201229842 六、發明說明: 【發明所屬之技術領域】 本發明是有關於一種感應元件,特別是一種觸控式感 應元件》 【先前技術】 觸控技術原是使用於工業控制領域,近年將觸控技術 導入可攜式電子產品的面板已成為市場主流。觸控面板主 要有電阻式觸控面板與電容式觸控面板兩種。其中,電阻 式觸控面板的壽命與对受性不足,無法繼續滿足未來作為 工業控制領域與消費性電子性品領域所需更嚴格的產品規 格與穩定度m式㈣面板還可應用於多點觸控功 能,因此,電容式觸控面板已成為觸控面板發展的主流。 參閱圖1 ’以一電容式觸控感應元件!為例說明目前的 觸控式感應元件,該電容式觸控感應元件丨包括一基板 11、一設置於該基板11上的電容電路12。該電容電路12 包括導電結構121、複數介電層膜122,及複數架橋123。 配合參閱圖2,該導電結構121形成於該基板u上, 並具有複數間隔排列的第—導電塊124、複數成間隔排列的 第二導電塊125,及複數連結塊126。該等第二導電塊125 與該等第-導電塊124成交錯分佈,該等連結塊126連接 在第方向Y上兩兩相鄰的第一導電塊124,該等連結塊 126與該等第一導電塊124界定複數沿第一方向γ延伸且間 隔排列的第一導電單元127» 該等介電層膜122以絕緣材料構成,並間隔地形成於 201229842 該等連結塊126上,而覆蓋該等連結塊126的其中一部 份。 配合參閱圖3,該等架橋123以可導電的材料所構成, 且連接兩相鄰的第二導電塊125,而使得該等第二導電塊 125及該等架橋123形成多數分別沿一異於該第一方向γ的 第二方向X且間隔排列的第二導電單元128。一般言,該第 一、二方向Υ、X彼此垂直。每一架橋123跨越對應的連結201229842 VI. Description of the Invention: [Technical Field] The present invention relates to an inductive component, in particular to a touch sensing component. [Prior Art] Touch technology was originally used in the field of industrial control, and touches have been used in recent years. The introduction of technology into the panel of portable electronic products has become the mainstream of the market. The touch panel mainly has two types of a resistive touch panel and a capacitive touch panel. Among them, the resistive touch panel has insufficient life and reliability, and can not continue to meet the future. As a more stringent product specification and stability required in the field of industrial control and consumer electronics, the m-type (four) panel can also be applied to multiple points. Touch function, therefore, capacitive touch panels have become the mainstream of touch panel development. See Figure 1' for a capacitive touch sensing element! For example, the current touch sensing device includes a substrate 11 and a capacitor circuit 12 disposed on the substrate 11. The capacitor circuit 12 includes a conductive structure 121, a plurality of dielectric layers 122, and a plurality of bridges 123. Referring to FIG. 2, the conductive structure 121 is formed on the substrate u, and has a plurality of first conductive blocks 124, a plurality of spaced second conductive blocks 125, and a plurality of connecting blocks 126. The second conductive blocks 125 are staggered with the first conductive blocks 124. The connecting blocks 126 are connected to two adjacent first conductive blocks 124 in the first direction Y, and the connecting blocks 126 and the same A conductive block 124 defines a plurality of first conductive units 127 extending in the first direction γ and spaced apart. The dielectric layer films 122 are formed of an insulating material and are formed at intervals on the connecting blocks 126 of 201229842 to cover the And a part of the connection block 126. Referring to FIG. 3, the bridges 123 are made of a conductive material and connect two adjacent second conductive blocks 125, so that the second conductive blocks 125 and the bridges 123 form a majority. The second conductive unit 128 is arranged in the second direction X of the first direction γ and spaced apart. In general, the first and second directions Υ and X are perpendicular to each other. Each bridge 123 spans the corresponding link
塊126而連接位於该對應的連結塊126上的介電層膜122。 該等第一、二導電塊124、125、該等連結塊126、該等介 電層膜122、该等架橋123與周邊設置區域相配合而形成多 數感應電容129。 當以手指觸壓該電容式觸控感應元件丨時,會使其上 的電荷重新分布調整,觸Μ處的電容值產生變化,日該電容 :觸控感應兀件!的運算器(圖未示出)即可計算出該感應電 谷129的數值發生變化的位置,以供後續例如顯示、或是 其他作動參數。 目月,】電容柄_應元件丨的主要問題在於該導電結 出:21 :第—導電塊124、第二導電塊125與連結塊126是 ^導電材料,例如氧化錫或銦錫氧化 lnn〇/ 2 的早位面積的面電阻值大約為30Ω〜Block 126 connects the dielectric layer film 122 on the corresponding connection block 126. The first and second conductive blocks 124 and 125, the connecting blocks 126, the dielectric film 122, and the bridges 123 cooperate with the peripherally disposed regions to form a plurality of sensing capacitors 129. When the capacitive touch sensing element is pressed with a finger, the charge on the touch is redistributed and the capacitance value at the touch is changed. The capacitance is: touch sensing element! The operator (not shown) can calculate the position at which the value of the induced valley 129 changes for subsequent display, or other actuation parameters. The main problem of the capacitor handle is that the conductive junction: 21: the first conductive block 124, the second conductive block 125 and the connecting block 126 are conductive materials, such as tin oxide or indium tin oxide lnn〇 / 2 The area resistance of the early area is about 30Ω~
