RU47497U1 - SOLAR PHOTOELECTRIC INSTALLATION - Google Patents

Abstract

The solar photovoltaic installation contains a solar battery with Fresnel lenses and photoelectric converters receiving radiation, located on a mechanical system that maintains the perpendicular position of the solar battery to the direction to the Sun and is equipped with a solar battery orientation system to the Sun. What is new is that the supporting mechanical system is formed by two frames - the base frame (1) and the suspended frame (2). The base frame (1) is mounted to rotate around a vertical axis (6), resting on the underlying surface with the help of wheels (3, 4 and 5). The wheel (3) is equipped with a drive, and the suspended frame (2) is mounted to rotate around a horizontal axis (8) from the electric drive. The solar battery consists of modules (10) with solar concentrators located on a suspended frame (2) in the form of steps. The battery orientation system contains a primary sensor (13) and an additional sensor (18) for the position of the Sun. The main sensor consists of a shading screen (14) with a hole (15) and eight cascade-type photocells, four photocells (16) of which are placed on the right, left, top and bottom on the outer sides of the screen and form azimuthal and zenith coarse guidance channels generating electrical signals when the position of the sun changes. Four other photocells (17) are located in the same way on the inner sides of the screen and form accurate guidance channels. The mentioned additional sensor (18) consists of three cascade type photocells connected to the azimuth channel, two of which (19) are directed left and right along

in relation to the main sensor (13), and the third (20) - in the opposite direction and the polarity of its connection changes when passing the South-North direction. In this case, the signal to turn on the electric drive of the drive wheel (3) of the base frame (1) is supplied from the photocells of the azimuth channel, and the signal to turn on the electric drive of the suspended frame (2) is supplied from the photocells of the anti-aircraft channel.

1 n.p. f., 6 ill.

Description

The utility model relates to solar energy and can be used in solar power plants to convert solar energy into electrical energy, and in addition, it can be used as an individual power plant.

Known solar photovoltaic installation according to the patent of the Russian Federation No. 2222755 from 05.17.2002. A solar photovoltaic installation contains a supporting structure with a parabolic concentrator mounted on it, made of flat mirror faces, connected to the output of the sun tracking unit, as well as an extended photoelectric converter located along the focal line of the parabolic concentrator. An elliptical reflector is mounted coaxially with it on the supporting structure behind the parabolic concentrator, one focus of which is combined with the focus of the parabolic concentrator, in the second focus of which there is a photoelectric sensor, the output of which is connected to the input of the solar tracking unit. A flat reflecting element facing an elliptical reflector is mounted on the rear side of each of the mirror facets on its longitudinal axis perpendicular to its surface.

This installation has a relatively simple design. However, it has a uniaxial tracking system for the sun. It uses large area photoelectric converters, which makes installation more expensive due to the high consumption of expensive converter semiconductor materials. A combined guidance system in the sun is used. Rough guidance

from an external processor using astronomical time and latitude. Any change in installation location requires reprogramming of the processor.

More advanced is the IHCPV solar photovoltaic installation, which is the closest analogue of the claimed utility model (see "Cost Estimation of Integrated High-Concentrated Photovoltaics for Large-Scale Applications Related to Centralized Power Supply Networks." Materials of the 25th Conference of Photovoltaic Specialists of the American Institute of Electrical and Electronics Engineers. Washington ; May 13-17, 1996, p. 1373-1376).

This solar photovoltaic installation contains a solar battery with Fresnel lenses and radiation-receiving photoelectric converters, placed on a mechanical support system and equipped with a battery orientation system to the Sun. The solar battery consists of 168 Fresnel lenses and their corresponding photoelectric converters. Fresnel lenses and photoelectric converters are placed in a rectangular perforated metal frame with an area of 159 m ² , which has the possibility of biaxial mechanical movement, which is installed on a strictly vertical support column, rigidly fixed in the ground. The supporting frame of the solar battery is equipped with a solar orientation system. The biaxial tracking system uses an engine for azimuthal rotation and a mechanism with a screw jack for vertical rotation. The engine can rotate the system ± 180 ° relative to the south and 90 ° vertically. Tracking is monitored using an open loop automatic control system. The microprocessor calculates the direction to the Sun using

astronomical time and latitude, and accordingly orient the tracking system. The tracking system maintains its correct position using Hall sensors mounted on the axis of the azimuthal and vertical drives. Considering the number of revolutions of the motor relative to the known zero position and the data of the drive parameters, the control system can orient the tracking system to the Sun with an accuracy of 0.05 °.

