RU2031308C1 - Solar illuminant device - Google Patents

Abstract

FIELD: lighting engineering. SUBSTANCE: illuminant solar device has rotary screen which has any section be provided with sun-light collector, member for removing energy and mechanism of zenithal and azimuthal rotation of the screen provided with drive 6. Light-dissipating elements 8 are introduced into the device, mounted on any illuminated part according to number of sections of the screen which is mounted onto support 2. The elements are optically conjugated with corresponding sun-light collector. Any sun-light collector is made of single flat mirror 4 at least. Zenithal rotation mechanism with drive is made in form of reducer 7. Output shaft of the reducer is connected with zenithal axis of the screen. The reducer is provided with step-down gearing. Engine is connected with drive gear of the reducer. Energy removing element is made in form of a primary photoelectric solar energy converter 5 and mounted at the center of symmetry of the screen. The screen sections are disposed symmetrically in relation to its axis of symmetry. EFFECT: improved efficiency; improved comfort. 2 dwg

Description

 The invention relates to lighting equipment and construction, in particular to systems for obtaining a uniform light flux, and can be used in devices that contribute to the creation of a comfortable light environment in rooms and using solar radiation.

 Currently, the problem of creating environmentally friendly, affordable and cheap energy sources has become quite acute. A special place among such energy sources in terms of inexhaustibility and accessibility is solar energy. Devices currently used to control the luminous flux of rooms requiring additional lighting are not effective enough for several reasons. Additional natural lighting of such rooms requires the presence of additional devices such as curtains, protective screens that protect the room from direct sunlight, and lighting cannot be carried out on rooms located on the north side of the building where the sun never appears. Such devices lead to a violation of the aesthetics of the interior and decoration of both the room and the building as a whole.

It is known a lighting device comprising light sources arranged at an equal distance from one another and mounted in series in relation to each other at an angle of ⁹⁰ °, and the flat mirror arranged in front of the rows at an angle of ^{45 °} to the optical axes of the light sources, and mounted so that the projection of the length of each mirror on one of the rows of light sources is equal to half the distance between these light sources (see USSR author's certificate N 626309, class F 21 V 9/02, 1978).

 However, the known device uses several artificial light sources, which complicates its design and increases cost, and does not provide a uniform distribution of illumination throughout the room and reduce the brightness of the transmitted radiation to the required level when lighting the room. Therefore, either the regulation of the power of the light sources or the presence of protective, such as curtain, regulators is required. Effective use of radiation is not ensured (conversion of the unused part of it into other types of energy for technical needs and ensuring the functioning of the device itself.

 The closest in technical essence is a solar device that includes a rotary screen mounted on the lower horizontal side of the frame of the opening and made of two articulated sections and sequentially installed from the opening of the sections, each of which is equipped with a solar receiver with energy-removing elements, with a protective coating placed on the far from the opening of the screen section and made in the form of a shell having the shape of a truncated segment of a circular torus of material with a highly reflective and the high transmittance in the infrared region of the spectrum, and a screen rotation mechanism with a drive made in the form of telescopic consoles mounted on a frame below the screen mount, and the free end of each console is connected to the screen section farthest from the opening, while the energy-removing elements are passed through telescopic consoles (see USSR Author's Certificate N 1560723, class E 06 B 9/24, 1990).

 However, the known device does not provide uniform distribution throughout the room of light radiation and reduce its brightness to the required level when lighting the room. Therefore, additional protective shields are required against the blinding effect of direct sunlight, which are located on the opening of the next highest room from the illuminated area. This complicates the design of the device. In addition, the aesthetics of the interior are violated.

 The purpose of the invention is the expansion of the functionality of using a natural light source and the elimination of the blinding effects of direct sunlight reflected from mirrors by scattering them.

 This is achieved by the fact that in the solar lighting device including a rotary screen, each section of which is equipped with a solar receiver, an energy-removing element and a mechanism for zenithal and azimuthal rotation of the screen with a drive, light-scattering elements are introduced, installed on each illuminated area according to the number of screen sections mounted on the support , and are optically coupled to a corresponding solar receiver, each solar receiver is made of at least one flat mirror, the mechanism of zenithal rotation of the screen with water is made in the form of a gearbox, the output shaft of which is connected to the zenith axis of the screen, the gearbox is equipped with a reduction gear, the engine is connected to the gear of the gearbox, and the energy-removing element is made in the form of a primary photovoltaic solar energy converter and is installed in the center of symmetry of the screen, with sections screen are located symmetrically about the axis of its symmetry.

