WO2017176162A1 - Led lamp - Google Patents

Abstract

The invention relates to lighting technology, and specifically to energy-saving lighting devices created on the foundation of powerful LEDs having a long service life. The invention may be used for creating illumination devices not having a blinding effect, for spaces such as residential rooms, office spaces, car approach areas outside of buildings, and also for illuminating streets and highways. The technical result consists in eliminating the blinding effect of LEDs and providing for uniform illumination. An LED lamp contains a housing, LEDs, a diffusion cover, and reflective plates, which reflective plates are installed in a way that at least a portion of the reflective plates have surfaces which face the LEDs and which are not shielded from LED radiation by reflective plates (not otherwise obscured by the reflective plates) which are located closer to the LEDs in the direction of propagation of a light flux from the LEDs. The LEDs are installed on a circuit board which is perpendicular to the front plane of the projection of the housing and which is inclined toward the diffusion cover, wherein the central rays of the LEDs are directed at a front reflecting plate. The front reflecting plate is installed between the reflective plates and the housing, and has an arc-shaped reflective profile. The reflective plates are in the form of plates having curved reflective surfaces. The reflective plates have varying cross-sectional thickness. The reflective plates abut the diffusion cover. The reflective plates and the diffusion cover are carried out as a single component. The invention contains an end reflecting plate and a front reflecting plate, which are carried out as a single component. An external device is used for power supply.

Description

 LED lamp

The invention relates to lighting engineering, in particular to energy-saving lighting devices created on the basis of high-power LEDs with a long service life. It can be used to create non-blinding illuminators for lighting rooms, such as living rooms, office rooms, driveways, as well as for street lighting and highway lighting.

 Known LED lamp (Utility Model RU 1 10816 U1), comprising a housing of heat-conducting material, located in the housing at least one light source made of one or a group of LEDs, two covers mounted on the ends of the housing, a front panel with at least , one transparent optical element located opposite the light source, forming the luminous flux of the lamp, and a power source, characterized in that at least on one outer surface of the housing longitudinal ribs are made, the diodes are located on at least one printed circuit board mounted on the inner surface of the housing with the possibility of efficient heat transfer, the optical element is formed by a protective glass having local and / or regular changes in curvature, and / or thickness, and / or optical properties, on the covers ribs are made, repeating the shape of the ribs of the housing, the lamp is equipped with an additional housing, and the power source is placed in an additional housing. To eliminate the blinding effect in the specified device, it is proposed to perform an optical element in the form of a Fresnel lens; or perform microprisms on the glass surface of the optical element; or perform group lenses on the glass of an optical element on all or part of the LEDs; or perform on the glass of the optical element of the lens or group of lenses located above each or part of the LEDs. An obvious design flaw is the difficulty in manufacturing associated with the complexity of manufacturing the mentioned optical elements (Fresnel lenses, microprisms, group lenses, lenses and lens groups located above each or part of the LEDs).

A known lamp with reflectors (IPC F21S8 / 10 (2006.01), RU 2401395 C1) comprising a housing with a board on which three rows of LED lamps are mounted, a power supply located in the housing, and having reflective plates with high reflectivity installed behind first row at an angle of 60 ° to plane of the board, behind the second row - at an angle of 45 ° to the plane of the board and behind the third row - at an angle of 90 ° to the plane of the board. Such a lamp has a reduced blinding effect when it is located relatively far away from the lighted point, that is, when it is used to illuminate open spaces, access roads of vehicles, in quarries, moorings, etc. The disadvantage of this device is the inability to use it indoor because of the high glare, as the use of reflective plates does not affect the brightness of LEDs in certain directions.

 A car lamp is known (US20050073229 A1), comprising a device for distributing light, producing a parallel light flux, which is then removed from the lamp through a plurality of partially transmission plates located at an angle to the light passing through them. In this case, partially transmitting plates can be located at different angles to the incident radiation, which allows you to change the radiation pattern. On each plate, only part of the light flux is reflected, which significantly reduces the blinding effect of the light source. The disadvantage is that the luminous flux of the source is distributed unevenly over the output window, in addition, in this patent, from the various options for the arrangement of the plates, neither the optimal law nor the general regularity of their arrangement relative to each other, which would ensure the most uniform distribution of the light flux and lighting all directions.

