201227799 六、發明說明: 【發明所屬之技術領域】 本發明係有關一種紫外線(Ultraviolet,UV)熟化燈,尤其是 UV 冷陰極螢光燈(ColdCathodeFlorescentLamp,CCFL),利用 UV激發的UV磷光體以轉換光線的uv波長,使塗佈在人手指 或腳趾之指甲以及動物寵物指曱上的特定指甲膠固化。 【先前技術】 指曱藝術的專業技術領域已經被廣泛的引進全世界,並且已 ® 經隨著照射及指甲膠組合物的發展及改善而成長,以調合不同的 新技術。一般,指曱藝術是指針對手指或腳趾之指甲的化妝或裝 飾。傳統的指甲藝術可使用在室溫下聚合的樹脂或膠態人造組合 物以形成人造指甲。能在相當短的時間内形成或聚合成人造指甲 的更先進指甲膠,可使用UV輻射以加強這種熟化或聚合處理。 已經有白熾UV燈可適合不同產業及商業應用中的不同燈 具。傳統的白熾UV燈大部分包括塗佈層或波長濾光層/膜,以達 成所需目的之UV照射,包括發射不同光譜範圍的uva、UVB及 ® UVC。然而,在指曱藝術領域中使用這種υγ白熾燈,會有至少 二項疑慮是與在該領域使用這種UV白熾燈有關。其中之一是,在 這些IJV白熾燈或燈泡下會讓人的皮膚長時間曝露至^光線而導 致皮膚癌的危險性,因為參照對皮膚的保護,w白熾燈通常發射 三種UV光’這些是UVA(波長400nm至315nm)、UVB(波長315nm 至280nm) ’以及UVC(波長280 nm至100 nm)。很重要的是,已 知在這三種光線中’280nm至l〇〇nm的UVC波長,或以能量來看, 是三種中最具傷害性且具最高能量。另一主要缺點是UV白熾燈的 使用壽限相當短,而需要經常保養。一般的UV白熾燈具有3000 201227799 小時(或大約4個月)的使用壽限,且如果採用這種^燈的燈具或 機器係包括精細元件及/或電氣插頭及/或電路時,則在必須進行更 換時並非最理想。 最近在綱上触術碰也鮮麟(CQmpaet Fbrescent Lamp,CFL)及發光二極體(LED)照明在不同商業及工業應用中變 為可能。已知CFL燈在-般照明領域中具有相當能量,能產生大 角度的足触明:細’目前其崎獅讀管紐包的螺旋形 狀及尺寸大小’如果在操作時有任何w激發化合物被引入其内以 φ 響應被激發取包含於其内的汞電梁而藉以產生或達成具足夠流明 輸出的所需均勻照明時,會很容易發生問題。易言之’已發現到 CFL的目前或標準形狀及結構是無法只於其内注入w激發化合 物以響朗或-起與包含於其内之絲子蒸氣或電漿而產生足夠 或所需的均勻uv輻射。此外,由半導體材料構成的LED也可用 以產生UV輻射。LED發射光線的波長是p-n接面所使用材料之 能帶隙的函數。已知LED在將電力轉換成光線中具有很高的效 率;儘管如此,目前能發射波長在uv光譜内的wLED或LED φ 還是要被開發成具有在可見光波長中與一般LED相當的效率。事 貫上已發現,由於現有UV LED的限制,發射在uv光譜範圍内 的UV輻射還遠遠未被考慮成在可見光光譜内具有與其他已知 LED相同的效率》此外,uv led就像大部分現有led —樣係受 限於其點光源的發光角度’而需要多個模組用於照明區域,與相 同照明輸出及給定面積的白熾或CFL照明比較,會增加不需要的 整體材料及安置成本。由現有UVLED產生足夠或所需^輻射 的所需較大功率,會增加UV LED太多的操作溫度或接面溫度, 對於現有UV輻射及最現代的應用會造成不宜或不實際的解決方 201227799 乂而且對於指甲藝術領域,已知熟化時間及熟化後指甲膠的外 子;人^3才曰甲疋相當重要。亦即,為了如上所述在較短的熟化 。寺門内70成#化處理’所以指甲膠必須響應^^輕射以使得指甲膠 可在規疋铜崎合或固化。商品化的指甲膠可為高黏滞性的液 體材料’包含能在正常室溫下於某-時間後聚合或固化的以甲基 丙稀S<L為主之單體。而麟統崎脂型指f膠比較起來 ,這些膠 也的人造指Ψ會造成較淡的氣味或皮膚舰,且也會具有更佳的 可操性。然:而’膠態指甲的熟化人造指甲仍會變黃,並因而無法 滿足客戶的審美需求。另—因素S,典型指曱膠的熟化或固化一 般需要很長的處辦間’且可特或不轉光聚合啟關。已知, 讀光聚合縣綱於某·甲毅重要齡,㈣魏W光線 而可藉UV輪射以有效的熟化。 由於上述及針對指曱藝術領域,因此最佳的方式是要同時考 慮UV光源以及要藉UV光源之w細以進行熟化之指甲膠的形 式,以使得至少UV骑燈具有高能量鱗,uy光_人體的不 利衫響會降低’尤其是8Gnm至iGGnm之間的UVC波長,而且可 刻意獲得包括這種UV可熟化系統的人造指曱之指曱膠外觀的結 果。亦即’需要-種能克服包括上述所提白麟、CFL燈及LED 燈之已知技術缺點的UV燈,而能產生安全、可靠、有效率的uv 輻射’尤其是在指甲藝術的領域以及針對在這種W轄射下可熟化 的指曱膠。此外’需要提供一種UY燈,以方便一次安全及有效的 創造具南可#度的指甲藝術及多個手指或腳趾之指甲保護。 【發明内容】 為克服上述的缺點’本發明的特點提供一種能用W輕射熟 化如壓克力膠之UV硬化或可聚合膠的uyccfl燈泡,係可響應 201227799 uv輻射而將液體安全且均一性的聚合或固化成固態。而且較佳的 是’本發明UV CCFL燈所提供的UV輻射係足夠熟化某種指甲 膠,以所需的照明效率(lm/W)而言是很有效且有效率,比如與已知 的白熾或LED燈作比較。該輻射較佳的具有36〇度的發光角度, 以使彳于本發明UV CCFL所提供的UV輕射本質上在不同方向上是 均勻的。 本發明的另一特點係提供一種uv CCFL燈,用以藉w輻射 而熟化UV可熟化指甲膠,能方便熟化指曱膠以達成最佳結果。較 佳的,UVCCFL燈可較佳的設置而與特定形式指曱膠協同使用。 更佳的是,為了從本發明UV CCFL燈的w輻射達成最佳熟化結 果,UV可熟化指甲膠可具有包括在分子中具至少一官能基可聚合 未飽合雙鍵的第一成分以及光聚合啟始劑的第二成份。 本發明的再一特點是提供一種UY CCFL燈,能產生較佳為 UVA光譜範圍内的安全]^輻射,比如波長牝此以至釘如⑺之 間。杈佳的是,本發明UVCCFL·燈利用包含銪摻雜之組合物的 UV激發磷光體,以製造或產生這種較安全的㈣八輕射尤其是 對於在指曱領域熟化的指甲膠,特別是供人使用。 本發明的又一特點是提供一種UVCCFL燈,利用上述的UV 激發破光魅财獅設置以提縣質上均自的傭輸出。較佳 的疋’燈官’包括其尺寸大小及職’是很有繼設置成方便㈣ 光線此照射到安置在燈管上之魏體或與之反應,可藉以獲得均 勻的UV輕射。 在本發明的貫施例中,提供一種藉yy轄射以熟化W可熟 化指甲膠的UV CCTL燈。而且較佳蚊,本㈣的w CCFL燈 可提供肋熟化特定指甲_ uv _,比如具枕含在分子中具 有至少-官可聚合未飽合雙敎第—齡以歧合啟始劑 7 201227799 之第二成分之組合物的指曱ι本發明的w CCFL燈可包括較佳 為螺旋形狀辭透管、賴至燈管或燈料㈣放電電極、 包含激發離子蒸氣電紅密封在半翻密贿㈣用以產生wc 波長(比如28〇nm至1〇〇11111)之第一發射光譜的放電媒介以及包 含用以提供電力以激發«齡之魏供應器並連結至燈管及放 電電極的燈座。為了由放電齡所產生之該wc魏光譜提供 UVA輻射’本發明力^^肌燈可進一步包括安置在該半透明 燈管内並翻触電齡_紐,錢得料光線可照射 到其内_紐而產摘需的UV A鋪輸ώ。依據本發明的實施 例,該磷光體可包括銪摻雜氧化硼锶(B4Sr〇7:Eu+)的組合物,用以 響應放電媒介的該第一發射光譜而產生UV輻射。 依據本發明的另一實施例,提供一種用以熟化^可熟化指 甲膠的UV CCFL燈。而且較佳的是,本發明的yy CCFL燈可產 生用以熟化特定指曱膠的UV輻射,比如具有包含在分子中具至少 一 g能基可聚合未飽合雙鍵之第一成分以及光聚合啟始劑之第二 成分之組合物的指甲膠。此外,指曱膠組合物之第二成分的量可 為0.05至4.00份重量,係相對於100份重量的指甲膠組合物之第 一成分。本發明的UV CCFL燈可包括較佳為螺旋形狀的半透明燈 管、連結至燈管或燈泡殼的放電電極、包含激發離子蒸氣電漿且 密封在半透明密封燈管内用以產生UVC波長之第一發射光譜的放 電媒介,以及包含用以提供電力以激發放電媒介之電源供應器並 連結至燈管及放電電極的燈座。為了由放電媒介所產生之該uvc 發射光譜提供UVA輪射(比如波長4〇〇nm至350nm),本發明的 UVCCFL燈可進一步包括安置在該半透明燈管内並接觸該放電媒 介的磷光體,以使得UVC紫外光線可照射到其内的磷光體以產生 所需的UVA輻射輸出。依據本發明的實施例,該磷光體可包括銪 201227799 摻雜氧化銘氟蝴(SrFB2〇35:Eu2+)的組合物,用以響應放電媒介的第 一發射光譜而產生UV輻射。 因為本發明UV CCFL燈所提供之uv轄射係較佳的為均勾且 具有足夠功率或照明效率,所以依據本發明,包圍住上述示範性 實施例UV紐魏體以產生非uvC細且雛的為WA輕射 的燈官,可很有利的設置成具有螺旋管形狀,該螺旋管形狀包含 本貝上具有所選取之直徑的圓形截面,並製作成方便用被激發至 電躁蒸氣形紅放電媒介-開始所產生的料線㈣以照射碟光 體功率,使得可獲得本發明UV CCFL燈之UVA光譜或波長的均 勻輕射輸出。 此外,為很有利的提供均勻UV輻射輸出,較佳的是在MA 光譜範圍内,所以上述備製以安置在本發明w CCFL燈之燈管内 的UV激發磷光體可為粉末形式’使得用放電媒介之電漿的離子激 發蒸氣所產生的紫外光射線以照射磷光體會增加並強化。在實施 例中,填光體可包括具有平均粒徑為12μηι至間之銪摻雜氧 化硼鋰(B4Sr〇7:Eu+)的組合物。在另一實施例中,磷光體可包括具 有平均粒徑為5.5μηι至11.5μηι間之銪掺雜氧化锶氟硼 (SrFB2035:Eu2+)的組合物。 上述摘要係引用本發明的較佳實施例並係為了解釋性目的。 本發明的實施例可以不同方式實現,並且也應在其範圍内當成本 發明的一部分。詳細的本發明示範性實施例將進一步在以下内容 中說明。 【實施方式】 第1圖及第2圖顯示本發明實施例紫外線冷陰極螢光燈(uv CCFL燈)的示範性實施例’ υγ ccfl燈100係設置以熟化UV可 201227799 熟化或可聚合膠,尤其是UVCCFL燈100可很有利的設置而在指 甲藝術領域或應用中,利用UV輻射,較佳的是如^八(4()〇11111至 315nm)或UVB(315nm至280nm)的非UVC光譜範圍,以熟化指曱 膠,而確保更安全及更健康的使用。在示範性實例中,本發明的 UVCCFL燈100可包括燈管11〇,放電媒介12〇具有被放電電極 140所提供之高電壓電力而激發至電漿狀態的離子,放電電極14〇 係連結並配置在燈管110之二端部U2及114上。UV激發磷光體 130也可安置於本發明UVCCFL燈100的燈管11〇内,並分佈以 接觸該放電媒介120,提供較佳的為非uyc光譜範圍内的^輻 射。本發明的UV CCFL燈100也可進一步包括燈座mo ,係連結 至戎燈管110並配置以接收放電電極112及114。為提供或供應 上述尚電壓電力以激發推閉在燈管11〇内的放電媒介12〇,燈座 150也可包括電源供應器(圖中未顯示),係調適於插座並電氣連接 至外部電源’較佳的是並聯(on-grid)電源。 與傳統的白熾燈、節能燈CFL及LED燈比較起來,以使用 哥限及發光效率來看,CCFL燈的優點是也可應用至本發明的^ CCFL燈1〇〇。某些明顯的事實是眾所周知且將詳細說明,包括如 CCFL燈疋比白熾燈及CFL燈具有更長的使用壽限,比燈具 有較低汞含量’並且能比LED燈產生更大的發光角度。雖然如此, 本發明的UV CCFL燈100也分享到CCFL燈的優點,發射可見光 譜範圍内的光線。藉使用放電媒介12〇,包含分佈並密封於半透明 密封燈管110内的激發離子蒸氣電漿,本發明的UVCCFL燈〗〇〇 也可在操作期間產生UVC波長的第-發射光譜,比如280邮至 100nm之間。在本發明的示範性實例中,離子蒸氣電漿可為藉高 電壓電源供應器而被激發至電漿狀態的汞Hg離子蒸氣,較佳的是 一千伏特或以上之範圍。激發離子蒸氣電漿所產生的w輻射可屬 201227799 於280nm至100nm的發射光譜,而且這種啟始或最初的υγ輻射 可進一步用安置在燈管110内且接觸離子蒸氣電漿的磷光體13〇 照射或轉換,以產生第一發射光譜的啟始UV輻射,比如UVC光 譜範圍内。安置在本發明燈管110内的UV激發磷光體13〇的細節 將在後續内容中提供。在本發明的另一實施例中,離子化汞電漿 之放電媒介的激發離子蒸氣電漿所產生的該第一發射光譜可屬於 260nm至240nm間範圍内的光譜。 針對指曱領域中本發明UV CCFL燈100的示範性應用,UV CCFL燈100可較佳的配置並設置成用以熟化^可熟化指甲膠。 在實施例中,用本發明UV CCFL燈1〇〇的UV輻射以熟化的指曱 膠可具有包括在分子中具至少一官能基可聚合未飽合雙鍵之第一 成分以及光聚合啟始劑之第二成份的組合物,以及其中第二成分 的量為0.05至4.00份重量,係相對於1〇〇份重量的第一成分。這 種曝光至uv輻射而可聚合的指甲膠之實例可參考由Tanaka等人 所申請的日本專利公開No. 