RU2301475C1 - Light-emitting assembly, method for creating fluorescence of light-emitting assembly, and device implementing this method - Google Patents

Abstract

FIELD: lighting engineering.

SUBSTANCE: proposed light-emitting assembly has translucent substrate and light beam dissipating MEANS in the form of fluorescent coat covering mentioned substrate. Method for creating fluorescence of light-emitting assembly includes generation of light beam that acts on mentioned fluorescent coat. Light beam being generated has wavelength chosen between values given in formula. Device implementing proposed method has case incorporating translucent face. Case accommodates light source in the form plate-mounted light-emitting diodes and dissipating means. Wavelength of light emitted by light-emitting diodes is chosen between values given in formula; case has light-reflecting inner surface; mentioned face is made in the form of mentioned substrate with mentioned light-dissipating means. Novelty is that fluorescent coat incorporates light-transmitting component as binder and photo-phosphor, as filler. Amount of photo-phosphor, fluorescent coat thickness and coat transmittance are given in invention specification.

EFFECT: simplified design, facilitated procedure, improved luminance of light-emitting surface and brightness, enhanced efficiency of light source.

3 cl, 5 dwg

Description

The invention relates to lighting engineering, and in particular to means for creating a luminous flux and methods for their functioning, and can be used in the development and manufacture, for example, of lighting devices for general, local lighting or for light indicators.

To increase the ergonomic characteristics of such devices, it is necessary to create a uniform luminosity of the radiation surface, for example, by aligning the light flux generated by the light source with, for example, a light-diffusing screen.

Quantitatively, the uniformity of the surface luminosity can be characterized by ΔM, which is the difference between the luminosities Mι and Mκ of the compared sections of the luminous surface. The smaller this difference, the higher uniformity the surface luminosity has.

Known light-emitting site containing a glass substrate and a luminescent coating deposited on its surface (RF patent No. 21545416 for an invention, MKI H01J 63/06, published August 27, 2000).

The advantage of the known solution is the good uniformity of the luminosity of the radiation surface. The disadvantages are: the need to create a sealed volume both to protect the luminescent coating from environmental influences, and to be able to create a directed radiation flux by the accelerating electric field of charged particles, necessary to excite the luminescence of the luminescent coating, including the cathodoluminophore. Under cathodoluminophores are understood substances that luminesce under the action of an electron beam.

A known light-emitting assembly made in the form of a light-transmitting substrate with a light-emitting surface and equipped with shielding / re-reflection and diffusion of the light flux of light sources (PCT application WO 2005/001331, MKI F21S 8/00, published on January 6, 2005).

The disadvantages of the known solutions are the loss of light flux as a result of repeated re-reflection. Another serious drawback is the relative complexity of the design, containing specially introduced light-scattering lenses, provided with a reflective coating and mounted near each of the light sources, in this case, near the LED.

The closest analogue of the claimed solution is the decision on the PCT application WO 2005/001331.

The technical result of the light-emitting unit according to the invention is to simplify the design, improve the uniformity of the luminosity of the light-emitting surface and increase the efficiency of light sources.

The essence of the light-emitting unit according to the invention can be expressed by the following set of essential features: a light-emitting unit containing a light-transmitting substrate and a light flux scattering means, made in the form of a luminescent coating deposited on a light-transmitting substrate, comprising an optically transparent component - a binder with suspended particles of the photoluminophore introduced into it in the amount of 4-8 mg per 1 cm ^{2 of a} luminescent coating, while the thickness of such a coating is selected from the expression:

0.5 <b <1.5,

where b is the thickness of the luminescent coating, mm,

and its transparency coefficient is selected from the expression:

0.4 <K <0.8,

where K is the transparency coefficient of the luminescent coating.

This coefficient is the ratio of the magnitude of the flux of radiation entering the luminescent coating to the magnitude of the flux of radiation transmitted in the luminescent coating without changing the direction of propagation.

Photoluminophores are substances that luminesce under ultraviolet, visible or infrared light.

