201101521 六、發明說明: 【發明所屬之技術領域】 本發明係關於一種具有保護性塗層(例如驗性障壁層)之 太陽能反射鏡(例如抛物面形太陽能反射玻璃鏡)及其製造 方法,更特定言之,本發明係關於在該鏡之凹表面上之驗 性障壁層,以避免鹼性離子(例如鈉離子)在該鏡之凹表面 上沉澱。較佳的本發明鹼性障壁層具有耐劃痕及耐化學品 特性’以避免對該鏡之凹表面的摩擦損傷。 【先前技術】 目前,提高太陽能集光器之效率受到關注,例如(且不 限於本發明),改善太陽能鏡(例如拋物面形鏡)之效率,該 太陽能鏡用於反射太陽光線至位於該拋物面鏡之焦點上之 裝置。該裝置通常係相關技藝已知類型,用以將太陽能量 轉換至另一可用形式的能量,如電能。在另一項先前技術 實施例中,該拋物面鏡係第一鏡,其反射太陽光線至相對 位於該第一鏡之焦點的第二鏡,以將該太陽光線反射至轉 換裝置。 一般而言,該抛物面形鏡包括在該成形基板之凸表面上 具有一反射表面(例如銀塗層)之拋物面形基板。較佳的成 形基板材料係鈉鈣矽玻璃,因為在使平面玻璃板材成形為 抛物面板材或基板中之高產量;製造平面玻璃板材之低成 本;及將太陽能反射塗層施用於該成形玻璃基板表面上的 高產量及低成本。 雖然鈉鈣矽玻璃係一種用於太陽能反射鏡之基板可接受 147285.doc 201101521 之材料’但是使用玻璃有限制性。更特定言之,在成形製 程中’將平板玻璃板材加熱至u〇〇。華氏度(下文亦稱為 F」)以上之溫度,並使其成形為抛物面形。在該玻璃片 之加熱及成形期間,在該玻璃板材中之鹼性離子(例如鈉 . 離子)自該玻璃片擴散或浸出。此外,在該抛物面形玻璃 . 基板暴露於太陽能期間(例如長期的環境暴露),使額外的 鈉離子自該玻璃基板浸出。正如熟習此項技術者所瞭解, 該等鈉離子自該玻璃之浸出或擴散係預期中的事件,且在 低溫下係個、緩慢的$程、然%,加熱該玻璃及/或該玻璃 長期锿境暴露於太陽能下將加速鈉離子自該玻璃之浸出或 擴散,並增加自該玻璃浸出之鈉離子的量。該玻璃浸出之 鈉離子與大氣中的水分反應,並將鈉離子轉化為鈉化合 物,例如氫氧化納及碳酸鈉。該等納化合物可敍刻該玻璃 之表面且可於沉澱物形式下沉積於該玻璃之表面上。該鈉 化合物沉澱減少通過該玻璃(例如細為抛物面形玻璃基板 ◎ 時)之可見光透射,減少太陽能透射至該成形玻璃基板四 表面上之反射塗層,且減少自該反射塗層反射之太陽能通 過該成形玻璃基板,透射至該成形破璃基板之凹表面。201101521 VI. Description of the Invention: [Technical Field] The present invention relates to a solar mirror (for example, a parabolic solar reflective glass mirror) having a protective coating (for example, an anisotropic barrier layer) and a method of manufacturing the same, and more specifically In other words, the present invention relates to an inspective barrier layer on the concave surface of the mirror to prevent precipitation of alkaline ions (e.g., sodium ions) on the concave surface of the mirror. Preferably, the alkaline barrier layer of the present invention has scratch and chemical resistance characteristics to avoid frictional damage to the concave surface of the mirror. [Prior Art] At present, there is a concern to improve the efficiency of a solar concentrator, such as (and not limited to the present invention), to improve the efficiency of a solar mirror (for example, a parabolic mirror) for reflecting solar rays to be located at the parabolic mirror The device in focus. The device is typically of the type known in the art to convert the amount of solar energy to another available form of energy, such as electrical energy. In another prior art embodiment, the parabolic mirror is a first mirror that reflects sunlight to a second mirror that is at a focus relative to the first mirror to reflect the sunlight to the conversion device. In general, the parabolic mirror includes a parabolic substrate having a reflective surface (e.g., a silver coating) on the convex surface of the shaped substrate. The preferred shaped substrate material is soda lime bismuth glass because of the high yield in forming a flat glass sheet into a parabolic sheet or substrate; the low cost of manufacturing a flat glass sheet; and the application of a solar reflective coating to the surface of the shaped glass substrate High output and low cost. Although sodium sulphate glass is a material used in solar mirrors, the material of 147285.doc 201101521 is acceptable, but the use of glass is limited. More specifically, the flat glass sheet is heated to u〇〇 during the forming process. The temperature above Fahrenheit (hereinafter also referred to as F) is formed into a parabolic shape. During the heating and forming of the glass sheet, alkaline ions (e.g., sodium ions) in the glass sheet are diffused or leached from the glass sheet. In addition, during the exposure of the parabolic glass to the solar energy (e.g., long-term environmental exposure), additional sodium ions are leached from the glass substrate. As is known to those skilled in the art, the leaching or diffusion of such sodium ions from the glass is an expected event, and at a low temperature, a slow, slow, heat, heating of the glass and/or the glass for a long period of time. Exposure to solar energy will accelerate the leaching or diffusion of sodium ions from the glass and increase the amount of sodium ions leached from the glass. The glass leached sodium ions react with moisture in the atmosphere and convert the sodium ions into sodium compounds such as sodium hydroxide and sodium carbonate. The nano-compounds can be patterned on the surface of the glass and deposited on the surface of the glass in the form of a precipitate. Precipitation of the sodium compound reduces visible light transmission through the glass (for example, when the parabolic glass substrate is ◎), reduces the transmission of solar energy to the reflective coating on the four surfaces of the shaped glass substrate, and reduces the passage of solar energy reflected from the reflective coating. The shaped glass substrate is transmitted to the concave surface of the shaped glass substrate.
過該沉澱之光線遠離該第一鏡之焦點) 在該凹玻璃表面上之鈉化合物 ‘漫射表面(其引導該反射且穿 鏡之焦點)。本文使用之術語 147285.doc 201101521 「鏡面」意即其中人射於該反射表面上之光線具有等於反 射角之入射角的光反射表面。本文使用之術語「非鏡面或 漫射表面」意即其中入射於該反射表面上之光線具有不同 於反射角之入射角的光反射表面。 玻璃的另-個限制性係必須小心操作以避免劃到該玻璃 表面。在該玻璃表面上之劃痕亦可將鏡面轉變為非鏡面或 漫射表面。正如熟習此項技術者所瞭解,由於該反射凹表 面自鏡面轉變為非鏡面或漫射表面,將減少入射至該抛物 面形鏡之焦點上之反射太陽光線的百分比,從而降低該太 陽能反射鏡之效率。 自拋物面鏡之凹表面移除及/或消除鈉化合物沉澱之當 則技術包括清洗該等表面及/或將該鏡之凹表面封閉於具 有惰性氣體之密封室中以避免該等鈉離子形成沉澱。用於 去除劃痕之當前技術包括將具有劃痕之玻璃片之表面拋 光。所有確保該太陽能鏡之表面保持鏡面之此等技術皆極 為昂貴。 障壁層係相關技藝中已知,例如揭示於美國專利第 4,238’276、5,270,615、5,830,252及 6,027,766號,及美國 專利申請案第08/597543號及美國公開案第 2007/0275253A1號中者。當前可獲得之鹼性障壁層及/或 耐劃痕層之一項限制係其可有效地使用於玻璃基板之平面 或成形表面,但是無法有效地使用於隨後成形為曲面(例 如拋物面鏡之凹表面)的平板表面。在先前技術中對於當 塗覆有障壁層及/或耐劃痕層之基板係自平面塗覆基板成 I47285.doc 201101521 形為抛物面形經塗覆塗層基板時所必須解決之該等問題的 辨識或討論微乎其微(如果有的話)。更特定言之,在先前 技術中,對於當該經塗覆之玻璃的輪廓自具有平 = 玻璃片轉變為具有凹表面之成形玻璃基板時,消除該塗層 . 之碎裂及/或屈曲的討論極少(如果有的話)。正如本申請案 . ㈣解’ #擠壓該障壁塗層時,該塗層碎裂且使該等:離 子暴露於大氣中’並在該玻璃基板之表面上形成鋼化合物 沉澱,且/或當該障壁塗層及/或而十劃痕塗層屈曲時,該等 表面自鏡面轉變為非鏡面或漫射表面。 正如熟習此項技術者現可瞭解,提供一具有耐劃痕特性 之鹼性障壁塗層或層(例如鈉離子障壁塗層)以避免該第一 鏡及第二鏡之凹表面自鏡面轉變為非鏡面或漫射表面,將 成為優勢。 【發明内容】 本發明係關於一種具.有彎曲反射表面之太陽能反射鏡, 〇 纟尤其包括-具有凸表面及相對的凹表面之透明基板、及 一在該凸表面上方之反射塗層及—在該凹表面上方之驗性 障壁層或塗層。該反射塗層反射選^波長的電磁頻譜。 . 此外,本發明係關於一種製造具有彎曲反射表面之太陽 . 能反射鏡之方法,其(尤其)藉由提供一平板透明板材;使 该板材成形以提供具有凸表面及相對的凹表面及焦點區之 成开^透明基板,在该基板之凸表面上方之施用一反射塗 層,及在該基板之凹表面上方提供一鹼性障壁層。 此外,本發明係關於一種尤其包括矽及鋁之氧化物的鹼 147285.doc 201101521 性障壁層。 此外,本發明係關於一種具有彎曲反射表面之太陽能反 射鏡。該鏡尤其包括複數個透明成形片段;固定設施用 以將該等片段保持在一起,以提供具有凸表面及相對凹表 面之成形透明基板,該成形基板之—個表面上方具有焦點 區及太陽能反射塗層,其中該塗層將電磁頻譜之可見光及 紅外光反射朝向該成形透明基板之焦點區。 本發明另外關於一種製造成形太陽能反射鏡之方法。該 方法尤其藉由使兩或更多平板透明片段成形以提供兩或更 多成形透明片段而實現,其中各該成形透明片段包括 (ι/(該成形透明基板之片段總數))部分之該成形玻璃透明 基板;將該成形透明片段固定在一起,以提供該成形透明 基板’其中該成形透明基板尤其包括凸表面及具有焦點區 之相對的凹表面,且在該透明基板之至少一表面上方提供 一反射塗層。 【實施方式】 在以下討論中,關於本發明之空間及方向術語,如 「内二「外」、「左」、「右」、「上」、「下」、「水平」、「垂 直」等係如其顯示於圖中。然而應瞭解,本發明可假設多 種選擇疋向,且因此此等術語不應視作限制性。此外應瞭 解,用於本專利說明書及專利申請範圍之表現尺寸、物理 特性等等的所有數字在所有情況下視作被術語「約」修 飾因此,除非有相反的表示,否則在以下專利說明書及 專利申請範圍規定之數值將依據本發明意欲獲得之需求特 147285.doc 201101521 性而不同。在最低限度,而不是意圖限制等效於該專利申 請範圍之教義上之應用,至少應按照所報告的有效數位的 數Ϊ且藉由應用日常的四捨五入技術理解各數值參數。此 外應瞭解,本文揭示之所有範圍係包括任何及所有其納入 之子範圍。例如,Γ1至10」之既定範圍應視為包括任何及 所有在最小值為丨與最大值為10之間(及包括)的子範圍;意 即’所有以最小值為i或更大開始及以最大值為10或更^ ο 〇 結束之子範圍,例如m7、或3 2至81、或5 5至10。此 外,本文使用之術語「在…上方施用」或「在...上方提 供」意即施用或提供但不—定在表面接觸。例如,將一材 料施用至一基板或基板表面上方」並不排除在該沉積材 料與該基板或基板表面之間存在一或多種其他相同或不同 組成之材料。 在°寸順夕項本發明之非限制性實施例前,應瞭解,本發 Z不限於本文顯示及討論之特定非限制性實施例之細節的 :二因為本發明可係其他實施例。此外本文用於討論 本發明之術語係為描述之目的而非限制性 外說明,否則力,V nr ϋ ^ ^ 、在下纣論令類似的編號係指類似的元件。 本發明之障壁塗層或層係以下詳細討論之石夕铭氧化物塗 ^ =發明之,夕銘氧化物塗層亦提供對抗機 ==損傷(例如,自具有阳範圍7_(及尤其係9 至14)之物質的化學蝕 保護。除非另外說明,否則以 下關於本發明塗層之陸辟 土特性之討論係適於本發明塗層之 3 性。就此言之’在塗層厚度低於50奈米(以下亦 147285.doc 201101521 稱為「nm」)下,本發明之矽鋁氧化物塗層失去對機械損 傷及化學損傷之抗性。 為明確地進行討論,術語「鹼性障壁層或塗層」及「鈉 離子障壁層或塗層」意指一層或塗層,其作用為作為避免 或限制在上方或表層上施加有該層或塗層的表面上形成驗 性或納沉澱的障壁,且視情況具有避免或限制上述表面之 機械及/或化學損傷之抗性。「保護性層或塗層」意指一層 或塗層’其具有避免或限制對該表面(施用該層或塗層於 其上方,或表層上)之機械及/或化學損傷之抗性,及/或可 限制在該表面上形成鹼性或鈉沉澱。 將討論本發明之非限制性實施例,其使用磁控濺射真空 沉積(以下亦稱為「MSVD」)塗層處理以施用塗層或層或 膜於一基板表面上方或表層上’該基板表面係對抗鹼性離 子之障壁’例如,避免該等鈉離子與大氣中之水分反應並 將該等鈉離子轉化為鈉化合物(例如氫氧化鈉及碳酸鈉), 該等化合物如以上所討論沉澱在該玻璃之表面上)。應瞭 解,本發明並不限於該塗覆方法,且該塗覆方法可係任何 在玻璃表面上或上方施用或塗布驗性離子(例如鈉離子)、 障壁膜或層之塗覆方法。 以下討論係針對施用鹼性離子障壁塗層或層之非限制性 貫施例。除非另外說明,否則該討論可適於耐劃痕塗層或 〇 應瞭解,該玻璃基板或片對本發明不具限制性,且該玻 璃可係任何組成之玻璃;該玻璃可係透明或有色玻璃,及/ 147285.doc 1Λ 201101521 或該玻璃可係經退火、熱加強或回火之玻璃。該玻璃片或 基板可具有任何形狀、厚度及大小。本發明之非限制性實 施例係作為關於太陽能反射鏡之實施例呈現。然而本發明 不限於此,且可實行本發明於製造:商業及住宅窗戶;淋 浴門玻璃;用於空氣、空間、土地及水車輛之透明物;塗 層瓶;用於薄膜光伏打應用之經塗覆之玻璃;用於防霧商 用冰箱之電加熱的玻璃;及作傢具用之玻璃。 在以下討論中,該成形太陽能反射鏡係指抛物面形反射The light passing through the precipitate is away from the focus of the first mirror. The sodium compound on the surface of the concave glass is a diffusing surface (which directs the reflection and the focus of the mirror). The term 147285.doc 201101521 is used herein to mean that a ray of light incident on the reflective surface has a light reflecting surface equal to the angle of incidence of the angle of reflection. The term "non-mirror or diffuse surface" as used herein means that the light incident on the reflective surface has a light reflecting surface that is different from the angle of incidence of the reflected angle. Another limitation of the glass must be handled with care to avoid scratching the glass surface. Scratches on the surface of the glass can also transform the mirror into a non-specular or diffuse surface. As will be appreciated by those skilled in the art, since the reflective concave surface changes from a specular surface to a non-specular or diffuse surface, the percentage of reflected solar light incident on the focus of the parabolic mirror will be reduced, thereby reducing the solar mirror. effectiveness. Techniques for removing and/or eliminating the precipitation of sodium compounds from the concave surface of the parabolic mirror include cleaning the surfaces and/or enclosing the concave surface of the mirror in a sealed chamber having an inert gas to prevent precipitation of the sodium ions. . Current techniques for removing scratches include polishing the surface of a scratched glass sheet. All of these techniques to ensure that the surface of the solar mirror remains mirrored are extremely expensive. The barrier layer is known in the art, for example, as disclosed in U.S. Patent Nos. 4,238,276, 5, 270, 615, 5, 830, 252 and 6, 027, 766, and U.S. Patent Application Serial No. 08/597,543, and U.S. Patent Publication No. 2007/0275253 A1. One limitation of currently available alkaline barrier layers and/or scratch resistant layers is that they can be effectively applied to the planar or shaped surface of a glass substrate, but cannot be effectively used to subsequently form a curved surface (eg, a concave parabolic mirror). Surface) of the surface of the plate. In the prior art, the problem that must be solved when the substrate coated with the barrier layer and/or the scratch-resistant layer is from the planar coated substrate is a parabolic coated substrate. Identification or discussion is minimal (if any). More specifically, in the prior art, the fracture and/or buckling of the coating is eliminated when the profile of the coated glass is changed from a flat glass sheet to a shaped glass substrate having a concave surface. There are very few discussions (if any). As in the present application. (d) Solution '# When the barrier coating is pressed, the coating is broken and the ions are exposed to the atmosphere' and a steel compound precipitates on the surface of the glass substrate, and/or when When the barrier coating and/or the ten-scratch coating buckles, the surfaces change from a specular surface to a non-specular or diffuse surface. As will be appreciated by those skilled in the art, an alkaline barrier coating or layer having a scratch resistant property (e.g., a sodium ion barrier coating) is provided to prevent the concave surfaces of the first and second mirrors from being converted from specular to Non-mirror or diffuse surfaces will be an advantage. SUMMARY OF THE INVENTION The present invention is directed to a solar mirror having a curved reflective surface, and particularly comprising a transparent substrate having a convex surface and an opposite concave surface, and a reflective coating over the convex surface and - An organic barrier layer or coating over the concave surface. The reflective coating reflects the electromagnetic spectrum of the selected wavelength. Furthermore, the present invention relates to a method of manufacturing a solar energy mirror having a curved reflective surface, in particular by providing a flat transparent sheet; shaping the sheet to provide a convex surface and an opposite concave surface and focus The region is opened to a transparent substrate, a reflective coating is applied over the convex surface of the substrate, and an alkaline barrier layer is provided over the concave surface of the substrate. Furthermore, the present invention relates to a base 147285.doc 201101521 barrier layer comprising, inter alia, an oxide of bismuth and aluminum. Furthermore, the invention relates to a solar reflector