200912494 九、發明說明: •【發明所屬之技術領域】 本發明係關於一種液晶顯示面板。 【先前技術】 液晶顯示面板因具有低輻射性、體積小及耗電低等特 點,已廣泛應用於手機、個人數位助理、筆記型電腦、個 人電腦及電視等領域。 請參閱圖1,係一種先前技術液晶顯示面板之平面結 構示意圖。該液晶顯示面板10包括複數相互平行之掃描線 101、複數與該掃描線101垂直絕緣相交之資料線102、複 數公共電極103及複數像素電極104。 該掃描線101及該資料線104界定複數像素區域(未標 號)。該像素電極104位於該像素區域内。該公共電極103 包括一第一公共電極1031及複數第二公共電極1032。該 第一公共電極1031貫穿該像素區域且與該掃描線101相互 平行。該第二公共電極1032位於該像素區域内該資料線 、102之右侧,並與該第一公共電極1031垂直連接。 該像素電極104分別與該第一公共電極1031及該第二 公共電極1032部份交疊,交疊處分別形成存儲電容(未標 示)。 通常,在該液晶顯示面板10之製程中,如果像素區域 所在之基板表面不平,或者在加熱或蝕刻時,容易導致該 公共電極103及該像素電極104之間產生短路缺陷。因此, 為了提高產品之良率,需要對短路進行修補。 200912494 當檢測發現該第一公共電極1031與該像素電極104 •之間發生短路時,例如圖1所示之第一点1033發生短路, 可沿圖1所示之虛線1切斷該像素電極104及與該像素電 極104交疊之部份第二公共電極1032,從而斷開該第一公 共電極1031與像素電極104之連接。 當檢測發現該第二公共電極1032與該像素電極104 之間發生短路時,例如圖1所示之第二點1034發生短路, 可沿圖1所示之虛線2切斷該第二公共電極1032及與該第 二公共電極1032交疊之部份像素電極104,從而斷開該第 二公共電極1032與該像素電極104之連接。 由上述可知,無論是修補該第一公共電極1031與該像 素電極104之間之短路,還是修補該第二公共電極1032 與該像素電極104之間之短路,該第二公共電極1032與該 像素電極104會同時被切到。惟,該第二公共電極1032 與該像素電極104同時被切到,容易使該第二公共電極 1032與該像素電極丨04電連接,再次發生短路,導致該液 ' 晶顯示面板10之修補成功率較低。 【發明内容】 有鑑於此,提供一種修補成功率較高之液晶顯示面板 實為必需。 一種液晶顯示面板,其包括複數公共電極及複數像素 電極。每一公共電極包括一第一公共電極及複數第二公共 電極。該第二公共電極分別與該第·一公共電極連接。該像 素電極分別與該第一公共電極及該第二公共電極交疊形成 7 200912494 存儲電容。該像素電極分別與該第一公共電極及該第二公 共電極交疊形成存儲電容。該第二公共電極具有一第一缺 口,該第一缺口對應於該像素電極,該第一缺口處無第二 公共電極與該像素電極交疊。 一種液晶顯示面板,其包括複數公共電極及複數像素 電極。每一公共電極包括一第一公共電極及複數第二公共 電極。該第二公共電極分別與該第一公共電極連接。該像 素電極分別與該第一公共電極及該第二公共電極交疊形成 存儲電容。該像素電極具有一第一缺口,該第一缺口對應 於該第二公共電極,該第一缺口處無像素電極與該第二公 共電極交疊。 相較於先前技術,本發明液晶顯示面板之第二公共電 極或像素電極具有一第一缺口,使該缺口處該像素電極與 該第二公共電極無交疊。在修補該公共電極與該像素電極 之短路時,沿該第一缺口位置進行切斷僅會切斷該像素電 極或該第二公共電極其中之一,從而避免因切斷引起之該 像素電極與該第二公共電極電連接,再次短路之問題。因 此,該液晶顯示面板之修補成功率較高。 【實施方式】 請參閱圖2,係本發明液晶顯示面板第一實施方式之 平面結構示意圖。該液晶顯示面板20包括複數相互平行之 掃描線201、複數與該掃描線201垂直絕緣相交之資料線 202、複數公共電極203及複數像素電極204。 該掃描線201及該資料線202界定複數像素區域(未標 8 200912494 號)。該像素電極204位於該像素區域内。該公共電極203 .包括一第一公共電極2031及複數第二公共電極2032。該 第一公共電極2031貫穿該像素區域且與該掃描線201相互 平行。該第二公共電極2032位於該像素區域内該資料線 202之右侧,並與該第一公共電極2031垂直連接於一第一 点 208。 該像素電極204分別與該第一公共電極2031及該第二 公共電極2032部份交疊,交疊處分別形成一存儲電容(未 標示)。該第二公共電極2032鄰近該第一点208之一端具 有一缺口 205,該缺口 205對應於部份像素電極204,使得 該缺口 205處無第二公共電極2032與像素電極204交疊。 當檢測發現該第一公共電極2031與該像素電極204 之間發生短路時,例如圖2所示之一第一短路點2033,可 沿該缺口 205處對應之虛線1切斷該像素電極204,從而 斷開該第一公共電極2031與像素電極204之連接。 當檢測發現該第二公共電極2032與該像素電極204 之間發生短路時,例如圖2所示之一第二短路點2034,可 沿該缺口 205處對應之虛線2切斷該第二公共電極2032, 從而斷開該第二公共電極2032與該像素電極204之連接。 相較於先前技術,該液晶顯示面板20之第二公共電極 2032鄰近該第一点之一端具有一缺口 205,該缺口 205對 應於部份像素電極204,使得該缺口 205處無第二公共電 極2032與像素電極204交疊。因此在修補該液晶顯示面板 20之短路時,沿該缺口 205位置進行切斷僅會切斷該像素 9 200912494 電極204或該第二公共電極2032之一,從而避免因切斷引 .起之該像素電極204與該第二公共電極2032電連接,即再 次短路之問題。因此,該液晶顯示面板20之修補成功率較 南。 請參閱圖3,係本發明液晶顯示面板第二實施方式之 平面結構示意圖。該液晶顯示面板3 0包括複數相互平行之 掃描線301、複數與該掃描線301垂直絕緣相交之資料線 302、複數公共電極303及複數像素電極304。 該掃描線301及該資料線302界定複數像素區域。該 像素電極304位於該像素區域内。該公共電極303包括一 第一公共電極3031及複數第二公共電極3032。該第一公 共電極3031貫穿該像素區域且與該掃描線301相互平行。 該第二公共電極3032位於該像素區域内該資料線302之右 側,並與該第一公共電極3031垂直連接於一第一点308。 該像素電極304分別與該第一公共電極3031及該第二 公共電極3032部份交疊,交疊處分別形成一存儲電容(未 標示)。該像素電極304具有一缺口 305,該缺口 305之位 置對應於該第二公共電極3032之鄰近於該第一点308處, 使得該缺口 305處無像素電極304與第二公共電極3032 田 父豐。 請參閱圖4,係本發明液晶顯示面板第三實施方式之 平面結構示意圖。該液晶顯示面板40與第一實施方式之液 晶顯不面板20基本相同’其主要區別之處在於·公共電極 403進一步包括複數第三公共電極4033,該第三公共電極 10 200912494 4033位於像素區域内資料線402之左侧,並與第一公共電 極4031垂直連接於一第二点408。像素電極404與該第三 公共電極4033部份交疊,交疊處亦形成一存儲電容。該第 三公共電極4033鄰近該第二点408之一端具有一第二缺口 405,該缺口 405對應於部份像素電極404,使該第二缺口 405處無第三公共電極4033與像素電極404交疊。 請參閱圖5,係本發明液晶顯示面板第四實施方式之 平面結構示意圖。