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TWI390147B - Road illumination device - Google Patents

Road illumination device Download PDF

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Publication number
TWI390147B
TWI390147B TW099103546A TW99103546A TWI390147B TW I390147 B TWI390147 B TW I390147B TW 099103546 A TW099103546 A TW 099103546A TW 99103546 A TW99103546 A TW 99103546A TW I390147 B TWI390147 B TW I390147B
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TW
Taiwan
Prior art keywords
light
road
emitting diode
light source
lens
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TW099103546A
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Chinese (zh)
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TW201128109A (en
Inventor
Chi Chung Hu
Chih Ming Lai
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Foxsemicon Integrated Tech Inc
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Priority to TW099103546A priority Critical patent/TWI390147B/en
Publication of TW201128109A publication Critical patent/TW201128109A/en
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Publication of TWI390147B publication Critical patent/TWI390147B/en

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    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02BCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
    • Y02B20/00Energy efficient lighting technologies, e.g. halogen lamps or gas discharge lamps
    • Y02B20/72Energy efficient lighting technologies, e.g. halogen lamps or gas discharge lamps in street lighting

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  • Non-Portable Lighting Devices Or Systems Thereof (AREA)
  • Led Device Packages (AREA)

Abstract

The present invention relates to an anti-glare road illumination device for lighting a road. The illumination device includes at least one light source which comprises a light emitting diode and at least one optical element coupled to the at least one light emitting diode. The at least one optical element is configured to make light emitted from the at least one light emitting diode deflected to two opposite sides of the at least one light source along a first direction that is perpendicular to an extending direction of the road to from a winglike distribution curve. Thus the light which has a large light intensity from the at least one light emitting diode emits towards two sides of a glared area along the first direction. The at least one optical element is configured to make light emitting from the at least one light emitting diode deflected to a car going side with a predetermined angle along a second direction parallel to the extension direction of the road.

Description

路面照明裝置 Road lighting

本發明涉及一種照明裝置,以及一種具有防止眩光功能的路面照明裝置。 The present invention relates to a lighting device, and a road lighting device having a function of preventing glare.

車輛駛入或者駛出隧道時,亮度的突變會使駕駛員的視覺產生“黑洞效應”或者“白洞效應”,從而造成行車安全隱患。為了解決這一安全問題,公路隧道內就要配置照明燈具。如圖1所示,隧道100的截面通常呈弓形,燈具101設置於隧道100的內壁面的中央,燈具101發射的光線以其自身為中心向路面102進行投射。 When a vehicle enters or exits a tunnel, a sudden change in brightness can cause a "black hole effect" or "white hole effect" in the driver's vision, thereby causing a driving safety hazard. In order to solve this safety problem, lighting fixtures should be arranged in the road tunnel. As shown in FIG. 1, the tunnel 100 is generally arcuate in cross section, and the luminaire 101 is disposed at the center of the inner wall surface of the tunnel 100, and the light emitted by the luminaire 101 is projected toward the road surface 102 centering on itself.

習知技術中雖然可實現燈具101在車輛行駛的X方向上的輻射範圍大於與X方向垂直的Y方向的輻射範圍,以有效。地提高燈具101的光利用率。然而,燈具101在X方向上形成的輻射範圍仍然是以燈具101自身為中心對稱分佈的,即燈具101在X方向上向其兩側的輻射角θ 1與θ 2相等,通常θ 1=θ 2=70度。在此,輻射角也可稱為半峰邊角(half-peak side angle),是指以垂直路面為中心向左右兩側量測最大光強度的一半所得的角度,也就是光源所發出的發光強度為平面上最大發光強度的50%的光線與垂直線的夾角。請參閱圖2,為圖1中燈具101在平行於車輛行駛的X方向上的配光曲線,圖中A點對應光線的光強度為該燈具101在0度到90度中最大光強度的50%,B點對應光線的光強度為該燈具101在0度到90度中的最大光強度,燈具101的輻射角約等於70度。請參閱圖3,當光 源101位於人眼104上方時,自人眼104所在垂直面105偏轉45度至85度之間的範圍內,光源101容易對人眼104造成直接眩光。由此可見,習知的隧道100內燈具101會對駕駛者的眼睛造成直接眩光。 In the prior art, it is effective to realize that the radiation range of the lamp 101 in the X direction in which the vehicle travels is larger than the radiation range in the Y direction perpendicular to the X direction. The light utilization efficiency of the lamp 101 is improved. However, the radiation range formed by the luminaire 101 in the X direction is still symmetrically distributed around the luminaire 101 itself, that is, the illuminating angles θ 1 and θ 2 of the luminaire 101 to the sides thereof in the X direction are equal, usually θ 1 = θ 2 = 70 degrees. Here, the radiation angle may also be referred to as a half-peak side angle, which is an angle obtained by measuring half of the maximum light intensity toward the left and right sides centering on the vertical road surface, that is, the light emitted by the light source. The intensity is the angle between the light of 50% of the maximum luminous intensity on the plane and the vertical line. Referring to FIG. 2 , the light distribution curve of the lamp 101 in FIG. 1 in the X direction parallel to the running of the vehicle, wherein the light intensity of the point A corresponding to the light is 50 of the maximum light intensity of the lamp 101 between 0 degrees and 90 degrees. %, the light intensity of point B corresponds to the maximum light intensity of the lamp 101 in the range of 0 to 90 degrees, and the radiation angle of the lamp 101 is approximately equal to 70 degrees. See Figure 3, when the light When the source 101 is positioned above the human eye 104, the light source 101 tends to cause direct glare to the human eye 104 from a range of between 45 and 85 degrees from the vertical plane 105 where the human eye 104 is located. It can be seen that the conventional lamp 100 in the tunnel 100 causes direct glare to the driver's eyes.

下面將以實施例說明一種可以有效減少眩光的路面照明裝置。 A road lighting device that can effectively reduce glare will be described below by way of example.

一種路面照明裝置,其包括用以向路面照射的至少一光源,該至少一光源包括一發光二極體及與該發光二極體搭配的至少一光學元件,所述光學元件在垂直於路面延伸的方向上將該至少一光源發出的光線向該至少一光源的側向偏折而形成翼形配光曲線,使得光強度較大的光線分別位於眩光區域的兩外側,並在平行於路面延伸的方向上將該至少一光源發出的光線向行車遠離側偏折一預定的角度。 A road lighting device comprising at least one light source for illuminating a road surface, the at least one light source comprising a light emitting diode and at least one optical component matched with the light emitting diode, the optical component extending perpendicular to the road surface The light emitted by the at least one light source is laterally deflected toward the at least one light source to form a wing-shaped light distribution curve, so that the light having a larger light intensity is respectively located on both outer sides of the glare region and extends parallel to the road surface. The light emitted by the at least one light source is deflected toward the driving side away from the side by a predetermined angle.

相對於習知技術,所述路面照明裝置向路面照射時,在垂直於該路面延伸的方向上光線偏折向該至少一光源的側向出射而形成翼形配光曲線,使得光強度較大的光線分別位於眩光區域的兩外側,從而在靠近光源的軸線的眩光區域內的光強度減弱而不會對車輛駕駛員產生直接眩光的影響;在平行於路面延伸的方向上光線向行車遠離側偏折,當車輛行駛於路面上時,行車靠近側的光強度不會超出人眼所承受的範圍,不會對車輛駕駛員產生直接眩光的影響,從而有效保障了駕駛員的行車安全。 Compared with the prior art, when the road surface illumination device is irradiated to the road surface, the light is deflected toward the lateral direction of the at least one light source in a direction perpendicular to the road surface to form a wing-shaped light distribution curve, so that the light intensity is large. The light rays are respectively located on both outer sides of the glare region, so that the light intensity in the glare region near the axis of the light source is weakened without causing direct glare to the driver of the vehicle; the light is directed away from the side in the direction parallel to the road surface. When the vehicle is driving on the road, the light intensity near the side of the vehicle will not exceed the range of the human eye, and will not affect the driver's driver's direct glare, thus effectively ensuring the driver's driving safety.