having a curved reflective surface. The mirror includes, in particular, a plurality of transparent shaped segments; a fixture is provided to hold the segments together to provide a shaped transparent substrate having a convex surface and a relatively concave surface, the shaped substrate having a focal region and solar reflection above the surface a coating, wherein the coating reflects visible and infrared light of the electromagnetic spectrum toward a focal region of the shaped transparent substrate. The invention further relates to a method of making a shaped solar mirror. The method is achieved, inter alia, by shaping two or more flat transparent segments to provide two or more shaped transparent segments, wherein each of the shaped transparent segments comprises a portion of (i / (the total number of segments of the shaped transparent substrate)) a glass transparent substrate; the shaped transparent segments are secured together to provide the shaped transparent substrate, wherein the shaped transparent substrate comprises, in particular, a convex surface and an opposite concave surface having a focal region, and is provided over at least one surface of the transparent substrate A reflective coating. [Embodiment] In the following discussion, the spatial and directional terms of the present invention, such as "inside", "outside", "left", "right", "upper", "lower", "horizontal", "vertical", etc. It is shown in the figure. It should be understood, however, that the present invention can assume a variety of alternative orientations, and thus such terms should not be construed as limiting. In addition, it should be understood that all numbers of the dimensions, physical characteristics, and the like, which are used in the specification and the scope of the patent application, are to be construed as being modified by the term "about" in each case, and unless otherwise indicated, the following patent specification and The numerical values specified in the scope of the patent application will vary according to the requirements of the invention which are intended to be obtained by the invention. At the minimum, and not as intended to limit the application of the teachings equivalent to the scope of the patent application, the numerical parameters should be understood at least in accordance with the number of significant digits reported and by applying routine rounding techniques. In addition, it should be understood that all ranges disclosed herein are inclusive of any and all sub-ranges thereof. For example, the stated range of Γ1 to 10" shall be deemed to include any and all sub-ranges between (and including) a minimum of 丨 and a maximum of 10; that is, 'all starting with a minimum of i or greater and A sub-range ending with a maximum of 10 or more, such as m7, or 3 2 to 81, or 5 5 to 10. In addition, the terms "administered above" or "provided above" are used herein to mean that they are applied or provided but not intended to be in surface contact. For example, applying a material to a substrate or substrate surface does not exclude the presence of one or more other materials of the same or different composition between the deposition material and the substrate or substrate surface. In the prior art, the present invention is not limited to the details of the specific non-limiting embodiments shown and discussed herein. Further, the terminology used herein is for the purpose of description and not limitation, unless otherwise, the sufficiency, V nr ϋ ^ ^ The barrier coating or layer of the present invention is discussed in detail below. In the invention, the Ximu oxide coating also provides resistance to the machine == damage (for example, from the positive range 7_ (and especially the system 9) The chemical etching protection of the substance to 14). Unless otherwise stated, the following discussion of the characteristics of the soil of the coating of the present invention is suitable for the properties of the coating of the present invention. In this case, the coating thickness is less than 50 nm. (The following 147285.doc 201101521 is called "nm"), the bismuth aluminum oxide coating of the present invention loses resistance to mechanical damage and chemical damage. For the sake of clarity, the term "alkaline barrier layer or coating" And "sodium ion barrier layer or coating" means a layer or coating that acts to avoid or limit the formation of an inspector or nanoprecipitate barrier on the surface on which the layer or coating is applied or on the surface layer, and Having the resistance to mechanical or/and chemical damage to the above surfaces, as appropriate. "Protective layer or coating" means a layer or coating which has the ability to avoid or limit the surface (application of the layer or coating) Above it, or on the surface Resistance to mechanical and/or chemical damage, and/or may limit the formation of alkaline or sodium precipitates on the surface. A non-limiting embodiment of the invention will be discussed, which uses magnetron sputtering vacuum deposition (hereinafter also a coating treatment called "MSVD" to apply a coating or layer or film over a substrate surface or on a surface layer 'the substrate surface is a barrier against alkaline ions', for example, to prevent such sodium ions from reacting with moisture in the atmosphere The sodium ions are converted to sodium compounds (e.g., sodium hydroxide and sodium carbonate) which precipitate on the surface of the glass as discussed above). It should be understood that the present invention is not limited to the coating method, and the coating method may be any coating method of applying or coating an ion (e.g., sodium ion), a barrier film or a layer on or above the surface of the glass. The following discussion is directed to a non-limiting example of the application of an alkaline ion barrier coating or layer. Unless otherwise stated, the discussion may be adapted to a scratch resistant coating or enamel that is not limiting to the invention, and the glass may be a glass of any composition; the glass may be a clear or tinted glass, And / 147285.doc 1Λ 201101521 or the glass may be annealed, heat strengthened or tempered glass. The glass sheet or substrate can have any shape, thickness and size. Non-limiting embodiments of the invention are presented as embodiments relating to solar mirrors. However, the invention is not limited thereto, and the invention can be practiced in the manufacture of: commercial and residential windows; shower door glass; transparency for air, space, land and water vehicles; coated bottles; for thin film photovoltaic applications Coated glass; electrically heated glass for anti-fog commercial refrigerators; and glass for furniture. In the following discussion, the shaped solar mirror refers to parabolic reflection
鏡’然而,本發明並不限於此,且除非另外說明,否則本 發明可使用任何具有彎曲反射表面及焦點或焦點區之面鏡 實行,例如(但不限於本發明):抛物面形鏡及球面形鏡。 「焦點」及「焦點區」定義為其中8〇%以上自該鏡反射的 太陽光線所會聚的位置。該「焦點區」之大小及位置係不 限制本發明,且在一項本發明之非限制性實施例中,該焦 點區係少於該鏡反射區之五分之一(丨/5)。 如圖1所示,其係一先前技術之成形太陽能集光器2〇(參 見圖2)以將太陽能轉換為電能之陣列丨8。本發明係不限 制在該陣列18中連接該等太陽能集光器2〇之方式,且任何 相關技藝已知之技術皆可用於該陣列18中連接該太陽能集 光器20。此外,本發明係不限制在該陣㈣中之太陽能集 光器20之數量,例如本發明可在一個太陽能集光器滅 2、3、4、5、10、20、多於5〇個之陣列及任何數量之太陽 能集光器組合上實行。此外’本發明設計_以任何習知方 式安裝於固定位置之太陽能集光器2〇之陣列Η,或一以任 147285.doc 201101521 何習知方式安裝的太陽能集光器20之陣列18,卩追縱太陽 路徑使該太陽能集光器於太陽能下之暴露量達到最大。每 個太陽能集光器20各可具有相同或具有不同的設計,以將 該太陽能量引導至特定區域,於此區域將太陽能量轉換為 另類能源(例如電能或熱能)。 參考圖2’每個太陽能集光器心包括—成形反射鏡, 例如抛物面形鏡22(本文亦稱為「第—鏡」)以集中太陽能 於裝置26上,從而將太陽能轉換為電能。該抛物面形鏡“ 包括一抛物面形玻璃基板28。該玻璃基板28較佳具有低於 〇.〇20重量%之總離子含量、在可見範圍内(例如35〇至77〇 不米(nm」))及紅外(r IR」)範圍内(例如高於77〇至 奈米(「nm」))之電磁頻譜的9〇%透射,及低吸光度(例 如,在該可見範圍及紅外範圍内之低於2%)。具有前述光 學特性之玻璃係揭示於“⑽年丨丨月21曰申請之美國專利申 請案第12/275,264號及美國專利第5,〇3〇,594號中,該等文 獻之全文以引用的方式併入本文中。ppG IndusiHes,inc 出售具有以上特性之玻璃,商標名為STARpHIRE及 SOLARPHIRE PV。該成形玻璃基板28具有凹表面3〇及相 對的凸表面32。使成形玻璃基板28之外周成形以提供邊 33。如圖1所示,相鄰太陽能集光器2〇之邊33彼此接觸以 使既定具有反射表面之區域的覆蓋達到最大。一反射塗 層、層或膜34(清晰地顯示於圖2中)係在該成形玻璃基板28 之凸表面32上方(及較佳係其表層上)。該反射膜34可係金 屬,例如但不限於:銀、鋁、鎳、不銹鋼或金。該反射膜 147285.doc 12 201101521 34通常係銀。 〇 ❹ 繼續參考圖2 ’由射線36表示之平行太陽能射線係入射 至該凹表面30上。該等射線36之一部分37係自該凹表面30 反射至該轉換裝置26,及一部分38穿過該凹表面3〇並透過 该成形玻璃基板28,並自該反射膜34之表面42以反射線 43(参考圖2A)形式通過該成形玻璃基板28反射回至該轉換 裝置26。為清晰及簡潔之目的,該等太陽能射線係以兩條 射線36代表顯示於圖2中,而不是無限多的平行太陽能射 線入射至该凹表面30上。此外,如熟習此項技術者所瞭 解,在該成形玻璃基板28之凹表面3〇與凸表面32之間有該 等太陽光線之反射;然而,該等入射及穿過透明基板之太 陽能射線的透射、吸收及反射之詳細討論係相關技藝已熟 知且沒有必要進一步討論。 在圖1及2中顯示之實施例中,該轉換裝置%包括相對於 該抛物面形鏡或第一鏡22之焦點放置的成形第二鏡44,及 在該第二鏡44之焦點區之光桿或光棒邨(明確地顯示於圖2 中)。多接點太陽能電池48係置於該光棒46之末端5〇。由 於此配置’該反射光線37及43(參見圖2A)係人射至該第二 鏡44上;該第二鏡將該射線37及43反射至該光棒46之末端 52(:月碎地顯示於圖2中)。穿過該光棒46並穿出該光棒仏之 末端50之射線37及43係人射至該太陽能電池48以將該太陽 能轉換為電能。如熟習此項技術者所瞭解,該太陽能電池 48可置於該第-鏡22之焦點處,而略去該第二鏡44。 本發明係不限制該第二鏡44之形狀。更特定而言,在本 147285.doc 13· 201101521 發明實務中,該第二鏡較佳具有平板反射表面。在本發明 實務中,該第二鏡係具有太陽能反射塗層表面(例如銀塗 層表面)之圓形平板玻璃片。然而,本發明可使用具有凹 及凸表面之成形第二鏡及在至少一個該表面(例如凸表面) 上之反射塗層而實行。 參考圖1,在太陽能集光器之陣列上方支撐一蓋罩6〇(部 分顯示於圖丨之左上角),以避免灰塵及水沉積於該太陽能 集光器20之抛物面形鏡22的凹表面30上。如相關技藝已 知,該蓋罩60對可見光及電磁波規格IR波長範圍之係透明 的。視情況,該第一鏡22之成形玻璃基板28在該玻璃成形 基板28之底部具有一切口 64(明確地顯示於圖2中),以提供 通達該光棒46及該太陽能電池48之管道。 如以上「先前技術」部分所討論,目前可用的太陽能集 光器之限制係使用鈉鈣矽玻璃基板於該第一鏡22及於該第 二鏡44。該等玻璃基板通常係自浮法玻璃方法(例如,揭 不於美國專利第3,333,936及4,402,722號之玻璃製造方法, 其之王文以引用的方式併入本文中)製造之連續玻璃帶切 塊得之切割玻璃片。如相關技藝所熟知,該鈉鈣矽玻璃含 有鈉離子。長期的環境暴露(例如於撞擊該第一鏡。之該 等太陽光線36)加熱該成形玻璃基板28,且加熱該玻璃以 形成該抛物面形基板28,為鈉離子提供能量,而自該成形 玻璃基板28擴散或浸出。自該成形玻璃基板28浸出之納離 子在該表面30及32上與大氣中之水分反應並將該等納離 子轉換為鈉化合物,例如氫氧化鈉及碳酸鈉。該等鈉化合 147285.doc •14· 201101521 物以沉澱物形式沉積於該成形玻璃基板28之表面上。在該 成形玻璃基板28之凹表面30上之鈉化合物沉澱減少該成形 玻璃基板28之可見光透射,且使部分具有該鈉化合物沉澱 之凹表面30成為非鏡面或漫射表面(其引導該等反射線37 及43遠離該第一鏡22之焦點,或遠離該第二鏡44)。在該 第一鏡22之凸表面32上有少量(如果有的話)鈉化合物沉 澱’因為該凸表面具有該反射塗層34及在該反射塗層上方 之保護性塑料塗層或膜53(僅在圖2中顯示)。如相關技藝所 知’該保護性塗層53保護該反射塗層34防止環境傷害,且 在本發明之實務中,該保護性塗層53限制位在該玻璃基板 28凸表面32上之鈉離子防止其與該環境物反應而形成鈉沉 澱物。雖然該反射塗層34之保護性塗層53避免形成鈉化合 物沉澱,但是本發明設計在該玻璃基板28之凸表面32上實 行本發明。如現在可瞭解,由鈉鈣矽玻璃製成之第二鏡44 可具有如該第一鏡22相同的缺點,除了在該第二鏡上之鈉 化合物沉澱引導自第一鏡22反射之光線遠離該光桿牝以 外。 參考圖3,在一項本發明之非限制性實施例中,該第一 鏡22之成形玻璃基板28之凹表面3〇具有一鈉障壁塗層或層 或膜66。 參考圖4,將該鈉障壁塗層66施用於一圓形平板玻璃片 70之表面68上方(及較佳於其表層上)。該破璃片%之表面 68係指定為該成形玻璃基板28之凹表面3〇。在本發明實務 令’該障壁層66較佳透射多㈣%,更佳多於㈣及最佳力 147285.doc 15 201101521 麵之可見光及具電磁波長度之爪光。該障壁層66較佳 可承受高於該玻璃之成形及彎曲溫度的溫度,例如對於納 鈣矽玻璃而言,高於1220。華氏度(「F」)之溫度。此外, 該障壁層66較佳係不會在該玻璃片7()成形期間碎裂或屈曲 至某一程度,故而鹼性離子(例如鈉離子)不能移動穿透該 障壁塗層66中之裂縫,且該屈曲不會使該等射線”及“明 顯偏折遠離該拋物面形鏡22之焦點。在障壁塗層66中之碎 裂及該障壁塗層66之屈曲的討論更詳細地顯示如下。 在一項本發明之非限制性實施例中,該圓形平板玻璃片 7〇具有18英吋(45.72釐米(「(:111」))之直徑及〇〇83英吋(21 毫米(「mm」))之厚度。將85原子%矽及15原子%鋁之氧化 物之800埃厚的障壁塗層66藉由MSVD塗覆方法沉積於該玻 璃片70之表面68(指定為該成形玻璃基板28之凹表面3〇) 上。將该經塗覆之玻璃片之表面72(指定為該成形玻璃基 板28之凸表面32)置於一真空成形模具76(參見圖5A)之開 口端74,且將該玻璃片70及該模具76在爐(未顯示)中加熱 以加熱該玻璃片至1220卞(660。攝氏度(「C」))。以任何通 常的方式將該經塗覆之玻璃片70及該真空模具76均勻加 熱。將該經塗覆之玻璃片70及該真空模具76加熱至1220T (660 C )後,藉由間隔孔77將空氣自該模具76之内部78抽 空’以迫使該加熱的玻璃片70進入該真空模具76之内部 78 ’獲得具有該塗層66之成形玻璃基板28(參見圖5B)。所 加熱的成形玻璃基板係可控制地冷卻,以使該成形玻璃基 板退火。如可瞭解’本發明設計分別加熱該玻璃片70及該 147285.doc 201101521 真空模具76,且因此放置該玻璃片7〇於該真空模具%之開 口端74上’並如上描述使該玻璃片7〇成形。用於加熱玻 璃、在真空模具中使玻璃成形、用於退火玻璃及塗布玻璃 之方法及設備係相關技藝所熟知且沒有必要詳細討論。 • 在該成形過程期間,由於該平板玻璃片70(參見圖4)係 偏向或拉入該真空模具76之内部78,所以該平板玻璃片7〇 之中間部分79係經拉伸。因為該拉伸之結果,在該成形玻 璃基板28(參見圖5B)之底部區域80處(對應於圖4中該玻璃 Ο 片70之中間部分79及圖3中洞64)的厚度係該玻璃片7〇(參見 圖4)之中間部分79之厚度的80%,且該成形玻璃基板28(參 見圖5B)之邊緣81的厚度係該平板玻璃片7〇(參見圖句之邊 緣82之厚度的1〇5%。如可瞭解,該成形玻璃基板28之邊 緣81係經高度應變且具有光學失真。在本發明之實務中 (但不限於此),將該成形玻璃基板28(參見圖5b)之一片段 83切除’以移除部分經高度應變及光學上失真之玻璃,並 ◎ 將相鄰的成形太陽能鏡2〇之邊33放置成彼此緊靠,如該陣 列1 8 (參見圖1)中所示。在本發明之實務中,但不限制本發 明’將自該成形玻璃基板28之外周邊緣84朝向該底部 8〇(參見圖5B)測得約2英吋之區段切除。將該成形玻璃基 板之外周邊緣的另外部分移除以獲得該成形玻璃基板28之 邊3 3(參見圖3)。在該成形玻璃基板28之底部區域8〇(參見 圖5B)切出該切口或洞64(參見圖3)。之後,將該反射塗層 (例如銀層)34施用於該成形玻璃基板28(參見圖3)之凸表面 32上方’且將該保護性膜53(參見圖2)施用於該反射塗層34 147285.doc 201101521 上。 如所瞭解’本發明係不限制在該成形玻璃基板28之底部 區域80(參見圖5B)中切除該洞64、切除該成形玻璃基板之 外周邊緣84之方法,或不限制在該成形玻璃基板28之凸表 面32上方施用該反射塗層34及該保護性塗層53之塗覆方 法’且任何相關技藝中已知之切除及/或塗層技術可用於 本發明實務中。 在1200。至13〇〇卞(649。至704°C)範圍之溫度下,該玻璃 片7 0係熱軟化或黏性;在另一方面,本發明之障壁塗層 ό6(例如紹及石夕之氧化物)係对火材料且在12〇〇。至丨3⑼。^ (649至704 C )範圍之溫度下保持尺寸上安定。本文使用之 術語「尺寸上安定」意指該塗層之物理尺寸在加熱該玻璃 片期間(及/或之後)改變不多於±5%及較佳不多於士2%。在 s亥平板玻璃片70成形至該成形玻璃基板28期間,顯示於圖 6至8中之應變模式在該成形玻璃基板28中發展。根據需要 參考圖6至8,由數字90所示之徑向張力應變係存在於該成 形玻璃基板之底部(參考圖8) ’且由數字92所示之圓周麗縮 應變係存在於該成形玻璃基板28之外周84。該障壁塗層66 體驗由於黏附至該玻璃基板之凹表面的應力。隨著在朝向 6亥成形玻璃基板28之底部區域8〇方向上距該成形玻璃基板 28之外周84的距離增加(參見圖7),該徑向張力應變9〇一般 保持不變,且該圓周壓縮應變92下降至指定為「過渡線」 之位置且在圖7中由數字9 4確定,此處由數字1 〇2指定之圓 周張力應變(參見圖8)在該玻璃中開始且該徑向張力應變 147285.doc •18- 201101521 9〇(參見圖8)係存在於該玻璃中。對於所討論之成形玻璃基 板28(例如由具有18英吋(45 72 cm)之直徑及〇 〇83英对(2」 mm)之厚度的平板玻璃片7〇製得之該成形玻璃基板28)而 吕’該過渡線94係對應於在該平板玻璃片7〇上距中心 (即:距該平板玻璃片70之中心部分79之中心)約3英吋 (7.62 cm)的位置之一該成形玻璃基板28上的位置。隨著在 朝向該成形玻璃基板28之底部區域80方向上距該過渡線94 的距離增加’該成形玻璃基板具有增加的(由數字1〇2指定 〇 之)圓周張力應變且具有該徑向張力應變90(參見圖8)。 如熟習此項技術者所瞭解’在該成形玻璃基板28中之應 文可藉由任何習知方法測量。在本發明實務中,所討論之 該成形玻璃片28之應變係使用ANSYS有限元素電腦程式計 算得。 在該成形玻璃基板28之圓周壓縮區域1〇3(即,在該成形 玻璃基板28(參見圖7)之外周84與該過渡線94之間之區域) 中,觀察到鈉障壁塗層66在垂直於該玻璃中之壓縮應變的 徑向上具有屈曲。在該過渡線94位置中,觀察該障壁塗層 66具有徑向裂縫區域。在該成形玻璃基板28之圓周張力區 ' 域104(即,在該成形玻璃基板28(參見圖7)之過渡線94與該 底部區域80之間之區域)中,觀察該障壁塗層66具有小的 無規裂縫或碎裂。 