RU2324122C2 - Solar power station - Google Patents

Abstract

FIELD: electricity; helionics; solar power stations.

SUBSTANCE: in a solar power station, consisting of photoelectric and/or thermodynamic converters of solar energy, a device for measuring power output and energy of the solar power station, there is also a threshold device, a logical multiplication unit, a cloudiness analysing unit, a unit for assessing weather conditions, a negative oxygen ion generator and a control device. The output of the power station is connected to the input of the device for measuring power and energy of the solar power station. The output of the device for measuring power and energy is connected to the input of the threshold device. If the signal from the device for measuring power and energy of the power station is lower than a given threshold value, the output signal of the threshold device is applied to one of the inputs of the logical multiplication unit, while a signal from the cloudiness analysing unit is applied to the second input. The output of the logical multiplication unit is connected to one of the inputs of the control device, while the second input is connected to the output of the device for assessing weather conditions. The output of the control device is connected to the input of the generator of negative oxygen ions.

EFFECT: increased power of the solar power station due to scattering of clouds.

6 cl, 1 dwg

Description

The invention relates to solar engineering, in particular to solar power plants for generating electricity and heat.

Known solar thermodynamic power plant containing a block of parabolic mirror reflectors with heat receivers in the focal axis, a solar energy storage unit at phase transitions, a steam turbine unit, a unit for measuring and controlling the parameters of a solar power station, a unit for converting direct current to alternating industrial frequency. A disadvantage of the known solar power plant is the need for high-temperature storage of solar energy in case of a short-term decrease in electric power in the daytime due to cloudiness, as well as the need to use a fuel backup in the form of a gas boiler. (Sun & Wind Energy 2006, No. 1, pp. 18-22.)

Known solar photovoltaic power plant containing a block of photovoltaic converters of solar energy, a unit for measuring and controlling parameters and an inverter for converting direct current to alternating industrial frequency. (Bezrukikh P.P., Strebkov D.S. Renewable energy. Strategy, resources, technologies. M., 2005, ed. VIESH, pp. 117-183.) A disadvantage of the known power plant is the need to use a special inverter with controlled selection maximum power, which changes when the transparency of the atmosphere and the appearance of clouds.

The disadvantage of all known solar power plants is a decrease in electrical power with a change in cloud density. It is known that in cloudy conditions there is a significant decrease in the electric power of a solar power station. This leads to a decrease in the generated electric energy and an increase in the cost of one kWh, especially in countries with a large number of cloudy days per year. In this regard, the problem of cloud dispersion over a given area where solar power plants are located is extremely urgent for the development of solar energy.

The objective of the invention is to increase the power of solar power plants due to the dispersion of clouds.

As a result of using the present invention, the power of a solar power plant is increased due to the dispersion of cloudiness.

The above technical result is achieved in that a threshold device, a logical multiplication unit, a cloud analysis unit, a weather estimation unit, a negatively charged ion generator are additionally introduced into a solar power plant containing photovoltaic and / or thermodynamic converters of solar energy, a meter for the output power and energy of a solar power station oxygen control device, while the output of the solar power plant is connected to the input of the solar power and energy meter of the power plant, the output of the power and energy meter of the solar power plant is connected to the input of the threshold device, the output signal from which, provided that the signal from the power and energy meter of the solar power plant is less than the specified threshold, is fed to one of the inputs of the logical multiplication block, to the second input of which a signal is supplied from the cloud analysis unit, the output of the logical multiplication unit is connected to one of the inputs of the control device, the second input of which is connected to the output of the meteorological unit application, the control unit output is connected to the input of the generator of negatively charged oxygen ions.

In the inventive solar power station, the cloud analysis unit is made in the form of a fisheye-type video camera with an automatic cloud separation unit and / or a station for receiving and analyzing Earth remote sensing data from space.

In a solar power plant, a control device and a generator of negatively charged oxygen ions are located at a distance of 0-100 km from photovoltaic and / or thermodynamic converters of solar energy.

