TW201616691A - White light emitting device - Google Patents

White light emitting device Download PDF

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TW201616691A
TW201616691A TW103137031A TW103137031A TW201616691A TW 201616691 A TW201616691 A TW 201616691A TW 103137031 A TW103137031 A TW 103137031A TW 103137031 A TW103137031 A TW 103137031A TW 201616691 A TW201616691 A TW 201616691A
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light emitting
phosphor
emitting device
white light
peak wavelength
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TW103137031A
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TWI545807B (en
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陳奕璇
徐世昌
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光寶光電(常州)有限公司
光寶科技股份有限公司
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Abstract

A white light emitting device comprises a light emitting diode chip having a dominant wavelength of 390 to 430 nm, and a phosphor resin layer including first, second, and third fluorescent materials. The first fluorescent material can be excited to emit a light with a peak wavelength of 450nm to 470nm. The second fluorescent material can be excited to emit a light with a peak wavelength of 520nm to 530nm. The third fluorescent material can be excited to emit a light with a peak wavelength of 630nm to 650nm. The light emitted by the white light emitting device has a color temperature less than 5000K, a general color rendering index value Ra greater than 90, and special color rendering index values R9-R15 greater than 90.

Description

白光發光裝置White light emitting device

本發明是有關於一種發光裝置,特別是指一種具有高演色性的白光發光裝置。 The present invention relates to a light-emitting device, and more particularly to a white light-emitting device having high color rendering properties.

一般照明用的光源演色性越高,可使被照物體所呈現的顏色越真實,反之,若演色性越低,會使被照物體所呈現的顏色越失真。 The higher the color rendering of the light source for general illumination, the more realistic the color of the illuminated object, and vice versa, the lower the color rendering, the more the color of the illuminated object will be distorted.

現有利用半導體晶片發光的光源,例如LED光源,在色溫5000K以下的,通常演色性無法達到平均演色評價數Ra及特殊演色評價數R9至R15的值都大於90,尤其是R9及R12通常其中之一的值無法大於90。 Conventionally, a light source that emits light using a semiconductor wafer, such as an LED light source, has a color temperature of 5000 K or less, and generally the color rendering performance cannot reach the average color rendering evaluation Ra and the special color rendering evaluation numbers R9 to R15 are greater than 90, especially R9 and R12. The value of one cannot be greater than 90.

由於LED光源具有節能省電、環保、使用壽命長等優點,如何達到更高的演色性以擴展LED光源的應用領域,是需要解決的課題。 Since the LED light source has the advantages of energy saving, environmental protection, long service life, etc., how to achieve higher color rendering to expand the application field of the LED light source is a problem to be solved.

因此,本發明之目的,即在提供一種具有色溫5000K以下,平均演色評價數Ra及特殊演色評價數R9至R15的值都大於90的白光發光裝置。 Therefore, an object of the present invention is to provide a white light-emitting device having a color temperature of 5000 K or less, an average color rendering evaluation value Ra, and a special color rendering evaluation number R9 to R15 of more than 90.

於是本發明白光發光裝置,包含一發光晶片及 一螢光體層。該發光晶片可發出波峰波長介於390至430nm的光。該螢光體層包括一第一螢光材料、一第二螢光材料及一第三螢光材料。該第一螢光材料可被激發出波峰波長介於450至470nm的光。該第二螢光材料可被激發出波峰波長介於520至530nm的光,且在490nm波長的發光強度IG(490nm)與峰值波長的發光強度IG(Wp)之比值不小於0.3,即IG(490nm)/IG(Wp)≧0.3。第三螢光材料可被激發出波峰波長介於630至650nm的光,且在580nm波長的發光強度IR(580nm)與峰值波長的發光強度IR(Wp)之比值不小於0.3,即IR(580nm)/IR(Wp)≧0.3。因而該白光發光裝置形成之整體混光的色溫在5000K以下且平均演色評價數Ra及特殊演色評價數R9至R15的值都大於90。 Thus, the white light emitting device of the present invention comprises a light emitting chip and a phosphor layer. The luminescent wafer emits light having a peak wavelength between 390 and 430 nm. The phosphor layer includes a first phosphor material, a second phosphor material, and a third phosphor material. The first phosphor material can be excited to emit light having a peak wavelength between 450 and 470 nm. The second fluorescent material can be excited to emit light having a peak wavelength of 520 to 530 nm, and the ratio of the luminous intensity I G (490 nm) at a wavelength of 490 nm to the luminous intensity I G (Wp) of the peak wavelength is not less than 0.3, that is, I G (490 nm) / I G (Wp) ≧ 0.3. The third fluorescent material can be excited to emit light having a peak wavelength of 630 to 650 nm, and the ratio of the luminous intensity I R (580 nm) at a wavelength of 580 nm to the luminous intensity I R (Wp) of the peak wavelength is not less than 0.3, that is, I R (580 nm) / I R (Wp) ≧ 0.3. Therefore, the color temperature of the overall mixed light formed by the white light emitting device is 5000 K or less, and the values of the average color rendering evaluation Ra and the special color rendering evaluation numbers R9 to R15 are both greater than 90.

