RU2377472C1 - Solar power plant - Google Patents

Abstract

FIELD: heating systems.

SUBSTANCE: invention refers to solar engineering and can be used both at solar power stations and as private power plant. Solar photo power plant includes solar battery (1) arranged on mechanical system (2). Solar battery consists of separate similar modules (3) with panel (6) of solar-heat collectors and panel (7) of photocells. Mechanical system (2) includes drive (10) of azimuth rotation and drives (9) of zenith rotation and is equipped with device (8) of the Sun position control. Modules (3) are located on mechanical system in parallel rows (5) immediately adjacent to each other in each row (5). Solar battery (1) is connected at least to one drive (9) of zenith rotation and one drive (10) of azimuth rotation.

EFFECT: invention must provide decrease of wind loads at maintaining the simplified design and high efficiency of conversion of solar energy into electricity.

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Description

The invention relates to solar energy and can be used both in solar power plants and as an individual power plant.

The photovoltaic conversion of concentrated solar radiation using solar cells, optical concentrators and special rotary support devices equipped with solar position sensors and electric drives is one of the most promising methods for generating electricity from renewable sources.

A known solar power plant (see patent RU No. 2270964, IPC F24J 2/16, published 02.27.2006), including a solar module for converting electromagnetic radiation and its orientation system. The solar energy module for converting the received electromagnetic radiation includes rectangular solar panels arranged horizontally on the supporting surface of the supporting structure with side reflectors mounted obliquely to the photosensitive surface of the panels in the row spacing of the latter. In the orientation system, including a tracking unit connected by the output to the supporting structure, a first photoelectric sensor, a second photoelectric sensor is connected, connected to the second input provided on the tracking unit by the output. The first photoelectric sensor is optically coupled by its input to the source of the converted electromagnetic radiation, and the output is connected to the first input of the tracking unit. The first and second photoelectric sensors are mounted under the side reflectors of one of the solar panels mirror-symmetrically relative to the longitudinal axis of symmetry of the latter.

The well-known solar power plant has a large windage, and also does not provide a high multiplicity of concentration of solar radiation converted by solar cells.

Known solar power plant with vertical panels (see international application No. WO 2007091287, IPC H01L 31/042, published 16.08.2007). The installation includes a support tower in the form of a triangular or pentagonal frame, on the side of which a panel of photoelectric converters is installed. A tower equipped with a system of rotation around a horizontal axis is mounted on a circle equipped with a drive and rotating around a vertical axis. The system of rotation around the horizontal axis includes two arc gears fixed on the circular cylindrical base of the support tower, engaged with gears fixed on the horizontal axis of the drive.

A disadvantage of the known installation is the fact that the panel of photovoltaic cells is experiencing significant wind load.

The IHCPV solar power plant is known (see "Estimating the Cost of Integrated High-Concentrated Photovoltaics for Large-Scale Applications Related to Centralized Power Supply Networks"; Proceedings 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 power plant contains a solar battery with Fresnel lenses and radiation-receiving photoelectric converters, located 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 mounted on a strictly vertical support rack, 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 orientes 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 °.

The known solar power plant is subjected to relatively large wind loads due to the solar battery, presented in the form of a monolithic panel of large dimensions. In addition, the IHCPV solar photovoltaic installation has a rather complicated design, and the installation technology requires a lot of labor due to the need for rigid and strictly vertical fixation of the mechanical support system in the ground of the support column.

Known solar power installation (see patent RU No. 2286517, IPC F24J 2/42, published October 27, 2006), which coincides with the claimed technical solution for the largest number of essential features and adopted as a prototype. The prototype installation contains a solar battery of concentrator photovoltaic modules placed on a mechanical orientation system of concentrator photovoltaic modules on the Sun, containing an azimuthal rotation drive, a zenithal rotation drive and a sun position control device having anti-aircraft and azimuthal tracking subsystems. The mechanical orientation system is formed by two frames - base and suspended. The base frame is mounted to rotate around a vertical axis, relying on the underlying surface using wheels, one of which is equipped with an electric drive. The suspended frame is mounted to rotate around a horizontal axis from the electric drive. The solar battery consists of modules with solar concentrators located on a suspended frame in the form of steps. The battery orientation system contains the primary and secondary sensors for the position of the sun. The main sensor consists of a shading screen with a hole and eight cascade-type photocells, four of which are placed on the right, left, top and bottom on the outside of the screen and form coarse azimuth and zenith channels. Four other photocells are located in the same way on the inner sides of the screen and form accurate guidance channels. An additional sensor consists of three cascade type photocells connected to the azimuth channel. In this case, the signal for turning on the electric drive of the wheel of the base frame is supplied from the photocells of the azimuth channel, and the signal for turning on the electric drive of the suspended frame is supplied from the photocells of the anti-aircraft channel.

The known photovoltaic installation has a relatively simple design, high efficiency of converting solar energy into electricity through the use of Fresnel lenses as concentrators, however, the location of modules with solar concentrators on a suspended frame in the form of steps can lead to increased wind loads on the installation.

The objective of the proposed technical solution was the development of a photovoltaic installation having reduced wind loads while maintaining a simplified design and high efficiency of converting solar energy into electricity.