2008-147720 “Artificial Nail201227799 VI. Description of the Invention: [Technical Field] The present invention relates to an ultraviolet (UV) curing lamp, in particular, a Cold Cathode Fluorescent Lamp (CCFL), which utilizes UV-excited UV phosphor to convert The uv wavelength of the light cures the specific nail glue applied to the nails of the human fingers or toes and the finger nails of the animal. [Prior Art] The technical field of the art of fingering has been widely introduced throughout the world, and has grown with the development and improvement of irradiation and nail glue compositions to blend different new technologies. In general, fingering art is a makeup or decoration that points to the nails of a finger or toe. Conventional nail art can use a resin or a colloidal artificial composition polymerized at room temperature to form an artificial nail. More advanced nail glue that can be formed or polymerized into artificial nails in a relatively short period of time can be enhanced by UV radiation to enhance such ripening or polymerization. Incandescent UV lamps are already available for different lamps in different industrial and commercial applications. Conventional incandescent UV lamps mostly include a coating layer or a wavelength filter/film to achieve the desired UV illumination, including the emission of different spectral ranges of uva, UVB and ® UVC. However, the use of such υγ incandescent lamps in the art of fingerprinting has at least two concerns related to the use of such UV incandescent lamps in the field. One of them is that under these IJV incandescent lamps or bulbs, people's skin will be exposed to light for a long time and cause skin cancer. Because of the protection of the skin, w incandescent lamps usually emit three kinds of UV light. UVA (wavelength 400 nm to 315 nm), UVB (wavelength 315 nm to 280 nm) ', and UVC (wavelength 280 nm to 100 nm). It is important to know that the UVC wavelengths of '280 nm to l〇〇nm in these three types of light, or energy, are the most damaging and highest energy of the three. Another major drawback is that the life of UV incandescent lamps is quite short and requires frequent maintenance. A typical UV incandescent lamp has a service life of 3000 201227799 hours (or approximately 4 months), and if the lamp or machine using such a lamp includes fine components and/or electrical plugs and/or circuits, then It is not optimal when making replacements. Recently, CQmpaet Fbrescent Lamp (CFL) and LED lighting have become possible in different commercial and industrial applications. It is known that CFL lamps have considerable energy in the field of general illumination, and can produce a large angle of foot touch: fine 'current spiral shape and size of its singular lion tube' if any w-excited compounds are manipulated during operation Problems can easily occur when introduced into a mercury beam that is excited by the φ response to generate or achieve the desired uniform illumination with sufficient lumen output. It has been found that the current or standard shape and structure of the CFL cannot be sufficient or required to inject the w-exciting compound into the sound or the vapor or plasma contained therein. Uniform uv radiation. In addition, LEDs composed of semiconductor materials can also be used to generate UV radiation. The wavelength at which the LED emits light is a function of the bandgap of the material used for the p-n junction. LEDs are known to be highly efficient in converting electrical power into light; nevertheless, wLEDs or LEDs that are currently capable of emitting wavelengths in the uv spectrum are yet to be developed to have efficiencies comparable to those of typical LEDs in the visible wavelength. It has been found that due to the limitations of existing UV LEDs, UV radiation emitted in the UV spectrum is far from being considered to have the same efficiency as other known LEDs in the visible spectrum. In addition, uv led is like a large Some existing LED-like systems are limited by the illumination angle of their point source' and require multiple modules for the illumination area. Compared with the same illumination output and a given area of incandescent or CFL illumination, it will increase the unnecessary overall material and Placement costs. The large power required to generate sufficient or required radiation from existing UVLEDs will increase the operating temperature or junction temperature of the UV LED, which may cause unsuitable or impractical solutions for existing UV radiation and the most modern applications 201227799乂 And for the nail art field, it is known that the ripening time and the external appearance of the nail glue after ripening; That is, in order to be short-lived as described above. 70% of the temple door is treated. So the nail glue must respond to the ^^ light shot so that the nail glue can be combined or cured. The commercially available nail lacquer may be a highly viscous liquid material' comprising a monomer comprising methyl propyl S<L which can be polymerized or cured after a certain period of time at normal room temperature. Compared with the N-type resin, the artificial finger of these glues will also result in a lighter smell or skin ship, and will also have better maneuverability. However: the mature nails of the 'colloidal nails will still turn yellow, and thus can not meet the aesthetic needs of customers. Another factor, S, typically means that the curing or curing of the silicone usually requires a long period of operation and can be switched on or off. It is known that the reading photopolymerization county is in the important age of a certain Jiayi, and (4) Wei W light can be effectively matured by UV radiation. Because of the above and in the art field of finger pointing, the best way is to consider both the UV light source and the form of nail glue to be matured by the UV light source so that at least the UV riding light has a high energy scale, uy light The unfavorable shirting of the human body reduces the UVC wavelength between '8Gnm and iGGnm, especially the result of the fingerprint of the artificial finger which includes such a UV-curable system. That is, 'needs to overcome the known technical disadvantages of the above-mentioned white lining, CFL lamps and LED lamps, and to produce safe, reliable and efficient uv radiation', especially in the field of nail art and For the fingertips that can be cured under this kind of