五、新型說明: 【新型所屬之技術領域】 本創作係有關於一種訊號傳輸線,尤指一種透過開放部之 界定降低殘技效應(Stub effect)並可於數位訊號傳送時具 有較佳的阻抗匹配與降低串音干擾現象之刺破型訊號傳輸線。 【先前技術】 按,現行電子設備依照不同硬體之傳輸介面具有不同之傳 輸排線及轉接頭,例如USB2. 0介面及USB3. 0介面及SATA介 面及HDMI介面為現行較為常見之傳輸介面,且該些傳輸介面 同時延伸有以刺破方式電氣連接傳輸排線與連接器之技術產 生; 請參閲第1A圖及第1B圖,如圖所示於習知技術中其排線 1於没计上需先個別在訊號傳輸線材I〗上縱向包覆一内絕緣 詹12以避免訊號傳輸線材u相互導通觸接,而後再於内絕緣 層12上佈置一外絕緣層13包覆,並將其排線1與複數導電端 子20相互組設,該等導電端子2〇 一端形成有一對接部21, 而另端形成有複數刺破部22,而於排線1與所述導電端子20 組設時’該等刺破部22則穿過所述外絕緣層13及内絕緣層 12並電氣連接所述訊號傳輸線材^,以完成電性導通之目 的’其中所述刺破部端緣定位於外絕緣層13外側形成有一殘. 枝部221 ’而所述排線1傳送數位訊號時,由於數位訊號包含 有直流至高頻的弦波訊號成分,並為一寬頻訊號,且其數位訊 100211156 1003436498-0 3 M424576 號的頻寬是與錄健朗料關⑻⑨time)成反比。 其中低速減餅時驗長,具有較低蚊,破位訊號會直 接經由刺破部22直接流向對接部21,可避免受殘枝部221的 影響而完成訊號傳輸的目的,而隨著數位訊號傳輸速率越來越 快’攸升時間越來越短,數⑽號所包含的頻寬越來越大但 由於殘枝4 221所產生之寄生電容與電感效應將會影響數位 訊號之高頻成分,進而造成訊號傳輸線材n與導電端子2〇之 刺破部22具雜大的阻抗變異,料彡㈣位減傳遞時的完 整性與產生較大的串音干擾現象。 故,創作人有鑑於上述缺失,乃搜集相關資料,經由多方 評估及考量’並以從事於此行業累積之多年經驗,經由不斷試 作及修改’始料^此種刺破魏賴輸線之新型專利者。 【新型内容】 友此’為解虹述習知技術之缺點,本創狀主要目的係 提供-種_職較狀機導叙殘肢應,可於數位訊 號傳送時降低阻抗變異維持訊號傳遞時的完整性,並降低率音 干擾現象之刺破型訊號傳輪線。 為達上述之目的’本創作係提供一種刺破型訊號傳輸線, 係包含·-排線及複數導電端子,該排線内設有複數導線各 導線刀別界疋有一包覆部及一開放部’其各包覆部位置外緣處 披覆有帛-披覆層’並於該等第一披覆層外緣共同披覆有一 第二披覆層’且該開放部界定之長度介於G.Glmm〜4刪之間, 4 100211156 1003436498-0 M424576 而該等導電端子一端形成有一對接部,而另端則形成有對接所 述導線之複數穿封部;因此藉由所述開放部之界定可降低其殘 枝效應(Stub effect)並於數位訊號傳送時可達到阻抗匹配 與降低串音干擾現象之功效;故本創作具有下列優點: 1·降低數位訊號受串音干擾之現象產生; 2.提南數位訊號傳輸之完整性。 【實施方式】 為達成上述目的及功效,本創作所採用之技術手段及構 造’茲綠圖就本創作較佳實施例詳加說明其特徵與功能如下, 俾利完全了解。 請參閱第2圖、第3圖及第4圖所示,係為本創作第一較 佳實施例之立體分解圖、立體組合圖及排線剖視圖,本創作之 刺破型訊號傳輪線3係包含有一排線40,該排線4Ό内設置有 複數導線41 ’其各導線41 一端位置處界定有一包覆部411, 而相對包覆部另一端界定有一開放部412,所述包覆部411位 置外緣處披覆有一第一彼覆層42,並於各第一彼覆層42外緣 共同坡覆有一第二彼覆層43,且該開放部412界定之長度係 介於0. 01mm〜4mm之間; 其中所述排線40之第一披覆層42及第二彼覆層43係為 一種具不導電特性之材料,藉由前述第一彼覆層42及第 二坡覆層43係可防止内部導線41間短路現象並同時 保護内部導線41 ’以避免該排線40受環境溫度與濕度之影 100211156 1003436498-0 5 響而造成腐姓; 複數導電端子5〇,該等導電端子5〇 一端形成有一對接部 51而另端則形成有複數穿刺部52,且务導電端子50於兩對 應之穿刺部52間形成有一通道521,並於兩對應穿刺部52間 之通道521 —端形成有一定位槽522 :所述穿刺部52係對接 所述導線41,且使導線41之位置相對設置於所述通道521或 通過所述通道521設置於該定位槽522内,使其導電端子5〇 透過所述穿刺部52電氣連接所述導線41 ’並達到排線4〇可 傳輸數位sfl號至導電端子50之目的者; 於本實施例中,所述開放部412之界定係形成於部分穿刺 部52之邊緣處,使其部分穿刺部52係外露於第一披覆層42 及弟二彼覆層43,而其餘穿刺部52係包覆於第一彼覆層42 與第二彼覆層43内; 其中’所述穿刺部52穿過所述第一彼覆層42及第二彼覆 層43時,其排線40與導電端子50會有電容效應現象產生且 降低其阻抗值; 其中所述排線40傳送之數位訊號為一寬頻訊號,於本實 施例中,其數位訊號攸升時間(Rise time)界定之範圍係為 S250pico sec (250x10 12sec) ’且此數位訊號所對應之頻寬 之範圍係為$〇. 5/爬升時間之頻率内; 又’由於數位訊號傳輸過程中之低頻訊號會直接流向所述 對接部51,並不受開放部412殘枝效應的影響,但數位訊號 100211156 100343649B-0 6 M424576 傳輸過程尹之高頻訊號則受開放部412殘枝效應寄生電容影 響而往開放部412方向流動,此時,藉由其開放部412之界定 0牛低'、淺枝政應g而降低其寄生電容效應可進行較佳的阻 抗匹配’且於數健賴送時可轉峨完整性並可有效降低 訊號串音干擾之現象產生,有效將其數位峨傳送至對接部 凊同時參閱第5A圖所示,係為本創作第二較佳實施例之 剖視示意®-,其與上—實施例的元件及連結義與運作大致 相同在此林贅述相_元件及元件舰,惟本較佳實施例的 相異處在於所述開放部412係以另一長度作表示,如前所述, 其開放部412界定之長度係介於〇. Glrnm〜4mm之間,可視排線 傳送數位訊號之頻寬設置’因此,於本實施例中其開放部仙 之界定係形成於第-披覆層42及第二披覆層43邊緣處,而其 所有穿刺部52係包覆於第-彼覆層42與第二披覆層43内, 同樣可達到藉由其開放部412之界定可降低其殘枝效應進而 降低其寄生電容效應,並練健麟送時可轉訊號完整性 與有效降低訊號串音干擾之現象產生,有效將其數位訊號傳送 至對接部51 ; 又,如第5B ' 5C所示,係為本創作第二較佳實施例之刮 視不思圖二、三,其與上一實施例的元件及連結關係與運作大 致相同在此即不贅述相同的元件及元件符號,惟本較佳實施例 的相異處在於所述第一坡覆層42及第二彼覆層43可分別以不 7 1〇〇211156 1003436498-0 M424576 同長度作表示’如前所述,其開放部412界定之長度係介於 0.01mm〜4麵之間,因此’於本實施例中可視排線4〇傳送數 位訊號之頻寬分別調整其第一披覆層42或第二披覆層43之長 度,使其開放部412之長度介於〇. 〇1麵〜4麵之間,同樣可達 到藉由其部412之界定降低其賊效應進而降低其寄生 電容效應’並於數位訊號傳送時可維持訊號完整性與有效降低 訊號串音干擾之現象產生’有效將其触峨傳送至對接部 51。 請同時參閱第6A圖及第6B圖所示’係為本創作第三較佳 實施例之實施分解示意圖及實施立體示意圖,其中所述刺破型 訊號傳輸線3係與一接頭60配置組設,該接頭6〇具有一底座 61及一對應蓋合前述底座61之蓋體62,其中該底座61具有 一谷置部611,該容置部611係可供所述刺破型訊號傳輸線3 谷置,並由所述蓋體62對應蓋合所述刺破型訊號傳輸線3與 底座61,令所述刺破型訊號傳輸線3可穩固設置於所述容置 部611内且同時罩蓋其開放部412,使該刺破型訊號傳輸線3 與該接頭60可穩固結合,以達到快速且穩固之結合效果。 