CN108922955A - A kind of light source module group and the lighting device including the light source module group - Google Patents

Abstract

Translated fromChinese

一种光源模组和使用所述光源模组的照明装置，光源模组包括包括第一发光元件和覆盖于第一发光元件的封装部，封装部中包括第一附加发光体、第二附加发光体、第三附加发光体，各发光体发出的光混合成暖白光，作为光源模组的发射光。本发明所提供的光源模组在通过控制对CS值影响最大的495~560nm波长区域内发光能量在总发光能量中的占比，提供了一种同时具有高光效、高CS值、高显色性的LED中性白光(4000K)光源。这种高CS值的光谱，在相同照度下，特别适合人集中注意力进行学习和工作。

A light source module and a lighting device using the light source module. The light source module includes a first light-emitting element and an encapsulation part covering the first light-emitting element. The encapsulation part includes a first additional illuminant, a second additional light-emitting body, the third additional illuminant, the light emitted by each illuminant is mixed into warm white light, which is used as the emitted light of the light source module. The light source module provided by the present invention controls the proportion of luminous energy in the total luminous energy in the 495-560nm wavelength region that has the greatest impact on the CS value, providing a light source module with high luminous efficacy, high CS value, and high color rendering. LED neutral white light (4000K) light source. This kind of spectrum with high CS value is especially suitable for people to concentrate on studying and working under the same illuminance.

Description

Translated fromChinese

一种光源模组及包括该光源模组的照明装置A light source module and a lighting device including the light source module

技术领域technical field

本发明涉及一种光源模组及包括该光源模组的照明装置。The invention relates to a light source module and a lighting device including the light source module.

背景技术Background technique

随着第三次照明技术革命的到来和发展，白炽灯、卤素灯等由于光效低、不节能已经逐渐被世界各国禁止生产和销售，LED照明器具取而代之已被广泛的使用。现有的LED照明产品主要解决的是节能、照度、颜色和显色性问题。在使用LED照明产品时，越来越多的人们关注到LED中的蓝光较多，可能会对人体的生理节律产生影响。对于照明产品对人体的生理节律产生影响，我们可以通过昼夜刺激(Circadian StimuIus)评价模型来进行评价，即业内所说的CS值，高CS值的光谱，在相同照度下，特别适合人集中注意力进行学习和工作。当前市场上缺乏在兼顾节能、照度、颜色和显色性的同时，可以进一步考虑光对人体生理节律影响的，具有高CS值的LED照明产品。With the advent and development of the third lighting technology revolution, the production and sale of incandescent lamps and halogen lamps have been gradually banned by countries all over the world due to their low light efficiency and lack of energy saving. LED lighting appliances have been widely used instead. Existing LED lighting products mainly solve the problems of energy saving, illuminance, color and color rendering. When using LED lighting products, more and more people are concerned that there is more blue light in LEDs, which may affect the circadian rhythm of the human body. For the impact of lighting products on the circadian rhythm of the human body, we can use the Circadian StimuIus evaluation model to evaluate, that is, the CS value referred to in the industry. The spectrum with high CS value is especially suitable for people to concentrate on the same illuminance. to study and work. The current market lacks LED lighting products with high CS values that can further consider the impact of light on the human body's circadian rhythm while taking into account energy saving, illuminance, color and color rendering.

发明内容Contents of the invention

本发明的目的是为了解决上述问题，寻找一种高CS值、高显色性，同时具有高光效的LED白光光源。The object of the present invention is to solve the above problems and find an LED white light source with high CS value, high color rendering and high light efficiency.

本发明为实现上述功能，所采用的技术方案是提供一种光源模组，其特征在于，包括第一发光元件和覆盖于第一发光元件的封装部，In order to realize the above functions, the technical solution adopted by the present invention is to provide a light source module, which is characterized in that it includes a first light-emitting element and a packaging part covering the first light-emitting element,

所述第一发光元件发出峰值波长位于435~465nm的第一颜色光；The first light-emitting element emits first color light with a peak wavelength at 435-465nm;

所述封装部包括：The package includes:

第一附加发光体，所述第一附加发光体被布置为接收所述第一发光元件所发射的部分光线，并将其转换为峰值波长位于485~520nm的第二颜色光；A first additional luminous body, the first additional luminous body is arranged to receive part of the light emitted by the first light-emitting element, and convert it into a second color light with a peak wavelength of 485-520 nm;

第二附加发光体，所述第二附加发光体被布置为接收所述第一发光元件所发射的部分光线，并将其转换为峰值波长位于530~580nm的第三颜色光；A second additional luminous body, the second additional luminous body is arranged to receive part of the light emitted by the first light emitting element, and convert it into a third color light with a peak wavelength of 530-580 nm;

第三附加发光体，所述第三附加发光体被布置为接收所述第一发光元件所发射的部分光线，并将其转换为峰值波长位于605~645nm的第四颜色光，a third additional luminous body, the third additional luminous body is arranged to receive part of the light emitted by the first light-emitting element, and convert it into light of a fourth color with a peak wavelength of 605-645 nm,

所述第一颜色、第二颜色光、第三颜色光和第四颜色光混合形成所述光源模组的发射光，所述发射光为中性白光，即所述发射光在CIE1931色空间上，位于相关色温4000±280K与黑体轨迹的距离duv= -0.006~0.006的点围成的区间内，The first color, the second color light, the third color light and the fourth color light are mixed to form the emitted light of the light source module, and the emitted light is neutral white light, that is, the emitted light is in the CIE1931 color space , located in the interval surrounded by points with a correlated color temperature of 4000±280K and the distance duv= -0.006~0.006 from the blackbody locus,

所述发射光的光谱在380~780nm可见光范围光谱连续分布，定义光谱中相邻两点的光谱强度相对偏差值ΔI，The spectrum of the emitted light is continuously distributed in the visible light range of 380~780nm, and the relative deviation value ΔI of the spectral intensity between two adjacent points in the spectrum is defined,

其中Intensit（i）、Intensit（i+1）分别表示光谱中波长差为步长I的两点的光谱强度，1nm≤I≤5nm，Among them, Intensit(i) and Intensit(i+1) respectively represent the spectral intensity of two points in the spectrum whose wavelength difference is the step size I, 1nm≤I≤5nm,

所述发射光光谱包括两个波峰、一个峰谷和一个稳定分布区间：The emitted light spectrum includes two peaks, a peak valley and a stable distribution interval:

第一峰位于435~465nm波长区域内；The first peak is located in the wavelength region of 435~465nm;

第二峰位于605~645nm波长区域内，所述第二峰的光谱强度和所述第一峰的光谱强度的比值在70%~130%之间；The second peak is located in the 605-645nm wavelength region, and the ratio of the spectral intensity of the second peak to the spectral intensity of the first peak is between 70% and 130%;

峰谷位于455~485nm波长区域内，所述峰谷的光谱强度和所述第一峰的光谱强度的比值大于等于25%，且峰谷向长波方向的宽度小于等于30nm，定义峰谷长波方向结束点为由峰谷位置向长波方向出现的第一个ΔI≤2%时相邻两点中靠近峰谷的点，所述峰谷向长波方向的宽度指峰谷长波方向结束点和峰谷之间的波长差；The peak and valley are located in the 455-485nm wavelength region, the ratio of the spectral intensity of the peak and valley to the spectral intensity of the first peak is greater than or equal to 25%, and the width of the peak and valley to the long-wave direction is less than or equal to 30nm, defining the peak-valley long-wave direction The end point is the point close to the peak valley among the two adjacent points when the first ΔI≤2% appears from the peak valley position to the long wave direction, and the width of the peak valley to the long wave direction refers to the end point of the peak valley long wave direction and the peak valley The wavelength difference between;

稳定分布区间为495~560nm波长区域，所述稳定分布区间中任意一点的光谱强度和所述第一峰的光谱强度的比值在60~80%之间，且其中任意相邻两点的ΔI不大于1.5%。The stable distribution interval is the 495-560nm wavelength region, the ratio of the spectral intensity of any point in the stable distribution interval to the spectral intensity of the first peak is between 60-80%, and the ΔI of any two adjacent points is not Greater than 1.5%.

优选的，所述第二峰的光谱强度和所述第一峰的光谱强度的比值在80%~110%之间。Preferably, the ratio of the spectral intensity of the second peak to the spectral intensity of the first peak is between 80% and 110%.

优选的，所述峰谷的光谱强度和所述第一峰的光谱强度的比值在30%~60%之间。Preferably, the ratio of the spectral intensity of the peak valley to the spectral intensity of the first peak is between 30% and 60%.

4、如权利要求1所述的光源模组，其特征在于，所述稳定分布区间中任意相邻两点的ΔI不大于0.8%。4. The light source module according to claim 1, wherein the ΔI of any two adjacent points in the stable distribution interval is not greater than 0.8%.

优选的，所述第一发光元件为发射光峰值波长在435~465nm的蓝光LED；所述第一附加发光体为峰值波长在485~520nm，半宽度25~65nm的蓝绿色荧光粉；所述第二附加发光体为包括黄色荧光粉和绿色荧光粉的黄绿色荧光粉组合，其中包含至少一种峰值波长大于540nm的黄色荧光粉和至少一种峰值波长小于540的绿色荧光粉，所述黄绿色荧光粉组合的峰值波长在530~580nm，半宽度60~115nm；所述第三附加发光体为峰值波长在605~645nm，半宽度80~120nm的红色或橙色荧光粉。Preferably, the first light-emitting element is a blue LED emitting light with a peak wavelength of 435-465nm; the first additional luminous body is a blue-green phosphor with a peak wavelength of 485-520nm and a half-width of 25-65nm; The second additional luminous body is a yellow-green fluorescent powder combination including yellow fluorescent powder and green fluorescent powder, which contains at least one yellow fluorescent powder with a peak wavelength greater than 540 nm and at least one green fluorescent powder with a peak wavelength smaller than 540 nm. The peak wavelength of the green phosphor combination is 530-580nm, and the half-width is 60-115nm; the third additional luminous body is a red or orange phosphor with a peak wavelength of 605-645nm, and a half-width of 80-120nm.

