I3238U4 六、發明說明: . 【發明所屬之技術領域】 - 本發明劍於—種電路元件連接結構及使用該電路元件連接結構 • 之液晶顯示面板。 . 【先前技術】 液晶顯示裝置因其具有低輕射性、輕薄短小及耗電低等特點,故 於使用上日漸廣泛,且隨著綱技術之絲及鑛,其種類亦日益繁 鲁多。 、里’、 採用主動矩陣陣列之液晶顯示裝置一般包括設置於同一基板之複 數閘極線及源極線相互交又形成之像素區域及複數設置於間極線及源 極線父叉處之薄膜電晶體(丁1!111朽11111^118181〇1*,丁1^),其中,每一像素 區域有-像素電極’該薄膜電晶體用於控制該像素電極之開關。 該閘極線及源極線分別與閘極驅動IC及源極驅動汇連接,以提 供驅動訊賴人至_電晶體’啟動像素區域。該酿驅動『及源極 _驅動1C藉由軟性電路板與印刷電路板連接。該驅動IC與基板之間、 "亥軟性電路板與基板之間、該軟性電路板與印刷電路板之間等電路元 +連接、,ό構通吊使用異方性導電薄膜(Anisotropic Conductive Film, ACF)貫現機械連接及電性連接。 請參閱第—圖,一種先前技術液晶顯示裝置1包括一液晶面板 10、一背光模組20及外框30。該背光模組20功能在於向液晶面板10 提供輝度充分而且分佈均勻的面光源。該外框3〇用於收容該液晶面板 W與背光模組20。 3 ^23804 請一併參閱第二、三圖,第二圖係第—圖中沿線Π-Π之剖面結構 不意圖’第三圖係第i中沿線則!之剖面結構示意圖。該液晶面 板10包括第-基板u、第二基板12及夾於該第一基板u與第二基 板U之間之液晶層U。在第一基板u之相鄰兩側邊緣包括貼附叫 _附區域通常由異方性導電薄膜15所覆蓋。貼附區域中,承載驅動 1C 之區域為連接區域。連接區域中,驅動ΐ(: 14藉由異方性導電薄 膜15與第-基板U實現機械連接及電性連接。驅動ic μ之間之區 域為間隔區域。 該財性導電_ 15係通過鹤分子樹脂(如魏樹脂或丙稀酸 ’月曰内政佈^電粒子製成,並且在該異方性導電薄膜b之一個表面 上設置-隔離膜。貼附驅動IC 14時,低溫下先將異方性導電薄膜Μ p於貼_域,娜異方性導電_15之隔離膜,再將驅動㈣ 至於連接區域’高溫下加麗於驅動IC 14上實現連接。 惟’貼附區域t ’由於連接區域具有閘極線或源極線之連接 因此連接區域與間隔區域之間存在高度差。讎中 及=並沒有充分地傳送至間隔區域之異方性導電_備之= =域::_電_15嫩㈣合_。獅隔二 影塑電薄膜15在間隔區域内浮起甚至斷裂捲起,從而 二=異方性料賴15絲板11之私_,降低連接 縣敝歸伽嫩減少異方 里准’麵晶面板10中,覆蓋間隔區域之異 1323804 方性導電薄膜15增加了異方性導電薄膜15之使用量,增加成本。 【發明内容】 有鑑於此’提供一種可靠性高、成本低之液晶顯示面板實為必需。 -· 本發明還提供一可靠性高、成本低之電路元件連接結構。 . 本發明之一實施方式揭示了一種液晶顯示面板,其包括一第一基 板、一與第一基板相對設置第二基板、一位於該二基板之間液晶層, 该第一基板上設有貼附區域,該貼附區域包括一源極貼附區域及一閘 鲁極貼附區域,其中該閘極貼附區域及該源極貼附區域均包括連接區域 及間隔區域’·'該間隔區域位於兩個相鄰之連接區域之間;異方性導電 薄膜覆蓋於源極貼附區域的連接區域及間隔區域,覆蓋於閘極貼附區 域的連接區域;複數驅動1C其藉由該異方性導電薄膜連接於源極貼附 區域及閘極貼附區域的連接區域。 本發明之另一實施方式揭示了一種電路元件連接結構,其包括一 承载基板、複數連接元件、異方性導電薄膜,該承載基板上設有貼附 •區域,該貼附區域包括一源極貼附區域及一閘極貼附區域,其中該閘 極貼附區域及該源極貼附區域均包括連接區域及間隔區域,該間隔區 域位於兩個相鄰之連接區域之間,該異方性導電薄膜覆蓋於源極貼附 區域的連接區域及間隔區域,覆蓋於閘極貼附區域的連接區域,該連 接兀件藉由該異方性導電薄膜連接於源極貼附區域及閘極貼附區域的 連接區域。 與先4技術相比,本發明之液晶顯示面板或電路元件連接結構具 有如下優點:該液晶顯示面板或電路元件連接結構之異方性導電薄膜 5 ,隔的設置於該貼_域上’也就是於間隔區域並不設置異方性導電 •溥膜或僅在部份間隔區域並設置異方性導電_,麵異方性導電= ·.膜後’剝離隔離膜時並不影響異方性導電薄膜與基板之齡強度电因 •,此連接可靠性^並且,該液晶顯示面板或電路元件連接結構二少了 .異方性導電薄膜之使用量,成本低。 【實施方式】 —睛-併參閱第四、五、六圖,第四圖係本發明液晶顯示面板第一 鲁實施方式之結構示意圖,第五圖係第四圖中沿線ν·ν之剖面結構示音 圖’第六圖係第四圖中沿線VI_VI之剖面結構示意圖。練晶顯示面 板100包括-第-基板11〇、一與第一基板11〇姉設置之第二基板 120、一位於該二基板11〇、12〇間之液晶層⑽。 在第基板110之相鄰兩側邊緣分別包括源極貼附區域i口及問 極貼附區域118,該二貼附區域117、118包括連接區域及間隔區域。 其中’承載驅動1C 114之區域為連接區域,軸IC 114之間之區域為 φ門隔區域異方}•生導電薄膜出分別間隔的設置於貼附區域m、118 中P連接區域《又置異方性導電薄膜115,間隔區域則不設置異方性 導電薄膜115連接區域中’驅動Ic 114藉由異方性導電薄膜與 第一基板110實現連接。 業界中’對於17时液晶顯示面板,通常在源極貼附區域117貼附 1〇顆驅動1(:114’在閘極貼附區域118貼附4顆驅動1(:114,先前技 術令而要使用約513·6 %米異方性導電薄膜i 1S,本發明中則僅需使用 約26〇·2笔米異方性導電薄膜m。對於M忖液晶顯示面板,通常在 6 1323804 源極貼附區域117貼附8顆驅動IC 114,在閘極貼附區域118貼附3 顆驅動1C 114,先前技術中需要使用約4287毫米異方性導電薄膜 • 115,本發明中則僅需使用約2〇29毫米異方性導電薄膜115。因此, ’本發明可有效的減少異方性導電薄膜115之使用量,極大的降低成本。 ; 同時,由於本發明間隔區域並不設置異方性導電薄膜115,預壓 異方性導電薄膜115之連接區域後,剝離隔離膜時並不影響異方性導 電薄膜115與第一基板11〇之粘合強度,因此連接可靠性高。 • 請參閱第七圖,係本發明液晶顯示面板第二實施方式之結構示意 圖。該液晶顯示面板200與液晶顯示面板1〇〇之結構大致相同,其區 別在於:於源極貼附區域217,異方性導電薄膜215覆蓋該源極貼附 區域217;於閘極貼附區域218 ’異方性導電薄膜215貼附於連接區域。 請參閱第八圖,係本發明液晶顯示面板第三實施方式之結構示意 圖。該液晶顯示面板300與液晶顯示面板1〇〇之結構大致相同,其區 別在於:於源極貼附區域317 ’異方性導電薄膜315貼附於連接區域; 擊於閘極貼附區域318,異方性導電薄膜315覆蓋該閘極貼附區域318。 請參閱第九圖,係本發明液晶顯示面板第四實施方式之結構示专 圖。該液晶顯示面板400與液晶顯示面板1〇〇之結構大致相同,其區 別在於:於源極貼附區域417,部份間隔區域設置異方性導電薄膜 415 ;於閘極貼附區域418 ’部份間隔區域亦設置異方性導電薄膜415。 在液晶顯示裝置中’其它需使用異方性導電薄膜之電路元件連接 結構,如軟性電路板與基板之間、軟性電路板與印刷電路板之間之連 接,同樣可採用本發明於間隔區域不設置異方性導電薄膜或者僅在部 7 份設置異方性導電薄臈之結構。 本發明中’該液晶顯示面板或電路元件連接結構之異方性 導電薄 膜間隔的設置_貼_域上,也就是關隔_並不設置異方 電薄膜或贴部份間_輕置異柿導電細,讎異方性 膜後,剝隔離_並不影響異方性導㈣膜與基板之齡強度,因: 連接可祕尚。並且’該液晶顯示面板錢路元件連接結構減少 方性導電薄膜之使用量,成本低。 厂" 綜上所述,本發明確已符合發明之要件,爰依法提出專利申姓 惟,以上職者僅林發明德⑽财式,本發权關並不Z 逃貫施方式祕,舉凡„本紐藝之人士援依本發明 等效修倚或變化,皆應涵蓋於以下申請專利範圍内。 