五、新型說明: 【新型所屬之技術領域】 一種插裝光纖跳接線的配線盒,特別是指一種裝置於 壁面’讓使用者以光纖跳接線將資訊裝置與預埋於牆面中 的光纖線路相連接的光纖配線盒。 【先前技術】 隨著人們對資料傳遞流量以及速度要求的增加,電信 技術隨之不斷的發展’傳統用於傳遞訊號的各種銅纜線亦 逐漸的被新一代的光纖纜線所取代,相較於傳統的銅纜 線,光纖纜線不但具有線材體積小,資料傳輸不使用電流 故不會受電磁干擾的優點’而且資料傳遞的速度更快,是 一種非常具有潛力的電信線材。 然而光纖線材相較於傳統的銅纜線卻有著安裝技術較 高的問題,傳統的銅纜線在接線時只要纜線中的銅芯沒有 斷線,電信號便可以繼續傳遞下去;而光纖纜線在接線時 卻需要經由精密的熔接工序,確保對接的兩光纖纜線在接 合處確實的融為一體,且光纖線連接至光纖數據機的接面 也必須確保接面達到需求的平整度,因此光纖線無論是因 過長而茜要修短’或是因長度不足而必須接長,都顯非一 般使用者可以自行處理的問題。 此外光纖纜線相較於傳統銅纜線亦有著不能劇烈彎折 的問題,由於光纖纜線是利用光線訊號在光纖中不斷折射 以及全反射,以期光線訊號在不衰減的情形下持續傳遞, 因此若是光纖纜線彎曲角度過大時則光線訊號在光纖中便 3 無法依預期狀況進行折射,而使得光線訊號衰減或遺失。 由於光纖纜線存有接線不易以及佈線不能劇烈彎曲的 問題,所以在電信業界中長期以來只能將光纖網路使用於 電信網路的主骨幹,使得FTTH(光纖到府)以及FTTD(光纖 到桌)的目標遲遲無法完成,其中最大的難處之一便在於使 用者端的線路配線不易,為了讓使用者能夠配合室内場所 的擺設配置而移動光纖配線,目前較為理想的作法是在線 路的最末端使用各個使用者都能輕易接線的光纖跳接線, 然而為了配合一般使用者便於使用光纖跳接線。開發一種 方便使用者也能輕鬆接線’方便佈線,並能避免因光纖纜 線彎折過大而讓訊號衰減的光纖配線盒實乃業界以及消費 者的共同期盼。 【新型内容】 因此,本創作之主要目的,旨在提供一種可配合一般 電信或電力配線管路使用,將光纖線路安裝於牆壁的預埋 通路中,並將光纖線路的終端安裝於牆壁壁面上,以便於 一般使用者進行接線使用的光纖配線盒。 本創作之又一目的在提供一種避免光纖線在接線過程 中因彎折過大而增加錢衰減料光纖配線盒,藉由環狀 的、堯線走向達成在—般插座面板的體積大小内讓光纖線有 足夠空間繞線及接線。 、本創作之又-目的在提供一種具有收線空間,可繞收 過=的it纖線的光纖配線盒,讓多餘的光纖財必時常進 丁’線或接線的動作,而可盤繞收人先難線盒中。 為達上述目的,本創作包含一個内部具有容置空間並 裝設於牆面的盒體;所述盒體設有配合内埋於壁面的繞線 盒的組接件,並由一背板以及一蓋板互相併合而成,上述 背板開有一光纖透孔,於光纖透孔兩側分別設有一個以上 的導線板,並在左、右兩側的導線板之間的容置空間中設 有至少一個光連接器,而上述盒體於左、右兩側導線板的 導出對應方向設有至少一光纖線接孔,供使用戶端的光纖 線能夠穿入光纖配線盒中與上述光連接器組接配線。 於一較佳實施例中,上述背板的背側進一步組接一繞 、-'良·&所述繞線盒的頂面設為一開口結構,並於四周側壁 上預設有穿線口,由所述開口結構使繞線盒的内部空間與 上述各置空間相連通。上述繞線^之中設有—關件將繞 、”良益的内。卩^間分線區與繞線區,並在隔間件上開設 、通孔使主線區與繞線區相連通,由外部引入的光 纖線於上魏巾盤繞並輕長度,進而朗整理光纖 、”Μ·長的作用。且上述繞線盒在開口結構的兩側各設有一 個與上述背板連接的連接件。 而上述隔間件設有一分隔板,並由分隔板各別向上、 2伸形紅找域τ支雜,虹支撐減下支撐板 #使刀&板維持於上述繞線盒的中央,並將繞線盒 空間分為主魏以及繞線區,而上述分隔板之通孔 繞線盒兩端連接件下方_應位置,使關件易於 盒中定位。且上述上讀板_卩進—步設有勾 、疋、纖線簡線板’在繞線_先_長度時可避免 光纖線脫離。 在又一較佳實施例之中,上述背板進一步在導線板所 導接的位置上吸有束線結構;而上述束線結構可設為束線 孔或夾扣件的其中—種。在上述導線板的頂部進一步設有 勾持固定光纖線㈣板1上述彎板進-步設有束線孔。 【實施方式】 炫為便於更進—步對本創作之構造、使収其特徵有 更/米層明確、4貫的認識與瞭解,妥舉出較佳實施例, 配合圖式詳細說明如下: 現請參閱第1圖及第2圖,如圖巾所示,本創作包含 -個内部6X有谷置空間並裝設於牆面的盒體1(),所述盒體 10 a又有配合内埋於壁面的繞線盒20的組接件1〇1,並由一 背板11以及一蓋板12互相併合而成,在上述背板n底緣 處開有一光纖透孔13 ’於光纖透孔13的兩側設有複數個並 列的導線板14’並在左右兩側的導線板14之間設有至少一 個光連接器15。 於第1圖所示之較佳實施例中,上述組接件101設為 背板11上之螺孔’而光纖透孔13設為一長方形開孔,上 述光連接器15設有第一光連接孔151和第二光連接孔 152,並於光纖透孔13的兩侧各別設有複數個弧形的導線 板14,所述導線板14包含設於背板11接近光纖透孔13兩 側的内導引板141 ’設於上述第一光連接孔151兩側的第一 外導引板142 ’以及设於上述弟一光連接孔152兩側的第二 外導引板143。在各個導線板14之間保持特定間距,使光 纖線套接於導線板Η之剛村藉由先齡自身抵抗弯折的 彈性而與導驗14,_峡。❹卜上敬錢在左右 兩側導線板Μ的導㈣應位置處設有至少—先纖線接孔 16 ’使用戶端的光纖線能_人先纖配線盒中而進行配線。 而上述各導線板14的頂部進—步設有彎板144,所述 彎板⑷由導線板14的頂部侧向延伸,將光纖線勾持固定 於導線板14的範圍中,避免光纖線由導線板μ的頂部彈 出。在本圖所示之較佳實施例中,上述内導引板⑷頂部 的彎板144上進-步設有束線結構17,於此一實施例中所 述束線結構設H魏171,便於使时將光纖線固定, 然而在此所述之束線結構17僅為方便舉例說明之用,並非 唯一配置。 再請參閱第2圖及第3圖,如圖中所示,上述背板u 的背側進-步組接-繞線盒2G,所述繞線盒2G的頂面設為 一開口結構2(M ’並於四周側壁上預設有穿線^ 21,由所 述開口結構201使繞線盒2〇的内部空間與上述容置空間相 連通。且上述繞線盒20在開口結構2〇1的兩側各設有一個 與上述背板11連接的連接件202。 在本圖所示之較佳實施例中,在繞線盒20的内部空間 中進一步設有一個隔間件22,上述隔間件22設有-分隔板 26,並由分隔板26各別向上、下兩端延伸形成上支掉板 與下支撐板28,由上支樓板27與下支撐板28的支撐,使 分隔板26維持於上述繞線盒20的中央,並將繞線盒20的 内部空間分為主魏23以及麟區24,社述分隔板26 之通孔25開設於繞線盒.20兩端連接件202下方的對應位 置,使隔間件22易於套入繞線盒20中定位,並使主線區 23與繞線區24相連通。且上述上支撐板27的頂部進一步 設有擋線板271,可避免光纖線在繞線調整長度時由上支樓 板27的頂部脫離。 現請參閱第4A圖及第4B圖,於上述實施例中所述的 導線板14設置方式僅為舉例說明之用,並非唯一配置,在 第4A圖所示之另一較佳實施例中,上述導線板14包含了 設在背板11接近光纖透孔13兩側處的成對内導引板 141a’設於内導引板141a兩側並彎曲指向第一光纖接孔丨51 的第一外導引板142a,以及設於第一外導引板142a外側並 將底部延伸指向背板11底緣的第二外導引板143a。使得光 纖線由光纖透孔13穿出後,繞過内導引板141a的外部以 避免光纖線過度彎折,並在第一外導引板142a或第二外導 引板143a的導引下使光纖線插接至光連接器15之中 在上述之不同實施例中,雖然導線板14的配置樣式略 有不同’卻共同將導線板14選設於光纖透孔13及光連接 器15之間’並在左右兩側的導線板14之間設有光連接器 15,故本創作之特點在於將光纖透孔與光連接器15分 別設於光纖配線盒容置空間中的相對兩側,並在光纖透孔 13與光連接器15的兩側分別設有至少一個導線板】4,使 光纖線由光纖透孔13中穿出之後在導線板14的導引下以 和緩的弧度彎曲反轉,再連接指向設於光纖透孔13相對側 的光連接器】5。 