該液晶顯示面板50與第一實施方式之液 晶顯不面板20基本相同,其主要區別之處在於.像素電極 504具有一與第二公共電極5032之缺口 505對應之第二缺 口 506。 請參閱圖6,係本發明液晶顯示面板第五實施方式之 平面結構示意圖。該液晶顯示面板60與第三實施方式之液 晶顯不面板4 0基本相同’其主要區別之處在於.像素電極 604具有一與第二公共電極6032之缺口 605對應之第三缺 口 606及一與該第三.公共電極6033之第二缺口 607對應之 第四缺口 608。 請參閱圖7,係本發明液晶顯示面板第六實施方式之 平面結構示意圖。該液晶顯示面板70包括複數相互平行之 掃描線701、複數與該掃描線701垂直絕緣相交之資料線 702、複數公共電極703及複數像素電極704。 該掃描線701及該資料線702界定複數像素區域(未標 號)。該像素電極704位於該像素區域内。該公共電極703 包括一第一公共電極7031及複數第二公共電極7032。該 11 200912494 第一公共電極7031貫穿該像素區域且與該掃描線701相互 .平行。該第二公共電極7032位於該像素區域内該資料線 702之右侧,並與該第一公共電極7031垂直連接於一第一 点 709。 該像素電極704分別與該第一公共電極7031及該第二 公共電極7032交疊,交疊處分別形成一存儲電容。該第二 公共電極7032鄰近該第一点709處及遠離該第一点709 處分別垂直延伸出一突出部7033,該突出部7033與該資 料線702垂直絕緣相交,用於修補該資料線702之斷線。 該第二公共電極7032鄰近該第一点709之一端具有一 缺口 705,該缺口 705對應於部份像素電極704,使該缺口 705處無第二公共電極7032與像素電極704交疊。 當檢測發現該資料線702具有一斷點708時,可採用 焊接(Welding)方式使該二突出部7033分別與該資料線702 之相父處電導通,並沿該缺口 7 0 5處對應之虛線1切斷該 第二公共電極7032。.如此,該資料線702可藉由該第二公 、 共電極7032導通。亦即,該斷點708所在之資料線702 上之訊號可正常傳輸。 由於該液晶顯示面板70之第二公共電極7032鄰近該 第一点709之一端具有一缺口 705,該缺口 705對應於部 份像素電極704,使該缺口 705處無第二公共電極7032與 像素電極704交疊。因此在修補該資料線702之斷点708, 切斷該第一公共電極7031與該第二公共電極7032之連接 時,沿該缺口 705位置進行切斷不會切到該像素電極704, 12 200912494 從而避免因切斷引起之号·+ t m Γ 電極704與該第二公共電極 7032電連接,產生短路之問題。 树=之液晶顯示面板亦可具其它多種變更設計, 、隹丄f方式之液晶顯示面板7〇之公共電極703亦可 進、^括複數弟二公共電極,該第三公共電極位於像素 區域内貧料線702之左侧,並與該第一公共電極7〇3ι垂直 ,接於-点。該像伽704 _三公共電極部份交 豐三交疊處亦形成一存儲電容。該第三公共電極一端具有 第缺口,使該第二缺口處無第三公共電極與像素電極 第六實施方式之液晶顯示面板70之像素電極704亦可 具有一與第二公共電極7032之缺口 7033對應之第二缺口。 綜上所述,本發明確已符合發明專利之要件,爰依法 提出專利申請。惟,以上所述者僅為本發明之較佳方 式’本發明之範圍並不以上述實施方式為限,舉凡S系本 案技藝之人士援依本Γ發明之精神所作之等效修都或變化, 皆應涵蓋於以下申請專利範圍内。 【圖式簡單說明】 圖1係一種先前技術液晶顯示面板之平面結構示专图。 圖2係本發明液晶顯示面板第一實施方式之平面纟士構示今 圖。 圖3係本發明液晶顯示面板第二實施方式之平面結構示音 圖。 圖4係本發明液晶顯示面板第三實施方式之平面結構示音 13 200912494 圖。 圖5係本發明液晶顯示面板第四實施方式之平面結構示意 圖。 圖6係本發明液晶顯示面板第五實施方式之平面結構示意 圖。 圖7係本發明液晶顯示面板第六實施方式之平面結構示意 圖。 【主要元件符號說明】 液晶顯不面板 20 、 30 、 40 、 50 、 60 、 70 掃描線 201 ' 301、701 資料線 202 、 302 、 402 、 702 公共電極 203 、 303 、 403 、 703 像素電極 204 、 304 ' 404 、 504 、 604 、 704 缺口 205 ' 305 、 505 、 605 、 705 第二缺口 405 、 607 、 506 第三缺口 606 第四缺口 608 第一公共電極 2031 ' 3031、4031、7031 第二公共電極 - 2032、3032、5032、6032、7032 第三公共電極 4033 、 6033 突出部 7033 第一點 208 ' 308 ' 709 第二點 第一短路点 第二短路点 斷点 408 2033 2034 708 14200912494 IX. Description of the invention: • Technical field to which the invention pertains The present invention relates to a liquid crystal display panel. [Prior Art] Liquid crystal display panels have been widely used in mobile phones, personal digital assistants, notebook computers, personal computers, and televisions due to their low radiation, small size, and low power consumption. Referring to Figure 1, there is shown a schematic diagram of a planar structure of a prior art liquid crystal display panel. The liquid crystal display panel 10 includes a plurality of scanning lines 101 that are parallel to each other, a plurality of data lines 102 that are vertically insulated from the scanning lines 101, a plurality of common electrodes 103, and a plurality of pixel electrodes 104. The scan line 101 and the data line 104 define a plurality of pixel regions (not labeled). The pixel electrode 104 is located in the pixel area. The common electrode 103 includes a first common electrode 1031 and a plurality of second common electrodes 1032. The first common electrode 1031 penetrates the pixel region and is parallel to the scan line 101. The