RU2039183C1 - Solar illumination device with protection against direct sun rays - Google Patents

Abstract

FIELD: construction. SUBSTANCE: solar illumination device has rotary screen with solar collector and energy baffling member, screen rotating mechanism with drive connected with follower detector. Illumination device is further provided with variable transmission radius member disposed in front of solar collector, mechanism for moving variable transmission radius member along optical axis of solar collector and illumination level sensor positioned in illuminated area. First output of illumination level sensor is connected with follower detector and second output is connected with mechanism for moving variable transmission radius member. Screen is mounted on support. Solar collector is made curved. Variable transmission radius member may be formed as rotating multiple arm sprocket, whose leading and tail parts are aligned on two spirals, with one spiral embracing central zone of solar collector and second spiral being circumscribed within its peripheral zone. Mechanism for moving variable transmission radius member along optical axis of solar collector is kinematically connected with sprocket axle. EFFECT: efficient protection against dazzling effect of direct sun rays by regulating radial reflectivity of solar collector. 2 cl, 5 dwg

Description

 The invention relates to construction and optical instrumentation, in particular to systems for regulating light flux, and can be used in devices that contribute to creating a comfortable light environment in rooms and protecting them from direct sunlight 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. So, additional natural lighting in such rooms requires the presence of additional devices such as curtains, protective screens, etc. protecting the premises from direct sunlight, and cannot illuminate rooms located, for example, 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.

Known sunscreen device comprising a rotary screen mounted on the outer side of the frame of the opening, the mechanism of rotation of the screen with the drive and a protective coating [1]
However, the known device does not protect the illuminated room from direct sunlight, since reflection from the rotary screen of solar radiation produces a dazzling effect in the illuminated room, and therefore requires the creation of additional sun protection devices, such as curtain regulators. Additional lighting is not provided far from the light source of the area of the room and the effective use of solar radiation, and the aesthetic interior and decoration of both the room and the building as a whole are violated. The known sun protection device only functions if there is an optical coating on the screen.

The closest in technical essence (prototype) is a solar lighting device with protection from direct sunlight, including a rotary screen mounted on the lower horizontal side of the frame of the opening and made of two sections articulated and sequentially installed from the opening, each of which is equipped with solar receivers with outlet energy by elements with a protective coating located on the section of the screen farthest from the opening and made in the form of a shell having the shape of a truncated round segment a torus of material with a highly reflective ability in the visible region of the spectrum and a high transmittance in the infrared region of the solar 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 farthest from the opening section of the screen, while the energy-removing elements are passed through telescopic consoles [2]
However, the known device does not regulate the additional solar radiation supplied to the room from the screen, which can significantly exceed normal working light (300 lux), especially in the summer, and can lead to a dazzling action, which requires the presence of protective devices (having a higher screen a similar device and a curtain regulator in a light beam); violates the aesthetics of the interior and decoration of both the room and the building as a whole. The known device operates only in the presence of an optical protective coating of a special form.

 The achieved technical result of the invention is the elimination of the blinding effect of direct sunlight reflected from the solar receiver by adjusting the reflectivity along the radius of the solar receiver.

 The technical result is achieved by the fact that the known solar lighting device with protection from direct sunlight, comprising a rotary screen with a solar receiver and an energy-removing element, a screen rotation mechanism with a drive connected to a tracking sensor, in contrast to the prototype, is equipped with a variable transmission radius element, placed in front of the solar receiver, a mechanism for moving the variable element along the transmission radius along the optical axis of the solar receiver and a light level sensor installed and the illuminated portion, the first illumination level of the sensor output is connected to the tracking sensor, and the second output element with the mechanism for moving radially variable transmission, wherein the screen is mounted on a support and formed with a curved shape of the solar collector.

 The variable-radius element of transmission can be made in the form of a rotating multi-ray sprocket, the beginnings and ends of which are aligned on two spirals, the first of which covers the central zone of the solar receiver, and the second is inscribed in its peripheral zone, while the mechanism of moving the variable element along the transmission radius along the optical axis of the solar receiver is kinematically connected with the axis of the sprocket.

