1271368 九、發明說明: 【發明所屬之技術領域】 本發明係關於一種玻璃基板之藏運盒,特別是關於一 種具有滑動承板的玻璃基板藏運盒。 【先前技術】 液晶面板的製造過程包括將薄膜電晶體製作於一大片 玻璃基板上,再將該玻璃基板與一濾光基板貼合作如也明) 後進行裁切(cutting)成複數個液晶面板。通常裁切程序與兩 基板貼合前的程序係獨立運作,貼合後尚未裁切的大片面 板必須利用藏運盒(cassette)進行暫存,直到藏運盒滿截時 才運送至裁切廠。隨著玻璃基板的尺寸越來越大,並且大 $面板必須於藏運盒暫存一段時間等待其滿載,藏運盒的 設計也越來越要求暫存期間的支撐效果及運送時取放動作 的便利性。 人明參照圖1A ’係為習知技術一之藏運盒示意圖。藏運 盒1係為-矩形之中空容器1G,其前方設有—輸出入口 η ’ ^内部之二侧表面係分別設有複數個支撐桿12,上、 下支撐杯12之間係形成複數個插槽〗3,玻璃基板4則是 置於插槽13 +並承載於支撐桿I〗之上,—取放機具5可 以由藏運盒1前方之輸出入口 u,進入插槽13之中並對 玻璃基板4進行取放之動作。 隨著面板的面積加大且厚度也越來越薄,當大尺寸之 玻璃基板4送人藏運盒卩之插槽13時,若是健利用其二 側之支撐桿12加以支撐,玻璃基板4中間無支撐之部位勢 1271368 必會因重力而下垂變形(bending),如圖1B所示。一旦玻 璃基板4的下垂變形幅度過大,取放機具5在進入插槽13 取放的過程中,便可能和玻璃基板4發生碰撞而破裂。雖 然可以加大插槽13間距的方式避面增加碰撞的機會,然 而,加大插槽13的間距會減少藏運盒1的承載量。更重要 的是,下垂變形量過大也會使玻璃基板4表面產生應力, 進而使製作在玻璃基板4表面上的元件發生毀損。 當習知技術一的藏運盒1滿載玻璃基板4時,上下玻 璃基板之間並無隔板。若有一片玻璃基板發生破裂,會使 得該玻璃基板下方的玻璃基板刮傷,甚至造成複數片玻璃 基板連續破裂,並污染藏運盒的其它部位。對於破裂的玻 璃基板,亦無法利用取放機具即時取出。 請參照圖2A,係為習知技術二之藏運盒示意圖。藏運 盒2之二侧表面係分別設有複數條支撐線21,上、下支撐 線21之間係形成複數個插槽22,玻璃基板4則是置於插 槽22之中,並承載於支撐線21之上。然而,這種型式之 藏運益2仍然無法避免玻璃基板4發生變形,且由於玻璃 基板4與支撐線21係為緊貼,取放機具無法由玻璃基板4 與支撐線21之間插入,將玻璃基板4取出或放入。 因此,習知技術二在取出玻璃基板4時,必須利用一 輸送滾輪6插入藏運盒2之底層,將玻璃基板4頂起之後, 再利用滾輪6的滾動將玻璃基板4由下而上一片一片地帶 出,如圖2B所示。反之,在送入時則必須將玻璃基板4 由上而下一片一片地帶入,無法對藏運盒2中間之任何一 片玻璃基板4進行隨機取放。 6 1271368 ,之明可知,大尺寸破璃基板若置放於目前所設 損或破片之外,若有则產 的疋件毀 祜癌从- 汉力座玍刀無沄酼機取出。此外,當 土板的—端域於紐鱗,麵 f;若f盒在輸送的過程中所產生之振^ ί造侧率接近時,玻璃基板將發生共振,甚至 何針對習知技術之缺點加以改進,以期能夠獲 :又、取放方便之藏運盒,實為現階段相關研發人 貝所亟欲解決之任務。 【發明内容】 本發%的目的在於提供_種玻璃基板之藏運盒,可避 免玻,基板魏太久秘生騎,以聽造絲面上的元 件毁損或破m若有破#亦可賴取丨。 本發明之玻璃基板之藏運盒,包括一盒體、一平板設 於盒體内部,以及一承板置於平板之上。該盒體側壁具有 一開口以供一玻璃基板置入。該平板係固接於該盒體之侧 壁内側,並平行於該盒體之底面。該承板具有一浪板結構, 並置放於該平板之上,其中該浪板結構包括至少一凹溝, 該凹溝之一端口部朝向該盒體之開口以提供一取放機具上 载及下載該玻璃基板。 較佳的實施方式為,在盒體兩側壁開設一第一開口及 一第二開口,如此承板可由該第一開口抽離該盒體之外, 並由該第二開口上載及下載該玻璃基板。 因此’平板的設置可以提高承板的承載力,在承載大 尺寸玻璃基板時較不易發生變形,不僅可以避免玻璃基板 表面產生應力,也可避免玻璃基板表面元件發生毀損。本 發明之承板可以活動,當有玻璃基板破裂時,抽出破片之 動作與置入玻璃基板的動作可同時進行。 【實施方式】 茲配合圖示詳述本發明「玻璃基板之藏運盒」,並列舉 較佳實施例說明如下: 請參照圖3A,係為本發明之藏運盒。藏運盒5〇的基 本組件包括一盒體51具有兩開口分別開設於兩侧壁、至少 一平板32設於盒體51内部,以及至少一承板33置於平板 32之上。盒體51為一立方體中空容器,其具有一輸出入 口 511及一抽出口 512,分別開設於相鄰兩側壁51〇&及 510b上。輸出入口 511位於盒體51正面以供玻璃基板4 之取放。抽出口 512則提供承板33由盒體51侧面抽出。 複數個平板32邊緣固接於盒體51之側壁内側而平行 於益體51之底面,並且彼此保持一設定距離。在圖3A中, 平板32有一邊緣裸露於輸出入口 5n,另一邊邊裸露於抽 出口 512 ’其餘二邊與盒體51之側壁接合,將輸出入口 511如成複數個插槽(未標號)。一個彎折成浪板結構gw的 承板33被插入插槽中而置放於平板32之上,但不加以固 定以保持可滑動狀態,每一個承板33可承載一片玻璃基板 4。如此一來,破璃基板4可以隨著承板33被抽出盒體51 之外。 上述浪板結構331具有至少一凹溝332,凹溝332之 兩端口部3321其中之-朝向盒體51之輸出入口 511以提 1271368 供-取放機具5(如圖ία所示)上載及下載一玻璃基板4, 另一端口部(未圖示)則朝向盒體51背面。滑動的承板33 設計可以將破__基板4個職ώ,而平板32阻隔於 兩玻璃基板4之間,可避免上方玻璃基板4破裂後,向下 陷落而引起連續破片的問題。 較佳的承板33縣-具有錢波型H之浪板,其中每 個方塊波之齡同高,使朗基板4得以水平地放置於承 板33之上。浪板結構別之凹溝332的數量和尺寸以能夠 讓取放機具5插入其中為最佳,使得取放機具5能夠由 輸出入口 511進入凹溝332之中,並對放置在承板33上 之玻璃基板4進行取放。 圖3Β儀為藏運盒50之正視圖。承板33左右兩端向 一延伸壁333,延伸壁333高度約與平板32間隔 目專。® 3C為藏運盒5〇之側視圖,朝向抽出口 512 的=伸壁333外表面可設置握把41。此外,止擋塊42亦 =置於平板32裸露於抽出口 512之邊緣上以止撞延伸壁 33=止魏42旋轉至―第—位置㈣,即突出於平板 、面而將承板33止擋於盒體51中 1動時,可防止承板33任意滑動。當止^^ 婦平板32偏允許 I一端^^圖3C,止擒塊42係為一長方體,該長方體以 置=央部位與平板32邊_妾。每一平板%可設 平塊42。當讀塊42財央雜樞接於 ^將其旋轉至與平板32板面垂直,即突出於平 9 板32的上下表面而可明時上核下方承板33之延 伸壁333。當止擔塊42以其—端樞接於平板%時,將另 -端向上扳動可使之突出於平板32上表面而齡上方承 板33。相對地,若將另-端向下扳動則使之突出於平板% 下表面而擔住下方承板33。 請參照® 4,係為本發明之第二錄實關。藏運盒 60與圖3A之差異為’藏運盒60之輸出入口 6i與抽出口 62係開設於相對兩侧壁。輸出入〇 6U立於藏運盒6〇正 面,其構造與圖3A所示相同。抽出口 62 各 之背面,其構造與圖3A之抽出口 512大致相同 之左右延伸壁333.與藏運盒60的側壁之間可以藉由一滑執 334以引導承板33向抽出口 62運動。 在以上實施例中,複數個平板32最好間隔相等間距, 而承板33所使用之材質可以是各種薄板結構材料,如鋁 板、鋼板、鈦板、強化玻璃纖維或是強化碳纖維。此外, 平板32可與盒體51—體成型。 綜上所述,本發明之藏運盒與習知技術相^t,具有下 列之優點 \ ^ ^ ^ ^ ^ ^ Λ 1·平板的設置可以提高承板的承載力,在承載大尺 寸玻璃基板時較不易發生變形,不僅可以避免破璃基板表 面產生應力,也可避免玻璃基板表面元件發生毁損。 2·本發明之承板可以活動,以便手動將破片單獨取 出,而不影響玻璃基板取放動作之進行。 1271368 響其3它ίί反是層層獨立的’所以任一層發生問題’不會影 4.盒體與平板係一體成型,所以不用拆裝螺絲。 、上列詳細說明並非用以限制本發明之專利範圍,凡未 脫離本發明技藝精摘為之·實施或變更,均應包含於 本案之專利範圍中。