201017059 六、發明說明: 【發明所屬之技術領域】 本發明係有關於一種LED光源系統,特別是指一種光源 效率佳之LED光源系統。 【先前技術】201017059 VI. Description of the Invention: [Technical Field] The present invention relates to an LED light source system, and more particularly to an LED light source system with excellent light source efficiency. [Prior Art]
按,關於以LED做為光源之應用,已公開的專利技術諸 如有台灣新型公告第M327449號「LED光源結構」、第 M331079號「LED照明單元及其光源模組」及第^297441「LED 投射光源模組」等’在此併入本文,以供參考。 【發明内容】 本發明之一目的係提供一種LED光源系統,可用比較少 的能量(功率),達到較佳之光亮度,而可節能省電。 本發明之另一目的係提供一種LED光源系統,用以可作 為紫外線固化機或紫外線曝光機。 根據本發明之觀點,該LH)光源系統,包括有一 Lm)光源 模組,用以產生一第一光源;一反射件,具有一反射面,該反 射面包括一預定的曲率相對於該LED光源模組;及一散熱模 組,設置於相鄰該LED光源模組,用以對該LED光源模組所產 生之熱加以散熱;其中,該反射件之反射面是用以反射該第一 光源而形成一第一反射光源朝向在一預定的聚焦位置。 根據本發明之另一觀點,該LED光源系統,包括一 le:D光 源模組,用以產生—第―光源;—反射件,具有__反射面,該 反射面相對於該LED光源模組,且該反射面用以反射該第一光 $形成一反射光源;一聚焦透鏡,用以聚焦該反射光源形成一 聚,光束;及一散熱模組,設置於相鄰該LE:D光源模組,用以 對該LED光源模組所產生之熱加以散熱。 其中,更包括有一連接器用以接收該第一反射光源。 其中,更包括有一柱狀透鏡(1*0(11如3)用以接收該第一 反射光源。 201017059 其中’更包括有一複眼透鏡(fly eye lens)用以接收該 第一反射光源。 其中’更包括有一濾鏡用以過濾該第一反射光源。 其中,更包括有一第一外部反射件用以反射該第一反射光 源形成一第一外部反射光源。 ' 其中’更包括有一第二透鏡及一第二外部反射件用以反射 • 該第一反射光源形成一第一外部反射光源’其中,該第二透鏡 用以接收該第一外部反射光源。 其中’更包括有一第二散熱模組,用以對該殼體之容置空 間所產生之熱加以散熱。 其中’更包括有一感測器用以感測該第一反射光源之一訊 號及一控制模組用以接收該訊號,並根據該訊號控制該LED光 源模組。 其中,更包括有一連接器用以接收該聚焦光束》 其中,更包括有一柱狀透鏡(rod lens)用以接收該聚焦 光束。 其中,更包括有一複眼透鏡(fly eye lens)用以接收該聚 焦光束。 其中,更包括有一濾鏡用以過濾該聚焦光束。 © 其中,更包括有一第二散熱模組,用以對該殼體之容置空 間所產生之熱加以散熱。 其中’更包括有一感測器用以感測該聚焦光束之一訊號及 才二制模組用以接收該訊號,並根據該訊號控制該led光源 模組。 八 【實施方式】 卜參,第1圖,其係本發明第一實施例之LED光源系統之 苐一型態架構示意圖。本實施例中,包括有: 一殼體100,包括有一容置空間102。 一 LED光源模組1〇4 ’設置在該殼體1〇〇之容置空間 102 ’該LED光源模組1〇4用以產生一第—光源1〇6。工 201017059 一反射件108,具有一反射面110,該反射面no包括一 預定的曲率相對於該LED光源模組104。 一散熱模組112,設置於相鄰該LED光源模組1〇4,用以 對該LED光源模組104所產生之熱加以散熱。本實施例中, 該散熱模組112為一風扇、熱導管、散熱鰭片或其它具有消除 . 熱之散熱物質。 其中’該反射件108之反射面110是用以反射該第一光源 • 106而形成一第一反射光源114朝向在一預定的聚焦位置。 其中’更包括有一連接器116用以接收該第一反射光源 114。本實施例中’該連接器116為一光纖接頭,設置在該殼 ❸ 體100上。 其中’更包括有一柱狀透鏡118 (rodlens)用以接收該第 一反射光源114,如第3圖所示。本實施例中,該柱狀透鏡118 接收该第一反射光源114後’在該柱狀透鏡118内震盈作連續 變化,形成一預定的光源分佈。 ' 其中’更包括有一複眼透鏡120 (fly eye lens)用以接收 該第一反射光源114 ’如第4圖所示。 其中’更包括有一濾鏡122用以過濾該第一反射光源 114,如第2至第4圖所示。本實施例中,更包括有複數個可 ❹ 以改變頻譜之濾鏡122 ’及一馬達124包括有一連接件126連 接至該些濾鏡122,用以可控制該些濾鏡122位移,使得該些 濾鏡122可以調整控制改變該第一反射光源114之頻譜。以^ 施例中’ 5亥連接件126可為皮帶或齒輪或其他之傳動元件。 其中,更包括有一第一外部反射件128用以反射該第一反 射光源114形成一第一外部反射光源13〇。本實施例中,該第 一外部反射件128為一弧面反射件,而可直接產生反射之 光源,如第9圖所示。此外,該LED光源模組1〇4可採 外線LED (UV LED),使得本實施例可作為uv固化機或趴^ 光機。 喂 其中,更包括有一第二透鏡132及一第二外部反射件134 201017059 用以反,J第-反射光源114形成__第—外部反射光源13〇, ,中,該第二透鏡132用以接收該第一外部反射光源13〇。本 貫施例中,該第二外部反射件134為一平面反射件,而產生一 反射光源’如第10圖所示。該第二透鏡132為一凸透鏡。此 外’該LED光源模組顺可採用紫外線LED (uv LED),使 得本實施例可作為UV固化機或UV爆光機。 其中,更包括有一第二散熱模組136,用以對該殼體1〇〇 之谷置空間102所產生之熱加以散熱。本實施例中,該第二散 熱模組136設置在該殼體100上,其可為一風扇、熱導管、散 魯 熱鰭片或其它具有消除熱之散熱物質。 其中,更包括有一感測器138用以感測該第一反射光源 114之一訊號(如第2至第4圖所示)及一控制模組14〇用以 接收該訊號,並根據該訊號控制該LED光源模組1〇4。本實 施例中,該控制模組140包括一 LED電源及通訊模組。 其中,更包括有一第二LED光源模組142(或複數個LED 光源模組)設置在該殼體1〇〇之容置空間1〇2内(如第5圖所 不),該第二LED光源模組142用以產生一第二光源,及一第 二反射件146具有一第二反射面148,該第二反射面148包括 一第二預定的曲率相對於該LED光源模組1〇4,該第二反射 件146之第二反射面148是用以反射前述該第一反射光源114 而形成一第二反射光源150朝向一預定的聚焦位置。或者,直 接以該第二反射件146用以反射該第一反射光源114而形成一 第二反射光源150朝向一預定的聚焦位置。 其中,更包括有一連接器116用以接收該第二反射光源 150。本實施例中,該連接器116為一光纖接頭,設置在該殼 體100上。 其中,更包括有一柱狀透鏡118 (rod lens)用以接收該第 二反射光源150,如第7圖所示。本實施例中,該柱狀透鏡118 接收該第二反射光源150後,在該柱狀透鏡118内震盈作連續 變化,形成一預定的光源分佈。 201017059 其中’更包括有一複眼透鏡120 (fly eye iens)用技 該第二反射光源150,如第8圖所示。 ^接收 其中―,更包括有一濾鏡122用以過濾該第二反射光源 150,如第6至第8圖所示。本實施例中,更包括有複數個可 以改變頻譜之濾鏡122 ’及一馬達124包括有一連接件126連 接至該些濾鏡122,用以可控制該些濾鏡122位移,使得該些 . 濾鏡122可以調整控制改變該第二反射光源150之頻譜。本f 施例中’該連接件126可為皮帶或齒輪或其他之傳動元件。 其中,更包括有一感測器138用以感測該第二反射光源 ® I50之一訊號(如第6至第8圖所示)及一控制模組140用以 接收該訊號,並根據該訊號控制該LED光源模組1〇4、142。 本實施例中,該控制模組140包括一 LED電源及通訊模組。 參閱第11圖,其係本發明第二實施例之LED光源系統之 第一型態架構示意圖。本實施例中,包括有: 一殼體200,包括有一容置空間202。 