jurisdiction. In addition, it is necessary to provide a UY lamp to facilitate the safe and effective creation of a nail art with a degree of nails and multiple finger or toe nail protection. SUMMARY OF THE INVENTION In order to overcome the above-mentioned disadvantages, the present invention provides a uyccfl bulb capable of curing by light, such as UV-curing or polymerizable glue of acrylic glue, which is safe and uniform in response to 201227799 uv radiation. Sexually polymerize or solidify into a solid state. Moreover, it is preferred that the UV radiation provided by the UV CCFL lamp of the present invention is sufficient to mature a certain type of nail glue, which is effective and efficient in terms of the required illumination efficiency (lm/W), such as with known incandescent Or LED lights for comparison. The radiation preferably has an illumination angle of 36 degrees of turbulence so that the UV light radiation provided by the UV CCFL of the present invention is substantially uniform in different directions. Another feature of the present invention is to provide a uv CCFL lamp for curing UV-curable nail varnish by w-radiation, which facilitates ripening of the finger gutta gum to achieve the best results. Preferably, the UVCCFL lamp can be preferably placed in conjunction with a particular form of silicone. More preferably, in order to achieve optimal ripening results from the w-radiation of the UV CCFL lamp of the present invention, the UV curable nail gel may have a first component comprising at least one functional group polymerizable unsaturated double bond in the molecule and light. The second component of the polymerization initiator. It is yet another feature of the present invention to provide a UY CCFL lamp that produces a preferred range of radiation in the UVA spectral range, such as wavelengths such as between the nails and (7). Preferably, the UVCCFL lamp of the present invention utilizes a UV-excited phosphor comprising a cerium-doped composition to produce or produce such a safer (four) eight light shots, especially for nail varnishes that are matured in the field of finger licking, particularly It is for people to use. Another feature of the present invention is to provide a UVCCFL lamp, which utilizes the above-mentioned UV-excited light-breaking charm lion to set the servant output of the county. The preferred 疋 'lights' include its size and position, which is set to be convenient (4). This light is irradiated onto or reacted with the Wei body placed on the tube to obtain a uniform UV light shot. In one embodiment of the invention, a UV CCTL lamp is provided which is conditioned by yy to cure W-curable nail glue. Moreover, the preferred mosquito, the (four) w CCFL lamp can provide rib curing of a specific nail _ uv _, such as a pillow containing in the molecule with at least - officially polymerizable unsaturated bismuth - age to disambiguate starter 7 201227799 The CCFL lamp of the present invention may include a spiral shape reciprocating tube, a lamp tube or a lamp material (four) discharge electrode, and an excited ion vapor red seal in a semi-folded atmosphere. Bribe (4) a discharge medium for generating a first emission spectrum of a wc wavelength (for example, 28 〇 nm to 1 〇〇 11111) and a lamp for supplying electric power to excite a wei wei supply and connected to a lamp and a discharge electrode seat. In order to provide UVA radiation from the wc Wei spectrum generated by the age of discharge, the present invention may further comprise a light bulb disposed in the translucent tube and being touched by the electric age. _ New Zealand's production of UV A shop. In accordance with an embodiment of the present invention, the phosphor may comprise a composition of cerium-doped lanthanum oxide lanthanum (B4Sr 〇 7: Eu +) for generating UV radiation in response to the first emission spectrum of the discharge medium. In accordance with another embodiment of the present invention, a UV CCFL lamp for curing a gelatinizable fingernail is provided. Further preferably, the yy CCFL lamp of the present invention can produce UV radiation for curing a specific fingerprint, such as having a first component comprising at least one g-polymerizable unsaturated double bond in the molecule and light. A nail glue that polymerizes a composition of the second component of the initiator. Further, the amount of the second component of the silicone composition may be from 0.05 to 4.00 parts by weight relative to 100 parts by weight of the first component of the nail glue composition. The UV CCFL lamp of the present invention may comprise a translucent tube preferably in the shape of a spiral, a discharge electrode coupled to the tube or bulb, containing an excited ion vapor plasma and sealed in a translucent sealed tube for generating UVC wavelengths. a discharge medium of the first emission spectrum, and a lamp holder including a power supply for supplying electric power to excite the discharge medium and coupled to the lamp tube and the discharge electrode. In order to provide a UVA emission (such as a wavelength of 4 〇〇 nm to 350 nm) by the uvc emission spectrum generated by the discharge medium, the UVCCFL lamp of the present invention may further comprise a phosphor disposed within the translucent tube and contacting the discharge medium. In order to allow the UVC ultraviolet light to illuminate the phosphor therein to produce the desired UVA radiation output. In accordance with an embodiment of the present invention, the phosphor may comprise a composition of 铕201227799 doped oxidized fluorinated butterfly (SrFB2〇35:Eu2+) for generating UV radiation in response to a first emission spectrum of the discharge medium. Since the uv ray-providing system provided by the UV CCFL lamp of the present invention is preferably uniform and has sufficient power or illumination efficiency, according to the present invention, the above-mentioned exemplary embodiment of the UV neutrophil is surrounded to produce a non-uvC fine