實施例中,坩堝為含有鋼絲絨之銅材料且舟為不鏽鋼材料。 (2) A superhydrophobic material layer 506 having a thickness of about 30 to 40 nm is formed on the optical surface 504, wherein the superhydrophobic material contains from about 1.7% by weight to about 8.3% by weight of the superhydrophobic material. In one embodiment, the superhydrophobic material is contained within one or more of the crucibles in contact with the metal sheet or boat. In certain embodiments, the superhydrophobic material is vacuum evaporated from one or more crucibles while the metal boat is heated to a temperature between about 200 ° C and about 500 ° C. In some In the embodiment, the crucible is a copper material containing steel wool and the boat is a stainless steel material.
(3)在層506上形成在不使用離子輔助之情況下沈積且厚度為約5至40nm之SiO2層510。 (3) A SiO 2 layer 510 deposited on the layer 506 without using ion assist and having a thickness of about 5 to 40 nm is formed.
(4)在層510上形成使用離子輔助沈積且厚度為約5至100nm之SiO2層512。 (4) A SiO 2 layer 512 deposited using ions assisted and having a thickness of about 5 to 100 nm is formed on the layer 510.
(5)在層512上形成厚度為約40至50nm之ZrO2層514。 (5) A ZrO 2 layer 514 having a thickness of about 40 to 50 nm is formed on the layer 512.
(6)在層514上形成在不使用離子輔助之情況下沈積且厚度為約10至20nm之SiO2層516。 (6) A SiO 2 layer 516 deposited on the layer 514 without using ion assist and having a thickness of about 10 to 20 nm is formed.
(7)在層516上形成厚度為約50至70nm之ZrO2層518。 (7) A ZrO 2 layer 518 having a thickness of about 50 to 70 nm is formed on the layer 516.
(8)在層518上形成在不使用離子輔助之情況下沈積且厚度為約25至40nm之SiO2層520。 (8) A SiO 2 layer 520 deposited on the layer 518 without using ion assist and having a thickness of about 25 to 40 nm is formed.
(9)在層520上形成厚度為約10至25nm之ZrO2層522。 (9) A ZrO 2 layer 522 having a thickness of about 10 to 25 nm is formed on the layer 520.
(10)在層522上形成使用離子輔助沈積且厚度為約5至15nm之SiO2層524。 (10) A SiO 2 layer 524 deposited using ion assisted deposition and having a thickness of about 5 to 15 nm is formed on layer 522.
(11)在層524上形成使用氣相沈積沈積且單層厚之偶合劑層526。 (11) A single layer thick coupler layer 526 deposited using vapor deposition is formed over layer 524.
在實例4及5中,本發明尤其由塗覆於塗佈AR之模具上以促進硬塗層之黏著之偶合劑層來實踐。 In Examples 4 and 5, the present invention was practiced, inter alia, by applying a layer of a coupling agent applied to an AR coated mold to promote adhesion of the hard coat layer.
在材料方面(Material-wise),偶合劑為官能性矽烷,其中矽烷結合於AR塗層且官能基與有機硬塗層結合。根 據本發明之一個實施例,環狀氮雜矽烷尤其充分適合於此塗覆,此係因為器在室溫下經由開環反應形成矽烷結合。由此產生具有易於連接至硬塗層之官能基的單層,從而形成強AR硬塗層結合。咸信,該行業中首次且僅本發明之發現在光學鏡片形成製程中將環狀氮雜矽烷用作偶合劑。在另一個實施例中,官能性矽烷為雙臂矽烷。對於如圖4及5中所示之實施例而言,在將SiO2用作具有第一折射率之第一材料之情況下,將雙(三甲氧基矽烷基丙基)胺用作矽烷偶合劑,從而產生強AR硬塗層結合且實現現場AR鏡片形成。 In material-wise, the coupling agent is a functional decane wherein decane is bonded to the AR coating and the functional groups are combined with the organic hardcoat. According to one embodiment of the invention, the cyclic azanonane is particularly well suited for this coating because the device forms a decane bond via a ring opening reaction at room temperature. This results in a single layer having functional groups that are easily attached to the hard coat layer to form a strong AR hard coat bond. Xianxin, the first and only discovery of the present invention in the industry, used cyclic azadecane as a coupling agent in the optical lens forming process. In another embodiment, the functional decane is a double-arm decane. For the examples as shown in Figures 4 and 5, bis(trimethoxydecylpropyl)amine was used as the decane couple in the case where SiO 2 was used as the first material having the first refractive index. Mixtures to create a strong AR hardcoat bond and achieve in-situ AR lens formation.