一 LED光源模組204,設置在該殼體200之容置空間 202 ’該LED光源模組204用以產生一第一光源206。 一反射件208 ’具有一反射面210,該反射面210相對於 .該LED光源模組204,且該反射面210用以反射該第一光源 206形成一反射光源212。 一聚焦透鏡214 ’用以聚焦該反射光源212形成一聚焦光 束216朝向一預定的聚焦位置, 一散熱模組218,設置於相鄰該LED光源模組204,用以 對該LED光源模組204所產生之熱加以散熱。本實施例中, 該散熱模組218為一風扇、熱導管、散熱鰭片或其它具有消除 熱之散熱物質。 其中,更包括有一連接器220用以接收該聚焦光束216。 本實施例中,該連接器220為一光纖接頭,設置在該殼體200 上。 其中’更包括有一柱狀透鏡222 (rod lens)用以接收該聚 201017059 焦光束216,如第13圖所示。本實施例中,該柱狀透鏡222 接收3亥1焦光束216後,在该柱狀透鏡222内震廬作連續變 化,形成一預定的光源分佈。 ~ 其中,更包括有一複眼逸鏡224 (fly eye lens)用以接收 該聚焦光束216,如第14圖所示。 ' 其中,更包括有一濾鏡226用以過濾該聚焦光束216,如 . 第12至第14圖所示。本實施例中,更包括有複數個可以改變 頻譜之濾鏡226 ’及一馬達228包括有一連接件230連接至該 .些處鏡226 ’用以可控制該些渡鏡226位移,使得該些遽鏡226 可以調整控制改變該聚焦光束216之頻譜。本實施例^,該連 接件230可為皮帶或齒輪或其他之傳動元件。 其中’更包括有一第二散熱模組240,用以對該殼體2〇〇 之谷置空間202所產生之熱加以散熱。本實施例中,該第二散 熱模組240設置在該殼體200上,其可為一風扇、熱導管、散 熱鰭片或其它具有消除熱之散熱物質。 其中,更包括有一感測器242用以感測該聚焦光束216之 —訊號(如第12至第14圊)及一控制模組244用以接收該訊 號,並根據該訊號控制該LED光源模組204。本實施例中, 該控制模組244包括一 LED電源及通訊模組。 ⑩ 其中’更包括有複數個LED光源模組204 (如第15圖 所示)用以產生一第一光源206,藉該反射件208之反射面210 用以反射該第一光源206形成一反射光源212。 其中’更包括有一第一外部反射件232用以反射該聚焦光 束216形成一第一外部反射光源230。本實施例中,該第一外 反射件232為一弧面反射件,而可直接產生反射之平行光 源’如第16圖所示。此外,該LED光源模組204可採用紫外 線LED (UV LED),使得本實施例可作為UV固化機或UV 曝光機。 其中’更包括有一第二透鏡236及一第二外部反射件238 用以反射該聚焦光束216形成一第一外部反射光源234,其 201017059 中’該第二透鏡236用以接收該第一外部反射光源234。本實 施例中,該第二外部反射件238為一平面反射件,而產生一反 射光源,如第17圖所示。該第二透鏡236為一凸透鏡。此外, 該LED光源模組204可採用紫外線LED (UV LED),使得本 實施例可作為UV固化機或UV曝光機。 如前所述’請參閱第18圖’其係本發明前述實施例之led 模組配置示意圖。本實施例中,該LED光源模組104或204According to the application of LED as a light source, the disclosed patented technologies include, for example, Taiwan's new bulletin No. M327449 "LED light source structure", No. M331079 "LED lighting unit and its light source module" and the second "297441" LED projection Light source modules, etc., are incorporated herein by reference. SUMMARY OF THE INVENTION One object of the present invention is to provide an LED light source system that can achieve better light brightness with less energy (power), and can save energy and power. Another object of the present invention is to provide an LED light source system for use as an ultraviolet curing machine or an ultraviolet exposure machine. According to an aspect of the present invention, the LH) light source system includes an Lm) light source module for generating a first light source; and a reflective member having a reflective surface, the reflective surface including a predetermined curvature relative to the LED light source And a heat dissipation module disposed adjacent to the LED light source module for dissipating heat generated by the LED light source module; wherein a reflective surface of the reflective component is for reflecting the first light source A first reflected light source is formed to face a predetermined focus position. According to another aspect of the present invention, the LED light source system includes a light source module for generating a first light source, and a reflective member having a __reflecting surface opposite to the LED light source module. And the reflecting surface is configured to reflect the first light to form a reflective light source; a focusing lens for focusing the reflective light source to form a focusing light beam; and a heat dissipation module disposed adjacent to the LE:D light source module The heat generated by the LED light source module is used to dissipate heat. The method further includes a connector for receiving the first reflected light source. The method further includes a cylindrical lens (1*0 (11 such as 3) for receiving the first reflective light source. 