請同時參閱第7A、7B、7C及7D圖所示,係為本創作第四 較佳實施例之立體示意圖及局部平面示意圖及實施示意圖及 剖視不意圖,其與上一實施例的元件及連結關係與運作大致相 同在此即不贅述相同的元件及元件符號,惟本較佳實施例的相 異處在於所述部分穿刺部52係直接對接所述導線41之開放部 100211156 8 1003436498-0 M424576 412位置處,而其餘穿刺部52係包覆於第一披覆層犯與第工 被覆層43内,其中所述部分穿刺部52對接所述開放部似 時,其穿刺部52係紐所述導線41至通道521位置處,並藉 由通道521局部迫緊該導線41,進而達射增加其排線仙與 導電端子50相互間之拉拔力; 又销放部412具有-彎折部413 ’該彎折部413相對所 述蓋體62延伸,而該蓋體62栢對於彎折部413位置處具有一 定位部62卜藉此,其刺破型訊號傳輸線3與接頭6〇配置組 設時,可透過其彎折部413自設所述定位部621而增加其刺破 型訊號傳輸線3之拉拔力,進而達到所述刺破型訊號傳輸線3 可穩固設置於該_ 6G内,並具有可轉_完整性與有效 降低訊號串音干擾之現象產生之功效。請同時參閱第8Α、8β 圖所示’係為本創作第五較佳實施例之立體示意圖及實施示意 圖,其與上一貫施例的元件及連結關係與運作大致相同在此即 不贅述相㈣元件及元件符號,惟本較佳實關的相異處在於 所述所有穿刺部52係直接對接所述導線41之開放部412位置 處,且忒開放部412形成有所述彎折部413,並透過其彎折部 413勾設所述定位部621而增加其刺破型訊號傳輸線3之拉拔 力’進而達到所述刺破型訊號傳輸線3可穩固設置於該接頭 60内,並具有可維持訊號完整性與有效降低訊號串音干擾之 現象產生之功效。 針對前述各實施例之降低串音干擾現象之傳輸線透 100211156 1003436498-0 9 過時域分析儀(TDR) 長度對特性阻抗之影響 示所述實驗數據; 在一定之條件下,量測不同開放部4 i 2 ,·並透過所述時域分析儀(TDR)顯 二號傳輸線材11上完全披覆有所述内絕緣層及外絕緣 ^去為未具有開放部),並於其排線1上組設有-上蓋(圖 表不)之實施方式透過該時域分析儀⑽)測試未呈 有開放部對訊號傳輪線特性阻抗之影響; 〃 一月,閱第11A、11B圖所示,並同時搭配第3圖 所不’其中圖ΙΙΑ'ΐΐΒ係為本創作開放部412界定於 部分穿刺部52之邊緣處’使細分穿卿52斜露於第一彼 覆層42及第二披覆層43 ’而其餘穿卿52係包覆於第一彼 覆層42與第二彼覆層43内為實施方式,並透過料域分析 儀(TDR)測試該開放部412對排線4〇特性阻抗之影響; 請參閱第12A、12B圖所示,並同時搭配第7八圖 所示’其中圖m、12B係為本創作部分穿刺部52係直 接對接所述導線4丨之開放部412位置處,而其餘穿刺部52係 包覆於第-披覆層42與第二披_ 43内為實施方式,並透過 該時域分析儀(雙)測試該開放部412對排線4〇特性阻抗 之影響; 100211156 請參閱第 13A、13B圖所示 ’並同時搭配第8A圖 10 1003436498-0 2011年11月24日修正替換頁 "中圖13A、13B係為本創作所有穿刺部52係直 接_所述導線41之開放部412位置處為實施方式,並透過 A域;7析儀(TDR)測試該開放部412對排線4()特性 之影響; 最後測得V. New Description: [New Technology Field] This creation is about a signal transmission line, especially a type of Stub effect that can be modified by the definition of the open part and has better impedance matching when transmitting digital signals. A piercing signal transmission line that reduces crosstalk interference. [Prior Art] According to the current electronic device, there are different transmission cables and adapters according to different hardware transmission interfaces, such as USB2.0 interface and USB3.0 interface and SATA interface and HDMI interface are the more common transmission interfaces. And the transmission interface is simultaneously extended by a technique of electrically connecting the transmission cable and the connector in a piercing manner; please refer to FIG. 1A and FIG. 1B, as shown in the prior art, the cable 1 is It is not necessary to individually cover an inner insulating cable 12 on the signal transmission wire I to avoid the signal transmission wires u being electrically connected to each other, and then arranging an outer insulating layer 13 on the inner insulating layer 12, and The cable 1 and the plurality of conductive terminals 20 are disposed to each other. One end of the conductive terminals 2 is formed with a pair of connecting portions 21, and the other end is formed with a plurality of piercing portions 22, and the connecting wires 1 and the conductive terminals 20 are formed. When the components are disposed, the piercing portions 22 pass through the outer insulating layer 13 and the inner insulating layer 12 and electrically connect the signal transmission wires ^ to complete the electrical conduction. Positioned outside the outer insulating layer 13 When the cable 1 transmits the digital signal, the digital signal contains a DC to high frequency sine wave signal component, and is a broadband signal, and its digital signal 100211156 1003436498-0 3 M424576 The bandwidth is inversely proportional to the recorded health (8) 9time). Among them, the