lUUiz /cm 5 甘-χ- I 件i… 於loon/cm2’所以會在該觸控式感應元 愈大,=路的高阻抗,導致隨著面板尺寸 【發明内容r 斷路而無法作動。 201229842 因此,本發明之目的,即在提供一種具有低阻抗且適 用於大尺寸的觸控式感應元件。 此外’本發明之另一目的,即在提供一種適合應用於 大尺寸觸控用的導電電極結構。 於是’本發明觸控式感應元#,包含一基板及一觸控 式感應電路。該觸控式感應電路設置於該基板上並包括一 導電塊結構、一導電電極結構,及複數介電層冑,該導電 塊結構具有複數成間隔陣列排列的第一導電塊、複數第二 導電塊,及複數連結塊,每一連結塊連接兩相鄰之第一導 電塊’而使該等第-導電塊藉由該等連結塊連結而成多數 排間隔排列的第一導電單元,該等第二導電塊與該等第一 導電塊交錯分佈,該等第二導電塊彼此電連接而成多數 排間隔排列,且與該等第一導電單元交錯的第二導電單 元,該導電電極結構包括複數分別設置於該等第一導電塊 的第一導線,每一第—導線是以電阻值低於該第一導電塊 和連結塊的材料構成,每一介電層膜設 置於任一第一、二 導電單兀的交會處,而使該交會處的第一、二導電單元藉 該介電層膜彼此間隔,每一第一導線沿該排第—導電單元 長度方向的總投影長度與每一第一導電單元沿該排第一導 電單凡長度方向的投影長度的比例不小於30〇/〇。 本發明另一導電電極結構設置在一觸控感應電路上, 邊觸控感應電路具有複數排第一導電單元、複數排與該等 第一導電單元交錯的第二導.電單元,及複數分別設置於任 第一導電單凡與任一第二導電單元的交會處的介電層 201229842 膜,該導電電極結構包含複數第—導線,每一第一導線以 電阻值低於該第一導電單元的材料構成並對應設置於每一 第-導電單元上,每-第-導線沿該排第_導電單元長度 方向的總投影長度與每一第一導電單元沿該排第一導電單 元長度方向的投影長度的比例不小於3 〇 %。 本發明之功效:在第一導電塊上設置阻抗更低的第_ 導線,m線沿該排第一$電單元長度方向的總投 影長度與每一第一導電單元沿該排第一導電單元長度方向 的投影長度的比例不小於30%,使觸控感應電路整體具有 更均勻的·#效低阻抗電路,而可適用於大尺寸觸控操作。 【實施方式】 有關本發明之前述及其他技術内容、特點與功效,在 以下配合參考圖式之二個較佳實施例的詳細說明中將可 清楚的呈現。 在本發明被詳細描述之前,要注意的是,在以下的說 明内谷中,類似的元件是以相同的編號來表示。 參閱圖4’本發明的第一較佳實施例是以一電容式的觸 控式感應件2為例作說明,包含一基板21,及一設置於 該基板21上的觸控式感應電路22〇該觸控式感應電路22 包括一導電塊結構221、—導電電極結構222,及複數介電 層膜223。 该基板21是可選自壓克力、聚碳酸酯、聚乙烯、塑 膠玻璃’及此等之一組合為材料所構成。 "玄導電塊結構221以可導電材料構成並設置在該基板 201229842 21上,並包括複數成陣列式排列且彼此間隔的第一導電塊 224、複數成陣列式排列且彼此間隔的第二導電塊,及 複數連結塊226,該導電塊結構221的第一導電塊224與第 一導電塊225可以是矩形、菱形、三角形、多邊形等。 配合參閱圖5,該等連結塊226分別連結在一第一方向 Υ兩兩相鄰的第一導電塊224, *使該等第—導電塊224及 該等連結塊226界定複數分別朝該第一方向γ且彼此平行 的第-導電單元231,即,該第一方向γ為一第一導電單元 231長度方向或電性傳導方向。 在該第一較佳實施例中,該導電塊結構221是選自金 屬、合金、氧化錫、銦錫氧化物、銦鋅氧化物,或奈米碳 管,及其中之一組合為材料所構成。 該導電電極結構222以可導電的材料構成,且該可導 電的材料的面電阻值小於構成該導電塊結構221的導電材 料的面電阻值,在此選自低阻抗的金屬構成。該導電電極 結構222包括複數第—導線227,及複數第二導線228。該 等第一導線227分別連接於該等第一導電塊224上,且長 度方向沿該第一導電單元231長度方向,每一第一導線227 是以電阻值低於該第一導電塊224和連結塊226的材料構 成,另外,每一第一導線227在該第一導電單元23ι長度 方向的總投影長度與每一第一導電單元231長度方向的投 影長度的比例不小於30%。 參閱圖4、圖5、圖6,該導電塊結構221的第二導電 塊225於一第二方向X上透過該導電電極結構222的第二 201229842 導線228電連接成複數彼此平行且間隔排列的第二導電單 元232。因此’ §玄第·一方向X為該第二導電單元232長度方 向或電性傳導方向。該第二導電單元232與第一導電單元 23 1之該等連結塊226的交會處不與該等連結塊226接觸地 設置。每一第二導線228在該第二導電單元232長度方向 的總投影長度與每一第二導電單元232在第二導電單元232 長度方向之投影長度的比例不小於30%。 較佳地,每一第二導電單元232上的第二導線228沿 §亥排第二導電單元232長度方向的總投影長度與每一第二 導電單元232沿該排第二導電單元232長度方向的投影長 度的比例不小於90%,每一第一導電單元231上的第一導 線沿該排第一導電單元23 1長度方向的總投影長度與每一 第一導電單元231沿該排第一導電單元231長度方向的投 影長度的比例不小於90%,及/或該導電電極結構222的構 成材料的面電阻值與該導電塊結構221的構成材料的面電 阻值的比例小於10%。 較佳地,設置於每一第一導電單元231上的第一導線 227沿該排第一導電單元23 1長度方向的總投影長度與每一 第一導電單元231沿該排第一導電單元231長度方向的投 影長度的比例不小於95%,該第二導線228沿該排第二導 電單元232長度方向的總投影長度與每一第二導電單元232 Λ a亥排第一導電單元232長度方向的投影長度的比例不小 於95%。可更顯著地降低元件整體所需的阻抗。更佳地, 設置於每一第一導電單元231上的第一導線227沿該排第 201229842 一導電單元231長度方向的總投影長度與每一第一導電單 元231沿該排第一導電單元231長度方向的投影長度的比 例為100%而為全線導通’該第二導線228沿該排第二導電 單元232長度方向的總投影長度與每一第二導電單元232 沿該排第二導電單元232長度方向的投影長度的比例為 100%而為全線導通。 更佳地,該導電電極結構222的構成材料的面電阻值 與該導電塊結構221的構成材料的面電阻值的比例小於 母介電層膜223分別對應地設置於每一第一導電單 元231,及每一第二導電單元232的交會處,並以該介電層 膜223作為該交會處的連結塊226,及第二導線228的間 224、225、該連結塊 象228,及該等介電層 隔,而使得該等第一、二導電塊2 226、該等一導線227、該等第二導線 數電容感應單元233。 一般言,該第一、二方向 膜223的重疊處,與其相連的第一導電單元131和第二導 電單元132的周邊區域相互感應作用,並相配合而形成複 Y、X彼此夾一特定角度。在lUUiz /cm 5 Gan-χ- I piece i... In loon/cm2', the larger the touch-sensitive sensor element is, the higher the impedance of the circuit, resulting in the panel size [The invention r is disconnected and cannot be activated. 201229842 Accordingly, it is an object of the present invention to provide a touch sensing element having a low impedance and suitable for a large size. Further, another object of the present invention is to provide a conductive electrode structure suitable for use in a large-sized touch. Thus, the touch sensing element # of the present invention comprises a substrate and a touch sensing circuit. The touch sensing circuit is disposed on the substrate and includes a conductive block structure, a conductive electrode structure, and a plurality of dielectric layers, the conductive block structure having a plurality of first conductive blocks arranged in a spaced array, and a plurality of second conductive layers a block, and a plurality of connecting blocks, each connecting block connecting two adjacent first conductive blocks' such that the first conductive blocks are connected by the connecting blocks to form a plurality of first conductive units arranged in a row. The second conductive block is alternately distributed with the first conductive blocks, and the second conductive blocks are electrically connected to each other to form a plurality of rows of second conductive cells interlaced with the first conductive cells, the conductive electrode structure including a plurality of first wires respectively disposed on the first conductive blocks, each of the first wires being composed of a material having a lower resistance value than the first conductive block and the connecting block, each dielectric layer film being disposed on any first And the intersection of the two conductive single turns, wherein the first and second