M317026 八、新型說明: 【新型所屬之技術領域】 本創作係關於一種RGB影像光源結構,特別係關於一種 透過RGB三種不同光波長之光線之混合,投射出與玻璃基板 顏色相應光譜之RGB影像光源結構。M317026 VIII. New Description: [New Technology Field] This creator is about an RGB image source structure, especially for a RGB image source that emits light corresponding to the color of the glass substrate through a mixture of three different wavelengths of light in RGB. structure.
I 【先前技術】 請參閱第一圖所示,係習用影像光源結構示意圖,習用影 0 像光源主要係採用一鹵素燈91作為光線來源,並於鹵素燈91 之光源輸出口上加裝一遽光片92,使得鹵素燈91所產生之光 源經由濾光片92之濾成不同光波長之光線;係將鹵素燈9 i 之光源輸出口裝設於一套筒93上,該套筒93頂端設置有一 CCD鏡頭94,底端設置有玻璃基板95,並於套筒93内設置 有與鹵素燈91光源輸出口相對應之反射鏡片96,使的鹵素燈 91經由濾光片 璃基板95上 92渡光後之光線97可經反射鏡爿96反射於玻 Φ 光源在應用上仍然具有以下之缺失:I [Prior Art] Please refer to the first figure, which is a schematic diagram of the structure of the conventional image light source. The conventional image 0 light source mainly uses a halogen lamp 91 as a light source, and a light is added to the light source output port of the halogen lamp 91. The sheet 92 is such that the light source generated by the halogen lamp 91 is filtered by the filter 92 into light of different light wavelengths; the light source output port of the halogen lamp 9 i is mounted on a sleeve 93, and the sleeve 93 is disposed at the top end. There is a CCD lens 94, a glass substrate 95 is disposed at the bottom end, and a reflecting mirror 96 corresponding to the light source output port of the halogen lamp 91 is disposed in the sleeve 93, so that the halogen lamp 91 passes through the filter glass substrate 95. The light behind the light 97 can be reflected by the mirror 爿96 to the glass Φ. The light source still has the following drawbacks in application:
土反5上,並經由CCD鏡頭94擷取,以確保投射於玻璃 基板95上之光線相應於玻璃基板%之顏色;然而,習用影像The soil is reversed 5 and captured by the CCD lens 94 to ensure that the light projected onto the glass substrate 95 corresponds to the color of the glass substrate; however, the conventional image
3.習用做法若出現瑕疵品必須 順暢度。 立即停機,將減少量產的 4.白用係採用鹵素燈91作 產生尚熱,且耗電量大, 作為發光源,而i素燈91容易 實用性欠佳。 M317026 5·白用濾光片92為常用規格,若有不同必須更換,甚至 另外訂作,費時費事。 6·習用玻璃基板95縱使係統一製作完成,其在色澤上仍 會有偏差,造成必須先分析玻璃基板95之光譜後,再 <Γ做與玻璃基板95顏色相應之濾光片92。 ‘ 【新型内容】 - 本創作之RGB影像光源結構,主要包含有一外殼,該外 鲁殼内具有一容置‘空間,且其一端為封閉端,另一端為空心之擴 散光柱,該封閉端之内壁面上定位有一電路板,該電路板上連 接有紅光、綠光、藍光(R,、G、B)三種不同光波長之㈣, 以透過RGB三種不同光波長之LED進行混光,並於接近擴散 光柱處設置有一聚光鏡,該聚光鏡係與RGB三光色之lED相 對應,使得RGB三光色之LED混合後產生之光線可經聚光 鏡傳導至擴散光柱中,進而透過擴散光柱將光線輸出;係將該 外殼之擴散光柱與一套筒相連接,該套筒頂端設置有一 CCD 鏡頭,底端放置有一玻璃基板,並於套筒中設置有一與空心之 _ 擴散光柱相對應之反射鏡片,使得RGB三光色LED混合後之 光線可投射至反射鏡片上,透過反射鏡片將光線反射於玻璃基 板上’再透過CCD鏡頭#|取玻璃基板上之光譜信號,並將信 號傳送至電腦主機中進行自動調光或手動調光之動作,使得反 射於玻璃基板上之光線與玻璃基板之顏色相對應。 【實施方式】 請參閱第二圖及第三圖所示,係為本創作之RGB影像光 源結構示意圖,主要包括: 一外殼1,該外殼1内具有一容置空間n,該容置空間u M317026 且其一端為封閉端U1,另一端為空心擴散光柱112; 聚光鏡2,該聚光鏡2係定位於外殼1中,並接近擴散 光柱112處; 一連接有RGB三光色LED4之電路板3,該電路板3係定 位於外殼1之封閉端111内壁面上,使得RGB三光色LED4 與聚光鏡2相對應,且該電路板3並與一電腦主機相連接(圖 中未標示),使電腦主機可控制調整RGB三光色LED4之發光 比例,使付RGB二光色LED4可進行混光,以產生各種不同 塵波長之光線,該光線可經具聚光鏡2聚光後,由擴散光柱112 .輸出。 請參閱第四圖、第五圖及第六圖所示,係本創作之實施示 意圖,係將該外殼1之擴散光柱112與一套筒5相連接,該套 筒5頂端設置有一 CCD鏡頭7,底端放置有一玻璃基板8,並 於套筒5中設置有一與擴散光柱112相對應之反射鏡片6(如 第四圖所示),使得RGB三光色led4混合後之光線12可經 擴散光柱112投射至反射鏡片6上(如第五圖所示),透過反 射鏡片6將光線12反射於玻璃基板8上,再透過CCD鏡頭7 φ 擷取玻璃基板8上之光譜信號,並將信號傳送至電腦主機中, 再透過一顯示介面81顯示玻璃基板上之光譜影像811、RC}B 三光色之比例812、手動調整介面813及判斷率選擇介面814 (如第六圖所示);若所投射之光線12不符合玻璃基板8之顏 — 色,使用者可選擇以自動方式或手動方式進行RGB三光色 • LED4比例之調光,以確保反射於玻璃基板8上之光線12可 與玻璃基板8之顏色相對應。 為使本創作更加顯現出進步性與實用性,茲與習用物品作 一比較分析如下: 習用缺失: M317026 ι·習用做法因機台作動快速,因此無法迅速更換濾光片。 2. 習用做法係採用滤光片之渡光輸出與玻璃基板顏色相 應之光線,若玻璃基板出現瑕疵,則必須再找合適的 濾光片。 3. 習用做法若出現瑕疵品必須立即停機,將減少量產的 順暢度。 4·習用係採用鹵素燈作為發光源,而鹵素燈容易產生高 熱,且耗電量大,實用性欠佳。 5 ·習用濾光片為常用規格,若有不同必須更換,甚至另 外訂作,費時費事。 6 ·習用玻璃基板縱使係統一製作完成,其在色澤上仍會 有偏差,造成必須先分析玻璃基板之光譜後,再訂作 與玻璃基板顏色相應之濾光片。 本創作之優點: 1.本創作係採用RGB三光色進行混光,.使其可依RGB 二光色比例之不同混合產生與玻璃基板顏色相應之光 線’以改善習用使用濾光片之缺失。, 2·本創作係採用RGB三光色進行混光,無論玻璃基板之 色澤為何,皆可產生與其顏色相應之光線。 3·本創作係採用LED作為發光源,使其具有低熱度、低 耗電量及體積小等優點。 【圖式簡單說明】 第一圖習用影像光源結構示意圖。 第二圖為本創作RGB影像光源結構之剖面示意圖。 第二圖為本創作RGB影像光源結構之立體示意圖。 第四圖為本創作RGB影像光源結構之應用示意圖。 M317026 第五圖為本創作RGB影像光源結構之RGB混光示意圖。 