如上所述,最大壓縮應力係在該成形玻璃基板28(參見 圖5B及7)之邊緣部分81,且預計該障壁塗層66之最大屈曲 將存在於δ亥邊緣部分8 1上。亦已觀察到,極少數撞擊該初 147285.doc -19- 201101521 步成形玻璃基板28之邊緣部分8】之太陽光線係引導至該成 形玻璃基板28之焦點或焦點區。鑒於上述情況,將自該成 形玻璃基板28之外周邊緣84延長的一段距離(其等於該外 周邊緣84至該初步成形玻璃基板之底部區域8〇的中心測得 之距離的10至15%)之該初步成形玻璃基板28之邊緣部分8ι 移除在項本發明之非限制性實施例中,對於由具有j 8 英吋(45.72 cm)之直徑的平板玻璃片7〇成形之成形玻璃基 板28而έ,切除自該成形玻璃基板之外周邊緣朝向該底 部8〇(參見圖叫測得之約2英忖(5 〇8⑽)的區段,以移除 部分之該經高度應變及光學上失真的玻璃。將該成形玻璃 基板之外周邊緣的另外部分移㊉以提供該成形玻璃基板 28(參見圖3)之邊33。 寸,見在係針對於所觀察及/或預期的由該障壁塗層 之裂縫或碎裂造成之缺陷,及所觀察及/或預期的由 轉壁塗層之屈曲造成之缺陷。據預計,擴展跨經該障壁 塗⑽厚度之碎裂或裂縫會為大氣中之水分與該玻璃浸出 之鈉離子提供通道,使其彼此相互作用形成沉積於該障壁 塗層66(參見圖7)之表面⑽上及/或在該成形玻璃基板28之 '、凹表面3〇之間的納化合物沉澱。在該障壁塗 二6之表面1〇8上之鈉化合物可將該障壁塗層66之鏡面改 邊為非鏡面或主 飞<射表面,且在該障壁塗層與該凹表面3〇之 間的鈉化合物可造成該障壁塗層66之分離。 屈曲缺陷可將該障壁塗層66之表面1〇8自鏡面改變為非 鏡面或漫射表面,且嚴重的屈曲情況下可(另外)造成該障 147285.doc -20- 201101521 壁塗層之碎裂。以下討論係針對該障壁塗層66,且除非另 外說明,否則該討論係可適用於該障壁塗層之耐劃痕特性 (如上所述)。 根據需要參考圖9A至9C,在該玻璃片7〇(圖9A)之片段 110(預期成為圓周壓縮區域1〇3(參見圖7))上之障壁塗層66 具有在邊112與113之間測得之長度,及在邊1〗6與117之間 測得之寬度。將該玻璃片70成形為該成形玻璃基板28之 後’該平板玻璃片70之片段11〇對應於該成形玻璃基板28 〇 之片段118。該成形玻璃基板28之片段Π8之凸表面32具有 如在該片段118之邊112與113之間測得之長度,其係稍大 於在該平板玻璃片70之片段11〇之邊112與ι13之間測得之 長度’且該成形玻璃基板28之片段118之凸表面32具有如 在該片段118之邊116與117之間測得之寬度,其係小於如 在該片段118之邊116與117之間測得之在該平板玻璃片7〇 之片段110之寬度。該成形玻璃基板28之片段118之凹表面 ◎ 3 0具有如在該片段11 8之邊112與113之間測得之長度,其 係稱大於在該平板玻璃片7〇之片段11〇之邊112與113之間 測得之長度’且該成形玻璃基板28之片段118之凹表面3〇 具有如在該片段118之邊116與117之間測得之寬度,其係 小於如在片段118之邊116與n7之間測得之該平板玻璃片 70之寬度。 在該凸表面32之長度與該凹表面3〇之長度(如在該片段 118之邊112與113之間測得)之間增加的差異較小。在該凹 表面30之寬度(如在該片段118之邊116與117之間測得)之間 147285.doc 21 201101521 的下降差異係大於在該片段118之凹邊與凸邊之間的差 異。藉由闡述的方式但不限制本發明,在該片段丨丨0之邊 112與113之間及在該片段ι18之邊112與U3之間測得之膨 脹對於凹邊及該凸邊而言皆係2至6%。在該成形玻璃基板 28之外周測得之在該片段11〇之邊116與118之間及在該片 段118之邊116與118之間的收縮係14%,其中具有14%收縮 之凹邊30及具有13%收縮之凸邊32。在該成形玻璃基板28 之底部80 ’對於該凸及凹邊之伸長率分別為5%及4%。 Ο 另一方面,該障壁塗層66之長度及寬度保持不變,且由 於相較於對應的該平板玻璃片7〇之寬度,該成形玻璃基板 28之凹及凸表面的寬度降低而造成的&曲通常稱作應變。 更特定言之,在該成形處理期間,該玻璃係黏稠的,且該 障壁塗層66之屈曲將該成形玻璃基板28之凹表面30的輪廓 改變為具有皺褶120之表s,例如一波紋表面(參見圖 9B),以因應該平板破璃片7〇之表面72的寬度的降低。該 等敏摺12G將該障壁塗層66之表面⑽及該成形玻璃基板28 之凹表面3〇自圖9A中之鏡面改變為圖卯中之非鏡面或漫 射表面。在第-個實例中(圖9B),隨著該障壁塗㈣之厚 度增加(例如,該障壁塗層增加至⑽奈米(「」)之厚 度),而該平板麵片之寬度的收縮量仍保持不變,㈣ 120之數罝及該等皺褶12〇之高度增加,直 ,、增加反射太陽光 線37及43(參見圖2及2A)之漫射百分比。在第二㈣例中 (叫隨者該障壁塗層66之厚度減少(例如,該障壁塗声 6〇⑽之厚度),而該平板破璃片之寬度的收縮量仍 147285.doc •22- 201101521 保持不變,在第二個實例(圖9C)中之皺褶120之數量及該 等皺褶120之高度係低於在第一個實例(參見圖9B)中之皺 褶120之數量及該等皺褶120之高度,其減少反射太陽光線 37及43(參見圖2及2A)之漫射百分比。如上所述,該圓周 壓縮區域103(參見圖7)隨著距該成形玻璃基板28之外周84 的距離增加(參見圖6至8)而減少;因此該成形玻璃基板28 之凹表面30的外周寬度的收縮百分比隨著距該成形玻璃基 ❹Mirror 'However, the invention is not limited thereto, and unless otherwise stated, the invention may be practiced using any mirror having a curved reflective surface and a focus or focus region, such as, but not limited to, the invention: parabolic mirrors and spheres Shape mirror. "Focus" and "Focus Zone" are defined as locations where more than 8% of the sun's rays reflected from the mirror converge. The size and location of the "focus zone" does not limit the invention, and in a non-limiting embodiment of the invention, the focal zone is less than one fifth (丨/5) of the mirror reflection zone. As shown in Figure 1, it is a prior art shaped solar concentrator 2 (see Figure 2) to convert solar energy into an array of electrical energy 丨8. The present invention is not limited to the manner in which the solar concentrators 2 are connected in the array 18, and any technique known in the art can be used to connect the solar concentrators 20 in the array 18. In addition, the present invention is not limited to the number of solar concentrators 20 in the array (4). For example, the present invention can eliminate 2, 3, 4, 5, 10, 20, more than 5 在 in one solar concentrator. The array and any number of solar concentrators are combined. In addition, the present invention is an array of solar concentrators 2 that are mounted in a fixed position in any conventional manner, or an array 18 of solar concentrators 20 that are mounted in any conventional manner, 卩 147 147 285. The solar path maximizes the exposure of the solar concentrator to solar energy. Each of the solar concentrators 20 can each have the same or have a different design to direct the amount of solar energy to a particular area where the amount of solar energy is converted to an alternative source of energy (e.g., electrical energy or thermal energy). Referring to Figure 2', each solar concentrator core includes a shaping mirror, such as a parabolic mirror 22 (also referred to herein as a "first mirror") to concentrate solar energy on the device 26 to convert solar energy into electrical energy. The parabolic mirror "includes a parabolic glass substrate 28. The glass substrate 28 preferably has a total ion content of less than 20% by weight of 〇. 在 in the visible range (eg, 35 〇 to 77 〇 米 (nm)) And infrared (rIR)) (eg, higher than 77〇 to nanometer (“nm”)), 9〇% transmission of the electromagnetic spectrum, and low absorbance (eg, low in the visible range and infrared range) At 2%). The glass system having the aforementioned optical properties is disclosed in U.S. Patent Application Serial No. 12/275,264, the entire disclosure of which is incorporated herein by reference. The manner is incorporated herein. ppG IndusiHes, Inc. sells glass having the above characteristics under the trade names STARpHIRE and SOLARPHIRE PV. The shaped glass substrate 28 has a concave surface 3〇 and an opposite convex surface 32. The outer periphery of the shaped glass substrate 28 is formed. To provide the edge 33. As shown in Figure 1, the edges 33 of adjacent solar concentrators 2 are in contact with each other to maximize coverage of a region having a reflective surface. A reflective coating, layer or film 34 (clearly displayed) 2 is above the convex surface 32 of the shaped glass substrate 28 (and preferably on its surface layer). The reflective film 34 can be metal such as, but not limited to, silver, aluminum, nickel, stainless steel or gold. The reflective film 147285.doc 12 201101521 34 is typically silver. 〇❹ Continuing with reference to Figure 2, a parallel solar ray system, indicated by ray 36, is incident on the concave surface 30. One portion 37 of the ray 36 is from the concave surface 30.The conversion device 26 is directed, and a portion 38 passes through the concave surface 3〇 and through the shaped glass substrate 28, and passes through the shaped glass substrate 28 from the surface 42 of the reflective film 34 in the form of a reflection line 43 (refer to FIG. 2A). Reflected back to the conversion device 26. For purposes of clarity and brevity, the solar ray is represented by two rays 36 as shown in Figure 2, rather than an infinite number of parallel solar rays incident on the concave surface 30. As is known to those skilled in the art, there is reflection of such solar rays between the concave surface 3〇 and the convex surface 32 of the shaped glass substrate 28; however, the transmission of such solar rays incident and through the transparent substrate, A detailed discussion of absorption and reflection is well known in the art and need not be discussed further. In the embodiment shown in Figures 1 and 2, the conversion device % includes shaping relative to the focus of the parabolic mirror or first mirror 22. A second mirror 44, and a polished rod or light bar in the focal region of the second mirror 44 (shown explicitly in Figure 2). A multi-contact solar cell 48 is placed at the end 5 of the light bar 46. This configuration 'the reflected rays 37 and 43 (see FIG. 2A) are incident on the second mirror 44; the second mirror reflects the rays 37 and 43 to the end 52 of the light bar 46 (: monthly display) In Fig. 2), rays 37 and 43 passing through the light rod 46 and passing through the end 50 of the rod stop are directed to the solar cell 48 to convert the solar energy into electrical energy. It is understood that the solar cell 48 can be placed at the focus of the first mirror 22, and the second mirror 44 is omitted. The present invention does not limit the shape of the second mirror 44. More specifically, in this 147285.doc 13. 201101521 In the practice of the invention, the second mirror preferably has a flat reflective surface. In the practice of the invention, the second mirror is a circular flat glass sheet having a solar reflective coating surface (e.g., a silver coated surface). However, the invention can be practiced using a shaped second mirror having concave and convex surfaces and a reflective coating on at least one of the surfaces (e.g., convex surfaces). Referring to FIG. 1, a cover 6〇 (partially shown in the upper left corner of the figure) is supported above the array of solar concentrators to prevent dust and water from depositing on the concave surface of the parabolic mirror 22 of the solar concentrator 20. 30 on. As is known in the art, the cover 60 is transparent to the visible and electromagnetic wave specifications IR wavelength range. Optionally, the formed glass substrate 28 of the first mirror 22 has a port 64 (shown explicitly in Figure 2) at the bottom of the glass forming substrate 28 to provide access to the light bar 46 and the solar cell 48. As discussed in the "Prior Art" section above, currently available solar collectors are limited to the use of a soda-lime-glass substrate to the first mirror 22 and the second mirror 44. The glass substrates are typically manufactured from a float glass process (e.g., a method of making glass according to U.S. Patent Nos. 3,333,936 and 4,402,722, the disclosure of which is incorporated herein by reference) Cutting the glass piece. As is well known in the relevant art, the soda-lime glass contains sodium ions. Long-term environmental exposure (eg, the sun rays 36 striking the first mirror) heats the shaped glass substrate 28 and heats the glass to form the parabolic substrate 28 to provide energy for the sodium ions from the shaped glass The substrate 28 is diffused or leached. Nanoparticles leached from the shaped glass substrate 28 react with moisture in the atmosphere on the surfaces 30 and 32 and convert the nanoparticles into sodium compounds such as sodium hydroxide and sodium carbonate. The sodium compound 147285.doc •14·201101521 is deposited as a precipitate on the surface of the shaped glass substrate 28. Precipitation of the sodium compound on the concave surface 30 of the shaped glass substrate 28 reduces visible light transmission of the shaped glass substrate 28 and causes a concave surface 30 having a portion of the precipitate of the sodium compound to become a non-specular or diffuse surface (which directs the reflections) Lines 37 and 43 are remote from the focus of the first mirror 22 or away from the second mirror 44). A small amount, if any, of the sodium compound precipitates on the convex surface 32 of the first mirror 22 because the convex surface has the reflective coating 34 and a protective plastic coating or film 53 over the reflective coating ( Only shown in Figure 2). The protective coating 53 protects the reflective coating 34 from environmental damage as is known in the art, and in the practice of the present invention, the protective coating 53 limits sodium ions on the convex surface 32 of the glass substrate 28. It is prevented from reacting with the environment to form a sodium precipitate. While the protective coating 53 of the reflective coating 34 avoids the formation of sodium compound precipitates, the present invention contemplates the practice of the present invention on the convex surface 32 of the glass substrate 28. As can now be appreciated, the second mirror 44 made of soda-lime-germ glass can have the same disadvantages as the first mirror 22 except that the sodium compound precipitate on the second mirror directs the light reflected from the first mirror 22 away. The light rod is outside. Referring to Figure 3, in a non-limiting embodiment of the invention, the concave surface 3 of the shaped glass substrate 28 of the first mirror 22 has a sodium barrier coating or layer 66. Referring to Figure 4, the sodium barrier coating 66 is applied over the surface 68 of a circular plate glass sheet 70 (and preferably over its surface layer). The surface 68 of the granules is designated as the concave surface 3 of the formed glass substrate 28. In the practice of the present invention, the barrier layer 66 preferably transmits more than (four)%, more preferably more than (four) and an optimum force 147285.doc 15 201101521 visible light and claw light having an electromagnetic wave length. The barrier layer 66 is preferably capable of withstanding temperatures above the forming and bending temperatures of the glass, such as above 1220 for nano-calcium glass. The temperature of Fahrenheit ("F"). In addition, the barrier layer 66 preferably does not chip or buckle to some extent during the formation of the glass sheet 7 (), so that alkaline ions (such as sodium ions) cannot move through the crack in the barrier coating 66. And the buckling does not cause the rays to "and" deflect significantly away from the focus of the parabolic mirror 22. The discussion of the fracture in the barrier coating 66 and the buckling of the barrier coating 66 is shown in more detail below. In a non-limiting embodiment of the invention, the circular flat glass sheet 7 has a diameter of 18 inches (45.72 cm ("(: 111"))) and a diameter of 83 inches (21 mm ("mm The thickness of the barrier coating 66 of 85 atomic percent and 15 atomic percent of the aluminum oxide is deposited on the surface 68 of the glass sheet 70 by the MSVD coating method (designated as the shaped glass substrate) The surface 72 of the coated glass sheet (designated as the convex surface 32 of the shaped glass substrate 28) is placed on the open end 74 of a vacuum forming mold 76 (see Fig. 5A). And the glass sheet 70 and the mold 76 are heated in a furnace (not shown) to heat the glass sheet to 1220 卞 (660 ° C ("C")). The coated glass piece is in any conventional manner. 