M381999M381999
.·_ J 五、新型說明: 【新型所屬之技術領域】 本創作係關於生物成長輔助燈具,特別是利用發光二 極體晶片發光之生物成長辅助燈具。 Λ ▲ 【先前技術】 由於光線強度與光照時間對於生物的成長相當重要,攀) 各類人工光源常被用來取代或補充太陽光的不足,以改善 動植物的生長環境或增進生長速度。 就動物培育的應用而言,目前養殖場仍採用傳統的人 工光源,例如分別設置之白熾燈泡與紫外線燈管等,分別 作為照明與消毒殺菌目的使用,傳統的人工光源使用螢光 燈或白熾燈泡’但這類先前技術所採用的光源壽命短、發 光效率差、消耗功率大,而且無法一次提供多種波長之光 線’造成在使用這類人工光源時,相關照明與降溫的耗電·參 成本相當可觀。易言之,習用技術所採用的光源必須視目-的之種類而裝設不同用途的燈具,對於空間利用並不方 便’而且單獨操作將不易達成整合的功效。 就植物生長的應用而言,太陽光對植物生長有相當大 的影響’因為植物的葉綠素吸收66〇nm前後之波段以進行 光合作用、光敏素吸收660至730nm波段之光源以控制許 多反應,而類胡蘿蔔素則吸收450nm波長引起屈光性以及 4 高能量光形態發生(photomc^hogenesis)。由於植物相當仰 賴這些波段的光源,習用技術也逐漸開發相關的應用,例 如將燈泡型發光一級體(Light-Emitting Diode,. LED)應用 於作物栽培,或是研究人工光源的光量大小對於植物生長 的影響等。儘管在植物的生長應用中,以燈泡型發光二極 體取代一般的傳統光源,而能提供壽命較長、光源較為穩 定之人工光源,但採用燈泡型發光二極體的作法仍具有以 下缺失:首先,燈泡型發光二極體元件佔用面積大,面積 使用率不佳,其次,當出光光色為藍光等接近紫外光波段 之光色時,燈泡型發光二極體元件容易劣化產生光衰^ 象,導致人工光源的使用年限降低;再者,燈泡型發光二 極體係以個別顆粒焊接於印刷電路板上,個別顆粒^距離 基於燈泡型外觀的限制,無法非常靠近,導致出光面之光 色產生散亂的現象;最後,燈泡型發光二極體因為體積之 限制,必須以平板式的方式陳列,因此與傳統的人工光源 之燈具結構並不相容,造成使用者額外的成本負擔。 綜上所述,習用技術所提供之人工光源具有相當多的 缺失’因此本創作便以改善上述習用技術缺失為本^之主 要目的。 【新型内容】 本案係為一種生物成長輔助燈具,可連接至一帝 應裝置,該燈具包含:一第一晶片承载基材;一第二 M381999 二極體晶片,電連接於該第—晶>1承載基材,其可以發出 第波段光源,-第二晶片承載基材,設置於該第一晶 片承載基材之側邊;—第二發片,電連接於該 第二晶片承載基材,其可以發出—第二波段光源;以及」 燈具本體’連接於該第—晶#承載基材與該第二晶片承載 基材之底部並可轉式連接至該電源供應裝置,用以接收 該電源供應裝置所提供之電能來驅_第_發光二極體晶 片及該第二發光二極體晶片發光。 根據上述構想,本案所述之生物成長辅助燈具,其中 "玄苐波#又光源係可提供一消毒殺菌功能。 根據上述構想,本案所述之生物成長輔助燈具,其中 該第一波段光源係可為一波長360至445 nm之紫光光源或 一波長小於36〇nm之紫外光光源,其具有消毒殺菌功能。 根據上述構想,本案所述之燈具,該燈具更包含:一 阻絕構造,用以阻絕該第一發光二極體晶片所發出之該第 一波段光源對該第二晶片承載基材造成劣化現象。 根據上述構想,本案所述之生物成長輔助燈具,其中 該阻絕構造係可為一抗UV材質,如一玻璃材質或一抗UV 矽膠。 根據上述構想’本案所述之生物成長輔助燈具,其中 該第一波段光源係可提供照明功能或促進生物生長,且該 第一波段光源係可為一波長445至500nm之藍光光源、一 波長500至575nm之綠光光源、一波長575至585nm之黃 光光源、一波長585至620nm之橘光光源、一波長620至 740nm之紅光光源、或一波長15〇〇至8000nm之遠紅外線 6 M381999 光源。 根據上述構想,本案所述之生物成長輔助燈具,其中 該第二波段光源係可提供照明功能或促進生物生長,且該 第二波段光源係可為一波長445至500nm之藍光光源、一 波長500至575nm之綠光光源、一波長575至585nm之黃 光光源、一波長585至620nm之橘光光源、一波長620至 740nm之紅光光源 '或一波長1500至8000nm之遠紅外線 -· 光源。 φ 根據上述構想,本案所述之生物成長輔助燈具,該燈 具更包含:一控制器,電連接於該燈具本體,其係發出一 控制信號來使該第一發光二極體晶片於一第一預設期間内 發出該第一波段光源’以及使該第二發光二極體晶片於一 第二預設期間内發出該第二波段光源。 根據上述構想’本案所述之生物成長辅助燈具,其中 該第一預設期間可與該第二預設期間相同,其係使該第一 發光二極體晶片發出之該第一波段光源與該第二發光二極 • 晶片發出之該第二波段光源產生-混光效果。 彡 根據上述構想’本案所述之生物成長辅助燈具,其中 , 。亥控制器係可以控制該第一預設期間與該第二預設期間之 前後、交替或重複關係。 根據上述構想’本案所述之生物成長辅助燈具,其中 該控制信號之流程,係可為一預存之控制流程,或一使用 者自行設定之控制流程。 根據上述構想,本案所述之生物成長輔助燈具,其中 該控制器係可以為一設定連續或間續波段輸出一設定使 7 用波&之時間n預約設定魏,以提供該生物成長 辅助燈具之流程控制。 々根據上述構想,本案所述之生物成長輔助燈具,其中 該第發光二極體晶片係以黏著基台的方式,電連接於該 第一晶片承載基材,以及該第二發光二極體晶片係以黏著 基台的方式,電連接於該第二晶片承載基材。 根據上述構想,本案所述之生物成長輔助燈具,其中 該等晶片承載基材係使用一可導熱但為非導電體之材質, 如石 夕材質承載基材或一陶瓷材質承載基材。 本案之另一方面為一種生物成長輔助燈具,用以促進 生物成長,其可以連接至一電源供應裝置,該燈具包含: 第發光二極體晶片,其可以發出一第一波段光源,且 該第一波段光源具有一第一生物成長效果;一第二發光二 極體晶片’其可以發出—第二波段光源,且該第二波段光 源具有一第一生物成長效果;一晶片承載基材,電連接至 該第一發光二極體晶片與該第二發光二極體晶片;一燈具 本體連接於該晶片承載基材之底部並可活動式連接至該 電源供應装置,用以接收該電源供應裝置所提供之電能來 驅動3亥第一發光二極體晶片及該第二發光二極體晶片發 光;以及一控制器,電連接於該晶片承載基材,其係發出 一控制信號來使該第一發光二極體晶片於一第一預設期間 内發出該第一波段光源,以及使該第二發光二極體晶片於 一第二預設期間内發出該第二波段光源。 根據上述構想,本案所述之生物成長輔助燈具,其中 談第一波段光源與該第二波段光源係可為一波長36〇至 445 nm之紫光光源、一波長小於36〇nm之紫外光光源、一 波長445至500nm之藍光光源、一波長500至575nm之綠 光光源、一波長575至585iim之黃光光源、一波長585至 620nm之橘光光源、一波長62〇至74〇nm之紅光光源或一 波長1500至8000nm之遠紅外線光源。 根據上述構想,本案所述之生物成長輔助燈具,其中 該第一預設期間可與該第二預設期間相同,其係使該第一 發光二極體晶片發出之該第一波段光源與該第二發光二極 體晶片發出之該第二波段光源產生一混光效果。 根據上述構想,本案所述之生物成長輔助燈具,其中 該控制器係可以控制該第一預設期間與該第二預設期間之 前後、交替或重複關係。 根據上述構想,本案所述之生物成長輔助燈具,其中 忒控制彳§號係可以調整該第一發光二極體晶片與該第二發 光一極體晶片之發光強度與發光頻率。 根據上述構想,本案所述之生物成長輔助燈具,其中 該等晶片承載基材係使用一可導熱但為非導電體之材質, 如一矽材質承載基材或一陶瓷材質承載基材。 【實施方式】 習用技術所提供之人工光源或有採用白熾燈泡蛊紫外 線燈管分別作為照明與消毒殺菌目的使用者,或有=不同 波長光源之燈泡型發光二極體制而成者。前者的作法造 成使用時必須視目的來裝設不同的燈具,而後者的作法則 因燈泡型發光二極體的先天限制產生諸多缺失,二者均造 成額外成本開銷與空間利用的雙重負荷,因此本創作便以 此缺失作為改善習用技術的方向,發展出能提供多重發光 功能之新型生物成長辅助燈具。 為了改善前述缺失,本創作將人工光源所產生的方式 施以根本的改變,其雜是以至少-個晶片承載基材連接 於具有一般常見之各類燈具外觀的燈具本體上,並在該等 晶片承载基材上視使用目的之需要而連接個數與種類不等 之發光二極體晶片來發出各種波段之光源。藉由具有一般 燈具外觀之祕本财狀作法,摘作的成品相鱼二 般的燈座搭配使用’而不需要因為作法不同而花費大筆的 改裝費用;至於晶片承載基材與發光二極體晶片的選用, 則可以提做时乡樣㈣騎,㈣視實㈣要而選擇 不同波段的来.溫。 頁月參見(第一圖(a)(b) 一 \”八”六巧丹啕一般常見之燈泡盘 燈管造型之生物成長辅助燈具卜2之外觀示意圖。本_ 作法可藉由具有·造型之燈具柄12()、22(),以各種 活動式之機構設計如··旋轉、栓扣等,連接於—外部的電 源供應裝置,用以減該供縣置所提供之電 動本創作之生物成長輔祕具卜2使用。注 是,儘管第-圖⑷之燈具本體12〇與第一剛之燈且:體 220造财異,但㈣連接之··構成射以相同, 為求毅,以下僅以第―圖⑷的生物成長輔助燈具!之产 具本體120作為較佳實施例進行講解。 且 M381999 • * *.