1259739 九、發明說明: 【發明所屬之技術領域】 - 本發明係有關一種有機發光二極體(Organic Light - Emitting Diode ; OLED )之電極引線的佈設結構,其中顯 示器之陽極引線與陰極引線透過複數個電極與外部之驅動 電路相電連接。 【先前技術】 有機發光二極體(Organic Light Emitting Diode; * OLED)具有輕、薄、自發光、廣視角、解析度佳、高亮度、 低耗電及高應答速度等特性,因此被視為下一世代的平面 顯示器所應用的新興技術。然,有機發光二極體0LED顯示 器的設計並不簡單,除了要考慮發光元件(即0LED)的壽 命,即耗電量等問題,同時在面板設計方面,亦有很大的 改善空間。 習知的有機發光二極體0LED顯示模組,尤指大面積 (如面板規格為128*160)高解析度的顯示器,其需掃描 | 週期數高,瞬間電流大的驅動電路來供應面板所需求之驅 動能力,請參考第一圖,為習知使用二顆驅動電路IC驅動 有機發光二極體128*160顯示模組外觀示意圖。在習知技 藝中,面板規格為128*160之有機發光二極體顯示模組分 成一第一顯示模組1與一第二顯示模組2,其面板規格為 128*160之顯示區12分別需由二個驅動電路ICJ、IC2控 制。驅動電路IC1透過第一電極端11控制第一顯示模組1 所屬之顯不區12 ’另’驅動電路IC 2透過第二電極端1 / 控制第二顯示模組2所屬之顯示區12,如此即形成使甩二 個驅動電路IC1、IC2控制128*160顯示區12之顯示。 1259739 請參考第二A至第二C圖,係為習知之面板電極佈線 結構示意圖。第二A圖係為陽極之佈線結構,第二A圖中 顯示透明基板16的側邊10,係以作為外部驅動電路所輸 出訊號的接收端,且侧邊10係垂直於複數個陽極引線18 的延伸方向,而且複數條陽極引線18分別連接複數個陽極 電極14且彼此間隔佈設於透明基板16的側邊10上方。同 時,複數個陽極電極14係形成一顯示區12。 第二B圖係為陰極之佈線結構,第二B圖中顯示複數 φ 條陰極引線15分別連接其對應之陰極電極13的一端,且 彼此間隔佈設於透明基板16之侧邊10上方。同時,複數 個陰極電極13係形成該顯不區12。 • 第二C圖為第二A圖與第二B圖之組合圖,第二C圖 • 中顯示在顯示區12内佈設有複數條彼此交叉的陽極電極 14與陰極電極13,並陽徑電裡14與陰極電極13的更豐區 域即為有機發光二極體顯示模組的發光區域19。而且,複 數條陽極引線18與複數條陰極引線15皆置於同一侧邊10 Φ 的上方。 考慮顯示面板在全部點亮情況下,每一條陰極電極13 或陰極引線15在瞬間需承受複數條從陽極電極14流出的 電流總和,因此陰極電極13或陰極引線15所容納的電流 將遠大於陽極電極14的電流◦同時,在面板佈設時,陰極 引線15的佈設會使得阻抗增加,最後造成顯示器之電能消 耗主要係浪費在陰極電極13及與陰極引線15上,且使得 電極所需之驅動電壓提高。另外陽極引線18的佈設也會使 得阻抗增加,而浪費顯示器顯示所需的電能。 請參考第三圖,為習知有機發光二極體OLED顯示模組 6 1259739 之電路示意圖。驅動電路輸出之掃描訊號(SI、S2〜Sm) 與資料訊號(D1、D2..Dn)分別透過複數條陰極引線15 與陽極引線18傳送到顯示區12中的陰極電極13與陽極電 極14,使得發光區域19中的有機發光二極體191可以根 據該些輸入的訊號進行發光顯示。1259739 IX. Description of the Invention: [Technical Field of the Invention] - The present invention relates to an arrangement structure of an electrode lead of an organic light-emitting diode (OLED), wherein an anode lead and a cathode lead of the display pass through a plurality of The electrodes are electrically connected to an external driving circuit. [Prior Art] Organic Light Emitting Diode (*OLED) is characterized by lightness, thinness, self-luminescence, wide viewing angle, good resolution, high brightness, low power consumption, and high response speed. Emerging technologies used in next generation flat panel displays. However, the design of the organic light-emitting diode OLED display is not simple, except that the life of the light-emitting element (ie, OLED), that is, the power consumption, is considered, and there is also a large room for improvement in panel design. The conventional organic light-emitting diode OLED display module, especially a large-area (such as a panel size of 128*160) high-resolution display, which needs to scan | a high number of cycles, a large instantaneous current drive circuit to supply the panel For the driving ability of the demand, please refer to the first figure, which is a schematic diagram of the appearance of the display module of the organic light-emitting diode 128*160 driven by two driving circuit ICs. In the prior art, the OLED display module having a panel size of 128*160 is divided into a first display module 1 and a second display module 2, and the display area 12 of the panel size of 128*160 is respectively It needs to be controlled by two drive circuits ICJ and IC2. The driving circuit IC1 controls the display area 1 to which the first display module 1 belongs through the first electrode terminal 11 to drive the display circuit IC 2 through the second electrode end 1 / control the display area 12 to which the second display module 2 belongs. That is, the display of the display area 12 of the 128*160 is controlled by the two driving circuits IC1 and IC2. 