70 and the vacuum mold 76 are uniformly heated. After the coated glass sheet 70 and the vacuum mold 76 are heated to 1220T (660 C), air is evacuated from the interior 78 of the mold 76 by spacer holes 77 to force The heated glass sheet 70 enters the interior 78' of the vacuum mold 76 to obtain the formation of the coating 66 a glass substrate 28 (see Fig. 5B). The heated shaped glass substrate is controllably cooled to anneal the shaped glass substrate. As can be appreciated, the design of the present invention separately heats the glass sheet 70 and the 147285.doc 201101521 vacuum mold 76, and thus placing the glass sheet 7 on the open end 74 of the vacuum mold % and shaping the glass sheet 7 as described above. For heating glass, forming glass in a vacuum mold, for annealing glass and Methods and apparatus for coating glass are well known in the art and need not be discussed in detail. • During the forming process, since the flat glass sheet 70 (see Fig. 4) is biased or pulled into the interior 78 of the vacuum mold 76, The intermediate portion 79 of the flat glass sheet 7 is stretched. As a result of the stretching, at the bottom portion 80 of the formed glass substrate 28 (see Fig. 5B) (corresponding to the middle of the glass sheet 70 in Fig. 4) The thickness of the portion 79 and the hole 64) of Fig. 3 is 80% of the thickness of the intermediate portion 79 of the glass sheet 7 (see Fig. 4), and the thickness of the edge 81 of the shaped glass substrate 28 (see Fig. 5B) is Flat glass sheet 7〇 (See 〇5% of the thickness of the edge 82 of the figure. As can be appreciated, the edge 81 of the shaped glass substrate 28 is highly strained and optically distorted. In the practice of the invention, but not limited thereto, A segment 83 of the shaped glass substrate 28 (see Fig. 5b) is cut away to remove portions of the highly strained and optically distorted glass, and ◎ the edges 33 of adjacent shaped solar mirrors 2 are placed in close proximity to each other. As shown in the array 18 (see Figure 1), in the practice of the present invention, but not limiting, the invention will be measured from the peripheral edge 84 of the shaped glass substrate 28 toward the bottom 8 (see Figure 5B). A section of about 2 inches was removed. An additional portion of the outer peripheral edge of the shaped glass substrate is removed to obtain the edge 33 of the shaped glass substrate 28 (see Figure 3). The slit or hole 64 is cut out in the bottom region 8 of the formed glass substrate 28 (see Fig. 5B) (see Fig. 3). Thereafter, a reflective coating (eg, a silver layer) 34 is applied over the convex surface 32 of the shaped glass substrate 28 (see FIG. 3) and the protective film 53 (see FIG. 2) is applied to the reflective coating 34. 147285.doc 201101521 on. As is understood, the present invention is not limited to the method of cutting the hole 64 in the bottom region 80 (see FIG. 5B) of the shaped glass substrate 28, and cutting off the peripheral edge 84 of the shaped glass substrate, or is not limited to the shaped glass substrate. The method of applying the reflective coating 34 and the protective coating 53 over the convex surface 32 of 28 and any cutting and/or coating techniques known in the art can be used in the practice of the present invention. At 1200. The glass sheet 70 is thermally softened or viscous at a temperature ranging from 13 〇〇卞 (649 to 704 ° C); on the other hand, the barrier coating ό 6 of the present invention (for example, oxidation of Shi Xi ()) is a fire material and is at 12 〇〇. To 3(9). ^ (649 to 704 C) maintains dimensional stability at temperatures. As used herein, the term "stable in size" means that the physical dimension of the coating changes by no more than ± 5% and preferably no more than ± 2% during (and/or after) heating the glass sheet. During the formation of the slab glass sheet 70 to the shaped glass substrate 28, the strain patterns shown in Figs. 6 to 8 develop in the formed glass substrate 28. Referring to Figures 6 to 8, as needed, a radial tensile strain system indicated by numeral 90 exists at the bottom of the shaped glass substrate (refer to Figure 8) and the circumferentially swelled strain system indicated by numeral 92 is present in the shaped glass. The outer periphery 84 of the substrate 28. The barrier coating 66 experiences stress due to adhesion to the concave surface of the glass substrate. As the distance from the outer periphery 84 of the shaped glass substrate 28 increases in the direction toward the bottom region 8 of the 6-well shaped glass substrate 28 (see FIG. 7), the radial tensile strain 9 〇 generally remains unchanged, and the circumference The compressive strain 92 drops to the position designated as "transition line" and is determined by the number 9 4 in Figure 7, where the circumferential tensile strain (see Figure 8) specified by the number 1 〇 2 begins in the glass and the radial direction Tension strain 147285.doc • 18-201101521 9〇 (see Figure 8) is present in the glass. For the formed glass substrate 28 in question (for example, the shaped glass substrate 28 made of a flat glass sheet 7 having a diameter of 18 inches (45 72 cm) and a thickness of 83 inches (2" mm)) And the transition line 94 corresponds to one of the positions on the flat glass sheet 7 at a distance of about 3 inches (7.62 cm) from the center (i.e., from the center of the central portion 79 of the flat glass sheet 70). The position on the glass substrate 28. As the distance from the transition line 94 increases in the direction toward the bottom region 80 of the shaped glass substrate 28, the shaped glass substrate has an increased circumferential tension strain (specified by the number 1 〇 2) and has the radial tension Strain 90 (see Figure 8). As will be appreciated by those skilled in the art, the application in the shaped glass substrate 28 can be measured by any conventional method. In the practice of the present invention, the strain of the shaped glass sheet 28 in question is calculated using the ANSYS finite element computer program. In the circumferential compression region 1〇3 of the shaped glass substrate 28 (i.e., in the region between the outer perimeter 84 of the shaped glass substrate 28 (see FIG. 7) and the transition line 94), the sodium barrier coating 66 is observed at There is buckling in the radial direction perpendicular to the compressive strain in the glass. In this transition line 94 position, the barrier coating 66 is observed to have a radial crack region. In the circumferential tension zone ' region 104 of the formed glass substrate 28 (i.e., the region between the transition line 94 of the shaped glass substrate 28 (see FIG. 7) and the bottom region 80), the barrier coating 66 is observed to have Small random cracks or cracks. As described above, the maximum compressive stress is at the edge portion 81 of the shaped glass substrate 28 (see Figs. 5B and 7), and it is expected that the maximum buckling of the barrier coating 66 will exist on the δ-edge portion 81. It has also been observed that a very small amount of solar light impinging on the edge portion 8 of the forming glass substrate 28 of the first step 147285.doc -19-201101521 leads to the focus or focus area of the shaped glass substrate 28. In view of the above, a distance extending from the outer peripheral edge 84 of the shaped glass substrate 28 (which is equal to 10 to 15% of the distance measured by the peripheral edge 84 to the center of the bottom region 8 of the preliminary shaped glass substrate) is The edge portion 8 of the preliminary shaped glass substrate 28 is removed in a non-limiting embodiment of the invention for a shaped glass substrate 28 formed from a flat glass sheet 7 having a diameter of j 8 inches (45.72 cm). έ, cut from the outer peripheral edge of the shaped glass substrate toward the bottom 8 〇 (see the figure about 2 inches (5 〇 8 (10)), to remove the highly strained and optically distorted portion Glass. The additional portion of the peripheral edge of the shaped glass substrate is moved ten to provide the edge 33 of the shaped glass substrate 28 (see Figure 3). See, for example, the barrier coating for the observed and/or anticipated Defects caused by cracks or chipping, and defects observed and/or expected to be caused by buckling of the transfer wall coating. It is expected that the crack or crack extending across the thickness of the barrier coating (10) will be moisture in the atmosphere. With the glass dip The sodium ions provide channels that interact with each other to form a nano-compound deposited on the surface (10) of the barrier coating 66 (see Figure 7) and/or between the ', concave surface 3' of the shaped glass substrate 28. Precipitating. The sodium compound on the surface 1〇8 of the barrier coating layer 6 can change the mirror surface of the barrier coating 66 to a non-specular or main flying <jecting surface, and the barrier coating and the concave surface 3 The sodium compound between the crucibles can cause separation of the barrier coating 66. The buckling defect can change the surface 1〇8 of the barrier coating 66 from a specular surface to a non-specular or diffuse surface, and in the case of severe buckling (additional Producing the barrier 147285.doc -20- 201101521 Fragmentation of the wall coating. The following discussion is directed to the barrier coating 66, and unless otherwise stated, the discussion may apply to the scratch resistance of the barrier coating ( As described above, referring to Figures 9A to 9C, the barrier coating 66 on the side of the segment 110 of the glass sheet 7 (Fig. 9A) (expected to be a circumferential compression region 1〇3 (see Fig. 7)) has a side The length measured between 112 and 113, and the width measured between the edges 1 and 6 and 117 After the glass sheet 70 is formed into the shaped glass substrate 28, the segment 11 of the flat glass sheet 70 corresponds to the segment 118 of the shaped glass substrate 28. The convex surface 32 of the segment 8 of the shaped glass substrate 28 has The length as measured between the sides 112 and 113 of the segment 118 is slightly greater than the length measured between the sides 112 and ι 13 of the segment 11 of the plate glass 70 and the shaped glass substrate 28 The convex surface 32 of the segment 118 has a width as measured between the edges 116 and 117 of the segment 118 which is less than the flat glass sheet 7 as measured between the edges 116 and 117 of the segment 118. The width of the segment 110. The concave surface of the segment 118 of the shaped glass substrate 28 has a length as measured between the sides 112 and 113 of the segment 118, which is said to be larger than the segment 11 of the flat glass sheet 7 The length measured between 112 and 113' and the concave surface 3 of the segment 118 of the shaped glass substrate 28 has a width as measured between the edges 116 and 117 of the segment 118, which is less than as in segment 118. The width of the flat glass sheet 70 is measured between the edges 116 and n7. The difference between the length of the convex surface 32 and the length of the concave surface 3 (as measured between the sides 112 and 113 of the segment 118) is small. The difference