之 【圖式簡單說明】 第一圖係先前技術液晶顯示裝置之結構示意圖。 第二圖係第—圖中沿線IWI之剖面結構示意圖。 •第三圖係第一圖中沿線ΙΠ-ΙΙΙ之剖面結構示意圖。 第四圖係本發晶顯示面板第—實施方式之結構示意圖。 第五圖係第四圖中沿線νν之剖面結構示意圖。 第六圖係第四圖中沿線VI_VI之剖面結構示意圖。 第七圖係本發明液晶顯示面板第二實施方式之結構示意圖。 第八圖係本發明液晶顯示面板第三實施方式之結構示意圖。 第九圖係本發明液晶顯示面板第四實施方式之結構示意圖。 【主要元件符號說明】 8 1323804 液晶顯不面板 100、200、300、400 異方性導電薄膜 115、215、315、415 源極貼附區域 117、217、317、417 閘極貼附區域 118、218、318、418 第一基板 110 第二基板 120 液晶層 130 驅動1C 114I3238U4 VI. Description of the Invention: [Technical Field of the Invention] - The present invention is a liquid crystal display panel in which a circuit element connection structure and a circuit element connection structure are used. [Prior Art] Due to its low light-emitting property, light weight, shortness, and low power consumption, liquid crystal display devices are becoming more and more widely used, and their types are becoming more and more complicated with the technology and silk. The liquid crystal display device using the active matrix array generally includes a pixel region in which a plurality of gate lines and source lines are disposed on the same substrate, and a plurality of films disposed at the intersection of the interpole line and the source line. A transistor (D1! 111 1111111^118181〇1*, 丁1^), wherein each pixel region has a -pixel electrode' which is used to control the switching of the pixel electrode. The gate line and the source line are respectively connected to the gate driver IC and the source driver to provide a driving signal to the transistor. The brewing drive "and the source _ drive 1C are connected to the printed circuit board by a flexible circuit board. The circuit element + connection between the driver IC and the substrate, between the flexible circuit board and the substrate, between the flexible circuit board and the printed circuit board, and the use of an anisotropic conductive film (Anisotropic Conductive Film) , ACF) continuous mechanical connection and electrical connection. Referring to FIG. 1 , a prior art liquid crystal display device 1 includes a liquid crystal panel 10 , a backlight module 20 , and an outer frame 30 . The backlight module 20 functions to provide a liquid crystal panel 10 with a surface light source that is sufficiently bright and uniformly distributed. The outer frame 3 is for accommodating the liquid crystal panel W and the backlight module 20. 3 ^23804 Please refer to the second and third figures together. The second picture is the cross-sectional structure of the Π-Π along the line in the figure - not intended. The third picture is along the i-th line! Schematic diagram of the cross section structure. The liquid crystal panel 10 includes a first substrate u, a second substrate 12, and a liquid crystal layer U sandwiched between the first substrate u and the second substrate U. The attachment of the adjacent side edges of the first substrate u to the adjacent side is usually covered by the anisotropic conductive film 15. In the attached area, the area carrying the drive 1C is the connection area. In the connection region, the driving ΐ (: 14 is mechanically and electrically connected by the anisotropic conductive film 15 and the first substrate U. The region between the driving ic μ is a spacer region. The financial conductivity _ 15 system through the crane Molecular resin (such as Wei resin or acrylic acid 'moon 曰 曰 曰 电 电 电 电 电 , , , , , , , , , , , , 制成 制成 制成 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 The anisotropic conductive film Μ p in the _ domain, the anisotropic conductive _15 isolation film, and then drive (four) as for the connection area 'high temperature under the driver IC 14 to achieve the connection. Only 'attachment area t ' Since the connection region has the connection of the gate line or the source line, there is a height difference between the connection area and the space area. 