·_ J V. New description: [New technical field] This creation is about biological growth auxiliary lamps, especially biological growth auxiliary lamps that use light-emitting diode chips to emit light. Λ ▲ [Prior Art] Because light intensity and illumination time are important for the growth of living things, various artificial light sources are often used to replace or supplement the lack of sunlight to improve the growth environment of animals and plants or to increase the growth rate. As far as the application of animal breeding is concerned, the farm currently uses traditional artificial light sources, such as incandescent bulbs and ultraviolet lamps, which are separately provided for illumination and disinfection purposes. Traditional artificial light sources use fluorescent or incandescent bulbs. 'But the light source used in this prior art has a short life, poor luminous efficiency, high power consumption, and cannot provide multiple wavelengths of light at a time.] When using such artificial light sources, the related lighting and cooling power consumption and cost are equivalent. considerable. In other words, the light source used in the conventional technology must be equipped with different types of lamps depending on the type of the object, which is not convenient for space utilization, and the individual operation will not easily achieve integration. For plant growth applications, sunlight has a considerable impact on plant growth' because plant chlorophyll absorbs bands around 66〇nm for photosynthesis, and photosensitizers absorb light sources in the 660 to 730nm band to control many reactions. Carotenoids absorb the 450 nm wavelength causing refraction and 4 high energy photomorphogenesis (photomc^hogenesis). Since plants rely heavily on light sources in these bands, conventional techniques are gradually being developed, such as applying Light-Emitting Diodes (LEDs) to crop cultivation, or studying the amount of light from artificial light sources for plant growth. The impact and so on. Although the bulb-type light-emitting diode replaces the conventional light source in the growth application of the plant, and can provide an artificial light source with a long life and a stable light source, the bulb-type light-emitting diode still has the following defects: First, the bulb-type light-emitting diode component has a large area occupied, and the area usage rate is not good. Secondly, when the light-emitting color is a light color such as a blue light that is close to the ultraviolet light band, the bulb-type light-emitting diode element is easily deteriorated to cause light decay. The use of the artificial light source is reduced. In addition, the bulb-type light-emitting diode system is soldered to the printed circuit board with individual particles. The distance between the individual particles is not very close based on the appearance of the bulb type, resulting in the light color of the light-emitting surface. In the end, the bulb-type light-emitting diodes must be displayed in a flat manner due to the limitation of the volume, and thus are incompatible with the structure of the conventional artificial light source, resulting in an additional cost burden for the user. In summary, the artificial light source provided by the conventional technology has quite a lot of defects. Therefore, the present invention aims to improve the above-mentioned conventional technology. [New content] This case is a biological growth auxiliary lamp that can be connected to an emperor device. The lamp comprises: a first wafer carrier substrate; a second M381999 diode chip electrically connected to the first crystal> a carrier substrate capable of emitting a first-wavelength light source, a second wafer carrier substrate disposed on a side of the first wafer carrier substrate, and a second wafer electrically connected to the second wafer carrier substrate a second band light source; and a "light body" coupled to the bottom of the first crystal carrier substrate and the second wafer carrier substrate and rotatably