1376548 101年.08月10日核正替换頁 六、發明說明·· 【發明所屬之技術領域】 [0001] 本發明涉及一種導光板以及具有該導光板之背光模組。 【先前技術】 [0002] 由於液晶顯示器面板之液晶本身不具發光特性,因而, 為達到顯不效果,向液aa顯不面板提供一面光源麥 置’如背光模組,其作用在於向液晶顯示器面板供應輝 度充分且分佈均勻之面光源。 [0003] 先前技術之背光模組主要由光源、導光板、反射板、擴 散板與棱鏡板組成。該光源可設置於導光板一側或兩相 對侧並將光束發射至該導光板。該導光板之作用在於引 導光束傳輸方向,使光束由導光板之出光面均勻出射, 反射板相對該導光板之底面設置,以將由導光板底面出 射之光束再次反射入該導光板内’提南光束之利用率。 擴散板與棱鏡板相對導光板之出光面依次設置,以使由 導光板出射之光束分佈更加均勻,進而提高液晶顯示器 面板之輝度與均勻性。 [0004] 由於發光二極體具有工作電壓低、發光輝度高、回應速 度快、壽命長之優點,使其廣泛應用於手機、pda(個人 數位助理)、顯示器之背光模組中。然’發光二極體之出 射光具較強之光學指向性,即出射光具有一定之發散角 度’當其直接射入背光模組之導光板時,使得導光板入 光面一側易出現光學暗區,且與發光二極體相對之位置 易出現光柱,不易獲得較佳之入光均勻度。 [0005] 請參閱圖1與圖2,分別係一種先前技術背光模組之平面 1013305174-0 095146131^單編號Α〇1ίΠ 第3頁/共找頁 1376548 101年08月10日修正替换頁 示意圖與立體示意圖。該背光模組10包括光源12及導光 板13,導光板13包括一入光面131,一與入光面131相連 的出光面132,及一與出光面132相對之底面133。光源 12相對導光板13之入光面131設置,該光源12為若干發 光二極體,該若干發光二極體之出射光束由導光板13之 入光面131進入導光板13後,於導光板13内發生反射。該 導光板13引導光源12發出光束之傳輸方向,並將其轉換 成平面光從導光板13之出光面132出射。然而,由於發光 二極體之出射光具有一定發散角,使得導光板13之入光 面131—側出現光學暗區15及光柱16,該光學暗區15主 要分佈於二相鄰發光二極體之間,該光柱16分佈於導光 板13正對著發光二極體的位置,影響背光模組10之輝度 及出光均勻性。 [0006] 有鑒於此,有必要提供一種可使光線均勻出射之導光板 ,以及發光輝度均勻之背光模組。 【發明内容】 [0007] 以下,將以實施例說明一種可通過對入射光進行有效調 控使得光線均勻出射之導光板,以及具有該導光板之背 光模組。 [0008] 提供一種導光板,其包括一入光面,一與入光面相交之 出光面及一與出光面相對之底面。所述入光面具有至少 一凹面及至少一平面,所述至少一平面與所述至少一凹 面交替排列,用以形成不同之光接收區域,分別對應具 有不同形狀發光表面之光源,該光接收區域之形狀與光 源發光表面之形狀互補,該至少一凹面對應之光源之發 _613产單编號A〇101 第4頁/共22頁 1013305174-0 Γ376548 101年.08月10日修正替换頁 光表面為凸面,該至少一平面對應之光源之發光表面為 平面,所述凹面上設置有複數個第一微稜鏡,所述至少 一平面上設置有結構、尺寸不同於第一微棱鏡之複數個 第二微‘稜鏡。 [0009] 另外,提供一種背光模組,其包括上述導光板與至少二 光源。該至少二光源具有不同形狀之發光表面。該導光 板包括一入光面,一與入光面相交之出光面及一與出光 面相對之底面,所述入光面具有至少一凹面及至少一平 面,所述至少一平面與所述至少一凹面交替排列,用以 形成不同之光接收區域,該光接收區域之形狀與對應光 源之發光表面之形狀互補,該至少一凹面對應之光源之 發光表面為凸面,該至少一平面對應之光源之發光表面 為平面。所述凹面上設置有複數個第一微稜鏡,所述至 少一平面上設置有結構、尺寸不同於第一微稜鏡之複數 個第二微棱鏡。 [0010] 所述實施例之導光板具有以下特點:首先,導光板之入 光面可設置不同結構之凹面作為光接收區域,以實現對 不同光源發射出之光線之導引及調整;其次,凹面上設 置之微棱鏡結構亦可根據光源發射出光線之發散情況, 或根據預定導光板之導光效果進行設置,以達到實際之 需要。1376548 101. Aug. 10, 2010. The invention is related to the invention. [0001] The present invention relates to a light guide plate and a backlight module having the same. [Prior Art] [0002] Since the liquid crystal of the liquid crystal display panel itself does not have the illuminating property, in order to achieve the display effect, the liquid crystal display panel is provided with a light source, such as a backlight module, which functions as a liquid crystal display panel. A surface light source with sufficient brightness and uniform distribution is supplied. [0003] The backlight module of the prior art is mainly composed of a light source, a light guide plate, a reflection plate, a diffusion plate and a prism plate. The light source may be disposed on one side or two opposite sides of the light guide plate and emit a light beam to the light guide plate. The light guide plate is configured to guide the beam transmission direction so that the light beam is uniformly emitted from the light exit surface of the light guide plate, and the reflector plate is disposed opposite to the bottom surface of the light guide plate to reflect the light beam emitted from the bottom surface of the light guide plate into the light guide plate again. The utilization of the beam. The diffusing plate and the prism plate are arranged in sequence with respect to the light-emitting surface of the light guide plate, so that the light beam emitted from the light guide plate is more evenly distributed, thereby improving the brightness and uniformity of the liquid crystal display panel. [0004] Since the light-emitting diode has the advantages of low operating voltage, high luminance, fast response speed, and long life, it is widely used in mobile phones, pda (personal digital assistants), and backlight modules of displays. However, the light emitted by the light-emitting diode has a strong optical directivity, that is, the emitted light has a certain divergence angle. When it is directly incident on the light guide plate of the backlight module, the light-emitting plate is easily exposed to the light-incident side. In the dark region, and the position opposite to the light-emitting diode is prone to appear light column, it is difficult to obtain better uniformity of light entering. [0005] Please refer to FIG. 1 and FIG. 2, which are respectively a plane of a prior art backlight module, 1013305174-0 095146131^, single number Α〇1ίΠ, page 3/total page 1376548, revised on August 10, 2010 Stereoscopic view. The backlight module 10 includes a light source 12 and a light guide plate 13. The light guide plate 13 includes a light incident surface 131, a light exit surface 132 connected to the light incident surface 131, and a bottom surface 133 opposite to the light exit surface 132. The light source 12 is disposed on the light incident surface 131 of the light guide plate 13. The light source 12 is a plurality of light emitting diodes. The light beam of the plurality of light emitting diodes enters the light guide plate 13 from the light incident surface 131 of the light guide plate 13 and is disposed on the light guide plate. Reflection