1259739 Please refer to the second to second C diagrams for the structure of the conventional panel electrode wiring. The second A diagram is the wiring structure of the anode, and the second side A shows the side 10 of the transparent substrate 16 as the receiving end of the signal outputted by the external driving circuit, and the side 10 is perpendicular to the plurality of anode leads 18 The extending direction of the plurality of anode leads 18 is connected to the plurality of anode electrodes 14 and spaced apart from each other above the side 10 of the transparent substrate 16. At the same time, a plurality of anode electrodes 14 form a display region 12. The second B is a wiring structure of the cathode, and the second B shows that a plurality of φ cathode leads 15 are respectively connected to one ends of the corresponding cathode electrodes 13, and are disposed above the side edges 10 of the transparent substrate 16 at intervals. At the same time, a plurality of cathode electrodes 13 form the display region 12. • The second C diagram is a combination of the second A diagram and the second B diagram, and the second C diagram shows that a plurality of anode electrodes 14 and cathode electrodes 13 intersecting each other are arranged in the display area 12, and the anode diameter is electrically The richer region of the inner 14 and the cathode electrode 13 is the light-emitting region 19 of the organic light-emitting diode display module. Moreover, a plurality of anode leads 18 and a plurality of cathode leads 15 are placed above the same side 10 Φ . Considering that the display panel is fully illuminated, each cathode electrode 13 or cathode lead 15 is subjected to a plurality of currents flowing from the anode electrode 14 in an instant, so that the current contained in the cathode electrode 13 or the cathode lead 15 will be much larger than that of the anode. At the same time, the current of the electrode 14 is at the same time, when the panel is laid, the arrangement of the cathode lead 15 causes the impedance to increase, and finally the power consumption of the display is mainly wasted on the cathode electrode 13 and the cathode lead 15, and the driving voltage required for the electrode is made. improve. In addition, the layout of the anode lead 18 also increases the impedance, wasting the display of the required electrical energy. Please refer to the third figure, which is a schematic circuit diagram of a conventional organic light emitting diode OLED display module 6 1259739. The scanning signals (SI, S2~Sm) and the data signals (D1, D2..Dn) outputted by the driving circuit are respectively transmitted to the cathode electrode 13 and the anode electrode 14 in the display area 12 through the plurality of cathode leads 15 and the anode lead 18, The organic light emitting diode 191 in the light emitting region 19 can be illuminated according to the input signals.