conductive units of the intersection are separated from each other by the dielectric layer film, and the total projection length of each first wire along the length direction of the first conductive unit of the row The ratio of the projected length of the first conductive unit in a single row where a first conductive longitudinal direction is not less than 30〇 / square. Another conductive electrode structure of the present invention is disposed on a touch sensing circuit, wherein the touch sensing circuit has a plurality of first conductive units, a plurality of second conductive units interleaved with the first conductive units, and a plurality of respective a dielectric layer 201229842 film disposed at an intersection of any first conductive element and any second conductive unit, the conductive electrode structure comprising a plurality of first wires, each of the first wires having a lower resistance value than the first conductive unit The material is configured and correspondingly disposed on each of the first conductive units, the total projected length of each of the first conductive lines along the length of the first conductive unit of the row and the length of each of the first conductive units along the length of the first conductive unit of the row The ratio of the projection length is not less than 3 〇%. The effect of the invention is that a first conductor having a lower impedance is disposed on the first conductive block, the total projected length of the m-line along the length direction of the first electric unit of the row and the first conductive unit along the first conductive unit of the first conductive unit The ratio of the projection length in the length direction is not less than 30%, so that the touch sensing circuit as a whole has a more uniform and low-impedance circuit, and can be applied to a large-sized touch operation. The above and other technical contents, features, and advantages of the present invention will be apparent from the following detailed description of the preferred embodiments. Before the present invention is described in detail, it is noted that in the following description, similar elements are denoted by the same reference numerals. The first preferred embodiment of the present invention is a capacitive touch sensing device 2 as an example, including a substrate 21 and a touch sensing circuit 22 disposed on the substrate 21. The touch sensing circuit 22 includes a conductive block structure 221, a conductive electrode structure 222, and a plurality of dielectric layers 223. The substrate 21 is made of a material selected from the group consisting of acrylic, polycarbonate, polyethylene, plastic glass, and the like. " mysterious conductive block structure 221 is formed of a conductive material and disposed on the substrate 201229842 21, and includes a plurality of first conductive blocks 224 arranged in an array and spaced apart from each other, a plurality of second conductive layers arranged in an array and spaced apart from each other The first conductive block 224 and the first conductive block 225 of the conductive block structure 221 may be rectangular, diamond, triangular, polygonal, or the like. Referring to FIG. 5, the connecting blocks 226 are respectively connected to the first conductive blocks 224 adjacent to each other in a first direction, and the first conductive blocks 224 and the connecting blocks 226 are respectively defined to the first The first conductive unit 231 is γ in a direction and parallel to each other, that is, the first direction γ is a longitudinal direction or an electrical conduction direction of the first conductive unit 231. In the first preferred embodiment, the conductive block structure 221 is selected from the group consisting of a metal, an alloy, a tin oxide, an indium tin oxide, an indium zinc oxide, or a carbon nanotube, and one of the combinations is a material. . The conductive electrode structure 222 is made of an electrically conductive material, and the surface resistance of the electrically conductive material is smaller than the surface resistance of the electrically conductive material constituting the conductive block structure 221, and is selected from a low-resistance metal. The conductive electrode structure 222 includes a plurality of first conductors 227 and a plurality of second conductors 228. The first wires 227 are respectively connected to the first conductive blocks 224, and the length direction is along the length direction of the first conductive unit 231, and each of the first wires 227 has a resistance value lower than the first conductive blocks 224 and The