优选的，定义所述蓝绿色荧光粉、所述黄绿色荧光粉组合、所述红色或橙色荧光粉的重量之和为总荧光粉重量，所述总荧光粉重量在所述封装部中的占比为25.0%~50.0%。Preferably, the sum of the weights of the blue-green phosphor, the combination of yellow-green phosphors, and the red or orange phosphor is defined as the total phosphor weight, and the proportion of the total phosphor weight in the packaging part is The ratio is 25.0%~50.0%.

优选的，所述蓝绿色荧光粉为下述荧光粉中的任意一种或两种以上混合而成：Preferably, the blue-green phosphor is any one or a mixture of two or more of the following phosphors:

(a)氮氧化物，Eu²⁺为激活剂(a) Nitrogen oxides, Eu²⁺ as activator

化学组成通式：(Ba,Ca)_1-xSi₂N₂O₂:Eu_xGeneral formula of chemical composition: (Ba,Ca)_1-x Si₂ N₂ O₂ :Eu_x

其中x=0.005~0.200；where x=0.005~0.200;

(b)掺Ga石榴石荧光粉，Eu²⁺为激活剂(b) Ga-doped garnet phosphor with Eu²⁺ as the activator

化学组成通式：Ga-LuAG:Eu；General formula of chemical composition: Ga-LuAG:Eu;

(c)硅酸盐荧光粉，Eu²⁺为激活剂(c) Silicate phosphor, Eu²⁺ as activator

化学组成通式：Ba₂SiO₄:Eu。General formula of chemical composition: Ba₂ SiO₄ :Eu.

优选的，所述蓝绿色荧光粉在所述总荧光粉重量中的占比为15.0~40.0%。Preferably, the proportion of the blue-green phosphor in the total phosphor weight is 15.0-40.0%.

优选的，所述黄色荧光粉/绿色荧光粉为下述荧光粉中的任意一种或两种以上混合而成：Preferably, the yellow phosphor/green phosphor is any one or a mixture of two or more of the following phosphors:

(a)石榴石结构荧光粉，Ce³⁺为激活剂(a) Garnet structure phosphor, Ce³⁺ as activator

化学组成通式：(M4)_3-x(M5)₅O₁₂:Ce_xGeneral formula of chemical composition: (M4)_3-x (M5)₅ O₁₂ :_Cex

其中M4为Y、Lu、Gd及La中至少一种元素，M5为Al、Ga中至少一种元素，x=0.005~0.200；Wherein M4 is at least one element among Y, Lu, Gd and La, M5 is at least one element among Al and Ga, x=0.005~0.200;

(b)硅酸盐体系荧光粉，Eu²⁺为激活剂(b) Silicate system phosphor, Eu²⁺ is the activator

化学组成通式：(M6)_2-xSiO₄：Eu_xGeneral formula of chemical composition: (M6)_2-x SiO₄ : Eu_x

或 (Ba,Ca,Sr)_2-x(Mg,Zn)Si₂O₇:Eu_xor (Ba,Ca,Sr)_2-x (Mg,Zn)Si₂ O₇ :Eu_x

其中M6为Mg、Sr、Ca、Ba中至少一种元素，x=0.01~0.20；Where M6 is at least one element of Mg, Sr, Ca, Ba, x=0.01~0.20;

(c)氮氧化物荧光粉 (塞隆体β-SiAlON)，Eu²⁺为激活剂(c) Oxynitride phosphor (Sialon β-SiAlON), Eu²⁺ is the activator

化学组成通式：Si_bAl_cO_dN_e：Eu_xGeneral formula of chemical composition: Si_b Al_c O_dNe : Eu_x

其中x=0.005~0.400，b+c=12，d+e=16；Where x=0.005~0.400, b+c=12, d+e=16;

(d)铝酸盐体系荧光粉，Eu²⁺为激活剂(d) Aluminate system phosphor, Eu²⁺ is the activator

化学组成通式：(Sr,Ba)_2-xAl₂O₄:Eu_xGeneral formula of chemical composition: (Sr,Ba)_2-x Al₂ O₄ :Eu_x

或 (Sr,Ba)_4-xAl₁₄O₂₅：Eu_xOr (Sr,Ba)_4-x Al₁₄ O₂₅ : Eu_x

其中x=0.01~0.15。where x=0.01~0.15.

优选的，所述黄绿色荧光粉组合在所述总荧光粉重量中的占比为25.0%~55.0%。Preferably, the yellow-green phosphor combination accounts for 25.0%-55.0% of the total phosphor weight.

优选的，所述红色或橙色荧光粉为下述荧光粉中的任意一种或两种以上混合而成：Preferably, the red or orange phosphor is any one or a mixture of two or more of the following phosphors:

(a)具有1113晶体结构的氮化物红粉，Eu²⁺为激活剂(a) Nitride red powder with 1113 crystal structure, Eu²⁺ as activator

化学组成通式：(M1)_1-xAlSiN₃:Eu_xGeneral formula of chemical composition: (M1)_1-x AlSiN₃ :Eu_x

其中M1为Ca、Sr、Ba中至少一种元素，x=0.005~0.300；Where M1 is at least one element among Ca, Sr and Ba, x=0.005~0.300;

(b)具有258晶体结构的氮化物红粉，Eu²⁺为激活剂(b) Nitride red powder with 258 crystal structure, Eu²⁺ as activator

化学组成通式：(M2)_2-xSi₅N₈：Eu_xGeneral formula of chemical composition: (M2)_2-x Si₅ N₈ : Eu_x

其中M2为Ca、Sr、Ba、Mg中至少一种元素，x=0.005~0.300；Where M2 is at least one element among Ca, Sr, Ba, Mg, x=0.005~0.300;

(c)氮氧化物荧光粉(塞隆体α-SiAlON)，Eu²⁺为激活剂(c) Oxynitride phosphor (Sialon α-SiAlON), Eu²⁺ is the activator

化学组成通式：((M3)_1-a)_xSi_bAl_cO_dN_e:Eu_aGeneral formula of chemical composition: ((M3)_1-a )_x Si_b Al_c O_dNe :Eu_a

其中M3为Li、Na、K、Rb、Cs、Sr、Ba、Sc、Y、La、Gd之中至少一种元素，x=0.15~1.5，a=0.005~0.300， b+c=12，d+e=16；Where M3 is at least one element among Li, Na, K, Rb, Cs, Sr, Ba, Sc, Y, La, Gd, x=0.15~1.5, a=0.005~0.300, b+c=12, d +e=16;

(d)硅酸盐荧光粉，Eu²⁺为激活剂(d) Silicate phosphor, Eu²⁺ as activator

化学组成通式：(Sr,Ba)_3-xSi₅O₅:Eu_xGeneral formula of chemical composition: (Sr,Ba)_3-x Si₅ O₅ :Eu_x

其中x=0.005~0.300。where x=0.005~0.300.

优选的，所述红色或橙色荧光粉在在所述总荧光粉重量中的占比为10.0%~40.0%。Preferably, the red or orange phosphor accounts for 10.0%-40.0% of the total phosphor weight.

优选的，所述黄绿色荧光粉组合的发射光半宽度为90~115nm。Preferably, the half-width of emitted light of the combination of yellow-green phosphors is 90-115 nm.

优选的，所述封装部还包括基底材料和光扩散剂，所述基底材料为硅胶或树脂，所述光扩散剂为纳米级氧化钛、氧化铝或氧化硅中的一种。Preferably, the encapsulation part further includes a base material and a light diffusing agent, the base material is silica gel or resin, and the light diffusing agent is one of nanoscale titanium oxide, aluminum oxide or silicon oxide.

优选的，所述光源模组发射光的光色在CIE1931色空间上，位于由D1(0.3991,0.4012)、D2(0.3722,0.3843)、D3(0.3658,0.3550)、D4(0.3885,0.3688)四个顶点围成的四边形区域内。Preferably, the light color of the light emitted by the light source module is located in the CIE1931 color space, which is composed of D1 (0.3991, 0.4012), D2 (0.3722, 0.3843), D3 (0.3658, 0.3550), and D4 (0.3885, 0.3688). within the quadrilateral bounded by vertices.

优选的，所述光源模组发射光的光色在CIE1931色空间上，位于中心点x0=0.3805，y0=0.3768，长轴a=0.00313，短轴b=0.00134，倾角θ=54.0°，SDCM=5.0的椭圆范围内。Preferably, the light color of the light emitted by the light source module is on the CIE1931 color space, located at the center point x0=0.3805, y0=0.3768, the long axis a=0.00313, the short axis b=0.00134, the inclination angle θ=54.0°, SDCM= 5.0 within the ellipse.

优选的，所述光源模组的发射光在照度500lux时，CS值≥0.34。Preferably, the emitted light of the light source module has a CS value ≥ 0.34 when the illuminance is 500 lux.

优选的，所述光源模组的发射光的显色指数CRI≥90.0，R9≥85.0。Preferably, the color rendering index CRI≥90.0 and R9≥85.0 of the emitted light of the light source module.

本发明还提供一种照明装置，包括上述光源模组。The present invention also provides an illuminating device, comprising the above-mentioned light source module.

本发明所提供的光源模组在通过控制对CS值影响最大的495~560nm波长区域内发光能量在总发光能量中的占比，提供了一种同时具有高光效、高CS值、高显色性的LED中性白光(4000K)光源。这种高CS值的光谱，在相同照度下，特别适合人集中注意力进行学习和工作。The light source module provided by the present invention controls the proportion of luminous energy in the total luminous energy in the 495-560nm wavelength region that has the greatest impact on the CS value, providing a light source module with high luminous efficiency, high CS value, and high color rendering. LED neutral white light (4000K) light source. This kind of spectrum with high CS value is especially suitable for people to concentrate on studying and working under the same illuminance.