occurred within 13. The light guide plate 13 guides the light source 12 to emit a light beam, and converts it into planar light to be emitted from the light exit surface 132 of the light guide plate 13. However, since the emitted light of the light-emitting diode has a certain divergence angle, the optical dark area 15 and the light column 16 appear on the light-emitting surface 131 side of the light guide plate 13, and the optical dark area 15 is mainly distributed in two adjacent light-emitting diodes. The position of the light column 16 is opposite to the position of the light guide plate 13 facing the light emitting diode, which affects the brightness and uniformity of the light output of the backlight module 10. In view of the above, it is necessary to provide a light guide plate that can uniformly emit light, and a backlight module with uniform luminance. SUMMARY OF THE INVENTION [0007] Hereinafter, a light guide plate that can uniformly emit light by effectively adjusting incident light, and a backlight module having the light guide plate will be described by way of embodiments. [0008] A light guide plate is provided, which includes a light incident surface, a light exit surface intersecting the light incident surface, and a bottom surface opposite to the light exit surface. The light incident surface has at least one concave surface and at least one plane, and the at least one plane and the at least one concave surface are alternately arranged to form different light receiving regions respectively corresponding to light sources having different shapes of light emitting surfaces, and the light receiving The shape of the area is complementary to the shape of the light-emitting surface of the light source, and the light source corresponding to the at least one concave surface _613 production order number A〇101 4th page/total 22 pages 1013305174-0 Γ376548 101. August 10th revised replacement page The light surface is a convex surface, and the light emitting surface of the light source corresponding to the at least one plane is a plane, and the concave surface is provided with a plurality of first micro turns, and the at least one plane is provided with a structure different from the first microprism. A plurality of second micro '稜鏡. In addition, a backlight module is provided, including the above-mentioned light guide plate and at least two light sources. The at least two light sources have different shapes of light emitting surfaces. The light guide plate includes a light incident surface, a light exit surface intersecting the light incident surface, and a bottom surface opposite to the light exit surface, the light incident surface having at least one concave surface and at least one plane, the at least one plane and the at least one plane A concave surface is alternately arranged to form different light receiving regions, wherein the shape of the light receiving region is complementary to the shape of the light emitting surface of the corresponding light source, and the light emitting surface of the light source corresponding to the at least one concave surface is a convex surface, and the light source corresponding to the at least one plane The light emitting surface is a flat surface. A plurality of first micro-turns are disposed on the concave surface, and at least one plane is provided with a plurality of second microprisms having a structure different from the first micro-turn. [0010] The light guide plate of the embodiment has the following features: First, the light incident surface of the light guide plate can be provided with concave surfaces of different structures as light receiving regions, so as to realize guiding and adjusting light emitted by different light sources; secondly, The microprism structure disposed on the concave surface may also be set according to the divergence of the light emitted by the light source, or according to the light guiding effect of the predetermined light guide plate, to achieve the actual needs.
II
[0011] 所述具有上述導光板之背光模組具有以下特點:根據所 述導光板之入光面特點可與不同種類之光源相配合,從 而形成具有多種發光效果之多功能背光模組,以便用於 多種電子產品中。 095146131^^^ A〇101 第5頁/共22頁 1013305174-0 1376548 __ 101年08月10日梭正替换頁 【實施方式】 [0012] 以下將結合附圖及複數個實施例對本技術方案之導光板 及具有該導光板之背光模組進行具體說明。 [0013] 如圖3與圖4所示,本技術方案第一實施例提供一種導光 板200,其包括一入光面21 0,一出光面2 2 0,一底面2 3 0 及複數個側面240。所述入光面210用來接收光源發出之 光線,所述出光面220與入光面210相交,所述底面230 與出光面220相對,所述複數個側面240用以連結入光面. 210、出光面220及底面230,以形成導光板200整體結構 。本實施例中,所述出光面220與入光面210垂直相交, 底面230與出光面220平行相對且與入光面210垂直相交 〇 [0014] 所述入光面210形成有至少一凹面或凸面作為光接收區域 ,用以與形狀相對應之光源相配合,以便使得光源發出 之光線依照預定之散射角度進入導光板200,並且使得進 入導光板200之光線以預定之光能量分佈於預定之區域, 從而達到導光板200入光面210對入射光之有效控制與調 配,為導光板200實現高品質之光線傳輸提供前提。例如 ,當光源之發光表面為凸面時,入光面210上與光源相對 之區域最好設置為凹面,而當光源之發光表面為凹面時 ,入光面210上與光源相對之區域最好設置為凸面。本實 施例中,導光板200用於與具有ώ面之至少一光源配合, 因此入光面210形成有至少一第一凹槽211。所述第一凹 槽211貫通出光面220與底面230,且第一凹槽211之表面 即為一凹面(圖未示),該凹面與出光面220與底面230相 095146131^^^^ Α〇101 第6頁/共22頁 1013305174-0 1376548 101年.08月10日核正替換頁 接通。 [0015] 所述第一凹槽211之縱向延伸方向(即,從導光板200之底 面230向出光面220之垂直延伸方向,或從出光面220向 底面230之垂直延伸方向)與入光面210之縱向延伸方向( 即,從底面230向出光面220之垂直延伸方向,或從出光 面220向底面230之垂直延伸方向)相平行。