low-speed cake reduction test has a lower mosquito, and the broken position signal directly flows directly to the docking portion 21 via the puncturing portion 22, thereby avoiding the purpose of signal transmission by the influence of the residual branch portion 221, and with the digital signal transmission. The rate is getting faster and faster, the soaring time is getting shorter and shorter, and the frequency contained in the number (10) is getting larger and larger, but the parasitic capacitance and inductance effect generated by the stub 4 221 will affect the high frequency components of the digital signal. Further, the signal transmission wire n and the piercing portion 22 of the conductive terminal 2 have a large impedance variation, and the (4) bit reduces the integrity of the transmission and causes a large crosstalk interference phenomenon. Therefore, in view of the above-mentioned deficiencies, the creators have collected relevant information, and through multi-party assessment and considerations, and through years of experience in the industry, through continuous trials and revisions, 'the new material ^ to break through the Wei Lai transmission line Patent holder. [New content] You are 'to solve the shortcomings of the traditional technology, the main purpose of this creation is to provide a kind of _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ Sex, and reduce the rate of sound interference phenomenon of the piercing signal transmission line. In order to achieve the above purpose, the present invention provides a puncture type signal transmission line, which comprises a cable and a plurality of conductive terminals, wherein the wire is provided with a plurality of wires, each of which has a cladding portion and an opening portion. 'The outer edge of each of the covering portions is covered with a 帛-cladding layer' and a second coating layer is co-coated on the outer edge of the first covering layer and the length defined by the opening portion is between G Between Gmmmm and 4, 4 100211156 1003436498-0 M424576 and one end of the conductive terminals is formed with a pair of joints, and the other end is formed with a plurality of sealing portions that abut the wires; thus, by the definition of the open portion It can reduce its stub effect and achieve impedance matching and reduce crosstalk interference when digital signal transmission; therefore, the creation has the following advantages: 1. Reduce the phenomenon that digital signals are interfered by crosstalk; 2 The integrity of the Digin digital signal transmission. [Embodiment] In order to achieve the above object and effect, the technical means and structure of the present invention are described in detail in the preferred embodiment of the present creation, and the features and functions are as follows. Please refer to FIG. 2, FIG. 3 and FIG. 4, which are perspective exploded view, perspective assembled view and sectional view of the first preferred embodiment of the present invention. The piercing signal transmission line 3 of the present invention is shown. The utility model comprises a row of wires 40, wherein the plurality of wires 41 are disposed in a plurality of wires 41 ′, wherein each of the wires 41 defines a covering portion 411 at one end thereof, and an opening portion 412 is defined at the other end of the covering portion, the covering portion The outer edge of the 411 is