TWI461283B - Vacuum imprinting apparatus, vacuum press-bonding apparatus, and manufacturing method for laminated optical device - Google Patents
Vacuum imprinting apparatus, vacuum press-bonding apparatus, and manufacturing method for laminated optical device Download PDFInfo
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Description
本發明關於一種層狀光學元件之製造方法及其使用之壓印裝置、壓合裝置,尤指利用真空製程之層狀光學元件製造方法及其使用之真空壓印裝置、真空壓合裝置。The present invention relates to a method for producing a layered optical element and an imprint apparatus and a press-fit apparatus therefor, and more particularly to a method for manufacturing a layered optical element using a vacuum process, a vacuum imprint apparatus therefor, and a vacuum press apparatus.
習知的層狀光學元件係於一基板上形成多層光學層製作,此多層光學層係依序利用光學膠固化形成,其中,光學層上可依需要利用模板印製圖案。於習知的製程中,該層狀光學元件係於大氣環境下經由塗佈、滾壓、固化等工序依序各別製作形成。於滾壓工序中,操作人工需將模板或保護膜以與光學膠層進行貼合對位,再以滾壓輪進行滾壓,此易造成貼合精度不足、貼合及滾壓易引入氣泡、滾壓不易控制壓合間隙、及固化前需移轉機台易造成光學膠層厚度變異。此外,於採用使用模板的滾壓工序以形成光學層流程中,該模板於光學膠層固化後,尚需人工脫模,但由於人工脫模作業存在著較大的不確定因素,容易產生製程不穩定性的問題。The conventional layered optical element is formed by forming a plurality of optical layers on a substrate, and the multilayer optical layer is sequentially formed by curing with an optical glue, wherein the optical layer can be printed with a template as needed. In a conventional process, the layered optical element is formed separately in the air by an application process such as coating, rolling, and curing. In the rolling process, the manual or the protective film needs to be aligned with the optical adhesive layer, and then rolled by the rolling wheel, which is easy to cause insufficient bonding precision, and the bonding and rolling are easy to introduce bubbles. Rolling pressure is not easy to control the press-fitting gap, and it is easy to change the thickness of the optical adhesive layer when the machine needs to be transferred before curing. In addition, in the process of forming a optical layer by using a rolling process using a template, the template needs to be manually demolded after the optical adhesive layer is cured, but the process is easy to produce due to large uncertainties in the manual demolding operation. The problem of instability.
鑑於先前技術中的問題,本發明的目的之一在於提供一種真空壓印裝置,利用真空環境及機器精密定位的特性,以有效控制光學層之厚度尺寸並抑制固化後於各光學層間產生的氣泡現象。In view of the problems in the prior art, one of the objects of the present invention is to provide a vacuum imprinting apparatus which utilizes the characteristics of a vacuum environment and precise positioning of a machine to effectively control the thickness dimension of the optical layer and suppress bubbles generated between the optical layers after curing. phenomenon.
本發明之真空壓印裝置包含一真空室、一下載台、一上載台及一固化裝置。該下載台設置於該真空室內,用以承載一基板,其上設置有一光學膠層。該上載台相對於該下載台設置於該真空室內,用以承載一模板,該上載台能朝向該下載台移動以使該模板壓印一圖案於該光學膠層上。該固化裝置用以固化該壓印的光學膠層以形成一光學層於該基板上。藉此,該真空壓印裝置利用真空抑制該模板壓印該光學膠層時引入空隙的可能性,並且可平穩且精確地控制該上載台下壓,使得該固化後的光學層厚度均勻且無氣泡。The vacuum imprinting apparatus of the present invention comprises a vacuum chamber, a downloading station, an loading station and a curing device. The downloading station is disposed in the vacuum chamber for carrying a substrate on which an optical adhesive layer is disposed. The loading station is disposed in the vacuum chamber relative to the downloading station for carrying a template, and the loading table can be moved toward the downloading station to imprint a pattern on the optical adhesive layer. The curing device is configured to cure the embossed optical adhesive layer to form an optical layer on the substrate. Thereby, the vacuum imprinting apparatus utilizes a vacuum to suppress the possibility of introducing a void when the template is imprinted with the optical adhesive layer, and can smoothly and accurately control the loading table to be pressed down, so that the cured optical layer has a uniform thickness and no bubble.
本發明之另一目的在於提供一種真空壓合裝置,亦利用真空環境及機器精密定位的特性,以有效控制光學層之厚度尺寸並抑制固化後於光學層與保護膜間產生的氣泡現象。Another object of the present invention is to provide a vacuum pressing device which also utilizes the characteristics of a vacuum environment and precise positioning of a machine to effectively control the thickness dimension of the optical layer and suppress the phenomenon of bubbles generated between the optical layer and the protective film after curing.
本發明之真空壓合裝置包含一真空室、一下載台、一上載台及一固化裝置。該下載台設置於該真空室內,用以承載一基板,其上形成有一第一光學層,該第一光學層上設置有一光學膠層。該上載台相對於該下載台設置於該真空室內,用以承載一保護膜,該上載台能朝向該下載台移動以使該保護膜平鋪於該光學膠層上。該固化裝置用以固化該光學膠層以形成一第二光學層於該第一光學層上。藉此,該真空壓合裝置亦利用真空抑制該保護膜平鋪於該光學膠層上時引入空隙的可能性,並且可平穩且精確地控制該上載台下壓,使得該固化後的第二光學層厚度均勻且無氣泡。The vacuum pressing device of the present invention comprises a vacuum chamber, a downloading station, an loading station and a curing device. The downloading station is disposed in the vacuum chamber for carrying a substrate, and a first optical layer is formed thereon, and an optical adhesive layer is disposed on the first optical layer. The loading platform is disposed in the vacuum chamber relative to the downloading station for carrying a protective film, and the loading table can be moved toward the downloading station to lay the protective film on the optical adhesive layer. The curing device is configured to cure the optical adhesive layer to form a second optical layer on the first optical layer. Thereby, the vacuum pressing device also utilizes vacuum to suppress the possibility of introducing a gap when the protective film is laid on the optical adhesive layer, and can smoothly and accurately control the pressing of the loading table, so that the second after curing The optical layer is uniform in thickness and free of air bubbles.
本發明之又一目的在於提供一種製造方法,利用本發明之真空壓印裝置及真空壓合裝置以製造一層狀光學元件,故該製造方法亦利用真空環境及機器精密定位的特性,以有效控制該層狀光學元件之各光學層之厚度尺寸並抑制固化後於該層狀光學元件之層狀結構中產生的氣泡現象。Still another object of the present invention is to provide a manufacturing method using the vacuum imprinting apparatus and the vacuum lamination apparatus of the present invention to manufacture a layered optical component, so that the manufacturing method also utilizes the vacuum environment and the precise positioning characteristics of the machine to effectively The thickness dimension of each of the optical layers of the layered optical element is controlled and the phenomenon of bubbles generated in the layered structure of the layered optical element after curing is suppressed.