In a solar power plant, the control device and the generator of negatively charged oxygen ions are functionally simultaneously connected to several photovoltaic and / or thermodynamic converters of solar energy.

In a solar power plant, a control device is connected to a generator of negatively charged oxygen ions via remote communication channels.

To increase the reliability of cloud dispersion over a given territory, two to five control devices and from two to five generators of negatively charged oxygen ions are used.

The essence of the invention is illustrated in the drawing, which shows a block diagram of the inventive solar power plant.

A solar power plant consists of photovoltaic and / or thermodynamic converters of solar energy 1, a meter for the output power and energy of a solar power station 2, a threshold device 3, a logical multiplication unit 4, a cloud analysis unit 5, a control unit 6, a weather estimation unit 7, a negative ion generator oxygen 8. In this case, the drawing shows clouds 10 that form precipitation, wind direction 11, clouds 12 that scatter at a distance L above the photoelectric and / or thermo Response Dynamic solar energy converters 1, the consumer 13 and the solar radiation 14.

The output of the solar power plant is connected to the input of the power and energy meter of the solar power plant 2, the output of which is connected to the input of the threshold device 3, the output of which is connected to the input of the logical multiplication unit 4, the second input of which is connected to the cloud analysis unit 5, the output of the logical multiplication unit 4 connected to one of the inputs of the control device 6, the second input of which is connected to the output of the weather assessment unit 7, the output of the control device 6 is connected to the input of the negatively charged generator and of oxygen 8.

The inventive solar power plant operates as follows.

At the output of photovoltaic and / or thermodynamic converters of solar energy (output of a solar power station) 1, electric power is measured using a meter of output power and energy of a solar power station 2, and when the power decreases below a certain level (when comparing it with a given threshold) in a threshold device 3 the signal is fed to one of the inputs of the logical multiplication unit 4. In the cloud analysis unit 5, which is a video camera with a wide lens (such as a "fisheye") with block av the systematic separation of clouds in the horizon in the visible range of electromagnetic wavelengths and / or the station for receiving and processing Earth remote sensing data from space in the event of cloudiness, a signal is generated that is fed to the second input of logical multiplication block 4 operating according to scheme I. time of two signals indicating that at the same time there was a decrease in electric power at the output of solar power station 1 and the presence of cloudiness in the sky, at the output of the block of multiplication 4, a signal is generated that is input to the control device 6. In the control device 6, based on information about the parameters of the initial meteorological situation (temperature, humidity, speed and direction of the wind, etc.) received from the meteorological unit 7, the operating modes of the generator are determined negatively charged oxygen ions, and a signal is supplied to the input of a negatively charged oxygen ion generator 8. The negatively charged oxygen ion generator 8 receives electrical energy from the sun power plant and generates a convective upward flow of negatively charged oxygen ions generated during corona discharge. The operating modes of the generator of negatively charged oxygen ions (level of electrostatic field strength and time intervals for maintaining a given level of electrostatic field strength) are set by control device 6 depending on the initial meteorological parameters of the atmosphere over a given territory. Convective upward flow of 9 negatively charged oxygen ions forms a convective atmospheric cell, which is a system of ascending and descending air flows. When several generators 8 of negatively charged oxygen ions are located along the perimeter of a given territory, on which photovoltaic and / or thermodynamic converters of solar energy 1 are located, they carry out a controlled process of exposure to atmospheric formations. When the generators 8 of negatively charged oxygen ions are turned on in the upper layers of the atmosphere in clouds 10, intense formation of cloud drops occurs due to condensation. With a duration of exposure to the same cloud formations, short-term or long-term precipitation occurs outside a given territory. At the same time, downward flows of dry superheated air are formed over a given territory (the location of photovoltaic and / or thermodynamic converters of solar energy), which, when they move, lead to intensive evaporation of cloudy particles 12 flowing in the wind 11 and precipitation, i.e. cloud scattering occurs.