然而,習知的有機發光二極體OLED顯示模組,尤指大 面積高解析度的顯示器,因掃描週期數高,瞬間電流大, 再加上面板上之電極阻抗值高,而使得大面板之驅動能力 參 所需甚大。而往往單顆驅動1C無法輸出足夠能力給面板, 而需使用二個驅動電路1C來控制驅動大面積之顯示面板 (128*160規格)。再者,目前業界中有機發光二極體OLED • 顯示模組仍然存在有下面缺點: • 1.面板機構設計不方便。 2. 需二驅動1C進行大面板之驅動。 3. 驅動1C之銲線製程不易。 4. 程式、控制訊號等不易撰寫。 春 5.驅動IC效率不易控制,此點會造成面板顏色、亮度不 均之現象發生。 【發明内容】 有鑑於此,本發明為一種有機發光二極體顯示器之電 極引線佈設結構,其主要私點在於佈设在顯不裔向板上之 複數個陽極電極其具有連續多組凹Λ部,且兩兩陽極引線 相互咬合,同時,使用複數條寬度等於陽極電極之一凹凸 部寬度之陰極電極,使之垂直層疊於該些陽極電極。藉由 陽、陰極電極的結構改變,使得顯示器面板在動昨時,電 1259739 極阻抗值會大大減少,而可以達到單顆驅動i c驅動大面積 白勺OLED面板C 1 2 8 * 16 0規格同時改善習知驅動IC效率 不易控制,所造成面板顏色、亮度不均等缺點。 _ 本發明一種有機發光二極體顯示器之電極引線佈設結 構,有機發光二極體顯示器由一陽極層與一陰極層組成, 陰極層層疊於該陽極層。陽極層具有複數陽極電極5其中 每一陽極電極具有連續多組凹凸部,且兩兩陽極電極相互 咬合。另,陰極層具有複數陰極電極,該些陰極電極垂直 φ 於該些陽極電極。其中,該些陰極電極與該些陽極電極之 重疊區域,係為該顯示器之發光區域。 以上的概述與接下來的詳細說明皆為示範性質,是為 • 了進一步說明本發明的申請專利範圍。而有關本發明的其 . 他目的與優點,將在後續的說明與圖示加以闡述。 【實施方式】 請參考第四圖,為本發明使用單顆驅動1C驅動有機發 光二極體128*160顯示模組外觀示意圖。面板規格為 φ 128*160之有機發光二極體顯示模組3係受控於一驅動電 路1C,該驅動電路1C透過電極端31控制顯示模組3所屬 之顯示區3 2。 請參考第五A至第五C圖,係為本發明之面板電極佈 線結構實施例示意圖。第五A圖係為陽極之佈線結構,第 五A圖中顯示透明基板3 6的側邊3 0,係以作為外部驅動 1C所輸出訊號的接收端,且側邊30係垂直於複數個陽極 引線38的延伸方向,而且複數條陽極引線38分別連接複 數個陽極電極34且彼此間隔佈設於透明基板36的侧邊30 上方,且該些陽極電極34分別透過複數陽極引線38連接 8 1259739 到該驅動電路1C。同時,複數個陽極電極34其面積係可 形成一顯示區32。 第五B圖係為陰極之佈線結構,第五B圖中顯示複數 條陰極引線35分別在透明基板36兩侧連接其對應之陰極 電極33的一端,分別於透明基板36—侧連接單數的陰極 電極3 3,另一側连接雙數的陰極電極3 3,且彼此間隔佈設 於透明基板36之側邊30上方,且該些陰極電極33分別透 過複數陰極引線35連接到該驅動電路1C。同時,複數個 陰極電極3 3其面積1糸形成该顯不區3 2。 第五C圖為第五A圖與第五B圖之組合圖,第五C圖 中顯示在顯示區32内佈設有複數條彼此交叉的陽極電極 34與陰極電極33,並陽極電極34與陰極電極33的重疊區 域即為有機發光二極體顯示模組的發光區域39。而且,複 數條陽極引線38與複數條陰極引線35皆置於同一側邊30 的上方。 上述說明中,有機發光二極體顯示器由一陽極層與一 陰極層組成,陰極層層疊於該陽極層。陽極層具有複數陽 極電極34,其中每一陽極電極34具有連續多組凹凸部, 且兩兩陽極電極34相互咬合,並且,該陽極電極34之凸 部包含一有機發光二極體(未標不)。另’陰極層具有複數 陰極電極3 3 ^該些陰極電極3 3垂直於該些極電極3 4。 其中,該些陰極電極3 3與該些陽極電極3 4之重豐區域’ 係為該顯示器之發光區域3 9。 複數個陽極電極3 4其分別具有迷續多組凹凸部’且兩 兩陽極電極34相亙咬合,同時,使用複數條寬度等於陽極 電極34之一凹凸部寬度之陰極電極33,使之垂直層疊於 1259739 該些陽極電極34。藉由陽極電極34與陰極電極33的結構 改變,即兩兩陽極電極34相互咬合與加寬的陰極電極33, 使得其電極本身產生的阻抗降低。測試數據如下:陽極電 極34的電阻值由1000 Ω下降到500 Ω ;陰極電極33的電 阻值則由320 Ω下降到160Ω。因此從數據可以得知,使用 本發明有機發光二極體顯示器之電極引線佈設結構,可以 讓顯示器發光所需的電能降低兩倍。所以使用單顆驅動1C 即可以有效驅動以本發明結構所組成之大面積的OLED面 φ 板(128*160規格),同時改善習知驅動1C效率不易控制, 所造成面板顏色、党度不均等缺點。 請參考第六A至第六C圖5係為本發明之面板電極佈 • 線結構另一實施例示意圖。第六A圖係為陽極之佈線結 . 構,其結構係相同於ϋ述貫施1列’杜此不多加賢述。弟穴 Β圖係為陰極之佈線結構,第六Β圖中顯示複數條陰極引 線35分別在透明基板36兩側連接其對應之陰極電極33 的一端,分別於透明基板36 —側為上排的陰極電極33, 另一側為下排的陰極電極33,且彼此間隔佈設於透明基板 ® 36之側邊30上方,且該些陰極電極33分別透過複數陰極 引線35連接到該驅動電路1C ◦同時,複數個陰極電極33 其面積係形成該顯示區32。 第六C圖為第六Α圖與第六Β圖之組合圖,第六C圖 中顯示在顯示區32内佈設有複數條彼此交叉的陽極電極 3 4與陰極電極3 3 ’並陽極電極3 4與陰極電極3 3的里豐區 域即為有機發光二極體顯示模組的發光區域39。而且,複 數條陽極引線38與複數條陰極引線35皆置於同一侧邊30 的上方。 10 1259739 綜上所述,本發明為一種有機發光二極體顯示器之電 極引線佈設結構’其主要特點在於仰设在择員不為®板上之 複數個陽極電極其具有連續多組凹凸部,且兩兩陽極引線 相互咬合,同時,使用複數條寬度等於陽極電極之一凹凸 部寬度之陰極電極,使之垂直層疊於該些陽極電極。藉由 陽、陰極電極的結構改變,使得其電極本身產生的阻抗降 低,因此,使用本發明有機發光二極體顯示器之電極引線 佈設結構,可以讓顯示器發光所需的電能降低兩倍。 所以使用單顆驅動1C即可以有效驅動以本發明結構 所組成之大面積的OLED面板(128*160規格),同時改善 習知驅動IC效率不易控制,所造成面板顏色、亮度不均等 缺點。 綜上所述,本發明完全符合專利申請之要件,故爰依 專利法提出申請,請詳查並請早曰惠准專利,實感德便, 以保障發明者之權益,若鈞局之貴審查委員有任何的稽 疲’請个合來幽相不。 惟,以上所述,僅為本發明最佳之一的具體實施例之 詳細說明與圖式,惟本發明之特徵並不侷限於此,並非用 以限制本發明,本發明之所有範圍應以下述之申請專利範 圍為準,凡合於本發明申請專利範圍之精神與其類似變化 之實施例,皆應包含於本發明之範疇中,任何熟悉該項技 藝者在本發明之領域内,可輕易思及之變化或修飾皆可涵 蓋在以下本案之專利範圍。 