下面將結合圖式對本發明實施例作進一步之詳細說明。 The embodiments of the present invention will be further described in detail below with reference to the drawings.

請參閱圖4,為本發明第一實施例所提供的一種於隧道20內安裝燈具21的狀態示意圖。該隧道21的截面呈弓形,其包括一圍設於路面22上方且與該路面22相對的一弧形的內壁面23。該路面22包括分別位於左右兩側的第一車道221和第二車道222,所述第一車道221和第二車道222分別供車輛單向行駛。該內壁面23的左右兩側上方沿隧道21延伸的X方向分別等間隔地安裝有複數燈具21,左右兩側的燈具21分別主要用於對隧道20內靠近對應側的第一、第二車道221、222進行照明。優選地,該內壁面23為一粗糙表面,因此部分出射在該內壁面23上的光線產生擴散反射或者漫反射的現象,使得光線較為均勻,呈現出較為舒適的光照明環境。其中,該粗糙的內壁面23可以通過噴沙處理方式形成。 Please refer to FIG. 4 , which is a schematic diagram of a state in which the lamp 21 is installed in the tunnel 20 according to the first embodiment of the present invention. The tunnel 21 has an arcuate cross section and includes an arcuate inner wall surface 23 that is disposed above the road surface 22 and opposite the road surface 22. The road surface 22 includes a first lane 221 and a second lane 222 respectively located on the left and right sides, and the first lane 221 and the second lane 222 are respectively for one-way driving of the vehicle. A plurality of lamps 21 are mounted at equal intervals in the X direction extending along the tunnel 21 in the upper and lower sides of the inner wall surface 23, and the lamps 21 on the left and right sides are mainly used for the first and second lanes in the tunnel 20 adjacent to the corresponding sides. 221, 222 for illumination. Preferably, the inner wall surface 23 is a rough surface, so that the light that is partially emitted on the inner wall surface 23 is diffusely reflected or diffused, so that the light is relatively uniform and presents a relatively comfortable light illumination environment. The rough inner wall surface 23 can be formed by sandblasting.

該燈具21包括一平板狀的電路板(圖未示)及安裝於電路板上的多個固態光源25。請參閱圖5,每一光源25包括一發光二極體250及與該發光二極體250配合的光學元件。所述光學元件包括一透鏡251及一反射鏡252。該透鏡251包括一底面253、一與底面253相對的“V”字形頂面254及連接所述底面253和頂面254的側面255。該底面253的中央向頂面254所在方向凹陷設有一收容發光二極體250的收容室256。該發光二極體250具有一中心軸線H,發光二極體250設置在該透鏡251的底部的幾何中心處,透鏡251通過該中心軸線H呈中心對稱。該側面255上設有沿中心軸線H方向排列的複數鋸齒狀的光學微結構257 。每一光學微結構257包括一第一斜面2571及與該第一斜面2571相交的一第二斜面2572,所述第一斜面2571與第二斜面2572之間於遠離中心軸線H的一端相交形成一銳角。該頂面254是一個二次曲面,該發光二極體250與透鏡251光學耦合,即發光二極體250發出的光線直接進入透鏡251內,並經由透鏡251的光學作用射出。其中,發光二極體250發出的一部分光線射向頂面254,在頂面254發生全反射並以與中心軸線H大致呈90度角經由側面255射出,而另一部分光線直接射向側面255經由側面255出射。因此,經由透鏡251出射的光線會偏離中心軸線H一定角度,使得該光源25發出的光線在沿垂直於路面延伸的Y方向上偏折向該光源25的側向出射而形成翼型的配光曲線,從而改變該光源25照射路面22的光線中的光強度較大的光線所集中的範圍。 The luminaire 21 includes a flat circuit board (not shown) and a plurality of solid state light sources 25 mounted on the circuit board. Referring to FIG. 5, each light source 25 includes a light emitting diode 250 and an optical component mated with the light emitting diode 250. The optical component includes a lens 251 and a mirror 252. The lens 251 includes a bottom surface 253, a "V" shaped top surface 254 opposite the bottom surface 253, and a side surface 255 connecting the bottom surface 253 and the top surface 254. A receiving chamber 256 for receiving the LEDs 250 is recessed in the center of the bottom surface 253 in the direction of the top surface 254. The light-emitting diode 250 has a central axis H, and the light-emitting diode 250 is disposed at a geometric center of the bottom of the lens 251, and the lens 251 is centrally symmetric by the central axis H. The side surface 255 is provided with a plurality of zigzag optical microstructures 257 arranged along the central axis H direction. . Each of the optical microstructures 257 includes a first inclined surface 2571 and a second inclined surface 2572 intersecting the first inclined surface 2571. The first inclined surface 2571 and the second inclined surface 2572 intersect at an end away from the central axis H to form a Sharp angle. The top surface 254 is a quadric surface. The light emitting diode 250 is optically coupled to the lens 251. That is, the light emitted by the light emitting diode 250 directly enters the lens 251 and is emitted through the optical action of the lens 251. Wherein, a portion of the light emitted by the light-emitting diode 250 is directed toward the top surface 254, is totally reflected at the top surface 254, and is emitted through the side surface 255 at an angle of substantially 90 degrees to the central axis H, and another portion of the light is directly incident to the side 255 via Side 255 exits. Therefore, the light emitted through the lens 251 is offset from the central axis H by an angle such that the light emitted by the light source 25 is deflected toward the lateral direction of the light source 25 in the Y direction extending perpendicular to the road surface to form an airfoil of the airfoil. The curve is such that the range in which the light having a large intensity of light in the light of the light source 25 irradiated on the road surface 22 is concentrated is changed.

通常,在路面22行駛的車輛駕駛員的眼睛與光源25之間的相對位置確定的情況下,自眼睛所在垂直面偏轉45度至85度之間的範圍為容易產生直接眩光的角度範圍,在此,將其定義為眩光區域。具體實施時,當光源25位於路面22上方並相對路面22上行駛的車輛駕駛員的眼睛位置確定的情況下,由於光源25中經由透鏡251出射的光線可向遠離中心軸線H的側向偏折一定角度,因此,通過調整該透鏡251使得光線偏折的角度的大小可使得光源25發出的大部分光線偏折後位於該眩光區域之外,從而使得眩光區域內的光線的光強度減弱,以減少甚至防止眩光的產生。其中,所述大部分光線也是光源25所發出的光 線中光強度較大的光線,假設某光線直射眼睛時候可以產生直接眩光的光線的光強度為一定值,那麼,光強度大於該一定值的光線均屬於光強度較大的光線。進一步的,由於所述燈具25是安裝於隧道20的內壁面23的兩側進行照明,且該隧道20的內壁面23呈弓形而圍設於路面22的上方,因此,在垂直於路面22延伸的Y方向上經由透鏡251出射的光線相對該中心軸線H偏折的角度應使得光源25出射的一部分光線可以直接射在光源25的周圍的內壁面23上,通過光線在內壁面23上發生漫反射或者擴散反射後出射至路面22,因而形成均勻地光照環境。優選地,在垂直於路面22延伸的Y方向上光源25發出的大部分光線相對中心軸線H偏折後分別集中在眩光區域的兩側,且在中心軸線H上的光線的光強度小於其最大光強度的三分之一,如此可避免強光直接射向路面22上車輛駕駛員而產生直接眩光。由於側面255形成有鋸齒狀光學微結構257,當光源25的光線由光學微結構257的第一斜面2571或第二斜面2572出射時,在第一斜面2571或第二斜面2572上產生折射,可進一步使得從側面255出射的光線集中在預定的非眩光區域範圍內,同時更多的光線可以通過射向內壁面23發生漫反射或者擴散反射後形成均勻的光照環境。 Generally, in the case where the relative position between the driver's eyes of the vehicle traveling on the road surface 22 and the light source 25 is determined, the range from 45 degrees to 85 degrees from the vertical plane of the eye is an angle range in which direct glare is easily generated. Therefore, it is defined as a glare area. In a specific implementation, when the light source 25 is located above the road surface 22 and is determined relative to the eye position of the driver of the vehicle traveling on the road surface 22, the light emitted from the light source 25 via the lens 251 may be laterally deflected away from the central axis H. At a certain angle, therefore, by adjusting the lens 251, the angle of the light deflected may be such that most of the light emitted by the light source 25 is deflected and located outside the glare area, so that the light intensity of the light in the glare area is weakened, so that Reduce or even prevent the generation of glare. Wherein, most of the light is also the light emitted by the light source 25. The light with a relatively high light intensity in the line assumes that the light intensity of the light that can directly glare when the light is directly directed to the eye is a certain value. Then, the light whose light intensity is greater than the certain value belongs to the light with a relatively high light intensity. Further, since the lamp 25 is mounted on both sides of the inner wall surface 23 of the tunnel 20 for illumination, and the inner wall surface 23 of the tunnel 20 is arcuately disposed above the road surface 22, it extends perpendicular to the road surface 22. The angle of the light emitted through the lens 251 in the Y direction is offset from the central axis H such that a part of the light emitted from the light source 25 can be directly incident on the inner wall surface 23 around the light source 25, and the light is diffused on the inner wall surface 23 After reflection or diffusion reflection, it exits to the road surface 22, thus forming a uniform illumination environment. Preferably, most of the light emitted by the light source 25 in the Y direction extending perpendicular to the road surface 22 is deflected with respect to the central axis H and concentrated on both sides of the glare region, respectively, and the light intensity of the light on the central axis H is less than its maximum One-third of the light intensity prevents direct glare from being directed at the driver of the vehicle on the road surface 22 directly. Since the side surface 255 is formed with the zigzag optical microstructure 257, when the light of the light source 25 is emitted by the first inclined surface 2571 or the second inclined surface 2572 of the optical microstructure 257, refraction is generated on the first inclined surface 2571 or the second inclined surface 2572. Further, the light emitted from the side surface 255 is concentrated in a predetermined non-glare area, and more light can be diffusely reflected or diffused and reflected to the inner wall surface 23 to form a uniform illumination environment.