所述第一凹槽 211沿其縱向延伸方向之投影可以為U形、V形、弧形等規 則或不規則形狀。本實施例中入光面210設置兩第一凹槽 211,且該兩第一凹槽211沿其縱向延伸方向之投影均為 相同形狀與尺寸之弧形。 [0016] 為能夠進一步對從入光面210進入導光板200之光線之散 射角度與光線傳播之均勻性進行調控與分配,入光面210 之第一凹槽211中進一步設置有第一微稜鏡213,具體為 至少一第一微棱鏡213設置於第一凹槽211之表面。所述 每一第一微稜鏡213垂直於其與第一凹槽211之凹面接觸 點之切線,即,複數個第一微稜鏡213於第一凹槽211之 表面排列成一曲面體,該曲面體與第一凹槽211之結構相 似,亦即,該曲面體定義出與第一凹槽211形狀相同之另 一凹槽。此外,所述複數個第一微稜鏡213貫通出光面 220與底面230形成於第一凹槽211之表面,且所述複數 個第一微棱鏡213最好結構、尺寸相同,並且相互平行地 且間隔相等地形成於所述入光面210之第一凹槽211之表 面。 [0017] 所述第一微稜鏡213可為凹槽結構,亦可為凸塊結構,以 凸塊結構為例具體說明第一微棱鏡213之特點,即,於第 0951461#單編號纽01 第7頁/共22頁 1013305174-0 1376548 101年08月10日核正替換頁 一凹槽211之表面設置複數個三棱柱,優選地,所述複數 個三棱柱均勻分佈於第一凹槽211之表面,且所述三棱柱 按照與第一凹槽211相同之曲率半徑排列成與第一凹槽 211相同曲率之曲面,即,複數個三棱柱形第一微稜鏡 213所排列成之曲面體於底面230上之投影與第一凹槽 211於底面230上之投影形狀、曲率相同。本實施例中, 第一凹槽211於底面230上之投影為弧形,複數個三棱柱 形第一微稜鏡213垂直於出光面220及底面230,且複數 個三棱柱形第一微棱鏡213所排列成之形狀於底面230上 之投影亦為與第一凹槽211之投影相同曲率之弧形。 [0018] 所述入光面210上之第一凹槽211之尺寸與形狀以將入射 光之輝度視角限定於140度之範圍内為准,最好限定於 100度之範圍内。複數個三棱柱形第一微稜鏡213均勻地 且以與第一凹槽211相同曲率分佈於第一凹槽211表面, 一方面可配合第一凹槽211更好之將入射光之輝度視角限 定於140度(包括140度)之範圍内,或最好限定於100度 之範圍内;另一方面,可使入射光輝度均勻地分佈於上 述140度或100度之視角範圍内。 [0019] 所述出光面220上亦形成有至少一出光微棱鏡221,以實 現光線依照預定之出射視角以及預定均勻之輝度從導光 板200導出。所述微稜鏡221可為凹槽,亦可為凸塊。例 如,導光板200之出光面220表面設置複數個凸塊狀出光 微棱鏡221,且複數個出光微棱鏡221形狀、尺寸相同, 並且複數個出光微稜鏡221均勻地分佈於出光面220上。 所述出光微棱鏡221之橫向延伸方向(即,從出光面220與 _613产單编號A0101 第8頁/共22頁 1013305174-0 1376548 101年.08月10日按正替換頁 入光面210相交之一邊向出光面220之另一相對邊垂直延 伸之方向,或相反地,從出光面220與入光面210相對一 側面240相交之一邊向出光面220之另一相對邊垂直延伸 之方向)與出光面22 0之橫向延伸方向(即,從出光面220 與入光面210相交之一邊向出光面220之另一相對邊垂直 延伸之方向,或相反地,從出光面220與入光面210相對 之側面240相交之一邊向出光面220之另一相對邊垂直延 伸之方向)相平行或一致。 [0020] 所述出光微稜鏡221沿其橫向延伸方向之投影可為三角形 、梯形、扇形、圓缺(小於半圓之圖形,由劣弧與直線而 圍成之圖形)。所述出光微棱鏡221滿足條件:光線經出 光微稜鏡221折射後之視角小於等於110度,最好小於等 於100度。本實施例中,出光微稜鏡221沿其橫向延伸方 向之投影為三角形,即,出光微棱鏡221為三棱柱。 [0021] 由於導光板200入光面210可設置不同結構之第一凹槽 211,例如不同曲率之弧面形凹槽,可得到不同結構之入 射區域以實現對不同光源發射出光線之導引與調整,因 此本實施例之導光板200可與不同種類之光源相配合形成 背光模組,並且使得所得到之背光模組具有複數種發光 效果。另外,第一凹槽211上之第一微棱鏡即第二凹槽 213之結構亦可根據光源發射出光線之發散情況,或根據 預定導光板之導光效果進行設置,以達到實際之需要。 [0022] 如圖5與圖6所示,本技術方案第二實施例之導光板300與 第一實施例之導光板200結構大體相同,除入光面310與 出光面320之結構外。第二實施例之導光板300之入光面 〇9514613产單編號 Α0101 第9頁/共22頁 1013305174-0 1376548 101年08月10日修正替换頁 310定義至少一凹面311與至少一平面312 ’所述凹面311 貫通出光面320及與出光面320相對之底面(圖未標示), 同樣所述平面312與出光面320及與出光面320相對之底 面相接通,且平面312垂直於出光面320。本實施例中, 入光面310定義有兩凹面311與三個平面312,且凹面311 與平面312交替排列,凹面311與平面312分別與出光面 320及與出光面320相對之底面相連通,且平面312垂直 於出光面320。 [〇〇23] 凹面311上形成有第一微棱鏡陣列313,平面312上形成 有第二微稜鏡陣列314,且第一微稜鏡陣列313與第二微 稜鏡陣列314分別與出光面320及與出光面320相對之底 面相連通。第一微稜鏡陣列31 3中每一第一微稜鏡垂直於 該第一微稜鏡與凹面311接觸點之切線,即,第一微棱鏡 陣列313於凹面311上排列成一曲面體,該曲面體與凹面 311之結構相似,亦即’該曲面體定義出與凹面3丨丨形狀 相同之另一凹面。所述第二微稜鏡陣列314與平面312平 行’且第二微稜鏡陣列314中第二微棱鏡上相同點到平面[0011] The backlight module having the light guide plate has the following features: according to the light entrance surface characteristic of the light guide plate, it can cooperate with different types of light sources to form a multifunctional backlight module having multiple illumination effects, so that Used in a variety of electronic products. 095146131^^^ A〇101 Page 5 of 22 pages 1013305174-0 1376548 __August 10th, 2010 Shuttle replacement page [Embodiment] [0012] Hereinafter, the technical solution will be described with reference to the accompanying drawings and a plurality of embodiments. The light guide plate and the backlight module having the light guide plate are specifically described. As shown in FIG. 3 and FIG. 4 , the first embodiment of the present invention provides a light guide plate 200 including a light incident surface 21 0 , a light exit surface 2 2 0 , a bottom surface 2 3 0 , and a plurality of sides. 240. The light incident surface 210 is configured to receive the light emitted by the light source. The light emitting surface 220 intersects the light incident surface 210. The bottom surface 230 is opposite to the light emitting surface 220. The plurality of side surfaces 240 are used to join the light surface. 210 The light-emitting surface 220 and the bottom surface 230 are formed to form an overall structure of the light guide plate 200. In this embodiment, the light-emitting surface 220 and the light-incident surface 210 intersect perpendicularly, and the bottom surface 230 is parallel to the light-emitting surface 220 and perpendicular to the light-incident surface 210. [0014] The light-incident surface 210 is formed with at least one concave surface or The convex surface serves as a light receiving region for matching the light source corresponding to the shape, so that the light emitted by the light source enters the light guide plate 200 according to a predetermined scattering angle, and the light entering the light guide plate 200 is distributed with a predetermined light energy at a predetermined wavelength. The region, thereby achieving effective control and deployment of the incident light by the light-incident surface 210 of the light guide plate 200, provides a prerequisite for the light-guide plate 200 to achieve high-quality light transmission. For example, when the light emitting surface of the light source is