在程序方面,偶合劑必須在非質子性條件下進行塗覆且可使用許多現今常在鏡片行業中實踐之方法來進行,諸如旋塗、噴塗、浸塗及真空塗佈。以下提供偶合劑塗覆之三種特定實例。 In terms of procedural, the coupling agent must be coated under aprotic conditions and can be carried out using a number of methods commonly practiced in the lens industry today, such as spin coating, spray coating, dip coating, and vacuum coating. Three specific examples of coupling agent coating are provided below.
A.真空塗佈--程序: A. Vacuum coating - program:
(1)將包含前模具及後模具之一對光學模具置於真空腔室中,其中模具之對應光學表面為如實例4及5中所示根據本發明之各種實施例中之一者的塗佈AR之模具,將該真空腔室抽氣以產生具有預定壓力之非質子性環境,其中在將偶合劑引入腔室中時偶合劑將汽化。 (1) placing the optical mold in one of the front mold and the rear mold in a vacuum chamber, wherein the corresponding optical surface of the mold is coated according to one of the various embodiments of the present invention as shown in Examples 4 and 5. A mold of cloth AR, the vacuum chamber is evacuated to produce an aprotic environment having a predetermined pressure, wherein the coupling agent will vaporize as the coupling agent is introduced into the chamber.
(2)將偶合劑引入密封腔室中且使其塗佈且與各AR塗層反應最少10分鐘。 (2) Introducing the coupling agent into the sealed chamber and coating it and reacting with each AR coating for a minimum of 10 minutes.
(3)將腔室抽氣至初始(預偶合劑)預定壓力以移除過量偶合劑。 (3) The chamber is evacuated to an initial (pre-coupler) predetermined pressure to remove excess coupling agent.
(4)釋放真空且自腔室移出光學模具總成。之後,可塗覆硬塗層。 (4) The vacuum is released and the optical mold assembly is removed from the chamber. Thereafter, a hard coat layer can be applied.
B.浸塗--程序: B. Dip coating - - program:
(1)製備偶合劑於非質子性溶劑中之溶液(最小為0.05%)。非質子性溶劑之實例包括甲苯、苯、石油醚或其他烴溶劑。 (1) A solution of a coupling agent in an aprotic solvent (minimum 0.05%). Examples of aprotic solvents include toluene, benzene, petroleum ether or other hydrocarbon solvents.
(2)在室溫下將如實例4及5中所示根據本發明之各種實施例中之一者製備之塗佈AR之模具曝露於溶液(或用溶液處理)最少5分鐘。 (2) The AR coated mold prepared according to one of the various embodiments of the present invention as shown in Examples 4 and 5 was exposed to a solution (or treated with a solution) for a minimum of 5 minutes at room temperature.
(3)自溶液移出經處理之模具且用乙醇或類似溶劑清洗。 (3) The treated mold is removed from the solution and washed with ethanol or a similar solvent.
(4)接著使模具空氣乾燥且之後可塗覆硬塗層。 (4) The mold is then air dried and then a hard coat layer can be applied.
C.旋塗-程序: C. Spin coating - program:
(1)製備偶合劑於非質子性溶劑中之溶液(最小為0.05%)。非質子性溶劑之實例包括甲苯、苯、石油醚、Isopar L或其他烴溶劑。 (1) A solution of a coupling agent in an aprotic solvent (minimum 0.05%). Examples of aprotic solvents include toluene, benzene, petroleum ether, Isopar L or other hydrocarbon solvents.
(2)將溶液置於旋塗系統中,其中使用泵或壓力腔室將溶液噴霧於快速旋轉之轉軸上。 (2) The solution is placed in a spin coating system in which a pump or pressure chamber is used to spray the solution onto a rapidly rotating shaft.