and young The lighter of the WA light can be advantageously arranged to have a spiral tube shape, the spiral tube shape comprising a circular cross section having a selected diameter on the shell, and being made to be easily excited to evaporate vapor red Discharge Medium - Start the resulting feed line (4) to illuminate the disc power so that a uniform light output of the UVA spectrum or wavelength of the UV CCFL lamp of the present invention can be obtained. In addition, it is advantageous to provide a uniform UV radiation output, preferably in the MA spectral range, so that the UV-excited phosphor prepared in the lamp tube of the w CCFL lamp of the present invention can be in powder form. The ions of the plasma of the discharge medium excite the ultraviolet rays generated by the vapor to increase and strengthen the irradiated phosphor. In an embodiment, the filler may comprise a composition having a cerium-doped lithium borohydride (B4Sr〇7:Eu+) having an average particle size of from 12 μm to between. In another embodiment, the phosphor may comprise a composition having cerium-doped cerium oxide fluoroboron (SrFB2035: Eu 2+) having an average particle size of between 5.5 μηι and 11.5 μηι. The above summary is a preferred embodiment of the invention and is for illustrative purposes. Embodiments of the invention may be implemented in different ways and should also be within the scope of the invention. Detailed exemplary embodiments of the present invention will be further described below. [Embodiment] Figs. 1 and 2 show an exemplary embodiment of an ultraviolet cold cathode fluorescent lamp (uv CCFL lamp) according to an embodiment of the present invention. The υγ ccfl lamp 100 is provided to cure UV can be 201227799 aging or polymerizable glue, In particular, the UVCCFL lamp 100 can be advantageously arranged in the field of nail art or in the application of UV radiation, preferably non-UVC spectra such as ^8 (4()〇11111 to 315nm) or UVB (315nm to 280nm). Scope to ripen the gelatin to ensure safer and healthier use. In an exemplary embodiment, the UVCCFL lamp 100 of the present invention may include a lamp 11 〇 having a high voltage power supplied by the discharge electrode 140 to excite ions in a plasma state, and the discharge electrode 14 is coupled and It is disposed on the two ends U2 and 114 of the lamp tube 110. The UV-excited phosphor 130 can also be disposed within the tube 11 of the UVCCFL lamp 100 of the present invention and distributed to contact the discharge medium 120 to provide radiation that is preferably in the non-uyc spectral range. The UV CCFL lamp 100 of the present invention may further include a socket mo coupled to the xenon tube 110 and configured to receive the discharge electrodes 112 and 114. In order to supply or supply the above-mentioned voltage power to excite the discharge medium 12〇 that is pushed and closed in the lamp tube 11〇, the lamp holder 150 may also include a power supply (not shown), which is adapted to the socket and electrically connected to the external power source. 'Better is an on-grid power supply. Compared with the conventional incandescent lamp, energy-saving lamp CFL and LED lamp, the advantage of the CCFL lamp is that it can also be applied to the CCFL lamp of the present invention in terms of the use of the light limit and the luminous efficiency. Some obvious facts are well known and will be explained in detail, including, for example, CCFL lamps have a longer service life than incandescent lamps and CFL lamps, have a lower mercury content than lamps, and can produce a larger illumination angle than LED lamps. . Nonetheless, the UV CCFL lamp 100 of the present invention also shares the advantages of a CCFL lamp that emits light in the visible spectrum. By using a discharge medium 12, comprising an excited ion vapor plasma distributed and sealed within the translucent sealed bulb 110, the UVCCFL lamp of the present invention can also produce a first-emission spectrum of UVC wavelength during operation, such as 280. Mail to 100nm. In an exemplary embodiment of the invention, the ion vapor plasma may be a mercury Hg ion vapor that is excited to a plasma state by a high voltage power supply, preferably in the range of one kilovolt or more. The w radiation generated by the excited ion vapor plasma may belong to the emission spectrum of 201227799 at 280 nm to 100 nm, and the initial or initial gamma gamma radiation may further be used with the phosphor 13 disposed in the bulb 110 and contacting the ion vapor plasma. The helium is illuminated or converted to produce a starting UV radiation of the first emission spectrum, such as in the UVC spectral range. Details of the UV-excited phosphor 13〇 disposed within the tube 110 of the present invention will be provided in the subsequent sections. In another embodiment of the invention, the first emission spectrum produced by the excited ion vapor plasma of the discharge medium of the ionized mercury plasma may belong to a spectrum ranging from 260 nm to 240 nm. For an exemplary application of the UV CCFL lamp 100 of the present invention in the field of fingerprinting, the UV CCFL lamp 100 can be preferably configured and configured to cure the matured nail glue. In an embodiment, the UV-irradiated fingerprint of the UV CCFL lamp of the present invention may have a first component comprising a polymerizable unsaturated double bond having at least one functional group in the molecule and photopolymerization initiation. The composition of the second component of the agent, and wherein the amount of the second component is 0.05 to 4.00 parts by weight, based on 1 part by weight of the first component. An example of such a nail-adhesive which is polymerizable to uv radiation can be referred to Japanese Patent Publication No. 2008-147720, filed by Tanaka et al., "Artificial Nail".
Composition Having Excellent Appearance”,以及由 Tanaka 等人所 申凊的日本專利公開 Ng ·9·152449 “Artifidal Nail CGmpositionComposition Having Excellent Appearance", and Japanese patent publication filed by Tanaka et al. Ng · 9·152449 "Artifidal Nail CGmposition