 Figure 1 presents a schematic diagram of a solar lighting device with protection from direct sunlight; figure 2 is the same front view; figure 3 the same, left view; figure 4 is a schematic diagram of a device under operating conditions; figure 5 curves of the transmission coefficient T from the angle of coverage of the solar receiver α at different positions of the rotating sprocket (A position of the sprocket near the reflective surface; B average position of the sprocket; In the approximation of the sprocket to the focus).

 A solar lighting device with protection against direct sunlight consists of a rotary screen 1 with a solar receiver 2 of a curved shape and an energy-removing element 3, the screen is mounted on a support 4; the rotation mechanism 5 of the screen 1 with a drive connected to the tracking sensor 6; an element of variable in transmission radius, made in the form of a rotating multi-beam sprocket 7, the beginning and ends of the beams of which are aligned on two spirals 8 and 9, the first of which covers the central zone of the solar receiver 2, and the second is inscribed in its peripheral zone; a movement mechanism 11 of an element of variable along the transmission radius along the optical axis of the solar receiver 2, kinematically connected with the axis of the sprocket 7; the light level sensor 10 installed on the illuminated area 12, the first output of the light level sensor 10 is connected to a tracking sensor 6, and the second output with a movement mechanism 11 of the variable element along the transmission radius.

 As a solar collector 2 of the rotary screen 1, for example, an element with a uniformly reflecting surface is used, the reflection coefficient of which in the visible spectrum is 82-84% made of aluminum alloy AMG-6 and processed to the required radius of curvature, for example, R 5 m, using the diamond method turning according to standard technology with subsequent shaping by a punch into a matrix with optically processed work surfaces.

 As a light level sensor 10, for example, a light meter is used, which is a microammeter connected, for example, to a selenium photocell, or photo resistance (Kuhling K. Physics Handbook, edited by E. M. Leikin, Mir, 1985, p. 309 )

 As the rotation mechanism 5 of the screen 1 with the drive towards the sun in the azimuthal and zenithal planes, the solar tracking mechanisms widely known in solar engineering are used, for example, the device described in a. from. USSR N 1196621, class F 24 J 2/38, 1984.

 As the tracking sensor 6, for example, a photosensitive sensor is used, consisting of an opaque base, in which photosensitive elements are placed, for example, FGT-3-02-0582 infrared phototransistors. An electronic circuit that transmits an electrical signal from photosensitive elements (phototransistors) when the sun moves to the actuator 5 of the screen 1 with a drive is described in Bayer T. Book of 20 designs with solar cells. M. Mir, 1987: c. 162-172.

 Through the hole in the center of the solar receiver 2 passes the axis of rotation of the multi-beam sprocket 7 (Fig. 1). The latter delays the part of the light flux incident on the solar receiver 2, and the closer to the center, the less energy passes through the sprocket 7 from the reflective surface of the solar receiver 2. The central part of the sprocket 7 does not transmit light at all. Therefore, the reflection coefficient in such a device varies from a maximum at the periphery to a minimum at the center. The maximum reflection coefficient is determined by the quality of the optical processing of the reflecting surface (or the quality of the applied reflective coating) of the solar receiver 2, and the minimum component of specular reflection from the scattering coating, which can be applied to the surface of the sprocket 7. By changing the configuration of the variable element with respect to the transmission radius, the law of change can be adjusted reflection coefficient. Rotation of an element of variable in transmission radius (multi-beam sprocket 7) with the necessary speed gives a stable picture of transmission through an element of variable in transmission radius from solar collector 2.

 The beginning and ends of the multi-beam sprocket 7 are aligned with points lying on two spirals 8 and 9 (Fig. 2), the first of which covers the central zone, and the second lies in the peripheral zone. This design allows you to more smoothly change the transmittance from the reflecting surface of the solar receiver 2 from the center to the periphery. In FIG. 1 shows the design of sprocket 7 in the form of a flat figure. The sprocket 7 can also be made in such a way that in the plane passing through the axis of rotation, the sections of the rays expand to the periphery, forming the shape of the blades, providing rotation of the air capture for cooling the solar lighting device with protection from direct sunlight.