convex, the area of the light incident surface 210 opposite to the light source is preferably set to a concave surface, and when the light emitting surface of the light source is concave, the area of the light incident surface 210 opposite to the light source is preferably set. It is convex. In this embodiment, the light guide plate 200 is configured to cooperate with at least one light source having a kneading surface. Therefore, the light incident surface 210 is formed with at least one first groove 211. The first groove 211 penetrates the light emitting surface 220 and the bottom surface 230, and the surface of the first groove 211 is a concave surface (not shown), and the concave surface and the light emitting surface 220 and the bottom surface 230 are 095146131^^^^ 101 Page 6 of 22 1013305174-0 1376548 101. On August 10, the nuclear replacement page is connected. [0015] The longitudinal direction of the first groove 211 (ie, the direction from the bottom surface 230 of the light guide plate 200 to the vertical direction of the light exit surface 220, or the vertical direction from the light exit surface 220 to the bottom surface 230) and the light incident surface The longitudinal extension direction of 210 (i.e., the direction from the bottom surface 230 to the vertical direction of the light exit surface 220, or the direction from the light exit surface 220 to the vertical direction of the bottom surface 230) is parallel. The projection of the first groove 211 along its longitudinal extension direction may be a regular or irregular shape such as a U shape, a V shape, an arc shape or the like. In the embodiment, the light-incident surface 210 is provided with two first grooves 211, and the projections of the two first grooves 211 along the longitudinal extension direction thereof are arcs of the same shape and size. [0016] In order to further adjust and distribute the scattering angle of the light entering the light guide plate 200 from the light incident surface 210 and the uniformity of the light propagation, the first groove 211 of the light incident surface 210 is further provided with a first micro edge. The mirror 213 , specifically the at least one first microprism 213 , is disposed on the surface of the first recess 211 . Each of the first micro-twist 213 is perpendicular to a tangent to the concave contact point of the first groove 211, that is, the plurality of first micro-strips 213 are arranged on the surface of the first groove 211 to form a curved body. The curved body is similar in structure to the first groove 211, that is, the curved body defines another groove having the same shape as the first groove 211. In addition, the plurality of first micro-piles 213 are formed on the surface of the first groove 211 through the light-emitting surface 220 and the bottom surface 230, and the plurality of first micro-prisms 213 are preferably identical in structure and size, and are parallel to each other. And being equally formed on the surface of the first groove 211 of the light incident surface 210. [0017] The first micro-clip 213 may be a groove structure or a bump structure, and the features of the first micro-prism 213 are specifically described by using a bump structure as an example, that is, the number 0951461# single number button 01 Page 7 of 22 Page 1013305174-0 1376548 On August 10, 101, the surface of the replacement page-groove 211 is provided with a plurality of triangular prisms. Preferably, the plurality of triangular prisms are evenly distributed in the first recess 211. a surface of the triangular prism which is arranged to have the same curvature as the first groove 211 according to the same radius of curvature as the first groove 211, that is, a plurality of triangular prism-shaped first micro-strips 213 are arranged in a curved surface The projection on the bottom surface 230 is the same as the projection shape and curvature of the first groove 211 on the bottom surface 230. In this embodiment, the projection of the first groove 211 on the bottom surface 230 is curved, and the plurality of triangular prism-shaped first micro-strips 213 are perpendicular to the light-emitting surface 220 and the bottom surface 230, and the plurality of triangular prism-shaped first microprisms The projections of the shape 213 arranged on the bottom surface 230 are also curved in the same curvature as the projection of the first groove 211. [0018] The size and shape of the first recess 211 on the light incident surface 210 is such that the luminance angle of view of the incident light is limited to 140 degrees, preferably within a range of 100 degrees. The plurality of triangular prism-shaped first micro-tunes 213 are evenly distributed on the surface of the first recess 211 with the same curvature as the first recess 211, and the first recess 211 can be matched to better reflect the incident light. It is limited to a range of 140 degrees (including 140 degrees), or preferably limited to 