Having Improved Curability’、Tanaka揭示這類適合指曱膠之膠型 材料的實例’且可在足夠w輻射下而被固化及熟化。本發明的 UV CCFL燈1〇〇可用以結合或協同這種可聚合或可熟化指甲 膠,以達成指曱藝術領域中人造指曱的最佳結果。此外,對於更 安全且更健康的UV輻射,本發明uv CCFL燈1〇〇可較佳的藉安 置於上述半透明密封燈管11〇中之^^激發填光體13〇以提供 UVA光譜制内足触均骑,碰管nG係配置成方 便該初始W騎的照射’係用其内的UV激發磷光體130而由汞 離子蒸氣電漿120所產生。 201227799 依據本發明的另一實施例’ UV CCFL燈100包括UV激發鱗 光體130,以產生上述uv輻射或由uvc光譜轉換成如在 光譜範圍内的非UVC光譜。UV激發磷光體13〇可較佳的為安置 於本發明UVCCFL燈100的半透明密封燈管u〇中,並也可接觸 該放電媒介120。如第3圖所示本發明UVCCFL燈1〇〇的半透明 密封燈管11〇的部分【之放大示意圖的示範性實例,磷光體13〇 可較佳的安置於燈管11〇的内壁116上。在實施例中,磷光體13〇 可具有包含銪摻雜氧化蝴|^(B4Sr〇7:Eu+)的組合物。包含銪摻雜氧 化硼鳃(B4Sr〇7:Eu+)的磷光體130可較佳的以粉末形式備製具有預 先設定或選取的平均粒徑,用於塗佈到本發明w CCFL燈1〇〇的 半透明密封燈管110的内壁116上之磷光體混合溶液。然後,設 置於燈管110上並接觸上述放電媒介120的磷光體130在操作時 可產生該UV輻射以響應放電媒介12〇的該第一發射光譜。在示範 性實例中’第-發射光譜的uv輕射可為具有波長28〇nm至刚⑽ 之間的UVC輻射,尤其是可較佳的為26〇ηηι至240nm之間。該 磷光體130所產生或轉換的輸出w輻射,經由如放電媒介12〇 的uvc輻射之照射而用安置於燈管110内之磷光體13〇,可較佳 的屬於非UVC波長範圍内的第二發射光譜;在實施例中,響應該 第一發射光譜所產生的本發明1^〇:1^燈100的輸出w輻射可 為具波長400nm至350nm間的UVA輻射。此外,在本發明w CCFL燈1〇〇的示範性實施例中,利用具有包含祕〇啦+於其内 之組合物的上述碟光體丨3〇,磷光體13〇產生的非wc輕射之第 二發射光譜可屬於UVA光譜,係響應於放電媒介12〇所產生之第 一發射光譜的啟始uv輻射。 為了達成並產生由依據本發明示範性實施例之UY ccfl燈 1 〇〇所輸出的最佳UV轄射,如圖所示的半透明密封燈管】j 〇可較 12 201227799 佳的配置成具有某-形狀及大小,用以方便上述鱗光體U0用啟 ^ ^射照射以產生非UVC光譜或較佳UVA光譜範圍内之所 而或最佳uvm在第$騎示的本發明實施财,半透明密封 燈e 110可包括本質上圓形截面的石夕石管⑽,係具有均勾直徑D 且=具有二端部112及114之螺旋形式。較佳的是,半透明密封 燈管11〇的螺旋管之直徑D或外徑是2mm至l〇mm (02至_) 之間’且更具體的是,在示範性實施例中可較佳的為4mm (04)。 此夕^為達成本發明uv CCFL燈_所輸出之—激發以熟化指 • 甲膠’燈管110可較佳的由非W可吸收及/或uv半透明材料而 形成在貫;例中,本發明yyCCFL燈卿的半透明密封燈管11〇Having Improved Curability', Tanaka discloses an example of such a gel-type material suitable for silicone and can be cured and cured under sufficient w radiation. The UV CCFL lamp of the present invention can be used in conjunction with or in conjunction with such polymerizable or matureable nail varnishes to achieve the best results of artificial fingerprints in the art of fingerprinting. In addition, for safer and healthier UV radiation, the uv CCFL lamp of the present invention can preferably be placed in the above-mentioned translucent sealed lamp tube 11 to activate the light-filling body 13 to provide UVA spectroscopy. The inner foot is evenly rided, and the nG system is configured to facilitate the illumination of the initial W ride by the mercury ion plasma 120 with the UV excitation phosphor 130 therein. 201227799 Another embodiment of the present invention UV CCFL lamp 100 includes a UV excitation scale 130 to produce the above uv radiation or to convert from a uvc spectrum to a non-UVC spectrum as in the spectral range. The UV-excited phosphor 13 can preferably be disposed in the translucent sealed lamp tube of the UVCCFL lamp 100 of the present invention and can also contact the discharge medium 120. As shown in Fig. 3, an exemplary embodiment of an enlarged schematic view of a portion of the translucent sealed lamp tube 11 of the UVCCFL lamp of the present invention, the phosphor 13 is preferably disposed on the inner wall 116 of the bulb 11〇. . In an embodiment, the phosphor 13 may have a composition comprising an antimony doped oxidized film (B4Sr〇7: Eu+). The phosphor 130 comprising ytterbium-doped lanthanum boride (B4Sr〇7:Eu+) may preferably be prepared in powder form with a predetermined or selected average particle size for coating onto the CC CC lamp of the present invention. The phosphor mixture solution on the inner wall 116 of the translucent sealed bulb 110. Then, the phosphor 130 disposed on the bulb 110 and contacting the discharge medium 120 described above can generate the UV radiation in response to the first emission spectrum of the discharge medium 12A. In the exemplary embodiment, the uv light of the 'first-emission spectrum' may be UVC radiation having a wavelength between 28 〇 nm and just (10), and particularly preferably between 26 〇ηη and 240 nm. The output w radiation generated or converted by the phosphor 130 is irradiated with the uvc radiation such as the discharge medium 12 by the phosphor 13 disposed in the bulb 110, preferably in the non-UVC wavelength range. A second emission spectrum; in an embodiment, the output w radiation of the present invention in response to the first emission spectrum may be UVA radiation having a wavelength between 400 nm and 350 nm. Further, in the exemplary embodiment of the w CCFL lamp of the present invention, the non-wc light shot produced by the phosphor 13 is utilized by using the above-mentioned disc 丨 3 具有 having the composition containing the secret + + therein. The second emission spectrum may belong to the UVA spectrum and is the initiation uv radiation of the first emission spectrum generated in response to the discharge medium 12〇. In order to achieve and produce the optimal UV radiation output by the UY ccfl lamp 1 依据 according to an exemplary embodiment of the present invention, the translucent sealed lamp tube as shown in the figure can be configured to have better than 12 201227799. a shape and size for facilitating the illumination of the scale body U0 to produce a non-UVC spectrum or a preferred UVA spectrum, or an optimum uvm in the implementation of the invention. The translucent sealing lamp e 110 may comprise a stone tube (10) having a substantially circular cross section with a uniform hook diameter D and a spiral form having two end portions 112 and 114. Preferably, the diameter D or the outer diameter of the spiral tube of the translucent sealing tube 11 is between 2 mm and 1 mm (02 to _)' and more specifically, in the exemplary embodiment, preferably It is 4mm (04). In this case, in order to achieve the uv CCFL lamp of the present invention - the excitation to the aging finger can be preferably formed by a non-W absorbing and/or uv translucent material; The translucent sealed lamp tube of the yyCCFL lamp of the invention is 11〇
