RU2789285C1 - Solar photo power plant - Google Patents

Abstract

FIELD: solar energy.

SUBSTANCE: invention relates to solar energy, namely to solar energy systems designed to generate electricity by photoelectric conversion of solar energy on the surface of the moon. Solar photoelectric power plant comprises a hollow cylindrical support (1), a hollow shaft (2) with a drive (3) mounted for rotation in the cavity of the cylindrical support (1), a solar battery (5) with a solar radiation concentrator on a heat-removing base (6), placed on the upper end of the hollow shaft (2). The optical axis (8) of the solar battery (5) is mounted orthogonally to the axis (9) of the hollow shaft (2). The hot part of the heat pipe (10) adjoins the heat-removing base (6), and the cold part of the heat pipe (10), equipped with a radiator (11), is located in the cavity of the heat exchanger (12) located on the upper end of the hollow shaft (2). The cavity of the heat exchanger (12) is connected through a system of coaxial channels (13), (14) equipped with a pump (15) to an expansion tank (16) made of a material with high thermal conductivity, installed adjacent to the lower part (17) of a hollow cylindrical support (1).

EFFECT: solar photovoltaic plant according to the invention provides efficient conversion of solar radiation into electrical energy and obtaining high specific energy output due to efficient heat removal and stabilization of the operating temperature of the photovoltaic battery under conditions of long-term operation of the photovoltaic power plant on the lunar surface.

3 cl, 1 dwg

Description

The invention relates to solar energy, namely to solar energy systems designed to generate electricity by photoelectric conversion of solar energy on the surface of the moon.

The efficiency of solar energy conversion largely depends on maintaining the optimal temperature regime for the operation of photovoltaic converters. When using solar power devices in outer space, the cooling of solar cells is carried out only by the radiation method, since in the absence of an air atmosphere, the mechanism of convection heat transfer cannot be activated. Heat removal from solar power systems when installed on the surface of the Moon becomes more complicated, since during the lunar day the open lunar surface is heated by the Sun to a temperature of more than 120 ° C, which leads to additional heating of the structural elements of the power plant and reduces the efficiency of heat removal from solar cells to open space .

Known solar photovoltaic station (see RU2764866, IPC H01L 31/042, H02S 20/30, H02S 20/32, publ. 01/21/2022), including an intermediate frame made in the form of a round cylindrical beam, equipped with a drive, an optical solar sensor, sensitive to the displacement of the Sun in the plane of the ecliptic, and installed with the possibility of rotation in the vertical plane by means of the first cylindrical hinges on two posts attached to the base, one of which is equipped with a mechanism for its vertical reciprocating movement. The solar photovoltaic station also includes a solar cell frame attached to the intermediate frame, a control unit connected to the input to the optical solar sensor, and the output to the drive. The intermediate frame is installed with the possibility of rotation by the drive around its axis by means of the second cylindrical hinges orthogonally fixed on the first cylindrical hinges. The frame of solar cells is installed parallel to the axis of rotation of the intermediate frame and is equipped with solar radiation concentrators, in the focus of which solar cells are installed, made in the form of rectangles with a long side parallel to the axis of a round cylindrical beam, while the length d and width h of the rectangles satisfy certain ratios.

A disadvantage of the known solar photovoltaic station during its operation on the lunar surface is an insufficiently efficient heat removal system, which makes it difficult to maintain the operating temperature of solar cells, reduces the efficiency of solar radiation conversion and leads to a reduction in their service life.

Known solar photovoltaic installation (see patent RU2715901, IPC H02S20 / 30, H01L31 / 042, publ. 03/04/2020), including an intermediate frame equipped with a first drive and mounted for rotation by means of the first cylindrical hinges on two racks attached to the base, a solar panel frame provided with a second drive and rotatably attached to the intermediate frame by means of a support with a second cylindrical hinge, the axis of which lies in a plane orthogonal to the axes of the first cylindrical hinges. The photovoltaic installation also includes a control unit connected by the first and second outputs, respectively, to the first and second drives. The intermediate frame is made in the form of a round cylindrical beam, which serves as the axis of the second cylindrical hinge of the support. The frame of the solar panels is attached to the support by means of the first cylindrical hinge and is equipped with the first optical solar sensor sensitive to the Sun's displacement in the ecliptic plane, and the second solar sensor sensitive to the Sun's displacement in the plane passing through the Earth's axis and the location of the installation. One of the racks is equipped with a mechanism for its vertical reciprocating movement.