附图说明Description of drawings

图1是符合本发明优选实施例的光源模组的结构示意图；Fig. 1 is a schematic structural diagram of a light source module according to a preferred embodiment of the present invention;

图2是符合本发明优选实施例的光源模组的光谱特征示意图；Fig. 2 is a schematic diagram of the spectral characteristics of the light source module according to the preferred embodiment of the present invention;

图3是符合本发明的优选实施例1~8的CIE1931色坐标图；Fig. 3 is the CIE1931 chromatic coordinate figure that accords with preferred embodiment 1～8 of the present invention;

图4是本发明中优选实施例1的发射光光谱图；Fig. 4 is the emission spectrogram of preferred embodiment 1 in the present invention;

图5是本发明中优选实施例2的发射光光谱图；Fig. 5 is the emission spectrogram of preferred embodiment 2 in the present invention;

图6是本发明中优选实施例3的发射光光谱图；Fig. 6 is the emission spectrogram of preferred embodiment 3 in the present invention;

图7是本发明中优选实施例4的发射光光谱图；Fig. 7 is the emission spectrogram of preferred embodiment 4 in the present invention;

图8是本发明中优选实施例5的发射光光谱图；Fig. 8 is the emission spectrogram of preferred embodiment 5 in the present invention;

图9是本发明中优选实施例6的发射光光谱图；Fig. 9 is the emission spectrum figure of preferred embodiment 6 in the present invention;

图10是本发明中优选实施例7的发射光光谱图；Fig. 10 is the emission spectrum figure of preferred embodiment 7 in the present invention;

图11是本发明中优选实施例8的发射光光谱图。Fig. 11 is a spectrum diagram of the emitted light of the preferred embodiment 8 of the present invention.

具体实施方式Detailed ways

以下结合附图和一些符合本发明的优选实施例对本发明提出的一种光源模组及照明装置作进一步详细的说明。A light source module and lighting device proposed by the present invention will be further described in detail below with reference to the accompanying drawings and some preferred embodiments in accordance with the present invention.

如图1所示，本发明提供的光源模组L1是一种光源产品，其可应用于照明装置（未图示）中用以提供日常照明。照明装置可以是台灯、吊灯、吸顶灯、筒灯、射灯等各类灯具，照明装置包括光源模组L1和向光源模组L1提供工作所需电力的电源模组，照明装置还可以根据具体灯具的功能、需求带有控制器、散热装置和配光部件等。控制器可用于调整光源模组L1所发出照射光的光色、光强等，而配光部件可以是灯罩、透镜、扩散元件、光导等。As shown in FIG. 1 , the light source module L1 provided by the present invention is a light source product, which can be applied in a lighting device (not shown) to provide daily lighting. The lighting device can be a table lamp, a chandelier, a ceiling lamp, a downlight, a spotlight and other lamps. The lighting device includes a light source module L1 and a power supply module that provides power to the light source module L1. The functions and requirements of lamps and lanterns include controllers, cooling devices and light distribution components. The controller can be used to adjust the light color and intensity of the light emitted by the light source module L1, and the light distribution component can be a lampshade, a lens, a diffusion element, a light guide, etc.

本发明的光源模组L1的一个具体实施方式为一个混光的白光LED封装芯片，其可以为具有一般贴片封装结构或COB封装结构LED芯片如图1所示，光源模组L1至少包括一个第一发光元件1和覆盖于第一发光元件的封装部2。A specific embodiment of the light source module L1 of the present invention is a light-mixing white LED package chip, which can be an LED chip with a general patch package structure or a COB package structure. As shown in Figure 1, the light source module L1 includes at least one The first light emitting element 1 and the encapsulation part 2 covering the first light emitting element.

第一发光元件1为蓝光LED芯片，由半导体材料直接激发发光，其发光的峰值波长位于435~465nm，光色呈蓝色，这里我们称第一发光元件1发出的光为第一颜色光。在另一优选实施方式中也可采用峰值波长位置在435~465nm的蓝光LED芯片。LED芯片(LED Chip),包括正装或倒装，单颗LED Chip或者多颗LED Chip按串联、并联或串并联方式连接在一起。The first light-emitting element 1 is a blue LED chip, which is directly excited by a semiconductor material to emit light. The peak wavelength of the light is 435-465nm, and the light color is blue. Here we call the light emitted by the first light-emitting element 1 the first color light. In another preferred embodiment, a blue LED chip with a peak wavelength position of 435-465 nm may also be used. LED chip (LED Chip), including front-mounted or flip-chip, a single LED Chip or multiple LED Chips are connected together in series, parallel or series-parallel.

封装部2以透明硅胶或透明树脂作为基底材料201，其中透明树脂是指环氧树脂、尿素树脂的一种。基底材料204中掺入有第一附加发光体201、第二附加发光体202、第三附加发光体203。其中第一附加发光体201为接收第一发光元件1所发射的部分光线，并将其转换为峰值波长在485~520nm，半宽度25~65nm的第二颜色光的蓝绿色荧光粉。第二附加发光体202为包含至少一种峰值波长大于540nm的黄色荧光粉和至少一种峰值波长小于540nm的绿色荧光粉的黄绿色荧光粉组合，组合后的第二附加发光体202接收所述第一发光元件1所发射的部分光线，并将其转换为峰值波长位于530~580nm，半宽度60~115nm的第三颜色光，优选的半宽度为90~115nm。第三附加发光体203为接收所述第一发光元件1所发射的部分光线，并将其转换为峰值波长位于605~645nm的，半宽度80~120nm的第四颜色光的红色或橙色荧光粉，优选的半宽度为80~100nm。封装部2中还可以包括有光扩散剂，光扩散剂可以是纳米级氧化钛、氧化铝或氧化硅中的一种。上述各类荧光粉和光扩散剂混入封装基底204，并均匀地分布在封装基底204中，混入荧光粉的封装基底204覆盖在作为第一发光元件1的蓝光LED 芯片上方形成封装部2。The package part 2 uses transparent silica gel or transparent resin as the base material 201 , wherein the transparent resin refers to one of epoxy resin and urea resin. The base material 204 is doped with a first additional light emitter 201 , a second additional light emitter 202 and a third additional light emitter 203 . The first additional luminous body 201 is a blue-green phosphor that receives part of the light emitted by the first light-emitting element 1 and converts it into a second color light with a peak wavelength of 485-520 nm and a half-width of 25-65 nm. The second additional illuminant 202 is a combination of yellow-green phosphors comprising at least one yellow phosphor with a peak wavelength greater than 540nm and at least one green phosphor with a peak wavelength less than 540nm, and the combined second additional illuminant 202 receives the described Part of the light emitted by the first light-emitting element 1 is converted into third color light with a peak wavelength of 530-580 nm and a half-width of 60-115 nm, preferably a half-width of 90-115 nm. The third additional luminous body 203 is a red or orange phosphor that receives part of the light emitted by the first light-emitting element 1 and converts it into a fourth color light with a peak wavelength of 605-645 nm and a half-width of 80-120 nm. , the preferred half width is 80~100nm. The encapsulation part 2 may also include a light diffusing agent, and the light diffusing agent may be one of nanoscale titanium oxide, aluminum oxide or silicon oxide. The above-mentioned various phosphors and light diffusing agents are mixed into the encapsulation base 204 and evenly distributed in the encapsulation base 204 . The encapsulation base 204 mixed with phosphor covers the blue LED chip as the first light emitting element 1 to form the encapsulation part 2 .

附加发光体在光源模组1中的作用是接收所述第一发光元件1所发射的部分光线，并将其转换为不同于第一颜色的其他颜色的光，在本实施方式中第一颜色光、第二颜色光、第三颜色光和第四颜色光混合后即形成光源模组L1的发射光，光源模组L1的发射光为在CIE1931色空间上位于相关色温4000±280K与黑体轨迹的距离duv= -0.006~0.006的点围成的区间内的白光。The role of the additional illuminant in the light source module 1 is to receive part of the light emitted by the first light-emitting element 1 and convert it into light of a color other than the first color. In this embodiment, the first color Light, the second color light, the third color light and the fourth color light are mixed to form the emitted light of the light source module L1. The emitted light of the light source module L1 is located on the CIE1931 color space with a correlated color temperature of 4000±280K and a blackbody locus White light in the interval surrounded by points with a distance of duv= -0.006~0.006.

下面我们对我们所使用的各种荧光粉进行说明，为了便于描述方便，我们定义上述蓝绿色荧光粉、黄绿色荧光粉组合、红色或橙色荧光粉的重量之和为总荧光粉重量。总荧光粉重量在封装部2中的占比为25~50%。封装部2的重量为混入荧光粉、光扩散剂后的封装基底204的总重量。Below we describe the various phosphors we use. For the convenience of description, we define the sum of the weights of the above-mentioned blue-green phosphors, yellow-green phosphors, red or orange phosphors as the total phosphor weight. The weight of the total phosphor powder accounts for 25-50% of the encapsulation part 2 . The weight of the encapsulation part 2 is the total weight of the encapsulation base 204 mixed with phosphor powder and light diffusing agent.

作为第一附加发光体201的蓝绿色荧光粉在总荧光粉重量中的占比为15.0~40.0%，其可以选择下述荧光粉中的任意一种，或者从下述荧光粉中选择两种或以上混合而成。具体的荧光粉种类如下(在本发明中以x来表示摩尔比)：The blue-green phosphor as the first additional luminous body 201 accounts for 15.0~40.0% of the total phosphor weight, and it can choose any one of the following phosphors, or choose two of the following phosphors or a mix of the above. Concrete fluorescent powder kind is as follows (express molar ratio with x in the present invention):

(a)氮氧化物，Eu²⁺为激活剂(a) Nitrogen oxides, Eu²⁺ as activator

化学组成通式：(Ba,Ca)_1-xSi₂N₂O₂:Eu_xGeneral formula of chemical composition: (Ba,Ca)_1-x Si₂ N₂ O₂ :Eu_x

其中x=0.005~0.200；where x=0.005~0.200;

(b)掺Ga石榴石荧光粉，Eu²⁺为激活剂(b) Ga-doped garnet phosphor with Eu²⁺ as the activator

化学组成通式：Ga-LuAG:Eu；General formula of chemical composition: Ga-LuAG:Eu;

(c)硅酸盐荧光粉，Eu²⁺为激活剂(c) Silicate phosphor, Eu²⁺ as activator

化学组成通式：Ba₂SiO₄:Eu。General formula of chemical composition: Ba₂ SiO₄ :Eu.

