RU2784577C1 - Lighting device - Google Patents

Abstract

FIELD: lighting engineering.

SUBSTANCE: lighting device belongs to the field of lighting engineering and is intended for use as a lighting device in office, retail, sports, industrial and other, for example, domestic premises. The claimed lighting device contains a carrier surface with radiation sources installed on it in the form of LEDs and a set of reflective surfaces, excluding direct observation of radiation sources that form the radiation indicatrix they create, reflections and the final indicatrix of the total luminous flux. The carrier surface is made in the form of a polyhedral, including a truncated, pyramid, on the faces of which radiation sources are installed in the amount n1, selected within 1≤n1≤10², forming the radiation indicatrix together with the reflecting sections of the carrier surface, the total area S1 of which is selected in relation to the area S2 of the entire bearing surface within 1≤(S1+S2)/S2≤1.7, the polyhedral pyramid is made with the number of faces n2, selected in relation to the number n3 of the maximum possible number of faces within 1,003≤(n2+n3)/n3≤2.

EFFECT: increasing the uniformity of the radiation intensity in space in the range of its observation surfaces.

4 cl, 4 dwg

Description

The proposed device relates to the field of lighting engineering and is intended for use as a lighting device in office trade, sports, industrial and other, for example, domestic premises.

To illustrate the known level of developments in this area, one can indicate the objects protected by patents No. 2240470, 24099162, 473007, 2502013, 2506492 and 2509952 for inventions, as well as information reflected in the monograph "Reference Book on Lighting Engineering" edited by Yu.B. Aizenberg (195, Moscow, Energoatomizdat publishing house). The disadvantages of the known devices are, in particular, the uniformity of the intensity of the light flux in space in many practical cases of use in the range of its observation surfaces and limited possibilities for controlling the light flux.

The closest analogue (prototype) of the claimed technical solution in terms of the similarity of essential features is a product protected by patent No. This lighting device contains a carrier surface with radiation sources installed on it in the form of LEDs and a set of reflective surfaces, excluding direct observation of radiation sources that form the radiation indicatrix they create, reflections and the final indicatrix of the total luminous flux.

The problem solved by the product is to improve the known devices to eliminate their shortcomings with the achievement of a technical result in terms of increasing the uniformity of the intensity of the light flux in space in the range of its observation surfaces.

The specified technical result is provided with the help of the proposed lighting device, schematically reflected in the following figures of the drawings.

Fig. 1 - Image of the cross section of the lighting device.

Fig. 2 - Top view of a lighting device with a bearing surface in the form of a tetrahedral pyramid.

Fig. 3 - Schematic representation of the LED with its angle of inclination to the vertical.

Fig. 4 - Schematic representation of the section of the lighting device with additional reflective surfaces.

In FIG. 1-4 - numbers indicate:

1 - the bearing surface of the device, made in the form of a polyhedral pyramid,

2 - radiation sources (LEDs),

3 - observation surface of the total radiation indicatrix in its cross section of the luminous flux of all LEDs,

4 - reflective sections of the bearing surface,

5 - main reflective surface,

6 - schematic representation of the small base of a truncated pyramid,

7 - working surface of a silicon wafer,

8 - center of mass of the silicon wafer,

9 - silicon plate of the LED,

10 - line lying on the working surface of the silicon wafer 9 and passing through the vertical,

11 - point of maximum distance from the horizontal section 12 of the main reflective surface 5,

12 - horizontal section 12 of the reflective surface 5,

13 - dotted line passing through the center 8 of the mass of the LED 2 and parallel to the horizontal section 12,

14 - a set of additional reflective surfaces of the device S3, S4 and S5,

15 - dotted line marked plane parallel to the horizontal section 12 of the main reflective surface 5 and passing through the point 11 of the main reflective surface that is the most remote from it,

16 - final indicatrix of the total luminous flux of radiation sources and all reflective surfaces,

17 - observation surface illustrating the achievement of the specified technical result.

List of letter designations in the claims and on the figures of the drawings.

n1 - number of radiation sources,

S1 - the total area of the reflective sections 4 of the bearing surface,

S2 - area of the entire bearing surface,

n2 - the number of faces of the polyhedral pyramid,

n3 is the maximum possible number of pyramid faces,

α1 - the minimum of the angle values at each of the vertices of the faces of the pyramid,

α2 - the maximum possible value of the angles at the vertices of the faces of the pyramid,

β is the angle of inclination of the face of the pyramid to the vertical of the LED (in Fig. 1) and, accordingly, the angle of inclination of the LED (in Fig. 3),

γ is the angle of the radiation indicatrix in its cross section of the final formed light flux of its total intensities,

L1 - minimum size of the main reflective surface 5,

L2 - maximum size of the main reflective surface 5,

L3 is the distance from the plane passing through the horizontal section 12 of the main reflective surface 5 to a parallel plane passing through the center of mass 8 of the silicon wafer,

L4 is the distance from the plane passing through the horizontal section 12 of the main 5 reflective surface to a plane parallel to it, passing through the point 11 of the main reflective surface 5 that is the most remote from it,

S3, S4, S5, S6 and S7 are the areas of additional reflective surfaces, respectively,

S is the total sum of the area of all five additional reflective surfaces,

In a detailed description of the lighting device (Fig. 1-4), it is not advisable to dwell on its structural units and elements known from published sources, but only the following, mainly distinctive, design and other essential features should be described in more detail. To achieve this technical result, a lighting device is proposed that contains a carrier surface 1 (Fig. 1,2,4) with radiation sources 2 installed on it in the form of LEDs and a set of reflective surfaces that excludes direct observation of radiation sources that form the reflection radiation indicatrices created by them and the final indicatrix 16 of the total luminous flux.