covered with a first cover layer 42 and a second cover layer 43 is disposed on the outer edge of each of the first cover layers 42. The length defined by the open portion 412 is 0. The first cladding layer 42 and the second cladding layer 43 of the cable 40 are a material having non-conducting properties, and the first cladding layer 42 and the second slope layer are formed by the first cladding layer 42 and the second cladding layer 43. The layer 43 prevents the short circuit between the inner wires 41 and simultaneously protects the inner wires 41' to prevent the cable 40 from being affected by the ambient temperature and humidity 100211156 1003436498-0 5; the plurality of conductive terminals 5〇, such One end of the conductive terminal 5 is formed with a pair of joints 51 and the other end is formed with a plurality of punctures 52. The conductive terminal 50 defines a channel 521 between the two corresponding puncture portions 52, and a positioning groove 522 is formed at the end of the channel 521 between the two corresponding puncture portions 52: the puncture portion 52 is butted to the wire 41. And the position of the wire 41 is oppositely disposed in the channel 521 or disposed in the positioning groove 522 through the channel 521, so that the conductive terminal 5 电气 electrically connects the wire 41 ' through the piercing portion 52 and reaches the row In the embodiment, the definition of the open portion 412 is formed at the edge of the partial puncture portion 52, so that part of the puncture portion 52 is exposed to the first portion. a cover layer 42 and a second cover layer 43, and the remaining piercing portions 52 are wrapped in the first cover layer 42 and the second cover layer 43; wherein the piercing portion 52 passes through the first When the cladding layer 42 and the second cladding layer 43 are disposed, the wiring line 40 and the conductive terminal 50 have a capacitive effect phenomenon and reduce the impedance value thereof; wherein the digital signal transmitted by the cable 40 is a broadband signal, In the embodiment, the digital signal rise time (Rise time) is defined The range is S250pico sec (250x10 12sec)' and the range of the bandwidth corresponding to the digital signal is within the range of $〇.5/climing time; and 'the low frequency signal during the digital signal transmission will flow directly to the above The abutting portion 51 is not affected by the residual effect of the opening portion 412, but the digital signal 100211156 100343649B-0 6 M424576 transmission process Yin high frequency signal is affected by the residual portion 412 residual effect parasitic capacitance and flows toward the opening portion 412 At this time, by the definition of the open portion 412, the low-threshold ', the shallow branch is g, and the parasitic capacitance effect can be reduced to perform better impedance matching', and the integrity can be transferred when the number is stable. Effectively reducing the occurrence of signal crosstalk interference, effectively transmitting its digits to the docking section, while referring to FIG. 5A, which is a cross-sectional illustration of the second preferred embodiment of the present invention, which is implemented with The components and the meanings of the examples are substantially the same as those of the components. The difference between the preferred embodiment and the component ship is