201017059 wherein 'further includes a fly eye lens for receiving the first reflective light source. The method further includes a filter for filtering the first reflective light source, wherein the first external reflective member is configured to reflect the first reflective light source to form a first external reflective light source. a second external reflector for reflecting the first reflective source to form a first externally reflected source, wherein the second lens is for receiving the first externally reflected source. The 'including a second heat dissipation module, The heat generated by the accommodating space of the housing is dissipated. The method further includes a sensor for sensing one of the first reflected light sources and a control module for receiving the signal, and according to the The signal controls the LED light source module, and further includes a connector for receiving the focused beam, wherein the lens further includes a rod lens for receiving the focused beam. The method further includes a fly eye lens for receiving the focused beam, wherein the filter further includes a filter for filtering the focused beam, wherein: further comprising a second heat dissipation module for the shell The heat generated by the space of the body is dissipated. wherein the sensor further comprises a sensor for sensing the signal of the focused beam and the module for receiving the signal, and controlling the LED light source mode according to the signal. [Embodiment] FIG. 1 is a schematic diagram of a first-type architecture of an LED light source system according to a first embodiment of the present invention. In this embodiment, a housing 100 includes a housing. The space 102 is disposed. An LED light source module 1〇4' is disposed in the housing space 102 of the housing 1'. The LED light source module 1〇4 is used to generate a first light source 1〇6. The component 108 has a reflective surface 110, and the reflective surface no includes a predetermined curvature relative to the LED light source module 104. A heat dissipation module 112 is disposed adjacent to the LED light source module 1〇4 for The heat generated by the LED light source module 104 is applied In this embodiment, the heat dissipation module 112 is a fan, a heat pipe, a heat dissipation fin, or other heat dissipation material having a heat dissipation. The reflective surface 110 of the reflector 108 is used to reflect the first light source. The first reflective light source 114 is formed to face a predetermined focus position. The 'more includes a connector 116 for receiving the first reflective light source 114. In the embodiment, the connector 116 is a fiber optic connector. The lens body 100 is disposed on the housing 100. The 'including a lenticular lens 118 for receiving the first reflective light source 114, as shown in FIG. 3. In the embodiment, the lenticular lens 118 receives the After the first reflected light source 114, the shock is continuously changed within the lenticular lens 118 to form a predetermined light source distribution. The 'inside' further includes a fly eye lens for receiving the first reflected light source 114' as shown in FIG. Wherein ' further includes a filter 122 for filtering the first reflected light source 114, as shown in Figures 2 through 4. In this embodiment, a filter 122 is further included, and a motor 124 is included. The motor 124 includes a connecting member 126 connected to the filters 122 for controlling the displacement of the filters 122. The filters 122 can adjust the control to change the frequency spectrum of the first reflected light source 114. In the