coupled to the power supply device for receiving the The power provided by the power supply device drives the first-light emitting diode chip and the second light-emitting diode chip to emit light. According to the above concept, the biological growth auxiliary lamp described in the present case, wherein the "Xuan Xiaobo# and the light source system can provide a disinfection and sterilization function. According to the above concept, the biological growth auxiliary luminaire of the present invention, wherein the first wavelength light source is a violet light source with a wavelength of 360 to 445 nm or an ultraviolet light source with a wavelength of less than 36 〇 nm, which has a disinfecting and sterilizing function. According to the above concept, the lamp of the present invention further includes: a resisting structure for blocking the deterioration of the second wafer carrier substrate by the first wavelength band emitted by the first LED chip. According to the above concept, the biological growth auxiliary lamp of the present invention, wherein the resistive structure can be a UV resistant material, such as a glass material or a UV resistant silicone rubber. According to the above concept, the biological growth auxiliary luminaire of the present invention, wherein the first wavelength light source can provide an illumination function or promote biological growth, and the first wavelength light source can be a blue light source with a wavelength of 445 to 500 nm, a wavelength of 500. A green light source to 575 nm, a yellow light source with a wavelength of 575 to 585 nm, an orange light source with a wavelength of 585 to 620 nm, a red light source with a wavelength of 620 to 740 nm, or a far infrared light with a wavelength of 15 to 8000 nm. 6 M381999 light source. According to the above concept, the biological growth auxiliary luminaire of the present invention, wherein the second wavelength light source can provide an illumination function or promote biological growth, and the second wavelength light source can be a blue light source with a wavelength of 445 to 500 nm, and a wavelength of 500. A green light source of 575 nm, a yellow light source with a wavelength of 575 to 585 nm, an orange light source with a wavelength of 585 to 620 nm, a red light source with a wavelength of 620 to 740 nm, or a far infrared light with a wavelength of 1500 to 8000 nm. According to the above concept, the biological growth auxiliary lamp of the present invention further includes: a controller electrically connected to the lamp body, which emits a control signal to make the first LED chip first The first band light source is emitted during a preset period and the second band light source is emitted by the second LED chip for a second predetermined period. According to the above concept, the biological growth auxiliary luminaire of the present invention, wherein the first preset period is the same as the second preset period, the first wavelength band emitted by the first illuminating diode chip and the The second light emitting diode • the second wavelength light source emitted by the wafer produces a light mixing effect.彡 According to the above concept, the biological growth auxiliary lamp described in the present case, wherein . The controller can control the pre-, alternating or repeated relationship between the first preset period and the second preset period. According to the above concept, the biological growth auxiliary luminaire described in the present invention, wherein the control signal flow may be a pre-existing control flow or a control flow set by a user. According to the above concept, the biological growth auxiliary lamp of the present invention, wherein the controller can set a continuous or continuous band output setting to make a time setting for the wave & Process control. According to the above concept, the biological growth auxiliary lamp of the present invention, wherein the first light emitting diode chip is electrically connected to the first wafer