that the open portion 412 is represented by another length, as described above. Open The length defined by 412 is between 〇. Glrnm~4mm, and the bandwidth of the digital signal is transmitted by the visual cable. Therefore, in the present embodiment, the definition of the open part is formed on the first-cladding layer 42 and the first At the edge of the second cladding layer 43, and all of the puncture portions 52 are wrapped in the first and second cladding layers 42 and the second cladding layer 43, the same can be achieved by the definition of the opening portion 412. In turn, the effect of the parasitic capacitance is reduced, and the integrity of the signal is transmitted and the phenomenon of effectively reducing the signal crosstalk is effectively generated, and the digital signal is effectively transmitted to the docking portion 51; and, as shown in FIG. 5B '5C, The second embodiment of the present invention is the second embodiment of the present invention. The components and the connection and operation of the previous embodiment are substantially the same, and the same components and component symbols are not described herein. The difference between the preferred embodiment is that the first slope layer 42 and the second cladding layer 43 can be represented by the same length as 7 1 〇〇 211156 1003436498-0 M424576 respectively. The defined length is between 0.01mm and 4 faces, so 'in this In the embodiment, the width of the visible signal line 4 is adjusted to adjust the length of the first cladding layer 42 or the second cladding layer 43 so that the length of the opening portion 412 is between 〇1面4 faces. Between the same, the thief effect can be reduced by the definition of its part 412 to reduce its parasitic capacitance effect, and the signal integrity can be maintained and the crosstalk interference can be effectively reduced when the digital signal is transmitted.峨 is transmitted to the docking section 51. Please refer to FIG. 6A and FIG. 6B for a schematic exploded view and a perspective view of a third preferred embodiment of the present invention. The piercing signal transmission line 3 is configured with a connector 60. The connector 6 has a base 61 and a cover 62 corresponding to the base 61. The base 61 has a valley portion 611, and the receiving portion 611 is provided for the piercing type signal transmission line 3 The punctured signal transmission line 3 and the base 61 are correspondingly closed by the cover body 62, so that the punctured signal transmission line 3 can be stably disposed in the accommodating portion 611 while covering the open portion thereof. 412, the piercing type signal transmission line 3 and the joint 60 can be firmly combined to achieve a fast and stable combination. Please refer to FIGS. 7A, 7B, 7C and 7D, which are schematic perspective views and partial plan views and schematic views and cross-sectional views of the fourth preferred embodiment of the present invention, which are related to the components of the previous embodiment and The connection relationship and the operation are substantially the same, and the same components and component symbols are not described herein. However, the difference between the preferred embodiment is that the partial puncture portion 52 directly abuts the open portion of the wire 41. 