的上述碎石f可為石英玻璃;在另—實施例中,⑪石管可為W 等級的熔合石夕石’以方便發射w光線或穿過該溶合石夕石而輕射。 UVCCFL燈1〇〇的半透明密封燈管11〇的該二端部ιΐ2及⑴可 配置成接收放電· 140,能提供高電壓電力以激發燈㈣〇内放 電媒介120的離子蒸氣電漿。亦即,配置在半透明密封燈管11〇 的該二端部112上之放電電極M〇係分隔開本質上大於或等於 _ 5麵喊度W ’進而燈座15〇的電源供應器所供應的電力係安全 的在大於—千伏特之高賴下操作;在示紐實酬巾,在半透 明密封燈管110的該二端部U2上之放電電極M〇之間的寬度w 可為20mm。 請再次參閱第3圖及第4圖。除上述以外,為方便照射安置 於本發明UVCCFL燈1〇〇的半透明密封燈管11〇内之磷光體 130’以使得UV轄射輸出,較佳的是在WA光譜範圍内,可為 均勻且足夠用以熟化指甲藝術領域令的指甲膠。依據本發明W CCFL燈100的實施例,其中係利用磷光體13〇的銷推雜氧化聰 (B4Sr〇7:EU+)之組合物;B4Sr〇7:Eu+可报有利的備製成具有較佳。 13 201227799 12μπι至18μηι間的平均粒徑。在實施例中,磷光體13〇的平均粒 徑可較佳的本質上等於丨5μηι (或15μηι±3μηι)。亦即,磷光體13〇 可較佳的備製成具有某—平均練的粉末形式,係預先設定或選 取而用於塗佈到本發明UV CCFL燈100的燈管丨1()之内壁丨16上 的構光體’/¾合溶液’如赋巾的影線部分所示。這種構光體混合 溶液可較佳的在本發日月UV CCFL燈·的示範性製作處理期間而 設置並塗佈。然後,設置在燈管11G上尤其是上述的内壁116,並 接觸上述放魏介i2G的魏體13〇,可在操作_產錢Μ輕 射以響應放電媒介12G的該第—發射光譜。此外,依據本發明的 另-實施例並針對設置在本發明uv CCFL燈丨⑻之燈f丨1〇内的 放電媒"12G,離子蒸氣電紫,比如被經由放電電極i4G以及燈座 150的電源供應器所供應的高電廢而激發至魏狀態的汞啤離子 热氣’在本發明UVCCFL燈100的半透明密封燈管11〇中,可具 有2.7gW至3.7_3之_密度。在實施例中,比如要被激發 至電漿狀紅絲子魏驗發軒統 觸的半侧聰UG㈣崎 依據本發明的實_,UV CCTL燈⑽所提供的輸出W輕 射可較佳_於非UVC波長,藉以提供更安全及更歸的w光 使用以及應用,尤其是對於如指甲藝術領域中熟化的指甲膠應 用。由碗光體130響應激發離子蒸氣電漿之啟始w輻射的第一發 射光错而產生的上述具有第二發射光譜的輸出w輻射可屬於 400腿至350nm之間的㈣波長,比如該啟始w輕射為施爪 至24〇nm間。在本發明的實施例中,包含BAO叔組合物的上 述填光體13〇所產生的第二發射光譜,可較佳的包括本質上等於 368nm的尖峰波長。 依據本發明的另-實施例,肋藉w輻射而熟化㈣可熟 201227799 化指甲膠的UV CCFL燈100 ’可利用包含销摻雜氧化錄氣硼 (SrFB2〇35:Eu2+)之組合物的磷光體n〇。相類似的,包含激發離子 蒸氣的放電媒介120也可設置或安置在半透明密封燈管11〇内, 係用以藉所輸入之高電壓電力而放電以產iuvc波長之第一發射 光譜,使得在本發明UV CCFL燈100操作時可被激發至電漿狀 態。包含SrFB2〇35:Eu2+之組合物的磷光體130可很有利的備製並 安置於半透明密封燈管110内,較佳的是在上述燈管11〇的内壁 116上並接觸該放電媒介120,使得在操作以及用故電媒介12〇之 φ 啟始UVC輻射而照射時,響應放電媒介120的該第一發射光譜的 輸出UV輻射可屬於非UVC波長的第二發射光譜,較佳的是WA 波長,比如400nrn至350nm之間。 類似的’要協同使用或結合本發明UV CCFL燈1〇〇所提供之 UV輻射的UV可熟化指甲膠,也可具有包括在分子中具至少一官 能基可聚合未飽合雙鍵之一第一成分以及光聚合啟始劑之一第二 成份的組合物。如先前所述’第二成分的量為〇 〇5至4 〇〇份重量, 係相對於100份重量的第一成分。UV可熟化膠可在曝光於本發明 鲁 UV CCFL燈100的輸出UV輻射下,由液態轉變成固態;此外, UV可熟化指曱膠的熟化結果也可取決於本發明uv CCFL燈100 的瓦數以及在這種UV輻射曝光下的熟化時間。此外,uv可熟化 指甲膠的實例,比如壓克力膠,包括胺基甲酸酯-丙烯酸甲酯以及 環氧樹脂-丙烯酸曱酯,也可包括或參考來自如Keyst〇ne®、BI〇®、 CNC®及COSMEX™之製造商的產品。加入可包括本發明υγ CCFL燈100的UVCCFL裝置而與任何uv可熟化指曱膠一起, 也必須被視為在本發明的範圍内。 依據本發明UV CCFL燈100的示範性實施例,其中放電媒介 120包括激發離子蒸氣,比如在該燈操作時被激發至電漿狀態的汞 15 201227799 離子蒸氣,係分佈並密封在半透明密封燈管U〇内用以產生較佳 為26〇nm至24〇nm之UVC波長的第一發射光譜,而且磷光體13〇 係安置於半透明密封燈管U〇内並接觸該放電媒介12(),用以產生 輸出UV姉,係具有非uvC波長_二魏光譜,較佳的是 4〇〇mn至35〇nm之間,以響應放電媒介12〇 _第一發射光错。 碟光體130可包括上述SrFB2〇35:Eu2+的組合物,並可很有利的備 製成具有較佳為5.5μηι至11·5μπι之間的平均粒徑。在實施例中, 磷光體130的平均粒徑可較佳的本質上等於&5μηι (或 Β^μη^^μιη)。亦即,磷光體130可很有利的備製成具有某一平均 粒徑的粉末形式,係預先設定或選取而用於塗佈到本發明w CCFL燈1〇〇的燈管110之内壁116上的峨光體混合溶液比如在 本發明UVCCFL燈1〇〇的示範性製程期間。然後,設置在燈管11〇 上,尤其是上述内壁116’並接觸上述放電媒介12〇的磷光體13〇, 可在刼作時產生該uv輻射以響應該放電媒介12〇的第一發射光 譜。此外,依據本發明的另一實施例並針對安置在本發明w ccfl 燈100的燈管110上的放電媒介12〇,離子蒸氣電漿,比如被經由 放電電極140以及燈座150的電源供應器所供應的高電壓而激發 至電漿狀態的汞Hg離子蒸氣,在本發明1^(:(:1^燈1〇〇的半透 明密封燈管no中可具有2.7g/cn^3 7gW之間的密度。在實 施例中’比如要被激發至電聚狀態之采離子蒸氣的激發離子蒸 氣,在本發明UV CCFL燈100的半透明密封燈管n〇中可較佳的 本質上等於3.5g/cm3。 相類似的,依據發明的實施例,W CCFL燈丨〇〇所提供的 輸出UV輻射可較佳的屬於非uvc波長,提供對w光更安全與 更健康的使用以及應用,尤其是用於如指甲藝術領域中熟化的指 曱膠的顧。紐離子蒸氣電⑽啟始UV輕射的上述輸出―曰轄 16 201227799 射’具有磷光體130響應如260nm至240nm間的第一發射光譜而 產生之第二發射光譜,可具有40〇nm至35〇nm之間的μα波長。 本發明的實施例中’包含SrFB2〇3.5:Eu2+之組合物的上_光體13〇 所產生的第二發射光譜,係較佳的包括本質上等於366nm的尖峰 波長。 請再次參閱第1圖及第2圖。當作高電壓下操作之裝置的部 分安全性量度,配置在本發明UV CCFL燈1GG的半透明密封燈管 110之二端部112及114上的上述至少放電電極13〇,可較佳的以 • 本質上大於或等於5_的寬度w分開,進而燈座⑼的電源供 應器所供應的電力可在大於一千伏特的高電壓下安全操作。在示 範性實施例中’燈管110之二端部112及114上放電電極14〇之 間的寬度W可為20mm。此外,連結至該半透明密封燈管11〇的 燈座150也可包括電源供應$,用以供應電力而激發該放電媒介 120至電漿狀態,比如汞離子蒸氣電漿。The above-mentioned gravel f may be quartz glass; in another embodiment, the 11 stone tube may be a W-grade fusion stone stone to facilitate the emission of light or light through the fused stone. The two ends ι 2 and (1) of the translucent sealed tube 11 of the UVCCFL lamp can be configured to receive a discharge 140, which can provide high voltage power to excite the ion vapor plasma of the discharge medium (12). That is, the discharge electrodes M disposed on the two end portions 112 of the translucent sealing lamp tube 11 are separated by a power supply device which is substantially greater than or equal to _ 5 face shouting degree W' and thus the lamp holder 15〇. The supplied power is safely operated at a height greater than - kilovolts; the width w between the discharge electrodes M2 on the two ends U2 of the translucent sealed bulb 110 can be 20mm. Please refer to Figure 3 and Figure 4 again. In addition to the above, in order to facilitate the irradiation of the phosphor 130' disposed in the translucent sealed lamp tube 11 of the UVCCFL lamp of the present invention so that the UV emission output, preferably in the WA spectral range, may be uniform It is enough to mature the nail glue in the nail art field. According to an embodiment of the W CCFL lamp 100 of the present invention, wherein the composition of the phosphorous iridium (B4Sr〇7: EU+) is used by the pin of the phosphor 13〇; the B4Sr〇7:Eu+ can be advantageously prepared to have a better preparation. . 13 201227799 Average particle size between 12μπι and 18μηι. In the embodiment, the average particle diameter of the phosphor 13 turns may preferably be substantially equal to 丨5μηι (or 15μηι ± 3μηι). That is, the phosphor 13 is preferably prepared in a powder form having a certain average, which is previously set or selected for application to the inner wall of the tube 丨 1 () of the UV CCFL lamp 100 of the present invention. The photostructure '/3⁄4 solution' on the 16 is shown in the hatched portion of the towel. This illuminating body mixture solution can be preferably disposed and coated during the exemplary fabrication process of the UV CCFL lamp of the present day. Then, it is disposed on the bulb 11G, particularly the inner wall 116 described above, and is in contact with the Wei body 13 of the above-mentioned Weisui i2G, and can be lightly irradiated in operation _ in response to the first emission spectrum of the discharge medium 12G. Further, in accordance with another embodiment of the present invention and for the discharge medium "12G disposed in the lamp 丨1〇 of the uv CCFL lamp (8) of the present invention, the ion vapor violet is, for example, passed through the discharge electrode i4G and the socket 150. The high-power waste supplied by the power supply source excites the mercury-containing hot gas of the Wei state. In the translucent sealed lamp tube 11 of the UVCCFL lamp 100 of the present invention, it may have a density of 2.7 gW to 3.7 mm. In the