、 【圖式簡單說明】 圖1Α係為習知技術一之藏運盒示意圖; 圖1Β係為習知技術一之藏運盒正視圖; 圖2Α係為習知技術二之藏運盒正視圖; _ ® 2Β係為習知技術二利用輸送滾輪將玻璃基板帶出 之示意圖; 圖3Α係為本發明藏運盒之基^^結構; 圖3Β係為圖3Α正視圖; 圖3C係為圖3Β侧視圖;以及 圖4係為本發明之第二較佳實施例。 【主要元件符號說明】 4 玻璃基板 41 握把 42 止擋塊 5 取放機具 1 藏運盒 10 矩形中空容器 11 輸出入口 12 支樓桿 12713681271368 IX. Description of the Invention: [Technical Field] The present invention relates to a storage case for a glass substrate, and more particularly to a glass substrate storage case having a sliding carrier. [Prior Art] The manufacturing process of the liquid crystal panel includes forming a thin film transistor on a large glass substrate, and then bonding the glass substrate to a filter substrate, and then cutting into a plurality of liquid crystal panels. . Usually, the cutting process is independent of the program before the two substrates are attached. The large panels that have not been cut after the bonding must be temporarily stored by the cassettes until they are delivered to the cutting factory. . As the size of the glass substrate becomes larger and larger, and the large $ panel must be temporarily stored in the storage box for a period of time to wait for its full load, the design of the storage box is increasingly required for the support effect during the temporary storage period and the pick-and-place action during transportation. Convenience. Referring to FIG. 1A', a schematic diagram of a storage box of the prior art is shown. The storage box 1 is a rectangular container 1G, and the front side is provided with an output port η'. The inner side surfaces are respectively provided with a plurality of support rods 12, and a plurality of upper and lower support cups 12 are formed. Slot 3, the glass substrate 4 is placed in the slot 13 + and carried on the support rod I, the pick-and-place implement 5 can be inserted into the slot 13 from the output inlet u in front of the storage box 1 and The operation of picking and placing the glass substrate 4 is performed. As the area of the panel is increased and the thickness is also thinner and thinner, when the large-sized glass substrate 4 is sent to the slot 13 of the storage box, if it is supported by the support rods 12 on both sides, the glass substrate 4 is supported. The unsupported part of the middle potential 1271368 will be drooped due to gravity, as shown in Figure 1B. Once the sagging deformation amplitude of the glass substrate 4 is excessively large, the pick-and-place implement 5 may collide with the glass substrate 4 to be broken during the process of picking up and dropping into the slot 13. Although it is possible to increase the spacing of the slots 13 to avoid the chance of collision, increasing the spacing of the slots 13 reduces the carrying capacity of the storage box 1. More importantly, if the amount of sagging deformation is too large, stress is generated on the surface of the glass substrate 4, and the elements fabricated on the surface of the glass substrate 4 are damaged. When the storage case 1 of the prior art 1 is loaded with the glass substrate 4, there is no partition between the upper and lower glass substrates. If a piece of glass substrate is broken, the glass substrate under the glass substrate may be scratched, or even a plurality of glass substrates may be continuously broken, and other parts of the storage box may be contaminated. For a broken glass substrate, it is also impossible to take it out immediately by using the pick-and-place tool. Please refer to FIG. 2A , which is a schematic diagram of a storage box of the prior art. The two side surfaces of the storage box 2 are respectively provided with a plurality of support lines 21, and a plurality of slots 22 are formed between the upper and lower