100211156 8 1003436498-0 M424576 412 position, and the remaining puncture portion 52 is wrapped in the first coating layer and the working coating layer 43, wherein the partial puncture portion 52 is similar to the opening portion, and the puncture portion 52 is The wire 41 is at the position of the channel 521, and the wire 41 is partially pressed by the channel 521 to further increase the pulling force between the wire and the conductive terminal 50; and the pin portion 412 has a bent portion. 413 'The bent portion 413 extends relative to the cover body 62, and the cover body 62 has a positioning portion 62 at a position of the bent portion 413, and the piercing type signal transmission line 3 and the joint 6〇 are disposed. When set, it can be set through its bent portion 413 The positioning portion 621 increases the pulling force of the punctured signal transmission line 3, so that the punctured signal transmission line 3 can be stably disposed in the _6G, and has a convertible_integrity and an effective reduced signal string. The effect of the phenomenon of sound interference. Please also refer to the eighth embodiment and the 8β figure for a schematic view and a schematic diagram of the fifth preferred embodiment of the present invention. The components and the connection relationship and operation of the above-mentioned conventional embodiment are substantially the same. The components and the component symbols are different from each other in that the puncture portion 52 directly abuts the position of the opening portion 412 of the wire 41, and the opening portion 412 is formed with the bent portion 413. And the positioning portion 621 is hooked through the bent portion 413 to increase the pulling force of the punctured signal transmission line 3, so that the punctured signal transmission line 3 can be stably disposed in the joint 60, and has Maintain signal integrity and effectively reduce the effects of signal crosstalk. The transmission line for reducing the crosstalk interference phenomenon of the foregoing embodiments is 100211156 1003436498-0 9 The effect of the length of the time domain analyzer (TDR) on the characteristic impedance is shown in the experimental data; under certain conditions, the different open parts are measured 4 i 2 , and through the time domain analyzer (TDR), the second transmission wire 11 is completely covered with the inner insulating layer and the outer insulation is not open, and is disposed on the cable 1 The embodiment with the upper cover (not shown) tests the effect of the open circuit on the characteristic impedance of the signal transmission line through the time domain analyzer (10); 〃 in January, as shown in Figures 11A and 11B, and At the same time, in conjunction with Fig. 3, the figure "为本" is defined as the creation opening portion 412 is defined at the edge of the portion of the puncture portion 52, so that the subdivided layer 52 is obliquely exposed to the first cover layer 42 and the second cladding layer. 