該反射鏡252位於該透鏡251的一側,其包括一面向發光二極體250並用於反射光線的弧形的反射面2521。該反射鏡252於發光二極體250所在平面的投影與該透鏡251的頂面254於發光二極體250所在平面的投影部分重疊,優 選的是,該反射鏡252於發光二極體250所在平面的投影與發光二極體250的出光面部分重疊。該反射鏡252用於使發光二極體250發出的光線在路面22延伸的X方向上偏折向該燈具21的側向出射,從而使得燈具21照射路面22的光線沿路面22延伸的X方向的配光曲線為一不對稱的配光曲線。請再次參閱圖4,使用時,所述燈具21設置在路面22上方,該燈具21的軸線211沿路面22延伸的X方向將該路面22的車道221、222劃分為行車靠近側265及行車遠離側266,在路面22上行駛的車輛由行車靠近側265駛向行車遠離側266。通過反射鏡252的反射作用使得光源25照射路面22的光線在路面22延伸的X方向的配光曲線中光強度最大值向行車遠離側266方向偏移中心軸線H一定角度,如45度角,如此可使得光源25照射路面的光線中於行車靠近側265的光線的光強度遠小於行車遠離側266的光線的光強度。由於車輛在沿路面22延伸的X方向行進的過程中,容易產生直接眩光的方向通常會發生在車輛駕駛員的前方,也就是發生在車輛駕駛員位於行車靠近側265時,自其眼睛所在垂直面偏轉45度至85度之間的範圍內,因此,通過反射鏡252使得光源25照射路面22的光線向行車遠離側266偏折,使得行車靠近側265的光強度減弱,當駕駛員位於行車靠近側265時,其眼睛受到的光線刺激沒有超出正常範圍,不會受到直接眩光的影響,而當車輛由行車靠近側265駛向行車遠離側266時,駕駛員背向光線照射方向,其也不會受到直接眩光的影響。優選的,該反射鏡252使得光源25照射路面22的光線在沿路面22延伸的方向上向行車遠離側266偏折後,於行車靠 近側265的45度角處的光線的光強度小於行車遠離側266的光線的最大光強度的六分之一。優選的,於行車靠近側265的45至85度角處的光線的光強度小於行車遠離側266的光線的最大光強度的六分之一。 The mirror 252 is located on one side of the lens 251 and includes an arcuate reflecting surface 2521 that faces the light emitting diode 250 and is used to reflect light. The projection of the mirror 252 on the plane of the light-emitting diode 250 overlaps with the projection of the top surface 254 of the lens 251 on the plane of the light-emitting diode 250. The projection of the mirror 252 on the plane of the LED 220 partially overlaps the light-emitting surface of the LED 230. The mirror 252 is configured to deflect the light emitted by the LED 230 in the X direction in which the road surface 22 extends in the lateral direction of the lamp 21, so that the light that the lamp 21 illuminates the road surface 22 extends along the X direction of the road surface 22. The light distribution curve is an asymmetric light distribution curve. Referring again to FIG. 4, in use, the luminaire 21 is disposed above the road surface 22. The axis 211 of the luminaire 21 divides the lanes 221, 222 of the road surface 22 into the approaching side 265 and away from the road along the X direction in which the road surface 22 extends. Side 266, the vehicle traveling on road surface 22 is driven toward the away side 266 by the approaching side 265. The light intensity of the light source 25 illuminating the road surface 22 causes the light intensity of the light source 25 to illuminate the road surface 22 in the X-direction light distribution curve of the road surface 22 to be offset from the center axis H by a certain angle, such as a 45 degree angle, toward the traveling away side 266. Thus, the light intensity of the light illuminating the road surface with light from the light source 25 on the approaching side 265 is much less than the light intensity of the light traveling away from the side 266. As the vehicle travels in the X direction extending along the road surface 22, the direction in which direct glare is likely to occur typically occurs in front of the driver of the vehicle, that is, when the driver of the vehicle is on the approach side 265, from the vertical of his eye. The surface is deflected in a range between 45 degrees and 85 degrees. Therefore, the light illuminating the road surface 22 by the light source 25 is deflected toward the traveling away side 266 by the mirror 252, so that the light intensity of the approaching side 265 is weakened when the driver is in the driving. When approaching the side 265, the eye is not stimulated by the light beyond the normal range and is not affected by the direct glare. When the vehicle is approaching the side 265 toward the driving away from the side 266, the driver is facing away from the direction of the light, which is also Will not be affected by direct glare. Preferably, the mirror 252 causes the light of the light source 25 to illuminate the road surface 22 to be deflected toward the traveling away side 266 in the direction along the road surface 22, and then leans on the road. The light intensity at the 45 degree angle of the proximal side 265 is less than one sixth of the maximum light intensity of the light traveling away from the side 266. Preferably, the light intensity at a 45 to 85 degree angle of the approaching side 265 of the vehicle is less than one sixth of the maximum light intensity of the light traveling away from the side 266.