This solar photovoltaic installation is superior in its performance to the installation discussed above with a single-axis solar tracking system. However, the IHCPV solar photovoltaic installation has a complex structure and large dimensions of solar battery modules placed in one plane, as a result of which it is subjected to relatively large wind loads. Installation technology of the installation requires large labor costs due to the need to provide rigid and strictly vertical fixation in the soil of the supporting column of the mechanical supporting system of the solar battery. In addition, its open loop tracking system on a microprocessor performs continuous movement of the solar battery regardless of whether the Sun is in direct line of sight or is beyond the clouds.

The present utility model was based on the task of developing a solar photovoltaic installation in which the supporting mechanical system of the solar battery itself, as well as the guidance system, would be made in such a way as to simplify the design of the mechanical system and the technology of its installation, and to monitor the position The sun was provided only in the presence of direct solar radiation.

The problem is solved in that in a solar photovoltaic installation containing a solar battery with lenses

Fresnel and photoelectric converters receiving radiation placed on a mechanical system supporting the perpendicular position of the solar battery toward the Sun and equipped with a solar battery orientation system on the Sun, it is new that the supporting mechanical system is formed by two frames - base and suspended, of which the base frame installed with the possibility of rotation around a vertical axis, relying on the underlying surface using wheels, one of which is equipped with electric water, and the suspended frame is mounted to rotate around a horizontal axis from the electric drive, while the solar battery itself consists of modules with solar concentrators located on the suspended frame in the form of steps, and the battery orientation system contains the primary and secondary solar position sensors, the main of which consists of a shading screen with a hole and eight cascade type photocells, four of which are located on the right, left, top and bottom on the outside of the screen and form the channels coarse and zenith coarse guidance, generating electrical signals when the position of the Sun changes, and four other photocells are located in the same way on the inner sides of the screen and form accurate guidance channels, the mentioned additional sensor consists of three cascade type photocells connected to the azimuth channel, two of which directed left and right in relation to the main sensor, and the third - in the opposite direction and the polarity of its connection changes when passing the direction of South -North, while the signal to turn on the electric drive of the driving wheel of the base frame is supplied from the photocells of the azimuth channel, and the signal to turn on the electric drive of the suspended frame is supplied from the photocells of the zenithal

channel.

Thanks to this embodiment of the supporting mechanical system, any flat surface with a hardness sufficient to move the wheels of the base frame along it is suitable for the installation, the installation technology and its operation are simplified. The implementation of the solar battery from the modules, stepwise located on a suspended frame, reduces the wind and possible snow load, and also increases the rigidity of the supporting frame. Due to the presence of the primary and secondary sensors of the position of the Sun in the guidance system, there is no need to control the current position of the installation, and there is no need to bind to astronomical time and latitude, which is necessary in the closest analogue of the invention. The multi-junction photocells used as sensors, which have the greatest sensitivity to direct solar radiation, prevent the operation of false radiation sources and increase the accuracy of tracking the visible position of the solar disk. The increased output voltage of these elements allows the use of a simple control circuit for tracking engines.

Below the essence of this utility model is explained in more detail with specific examples of its implementation with reference to the accompanying drawings, in which:

figure 1 schematically shows the inventive solar photovoltaic installation, side view;

figure 2 schematically shows the inventive solar photovoltaic installation, top view;

figure 3 schematically shows the design of the main sensor of the position of the sun, side view;

figure 4 schematically shows the design of the main

Sun position sensor, front view;

figure 5 schematically shows the design of an additional position sensor of the Sun, side view;

Fig.6 schematically shows the design of an additional sensor of the position of the Sun, rear view.

The inventive solar photovoltaic installation includes a solar battery with Fresnel lenses and radiation-receiving photoelectric converters, mounted on a mechanical support system supporting the perpendicular position of the solar battery to the direction to the Sun and equipped with a solar battery orientation system to the Sun. The supporting mechanical system is formed by two frames — the base frame 1 (FIG. 1) and the suspended frame 2. The base frame 1 (FIG. 2) has a plan view of an isosceles triangle, on the tops of which wheels 3, 4 and 5 are installed, with which the base frame 1 relies on the underlying surface. The base frame 1 is mounted rotatably around a fixed vertical axis 6 of azimuthal rotation, mounted in the underlying surface. Wheel 3 (figure 1) is made leading. The drive 7 is installed on the frame 1. The suspended frame 2 (Fig. 2) has a rectangular lattice structure in plan and is mounted on the horizontal axis of zenithal rotation, mounted on the brackets 9 (Fig. 1) of the base frame 1. The suspended frame 2 is made of galvanized steel in the form of bent perforated profiles. The drive 7 contains two DC motors with gears, a buffer power battery and a control circuit. One of the electric motors is connected to the driving wheel 3 of the base frame, and the other is designed for anti-aircraft movement of the suspended frame.