作为第二附加发光体202的黄绿色荧光粉组合在总荧光粉重量中的占比为25.0~55.0%。一般而言黄色和绿色荧光粉并没有一个明确的界定，这两者基本上具有相同的化学通式，其区别仅在于其中成分的摩尔比不同，本申请的特点在于在500~580nm波段中选用两种峰值波长不同的荧光粉进行组合，其中一种峰值波长大于540nm小于580nm的我们称其为黄色荧光粉，另一种荧光粉的峰值波长小于540nm大于500nm的我们称其为绿色荧光粉。当然在其他较佳的实施方式中，也可以选用更多种的荧光粉进行混合，但是其中需要包括一种我们所说的黄色荧光粉和一种我们所说的绿色荧光粉。具体的黄色荧光粉/绿色荧光粉可以为下述荧光粉中的任意一种或两种以上混合而成：The yellow-green phosphor combination as the second additional luminous body 202 accounts for 25.0-55.0% of the total phosphor weight. Generally speaking, yellow and green phosphors do not have a clear definition. They basically have the same general chemical formula, and the difference is only in the molar ratio of the components. Two phosphors with different peak wavelengths are combined, one of which has a peak wavelength greater than 540nm and less than 580nm is called yellow phosphor, and the other phosphor whose peak wavelength is less than 540nm and greater than 500nm is called green phosphor. Of course, in other preferred embodiments, more kinds of phosphors can also be selected for mixing, but it needs to include one kind of yellow phosphor powder and one green phosphor powder. The specific yellow phosphor/green phosphor can be any one or a mixture of two or more of the following phosphors:

(a)石榴石结构荧光粉，Ce³⁺为激活剂(a) Garnet structure phosphor, Ce³⁺ as activator

化学组成通式：(M4)_3-x(M5)₅O₁₂:Ce_xGeneral formula of chemical composition: (M4)_3-x (M5)₅ O₁₂ :_Cex

其中M4为Y、Lu、Gd及La中至少一种元素，M5为Al、Ga中至少一种元素，x=0.005~0.200；Wherein M4 is at least one element among Y, Lu, Gd and La, M5 is at least one element among Al and Ga, x=0.005~0.200;

(b)硅酸盐体系荧光粉，Eu²⁺为激活剂(b) Silicate system phosphor, Eu²⁺ is the activator

化学组成通式：(M6)_2-xSiO₄：Eu_xGeneral formula of chemical composition: (M6)_2-x SiO₄ : Eu_x

或 (Ba,Ca,Sr)_2-x(Mg,Zn)Si₂O₇:Eu_xor (Ba,Ca,Sr)_2-x (Mg,Zn)Si₂ O₇ :Eu_x

其中M6为Mg、Sr、Ca、Ba中至少一种元素，x=0.01~0.20；Where M6 is at least one element of Mg, Sr, Ca, Ba, x=0.01~0.20;

(c)氮氧化物荧光粉 (塞隆体β-SiAlON)，Eu²⁺为激活剂(c) Oxynitride phosphor (Sialon β-SiAlON), Eu²⁺ is the activator

化学组成通式：Si_bAl_cO_dN_e：Eu_xGeneral formula of chemical composition: Si_b Al_c O_dNe : Eu_x

其中x=0.005~0.400，b+c=12，d+e=16；Where x=0.005~0.400, b+c=12, d+e=16;

(d)铝酸盐体系荧光粉，Eu²⁺为激活剂(d) Aluminate system phosphor, Eu²⁺ as activator

化学组成通式：(Sr,Ba)_2-xAl₂O₄:Eu_xGeneral formula of chemical composition: (Sr,Ba)_2-x Al₂ O₄ :Eu_x

或 (Sr,Ba)_4-xAl₁₄O₂₅：Eu_xOr (Sr,Ba)_4-x Al₁₄ O₂₅ : Eu_x

其中x=0.01~0.15。where x=0.01~0.15.

作为第三附加发光体203的红色或橙色荧光粉在总荧光粉重量中的占比为10.0~40.0%，其可以选择下述荧光粉中的任意一种，或者从下述荧光粉中选择两种或以上混合而成。具体的荧光粉种类如下(在本发明中以x来表示摩尔比)：The red or orange phosphor as the third additional luminous body 203 accounts for 10.0-40.0% of the total phosphor weight, and it can choose any one of the following phosphors, or choose two phosphors from the following phosphors. A mixture of one or more of the above. Concrete fluorescent powder kind is as follows (express molar ratio with x in the present invention):

(a)具有1113晶体结构的氮化物红粉，Eu²⁺为激活剂(a) Nitride red powder with 1113 crystal structure, Eu²⁺ as activator

化学组成通式：(M1)_1-xAlSiN₃:Eu_xGeneral formula of chemical composition: (M1)_1-x AlSiN₃ :Eu_x

其中M1为Ca、Sr、Ba中至少一种元素，x=0.005~0.300；Where M1 is at least one element among Ca, Sr and Ba, x=0.005~0.300;

(b)具有258晶体结构的氮化物红粉，Eu²⁺为激活剂(b) Nitride red powder with 258 crystal structure, Eu²⁺ as activator

化学组成通式：(M2)_2-xSi₅N₈：Eu_xGeneral formula of chemical composition: (M2)_2-x Si₅ N₈ : Eu_x

其中M2为Ca、Sr、Ba、Mg中至少一种元素，x=0.005~0.300；Where M2 is at least one element among Ca, Sr, Ba, Mg, x=0.005~0.300;

(c)氮氧化物荧光粉(塞隆体α-SiAlON)，Eu²⁺为激活剂(c) Oxynitride phosphor (Sialon α-SiAlON), Eu²⁺ is the activator

化学组成通式：((M3)_1-a)_xSi_bAl_cO_dN_e:EuaGeneral formula of chemical composition: ((M3)_1-a )_x Si_b Al_c O_d Ne :_Eua

其中M3为Li、Na、K、Rb、Cs、Sr、Ba、Sc、Y、La、Gd之中至少一种元素，x=0.15~1.5，a=0.005~0.300， b+c=12，d+e=16；Where M3 is at least one element among Li, Na, K, Rb, Cs, Sr, Ba, Sc, Y, La, Gd, x=0.15~1.5, a=0.005~0.300, b+c=12, d +e=16;

(d)硅酸盐荧光粉，Eu²⁺为激活剂(d) Silicate phosphor, Eu²⁺ as activator

化学组成通式：(Sr,Ba)_3-xSi₅O₅:Eu_xGeneral formula of chemical composition: (Sr,Ba)_3-x Si₅ O₅ :Eu_x

其中x=0.005~0.300。where x=0.005~0.300.

以上给出的是可以选用的荧光粉种类，在本申请中我们提供了8个具体实施例，在这些实施例中一共选用了10种荧光粉，实施例选用的各荧光粉的参数及化学式见下表。为了便于描述，在表1中我们给荧光粉定义了代号，在后续的实施例说明中我们就以该代号来进行描述，不再在每个实施例中都详细描述荧光粉的峰值及化学式了。Provided above is the kind of fluorescent powder that can be selected. In this application, we have provided 8 specific embodiments. In these embodiments, 10 kinds of fluorescent powders have been selected. For the parameters and chemical formulas of each fluorescent powder selected in the embodiment, see The following table. For the convenience of description, in Table 1, we have defined the code for the phosphor, and we will use this code to describe in the description of the following examples, and no longer describe the peak value and chemical formula of the phosphor in detail in each embodiment. .

表1Table 1

在上表中参数都是针对该种荧光粉而言的，x、y表示荧光粉的光色在CIE1931色空间上的坐标值，Peak表示峰值波长，Hw表示半宽度，以上数值都是实施例中采用的荧光粉的实际数值，并不是对本发明的限定，因为在实际生产中由于荧光粉纯度、颗粒大小的不同其峰值波长和半宽度都有可能会和以上数据稍有偏差，这个偏差值一般会被控制在±5nm之间，应该认为在这个范围内的其他方案是等同于上述荧光粉的。The parameters in the above table are all for this kind of phosphor, x and y represent the coordinate values of the light color of the phosphor in the CIE1931 color space, Peak represents the peak wavelength, Hw represents the half width, and the above values are examples The actual value of the phosphor powder used in the above is not a limitation of the present invention, because in actual production, due to the difference in the purity and particle size of the phosphor powder, its peak wavelength and half width may have a slight deviation from the above data. This deviation value Generally, it will be controlled within ±5nm, and it should be considered that other solutions within this range are equivalent to the above-mentioned phosphors.

表2展示了本申请的8个实施例，以及各实施例中所采用的荧光粉种类和各类荧光粉的重量，其中黄绿粉占比是指混合后的黄粉和绿粉在总荧光粉重量中的占比，而总荧光粉占比是指总荧光粉重量，在全部四种荧光粉和封装基底204混合后的封装部2的总重量中的占比。在这些实施例中封装基底204都是透明硅胶，重量为10g。Table 2 shows 8 embodiments of the present application, as well as the types of phosphors used in each embodiment and the weight of various phosphors, wherein the proportion of yellow-green powder refers to the proportion of mixed yellow powder and green powder in the total phosphor powder The proportion in the weight, and the proportion of the total phosphor refers to the proportion of the weight of the total phosphor in the total weight of the package part 2 after all four phosphors and the package substrate 204 are mixed. In these embodiments, the encapsulation substrate 204 is all transparent silicone and weighs 10 g.