【圖式簡單說明】 第一圖為習知使用二顆驅動1C驅動有機發光二極體 128*160顯示模組外觀示意圖; 11 1259739 第二A至第二C圖為習知之面板電極彳印線結構不意圖, 第三圖為習知有機發光二極體OLED顯示模組之電路示意 圖; 第四圖為本發明使用單顆驅動1C驅動有機發光二極體 128*160顯示模組外觀示意圖; 第五A至第五C圖,係為本發明之面板電極佈線結構實施 例示意圖;及 第六A至第六C圖,係為本發明之面板電極佈線結構另一 實施例示意圖。 [主要元件符號說明】 習知: 第一顯示模組1 第二顯示模組2 顯示區12 驅動電路IC1、IC2 側邊10 第一電極端11 陰極電極13 陽極電極14 陰極引線15 透明基板16 第二電極端17 陽極引線18 發光區域19 1259739 有機發光二極體191 本發明: 顯示模組3 驅動電路1C 側邊30 電極端31 顯示區32 陰極電極3 3 陽極電極34 陰極引線35 透明基板36 陽極引線3 8 發光區域39However, the conventional organic light-emitting diode OLED display module, especially a large-area high-resolution display, has a large number of scanning cycles, a large instantaneous current, and a high electrode impedance value on the panel, so that the large panel The driving ability is very large. However, a single drive 1C cannot output sufficient capacity for the panel, and two drive circuits 1C are required to control a large-area display panel (128*160 size). Furthermore, the current organic light-emitting diode OLED display module still has the following disadvantages: • 1. The panel mechanism is inconvenient to design. 2. It is necessary to drive 1C to drive the large panel. 3. It is not easy to drive the 1C wire bonding process. 4. Programs, control signals, etc. are not easy to write. Spring 5. The efficiency of the driver IC is not easy to control. This will cause the panel color and brightness to be uneven. SUMMARY OF THE INVENTION In view of the above, the present invention is an electrode lead routing structure of an organic light emitting diode display, the main point of which is a plurality of anode electrodes disposed on a display plate having a continuous plurality of concave ridges. And the two anode lead wires are engaged with each other, and at the same time, a plurality of cathode electrodes having a width equal to the width of the concave and convex portions of the anode electrode are used to be vertically stacked on the anode electrodes. By changing the structure of the anode and cathode electrodes, the display panel is moved at the same time, the electric resistance value of the 1259739 pole is greatly reduced, and the single-drive ic drive can drive the large-area OLED panel C 1 2 8 * 16 0 specifications at the same time. It is difficult to control the efficiency of the conventional driver IC, resulting in defects such as uneven color and brightness of the panel. The electrode lead wiring structure of the organic light emitting diode display of the present invention, the organic light emitting diode display comprises an anode layer and a cathode layer, and a cathode layer is laminated on the anode layer. The anode layer has a plurality of anode electrodes 5 each of which has a continuous plurality of sets of irregularities, and the two anode electrodes are engaged with each other. Further, the cathode layer has a plurality of cathode electrodes which are perpendicular to the anode electrodes. The overlapping area of the cathode electrode and the anode electrodes is a light-emitting area of the display. The above summary and the following detailed description are exemplary and are intended to further illustrate the scope of the invention. The objects and advantages of the present invention will be