in the difference between the width of the concave surface 30 (as measured between the edges 116 and 117 of the segment 118) 147285.doc 21 201101521 is greater than the difference between the concave and convex edges of the segment 118. By way of illustration and not limitation of the invention, the expansion measured between the edges 112 and 113 of the segment 丨丨0 and between the edges 112 and U3 of the segment ι18 is for both the concave edge and the convex edge. 2 to 6%. The contraction between the sides 116 and 118 of the segment 11〇 and between the edges 116 and 118 of the segment 118 measured at the outer periphery of the shaped glass substrate 28 is 14% with a 14% constricted concave edge 30. And a flange 32 having a 13% contraction. The elongation at the bottom 80' of the formed glass substrate 28 with respect to the convex and concave sides was 5% and 4%, respectively. Ο On the other hand, the length and width of the barrier coating 66 remain unchanged, and the width of the concave and convex surfaces of the shaped glass substrate 28 is reduced due to the width of the corresponding flat glass sheet 7〇. & songs are often called strains. More specifically, during the forming process, the glass is viscous and the buckling of the barrier coating 66 changes the contour of the concave surface 30 of the shaped glass substrate 28 to have a surface s of the pleats 120, such as a corrugation The surface (see Fig. 9B) is such that the width of the surface 72 of the flat glass slab 7 is reduced. The viscous fold 12G changes the surface (10) of the barrier coating 66 and the concave surface 3 of the shaped glass substrate 28 from the mirror surface in Fig. 9A to the non-mirror or diffusing surface in Fig. 9A. In the first example (Fig. 9B), as the thickness of the barrier coating (4) increases (for example, the barrier coating increases to a thickness of (10) nanometer (""), and the width of the flat panel shrinks It remains the same, (4) the number of 120 and the height of the wrinkles 12 增加 increase, straight, increase the diffuse percentage of reflected solar rays 37 and 43 (see Figures 2 and 2A). In the second (four) example (the thickness of the barrier coating 66 is reduced (for example, the thickness of the barrier is 6 〇 (10)), and the shrinkage of the width of the slab is still 147285.doc • 22- 201101521 remains unchanged, the number of pleats 120 in the second example (Fig. 9C) and the height of the pleats 120 are lower than the number of pleats 120 in the first example (see Fig. 9B) and The height of the pleats 120, which reduces the percentage of diffusion of the reflected solar rays 37 and 43 (see Figures 2 and 2A). As described above, the circumferentially compressed region 103 (see Figure 7) is offset from the shaped glass substrate 28 The distance of the outer circumference 84 is increased (see FIGS. 6 to 8) to be reduced; therefore, the percentage of shrinkage of the outer peripheral width of the concave surface 30 of the shaped glass substrate 28 is increased from the formed glass base.
板2 8之外周8 4的距離增加而減少’且該障壁塗層6 6之厚度 可在不增加皺褶120之數量及該等皺褶之幅度(參見圖叩及 9C)下而增加。 在一項本發明非限制實施例中,該障壁塗層66之厚度係 經選擇以具有鈉障壁特性且使屈曲最小。更特定言之該 障壁塗層66之最小厚度係經選擇以避免該等納離子與大氣 中之水分反應而將鈉離子轉換為鈉化合物沉殿且以使屈曲 最小。如熟習此項技術者所瞭解’鈉離子自該玻璃移出之 機制係-擴散過程且就本發明之目的而言,受關注的參數 係存在於該玻璃中之納離子的數量。不將擴散速度、驗性 離子(例如鈉離子)大小、及驅動鈉離子至該成形玻璃基板 28之表面的能量視作與本發明相關1因係該太陽能鏡之 使用係一項長期使用,例如3〇年。 =前述内容’在玻璃中之驗性離子或納 該玻璃組成及該玻璃片厚度之函’ 基板28之玻璃片70的厚度增加,則:者細玻璃 的數#it^iμ片中之鈉離子 佳係增加該障壁塗層之厚度及/或密 147285.doc •23- 201101521 度。對於鈉鈣矽玻璃而言,該鈉離子濃度—般係μ重量 %。在-項本發明非限制性實施射,該拋物面形鏡 由具有0.083英吋(2.丨毫米)厚度之玻璃基板製成。在此本 發明非限制性實施例中,該障壁塗層係85原子%矽與Μ原 子%鋁之氧化物的MSVD塗層。避免鈉離子與環境中之水 分反應將該鈉離子轉換為鈉化合物沉澱的最小塗層厚度係 40 nm。如所瞭解,任何大於該最小厚度之厚度皆可避免 鈉離子與環境中之水分反應;然而,隨著該障壁層66之厚 度增加,該屈曲之嚴重度增加。在本發明實務中,在該圓 周張力區域1〇4(參見圖7)中之障壁塗層66較佳係在4〇至j 〇〇 nm之範圍内,更佳在6〇至1〇〇11111之範圍内,且最佳在6〇至 80 nm之範圍内。具有4〇至1〇〇 nm範圍塗層厚度的相同塗 料組合物提供對抗機械及化學侵蝕及/或損傷的保護性塗 層。 如上所述,使用該真空模具76(參見圖5A及5B)使該平板 玻璃片70成形。使該平板玻璃片70成形之後,當該玻璃係 尺寸上安定且經退火時,將該成形玻璃基板自該模具76移 除。對本發明之目的而言’當該成形玻璃可支撐起本身之 重量而不改變其形狀時可視為該玻璃係尺寸上安定。對於 揭示於2008年11月21曰申請的美國專利申請案第 12/275,264號及美國專利第5,030,594號之玻璃而言,該玻 璃在1 050°F之溫度下係尺寸上安定。退火處理降低在該障 壁塗層66中及在該成形玻璃基板28中之内在應力,以使餘 下應力最小,以便在不打破該基板28或壓裂該障壁塗層下 147285.doc -24- 201101521 切割該障壁塗層及該成形玻璃基板28。退火設備及退火該 平板玻璃基板2 8之速度係不限於本發明,且任何相關技藝 已知之退火設備及方法及速度皆可用於本發明實務中。退 火塗層或無塗層之玻璃製品係相關技藝已熟知且沒有必要 進一步討論。 本發明不限制該玻璃片70之厚度,且該玻璃片可係任何 厚度。在較佳的本發明實務中’該玻璃片7〇較佳係輕薄以 提供輕量級的成形玻璃基板28。雖然薄玻璃較佳’但是該 〇 玻璃厚度應足夠厚以具有結構安定性。本文使用之術語 「結構安定性」意指該玻璃必須使用具有最小玻璃破損之 真空模具或壓製模具自該平板玻璃片7〇(參見圖4)處理成該 抛物面形鏡22(參見3)。在本發明實務中,該玻璃厚度較佳 係在0.075至0.126英吋(1.9至3·2 mm)之範圍内,更佳係在 0.078至0·11〇英吋(2·〇至2·8 mm)之範圍内,且最佳係在 0.083至0.091英吋(2.1至2.3 mm)之範圍内。 ^ 在較it的本务明貫務中,該障壁塗層“係1 5原子%銘及 85原子%矽之氧化物。增加鋁之原子%使塗層堅硬。雖然 堅硬的塗層減少屈曲,但是其容易碎裂。在該塗層中之碎 1可導致大氣中之水分與該等鈉離子反應而將該等納離子 轉換為鈉化合物。對於鋁及矽之氧化物之障壁塗層而言, 該等塗層較佳包括30至100原子%矽及〇至7〇原子%鋁,更 佳係50至95原子%矽及5至5〇原子%鋁(例如,川至低於〗⑽ 原子%石夕及高於〇至70原子%銘),且最佳包括6〇至9〇原子% 石夕及10至40原子%銘。如可瞭解,本發明係不限制紹及石夕 147285.doc -25- 201101521 之氧化物之障壁塗層或膜,且任何相關技藝已知類型之鈉 障壁膜可用於本發明實務中。可用於本發明實務中之障壁 塗層類型包括但不限於:揭示於美國公開案 2007/0275253A1中之塗層或膜,該文獻之全文以引用的方 式併入本文中。 如熟習MS VD塗層技術者所瞭解,可改變沉積參數以減 少在該塗層障壁膜中之内在應力;然而,如上所述,該障 壁膜及s玄成形玻璃基板係在相同時間退火以使餘下應力最 小,以使可在不打破該基板28下切割該成形玻璃基板28。 因此,在沉積該塗層期間,減少在該障壁塗層中之内在應 力係視情況而定且不限於本發明。 本發明設計藉由縮短使該玻璃片7〇(參見圖4)成形為該 成形玻璃基板2 8 (參見圖5 b )的時間來減少在該成形玻璃基 板28中之應變。如可瞭解,隨著該玻璃片7〇之溫度升高, 該玻璃之黏度下降,且該障壁塗層66之屈曲幅度增加,原 因係該塗層有時間屈曲至其完全程度,且該玻璃有時間在 及塗層之平面上流動,例如該玻璃有時間流入該障壁塗層 66之皺褶或120中(參見圖9C)。此外,增加該成形時間 (即:拉動該玻璃片70至該成形模具76之腔中所花費的時 間)增加該障壁塗層66之屈曲的幅度,原因係該塗層66有 時間屈曲至其完全程度,且該玻璃有時間流入該障壁塗層 66(參見圖4)之皺褶或12〇中(參見圖9C)。 在本發明實務中,在該玻璃片7〇成形時較佳具有丨〇〇 X 1〇泊至5·36 X 1〇9泊範圍的黏度(當將該玻璃片拉入該真 147285.doc •26· 201101521 空模具76中時)。在此黏度範圍,發現當該成形時間係三 私時發生該障壁塗層66之最小屈曲,且發現當該成形時間 係25秒時發生該障壁塗層66之最大屈曲。基於前述内容, 據預計對於黏度範圍為丨.00 χ 1〇7,8泊至5 36 χ 1〇9泊之玻璃 而言,該障壁塗層66之最小屈曲係大於零至五秒且較佳三 秒’且該障壁塗層之最大屈曲係25或更多秒。 如熟習此項技術者所瞭解,玻璃之溫度對黏度之曲線取 決於該玻璃組成。已確定,由PPG Industries,Inc在註冊 Ο 商標STARPHIRE下出售之鈉鈣矽玻璃類型在1200°F至1300The distance of the outer periphery 84 of the plate 2 8 is increased and decreased' and the thickness of the barrier coating 66 can be increased without increasing the number of wrinkles 120 and the extent of the wrinkles (see Figures 叩 and 9C). In a non-limiting embodiment of the invention, the thickness of the barrier coating 66 is selected to have sodium barrier properties and minimize buckling. More specifically, the minimum thickness of the barrier coating 66 is selected to prevent the sodium ions from reacting with moisture in the atmosphere to convert sodium ions into sodium compound sinks and to minimize buckling. As is well known to those skilled in the art, the mechanism of diffusion of sodium ions from the glass is a diffusion process and for the purposes of the present invention, the parameter of interest is the amount of nano ions present in the glass. The diffusion rate, the size of the detectable ions (e.g., sodium ions), and the energy for driving the sodium ions to the surface of the shaped glass substrate 28 are not considered to be related to the present invention. The use of the solar mirror is a long-term use, for example, 3 years. = The above-mentioned 'inspective ions in the glass or the composition of the glass and the thickness of the glass sheet' The thickness of the glass sheet 70 of the substrate 28 is increased, and the sodium ion in the number of fine glass is #it^iμ The system increases the thickness of the barrier coating and/or the density of 147285.doc •23- 201101521 degrees. For soda-lime-tantalum glass, the sodium ion concentration is generally μ% by weight. In a non-limiting embodiment of the invention, the parabolic mirror is made of a glass substrate having a thickness of 0.083 inches (2 mm). In a non-limiting embodiment of the invention, the barrier coating is an MSVD coating of 85 atomic percent lanthanum and cerium atom % aluminum oxide. Avoid the reaction of sodium ions with the water in the environment to convert the sodium ions into a minimum coating thickness of 40 nm. As is understood, any thickness greater than the minimum thickness prevents sodium ions from reacting with moisture in the environment; however, as the thickness of the barrier layer 66 increases, the severity of the buckling increases. In the practice of the present invention, the barrier coating 66 in the circumferential tension region 1 〇 4 (see FIG. 7) is preferably in the range of 4 〇 to j 〇〇 nm, more preferably 6 〇 to 1 〇〇 11111. Within the range, and optimally in the range of 6 〇 to 80 nm. The same coating composition having a coating thickness in the range of 4 Å to 1 〇〇 nm provides a protective coating against mechanical and chemical attack and/or damage. As described above, the flat glass sheet 70 is shaped using the vacuum mold 76 (see Figs. 5A and 5B). After the flat glass piece 70 is formed, the formed glass substrate is removed from the mold 76 when the glass system is dimensionally stable and annealed. For the purposes of the present invention, the glass may be dimensionally stable when it can support its own weight without changing its shape. The glass is dimensionally stable at a temperature of 1 050 °F for the glass of U.S. Patent Application Serial No. 12/275,264 and U.S. Patent No. 5,030,594, which are incorporated herein by reference. The annealing treatment reduces the intrinsic stress in the barrier coating 66 and in the shaped glass substrate 28 to minimize residual stress so as not to break the substrate 28 or to fracture the barrier coating 147285.doc -24 - 201101521 The barrier coating and the shaped glass substrate 28 are cut. The annealing apparatus and the speed at which the flat glass substrate 28 is annealed are not limited to the present invention, and any annealing apparatus and method and speed known in the art can be used in the practice of the present invention. Arthroplasty or uncoated glass articles are well known and need not be discussed further. The present invention does not limit the thickness of the glass sheet 70, and the glass sheet can be of any thickness. In the preferred practice of the invention, the glass sheet 7 is preferably lightweight to provide a lightweight shaped glass substrate 28. Although thin glass is preferred 'but the thickness of the enamel glass should be thick enough to have structural stability. As used herein, the term "structural stability" means that the glass must be processed into the parabolic mirror 22 (see 3) from the flat glass sheet 7 (see Figure 4) using a vacuum mold or press mold having minimal glass breakage. In the practice of the present invention, the thickness of the glass is preferably in the range of 0.075 to 0.126 inches (1.9 to 3.2 mm), more preferably in the range of 0.078 to 0.11 inch (2. to 2. 8). Within the range of mm), and the optimum is in the range of 0.083 to 0.091 inches (2.1 to 2.3 mm). ^ In the more basic business, the barrier coating "is 1 atomic percent and 85 atomic percent of lanthanum oxide. Increasing the atomic % of aluminum makes the coating hard. Although the hard coating reduces buckling, However, it is easily broken. The crush 1 in the coating can cause the moisture in the atmosphere to react with the sodium ions to convert the nano ions into sodium compounds. For the barrier coating of aluminum and antimony oxides Preferably, the coatings comprise from 30 to 100 atomic % lanthanum and lanthanum to 7 atomic percent aluminum, more preferably from 50 to 95 atomic % lanthanum and from 5 to 5 atomic percent aluminum (for example, Chuanzhi to less than (10) atoms. %石夕和以上至〇至70原子%明), and preferably includes 6〇 to 9〇 atom% Shi Xi and 10 to 40 atom% of Ming. As can be understood, the present invention is not limited to Shi Xi 147285. A barrier coating or film of an oxide of doc-25-201101521, and a sodium barrier film of any type known in the art can be used in the practice of the invention. Types of barrier coatings useful in the practice of the invention include, but are not limited to, disclosure Coating or film in U.S. Publication No. 2007/0275253 A1, the entire disclosure of which is incorporated by reference. The formula is incorporated herein. As understood by those skilled in the art of MS VD coating, the deposition parameters can be varied to reduce the intrinsic stress in the barrier film; however, as described above, the barrier film and the s-shaped glass substrate are Annealing at the same time to minimize residual stress so that the shaped glass substrate 28 can be cut without breaking the substrate 28. Thus, during deposition of the coating, the intrinsic stress in the barrier coating is reduced as appropriate. The present invention is not limited to the present invention. The design of the present invention is reduced in the shaped glass substrate 