carrier substrate and the second light emitting diode chip by way of an adhesive base. The second wafer carrier substrate is electrically connected by means of an adhesive abutment. According to the above concept, the biological growth auxiliary lamp of the present invention, wherein the wafer bearing substrate is made of a heat conductive but non-conductive material, such as a stone material carrier substrate or a ceramic material carrier substrate. Another aspect of the present invention is a biological growth auxiliary lamp for promoting biological growth, which can be connected to a power supply device, the lamp comprising: a second light emitting diode chip, which can emit a first wavelength light source, and the first a first-wavelength light source has a first biological growth effect; a second light-emitting diode wafer can emit a second-wavelength light source, and the second-wavelength light source has a first biological growth effect; a wafer-bearing substrate, electricity Connecting to the first light emitting diode chip and the second light emitting diode chip; a lamp body is connected to the bottom of the wafer carrier substrate and movably connected to the power supply device for receiving the power supply device Providing electrical energy to drive the 3H first light emitting diode chip and the second light emitting diode chip to emit light; and a controller electrically connected to the wafer carrying substrate, which sends a control signal to make the first The LED chip emits the first wavelength band during a first predetermined period of time, and causes the second LED chip to be emitted within a second predetermined period The second band light source. According to the above concept, the biological growth auxiliary lamp described in the present invention, wherein the first wave source and the second band source are a violet light source having a wavelength of 36 〇 to 445 nm, and an ultraviolet light source having a wavelength of less than 36 〇 nm, A blue light source with a wavelength of 445 to 500 nm, a green light source with a wavelength of 500 to 575 nm, a yellow light source with a wavelength of 575 to 585 μim, an orange light source with a wavelength of 585 to 620 nm, and a red light with a wavelength of 62 to 74 nm. A light source or a far infrared source having a wavelength of 1500 to 8000 nm. According to the above concept, the biological growth auxiliary luminaire of the present invention, wherein the first preset period is the same as the second preset period, the first wavelength band emitted by the first LED chip and the The second wavelength source emitted by the second LED chip produces a light mixing effect. According to the above concept, the biological growth assisting luminaire of the present invention, wherein the controller is capable of controlling a front-back, alternating or repeated relationship between the first preset period and the second preset period. According to the above concept, the biological growth auxiliary lamp of the present invention, wherein the 忒 control system can adjust the luminous intensity and the illuminating frequency of the first illuminating diode chip and the second illuminating body wafer. According to the above concept, the biological growth auxiliary lamp of the present invention, wherein the wafer bearing substrate is made of a heat conductive but non-conductive material, such as a material bearing substrate or a ceramic material carrier substrate. [Embodiment] The artificial light source provided by the conventional technology or the user who uses the incandescent bulb and the ultraviolet lamp for the purpose of illumination and sterilization, or the bulb-type light-emitting diode of the light source of different wavelengths. The former method requires different lamps to be installed according to the purpose, and the latter method has many defects due to the innate limitation of the bulb-type light-emitting diode, both of which cause double load of additional cost and space utilization. This