A known method of creating a glow of a light-emitting assembly, including generating a light flux by point sources of light, aligning the brightness of the light flux, including by reflecting part of the light flux emitted by the light sources in the axial direction, and then re-reflecting it towards the light-transmitting substrate (PCT application WO 2005/001331, MKI F21S 8/00, published 06.01.2005).

The disadvantages of the known solutions are the loss of luminous flux as a result of its partial shielding and subsequent re-reflection, insufficiently uniformity of the resulting luminosity of the radiating surface.

A known method of creating a glow of a light-emitting assembly, including generating a radiation flux, directing said flux to a luminescent coating to excite luminescence in the visible spectrum (RF patent for invention No. 2155416 for invention, MKI H01J 63/06, publ. 27.08.2000).

The disadvantages of the known solution are its complexity, due to the need to generate an electron flow in vacuum, the creation of an accelerating electric field to excite the luminescence of the luminescent coating, the luminescence source of which is the cathodoluminophore, i.e. a substance having luminescence under the influence of an electron stream.

The closest analogue of the claimed decision on the totality of the operations is the decision on the patent of the Russian Federation No. 21545416.

The technical result of the method is its simplification, improving the uniformity of luminosity and luminance of the glow, increasing the efficiency of light sources.

The essence of the method can be expressed by the following set of essential features:

A method of creating a glow of a light-emitting assembly, including generating a radiation flux, influencing this flux on a luminescent coating, characterized in that a flux of light radiation with a wavelength λ1 is generated, the value of which is selected from the expression:

300 <λ1 <480,

where λ1 is the wavelength of light radiation, nm;

the specified flux of light radiation acts on a luminescent coating, a light transmitting component is used as a binder, and a photoluminophore with a radiation wavelength λ2 of 4-8 mg / cm ² is used as a filler, and the thickness of the luminescent coating is selected from the expression:

0.5 <b <1.5,

where b is the thickness of the luminescent coating, mm,

and the transparency coefficient of the luminescent coating is selected from the expression:

0.4 <K <0.8,

where K is the transparency coefficient of the luminescent coating;

and summing the light fluxes of radiation with wavelengths λ1 and λ2.

The advantages of the method are the ability to vary the brightness and color of the glow of the radiating surface by changing the parameters of the photoluminophore, its amount, wavelength λ1 and transparency coefficient K within the specified limits.

A device is known for creating a glow of a light-emitting assembly, comprising a housing filled with a working gas, inside which a radiation source in the form of a flat cathode is placed, and an accelerating mesh electrode, one of the faces of the housing being made in the form of a light-transmitting substrate coated with a luminescent coating (RF patent No. 21545416 for an invention, MKI H01J 63/06, published August 27, 2000).

The disadvantages of the known device are the design complexity due to the presence of the electrode system, the need to seal the internal volume for the possibility of creating a vacuum and dosing of the working gas.

A device is known for creating a glow of a light-emitting assembly, comprising a housing, one of the faces of which is made in the form of a light-transmitting plate, the outer side of which is a light-emitting surface. Inside the housing there is a light source made in the form of a board with LEDs regularly placed on it, each of which is equipped with means for reflecting the axial component of the light flux, as well as means for re-reflecting and scattering the light flux (PCT application WO 2005/001331, MKI F21S 8/00 , published on January 6, 2005).

A disadvantage of the known solution is the structural complexity and inefficiency of the means to ensure the alignment of the resulting light flux, resulting in losses due to repeated re-reflection.

The closest analogue of the claimed device in the number of matching essential features is the decision on the PCT application WO 2005/001331.

The technical result of the claimed device is to simplify the design, improve the uniformity of luminosity and luminosity, as well as increase the efficiency of light sources.