material of the connection block 226 is configured. In addition, the ratio of the total projection length of each of the first wires 227 in the longitudinal direction of the first conductive unit 23 to the projection length in the longitudinal direction of each of the first conductive units 231 is not less than 30%. Referring to FIG. 4, FIG. 5, FIG. 6, the second conductive block 225 of the conductive block structure 221 is electrically connected in a second direction X through the second 201229842 wire 228 of the conductive electrode structure 222 to be parallel and spaced apart from each other. The second conductive unit 232. Therefore, the direction X is the length direction or the electrical conduction direction of the second conductive unit 232. The intersection of the second conductive unit 232 and the connecting blocks 226 of the first conductive unit 23 1 is not disposed in contact with the connecting blocks 226. The ratio of the total projected length of each of the second wires 228 in the longitudinal direction of the second conductive unit 232 to the projected length of each of the second conductive units 232 in the longitudinal direction of the second conductive unit 232 is not less than 30%. Preferably, the total length of the second wire 228 on each second conductive unit 232 along the length direction of the second conductive unit 232 and the length of each second conductive unit 232 along the second conductive unit 232 of the row The ratio of the projection length is not less than 90%, the total projection length of the first conductive line on each first conductive unit 231 along the length direction of the first conductive unit 23 1 of the row and the first conductive unit 231 along the first row of the first conductive unit 231 The ratio of the projection length of the conductive unit 231 in the longitudinal direction is not less than 90%, and/or the ratio of the sheet resistance value of the constituent material of the conductive electrode structure 222 to the sheet resistance value of the constituent material of the conductive block structure 221 is less than 10%. Preferably, the total length of the first wire 227 disposed on each of the first conductive units 231 along the length direction of the first conductive unit 23 1 of the row and the first conductive unit 231 along the first conductive unit 231 of the first conductive unit 231 The ratio of the length of the projection in the length direction is not less than 95%, the total projection length of the second wire 228 along the length direction of the second conductive unit 232 of the row and the length of the first conductive unit 232 of each of the second conductive units 232 The ratio of the projected length is not less than 95%. The impedance required for the overall component can be significantly reduced. More preferably, the total length of the first wire 227 disposed on each of the first conductive units 231 along the length direction of the conductive unit 231 of the row 201229842 and the first conductive unit 231 along the first conductive unit 231 of the first conductive unit 231 The ratio of the projection length in the length direction is 100% and is the full line conduction. The total projection length of the second wire 228 along the length direction of the second conductive unit 232 of the row and each second conductive unit 232 along the second conductive unit 232 of the row. The ratio of the projection length in the longitudinal direction is 100% and is turned on all the lines. More preferably, the ratio of the sheet resistance of the constituent material of the conductive electrode structure 222 to the sheet resistance of the constituent material of the conductive block structure 221 is smaller than that of the mother dielectric layer film 223, and is disposed on each of the first conductive units 231, respectively. And the intersection of each of the second conductive units 232, and the dielectric layer film 223 is used as the connection block 226 of the intersection, and the spaces 224, 225 of the second wires 228, the connection block image 228, and the like The dielectric layer is separated by the first and second conductive blocks 2 226, the one wire 227, and the second wire number capacitance sensing unit 233. Generally speaking, the overlapping portions of the first and second-direction films 223, the peripheral regions of the first conductive unit 131 and the second conductive unit 132 connected thereto are mutually inductively coupled to each other to form a complex Y and X sandwiching a specific angle with each other. . in
膠’玻璃,及此等之一組合。Glue glass, and a combination of these.