(3)將如實例4及5中所示根據本發明之各種實施例中之一者製備之塗佈AR之模具置於轉軸中。塗覆偶合劑溶液,同時使模具旋轉,從而產生均勻塗層。 (3) An AR-coated mold prepared according to one of the various embodiments of the present invention as shown in Examples 4 and 5 was placed in a rotating shaft. The coupling agent solution is applied while rotating the mold to produce a uniform coating.
(4)自轉軸移出經處理之模具且在IR加熱下乾燥。接著可塗覆硬塗層。 (4) The rotating shaft was removed from the treated mold and dried under IR heating. A hard coat layer can then be applied.
此實例展示製造根據本發明之一個實施例之塗佈AR之鏡片的方法或程序。 This example demonstrates a method or procedure for making an AR coated lens in accordance with one embodiment of the present invention.
根據實例4及5中之一者中所示之本發明之一個實施例,光學模具總成之前模具及後模具之對應光學表面經AR塗佈。接著使用如上文實例6中所述之浸塗方法在AR表面(424,524)上形成由N-正丁基-氮雜-2,2-二甲氧基-矽雜環戊烷組成或具有N-正丁基-氮雜-2,2-二甲氧基-矽雜環戊烷之偶合劑層(426,526)。製備0.05%偶合劑於石油醚中之溶液。在室溫下將光學表面浸沒於溶液中5分鐘。接著將其用乙醇清洗,使得空氣乾燥,且即刻使用旋塗製程進行硬塗佈。鑄造時,將硬塗層、AR及超疏水性塗層自模具轉移至鏡片上。 According to one embodiment of the invention as shown in one of Examples 4 and 5, the corresponding optical surfaces of the front and rear molds of the optical mold assembly are AR coated. Subsequent to the formation of N-n-butyl-aza-2,2-dimethoxy-hydrazine heterocyclopentane on the AR surface (424, 524) using a dip coating process as described in Example 6 above. A coupling layer of N-n-butyl-aza-2,2-dimethoxy-hydrazine heterocyclopentane (426, 526). A solution of 0.05% coupling agent in petroleum ether was prepared. The optical surface was immersed in the solution for 5 minutes at room temperature. It was then washed with ethanol, allowed to air dry, and immediately subjected to a hard coating using a spin coating process. The hard coat, AR and superhydrophobic coating are transferred from the mold to the lens during casting.
一方面,本發明係關於一種將抗反射塗層塗覆於模具之光學表面上之方法。在如圖4及5中所示之本發明之多個實施例中,此類方法具有以下步驟:提供具有光學表面404或504之鏡片模具402或502;於光學表面404或504上形成厚度為約20至100nm之超疏水性材料層406或506,其中超疏水性材料含有以超疏水性材料計約1.7重量%-8.3重量%之雙臂矽烷;於超疏水性層406或506上形成抗反射塗層層狀結構411或511;及於抗反射塗層層狀結構411或511上形成使用浸塗、旋塗或氣相沈積沈積且具有單層厚度之偶合劑層426或526。 In one aspect, the invention relates to a method of applying an anti-reflective coating to an optical surface of a mold. In various embodiments of the invention as shown in Figures 4 and 5, such methods have the steps of providing a lens mold 402 or 502 having an optical surface 404 or 504; forming a thickness on the optical surface 404 or 504 A superhydrophobic material layer 406 or 506 of about 20 to 100 nm, wherein the superhydrophobic material contains from about 1.7% to about 8.3% by weight of the superhydrophobic material of the cochleon; forming an anti-hydrophobic layer 406 or 506 A reflective coating layer structure 411 or 511; and a coupling agent layer 426 or 526 having a single layer thickness deposited using dip coating, spin coating or vapor deposition on the anti-reflective coating layer structure 411 or 511.
在一個實施例中,超疏水性材料含在一或多個與金屬板或舟接觸之坩堝內。在某些實施例中,自一或多個坩堝中真空蒸發超疏水性材料,同時將金屬舟加熱至約200℃與約500℃之間的溫度。在一些實施例中,坩堝為銅材料且舟為不鏽鋼材料。 In one embodiment, the superhydrophobic material is contained within one or more of the crucibles in contact with the metal sheet or boat. In certain embodiments, the superhydrophobic material is vacuum evaporated from one or more crucibles while the metal boat is heated to a temperature between about 200 ° C and about 500 ° C. In some embodiments, the crucible is a copper material and the boat is a stainless steel material.