The closest design adopted as the prototype is an LED lamp (F21V7 / 00 (2006.01), RU 2543513 C1) containing a power supply; housing; diffuser cover; reflector plates; fee; LEDs end and front reflective plates with a high light reflectance. At the same time, translucent plates are located at such angles that, thanks to the laws of Fresnel reflection, exactly the same amount of light is reflected on each subsequent plate as on the previous one. Thus, the light emitting diodes are evenly distributed over the diffuser cover and the blinding effect is eliminated most effectively. The disadvantage of this lamp is that in order to obtain a uniform intensity distribution over the diffuser cover, it is required that the angle of incidence of light on each subsequent plate, if counted from the LEDs, be greater than the previous one. This leads to the fact that such a lamp does not provide uniform illumination in all directions. The technical result of the invention is to eliminate the blinding effect of LEDs and ensure uniform illumination.

 The technical result is achieved in an LED luminaire comprising a housing, LEDs, a diffuser cover, reflective plates mounted in such a way that at least a portion of the reflective plates have surfaces facing the LEDs that are not obscured by the LED radiation from the reflective plates (otherwise, blocked by reflecting plates) located closer to the LEDs, along the propagation of the light flux from the LEDs. LEDs are mounted on a board perpendicular to the frontal plane of the projection of the housing and inclined to the diffuser cover, with the central rays of the LEDs facing the front of the reflective plate. The front reflective plate installed between the reflector plates and the body has an arcuate reflective profile. Reflective plates are made in the form of plates with curved reflective surfaces. Reflecting plates have a thickness different in cross section. Reflective plates are adjacent to the diffuser cover. The reflecting plates and the diffuser cover are made as a single part. It contains an end reflective plate and a front reflective plate made in the form of a single part. An external device is used for power supply.

FIG. 1 shows an example of an LED luminaire equipped with five reflector plates made in the form of optically transparent plates adjacent to the diffuser cover, and the path of light radiation reflected from the first reflector plate to the diffuser cover: 1 - power supply unit; 2 - case; 3 - front reflective plate, 4 - board, 5 - LEDs, 6 - diffuser cover; 7-1, 7-2, ... 7-5 - reflector plates; 8 - end reflective plate; γι, γ ₂ , γ ₃ , at A, at 5 are the angles between the diffuser cover and the first, second, fifth reflector plates, respectively, counted from the LEDs, and Θ is the angle between the diffuser cover and the end reflective plate.

FIG. 2 shows an example of an LED luminaire equipped with five reflector plates made in the form of optically transparent plates adjacent to the diffuser cover, and the path of light radiation reflected from the second reflector plate to the diffuser cover: 1 - power supply unit; 2 - case; 3 - front reflective plate, 4 - board, 5 - LEDs, 6 - diffuser cover; 7-1, 7-2, ... 7-5 - reflector plates; 8 - end reflective plate; at γ ₂ , bonds, 74, At 5 - the angles between the diffuser cover and the first, second, fifth reflector plates, respectively, counted from the LEDs, Θ is the angle between the diffuser cover and the end reflective plate.

FIG. 3 shows an example of an LED lamp equipped with five reflector plates made in the form of optically transparent plates adjacent to the diffuser cover, and the course of the middle rays reflected from the reflector plates of the end reflective plate to the diffuser cover: 1 - power supply unit; 2 - case; 3 - front reflective plate, 4 - board, 5 - LEDs, 6 - diffuser cover; 7-1, 7-2, ... 7-5 - reflector plates; 8 - end reflective plate; γ _1? γ ₂ , γ ₃ , γ ₄ , γ ₅ are the angles between the diffuser cap and the first, second, fifth reflector plates, respectively, counted from the LEDs, Θ is the angle between the diffuser cap and the end reflective plate.

FIG. 4 shows an example of an LED lamp equipped with five reflector plates made in the form of optically transparent plates adjacent to the diffuser cover, with a board located at an angle to the diffuser cover: 1 - power supply unit; 2 - case; 3 - front reflective plate, 4 - board, 5 - LEDs, 6 - diffuser cover; 7-1, 7-2, ... 7-5 - reflector plates; 8 - end reflective plate; γι, γ ₂ , γ ₃ , γ ₄ , γ ₅ are the angles between the diffuser cover and the first, second, fifth reflector plates, respectively, counted from the LEDs, β is the angle between the diffuser cover and the circuit board with LEDs, Θ is the angle between the diffuser cap and the end reflective plate.