10 201229842 觸控的位置、數值、相距高度等,以供後續例如顯示、或 是其他作動參數。 由於每一第一導線227在第一導電單元231長度方向 的總投影長度與每一第一導電單元231長度方向的投影長 度的比例不小於30%時,及/或每一第二導線228在該第二 導電單元232長度方向的總投影長度與每一第二導電單元 232在第二導電單元232長度方向之投影長度的比例不小於 30%時,整體面電阻值會下降3〇%〜5〇% ;每一第二導電單 元232上的第二導線228沿該排第二導電單元232長度方 向的總投影長度與每一第二導電單元232沿該排第二導電 單元232長度方向的投影長度的比例不小於9〇%,及/或每 一第一導電單元231上的第一導線沿該排第一導電單元23 1 長度方向的總投影長度與每一第一導電單元231沿該排第 一導電單元231長度方向的投影長度的比例不小於9〇% 時,元件整體的面電阻值下降8〇%〜95%。因此,該第一較 佳實施例利用連結於該導電塊結構221的第一、二導電塊 224、225上的該導電電極結構222的第一、二 228的低等效面阻抗,而可增進作動時電流在該觸控式感應10 201229842 The position, value, height of the touch, etc. of the touch for subsequent display, or other actuation parameters. Since the ratio of the total projected length of each of the first wires 227 in the longitudinal direction of the first conductive unit 231 to the projected length of each of the first conductive units 231 is not less than 30%, and/or each of the second wires 228 is When the ratio of the total projection length of the second conductive unit 232 in the longitudinal direction to the projection length of each second conductive unit 232 in the longitudinal direction of the second conductive unit 232 is not less than 30%, the overall surface resistance value may decrease by 3〇%~5. 〇%; the total projected length of the second wire 228 on each second conductive unit 232 along the length of the second conductive unit 232 in the row and the projection of each second conductive unit 232 along the length of the second conductive unit 232 in the row The ratio of the length is not less than 9〇%, and/or the total projected length of the first wire on each first conductive unit 231 along the length direction of the first conductive unit 23 1 of the row and each row of the first conductive unit 231 along the row When the ratio of the projection length of the first conductive unit 231 in the longitudinal direction is not less than 9〇%, the sheet resistance of the entire element is lowered by 8〇% to 95%. Therefore, the first preferred embodiment can improve the low equivalent surface impedance of the first and second 228 of the conductive electrode structure 222 connected to the first and second conductive blocks 224 and 225 of the conductive block structure 221. Current during the touch sensing
應元件2的電流訊號的傳送速度更有效率。The current signal transmission speed of component 2 is more efficient.