本發明之製造方法利用本發明之真空壓印裝置及真空壓合裝置以製造一層狀光學元件,該真空壓印裝置包含一第一真空室、一第一下載台、一第一上載台及一第一固化裝置,該真空壓合裝置包含一第二真空室、一第二下載台、一第二上載台及一第二固化裝置,該第一下載台及該第一上載台設置於該第一真空室內,該第二下載台及該第二上載台設置於該第二真空室內;其他進一步說明,請參閱前述說明,不再贅述。該製造方法包含:準備一基板,放置於該第一下載台上;於該基板上塗布一第一光學膠層;準備一模板,固定於該第一上載台上;對該第一真空室抽真空;使該第一上載台朝向該第一下載台移動以使該模板壓印一圖案於該第一光學膠層上;利用該第一固化裝置固化該壓印的第一光學膠層以形成一第一光學層於該基板上;取出該基板及該第一光學層;放置該基板及該第一光學層於該第二下載台上;於該第一光學層上塗布一第二光學膠層;準備一保護膜,固定於該第二上載台上;對該第二真空室抽真空;使該第一上載台朝向該第二下載台移動以使該保護膜平鋪於該第二光學膠層上;以及利用該第二固化裝置固化該第二光學膠層以形成一第二光學層於該第一光學層上,進而形成該層狀光學元件。藉此,該層狀光學元件之該基板、該第一光學層、該第二光學層及該保護膜可被精確地定位,該第一光學層及該第二光學層之厚度能被精確控制,該第一光學層、該第二光學層及該保護膜間亦可緊密貼合。The manufacturing method of the present invention utilizes the vacuum imprinting apparatus and the vacuum laminating apparatus of the present invention to manufacture a layered optical component, the vacuum imprinting apparatus comprising a first vacuum chamber, a first downloading station, a first loading station, and a first curing device, the vacuum pressing device comprises a second vacuum chamber, a second downloading station, a second loading station and a second curing device, wherein the first downloading station and the first loading station are disposed on the vacuuming device In the first vacuum chamber, the second downloading station and the second loading station are disposed in the second vacuum chamber; for further description, please refer to the foregoing description, and no further details are provided. The manufacturing method includes: preparing a substrate, placing on the first downloading station; coating a first optical adhesive layer on the substrate; preparing a template, fixing on the first loading stage; and pumping the first vacuum chamber Vacuuming; moving the first loading stage toward the first downloading station to imprint a pattern on the first optical adhesive layer; curing the embossed first optical adhesive layer by the first curing device to form a first optical layer is disposed on the substrate; the substrate and the first optical layer are taken out; the substrate and the first optical layer are placed on the second downloading stage; and a second optical adhesive is coated on the first optical layer Forming a protective film fixed on the second loading stage; evacuating the second vacuum chamber; moving the first loading stage toward the second downloading station to planarize the protective film to the second optical And the second optical layer is cured by the second curing device to form a second optical layer on the first optical layer to form the layered optical element. Thereby, the substrate, the first optical layer, the second optical layer and the protective film of the layered optical element can be accurately positioned, and the thickness of the first optical layer and the second optical layer can be precisely controlled The first optical layer, the second optical layer, and the protective film may also be in close contact with each other.
簡言之,本發明於真空環境中形成光學膠層,以有效抑制固化後於該光學層形成之層狀結構中產生的氣泡現象,並且採用機具以提昇製程精度,排除人工操作的不穩定性,故本發明能有效解決先前技術之問題。Briefly, the present invention forms an optical adhesive layer in a vacuum environment to effectively suppress the bubble phenomenon generated in the layered structure formed by the optical layer after curing, and employs an implement to improve process precision and eliminate manual operation instability. Therefore, the present invention can effectively solve the problems of the prior art.
關於本發明之優點與精神可以藉由以下的發明詳述及所附圖式得到進一步的瞭解。The advantages and spirit of the present invention will be further understood from the following detailed description of the invention.
請參閱第1圖及第2圖,第1圖為根據本發明之一較佳實施例之真空壓印裝置1之示意圖,第2圖為第1圖中真空壓印裝置1於另一狀態之示意圖。真空壓印裝置1包含一真空室12、一下載台14、一上載台16及一固化裝置18。真空室12主要由一底板122及一罩體124組成,罩體124可相對於底板122分離,以供物件置入操作;當底板122及罩體124閉合時,如第2圖所示,即可對真空室12進行抽真空操作,其中抽氣裝置係為習知技術,不另說明及於圖中繪示。下載台14設置於真空室12內、底板122上,用以承載一基板42,其上設置有一光學膠層44。上載台16相對於下載台14設置於真空室12內,用以承載一模板20,上載台16能朝向下載台14移動以使模板20壓印一圖案於光學膠層44上。固化裝置18用以固化壓印的光學膠層44以形成一光學層於基板42上。Please refer to FIG. 1 and FIG. 2, FIG. 1 is a schematic view of a vacuum imprint apparatus 1 according to a preferred embodiment of the present invention, and FIG. 2 is a view showing the vacuum imprint apparatus 1 of FIG. 1 in another state. schematic diagram. The vacuum imprint apparatus 1 includes a vacuum chamber 12, a download station 14, an loading station 16, and a curing device 18. The vacuum chamber 12 is mainly composed of a bottom plate 122 and a cover 124. The cover 124 can be separated from the bottom plate 122 for the object to be placed. When the bottom plate 122 and the cover 124 are closed, as shown in FIG. 2, The evacuation operation can be performed on the vacuum chamber 12, wherein the air extraction device is a conventional technique, which is not illustrated and illustrated in the drawings. The downloading stage 14 is disposed in the vacuum chamber 12 and on the bottom plate 122 for carrying a substrate 42 on which an optical adhesive layer 44 is disposed. The loading table 16 is disposed in the vacuum chamber 12 with respect to the downloading station 14 for carrying a template 20, and the loading table 16 can be moved toward the downloading station 14 to imprint a template 20 on the optical adhesive layer 44. The curing device 18 is used to cure the embossed optical adhesive layer 44 to form an optical layer on the substrate 42.
進一步來說,真空壓印裝置1包含複數個L形夾持件22,設置於上載台16上以形成一滑槽222,模板20可滑入滑槽222中並被夾持件22夾持。於實作上,模板20可為一鎳板,此時真空壓印裝置1可更包含多個磁鐵24,可移動地設置於上載台16中,用以吸附模板20於上載台16上;藉此,當磁鐵24朝向下載台14移動時,磁鐵24可磁吸模板20於上載台16上,且當磁鐵24遠離下載台14移動時,可解除對模板20的磁吸作用,以將模板20自上載台16移開。補充說明的是,前述L形夾持件22與磁鐵24可擇一使用,本發明不以同時使用為限。Further, the vacuum imprint apparatus 1 includes a plurality of L-shaped clamping members 22 disposed on the loading table 16 to form a chute 222. The template 20 can be slid into the chute 222 and clamped by the clamping member 22. In practice, the template 20 can be a nickel plate, and the vacuum imprinting device 1 can further include a plurality of magnets 24 movably disposed in the loading table 16 for adsorbing the template 20 on the loading table 16; Thus, when the magnet 24 moves toward the download stage 14, the magnet 24 can magnetically clamp the template 20 onto the loading table 16, and when the magnet 24 moves away from the download stage 14, the magnetic attraction to the template 20 can be released to move the template 20. Remove from the uploading station 16. It should be noted that the foregoing L-shaped clamping member 22 and the magnet 24 may be used alternatively, and the present invention is not limited to the simultaneous use.
