M430654 五、新型說明: 【新型所屬之技術領域】 本創作是有關於一種觸控面板,且特別是有關於一種 具有高光線穿透率的觸控面板。 【先前技術】 在現今之資訊社會下,人們對電子產品之依賴性與曰 倶增。舉凡行動電話(mobile phone )、掌上型電腦(handheld pC )、個人化數位助理(Personal Digitai Assistance,pDA ) 或是智慧型手機(smart phone)等電子產品在生活中隨處可 見。為了達到更便利、體積更輕巧化以及更人性化的目的, 許多資訊產品已由傳統之鍵盤或滑鼠等輸入裝置,轉變為 使用觸控面板(touch panel)作為輸入裝置,其中同時具 有觸控與顯示功能的觸控顯示面板更是成為現今最流行的 產品之一。 一般而a,觸控顯示面板包括顯示面板與觸控面板, 其中觸控面板可内建於顯示面板中或外貼於顯示面板上。 觸控面板通常包括多個沿著X軸方向延伸之第一感測串 列,以及多個沿著Y軸方向延伸之第二感測串列,其中每 一第一感測串列與每一第二感測串列分別具有串接的多個 感測墊。當以手指觸碰觸控面板時,會改變感測墊之間的 電容,將此改變訊號傳回控制器,即可計算接觸發生點之 座標,進而使得顯示面板可以根據使用者的選擇而進行顯 禾畫面的改變。 * WJU654 率,會,為了使觸控面板具有高透光 料具有電阻值較高與原==:然而’透明導電材 【新型内容】 透性本創作提供—_控面板’其具有良好的電性與光穿 is a本創作提出—種觸控面板,其包括一其; ☆St基板具有-觸控A環= 層包層配置於基板_控區。感測_ 夕條第一感測串列與多條第二感測串列。每一第一 =串顺每-第二感測串列分別具有串接的多個網_ 蛩’其中每一網狀感測墊係由多條彼此平行的第一條狀 導電圖案以及多條彼此平行的第二條狀導電圖案所構成, ,第一條狀導電圖案與第二條狀導電圖案彼此交錯而構成 夕個孔洞。周邊線路配置於基板的周邊區,其中每一周邊 線路與其中一第一感測串列或其中一第二感測串列電性連 接’且周邊線路的材質與感測電極層的材質實質上相同。 在本創作之一實施例中,上述之感測電極層的材質包 ^ 導電高分子材料或一金屬。 在本創作之一實施例中’上述之每一第一條狀導電圖 案的線寬介於0.5微米至10微米之間,而每一第二條狀導 電圖案的線寬介於〇·5微米至10微米之間。 在本創作之一實施例中,上述之金屬包括紹、銅、鉬、 5 M430654 敛、銀、金、鉑及其合金。 作之一實施例中,上述之導電高分子材料包括 艰本乙烯磺酸、聚苯胺或摻雜有金屬粒子的古八子匕祜 括透日實賴f,上述之感測電=的材質包 幸乍之一實施例中’上述之每—第一條狀導電圖 於8微米至細微米之間,而每一第二條狀導 电園案的線寬介於8微米至200微米之間。 ^創作之一實施例中,上述之透明導電材料包括铜 錫乳化物或銦鋅氧化物。 f本創作之一實施例中,上述之觸控面板的開口率大 於90%以上。 ,基於上述,在本創作之觸控面板中,每一網狀感測墊 係由多條彼此平行㈣—條狀導f圖f以及多條彼此平行 的第二條狀導電圖案所構成,其中第-條狀導電圖案與第 二條狀導電難彼此交錯啸成乡個孔洞。如此—來,可 使得感測電極層兼具有高級穿透率與低電阻值的優點。 此外’由關邊線_材質與感職極層的材質實質上相 同,因此可有效提升本創作之觸控面板的觸控電性且可節 省製作成本。 為讓本;作之上述特徵和優點能更 舉實施例,並配合所附圖式作詳細說明如下 【實施方式】 M430654 圖i為本創作之-實施例之-種觸控面板的俯視示意 圖。請參考目1’在本實施例+,觸控面板1〇〇a包括一基 板U0、一感測電極層120a以及多條周邊線路13〇。詳二 來說,基板11〇具有一觸控區112及一環繞觸控區112之 周邊逐114。感測電極層論配置於基板UG的觸控區 112。感測電極層包括多條第一感測串列122a與多條 第二感測串列124a。每一第一感測串列U2a具有串接的 多個網狀感測墊123a,而母一第二感測串列124a具有串 接的多個網狀感測塾125a。特別是’每一網狀感測墊 及母一網狀感測塾125a皆是由多條彼此平行的第一條狀 導電圖案127a以及多條彼此平行的第二條狀導電圖案 129a所構成,且第一條狀導電圖案127a與第二條狀導電 圖案129a彼此交錯而構成多個孔洞η。周邊線路13〇配置 於基板110的周邊區114,其中每一周邊線路114與其中 一第一感測串列122a或其中一第二感測串列124a電性連 接,且周邊線路130的材質與感測電極層i2〇a的材質實質 上相同。 如圖1所示,本實施例之第一感測串列122a是沿著 一第一方向D1延伸並配置於基板110上,且不同的第一 感測串列122a彼此係相互電性絕緣。第二感測串列124a 是沿著一第二方向D2延伸並配置於基板110上’且不同 的第二感測串列124a彼此係相互電性絕緣。此外,第二方 向D2與第一方向D1實質上相交。在本實施中,第一方向 D1與第二方向D2可以相互垂直,或者在變化實施例中, 7 M430654 第一方向D1與第二方向D2之間的夾角可為其他不為90。 的角度。 更具體來說,本實施例之感測電極層12〇a的材質例 如是一導電高分子材料或一金屬’其中金屬例如是銘、銅、 鉬、鈦、銀、金、鉑及其合金,而導電高分子材料例如是 聚苯乙烯磺酸、聚苯胺或摻雜有金屬粒子的高分子。於此, 感測電極層120a是採用具有遮蔽性的材料,較佳地,每一 第一條狀導電圖案127a的線寬例如是介於〇.5微米至10 微米之間,而每一第二條狀導電圖案129a的線寬例如是介 於0.5微米至1〇微米之間。此外,本實施例之觸控面板 100a的開口率例如是大於90%以上。 由於本實施例可採用金屬來做為感測電極層120a的 材料,其中金屬具有良好導電性與延展性,因此本實施例 之觸控面板100a的面阻抗可有效降低且可有效提高導電 性。再者,由於本實施例之觸控面板l〇〇a之網狀感測墊 123a、125a係由第一條狀導電圖案127a與第二條狀導電 圖案129a所構成,且第一條狀導電圖案127a與第二條狀 導電圖案129a彼此父錯而構成孔洞Η ’因此可有效提局本 實施例之觸控面板100a的光線穿透率。於此,由於孔洞Η 的分布可使得網狀感測墊123a、125a具有足夠的光穿透率 而可作為觸控面板100a的感測電極層120a。因此,設計 者可以依照不同的需求調整孔洞Η的分布密度及尺寸大小 以獲得所需的感測電極層120a的性質。此外,由於周邊線 路130的材質與感測電極層120a的材質實質上相同,因此 8 M430654 可有效提升本實施例之_祕雜關控電性且可節 省製作成本。 、 在此必須說明的是,下述實施例沿用前述實施例的元 件標號與部㈣容,其巾_相同的標絲表示相同或近 似的元件,並且省略了相同技_容的綱。關於省略部 分的說明可參考前述實施例,下述實施例不再重複贅述。 圖2為本創作之另一實施例之一種觸控面板的俯視示 意圖。請參考圖2,本實施例之觸控面板1〇〇b與圖1之觸 控面板100a相似,惟二者主要差異之處在於:本實施例之 觸控面板100b的感測電極層120b的材質例如是透明導電 材料,其中透明導電材料例如是銦錫氧化物或銦鋅氧化 物。較佳地,每一第一條狀導電圖案127b的線寬例如是介 於8微米至200微米之間,而每一第二條狀導電圖案12% 的線寬例如是介於8微米至200微米之間。 本實施例可採用透明導電材料來做為感測電極層 120b的材料,且第一感測串列122b與第二感測串列124b 的網狀感測墊123b、125b係由第一條狀導電圖案127b與 第二條狀導電圖案129b所構成,且第一條狀導電圖案12^ 與第二條狀導電圖案129b彼此交錯而構成孔洞η,。如此 一來’可有效提高本實施例之觸控面板l〇〇b的光線穿透 率’且可透過孔洞H,的設計來降低感測電極層12%的面 阻抗,而使觸控面板100b具有低電阻值的優點。 值得一提的是,本創作並不限定孔洞H&H,的形狀, 雖然此處所提及的孔洞Η、H,具體化的形狀為矩形。^曰,’ 9 的實施例t,孔洞…,亦可依據第-條狀 編I士:: _a、127b與第二條狀導電圖案129a、129b的 而形成任意形狀,例如是菱形,對此本創作 並不加以限制。 後i Γ上所4,在本創作之觸控面板t,每感測塾 的夕條彼此平行㈣—條狀導電_以及多條彼此平行 的f二條狀導電圖案所構成,其中第-條狀導電圖案與第 -,狀導電圖案彼此交錯而構成多個孔洞。