 The movement mechanism 11 of the variable element along the transmission radius is as follows. The sprocket 7 is mounted on an axis 12 located in the center of symmetry of the solar receiver 2. The axis 12 has a round tide 14 and a channel 15, which includes the leading shank of the electric motor 16. The tide 14 is operatively connected to the drive movement of the sprocket 7, consisting of a plug 17 and a control screw eighteen.

 When moving a multi-beam sprocket 7 under the action of the movement mechanism 1 towards the reflective surface of the solar receiver 2 by rotating the adjusting screw 18, the transmittance to its central zone increases (Fig. 5, A). The average position of the sprocket 7 (figure 5, B) corresponds to the most uniform illumination.

 As the asterisk 7 approaches the focus (Fig. 5, B), the diameter of the central zone with a low transmittance expands and the transmittance through the asterisk 7 sharply increases from the periphery of the solar receiver 2. With an increase in the power of solar radiation, this makes it possible to better equalize the illumination of the illuminated section 13.

 The rotation of the multi-beam sprocket 7 during the entire time of illumination of the illuminated section 12 is achieved using an electric motor.

 Solar lighting device with protection from direct sunlight is as follows.

 A light level sensor 10 is installed, for example, in the area 13 (premises) farthest from the light opening, which additional lighting is produced. The sensor 10 sets the required level of illumination, for example, for a school building of 300 lux (Kuhling K. Handbook of Physics under the editorship of EM Leikin M.M. Mir, 1985, p. 307).

 Install the screen 1 on the support 4 in a place providing unhindered illumination of the solar receiver 2 with sunlight throughout the daylight hours, for example, on the roof of a house adjacent to the illuminated section 13 or in an open area.

 When the illumination level decreases below the level set on the sensor 10, it sends an electric signal from the first output to the tracking sensor 6, which sends an electric signal through the electronic circuit to the rotation mechanism 5, which moves the screen 1 in the azimuthal and zenithal planes towards the sun. As soon as the tracking sensor 6 occupies a position in which the solar receiver 2 of the screen 1 reflects solar radiation on the light-opening of the illuminated portion 13 (the room), the signal from the tracking sensor 6 ceases to be transmitted to the rotation mechanism 5 with the drive of the screen 1, which stops moving.

 From the second output, the light level sensor 10 sends an electric signal to the movement mechanism 11 of the multi-beam sprocket 7 (to the control screw) while turning on the electric motor 16. In this case, the multi-beam star 7 occupies such a position in front of the solar receiver 2 so that the luminous flux of focused solar radiation from the solar receiver 2 incident on the light penetration of the illuminated section 13 (premises) when the latter was added to the natural illumination, it increased the level of illumination in it to a predetermined (300 lux) dates 10. After that, the electrical signals from the light level sensor 10 cease to flow to the tracking sensor 6 and the movement mechanism 11 of the multi-beam sprocket 7. When the light level in the area 13 (room) decreases again as a result of a change in the position of the sun with a decrease in the natural level of light, the electrical signals the light level sensor 10 again comes to the tracking sensor 6 and to the movement mechanism 11 of the multi-beam sprocket 7, causing again, as described above, the position of the solar receiver 2 to change direction to the sun, providing illumination by reflected solar radiation of the light beam, and the position of the sprocket 7, in which the level of illumination in section 13 (room) reaches 300 lux, set by the sensor 10 of the level of normal illumination, etc.

 When using a solar lighting device that is protected from direct sunlight mainly in the summer, the illumination created by solar radiation is 100,000 lux, and with a cloudy sky 5000-20000 lux, which is often insufficient to provide standard working illumination of section 13 (premises) (300 lx), located on the north side of the building, where direct sunlight does not fall. However, in the summer period the level of natural illumination is rather high, and when using a solar lighting device protected from direct sunlight to maintain a given level of illumination of darkened areas 13 (rooms), the position of the multi-beam sprocket 7 near the focus of the solar receiver 2 is determined using the movement mechanism 11 according to the signal sensor 10. In this case, the spectral characteristic of transmission of solar radiation through an asterisk 7 corresponds to the spectrum presented in figure 5, B. In this case, pr the radiation transmitted through the asterisk 7 is minimal and represents solar radiation reflected from the peripheral sections of the solar receiver 2, providing additional illumination to section 13 to a normal value (300 lux) set by the light level sensor 10.