表2Table 2

表2中的实施例荧光粉重量都是我们在制作样例芯片时的数据，实际在批量生产中，由于荧光粉批次不同重量都会稍有差异，但是其基本占比是在一个固定的区间内的。从表2中可见作为第三附加发光体203的红色荧光粉在总荧光粉重量中的占比在22.9%到35.3%这一区间内，考虑到还可以采用其他种类荧光粉，本申请中认为第三附加发光体203在总荧光粉重量中的占比在应该在10%~40%这一范围内。表2中作为第二附加发光体202的黄绿色荧光粉组合在总荧光粉重量中的占比在40.2%到54.7%这一区间内，本申请中认为第二附加发光体202在总荧光粉重量中的占比在应该在35.0~55.0%这一范围内，进一步考虑其他荧光粉占比可扩大为25.0~55.0%。表2中作为第一附加发光体201的蓝绿色荧光粉在总荧光粉重量中的占比在17.6%到28.4%这一区间内，本申请中认为第一附加发光体201在总荧光粉重量中的占比在应该在15.0~30.0%这一范围内，进一步考虑其他荧光粉占比可扩大为15.0~40.0%。这些荧光粉可以通过混入透明硅胶涂覆在LED芯片之上，也可以是远程荧光粉设置在距离芯片较远的位置，或者部分混入封装胶，部分设置在外部，本申请对此不作限定。The weight of the phosphor powder in the examples in Table 2 is the data when we made the sample chip. In actual mass production, the weight of the phosphor powder in different batches will be slightly different, but its basic proportion is in a fixed range. inside. It can be seen from Table 2 that the red phosphor as the third additional luminous body 203 accounts for 22.9% to 35.3% of the total phosphor weight. Considering that other types of phosphors can also be used, it is considered in this application that The proportion of the third additional luminous body 203 in the total phosphor weight should be in the range of 10%~40%. In Table 2, the yellow-green phosphor combination as the second additional luminous body 202 accounts for 40.2% to 54.7% of the total phosphor weight. In this application, the second additional luminous body 202 is considered The proportion in the weight should be in the range of 35.0~55.0%, further considering the proportion of other phosphors can be expanded to 25.0~55.0%. In Table 2, the proportion of blue-green phosphor as the first additional luminous body 201 in the total phosphor weight is within the range of 17.6% to 28.4%. In this application, it is considered that the first additional luminous body 201 accounts for The proportion of phosphor powder should be in the range of 15.0~30.0%, further considering the proportion of other phosphors can be expanded to 15.0~40.0%. These phosphors can be coated on the LED chip by mixing transparent silica gel, or the remote phosphors can be placed far away from the chip, or part can be mixed with encapsulant and part can be placed outside, which is not limited in this application.

参考上表我们对各实施进行详细说明。Referring to the table above, we describe each implementation in detail.

实施例1，在光源模组L1中第一发光元件1为Peak=450nm的蓝光LED芯片。称取代号为R630的红色荧光粉1.45g作为第三附加发光体203。第二附加发光体202由代号为Y550的黄色荧光粉和代号为G-Ga535的绿色荧光粉组合而成，其中黄色荧光粉2.23g，绿色荧光粉0.86g，共计3.09g。称取代号为BG490的蓝绿色荧光粉1.80g作为第一附加发光体201。将上述荧光粉放入透明硅胶，再搅拌机充分混合均匀，涂覆在蓝光LED芯片上，烘干除气泡后得到一种中性白光LED芯片，其光谱见图4，具体发光特性见表3。Embodiment 1, the first light emitting element 1 in the light source module L1 is a blue LED chip with Peak=450nm. 1.45 g of red fluorescent powder with the substitution number R630 was used as the third additional luminous body 203 . The second additional illuminant 202 is composed of yellow phosphor powder code-named Y550 and green phosphor powder code-named G-Ga535, wherein 2.23g of yellow phosphor powder and 0.86g of green phosphor powder total 3.09g. 1.80 g of blue-green fluorescent powder with the substitution number BG490 was used as the first additional luminous body 201 . Put the above-mentioned fluorescent powder into transparent silica gel, and then fully mix it with a mixer, coat it on the blue LED chip, dry and remove air bubbles to obtain a neutral white LED chip, its spectrum is shown in Figure 4, and the specific luminous characteristics are shown in Table 3.

实施例2，在光源模组L1中第一发光元件1为Peak=450nm的蓝光LED芯片。称取代号为R630的红色荧光粉1.58g作为第三附加发光体203。第二附加发光体202由代号为Y550的黄色荧光粉和代号为G-Ga535的绿色荧光粉组合而成，其中黄色荧光粉0.90g，绿色荧光粉1.98g，共计2.88g。称取代号为BG490的蓝绿色荧光粉1.50g作为第一附加发光体201。将上述荧光粉放入透明硅胶，再搅拌机充分混合均匀，涂覆在蓝光LED芯片上，烘干除气泡后得到一种中性白光LED芯片，其光谱见图5，具体发光特性见表3。Embodiment 2, the first light emitting element 1 in the light source module L1 is a blue LED chip with Peak=450nm. 1.58 g of red fluorescent powder with the substitution number R630 was used as the third additional luminous body 203 . The second additional illuminant 202 is composed of yellow phosphor powder code-named Y550 and green phosphor powder code-named G-Ga535, wherein the yellow phosphor powder is 0.90g and the green phosphor powder is 1.98g, totaling 2.88g. 1.50 g of blue-green fluorescent powder with the substitution number BG490 was used as the first additional luminous body 201 . Put the above-mentioned fluorescent powder into transparent silica gel, and then fully mix it with a mixer, coat it on the blue LED chip, dry and remove air bubbles to obtain a neutral white LED chip, its spectrum is shown in Figure 5, and the specific luminous characteristics are shown in Table 3.

实施例3，在光源模组L1中第一发光元件1为Peak=455nm的蓝光LED芯片。称取代号为R640的红色荧光粉1.92g作为第三附加发光体203。第二附加发光体202由代号为Y565的黄色荧光粉和代号为G-L535的绿色荧光粉组合而成，其中黄色荧光粉1.37g，绿色荧光粉1.57g，共计2.94g。称取代号为BG490的蓝绿色荧光粉1.30g作为第一附加发光体201。将上述荧光粉放入透明硅胶，再搅拌机充分混合均匀，涂覆在蓝光LED芯片上，烘干除气泡后得到一种中性白光LED芯片，其光谱见图6，具体发光特性见表3。Embodiment 3, in the light source module L1, the first light emitting element 1 is a blue LED chip with Peak=455nm. 1.92 g of red fluorescent powder with the substitution number R640 was used as the third additional luminous body 203 . The second additional illuminant 202 is composed of a yellow phosphor coded Y565 and a green phosphor coded G-L535, wherein the yellow phosphor is 1.37g and the green phosphor is 1.57g, totaling 2.94g. 1.30 g of blue-green fluorescent powder with the substitution number BG490 was used as the first additional luminous body 201 . Put the above-mentioned fluorescent powder into transparent silica gel, and then fully mix it with a mixer, coat it on the blue LED chip, dry and remove air bubbles to obtain a neutral white LED chip, its spectrum is shown in Figure 6, and the specific luminous characteristics are shown in Table 3.

实施例4，在光源模组L1中第一发光元件1为Peak=450nm的蓝光LED芯片。称取代号为R640的红色荧光粉2.05g作为第三附加发光体203。第二附加发光体202由代号为Y565的黄色荧光粉和代号为G-L535的绿色荧光粉组合而成，其中黄色荧光粉1.27g，绿色荧光粉2.48g，共计3.75g。称取代号为BG490的蓝绿色荧光粉1.25g作为第一附加发光体201。将上述荧光粉放入透明硅胶，再搅拌机充分混合均匀，涂覆在蓝光LED芯片上，烘干除气泡后得到一种中性白光LED芯片，其光谱见图7，具体发光特性见表3。Embodiment 4, in the light source module L1, the first light emitting element 1 is a blue LED chip with Peak=450nm. 2.05 g of red fluorescent powder with the substitution number R640 is called as the third additional luminous body 203 . The second additional illuminant 202 is composed of a yellow phosphor coded Y565 and a green phosphor coded G-L535, wherein the yellow phosphor is 1.27g and the green phosphor is 2.48g, totaling 3.75g. 1.25 g of blue-green fluorescent powder with the substitution number BG490 was used as the first additional luminous body 201 . Put the above-mentioned fluorescent powder into transparent silica gel, and then fully mix it with a mixer, coat it on the blue LED chip, dry and remove air bubbles to obtain a neutral white LED chip, its spectrum is shown in Figure 7, and the specific luminous characteristics are shown in Table 3.

实施例5，在光源模组L1中第一发光元件1为Peak=450nm的蓝光LED芯片。称取代号为R650的红色荧光粉1.73g作为第三附加发光体203。第二附加发光体202由代号为Y550的黄色荧光粉和代号为G-L535的绿色荧光粉组合而成，其中黄色荧光粉2.17g，绿色荧光粉1.37g，共计3.54g。称取代号为BG490的蓝绿色荧光粉1.20g作为第一附加发光体201。将上述荧光粉放入透明硅胶，再搅拌机充分混合均匀，涂覆在蓝光LED芯片上，烘干除气泡后得到一种中性白光LED芯片，其光谱见图8，具体发光特性见表3。Embodiment 5, in the light source module L1, the first light emitting element 1 is a blue LED chip with Peak=450nm. 1.73 g of red fluorescent powder with the substitution number R650 was used as the third additional luminous body 203 . The second additional illuminant 202 is composed of yellow phosphor coded Y550 and green phosphor coded G-L535, wherein the yellow phosphor powder is 2.17g and the green phosphor powder is 1.37g, totaling 3.54g. 1.20 g of blue-green fluorescent powder with the substitution number BG490 was used as the first additional luminous body 201 . Put the above-mentioned fluorescent powder into transparent silica gel, and then fully mix it with a mixer, coat it on the blue LED chip, dry and remove air bubbles to obtain a neutral white LED chip, its spectrum is shown in Figure 8, and the specific luminous characteristics are shown in Table 3.

