RU2566816C2 - Optical system and surface lighting method - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention relates to lighting engineering. The optical system includes aggregate of point-light sources as well as aggregate of secondary optics - modular system of reflectors, at that point-light sources are divided into several groups, at that optical axes of light sources forming a separate group are parallel between each other while optical axes of different groups are not parallel. Each module consists of multitude of cells. In each cell there is one light-emitting diode; the cell comprises from four up to eight reflecting flat plates. The cells may be similar but they may also differ by number and shape of plates, plate tilt angle and optical axis of light source, geometry of light source in regard to plates. Similar and different cells may be placed both in the same reflecting module or different modules. The reflector cell and point-light source placed in it form together the secondary light source. Different light sources may have different characteristics of light distribution or different spatial orientation. Light distribution of the illuminator is obtained as composition of light distribution for all secondary light sources.

EFFECT: improvement of lighting quality.

6 cl, 5 dwg

Description

The present invention relates to the field of lighting engineering and can be used for lighting streets, courtyards, industrial areas, bridges and tunnels.

Known optical system described in patent US 8042968, published October 25, 2011 and includes a combination of point light sources (LEDs) and a modular system of reflectors. The geometric orientation of all LEDs is the same, that is, their optical axes are parallel. The modular reflector system used in the known optical system provides for the use of modules, each of which consists of many cells. Each cell has one LED, the cell has four reflective plates. Structurally, the reflector module is made of longitudinal and transverse strips of aluminum foil (for example, Alanoda brand). The foil is curved so that longitudinal reflective walls of the cells of the desired geometry are formed, bent V-shaped foil plates are inserted into the cutouts of the longitudinal reflective walls, which form the transverse walls of the cells. That is, the plates intersect with each other so that several cells / rows of cells of the reflector module are formed, in each of which, when the reflector is installed in the optical system of the lamp, an LED is placed. The shape and dimensions of the plates, as well as their angles of inclination to the optical axis of the LED and the location relative to the LED, are designed in such a way that each cell with the LED creates a certain spatial distribution of the light emission power. To increase stiffness, the reflector can be equipped with a frame with the necessary set of mounting tabs and holes. Each cell, together with the LED located in it, creates a secondary light source. Using cells of two or more geometric shapes, two or more secondary light sources with different light distribution characteristics can be created. The light distribution of the lamp is obtained as a composition of the light distributions of all secondary light sources.

The disadvantages of the known from US 8042968 optical system include the following:

- the same spatial orientation of the optical axes of the LEDs reduces the variability of the created light distributions and thereby reduces the possibility of obtaining with high accuracy the light distribution of the lamp in accordance with the required parameters;

- the method of mounting the reflector plates with each other does not provide sufficient structural rigidity and, as a consequence, the constancy of light distribution;

- the foil bending operation used in the manufacture of the reflector module cannot provide a sufficiently high accuracy of the geometry of the plates and, accordingly, the cells, which leads to a mismatch of the light distributions of the secondary light sources with the calculated requirements.

Due to deficiencies in the design of reflectors, the optical system described in US 8042968 does not provide the required redistribution quality and light direction, that is, it does not provide control of the lighting quality in a particular place, and the known optical system is also characterized by excessive design complexity.

As the closest analogue of the invention, an optical system having two groups of LEDs arranged in a luminaire such that the optical axis of the LEDs of both groups are not parallel to each other can be selected. There is a reflector, divided into separate cells according to the principle of one cell - one diode (US 2011075409, 03/31/2011).

However, this system does not contain a modular system of reflectors, in which different groups of cells of the modular system of reflectors have a different shape, which does not allow, in the presence of groups of diodes with different directions of the optical axes, to obtain such a composition of light fluxes to obtain a total light flux with a spatial distribution of light, providing optimal lighting.

In turn, the present invention will eliminate the above disadvantages and will allow us to offer an optical system that is characterized by the quality of lighting when combined with the simplicity of design.

The above technical result is achieved using the inventive optical system and surface lighting method.