The disadvantages of the known solar photovoltaic installation when placed on the surface of the Moon is a complicated system for controlling the movement of the solar cell frame, leading to a large angle of rotation of the solar panels in the plane of the perpendicular ecliptic, which creates an increased energy consumption when tracking the Sun and leads to a reduction in the service life of the installation, and also an inefficient heat dissipation system.

A solar photovoltaic installation is known (see patent US9027545, IPC F24J 2/54, publ. 05/12/2015), containing an intermediate frame equipped with a first drive and mounted for rotation by means of the first cylindrical hinges on two posts attached to the base, a frame of solar panels equipped with a second drive and rotatably attached to the intermediate frame by means of supports with second cylindrical hinges, and a control unit connected by interfaces with a satellite navigation system, an electronic altimeter and an electronic compass, and connected to the first and second drives respectively by the first and second outputs. The axes of the first cylindrical hinges lie in planes orthogonal to the axes of the second cylindrical hinges.

In the known solar photovoltaic installation, a complicated system for controlling the movement of the intermediate frame and the frame of solar panels is used, leading to a large angle of rotation of the solar panels in the ecliptic plane, which creates an increased energy consumption when tracking the Sun.

Known solar photovoltaic installation (see patent US10103685, IPC H02S 20/30, H02S 20/32; F24S 50/20, publ. towards the Sun during the day, and the tracking system includes two frames, each of which supports half of the array of photovoltaic modules. The primary axis of rotation is located horizontally and is driven by a linear actuator, located vertically by means of a chain drive, with a chain tensioning mechanism. Secondary axes of rotation are located perpendicular to the primary axis on the frames supporting the solar panels and are driven by a linear actuator connected by a single rod to the levers on the frames.

The disadvantages of the known solar photovoltaic installation are a significant backlash in the primary axis of rotation due to the use of a chain drive with a chain tensioner and accelerated wear of the drive mechanisms of the secondary axis of rotation, due to the constant adjustment of the angle of inclination of the secondary axis during the day.

A solar photovoltaic installation is known (see patent US8469022, IPC F24J 2/52, published 06/25/2013) including a solar panel, to the two ends of which, through a hinged connection, movable scissor-type frames are attached, equipped with an independent drive means and mounted on a fixed base, as well as Control block. Tracking the Sun is provided by raising or lowering the ends of the solar panel when appropriate signals are given from the control unit.

In the well-known photovoltaic installation, a complex drive system is used, consisting of a large number of moving elements, which reduces the durability and reliability of the device. Due to the design features of the installation, part of the time in the morning and evening hours the device is not able to follow the Sun, which leads to a decrease in the efficiency of the system.

Known solar photovoltaic (see RU2767718, IPC H01L 31/042, H02S 20/32, publ. 03/18/2022), coinciding with the present technical solution for the largest number of essential features and taken as a prototype. SUBSTANCE: solar photoelectric power station contains a vertical hollow cylindrical support, a shaft with the first drive and a thrust bearing, coaxially mounted for rotation in the cavity of the cylindrical support, a frame with a second drive and with an optical solar sensor sensitive to the displacement of the Sun, mounted on the upper end of the shaft by means of a cylindrical hinge, the axis of which is orthogonal to the axis of the shaft, and a solar battery mounted on the frame with concentrators of solar radiation, in the focus of which photoelectric converters are installed on a heat-removing base. The shaft is made of a material with increased thermal conductivity, the vertical hollow cylindrical support is made composite with the possibility of partial immersion in the soil of the installation site, the lower section of the cylindrical support is made of a material with increased thermal conductivity, the upper section of the cylindrical support is made of a heat-insulating material, and the outer surface of the shaft section protruding from the upper end of the cylindrical support, and the outer surface of the section of the cylindrical support that is not immersed in the ground, are made of reflective.