28 by shortening the time during which the glass sheet 7 (see Fig. 4) is formed into the shaped glass substrate 28 (see Fig. 5b). As can be appreciated, as the temperature of the glass sheet increases, the viscosity of the glass decreases, and the buckling amplitude of the barrier coating 66 increases because the coating has time to flex to its full extent, and The glass has time to flow in the plane of the coating, for example, the glass has time to flow into the pleats or 120 of the barrier coating 66 (see Figure 9C). In addition, the forming time is increased (ie, the glass sheet 70 is pulled to Forming The time spent in the cavity of the mold 76 increases the magnitude of the buckling of the barrier coating 66 because the coating 66 has time to flex to its full extent and the glass has time to flow into the barrier coating 66 (see Figure 4). Wrinkles or 12 inches (see Fig. 9C). In the practice of the invention, the glass sheet 7 is preferably formed to have a viscosity in the range of 丨〇〇X 1 〇 to 5·36 X 1 〇 9 poise. (When the glass piece is pulled into the true 147285.doc • 26·201101521 empty mold 76). In this viscosity range, it is found that the minimum buckling of the barrier coating 66 occurs when the forming time is three private, and it is found The maximum buckling of the barrier coating 66 occurs when the forming time is 25 seconds. Based on the foregoing, it is expected that for a glass having a viscosity range of 丨.00 χ 1〇7, 8 poises to 5 36 χ 1 〇 9 poise, the minimum buckling strain of the barrier coating 66 is greater than zero to five seconds and is preferred. Three seconds' and the maximum buckling of the barrier coating is 25 or more seconds. As will be appreciated by those skilled in the art, the temperature versus viscosity curve of the glass will depend on the composition of the glass. It has been determined that the type of soda-lime-tantalum glass sold by PPG Industries, Inc under the registered trademark STA STARPHIRE is between 1200 °F and 1300.
Ffe圍之溫度下具有i.oo χ 1〇7.8泊至5 36 χ 1〇9泊範圍之黏 度。在本發明實務中’在設定為1300卞之爐中將 STARPHIRE玻璃片70加熱,以加熱該玻璃片7〇至122〇卞之 預期溫度。該玻璃具有2.60 X 1 〇9泊之黏度,且發現當該 成形時間係三秒時發生該障壁塗層66之最小屈曲,且發現 當該成形時間係25秒時發生該障壁塗層66之最大屈曲。 0 現正如熟習此項技術者所瞭解,該成形玻璃片28之凸邊 之應變模式係類似於該成形玻璃片28之凹邊之應變模式。 根據需要參考圖10至13,本發明亦設計藉由自平面玻璃 板材切割某些片段’使該等片段成形並將該等成形片段連 接在一起以獲得形狀上類似於該成形玻璃基板28(參見圖3) 之成形玻璃基板,而減少在該成形玻璃基板28中之應變。 在一項本發明之非限制性實施例中,一平面玻璃板材126 之表面124係經該障壁塗層66(參見圖10)塗覆。該平面玻璃 板材126之表面124預期係成為該成形玻璃基板i3〇(參見圖 147285.doc -27- 201101521 12及13)之凹表面128。自該玻璃板材126切除四個平板片 段132至135。每個平板片段132至135包括一連接邊138及 14〇之圓角136 ; —連接邊144及146之平端142 ;邊138係在 轉角148處連接至邊144,且邊140係在轉角149處連接至邊 146 ° 確定每個平板片段13 2至13 5之大小使得如下所述使該等 片段132至135成形提供該成形玻璃基板130(參見圖12及13) 的1 /4,使得以如下所述之方式連接該成形片段丨3 2至1 3 5 在一起形成類似於該成形玻璃基板28(參見圖3)之該成形玻 ❹ 璃基板130。 本發明不限制自該玻璃板材126切除該等片段132至135 之方式’且任何相關技藝已知之切割或刻痕技術皆可用於 本發明實務中。可縫合該等片段132至135之邊緣,如相關 技藝已知之為安全之目的。以任何習知方式使用任何相關 技藝已知之壓製方法及設備使每個平板片段132至n5成 形’其例如但不限於··使用一具有成形用表面之固體上模 具及具有可撓性支撐表面之下模具;具有成形用表面之固 {) 體上模具及下環模具,及具有成形用表面之真空上模具 (例如揭示於美國專利第7,240,519及7,437,892號者,該等 專利之全文以引用的方式併入本文中)屈曲。 在較佳的本發明實務中,使用一具有成形用表面之上真 二模具使該等片段132至135成形。參考圖11,將片段132 至135中之一(例如片段132)加熱至1.00x1 07.8泊至5.36x109 泊範圍内之黏度並提供於下支撐元件157之曲面156上。使 147285.doc -28- 201101521 具有成形用表面之上真空成形模具158與支撐元件157彼此 相對移動,例如使該上模具158朝向下支撐元件157移動, 以使該片段132與該成形用表面159接觸。拉動真空通過該 上模具158之成形用表面159,以使該片段132成形。重複 ' 該處理以使剩餘的三個片段133至135成形而提供四個成形 片段160至163。視情況,可藉由提供具有四個成形區域之 成形模具同時成形該四個片段。 將該反射塗層34及該保護性塗層53(參見圖2)施用至該 〇 成形片段160至163之凸表面。 在較佳的本發明實務中,將該障壁塗層66施用至該平面 玻璃板材126之表面124,隨後將該等片段132至135自該玻 璃板材126中切除。然而,本發明設計將該障壁塗層&塗 覆至该平板片段132至135或該成形片段16〇至163。在本發 明實務中,將該反射塗層34及該保護性塗層53塗覆至該成 形片段1 60至163之凸表面;然而,本發明設計將該反射塗 ❹ 層34及該保護性塗層53塗覆至相對於該玻璃板材之表面 124的該玻璃板材126之表面。如可瞭解,如果將該反射塗 層34及該保護性塗層53塗覆於該等片段132至135後,再成 形,則該反射塗層34及該保護性塗層53必須承受成形該玻 .璃4段132至135之溫度、視情況,彳在成形該等片段後施 用該保護性塗層53。 本發明係不限制連接組成該成形玻璃基板13〇之片段132 至135之數量,且可藉由連接2、3、4、5或更多個片段形 成該成形玻璃基板130。如現在可瞭解,連接形成該成形 147285.doc -29- 201101521 玻璃基板130之成形片段的數量越多,則在該成形玻璃基 板28或130中之應變的減少越多。 參考圖12及13,以任何習知方式使該成形玻璃片段16〇 至163連接在一起。在一項本發明之非限制性實施例中, 將該等片段160至163放置在一起以形成該成形玻璃基板 130,及藉由黏合劑將一對環166及168固定至該反射塗層 34。在另一項本發明之非限制性實施例中,將該等環 及168連接至該成形玻璃基板之凸表面32。此後,以任何 習知方式用該反射塗層34及該保護性塗層53塗覆該連接的 成形片段160至163及該等環166及168之凸表面。在又一項 本發明之非限制性實施例中,該成形片段之邊係藉由黏合 劑連接在一起,例如,如圖12中所示,黏合劑使該等成形 片&之相鄰的邊14〇及該等成形片段之相鄰的邊138連接在 一起。如圖10及13所示,該圓角136形成該成形基板13〇之 切口 64。 本發明係不限制導出該等平板片段132至135之尺寸的方 式。例如(但不限制本發明),可自電腦程序、及自構建該 成形抛物面基板、切割該成形基板為所需數量的片段、並 測量戎等片段之邊而推導出該等平板片段之尺寸。 如見在可瞭解,應用上述技術將減少該玻璃中之應變且 將減V該障壁塗層66之屈曲及壓裂;然而,只要保持該玻 璃中之應變’則該障壁塗層66將具有屈曲及碎裂。鑒於前 述内谷,本發明另外設計藉由在該平板玻璃片70之選擇性 表面部分上方提供不同厚度的障壁塗層66來減少該障壁塗 147285.doc •30· 201101521 層66之壓裂及屈曲,該等選擇性表面係指定成為該成形玻 璃基板28(參見圖3)及該成形玻璃基板126(參見圖之凹 表面30。在以下討論中,本發明實施例係在該平板玻璃片 70上κ行以提供自該平板玻璃片7〇成形之該成形玻璃基板 - 28。‘然而除非另外說Β月’否則本發明可適用於將該障壁塗 66塗覆至該玻璃片段132至135,或該成形玻璃片段⑽ 至 163。 在第一項本發明之非限制性實施例中,該障壁塗層在該 平板玻璃片70(參見圖4)之表面68上方具有恆定厚度,該表 面68指定成為該成形玻璃基板28之凹表面%(以下稱為 「塗層技術1號」)。在第二項本發明之非限制性實施例 中改、支在5亥成形玻璃基板28之凹表面30中之圓周庫變传 藉由施用或沉積具有不同厚度(例如,隨著自二 玻璃片70之周邊150在朝該平板玻璃片7〇之中心部分π方 向的距離增加而增加的厚度)之障壁塗層或層66而補償(以 ◎ 下稱為塗層技術2號」)。在第三項本發明之非限制性實 ^例中,改變在該成形玻璃基板28之凹表面30中之圓周應 變係藉由施用或沉積具有兩個恆定厚度(第一個恆定厚度 係自該平板玻璃片70之周邊170至該過渡線94(參見圖乃之 預期位置,且第二個怪定厚度係自該過渡線%至該平板玻 璃片70之中心部分79,#中該障壁塗層之第二厚度比該障 壁塗層之第一厚度更厚)之障壁塗層或祕而補償(以下稱 為「塗層技術3號」)。 用於製造該成形玻璃基板28(參見圖3及5B)之塗層厚度 147285.doc •31 · 201101521 的變化可藉由掩蓋該平板片70之區域以具有薄塗層而完 成,例如當塗覆該平板玻璃片70之中心部分時,使用擋板 170以覆蓋預期成為圓周壓縮區域103(參見圖7)之該玻璃片 70(參見圖14)之表面。 藉由塗覆該平面玻璃板材126之表面124之前或之後,於 該板材中切割片段132至135之輪廓,實行塗層技術丨號以 提供該等片段160至163。在該等片段132至135藉由切割線 在該平面玻璃板材126中勾出輪廓後,或自該玻璃板材中 移除該等片段13 2至1 3 5後,藉由塗覆該等片段來實行塗層 技術2號:以提供該等片段16〇至163。用於塗層技術2號之該 塗層66之厚度隨著自該平端142(參見圖1〇)朝該圓角136方 向的距離的增加而增加。在該等片段132至135藉由切割線 在該平面玻璃板材126中勾出輪廓後,或自該玻璃板材中 移除該等片段132至135後,藉由塗覆該等片段來實行塗層 技術3號以供έ亥寺片段16 〇至1 6 3。將用於塗層技術3號之 該塗層66施用至該等片段132至135以具有自該等平板片段 132至135之邊144及146至該過渡線94(參見圖7)之預期位置 的第一個恆定厚度’及自該過渡線94至該等片段132至135 之圓角端1 3 6的第二個恆定厚度。 用於塗層技術1號之障壁塗層66具有40至1〇〇 nm範圍内 或80至100 nm範圍内之恆定厚度。在一項本發明之非限制 性實施例中,該障壁塗層66包括85原子%矽及15原子%銘 之氧化物。藉由MSVD將具有80 nm厚度之障壁塗層66沉積 於5玄平板片玻璃70之表面72上。該玻璃係揭示於2008年11 147285.doc • 32- 201101521 月21曰申請的美國專利申請案第12/275,264號或美國專利 第5,03 0,594號中之類型。該平板玻璃片70係具有n 75英 时直徑的圓形玻璃片;低於〇 〇2〇重量❶/〇之總離子含量,在 電磁頻譜之可見區域及汛區域之9〇%的透射,及在該可見 區域及IR區域中之低於2%的吸光度。該平板玻璃片7〇係 在真空模具中成形以提供該成形玻璃基板28,例如少於25 秒的彎曲時間。冷卻該成形玻璃基板之後,如上所述成形 该成形玻璃基板之外周以提供具有邊33及中心孔28(參見 〇 圖3)之成形玻璃基板28。將一反射銀塗層施用於該成形玻 璃基板28之凸表面32上方以提供該抛物面形鏡22。 塗層技術2號提供一障壁塗層66,其厚度隨著自該平板 玻璃片70之周邊向該中心部分79之距離的增加而增加,例 如,該障壁塗層(較佳但不限制本發明)自在該平板玻璃片 7〇之周邊172處的40 nm厚度增加至在該平板玻璃片7〇之中 、部分79處的80 nm。在此方式中,該障壁塗層66之厚度 Q 隨著°玄玻璃中之圓周應變的下降及該成形玻璃基板28之凹 表面30之寬度收縮%的減少而增加,以減少屈曲。通過過 渡線94朝向該成形玻璃基板28之中心部分,該障壁塗層 - 66之厚度隨著該外周張力的增加而增加。參考圖^,顯示 在/圓周張力區域1 〇4(其係在該過渡線94與該中心區域 8〇(參見圖7及15)之間)中之該成形玻璃基板28之截面。該 障壁塗層66具有裂縫174,然而該障壁塗層66係足夠厚使 得該等裂縫m不擴展至該障壁塗層66之表面1〇8。 用於塗層技術3號之㈣塗層66具有自該平板玻璃片7〇 147285.doc 33- 201101521 之周邊172至該成形玻璃基板28之過渡線94之預期位置的 第一個恆定厚度,及自該過渡線94至該平板玻璃片7〇之中 心部分的第二個恆定厚度,其中該障壁塗層66之第一個厚 度比該障壁塗層之第二個厚度更薄。在一項本發明之非限 制性實施例中,該障壁塗層66之第一個恆定厚度係在至 60 nm之範圍内,更佳在4〇至5〇 nm之範圍内,及該第二個 恆定厚度係在大於60至1〇〇 nm之範圍内,更佳在大於6〇至 8〇 nm之範圍内。由於此配置,該障壁塗層66之屈曲在該 圓周壓縮區域103中係最小,且該障壁塗層66之厚度在該 圓周張力區域104中係足夠厚使得該等裂缝174不擴展至該 障壁塗層66之表面1 〇8。此外,由於此配置,該障壁塗層 6 6在垓周邊緣8 4與該過渡線9 4之間(即:增加的玻璃厚度 以減少該障壁塗層66之屈曲的區域)之厚度係更薄,且該 障壁塗層66在該過渡線94與該成形玻璃基板28之底部區域 80之間(即.在更薄玻璃之區域,其中屈曲不如在該圓周 壓縮區域103中嚴重,且該等裂縫174係一問題)之厚度係 更厚。如可瞭解,本發明係不限制在該過渡線94之區域中 之塗層厚度改變,且該塗層厚度改變可係一漸進的改變或 階段式的改變。 現可瞭解,在該第二鏡44包括一成形基板之實例中,可 只行避免該障壁塗層66屈曲之技術以製造成形第二鏡。 其他本發明實施例包括但不限於: 1 將該障壁層66及/或該耐劃痕塗層施用至該平板玻璃片 70之表面68上方,該表面68係指定成為該成形玻璃基板28 147285.doc -34- 201101521 之凹表面30,且將該障壁層66施用至該平板玻璃片7〇(參 見圖16)之表面72上方,該表面72係指定成為該凸表面, 並將該平面玻璃板材70成形為該成形玻璃基板28。隨後, 將該反射層34及視情況之該保護性塗層53施用至該成形玻 - 璃基板28之凸表面32上之該障壁層66上方; _ 2.將該障壁層66及/或該耐劃痕塗層施用至該平板玻璃片 70之表面68上方,該表面68係指定成為該成形玻璃基板28 之凹表面,且將該障壁層66施用至該平板玻璃片7〇之表面 Ο 72上方,該表面72係指定成為該平板玻璃片70之凸表面, 並將該反射層34施用至在該表面72上之障壁層66上方(參 見圖17) ’及隨後將該平面玻璃板材7〇成形為該成形玻璃 基板28 ; 3. 將該平板玻璃片70成形為抛物面形玻璃基板28,並將 «亥I5早壁層66及/或該耐劃痕塗層施用至該拋物面形玻璃基 板28之凹表面30上方,且將該反射塗層34施用至該拋物面 〇 形玻璃基板28之凸表面32上方(參見圖18);及 4. 將該平板玻璃片70成形為該成形玻璃基板28,並將該 障壁層66施用至該成形玻璃基板28之凸表面32上方,且將 將該障壁層及/或該耐劃痕塗層施用至其之凹表面上 方,並將該反射塗層34施用至在該凸表面32上方(或表層 上)之該障壁層66之上方(或表層上)(參見圖19)。 如可瞭解,在本發明之非限制性實施例之實務中,當將 该反射層34及/或該障壁層66及/或耐劃痕塗層施用至該平 板玻螭片70,並將該塗層平板玻璃加熱及成形(例如,如 147285.doc •35- 201101521 上所述般)時,該反射層34及該障壁層66及/或耐劃痕塗層 具有承受成形之高溫(例如,高於12〇〇卞)的能力。可承受 咼溫之反射塗層係相關技藝已知,例如參見美國專利第 7,329,433號,該專利之全文將以引用的方式併入本文中。 該專利揭示沉積於反射層上之底漆膜以保護在高溫處理期 間之反射層。 在較佳的本發明實務中,使用MSVD設備施用該障壁層 66。如熟習此項技術者所瞭解,用於MSvd塗層之陰極必 須導電。為提供導電的矽陰極,將鋁添加至該矽中,例如 高於5重量%。然而,本發明係不限制該障壁層應 用法,且任何施用該障壁層之塗覆方法皆可用於本發明實 務中。此外,本發明係不限制具有均勻的障壁層,且本發 明設計具有變動的矽及鋁之氧化物的組成之障壁層。例 如,在一項本發明之非限制性實施例中,將6〇原子重量% 之鋁及40原子重量%之矽的氧化物之第一障壁層施用至該 玻璃之表面,且將85原子重量%之鋁及15原子重量%之矽 的氧化物之第二障壁層施用至該第一障壁層之上。 如現可瞭解,本發明之障壁層66可用於避免鈉離子破壞 光伏打裝置之導電層。更特定而言,且參考圖2(),其顯示 在本發明之障壁層66上方具有一導電塗層186之光伏打裝 置184。將該障壁層66施用至玻璃板材19〇之表面188。該 障壁層66避免該等鈉離子形成攻擊及破壞該光伏打電池 184之導電塗層186的鈉化合物。 如上所詳細討論般,矽及鋁之氧化物的障壁層除了提供 147285.doc -36 - 201101521 避免納離子自該玻璃移出之障壁以外,亦提供該玻璃之保 S蒦性層以避免對該玻璃表面之機械及化學損傷。 熟習此項技術者將容易理解,在不偏離以上描述中所揭 不之概念下,對本發明之非限制性實施例可作修飾,因 此,本文洋細描述之特定本發明非限制性實施例僅係說明 性且不限制本發明之範圍,其給予附屬申請專利範圍及其 任何及所有等效物之充分的廣度。 【圖式簡單說明】 圖1係先前技術之太陽能集光器陣列之立面平面圖。The temperature around the Ffe has a viscosity ranging from i.oo χ 1〇7.8 poise to 5 36 χ 1〇9 poise. In the practice of the invention, the STARPHIRE glass sheet 70 is heated in an oven set to 1300 Torr to heat the desired temperature of the glass sheet from 7 Torr to 122 Torr. The glass had a viscosity of 2.60 X 1 〇 9 poise, and it was found that the minimum buckling of the barrier coating 66 occurred when the forming time was three seconds, and it was found that the maximum of the barrier coating 66 occurred when the forming time was 25 seconds. Flexion. 0 As is known to those skilled in the art, the strain pattern of the convex edge of the shaped glass sheet 28 is similar to the strain pattern of the concave side of the shaped glass sheet 28. Referring to Figures 10 through 13 as desired, the present invention also contemplates shaping the segments by cutting certain segments from a flat glass sheet and joining the shaped segments together to obtain a shape similar to the shaped glass substrate 28 (see The formed glass substrate of Fig. 3) reduces the strain in the shaped glass substrate 28. In a non-limiting embodiment of the invention, the surface 124 of a planar glass sheet 126 is coated through the barrier coating 66 (see Figure 10). The surface 124 of the planar glass sheet 126 is intended to be the concave surface 128 of the shaped glass substrate i3 (see Figures 147285.doc -27-201101521 12 and 13). Four flat sheets 132 to 135 are cut from the glass sheet 126. Each of the plate segments 132-135 includes a fillet 136 of 14 and 14 turns; a flat end 142 connecting the edges 144 and 146; the edge 138 is attached to the edge 144 at a corner 148 and the edge 140 is at a corner 149 Connecting to the side 146 ° determines the size of each of the flat plate segments 13 2 to 13 5 such that the segments 132 to 135 are shaped to provide 1/4 of the shaped glass substrate 130 (see FIGS. 12 and 13) as follows, such that The formed segments 丨 3 2 to 1 3 5 are joined together to form the formed glass substrate 130 similar to the shaped glass substrate 28 (see Fig. 3). The present invention is not limited to the manner in which the segments 132 to 135 are cut from the glass sheet 126 and any cutting or scoring techniques known in the art can be used in the practice of the present invention. The edges of the segments 132 to 135 can be sewn as known in the art for safety purposes. Each of the plate segments 132 to n5 is shaped in any conventional manner using any of the pressing methods and apparatus known in the art, which are, for example, but not limited to, using a solid upper mold having a forming surface and having a flexible support surface. a lower mold; a solid mold having a forming surface; and a lower ring mold; and a vacuum upper mold having a surface for forming (for example, as disclosed in U.S. Patent Nos. 7,240,519 and 7,437,892, the entire contents of each of which are incorporated by reference. Incorporated herein) buckling. In a preferred practice of the invention, the segments 132 through 135 are formed using a true mold over the surface for forming. Referring to Figure 11, one of the segments 132-135 (e.g., segment 132) is heated to a viscosity in the range of 1.00 x 1 07.8 poise to 5.36 x 109 poise and provided on the curved surface 156 of the lower support member 157. 