而上述背板11在靠近導線板14所導接的位置處亦可 進一步設置束線結構17,以便於固定光纖線。且在第4A 圖所示之較佳實施例中,上述束線結構17設置為束線孔 171 ’便於使用者使用束線帶(圖未示)將光纖線固定於背板 11上’在第4B圖所示之另一可行實施例中,上述束線結構 17則設為彈性的夾扣件172。 現請參閱第5圖到第8圖,如圖中所示,本創作在裝 配時,先將光纖線牽引至繞線盒2〇的主線區23中,並將 要裝配的光纖線透過通^^ 25牽引至繞線區24中預備,其 餘光纖線則穿出繞線盒20繼續拉往他處,其中,牽引至繞 線區24中的光纖線先在繞線區24中進行盤繞以收納過長 的光纖線,僅將適量長度的光纖線穿過上述光纖透孔13並 牽引到上述盒體10中,因而可有效對光纖線進行整理。 牽引至上述盒體10中的光纖線由光纖透孔穿出 後’先繞至内導引板141的外側以避免光纖線在配線過程 中過度彎折’在内導引板141的限制作用下可限制光纖線 彎折的最小半徑,減_引板⑷相的光纖線再視組 配的需求而選擇適當的外導引板,於本圖所示之實施例中 光纖線經由第二外導引板丨43的引導而連接至第二光連接 孔152中預備’使光纖線平順的繞線並連接到光連接器15。 則當使用者要將資訊裝置(圖未示)與光纖網路相連接 時,僅需將連接用的光纖線與光連接器15插接便可完成連 線’由光連接器15連接而出的光纖線再經過適當導線版14 引導後由光纖線接孔16穿出光纖配線盒夕卜。因而可避免因 光纖線彎折角度過於劇烈而造成訊號衰減,並同時提高光 纖配線的便利性以及可靠性。 綜上所述,本創作光纖配線盒在背板的表面環狀地設 有光纖透孔’導線板以及光連接器’使得光纖線穿設在光 纖配線盒中時以一個和緩的角度繞圈並連接至光連接器, 無論是由牆中配線到光纖配線盒的光纖線,或是由光連接 裔連接延伸至資訊設備的光纖跳接線都可避免因劇烈的彎 折而降低光訊號的衰減率,不但可提高配線的便利性,更 4加了光纖網路的可罪性。並在搭配繞線盒使用時提供一 收納並整理過長光纖線的繞線空間,使整體配線更容易, 無需進行繁雜的光纖剪線以及接線程序。 以上所舉實施例,僅用為方便說明本創作並非加以限 制,在不離本創作精神範疇,熟悉此一行業技藝人士依本 創作申請專利範圍及創作說明所作之各種簡易變形與修 飾,均仍應含括於以下申請專利範圍中。 【圖式簡單說明】 第1圖係本創作中盒體之分解圖; 第2圖係繞線盒與背板組合之示意圖; 第3圖係繞線盒與隔間件組合之示意圖; 第4A圖係第1圖中導線板另一可行實施例之立體圖; 第4B圖係第1圖中導線板另一可行實施例之立體圖; 第5圖係光纖線於繞線盒中組配並收納之示意圖; 第6圖係光纖線於盒體中組配之示意圖; 第7圖係將使用者端的光纖線與光連接器插接並完成 M398286 西己接之示意圖;以及 第8圖係本創作裝設於牆面使用時之示意圖。 【主要元件符號說明】V. New Description: [New Technology Field] A wiring box with a fiber-optic patch cord, especially a device on the wall that allows the user to use the fiber jumper to connect the information device to the fiber line pre-buried in the wall. Connected fiber distribution box. [Prior Art] With the increase in data transmission traffic and speed requirements, telecommunications technology has continued to evolve. 'The traditional copper cables used to transmit signals are gradually being replaced by a new generation of fiber-optic cables. In the traditional copper cable, the fiber optic cable not only has the advantages of small wire volume, no data transmission, and therefore no electromagnetic interference, and the data transmission speed is faster, which is a very potential telecommunication wire. However, the optical fiber cable has a higher installation technology than the conventional copper cable. When the conventional copper cable is wired, as long as the copper core in the cable is not broken, the electrical signal can continue to be transmitted; When the wires are wired, a precise welding process is required to ensure that the two fiber-optic cables that are docked are indeed integrated at the joint, and the connection of the fiber-optic wires to the fiber-optic data machine must also ensure that the joints meet the required flatness. Therefore, the fiber optic cable has to be shortened either because it is too long or has to be lengthened due to insufficient length. This is a problem that ordinary users can handle on their own. In addition, the optical fiber cable has a problem that it cannot be bent sharply compared with the conventional copper cable. Since the optical fiber cable is continuously refracted and totally reflected by the optical signal in the optical fiber, the optical signal is continuously transmitted without being attenuated. If the bending angle of the optical fiber cable is too large, the optical signal in the optical fiber 3 cannot be refracted according to the expected condition, and the optical signal is attenuated or lost. Because fiber-optic cables have difficulties in wiring and the wiring cannot be bent sharply, in the