真空壓印裝置1包含三個伺服軸26(請同時參閱第3圖,於第1圖及第2圖中,僅繪示其中二個伺服軸26),穿過罩體124與上載台16連接,伺服軸26可各自獨立控制以驅動上載台16相對於下載台14移動。此三伺服軸26可控制上載台16與下載台14間之平面度,亦即控制基板42與模板20間之平面度,以使光學膠層44之厚度均勻。於本實施例中,真空壓印裝置1包含三個間隙感測裝置28(請同時參閱第3圖,於第1圖及第2圖中,僅繪示其中二個間隙感測裝置28),對應伺服軸26設置於下載台14,用以控制上載台16之移動。間隙感測裝置28可感測上載台16與下載台14間之距離,以回饋控制伺服軸26之作動,進而控制光學膠層44之厚度。於本實施例中,間隙感測裝置28直接對應伺服軸26設置可直接對應控制伺服軸26之作動,簡化控制,但本發明不以此為限;並且,本發明亦不以設置多個伺服軸26以驅動上載台16之移動為限。The vacuum imprint apparatus 1 includes three servo shafts 26 (please refer to FIG. 3 at the same time, only two of the servo shafts 26 are shown in FIGS. 1 and 2), and are connected to the loading table 16 through the cover 124. The servo shafts 26 can each be independently controlled to drive the loading station 16 to move relative to the download station 14. The three servo shafts 26 control the flatness between the loading stage 16 and the download stage 14, that is, the flatness between the substrate 42 and the template 20, so that the thickness of the optical adhesive layer 44 is uniform. In the present embodiment, the vacuum imprint apparatus 1 includes three gap sensing devices 28 (please refer to FIG. 3 at the same time, and only two of the gap sensing devices 28 are shown in FIGS. 1 and 2). A corresponding servo axis 26 is provided at the download station 14 for controlling the movement of the uploading station 16. The gap sensing device 28 senses the distance between the loading platform 16 and the downloading station 14 to feedback the actuation of the servo shaft 26 to control the thickness of the optical adhesive layer 44. In the present embodiment, the gap sensing device 28 is directly disposed corresponding to the servo shaft 26 to directly control the actuation of the servo shaft 26, simplifying the control, but the invention is not limited thereto; and the present invention does not set a plurality of servos. The shaft 26 is limited to drive the movement of the loading table 16.
另外,伺服軸26相對於上載台16之設置位置以考慮上載台16之有效控制移動且平均支撐為原則,例如第3圖之上載台16、伺服軸26及間隙感測裝置28之相對設置位置之示意圖所示,其中以矩形框表示上載台16之輪廓位置,大圓圈表示伺服軸26之位置,小圓圈表示間隙感測裝置28,十字標記表示上載台16重心162之位置。伺服軸26之位置至重心162之連線形成三個大致相等的夾角262,且伺服軸26之位置至重心162之距離亦相差不大。間隙感測裝置28則接近對應的伺服軸26設置,以簡化回饋控制複雜度。惟,本發明仍不以前述設置方式為限。In addition, the position of the servo shaft 26 relative to the loading table 16 is based on the principle of effective control movement of the loading table 16 and the average support, for example, the relative positions of the loading table 16, the servo shaft 26 and the gap sensing device 28 of FIG. In the schematic view, the outline position of the loading table 16 is indicated by a rectangular frame, the large circle indicates the position of the servo shaft 26, the small circle indicates the gap sensing device 28, and the cross mark indicates the position of the center of gravity 162 of the loading table 16. The line connecting the position of the servo shaft 26 to the center of gravity 162 forms three substantially equal angles 262, and the distance from the position of the servo shaft 26 to the center of gravity 162 is also small. The gap sensing device 28 is then placed close to the corresponding servo axis 26 to simplify the feedback control complexity. However, the present invention is not limited to the foregoing arrangement.
請回到第1圖及第2圖。於本實施例中,光學膠層44係為一UV膠,故固化裝置18包含一紫外光燈182,用以照射紫外光於光學膠層44以固化形成該光學層。又,於本實施例中,下載台14係透明,紫外光燈182設置於下載台14下方,以直接且均勻地照射紫外光於光學膠層44。但本發明均不以此為限,實作上自可配合不同的光學膠層特性採用不同的固化裝置以實現光學膠層的固化。Please return to Figure 1 and Figure 2. In the present embodiment, the optical adhesive layer 44 is a UV adhesive. Therefore, the curing device 18 includes an ultraviolet light 182 for irradiating ultraviolet light on the optical adhesive layer 44 to form the optical layer. Moreover, in the present embodiment, the downloading station 14 is transparent, and the ultraviolet lamp 182 is disposed under the downloading stage 14 to directly and uniformly irradiate ultraviolet light on the optical adhesive layer 44. However, the present invention is not limited thereto. In practice, different curing devices can be used to match the different optical adhesive layer characteristics to achieve curing of the optical adhesive layer.
於本實施例中,真空壓印裝置1包含二頂針30,貫穿上載台16設置,用以於該光學層脫模時,頂彎模板20。頂針30可由一氣壓缸驅動,頂針30相對模板20之設置位置可參閱第4圖中所示,其中以矩形表示模板20之輪廓位置,四個虛線方框表示夾持件22之位置,小圓圈表示頂針30之位置,其大致位於夾持件22中間。於該光學層(即後文中第一光學層45)脫模時,上載台16向上移動,並使頂針30相對上載台16突出即可頂彎模板20,如第5圖所示,此有助於該光學層脫模。In the present embodiment, the vacuum imprint apparatus 1 includes two ejector pins 30 disposed through the loading table 16 for bending the template 20 when the optical layer is demolded. The thimble 30 can be driven by a pneumatic cylinder. The position of the ejector pin 30 relative to the template 20 can be referred to in FIG. 4, wherein the outline position of the template 20 is indicated by a rectangle, and the four dotted squares indicate the position of the clamping member 22, a small circle. The position of the ejector pin 30 is shown, which is located substantially in the middle of the gripping member 22. When the optical layer (ie, the first optical layer 45 in the following) is demolded, the loading table 16 is moved upward, and the ejector pin 30 is protruded relative to the loading table 16 to bend the template 20, as shown in FIG. Demolding the optical layer.
請回到第1圖及第2圖。於本實施例中,真空壓印裝置1包含一吹氣裝置32,設置於下載台14旁,用以於該光學層脫模時,利用噴嘴322朝向模板20與該光學層吹氣。此吹氣裝置32可設置於罩體124外側,有利於吹氣裝置32之設置;但本發明不以此為限。補充說明的是,於第1圖及第2圖中僅繪示吹氣裝置32之噴嘴322及部分管線,以簡化繪圖,其建置(包含氣源)為習知技術,不另贅述。另外,於本實施例中,該光學層自模板20脫模同時採用頂針30及吹氣裝置32輔助,如第5圖所示;但本發明不以此為限。Please return to Figure 1 and Figure 2. In the present embodiment, the vacuum imprinting apparatus 1 includes an air blowing device 32 disposed beside the downloading station 14 for blowing the optical layer toward the template 20 by the nozzle 322 when the optical layer is demolded. The air blowing device 32 can be disposed outside the cover 124 to facilitate the setting of the air blowing device 32; however, the invention is not limited thereto. It is to be noted that in the first and second figures, only the nozzle 322 and part of the pipeline of the air blowing device 32 are shown to simplify the drawing, and the construction (including the air source) is a conventional technique, and will not be further described. In addition, in the embodiment, the optical layer is released from the template 20 and is assisted by the ejector pin 30 and the air blowing device 32, as shown in FIG. 5; however, the invention is not limited thereto.
請參閱第6圖及第7圖,第6圖為根據本發明之另一較佳實施例之真空壓合裝置5之示意圖,第7圖為第6圖中真空壓合裝置5於另一狀態之示意圖。真空壓合裝置5包含一真空室52、一下載台54、一上載台56及一固化裝置58。真空室52主要由一底板522及一罩體524組成,罩體524可相對於底板522分離,以供物件置入操作;當底板522及罩體524閉合時,如第7圖所示,即可對真空室52進行抽真空操作,其中抽氣裝置係為習知技術,不另說明及於圖中繪示。下載台54設置於真空室12內、底板522上,用以承載該基板42,其上形成有一第一光學層45,第一光學層45上設置有一光學膠層46。上載台56相對於下載台54設置於真空室52內,用以承載一保護膜60,上載台56能朝向下載台54移動以使保護膜60平鋪於光學膠層46上。固化裝置58用以固化光學膠層46以形成一第二光學層於第一光學層45上。補充說明的是,該基板42及其上形成之第一光學層45可為利用真空壓印裝置1製作形成,亦可取自其他層狀光學元件製程製作之半成品。Please refer to FIG. 6 and FIG. 7 , FIG. 6 is a schematic view of a vacuum pressing device 5 according to another preferred embodiment of the present invention, and FIG. 7 is a view showing the vacuum pressing device 5 in FIG. 6 in another state. Schematic diagram. The vacuum press device 5 includes a vacuum chamber 52, a download station 54, an loading station 56, and a curing device 58. The vacuum chamber 52 is mainly composed of a bottom plate 522 and a cover 524. The cover 524 can be separated from the bottom plate 522 for the object to be placed. When the bottom plate 522 and the cover 524 are closed, as shown in FIG. The vacuum chamber 52 can be subjected to a vacuuming operation, wherein the air suction device is a conventional technique, which is not illustrated and illustrated in the drawings. The downloading stage 54 is disposed in the vacuum chamber 12 and on the bottom plate 522 for carrying the substrate 42. The first optical layer 45 is formed on the first optical layer 45. The optical layer 46 is disposed on the first optical layer 45. The loading table 56 is disposed in the vacuum chamber 52 with respect to the downloading station 54 for carrying a protective film 60. The loading table 56 can be moved toward the downloading table 54 to lay the protective film 60 on the optical adhesive layer 46. The curing device 58 is used to cure the optical adhesive layer 46 to form a second optical layer on the first optical layer 45. It should be noted that the substrate 42 and the first optical layer 45 formed thereon may be formed by the vacuum imprint apparatus 1 or may be taken from other semi-finished optical component processes.