如此一來,可 感測電極層兼具有高光線穿透率與低電阻值的優點。 一 由於周邊線路的材質與感測電極層的材質實質上相 同因此可有效提升本創作之觸控面板的觸控電性且可節 省製作成本。 雖”、丨本創作已以實施例揭露如上,然其並非用以限定 創作’任何所屬技術領域中具有通常知識者,在不脫離 ^幻作之精神和範_,當可作些許之更動與潤飾,故本 lj作之保護範圍當視後附之申請專利範圍所界定者為準。 【圖式簡單說明】 圖1為本創作之一實施例之一種觸控面板的俯視示意 3 〇 圖2為本創作之另一實施例之一種觸控面板的俯視示 【主要元件符號說明】 M430654 100a、100b :觸控面板 110 :基板 112 :觸控區 114 :周邊區 120a :感測電極層 122a、122b :第一感測串列 123a、123b、125a、125b :網狀感測墊 124a、124b :第二感測串列 127a、127b :第一條狀導電圖案 129a、129b :第二條狀導電圖案 130 :周邊線路 Η、H’ :孔洞 D1 :第一方向 D2 :第二方向 11M430654 V. New Description: [New Technology Field] This creation is related to a touch panel, and in particular to a touch panel with high light transmittance. [Prior Art] In today's information society, people's dependence on electronic products has increased. Electronic products such as mobile phones, handheld pCs, personal Digitai Assistance (pDA) or smart phones are everywhere in life. In order to achieve more convenience, lighter weight and more humane purposes, many information products have been converted from traditional keyboards or mouse input devices to touch panels as input devices, with touch at the same time. The touch display panel with display function is one of the most popular products today. Generally, the touch display panel includes a display panel and a touch panel, wherein the touch panel can be built in the display panel or externally attached to the display panel. The touch panel generally includes a plurality of first sensing series extending along the X-axis direction, and a plurality of second sensing series extending along the Y-axis direction, wherein each of the first sensing series and each The second sensing series respectively have a plurality of sensing pads connected in series. When the touch panel is touched by the finger, the capacitance between the sensing pads is changed, and the change signal is transmitted back to the controller to calculate the coordinates of the contact occurrence point, so that the display panel can be selected according to the user's selection. The change of the picture. * WJU654 rate, will, in order to make the touch panel have high light-transmissive material with high resistance value and original ==: However, 'transparent conductive material [new content] permeability, this creation provides -_ control panel' which has good electricity Sexuality and light wear is a kind of touch panel, which includes one; ☆St substrate has - touch A ring = layer cladding layer is arranged in the substrate_control area. Sensing _ the first sensing series and the plurality of second sensing series. Each of the first=string-per-second sensing series respectively has a plurality of nets connected in series, wherein each of the mesh sensing pads is composed of a plurality of first strip-shaped conductive patterns parallel to each other and a plurality of strips The second strip-shaped conductive pattern parallel to each other is formed, and the first strip-shaped conductive pattern and the second strip-shaped conductive pattern are staggered with each other to form a hole. The peripheral circuit is disposed in a peripheral area of the substrate, wherein each of the peripheral lines is electrically connected to one of the first sensing series or one of the second sensing series and the material of the peripheral line and the material of the sensing electrode layer are substantially the same. In an embodiment of the present invention, the sensing electrode layer is made of a conductive polymer material or a metal. In one embodiment of the present invention, 'the line width of