明導電薄 結構222的低阻抗,而維持快速、穩定的觸 且可避免目前使用氧化錫或銦錫氧化物等透 201229842 膜作為忒導電結構之大尺寸觸控面板遭遇因成膜不均造成 的斷路、電阻抗不均勻或高阻抗線路問題而使其感應效果 不一致,導致觸控反應失效或線性不佳的問題,或是觸控 反應回饋緩慢,或是量產的再現性不好等問題,故可有效 . 提升製程、乃至產品良率。 另外,需說明的是,本發明觸控式感應元件2的製作 過程,大致是先利用光罩經沈積與圖案化等製程在該基板 21上形成該導電塊結構221的第一、二導電塊224、225, 再由另一光罩經沈積與圖案化等製程,在該等第一、二導籲 電塊224、225上形成該等介電層膜223;而由於該導電電 極結構222 A連接該面板與該運算器的訊號傳輸線路91 (圖7)皆是可以金屬構成,故最後可直接利用光罩並經沈 積與圖案化等製程在該第一、二導電塊224、225及該等介 電層膜223上同時形成、共構該等第一、二導線227、228 及Λ號傳輸線路91 (圖7),也就是說,本發明並不需特別 為製作該等第一、二導線227、228而多-道光罩製程,反 而可令δ玄等一、二導線227、228與訊號傳輸線路Μ (圖鲁 )於同道光罩製程中共構完成,而作出觸控、作動更穩定 的觸控式感應元件2。 特别地,本發明觸控式感應元件2還可包含一透明電 極層24 ’ 4透a月電極層24連接於該基板η遠離該觸控式 感應電路22的另外__側’且與該觸控式感應電路22間有 —預定距離’而可遮蔽外界的干擾電荷與訊號。 參閱圖7,此外,本發明觸控式感應元件2還可包含- 12 201229842 電連接該觸控式感應電路22並可接收外界訊號的訊號傳輸 線路91,且該訊號傳輸線路91與該導電電極結構222共構 成型。 再需說明的是’當本發明的每一第一導電單元231上 的第一導線227沿該排第一導電單元231長度方向的總投 影長度與每一第一導電單元231沿該排第一導電單元231 長度方向的投影長度的比例為不小於95%,且第二導電單 元232長度方向的總投影長度與每一第二導電單元232沿 該排第二導電單元232長度方向的投影長度的比例亦為不 小於95%,並將該第一、二導線227、228拉出且再分別與 a又置於该基板21上的第—導通線92與第二導通線93形成 迴路,s亥第一導通線92將該等第一導電單元231全部電性 導通,且§亥第一導通線93將該等第二導電單元232全部電 性導通,則可相配合作為電磁式觸控面板的迴路,而應用 於電磁式感應觸控面板。 再需說明的是,上述的導電電極結構222的第一、二 導線227、228主要以低阻值的金屬構成,所以除了可以將 本發明觸控式感應元件2運用於電容式觸控面板外,當本 發明的每一第一導電單元231上的第一導線227沿該排第 一導電單兀231長度方向的總投影長度與每一第一導電單 兀231沿該排第一導電單元231長度方向的投影長度的比 例為loo%而為電性導通,且第二導電單元232長度方向的 總投影長度與每一第二導電單元232沿該排第二導電單元 232長度方向的投影長度的比例亦為1 〇〇%而為電性導通, 13 201229842 並將該第一、二導線227、228拉出且再分別與設置於該基 板21上的第一導通線92與第二導通線93形成迴路該第 一導通線92將該等第一導電單元231全部電性導通,且該 第二導通線93將該等第二導電單元232全部電性導通,則 可相配合作為電磁式觸控面板的迴路,而應用於電磁式感 應觸控面板。 參閱圖8,此外,該觸控式感應元件2還可包含一與該 導電電極結構222的第一、二導線227、228電連接的切換 開關94,該切換開關94可選擇地切換該任一第一、二導電 單兀231、232成一電導通狀態,及一斷路狀態,當該切換 開關94導通時形成迴路,可相配合作為電磁式觸控的迴 路’而作為電磁式觸控面板,當該切換開關94斷路時可作 為電容式觸控感應元件’如此可為兼具電磁式和電容式感 應觸控面板。該切換開關94可視所需要的環境而選擇地設 置在基板、觸控式感應電路周邊、周邊電路,及積體電路 上。 參閱圖9、圖10’圖1〇是相異於圖9的剖面方向的剖籲 視圖,本發明的一第二較佳實施例與該第一較佳實施例相 似’其不同處僅在於該基板21包括一第—表面2ιι,及_ 相反於該帛表面的第二表面212’該導電塊結構如的第 -導電塊224設置於該基板21的第—表面2ιι上且成間隔 陣列排列’該等第二導電塊225設置於該基板21的第二表 面212上且與該等第一導電塊224交錯分佈,每一連結塊 226連接兩相鄰之第_導電塊224,該第二較佳實施例還可 14 201229842 數排Γ第—導料224藉由該等連…26連結而成多 t排列的第一導電單元231’該等第二導電塊225透 J 導線228彼此電連接而成多數排間隔排列且投 衫與該等第—導電單元231交錯的第二導電單元232。The low-impedance of the thin conductive structure 222, while maintaining a fast and stable contact, can avoid the use of tin oxide or indium tin oxide, etc., which is a large-sized touch panel with a conductive structure of 201229842 as a conductive structure, which is caused by uneven film formation. Open circuit, inconsistent impedance or high-impedance line problems, resulting in inconsistent sensing effects, resulting in failure of touch response or poor linearity, or slow feedback response, or poor reproducibility of mass production. Therefore, it can be effective. Improve the process, and even the product yield. In addition, it should be noted that, in the manufacturing process of the touch sensing element 2 of the present invention, the first and second conductive blocks of the conductive block structure 221 are formed on the substrate 21 by a process such as deposition and patterning of the mask. 224, 225, and then another mask is deposited and patterned, and the dielectric layers 223 are formed on the first and second conductive portions 224, 225; and the conductive electrode structure 222 A The signal transmission line 91 (FIG. 7) connecting the panel and the operator can be made of metal, so that the first and second conductive blocks 224, 225 and the process can be directly used by the mask and deposited and patterned. The first and second wires 227 and 228 and the nickname transmission line 91 (FIG. 7) are simultaneously formed and co-constructed on the dielectric layer film 223, that is, the present invention does not need to be specially made for the first The two-wire 227, 228 and multi-channel mask process can make the δ Xuan et al. 227 and 228 and the signal transmission line 图 (Tulu) co-constructed in the same mask process, and make touch and actuation. Stable touch sensing element 2. In particular, the touch sensing element 2 of the present invention may further include a transparent electrode layer 24'4 connected to the substrate η from the other side of the touch sensing circuit 22 and connected to the touch The control sensing circuit 22 has a predetermined distance 'to shield the external interference charge and signal. Referring to FIG. 7 , the touch sensing element 2 of the present invention may further include a signal transmission line 91 electrically connected to the touch sensing circuit 22 and receiving an external signal, and the signal transmission line 91 and the conductive