於層406或506上形成抗反射塗層層狀結構411或511之步驟可由以下步驟進行:(1)在超疏水性層406或506上形成具有第一折射率且厚度為約5至100nm之第一材料之第一層412、512或612;(2)在第一層412或512上形成具有第二折射率且厚度為約40至50nm之第二材料之第二層414或514;(3)在第二層414或514上形成具有第一折射率且厚度為約10至20nm之第一材料之第三層416或516;(4)在第三層416或516上形成具有第二折射率且厚度為約50至70nm之第二材料之第四層418或518;(5)在第四層418或518上形成具有第一折射率且厚度為約25至40nm之第一材料之第五層420或520;(6)在第五層420或520上形成具有第二折射率且厚度為約10至25nm之第二材料之第六層422或522;及(7)在第六層422或522上形成具有第一折射率且厚度為約5至15nm之第一材料之第七層424或524。 The step of forming the anti-reflective coating layer structure 411 or 511 on the layer 406 or 506 can be carried out by: (1) forming a first refractive index on the superhydrophobic layer 406 or 506 and having a thickness of about 5 to 100 nm. a first layer 412, 512 or 612 of a first material; (2) forming a second layer 414 or 514 of a second material having a second index of refraction and having a thickness of between about 40 and 50 nm on the first layer 412 or 512; 3) forming a third layer 416 or 516 having a first refractive index and a first material having a thickness of about 10 to 20 nm on the second layer 414 or 514; (4) forming a second layer on the third layer 416 or 516 a fourth layer 418 or 518 of a second material having a refractive index and a thickness of about 50 to 70 nm; (5) forming a first material having a first refractive index and a thickness of about 25 to 40 nm on the fourth layer 418 or 518 a fifth layer 420 or 520; (6) forming a sixth layer 422 or 522 having a second refractive index and a second material having a thickness of about 10 to 25 nm on the fifth layer 420 or 520; and (7) at the sixth A seventh layer 424 or 524 of a first material having a first index of refraction and a thickness of between about 5 and 15 nm is formed on layer 422 or 522.
在一個實施例中,第一折射率及第二折射率滿足H/L之比率>1,其中L及H分別為第一及第二折射率值。換言之,第二折射率值大於第一折射率值。 In one embodiment, the first refractive index and the second refractive index satisfy a ratio of H/L > 1, wherein L and H are first and second refractive index values, respectively. In other words, the second refractive index value is greater than the first refractive index value.
在一個實施例中,具有第一折射率之第一材料包含SiO2,且具有第二折射率之第二材料包含ZrO2。 In one embodiment, the first material having the first index of refraction comprises SiO 2 and the second material having the second index of refraction comprises ZrO 2 .
在根據上文所述之方法實踐本發明中,使用離子輔助或不使用離子輔助來沈積各SiO2層。 In practicing the invention in accordance with the methods described above, each SiO 2 layer is deposited using ion assist or without ion assist.
在如圖4及5中所示之實施例中,於超疏水性層406或506上形成抗反射塗層層狀結構411或511之步驟之 前,進行於超疏水性層406、506上形成在無離子輔助下沈積厚度為5至40nm之SiO2層410、510之步驟使得在超疏水性層506、606與第一層412、512之間形成SiO2層410、510。 In the embodiment shown in Figures 4 and 5, the steps of forming the anti-reflective coating layer structure 411 or 511 on the superhydrophobic layer 406 or 506 are performed on the superhydrophobic layers 406, 506. The step of depositing SiO 2 layers 410, 510 having a thickness of 5 to 40 nm without ion assisting results in the formation of SiO 2 layers 410, 510 between the superhydrophobic layers 506, 606 and the first layers 412, 512.
在一個實施例中,雙臂矽烷可為雙(三甲氧基矽烷基丙基)胺。 In one embodiment, the arms decane can be bis(trimethoxydecylpropyl)amine.