The indicatrix of radiation (reflection) is a curve that graphically displays the intensity of the light flux in the range of angles of its observation, as well as in the range of surfaces of its observation. The angle of the indicatrix or the range of angles of observation of the light flux of the indicatrix is determined by the boundaries at which the intensity of the light flux drops to 10% of its maximum value, or which cover 90% of the radiation. The observation surface is a set of nearby points of observation of the light flux, in which the difference in the values of the light flux is minimal. Also, the indicatrix is often called the directional pattern of the light flux.

The device differs from the known ones in that the bearing surface 1 is made in the form of a multifaceted pyramid, on the faces of which radiation sources 2 are installed in the amount of n1, selected within 1≤n1≤10 ² , forming the radiation indicatrix 3 (Fig. 2) in its cross section the luminous flux of all LEDs, together with the reflective sections 4 of the bearing surface. In this case, on one face of the pyramid of the bearing surface 1 there can be from one to 10 LEDs. The total area S1 of the reflective sections 4 is selected in relation to the area S2 of the entire bearing surface 1 within 1≤(S1+S2) / S2≤1.7. A polyhedral pyramid in many practical cases can be made truncated and/or composed of thin edges with their execution open.

The polyhedral pyramid is made with the number of faces n2, selected in relation to the number n3 of the maximum possible number of faces within 1.003≤(n2+n3) / n3≤2. In this case, the minimum value of the angle α1 at each of the vertices of the faces in relation to the maximum possible value α2 of the angles at the other vertices of the faces of the pyramid is chosen within 1.01≤(α1+α2) / α2≤1.8. The tilt angle β of the LED, coinciding with the angle of the pyramid faces with respect to its lower base, is chosen in the range from 10° to 70°. The tilt angle β of the LED is the angle between the vertical 6 (Fig. 3) passing through the center of mass 8 of the LED 2 and the line 10 lying on the working surface 7 of the silicon wafer 9 and passing through the vertical 6.

The set of reflective surfaces of the device is composed of the main reflective surface 5 and additional reflective surfaces 14. The main reflective surface 5 is made enclosing the bearing surface 1 with a ratio of its minimum L1 and maximum dimensions L2, interconnected by the ratio 0.56≤(L1+L2)≤1.8 , and also characterized by the dimensions L3 and L4, selected within 1.7≤(L3+L4) / L4≤2. Here L3 is the distance from the plane passing through the horizontal section 12 of the main reflective surface 5 to the plane 13 parallel to it, passing through the center 8 of the mass of the silicon wafer, and L4 is the distance from the plane passing through the horizontal section 12 of the main reflective surface 5 to the plane parallel to it 15 passing through the point 11 of the main reflective surface 5 that is the furthest away from it.

The number of additional reflective surfaces is chosen not to exceed five, with the values of their areas S3, S4, S5, S6 and S7, selected from the ratio 1≤(S3+S4+S5+S6+S7+S) / S≤2, where S - the total sum of the area of all five additional reflective surfaces. It is advisable to note that the bearing surface 1, the main reflective surface 5 and additional reflective surfaces 14 can be either connected to each other or spaced apart in space. The lighting device may be protected by a transparent surface to protect against, for example, dust and other undesirable external influences. At the same time, the angle γ of the indicatrix 16 of the radiation in its cross section of the final generated light flux of its total intensities, both the intensity of the light flux from the radiation sources 2, and from the diffuse scattering of the reflective sections of the bearing surface 1, reflected by the surface 5 of the light flux and from the totality of additional 14 reflective surfaces, selected in the range from 30° to 150°.

Diffuse reflection is a reflection of a beam of light emanating from a source, in which the incident beam is reflected at several angles, and not at one, as is the case with specular reflection. Since the diffuse reflection of materiality depends on the roughness of the reflecting surface 3, it is worth noting that GOST 9378-75 establishes roughness samples. On each sample, the values of the parameter Ra (µm) and the type of processing of the sample (turning, milling, planing, etc.) are indicated. To quantify and normalize the surface roughness, GOST 2789-73 establishes six parameters: three step (S, Sm) and the parameter of the relative reference length of the profile (t p), where. Ra - arithmetic mean profile deviation; Rz - the height of the irregularities in ten points; Rmax - the highest profile height; Sm is the average step of profile irregularities; S is the average step of the local protrusions of the profile; tp is the relative reference length of the profile, p is the level of the profile section. Roughness parameters (one or more) are selected from the given nomenclature: Ra - arithmetic mean deviation of the profile; Rz - the highest profile height; - total profile height; Sm - average step of irregularities; S is the average step of the local protrusions of the profile; is the relative reference length of the profile, where is the value of the level of the profile section. Taking into account the practical importance of these parameters, among the distinguishing features of the claimed device, it is indicated that the angle of the indicatrix with respect to diffuse scattering by the totality of its reflective surfaces of the radiation incident on them is corrected in the range of its selected values using the experimental coefficient ρ, the value of which, depending on the value of its roughness is chosen within 0.6≤ρ≤1.1. As the most suitable for quantitative assessment of the value of the experimental coefficient ρ is the parameter Rmax - the largest height of the profile.