The problem is solved in that the solar photovoltaic installation includes a solar battery of concentrator photovoltaic modules placed on a mechanical orientation system of concentrator photovoltaic modules on the Sun in the form of a horizontal frame structure containing an azimuthal rotation drive and anti-aircraft rotation drives. The solar photovoltaic installation is equipped with a device for monitoring the position of the Sun, which has channels of zenithal and azimuthal tracking. The mechanical system maintains the perpendicular position of the solar battery toward the direction of the sun. Concentrator photovoltaic modules are located on the mechanical system in parallel rows close to each other in each row, while the horizontal distance d between adjacent rows of concentrator photovoltaic modules satisfies the ratio, see:

h≤d≤h / sin (22.6-0.2 * φ),

where h is the vertical size of the module, cm;

φ - geographical latitude of the installation location, degrees.

The difference h _{1 the} heights of the previous and subsequent rows of concentrator photovoltaic modules satisfies the ratio, see:

0≤h ₁ ≤h.

The azimuthal tracking drive is common to all modules. Each row of concentrator photovoltaic modules can be equipped with an individual anti-aircraft rotation drive. The anti-aircraft rotation drive may be common to at least two rows of concentrator photovoltaic modules.

The horizontal distance d between the rows of modules must be equal to or greater than the vertical size of the module h, because the arrangement of the rows at a shorter distance will make it impossible to orient the modules perpendicular to the sun's rays if the sun is at its zenith. At the same time, the horizontal distance d between the rows of modules should be less than h / sin (22.6-0.2 * φ), where φ is the geographical latitude of the installation location in degrees. The arrangement of rows at a greater distance than h / sin (22.6-0.2 * φ) will lead to an unjustified increase in the size of the installation, which does not lead to a noticeable increase in the conversion efficiency. Each subsequent row of modules is located not lower than the previous row of modules, because otherwise, part of the lens surface of each subsequent row will be obscured by the previous row of modules. Each subsequent row of modules does not rise above the previous row by an amount greater than the vertical size of the module h. If the rows of modules rise above each other by an amount greater than the size of the module h, the installation will become cumbersome and less windproof.

Determining the position of the modules with reference to the geographical latitude of the terrain allows us to achieve the best combination of high conversion efficiency of solar radiation and good wind resistance regardless of where in the world this photovoltaic installation is used.

The inventive photovoltaic installation is illustrated by drawings, where

figure 1 shows the first variant of the inventive photovoltaic installation (side view);

figure 2 shows a second variant of the inventive photovoltaic installation (side view);

figure 3 shows a front view of the first embodiment of the inventive photovoltaic installation.

The inventive solar photovoltaic installation (see Fig.1-3) includes a solar battery 1 placed on the mechanical system 2 of the orientation of the concentrator photovoltaic modules 3 on the Sun in the form of a horizontal frame structure 4. The concentrator photovoltaic modules 3 are located on the mechanical system 2 in parallel rows 5 close to each other to each other in each row. Each module 3 of the battery 1 includes a panel 6 of solar concentrators and a panel of 7 solar cells. The mechanical orientation system 2 of the concentrator photovoltaic modules 3 on the Sun maintains the perpendicular position of the solar battery 1 to the direction on the Sun and is equipped with a device 8 for controlling the position of the Sun. The orientation system 2 includes actuators 9 of zenithal rotation, an azimuthal rotation drive 10, controlled by the device 8 for controlling the position of the sun. As the device 8 for monitoring the position of the Sun, any known device of the same purpose can be used, for example, the device for monitoring the position of the Sun described in patent RU No. 2286517. The mechanical system 2 with the help of the frame structure 4 provides support for the modules 3, the zenithal rotation of the rows 5, for example, by means of the rotating axles 11 connected by the actuators 9 of the zenithal rotation. The frame structure 4 is based on the underlying surface 12, for example, using wheels 13, one of which is connected to the drive 10 of the azimuthal rotation.

The mechanical orientation system 2 of the concentrator photovoltaic modules 3 on the Sun of a photovoltaic installation with a sun position control device 8 orientates the modules 3 in such a way as to place the solar concentrator panel 6 perpendicular to the sun's rays. Electricity generated by modules 3 is supplied to an external consumer or electric energy storage device.

The inventive solar photovoltaic installation allows you to expand the scope of photovoltaic installations due to their location on surfaces well lit by the Sun, but with strong gusts of wind, for example on the roofs of industrial and residential facilities or in coastal areas.

Claims (4)

1. Solar photovoltaic installation, including a solar battery of concentrator photovoltaic modules placed on a mechanical orientation system of concentrator photovoltaic modules on the Sun in the form of a horizontal frame structure containing an azimuthal rotation drive and zenithal rotation drives, a device for monitoring the position of the Sun having anti-aircraft and azimuthal tracking channels , the concentrator photovoltaic modules are arranged on said mechanical system in parallel series E close to each other in each row, the horizontal distance d between adjacent rows of photovoltaic concentrator modules satisfies the relation, see:
h≤d≤h / sin (22.6-0.2 · φ);
where h is the vertical size of the module, cm;
φ — geographical latitude of the installation location, degrees;
the difference h _{1 of the} heights of the previous and subsequent rows of concentrator photovoltaic modules satisfies the ratio, see:
0≤h ₁ ≤h. 2. Installation according to claim 1, characterized in that each row of concentrator photovoltaic modules is equipped with an individual anti-aircraft rotation drive. 3. Installation according to claim 1, characterized in that the anti-aircraft rotation drive is common to at least two rows of concentrator photovoltaic modules. 4. Installation according to claim 1, characterized in that the azimuthal rotation drive is common to all modules.

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