147285.doc -28-201101521 has a vacuum forming die 158 and a support member 157 that are moved relative to each other over the surface for forming, for example, moving the upper die 158 toward the lower support member 157 such that the segment 132 and the forming surface 159 contact. The vacuum is pulled through the forming surface 159 of the upper mold 158 to shape the segment 132. This process is repeated to shape the remaining three segments 133 to 135 to provide four shaped segments 160 to 163. Optionally, the four segments can be formed simultaneously by providing a forming die having four forming regions. The reflective coating 34 and the protective coating 53 (see Fig. 2) are applied to the convex surfaces of the 成形 shaped segments 160 to 163. In a preferred practice of the invention, the barrier coating 66 is applied to the surface 124 of the planar glass sheet 126, and the segments 132 through 135 are subsequently cut from the glass sheet 126. However, the present invention contemplates coating the barrier coating & to the plate segments 132 to 135 or the shaped segments 16A to 163. In the practice of the present invention, the reflective coating 34 and the protective coating 53 are applied to the convex surfaces of the shaped segments 166 to 163; however, the present invention designs the reflective coated layer 34 and the protective coating. Layer 53 is applied to the surface of the glass sheet 126 relative to the surface 124 of the glass sheet. As can be seen, if the reflective coating 34 and the protective coating 53 are applied to the segments 132 to 135 and then reshaped, the reflective coating 34 and the protective coating 53 must withstand the formation of the glass. The temperature of the glass segments 132 to 135, as appropriate, is applied to the protective coating 53 after forming the segments. The present invention is not limited to the number of the segments 132 to 135 which are joined to constitute the shaped glass substrate 13, and the formed glass substrate 130 can be formed by joining 2, 3, 4, 5 or more segments. As will now be appreciated, the greater the number of shaped segments of the glass substrate 130 that are joined to form the shaped 147285.doc -29-201101521, the greater the reduction in strain in the shaped glass substrate 28 or 130. Referring to Figures 12 and 13, the shaped glass segments 16A through 163 are joined together in any conventional manner. In a non-limiting embodiment of the invention, the segments 160-163 are placed together to form the shaped glass substrate 130, and a pair of rings 166 and 168 are secured to the reflective coating 34 by an adhesive. . In another non-limiting embodiment of the invention, the rings and 168 are attached to the convex surface 32 of the shaped glass substrate. Thereafter, the joined shaped segments 160 to 163 and the convex surfaces of the rings 166 and 168 are coated with the reflective coating 34 and the protective coating 53 in any conventional manner. In yet another non-limiting embodiment of the invention, the edges of the shaped segments are joined together by an adhesive, for example, as shown in Figure 12, the adhesive is adjacent to the formed sheets & Edges 14 and adjacent sides 138 of the shaped segments are joined together. As shown in Figs. 10 and 13, the fillet 136 forms a slit 64 of the formed substrate 13A. The present invention does not limit the manner in which the dimensions of the plate segments 132 to 135 are derived. For example, but not limiting of the invention, the dimensions of the slab segments can be derived from a computer program, and from constructing the shaped parabolic substrate, cutting the shaped substrate into a desired number of segments, and measuring the edges of the segments. As can be appreciated, applying the techniques described above will reduce strain in the glass and will reduce the buckling and fracture of the barrier coating 66; however, the barrier coating 66 will have buckling as long as the strain in the glass is maintained. And broken. In view of the foregoing inner valleys, the present invention is additionally designed to reduce the fracturing and buckling of the barrier layer by providing a barrier coating 66 of different thickness over the selective surface portion of the flat glass sheet 70. 147285.doc • 30· 201101521 The selective surface is designated as the shaped glass substrate 28 (see FIG. 3) and the shaped glass substrate 126 (see the concave surface 30 of the figure. In the following discussion, embodiments of the invention are on the flat glass sheet 70) The K-row row is provided with the formed glass substrate - 28 formed from the flat glass sheet 7'. However, unless otherwise stated, the present invention is applicable to apply the barrier coating 66 to the glass segments 132 to 135, or The shaped glass segments (10) to 163. In a first non-limiting embodiment of the invention, the barrier coating has a constant thickness over the surface 68 of the flat glass sheet 70 (see Figure 4), the surface 68 designated The concave surface % of the shaped glass substrate 28 (hereinafter referred to as "coating technique No. 1") is modified and supported in the concave surface 30 of the 5-well shaped glass substrate 28 in the second non-limiting embodiment of the present invention. Circumference library The barrier coating or layer 66 is applied by applying or depositing a thickness having a different thickness (e.g., as the distance from the perimeter 150 of the two glass sheets 70 increases in the direction of the π direction toward the central portion of the flat glass sheet 7). And compensation (hereinafter referred to as coating technique No. 2). In the third non-limiting embodiment of the invention, the circumferential strain in the concave surface 30 of the shaped glass substrate 28 is changed by application. Or depositing has two constant thicknesses (the first constant thickness is from the perimeter 170 of the flat glass sheet 70 to the transition line 94 (see the expected position of the figure, and the second strange thickness is from the transition line % to The central portion 79 of the flat glass piece 70, the second thickness of the barrier coating is thicker than the first thickness of the barrier coating, or the barrier coating is compensated (hereinafter referred to as "Coating Technology No. 3" The coating thickness 147285.doc • 31 · 201101521 used to fabricate the shaped glass substrate 28 (see FIGS. 3 and 5B) can be varied by masking the area of the flat sheet 70 to have a thin coating, such as When the central portion of the flat glass sheet 70 is coated, A baffle 170 is used to cover the surface of the glass sheet 70 (see Figure 14) intended to be a circumferential compression zone 103 (see Figure 7). By coating the surface 124 of the planar glass sheet 126 before or after, in the panel The contours of the segments 132 to 135 are cut and the coating technique number is applied to provide the segments 160 to 163. After the segments 132 to 135 are contoured in the flat glass sheet 126 by cutting lines, or from the glass After removing the segments 13 2 to 135 in the sheet, coating technique No. 2 was carried out by coating the fragments to provide the fragments 16 〇 to 163. The thickness of the coating 66 used in Coating Technology No. 2 increases with increasing distance from the flat end 142 (see Figure 1 〇) toward the fillet 136. After the segments 132 to 135 are contoured in the planar glass sheet 126 by cutting lines, or after the segments 132 to 135 are removed from the glass sheet, the coating is applied by coating the segments. Technology No. 3 is available for the 16th to 16th of the Temple of the Temple. The coating 66 for Coating Technology No. 3 is applied to the segments 132 to 135 to have the desired positions from the sides 144 and 146 of the plate segments 132 to 135 to the transition line 94 (see Figure 7). The first constant thickness 'and the second constant thickness from the transition line 94 to the rounded end 1 36 of the segments 132 to 135. The barrier coating 66 for coating technique No. 1 has a constant thickness in the range of 40 to 1 〇〇 nm or in the range of 80 to 100 nm. In a non-limiting embodiment of the invention, the barrier coating 66 comprises 85 atomic percent and 15 atomic percent of the oxide. A barrier coating 66 having a thickness of 80 nm is deposited on the surface 72 of the 5 slab glass 70 by the MSVD. The glass system is disclosed in U.S. Patent Application Serial No. 12/275,264, filed on Jan. No. No. No. No. No. No. No. No. No. No. No. The flat glass sheet 70 is a circular glass sheet having a diameter of n 75 inches; a total ion content of less than 〇〇2〇 weight ❶/〇, a transmission of 9〇% in the visible region of the electromagnetic spectrum and the 汛 region, and Absorbance below 2% in the visible and IR regions. The flat glass sheet 7 is formed in a vacuum mold to provide the shaped glass substrate 28, for example, a bending time of less than 25 seconds. After cooling the shaped glass substrate, the outer periphery of the shaped glass substrate is shaped as described above to provide a shaped glass substrate 28 having sides 33 and central holes 28 (see Fig. 3). A reflective silver coating is applied over the convex surface 32 of the shaped glass substrate 28 to provide the parabolic mirror 22. Coating Technology No. 2 provides a barrier coating 66 having a thickness that increases with increasing distance from the periphery of the flat glass sheet 70 to the central portion 79, such as the barrier coating (preferably, but not limiting of the invention) The thickness of 40 nm from the periphery 172 of the flat glass sheet 7 is increased to 80 nm at the portion 79 of the flat glass sheet. In this manner, the thickness Q of the barrier coating 66 increases as the circumferential strain in the deciduous glass decreases and the % shrinkage of the concave surface 30 of the shaped glass substrate 28 decreases to reduce buckling. The thickness of the barrier coating - 66 increases as the peripheral tension increases as the transition line 94 faces the central portion of the shaped glass substrate 28. Referring to Fig. 2, a section of the formed glass substrate 28 in the /peripheral tension region 1 〇 4 which is between the transition line 94 and the central region 8 (see Figs. 7 and 15) is shown. The barrier coating 66 has a crack 174, however the barrier coating 66 is sufficiently thick that the crack m does not extend to the surface 1〇8 of the barrier coating 66. The coating layer 66 for coating technique No. 3 has a first constant thickness from the desired position of the perimeter 172 of the flat glass sheet 7〇147285.doc 33-201101521 to the transition line 94 of the shaped glass substrate 28, and From the transition line 94 to a second constant thickness of the central portion of the flat glass sheet 7, wherein the first thickness of the barrier coating 66 is thinner than the second thickness of the barrier coating. In a non-limiting embodiment of the invention, the first constant thickness of the barrier coating 66 is in the range of up to 60 nm, more preferably in the range of 4 to 5 〇 nm, and the second The constant thickness is in the range of more than 60 to 1 〇〇 nm, more preferably in the range of more than 6 〇 to 8 〇 nm. Due to this configuration, the buckling of the barrier coating 66 is minimal in the circumferential compression zone 103, and the thickness of the barrier coating 66 is sufficiently thick in the circumferential tension region 104 that the cracks 174 do not extend to the barrier coating. The surface of layer 66 is 1 〇8. Moreover, due to this configuration, the barrier coating 66 is thinner between the peripheral edge 84 and the transition line 94 (i.e., the increased glass thickness to reduce the buckling of the barrier coating 66). And the barrier coating 66 is between the transition line 94 and the bottom region 80 of the shaped glass substrate 28 (ie, in the region of the thinner glass where the buckling is less severe than in the circumferential compression region 103, and the cracks The thickness of the 174 series is thicker. As can be appreciated, the present invention does not limit the change in coating thickness in the region of the transition line 94, and the change in thickness of the coating can be a gradual change or a step change. It will now be appreciated that in the example where the second mirror 44 includes a shaped substrate, only the technique of buckling the barrier coating 66 can be avoided to produce a shaped second mirror. Other embodiments of the invention include, but are not limited to: 1 applying the barrier layer 66 and/or the scratch resistant coating to the surface 68 of the flat glass sheet 70, the surface 68 being designated as the shaped glass substrate 28 147285. Doc -34 - 201101521 concave surface 30, and the barrier layer 66 is applied over the surface 72 of the flat glass sheet 7 (see Fig. 16), the surface 72 is designated as the