Thus, cloud cover is scattered above the surface of the solar power station, which in turn leads to an increase in its power. The power consumed by the generator 8 is of the order of 100 watts.

It is important to note that there is no need to connect external energy sources to ensure the functioning of the proposed device. This is due to the fact that the power supply of individual elements of the inventive device is carried out due to the energy generated by photovoltaic and / or thermodynamic converters of solar energy 1 without any particular damage to the end user. The energy flows from the photovoltaic and / or thermodynamic converters of solar energy 1 to the constituent elements of the proposed device are shown in dotted lines in the drawing.

The positive effect of the use of the invention is that its use significantly increases the electrical power and energy generated by the solar power station.

The efficiency coefficient of the device when using it as a source of additional energy can be calculated by the formula:

where P ₁ is the electric power generated by a solar power plant in the absence of cloudiness;

R ₃ - the electric power spent on power supply of the components of a solar power station;

P ₂ - electrical power generated by a solar power plant in the presence of cloudiness;

a - coefficient taking into account the increase in the electric power of a solar power station, provided there is no cloud cover.

It is known from practice that the coefficient a can vary from several units with small cloudiness to ten or more with strong continuous cyclonic cloudiness. If we assume that P ₃ << P ₂ , for example, when the power of the solar power plant is not less than 1 kilowatt, then, as can be seen from formula (1), the efficiency coefficient of the claimed solar power plant can reach a value of a. Physically, this means that due to the application of the invention, the useful electric power of a solar power plant can increase several times.

The control device 6 can be connected to a generator of negatively charged oxygen ions 8 using remote communication channels. Remote communication channels can be, for example, the Internet, intranet, satellite, radio, radio, mobile, and others.

To increase the reliability of providing the cloud dispersion process, depending on the meteorological situation, several (from two to five) control devices and several (from two to five) generators of negatively charged oxygen ions can be used simultaneously. At the same time, the joint work of several control units and generators of negatively charged oxygen ions will make it possible to provide cloud scattering in the territory with linear dimensions L = 50-100 km and over an area of up to 30,000 km ² over a period of several hours to 2-3 days, depending on the initial meteorological conditions.

Claims (6)

1. A solar power plant, including photovoltaic and / or thermodynamic converters of solar energy, a meter of output power and energy of a solar power plant, characterized in that the solar power plant comprises a threshold device, a logical multiplication unit, a cloud analysis unit, a meteorological environment assessment unit, a negatively charged oxygen ion generator , a control device, wherein the output of the solar power station is connected to the input of the power and energy meter of the solar power station, the power and energy meter of the solar power plant is connected to the input of the threshold device, the output signal from which, provided that the signal from the power and energy meter of the solar power plant is less than the specified threshold, is fed to one of the inputs of the logical multiplication unit, to the second input of which the signal from the block cloud analysis, the output of the logical multiplication unit is connected to one of the inputs of the control device, the second input of which is connected to the output of the unit for assessing meteorological conditions, the output of the device is systematic way connected to the input of the generator of negatively charged oxygen ions. 2. The solar power station according to claim 1, characterized in that the cloud analysis unit is made in the form of a fisheye video camera with an automatic cloud separation unit and / or a station for receiving and analyzing Earth remote sensing data from space. 3. The solar power station according to claim 1, characterized in that the control device and the generator of negatively charged oxygen ions are located at a distance of 0-100 km from the photovoltaic and / or thermodynamic converters of solar energy. 4. The solar power station according to claim 1, characterized in that the control device and the generator of negatively charged oxygen ions are functionally simultaneously connected to several photovoltaic and / or thermodynamic converters of solar energy. 5. The solar power station according to claim 1, characterized in that the control device is connected to a generator of negatively charged oxygen ions using remote communication channels. 6. The solar power station according to claim 1, characterized in that it contains from two to five control devices and from two to five generators of negatively charged oxygen ions.