進一步來說,真空壓合裝置5包含二磁鐵62及二固定板64,磁鐵62設置於上載台56內,固定板64對應磁鐵62吸附於上載台56上,用以固定保護膜60。於本實施例中,保護膜60係一PET膜,但本發明不以此為限,其他軟性薄膜亦可;固定板64可為鐵片或其他具有磁性之片狀物。另外,於本實施例中,上載台56包含複數個通氣孔562,用以對通氣孔562抽氣以真空吸附保護膜60於上載台56上,使得保護膜60可更容易平坦地放置於上載台56上,以及用以對通氣孔562通氣以自上載台56分離保護膜60,使得保護膜60易於自上載台56脫離。Further, the vacuum bonding apparatus 5 includes two magnets 62 and two fixing plates 64. The magnets 62 are disposed in the loading table 56. The fixing plates 64 are attached to the loading table 56 corresponding to the magnets 62 for fixing the protective film 60. In the present embodiment, the protective film 60 is a PET film, but the invention is not limited thereto, and other flexible films may be used; the fixing plate 64 may be an iron piece or other magnetic sheet. In addition, in the present embodiment, the loading table 56 includes a plurality of vent holes 562 for evacuating the vent holes 562 to vacuum-adsorb the protective film 60 on the loading table 56, so that the protective film 60 can be more easily placed on the uploading surface. The table 56 is vented to vent the vent 562 to separate the protective film 60 from the loading table 56, so that the protective film 60 is easily detached from the loading table 56.
於本實施例中,真空壓合裝置5包含一治具66,用以輔助保護膜60貼附於上載台56上。請參閱第8圖,其為治具66之示意圖。治具66包含一支架662、二固定部664及於每一個固定部664上設置多至少一個真空吸盤666。於使用時,先將固定板64置於真空吸盤666旁,再將保護膜60平坦置於固定板64及真空吸盤666上並被真空吸盤666吸住。將治具66伸入真空室52中,並將保護膜60平坦接觸上載台56,磁鐵62即吸附固定板64,再將真空吸盤666釋放真空,即完成保護膜60貼附於上載台56之操作;此時治具66即可移出真空室52。In the present embodiment, the vacuum pressing device 5 includes a jig 66 for assisting the protective film 60 to be attached to the loading table 56. Please refer to FIG. 8 , which is a schematic diagram of the jig 66 . The jig 66 includes a bracket 662, two fixing portions 664, and at least one vacuum chuck 666 disposed on each of the fixing portions 664. In use, the fixing plate 64 is placed next to the vacuum chuck 666, and the protective film 60 is placed flat on the fixing plate 64 and the vacuum suction cup 666 and sucked by the vacuum suction cup 666. The jig 66 is inserted into the vacuum chamber 52, and the protective film 60 is brought into flat contact with the loading table 56. The magnet 62 is the adsorption fixing plate 64, and the vacuum suction cup 666 is released from the vacuum, that is, the protective film 60 is attached to the loading table 56. Operation; at this time, the fixture 66 can be removed from the vacuum chamber 52.
請回到第6圖及第7圖。真空壓合裝置5包含三伺服軸68,穿過罩體524與上載台56連接,伺服軸68可各自獨立控制以驅動上載台56相對於下載台54移動。於本實施例中,真空壓合裝置5包含三間隙感測裝置70,對應伺服軸68設置於下載台54,用以控制上載台56之移動。關於伺服軸68及間隙感測裝置70之其他說明,可直接參閱前述有關伺服軸26及間隙感測裝置28之其他說明,在此不再贅述。Please return to Figures 6 and 7. The vacuum press unit 5 includes three servo shafts 68 that are coupled to the loading table 56 through a cover 524 that can be independently controlled to drive the loading table 56 to move relative to the download station 54. In the present embodiment, the vacuum pressing device 5 includes a three-gap sensing device 70, and the corresponding servo shaft 68 is disposed on the downloading station 54 for controlling the movement of the loading table 56. For other descriptions of the servo shaft 68 and the gap sensing device 70, other descriptions of the servo shaft 26 and the gap sensing device 28 may be directly referred to, and details are not described herein.
於本實施例中,光學膠層46係為一UV膠,故固化裝置58包含一紫外光燈582,用以照射紫外光於光學膠層46以固化形成該第二光學層。又,於本實施例中,上載台56係透明,紫外光燈582設置於上載台56上方,可均勻地照射紫外光於光學膠層46,但本發明均不以此為限。前述關於固化裝置18於此亦有適用,不另贅述。In the present embodiment, the optical adhesive layer 46 is a UV adhesive, so the curing device 58 includes an ultraviolet light 582 for irradiating ultraviolet light on the optical adhesive layer 46 to cure to form the second optical layer. Moreover, in the present embodiment, the loading table 56 is transparent, and the ultraviolet lamp 582 is disposed above the loading table 56 to uniformly irradiate the ultraviolet light on the optical adhesive layer 46. However, the present invention is not limited thereto. The above-mentioned curing device 18 is also applicable here, and will not be further described.
於本實施例中,下載台更包含一加熱裝置72,例如加熱棒,用以加熱光學膠層46,可增加光學膠層46之流動性,有利於保護膜60平鋪於光學膠層46上。補充說明的是,當保護膜60具有一配向結構於其表面上時,於上載台56下壓保護膜60於光學膠層46上時,亦能同時壓印該配向結構於光學膠層46上。In this embodiment, the downloading station further includes a heating device 72, such as a heating rod, for heating the optical adhesive layer 46, which increases the fluidity of the optical adhesive layer 46, and facilitates the protective film 60 to be laid on the optical adhesive layer 46. . It is to be noted that when the protective film 60 has an alignment structure on the surface thereof, when the protective film 60 is pressed onto the optical adhesive layer 46 on the loading table 56, the alignment structure can also be imprinted on the optical adhesive layer 46. .