本發明之功效,本發明藉由近紫外光(near-UV)晶片搭配具有特定發光波長及光譜的螢光材料,可使整體混光之色溫在5000K以下且演色性達到平均演色評價數Ra及特殊演色評價數R9至R15的值都大於90之高演色性。 The effect of the present invention is that the near-ultraviolet (near-UV) wafer is matched with a fluorescent material having a specific emission wavelength and spectrum, and the color temperature of the overall mixed light is below 5000K and the color rendering property reaches the average color rendering number Ra and The values of the special color rendering numbers R9 to R15 are all greater than the color rendering of 90.

1‧‧‧基座 1‧‧‧Base

11‧‧‧導線架 11‧‧‧ lead frame

111‧‧‧安裝槽 111‧‧‧Installation slot

12‧‧‧外框 12‧‧‧Front frame

121‧‧‧容置空間 121‧‧‧ accommodating space

13‧‧‧容置空間 13‧‧‧ accommodating space

2‧‧‧發光晶片 2‧‧‧Lighting chip

3‧‧‧螢光體層 3‧‧‧Fluorescent layer

4‧‧‧金屬線 4‧‧‧Metal wire

本發明之其他的特徵及功效,將於參照圖式的實施方式中清楚地呈現,其中:圖1是一立體圖,說明本發明白光發光裝置之第一實施例;圖2是一俯視圖,說明該第一實施例;圖3是一光譜圖,說明該第一實施例中第一、第二、第三螢光材料的發光光譜; 圖4是一光譜圖,說明該第一實施例的整體混光光譜;圖5為色溫5000K的參考光源的光譜圖;圖6為本發明白光發光裝置之第二實施例整體混光之光譜圖;圖7為色溫2700K的參考光源的光譜圖;及圖8是一立體圖,說明本發明白光發光裝置之第三實施例。 Other features and effects of the present invention will be apparent from the embodiments of the present invention, wherein: FIG. 1 is a perspective view illustrating a first embodiment of the white light emitting device of the present invention; FIG. 2 is a top view illustrating the First embodiment; FIG. 3 is a spectrogram illustrating the luminescence spectrum of the first, second, and third phosphor materials in the first embodiment; 4 is a spectrum diagram illustrating the overall mixed light spectrum of the first embodiment; FIG. 5 is a spectrum diagram of a reference light source having a color temperature of 5000 K; FIG. 6 is a spectrum diagram of the overall mixed light of the second embodiment of the white light emitting device of the present invention. Fig. 7 is a spectrum diagram of a reference light source having a color temperature of 2700 K; and Fig. 8 is a perspective view showing a third embodiment of the white light emitting device of the present invention.

在本發明被詳細描述之前,應當注意在以下的說明內容中,類似的元件是以相同的編號來表示。 Before the present invention is described in detail, it should be noted that in the following description, similar elements are denoted by the same reference numerals.

參閱圖1與圖2,本發明白光發光裝置之第一實施例包含一基座1、一發光晶片2及一螢光體層3。 Referring to FIG. 1 and FIG. 2, a first embodiment of the white light emitting device of the present invention comprises a susceptor 1, an illuminating wafer 2 and a phosphor layer 3.

該基座1具有一導線架11及一與該導線架11結合的外框12,其中上述二者界定一容置空間121用於容納設於該導線架11之該發光晶片2。並以金屬線4與該導線架11形成電連接。在本實施例中,該發光晶片2為近紫外光(near-UV)晶片,可發出波峰波長介於390至430nm的第一光線,具體之峰值波長(Wp)為407nm。 The pedestal 1 has a lead frame 11 and an outer frame 12 coupled to the lead frame 11. The two define an accommodating space 121 for accommodating the illuminating wafer 2 disposed on the lead frame 11. And the metal wire 4 is electrically connected to the lead frame 11. In this embodiment, the illuminating wafer 2 is a near-UV wafer, and emits a first ray having a peak wavelength of 390 to 430 nm, and specifically has a peak wavelength (Wp) of 407 nm.