creation has used this lack as a direction to improve the conventional technology, and developed a new biological growth auxiliary luminaire that can provide multiple illuminating functions. In order to improve the aforementioned deficiencies, the present invention applies a fundamental change to the manner in which the artificial light source is generated, which is connected to at least one wafer carrier substrate to the luminaire body having the appearance of various types of luminaires that are generally common, and Light-emitting diode chips of different numbers and types are connected to the wafer-carrying substrate to emit light sources of various wavelength bands as needed for the purpose of use. With the secret recipe of the general appearance of the luminaire, the finished two-piece lamp holder is used together with 'no need to spend a lot of modification costs because of different methods; as for the wafer carrier substrate and the light-emitting diode The selection of the body wafer can be done in the same time (four) riding, (four) depending on the actual (four) to choose different bands of temperature. See the picture of the month (first figure (a) (b) one \" eight" six skillful tantalum common general bulb lamp tube shape of the biological growth auxiliary lamp Bu 2 appearance. This _ can be done by modeling The lamp handles 12() and 22() are designed in various movable mechanisms such as · rotation, bolting, etc., and are connected to an external power supply device for reducing the electric creation provided by the county. The biological growth auxiliary auxiliary tool is used. Note that although the lamp body 12〇 of the first-figure (4) is different from the first light and the body 220 is different, but (4) the connection is made of the same, for the sake of determination, Hereinafter, only the production body 120 of the biological growth auxiliary lamp of Fig. 4 is explained as a preferred embodiment. And M381999 • * *
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請參見第一圖(c) (d),其係關於本案所發展出來關於生 物成長辅助燈具之較佳實施例之内部功能方塊圖。第一圖 (c)之生物成長輔助燈具1包含:一第一晶片承載基材1〇2, 其上方電連接一第一發光二極體晶片101,其可以發出一 第一波段光源;一第二晶片承載基材U2,設置於該第一 晶片承載基材102之侧邊,且該第二晶片承載基材112之 上方電連接一第二發光二極體晶片m,其可以發出一第 二波段光源;以及一燈具本體12〇,連接於該第一晶片承 載基材102與該第二晶片承載基材112之底部,並利用該 電源供應裝置130所提供之電能來驅動該第一發光二極體 晶片101及該第二發光二極體晶片U1發光。Please refer to the first figure (c) (d), which is an internal functional block diagram of a preferred embodiment of the bio-enhanced auxiliary lamp developed in the present invention. The biological growth auxiliary lamp 1 of the first figure (c) comprises: a first wafer carrier substrate 1〇2, electrically connected to a first LED chip 101 thereon, which can emit a first band light source; The second wafer carrier substrate U2 is disposed on a side of the first wafer carrier substrate 102, and a second LED substrate m is electrically connected to the second wafer carrier substrate 112. a light source; and a luminaire body 12 连接 connected to the bottom of the first wafer carrier substrate 102 and the second wafer carrier substrate 112, and using the power provided by the power supply device 130 to drive the first light The polar body wafer 101 and the second light emitting diode wafer U1 emit light.
隊r上迷暴本構造外,第一圖(c)之生物成長辅助燈j 1更可包含一控制器140,電連接於該燈具本體12〇,其4 發出一控制信號來使該第一發光二極體晶片1〇1於一第_ 預设期間内發出該第_波段光源,以及使該第二發光二4 體晶片111於-第二預設期_發出該第二波段光源。’ 而第一圖(d)所應用之生物成長輔助燈具丨則包含:_ 第一發光二極體晶片201,其可以發出一第一波段光源 且該第-波段光源具有-第—生物成長效果;—第二發; 厂極體晶片2G2’其可以發出—第二波段光源,且該第: ,段光源具有-第二生物成長效果;—晶片承载基材,^ j接至該第一發光二極體晶片與該第二發光二極體晶片; :燈具本體120 ’連接於該晶片承載基材2()2之底部並? 接至該鶴供縣置13G,⑽紐該電源則 、置所提供之電能來驅動該第-發光二極體晶片2〇 11 M381999 及該第二發光二極體晶片211發光;以及一控制器14〇, 該控制器可透過該燈具本體12〇而電連接於該晶片承載基 材202,其係發出一控制信號來使該第一發光二極體晶片 201於一第一預設期間内發出該第一波段光源,以及使該 第二發光二極體晶片211於一第二預設期間内發出該第二 波段光源。 由第一圖(c)(d)可以發現在本體構造12〇上所連接的晶 片承載基材數目並不相同。第一圖(c)之發光二極體晶片與 晶片承載基材之對應關係為多對多的模式,需注意的是, 儘管在此例中發光二極體晶片與晶片承載基材之數目均為 二,但在實際應用時,該些數目並不一定要相等;而第一 圖(d)中,發光一極體晶片與晶片承載基材之間則為多對一 之關係,即可發出個別波段之各個發光二極體晶片均附著 於同一個晶片承載基材上。 