雠中和= is not sufficiently transmitted to the spacer area of the anisotropic conduction_备之==domain:: _Electric _15 tender (four) _. Lions two shadow plastic film 15 floating in the interval area or even broken up, so two = anisotropy material 15 15 silk plate 11 private _, lower connection county 敝 伽 gamma The tenderness reduces the difference in the 'surface crystal panel 10', covering the interval area of the different 1323804 square The conductive film 15 increases the amount of the anisotropic conductive film 15 and increases the cost. [Invention] In view of the above, it is necessary to provide a liquid crystal display panel with high reliability and low cost. A high-reliability and low-cost circuit component connection structure. One embodiment of the present invention discloses a liquid crystal display panel including a first substrate, a second substrate opposite to the first substrate, and a second substrate. In the inter-liquid crystal layer, the first substrate is provided with an attaching area, the attaching area includes a source attaching area and a gate-luel attaching area, wherein the gate attaching area and the source attaching area are both The connection region and the spacer region are disposed between two adjacent connection regions; the anisotropic conductive film covers the connection region and the spacer region of the source attachment region, and covers the gate attachment region. a connection region; a plurality of driving electrodes 1C connected to the source attachment region and the connection region of the gate attachment region by the anisotropic conductive film. Another embodiment of the present invention discloses an electric The component connection structure includes a carrier substrate, a plurality of connection components, and an anisotropic conductive film. The carrier substrate is provided with an attachment area, and the attachment area includes a source attachment area and a gate attachment area. The gate attachment region and the source attachment region each include a connection region and a spacer region, and the spacer region is located between two adjacent connection regions, and the anisotropic conductive film covers the source attachment region. The connection region and the spacer region cover the connection region of the gate attachment region, and the connection member is connected to the connection region of the source attachment region and the gate attachment region by the anisotropic conductive film. In contrast, the liquid crystal display panel or circuit component connection structure of the present invention has the following advantages: the liquid crystal display panel or the circuit component is connected to the anisotropic conductive film 5, and the spacer is disposed on the sticker _ field, that is, in the interval region. Does not set anisotropic conductive