electrode Structure 222 is co-formed. It should be noted that 'the total projected length of the first wire 227 on each first conductive unit 231 of the present invention along the length direction of the first conductive unit 231 of the row and the first row of each first conductive unit 231 along the row The ratio of the projection length of the conductive unit 231 in the longitudinal direction is not less than 95%, and the total projection length of the second conductive unit 232 in the longitudinal direction and the projection length of each second conductive unit 232 along the length of the second conductive unit 232 in the row The ratio is also not less than 95%, and the first and second wires 227 and 228 are pulled out, and then the first conductive line 92 and the second conductive line 93, which are respectively placed on the substrate 21, form a loop. The first conductive line 231 is electrically connected to the first conductive unit 231, and the second conductive unit 232 is electrically connected to the second conductive unit 232, so as to cooperate with the electromagnetic touch panel. The circuit is applied to an electromagnetic induction touch panel. It should be noted that the first and second wires 227 and 228 of the conductive electrode structure 222 are mainly made of a low-resistance metal, so that the touch sensing element 2 of the present invention can be applied to the capacitive touch panel. When the first conductive line 227 on each of the first conductive units 231 of the present invention has a total projected length along the length direction of the first conductive unit 231 of the row, and each of the first conductive units 231 along the first conductive unit 231 of the row The ratio of the projection length in the length direction is loo% and is electrically conductive, and the total projection length of the second conductive unit 232 in the longitudinal direction and the projection length of each second conductive unit 232 along the length of the second conductive unit 232 in the row The ratio is also 1% and is electrically conductive, 13 201229842 and the first and second wires 227, 228 are pulled out and respectively connected to the first conductive line 92 and the second conductive line 93 disposed on the substrate 21. The first conductive line 231 is electrically connected to the first conductive line 231, and the second conductive unit 232 is electrically connected to the second conductive unit 232. Panel loop, and An electromagnetic sensing a touch panel to be used. Referring to FIG. 8 , the touch sensing element 2 can further include a switch 94 electrically connected to the first and second wires 227 , 228 of the conductive electrode structure 222 , and the switch 94 can selectively switch any of the switches The first and second conductive single turns 231, 232 are in an electrical conduction state, and a disconnected state, when the switch 94 is turned on, a loop is formed, which can be used as an electromagnetic touch circuit as an electromagnetic touch panel. When the switch 94 is disconnected, it can be used as a capacitive touch sensing element. Thus, it can be an electromagnetic and capacitive sensing touch panel. The switch 94 is selectively disposed on the substrate, the periphery of the touch sensing circuit, the peripheral circuit, and the integrated circuit depending on the required environment. Referring to FIG. 9 and FIG. 10', FIG. 1A is a cross-sectional view different from the cross-sectional direction of FIG. 9. A second preferred embodiment of the present invention is similar to the first preferred embodiment. The difference is only in the The substrate 21 includes a first surface 2 ιι, and a second surface 212 ′ opposite to the 帛 surface. The conductive block structure, such as the first conductive block 224, is disposed on the first surface 2 ι of the substrate 21 and arranged in a spaced array. The second conductive blocks 225 are disposed on the second surface 212 of the substrate 21 and are staggered with the first conductive blocks 224. Each of the connecting blocks 226 is connected to two adjacent conductive blocks 224. The preferred embodiment can also be 14 201229842. The first conductive unit 231 ′′ is connected by the connection 26 and the second conductive blocks 225 are electrically connected to each other through the J wires 228. The second conductive unit 232 is arranged in a plurality of rows and is tentatively staggered with the first conductive units 231.