依據本創作設計之生物成長輔助燈具,該些發光二極 體晶片所發出之該等波段光源係可為一波長36〇至445 nm 之紫光光源、一波長小於360nm之紫外光光源、一波長445 至500nm之藍光光源、一波長500至575nm之綠光光源、 一波長575至585nm之黃光光源、一波長585至62〇nm之 橘光光源、一波長620至740nm之紅光光源、或一波長15〇〇 至8000imi之遠紅外線光源,進而提供消毒殺菌功能、照 明功能或促進生物生長的效果。 由於該些發光二極體晶片所產生的光源可能為接近紫 外光專波段之具有南能量之光源’在此·種情況下,則可以 將發出高能量之發光二極體晶片附著於第一圖(c)中的該 12 M381999 * I * » 第晶片承載基材102上,接著再以一阻絕構造150將該 第二晶片承餘材112與該第—晶片承載基材 102區隔 開,用以阻絕該第一發光二極體晶片1〇1所發出之該第一 波段光源對該第二晶片承載基材U2造成劣化現象,該阻 、、邑構ie 150係可由玻璃或抗紫外光(uitravi〇iet,uv)石夕 膠等可抗UV之材質來完成。需注意的是,該阻絕構造150 的採用並非絕對必要’而需視發光二極體晶片所發出之波 *' 段光源而決定。 • 就細部構造而言’本創作將第一圖(c)(d)之該等發光二 極體晶片以次黏著基台(Submount)技術分別電連接於陶 竟材質或石夕材質等可導熱但為非導電體材質之該等晶片承 載基材上。由於發光二極體晶片之面積較小、發光效率較 尚,且在晶片承載基材上之相對距離大幅降低,而能改善 習知技術使用白熾燈泡與紫外線燈管等空間利用的問題。 除了本體構造120與連接於其上之承載基材外,本創 作之生物成長辅助燈具更可以提供一控制器14〇以提供設 • 定的功能。該控制器140可以設定使用波段數、設定連續 , 或間續波段輸出,設定使用個別波段之頻率與時間,以及 預約没疋功能等,而完成具多合一與自動切換光色功能的 生物成長辅助燈具1、2。如此一來,本實施例之生物成長 辅助燈具1、2可藉由控制器140調整個別種類之發光二極 體晶片所發出各該波段光源之預設期間彼此之間的關係, 例如令其個別之預設期間完全重疊或彼此間具有前後、交 替或部份重複等關係而產生混光光色之效果,如此可讓本 案所設計的生物成長輔助燈具1、2能有更多功能組合之變 13 M381999 化 就動物培育的應用而 法,令圖中之t n 丰茶了抓用第-圖(C)之作 極體晶片101發出-紫外光波段 r之㈣,第一發光二極體晶月102發出一可見光波 ▲又”、’ It由魅波段光源同時提供料㈣與照明功 用路:改善傳統人工光源的缺失,以提供使用年限 較長、發光效耗、储耗功率朗時提 物成長輔祕具。 ^ ^ g將本創作_於_生長的應用時,可進—步視種植 核境等需要’提供防水與防漏電等輔助設計,而内部作法 則可能因為不使用阻絕構造,而利用第—圖(d)中將複數個 發光二極體晶片附著於同—個晶片承載基材之作法。即, 將可以用來輔助植物生長的各波段絲,複數個發光 二極體晶片來提供,例如:將影響#綠素之載體進行光合 作用的64〇nm與66Gnm波長之光源,分別由—第—發光二 極體晶片與-第二發光二極體晶片來提供;利用—第三發 光二極體“來發出_波長為45Gnm的光源,藉以影響向 光載體的吸收情形,以及打開葉片之氣孔以利吸收二^化 碳進行後續之光合侧;接著相—第四發光二極體晶片 來發出光敏素載體所需要的735nm之波段光源等。 前述說明雖然將第一圖⑷與第一圖(d)作為動物與植 物成長方面的應用,但其並非用來限制本案生物成長輔助 燈具的用途。易言之,本創作之生物成長辅助燈具内部的 個別發光二極體晶片所發出波段之選用與晶片承载基材之 個數決定等,並無絕對的作法,而是以使用的目的來決定, 14 «〇δΙ999 « 並配合控制器的使用,調整個別發光二極體晶片之發光時 ]比發光強度、發光時間與順序等,以提供更彈性且更 為經濟的作法。 “採用本創作所設計的生物成長辅助燈具因為使用了發 光二極體晶片及控制器,而能產生以下的效益:首先,改 善習用技術中必須針對不同需求而裝設不同功能的燈具之 乍今,其—人使用發光一極體晶片的作法可以較習知技術 更為省電,而能延長生物成長輔助燈具的使用年限;再者, 由於般的發光一極體使用直流電源驅動,因此具有光 里、頻率與工作比可調整的特性,可避免在習用技術中因 為採用傳統發光燈泡與紫外線燈管而必須將發光功能設定 成為一固定值以進行發光的情形;最後,本案作法提供之 多種光源選擇性與自動化的光色切換流程,更大幅提昇使 用者在操作此生物成長輔助燈具的便利性。 雖然本創作已以較佳實施例揭露如上,然其並非用以 限疋本創作,本創作得由熟習此技藝之人士任施匠思而為 諸般修飾,然皆不脫如附申請專利範圍所欲保護者。 » 【圖式簡單說明】 本案得藉由下列圖式及說明,俾得更深入之了解: 第一圖(a)(b)’其為本案所發展出來關於生物成長辅助燈具 之較佳實施例之外觀示意圖。 第一圖(c)(d)’其為本案所發展出來關於生物成長輔助燈具 15 M381999 之功能方塊圖。 【主要元件符號說明】 、220燈具本體 控制器 阻絕構造 本案圖式中所包含之各元件列示如下: 1、2生物成長輔助燈具 120 10卜201第一發光二極體晶片 140 102第一晶片承載基材 150 111、211第二發光二極體晶片 112第二晶片承載基材 130電源供應裝置 202晶片承載基材 16In addition to the violent structure of the team, the biological growth assisting lamp j 1 of the first figure (c) may further include a controller 140 electrically connected to the lamp body 12 〇, and 4 sends a control signal to make the first The LED chip 1 发出1 emits the _wavelength source during a predetermined period of time, and causes the second illuminator 2 to emit the second band source during the second predetermined period. And the biological growth auxiliary lamp used in the first figure (d) comprises: a first light-emitting diode chip 201, which can emit a first-wavelength light source and the first-band light source has a -first biological growth effect ; the second hair; the factory body wafer 2G2 'which can emit - the second band light source, and the:: segment light source has - the second biological growth effect; - the wafer carrier substrate, ^ j connected to the first light a diode chip and the second LED chip; the lamp body 120' is connected to the bottom of the wafer carrier substrate 2 () 2 and Connected to the Hejia County, 13G, (10) New Zealand power supply, the provided power to drive the first-emitting diode chip 2〇11 M381999 and the second LED wafer 211 to emit light; and a controller 14, the controller is electrically connected to the wafer carrier substrate 202 through the lamp body 12〇, and sends a control signal to cause the first LED chip 201 to be emitted within a first predetermined period. The first band light source and the second LED chip 211 emit the second band light source for a second predetermined period. It can be seen from the first figure (c)(d) that the number of wafer carrier substrates attached to the body structure 12A is not the same. The corresponding relationship between the LED substrate of the first figure (c) and the wafer carrier substrate is a many-to-many