each of the first strip-shaped conductive patterns is between 0.5 micrometers and 10 micrometers, and the line width of each second strip-shaped conductive pattern is between 5 micrometers and 5 micrometers. Between 10 microns. In one embodiment of the present invention, the above metal includes slag, copper, molybdenum, 5 M430654, silver, gold, platinum, and alloys thereof. In one embodiment, the conductive polymer material comprises a difficult ethylene sulfonic acid, a polyaniline or an antimony doped with a metal particle, and the material of the above-mentioned sensing electric= In one embodiment, each of the above-described first strip-shaped conductive patterns is between 8 micrometers and fine micrometers, and each second strip-shaped conductive pattern has a line width of between 8 micrometers and 200 micrometers. In one embodiment of the invention, the transparent conductive material described above comprises a copper tin emulsion or an indium zinc oxide. In one embodiment of the present invention, the aperture ratio of the touch panel described above is greater than 90%. Based on the above, in the touch panel of the present invention, each of the mesh sensing pads is composed of a plurality of parallel (four)-strip-shaped conductive patterns f and a plurality of second conductive conductive patterns parallel to each other, wherein The first strip-shaped conductive pattern and the second strip-shaped conductive layer are difficult to cross each other to form a hole. In this way, the sensing electrode layer can have the advantages of high transmittance and low resistance. In addition, the material of the edge line _ material and the sensory layer is substantially the same, so that the touch power of the touch panel of the present invention can be effectively improved and the production cost can be saved. The above features and advantages of the present invention will be described in detail with reference to the accompanying drawings. [Embodiment] FIG. 1 is a top plan view of a touch panel of the present invention. Referring to FIG. 1', in the present embodiment, the touch panel 1A includes a substrate U0, a sensing electrode layer 120a, and a plurality of peripheral lines 13A. In detail, the substrate 11 has a touch area 112 and a periphery around the touch area 112. The sensing electrode layer is disposed on the touch area 112 of the substrate UG. The sensing electrode layer includes a plurality of first sensing series 122a and a plurality of second sensing series 124a. Each of the first sensing series U2a has a plurality of mesh sensing pads 123a connected in series, and the mother-second sensing series 124a has a plurality of mesh sensing ports 125a connected in series. In particular, each of the mesh sensing pads and the mother-mesh sensing electrodes 125a are composed of a plurality of first strip-shaped conductive patterns 127a parallel to each other and a plurality of second strip-shaped conductive patterns 129a parallel to each other. And the first strip-shaped conductive pattern 127a and the second strip-shaped conductive pattern 129a are staggered with each other to form a plurality of holes η. The peripheral line 13 is disposed in the peripheral area 114 of the substrate 110. Each of the peripheral lines 114 is electrically connected to one of the first sensing series 122a or one of the second sensing series 124a, and the material of the peripheral line 130 is The material of the sensing electrode layer i2〇a is substantially the same. As shown in FIG. 1, the