embodiment, the '5 hai connector 126 can be a belt or gear or other transmission component. There is further included a first external reflective member 128 for reflecting the first reflective light source 114 to form a first external reflected light source 13A. In this embodiment, the first external reflector 128 is a curved reflector, and the reflected light source can be directly generated, as shown in FIG. In addition, the LED light source module 1〇4 can adopt an external LED (UV LED), so that the embodiment can be used as a uv curing machine or a 趴^. In addition, a second lens 132 and a second external reflection member 134 201017059 are used for reverse, and the J-th reflection light source 114 forms a __--external reflection light source 13A, wherein the second lens 132 is used for The first externally reflected light source 13A is received. In the present embodiment, the second external reflection member 134 is a planar reflection member, and a reflection light source is produced as shown in Fig. 10. The second lens 132 is a convex lens. In addition, the LED light source module can adopt ultraviolet LED (uv LED), so that the embodiment can be used as a UV curing machine or a UV blasting machine. There is further included a second heat dissipation module 136 for dissipating heat generated by the valley space 102 of the housing 1 . In this embodiment, the second heat dissipation module 136 is disposed on the housing 100, and may be a fan, a heat pipe, a heat sink fin or other heat dissipating material having heat elimination. The method further includes a sensor 138 for sensing a signal of the first reflective light source 114 (as shown in FIGS. 2 to 4) and a control module 14 for receiving the signal, and according to the signal The LED light source module 1〇4 is controlled. In this embodiment, the control module 140 includes an LED power supply and a communication module. The second LED light source module 142 (or a plurality of LED light source modules) is disposed in the housing space 1〇2 of the housing 1 (as shown in FIG. 5), the second LED The light source module 142 is configured to generate a second light source, and the second reflective member 146 has a second reflective surface 148. The second reflective surface 148 includes a second predetermined curvature relative to the LED light source module 1〇4. The second reflective surface 148 of the second reflective member 146 is configured to reflect the first reflective light source 114 to form a second reflective light source 150 toward a predetermined focus position. Alternatively, the second reflective member 146 is used to reflect the first reflective light source 114 to form a second reflective light source 150 toward a predetermined focus position. There is further included a connector 116 for receiving the second reflective light source 150. In this embodiment, the connector 116 is a fiber optic connector disposed on the housing 100. There is further included a rod lens 118 for receiving the second reflection source 150, as shown in FIG. In this embodiment, after receiving the second reflective light source 150, the lenticular lens 118 undergoes a continuous change in the lenticular lens 118 to form a predetermined light source distribution. 