該螢光體層3填充於該容置空間121並覆蓋該發光晶片2,包括一膠體、一第一螢光材料、一第二螢光材料及一第三螢光材料,且該第一、第二、第三螢光材料位於該膠體內。其中,該第一螢光材料受一第一激發光源如該發光晶片2產生的第一光線激發而發出波峰波長介於450至470nm的第二光線;第二螢光材料受一第二激發光 源,例如部分該第一光線與第二光線,產生的光激發而發出波峰波長介於520至530nm的第三光線;第三螢光材料受一第三激發光源,例如部分該第一光線、第二光線與第三光線,產生的光激發而發出波峰波長介於630至650nm的光。具體而言,該第一螢光材料可被激發產生藍光、該第二螢光材料可被激發產生綠光、該第三螢光材料可被激發產生紅光。 The phosphor layer 3 is filled in the accommodating space 121 and covers the illuminating wafer 2, and includes a colloid, a first fluorescent material, a second fluorescent material and a third fluorescent material, and the first and the first 2. The third fluorescent material is located in the gel body. The first fluorescent material is excited by a first excitation light source, such as the first light generated by the light-emitting chip 2, to emit a second light having a peak wavelength of 450 to 470 nm; and the second fluorescent material is subjected to a second excitation light. The source, for example, the first light and the second light, the generated light is excited to emit a third light having a peak wavelength of 520 to 530 nm; and the third fluorescent material is subjected to a third excitation light source, for example, the first light, The second light and the third light, the generated light is excited to emit light having a peak wavelength between 630 and 650 nm. In particular, the first phosphor material can be excited to produce blue light, the second phosphor material can be excited to produce green light, and the third phosphor material can be excited to produce red light.

此外,該導線架11上更可具有一安裝槽111,該發光晶片2位於該安裝槽111內且與該容置空間121連通。或者說,該容置空間121亦包含該安裝槽111。故該螢光體層3亦填充於該安裝槽111及該容置空間121或填充於包含該安裝槽111的該容置空間121。 In addition, the lead frame 11 further has a mounting slot 111. The illuminating chip 2 is located in the mounting slot 111 and communicates with the accommodating space 121. In other words, the accommodating space 121 also includes the mounting slot 111. Therefore, the phosphor layer 3 is also filled in the mounting groove 111 and the accommodating space 121 or filled in the accommodating space 121 including the mounting groove 111.

本實施例所採用的螢光材料的放射光譜(Emission)如圖3所示。由於特殊演色評價數R12具體代表的顏色是飽和藍色(strong blue),為了有效提升R12,加入該第一螢光材料,即藍光螢光粉,其光譜的半高寬(FWHM)亦遠比一般藍光晶片寬。而且,由於該第一螢光材料的放射光波長主要分布於432-492nm之區間內,向下延伸至410nm,向上延伸至550nm,更進一步至600nm,應使用430nm以下之激發光較佳,所以前述發光晶片2採用近紫外光(near-UV)晶片。值得注意的是,本實施例所採用的第二螢光材料在490nm波長的發光強度IG(490nm)與峰值波長的發光強度IG(Wp)之比值不小於0.3,即IG(490nm)/IG(Wp)≧0.3,藉此補強該第一螢光材料在 490nm波段附近發光強度較弱的部分,以使R12可以達到90以上。此外,該第二螢光材料之放射光波長主要分布於503-563nm之區間內,向下延伸至460nm,向上延伸至640nm,更進一步至700nm。再者,本實施例所採用的第三螢光材料之放射光波長主要分布於600-700nm之區間內,向下延伸至500nm,向上延伸至750nm,更進一步至800nm、半高寬(FWHM)大於100nm,且在580nm波長的發光強度IR(580nm)與峰值波長的發光強度IR(Wp)之比值不小於0.3,即IR(580nm)/IR(Wp)≧0.3,以增加第二螢光材料的放射光譜與第三螢光材料的放射光譜之間的重疊面積,減少兩個光譜的波峰之間的落差,藉此形成較連續且平坦的光譜,能使平均演色評價數Ra及特殊演色評價數R9至R15的值都大於90,提升整體的演色性。 The emission spectrum (Emission) of the fluorescent material used in this embodiment is shown in FIG. Since the color of the special color evaluation number R12 is a strong blue color, in order to effectively increase R12, the first fluorescent material, that is, the blue fluorescent powder, is added, and the full width at half maximum (FWHM) of the spectrum is also much larger than that. Generally, the blue chip is wide. Moreover, since the wavelength of the emitted light of the first fluorescent material is mainly distributed in the interval of 432-492 nm, extending downward to 410 nm, extending upward to 550 nm, and further to 600 nm, excitation light of 430 nm or less should be used, so The aforementioned light-emitting wafer 2 employs a near-UV wafer. It should be noted that the ratio of the luminous intensity I G (490 nm) of the second fluorescent material used in the embodiment to the luminous intensity I G (Wp) of the peak wavelength is not less than 0.3, that is, I G (490 nm). /I G (Wp) ≧ 0.3, thereby reinforcing the portion of the first fluorescent material that is weak in intensity near the 490 nm band, so that R12 can reach 90 or more. In addition, the wavelength of the emitted light of the second fluorescent material is mainly distributed in the interval of 503-563 nm, extends downward to 460 nm, and extends upward to 640 nm, and further to 700 nm. Furthermore, the wavelength of the emitted light of the third fluorescent material used in this embodiment is mainly distributed in the range of 600-700 nm, extending downward to 500 nm, extending upward to 750 nm, and further to 800 nm, full width at half maximum (FWHM). More than 100 nm, and the ratio of the luminous intensity I R (580 nm) at a wavelength of 580 nm to the luminous intensity I R (Wp) of the peak wavelength is not less than 0.3, that is, I R (580 nm) / I R (Wp) ≧ 0.3, to increase the number The overlapping area between the emission spectrum of the two fluorescent materials and the emission spectrum of the third fluorescent material reduces the difference between the peaks of the two spectra, thereby forming a relatively continuous and flat spectrum, enabling the average color rendering number Ra And the value of the special color evaluation number R9 to R15 is greater than 90, improving the overall color rendering.