請參閱第9圖,其為根據本發明之一較佳實施例之層狀光學元件之製造方法之流程圖。該製造方法利用真空壓印裝置1及真空壓合裝置5以製造一層狀光學元件4(請參閱第10圖),其中真空壓印裝置1及真空壓合裝置5已如前述,不再贅述。該製造方法首先準備一基板42,放置於真空壓印裝置1之下載台14上,如步驟S100所示。該製造方法包含於基板42上塗布一光學膠層44,如步驟S102所示;其中,於實作上,光學膠層44可先塗布於基板42上,再將基板42連同光學膠層44一併放置於下載台14上。該製造方法亦準備模板20,固定於真空壓印裝置1之上載台16上,如步驟S104所示。步驟S100至步驟S104之實施先後不限於第9圖所示之順序;完成前述步驟後,真空壓印裝置1之狀態可參閱第1圖。Please refer to FIG. 9, which is a flow chart of a method of fabricating a layered optical element in accordance with a preferred embodiment of the present invention. The manufacturing method utilizes a vacuum imprinting apparatus 1 and a vacuum lamination apparatus 5 to manufacture a layered optical element 4 (refer to FIG. 10), wherein the vacuum imprint apparatus 1 and the vacuum lamination apparatus 5 have been described above, and are not described again. . The manufacturing method first prepares a substrate 42 and places it on the downloading stage 14 of the vacuum imprinting apparatus 1, as shown in step S100. The manufacturing method includes coating an optical adhesive layer 44 on the substrate 42 as shown in step S102. In practice, the optical adhesive layer 44 may be first applied to the substrate 42 and then the substrate 42 together with the optical adhesive layer 44. And placed on the download station 14. This manufacturing method also prepares the template 20, which is fixed to the loading table 16 of the vacuum imprint apparatus 1, as shown in step S104. The steps S100 to S104 are not limited to the order shown in FIG. 9; after the foregoing steps are completed, the state of the vacuum imprint apparatus 1 can be referred to FIG.
該製造方法接著將真空壓印裝置1之罩體124與底板122密合以對真空壓印裝置1之真空室12抽真空,如步驟S106所示;使真空壓印裝置1之上載台16朝向下載台14移動以使模板20壓印一圖案於光學膠層44上,如步驟S108所示。此圖案即用於於光學膠層44上形成表面幾何結構,例如鋸齒狀、錐狀、波浪狀等等,以達到所需的光學效果。完成前述步驟後,真空壓印裝置1之狀態可參閱第2圖。該製造方法接著利用真空壓印裝置1之固化裝置18固化壓印的光學膠層44以形成一第一光學層45,如步驟S110所示。實作上,於步驟S110實施前,可先將真空室12破真空,下載台14則以真空吸附的方式吸住基板42,此可避免第一光學層45引入過多的殘留應力並可維持住第一光學層45與基板42之相對位置。固化完成後,罩體124上升,以利於取出基板42及形成於其上之第一光學層45,如步驟S112所示。The manufacturing method then closes the cover 124 of the vacuum imprint apparatus 1 to the bottom plate 122 to evacuate the vacuum chamber 12 of the vacuum imprint apparatus 1, as shown in step S106; and the loading stage 16 of the vacuum imprint apparatus 1 is oriented. The download stage 14 is moved to cause the template 20 to imprint a pattern on the optical adhesive layer 44 as shown in step S108. This pattern is used to form surface geometries on the optical adhesive layer 44, such as serrated, tapered, wavy, etc., to achieve the desired optical effect. After completing the foregoing steps, the state of the vacuum imprint apparatus 1 can be referred to Fig. 2. The manufacturing method then cures the embossed optical adhesive layer 44 using the curing device 18 of the vacuum imprinting apparatus 1 to form a first optical layer 45, as shown in step S110. In practice, before the step S110 is performed, the vacuum chamber 12 can be vacuumed first, and the downloading station 14 sucks the substrate 42 by vacuum adsorption, which can prevent the first optical layer 45 from introducing excessive residual stress and can be maintained. The relative position of the first optical layer 45 to the substrate 42. After the curing is completed, the cover 124 is raised to facilitate the removal of the substrate 42 and the first optical layer 45 formed thereon, as shown in step S112.
進一步來說,步驟S104可包含將模板20滑入夾持件22形成之滑槽222中,以達到固定於上載台16之目的。又,真空壓印裝置1設計具有磁吸作用,故步驟S104可包含使磁鐵24朝向下載台14移動,以藉由磁鐵24將模板20吸附於上載台16上。關於夾持件22及磁鐵24之其他說明,請參閱前文,不再贅述。Further, step S104 may include sliding the template 20 into the chute 222 formed by the clamping member 22 for the purpose of being fixed to the loading table 16. Further, since the vacuum imprint apparatus 1 is designed to have a magnetic attraction effect, the step S104 may include moving the magnet 24 toward the download stage 14 to adsorb the template 20 to the loading stage 16 by the magnet 24. For other descriptions of the clamping member 22 and the magnet 24, please refer to the foregoing and will not be described again.
此外,真空壓印裝置1設計有可獨立控制之伺服軸26,以驅動上載台16之移動,故步驟S108可包含獨立控制伺服軸26,以驅動上載台16朝向下載台14移動。又,真空壓印裝置1設置有間隙感測裝置28,故步驟S108可為獨立控制伺服軸26,以驅動上載台16朝向下載台14移動,以使模板20接觸光學膠層44,以及根據間隙感測裝置28之回饋訊號,控制移動的上載台16之停止位置,以使模板20壓印該圖案於光學膠層44上並能精確控制光學膠層44之厚度。關於伺服軸26及間隙感測裝置28之其他說明,請參閱前文,不再贅述。Further, the vacuum imprint apparatus 1 is designed with an independently controllable servo shaft 26 to drive the movement of the loading stage 16, so step S108 may include independently controlling the servo shaft 26 to drive the loading stage 16 to move toward the download stage 14. Moreover, the vacuum imprint apparatus 1 is provided with the gap sensing device 28, so step S108 can independently control the servo shaft 26 to drive the loading stage 16 to move toward the download stage 14 to contact the template 20 with the optical adhesive layer 44, and according to the gap. The feedback signal of the sensing device 28 controls the stop position of the moving loading table 16 to cause the template 20 to imprint the pattern on the optical adhesive layer 44 and to precisely control the thickness of the optical adhesive layer 44. For other descriptions of the servo shaft 26 and the gap sensing device 28, please refer to the foregoing and will not be described again.
另外,於本實施例中,固化裝置18包含紫外光燈182,故步驟S110可為對真空室12破真空,以及利用設置於下載台14下方之紫外光燈182朝向上載台16照射紫外光於壓印的光學膠層44,以使壓印的光學膠層44固化形成第一光學層45。其他關於固化裝置18之其他說明,請參閱前文,不再贅述。In addition, in the embodiment, the curing device 18 includes the ultraviolet lamp 182, so the step S110 may be to vacuum the vacuum chamber 12, and the ultraviolet light 182 disposed under the downloading station 14 is irradiated to the loading table 16 with ultraviolet light. The embossed optical adhesive layer 44 is cured to form the embossed optical adhesive layer 44 to form the first optical layer 45. For other descriptions of the curing device 18, please refer to the foregoing and will not be described again.
於步驟S112中,於自真空室12取出基板42前,第一光學層45需自模板20脫模,又真空壓印裝置1設計有頂針30及吹氣裝置32,以輔助脫模,故步驟S112包含使上載台16遠離下載台14移動,同時使頂針30突出於上載台16,以頂彎模板20,以及同時利用吹氣裝置32朝向模板20與第一光學層45吹氣,其示意圖可參閱第5圖。其他關於頂針30及吹氣裝置32之其他說明,請參閱前文,不再贅述。In step S112, before the substrate 42 is taken out from the vacuum chamber 12, the first optical layer 45 needs to be demolded from the template 20, and the vacuum imprinting device 1 is designed with a ejector pin 30 and an air blowing device 32 to assist in demoulding, so the steps are performed. S112 includes moving the loading table 16 away from the downloading table 14 while the ejector pin 30 protrudes from the loading table 16 to bend the template 20, and simultaneously blows the air with the first optical layer 45 toward the template 20 by using the air blowing device 32. See Figure 5. For other descriptions of the thimble 30 and the air blowing device 32, please refer to the foregoing and will not be described again.