enamel film or only in some of the spacing area and set anisotropic conduction _, surface anisotropy conduction = ·. After the film 'peeling the separator does not affect the anisotropy Age strength of the substrate and the thin film electrical • result, connection reliability and ^, the liquid crystal display panel or the circuit element connection structures two less. The amount of the anisotropic conductive film, and low cost. [Embodiment] - eye - and refer to the fourth, fifth, and sixth figures, the fourth figure is a schematic structural view of the first embodiment of the liquid crystal display panel of the present invention, and the fifth figure is a sectional structure of the line ν·ν in the fourth figure The sixth diagram of the sound diagram is a schematic cross-sectional structure along line VI_VI in the fourth diagram. The crystal display panel 100 includes a first substrate 11 , a second substrate 120 disposed on the first substrate 11 , and a liquid crystal layer ( 10 ) between the two substrates 11 , 12 . The adjacent side edges of the first substrate 110 respectively include a source attaching area i port and a question attaching area 118, and the two attaching areas 117, 118 include a connecting area and a spacing area. Wherein the area carrying the drive 1C 114 is the connection area, and the area between the axis ICs 114 is the φ gate separation area.} The conductive film is spaced apart and disposed in the attachment area m, 118. The anisotropic conductive film 115 is not provided with an anisotropic conductive film 115 in the spacer region. The driving Ic 114 is connected to the first substrate 110 by the anisotropic conductive film. In the industry, for the 17-hour LCD panel, usually 1 drive 1 is attached to the source attachment area 117 (: 114' attaches 4 drives 1 in the gate attachment area 118 (: 114, prior art order To use about 51.6 % of anisotropic conductive film i 1S, in the present invention, only about 26 〇 2 meters of anisotropic conductive film m is required. For M 忖 liquid crystal display panels, usually at 6 1323804 source The mounting area 117 is attached with 8 driving ICs 114, and the 3 driving 1C 114 is attached to the gate attaching area 118. In the prior art, an anisotropic conductive film of about 4287 mm is required to be used. 115, in the present invention, only the use is required. About 2 〇 29 mm anisotropic conductive film 115. Therefore, the present invention can effectively reduce the amount of use of the anisotropic conductive film 115, greatly reducing the cost. Meanwhile, since the spacer region of the present invention does not have an anisotropy After the conductive film 115 and the connection region of the anisotropic conductive film 115 are pre-compressed, the adhesion of the anisotropic conductive film 115 to the first substrate 11 is not affected when the separator is peeled off, so that the connection reliability is high. The seventh figure is the liquid crystal display panel of the present invention. The structure of the liquid crystal display panel 200 is substantially the same as the structure of the liquid crystal display panel 1 , the difference is that in the source attaching region 217, the anisotropic conductive film 215 covers the source attaching region 217; The anisotropic conductive film 215 is attached to the connection region