該發光晶片2與該等螢光材料受激發光整體的混光光譜如圖4所示。在本實施例中,以多個樣品的光譜發光強度數值如表1所示,其中,IC(Wp)代表該發光晶片2的峰值波長發光強度、IB(Wp)代表該第一螢光材料的峰值波長發光強度、IG(Wp)代表該第二螢光材料的峰值波長發光強度及IR(Wp)代表該第三螢光材料的峰值波長發光強度,並以IB(Wp)之值為基準計算IC(Wp):IB(Wp):IG(Wp):IR(Wp)之比值,表中所列之比值A、B、C、D、E分別為不同樣品之測量值,估算比值範圍即IC(Wp):IB(Wp):IG(Wp):IR(Wp)約為3.4-5.2:1:1-1.6:1-1.5。 The light-mixing spectrum of the luminescent wafer 2 and the fluorescent material as a whole is shown in FIG. In the present embodiment, the spectral luminous intensity values of the plurality of samples are as shown in Table 1, wherein I C (Wp) represents the peak wavelength luminous intensity of the light-emitting wafer 2, and I B (Wp) represents the first fluorescent light. The peak wavelength luminescence intensity of the material, I G (Wp) represents the peak wavelength luminescence intensity of the second luminescent material, and I R (Wp) represents the peak wavelength luminescence intensity of the third luminescent material, and I B (Wp) The value is the ratio of I C (Wp): I B (Wp): I G (Wp): I R (Wp). The ratios A, B, C, D, and E listed in the table are different samples. The measured value, the estimated ratio range is I C (Wp): I B (Wp): I G (Wp): I R (Wp) is about 3.4-5.2:1:1-1.6:1-1.5.

以整體混光之色溫4875K為例,其平均演色評價數Ra及特殊演色評價數R9至R15的值都大於90,詳細數值如表2所示。 Taking the color temperature of the overall mixed light of 4875K as an example, the values of the average color rendering evaluation Ra and the special color rendering evaluation numbers R9 to R15 are all greater than 90, and the detailed numerical values are shown in Table 2.

參閱圖5,圖5為接近色溫5000K的參考光源的光譜圖,比較圖4與圖5可知,以波長450-470nm為第I區、470-520nm為第II區、520-530nm為第III區、530-580nm為第IV區、580-630nm為第V區,本實施例整體混光的光譜在各區間的波形分布趨勢與該參考光源的光譜在對應的區間的波形分布趨勢大致相同。此外,本實施態樣中,該白光發光裝置形成的整體混光的光譜於前述第III、IV、V區以連續且近乎平坦的波形分佈為較佳。 Referring to FIG. 5, FIG. 5 is a spectrum diagram of a reference light source with a color temperature close to 5000K. Comparing FIG. 4 with FIG. 5, it can be seen that the wavelength is 450-470 nm as the first region, 470-520 nm is the second region, and 520-530 nm is the third region. 530-580nm is the fourth region, and 580-630nm is the Vth region. In this embodiment, the waveform of the overall mixed light spectrum in each interval is substantially the same as the waveform distribution trend of the reference light source in the corresponding interval. Further, in the present embodiment, the spectrum of the overall mixed light formed by the white light-emitting device is preferably distributed in a continuous and nearly flat waveform in the III, IV, and V regions.