second common electrode 1032 is located on the right side of the data line, 102 in the pixel area, and is vertically connected to the first common electrode 1031. The pixel electrode 104 partially overlaps the first common electrode 1031 and the second common electrode 1032, respectively, and a storage capacitor (not shown) is formed at the overlap. Generally, in the process of the liquid crystal display panel 10, if the surface of the substrate where the pixel region is located is not flat, or when heating or etching, a short-circuit defect between the common electrode 103 and the pixel electrode 104 is easily caused. Therefore, in order to improve the yield of the product, it is necessary to repair the short circuit. When a short circuit occurs between the first common electrode 1031 and the pixel electrode 104, if a short circuit occurs, for example, the first point 1033 shown in FIG. 1, the pixel electrode 104 can be cut along the broken line 1 shown in FIG. And a portion of the second common electrode 1032 overlapping the pixel electrode 104, thereby disconnecting the first common electrode 1031 from the pixel electrode 104. When a short circuit occurs between the second common electrode 1032 and the pixel electrode 104, for example, a short circuit occurs at the second point 1034 shown in FIG. 1, the second common electrode 1032 can be cut along the broken line 2 shown in FIG. And a portion of the pixel electrode 104 overlapping the second common electrode 1032, thereby disconnecting the second common electrode 1032 from the pixel electrode 104. It can be seen from the above that whether the short circuit between the first common electrode 1031 and the pixel electrode 104 is repaired or the short circuit between the second common electrode 1032 and the pixel electrode 104 is repaired, the second common electrode 1032 and the pixel are The electrode 104 will be cut at the same time. However, the second common electrode 1032 is cut at the same time as the pixel electrode 104, and the second common electrode 1032 is easily electrically connected to the pixel electrode 丨04, and a short circuit occurs again, resulting in successful repair of the liquid crystal display panel 10. The rate is lower. SUMMARY OF THE INVENTION In view of the above, it is necessary to provide a liquid crystal display panel with a high repair success rate. A liquid crystal display panel includes a plurality of common electrodes and a plurality of pixel electrodes. Each of the common electrodes includes a first common electrode and a plurality of second common electrodes. The second common electrode is respectively connected to the first common electrode. The pixel electrodes respectively overlap the first common electrode and the second common electrode to form a 7200912494 storage capacitor. The pixel electrodes overlap the first common electrode and the second common electrode, respectively, to form a storage capacitor. The second common electrode has a first gap corresponding to the pixel electrode, and no second common electrode overlaps the pixel electrode at the first gap. A liquid crystal display panel includes a plurality of common electrodes and a plurality of pixel electrodes. Each of the common electrodes