mode, it should be noted that although in this example, the number of the LED substrate and the wafer carrier substrate are both Second, but in practical applications, the numbers do not have to be equal; in the first figure (d), there is a many-to-one relationship between the light-emitting one-pole wafer and the wafer-bearing substrate, which can be issued. Each of the LED chips of the individual bands is attached to the same wafer carrier substrate. According to the biological growth auxiliary lamp designed by the present invention, the light source emitted by the LED chips can be a violet light source with a wavelength of 36〇 to 445 nm, an ultraviolet light source with a wavelength less than 360 nm, and a wavelength of 445. a blue light source to 500 nm, a green light source with a wavelength of 500 to 575 nm, a yellow light source with a wavelength of 575 to 585 nm, an orange light source with a wavelength of 585 to 62 〇 nm, a red light source with a wavelength of 620 to 740 nm, or a A far-infrared source with a wavelength of 15 〇〇 to 8000 imi provides disinfection, illumination or biological growth. Since the light source generated by the light-emitting diode chips may be a light source having a south energy near the ultraviolet light band, in this case, the light-emitting diode chip emitting high energy may be attached to the first image. The 12 M381999 * I * in the (c) wafer carrier substrate 102, and then the second wafer carrier 112 is separated from the first wafer carrier substrate 102 by a resistive structure 150. The first wavelength band light source emitted by the first light-emitting diode chip 101 is caused to cause deterioration of the second wafer carrier substrate U2, and the resistor, the device 150 can be made of glass or anti-ultraviolet light ( Uitravi〇iet, uv) Shishi glue can be done with UV resistant materials. It should be noted that the use of the resistive structure 150 is not absolutely necessary, and is determined by the wavelength of the wave emitted by the LED chip. • For the detailed structure, the light-emitting diode chips of the first figure (c)(d) are electrically connected to the ceramic material or the stone material by the sub-mounting technology. However, the wafers are non-conducting materials on the substrate. Since the area of the light-emitting diode wafer is small, the luminous efficiency is relatively high, and the relative distance on the wafer-bearing substrate is greatly reduced, the problem of space utilization such as incandescent bulbs and ultraviolet lamps can be improved by the prior art. In addition to the body structure 120 and the carrier substrate attached thereto, the created bio-growth auxiliary luminaire can further provide a controller 14 to provide a set function. The controller 140 can set the number of used bands, set continuous, or continuous band output, set the frequency and time of using individual bands, and reserve the function, and complete the biological growth with all-in-one and automatic color switching functions. Auxiliary lamps 1, 2. In this way, the biological growth auxiliary lamps 1 and 2 of the embodiment can adjust the relationship between the preset periods of the light sources of the respective bands emitted by the LEDs of the respective types by the controller 140, for example, individually. The preset periods are completely overlapped or have the effect of mixing light, light, and light, etc., so that the biological growth auxiliary lamps 1 and 2 designed in this case can have more functional combinations. 