邊第二較佳實施_由以該基板21作為介電層或絕緣 ,可降低本發明觸控式感應元件2的成本, 在該基…第一表面211與第二表面222形成該3 、-導電塊224、225和連結塊226及該等第—、二導線 227 228 ’而不需要另外沉積介電層膜,更為精簡製程所 需時間與複雜程度。 ^上所述,本發明主要是利用分別設置於第一二導 電塊224、225的第—、二導線227、似,降低觸控式感應 凡件2整體的等效面阻抗,且可避免導電塊Mi結構因成 膜不均致觸控反應失效或線性不佳的機率或高阻抗線路等 門題’並提冋作動時的反應速率’而適於應用在大尺寸的 電谷式觸控面板’故確實能達成本發明之目的。故確實能 達成本發明之目的。 惟以上所述者,僅為本發明之較佳實施例而已,當不 能以此限定本發明實施之範圍,即大凡依本發明申請專利 範圍及發明說明内容所作之簡單的等效變化與修飾皆仍 屬本發明專利涵蓋之範圍内。 15 201229842 【圖式簡單說明】 圖1是一俯視示意圖’說明目前一觸控式感應元件; 圖2是一剖視示意圖’說明該觸控式感應元件的一第 一導電單元; 圖3是一刳視示意圖,說明該觸控式感應元件的一第 二導電單元; 圖4是一俯視示意圖,說明本發明觸控式感應元件的 第一較佳實施例; 圖5是一剖視示意圖,說明該第一較佳實施例的一第 —導電單元; 圖6疋一剖視示意圖,說明該第一較佳實施例的一第 二導電單元; 圖7是一俯視示意圖,說明本發明觸控式感應元件作 為電磁式的觸控式感應元件; 圖8是-俯視示意圖,說明本發明觸控式感應元件可 作為兼具電容式的觸控式感應元件和電磁式的觸控式感應 之元件; 圖9是一剖視示意圖,說明該第二較佳實施例的一第 —導電單元;及 圖10是-剖視示意圖,說明該第二較佳實施例的一第 二導電單元。 201229842 【主要元件符號說明】 2 ....... …觸控式感應元件 228… •…第二導線 21…… 基板 231… •…第一導電單元 211 ··· —第 表面 232 ·· •…第二導電單元 212 ···· …第二表面 233… •…電容感應單元 22…… …·觸控式感應電路 24… •…透明電極層 221 ···· …·導電塊結構 91 ••… •…訊號傳輸電路 222 ···· …·導電電極結構 92…·· •…第一導通線 223 ··· •…介電層膜 93 •…第一導通線 224 ··· …·第一導電塊 94…·. •…切換開關 225 ·· …第二導電塊 Y…… •…第一方向 226 …. •…連結塊 X…… •…第二方向 227 ··· …·第一導線According to the second preferred embodiment, the cost of the touch sensing element 2 of the present invention can be reduced by using the substrate 21 as a dielectric layer or insulation, and the first surface 211 and the second surface 222 form the 3, The conductive blocks 224, 225 and the connecting block 226 and the first and second wires 227 228 ' do not require additional deposition of a dielectric film, which simplifies the time and complexity required for the process. As described above, the present invention mainly utilizes the first and second wires 227 respectively disposed on the first two conductive blocks 224 and 225 to reduce the equivalent surface impedance of the touch sensing device 2 and avoids conduction. The block Mi structure is suitable for application in large-sized electric valley touch panels due to uneven film formation, such as failure of touch reaction or poor linearity or high-impedance line, and the reaction rate when the actuator is actuated. 'It is indeed possible to achieve the object of the present invention. Therefore, the object of the present invention can be achieved. The above is only the preferred embodiment of the present invention, and the scope of the present invention is not limited thereto, that is, the simple equivalent changes and modifications made by the scope of the invention and the description of the invention are all It is still within the scope of the invention patent. 15 201229842 [Simplified Schematic] FIG. 1 is a top plan view illustrating a touch sensing element; FIG. 2 is a cross-sectional view illustrating a first conductive unit of the touch sensing element; FIG. FIG. 4 is a top plan view showing a first preferred embodiment of the touch sensing element of the present invention; FIG. 5 is a cross-sectional view showing the first embodiment of the touch sensing element; A first conductive unit of the first preferred embodiment; FIG. 6 is a cross-sectional view showing a second conductive unit of the first preferred embodiment; FIG. 7 is a top plan view showing the touch control of the present invention. The sensing element is used as an electromagnetic touch sensing element; FIG. 8 is a top plan view showing the touch sensing element of the present invention as a capacitive touch sensing element and an electromagnetic touch sensing component; Figure 9 is a cross-sectional view showing a first conductive unit of the second preferred embodiment; and Figure 10 is a cross-sectional view showing a second conductive unit of the second preferred embodiment. 201229842 [Description of main component symbols] 2 ....... Touch sensing element 228... •...Second wire 21... Substrate 231... •...First conductive unit 211 ··· — Surface 232 ·· • Second conductive unit 212 • Second surface 233... • Capacitance sensing unit 22... Touch sensing circuit 24... • Transparent electrode layer 221 ·······Conductive block structure 91 ••... •...signal transmission circuit 222 ······conducting electrode structure 92...···...first conduction line 223 ···•...dielectric layer film 93•...first conduction line 224 ··· ... • First conductive block 94...·.•...Switching switch 225··...Second conductive block Y...•...first direction 226 .... •...linking block X... •...second direction 227 ··· ...· First wire
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