請參閱圖6,為光源25在垂直於路面延伸的Y方向上的配光曲線圖,C點示出透鏡251使得發光二極體250發出的光線在中心軸線H方向上的光強度約為280坎德拉(cd),D點示出發光二極體250發出的光線的最大光強度約為890坎德拉(cd),該發光二極體250發出的光線在中心軸線H上的光強度小於其最大光強度的三分之一。因此,當光源25分別位於隧道20的內壁面23的兩側的一定高度處,可使得出射至路面22的光強度較大的光線主要位於眩光區域的兩側,而不會直接對行駛在車道221、222上的車輛的駕駛員產生直接眩光的影響。請參閱圖7,為光源25在路面22的延伸X方向上的配光曲線圖,E點示出反射鏡252使得發光二極體250發出的光線在路面的延伸X方向上的最大光強度相對中心軸線H向行車遠離側266偏移大致50度角,E點示出發光二極體250發出的光線在行車遠離側266的最大光強度大致為750坎德拉(cd),而F點示出行車靠近側265的45度角處的光強度大致為100坎德拉(cd)。因此,當駕駛員位於行車靠近側265時,其眼睛受到的光線刺激沒有超出正常範圍,不會受到直接眩光的影響,而當車輛由行車靠近側265駛向行車遠離側266時,駕駛員背向光線照射方向,其也不會受到直接眩光的影響。 Please refer to FIG. 6 , which is a light distribution graph of the light source 25 in the Y direction extending perpendicular to the road surface, and point C shows the lens 251 such that the light intensity emitted by the light emitting diode 250 in the direction of the central axis H is about 280. Candela (cd), point D shows that the maximum light intensity of the light emitted by the light-emitting diode 250 is about 890 candelas (cd), and the light intensity of the light emitted by the light-emitting diode 250 on the central axis H is less than its maximum light intensity. One third of the. Therefore, when the light sources 25 are respectively located at a certain height on both sides of the inner wall surface 23 of the tunnel 20, it is possible to obtain that the light having a greater intensity of light incident on the road surface 22 is mainly located on both sides of the glare region, and does not directly travel in the lane. The driver of the vehicle on 221, 222 has the effect of direct glare. Please refer to FIG. 7 , which is a light distribution curve of the light source 25 in the extension X direction of the road surface 22 , and point E shows the mirror 252 such that the maximum light intensity of the light emitted by the light-emitting diode 250 in the extension X direction of the road surface is relatively The central axis H is offset from the side 266 away from the side 266 by an angle of substantially 50 degrees. The point E indicates that the maximum light intensity of the light emitted by the light-emitting diode 250 on the away side 266 is approximately 750 candelas (cd), while the point F shows the approach of the vehicle. The light intensity at the 45 degree angle of side 265 is approximately 100 candelas (cd). Therefore, when the driver is located on the approaching side 265, the eye is not stimulated by the light beyond the normal range and is not affected by the direct glare, and when the vehicle is approaching the side 265 from the driving side toward the driving away side 266, the driver's back It is directed toward the light and it is not affected by direct glare.

圖8所示為本發明第二實施例所提供的一種燈具21的光源35,其與上述第一實施例的區別在於:該光源35中透鏡351的結構不同。該透鏡351具有一圓形的板狀輪廓,其包括一平面狀的入光面350及一與入光面350相對的出光面353。該光源35具有一以發光二極體250所在位置為中心的對稱軸I。該透鏡351位於發光二極體250的上方,其入光面350面向發光二極體250設置,而出光面352上設有複數環形的條狀鋸齒形凸起352。每一凸起352包括一第一鋸齒面3521及一連接該第一鋸齒面3521的第二鋸齒面3522,其中,所述第一鋸齒面3521位於對應凸起352遠離對稱軸I的一側,且垂直於入光面350。而對於位於對稱軸I同一側的每一凸起352而言,其第二鋸齒面3522分別連接相鄰兩側凸起352的第一鋸齒面3521。如圖8中箭頭所示,發光二極體250發出的光線經入光面350入射至透鏡351,當光線由第一鋸齒面3521或第二鋸齒面3522上出射時均偏離對稱軸I一定角度,使得該光源35發出的光線偏折向該光源35的側向出射而形成翼型的配光曲線。因此光源35於垂直於路面22延伸的Y方向上出射的大部分光線遠離對稱軸I,所述光強度較大的光線位於眩光區域的外側,而在眩光區域內的光線的光強度相對減弱,可以避免強光射向車輛或者駕駛員而產生直接眩光。通過調整該第二鋸齒面3522相對第一鋸齒面3521傾斜的角度,便可獲得與第一實施例中的光源25相似的配光曲線。 FIG. 8 shows a light source 35 of a luminaire 21 according to a second embodiment of the present invention, which differs from the first embodiment in that the structure of the lens 351 in the light source 35 is different. The lens 351 has a circular plate-like profile including a planar light incident surface 350 and a light exit surface 353 opposite to the light incident surface 350. The light source 35 has an axis of symmetry I centered on the position of the light-emitting diode 250. The lens 351 is disposed above the light-emitting diode 250, and the light-incident surface 350 is disposed facing the light-emitting diode 250, and the light-emitting surface 352 is provided with a plurality of annular strip-shaped zigzag protrusions 352. Each of the protrusions 352 includes a first serration surface 3521 and a second serration surface 3522 connected to the first serration surface 3521 , wherein the first serration surface 3521 is located on a side of the corresponding protrusion 352 away from the axis of symmetry I. And perpendicular to the light incident surface 350. For each protrusion 352 on the same side of the axis of symmetry I, the second serration surface 3522 connects the first serration surface 3521 of the adjacent side protrusions 352, respectively. As shown by the arrow in FIG. 8, the light emitted by the LED 230 is incident on the lens 351 through the light incident surface 350, and is offset from the symmetry axis I when the light is emitted from the first sawtooth surface 3521 or the second sawtooth surface 3522. The light emitted by the light source 35 is deflected toward the side of the light source 35 to form an airfoil light distribution curve. Therefore, most of the light emitted by the light source 35 in the Y direction extending perpendicular to the road surface 22 is away from the axis of symmetry I, and the light having a higher light intensity is located outside the glare region, and the light intensity of the light in the glare region is relatively weakened. Direct glare can be avoided by glare from the vehicle or the driver. By adjusting the angle at which the second serration surface 3522 is inclined with respect to the first serration surface 3521, a light distribution curve similar to that of the light source 25 in the first embodiment can be obtained.

圖9所示為本發明第三實施例所提供的一種燈具21的光源 45,其與上述第一實施例的區別在於:該光源45中透鏡451的結構不同。該透鏡451具有一大致呈半球狀的輪廓,其包括一入光面453、一與入光面453相對的出光面454及一連接所述入光面453和出光面454的弧形側面455。該入光面453的中央朝向出光面454所在方向凹陷形成一收容發光二極體250的收容空間456。該出光面454的中央形成為一漏斗狀的凹面458。如圖9中箭頭所示,發光二極體250發出的光線經入光面453入射至透鏡451,當光線由出光面454出射時在出光面454中央的凹面458處發生全反射,改變原來的照射方向而經由側面455出射。通過調整該凹面458的曲率和面積,便可獲得與第一實施例的光源25的相似的配光曲線。 FIG. 9 shows a light source of a lamp 21 according to a third embodiment of the present invention. 45, which differs from the first embodiment described above in that the structure of the lens 451 in the light source 45 is different. The lens 451 has a substantially hemispherical contour, and includes a light incident surface 453, a light exit surface 454 opposite to the light incident surface 453, and a curved side surface 455 connecting the light incident surface 453 and the light exit surface 454. The center of the light incident surface 453 is recessed toward the light emitting surface 454 to form a receiving space 456 for receiving the light emitting diode 250. The center of the light exit surface 454 is formed as a funnel-shaped concave surface 458. As shown by the arrow in FIG. 9, the light emitted from the LED 230 is incident on the lens 451 through the light incident surface 453. When the light is emitted from the light exit surface 454, total reflection occurs at the concave surface 458 at the center of the light exit surface 454, and the original is changed. The direction of illumination is emitted through side 455. By adjusting the curvature and area of the concave surface 458, a light distribution curve similar to that of the light source 25 of the first embodiment can be obtained.

圖10所示為本發明第四實施例所提供的一種燈具21的光源55,其與上述第一實施例的區別在於:該光源55中的反射鏡552的結構不同。該反射鏡552包括一面向發光二極體250以用於反射光線的直線形的反射面5521。 FIG. 10 shows a light source 55 of a luminaire 21 according to a fourth embodiment of the present invention, which differs from the first embodiment in that the structure of the mirror 552 in the light source 55 is different. The mirror 552 includes a linear reflecting surface 5521 that faces the light emitting diode 250 for reflecting light.