The proposed optical system includes a set of LEDs (point light sources), as well as a set of secondary optics - a modular system of reflectors. LEDs are divided into several groups, and the optical axis of the light sources forming a separate group are parallel to each other, and the optical axis of the light sources of different groups are not parallel.

The modular reflector system consists of individual modules. Each module consists of many cells in which one LED is located in the presence of four to eight flat plates of reflective material, mainly foil, and in each of these plates grooves are made with a length equal to part of the height of the plate, each of the intersecting plates entering the groove of the other plates all the way. The module also consists of longitudinal and transverse flat plates of reflective material, mainly foil, intersecting each other with the formation of cells / rows of cells of the reflector module. In each of the indicated plates of the module, grooves are made with a length equal to a part of the height of the plate, and each of the intersecting plates fits into the groove of the other plate to the stop (the intersecting plates have a groove in the groove, that is, each of the intersecting plates with its groove enters the groove of the other plates all the way). The cells may be the same, but may differ between each other in the number and geometry of the plates, the angles of inclination of the plates between themselves and the optical axis of the light source, and the geometry of the location of the light source with respect to the plates. The same and different cells can be located in the same module of the modular system of reflectors, as well as in different modules of the modular system of reflectors. The module plates must be rigid enough to confidently maintain the given cell shape, and the material used for them should have the highest possible reflection coefficient (it is supposed to use Alanod reflective aluminum foil 0.4 mm thick with a reflection coefficient of 98%).

The module can be equipped with a frame that provides structural rigidity and formed by plates, moreover, for arranging the frame plates with each other and with reflective plates, a groove is made in each of the frame plates with a length equal to a part of the plate height, each of the intersecting plates entering the groove of the other plate up to emphasis. The frame plates are made of the same material as reflective plates or of a more rigid material, for example steel. For the necessary positioning of the reflector relative to the LEDs on the frame or reflective plates, protrusions are made which, when the reflector is installed in the lamp, enter the holes in the LED boards. The plates are made of laser-cut foil and assembled into a module, like a 3D puzzle. Such a design, on the one hand, allows one to achieve high accuracy (the accuracy of laser cutting is 0.1 mm) of the geometry of the cells of the modular reflector system and thereby ensure high accuracy of the correspondence of the real spatial distribution of the light emission to the calculated one, as well as to ensure the simplicity of manufacturing the modular reflector system.

The proposed method of surface illumination involves the use of an optical system including a set of LEDs (point light sources), as well as a set of secondary optics - a modular system of reflectors. In contrast to the analog, the optical system described above is used, while the spatial orientations of the LEDs, the shape and / or dimensions of the plates of the modular reflector system, as well as the location, including the tilt angles of the plates of the modular reflector system, are selected relative to the LED so that each cell with an LED provides a certain spatial distribution of light. The light distribution of the lamp is obtained as a composition of the light distributions formed by the cell and the LED located therein. In this case, different cells and the LEDs located in them form different spatial distributions of light, determined by the spatial orientation of the LEDs, the geometry of the cut plates, the relative position of the plates, the positioning of the LED cells and the shape of the cut plates. The geometric characteristics of the reflector cells, the placement of the LEDs from the point of view of their spatial orientation are calculated so that the light distribution of the lamp matches the required light parameters as closely as possible.

The operation of the proposed optical system / practical implementation of the proposed method of lighting the surface can be illustrated by the example of an LED lamp.

The luminaire consists (Fig. 1) of the central (three rows of LEDs, I group of LEDs) and two side (two rows of LEDs, II and III, as well as IV and V groups of LEDs) of the housing. The optical axis of all the LEDs of the central case are parallel to each other, and form the first group of LEDs. The optical axes of the group II LEDs of the side of the housing are tilted to the optical axes of the group I LEDs of the central case at an angle of 41 ° (respectively, the optical axis of the LEDs of group II and IV is 82 °). The optical axes of group III LEDs of the side housing are tilted to the optical axes of the LEDs of group I of the central body at an angle of 50 ° (respectively, the optical axis of the LEDs of group III and V of the group is 100 °).