embodiment, for example, it is to be excited to the plasma-like red silk, and the half-side of the fluorescing fluorescing UG (four) is in accordance with the invention, the output of the UV CCTL lamp (10) is preferably lighter. For non-UVC wavelengths, it provides safer and more versatile use and application, especially for nail varnish applications such as nail art. The output w radiation having the second emission spectrum generated by the bowl light body 130 in response to the first emission optical error of the initial w radiation of the excited ion vapor plasma may belong to a (four) wavelength between 400 legs and 350 nm, such as the The first w light shot is between the claws and 24 〇 nm. In an embodiment of the invention, the second emission spectrum produced by the above-described light-filling body 13 包含 comprising the BAO tertiary composition may preferably comprise a peak wavelength substantially equal to 368 nm. According to another embodiment of the present invention, the rib is cured by w radiation. (IV) The UV CCFL lamp 100' of the usable 201227799 nail glue can be phosphorescent using a composition comprising a pin-doped oxide-recorded boron (SrFB2〇35:Eu2+). Body n〇. Similarly, the discharge medium 120 containing the excited ion vapor can also be disposed or disposed within the translucent sealed tube 11 , for discharging by the input high voltage power to produce a first emission spectrum of the iuvc wavelength, such that The UV CCFL lamp 100 of the present invention can be excited to a plasma state during operation. The phosphor 130 comprising the composition of SrFB2〇35:Eu2+ can be advantageously prepared and disposed within the translucent sealed tube 110, preferably on the inner wall 116 of the tube 11〇 and in contact with the discharge medium 120. The output UV radiation in response to the first emission spectrum of the discharge medium 120 may belong to a second emission spectrum of the non-UVC wavelength, preferably when the operation and the initiation of the UVC radiation by the φ of the dielectric medium 12 φ are applied. WA wavelength, such as between 400nrn and 350nm. A similar UV-curable nail gel to be used in combination or in combination with the UV radiation provided by the UV CCFL lamp of the present invention may also have one of the polymerizable unsaturated double bonds comprising at least one functional group in the molecule. A composition of a component and a second component of a photopolymerization initiator. The amount of the second component as previously described is 〇 5 to 4 parts by weight relative to 100 parts by weight of the first component. The UV curable adhesive can be converted from a liquid state to a solid state under exposure to the output UV radiation of the Lu UV CCFL lamp 100 of the present invention; in addition, the curing result of the UV curable gel can also depend on the tile of the uv CCFL lamp 100 of the present invention. The number and the ripening time under exposure to this UV radiation. In addition, examples of uv-curable nail varnishes, such as acrylic adhesives, including urethane-methyl acrylate and epoxy-methacrylate, may also be included or referenced from, for example, Keyst〇ne®, BI〇® , the manufacturer of CNC® and COSMEXTM. The addition of a UVCCFL device that can include the υ γ CCFL lamp 100 of the present invention, along with any uv curable gutta percha, must also be considered within the scope of the present invention. An exemplary embodiment of a UV CCFL lamp 100 in accordance with the present invention, wherein the discharge medium 120 includes an excited ion vapor, such as mercury 15 201227799 ion vapor that is excited to a plasma state during operation of the lamp, distributed and sealed in a translucent sealed lamp a first emission spectrum for generating a UVC wavelength of preferably 26 〇 nm to 24 〇 nm in the tube U ,, and the phosphor 13 is disposed in the translucent sealing tube U 并 and contacting the discharge medium 12 () For generating an output UV enthalpy, having a non-uvC wavelength _Wu Wei spectrum, preferably between 4 〇〇 mn and 35 〇 nm, in response to the discharge medium 12 〇 _ first emission optical error. The disc body 130 may include the above composition of SrFB2〇35:Eu2+, and may be advantageously prepared to have an average particle diameter of preferably between 5.5 μm and 11·5 μm. In an embodiment, the average particle size of the phosphor 130 may preferably be substantially equal to & 5μηι (or Β^μη^^μηη). That is, the phosphor 130 can be advantageously prepared in the form of a powder having a certain average particle size, which is previously set or selected for application to the inner wall 116 of the bulb 110 of the w CCFL lamp of the present invention. The phosphor blend solution is, for example, during the exemplary process of the UVCCFL lamp of the present invention. Then, the phosphor 13 设置 disposed on the bulb 11 , especially the inner wall 116 ′ and contacting the discharge medium 12 〇, can generate the uv radiation in response to the first emission spectrum of the discharge medium 12 〇 . Further, in accordance with another embodiment of the present invention and with respect to the discharge medium 12A disposed on the bulb 110 of the w ccfl lamp 100 of the present invention, an ion vapor plasma, such as a power supply via the discharge electrode 140 and the socket 150 The mercury Hg ion vapor excited to the plasma state by the supplied high voltage may have 2.7 g/cn^3 7 gW in the translucent sealed lamp no of the present invention. In the embodiment, the excited ion vapor of the ionizing vapor, such as the ionizing vapor to be excited to the electropolymerized state, is preferably substantially equal to 3.5 in the translucent sealed tube of the UV CCFL lamp 100 of the present invention. g/cm3. Similarly, according to an embodiment of the invention, the output UV radiation provided by the W CCFL lamp can preferably be of non-uvc wavelength, providing safer and healthier use and application of w