explained in the following description and drawings. [Embodiment] Please refer to the fourth figure, which is a schematic diagram of the appearance of a display module of a single-drive 1C-driven organic light-emitting diode 128*160 according to the present invention. The OLED display module 3 having a panel size of φ 128*160 is controlled by a driving circuit 1C, and the driving circuit 1C controls the display area 3 2 to which the display module 3 belongs via the electrode terminal 31. Please refer to the fifth to fifth C drawings, which are schematic diagrams of the embodiment of the panel electrode wiring structure of the present invention. The fifth A diagram is the wiring structure of the anode, and the fifth side shows the side edge 30 of the transparent substrate 36, which is used as the receiving end of the output signal of the external driving 1C, and the side 30 is perpendicular to the plurality of anodes. The plurality of anode leads 38 are connected to the plurality of anode electrodes 34 and spaced apart from each other at the side 30 of the transparent substrate 36, and the anode electrodes 34 are respectively connected to the plurality of anode leads 38 through the first anode lead 38 to the Drive circuit 1C. At the same time, a plurality of anode electrodes 34 are formed to form a display region 32. The fifth B is a cathode wiring structure, and the fifth B shows that a plurality of cathode leads 35 are respectively connected to one ends of the corresponding cathode electrodes 33 on both sides of the transparent substrate 36, and a single cathode is connected to the transparent substrate 36 side. The electrode 3 3 is connected to the other side of the cathode electrode 33 and is disposed above the side 30 of the transparent substrate 36, and the cathode electrodes 33 are connected to the driving circuit 1C through the plurality of cathode leads 35, respectively. At the same time, a plurality of cathode electrodes 3 3 have an area of 1 糸 to form the display region 3 2 . The fifth C is a combination of the fifth A and the fifth B, and the fifth C shows that a plurality of anode electrodes 34 and cathode electrodes 33 intersecting each other are arranged in the display region 32, and the anode electrode 34 and the cathode are provided. The overlapping area of the electrodes 33 is the light-emitting area 39 of the organic light-emitting diode display module. Moreover, a plurality of anode leads 38 and a plurality of cathode leads 35 are placed over the same side 30. In the above description, the organic light emitting diode display comprises an anode layer and a cathode layer, and a cathode layer is laminated on the anode layer. The anode layer has a plurality of anode electrodes 34, wherein each anode electrode 34 has a plurality of sets of concave and convex portions, and the two anode electrodes 34 are engaged with each other, and the convex portion of the anode electrode 34 includes an organic light emitting diode (not labeled ). The other cathode layer has a plurality of cathode electrodes 33. The cathode electrodes 33 are perpendicular to the pole electrodes 34. The cathode regions 33 and the