实施例6，在光源模组L1中第一发光元件1为Peak=445nm的蓝光LED芯片。称取代号为R650的红色荧光粉1.80g作为第三附加发光体203。第二附加发光体202由代号为Y565的黄色荧光粉和代号为G-Ga535的绿色荧光粉组合而成，其中黄色荧光粉0.70g，绿色荧光粉1.35g，共计2.05g。称取代号为BG490的蓝绿色荧光粉1.25g作为第一附加发光体201。将上述荧光粉放入透明硅胶，再搅拌机充分混合均匀，涂覆在蓝光LED芯片上，烘干除气泡后得到一种中性白光LED芯片，其光谱见图9，具体发光特性见表3。Embodiment 6, in the light source module L1, the first light emitting element 1 is a blue LED chip with Peak=445nm. 1.80 g of red fluorescent powder with the substitution number R650 was used as the third additional luminous body 203 . The second additional illuminant 202 is composed of yellow fluorescent powder code-named Y565 and green fluorescent powder code-named G-Ga535, wherein the yellow fluorescent powder is 0.70g, and the green fluorescent powder is 1.35g, totaling 2.05g. 1.25 g of blue-green fluorescent powder with the substitution number BG490 was used as the first additional luminous body 201 . Put the above-mentioned fluorescent powder into transparent silica gel, and then fully mix it with a mixer, coat it on the blue LED chip, dry and remove air bubbles to obtain a neutral white LED chip, its spectrum is shown in Figure 9, and the specific luminous characteristics are shown in Table 3.

实施例7，在光源模组L1中第一发光元件1为Peak=455nm的蓝光LED芯片。称取代号为R630的红色荧光粉2.50g作为第三附加发光体203。第二附加发光体202由代号为Y550的黄色荧光粉和代号为G-Ga535的绿色荧光粉组合而成，其中黄色荧光粉2.33g，绿色荧光粉2.20g，共计4.53g。称取代号为BG490的蓝绿色荧光粉1.50g作为第一附加发光体201。将上述荧光粉放入透明硅胶，再搅拌机充分混合均匀，涂覆在蓝光LED芯片上，烘干除气泡后得到一种中性白光LED芯片，其光谱见图10，具体发光特性见表3。Embodiment 7, in the light source module L1, the first light emitting element 1 is a blue LED chip with Peak=455nm. 2.50 g of red fluorescent powder with a substituting number of R630 is called as the third additional luminous body 203 . The second additional illuminant 202 is composed of yellow phosphor powder code-named Y550 and green phosphor powder code-named G-Ga535, wherein the yellow phosphor powder is 2.33g and the green phosphor powder is 2.20g, totaling 4.53g. 1.50 g of blue-green fluorescent powder with the substitution number BG490 was used as the first additional luminous body 201 . Put the above-mentioned fluorescent powder into transparent silica gel, and then fully mix it with a mixer, coat it on the blue LED chip, dry and remove air bubbles to obtain a neutral white LED chip, its spectrum is shown in Figure 10, and the specific luminous characteristics are shown in Table 3.

实施例8，在光源模组L1中第一发光元件1为Peak=450nm的蓝光LED芯片。称取代号为R640的红色荧光粉1.90g作为第三附加发光体203。第二附加发光体202由代号为Y550的黄色荧光粉和代号为G-Ga535的绿色荧光粉组合而成，其中黄色荧光粉2.16g，绿色荧光粉0.90g，共计3.06g。称取代号为BG500的蓝绿色荧光粉1.24g作为第一附加发光体201。将上述荧光粉放入透明硅胶，再搅拌机充分混合均匀，涂覆在蓝光LED芯片上，烘干除气泡后得到一种中性白光LED芯片，其光谱见图11，具体发光特性见表3。Embodiment 8, in the light source module L1, the first light emitting element 1 is a blue LED chip with Peak=450nm. 1.90 g of red fluorescent powder with the substitution number R640 was used as the third additional luminous body 203 . The second additional illuminant 202 is composed of yellow phosphor powder code-named Y550 and green phosphor powder code-named G-Ga535, wherein the yellow phosphor powder is 2.16g, and the green phosphor powder is 0.90g, totaling 3.06g. 1.24 g of blue-green fluorescent powder with the substitution number BG500 was called as the first additional luminous body 201 . Put the above-mentioned fluorescent powder into transparent silica gel, and then fully mix it with a mixer, coat it on the blue LED chip, dry and remove air bubbles to obtain a neutral white LED chip, its spectrum is shown in Figure 11, and the specific luminous characteristics are shown in Table 3.

表 3table 3

表3中列出了实施例1-8中光源模组L1的发光特性，其中x、y表示光源模组L1的发射光的光色在CIE1931色坐标系上的x、y轴上的坐标值，CCT为色温，duv 表示在色坐标系里色彩偏移普朗克轨迹的距离与方向，CRI和R9为显色指数。CS值500lux在本申请中表示光源模组L1发射光在照度500lux时的CS值，具体计算公式如下：Table 3 lists the luminous characteristics of the light source module L1 in Examples 1-8, wherein x and y represent the coordinate values of the light color of the emitted light of the light source module L1 on the x and y axes of the CIE1931 color coordinate system , CCT is the color temperature, duv represents the distance and direction of the color shift Planckian locus in the color coordinate system, CRI and R9 are the color rendering index. The CS value of 500lux in this application represents the CS value of the light emitted by the light source module L1 at an illumination of 500lux. The specific calculation formula is as follows:

其中in

， ,

if；if ;

， ,

ifif

其中in

P₀(λ)：光源光谱分布P₀ (λ): Light source spectral distribution

P(λ)：对应500lux的光源光谱分布P(λ): The spectral distribution of the light source corresponding to 500lux

Mc(λ)：按晶状体透过率校正的视黑素敏感曲线Mc(λ): melanin sensitivity curve corrected by lens transmittance

S(λ)：S型锥状细胞敏感曲线S(λ): S-type cone cell sensitivity curve

mp(λ)：黄斑色素透过率mp(λ): macular pigment transmittance

V(λ)：明视觉光视效率函数V(λ): Photopic efficiency function

V'(λ)：暗视觉光视效率函数V'(λ): scotopic efficiency function

计算公式依据为LRC已经发布的人体节律光传导数学模型。The calculation formula is based on the mathematical model of human rhythmic light conduction published by LRC.

从表3中我们可以看到所有实施例的光源模组L1的发射光在照度500lux时的CS值均大于0.34，且其显色指数均符合CRI≥90.0，R9≥85.0。而我们将各实施例中的发光光色标注在CIE1931色坐标系上，如图3所示，各实施例光色均落在相关色温4000±280K的黑体轨迹的附近，距黑体轨迹BBL 距离均小于0.006，即duv在-0.006~0.006这一区间内。且所有点均落在位于由点D1(0.3991,0.4012)、点D2(0.3722,0.3843)、点D3(0.3658,0.3550)、点D4(0.3885,0.3688)四个顶点围成的四边形区域内，即图示区域1。在后期对这些实施例进行用户实验后，我们发现实施例1、2、3、4、6、7的效果更好，而从图3中我们可以发现，这些点都落入图示区域2内，区域2为中心点x0=0.3805，y0=0.3768，长轴a=0.00313，短轴b=0.00134，倾角θ=54.0°，SDCM=5.0的椭圆。From Table 3, we can see that the CS value of the emitted light of the light source module L1 in all embodiments is greater than 0.34 at an illumination of 500 lux, and its color rendering index meets CRI≥90.0 and R9≥85.0. And we mark the luminous light color in each embodiment on the CIE1931 color coordinate system, as shown in Figure 3, the light color of each embodiment falls near the black body locus with a correlated color temperature of 4000±280K, and the distance from the black body locus BBL Less than 0.006, that is, duv is in the range of -0.006~0.006. And all points fall in the quadrilateral area surrounded by the four vertices of point D1 (0.3991, 0.4012), point D2 (0.3722, 0.3843), point D3 (0.3658, 0.3550), point D4 (0.3885, 0.3688), that is Area 1 is shown in the diagram. After conducting user experiments on these embodiments in the later stage, we found that the effects of embodiments 1, 2, 3, 4, 6, and 7 are better. From Figure 3, we can find that these points all fall into the area 2 of the illustration , area 2 is an ellipse with center point x0=0.3805, y0=0.3768, major axis a=0.00313, minor axis b=0.00134, inclination θ=54.0°, SDCM=5.0.

在我们提供的这些实施例之所以能够实现较高的CS值，主要是由于发射光在不同波长的能量分布，这些特点可以通过他们的光谱特征来体现。图2是最能体现本申请光源模组L1发射光的光谱特点的示意性光谱图，我们依据图2来对本申请的光谱特点进行说明。从图2中可见，光源模组L1的发射光的光谱在380~780nm可见光范围光谱连续分布，即在380~780nm中的每一点均有一定的能量分布，这可以保证该光谱具有较佳的显示性。为了后续描述方便，这里我们先定义一个光谱中相邻两点的光谱强度相对偏差值ΔI，ΔI表示光谱中相邻两点光谱强调变化情况，在光谱图中表现为相邻两点之间连线的斜率。具体公式为，其中Intensit（i）、Intensit（i+1）分别表示光谱中波长差为步长I的相邻两点的光谱强度。对于光谱上的相邻两点，理论上线上的点是可以无限接近的，但是业内的习惯，相邻的两点一般指光谱图中间隔一定波长的两点，间隔的波长我们称为步长I，通常大家都采用5nm为步长，例如在光谱图中600nm和605nm这两个点我们就称之为相邻两点。因此相邻两点的的光谱强度相对偏差值ΔI是表征光谱平滑程度的一个值，而步长越短就越能够精确地来表示光谱的变化，所以定义步长I的取值范围可以为1nm≤I≤5nm，当然在本实施例中我们还是采用常规的定义，定义间隔5nm的两点为相邻两点。The reason why these embodiments provided by us can achieve higher CS value is mainly due to the energy distribution of emitted light at different wavelengths, and these characteristics can be reflected by their spectral characteristics. Fig. 2 is a schematic spectrogram that can best reflect the spectral characteristics of the light emitted by the light source module L1 of the present application. We will illustrate the spectral characteristics of the present application according to Fig. 2 . It can be seen from Figure 2 that the spectrum of the light emitted by the light source module L1 is continuously distributed in the visible light range of 380~780nm, that is, each point in 380~780nm has a certain energy distribution, which can ensure that the spectrum has a better revealing. For the convenience of subsequent description, here we first define the relative deviation value of spectral intensity ΔI between two adjacent points in a spectrum. The slope of the line. The specific formula is , where Intensit(i) and Intensit(i+1) respectively represent the spectral intensities of two adjacent points in the spectrum whose wavelength difference is the step size I. For two adjacent points on the spectrum, theoretically, the points on the line can be infinitely close, but as a custom in the industry, two adjacent points generally refer to two points separated by a certain wavelength in the spectrum, and the wavelength of the interval is called the step size I, usually everyone uses 5nm as the step size. For example, in the spectrogram, the two points of 600nm and 605nm are called two adjacent points. Therefore, the relative deviation value ΔI of the spectral intensity between two adjacent points is a value that characterizes the smoothness of the spectrum, and the shorter the step size, the more accurately it can represent the change of the spectrum, so the value range of the defined step size I can be 1nm ≤I≤5nm, of course, in this embodiment we still adopt the conventional definition, defining two points with an interval of 5nm as two adjacent points.