telecom industry, fiber-optic networks can only be used in the backbone of telecommunication networks for a long time, making FTTH (Fiber-to-the-Fly) and FTTD (Fiber-to-Fiber) The goal of the table) is delayed. One of the biggest difficulties is that the wiring of the user terminal is not easy. In order to allow the user to move the fiber optic wiring in accordance with the layout of the indoor place, it is currently the most ideal method in the line. The end uses a fiber patch cord that can be easily wired by each user, but it is convenient for the general user to use the fiber patch cord. It is a common expectation of the industry and consumers to develop a fiber-optic distribution box that is convenient for users to easily wire and facilitate wiring, and to avoid signal attenuation due to excessive bending of the fiber-optic cable. [New content] Therefore, the main purpose of this creation is to provide a pre-buried path for mounting fiber-optic lines to walls in conjunction with general telecommunications or power distribution lines, and to install the ends of the fiber-optic lines on the wall surface. In order to facilitate the general user to use the fiber distribution box for wiring. Another object of the present invention is to provide an optical fiber distribution box that avoids excessive bending of the optical fiber line during the wiring process, and the optical fiber distribution box is formed by the annular and the twisted line to achieve the volume of the socket panel. The line has enough space for winding and wiring. The purpose of this creation is to provide a fiber-optic distribution box with a wire-receiving space that can be wrapped around the = fiber line, so that the excess fiber optic money will often enter the D-line or wiring action, but can be coiled First difficult in the box. In order to achieve the above object, the present invention comprises a box body having an accommodating space therein and mounted on a wall surface; the box body is provided with a connecting member for a winding box embedded in the wall surface, and is provided by a backboard and A cover plate is combined with each other, the back plate is provided with a fiber through hole, and one or more wire plates are respectively disposed on two sides of the fiber through hole, and are disposed in the accommodating space between the left and right side wire plates There is at least one optical connector, and the above-mentioned box body is provided with at least one optical fiber connecting hole in the corresponding direction of the lead plates of the left and right sides, so that the optical fiber line of the user end can penetrate into the optical fiber distribution box and the optical connector Connect the wiring. In a preferred embodiment, the back side of the backboard is further assembled with a winding, and the top surface of the winding box is configured as an opening structure, and a threading opening is pre-arranged on the surrounding side walls. The opening structure allows the internal space of the winding box to communicate with the respective spaces. The above-mentioned winding ^ is provided with a closing member which will be wound around the inner and outer winding sections of the good and the winding area, and is opened on the partition member to connect the main line area with the winding area. The fiber-optic wire introduced from the outside is coiled on the upper Wei