 In FIG. 1 is a schematic diagram of a solar lighting device in working position during the day; figure 2 is the same in the extreme eastern position when it is turned on.

 The device consists of a rotary screen 1 mounted on a support 2, each section 3 of which is equipped with flat mirrors 4, a primary photovoltaic solar energy converter 5, mounted in the center of symmetry of the screen, a screen rotation mechanism with a drive 6, the anti-aircraft rotation of which is made in the form of a gear 7, the output the shaft of which is connected to the zenith axis of the shield 1. The gearbox is equipped with a reduction gear, the engine is connected to the drive gear of the gearbox 7, light-scattering elements 8 are installed on each axis eschaemom portion 9 by the number of sections 3 of the screen 1 disposed symmetrically with respect to its axis of symmetry and optically coupled with a corresponding plane mirror 4.

 As a flat mirror 4, a reflecting element is used, made, for example, of an aluminum alloy AMG-6 and processed optically by standard technology, for example, by diamond turning with a reflection coefficient in the visible spectrum of 84-88%.

 As the primary photovoltaic solar energy converter 5, for example, a silicon-based pn junction photoconverter made using standard technology is used.

 As the mechanism of azimuthal and zenithal rotation of the screen with the drive 6, solar tracking mechanisms widely known in solar engineering are used, the gearbox 7 of the drive 6 with a reduction gear are, for example, a reversible motor with a gearbox RD-09-478.

 As a light-scattering element, for example, a housing containing a package of glass fibers that provide a symmetrical radiation pattern of scattering of the light flux or scatterers with the surface of a hyperbolic paraboloid, providing uniform scattering throughout the illuminated area, can be used.

 Solar lighting device operates as follows.

 Light-scattering elements 8 are installed in the upper part of each illuminated room (section 9), for example in the center of the ceiling, in accordance with the number of sections 3 of the screen 1.

 The screen 1 is mounted on the support 2 in a place providing unhindered illumination of the flat mirrors 4 by solar radiation during the whole daylight hours, for example, on the roof of the house adjacent to the north side of the illuminated room (section 9) or in an open area.

 When the level of natural illumination in the room (section 9) decreases below a certain level determined by the light sensor installed in the illuminated room (section 9), or visually, the sections 3 of the screen 1 are oriented in the sun so that the previously optically conjugated flat mirrors 4 of each section 3 with the corresponding light-scattering element 8 of the corresponding illuminated room (section 9) emitted additional elements of solar radiation reflected from them 8, increasing the illumination of the room (section 9) to the required level.

 To do this, a tracking sensor (not shown) through an electronic circuit sends an electrical signal to the screen rotation mechanism with drive 6, which moves the screen 1 in the azimuthal and zenithal planes towards the sun so that the solar radiation reflected from the flat mirrors 4 of each section 3 to the corresponding scattering element 8 of the corresponding illuminated room (section 9). As soon as the tracking sensor occupies an optimal position with respect to the sun, in which flat mirrors of 4 sections 3 reflect solar radiation to the corresponding light-scattering elements 8 of the corresponding illuminated rooms (sections 9), the signal from the tracking sensor ceases to be transmitted to the screen rotation mechanism with drive 6 and the screen stops moving.

 With the next decrease in the illumination level of the illuminated room (section 9) as a result of a change in the position of the sun (the solar radiation reflected from the flat mirrors 4 disappears from the light-scattering elements 8), the tracking sensor again sends an electrical signal through the electronic circuit to the screen rotation mechanism with drive 6, which moves the screen 1 in the azimuthal and zenithal planes towards the sun so that the solar radiation reflected from the flat mirrors 4 of each section 3 again falls on the corresponding scattering element Ent 8 of the corresponding illuminated premises (plot 9). This movement of the screen 1 behind the sun is carried out for the entire time necessary to supply additional solar radiation to the natural light of the room (section 9), until it is insufficient or until the sun disappears.