也就是說,在選擇本實施例中所欲使用的三種螢光粉時,可搭配參考光源的光譜的波形分布,三種螢光粉所建構的整體混光光譜要與該參考光源的光譜的波形分布趨勢大致相同。但值得注意的是,螢光粉整體混光光譜要與參考光源的光譜完全一致是有其相當難度的,故要達到較好演色評價數(Ra,R9-R15),兩者在前述五個區間中至少兩個區間的波形分布趨勢要大致相符;更進一步地說,若將前述第I、II區定義為第一群組,將前述第III、IV、V區定義為第二群組,螢光粉整體混光光譜在第一、第二群組中分別至少有一區的波形分布趨勢要與參考光源光譜在對應的區間的波形分布趨勢大致相同。 That is to say, when selecting the three kinds of phosphor powders to be used in the embodiment, the waveform distribution of the spectrum of the reference light source can be matched, and the overall mixed light spectrum constructed by the three kinds of phosphor powders and the spectrum waveform of the reference light source. The distribution trend is roughly the same. However, it is worth noting that the overall mixing spectrum of the phosphor powder is completely consistent with the spectrum of the reference source, so it is difficult to achieve a better color rendering number (Ra, R9-R15). The waveform distribution trend of at least two sections in the interval is substantially consistent; further, if the foregoing zones I and II are defined as the first group, the aforementioned zones III, IV, and V are defined as the second group, The overall mixed light spectrum of the phosphor powder has a waveform distribution tendency of at least one region in the first group and the second group to be substantially the same as a waveform distribution trend in a corresponding interval of the reference light source spectrum.

在本實施例中,該第一螢光材料為藍色螢光粉,以鋁酸鹽螢光粉較佳,如BAM螢光粉,具體採用化學式為BaMgAl10O17:Eu之螢光粉。該第二螢光材料為綠色螢光粉,以矽酸鹽(Silicate)螢光粉較佳,具體採用化學式為(Ba,Sr,Ca)2SiO4:Eu之螢光粉。該第三螢光材料為紅色螢光粉,以含有銪(Eu)賦活的氮化物(Nitride)以及氮氧化物(Oxynitride)螢光粉較佳,如CASN、SCASN或CASON螢光粉,具體採用化學式為CaAlSi(ON)3:Eu之螢光粉。 In this embodiment, the first fluorescent material is blue fluorescent powder, and the aluminate fluorescent powder is preferably used, such as BAM fluorescent powder, specifically using a fluorescent powder of BaMgAl10O17:Eu. The second fluorescent material is a green fluorescent powder, and a silicic fluorescent powder is preferably used, specifically a fluorescent powder of the formula (Ba, Sr, Ca) 2 SiO 4 :Eu. The third fluorescent material is a red fluorescent powder, preferably a Nitrix-activated nitride (Nitride) and an oxynitride (Oxynitride) phosphor, such as CASN, SCASN or CASON phosphor, specifically The chemical formula is a CaAlSi(ON)3:Eu phosphor.

其中,以圖1為例的白光發光裝置,該第一螢光材料、該第二螢光材料與該第三螢光材料的混合比例為8:1:2,而且該等螢光材料總合與該膠體的比例,以重量百分比計為20.5wt%。 Wherein, in the white light emitting device exemplified in FIG. 1 , the mixing ratio of the first fluorescent material, the second fluorescent material and the third fluorescent material is 8:1:2, and the fluorescent materials are combined. The ratio to the colloid was 20.5 wt% in terms of weight percent.

參閱圖6與圖7,本發明白光發光裝置之第二實 施例,與第一實施例結構大致相同,惟,在本實施例中,該第一螢光材料、該第二螢光材料與該第三螢光材料混合形成整體混光之色溫2733K。如圖6所示為第二實施例整體混光之光譜圖,圖7為色溫2700K的參考光源的光譜圖,比較圖6與圖7可知,以波長450-470nm為第I區、470-520nm為第II區、520-530nm為第III區、530-580nm為第IV區、580-630nm為第V區,本實施例整體混光的光譜在各局部區間波形分布與該參考光源的光譜在對應的局部區間波形分布趨勢大致相同。同樣地,本實施例之平均演色評價數Ra及特殊演色評價數R9至R15的值都大於90,詳細數值如表3所示。 Referring to FIG. 6 and FIG. 7, the second embodiment of the white light emitting device of the present invention The embodiment is substantially the same as the structure of the first embodiment. However, in the embodiment, the first phosphor material, the second phosphor material and the third phosphor material are mixed to form a color temperature of 2733 K for overall mixed light. FIG. 6 is a spectrum diagram of the overall mixed light of the second embodiment, and FIG. 7 is a spectrum diagram of a reference light source with a color temperature of 2700 K. Comparing FIG. 6 with FIG. 7 , the wavelength of 450-470 nm is the first region, 470-520 nm. For the second region, 520-530nm is the third region, 530-580nm is the fourth region, and 580-630nm is the V region. In this embodiment, the spectrum of the overall mixed light is distributed in each local interval and the spectrum of the reference light source is The corresponding local interval waveform distribution trends are approximately the same. Similarly, the values of the average color rendering evaluation Ra and the special color rendering evaluation numbers R9 to R15 of the present embodiment are all greater than 90, and the detailed numerical values are shown in Table 3.