100 degrees; on the other hand, the incident light luminance can be uniformly distributed within the above-mentioned 140-degree or 100-degree viewing angle range. [0019] At least one light-emitting microprism 221 is also formed on the light-emitting surface 220 to realize light emission from the light guide plate 200 according to a predetermined exit angle of view and a predetermined uniform brightness. The micro-turn 221 may be a groove or a bump. For example, a plurality of bump-shaped light-emitting microprisms 221 are disposed on the surface of the light-emitting surface 220 of the light guide plate 200, and a plurality of light-emitting microprisms 221 have the same shape and size, and a plurality of light-emitting micro-rules 221 are evenly distributed on the light-emitting surface 220. The lateral direction of the light-emitting microprism 221 (ie, from the light-emitting surface 220 and the _613 production order number A0101 page 8 / total 22 pages 1013305174-0 1376548 101 years. August 10th, according to the replacement page into the glossy surface One of the intersections of 210 intersects the other opposite side of the light exit surface 220, or conversely, one side of the light exit surface 220 intersecting the light incident surface 210 opposite the one side 240 extends perpendicularly to the other opposite side of the light exit surface 220. The direction is the direction in which the light-emitting surface 22 extends laterally (ie, the direction from the side where the light-emitting surface 220 intersects the light-incident surface 210 to the other opposite side of the light-emitting surface 220, or vice versa, from the light-emitting surface 220 and One side of the smooth surface 210 intersecting the side surface 240 is parallel or uniform with respect to the direction in which the other opposite side of the light exit surface 220 extends vertically. [0020] The projection of the light-emitting pupil 221 along its lateral extension direction may be a triangle, a trapezoid, a fan, or a circle (a pattern smaller than a semicircle, a pattern surrounded by a bad arc and a straight line). The light-emitting microprism 221 satisfies the condition that the angle of view of the light refracted by the light-emitting pupil 221 is less than or equal to 110 degrees, preferably less than 100 degrees. In this embodiment, the projection of the light-emitting pupil 221 along its lateral extension direction is a triangle, that is, the light-emitting microprism 221 is a triangular prism. [0021] Since the first light groove 211 of different structures can be disposed on the light-incident surface 210 of the light guide plate 200, for example, the arc-shaped groove with different curvatures, the incident regions of different structures can be obtained to realize the light emission from different light sources. The light guide plate 200 of the present embodiment can be combined with different types of light sources to form a backlight module, and the resulting backlight module has a plurality of light-emitting effects. In addition, the structure of the first microprism, that is, the second recess 213, on the first recess 211 may also be set according to the divergence of the light emitted by the light source or according to the light guiding effect of the predetermined light guide plate to achieve the actual needs. As shown in FIG. 5 and FIG. 6, the light guide plate 300 of the second embodiment of the present invention has substantially the same structure as the light guide plate 200 of the first embodiment, except for the structure of the light surface 310 and the light exit surface 320. The light-receiving surface of the light guide plate 300 of the second embodiment is 9514613. The production number is Α0101. Page 9/22 pages 1013305174-0 1376548 The correction replacement page 310 of August 10 defines at least one concave surface 311 and at least one plane 312 ' The concave surface 311 passes through the light-emitting surface 320 and the bottom surface opposite to the light-emitting surface 320 (not shown). Similarly, the plane 312 is connected to the light-emitting surface 320 and the bottom surface opposite to the light-emitting surface 320, and the plane 312 is perpendicular to the light-emitting surface. 320. In this embodiment, the light incident surface 310 defines two concave surfaces 311 and three flat surfaces 312, and the concave surface 311 and the flat surface 312 are alternately arranged. The concave surface 311 and the flat surface 312 are respectively connected to the light emitting surface 320 and the bottom surface opposite to the light emitting surface 320. And the plane 312 is perpendicular to the light exit surface 320. [〇〇23] A first microprism array 313 is formed on the concave surface 311, and a second micro-array array 314 is formed on the plane 312, and the first micro-array array 313 and the second micro-array array 314 are respectively connected to the light-emitting surface. 320 and the bottom surface opposite to the light exit surface 320 are connected. Each first micro-turn of the first micro-array array 31 3 is perpendicular to a tangent to the contact point of the first micro-turn and the concave surface 311, that is, the first micro-prism array 313 is arranged on the concave surface 311 as a curved body. The curved body is similar in structure to the concave surface 311, that is, the curved surface defines another concave surface having the same shape as the concave surface. The second micro-array array 314 is parallel to the plane 312 and the second micro-prism in the second micro-array array 314 is the same point-to-plane