接著,該製造方法將利用真空壓合裝置5於基板42上進行另一光學層成形工序,說明如下。該製造方法接著放置基板42及形成於其上之第一光學層45於真空壓合裝置5之下載台54上,如步驟S114所示。該製造方法包含於第一光學層45上塗布一光學膠層46,如步驟S116所示;其中,於實作上,光學膠層46可先塗布於第一光學層45上,再將帶有第一光學層45之基板42連同光學膠層46一併放置於下載台54上。該製造方法亦準備保護膜60,固定於真空壓合裝置5之上載台56上,如步驟S118所示。步驟S114至步驟S118之實施先後不限於第9圖所示之順序;完成前述步驟後,真空壓合裝置5之狀態可參閱第6圖。Next, this manufacturing method will perform another optical layer forming process on the substrate 42 by the vacuum bonding apparatus 5, and will be described below. The manufacturing method then places the substrate 42 and the first optical layer 45 formed thereon on the downloading station 54 of the vacuum pressing device 5, as shown in step S114. The manufacturing method includes coating an optical adhesive layer 46 on the first optical layer 45, as shown in step S116; wherein, in practice, the optical adhesive layer 46 may be first applied to the first optical layer 45, and then The substrate 42 of the first optical layer 45 is placed on the download stage 54 together with the optical adhesive layer 46. This manufacturing method also prepares the protective film 60 and is fixed to the loading table 56 of the vacuum pressing device 5 as shown in step S118. The steps S114 to S118 are not limited to the sequence shown in FIG. 9; after the foregoing steps are completed, the state of the vacuum pressing device 5 can be referred to FIG.
該製造方法接著將真空壓合裝置5之罩體524與底板522密合以對真空壓合裝置5之真空室52抽真空,如步驟S120所示;使真空壓合裝置5之上載台56朝向下載台54移動以使保護膜60平鋪於光學膠層46上,如步驟S122所示。完成前述步驟後,真空壓合裝置5之狀態可參閱第7圖。該製造方法接著利用真空壓合裝置5之固化裝置58固化被壓平的光學膠層46以形成一第二光學層47,進而形成層狀光學元件4,如步驟S124。實作上,於步驟S124實施前,可先將真空室52破真空,下載台54則以真空吸附的方式吸住基板42,此可避免第二光學層47引入過多的殘留應力並可維持住第二光學層47與基板42之相對位置。固化完成後,罩體524上升,以利於取出基板42及形成於其上之第一光學層45及第二光學層47,如第10圖所示。The manufacturing method then closes the cover 524 of the vacuum pressing device 5 to the bottom plate 522 to evacuate the vacuum chamber 52 of the vacuum pressing device 5, as shown in step S120; and the loading table 56 of the vacuum pressing device 5 is oriented. The download stage 54 is moved to cause the protective film 60 to be laid on the optical adhesive layer 46 as shown in step S122. After the completion of the foregoing steps, the state of the vacuum press device 5 can be referred to Fig. 7. The manufacturing method then cures the flattened optical adhesive layer 46 by the curing device 58 of the vacuum pressing device 5 to form a second optical layer 47, thereby forming the layered optical element 4, as by step S124. In practice, before the step S124 is performed, the vacuum chamber 52 can be vacuumed first, and the downloading station 54 sucks the substrate 42 by vacuum adsorption, which can prevent the second optical layer 47 from introducing excessive residual stress and can be maintained. The relative position of the second optical layer 47 to the substrate 42. After the curing is completed, the cover 524 is raised to facilitate the removal of the substrate 42 and the first optical layer 45 and the second optical layer 47 formed thereon, as shown in FIG.
進一步來說,步驟S118可包含藉由固定板64對應磁鐵62吸附於上載台56上,以固定保護膜60於上載台56上。當使用治具66實施保護膜60固定於上載台56時,步驟S118可為將固定板64設置於真空吸盤666旁,將保護膜60平鋪於治具66上,利用真空吸盤666吸附保護膜60,將治具66伸入真空室52中,使保護膜60貼附於上載台56上,並使固定板64藉由磁鐵62吸附於上載台56上以固定保護膜60,釋放真空吸盤666之真空,以及移出治具66。其中,為使保護膜60能更平坦貼附於上載台56,步驟S118可包含對通氣孔562抽氣以真空吸附保護膜60於上載台56上。關於治具66及通氣孔562之其他說明,請參閱前文,不再贅述。Further, step S118 may include adsorbing the corresponding magnet 62 on the loading table 56 by the fixing plate 64 to fix the protective film 60 on the loading table 56. When the protective film 60 is fixed to the loading table 56 by using the jig 66, the step S118 may be such that the fixing plate 64 is disposed beside the vacuum suction cup 666, the protective film 60 is laid on the jig 66, and the protective film is adsorbed by the vacuum suction cup 666. 60, the jig 66 is inserted into the vacuum chamber 52, the protective film 60 is attached to the loading table 56, and the fixing plate 64 is attracted to the loading table 56 by the magnet 62 to fix the protective film 60, and the vacuum suction cup 666 is released. The vacuum, as well as the removal of the jig 66. In order to make the protective film 60 more flatly attached to the loading table 56, step S118 may include evacuating the vent 562 to vacuum-adsorb the protective film 60 on the loading table 56. For other descriptions of the jig 66 and the vent 562, please refer to the foregoing and will not be described again.
與真空壓印裝置1相同,真空壓合裝置5亦設計有可獨立控制之伺服軸68,故步驟S116可包含獨立控制伺服軸68,以驅動上載台56朝向下載台54移動。同樣地,真空壓合裝置5設置有間隙感測裝置70,故步驟S116可為獨立控制伺服軸68,以驅動上載台56朝向下載台54移動,以使保護膜60接觸於光學膠層46上,以及根據間隙感測裝置70之回饋訊號,控制移動的上載台56之停止位置,以使保護膜60平壓於光學膠層46上並能精確控制光學膠層46之厚度。關於伺服軸68及間隙感測裝置70之其他說明,請參閱前文,不再贅述。As with the vacuum imprinting apparatus 1, the vacuum lamination apparatus 5 is also designed with independently controllable servo shafts 68, so step S116 can include independently controlling the servo shaft 68 to drive the loading stage 56 to move toward the downloading stage 54. Similarly, the vacuum pressing device 5 is provided with the gap sensing device 70. Therefore, the step S116 can independently control the servo shaft 68 to drive the loading table 56 to move toward the downloading table 54 to contact the protective film 60 on the optical adhesive layer 46. And according to the feedback signal of the gap sensing device 70, the stopping position of the moving loading table 56 is controlled, so that the protective film 60 is pressed against the optical adhesive layer 46 and the thickness of the optical adhesive layer 46 can be precisely controlled. For other descriptions of the servo shaft 68 and the gap sensing device 70, please refer to the foregoing and will not be described again.
另外,於本實施例中,固化裝置58包含紫外光燈582,故步驟S124可為對真空室52破真空,以及利用設置於上載台56上方之紫外光燈582朝向下載台54照射紫外光於光學膠層46,以使光學膠層46固化形成第二光學層47。其他關於固化裝置58之其他說明,請參閱前文,不再贅述。In addition, in the embodiment, the curing device 58 includes the ultraviolet lamp 582. Therefore, the step S124 may be to vacuum the vacuum chamber 52, and the ultraviolet light 582 disposed above the loading table 56 is irradiated with ultraviolet light toward the downloading station 54. The optical adhesive layer 46 is such that the optical adhesive layer 46 is cured to form the second optical layer 47. For other descriptions of the curing device 58, please refer to the foregoing and will not be described again.