參閱圖8,本發明白光發光裝置之第三實施例包含一導線架11與一環繞該導線架11的外框12結合之基座1,該外框12與該導線架11共同界定一容置空間13,一發光晶片2設於該導線架11且位於該容置空間13內,一螢光體層3填充於該容置空間13並覆蓋該發光晶片2上。惟,在本實施例中,該基座1大致呈方形,該容置空間13大致呈圓形。再者,該螢光體層3的該等螢光材料總 合與該膠體的比例,以重量百分比計為50至70wt%。亦能達到與第一實施例相同的演色性。由不同的封裝態樣大致可以歸納該螢光體層3的該等螢光材料總合與該膠體的比例可用以下數學式表示:y=-20.11ln(x)+43.067,其中x代表該螢光體層3的總體積,y代表該等螢光材料總合的重量百分比。 Referring to FIG. 8, a third embodiment of the white light emitting device of the present invention comprises a lead frame 11 and a base 1 coupled to the outer frame 12 of the lead frame 11. The outer frame 12 and the lead frame 11 define an accommodation. A luminescent substrate 2 is disposed in the accommodating space 13 and a phosphor layer 3 is filled in the accommodating space 13 and covers the luminescent wafer 2. However, in this embodiment, the susceptor 1 is substantially square, and the accommodating space 13 is substantially circular. Furthermore, the total amount of the phosphor materials of the phosphor layer 3 The ratio of the colloid to the colloid is from 50 to 70% by weight. The same color rendering as in the first embodiment can also be achieved. The ratio of the sum of the phosphor materials of the phosphor layer 3 to the colloid can be roughly represented by different package patterns by the following mathematical expression: y=-20.11ln(x)+43.067, where x represents the fluorescence The total volume of the body layer 3, y represents the weight percentage of the total of the phosphor materials.

除前述實施例之外,螢光體層也可以只含有該等螢光材料且直接形成於晶片表面,或者形成於封裝膠體外表層或外置的光學結構內外表層而形成遠距螢光體層(Remote phosphor)的型態。 In addition to the foregoing embodiments, the phosphor layer may also contain only the phosphor materials and be formed directly on the surface of the wafer, or formed on the outer surface of the outer surface of the encapsulant or the outer surface of the outer optical structure to form a remote phosphor layer (Remote). The type of phosphor).

綜上所述,本發明藉由近紫外光(near-UV)晶片搭配三種分別具有特定發光波長及光譜的螢光材料,可使整體混光之色溫在5000K以下且演色性達到平均演色評價數Ra及特殊演色評價數R9至R15的值都大於90之高演色性,故確實能達成本發明之目的。 In summary, the present invention allows a near-ultraviolet (near-UV) wafer to be combined with three kinds of phosphor materials having specific emission wavelengths and spectra, so that the color temperature of the overall mixed light is below 5000K and the color rendering performance reaches the average color rendering number. The values of Ra and the special color rendering number R9 to R15 are both greater than the color rendering property of 90, so that the object of the present invention can be achieved.

惟以上所述者,僅為本發明之實施例而已,當不能以此限定本發明實施之範圍,即大凡依本發明申請專利範圍及專利說明書內容所作之簡單的等效變化與修飾,皆仍屬本發明專利涵蓋之範圍內。 However, the above is only the embodiment of the present invention, and the scope of the present invention is not limited thereto, that is, the simple equivalent changes and modifications made by the patent application scope and the patent specification of the present invention are still It is within the scope of the patent of the present invention.