圖11和圖12所示為本發明第五實施例所提供的一種燈具21的光源,該光源包括複數第一光源651和複數第二光源652。其中,第一光源651包括一發光二極體250及一第一透鏡6510,該第一透鏡6510結構與上述第一實施例中的光源25中透鏡251的結構完全相同。第二光源652包括一發光二極體250及一第二透鏡6521。該第二透鏡6521包括一與發光二極體250相鄰的入光面6521、一與入光面6521相對的出光面6522以及一連接於所述入光面6521與出光面6522之間的豎直的側壁6523。該入光面6521呈矩 形,該第二透鏡652具有一穿過入光面6520幾何中心的中心軸N。該出光面6522為一與該入光面6520成一預定夾角的內凹曲面。其中,該出光面6522朝向入光面6520所在方向凹陷,且出光面6522相對入光面6520的斜率由一側向另一側逐漸增加。使用時,安裝燈具21時使得第二透鏡652的出光面6522相對入光面6520的斜率較小的一側置於行車靠近側265,而另一側置於行車遠離側266。如圖12中箭頭所示,發光二極體250發出的光線經入光面6520入射至第二透鏡652內部,進而由第二透鏡652的出光面6522出射。當光線由出光面6522出射時,在該出光面6522發生折射,使得光線向行車遠離側266偏折。因此,位於行車遠離側266的光強度較大,而位於行車靠近側265的光強度相對較弱,通過調整第二透鏡652的出光面6522的曲率,便可使得光源照射路面22的光線於路面22延伸的X方向上向行車遠離側266偏折一預定的角度。第一光源651中透鏡6210的作用與光源25中透鏡251的作用相同,而如圖11中箭頭所示,發光二極體250發出的光線經由第一透鏡6510出射後,均偏離中心軸線H一預定範圍,如此可使得在垂直路面22延伸的Y方向上光強度較大的光線位於眩光區域的兩側,而在眩光區域內的光線的光強度相對減弱,從而避免強光射向車輛或者駕駛員而產生直接眩光。 11 and 12 illustrate a light source of a luminaire 21 according to a fifth embodiment of the present invention. The light source includes a plurality of first light sources 651 and a plurality of second light sources 652. The first light source 651 includes a light emitting diode 250 and a first lens 6510. The first lens 6510 has the same structure as the lens 251 of the light source 25 in the first embodiment. The second light source 652 includes a light emitting diode 250 and a second lens 6521. The second lens 6521 includes a light incident surface 6521 adjacent to the light emitting diode 250, a light emitting surface 6522 opposite to the light incident surface 6521, and a vertical connection between the light incident surface 6521 and the light emitting surface 6522. Straight side wall 6523. The light incident surface 6521 is a moment The second lens 652 has a central axis N that passes through the geometric center of the light incident surface 6520. The light-emitting surface 6522 is a concave curved surface at a predetermined angle with the light-incident surface 6520. The light exiting surface 6522 is recessed toward the light incident surface 6520, and the slope of the light exiting surface 6522 relative to the light incident surface 6520 gradually increases from one side to the other side. In use, the luminaire 21 is mounted such that the side of the light exiting surface 6522 of the second lens 652 with respect to the light incident surface 6520 is placed on the approaching side 265 while the other side is placed on the away side 266. As shown by the arrow in FIG. 12, the light emitted from the LED 230 is incident on the inside of the second lens 652 through the light incident surface 6520, and is further emitted from the light exit surface 6522 of the second lens 652. When the light is emitted from the light exit surface 6522, the light exit surface 6522 is refracted such that the light is deflected toward the traveling away side 266. Therefore, the light intensity at the driving away from side 266 is relatively large, and the light intensity at the approaching side 265 of the driving is relatively weak. By adjusting the curvature of the light emitting surface 6522 of the second lens 652, the light source illuminates the light of the road surface 22 on the road surface. The extended X direction is deflected toward the driving away from side 266 by a predetermined angle. The action of the lens 6210 in the first light source 651 is the same as that of the lens 251 in the light source 25, and as shown by the arrow in FIG. 11, the light emitted by the light-emitting diode 250 is emitted from the first lens 6510, and both are offset from the central axis H. The predetermined range is such that the light having a greater light intensity in the Y direction extending in the vertical road surface 22 is located on both sides of the glare region, and the light intensity of the light in the glare region is relatively weakened, thereby preventing the strong light from being directed toward the vehicle or driving. Direct glare from the staff.

圖13所示為本發明第六實施例所提供的一種燈具21的光源,其與上述第五實施例的區別在於:第二光源752中透鏡7521的結構不同。該透鏡7521包括一矩形的主體部 7520及形成於該主體部7520的頂面7523的中央的光學部7522。該光學部7522的外表面7524為一朝遠離主體部7520的方向凸起的球面,該光學部7522的厚度從第二光源752的一側向另一側逐漸增加,即光學部7522的外表面7524與主體部7520的頂面7523之間的距離從一側向另一側逐漸增加。主體部7520的底面於靠近光學部7522的厚度較小的一側的地方向頂面所在方向凹陷形成一收容發光二極體250的空間7525。如圖13中箭頭所示,以發光二極體250所在位置為中心具有一軸線M,發光二極體250發出的光線入射至透鏡7521內,當光線由光學部7522的外表面7524出射時,在該外表面7524發生折射,使得光線向光學部7522的厚度較大的一側偏折。使用時,將透鏡7521的光學部7522厚度較大的一側置於行車遠離側266,經由該透鏡7521出射的光線向行車遠離側266偏折,因此,位於行車遠離側266的光強度較大,而位於行車靠近側265的光強度較弱,通過調整該光學部7522的外表面7524的曲率,便可使得光源照射路面22的光線於路面22延伸的X方向上向行車遠離側266偏折一預定的角度。 FIG. 13 shows a light source of a luminaire 21 according to a sixth embodiment of the present invention, which differs from the fifth embodiment in that the structure of the lens 7521 in the second light source 752 is different. The lens 7521 includes a rectangular body portion 7520 and an optical portion 7522 formed at the center of the top surface 7523 of the main body portion 7520. The outer surface 7524 of the optical portion 7522 is a spherical surface that is convex away from the main body portion 7520. The thickness of the optical portion 7522 gradually increases from one side of the second light source 752 to the other side, that is, the outer surface of the optical portion 7522. The distance between the 7524 and the top surface 7523 of the body portion 7520 gradually increases from one side to the other. The bottom surface of the main body portion 7520 is recessed in a direction away from the top surface of the side of the optical portion 7522 having a smaller thickness to form a space 7525 for accommodating the LEDs 250. As shown by the arrow in FIG. 13, the light emitting diode 250 has an axis M centered on the position of the light emitting diode 250, and the light emitted from the light emitting diode 250 is incident into the lens 7521. When the light is emitted from the outer surface 7524 of the optical portion 7522, The outer surface 7524 is refracted such that the light is deflected toward the side of the optical portion 7522 having a larger thickness. In use, the side of the optical portion 7522 of the lens 7521 having a larger thickness is placed on the traveling away side 266, and the light emitted through the lens 7521 is deflected toward the traveling away side 266, so that the light intensity at the traveling away side 266 is large. The light intensity on the approaching side 265 is weak. By adjusting the curvature of the outer surface 7524 of the optical portion 7522, the light illuminating the road surface 22 by the light source can be deflected toward the traveling away side 266 in the X direction in which the road surface 22 extends. a predetermined angle.