convex surface, and the flat glass sheet is 70 is formed into the formed glass substrate 28. Subsequently, the reflective layer 34 and optionally the protective coating 53 are applied over the barrier layer 66 on the convex surface 32 of the shaped glass substrate 28; _ 2. the barrier layer 66 and/or the A scratch resistant coating is applied over the surface 68 of the flat glass sheet 70, which is designated as the concave surface of the shaped glass substrate 28, and the barrier layer 66 is applied to the surface of the flat glass sheet 7 Above, the surface 72 is designated as the convex surface of the flat glass sheet 70, and the reflective layer 34 is applied over the barrier layer 66 on the surface 72 (see Figure 17) 'and subsequently the flat glass sheet 7 Formed into the shaped glass substrate 28; 3. The flat glass sheet 70 is formed into a parabolic glass substrate 28, and the "IlI5 early wall layer 66" and/or the scratch resistant coating is applied to the parabolic glass substrate 28 Above the concave surface 30, and applying the reflective coating 34 to the convex surface 32 of the parabolic enamel glass substrate 28 (see FIG. 18); and 4. forming the flat glass sheet 70 into the shaped glass substrate 28, Applying the barrier layer 66 to the convexity of the shaped glass substrate 28 Above the surface 32, and applying the barrier layer and/or the scratch resistant coating to the concave surface thereof, and applying the reflective coating 34 to the barrier above the convex surface 32 (or on the surface) Above layer 66 (or on the surface) (see Figure 19). As can be appreciated, in the practice of the non-limiting embodiments of the present invention, when the reflective layer 34 and/or the barrier layer 66 and/or the scratch resistant coating are applied to the flat glass sheet 70, and When the coated flat glass is heated and formed (for example, as described in 147285.doc • 35-201101521), the reflective layer 34 and the barrier layer 66 and/or the scratch resistant coating have a high temperature to withstand formation (for example, Ability above 12〇〇卞). Reflective coatings which can withstand enthalpy are known in the art, for example, see U.S. Patent No. 7,329,433, the disclosure of which is incorporated herein in its entirety by reference. This patent discloses a primer film deposited on a reflective layer to protect the reflective layer during high temperature processing. In a preferred practice of the invention, the barrier layer 66 is applied using an MSVD device. As will be appreciated by those skilled in the art, the cathode for the MSvd coating must be electrically conductive. To provide a conductive tantalum cathode, aluminum is added to the crucible, for example above 5% by weight. However, the present invention does not limit the application of the barrier layer, and any coating method of applying the barrier layer can be used in the practice of the present invention. Further, the present invention is not limited to having a uniform barrier layer, and the present invention is designed to have a barrier layer composed of a varying composition of tantalum and aluminum oxide. For example, in a non-limiting embodiment of the invention, a first barrier layer of 6 Å atomic percent aluminum and 40 atomic percent lanthanum oxide is applied to the surface of the glass and 85 atomic weight A second barrier layer of % aluminum and 15 atomic percent of the oxide of the tantalum is applied over the first barrier layer. As will now be appreciated, the barrier layer 66 of the present invention can be used to prevent sodium ions from damaging the conductive layers of the photovoltaic device. More specifically, and with reference to Figure 2(), there is shown a photovoltaic device 184 having a conductive coating 186 over the barrier layer 66 of the present invention. The barrier layer 66 is applied to the surface 188 of the glass sheet 19 . The barrier layer 66 prevents the sodium ions from forming an attack and destroying the sodium compound of the conductive coating 186 of the photovoltaic cell 184. As discussed in detail above, the barrier layer of tantalum and aluminum oxide provides a protective layer of the glass in addition to the barrier that prevents nano ions from being removed from the glass, in addition to providing a barrier layer for the removal of nano ions from the glass. Mechanical and chemical damage to the surface. It will be readily understood by those skilled in the art that the non-limiting embodiments of the invention may be modified without departing from the scope of the invention. The scope of the invention is intended to be illustrative, and not to limit the scope of the invention. BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is an elevational plan view of a prior art solar concentrator array.
圖2係一先前技術之太陽能集光器之等角視圖,及圖2A 係一太陽光線入射至該太陽能集光器之凹表面上之擴大 圖。 圖3係顯示一本發明太陽能鏡之類似於圖2視圖之視圖。 圖4係具有一本發明塗層之玻璃片的等角視圖,在圖4中 之塗層具有為清晰之目的移除之部分。 圖5A係一具有圖4之玻璃片的真空模具之立面側視圖, 该玻璃片安裝於該真空模具之開口端,及圖5B係在該真空 模具之内部具有本發明之成形玻璃基板之真空模具的橫截 面視圖。 圖6係本發明之成形玻璃基板之立面俯視圖,其顯示在 該成形玻璃基板之周邊的圓周壓縮應變的模式。 圖7係圖6沿直線7_7之視圖,其尤其顯示該成形玻璃基 板之過渡應變線。 圖8係圖7沿直線8_8之視圖,其顯示該成形玻璃基板之 147285.doc -37- 201101521 外周拉伸應變及徑向拉伸應變。 圖9 A係一圖4所示之玻璃片的片段的等角視圖;圖9B係 圖9A所示之片段在將該玻璃片成形為該成形玻璃基板後之 等角視圖,該塗層有高峰及低谷;及圖9C係類似於圖9B 視圖之視圖,其顯示一由根據本發明教示製造之成形玻璃 基板的片段’該塗層具有數量減少的高峰及低谷、減少的 高峰之高度及減少的低谷之深度。 圖10係類似於圖4視圖之視圖,其顯示另一項本發明實 施例,以製造包括切割經塗覆之玻璃成為片段之本發明成 形太陽能鏡。 圖11係一玻璃板材壓製配置之等角俯視圖,其可用於本 發明貫務中以成形自圖1 〇之經塗覆之玻璃切割而來之片 段。 圖12係一藉由連接成形玻璃片段製造之本發明成形太陽 能鏡的俯視圖。 圖13係類似於圖3視圖之視圖,其顯示由該等成形坡璃 片段組成之本發明成形太陽能鏡。 圖14係類似於圖4視圖之視圖,其顯示在圓形玻璃片上 方之塗層擋板。 圖1 5係在該成形玻璃基板之過渡應變線與底部之間的位 置上,該成形玻璃基板之立面橫截面俯視圖,該視圖顯示 在該成形玻璃基板之外周張力及徑向張力區 〜我縫, 為h晰之目的沒有顯示該塗層之交又剖面線。 圖 16至19係圖4中所示 類型之平板破璃片的區段之槔截 147285.doc -38- 201101521 面側視圖,在該等玻璃片之一或兩個表面上具有本發明之 障壁塗層及/或财劃痕塗層,及視情況在該等玻璃片之— 個表面上方具有反射表面。 圖20係-具有本發明障壁層《光伏夺丁電池之區段的側視 圖0 【主要元件符號說明】 οFigure 2 is an isometric view of a prior art solar concentrator, and Figure 2A is an enlarged view of a solar ray incident on a concave surface of the solar concentrator. Figure 3 is a view similar to the view of Figure 2 showing a solar mirror of the present invention. Figure 4 is an isometric view of a glass sheet having a coating of the present invention, the coating of Figure 4 having portions removed for clarity. Figure 5A is a side elevational view of a vacuum mold having the glass sheet of Figure 4 mounted to the open end of the vacuum mold, and Figure 5B is within the vacuum mold having the vacuum of the formed glass substrate of the present invention. A cross-sectional view of the mold. Fig. 6 is a top plan view of a molded glass substrate of the present invention, showing a mode of circumferential compressive strain around the periphery of the formed glass substrate. Figure 7 is a view of Figure 6 taken along line 7-7, which in particular shows the transition strain lines of the shaped glass substrate. Figure 8 is a view along line 8-8 of Figure 7 showing the peripheral tensile strain and radial tensile strain of the shaped glass substrate 147285.doc -37 - 201101521. Figure 9A is an isometric view of a fragment of the glass sheet shown in Figure 4; Figure 9B is an isometric view of the fragment shown in Figure 9A after forming the glass sheet into the shaped glass substrate, the coating having a peak And FIG. 9C is a view similar to the view of FIG. 9B showing a fragment of a shaped glass substrate manufactured by the teachings of the present invention having a reduced number of peaks and valleys, reduced peak heights, and reduced The depth of the valley. Figure 10 is a view similar to the view of Figure 4 showing another embodiment of the invention for fabricating a shaped solar mirror of the present invention comprising cutting a coated glass into segments. Figure 11 is an isometric top view of a glass sheet press configuration that can be used in the present invention to cut from a coated glass formed from Figure 1 . Figure 12 is a top plan view of a shaped solar lens of the present invention fabricated by joining shaped glass segments. Figure 13 is a view similar to the view of Figure 3 showing the shaped solar mirror of the present invention comprised of such shaped glass segments. Figure 14 is a view similar to the view of Figure 4 showing the coated baffle above the circular glass sheet. Figure 15 is a top plan cross-sectional view of the formed glass substrate at a position between the transition strain line and the bottom of the shaped glass substrate, the view showing the peripheral tension and the radial tension zone outside the formed glass substrate. The seam, for the purpose of clarity, does not show the cross section of the coating. Figures 16 through 19 are cross-sectional views of a section of a flat glass sheet of the type shown in Figure 4, 147, 285. doc - 38 - 201101521, having a barrier of the present invention on one or both surfaces of the glass sheets A coating and/or a scratch coating, and optionally a reflective surface over the surface of the glass. Figure 20 is a side view of a section of a barrier layer having a photovoltaic cell of the present invention. Figure 10 [Description of main component symbols]
18 太陽能集光器陣列 20 成形太陽能集光器 22 抛物面形鏡(第一鏡) 26 轉換太陽能之裝置 28 成形(抛物面形)玻璃基板 30 成形玻璃基板28之凹表面 32 成形玻璃基板28之凸表面 33 成形玻璃基板28之邊 34 反射塗層或層或膜 36 太陽光線 37 一部分太陽光線 38 一部分太陽光線 43 反射光線 44 成形第二鏡 46 光桿或光棒 48 太陽能電池 50 光才干或光棒46之一末端 52 光才干或光棒46之一末端 147285.doc -39- 201101521 53 64 保護性塗層或層或膜 切口或洞 66 68 70 72 74 76 障壁塗層或層或膜 平板玻璃片70之一表面(指定成為凹表面3〇) 平板玻璃片(或板材) 平板玻璃片70之一表面(指定成為凸表面32) 真空模具76之開口端 真空模具 77 隔開孔 78 79 80 81 82 83 84 90 92 102 103 真空模具76之内部 平板玻璃片70之中間部分 成形玻璃基板28之底部區域 成形玻璃基板28之邊緣 平板玻璃片70之邊緣 成形玻璃基板28之片段 成形玻璃基板28之外周邊緣 徑向張力應變 圓周壓縮應變 圓周張力應變 圓周壓縮區域 104 108 110 112 圓周張力區域 障壁塗層或層或膜之表面 平板玻璃片70之片段 片段118或11〇之邊 147285.doc -40- 201101521 113 片段118或110之邊 116 片段118或110之邊 117 片段118或110之邊 118 成形玻璃基板28之片段 - 120 皺褶 124 平面玻璃板材126之表面 126 平面玻璃板材 128 成形玻璃基板130之凹表面 Ο 130 成形玻璃基板 132 平板片段 133 平板片段 134 平板片段 135 平板片段 136 圓角 138 邊 140 邊 142 平端 144 邊 146 邊 148 轉角 149 轉角 156 下支撐元件157之曲面 157 下支撐元件 158 上真空成形模具 147285.doc -41 - 201101521 159 上模具158之成形用表面 160 成形片段 161 成形片段 162 成形片段 163 成形片段 166 環 168 環 170 擋板 172 該平板玻璃片70之外周 174 裂缝 184 光伏打裝置(光伏打電池) 186 導電塗層 188 玻璃板材190之表面 190 玻璃板材 147285.doc -42-18 Solar concentrator array 20 Formed solar concentrator 22 Parabolic mirror (first mirror) 26 Solar energy conversion device 28 Formed (parabolic) glass substrate 30 The concave surface of the shaped glass substrate 28 The convex surface of the shaped glass substrate 28 33 Edge 34 of the shaped glass substrate 28 Reflective coating or layer or film 36 Solar rays 37 Part of the sun's rays 38 Part of the sun's rays 43 Reflected rays 44 Forming the second mirror 46 Light rods or rods 48 Solar cells 50 Light or light rods 46 One end 52 light or one end of light bar 46 147285.doc -39- 201101521 53 64 Protective coating or layer or film slit or hole 66 68 70 72 74 76 barrier coating or layer or film plate glass 70 One surface (designated as concave surface 3〇) Flat glass piece (or sheet) One surface of flat glass piece 70 (designated to be convex surface 32) Open end of vacuum mold 76 Vacuum mold 77 Separation hole 78 79 80 81 82 83 84 90 92 102 103 The middle portion of the inner flat glass sheet 70 of the vacuum mold 76 forms the bottom portion of the glass substrate 28 and forms the edge flat plate of the glass substrate 28. Edge of glass sheet 70 Forming glass substrate 28 Segment forming Glass substrate 28 Outer peripheral edge Radial tensile strain circumferential compression strain circumferential tension strain circumferential compression region 104 108 112 112 circumferential tension region barrier coating or layer or film surface flat glass sheet 70 segment fragment 118 or 11〇 edge 147285.doc -40- 201101521 113 segment 118 or 110 edge 116 segment 118 or 110 edge 117 segment 118 or 110 edge 118 forming segment of glass substrate 28 - 120 wrinkle 124 Surface of sheet glass 126 Surface 126 Planar glass sheet 128 Concave surface of shaped glass substrate 130 成形 Formed glass substrate 132 Plate segment 133 Plate segment 134 Plate segment 135 Plate segment 136 Rounded corner 138 Edge 140 Edge 142 Flat end 144 Edge 146 Edge 148 Corner 149 Corner 156 Lower surface of support element 157 Lower support element 158 Upper vacuum forming die 147285.doc -41 - 201101521 159 Forming surface 160 of upper mold 158 Forming segment 161 Forming segment 162 Forming segment 163 Forming segment 166 Ring 168 Ring 170 Baffle 172 Circumferential cracks 174 184 photovoltaic devices (photovoltaic cells) 186 conductive coating 188 of the surface 190 of glass sheet 190 glass sheet 147285.doc -42-