light, especially It is used for the finger-like gelatin which is matured in the field of nail art. New-ion vapor electricity (10) initiates the above-mentioned output of UV light-lighting - 曰 16 16 201227799 射 'has a phosphor 130 response such as the first emission between 260 nm and 240 nm a second emission spectrum produced by the spectrum Μα wavelength between 40 〇 nm and 35 〇 nm. In the embodiment of the present invention, the second emission spectrum generated by the upper photobody 13 包含 comprising the composition of SrFB 2 〇 3.5: Eu 2+ preferably includes the essence The peak wavelength is equal to 366 nm. Please refer to Fig. 1 and Fig. 2 again. As part of the safety measure of the device operating at high voltage, it is disposed at the two ends of the translucent sealed lamp tube 110 of the UV CCFL lamp 1GG of the present invention. The at least discharge electrodes 13A on the portions 112 and 114 may preferably be separated by a width w which is substantially greater than or equal to 5 mm, so that the power supplied by the power supply of the lamp holder (9) may be greater than one thousand volts. Safe operation at high voltage. In the exemplary embodiment, the width W between the two ends 112 and 114 of the bulb 110 may be 20 mm. Further, the translucent sealing tube 11 The socket 150 can also include a power supply $ for supplying power to excite the discharge medium 120 to a plasma state, such as mercury ion vapor plasma.
在本發明UV CCFL燈100的示範性操作中,尤其是在指甲藝 術領域的應用,指甲谬可較佳的用以協同並結合^^沉燈W • 100,並可塗佈到使用者的手指或腳趾指甲,以使得uy可孰化γ 化。因為高電壓電妓經由燈座15G的電源供應器而供應,該燈 座150具有燈插座’係電氣連接至比如並聯電源輸入以及本發明 UVCCFL燈的放電電極14〇,所以安置在半透明密封燈管ιι〇 内的放電齡12G ’比如汞統,可被激發至離子蒸氣魏,並可 發射260m至24Gnm間範_的第—魏光譜的啟始w 輻射。因為包含上述崎〇7祝或SrFB2〇35:Eu2+之組合物的w 激發麟光體130也可較佳的設置並安置於燈管11〇内且接觸放電 媒介120,所以較佳的在4〇〇nm至35〇nm間的⑽八範圍内之第 17 201227799 一發射光譜的輸出w輕射,係可經由啟始w細照娜光體粉 末或響應第-發設光言普的uv輕射而獲得。然後,塗佈在使用者之 指甲上且較佳的包括含有在分子巾具至少—官能基可聚合未飽合 雙鍵的第-成分以及光聚合啟始劑的—第二成份之組合物的的指 曱膠,可在這種熟化處理後被熟化以達成最佳結果的人造指甲, 因為本發明UVCCFL燈刚可藉本發明所提供之爾輻射光 譜,並參照本發明UV CCFL燈的特定瓦數而在更短的熟化時 間’很有效且很有安全性的與這種指甲膠一起協同工作。 • 雖然本發明係參照以上較佳實施例或實例而揭示,但是要了 解的是,這些實施贼實例係為了轉性目的,不應被視為用以 ,制本發明。考慮到,對·知該猶的人士,修改及結合將很 谷易發生’而修改及結合娜在本發明的精神及以下巾請專利範 圍的範圍之内。 【圖式簡單說明】 本發明可叫同形式實現,且本發雜佳實關的細節係參 考所附圖式而於上勒容巾進行說明。這些圖式(未依據實際尺寸 大小)顯示並畫出只有本發明的較佳實施例1必須不能視為用以 限定本發_麵。本發_容的修改也必須視為在本發明的精 神内。 第1圖為依據本發明實施例UVCCFL燈的立體示意圖; 第2圖為第1圖中本發明uvcCFL燈的上視圖; 第3圖為第2®tUVCCFL燈的燈管之部分!的放大示意圖;以 及 , 第4圖為第3圖中依據本發明實施例UVCCFL燈的燈管沿割線 A-A的剖示圖。 201227799 【主要元件符號說明】 100UVCCFL 燈 110燈管 112端部 114端部 116内壁 120放電媒介 130磷光體 140放電電極 150燈座 A-A割線 D直徑 I部分 W寬度In the exemplary operation of the UV CCFL lamp 100 of the present invention, especially in the field of nail art, the nail file can preferably be used in conjunction with and in combination with the sunburst lamp W 100 and can be applied to the user's finger. Or toe nails, so that uy can be deuterated. Since the high voltage power is supplied via the power supply of the lamp holder 15G, the lamp socket 150 has a lamp socket 'electrically connected to, for example, a parallel power supply input and a discharge electrode 14A of the UVCCFL lamp of the present invention, so that it is placed in a translucent sealed lamp The discharge age of 12G in the tube ιι', such as the mercury system, can be excited to the ion vapor Wei, and can emit the initial w radiation of the first-Wei spectrum between 260m and 24Gnm. Since the w-excited spheroid 130 comprising the composition of the above-mentioned rugged 7 or SrFB2 〇 35:Eu 2+ is also preferably disposed and disposed in the bulb 11 接触 and in contact with the discharge medium 120, it is preferably 4 〇. From the range of 〇nm to 35〇nm (10) in the range of 18th 201227799, the output of an emission spectrum is lightly shot, which can be lightly irradiated through the start of the light or in response to the first-generation uv light. And get. Then, it is applied to the nail of the user and preferably comprises a composition comprising a first component of at least a functional group polymerizable unsaturated double bond in the molecular towel and a second component of a photopolymerization initiator. Finger gutta-percha, an artificial nail that can be aged after this curing treatment to achieve the best results, because the UVCCFL lamp of the present invention can just use the radiation spectrum provided by the present invention, and refer to the specific tile of the UV CCFL lamp of the present invention. And in a shorter curing time 'very effective and very safe to work with this nail glue. Although the present invention has been disclosed with reference to the preferred embodiments or examples above, it is to be understood that these examples of thieves are not intended to be used for the purpose of the invention. It is considered that the modification and combination of those who know the singularity will be very easy to happen. The modifications and combinations are within the scope of the spirit of the invention and the scope of the patent application. BRIEF DESCRIPTION OF THE DRAWINGS The present invention may be embodied in the same form, and the details of the present invention are described in the accompanying drawings. These drawings (not according to the actual size) are shown and drawn. Only the preferred embodiment 1 of the present invention must not be considered to limit the present invention. Modifications of the present invention must also be considered within the spirit of the present invention. 1 is a perspective view of a UVCCFL lamp according to an embodiment of the present invention; FIG. 2 is a top view of the uvcCFL lamp of the present invention in FIG. 1; and FIG. 3 is a portion of the lamp of the second ® tUVCCFL lamp! FIG. 4 is a cross-sectional view of the lamp tube along the secant line A-A of the UVCCFL lamp according to the embodiment of the present invention in FIG. 201227799 [Description of main component symbols] 100UVCCFL lamp 110 lamp tube 112 end portion 114 end portion 116 inner wall 120 discharge medium 130 phosphor 140 discharge electrode 150 lamp holder A-A secant line D diameter I part W width