Claims (13)

一種白光發光裝置,包含:一發光晶片,可發出波長介於390至430nm的光;及一螢光體層,包括一第一螢光材料,可被激發出波峰波長介於450至470nm的光,一第二螢光材料,可被激發出波峰波長介於520至530nm的光,且在490nm波長的發光強度IG(490nm)與峰值波長的發光強度IG(Wp)之比值不小於0.3,即IG(490nm)/IG(Wp)≧0.3,及一第三螢光材料,可被激發出波峰波長介於630至650nm的光,且在580nm波長的發光強度IR(580nm)與峰值波長的發光強度IR(Wp)之比值不小於0.3,即IR(580nm)/IR(Wp)≧0.3;該白光發光裝置形成之整體混光的色溫在5000K以下且平均演色評價數Ra及特殊演色評價數R9至R15的值都大於90。 A white light emitting device comprising: an illuminating wafer emitting light having a wavelength of 390 to 430 nm; and a phosphor layer comprising a first fluorescent material capable of exciting light having a peak wavelength of 450 to 470 nm, a second fluorescent material capable of being excited to emit light having a peak wavelength of 520 to 530 nm, and a ratio of an emission intensity I G (490 nm) at a wavelength of 490 nm to an emission intensity I G (Wp) of a peak wavelength is not less than 0.3, That is, I G (490 nm) / I G (Wp) ≧ 0.3, and a third fluorescent material, can be excited to emit light having a peak wavelength of 630 to 650 nm, and the luminous intensity I R (580 nm) at a wavelength of 580 nm and The ratio of the luminous intensity I R (Wp) of the peak wavelength is not less than 0.3, that is, I R (580 nm) / I R (Wp) ≧ 0.3; the color temperature of the overall mixed light formed by the white light emitting device is 5000 K or less and the average color rendering number is The values of Ra and special color evaluation numbers R9 to R15 are both greater than 90. 如請求項1所述的白光發光裝置,其中,該發光晶片的峰值波長發光強度IC(Wp)、該第一螢光材料的峰值波長發光強度IB(Wp)、該第二螢光材料的峰值波長發光強度IG(Wp)及該第三螢光材料的峰值波長發光強度IR(Wp)之比值為:IC(Wp):IB(Wp):IG(Wp):IR(Wp)=3.4-5.2:1:1-1.6:1-1.5。 The white light emitting device according to a request item 1, wherein the intensity peak wavelength of emission of the light emitting chip I C (Wp), the peak wavelength of emission intensity of the first fluorescent material I B (Wp), the second fluorescent material The ratio of the peak wavelength luminous intensity I G (Wp) to the peak wavelength luminous intensity I R (Wp) of the third fluorescent material is: I C (Wp): I B (Wp): I G (Wp): I R (Wp) = 3.4 - 5.2: 1:1 - 1.6: 1-1.5. 如請求項1所述的白光發光裝置,其中,該第三螢光材料發出的光之半高寬(FWHM)大於100nm。 The white light emitting device of claim 1, wherein the third phosphor material emits a full width at half maximum (FWHM) of greater than 100 nm. 如請求項1所述的白光發光裝置,其中,該第一螢光材料為鋇鋁酸鹽螢光粉、該第二螢光材料為矽酸鹽螢光粉及該第三螢光材料為含有銪賦活的氮化物螢光粉或氮氧化物螢光粉。 The white light emitting device of claim 1, wherein the first fluorescent material is yttrium aluminate phosphor, the second fluorescent material is bismuth silicate powder, and the third fluorescent material is contained An active nitride phosphor or oxynitride phosphor. 如請求項1至4其中任一項所述的白光發光裝置,還包含一基座,且該基座具有一導線架及一與該導線架結合的外框,該外框與該導線架共同界定一容置空間,該發光晶片設於該導線架且位於該容置空間內,該螢光體層還包括一膠體且填充於該容置空間並覆蓋該發光晶片。 The white light emitting device of any one of claims 1 to 4, further comprising a base, the base having a lead frame and an outer frame coupled to the lead frame, the outer frame being common with the lead frame An illuminating chip is disposed on the lead frame and located in the accommodating space. The phosphor layer further includes a colloid and is filled in the accommodating space and covers the illuminating wafer. 如請求項5所述的白光發光裝置,其中,該螢光體層的該等螢光材料總合與該膠體的比例可用以下數學式表示:y=-20.11ln(x)+43.067,其中x代表該螢光體層的總體積,y代表該等螢光材料總合的重量百分比。 The white light emitting device of claim 5, wherein the ratio of the sum of the phosphor materials of the phosphor layer to the colloid is represented by the following mathematical formula: y=-20.11ln(x)+43.067, where x represents The total volume of the phosphor layer, y represents the weight percent of the total of the phosphor materials. 一種白光發光裝置,包含:一發光晶片,可發出波長介於390至430nm的光;及一螢光體層,包括一第一螢光材料,可被激發出波峰波長介於450至470nm的光,一第二螢光材料,可被激發出波峰波長介於520至530nm的光,及一第三螢光材料,可被激發出波峰波長介於 630至650nm的光;以波長450-470nm為第I區、470-520nm為第II區、520-530nm為第III區、530-580nm為第IV區、580-630nm為第V區,該白光發光裝置形成之整體混光的光譜在前述波長區間中至少有兩區的波形分布趨勢與其對應色溫的參考光源的光譜在對應的區間的波形分布趨勢相同,使得色溫在5000K以下且平均演色評價數Ra及特殊演色評價數R9至R15的值都大於90。 