abundance regions of the anode electrodes 34 are the light-emitting regions 39 of the display. The plurality of anode electrodes 34 each have a plurality of sets of concave and convex portions' and the two anode electrodes 34 are occluded, and a plurality of cathode electrodes 33 having a width equal to the width of the concave and convex portions of the anode electrode 34 are used to be vertically stacked. The anode electrode 34 is at 1259739. The structure of the anode electrode 34 and the cathode electrode 33 is changed, that is, the two anode electrodes 34 are engaged with each other and the widened cathode electrode 33, so that the impedance generated by the electrode itself is lowered. The test data is as follows: the resistance value of the anode electrode 34 is reduced from 1000 Ω to 500 Ω; and the resistance value of the cathode electrode 33 is decreased from 320 Ω to 160 Ω. Therefore, it can be known from the data that the electrode lead wiring structure of the organic light-emitting diode display of the present invention can reduce the power required for the display to be doubled. Therefore, the use of a single drive 1C can effectively drive the large-area OLED surface φ plate (128*160 specification) composed of the structure of the present invention, and at the same time improve the conventional drive 1C efficiency, which is difficult to control, resulting in panel color and party unequality. Disadvantages. Please refer to FIGS. 6A to 6C. FIG. 5 is a schematic view showing another embodiment of the panel electrode cloth of the present invention. The sixth picture A is the wiring structure of the anode. The structure is the same as that of the first column. The ridge diagram is a cathode wiring structure. In the sixth diagram, a plurality of cathode leads 35 are respectively connected to one ends of the corresponding cathode electrodes 33 on both sides of the transparent substrate 36, and are respectively arranged on the side of the transparent substrate 36. The cathode electrode 33 and the other side are the cathode electrodes 33 of the lower row, and are disposed above the side edges 30 of the transparent substrate® 36, and the cathode electrodes 33 are respectively connected to the driving circuit 1C through the plurality of cathode leads 35. A plurality of cathode electrodes 33 have an area that forms the display region 32. The sixth C is a combination of a sixth map and a sixth map, and the sixth C shows that a plurality of anode electrodes 34 and cathode electrodes 3 3 ' and the anode electrodes 3 intersecting each other are disposed in the display region 32. The Rifant region of the fourth electrode and the cathode electrode 33 is the light-emitting region 39 of the organic light-emitting diode display module. Moreover, a plurality of anode leads 38 and a plurality of cathode leads 35 are placed over the same side 30. 