201017059 wherein 'there is a fly-eye lens 120 (fly eye iens) using the second reflected light source 150, as shown in FIG. ^ Received, and further includes a filter 122 for filtering the second reflected light source 150, as shown in Figures 6-8. In this embodiment, a filter 122 having a plurality of spectral changes is further included, and a motor 124 includes a connecting member 126 connected to the filters 122 for controlling the displacement of the filters 122. The filter 122 can adjust the control to change the spectrum of the second reflected light source 150. In the present embodiment, the connector 126 can be a belt or gear or other transmission component. The method further includes a sensor 138 for sensing a signal of the second reflected light source® I50 (as shown in FIGS. 6-8) and a control module 140 for receiving the signal, and according to the signal The LED light source modules 1〇4, 142 are controlled. In this embodiment, the control module 140 includes an LED power supply and a communication module. Referring to Figure 11, there is shown a schematic diagram of a first type of architecture of an LED light source system in accordance with a second embodiment of the present invention. In this embodiment, a housing 200 is included, including an accommodating space 202. An LED light source module 204 is disposed in the housing space 202 of the housing 200. The LED light source module 204 is configured to generate a first light source 206. A reflective member 208' has a reflective surface 210 opposite to the LED light source module 204, and the reflective surface 210 reflects the first light source 206 to form a reflective light source 212. A focusing lens 214 ′ is used to focus the reflective light source 212 to form a focused beam 216 toward a predetermined focus position. A heat dissipation module 218 is disposed adjacent to the LED light source module 204 for the LED light source module 204. The heat generated is dissipated. In this embodiment, the heat dissipation module 218 is a fan, a heat pipe, a heat sink fin, or other heat dissipating material having heat elimination. There is further included a connector 220 for receiving the focused beam 216. In this embodiment, the connector 220 is a fiber optic connector disposed on the housing 200. Wherein' further includes a rod lens 222 for receiving the poly 201017059 focal beam 216, as shown in FIG. In this embodiment, after the lenticular lens 222 receives the 3 GHz 1 focal beam 216, it is continuously changed in the lenticular lens 222 to form a predetermined light source distribution. ~ There is further included a fly eye lens 224 for receiving the focused beam 216, as shown in FIG. Wherein, a filter 226 is further included for filtering the focused beam 216, as shown in Figs. 12 to 14. In this embodiment, a plurality of filters 226' that can change the spectrum are further included, and a motor 228 includes a connecting member 230 connected to the mirrors 226' for controlling the displacement of the plurality of mirrors 226, so that the The pupil mirror 226 can adjust the control to change the spectrum of the focused beam 216. In this embodiment, the connector 230 can be a belt or a gear or other transmission component. The further includes a second heat dissipation module 240 for dissipating heat generated by the valley space 202 of the casing 2〇〇. In this embodiment, the second heat dissipation module 240 is disposed on the housing 200, and may be a fan, a heat pipe, a heat sink fin, or other heat dissipating material having heat elimination. The method further includes a sensor 242 for sensing the signal of the focused beam 216 (such as 12th to 14th) and a control module 244 for receiving the signal, and controlling the LED light source mode according to the signal. Group 204. In this embodiment, the control module 244 includes an LED power supply and a communication module. 