support lines 21, and the glass substrate 4 is placed in the slot 22 and carried on Above the support line 21. However, this type of storage operation 2 still cannot prevent the glass substrate 4 from being deformed, and since the glass substrate 4 and the support line 21 are closely attached, the pick-and-place tool cannot be inserted between the glass substrate 4 and the support line 21, and The glass substrate 4 is taken out or placed. Therefore, in the prior art, when the glass substrate 4 is taken out, it is necessary to insert the bottom surface of the storage case 2 with a transport roller 6, and after the glass substrate 4 is lifted up, the glass substrate 4 is rolled from the bottom up by the rolling of the roller 6. One piece is taken out, as shown in Figure 2B. On the other hand, when feeding, it is necessary to bring the glass substrate 4 one by one from the top to the bottom, and it is impossible to randomly pick and place any one of the glass substrates 4 in the middle of the storage box 2. 6 1271368, it can be seen that if the large-size glass substrate is placed outside the current damage or fragmentation, if any, the defective material will be removed from the Hanli seat file. In addition, when the end of the soil plate is in the neon scale, the surface f; if the vibration of the f-box during the transport process is close to the side, the glass substrate will resonate, even for the shortcomings of the prior art. It has been improved, in order to be able to obtain: the convenient and convenient storage box, which is the task that the relevant research and development people at the current stage want to solve. SUMMARY OF THE INVENTION The purpose of the present invention is to provide a storage box for a glass substrate, which can avoid glass, the substrate Wei too long secret ride, to hear the components on the silk surface damaged or broken m if it is broken # can also take Hey. The storage box of the glass substrate of the present invention comprises a box body, a flat plate disposed inside the box body, and a carrier plate placed on the flat plate. The side wall of the casing has an opening for a glass substrate to be placed. The plate is fixed to the inner side of the side wall of the casing and parallel to the bottom surface of the casing. The carrier has a wave board structure and is placed on the flat plate, wherein the wave board structure comprises at least one groove, and one port portion of the groove faces the opening of the box body to provide a pick-and-place tool for uploading and downloading the glass Substrate. In a preferred embodiment, a first opening and a second opening are defined in the two side walls of the box, such that the receiving plate can be pulled out of the box by the first opening, and the glass is uploaded and downloaded from the second opening. Substrate. Therefore, the setting of the flat plate can improve the bearing capacity of the carrier, and it is less likely to be deformed when carrying a large-sized glass substrate, thereby not only preventing stress on the surface of the glass substrate, but also avoiding damage of the surface elements of the glass substrate. The carrier of the present invention can be moved. When a glass substrate is broken, the action of extracting the fragment and the action of placing the glass substrate can be simultaneously performed. [Embodiment] The "glass substrate storage cassette" of the present invention will be described in detail with reference to the drawings, and the preferred embodiment will be described as follows. Please refer to Fig. 3A, which is a storage box