includes a first common electrode and a plurality of second common electrodes. The second common electrode is respectively connected to the first common electrode. The pixel electrodes overlap the first common electrode and the second common electrode, respectively, to form a storage capacitor. The pixel electrode has a first notch corresponding to the second common electrode, and no pixel electrode overlaps the second common electrode at the first notch. Compared with the prior art, the second common electrode or the pixel electrode of the liquid crystal display panel of the present invention has a first gap so that the pixel electrode and the second common electrode do not overlap at the notch. When repairing the short circuit between the common electrode and the pixel electrode, cutting along the first gap position only cuts one of the pixel electrode or the second common electrode, thereby avoiding the pixel electrode caused by the cutting. The second common electrode is electrically connected, and the problem of short circuit again. Therefore, the liquid crystal display panel has a high success rate of repair. [Embodiment] Referring to Figure 2, there is shown a plan view of a first embodiment of a liquid crystal display panel of the present invention. The liquid crystal display panel 20 includes a plurality of scanning lines 201 that are parallel to each other, a plurality of data lines 202 that are vertically insulated from the scanning lines 201, a plurality of common electrodes 203, and a plurality of pixel electrodes 204. The scan line 201 and the data line 202 define a plurality of pixel regions (not labeled 8200912494). The pixel electrode 204 is located within the pixel area. The common electrode 203 includes a first common electrode 2031 and a plurality of second common electrodes 2032. The first common electrode 2031 penetrates the pixel region and is parallel to the scan line 201. The second common electrode 2032 is located on the right side of the data line 202 in the pixel region, and is perpendicularly connected to the first common electrode 2031 to a first point 208. The pixel electrode 204 partially overlaps the first common electrode 2031 and the second common electrode 2032, respectively, and a storage capacitor (not labeled) is formed at the overlap. The second common electrode 2032 has a notch 205 adjacent to one end of the first point 208. The notch 205 corresponds to a portion of the pixel electrode 204 such that the second common electrode 2032 overlaps the pixel electrode 204 at the notch 205. When a short circuit occurs between the first common electrode 2031 and the pixel electrode 204, for example, one of the first short-circuit points 2033 shown in FIG. 2, the pixel electrode 204 can be cut along the corresponding broken line 1 at the notch 205. Thereby, the connection of the first common electrode 2031 and the pixel electrode 204 is broken. When a short circuit occurs between the second common electrode 2032 and the pixel electrode 204, for example, a second short circuit point 2034 shown in FIG. 2, the second common electrode can be cut along a corresponding broken line 2 at the notch 205. 