towel and has a light length, thereby arranging the fiber, and the role of the fiber. And the winding box is provided on each side of the opening structure with a connecting member connected to the backing plate. The partition member is provided with a partition plate, and the partition plate is respectively upwardly oriented, and the red support is used to reduce the support plate. The support plate is maintained in the center of the winding box. And the winding box space is divided into the main Wei and the winding area, and the above-mentioned partitioning plate of the through-hole winding box at the two ends of the connecting piece _ should be positioned, so that the closing piece is easy to be positioned in the box. Moreover, the above-mentioned upper reading plate _ 卩 — step is provided with a hook, a 疋, a fiber 简 线 板 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 In still another preferred embodiment, the backing plate further absorbs a wire harness structure at a position where the wire guide is guided; and the wire harness structure may be set as one of a wire harness hole or a clip member. Further, the top of the wire plate is further provided with a hooking and fixing optical fiber (4) plate. The bent plate is provided with a wire harness hole. [Embodiment] Hyun is more convenient and more step-by-step to the structure of the creation, so that the characteristics of the collection has a clearer, clearer, four-dimensional understanding and understanding, the preferred embodiment is exemplified, with the following detailed description: Please refer to FIG. 1 and FIG. 2 . As shown in the figure, the present invention includes an inner 6X box body 1( ) having a valley space and being mounted on the wall. The box body 10 a has a fit inside. The assembly member 1〇1 of the winding box 20 buried in the wall is formed by a back plate 11 and a cover plate 12, and a fiber through hole 13' is opened at the bottom edge of the back plate n. A plurality of juxtaposed wire guides 14' are disposed on both sides of the hole 13 and at least one optical connector 15 is disposed between the left and right wire guide plates 14. In the preferred embodiment shown in FIG. 1, the assembly member 101 is configured as a screw hole ' on the back plate 11 and the fiber through hole 13 is formed as a rectangular opening. The optical connector 15 is provided with a first light. The connecting hole 151 and the second optical connecting hole 152 are respectively provided with a plurality of curved lead plates 14 on both sides of the optical fiber through hole 13. The conductive plate 14 is disposed on the back plate 11 and adjacent to the optical fiber through hole 13 The side inner guiding plate 141' is disposed on the first outer guiding plate 142' on both sides of the first optical connecting hole 151, and the second outer guiding plate 143 disposed on both sides of the first optical connecting hole 152. A specific spacing is maintained between the individual conductor plates 14, so that the fiber optic cable is sleeved to the wire plate, and the village is restrained by the flexibility of the aging aging itself and the guide 14, gorge. On the left and right sides of the lead plate Μ guide (4) at the position should be at least - the first fiber line hole 16 ′ so that the user's fiber line can be wired in the fiber box. The top of each of the lead plates 14 is further provided with a