The modular reflector system consists of five modules: one reflector module in the central part of the housing and two reflector modules in each side part:

The 1st module forms the same cells for the LEDs of group I, the cells of the 1st module have 4 plates and form the 1st type of cells (Fig. 2, Fig. 5);

The 2nd module forms the cells for the LEDs of group II and III, the 2nd module contains cells of the 2nd and 3rd type, which have 4 plates (Fig. 3, Fig. 5);

The 3rd module forms the cells for the LEDs of group II and III, the 3rd module contains cells of the 4th and 5th type, which have 4 plates (Fig. 4, Fig. 5);

The 2nd and 3rd modules are mirror symmetric to the 4th and 5th modules, respectively, as a result we get 2 types of cells of the 4th module (6th and 7th types) and 2 types of cells of the 5th module ( 8th and 9th species) (Fig. 3, Fig. 4, Fig. 5).

As a result:

group I LEDs together with cells of the 1st type form the spatial distribution of light of the 1st type;

group II LEDs together with cells of the 2nd type form the spatial distribution of light of the 2nd type;

group III LEDs together with cells of the 3rd type form the spatial distribution of light of the 3rd type;

group II LEDs together with cells of the 4th type form the spatial distribution of light of the 4th type;

group III LEDs together with cells of the 5th form form the spatial distribution of light of the 5th type;

group IV LEDs together with cells of the 6th type form the spatial distribution of light of the 6th type;

group V LEDs together with 7th type cells form the spatial distribution of 7th type light;

group IV LEDs together with 8th type cells form the spatial distribution of 8th type light;

group V LEDs together with 9th type cells form the spatial distribution of 9th type light.

The result of the composition of the spatial distribution of light of all the above types of spatial distribution of light is the formation of a new spatial distribution of light of the entire lamp, which differs from the 1st - 9th types of spatial distribution of light. This distribution of light has parameters that allow for certain ways of arranging the fixtures in relation to the road to provide effective, from the point of view of fulfilling the standards of lighting and energy consumption, street lighting and highways.

The proposed approach to lighting control can be used in various fields of science and technology. The invention described above allows specialists to make and use what is currently considered the best, these specialists will understand and appreciate the presence of variations, combinations, equivalents of a particular embodiment, method, and examples described above. The invention therefore should be limited not only to the above options, methods and examples, but also to all options and methods within the scope and spirit of the invention.

Claims (6)

1. An optical system, characterized in that it includes a set of LEDs and a set of secondary optics - a modular system of reflectors, while the LEDs are divided into several groups, the optical axes of the LEDs forming a separate group are parallel to each other, and the optical axis of the LEDs of different groups not parallel, moreover, the module of the modular system of reflectors consists of many cells formed by intersecting from each other from four to eight longitudinal and transverse flat plates of light Rage material and each of which has one LED in each of said plate grooves formed length equal to the height of the plate portion, wherein each of the intersecting plates included in the groove of the other plate up to the stop. 2. The optical system according to claim 1, characterized in that the reflective material is foil. 3. The optical system according to claim 1, characterized in that the module of the modular system of reflectors is equipped with a frame formed by plates, and for arranging the frame plates with each other and with reflective plates, a groove is made in each of the frame plates equal to a part of the plate height. 4. The optical system according to claim 3, characterized in that for the necessary positioning of the reflector relative to the LEDs on the frame or reflective plates, protrusions are made which, when the reflector is installed in the lamp, enter the holes in the LED boards. 5. The optical system according to claim 1 or 3, characterized in that the plates of the modular reflector system are made of laser-cut foil sheet and assembled into a module as a 3D puzzle. 6. The method of lighting the surface, involving the use of an optical system comprising a set of LEDs and a set of secondary optics - a modular system of reflectors, characterized in that they use the optical system according to any one of paragraphs. 1-5,
the shape and / or dimensions of the plates of the modular system of reflectors, as well as the location, including the angles of inclination of the plates of the modular system of reflectors relative to the LED, are selected so that each cell with an LED provides a spatial distribution of light that most closely matches the required light parameters and has different light distribution characteristics and / or spatial orientation.

Images