2032, thereby disconnecting the second common electrode 2032 from the pixel electrode 204. Compared with the prior art, the second common electrode 2032 of the liquid crystal display panel 20 has a notch 205 adjacent to one end of the first point, and the notch 205 corresponds to the partial pixel electrode 204 such that there is no second common electrode at the notch 205. 2032 overlaps the pixel electrode 204. Therefore, when repairing the short circuit of the liquid crystal display panel 20, cutting along the position of the notch 205 only cuts off one of the pixel 9 200912494 electrode 204 or the second common electrode 2032, thereby avoiding the The pixel electrode 204 is electrically connected to the second common electrode 2032, that is, the problem of being short-circuited again. Therefore, the repair success rate of the liquid crystal display panel 20 is relatively small. Please refer to FIG. 3, which is a schematic diagram of a planar structure of a second embodiment of a liquid crystal display panel of the present invention. The liquid crystal display panel 30 includes a plurality of scanning lines 301 that are parallel to each other, a plurality of data lines 302 that are vertically insulated from the scanning lines 301, a plurality of common electrodes 303, and a plurality of pixel electrodes 304. The scan line 301 and the data line 302 define a plurality of pixel regions. The pixel electrode 304 is located within the pixel area. The common electrode 303 includes a first common electrode 3031 and a plurality of second common electrodes 3032. The first common electrode 3031 penetrates the pixel region and is parallel to the scan line 301. The second common electrode 3032 is located on the right side of the data line 302 in the pixel area, and is perpendicularly connected to the first common electrode 3031 to a first point 308. The pixel electrodes 304 partially overlap the first common electrode 3031 and the second common electrode 3032, respectively, and a storage capacitor (not labeled) is formed at the overlap. The pixel electrode 304 has a notch 305. The position of the notch 305 corresponds to the second common electrode 3032 adjacent to the first point 308, so that the pixel electrode 304 and the second common electrode 3032 are not covered at the notch 305. . Referring to Fig. 4, there is shown a plan view of a third embodiment of a liquid crystal display panel of the present invention. The liquid crystal display panel 40 is substantially the same as the liquid crystal display panel 20 of the first embodiment. The main difference is that the common electrode 403 further includes a plurality of third common electrodes 4033, and the third common electrode 10 200912494 4033 is located in the pixel region. The data line 402 is on the left side and is perpendicularly connected to the first common electrode 4031 to a second point 408. The pixel electrode 404 partially overlaps the third common electrode 4033, and a storage capacitor is also formed at the overlap. The third common electrode 4033 has a second notch 405 adjacent to the second end 408. The notch 405 corresponds to the partial pixel electrode 404, so that the third common electrode 4033 and the pixel electrode 404 are not disposed at the second notch 405. Stack. Referring to Fig. 5, there is shown