bent plate 144. The bent plate (4) extends laterally from the top of the lead plate 14 to fix the optical fiber line in the range of the conductive plate 14 to avoid the optical fiber line. The top of the wire board μ pops up. In the preferred embodiment shown in the figure, the curved plate 144 on the top of the inner guiding plate (4) is further provided with a wire harness structure 17, and in the embodiment, the wire harness structure is set to H 171. It is convenient to fix the fiber optic line in time, however, the wire harness structure 17 described herein is for convenience of illustration only and is not the only configuration. Referring to FIG. 2 and FIG. 3 again, as shown in the figure, the back side of the back plate u is step-by-step-winding box 2G, and the top surface of the winding box 2G is set as an opening structure 2 (M' is pre-configured with a threading 21 on the side wall, and the opening structure 201 connects the inner space of the winding box 2〇 with the accommodating space. The winding box 20 is in the opening structure 2〇1 Each of the two sides is provided with a connecting member 202 connected to the backing plate 11. In the preferred embodiment shown in the figure, a compartment member 22 is further disposed in the inner space of the winding box 20, and the partition is provided. The partition member 22 is provided with a partitioning plate 26, and is extended from the upper and lower ends of the partitioning plate 26 to form an upper supporting plate and a lower supporting plate 28, which are supported by the upper supporting floor plate 27 and the lower supporting plate 28, so that The partition plate 26 is maintained at the center of the winding box 20, and the inner space of the winding box 20 is divided into a main Wei 23 and a lining 24, and the through hole 25 of the separating plate 26 is opened in the winding box. The corresponding position below the connecting members 202 at both ends makes it easy for the partition member 22 to be nested in the winding box 20 and to communicate the main line region 23 with the winding portion 24. The upper support plate 27 is also provided. The top of the top is further provided with a retaining plate 271 to prevent the optical fiber from being detached from the top of the upper supporting floor 27 when the winding is adjusted in length. Referring now to Figures 4A and 4B, the wiring board described in the above embodiment The arrangement of the 14 is for illustrative purposes only, and is not the only configuration. In another preferred embodiment shown in FIG. 4A, the wire guide 14 includes a portion disposed on the opposite side of the back plate 11 near the fiber through hole 13. The inner guiding plates 141a' are disposed on both sides of the inner guiding plate 141a and bent toward the first outer guiding plate 142a of the first fiber receiving hole 51, and are disposed outside the first outer guiding plate 142a and extend the bottom a second outer guiding plate 143a directed to the bottom edge of the backing plate 11. After the optical fiber is passed through the optical fiber through hole 13, the outer portion of the inner guiding plate 141a is bypassed to avoid excessive bending of the optical fiber, and is in the first outer guide. The guiding of the lead plate 142a or the second outer guiding plate 143a causes the optical fiber cable to be inserted into the optical connector 15. In the different