圖14所示為本發明第七實施例所提供的一種燈具21的光源,其與上述第五實施例的區別在於:第二光源852中透鏡8521的結構不同。該透鏡8521具有一個板狀輪廓,其包括一入光面8520及一與入光面8520相對的出光面8522。該透鏡8521位於發光二極體250的上方,其入光面8520為平面且與發光二極體250相鄰設置,而出光面8522上設有複數條狀的鋸齒形突起8523。每一突起8523 包括一豎直面8525及一連接該豎直面8525的傾斜面8524。其中,所述豎直面8525相互平行,分別垂直於入光面8520,而傾斜面8524傾斜延伸並連接其相鄰兩側的豎直面8525。如圖14中箭頭所示,發光二極體250發出的光線經入光面8520入射至透鏡8521,當光線經由出光面8522上的豎直面8525或傾斜面8522出射時發生折射,並朝向對應突起8523的豎直面8525所在一側偏折射出。使用時,安裝燈具21使得透鏡8521中突起8523的豎直面8525置於行車遠離側266的一側,因此,經由該透鏡8521出射的光線向行車遠離側266偏折。通過調整該突起8523中傾斜面8524的斜率,便可使得光源照射路面22的光線於路面22延伸的X方向上向行車遠離側266偏折一預定的角度。 FIG. 14 shows a light source of a luminaire 21 according to a seventh embodiment of the present invention, which differs from the fifth embodiment in that the structure of the lens 8521 in the second light source 852 is different. The lens 8521 has a plate-like profile, and includes a light-incident surface 8520 and a light-emitting surface 8522 opposite to the light-incident surface 8520. The lens 8521 is located above the light-emitting diode 250, and the light-incident surface 8520 is planar and disposed adjacent to the light-emitting diode 250. The light-emitting surface 8522 is provided with a plurality of zigzag-shaped protrusions 8523. Each protrusion 8523 A vertical surface 8525 and an inclined surface 8524 connecting the vertical surface 8525 are included. Wherein, the vertical faces 8525 are parallel to each other, respectively perpendicular to the light incident surface 8520, and the inclined faces 8524 are obliquely extended and connected to the vertical faces 8525 of the adjacent sides thereof. As shown by the arrow in FIG. 14, the light emitted from the LED 230 is incident on the lens 8521 through the light incident surface 8520, and is refracted when the light is emitted through the vertical surface 8525 or the inclined surface 8522 on the light exit surface 8522, and is directed toward the corresponding protrusion. The side of the vertical face 8525 of the 8523 is partially deflected. In use, the luminaire 21 is mounted such that the vertical face 8525 of the protrusion 8523 in the lens 8521 is placed on the side of the vehicle away from the side 266, and thus the light exiting through the lens 8521 is deflected toward the away side 266. By adjusting the slope of the inclined surface 8524 in the protrusion 8523, the light illuminating the road surface 22 by the light source can be deflected by a predetermined angle toward the traveling away side 266 in the X direction in which the road surface 22 extends.

終上所述,第一、第二、第三實施例中的光源25、35、45中的透鏡251、351、451分別可用於改變發光二極體250發出的光線中的光強度較大的光線所集中的範圍,使得發光二極體250發出的光線均向側向偏離而形成翼型的配光曲線,因此,燈具21照射路面22的光線在垂直路面22延伸的Y方向上,通過確定燈具21與路面22上行駛的車輛駕駛員的眼睛的相對位置,使得所述向側向偏離的光強度較大的光線位於眩光區域的外側,於眩光區域內的光強度減弱,從而避免強光直接照射車輛或者駕駛員而產生直接眩光。其中該燈具21作為隧道20內照明燈具使用時,在垂直於路面22延伸的Y方向上一部分光線射在隧道20的內壁面23上發生漫反射或者擴散發射後再均勻地 出射至路面22,以進一步形成均勻的光照環境。第五、第六和第七實施例中的第二光源652、752、852中的透鏡6521、7521、8521分別可用於改變發光二極體250發出的光線的出射方向,從而可使得燈具21照射路面22的光線沿路面22延伸的X方向朝向行車遠離側266偏折,當駕駛員行駛在路面22上位於行車靠近側265時,其眼睛受到的光線刺激不會超出正常範圍,因而不會受到直接眩光的影響,而當汽車由行車靠近側265駛向行車遠離側266時,駕駛員背向光線照射方向,其也不會受到直接眩光的影響。具體實施時,燈具21可以包括其他不同的光源的組合方式來達成上述避免直接眩光的目的,如該燈具21可以包括上述第一、第二、第三實施例中的光源25、35、45中的任意一種中發光二極體250和透鏡251、351、451的組合與第五、第六、第七實施例中的第二光源652、752、852中的任意一種配合使用,以避免駕駛員在路面22上行駛時受到直接眩光的影響。 Finally, the lenses 251, 351, 451 of the light sources 25, 35, 45 in the first, second, and third embodiments can be used to change the light intensity in the light emitted by the light-emitting diode 250, respectively. The range in which the light is concentrated is such that the light emitted by the light-emitting diode 250 is laterally offset to form a light distribution curve of the airfoil. Therefore, the light of the light emitted from the light-emitting surface of the light-emitting device 21 is determined in the Y direction extending perpendicular to the road surface 22 The relative position of the luminaire 21 and the eyes of the driver of the vehicle traveling on the road surface 22 is such that the light having a relatively large light intensity that is laterally offset is located outside the glare region, and the light intensity in the glare region is weakened, thereby avoiding glare. Direct glare is produced by direct illumination of the vehicle or driver. When the luminaire 21 is used as a luminaire in the tunnel 20, a part of the ray in the Y direction extending perpendicular to the road surface 22 is projected on the inner wall surface 23 of the tunnel 20 to be diffusely reflected or diffused and then uniformly It exits to the road surface 22 to further form a uniform light environment. The lenses 6521, 7521, and 8521 of the second light sources 652, 752, and 852 in the fifth, sixth, and seventh embodiments, respectively, can be used to change the outgoing direction of the light emitted by the light-emitting diode 250, thereby allowing the lamp 21 to be illuminated. The light of the road surface 22 is deflected toward the driving away side 266 along the X direction in which the road surface 22 extends. When the driver is traveling on the road surface 22 on the approaching side 265 of the road, the light stimulation of the eyes does not exceed the normal range, and thus is not subject to The effect of direct glare, and when the car is driven from the approaching side 265 toward the driving away from side 266, the driver is facing away from the direction of light illumination, which is also unaffected by direct glare. In a specific implementation, the luminaire 21 may include a combination of other different light sources to achieve the above-mentioned purpose of avoiding direct glare. For example, the luminaire 21 may include the light sources 25, 35, 45 in the first, second, and third embodiments described above. Any combination of the middle light emitting diode 250 and the lenses 251, 351, 451 is used in combination with any of the second light sources 652, 752, 852 in the fifth, sixth, and seventh embodiments to avoid the driver It is affected by direct glare when traveling on the road surface 22.

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內。 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 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.

100、20‧‧‧隧道 100, 20‧‧‧ tunnel

101、21‧‧‧燈具 101, 21‧‧‧ lamps

102、22‧‧‧路面 102, 22‧‧‧ pavement

104‧‧‧人眼 104‧‧‧ human eyes

105‧‧‧垂直面 105‧‧‧Vertical

211‧‧‧軸線 211‧‧‧ axis

221‧‧‧第一車道 221‧‧‧First lane

222‧‧‧第二車道 222‧‧‧second lane

23‧‧‧內壁面 23‧‧‧ inner wall

25、35、45、55‧‧‧光源 25, 35, 45, 55‧‧‧ light source

250‧‧‧發光二極體 250‧‧‧Lighting diode

251、351、451、7521、8521‧‧‧透鏡 251, 351, 451, 7521, 8521 ‧ lens

252、552‧‧‧反射鏡 252, 552‧‧ ‧ mirror

2521、5521‧‧‧反射面 2521, 5521‧‧‧reflecting surface

253‧‧‧底面 253‧‧‧ bottom

254‧‧‧頂面 254‧‧‧ top surface

255‧‧‧側面 255‧‧‧ side

256‧‧‧收容室 256‧‧‧ containment room

257‧‧‧光學微結構 257‧‧‧Optical microstructure

2571‧‧‧第一斜面 2571‧‧‧First bevel

2572‧‧‧第二斜面 2572‧‧‧second bevel

265‧‧‧行車靠近側 265‧‧‧ Driving near the side

266‧‧‧行車遠離側 266‧‧‧ Driving away from the side

350、453、6520、8520‧‧‧入光面 350, 453, 6520, 8520‧‧‧ into the glossy surface

352‧‧‧凸起 352‧‧‧ bumps

3521‧‧‧第一鋸齒面 3521‧‧‧First serrated surface

3522‧‧‧第二鋸齒面 3522‧‧‧Second serrated surface

353、454、6522、8522‧‧‧出光面 353, 454, 6522, 8522‧‧ ‧ light surface

455‧‧‧側面 455‧‧‧ side

456‧‧‧收容空間 456‧‧‧ accommodating space

458‧‧‧凹面 458‧‧‧ concave

651‧‧‧第一光源 651‧‧‧First light source

6510‧‧‧第一透鏡 6510‧‧‧First lens

652、752、852‧‧‧第二光源 652, 752, 852‧‧‧ second light source

6521‧‧‧第二透鏡 6521‧‧‧second lens

6523‧‧‧側壁 6523‧‧‧ side wall

7520‧‧‧主體部 7520‧‧‧ Main body

7522‧‧‧光學部 7522‧‧‧Optical Department

7523‧‧‧頂面 7523‧‧‧ top surface

7524‧‧‧外表面 7524‧‧‧ outer surface

7525‧‧‧空間 7525‧‧‧ space

8523‧‧‧突起 8523‧‧‧Protrusion

8524‧‧‧傾斜面 8524‧‧‧Sloping surface

8525‧‧‧豎直面 8525‧‧‧Vertical

圖1是一種習知的隧道內燈具的使用狀態示意圖。 Fig. 1 is a schematic view showing the state of use of a conventional luminaire in a tunnel.