10, wherein a plurality of LED light source modules 204 (as shown in FIG. 15) are used to generate a first light source 206, and the reflective surface 210 of the reflective member 208 is used to reflect the first light source 206 to form a reflection. Light source 212. Wherein, a further comprising a first external reflector 232 for reflecting the focused beam 216 forms a first externally reflected source 230. In this embodiment, the first external reflector 232 is a curved reflector, and the parallel parallel light source can be directly generated as shown in FIG. In addition, the LED light source module 204 can adopt ultraviolet LED (UV LED), so that the embodiment can be used as a UV curing machine or a UV exposure machine. The second lens 236 and the second external reflector 238 are configured to reflect the focused beam 216 to form a first external reflection source 234. The second lens 236 of the 201017059 is configured to receive the first external reflection. Light source 234. In this embodiment, the second external reflector 238 is a planar reflector that produces a reflective source, as shown in FIG. The second lens 236 is a convex lens. In addition, the LED light source module 204 can employ ultraviolet LEDs (UV LEDs), so that the embodiment can be used as a UV curing machine or a UV exposure machine. As described above, please refer to FIG. 18, which is a schematic diagram of a configuration of a LED module according to the foregoing embodiment of the present invention. In this embodiment, the LED light source module 104 or 204
包含有至少一 LED次模組264,每一 LED次模組(sub module) 264更包括有複數個LED元件266 ’如第19圖所示。其中, 該LED次模組264可根據使用者之需求來設計。此外,該' LED 次模組264可採用單一種顏色規格或單一顆LED元件266包 含有複數種顏色規格,亦即具有可變換複數種顏色之功能,例 如:R、G、B三色組合在單一顆led。 …如前所述’本發明實施例之絲照射之示意狀態僅係基於 忒明本發明之用,並非用以限制本發明。 如前所述,本發明之LED模組透過採用單一顆LED元件 包含有複數種顏色規格,即可達到變換調整光源顏色。 獅描述及圖式已揭示本發明之較佳實施,惟此乃 發明現,舉凡各種增添、修改和取代可能使用於本 落人本發明之中請專利範圍所界定之 用以,月太發明本,此所揭示的實施例所有觀點,應被視為 S2專利範圍所界定,並涵蓋其合以==At least one LED sub-module 264 is included, and each sub-module 264 further includes a plurality of LED elements 266' as shown in FIG. The LED sub-module 264 can be designed according to the needs of the user. In addition, the 'LED sub-module 264 can adopt a single color specification or a single LED element 266 includes a plurality of color specifications, that is, a function of converting a plurality of colors, for example, a combination of R, G, and B colors. Single led. The foregoing state of the invention of the present invention is based on the invention and is not intended to limit the invention. As described above, the LED module of the present invention can change and adjust the color of the light source by using a single LED component including a plurality of color specifications. The lion's description and drawings have disclosed the preferred embodiments of the present invention, but the present invention is invented, and various additions, modifications, and substitutions may be used in the present invention as defined by the scope of the patent. All views of the embodiments disclosed herein should be considered as defined by the scope of the S2 patent and cover the combination ==