在图2的光谱中主要包括第一峰P1、第二峰P2、峰谷V1和一个稳定分布区间Z这些特征。The spectrum in FIG. 2 mainly includes the features of the first peak P1, the second peak P2, the peak valley V1 and a stable distribution interval Z.

第一峰P1位于435~465nm波长区域内，由于光源模组L1是由第一发光元件1蓝光LED芯片作为激发光源，虽然蓝光LED芯片发出的光有很大一部分发射光经过附加发光体进行了波长转换，但是仍有一部分能量未经转换，这些能量在435~465nm波长区域内形成了第一峰，这个P1点可能和蓝光LED芯片的峰值波长相同，因为这个峰的能量的主要来源为第一发光元件1，但是各附加发光体转换后的光在该波长段也可能会有部分能量，两者混合后，此第一峰P1并不一定和原第一发光元件1蓝光LED芯片的峰值波长位置完全重合，可能会稍有漂移，但仍然在435~465nm波长区域内。The first peak P1 is located in the wavelength range of 435~465nm. Since the light source module L1 uses the first light-emitting element 1 blue LED chip as the excitation light source, although a large part of the light emitted by the blue LED chip passes through the additional luminous body. The wavelength is converted, but there is still a part of the energy that has not been converted. These energies form the first peak in the wavelength region of 435~465nm. This P1 point may be the same as the peak wavelength of the blue LED chip, because the main source of the energy of this peak is the second peak. A light-emitting element 1, but the light converted by each additional light-emitting body may also have some energy in this wavelength range. After the two are mixed, the first peak P1 is not necessarily the same as the peak value of the original first light-emitting element 1 blue LED chip The wavelength positions are completely coincident, there may be a slight shift, but they are still in the 435~465nm wavelength region.

第二峰P2位于605~645nm波长区域内，第二峰P2的能量是由第三附加发光体203的红色荧光粉接收第一发光元件1蓝光LED芯片所发射的部分光线转换成为的红光所提供的。第二峰P2的光谱强度和第一峰P1的光谱强度的比值在70~130%之间，优选的是80~110%。在图2中第二峰P2比第一峰P1稍低，比值接近95%，而在实施例2、4、5、7中第二峰P2明显高于第一峰P1，两者比值大于100%。The second peak P2 is located in the wavelength region of 605-645nm, and the energy of the second peak P2 is obtained by the red phosphor powder of the third additional luminous body 203 receiving part of the light emitted by the first light-emitting element 1 blue LED chip and converting it into red light. which provided. The ratio of the spectral intensity of the second peak P2 to the spectral intensity of the first peak P1 is between 70-130%, preferably 80-110%. In Fig. 2, the second peak P2 is slightly lower than the first peak P1, and the ratio is close to 95%, while in Examples 2, 4, 5, and 7, the second peak P2 is obviously higher than the first peak P1, and the ratio of the two is greater than 100 %.

峰谷V1位于455~485nm波长区域内，为了保证在该区域内的能量不过低，峰谷V1的光谱强度和第一峰的光谱强度的比值应该大于等于25%，更佳的是30~60%，这部分能量是由第一附加发光体201的蓝绿色荧光粉接收第一发光元件1蓝光LED芯片所发射的部分光线转换成为的蓝绿所提供的，蓝绿色荧光粉的加入就是为了保证这一部分的能量不会太低。但是即使保证了谷底的高度，影响能量分布的还有峰谷V1的宽度，为了实现本申请要求的效果，我们要求峰谷V1向长波方向的宽度应该小于等于30nm，峰谷V1向长波方向的宽度在图2上表示为峰谷V1到点A的距离W，其中点A为由峰谷V1位置向长波方向出现的第一个ΔI≤2%时的相邻两点中靠近峰谷V1的点，我们称之为峰谷长波方向结束点A，在A点之前ΔI较大则斜率较大，呈现出谷的状态，A点之后ΔI变小，光谱上升相对较为平缓。峰谷V1向长波方向的宽度W等于A点和峰谷V1之间的波长差。The peak-valley V1 is located in the 455-485nm wavelength region. In order to ensure that the energy in this region is not too low, the ratio of the spectral intensity of the peak-valley V1 to the spectral intensity of the first peak should be greater than or equal to 25%, more preferably 30-60 %, this part of energy is provided by the blue-green phosphor powder of the first additional luminous body 201 receiving part of the light emitted by the first light-emitting element 1 blue LED chip and converting it into blue-green. The addition of the blue-green phosphor powder is to ensure The energy of this part will not be too low. But even if the height of the valley bottom is guaranteed, the width of the peak and valley V1 also affects the energy distribution. In order to achieve the effect required by this application, we require that the width of the peak and valley V1 to the long-wave direction should be less than or equal to 30nm, and the width of the peak and valley V1 to the long-wave direction should be less than or equal to 30nm. Width is shown in Figure 2 as the distance W from the peak-valley V1 to point A, where point A is the first ΔI≤2% from the position of the peak-valley V1 to the long wave direction, which is close to the peak-valley V1 among the two adjacent points Point, we call it the end point A of the peak-valley long-wave direction. Before point A, the ΔI is larger and the slope is larger, showing a valley state. After point A, ΔI becomes smaller, and the spectrum rises relatively smoothly. The width W of the peak-valley V1 in the long-wave direction is equal to the wavelength difference between point A and the peak-valley V1.

稳定分布区间Z为495~560nm波长区域，之所以称其为稳定分布区间，是因为这一区间内光谱强度变化较小，这一段的光谱曲线几乎是呈平台状的，其中任意相邻两点的ΔI都不大于1.5%，更佳的是不大于0.8%，其任意一点的光谱强度和第一峰P1的光谱强度的比值都在60~80%之间。图2是本申请理想的光谱示意图，因此A点正好位于稳定分布区间Z的起始位置，在具体实施例中，A点可能落入稳定分布区间Z，也可能在稳定分布区间Z之外，本申请对此不做限定。稳定分布区间Z的能量是由第二附加发光体202的黄绿色荧光粉组合接收第一发光元件1蓝光LED芯片所发射的部分光线转换成后提供的，在图2中是一种比较理想的状态，稳定分布区间Z整体波动很小，但是由于黄绿色荧光粉组合是由两种荧光粉混合而成，因此也有可能在这个区间内再出现一个小的峰值，如实施例5、6、7、8的光谱中所显示的那样，但是只要ΔI在我们所限定的范围内，就不会对结果产生太大的影响，仍然可以实现我们要的CS值。The stable distribution interval Z is the wavelength region of 495~560nm. The reason why it is called the stable distribution interval is that the spectral intensity changes in this interval are small, and the spectral curve of this section is almost platform-shaped, and any two adjacent points ΔI is not greater than 1.5%, more preferably not greater than 0.8%, and the ratio of the spectral intensity at any point to the spectral intensity of the first peak P1 is between 60% and 80%. Fig. 2 is a schematic diagram of the ideal spectrum of the present application, so point A is just at the starting position of the stable distribution interval Z, in a specific embodiment, point A may fall into the stable distribution interval Z, and may also be outside the stable distribution interval Z, This application does not limit this. The energy in the stable distribution interval Z is provided by the combination of the yellow-green phosphor powder of the second additional luminous body 202 after receiving part of the light emitted by the first light-emitting element 1 blue LED chip and converting it, which is an ideal one in Fig. 2 State, the overall fluctuation of the stable distribution interval Z is very small, but because the combination of yellow-green phosphors is a mixture of two phosphors, it is also possible that a small peak will appear in this interval, as in Examples 5, 6, and 7. , 8, as shown in the spectrum, but as long as ΔI is within our limited range, it will not have much impact on the results, and the CS value we want can still be achieved.

表4列出了实施例1-8各光谱的特征值，其中P1波长、P2波长、V1波长分别指第一波峰P1、第二波峰P2、峰谷V1这些点的波长，P2能量比指第二峰P2的光谱强度和第一峰P1的光谱强度的比值，V1能量比指峰谷V1的光谱强度和第一峰P1的光谱强度的比值，Z区间能量比最小值指稳定分布区间Z中任意一点的光谱强度和第一峰P1的光谱强度的比值中的最小值，Z区间ΔI最大值指稳定分布区间Z中任意相邻两点的ΔI值中的最大值，W指峰谷V1长波方向结束点A和峰谷V1之间的波长差。Table 4 has listed the characteristic value of each spectrum of embodiment 1-8, wherein P1 wavelength, P2 wavelength, V1 wavelength refer to the wavelength of these points of the first peak P1, the second peak P2, peak valley V1 respectively, P2 energy ratio refers to the first The ratio of the spectral intensity of the second peak P2 to the spectral intensity of the first peak P1, the V1 energy ratio refers to the ratio of the spectral intensity of the peak valley V1 to the spectral intensity of the first peak P1, and the minimum energy ratio in the Z interval refers to the stable distribution interval Z The minimum value of the ratio of the spectral intensity at any point to the spectral intensity of the first peak P1, the maximum value of ΔI in the Z interval refers to the maximum value of the ΔI value of any two adjacent points in the stable distribution interval Z, and W refers to the long wave of peak valley V1 The wavelength difference between the direction end point A and the peak-valley V1.

表 4Table 4

这些特征值均落在前面所描述光谱特征范围内，正是由于这些特征的存在，具有这些光谱特征的实施例1-8可以实现表3中的高CS值高显示性的发光特性。These characteristic values all fall within the range of the spectral characteristics described above. It is because of the existence of these characteristics that Examples 1-8 with these spectral characteristics can achieve the high CS value and high display luminescence characteristics in Table 3.