The essence of the claimed device is characterized by the following set of essential features:

a device for implementing a method for generating a glow of a light-emitting assembly, comprising a housing provided with a light-transmitting facet, inside which a light source is mounted, made in the form of LEDs placed on a board, and a light flux scattering means, characterized in that the wavelength of the radiation of the LEDs is selected from the expression:

300 <λ1 <480,

where λ1 is the wavelength of the radiation of the LEDs, nm;

the inner surface of the body is made of reflective, light-transmitting facet — in the form of a light-transmitting substrate, equipped with a light flux scattering means, made in the form of a luminescent coating deposited on said substrate and including a light-transmitting component — a binder and a photoluminophore, the amount of which is selected from the expression:

4 <C <8,

where C is the number of photoluminophore per unit area of the coating, mg / cm ² ;

the thickness of the luminescent coating is selected from the expression:

0.5 <b <1.5,

where b is the thickness of the luminescent coating, mm;

and the transparency coefficient of the luminescent coating is selected from the expression:

0.4 <K <0.8,

where K is the transparency coefficient of the luminescent coating.

An additional technical effect can be obtained:

- in the presence of a reflective coating on the surface of the board;

- the choice of the distance between the light-emitting node and the board to place the light source from the expression:

L≤51f,

where L is the distance between the light-emitting node and the board to accommodate the light source, mm,

f is the height of the light source, mm;

- by choosing the density of LEDs on the board in the amount of one LED per square centimeter of the board.

Figure 1 shows a fragment of a cross section of a light emitting node according to the invention.

Figure 2 shows an enlarged image of a fragment of a cross section of the light-emitting node shown in figure 1.

Figure 3 shows a device containing a light-emitting assembly shown in figure 1.

Figure 4 shows a diagram of the path of the rays in the device shown in figure 3. The solid line indicates the rays with a wavelength of λ1 generated by LEDs, the dotted line indicates the path of the rays generated by the photoluminophore particles through a light-transmitting substrate with a wavelength of λ2.

Figure 5 illustrates the course of the rays with a wavelength of λ2 generated by the phosphor particles inside the device.

The light-emitting assembly comprises a light-transmitting substrate 1 and a luminescent coating 2, a light-transmitting component - a binder 3 and photoluminophore particles 4.

A device for implementing the method of creating a glow of the light emitting assembly 10 comprises a housing 5 provided with a light transmitting substrate 1 and a luminescent coating 2, a board 6 of LEDs 7, and reflective surfaces 8.

The light emitting node including the device for implementing the method of creating a glow of the light emitting node operates as follows.

Light sources - LEDs 7, located on the board 6, generate a radiation flux with a wavelength of λ1, the value of which is selected from the interval 300 <λ1 <480 nm, falling on the luminescent coating 2, reflective surface 8. Part of the radiation flux with a wavelength of λ1, getting onto a luminescent coating 2, excites into the sphere the light emission of photoluminophore particles 4 with a wavelength of λ2, while a part of the light flux with a wavelength of λ2 passes through the layer of the light transmitting component - binder 3 and the light transmitting substrate 1, is emitted from the light Luciano surface 9. The other part of the light flux with wavelength λ2 in length directed into the housing 5, is reflected from the reflective surfaces 8, penetrates through the cover 2 and the substrate 1 is emitted from the surface 9. Thus, one can maximize the use of LED generated light beam 7.

The concentration of particles of photoluminophore 4 in the light transmitting component - binder 3 is such that they do not completely absorb the light flux with a wavelength of λ1, part of which passes without conversion through the layer of the component - binder 3 and substrate 1 to the light-emitting surface 9. This fact was reflected in the indicated the range of acceptable values of the transmittance of the luminescent coating.

Thus, the resulting luminous flux emitted from the surface 9 is the sum of the luminous fluxes with wavelengths λ1 and λ2.

The value of the concentration of photoluminophore in the binder component in the amount of 4-8 mg per square centimeter for a coating with a thickness of 0.5-1.5 mm is optimal and was established by the applicant as a result of statistical processing of numerous experiments.

The range of possible wavelengths of LED radiation in the form 300 <λ1 <480 nm is selected taking into account the possibility of generating photoluminophore radiation with a wavelength of λ2 lying in the visible spectrum. The summation of two light fluxes with wavelengths λ1 and λ2, the last of which, in turn, is the total radiation flux into the sphere of photoluminophore particles, makes it possible to obtain a bright and uniform glow of the light-emitting surface 9.