a plan view of a fourth embodiment of a liquid crystal display panel of the present invention. The liquid crystal display panel 50 is substantially the same as the liquid crystal display panel 20 of the first embodiment, and the main difference is that the pixel electrode 504 has a second gap 506 corresponding to the notch 505 of the second common electrode 5032. Referring to Fig. 6, a plan view of a fifth embodiment of a liquid crystal display panel of the present invention is shown. The liquid crystal display panel 60 is substantially the same as the liquid crystal display panel 40 of the third embodiment. The main difference is that the pixel electrode 604 has a third notch 606 corresponding to the notch 605 of the second common electrode 6032 and a The second notch 607 of the third common electrode 6033 corresponds to the fourth notch 608. Referring to Fig. 7, a plan view of a sixth embodiment of a liquid crystal display panel of the present invention is shown. The liquid crystal display panel 70 includes a plurality of scanning lines 701 parallel to each other, a plurality of data lines 702 vertically intersecting the scanning lines 701, a plurality of common electrodes 703, and a plurality of pixel electrodes 704. The scan line 701 and the data line 702 define a plurality of pixel regions (not labeled). The pixel electrode 704 is located within the pixel area. The common electrode 703 includes a first common electrode 7031 and a plurality of second common electrodes 7032. The 11 200912494 first common electrode 7031 extends through the pixel region and is parallel to the scan line 701. The second common electrode 7032 is located on the right side of the data line 702 in the pixel region, and is perpendicularly connected to the first common electrode 7031 to a first point 709. The pixel electrode 704 overlaps the first common electrode 7031 and the second common electrode 7032, respectively, and a storage capacitor is formed at the overlap. A protruding portion 7033 extends perpendicularly from the first point 709 and away from the first point 709, and the protruding portion 7033 is perpendicularly insulated from the data line 702 for repairing the data line 702. Broken line. The second common electrode 7032 has a notch 705 adjacent to the first end 709. The notch 705 corresponds to the partial pixel electrode 704, so that the second common electrode 7032 does not overlap the pixel electrode 704 at the notch 705. When it is found that the data line 702 has a break point 708, the two protrusions 7033 can be electrically connected to the father of the data line 702 by a welding method, and corresponding to the gap 7 0 5 The second common electrode 7032 is cut by a broken line 1. Thus, the data line 702 can be turned on by the second common and common electrodes 7032. That is, the signal on the data line 702 where the breakpoint 708 is located can be transmitted normally. The second common electrode 7032 of the liquid crystal display panel 70 has a notch 705 adjacent to the first end 709. The notch 705 corresponds to the partial pixel electrode 704, so that the second common electrode 7032 and the pixel electrode are not disposed at the notch 705. 