上文对本发明优选实施例的描述是为了说明和描述，并非想要把本发明穷尽或局限于所公开的具体形式，显然，可能做出许多修改和变化，这些修改和变化可能对于本领域技术人员来说是显然的，应当包括在由所附权利要求书定义的本发明的范围之内。The foregoing description of the preferred embodiments of the present invention is for purposes of illustration and description, and is not intended to be exhaustive or to limit the invention to the specific forms disclosed. Obviously, many modifications and changes may be made, and these modifications and changes may be necessary for those skilled in the art. It is obvious to the person that it is intended to be included within the scope of the present invention as defined by the appended claims.

Claims (19)

1. a kind of light source module group, which is characterized in that including the first light-emitting component and the encapsulation part for being covered in the first light-emitting component,

First light-emitting component issues the first color of light that peak wavelength is located at 435 ~ 465nm；

The encapsulation part includes：

First additional illuminator, the first additional illuminator are arranged to receive the part that first light-emitting component is emittedLight, and it is converted into the second color of light that peak wavelength is located at 485 ~ 520nm；

Second additional illuminator, the second additional illuminator are arranged to receive the part that first light-emitting component is emittedLight, and it is converted into the third color of light that peak wavelength is located at 530 ~ 580nm；

Third adds illuminator, and the third adds illuminator and is arranged to receive the part that first light-emitting component is emittedLight, and it is converted into the 4th color of light that peak wavelength is located at 605 ~ 645nm,

First color, the second color of light, third color of light and the 4th color of light are mixed to form the transmitting of the light source module groupLight, the transmitting light are neutral white light, i.e., the described transmitting light is located at 4000 ± 280K of correlated colour temperature in the CIE1931 colour spaceIn the section that the point of black body locus distance duv=- 0.006 ~ 0.006 surrounds,

The spectrum of the transmitting light is continuously distributed in 380 ~ 780nm visible-range spectrum, defines the light of adjacent two o'clock in spectrumSpectral intensity relative standard deviation values Δ I,

Wherein Intensit（i）,Intensit（i+1）The spectral intensity for the two o'clock that spectrum medium wavelength difference is step-length I is respectively indicated,1nm≤I≤5nm,

The emissioning light spectrum includes two wave crests, a peak valley and a Stable distritation section：

First peak is located in 435 ~ 465nm wavelength region；

Second peak is located in 605 ~ 645nm wavelength region, the spectral intensity at second peak and the spectral intensity of the first peakRatio between 70% ~ 130%；

Peak valley is located in 455 ~ 485nm wavelength region, the ratio of the spectral intensity of the spectral intensity of the peak valley and the first peakValue is more than or equal to 25%, and peak valley is less than or equal to 30nm to the width of long wave direction, and defining peak valley long wave direction end point is by peakPoint when paddy position is to first Δ I≤2% that long wave direction occurs in adjacent two o'clock close to peak valley, the peak valley is to long wave sideTo width refer to the wavelength difference between peak valley long wave direction end point and peak valley；

Stable distritation section is 495 ~ 560nm wavelength region, the spectral intensity at any point and institute in the Stable distritation sectionThe ratio of the spectral intensity of first peak is stated between 60 ~ 80%, and wherein the Δ I of arbitrary neighborhood two o'clock is not more than 1.5%.

2. light source module group as described in claim 1, which is characterized in that the spectral intensity at second peak and the first peakThe ratio of spectral intensity is between 80% ~ 110%.

3. light source module group as described in claim 1, which is characterized in that the light of the spectral intensity of the peak valley and the first peakThe ratio of spectral intensity is between 30% ~ 60%.

4. light source module group as described in claim 1, which is characterized in that the Δ of arbitrary neighborhood two o'clock in the Stable distritation sectionI is not more than 0.8%.

5. light source module group as described in claim 1, which is characterized in that first light-emitting component is that transmitting peak wavelength existsThe blue-ray LED of 435 ~ 465nm；The first additional illuminator is peak wavelength in 485 ~ 520nm, the indigo plant of 25 ~ 65nm of half widthGreen emitting phosphor；The second additional illuminator is the yellowish green fluorescent powder combination for including yellow fluorescent powder and green emitting phosphor,Wherein it is greater than the green of yellow fluorescent powder and at least one peak wavelength less than 540 of 540nm comprising at least one peak wavelengthFluorescent powder, the peak wavelength of the yellowish green fluorescent powder combination is in 530 ~ 580nm, 60 ~ 115nm of half width；The third is additionalIlluminator is peak wavelength in 605 ~ 645nm, the red or orange fluorescent powder of 80 ~ 120nm of half width.

6. light source module group as claimed in claim 5, which is characterized in that it is glimmering to define the blue-green fluorescent powder, the yellow greenThe sum of the combination of light powder, red or orange fluorescent powder the weight are total fluorescent powder weight, and total fluorescent powder weight is describedAccounting in encapsulation part is 25.0% ~ 50.0%.

7. light source module group as claimed in claim 6, which is characterized in that the blue-green fluorescent powder is appointing in following fluorescent powdersMeaning one or more mix：

(a) nitrogen oxides, Eu²⁺For activator

Chemical composition general formula：(Ba,Ca)_1-xSi₂N₂O₂:Eu_x

Wherein x=0.005 ~ 0.200；

(b) Ga garnet phosphor powder, Eu are mixed²⁺For activator

Chemical composition general formula：Ga-LuAG:Eu；

(c) silicate fluorescent powder, Eu²⁺For activator

Chemical composition general formula：Ba₂SiO₄:Eu。

8. light source module group as claimed in claim 7, which is characterized in that the blue-green fluorescent powder is in total fluorescent powder weightIn accounting be 15.0 ~ 40.0%.

9. light source module group as claimed in claim 6, which is characterized in that the yellow fluorescent powder/green emitting phosphor is following glimmeringIn light powder any one or two or more mix：

(a) garnet structure fluorescent powder, Ce³⁺For activator

Chemical composition general formula：(M4)_3-x(M5)₅O₁₂:Ce_x

Wherein M4 is at least one of Y, Lu, Gd and La element, at least one of M5 Al, Ga element, x=0.005 ~ 0.200；

(b) silicate systems fluorescent powder, Eu²⁺For activator

Chemical composition general formula：(M6)_2-xSiO₄：Eu_x

Or (Ba, Ca, Sr)_2-x(Mg,Zn)Si₂O₇:Eu_x

Wherein M6 is at least one of Mg, Sr, Ca, Ba element, x=0.01 ~ 0.20；

(c) nitric oxide fluorescent powder (Sialon body β-SiAlON), Eu²⁺For activator

Chemical composition general formula：Si_bAl_cO_dN_e：Eu_x

Wherein x=0.005 ~ 0.400, b+c=12, d+e=16；

(d) aluminates system fluorescent powder, Eu²⁺For activator

Chemical composition general formula：(Sr,Ba)_2-xAl₂O₄:Eu_x

Or (Sr, Ba)_4-xAl₁₄O₂₅：Eu_x

Wherein x=0.01 ~ 0.15.

10. light source module group as claimed in claim 9, which is characterized in that the yellowish green fluorescent powder combination is in total fluorescenceAccounting in powder weight is 25.0% ~ 55.0%.

11. light source module group as claimed in claim 6, which is characterized in that the red or orange fluorescent powder is following fluorescent powdersIn any one or two or more mix：

(a) with the nitride rouge and powder of 1113 crystal structures, Eu²⁺For activator

Chemical composition general formula：(M1)_1-xAlSiN₃:Eu_x

Wherein M1 is at least one of Ca, Sr, Ba element, x=0.005 ~ 0.300；

(b) with the nitride rouge and powder of 258 crystal structures, Eu²⁺For activator

Chemical composition general formula：(M2)_2-xSi₅N₈：Eu_x

Wherein M2 is at least one of Ca, Sr, Ba, Mg element, x=0.005 ~ 0.300；

(c) nitric oxide fluorescent powder (Sialon body α-SiAlON), Eu²⁺For activator

Chemical composition general formula：((M3)_1-a)_xSi_bAl_cO_dN_e:Eu_a

Wherein M3 be Li, Na, K, Rb, Cs, Sr, Ba, Sc, Y, La, Gd at least one of element, x=0.15 ~ 1.5, a=0.005~ 0.300, b+c=12, d+e=16；

(d) silicate fluorescent powder, Eu²⁺For activator

Chemical composition general formula：(Sr,Ba)_3-xSi₅O₅:Eu_x

Wherein x=0.005 ~ 0.300.

12. light source module group as claimed in claim 11, which is characterized in that the red or orange fluorescent powder is described total glimmeringAccounting in light powder weight is 10.0% ~ 40.0%.

13. light source module group as claimed in claim 6, which is characterized in that the transmitting light half-breadth of the yellowish green fluorescent powder combinationDegree is 90 ~ 115nm.

14. light source module group as claimed in claim 6, which is characterized in that the encapsulation part further includes base material and light diffusionAgent, the base material are silica gel or resin, and the light diffusing agent is one in nano size Titania, aluminium oxide or silicaKind.

15. the light source module group as described in claim 1-14 is any, which is characterized in that light source module group transmitting light it is photochromicIn the CIE1931 colour space, be located at by D1 (0.3991,0.4012), D2 (0.3722,0.3843), D3 (0.3658,0.3550),In the quadrilateral area that four vertex D4 (0.3885,0.3688) surround.

16. light source module group as claimed in claim 15, which is characterized in that light source module group transmitting light it is photochromicIn the CIE1931 colour space, it is located at central point x0=0.3805, y0=0.3768, long axis a=0.00313, short axle b=0.00134 is inclinedAngle θ=54.0 °, in the oval range of SDCM=5.0.

17. the light source module group as described in claim 1-14 is any, which is characterized in that the transmitting light of the light source module group is in illuminationWhen 500lux, value >=0.34 CS.

18. the light source module group as described in claim 1-14 is any, which is characterized in that the colour developing of the transmitting light of the light source module groupIndex CRI >=90.0, R9 >=85.0.

19. a kind of lighting device, which is characterized in that including：Light source module group as described in any one of claim 1 to 18.