As already noted, the achieved technical result from the use of a lighting device is to increase the uniformity of the intensity of the light flux in space in the range of its observation surfaces, which makes it possible to obtain a non-uniformity of the illumination intensity not exceeding 1-2% in any spatial surface illuminated by the indicatrix γ of the final generated light flux its total intensities, as, in particular, displayed on the observation surface 17 (see Fig. 4). From the foregoing, it is obvious that the described constructive implementation of the claimed device predetermines the purposeful achievement of the specified technical result only when using an interconnected and inseparable set of all essential features indicated in the claims.

The design of the device, as follows from its description, provides the possibility of its serial production and the use of common materials and technologies for their processing, since the product, in particular, is not critical to the accuracy of manufacturing parts. The industrial applicability of the claimed solution is proved by the possibility of its repeated reproduction in the manufacturing process. At the same time, the claimed lighting device is novel, since the interconnected set of its essential features is not known from publicly available information, and due to the originality of its constructive implementation, which for a specialist does not explicitly follow from the prior art, the device meets the condition of inventive step.

Among other advantages of the described lighting device, it is advisable to note the possibility of achieving very high levels of illumination, as well as using it for recreational purposes, since light is necessary for a person for a normal existence and affects almost all aspects of his life, mental state and physiology. When using the claimed invention, it is possible to obtain illumination levels significantly higher than those of known devices, reaching levels above 2000 lux. As a result, it is comfortable to be in the room and the efficiency increases significantly with the humiliation of fatigue. Among other things, these results were achieved with illumination over 5000 lux, which are curative in a number of neuropsychiatric diseases, such as depression.

Claims (4)

1. A lighting device containing a carrier surface with radiation sources installed on it in the form of LEDs and a set of reflective surfaces, excluding direct observation of radiation sources that form the radiation indicatrix created by them, reflections and the final indicatrix of the total luminous flux, characterized in that the carrier surface is made in in the form of a polyhedral pyramid, on the faces of which radiation sources are installed in the amount of n1, selected within 1≤n1≤10 ² , forming the radiation indicatrix together with the reflective sections of the carrier surface, the total area S1 of which is selected in relation to the area S2 of the entire carrier surface within 1 ≤(S1+S2)/S2≤1.7, the polyhedral pyramid is made with the number of faces n2, selected in relation to the number n3 of the maximum possible number of faces within 1.003≤(n2+n3)/n3≤2, while the minimum angle α1 at each of the vertices of the faces in relation to the maximum possible value α2 of the angles at the other some vertices of the pyramid faces are selected within 1.01 ≤ (α1 + α2) / α2 ≤ 1.8, the angle β of the LED inclination is selected in the range from 20 to 60 °, the set of reflective surfaces is composed of the main reflective surface and additional reflective surfaces, the main the reflective surface is made enveloping the bearing surface with a ratio of its minimum L1 and maximum dimensions L2, interconnected by the ratio 0.56≤(L1+L2)≤1.8, and is also characterized by the dimensions L3 and L4, selected within 1.7≤(L3+ L4)/L4≤2, where L3 is the distance from the plane passing through the horizontal section of the main reflective surface to a plane parallel to it passing through the center of mass of the silicon wafer, L4 is the distance from the plane passing through the horizontal section of the main reflective surface to the plane parallel to it passing through the point of the main reflecting surface that is the most remote from it, while the number of additional reflecting surfaces is chosen not to exceed five, with their areas S3, S4, S5, S6 and S7 selected from the ratio 1≤(S3+S4+S5+S6+S7+S)/S≤2, where S is the total sum of the area of all five additional reflectors surfaces, and the angle γ of the radiation indicatrix in its cross section of the final formed luminous flux of its total intensities, both the intensity of the luminous flux from radiation sources, and from the diffuse scattering of the reflecting sections of the carrier surface, reflected by the main reflective surface of the luminous flux and from a combination of additional reflective surfaces, selected in the range from 30 to 150°. 2. The device according to claim 1, characterized in that the angle γ of the indicatrix with respect to diffuse scattering by the totality of its reflective surfaces of the radiation incident on them is corrected in the range of its selected values using the experimental coefficient ρ, the value of which, depending on the value of its roughness, is chosen within 0.6≤ρ≤1.1. 3. The device according to claim 1, characterized in that the multifaceted pyramid is truncated. 4. The device according to claim. 1, characterized in that the pyramid is composed of thin edges with their execution open.

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