 In the operating mode of a solar lighting device with direct sunlight protection, mainly in winter, the illumination created by sunlight is 10,000 lux, and with a cloudy sky 1000-2000 lux. Such a low level of natural light in winter when using a solar lighting device with protection from direct sunlight requires maintaining the location of the sprocket 7 using the adjusting screw 16 of the movement mechanism 11 when a signal is supplied from the light level sensor 10 near the reflecting surface of the solar receiver 2 (Fig. 5, AND). This arrangement of the sprocket 7 provides a significant transmission of the spectrum of the solar radiation reflected from the solar receiver 2, presented on the spectral characteristic (Fig. 5, A) and, as a result, only a small part of the solar radiation reflected from the solar receiver 2 does not pass the asterisk 7, thereby providing additional to natural light, the lighting set by the sensor 10 levels of illumination (300 lux) mainly in the winter.

 The average position of the sprocket 7 (Fig. 5, B) is used with an average level of natural light, which occurs mainly in the autumn-spring periods.

 The distance from the illuminated section 13 (room) to a solar lighting device with protection from direct sunlight is not more than 230 m and is due to both spatial factors (building height, the possibility of the presence of other objects that impede lighting), and diffusion of reflected solar radiation, for example, under the influence of interference, etc. sharply increasing at large distances and making it difficult to transmit a controlled flow of solar radiation over long distances.

 The volume and dimensions of section 13 (premises) correspond to the dimensions of the secondary school premises 10 m (length) x 5 m (width) x 5 m (height) and the required level of illumination in it (300 lux) (the amount of light transmission).

The area S _{g of the} reflecting surface of the solar receiver 2 is tentatively calculated according to the formula
E _norms. ˙ S _n About ₃ ˙ S _g ˙ R + E _eats. where E is the _norm. 300 lux preset illumination on the light sensor 6;
S _p 25 m ^{2 the} area farthest from the light transmission wall of the room 13;
About ₃ 10,000 lux and E _eats. 1000 lux illumination from the sun and the level of natural illumination of the light beam from the north side of the building in the winter, respectively;
R reflector of the solar receiver 2.

In the initial period of operation, R can reach the values obtained during optical processing for the material used (copper up to 85% aluminum up to 90%), however, such values are inappropriate to use because of their rapid decrease under the influence of adverse climatic factors. A reflection coefficient close to 84% is more economically feasible. For parameter values, the maximum area of the reflecting surface S _{r of the} solar collector is ≈ 0.77 m ² .

The optimal radius of curvature of the solar receiver 2 is approximately 4-35 m and corresponds to the creation of the necessary focal spot in the illuminated light opening of room 13 at a working distance from the solar lighting device with protection from direct sunlight to the illuminated area 12 230 m and the light opening area of 2x2 m ² .

Based on the foregoing achievable new technical result of the invention is:
protection from the blinding effects of direct sunlight reflected from the solar receiver of the illuminated area by adjusting the reflectivity of the solar receiver along the radius;
support for a given level of illumination in the illuminated area (room);
ensuring high smoothness and regulating the reflectivity of the solar receiver by moving relative to the solar receiver of a multi-beam sprocket of a special design.

Claims (2)

 1. SUNNY LIGHTING DEVICE PROTECTED FROM DIRECT SOLAR RAYS, including a rotary screen with a solar receiver and an energy-removing element, a screen rotation mechanism with a drive connected to a tracking sensor, characterized in that it is equipped with a variable-radius-transmitting element placed in front of the solar receiver movement of the variable element along the transmission radius along the optical axis of the solar collector and the light level sensor, which is installed on the illuminated area and the first output of which connected to a tracking sensor, and the second output with a mechanism for moving the variable element along the transmission radius, while the screen is mounted on a support and is made with a curved shape of the solar receiver.  2. The device according to claim 1, characterized in that the element of variable transmission radius is made in the form of a rotating multi-ray sprocket, the beginning and ends of the rays of which are aligned on two spirals, the first of which covers the central zone of the solar receiver, and the second is inscribed in its peripheral zone, the mechanism of moving the variable element along the transmission radius along the optical axis of the solar receiver is kinematically connected with the axis of the sprocket.

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