10 1259739 In summary, the present invention is an electrode lead wiring structure of an organic light-emitting diode display. The main feature of the present invention is that a plurality of anode electrodes are disposed on a plurality of anode electrodes on a member board, and have a plurality of sets of concave and convex portions. And the two anode leads are engaged with each other, and at the same time, a plurality of cathode electrodes having a width equal to the width of the uneven portion of the anode electrode are used to be vertically stacked on the anode electrodes. By changing the structure of the anode and cathode electrodes, the impedance generated by the electrodes themselves is lowered. Therefore, by using the electrode lead arrangement of the organic light-emitting diode display of the present invention, the electric energy required for the display illumination can be reduced by two times. Therefore, the use of a single drive 1C can effectively drive a large-area OLED panel (128*160 specification) composed of the structure of the present invention, and at the same time, it is difficult to control the efficiency of the conventional drive IC, resulting in disadvantages such as uneven color and brightness of the panel. In summary, the present invention fully complies with the requirements of the patent application, so the application is filed in accordance with the Patent Law. Please check and ask for the patent in advance, and feel the virtues to protect the rights and interests of the inventor. Members have any sorrows. However, the above description is only a detailed description of the preferred embodiments of the present invention, and the present invention is not limited thereto, and is not intended to limit the present invention. The scope of the patent application is subject to the scope of the present invention, and any one skilled in the art can easily include it in the field of the present invention. Any changes or modifications considered may be covered by the patents in this case below. [Simple description of the diagram] The first figure is a schematic diagram showing the appearance of a conventional display module using two drivers 1C to drive an organic light-emitting diode 128*160; 11 1259739 The second to second C diagrams are conventional panel electrode scanning lines. The structure is not intended, the third figure is a circuit diagram of a conventional organic light emitting diode OLED display module; the fourth figure is a schematic diagram of the appearance of a display module using a single driving 1C driving organic light emitting diode 128*160; 5A to 5C are schematic views showing an embodiment of the panel electrode wiring structure of the present invention; and FIGS. 6A to 6C are schematic views showing another embodiment of the panel electrode wiring structure of the present invention. [Main component symbol description] Convention: First display module 1 Second display module 2 Display area 12 Driving circuit IC1, IC2 Side 10 First electrode end 11 Cathode electrode 13 Anode electrode 14 Cathode lead 15 Transparent substrate 16 Two electrode terminal 17 Anode lead 18 Light emitting region 19 1259739 Organic light emitting diode 191 The present invention: Display module 3 Driving circuit 1C Side 30 Electrode end 31 Display area 32 Cathode electrode 3 3 Anode electrode 34 Cathode lead 35 Transparent substrate 36 Anode Lead 3 8 light emitting area 39