The range of optimal values of the distance between the luminescent coating 2 of the light emitting unit 10 and the light source board 6, indicated as: L≤51f, is determined experimentally, depends on the aperture of the LEDs and is a function of the distance at which the brightness of the light emitting trace of the LED on the surface 9 does not exceed 10 thousands cd / m ^2.

An example of a specific implementation of the invention is a lamp for local lighting, containing 200 LEDs with a wavelength of 465 nm, placed on the board with a regularity of 1 LED per square centimeter of the surface of the board, fixed at a distance of 30 mm (6f) from the light emitting node 10, including a glass substrate, a luminescent coating with a thickness of 0.9 mm with a photoluminophore type of yttrium aluminum garnet in an amount of 6 mg per square centimeter of coating and with a transparency coefficient of 0.6. In this case, the light intensity along the axis of the lamp increased by 28-30% and amounted to 140 cd, in the 2α = 90 ° direction the light intensity was 106 cd, and in the 2α = 160 ° direction it was 40 cd, which ensured an increase in uniformity and achievement of brightness of the light-emitting surface tysyach about 5 cd / m ^2.

Claims (6)

1. A light-emitting assembly containing a light-transmitting substrate and a light flux scattering means, characterized in that the light flux scattering means is made in the form of a luminescent coating deposited on a light-transmitting substrate and including a light-transmitting component - a binder and a phosphor in the amount of 4-8 mg per 1 cm of coating, while the thickness of the coating is selected from the expression 0.5 <b <1.5, where b is the thickness of the luminescent coating, mm, and the transparency coefficient of the luminescent coating is selected from the expression 0.4 <K <0.8, where K is the transparency coefficient of the luminescent coating. 2. A method of creating a glow of a light-emitting assembly, including generating a radiation flux, exposure of this flux to a luminescent coating, characterized in that a flux of light radiation with a wavelength, the value of which is selected from 300 <λ1 <480, where λ1 is the wavelength of light radiation, nm, a light transmitting component is used as a binder luminescent coating, and photoluminophore particles with a luminescence radiation wavelength λ2 in an amount of 4-8 mg / cm ² are used as filler, the thickness of the luminescent coating is chosen from the expression 0.5 <b <1.5, where b is the thickness of the luminescent coating, mm, and the transparency coefficient of the luminescent coating is selected from the expression 0.4 <K <0.8, where K is the transparency coefficient of the luminescent coating, and summing the light fluxes of radiation with wavelengths λ1 and λ2. 3. A device for implementing a method of creating a glow of a light-emitting assembly, comprising a housing provided with a light-transmitting face, inside which a light source is mounted, made in the form of LEDs placed on the board, and a light flux scattering means, characterized in that the radiation wavelength of the LEDs is selected from expressions 300 <λ1 <480, where λ1 is the wavelength of the radiation of the LEDs, nm, the inner surface of the casing is made of reflective, light transmitting facet — in the form of a light transmitting substrate, equipped with a light flux scattering means, made in the form of a luminescent coating deposited on said substrate and including a light transmitting component — a binder and a phosphor, the amount of which is selected from the expression 4 <C <8, where C is the number of photoluminophore per unit area of the luminescent coating, mg / cm ² , the thickness of the luminescent coating is selected from the expression 0.5 <b <1.5, where b is the thickness of the luminescent coating, mm, and the transparency coefficient of the luminescent coating is selected from the expression 0.4 <K <0.8, where K is the transparency coefficient of the luminescent coating. 4. A device for implementing the method of creating a glow of a light-emitting assembly according to claim 3, characterized in that the surface of the board is provided with a reflective coating. 5. A device for implementing the method of creating a glow of a light emitting node according to claim 3, characterized in that the distance between the light emitting node and the light source board is selected from the expression L≤51f, where L is the distance between the light emitting node and the board, mm, f is the height of the light source, mm 6. A device for implementing the method of creating a glow of a light emitting assembly according to claim 3, characterized in that the density of the LEDs is selected equal to one LED per square centimeter of the board.

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