圖2是圖1中燈具的配光曲線圖。 2 is a light distribution graph of the lamp of FIG. 1.

圖3是圖1所示燈具產生眩光的原理示意圖。 FIG. 3 is a schematic diagram showing the principle of glare generated by the lamp shown in FIG. 1. FIG.

圖4是本發明第一實施例提供的隧道內燈具的使用狀態示意圖。 4 is a schematic view showing the state of use of the luminaire in the tunnel provided by the first embodiment of the present invention.

圖5是圖4中燈具的光源的結構示意圖。 FIG. 5 is a schematic structural view of a light source of the luminaire of FIG. 4. FIG.

圖6是圖5中光源於垂直路面延伸的方向的配光曲線圖。 Figure 6 is a light distribution diagram of the light source of Figure 5 extending in a direction perpendicular to the road surface.

圖7是圖5中光源於路面延伸的方向的配光曲線圖。 Fig. 7 is a light distribution graph of the light source in Fig. 5 in a direction in which the road surface extends.

圖8是本發明第二實施例所提供的燈具的光源的結構示意圖。 FIG. 8 is a schematic structural view of a light source of a luminaire according to a second embodiment of the present invention.

圖9是本發明第三實施例所提供的燈具的光源的結構示意圖。 FIG. 9 is a schematic structural view of a light source of a luminaire according to a third embodiment of the present invention.

圖10是本發明第四實施例所提供的燈具的光源的結構示意圖。 FIG. 10 is a schematic structural view of a light source of a luminaire according to a fourth embodiment of the present invention.

圖11是本發明第五實施例所提供的燈具的第一光源的結構示意圖。 11 is a schematic structural view of a first light source of a luminaire according to a fifth embodiment of the present invention.

圖12是本發明第五實施例所提供的燈具的第二光源的結構示意圖。 FIG. 12 is a schematic structural view of a second light source of a luminaire according to a fifth embodiment of the present invention.

圖13是本發明第六實施例所提供的燈具的第二光源的結構示意圖。 FIG. 13 is a schematic structural diagram of a second light source of a luminaire according to a sixth embodiment of the present invention.

圖14是本發明第七實施例所提供的燈具的第二光源的結構示意圖。 14 is a schematic structural view of a second light source of a luminaire according to a seventh embodiment of the present invention.

25‧‧‧光源 25‧‧‧Light source

250‧‧‧發光二極體 250‧‧‧Lighting diode

251‧‧‧透鏡 251‧‧‧ lens

252‧‧‧反射鏡 252‧‧‧Mirror

2521‧‧‧反射面 2521‧‧‧reflecting surface

253‧‧‧底面 253‧‧‧ bottom

254‧‧‧頂面 254‧‧‧ top surface

255‧‧‧側面 255‧‧‧ side

256‧‧‧收容室 256‧‧‧ containment room

257‧‧‧光學微結構 257‧‧‧Optical microstructure

2571‧‧‧第一斜面 2571‧‧‧First bevel

2572‧‧‧第二斜面 2572‧‧‧second bevel

Claims (16)