在一個實施例中,偶合劑層由包含環狀氮雜矽烷之組合物形成。在一個特定實施例中,偶合劑層由N-正丁基-氮雜-2,2-二甲氧基-矽雜環戊烷形成。在另一個實施例中,偶合劑層由包含雙臂矽烷之組合物形成。 In one embodiment, the coupler layer is formed from a composition comprising a cyclic azanonane. In a particular embodiment, the coupler layer is formed from N-n-butyl-aza-2,2-dimethoxy-hydrazine heterocyclopentane. In another embodiment, the coupler layer is formed from a composition comprising dual-arm decane.
在另一個態樣中,本發明係關於一種具有有可轉移至鏡片之光學表面之抗反射塗層之光學表面的模具。在如圖4及5中所示之多個實施例中,此類模具具有沈積於模具402或502之光學表面404或504上之厚度為約20至100nm之超疏水性材料層406或506,其中超疏水性材料含有以超疏水性材料計約1.7重量%-8.3重量%之雙臂矽烷。在一個實施例中,超疏水性材料含在一或多個與金屬板或舟接觸之坩堝內。在某些實施例中,自一或多個坩堝中真空蒸發超疏水性材料,同時將金屬舟加熱至約200℃與約500℃之間的溫度。在一些實施例中,坩堝為銅材料且舟為不鏽鋼材料。 In another aspect, the invention is directed to a mold having an optical surface having an anti-reflective coating that can be transferred to an optical surface of the lens. In various embodiments as shown in Figures 4 and 5, such a mold has a superhydrophobic material layer 406 or 506 deposited on the optical surface 404 or 504 of the mold 402 or 502 having a thickness of about 20 to 100 nm. Wherein the superhydrophobic material contains from about 1.7% to about 8.3% by weight of the superhydrophobic material of the cobine. In one embodiment, the superhydrophobic material is contained within one or more of the crucibles in contact with the metal sheet or boat. In certain embodiments, the superhydrophobic material is vacuum evaporated from one or more crucibles while the metal boat is heated to a temperature between about 200 ° C and about 500 ° C. In some embodiments, the crucible is a copper material and the boat is a stainless steel material.
模具亦具有沈積於超疏水性層406或506上之抗反射塗層層狀結構411或511;及沈積於抗反射塗層層狀結構411或511上之使用浸塗或氣相沈積沈積且具有單層厚度之偶合劑層426或526。 The mold also has an anti-reflective coating layer structure 411 or 511 deposited on the superhydrophobic layer 406 or 506; and deposited on the anti-reflective coating layer structure 411 or 511 by dip coating or vapor deposition deposition and having A single layer thickness coupler layer 426 or 526.
如圖4及5中所示,抗反射塗層層狀結構411或511具有: (1)沈積於超疏水性層406或506上之具有第一折射率且厚度為約5至100nm之第一材料之第一層412或512;(2)沈積於第一層412或512上之具有第二折射率且厚度為約40至50nm之第二材料之第二層414或514;(3)沈積於第二層414或514上之具有第一折射率且厚度為約10至20nm之第一材料之第三層416或516;(4)沈積於第三層416或516上之具有第二折射率且厚度為約50至70nm之第二材料之第四層418或518;(5)沈積於第四層418或518上之具有第一折射率且厚度為約25至40nm之第一材料之第五層420或520;(6)沈積於第五層420或520上之具有第二折射率且厚度為約10至25nm之第二材料之第六層422或522;及(7)沈積於第六層422或522上之具有第一折射率且厚度為約5至15nm之第一材料之第七層424或524。 As shown in Figures 4 and 5, the anti-reflective coating layered structure 411 or 511 has: (1) a first layer 412 or 512 of a first material having a first refractive index and a thickness of about 5 to 100 nm deposited on the superhydrophobic layer 406 or 506; (2) deposited on the first layer 412 or 512 a second layer 414 or 514 having a second refractive index and a second material having a thickness of about 40 to 50 nm; (3) having a first refractive index deposited on the second layer 414 or 514 and having a thickness of about 10 to 20 nm a third layer 416 or 516 of the first material; (4) a fourth layer 418 or 518 of a second material having a second index of refraction and having a thickness of about 50 to 70 nm deposited on the third layer 416 or 516; 5) a fifth layer 420 or 520 deposited on the fourth layer 418 or 518 having a first refractive index and a first material having a thickness of about 25 to 40 nm; (6) deposited on the fifth layer 420 or 520 a sixth layer 422 or 522 of a second material having a second refractive index and a thickness of about 10 to 25 nm; and (7) a first refractive index deposited on the sixth layer 422 or 522 and having a thickness of about 5 to 15 nm The seventh layer 424 or 524 of the first material.