43' and the remaining wearer 52 is wrapped in the first and second cladding layers 42 and 43 as an embodiment, and the characteristic impedance of the opening portion 412 to the cable 4 is tested by a region analyzer (TDR). The impact; please refer to the 12A, 12B picture, and at the same time with the 7th In the figure, the figures m and 12B are the positions where the puncturing portion 52 of the imaginary portion directly abuts the opening portion 412 of the wire 4丨, and the remaining puncturing portions 52 are covered by the first coating layer 42 and the second portion. The inside of the _ 43 is an embodiment, and the influence of the open portion 412 on the characteristic impedance of the cable 4 测试 is tested by the time domain analyzer (double); 100211156 Please refer to the figure 13A, 13B and at the same time with the 8A 10 1003436498-0 November 24, 2011, the revised replacement page " 13A, 13B is the creation of all the puncture portion 52 directly - the position of the open portion 412 of the wire 41 is the embodiment, and through the A domain; 7 analyzer (TDR) test the effect of the open part 412 on the characteristics of the cable 4 ();
習知 第~實施例 108.1 108 83.7 108.6 83.6 -33.9 第-實施例 112.2 87 110.1 90 33.9 92 第四實施例 111.5 97.9 114.5 114.4 90.5 97.6 -34.3 -34.1Conventions - Examples 108.1 108 83.7 108.6 83.6 -33.9 First embodiment 112.2 87 110.1 90 33.9 92 Fourth embodiment 111.5 97.9 114.5 114.4 90.5 97.6 -34.3 -34.1
表1開放部成形方式對排線特性阻抗之影響數據 另同時請參閱表1所示,係為前述多種實施方式 以時域分析儀(僅)測試該開放部412對排線4G特性阻抗 之影響數據’糾表中所示之mating impedanee為連接器公 端端子與母端端子機點之阻抗數據,100為_與端子穿刺 之阻抗數據,NEXT表7F近端串音量數據。需陳明者,以上所 述僅為本案之雛實細’並_以關糊作,若依本創作 之構想所作之改變’在不脫離本創作精神細内,例如:對於 1003436498-0 11 1156 M424576 構形或佈置型態加以變換’對於各觀化,修飾與應用,所產 生等效作用’均聽含於本案之權概_,合予陳明。、 綜上所述,本創作之刺破型訊號傳輸線於使用時,為確實 此達到其功效及目的,故本創作誠為—實用性優異之創作,為 符合新型專利之申請要件’爰依法提出申請,盼轉早日賜 准本案’贿P摘作人之辛作,齡躺審委有任何稽 疑’請不吝來函指示,創作人定當竭力配合,實感德便。 【圖式簡單說明】 弟1A圖係為習知技術之分解示意圖; 第1B圖係為習知技術之組合示意圖; 第2圖係為本創作第—較佳實關之立體分解圖; 第3圖係為本創作第—較佳實施例之立體組合圖; 第4圖係林解第—絲實施例之排線剖視圖; 第5A圖係為本創作第二較佳實施例之剖視示 意圖一; 第5B圖係為本創作之第二較佳實施例之剖視示意圖二; 第5C圖係為本創作之第二較佳實施例之剖視示意圖三; 第6A圖係林解第三触實酬之實齡解示意圖; 第6B圖係為本創作第三較佳實補之實施立體示意圖; 第7A圖係為本創作第吨佳實施例之讀示意圖; 第7B圖係為本創作第吨佳實施例之局部平面示意圖; 第7C圖係為本創作第四較佳實施例之實施示意圖; 第7D圖係為本料如她實如狀舰示意圖; 12 100211156 1003436498-0 M424576 第8A圖#、為本創作第五較佳實施例之立體示意圖; 第8B 創㈣雜佳實關之實施示意圖; 第9A圖係^本創作透過時域分析儀(tdr)第一實施方式 之測試圖示一; 第9B圖係為本創作透過時域分析儀(TDR)第一 實施方式之測 試圖不; 第10A圖絲本創作透過時域分析儀(則第二實施方式之測 試圖示一; 第10B圖係為本創作透過時域分析儀⑽)第二實施方式之測 試圖示二; 第m圖係為本創作透過時域分析儀(徽)第三實施方式之測 試圖不'~ ; 第11B圖係為本創作透過時域分析儀⑽)第三實施方式之測 試圖不; $ 12A 作透過時域分析儀(则第四實施方式之測 試圖不一; 第12B圖係為本創作透過時域分析儀(TDR)第四實施方式之測 試圖不; 第13A圖係為本創作透過時域分析儀(TDR)第五實施方式之測 試圖示一; 第13B圖係為本創作透過時域分析儀(TDR)第五實施方式之測 試圖不二; 100211156 13 1003436498-0 M424576 表1係為時域分析儀(TDR)測試該開放部對排線特性阻抗之影 響數據。 【主要元件符號說明】 _ 刺破型訊號傳輸線3 對接部51 排線40 穿刺部52 導線41 通道521 包覆部411 定位槽522 開放部412 接頭60 彎折部413 底座61 第一披覆層42 容置部611 第二披覆層43 蓋體62 導電端子50 定位部621 100211156 1003436498-0 14Table 1 The influence of the forming method of the open part on the characteristic impedance of the cable is also shown in Table 1. The various embodiments described above test the influence of the open part 412 on the characteristic impedance of the cable 4G by the time domain analyzer (only). The mating impedanee shown in the data 'correction table' is the impedance data of the connector male terminal and the female terminal, 100 is the impedance data of the terminal piercing, and the NEXT table 7F the proximal string volume data. Those who need to be clarified, the above is only the actual case of the case 'and _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ M424576 The configuration or arrangement type is transformed 'for the various aspects, the modification and the application, the equivalent effect' is heard in the power of the case _, and is combined with Chen Ming. In summary, the piercing signal transmission line of this creation is used to achieve its efficacy and purpose. Therefore, this creation is a creative and practical creation, which