一種路面照明裝置,其包括用以向路面照射的至少一光源,該至少一光源包括一發光二極體及與該發光二極體搭配的至少一光學元件,所述光學元件在垂直於路面延伸的方向上將該至少一光源發出的光線向該至少一光源的側向偏折而形成翼形配光曲線,使得光強度較大的光線分別位於眩光區域的兩外側,並在平行於路面延伸的方向上將該至少一光源發出的光線向行車遠離側偏折一預定的角度,該至少一光源在垂直於路面延伸的方向上於軸線上的光線的光強度小於該方向上的光線的最大光強度的三分之一,並在平行於路面延伸的方向上於行車遠離側的45至85度角處的光線的光強度小於行車靠近側的光線的最大光強度的六分之一。 A road lighting device comprising at least one light source for illuminating a road surface, the at least one light source comprising a light emitting diode and at least one optical component matched with the light emitting diode, the optical component extending perpendicular to the road surface The light emitted by the at least one light source is laterally deflected toward the at least one light source to form a wing-shaped light distribution curve, so that the light having a larger light intensity is respectively located on both outer sides of the glare region and extends parallel to the road surface. The light emitted by the at least one light source is deflected toward the driving away from the side by a predetermined angle, and the light intensity of the light on the axis of the at least one light source extending in a direction perpendicular to the road surface is smaller than the maximum light in the direction One-third of the light intensity, and the light intensity at a 45 to 85 degree angle away from the side of the vehicle in a direction parallel to the road surface is less than one-sixth of the maximum light intensity of the light on the approaching side of the vehicle. 如申請專利範圍第1項所述之路面照明裝置,其中,該至少一光源的光學元件包括一與該發光二極體耦合的透鏡及位於該透鏡一側的反射鏡,該透鏡用以使得發光二極體發出的光線在垂直於路面延伸的方向上將該至少一光源發出的光線向該至少一光源的側向偏折出射,該反射鏡用以將發光二極體發出的光線向行車遠離側偏折。 The road lighting device of claim 1, wherein the optical component of the at least one light source comprises a lens coupled to the light emitting diode and a mirror on a side of the lens for causing illumination The light emitted by the diode emits the light emitted by the at least one light source to the lateral direction of the at least one light source in a direction perpendicular to the road surface, and the mirror is used to move the light emitted by the light emitting diode away from the driving Side deflection. 如申請專利範圍第2項所述之路面照明裝置,其中,該透鏡包括一底面、一與該底面相對的“V”字形頂面及一連接底面與頂面的側面,該底面向頂面所在方向凹陷形成一收容該發光二極體的收容室,發光二極體發出的部分光線射向頂面,在頂面發生全反射後射向側面而經由側面射出。 The road lighting device of claim 2, wherein the lens comprises a bottom surface, a "V" shaped top surface opposite the bottom surface, and a side surface connecting the bottom surface and the top surface, the bottom surface facing the top surface The direction recess forms a receiving chamber for accommodating the light emitting diode, and part of the light emitted by the light emitting diode is emitted to the top surface, and is totally reflected on the top surface, and then is emitted to the side surface and is emitted through the side surface. 如申請專利範圍第3項所述之路面照明裝置,其中,該側面上沿軸向設有複數凸起,每一凸起包括分別與軸線傾斜的第一斜面及第二斜面,所述第一斜面與第二斜面於遠離軸線的一端相交形成一銳角。 The road lighting device of claim 3, wherein the side surface is provided with a plurality of protrusions in the axial direction, and each protrusion includes a first slope and a second slope respectively inclined to the axis, the first The bevel intersects the second bevel at an end remote from the axis to form an acute angle. 如申請專利範圍第2項所述之路面照明裝置,其中,該透鏡位於發光二極體的上方,其包括一平面狀的入光面及一相對的出光面,該出光面上設有複數凸起,每一凸起包括一與入光面垂直的第一鋸齒面及一與該第一鋸齒面相交的第二鋸齒面,所述凸起相對軸線呈中心對稱設置,位於軸線同一側的凸起的第一鋸齒面均位於遠離軸線的一側。 The road lighting device of claim 2, wherein the lens is located above the light emitting diode, and comprises a planar light incident surface and an opposite light emitting surface, wherein the light emitting surface is provided with a plurality of convex surfaces. Each of the protrusions includes a first sawtooth surface perpendicular to the light incident surface and a second sawtooth surface intersecting the first sawtooth surface, the protrusions being symmetrically disposed with respect to the axis, and convex on the same side of the axis The first serrated faces are located on one side away from the axis. 如申請專利範圍第2項所述之路面照明裝置,其中,該透鏡包括一入光面、一與入光面相對的出光面及一連接入光面和出光面的弧形側面,該入光面朝向出光面所在方向凹陷形成一收容發光二極體的收容空間,該出光面的中央形成為一漏斗狀的凹面。 The road surface illumination device of claim 2, wherein the lens comprises a light incident surface, a light exit surface opposite to the light incident surface, and a curved side surface connected to the light surface and the light exit surface, the light entering The surface is recessed toward the light-emitting surface to form a receiving space for receiving the light-emitting diode. The center of the light-emitting surface is formed as a funnel-shaped concave surface. 如申請專利範圍第2-6項中任意一項所述之路面照明裝置,其中,該反射鏡具有一面向發光二極體以用於反射光線的弧形或者直線形的反射面,該反射鏡於發光二極體所在平面的投影與發光二極體至少部分重疊。 A road lighting device according to any one of claims 2-6, wherein the mirror has an arc-shaped or linear reflecting surface facing the light-emitting diode for reflecting light, the mirror The projection on the plane of the light-emitting diode at least partially overlaps the light-emitting diode. 如申請專利範圍第1項所述之路面照明裝置,其中,該至少一光源包括至少一第一光源和至少一第二光源,所述第一光源的至少一光學元件包括一第一透鏡,該第一透鏡用以使發光二極體發出的光線向所述第一光源的側向偏折出射而形成翼形配光曲線,所述第二光源的至少一光學元件包括一第二透鏡,該第二透鏡用以將發光二極體發出的光線向行車遠離側偏折。 The road lighting device of claim 1, wherein the at least one light source comprises at least one first light source and at least one second light source, and the at least one optical component of the first light source comprises a first lens, The first lens is configured to cause a light emitted from the LED to be laterally deflected toward the first light source to form a wing-shaped light distribution curve, and at least one optical component of the second light source includes a second lens. The second lens is configured to deflect the light emitted by the LED from the side away from the vehicle. 如申請專利範圍第8項所述之路面照明裝置,其中,該第二透鏡包括一平面形的入光面、一相對的出光面及一連接入光面和出光面的豎直側面,該出光面為與入光面呈一預定夾角的內凹曲面,出光面相對入光面的斜率由第二光源的一側向另一側逐漸增加。 The road surface illumination device of claim 8, wherein the second lens comprises a planar light-incident surface, an opposite light-emitting surface, and a vertical side surface connected to the light-emitting surface and the light-emitting surface. The surface is a concave curved surface at a predetermined angle with the light incident surface, and the slope of the light emitting surface opposite to the light incident surface is gradually increased from one side of the second light source to the other side. 如申請專利範圍第8項所述之路面照明裝置,其中,該第二透鏡包括一矩形的本體部及形成於主體部的頂面的光學部,該光學部的外表面為一朝遠離主體部的方向凸起的球面,光學部的厚度從第二光源的一側向另一側逐漸增加。 The road illumination device of claim 8, wherein the second lens comprises a rectangular body portion and an optical portion formed on a top surface of the body portion, the outer surface of the optical portion being away from the body portion In the direction of the convex spherical surface, the thickness of the optical portion gradually increases from one side of the second light source to the other side. 如申請專利範圍第10項所述之路面照明裝置,其中,該本體部的底面向頂面所在方向凹陷形成一收容發光二極體的收容空間,該收容空間靠近該光學部的厚度較小的一側設置。 The road lighting device of claim 10, wherein the bottom portion of the body portion is recessed toward the top surface to form a receiving space for receiving the light emitting diode, wherein the receiving space is close to the optical portion. Set on one side. 如申請專利範圍第8項所述之路面照明裝置,其中,該第二透鏡位於發光二極體的上方,其包括一平面狀的入光面及一與入光面相對的出光面,該出光面上設有複數凸起,每一凸起包括一垂直於入光面的豎直面及一連接該豎直面的傾斜面,所述豎直面相互平行,所述傾斜面分別連接相鄰的兩個豎直面。 The road surface illumination device of claim 8, wherein the second lens is located above the light emitting diode, and comprises a planar light incident surface and a light emitting surface opposite to the light incident surface, the light output a plurality of protrusions are disposed on the surface, each protrusion includes a vertical surface perpendicular to the light incident surface and an inclined surface connecting the vertical surfaces, the vertical surfaces are parallel to each other, and the inclined surfaces are respectively connected to the adjacent two Vertical face. 如申請專利範圍第12項所述之路面照明裝置,其中,該第一透鏡包括一底面、一與該底面相對的“V”字形頂面及一連接底面與頂面的側面,該底面的中央向頂面所在方向凹陷形成一收容該發光二極體的收容室,該側面上沿軸向設有複數凸起,每一凸起包括分別與軸線傾斜的第一斜面及第二斜面,所述第一斜面與第二斜面於遠離中心軸線的一端相交形成一銳角。 The road surface lighting device of claim 12, wherein the first lens comprises a bottom surface, a "V" shaped top surface opposite the bottom surface, and a side surface connecting the bottom surface and the top surface, the center of the bottom surface Forming a receiving chamber for accommodating the light emitting diode in a direction of the top surface, wherein the side surface is provided with a plurality of protrusions in the axial direction, and each of the protrusions includes a first inclined surface and a second inclined surface respectively inclined to the axis, The first slope intersects the second slope at an end remote from the central axis to form an acute angle. 如申請專利範圍第9-12項中任意一項所述之路面照明裝置,其中,該透鏡位於發光二極體的上方,其包括一平面狀的入光面及一與入光面相對的出光面,該出光面上設有複數凸起,每一凸起包括一與入光面垂直的第一鋸齒面及一與該第一鋸齒面相交的第二鋸齒面,所述凸起相對軸線呈中心對稱設置,位於軸線同一側的凸起的第一鋸齒面均位於遠離軸線的一側。 The road surface illumination device according to any one of claims 9 to 12, wherein the lens is located above the light emitting diode, and comprises a planar light incident surface and a light exiting the light incident surface. a plurality of protrusions on the light-emitting surface, each protrusion includes a first sawtooth surface perpendicular to the light incident surface and a second sawtooth surface intersecting the first sawtooth surface, the protrusion being opposite to the axis The center is symmetrically disposed, and the convex first serrated faces on the same side of the axis are located on one side away from the axis. 如申請專利範圍第9-12項中任意一項所述之路面照明裝置,其中,該透鏡包括一入光面、一與入光面相對的出光面及一連接入光面和出光面的弧形側面,該入光面的中央朝向出光面所在方向凹陷形成一收容發光二極體的收容空間,該出光面的中央形成為一漏斗狀的凹面。 The road surface illumination device of any one of claims 9-12, wherein the lens comprises a light incident surface, a light exit surface opposite to the light incident surface, and an arc connected to the light surface and the light exit surface. The central side of the light-incident surface is recessed toward the light-emitting surface to form a receiving space for receiving the light-emitting diode. The center of the light-emitting surface is formed as a funnel-shaped concave surface. 如申請專利範圍第9-12項中任意一項所述之路面照明裝置,其中,該至少一光源在垂直於路面延伸的方向上於軸線上的光線的光強度小於該方向上的光線的最大光強度的三分之一,並在平行於路面延伸的方向上於行車遠離側的45至85度角處的光線的光強度小於行車靠近側的光線的最大光強度的六分之一。 The road lighting device according to any one of claims 9 to 12, wherein the light intensity of the light on the axis in the direction perpendicular to the road surface of the at least one light source is smaller than the maximum light in the direction One-third of the light intensity, and the light intensity at a 45 to 85 degree angle away from the side of the vehicle in a direction parallel to the road surface is less than one-sixth of the maximum light intensity of the light on the approaching side of the vehicle.
TW099103546A 2010-02-05 2010-02-05 Road illumination device TWI390147B (en)

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