V 312表面之距離相等。所述第一微稜鏡陣列313與第二微 棱鏡陣列314交替排列於入光面31〇。第一微棱鏡陣列 313係由相同結構、相同尺寸之複數個第一微棱鏡相互平 行且間隔相同地排列組成;第二微棱鏡陣列314由相同結 構、相同尺寸之複數個第二微稜鏡相互平行且間隔相同 地排列組成,其中,組成第一微棱鏡陣列313之第一微棱 鏡之結構、尺寸與組成第二微棱鏡陣列314之第二微稜鏡 之結構、尺寸不同。本實施例中’第一微稜鏡陣列31 3為 〇9514613产單編號 A0101 第10頁/共22頁 1013305174-0 ^/6548 101年08月10日修正替換頁 三棱柱陣列,且經過第一微稜鏡陣列313之光線之視角為 100度,第二微稜鏡陣列314為V形凹槽陣列,且經過第二 微稜鏡陣列314之光線之視角為140度。 [〇〇24] 所述導光板300之出光面320形成有至少一第三微稜鏡陣 列321與至少一第四微棱鏡陣列322,所述第三微棱鏡陣 列321與第四微棱鏡陣列322排列於出光面320。所述第 三微稜鏡陣列321與入光面310之第一微棱鏡陣列313相 對應設置,例如,第三微稜鏡陣列321與第一微棱鏡陣列 313垂直相交》所述第四微稜鏡陣列322與第二微稜鏡陣 歹'J314相對應設置,例如,第四微棱鏡陣列322與第二微 稜鏡陣列314垂直相交。 [〇〇25] 第三微稜鏡陣列3 21與第四微棱鏡陣列3 2 2分別由相同結 構尺寸之微稜鏡平行且相同間隔地排列組成,其中,組 成第三微稜鏡陣列321之微棱鏡之結構與組成第四微棱鏡 陣列322之微稜鏡之結構不同》本實施例中,第三微稜鏡 陣列321為三棱柱陣列,且經過第三微稜鏡陣列321之光 線之視角為1〇〇度。而第四微稜鏡陣列322為圓缺形柱體 ’所謂圓缺形枉體係指,柱體之底面為圓缺面(有一條弧 和一條線段為成之形狀),第四微稜鏡陣列322中之每一 微稜鏡亦可看作係沿圓杈體轴線切取一定角度之扇形醴 ’該扇形體之底面為扇形,以該扇形面上之弧線所對應 之弦與兩條直線邊所圍成之三角形為底面,於該扇形體 上且除一三棱柱後所剩餘之柱體結構,即為第四微稜鏡 陣列322之一微梭鏡結構。經過第四微稜鏡陣列322之光 線之視角為110度。 1013305174-0 〇951妨13产單蝙號Αοιοι 第11頁/共22頁 1376548 ιοί年〇8月ίο日核正替换π [0026] 由於入光面310形成有不同結構之入射區域以實現對不同 光源發射出之光線之導引與調整,因此本實施例中之導 光板可與不同種類之光源相配合形成背光模組。例如對 於入光面之第一凹面311區域可設置發光面為凸面之光源 ,而第一平面312區域可設置發光面為平面之光源,因此 ,該導光板可同時配合不同種類之複數個光源進行使用 。另外,第一凹面311之第一微稜鏡31 3與第一平面31 2 之第二微稜鏡314之結構亦可根據光源發射出光線之發散 情況,或根據預定導光板之導光效果進行設置,以達到 實際之需要。 [0027] 如圖7所示,本技術方案第三實施例提供一種具有第一實 施例中導光板20 0之背光模組400。所述背光模組40 0包 括至少一光源410與一導光板200。所述光源410具有一 發光表面411,且該發光表面411之結構與導光板200入 光面210之光接收區域之結構相對應。所述光源410設置 於導光板200入光面210之光接收區域相對之位置,且發 光表面411與入光面210之光接收區域相對設置。所謂發 光表面411之結構與導光板200入光面210之光接收區域 之結構相對應,係指發光表面411之形狀與導光板200入 光面210之光接收區域之形狀呈互補關係,即,當光源 410之發光表面411為凸面時,入光面210上與光源相對 之光接收區域最好設置為凹面,而當光源410之發光表面 411為凹面時,入光面210上與光源相對之光接收區域最 好設置為凸面。 [0028] 本實施例中,導光板200之入光面210上開設有兩第一凹 1013305174-0 第12頁/共22頁 1376548 101年.08月10日慘正替换頁 槽211作為光接收區域,與每一第一凹槽211相對之位置 • 設置有兩光源410。所述光源410之發光表面4Π之形狀 與第一凹槽211之形狀相對應,即,發光表面411之形狀 與第一凹槽211之形狀呈互補關係,例如,當第—凹槽 211於導光板200之底面230(參見圖3)上之投影為弧形時 ,發光表面411於導光板200之底面230(參見圖3)之延長 面上之投影為與第一凹槽211之投影相同曲率之弧形。 [0029] 本實施例之背光模組4〇〇令,導光板200入光面21〇可設 置不同結構之第一凹槽211 ,例如不同曲率之弧面形凹槽 ,以配置與該第一凹槽211相對應之不同種類之光源41〇( 如點光源、面光源等),可得到具有複數種發光功能及效 果之背光模組400。 [0030] 如圖8所示,本技術方案第四實施例提供一種具有第二實 施例中導光板300之背光模組500 ^所述背光模組5〇〇包 括至少一光源與一導光板3〇〇。由於導光板30〇之入光面 具有兩第一凹面311與三個第一平面312,且第一凹面 311與第一平面312交錯排列。為此,背光模組5〇〇中包 括兩第一光源510與三個第二光源52〇 β兩第一光源51〇 为別設置於導光板300之兩第一凹面311相對之位置,且 二個第二光源520分別設置於導光板3〇〇之三個第二平面 312相對之位置。 [〇〇31]本實施例之背光模組5〇〇中,導光板300之入光面310設 置複數個光接收區域,如第一凹面311與第二平面312, 以同時配合不同種類之複數個光源(如點光源、面光源等 )組成具有複數種發光特點之多功能背光模組5〇〇 ,從而 095146131*單編號Α0101 第13頁/共22頁 1013305174-0 1376548 1101年08月10日修正替換β 使得該背光模組500可用於多種電子產品。 · [0032] 綜上所述,本發明確已符合發明專利之要件,遂依法提 出專利申請。惟,以上所述者僅為本發明之較佳實施方 式,自不能以此限制本案之申請專利範圍。舉凡熟悉本 案技藝之人士援依本發明之精神所作之等效修飾或變化 ,皆應涵蓋於以下申請專利範圍内。 【圖式簡單說明】 [0033] 圖1為先前技術背光模組之平面示意圖。 [0034] 圖2為先前技術背光模組之立體示意圖。 [0035] 圖3為本技術方案第一實施例之導光板之立體示意圖。 [0036] 圖4為本技術方案第一實施例之導光板之平面示意圖。 [0037] 圖5為本技術方案第二實施例之導光板之立體示意圖。 [0038] 圖6為本技術方案第二實施例之導光板之平面示意圖。 [0039] 圖7為本技術方案第三實施例之背光模組平面示意圖。 [0040] 圖8為本技術方案第四實施例之背光模組平面示意圖。 【主要元件符號說明】 [0041] 導光板:200,300 [0042] 背光模組:400,500 [0043] 入光面:210,310 [0044] 出光面:220,320 [0045] 底面:2 3 0 09514613^^^ Α〇101 第14頁/共22頁 1013305174-0 1376548 [0046] 側面:2 4 0 [0047] 第一凹槽:211 [0048] 第一微稜鏡:213 [0049] 出光微稜鏡:221 [0050] 凹面:311 [0051] 平面:312 [0052] 第一微稜鏡陣列: 313 [0053] 第二微稜鏡陣列: 314 [0054] 第三微稜鏡陣列: 321 [0055] 第四微棱鏡陣列: 322 [0056] 光源:41 0 [0057] 發光表面:411 [0058] 第一光源:51 0 [0059] 第二光源:520 0951461#單編號删1 第15頁/共22頁 101年.08月10日梭正替換頁 1013305174-0The distances of the V 312 surfaces are equal. The first micro-array array 313 and the second micro-prism array 314 are alternately arranged on the light-incident surface 31A. The first microprism array 313 is composed of a plurality of first microprisms of the same structure and the same size arranged parallel to each other and equally spaced; the second microprism array 314 is composed of a plurality of second microstrips of the same structure and the same size. The components are arranged in parallel and at the same interval, wherein the structure and size of the first microprism constituting the first microprism array 313 are different from the structure and size of the second microcube constituting the second microprism array 314. In the present embodiment, the first micro-array array 31 3 is 〇9514613, the production order number A0101, the 10th page, the total 22 pages, the 1013305174-0^/6548, the correction of the replacement page triangular prism array on August 10, and after the first The