The solar battery consists of modules 10 containing lenses

Fresnel, solar concentrators and photovoltaic converters, which are the subject of a separate previously claimed invention. The solar modules 10 are located on the suspended frame in 2 rows in the form of steps. This embodiment of the solar battery reduces wind and possible snow load, and also increases the stiffness of the suspended frame 2. The suspended frame 2 is equipped with two gear sectors 11 associated with the drive 7 (figure 2).

The electric drives of the base frame 1 and the suspended frame 2 are powered by a separate solar battery 12 located on the suspended frame 2 and supplying the electric drive 7 by recharging the battery.

The orientation system of the solar battery on the Sun contains the main sensor 13 of the position of the Sun, located on the second stage of the solar battery (figure 1). The main position sensor 13 consists of a shading screen 14 (Fig. 3) with an opening 15 and eight cascade-type photocells, four of which 16 are located on the top, bottom, right and left on the outside of the screen and form azimuthal and zenithal coarse guidance channels generating signals when the position of the sun changes. Four other photocells 17 are located on the top, bottom, right and left on the inner sides of the screen and form accurate guidance channels. An additional sensor 18 of the position of the Sun consists of three solar cells of the cascade type (Fig.6) connected to the azimuth channel. This sensor is installed in the upper part of the suspended frame 2. It contains two photovoltaic cells of the cascade type 19, directed to the right and left with respect to the main sensor 13 (figure 2). The third photoelectric element 20 is directed in the opposite direction from the main sensor 13

the side and polarity of its connection is changed by a special switch when passing the South-North direction.

The installation is mounted on any flat underlying surface with a hardness sufficient to move the wheels 3, 4 and 5 of the base frame 1 on it (Fig. 1). A fixed axis 6 of azimuthal rotation of the base frame 1 is fixed in the underlying surface. The implementation of the solar battery from modules 10, which are stepwise located on the suspended frame 2, reduces the wind and possible snow load on the supporting structure, which increases the reliability and durability of the installation. The presence of the main sensor 13 and an additional sensor 18 of the position of the Sun in the guidance system that controls the electric drives of the base frame 1 and the suspended frame 2 eliminates the need to control the current position of the installation, as well as the need for reference to astronomical time and latitude of the installation location, which is mandatory for the closest analogue inventions. Multi-junction photocells used as solar position sensors have the highest sensitivity to direct solar radiation. They prevent the operation of false radiation sources and increase the accuracy of tracking the visible position of the Sun. The sun tracking system only works in the presence of direct solar radiation. The increased output voltage of these photocells allows the use of a simple control circuit for tracking motors.

From the above specific examples of the implementation of the claimed utility model for any specialist in this field, the possibility of its implementation with a simultaneous solution of the problem is obvious. At the same time, it is also obvious that insignificant changes can be made when implementing a utility model.

in its design, which, however, will not go beyond the limits defined by the utility model formula given below.

The inventive solar photovoltaic installation has a simple design. Installation installation technology is also simple. Operation of the installation can be carried out anywhere without reference to astronomical time and latitude.

Claims (1)

A solar photovoltaic installation comprising a solar battery with Fresnel lenses and receiving photoelectric converters, mounted on a mechanical system supporting the perpendicular position of the solar battery to the direction to the Sun, and equipped with a solar battery orientation system to the Sun, characterized in that the supporting mechanical system is formed by two frames - base and suspended, of which the base frame is mounted to rotate around a vertical axis, resting and the underlying surface with the help of wheels, one of which is equipped with an electric drive, and the suspended frame is mounted to rotate around a horizontal axis from the electric drive, while the solar battery itself consists of modules with solar concentrators located on the suspended frame in the form of steps, and the battery orientation system contains the primary and secondary sensors of the position of the Sun, the main of which consists of a shading screen with a hole and eight cascade type solar cells, four of which are located on the right, left, top and bottom on the outer sides of the screen and form azimuthal and zenithal coarse guidance channels that generate electrical signals when the position of the Sun changes, and four other photocells are located in the same way on the inner sides of the screen and form accurate guidance channels, the mentioned additional sensor consists of three cascade type photocells connected to the azimuth channel, two of which are directed left and right with respect to the main sensor, and the third in the opposite direction th side and the polarity of the connection is changed when passing South-North direction, wherein the closing signal is supplied from channel photocells azimuthal drive wheel base frame, and a signal to switch the actuator is supplied from a suspended frame of photocells zenith channel.