of the present invention. The basic assembly of the cassette 5 includes a case 51 having two openings respectively formed on the side walls, at least one plate 32 being disposed inside the case 51, and at least one of the plates 33 being placed on the plate 32. The casing 51 is a cubic hollow container having an output inlet 511 and an extraction opening 512 which are respectively opened on the adjacent side walls 51〇& and 510b. The output inlet 511 is located on the front side of the casing 51 for accessing the glass substrate 4. The suction port 512 provides the carrier 33 to be withdrawn from the side of the casing 51. The edges of the plurality of flat plates 32 are fixed to the inner side of the side wall of the casing 51 and parallel to the bottom surface of the profit body 51, and are maintained at a set distance from each other. In Fig. 3A, the flat plate 32 has an edge exposed to the output inlet 5n, and the other side is exposed to the other side of the extraction port 512' to engage the side wall of the casing 51, and the output inlet 511 is formed into a plurality of slots (not numbered). A carrier plate 33 bent into a wave-plate structure gw is inserted into the slot and placed on the flat plate 32, but is not fixed to maintain a slidable state, and each of the carrier plates 33 can carry a glass substrate 4. As a result, the glass substrate 4 can be withdrawn from the casing 51 along with the carrier 33. The wave structure 331 has at least one groove 332. The two port portions 3321 of the groove 332 are oriented toward the output port 511 of the casing 51 for uploading and downloading 1271368 for the pick-and-place tool 5 (shown in FIG. The other glass port 4 (not shown) faces the back surface of the casing 51. The sliding carrier 33 is designed to break the __ substrate 4 positions, and the flat plate 32 is blocked between the two glass substrates 4, so as to avoid the problem that the upper glass substrate 4 is collapsed and collapsed to cause continuous rupture. The preferred deck 33--with the wave-type H-wave board, wherein each square wave is of the same height, allows the Lang substrate 4 to be placed horizontally on the deck 33. The number and size of the grooves 332 of the wave structure are optimized to allow the pick-and-place implement 5 to be inserted therein, so that the pick-and-place implement 5 can be inserted into the groove 332 from the output inlet 511 and placed on the carrier 33. The glass substrate 4 is picked up and placed. Fig. 3 is a front view of the storage box 50. The left and right ends of the carrier plate 33 are directed toward an extending wall 333, and the height of the extending wall 333 is approximately spaced from the flat plate 32. ® 3C is a side view of the storage box 5 ,, and the grip 41 can be disposed on the outer surface of the extension wall 333 toward the discharge port 512. In addition, the stopper 42 is also placed on the edge of the flat plate 32 exposed on the outlet 512 to stop the extension wall 33=the stop 42 is rotated to the first position (four), that is, protruding from the flat plate, the surface and the support plate 33 When the one of the casings 51 is moved, the deck 33 can be prevented from sliding freely. When the female tablet 32 is biased to allow the I end to be in the form of a rectangular parallelepiped, the crotch block 42 is a rectangular parallelepiped, and the cuboid is placed at the central portion and the flat plate 32 side _ 妾. Each plate % can be provided with a flat block 42. When the reading block 42 is pivoted, it is rotated to be perpendicular to the plane of the flat