第一折射率及第二折射率滿足H/L之比率>1,其中L及H分別為第一及第二折射率值。換言之,第二折射率值大於第一折射率值。 The first refractive index and the second refractive index satisfy a ratio of H/L > 1, wherein L and H are first and second refractive index values, respectively. In other words, the second refractive index value is greater than the first refractive index value.
在一個實施例中,具有第一折射率之第一材料包含SiO2,且具有第二折射率之第二材料包含ZrO2。 In one embodiment, the first material having the first index of refraction comprises SiO 2 and the second material having the second index of refraction comprises ZrO 2 .
抗反射塗層層狀結構中之各SiO2層使用離子輔助或不使用離子輔助進行沈積。 Each SiO 2 layer in the antireflective coating layered structure is deposited using ion assist or without ion assist.
或者,在如圖4及5中所示之多個實施例中,於層406、506上在無離子輔助下沈積厚度為5至40nm之SiO2層410、510,使得在層406、506與層412、512之間形成層410、510。 Alternatively, in various embodiments as shown in Figures 4 and 5, SiO 2 layers 410, 510 having a thickness of 5 to 40 nm are deposited on layers 406, 506 without ion assistance such that layers 406, 506 are Layers 410, 510 are formed between layers 412, 512.
雙臂矽烷可為雙(三甲氧基矽烷基丙基)胺。 The double-armed decane may be bis(trimethoxydecylpropyl)amine.
偶合劑層由包含功能性矽烷之組合物形成。在一些實施例中,功能性矽烷包含雙臂矽烷。在其他實施例中,功能性矽烷包含環狀氮雜矽烷。在如圖4及5中所示之多個實施例中,偶合劑層由N-正丁基-氮雜-2,2-二甲氧基-矽雜環戊烷形成。 The coupling agent layer is formed from a composition comprising functional decane. In some embodiments, the functional decane comprises a double-arm decane. In other embodiments, the functional decane comprises a cyclic azanonane. In various embodiments as shown in Figures 4 and 5, the coupler layer is formed from N-n-butyl-aza-2,2-dimethoxy-hydrazine heterocyclopentane.
在另一個態樣中,本發明係關於一種光學鏡片。光學鏡片具有光學表面之鏡片主體及形成於光學表面上之抗反射塗層,其中在如圖4及5中所示之多個實施例中,抗反射塗層具有沈積於模具402或502之光學表面404或504上之厚度為約20至100nm之超疏水性材料層406或506,其中超疏水性材料含有以超疏水性材料計約1.7重量%-8.3重量%之雙臂矽烷。在一個實施例中,超疏水性材料含在一或多個與金屬板或舟接觸之坩堝內。在某些實施例中,自一或多個坩堝中真空蒸發超疏水性材料,同時將金屬舟加熱至約200℃與約500℃之間的溫度。在一些實施例中,坩堝為銅材料且舟為不鏽鋼材料。 In another aspect, the invention is directed to an optical lens. An optical lens has a lens body having an optical surface and an anti-reflective coating formed on the optical surface, wherein in various embodiments as shown in Figures 4 and 5, the anti-reflective coating has an optical deposition on the mold 402 or 502 The super-hydrophobic material layer 406 or 506 having a thickness on the surface 404 or 504 of about 20 to 100 nm, wherein the superhydrophobic material contains from about 1.7% to about 8.3% by weight of the superhydrophobic material of the cobine. In one embodiment, the superhydrophobic material is contained within one or more of the crucibles in contact with the metal sheet or boat. In certain embodiments, the superhydrophobic material is vacuum evaporated from one or more crucibles while the metal boat is heated to a temperature between about 200 ° C and about 500 ° C. In some embodiments, the crucible is a copper material and the boat is a stainless steel material.