embodiments described above, although the arrangement pattern of the wiring plates 14 is slightly different, the wires are collectively The board 14 is selected between the fiber through hole 13 and the optical connector 15 and is guided on the left and right sides. The optical connector 15 is disposed between the wire boards 14. Therefore, the present invention is characterized in that the fiber through holes and the optical connectors 15 are respectively disposed on opposite sides of the optical fiber distribution box accommodating space, and the optical fiber through holes 13 and the light are provided. The two sides of the connector 15 are respectively provided with at least one lead plate 4, so that the optical fiber line is pierced from the optical fiber through hole 13 and then bent under the guidance of the conductive plate 14 in a gentle arc, and then connected to the optical fiber. The optical connector on the opposite side of the through hole 13 is 5. The above-mentioned back plate 11 can further be provided with a wire harness structure 17 at a position close to the lead plate 14 to facilitate fixing the optical fiber line, and is shown in FIG. 4A. In the preferred embodiment, the wire harness structure 17 is provided as a wire harness hole 171' for the user to fix the fiber optic cable to the back plate 11 using a cable tie (not shown) 'the other one shown in FIG. 4B In a possible embodiment, the wire harness structure 17 is configured as an elastic clip member 172. Referring now to Figures 5 to 8, as shown in the figure, in the assembly, the optical fiber cable is first drawn into the main line area 23 of the winding box 2, and the optical fiber line to be assembled is transmitted through the ^^ 25 is pulled into the winding area 24 for preparation, and the remaining optical fiber lines are pulled out of the winding box 20 to continue to be pulled there, wherein the optical fiber line drawn into the winding area 24 is first wound in the winding area 24 to be accommodated. In the long optical fiber line, only an appropriate length of the optical fiber line is passed through the above-mentioned optical fiber through hole 13 and pulled into the above-mentioned casing 10, so that the optical fiber line can be effectively arranged. After the optical fiber line drawn into the above-mentioned casing 10 is pierced by the optical fiber through hole, it is first wound around the outer side of the inner guiding plate 141 to prevent the optical fiber wire from being excessively bent during the wiring process, and the inner guiding plate 141 is restricted. The minimum radius of the bending of the optical fiber line can be limited, and the appropriate outer guiding plate can be selected according to the requirement of the optical fiber line of the (4) phase. In the embodiment shown in the figure, the optical fiber is guided by the second external guide. The lead of the tabs 43 is connected to the second optical connecting hole 152 to prepare a winding for smoothing the optical fiber and connecting to the optical connector 15. When the user wants to connect the information device (not shown) to the optical network, only the optical fiber cable for connection and the optical connector 15 need to be plugged in to complete the connection 'connected by the optical connector 15 The fiber optic cable is then guided through the appropriate wire plate 14 and then passed through