plate 32, i.e., protrudes from the upper and lower surfaces of the flat plate 32, and the extended wall 333 of the lower plate 33 of the lower core can be clarified. When the stop block 42 is pivotally connected to the flat plate at its end, the other end is pulled upward to protrude from the upper surface of the flat plate 32 to the upper deck 33. In contrast, if the other end is pulled downward, it protrudes from the lower surface of the flat plate to bear the lower deck 33. Please refer to ® 4, which is the second record of the invention. The difference between the storage box 60 and Fig. 3A is that the output inlet 6i and the outlet 62 of the storage box 60 are opened on opposite side walls. The output 〇 6U stands on the front side of the storage box, and its construction is the same as that shown in Fig. 3A. The back side of each of the extraction ports 62 is configured to be substantially the same as the suction opening 512 of FIG. 3A. The left and right extension walls 333. Between the side walls of the storage box 60 and the side wall of the storage box 60 can be used to guide the carrier plate 33 to the extraction port 62. . In the above embodiment, the plurality of flat plates 32 are preferably equally spaced, and the material used for the support plate 33 may be various thin plate structural materials such as aluminum plates, steel plates, titanium plates, tempered glass fibers or reinforced carbon fibers. Further, the flat plate 32 can be integrally formed with the casing 51. In summary, the storage box of the present invention has the following advantages with the prior art. ^ ^ ^ ^ ^ ^ ^ Λ 1 · The setting of the plate can improve the bearing capacity of the carrier, and carry the large-sized glass substrate. It is less prone to deformation, which not only avoids stress on the surface of the glass substrate, but also avoids damage to the surface components of the glass substrate. 2. The carrier of the present invention can be moved to manually take the fragments separately without affecting the pick-and-place operation of the glass substrate. 1271368 It's 3, it's ίί, it's layer-independent, so there's no problem with any layer. 4. The box and the flat are integrally formed, so there is no need to disassemble the screws. The above detailed description is not intended to limit the scope of the invention, and the invention may be included in the scope of the invention. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view of a conventional transport box of the prior art; FIG. 1 is a front view of a conventional transport box of the prior art; FIG. 2 is a front view of a conventional transport box of the prior art _ ® 2Β is a schematic diagram of the prior art using the transport roller to take out the glass substrate; Fig. 3 is the base structure of the storage box of the present invention; Fig. 3 is a front view of Fig. 3; Fig. 3C is a diagram 3Β side view; and FIG. 4 is a second preferred embodiment of the present invention. [Main component symbol description] 4 Glass substrate 41 Grip 42 Stopper 5 Pick-and-place tool 1 Storage box 10 Rectangular hollow container 11 Output inlet 12 Branch rod 1271368
13 插槽 50 2 藏運盒 51 21 支撐線 510a 22 插槽 510b 32 平板 511 33 承板 512 331 浪板結構 6 332 凹溝 60 3321 端口部 61 333 延伸壁 62 334 滑執 藏運盒 盒體 側壁 側壁 輸出入口 抽出口 輪送滾輪 藏運盒 輸出入口 抽出口 1213 Slot 50 2 Storage box 51 21 Support line 510a 22 Slot 510b 32 Plate 511 33 Carrier plate 512 331 Wave structure 6 332 Groove 60 3321 Port portion 61 333 Extension wall 62 334 Sliding storage box box side wall side wall Output inlet, outlet, wheel, roller, storage box, output, outlet, outlet 12