first sensing series 122a of the present embodiment extends along a first direction D1 and is disposed on the substrate 110, and the different first sensing series 122a are electrically insulated from each other. The second sensing series 124a extends along a second direction D2 and is disposed on the substrate 110' and the different second sensing series 124a are electrically insulated from each other. Further, the second direction D2 substantially intersects the first direction D1. In this embodiment, the first direction D1 and the second direction D2 may be perpendicular to each other, or in a variant embodiment, the angle between the first direction D1 and the second direction D2 of the 7 M430654 may be other than 90. Angle. More specifically, the material of the sensing electrode layer 12〇a of the embodiment is, for example, a conductive polymer material or a metal, wherein the metal is, for example, ingot, copper, molybdenum, titanium, silver, gold, platinum, and alloys thereof. The conductive polymer material is, for example, polystyrenesulfonic acid, polyaniline or a polymer doped with metal particles. Herein, the sensing electrode layer 120a is made of a material having shielding properties. Preferably, the line width of each of the first strip-shaped conductive patterns 127a is, for example, between 微米.5 micrometers and 10 micrometers, and each of the first The line width of the two strip-shaped conductive patterns 129a is, for example, between 0.5 μm and 1 μm. Further, the aperture ratio of the touch panel 100a of the present embodiment is, for example, more than 90%. Since the metal can be used as the material of the sensing electrode layer 120a, wherein the metal has good conductivity and ductility, the surface resistance of the touch panel 100a of the present embodiment can be effectively reduced and the conductivity can be effectively improved. Furthermore, the mesh sensing pads 123a, 125a of the touch panel 10a of the present embodiment are composed of a first strip-shaped conductive pattern 127a and a second strip-shaped conductive pattern 129a, and the first strip-shaped conductive pattern The pattern 127a and the second strip-shaped conductive pattern 129a are mutually wrong to form a hole Η', so that the light transmittance of the touch panel 100a of the present embodiment can be effectively improved. Here, the distribution of the holes 可 can make the mesh-shaped sensing pads 123a, 125a have sufficient light transmittance to serve as the sensing electrode layer 120a of the touch panel 100a. Therefore, the designer can adjust the distribution density and size of the hole 依照 according to different needs to obtain the desired properties of the sensing electrode layer 120a. In addition, since the material of the peripheral line 130 is substantially the same as the material of the sensing electrode layer 120a, the 8 M430654 can effectively improve the controllability of the embodiment and save the manufacturing cost. It is to be noted that the following embodiments follow the element numbers of the foregoing embodiments and the parts (4), and the same reference numerals indicate the same or similar elements, and the same technique is omitted. For the description of the omitted portions, reference may be made to the foregoing embodiments, and the following embodiments will not be repeated. 