is in accordance with the requirements of the new patent application. Application, I hope to transfer the case as soon as possible, 'Brit P is the masterpiece of the person, and there is any doubt in the review committee.' Please do not hesitate to give instructions, the creator will try his best to cooperate, and feel really good. [Simple diagram of the schema] The 1A diagram is a schematic diagram of the decomposition of the prior art; the 1st diagram is a combination diagram of the prior art; the 2nd diagram is the perspective decomposition diagram of the first-best implementation of the creation; Figure 4 is a perspective view of a preferred embodiment of the present invention; Figure 4 is a cross-sectional view of the embodiment of the first embodiment of the present invention; Figure 5A is a schematic cross-sectional view of the second preferred embodiment of the present invention. Figure 5B is a cross-sectional view of the second preferred embodiment of the present invention; Figure 5C is a cross-sectional view of the second preferred embodiment of the present invention; Figure 6A is the third touch of the forest solution A schematic diagram of the real-life solution of the actual reward; Figure 6B is a three-dimensional diagram of the implementation of the third best practice of the creation; Figure 7A is a schematic diagram of the reading of the first ton of the creation; FIG. 7C is a schematic view showing the implementation of the fourth preferred embodiment of the present invention; FIG. 7D is a schematic diagram of the material as if it were a real ship; 12 100211156 1003436498-0 M424576 Figure 8A #, is a three-dimensional schematic diagram of the fifth preferred embodiment of the creation; 8B (4) Schematic diagram of the implementation of Miscellaneous Guanshi; Section 9A is the test diagram of the first embodiment through the time domain analyzer (tdr); the 9B diagram is the creation of the time domain analyzer (TDR) The test chart of an embodiment is not; the 10A figure is created by the time domain analyzer (the test image of the second embodiment is shown; the 10B figure is the creation of the time domain analyzer (10) by the second embodiment) Test Figure 2; the mth picture is the third embodiment of the creation of the time domain analyzer (emble) through the test chart is not '~; the 11th picture is the third embodiment of the creation through the time domain analyzer (10)) The test chart is not; $12A is transmitted through the time domain analyzer (the test chart of the fourth embodiment is different; the 12th picture is the test chart of the fourth embodiment of the creation through the time domain analyzer (TDR); The figure is the test diagram 1 of the fifth embodiment of the creation time-domain analyzer (TDR); the 13th figure is the test chart of the fifth embodiment of the creation time-domain analyzer (TDR); 100211156 13 1003436498-0 M424576 Table 1 is a time domain analyzer (TDR) test for the open section Impedance influence data. [Main component symbol description] _ Puncture signal transmission line 3 Docking portion 51 Cable 40 Puncture portion 52 Conductor 41 Channel 521 Covering portion 411 Positioning groove 522 Opening portion 412 Connector 60 Bending portion 413 Base 61 a cladding layer 42 accommodating portion 611 second cladding layer 43 cover body 62 conductive terminal 50 positioning portion 621 100211156 1003436498-0 14