in the gate attachment region 218. Please refer to the eighth embodiment, which is a schematic structural view of the third embodiment of the liquid crystal display panel of the present invention. The liquid crystal display panel 300 and the liquid crystal display panel 1 The structure of the crucible is substantially the same, and the difference is that the anisotropic conductive film 315 is attached to the connection region in the source attachment region 317; in the gate attachment region 318, the anisotropic conductive film 315 covers the gate Attachment area 318. Please refer to the ninth drawing, which is a structural diagram of the fourth embodiment of the liquid crystal display panel of the present invention. The liquid crystal display panel 400 and the liquid crystal display panel 1 are substantially identical in structure, and the difference is: The abutting region 417 is provided with an anisotropic conductive film 415 in a portion of the spacer region; and the anisotropic conductive film 415 is also disposed in a portion of the gate attaching region 418'. In the device, other circuit component connection structures that require an anisotropic conductive film, such as a connection between a flexible circuit board and a substrate, and between a flexible circuit board and a printed circuit board, can also be used in the spacer region without an alienation. a conductive film or a structure in which an anisotropic conductive thin film is provided only in a portion of the portion. In the present invention, the arrangement of the anisotropic conductive film of the liquid crystal display panel or the circuit element connection structure is set to _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ It can be secret. And the liquid crystal display panel money path component connection structure reduces the amount of use of the square conductive film, and the cost is low. Factory " In summary, the invention has indeed met the requirements of the invention, and the patent is filed according to law. The above-mentioned employees are only Lin Dede (10), and the right to issue is not Z. The equivalent of the present invention shall be covered by the following claims. The first figure is a schematic diagram of the structure of the prior art liquid crystal display device. A schematic diagram of the cross-sectional structure along the line IWI in the first figure. • The third figure is a schematic view of the cross-sectional structure along the line ΙΠ-ΙΙΙ in the first figure. The fourth figure is a schematic structural view of the first embodiment of the present crystal display panel. A cross-sectional structural diagram along the line νν in the fourth figure. The sixth figure is a schematic cross-sectional structure along the line VI_VI in the fourth figure. The seventh figure is a schematic structural view of the second embodiment of the liquid crystal display panel of the present invention. FIG. 9 is a schematic structural view of a liquid crystal display panel according to a fourth embodiment of the present invention. [Main component symbol description] 8 1323804 LCD Non-panel 100, 200, 300, 400 anisotropic conductive film 115, 215, 315, 415 source attaching regions 117, 217, 317, 417 gate attaching regions 118, 218, 318, 418 first substrate 110 Two substrate 120 liquid crystal layer 130 driving 1C 114