FIG. 5 shows an example of an LED luminaire equipped with five reflector plates made in the form of optically transparent plates adjacent to the diffuser cover and the course of peripheral rays reflected from the front reflective plate with an arched reflective profile: 1 - power supply unit; 2 - case; 3 - front reflective plate, 4 - board, 5 - LEDs, 6 - diffuser cover; 7-1, 7-2, ... 7-5 - reflector plates; 8 - end reflective plate; γι, γ ₂ , γ ₃ , γ ₄ , γ ₅ are the angles between the diffuser cover and the first, second, fifth reflector plates, respectively, counted from the LEDs, Θ is the angle between the diffuser cover and the end reflective plate.

FIG. 6 shows an example of an LED lamp equipped with five reflector plates made in the form of optically transparent plates with curved reflective surfaces adjacent to the diffuser cover: 1 - block nutrition; 2 - case; 3 - front reflective plate, 4 - board, 5 - LEDs, 6 - diffuser cover; 7-1, 7-2, ... 7-5 - reflector plates; 8 - end reflective plate; γι, γ ₂ , γ ₃ , γ ₄ , γ ₅ are the angles between the diffuser cover and the first, second, fifth reflector plates, respectively, counted from the LEDs, Θ is the angle between the diffuser cover and the end reflective plate.

FIG. 7 shows an example of an LED luminaire equipped with five reflector plates with an unequal cross-sectional thickness, made in the form of optically transparent plates adjacent to the diffuser cover: 1 - power supply unit; 2 - case; 3 - front reflective plate, 4 - board, 5 - LEDs, 6 - diffuser cover; 7-1, 7-2, ... 7-5 - reflector plates; 8 - end reflective plate; y \, γ ₂ , γ ₃ , γ ₄ , γ ₅ are the angles between the diffuser cover and the first, second, fifth reflector plates, respectively, counted from the LEDs, and Θ is the angle between the diffuser cover and the end reflective plate.

FIG. 8 shows an example of an LED lamp equipped with five reflector plates made as a single part with a diffuser cover: 1 - power supply unit; 2 - case; 3 - front reflective plate, 4 - board, 5 - LEDs, 6 - diffuser cover; 7-1, 7-2, ... 7-5 - reflector plates; 8 - end reflective plate; γ _1? γ ₂ , γ ₃ , γ ₄ , γ ₅ are the angles between the diffuser cap and the first, second, fifth reflector plates, respectively, counted from the LEDs, Θ is the angle between the diffuser cap and the end reflective plate.

The LED lamp includes a power supply 1, housing 2, front reflective plate 3, board 4, LEDs 5, diffuser cover 6, reflective plates 7 (reflector plates 7) having different projection surfaces of reflective surfaces onto a plane simultaneously perpendicular to the plane of the diffuser and the frontal plane of the projection of the housing, the end reflective plate 8.

The reflecting plates 7 are installed in such a way that at least part of the reflecting plates 7 have surfaces that are not obscured by the radiation of the LEDs by the reflecting plates (not covered by the reflecting plates 7) located closer to the LEDs 5, along the propagation of the light flux from the LEDs 5. Below are described some of the possible options for implementing this principle associated with the use of reflective plates 7 of different sizes. For example, reflective plates (the term “reflector plates” is also used hereinafter) can have different projection surfaces of reflective surfaces onto a plane that is simultaneously perpendicular to the plane of the diffuser cover 6 and the frontal plane of projection of the housing 2, satisfying the condition Si <S ₂ <S ₃ <. .. <S _n- i <S _n , where Si, S ₂ , S3, S _n - _b S _n are the areas of the first, second, third, ..., η-first and η-th projections of the reflecting surfaces of the plates -reflectors 7, counted from the board with light-emitting diodes, and the reflector plates are adjacent to the diffuser cover. The board 4 with LEDs 5 can be installed perpendicular to the frontal plane of projection of the housing 2 and inclined to the diffuser cover, with the central rays of the LEDs 5 facing the front of the reflective plate 3.

In addition, the same result can be achieved with a different position of the sequence of reflective plates 7 in the housing 1.

The LEDs 5 are mounted on the board 4, perpendicular to the frontal plane of the projection of the housing and inclined to the diffuser cover 6, the central rays of the LEDs facing the front reflective plate 3. The front reflective plate 3, mounted between the reflector plates 7 and the housing 2, may have arcuate reflective profile.