viewing angle of the light of the micro-array array 313 is 100 degrees, the second micro-turn array 314 is a V-shaped groove array, and the viewing angle of the light passing through the second micro-turn array 314 is 140 degrees. The light-emitting surface 320 of the light guide plate 300 is formed with at least one third micro-array array 321 and at least one fourth micro-prism array 322, and the third micro-prism array 321 and the fourth micro-prism array 322. Arranged on the light exit surface 320. The third micro-array array 321 is disposed corresponding to the first micro-prism array 313 of the light-incident surface 310, for example, the third micro-array array 321 is perpendicularly intersected with the first micro-prism array 313. The mirror array 322 is disposed corresponding to the second micro-array array 'J314, for example, the fourth micro-prism array 322 and the second micro-array array 314 intersect perpendicularly. [〇〇25] The third micro-array array 3 21 and the fourth micro-prism array 3 2 2 are respectively arranged in parallel and at the same interval by the micro-稜鏡 of the same structural size, wherein the third micro-array array 321 is formed. The structure of the microprism is different from the structure of the micro-iridium constituting the fourth microprism array 322. In this embodiment, the third micro-iridium array 321 is a triangular prism array, and the light passing through the third micro-array array 321 is viewed from the perspective of the light. It is 1 degree. The fourth micro-array array 322 is a round-shaped cylinder. The so-called round-shaped 枉 system means that the bottom surface of the cylinder is a circular defect surface (there is an arc and a line segment is formed into a shape), and the fourth micro 稜鏡 array Each of the micro-turns 322 can also be regarded as a fan-shaped shape that is cut at a certain angle along the axis of the circular body. The bottom surface of the sector is a fan shape, and the chord and the two straight sides corresponding to the arc on the sector The enclosed triangle is a bottom surface, and the remaining cylindrical structure on the sector and except for a triangular prism is a micro-shock mirror structure of the fourth micro-array array 322. The viewing angle of the light passing through the fourth micro-array array 322 is 110 degrees. 1013305174-0 〇 妨 妨 产 产 产 产 ι ι ι ι ι ι ι ι ι ι ι ι ι ι ι ι ι ι 0026 0026 0026 0026 0026 0026 0026 0026 0026 0026 0026 0026 0026 0026 0026 0026 0026 0026 0026 0026 0026 0026 0026 0026 0026 0026 0026 0026 0026 0026 0026 0026 0026 0026 0026 The light guide plate is guided and adjusted by the light source. Therefore, the light guide plate in this embodiment can cooperate with different types of light sources to form a backlight module. For example, the first concave surface 311 of the light incident surface may be provided with a light source having a convex surface, and the first flat surface 312 may be provided with a light source having a flat light surface. Therefore, the light guide plate can simultaneously be combined with a plurality of light sources of different types. use. In addition, the structure of the first micro-turn 31 3 of the first concave surface 311 and the second micro-turn 314 of the first plane 31 2 may also be based on the divergence of the light emitted by the light source, or according to the light guiding effect of the predetermined light guide plate. Set up to meet actual needs. As shown in FIG. 7, a third embodiment of the present invention provides a backlight module 400 having a light guide plate 20 in the first embodiment. The backlight module 40 includes at least one light source 410 and one light guide plate 200. The light source 410 has a light emitting surface 411, and the structure of the light emitting surface 411 corresponds to the structure of the light receiving region of the light incident surface 210 of the light guide plate 200. The light source 410 is disposed at a position opposite to the light receiving area of the light incident surface 210 of the light guide plate 200, and the light emitting surface 411 is disposed opposite to the light receiving area of the light incident surface 210. The structure of the light-emitting surface 411 corresponds to the structure of the light-receiving region of the light-incident surface 210 of the light guide plate 200, which means that the shape of the light-emitting surface 411 is complementary to the shape of the light-receiving region of the light-incident surface 210 of the light guide plate 200, that is, When the light emitting surface 411 of the light source 410 is convex, the light receiving surface of the light incident surface 210 opposite to the light source is preferably disposed as a concave surface, and when the light emitting surface 411 of the light source 410 is concave, the light incident surface 210 is opposite to the light source. The light receiving area is preferably set to be convex. [0028] In this embodiment, the light-incident surface 210 of the light guide plate 200 is provided with two first recesses 1013305174-0. 