抗反射塗層亦具有沈積於超疏水性層406或506上之抗反射塗層層狀結構411或511;及沈積於抗反射塗層層狀結構411或511上且與鏡片主體之光學表面偶合之使用氣相沈積沈積且具有單層厚度之偶合劑層426或526。 The antireflective coating also has an antireflective coating layered structure 411 or 511 deposited on the superhydrophobic layer 406 or 506; and deposited on the antireflective coating layered structure 411 or 511 and coupled to the optical surface of the lens body A coupler layer 426 or 526 deposited using vapor deposition and having a single layer thickness.
抗反射塗層層狀結構411或511由以下形成:(1)沈積於超疏水性層406或506上之具有第一折射率且厚度為約5至100nm之第一材料之第一層412或512;(2)沈積於第一層412或512上之具有第二折射率且厚度 為約40至50nm之第二材料之第二層414或514;(3)沈積於第二層414或514上之具有第一折射率且厚度為約10至20nm之第一材料之第三層416或516;(4)沈積於第三層416或516上之具有第二折射率且厚度為約50至70nm之第二材料之第四層418或518;(5)沈積於第四層418或518上之具有第一折射率且厚度為約25至40nm之第一材料之第五層420或520;(6)沈積於第五層420或520上之具有第二折射率且厚度為約10至25nm之第二材料之第六層422或522;及(7)沈積於第六層422或522上且與偶合劑層426或526接觸之具有第一折射率且厚度為約5至15nm之第一材料之第七層424或524。 The anti-reflective coating layered structure 411 or 511 is formed by: (1) a first layer 412 of a first material having a first refractive index and a thickness of about 5 to 100 nm deposited on the superhydrophobic layer 406 or 506 or 512; (2) having a second refractive index and thickness deposited on the first layer 412 or 512 a second layer 414 or 514 of a second material of about 40 to 50 nm; (3) a third layer of the first material having a first refractive index and a thickness of about 10 to 20 nm deposited on the second layer 414 or 514 416 or 516; (4) a fourth layer 418 or 518 of a second material having a second index of refraction and having a thickness of about 50 to 70 nm deposited on the third layer 416 or 516; (5) deposited on the fourth layer 418 Or a fifth layer 420 or 520 of a first material having a first refractive index and a thickness of about 25 to 40 nm; or (6) having a second refractive index deposited on the fifth layer 420 or 520 and having a thickness of about a sixth layer 422 or 522 of a second material of 10 to 25 nm; and (7) a first refractive index deposited on the sixth layer 422 or 522 and in contact with the coupling agent layer 426 or 526 and having a thickness of about 5 to 15 nm The seventh layer 424 or 524 of the first material.
第一折射率及第二折射率滿足H/L之比率>1,其中L及H分別為第一及第二折射率值。換言之,第二折射率值大於第一折射率值。 The first refractive index and the second refractive index satisfy a ratio of H/L > 1, wherein L and H are first and second refractive index values, respectively. In other words, the second refractive index value is greater than the first refractive index value.
在一個實施例中,具有第一折射率之第一材料包含SiO2,且具有第二折射率之第二材料包含ZrO2。 In one embodiment, the first material having the first index of refraction comprises SiO 2 and the second material having the second index of refraction comprises ZrO 2 .
抗反射塗層層狀結構中之各SiO2層使用離子輔助或不使用離子輔助進行沈積。 Each SiO 2 layer in the antireflective coating layered structure is deposited using ion assist or without ion assist.
或者,在如圖4及5中所示之多個實施例中,於層406、506上在無離子輔助下沈積厚度為5至40nm之SiO2層410、510,使得在層406、506與第一層412、512之間形成層410、510。 Alternatively, in various embodiments as shown in Figures 4 and 5, SiO 2 layers 410, 510 having a thickness of 5 to 40 nm are deposited on layers 406, 506 without ion assistance such that layers 406, 506 are Layers 410, 510 are formed between the first layers 412, 512.
雙臂矽烷可為雙(三甲氧基矽烷基丙基)胺。 The double-armed decane may be bis(trimethoxydecylpropyl)amine.