第六圖為本創作RGB影像光源結構之電腦顯示介面示意 圖0 【主要元件符號說明】 1外殼 11容置空間 111封閉端 112擴散光柱 12光線 2聚光鏡 3電路板3. If the product is used, it must be smooth. Immediate shutdown will reduce mass production. 4. The white system uses halogen lamp 91 to generate heat, and consumes a large amount of electricity. As a light source, the i-lamp 91 is easy to use. M317026 5·White filter 92 is a common specification. If it is different, it must be replaced or even ordered. It takes time and effort. 6. Conventional Glass Substrate 95 Even if the system is completed, there will still be variations in the color, and it is necessary to analyze the spectrum of the glass substrate 95 first, and then to filter the color filter 92 corresponding to the color of the glass substrate 95. ' [New content] - The RGB image light source structure of the present invention mainly comprises a casing having a receiving space therein, and one end is a closed end, and the other end is a hollow diffusing light column, and the closed end is A circuit board is disposed on the inner wall surface, and the circuit board is connected with three different optical wavelengths of red light, green light, blue light (R, G, B), and is mixed by three LEDs of different wavelengths of light, and A concentrating mirror is disposed near the diffusing light column, and the condensing mirror corresponds to the ED of the RGB three-color color, so that the light generated by mixing the RGB three-color LEDs can be transmitted to the diffused light column through the condensing mirror, and then the light is output through the diffused light column; The diffusing light column of the outer casing is connected to a sleeve, a CCD lens is disposed at the top end of the sleeve, a glass substrate is disposed at the bottom end, and a reflecting mirror corresponding to the hollow diffusing light column is disposed in the sleeve, so that RGB is The light mixed by the three-color LED can be projected onto the reflective lens, and the light is reflected on the glass substrate through the reflective lens. Then the CCD lens is taken through the lens. The spectrum signal, and the signal is transmitted to the host computer for automatic dimming or dimming operation of the manual, so that the reflected light and the color of the glass substrate on the glass substrate, respectively. [Embodiment] Please refer to the second and third figures, which is a schematic diagram of the structure of the RGB image light source of the present invention, which mainly includes: a casing 1 having an accommodating space n therein, the accommodating space u M317026 has a closed end U1 at one end and a hollow diffused light column 112 at the other end; a concentrating mirror 2, which is positioned in the outer casing 1 and close to the diffusing light column 112; a circuit board 3 to which the RGB three-color LED 4 is connected, The circuit board 3 is positioned on the inner wall surface of the closed end 111 of the outer casing 1, so that the RGB three-color LED 4 corresponds to the condensing mirror 2, and the circuit board 3 is connected to a computer main body (not shown), so that the computer main body can be The illumination ratio of the RGB three-color LED 4 is controlled to be mixed, so that the RGB two-color LED 4 can be mixed to generate light of various dust wavelengths, and the light can be output by the diffusing beam 112 after being collected by the collecting mirror 2. Please refer to the fourth, fifth and sixth figures. The schematic diagram of the implementation of the present invention is to connect the diffusing beam 112 of the outer casing 1 to a sleeve 5, and a CCD lens 7 is arranged at the top of the sleeve 5. A glass substrate 8 is disposed at the bottom end, and a reflecting mirror 6 corresponding to the diffusing beam 112 is disposed in the sleeve 5 (as shown in the fourth figure), so that the light 12 mixed by the RGB three-color LED 4 can be diffused. 