12th page/total 22 pages 1376548 101. August 10th misplaced page slot 211 as light receiving The area, opposite to each of the first grooves 211, is provided with two light sources 410. The shape of the light emitting surface 4 of the light source 410 corresponds to the shape of the first groove 211, that is, the shape of the light emitting surface 411 is complementary to the shape of the first groove 211, for example, when the first groove 211 is guided When the projection on the bottom surface 230 (see FIG. 3) of the light plate 200 is curved, the projection of the light emitting surface 411 on the extended surface of the bottom surface 230 (see FIG. 3) of the light guide plate 200 is the same curvature as the projection of the first groove 211. The arc shape. [0029] In the backlight module 4 of the embodiment, the light-incident surface 21 of the light guide plate 200 can be provided with a first groove 211 of different structure, such as a curved surface groove of different curvature, to be configured with the first The different types of light sources 41 〇 (such as point light sources, surface light sources, etc.) corresponding to the grooves 211 can obtain a backlight module 400 having a plurality of light-emitting functions and effects. [0030] As shown in FIG. 8, the fourth embodiment of the present invention provides a backlight module 500 having a light guide plate 300 in the second embodiment. The backlight module 5 includes at least one light source and a light guide plate 3. Hey. Since the light incident surface of the light guide plate 30 has two first concave surfaces 311 and three first flat surfaces 312, the first concave surface 311 and the first flat surface 312 are staggered. To this end, the backlight module 5 includes two first light sources 510 and three second light sources 52 〇 β. The first light sources 51 are disposed opposite to the first concave surfaces 311 of the light guide plate 300, and The second light sources 520 are respectively disposed at positions opposite to the three second planes 312 of the light guide plate 3〇〇. In the backlight module 5 of the present embodiment, the light incident surface 310 of the light guide plate 300 is provided with a plurality of light receiving regions, such as a first concave surface 311 and a second planar surface 312, to simultaneously match different types of plural numbers. A light source (such as a point source, a surface light source, etc.) constitutes a multi-function backlight module with a plurality of illumination characteristics, such as 095146131* single number Α 0101 page 13 / total 22 pages 1013305174-0 1376548 1101 August 10 The correction replacement β makes the backlight module 500 usable for a variety of electronic products. [0032] In summary, the present invention has indeed met the requirements of the invention patent, and the patent application is filed according to law. However, the above description is only a preferred embodiment of the present invention, and it is not possible to limit the scope of the patent application of the present invention. Equivalent modifications or variations made by persons skilled in the art in light of the spirit of the invention are intended to be included within the scope of the following claims. BRIEF DESCRIPTION OF THE DRAWINGS [0033] FIG. 1 is a plan view of a prior art backlight module. 2 is a perspective view of a prior art backlight module. 3 is a perspective view of a light guide plate according to a first embodiment of the present technology. 4 is a schematic plan view of a light guide plate according to a first embodiment of the present technical solution. 5 is a perspective view of a light guide plate according to a second embodiment of the present technology. 6 is a schematic plan view of a light guide plate according to a second embodiment of the present technical solution. 7 is a schematic plan view of a backlight module according to a third embodiment of the present technology. 8 is a schematic plan view of a backlight module according to a fourth embodiment of the present technology. [Main component symbol description] [0041] Light guide plate: 200,300 [0042] Backlight module: 400,500 [0043] Light-in surface: 210, 310 [0044] Light-emitting surface: 220, 320 [0045] Bottom surface: 2 3 0 09514613^^^ Α〇101 Page 14 of 22 1013305174-0 1376548 [0046] Side: 2 4 0 [0047] First groove: 211 [0048] First micro 稜鏡: 213 [0049] Light micro稜鏡: 221 [0050] Concave surface: 311 [0051] Plane: 312 [0052] First micro 稜鏡 array: 313 [0053] Second micro 稜鏡 array: 314 [0054] Third micro 稜鏡 array: 321 [ 0055] Fourth microprism array: 322 [0056] Light source: 41 0 [0057] Light emitting surface: 411 [0058] First light source: 51 0 [0059] Second light source: 520 0951461# Single number deletion 1 Page 15 / Total 22 pages 101 years. August 10th shuttle replacement page 1013305174-0