 Reflective plates can be made in the form of plates with curved reflective surfaces. Reflecting plates may have a thickness of a different cross section. Reflective plates may abut the diffuser cover. Reflecting plates and a diffuser cover can be made as a single part. An external device is used for power supply.

LED lamp works as follows. When the power supply is turned on, the LEDs located on the board turn on. They begin to radiate light.

To understand the operation of the lamp, you need to know the following. The blinding effect of a light source is determined by its brightness. The greater the brightness, the higher the glare effect. Brightness is the luminous flux sent by a unit of visible surface area in a given direction to a unit solid angle. Therefore, at a given power of the light source, its brightness is inversely proportional to the area of the emitting surface. Thus, the blinding effect of the light source can be eliminated by increasing the visible to the observer emitting surface area. The visible radiating surface of the lamp for the observer in this case will be a diffuser cover. Therefore, to eliminate the blinding effect, it is necessary to evenly distribute the light flux from the LEDs on the diffuser cover. In this invention, this problem is solved using reflector plates, which also create the necessary radiation pattern of the entire lamp. Therefore, each reflector plate is positioned at such an angle to direct a certain amount of light flux at a certain angle to a specific area of the diffuser cover.

Let the number of reflector plates p. Each of the n reflector plates should reflect the same amount of light flux Φ ₀ , which is determined by the number of reflector plates.

 Since the distance from the LEDs to any reflector plate is comparable to the geometric dimensions of the reflector plate itself, as a result of which the rays incident at different points will fall at different angles, the reflector plates at each point will have different reflection coefficients. In addition, the intensity of each beam at each point of the reflector plate will also vary. Therefore, to explain the operation of the LED lamp according to this invention, it will be convenient to use averaged values.

It is known that the total light flux incident on the first reflector plate is i = Ii * S where I] is the average light flux density (light intensity) incident on the first reflector plate, St is the projection area of the reflective surface of the first reflector plate on the plane perpendicular to the plane of the diffuser cover and the frontal plane of the projection of the housing, determined by the formula Si = si * sin (yi), where si is the area of the reflective surface of the first reflector plate, γι is the angle between the first reflector plate and the diffuser cover (Phi d. 1). Let r! - the average coefficient of light reflection from the first reflector plate, taking into account reflection from two media boundaries for a given angle γι. Since the luminous flux reflected from the first reflector plate must be equal to Фо, ri * Ii * S ₁ = Oo- Since m _\ is determined by the angle of the plate reflector γι relative to the diffuser cap, which in turn depends on the direction of light reflection, a Ιι is determined by the distance from the reflector plate to the LEDs, then a certain projection area of the reflecting surface Sj is required for reflection from the first reflector plate of the light flux Ф ₀ . On the second the reflector plate should reflect the same amount of light flux f ₀ . In this case, due to the divergence of radiation, light with a lower intensity I ₂ <Ij will fall on the second reflector plate, since the second reflector plate is located farther from the LEDs. In addition, the luminous flux is partially attenuated by the first reflector plate. The averaged reflection coefficient from the second plate r _{2 is} predetermined by the orientation of the second reflector plate. To compensate for the decrease in intensity 1 _{2 the} second reflector plate should have a larger projection area of the reflecting surface S ₂ . The reflection of radiation from the second reflector plate is shown in FIG. 2. Similarly, the third reflector plate will have to have a projection area of the reflecting surface S ₃ > S ₂ , and the fourth plate with an area of S ₄ > S ₃ and so on. Due to the fact that the farther away from the LEDs the reflector plate is, the larger the projection area of its reflecting surface will be, light from the LEDs will be reflected in equal parts from the reflector plates. It is worth noting that the condition S _n > S _n- i for reflector plates may not be met, for example, in the manufacture of different reflector plates from different materials. Behind the last reflecting plate, an end reflecting plate with a high reflection coefficient is installed, which reflects the remnants of the light emitting diodes. By changing the angle between the end reflective plate and the diffuser cover Θ, the radiation reflected from the end reflective plate can be directed in the desired direction. For uniform distribution of radiation over the diffuser cover, it is necessary to install reflector plates so that the middle rays of the reflected radiation fall on the diffuser cover at approximately the same distance D from each other, with an accuracy sufficient for indistinguishable distances D to most users, while the accuracy of the same distances D may vary depending on the distance between the lamp and the user, in accordance with the approved norms and rules of artificial lighting for that other illuminated object (FIG. 3), where under the middle beam is meant beam propagating in the frontal housing projection plane and reflected from a point located in the middle of the segment, the resultant of beam incidence plane and the reflecting surface. The diffuser cover has a matte surface and is designed for scattering and depolarization of radiation, which further reduces the blinding effect of the lamp. Thus, the LED radiation will be equally distributed between all reflector plates and the end reflective plate, resulting in the brightness of the lamp to decrease at least n + 1 times and the blinding effect will be eliminated, while the total luminous flux of the lamp practically does not decrease.