the fiber optic cable hole 16 through the fiber optic cable distribution box. Therefore, it is possible to avoid signal attenuation due to the excessive bending angle of the optical fiber, and at the same time improve the convenience and reliability of the optical wiring. In summary, the optical fiber distribution box of the present invention is provided with a fiber through-hole 'wire plate and optical connector' on the surface of the back plate so that the optical fiber wire is wound at a gentle angle when it is inserted in the fiber distribution box. Connected to the optical connector, whether it is wired from the wall to the fiber optic cable of the fiber distribution box, or the fiber optic patch cord extending from the optical connection to the information device can avoid the attenuation of the optical signal due to severe bending Not only can it improve the convenience of wiring, but also increase the guilt of the fiber network. It also provides a winding space for accommodating and tidying long fiber optic cables when used with a wind box, making overall wiring easier, eliminating the need for complicated fiber trimming and wiring procedures. The above embodiments are used for convenience only to illustrate that the present invention is not limited. In the spirit of the creative spirit, all kinds of simple deformations and modifications made by those skilled in the industry in accordance with the scope of the patent application and the creative description of the creation should still be It is included in the scope of the following patent application. [Simple diagram of the drawing] Fig. 1 is an exploded view of the box in the present creation; Fig. 2 is a schematic diagram of the combination of the winding box and the backboard; Fig. 3 is a schematic diagram of the combination of the winding box and the compartment; 4A Figure 1 is a perspective view of another possible embodiment of the lead plate in Figure 1; Figure 4B is a perspective view of another possible embodiment of the lead plate in Figure 1; Figure 5 is an optical fiber line assembled and received in a winding box. Figure 6 is a schematic diagram of the assembly of the optical fiber in the box; Figure 7 is a schematic diagram of inserting the optical fiber cable of the user end with the optical connector and completing the connection of the M398286; and Figure 8 is the original installation. A schematic diagram when used on a wall surface. [Main component symbol description]
10…盒體 16…光纖線接孔 101—組接件 17—束線結構 11…背板 171…束線孔 12…盖板 172—夾扣件 13—光纖透孔 20—繞線盒 14--導線板 201…開口結構 141…内導引板 202—連接件 141a—内導引板 21—穿線孔 142—第一外導引板 22—隔間件 142a-第一外導引板 23—主線區 143---第二外導引板 24—繞線區 143a---第二外導引板 25—通孔 144青板 26—分隔板 15…光連接器 27—上支樓板 151…第一光連接孔 271…擋線板 152…第二光連接孔 28—下支樓板10...box 16...fiber line jack 101—assembly 17—bundle structure 11...backplane 171...bundle hole 12...cover 172—clip 13—fiber through hole 20—winding box 14- - Conductor plate 201 ... opening structure 141 ... inner guiding plate 202 - connecting member 141a - inner guiding plate 21 - threading hole 142 - first outer guiding plate 22 - compartment member 142a - first outer guiding plate 23 - Main line area 143---second outer guiding plate 24-winding area 143a---second outer guiding plate 25-through hole 144 green plate 26-partition plate 15...optical connector 27-upper floor 151 ...first optical connection hole 271...bar 152...second optical connection hole 28-lower slab