此外,於本實施例中,下載台56設置有加熱裝置72,故步驟S116可包含利用加熱裝置72以加熱光學膠層46,可增加光學膠層46之流動性,有利於保護膜60平鋪於光學膠層46上。關於加熱裝置72之其他說明,請參閱前文,不再贅述。又,當保護膜60具有一配向結構於其表面上時,步驟S116可包含利用保護膜60壓印該配向結構於光學膠層46上。關於該配向結構之其他說明,請參閱前文,不再贅述。In addition, in the present embodiment, the downloading station 56 is provided with the heating device 72. Therefore, the step S116 may include heating the optical adhesive layer 46 by using the heating device 72, which may increase the fluidity of the optical adhesive layer 46, and facilitate the tiling of the protective film 60. On the optical adhesive layer 46. For other descriptions of the heating device 72, please refer to the foregoing and will not be described again. Moreover, when the protective film 60 has an alignment structure on the surface thereof, the step S116 may include imprinting the alignment structure on the optical adhesive layer 46 with the protective film 60. For other explanations of the alignment structure, please refer to the foregoing and will not repeat them.
另外,補充說明的是,實作上,本發明之真空壓印裝置不以前述真空壓印裝置1為限,尤其是利用頂針30頂彎模板20之脫模機制。請參閱第1圖及第11圖,第11圖為根據本發明之另一實施例之真空壓印裝置3之示意圖。於本實施例中,真空壓印裝置3與第1圖中真空壓印裝置1,主要不同之處在於真空壓印裝置3使用之模板21無需使用夾持件22及磁鐵24,而改以二折板機構23及複數個固定件19設置於真空壓印裝置3之上載台17上。於真空壓印裝置3中,上載台17包含一突台172,模板21設置於突台172上,折板機構23設置於上載台17,折板機構23包含一致動桿232及與致動桿232連接之一固持件234,固持件234設置於突台172旁以能勾持模板21之相對兩側。於實作上,致動桿232得以氣壓缸驅動,使得固持件234能相對上載台17移動,但本發明不以此為限。In addition, it is to be noted that, in practice, the vacuum imprint apparatus of the present invention is not limited to the vacuum imprint apparatus 1 described above, and in particular, the demolding mechanism of the top plate 30 for bending the template 20 is utilized. Referring to Figures 1 and 11, Figure 11 is a schematic view of a vacuum imprinting apparatus 3 in accordance with another embodiment of the present invention. In the present embodiment, the vacuum imprint apparatus 3 is different from the vacuum imprint apparatus 1 of FIG. 1 in that the template 21 used in the vacuum imprint apparatus 3 does not need to use the holding member 22 and the magnet 24, but is changed to two. The folding mechanism 23 and the plurality of fixing members 19 are provided on the loading table 17 of the vacuum imprint apparatus 3. In the vacuum imprinting apparatus 3, the loading table 17 includes a projection 172, and the template 21 is disposed on the projection 172. The folding mechanism 23 is disposed on the loading table 17, and the folding mechanism 23 includes an interlocking rod 232 and an actuating lever. 232 is connected to one of the holding members 234, and the holding member 234 is disposed beside the protruding base 172 so as to be able to hook the opposite sides of the template 21. In practice, the actuating lever 232 is driven by the pneumatic cylinder so that the retaining member 234 can move relative to the loading table 17, but the invention is not limited thereto.
此外,固定件19固定於上載台17,模板21具有複數個固定孔212,對應該複數個固定件19,模板21藉由該複數個固定件19穿過該複數個固定孔212以設置於上載台17上。於本實施例中,固定孔212之載面大於對應的固定件19穿過固定孔212部位之載面,固定件19例如螺絲,鎖於上載台17,固定孔212包含一通道部2122及與通道部2122連通之一卡持部2124,其示意圖如第12圖所示;固定件19之螺絲頭穿過通道部2122,再卡持住通道部2122,以使模板21能固定突台172上。原則上,固持件234已可有效使模板21設置於突台172上,故實作上,固定件19及固定孔212之設置得省略;惟固定件19及固定孔212之設置仍有助於模板21之定位。另外,於實作上,突台172得另件設置於上載台17之本體上,不以第11圖中上載台17所示之一體成形結構為限。In addition, the fixing member 19 is fixed to the loading table 17, and the template 21 has a plurality of fixing holes 212 corresponding to the plurality of fixing members 19, and the template 21 is disposed on the uploading by the plurality of fixing members 19 through the plurality of fixing holes 212. On the 17th. In this embodiment, the mounting surface of the fixing hole 212 is larger than the bearing surface of the corresponding fixing member 19 passing through the fixing hole 212, and the fixing member 19, for example, a screw, is locked to the loading table 17, and the fixing hole 212 includes a channel portion 2122 and The channel portion 2122 communicates with one of the latching portions 2124, the schematic view of which is shown in FIG. 12; the screw head of the fixing member 19 passes through the channel portion 2122, and then the channel portion 2122 is clamped so that the template 21 can be fixed to the boss 172. . In principle, the holding member 234 can effectively set the template 21 on the protruding base 172. Therefore, the fixing member 19 and the fixing hole 212 are omitted from the setting; however, the setting of the fixing member 19 and the fixing hole 212 still contributes to the template. 21 positioning. Further, in practice, the projections 172 are provided on the main body of the loading table 17, and are not limited to the one-piece forming structure shown in the loading table 17 in Fig. 11.
請參閱第5圖及第13圖,第13圖為第11圖之真空壓印裝置3之脫模示意圖。真空壓印裝置3與第5圖中真空壓印裝置1之脫模機制大致相同,主要不同之處在於上載台17遠離下載台14移動時,真空壓印裝置1主要使用致動桿232驅動固持件234相對上載台17遠離下載台14移動以彎曲模板21。於本實施例中,固定件19並未將模板21之兩側完全固定,故模板21整體均可被彎曲,有助於模板21與第一光學層45分離,尤其是第一光學層45邊緣部分與模板21分離;其中,固定孔212與固定件19輪廓並非完全密合,故當模板21彎曲時,模板21可藉由固定孔212相對固定件19滑動,以避免模板21於彎曲受到過度的限制。另外,原則上,固持件234已可使模板21彎曲,然於實作上,真空壓印裝置3亦可輔助使用頂針30強化模板21彎曲程度,亦有助於模板21與第一光學層45分離。關於真空壓印裝置3之各部件之其他說明,請參閱前文,不再贅述。Please refer to FIG. 5 and FIG. 13 , and FIG. 13 is a schematic view showing the demolding of the vacuum imprint apparatus 3 of FIG. 11 . The vacuum imprinting device 3 is substantially the same as the demolding mechanism of the vacuum imprinting device 1 in FIG. 5, and the main difference is that when the loading table 17 moves away from the downloading table 14, the vacuum imprinting device 1 is mainly driven and held by the actuating lever 232. The piece 234 moves away from the download stage 14 relative to the loading table 17 to bend the template 21. In this embodiment, the fixing member 19 does not completely fix the two sides of the template 21, so that the template 21 as a whole can be bent, which helps the template 21 to be separated from the first optical layer 45, especially the edge of the first optical layer 45. The portion is separated from the template 21; wherein the fixing hole 212 and the fixing member 19 are not completely in close contact with each other, so that when the template 21 is bent, the template 21 can be slid relative to the fixing member 19 by the fixing hole 212 to prevent the template 21 from being excessively bent. limits. In addition, in principle, the holding member 234 can bend the template 21, but in practice, the vacuum imprinting device 3 can also assist in using the thimble 30 to strengthen the bending degree of the template 21, and also contribute to the template 21 and the first optical layer 45. Separation. For other descriptions of the various components of the vacuum imprinting apparatus 3, please refer to the foregoing and will not be described again.