 The principle described above will be applicable for reflector plates of any shape, however, the most technologically advanced and simplest for theoretical calculations will be the use of rectangular reflector plates adjacent to the reflector cover.

 Reflector plates in the LED lamp according to this invention, depending on the dimensions of the lamp, type and characteristics of LEDs, etc. can be located at different angles γ in the range 0 <γ <90 °.

The distribution of the light flux of the radiation of each LED in space is determined by its radiation pattern, i.e., the density of the light flux in different directions of the LED radiation will vary. As a rule, the central beam of an LED has a higher flux density than peripheral ones. Since I]> 1 _p , to reduce the difference Ii - I _{n, the} board with LEDs can be placed at an angle β to the housing so that the beam with the maximum light flux density is directed to the reflector plates located near the end reflective plate, bypassing near reflector plates (Fig. 4). Due to this, radiation with a lower flux density will fall on the reflectors closest to the LEDs of the plate, which further increases the uniformity of illumination on the diffuser cover, reducing the blinding effect of the lamp.

 The front reflective plate is used to reflect radiation falling on the inner surface of the housing. Its arcuate reflective profile provides the re-reflection of the peripheral rays of the LEDs on the reflector plates located near the end reflective plate (see Fig. 5). To simplify the design and reduce the cost of production, the front reflective plate can be made in the form of a single part with the end reflective plate.

 To increase the divergence of the radiation reflected from the reflector plates, the reflector plates may have curved reflective surfaces or uneven cross sectional thickness. Examples of luminaires with reflector plates having curved surfaces and uneven cross-sectional thicknesses are shown in Fig. 6 and Fig. 7, respectively.

In the LED lamp according to this invention, the number of LEDs can be from one to several tens or more. They can be located in one or more rows. Light diodes on the board can also be arranged out of order. Reflector plates can be made of optical material with a reflective coating that provides the necessary reflection coefficients. If reflector plates are made in the form of optically transparent plates, they can be made of any material transparent to visible light, for example, glass or polycarbonate. To simplify the design, the reflector plates and the diffuser cover can be manufactured in one piece (Fig. 8), for example, by extrusion.

It should be added that the implementation of reflector plates having different projection areas of reflective surfaces satisfying the condition Si <S ₂ S ₃ <... <S _n- i <S _n allows you to reduce the weight of the luminaire and save on material, thereby reducing its cost .

Claims

Claim

1. An LED lamp comprising a housing, LEDs, a diffuser cover, reflective plates mounted in such a way that at least a portion of the reflective plates have surfaces that are not obscured by LED radiation by reflective plates located closer to the LEDs, in the direction of propagation of the light flow from LEDs.

 2. The LED lamp according to claim 1, characterized in that the LEDs are mounted on a board perpendicular to the frontal plane of the projection of the housing and inclined to the diffuser cover, the central rays of the LEDs facing the front of the reflective plate.

 3. The LED lamp according to claim 1, characterized in that the front reflective plate mounted between the reflector plates and the housing has an arched reflective profile.

 4. The LED lamp according to claim 1, characterized in that the reflective plates are made in the form of plates with curved reflective surfaces.

 5. The LED lamp according to claim 1, characterized in that the reflective plates have a thickness different in cross section.

 6. The LED lamp according to claim 1, characterized in that the reflective plates are adjacent to the diffuser cover.

 7. The LED lamp according to claim 1, characterized in that the reflective plate and the diffuser cover are made in the form of a single part.

 8. The LED lamp according to claim 1, characterized in that it contains an end reflective plate and a front reflective plate made in the form of a single part.

 9. The LED lamp according to claim 1, characterized in that an external device is used for power supply.