叭間平s兄明J Ϊ=發明第-實施例之第-型態架構示咅圖 第=ir第一實施例之第:⑶ L· 一實施例之第四型態架構示意圖 圖係本毛料—實施例之第五型態架構示意圖 201017059 ,6圖係本發明第一實施例之第六型態架構示意圖。 第7圖係本發明第一實施例之第七型態架構示意圖。 ^ 8圖係本發明第一實施例之第八型態架構示意圖。 第9圖係本發明第一實施例之第九型態架構示意圖。 巧10圖係本發明第一實施例之第十型態架構示意圖。 第11圖係本發明第二實施例之第一型態架構示意圖。 第U圖係本發明第二實施例之第二型態架構示意圖。 巧13圖係本發明第二實施例之第三型態架構示意圖。 第14圖係本發明第二實施例之第四型態架構示意圖。 第15圖係本發明第二實施例之第五型態架構示意圖。 第16圖係本發明第二實施例之第六型態架構示意圖。 ,17圖係本發明第二實施例之第七型態架構示意圖。 第18圖係本發明實施例之LED光源模組配置示意圖。 第19圖係本發明實施例之LED次模組配置示意圖。 102容置空間 106第一光源 110反射面 114第一反射光源 118柱狀透鏡 122濾鏡 126連接件 B0第一外部反射光源 134第二外部反射件 138感測器 M2第二LED光振楔組 148第二反射面 200殼體 【主要元件符號說明】 1〇〇殼體 104 LED光源模組 Q 108反射件 112散熱模組 116連接器 120複眼透鏡 124馬達 128第一外部反射件 132第二透鏡 13 6第二散熱模組 140控制模組 146第二反射件 150第二反射光源 201017059间间平 s brother Ming J Ϊ = invention - embodiment of the first-type architecture shown in the figure = ir first embodiment of the first embodiment: (3) L · an embodiment of the fourth type of architecture diagram diagram of the wool - Schematic diagram of the fifth type architecture of the embodiment 201017059, 6 is a schematic diagram of the sixth type architecture of the first embodiment of the present invention. Figure 7 is a schematic diagram showing the seventh-type architecture of the first embodiment of the present invention. 8 is a schematic diagram of an eighth-type architecture of the first embodiment of the present invention. Figure 9 is a schematic view showing the ninth configuration of the first embodiment of the present invention. Figure 10 is a schematic diagram of a tenth-type architecture of the first embodiment of the present invention. Figure 11 is a schematic diagram showing the first type of architecture of the second embodiment of the present invention. Figure U is a schematic diagram of a second type of architecture of a second embodiment of the present invention. The figure 13 is a schematic diagram of a third type structure of the second embodiment of the present invention. Figure 14 is a diagram showing the fourth type of architecture of the second embodiment of the present invention. Figure 15 is a diagram showing the fifth type of architecture of the second embodiment of the present invention. Figure 16 is a diagram showing the sixth type of architecture of the second embodiment of the present invention. 17 is a schematic diagram of a seventh type architecture of the second embodiment of the present invention. Figure 18 is a schematic view showing the configuration of an LED light source module according to an embodiment of the present invention. FIG. 19 is a schematic diagram showing the configuration of an LED sub-module according to an embodiment of the present invention. 102 accommodating space 106 first light source 110 reflecting surface 114 first reflecting light source 118 lenticular lens 122 filter 126 connecting piece B0 first external reflecting light source 134 second external reflecting member 138 sensor M2 second LED light vibration wedge group 148 second reflective surface 200 housing [main component symbol description] 1 〇〇 housing 104 LED light source module Q 108 reflector 112 heat dissipation module 116 connector 120 fly eye lens 124 motor 128 first external reflector 132 second lens 13 6 second heat dissipation module 140 control module 146 second reflection member 150 second reflection light source 201017059
202容置空間 206 第一光源 210 反射面 214聚焦透鏡 218散熱模組 222柱狀透鏡 226濾鏡 230連接件 234第一外部反射光源 238第二外部反射件 242感測器 264 LED次模組 204 LED光源模組 208 反射件 212反射光源 216 聚焦光束 220連接器 224複眼透鏡 228 馬達 232 第一外部反射件 236 第二透鏡 240第二散熱模組 244控制模組 266 LED元件 11202 accommodating space 206 first light source 210 reflecting surface 214 focusing lens 218 heat dissipation module 222 cylindrical lens 226 filter 230 connecting member 234 first external reflecting light source 238 second external reflecting member 242 sensor 264 LED sub-module 204 LED light source module 208 reflector 212 reflective light source 216 focused beam 220 connector 224 fly eye lens 228 motor 232 first external reflector 236 second lens 240 second heat dissipation module 244 control module 266 LED component 11