13 M381999 In the application of animal breeding, the tn feng tea in the figure is used to capture the first wafer (C) of the polar body wafer 101 - ultraviolet band r (four), the first light-emitting diode crystal moon 102 emits a visible light wave ▲ ", ' It is provided by the charm band light source at the same time (4) and lighting function path: to improve the lack of traditional artificial light source, to provide longer life, luminous efficiency, storage power consumption Auxiliary secrets. ^ ^ g will be used in the application of _ growth, you can go - step to plant the nuclear environment, etc. need to provide waterproof and anti-leakage and other auxiliary design, while the internal method may not use the blocking structure, The method of attaching a plurality of light-emitting diode wafers to the same wafer-bearing substrate in the first-figure (d), that is, a plurality of light-emitting diode chips which can be used to assist plant growth, and a plurality of light-emitting diode chips Providing, for example, a source of 64 〇 nm and 66 G nm wavelengths for photosynthesis affecting the carrier of chlorophyll, respectively, provided by a -first light emitting diode chip and a second light emitting diode chip; The light-emitting diode "sends a light source with a wavelength of 45Gnm, thereby affecting the absorption of the light carrier, and opening the pores of the blade to absorb the carbonized carbon for the subsequent photosynthetic side; then the phase-fourth light-emitting diode The wafer emits a 735 nm band light source or the like required for the photoreceptor carrier. In the foregoing description, the first figure (4) and the first figure (d) are used as animal and plant growth applications, but they are not intended to limit the use of the biological growth auxiliary lamp of the present invention. In other words, there is no absolute way to determine the number of bands emitted by the individual light-emitting diode chips and the number of wafer-bearing substrates in the biological growth auxiliary lamp of the present invention, but to determine the purpose of use. 14 «〇δΙ999 « In conjunction with the use of controllers, adjusting the illumination of individual LED chips] than the luminous intensity, luminescence time and sequence, etc., to provide a more flexible and more economical approach. “The bio-growth-assisted luminaires designed with this design can produce the following benefits because of the use of LEDs and controllers: First, improve the luminaires that have to be installed with different functions for different needs in the conventional technology. The method of using a light-emitting one-pole wafer can save more power than the conventional technology, and can extend the service life of the biological growth auxiliary lamp; further, since the general-purpose light-emitting body is driven by a DC power source, The adjustable characteristics of light, frequency and work ratio can avoid the situation that the conventional light-emitting bulb and the ultraviolet light tube must be used to set the light-emitting function to a fixed value for illumination in the conventional technology. Finally, the various light sources provided by the present method are provided. The selective and automated light color switching process greatly enhances the user's convenience in operating the biological growth auxiliary luminaire. Although the present invention has been disclosed above in the preferred embodiment, it is not intended to limit the creation, the creation It’s up to people who are familiar with this skill to make all kinds of modifications, but they’re all attached. The scope of the protection is intended to be protected. » [Simple description of the schema] This case can be further understood by the following diagrams and descriptions: Figure 1 (a) (b) 'The development of the case on the biological growth A schematic view of the appearance of the preferred embodiment of the auxiliary luminaire. The first figure (c)(d)' is a functional block diagram of the biological growth auxiliary luminaire 15 M381999 developed in the present case. [Main component symbol description], 220 luminaire body control The components of the present invention are listed as follows: 1. 2 biological growth auxiliary lamps 120 10 201 first light emitting diode wafers 140 102 first wafer bearing substrate 150 111, 211 second light emitting two Polar body wafer 112 second wafer carrier substrate 130 power supply device 202 wafer carrier substrate 16