偶合劑層由包含環狀氮雜矽烷之組合物形成。在 如圖4及5中所示之多個實施例中,偶合劑層由N-正丁基-氮雜-2,2-二甲氧基-矽雜環戊烷形成。 The coupling agent layer is formed from a composition comprising a cyclic azanonane. in In various embodiments as shown in Figures 4 and 5, the coupler layer is formed from N-n-butyl-aza-2,2-dimethoxy-hydrazine heterocyclopentane.
在另一個態樣中,本發明係關於一種可用於鏡片製造之偶合劑。在一個實施例中,偶合劑包含雙臂矽烷。在一個實施例中,偶合劑包含環狀氮雜矽烷。在一個特定實施例中,環狀氮雜矽烷包含N-正丁基-氮雜-2,2-二甲氧基-矽雜環戊烷。應注意,在使用中,塗覆於溶劑中之環狀氮雜矽烷及雙臂矽烷。對於如圖4及5中所示之實施例而言,其中SiO2用作具有第一折射率之第一材料,利用N-正丁基-氮雜-2,2-二甲氧基-矽雜環戊烷作為偶合劑允許如圖2中所示之在無需水或加熱之情況下進行表面結合開環反應,從而產生較佳結合且實現現場AR鏡片形成。與尤其需要高熱之圖1所示之製程相比此情況較佳。 In another aspect, the invention is directed to a coupling agent useful in the manufacture of lenses. In one embodiment, the coupling agent comprises both arms decane. In one embodiment, the coupling agent comprises a cyclic azanonane. In a particular embodiment, the cyclic azanonane comprises N-n-butyl-aza-2,2-dimethoxy-hydrazine heterocyclopentane. It should be noted that, in use, a cyclic azanonane and a double-arm decane are applied in a solvent. For the examples as shown in Figures 4 and 5, wherein SiO 2 is used as the first material having the first refractive index, using N-n-butyl-aza-2,2-dimethoxy-oxime The heterocyclic pentane acts as a coupling agent to allow surface-bound ring-opening reactions as shown in Figure 2 without the need for water or heat, resulting in better bonding and on-site AR lens formation. This is better than the process shown in Figure 1 which requires especially high heat.
進一步應注意,在實踐本發明中,上文給出之各實施例之步驟可以如所既定之排序或以不同次序執行。 It is further noted that in practicing the present invention, the steps of the various embodiments given above may be performed as intended or in a different order.
在另一個態樣中,本發明係關於一種光學鏡片。在一個實施例中,光學鏡片具有有光學表面之鏡片主體、處於鏡片主體之光學表面上之硬塗層,及處於光學表面上之抗反射塗層。 In another aspect, the invention is directed to an optical lens. In one embodiment, the optical lens has a lens body having an optical surface, a hard coating on the optical surface of the lens body, and an anti-reflective coating on the optical surface.
以上對於本發明之例示性實施例的描述僅出於說明及描述之目的而提供,且並非意欲為窮舉的或將本發明限於所揭示之確切形式。根據上述揭示,實施例可能作出各種修改及變化。 The above description of the exemplary embodiments of the present invention is provided for the purpose of illustration and description, and is not intended to In view of the above disclosure, various modifications and changes may be made to the embodiments.
該等實施例之選擇及描述,係用以解釋本發明之原理及其實際應用,以便於其他熟習此技藝人士利用本發明 及各種實施例,且藉由適於所預期之特定用途的各種修改來利用本發明及各種實施例。在不背離本發明之精神及範疇的情況下,替代實施例對於本發明所屬技術熟習此技藝人士將為顯而易見。因此,本發明之範疇係藉由隨附申請專利範圍界定,而非藉由前述描述及在其中所描述之例示性實施例界定。 The selection and description of the embodiments are intended to explain the principles of the invention and its application in the application of the invention. The invention and the various embodiments are utilized by various modifications and modifications in the particular application. Alternate embodiments will be apparent to those skilled in the art from this disclosure, without departing from the scope of the invention. Therefore, the scope of the invention is defined by the scope of the appended claims, and not by the foregoing description and the exemplary embodiments described herein.
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US20200150313A1 (en) * | 2018-11-13 | 2020-05-14 | Quantum Innovations, Inc. | Anti-reflection lens and method for treating a lens to reduce reflections for placental mammals with dichromatic vision |
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