A white light emitting device comprising: an illuminating wafer emitting light having a wavelength of 390 to 430 nm; and a phosphor layer comprising a first fluorescent material capable of exciting light having a peak wavelength of 450 to 470 nm, a second phosphor material that is excited to emit light having a peak wavelength between 520 and 530 nm, and a third phosphor material that is excited to have a peak wavelength between Light of 630 to 650 nm; the first region with a wavelength of 450-470 nm, the second region with 470-520 nm, the third region with 520-530 nm, the fourth region with 530-580 nm, and the V region with 580-630 nm, the white light The spectrum of the overall mixed light formed by the illuminating device has the same waveform distribution tendency of at least two regions in the aforementioned wavelength interval and the spectrum of the reference light source corresponding to the color temperature in the corresponding interval, so that the color temperature is below 5000K and the average color rendering number is The values of Ra and special color evaluation numbers R9 to R15 are both greater than 90. 如請求項7所述的白光發光裝置,其中,將前述第I、II區定義為第一群組,將前述第III、IV、V區定義為第二群組,該白光發光裝置形成之整體混光光譜在該第一、第二群組中分別至少有一區的波形分布趨勢與該參考光源光譜在對應的區間的波形分布趨勢相同。 The white light emitting device according to claim 7, wherein the first and second regions are defined as a first group, and the third, fourth, and fourth regions are defined as a second group, and the white light emitting device is formed as a whole. The waveform of the mixed light spectrum in at least one of the first and second groups has the same waveform distribution tendency as the reference light source spectrum in the corresponding interval. 一種白光發光裝置,包含:一發光晶片,可發出波長介於390至430nm的光;及一螢光體層,包括一藍色螢光粉,化學式為BaMgAl10O17:Eu,及一紅色螢光粉,化學式為CaAlSi(ON)3:Eu;該白光發光裝置形成之整體混光的色溫在5000K以下且平均演色評價數Ra及特殊演色評價數R9至R15的值都大於90。 A white light emitting device comprising: a light emitting chip emitting light having a wavelength of 390 to 430 nm; and a phosphor layer comprising a blue phosphor, a chemical formula of BaMgAl 10 O 17 :Eu, and a red fluorescent The powder has a chemical formula of CaAlSi(ON) 3 :Eu; the color temperature of the overall mixed light formed by the white light emitting device is 5000 K or less, and the values of the average color rendering evaluation Ra and the special color rendering evaluation numbers R9 to R15 are both greater than 90. 如請求項9所述的白光發光裝置,其中,該螢光體層還包括一綠色螢光粉,化學式為(Ba,Sr,Ca)2SiO4:Eu。 The white light emitting device of claim 9, wherein the phosphor layer further comprises a green phosphor having a chemical formula of (Ba, Sr, Ca) 2 SiO 4 :Eu. 如請求項10所述的白光發光裝置,其中,該藍色螢光粉、該綠色螢光粉與該紅色螢光粉的混合比例為8:1:2。 The white light emitting device of claim 10, wherein the mixing ratio of the blue phosphor powder, the green phosphor powder and the red phosphor powder is 8:1:2. 如請求項9至11其中任一項所述的白光發光裝置,還包含一基座,且該基座具有一導線架及一與該導線架結合的外框,該外框與該導線架共同界定一容置空間,該發光晶片設於該導線架且位於該容置空間內,該螢光體層還包括一膠體且填充於該容置空間並覆蓋該發光晶片。 The white light emitting device of any one of claims 9 to 11, further comprising a pedestal, the pedestal having a lead frame and an outer frame combined with the lead frame, the outer frame being common with the lead frame An illuminating chip is disposed on the lead frame and located in the accommodating space. The phosphor layer further includes a colloid and is filled in the accommodating space and covers the illuminating wafer. 如請求項12所述的白光發光裝置,其中,該螢光體層的該等螢光材料總合與該膠體的比例可用以下數學式表示:y=-20.11ln(x)+43.067,其中x代表該螢光體層的總體積,y代表該等螢光材料總合的重量百分比。 The white light emitting device of claim 12, wherein the ratio of the sum of the phosphor materials of the phosphor layer to the colloid is represented by the following mathematical expression: y=-20.11ln(x)+43.067, where x represents The total volume of the phosphor layer, y represents the weight percent of the total of the phosphor materials.
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