112 is projected onto the reflecting mirror 6 (as shown in FIG. 5), and the light 12 is reflected on the glass substrate 8 through the reflecting mirror 6, and then the spectral signal on the glass substrate 8 is captured through the CCD lens 7 φ, and the signal is transmitted. In the host computer, a spectral image 811, RC}B three-color ratio 812, a manual adjustment interface 813, and a determination rate selection interface 814 are displayed through a display interface 81 (as shown in FIG. 6); The projected light 12 does not conform to the color of the glass substrate 8, and the user can select the RGB three-color color/LED4 ratio dimming in an automatic or manual manner to ensure that the light 12 reflected on the glass substrate 8 can be combined with the glass substrate. 8 color phase Should. In order to make this creation more progressive and practical, a comparative analysis with the customary items is as follows: Lack of use: M317026 ι·The practice is fast because the machine can be quickly replaced, so the filter cannot be changed quickly. 2. The conventional practice is to use the light of the filter to output light corresponding to the color of the glass substrate. If the glass substrate is flawed, it is necessary to find a suitable filter. 3. If the product is used, the product must be shut down immediately, which will reduce the smoothness of mass production. 4. The conventional system uses a halogen lamp as a light source, and the halogen lamp is prone to high heat, and consumes a large amount of power and has poor practicability. 5 • The conventional filter is a common specification. If it is different, it must be replaced or even ordered. It takes time and effort. 6 · Conventional glass substrates, even if the system is completed, there will still be deviations in the color, which makes it necessary to analyze the spectrum of the glass substrate before making a filter corresponding to the color of the glass substrate. Advantages of this creation: 1. This creation uses RGB three-color color to mix light, so that it can be mixed according to the RGB two-color ratio to produce the light corresponding to the color of the glass substrate' to improve the lack of conventional use of the filter. 2) This creation system uses RGB three-color color to mix light, regardless of the color of the glass substrate, it can produce light corresponding to its color. 3. This creation department uses LED as the light source to make it have the advantages of low heat, low power consumption and small volume. [Simple description of the figure] The first picture is a schematic diagram of the structure of the image source. The second figure is a schematic cross-sectional view of the structure of the RGB image light source. The second figure is a three-dimensional schematic diagram of the structure of the RGB image light source. The fourth picture is a schematic diagram of the application of the RGB image light source structure. M317026 The fifth figure is a schematic diagram of RGB mixed light of the RGB image light source structure. The sixth picture shows the computer display interface of the RGB image light source structure. Figure 0 [Main component symbol description] 1 Shell 11 accommodating space 111 closed end 112 diffused light column 12 light 2 concentrating mirror 3 circuit board
4LED 5套筒 6反射鏡片 7CCD鏡頭 8玻璃基板 81顯示介面 811光譜影棟 812RGB三光色之比例 813手動調整介面 814判斷率選擇介面 91鹵素燈 92濾光片 93套筒 94CCD鏡頭 95玻璃基板 M317026 96反射鏡片 97光線4LED 5 sleeve 6 reflective lens 7 CCD lens 8 glass substrate 81 display interface 811 spectral shadow 812RGB three color ratio 813 manual adjustment interface 814 judgment rate selection interface 91 halogen lamp 92 filter 93 sleeve 94CCD lens 95 glass substrate M317026 96 Reflective lens 97 light