Optical conjugation of the sun through flat mirrors of 4 sections 3 with the corresponding light-scattering elements 8 of the corresponding illuminated rooms (sections 9) is possible only if the screen moves with a speed lag compared with the movement of the sun, i.e. if the equinox the sun from east to west will move to ^180, the following error screen for the sun to provide optical coupling with light-scattering elements 8 move only ^90. Screen position when the sun strictly in the east is shown in Figure 2, the angle of refraction plane mirrors 4 reflected from the sun on the corresponding light diffusing member 8 of solar radiation is ⁹⁰ °, the screen itself is at an angle ^of 45 to the solar radiation. When the position of the sun strictly in the west, the screen will occupy the position opposite to that shown in figure 2.

 The presence in the mechanism of anti-aircraft rotation of the screen with the drive gear 7, the output shaft of which is connected to the zenith axis of the screen 1, equipped with a reduction gear, achieve screen movement with delay relative to the speed of movement of the sun. The mechanism of the zenithal rotation of the screen is carried out when the engine is connected, connected with the drive gear of the gear 7. In this case, the output shaft, made, for example, in the form of a screw having two independent movements: rotation around its axis and moving along it, makes it move associated with it, for example, through the lever, the zenith axis, freely rotating, for example, in radial bearings mounted in the screen housing 1, by a solid angle α, half that of the sun during this time by a solid angle 2 α. As a result of this, the screen 1 also moves by a solid angle α.

 The azimuthal tracking system can be made in the form of a gearbox, motor and gear located on the output shaft of the gearbox. During the whole time the solar lighting device is in operation, the primary photoelectric converter located in the center of the screen 1 converts the light radiation into electrical energy used to power the device itself (providing power to the electronic circuit of the sun tracking sensor and the screen rotation mechanism with drive 6) and for technical the needs of the illuminated room (section 9), for which, for example, batteries accumulate excess electricity during the day, and use it in the evening Artificial lighting. When sunlight reflected from flat mirrors gets on the corresponding light-scattering elements 8 installed in the illuminated room (section 9), they provide uniform, safe for the eye, diffusion of sunlight evenly throughout the room, including in the far sections of the room both above and down below.

The area of the mirrors used to illuminate the room (plot 9) depends on the dimensions of the illuminated room and the distance to it. With the size of the illuminated room 5x10x10 m and the distance of the solar lighting device to the room from 50 to 230 m, the area of flat mirrors should be from 0.1 to 0.8 m ² , depending on the level of natural illumination of the room (winter and summer periods, cloud cover).

 In the proposed device, the expansion of the functionality of using a natural light source and the elimination of the blinding effect of direct sunlight reflected from the mirrors due to their scattering is achieved by converting the light-protective device (according to the prototype) into a lighting one (there is no need to use the protective screens located above).

 At the same time, the scattering of reflected sunlight that occurs on the light-scattering elements allows one to avoid blinding by the sun's rays and to illuminate mainly not only the upper part of the room, but evenly the entire volume of the room.

 The use of a reduction gear with a reduction gear in the mechanism of zenithal rotation makes it possible to increase the accuracy of tracking the screen behind the sun and the lighting efficiency of the room as well as reduce the energy consumption for optimal tracking of the screen behind the sun.

 The use of a primary photoelectric converter to convert solar energy into electrical energy instead of a secondary converter using energy-removing elements makes it possible to increase the efficiency of conversion of solar energy and, consequently, the overall performance of the lighting device as a whole.

Claims (2)

 1. SUNNY LIGHTING DEVICE, including a rotary screen, consisting of sections, each section of the screen is equipped with a solar receiver, an energy-removing element and a mechanism for zenith rotation of the screen with a drive, characterized in that the rotary screen is mounted on a support, each solar receiver is made of at least one flat mirror, the mechanism of the anti-aircraft rotation of the screen with the drive is made in the form of a gearbox, the gearbox is equipped with a reduction gear, the output shaft of the gearbox is connected to the zenith axis of the screen, the drive gear of the gearbox is connected to the introduced engine, light-scattering elements are introduced that are installed in each section illuminated by the device, the number of light-scattering elements corresponds to the number of screen sections, while the light-scattering elements are optically coupled to the corresponding solar collector, the energy-removing element is made in the form of a primary photovoltaic solar energy converter and installed in the center of symmetry of the screen.  2. The device according to claim 1, characterized in that the screen sections are located symmetrically relative to the axis of symmetry of the screen.

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