此外,於本實施例中,突台172對應該二折板機構23之二邊緣上分別形成一導角1722,使得模板21彎曲時能緊貼導角1722,以避免過於銳利的邊緣擦傷模板21,亦能使模板21彎曲截面輪廓更為平順;但本發明不以此為限。補充說明的是,當使用頂針30彎曲模板21時,於模板21完成彎曲後,模板21實際上得已與突台172分離,此可使模板21獲得更的彎曲程度,有助於第一光學層45與模板21分離。另外,於本實施例中,上載台17具有容置空間以供折板機構23移動其中,故若模板21於彎曲時無結構干涉疑慮時,例如模板21彎入該容置空間中,突台172之結構亦可省略。又,模板21實際的彎曲輪廓可能因相關部件(例如折板機構23、固定件19、突台172等)之相對位置、結構尺寸、甚至模板21的材料特性而與第13圖所示者有異,此差異自可為熟習技藝者所了解而仍能基於本發明之精神實施本發明,不待贅述。In addition, in the present embodiment, the projections 172 respectively form a lead angle 1722 on the two edges of the two flap mechanism 23, so that the template 21 can be closely attached to the guide angle 1722 when bent, so as to avoid the excessively sharp edge scratching the template 21 Moreover, the curved cross-sectional profile of the template 21 can be made smoother; however, the invention is not limited thereto. In addition, when the template 21 is bent using the ejector pin 30, after the template 21 is completely bent, the template 21 is actually separated from the protrusion 172, which can make the template 21 more curved and contribute to the first optics. Layer 45 is separated from template 21. In addition, in the embodiment, the loading table 17 has an accommodating space for the folding mechanism 23 to move therein. Therefore, if the template 21 has no structural interference when bending, for example, the template 21 is bent into the accommodating space. The structure of 172 can also be omitted. Moreover, the actual curved profile of the template 21 may be due to the relative position of the related components (eg, the folding mechanism 23, the fixing member 19, the boss 172, etc.), the structural size, and even the material properties of the template 21, as shown in FIG. The present invention may be practiced based on the spirit of the present invention, and will not be described again.
綜上所述,本發明建置真空製造的環境,以利用真空特性使光學膠層於固化後形成的光學層的氣泡現象得以抑制,並且採用機具操作以提昇製程精度,排除人工操作的不穩定性,以有效解決先前技術之問題。In summary, the present invention establishes a vacuum manufacturing environment to utilize the vacuum property to suppress the bubble phenomenon of the optical layer formed by the optical adhesive layer after curing, and uses the operation of the implement to improve the process precision and eliminate the instability of manual operation. Sex to effectively solve the problems of prior art.
以上所述僅為本發明之較佳實施例,凡依本發明申請專利範圍所做之均等變化與修飾,皆應屬本發明之涵蓋範圍。The above are only the preferred embodiments of the present invention, and all changes and modifications made to the scope of the present invention should be within the scope of the present invention.
1、3...真空壓印裝置1, 3. . . Vacuum stamping device
4...層狀光學元件4. . . Layered optical component
5...真空壓合裝置5. . . Vacuum press device
12、52...真空室12, 52. . . Vacuum chamber
14、54...下載台14, 54. . . Download station
16、17、56...上載台16, 17, 56. . . Upload station
18、58...固化裝置18, 58. . . Curing device
19...固定件19. . . Fastener
20、21...模板20, 21. . . template
22...夾持件twenty two. . . Clamping piece
23...折板機構twenty three. . . Folding mechanism
24...磁鐵twenty four. . . magnet
26、68...伺服軸26, 68. . . Servo axis
28、70...間隙感測裝置28, 70. . . Gap sensing device
30...頂針30. . . thimble
32...吹氣裝置32. . . Blowing device
42...基板42. . . Substrate
44、46...光學膠層44, 46. . . Optical adhesive layer
45...第一光學層45. . . First optical layer
47...第二光學層47. . . Second optical layer
60...保護膜60. . . Protective film
62...磁鐵62. . . magnet
64...固定板64. . . Fixed plate
66...治具66. . . Fixture
72...加熱裝置72. . . heating equipment
122、522...底板122, 522. . . Bottom plate
124、524...罩體124, 524. . . Cover
162...重心162. . . Center of gravity
182、582...紫外光燈182, 582. . . Ultraviolet light
172...突台172. . . Burst
212...固定孔212. . . Fixed hole
222...滑槽222. . . Chute
262...夾角262. . . Angle
232...致動桿232. . . Actuating lever
234...固持件234. . . Holder
322...噴嘴322. . . nozzle
562...通氣孔562. . . Vent
662...支架662. . . support
664...固定部664. . . Fixed part
666...真空吸盤666. . . Vacuum chuck
1722...導角1722. . . Leading angle
2122...通道部2122. . . Channel department
2124...卡持部2124. . . Holder
S100~S124...實施步驟S100~S124. . . Implementation steps
第1圖為根據本發明之一較佳實施例之真空壓印裝置之示意圖。BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a schematic illustration of a vacuum imprint apparatus in accordance with a preferred embodiment of the present invention.
第2圖為第1圖中真空壓印裝置於另一狀態之示意圖。Fig. 2 is a view showing the vacuum imprint apparatus of Fig. 1 in another state.
第3圖為上載台、伺服軸及間隙感測裝置之相對設置位置之示意圖。Fig. 3 is a schematic view showing the relative arrangement positions of the loading table, the servo shaft, and the gap sensing device.
第4圖為頂針、模板及夾持件之相對設置位置之示意圖。Figure 4 is a schematic view showing the relative positions of the thimble, the stencil and the holding member.
第5圖為光學層自模板脫模之示意圖。Figure 5 is a schematic illustration of the release of the optical layer from the template.
第6圖為根據本發明之另一較佳實施例之真空壓合裝置之示意圖。Figure 6 is a schematic illustration of a vacuum compression apparatus in accordance with another preferred embodiment of the present invention.
第7圖為第6圖中真空壓合裝置於另一狀態之示意圖。Fig. 7 is a view showing the vacuum pressing device in Fig. 6 in another state.
第8圖為治具之示意圖。Figure 8 is a schematic diagram of the fixture.
第9圖為根據本發明之一較佳實施例之層狀光學元件之製造方法之流程圖。Figure 9 is a flow chart showing a method of fabricating a layered optical element in accordance with a preferred embodiment of the present invention.
第10圖為層狀光學元件之示意圖。Figure 10 is a schematic illustration of a layered optical component.
第11圖為根據本發明之另一實施例之真空壓印裝置之示意圖。Figure 11 is a schematic view of a vacuum imprint apparatus according to another embodiment of the present invention.
第12圖為第11圖之真空壓印裝置之模板之固定孔之示意圖。Fig. 12 is a view showing the fixing hole of the template of the vacuum imprinting apparatus of Fig. 11.
第13圖為第11圖之真空壓印裝置之脫模示意圖。Figure 13 is a schematic view showing the demolding of the vacuum imprinting apparatus of Figure 11.
1...真空壓印裝置1. . . Vacuum stamping device
12...真空室12. . . Vacuum chamber
14...下載台14. . . Download station
16...上載台16. . . Upload station
18...固化裝置18. . . Curing device
20...模板20. . . template
22...夾持件twenty two. . . Clamping piece
24...磁鐵twenty four. . . magnet
26...伺服軸26. . . Servo axis
28...間隙感測裝置28. . . Gap sensing device
30...頂針30. . . thimble
32...吹氣裝置32. . . Blowing device
42...基板42. . . Substrate
44...光學膠層44. . . Optical adhesive layer
122...底板122. . . Bottom plate
124...罩體124. . . Cover
182...紫外光燈182. . . Ultraviolet light
222...滑槽222. . . Chute
322...噴嘴322. . . nozzle
Claims (42)
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TW100142452A TWI461283B (en) | 2010-12-29 | 2011-11-18 | Vacuum imprinting apparatus, vacuum press-bonding apparatus, and manufacturing method for laminated optical device |
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TW100142452A TWI461283B (en) | 2010-12-29 | 2011-11-18 | Vacuum imprinting apparatus, vacuum press-bonding apparatus, and manufacturing method for laminated optical device |
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CN102765240A (en) | 2012-11-07 |
CN102765240B (en) | 2015-06-10 |
CN102173238A (en) | 2011-09-07 |
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