704 overlap. Therefore, when the connection of the first common electrode 7031 and the second common electrode 7032 is cut off at the break point 708 of the data line 702, the cutting along the gap 705 does not cut the pixel electrode 704, 12 200912494 Therefore, the problem that the number + + tm 电极 electrode 704 is electrically connected to the second common electrode 7032 due to the cutting is prevented, and a short circuit is generated. The liquid crystal display panel of the tree= can also be modified in various other ways. The common electrode 703 of the liquid crystal display panel 7 of the 隹丄f mode can also enter and include a plurality of common electrodes, and the third common electrode is located in the pixel area. The left side of the lean line 702 is perpendicular to the first common electrode 7〇3ι and is connected to the - point. The image gamma 704 _ three common electrode portions also form a storage capacitor at the intersection of the three intersections. The third common electrode has a notch at one end, and the third common electrode and the pixel electrode are not provided at the second notch. The pixel electrode 704 of the liquid crystal display panel 70 of the sixth embodiment may also have a gap 7033 between the second and second common electrodes 7032. Corresponding to the second gap. In summary, the present invention has indeed met the requirements of the invention patent, and has filed a patent application according to law. However, the above description is only a preferred mode of the present invention. The scope of the present invention is not limited to the above-described embodiments, and those skilled in the art of the present invention may apply the equivalent modification or change according to the spirit of the present invention. , should be covered by the following patent application. BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a plan view showing the planar structure of a prior art liquid crystal display panel. Fig. 2 is a plan view showing the first embodiment of the liquid crystal display panel of the present invention. Fig. 3 is a plan view showing the structure of a second embodiment of the liquid crystal display panel of the present invention. 4 is a plan view showing the structure of a third embodiment of the liquid crystal display panel of the present invention. Fig. 5 is a plan view showing the fourth embodiment of the liquid crystal display panel of the present invention. Fig. 6 is a plan view showing the structure of a fifth embodiment of the liquid crystal display panel of the present invention. Fig. 7 is a plan view showing the structure of a sixth embodiment of the liquid crystal display panel of the present invention. [Description of main component symbols] LCD display panel 20, 30, 40, 50, 60, 70 scan line 201 ' 301, 701 data line 202, 302, 402, 702 common electrode 203, 303, 403, 703 pixel electrode 204, 304 ' 404 , 504 , 604 , 704 notch 205 ' 305 , 505 , 605 , 705 second notch 405 , 607 , 506 third notch 606 fourth notch 608 first common electrode 2031 ' 3031 , 4031 , 7031 second common electrode - 2032, 3032, 5032, 6032, 7032 third common electrode 4033, 6033 protrusion 7033 first point 208 ' 308 ' 709 second point first short point second short point break point 408 2033 2034 708 14