2 is a top plan view of a touch panel according to another embodiment of the present invention. Referring to FIG. 2, the touch panel 1b of the present embodiment is similar to the touch panel 100a of FIG. 1, but the main difference is that the sensing electrode layer 120b of the touch panel 100b of the present embodiment is The material is, for example, a transparent conductive material, wherein the transparent conductive material is, for example, indium tin oxide or indium zinc oxide. Preferably, the line width of each of the first strip-shaped conductive patterns 127b is, for example, between 8 micrometers and 200 micrometers, and the line width of each second strip-shaped conductive pattern is, for example, 8 micrometers to 200 micrometers. Between microns. In this embodiment, a transparent conductive material can be used as the material of the sensing electrode layer 120b, and the mesh sensing pads 123b and 125b of the first sensing series 122b and the second sensing series 124b are formed by the first strip. The conductive pattern 127b and the second strip-shaped conductive pattern 129b are formed, and the first strip-shaped conductive pattern 12^ and the second strip-shaped conductive pattern 129b are staggered with each other to form a hole η. Therefore, the light transmittance of the touch panel 10b of the present embodiment can be effectively improved and the hole H can be designed to reduce the surface resistance of the sensing electrode layer by 12%, so that the touch panel 100b Has the advantage of low resistance value. It is worth mentioning that the creation does not limit the shape of the hole H&H, although the holes Η, H mentioned here are embodied in a rectangular shape. ^曰, the embodiment t of the '9, the hole... can also be formed into any shape according to the first strip-shaped I:: _a, 127b and the second strip-shaped conductive patterns 129a, 129b, for example, a diamond shape, This creation is not limited. In the second touch panel t, in the touch panel t of the present invention, each of the sensing strips is parallel to each other (four) - strip-shaped conductive _ and a plurality of fr-shaped conductive patterns parallel to each other, wherein the strip-shaped strip The conductive pattern and the first-shaped conductive pattern are staggered with each other to form a plurality of holes. As a result, the electrode layer can be sensed to have both high light transmittance and low resistance. Since the material of the peripheral line and the material of the sensing electrode layer are substantially the same, the touch electric property of the touch panel of the present invention can be effectively improved and the manufacturing cost can be saved. Although, 丨本 creation has been exposed as above in the examples, but it is not intended to limit the creation of any of the technical fields of the ordinary knowledge, without leaving the spirit and scope of the illusion, when some changes and retouching can be made Therefore, the scope of protection of the present invention is subject to the definition of the patent application scope. [FIG. 1] FIG. 1 is a top view of a touch panel according to an embodiment of the present invention. FIG. A top view of a touch panel according to another embodiment of the present invention [main element symbol description] M430654 100a, 100b: touch panel 110: substrate 112: touch area 114: peripheral area 120a: sensing electrode layers 122a, 122b : first sensing series 123a, 123b, 125a, 125b: mesh sensing pads 124a, 124b: second sensing series 127a, 127b: first strip conductive patterns 129a, 129b: second strip conductive patterns 130: Peripheral line Η, H': Hole D1: First direction D2: Second direction 11