The disadvantages of the known solar photoelectric power station are the complexity of the device for tracking the Sun, which ensures the rotation of the solar battery around two axes and, as a result, the low reliability of the design, as well as the insufficiently efficient cooling system for photovoltaic converters, the heat removal from which is determined by the thermal conductivity of a large number of structural elements, due to resulting in large temperature gradients between photovoltaic converters and heat dissipation elements.

The objective of the present invention was to develop a solar photovoltaic power plant for placement on the surface of the Moon, providing efficient conversion of solar radiation into electrical energy and obtaining a high specific energy output due to efficient heat removal and stabilization of the operating temperature of the photovoltaic battery under conditions of long-term operation of the photovoltaic power plant on the surface of the Moon.

The problem is solved by the fact that the solar photovoltaic power plant includes a hollow cylindrical support, a shaft with a drive and a thrust bearing mounted for rotation in the cavity of the cylindrical support, a solar battery with a solar radiation concentrator on a heat-removing base, installed on the upper end of the shaft, while the cylindrical support is made with the possibility of partial immersion in the ground of the installation site of a photoelectric power station on the Moon. What is new in the photoelectric power plant is that the shaft is made hollow, the optical axis of the solar battery is installed orthogonally to the axis of the shaft, the heat sink base is equipped with a heat pipe, the hot part of the heat pipe is adjacent to the heat sink base, and the cold part of the heat pipe, equipped with a heat exchange radiator, is located in the heat exchanger cavity, located at the upper end of the shaft, the heat exchanger cavity through a system of coaxial channels equipped with a pump installed in the hollow shaft is connected to an expansion tank made of a material with high thermal conductivity, attached to the lower part of the cylindrical support through a hermetic seal.

The expansion tank can be made of copper or aluminum alloy.

Installation of the hot part of the heat pipe adjacent to the heat-removing base provides heat removal from the solar battery and stabilization of its temperature, placement of a heat exchange radiator of the cold part of the heat pipe in the heat exchanger cavity ensures heat transfer by the heat pipe to the heat exchanger cavity. The connection of the heat exchanger cavity through a system of coaxial channels with an expansion tank, the implementation by the pump of forced flow of the coolant from the expansion tank to the heat exchange radiator, and the penetration into the lunar soil to a depth set in the range from 1.0 to 1.6 m, the lower end of the cylindrical support with the adjacent to the lower part by the expansion tank, heat is transferred by the coolant from the heat exchange radiator to the expansion tank and dissipated in the lunar soil by the surface of the expansion tank.

The installation of a hermetic seal between the lower part of the cylindrical support and the expansion tank ensures the tightness of the internal cavities of the heat exchanger, the shaft and the expansion tank when filled with a coolant to transfer heat from the heat exchange radiator to the expansion tank. The installation between the outer cylindrical surface of the hollow shaft and the end of the hollow cylindrical support of a hermetic seal ensures the tightness of the internal cavities of the heat exchanger, the shaft and the expansion tank when the shaft rotates in the cavity of the cylindrical support.

The implementation of the expansion tank from materials with high thermal conductivity - copper or aluminum alloy, increases the efficiency of heat transfer to the lunar soil.

To ensure maximum efficiency of heat transfer to the lunar soil, it is necessary that the entire surface of the expansion tank be at a depth of more than 1.0 m at a lunar soil temperature of minus 35°C. Placing the lower end of the cylindrical support at a depth of less than 1.0 m at a higher temperature of the near-surface layer of the lunar soil reduces the efficiency of heat dissipation in the lunar soil. An increase in the placement depth of the lower end of the cylindrical support by more than 1.6 m leads to an unjustified increase in the consumption of materials and the mass of the structure without increasing the efficiency of heat transfer to the lunar soil.

The choice of a coolant with a freezing temperature below minus 40-50°C ensures the pumping of the coolant through a system of coaxial channels equipped with a pump installed in a hollow shaft into an expansion tank located in the lunar soil at a temperature of minus 35°C, and heat transfer from the heat-removing base to lunar soil during the operation of the power plant during the lunar days of the entire life of the station. An aqueous solution of ethyl alcohol can be used as a heat carrier, the freezing point of which varies from minus 40°C to minus 110°C with an increase in the alcohol concentration from 70% to 96%.

The essence of the present technical solution is illustrated by a drawing, which shows in a longitudinal section a general view of a solar photoelectric power station.

This solar photoelectric power plant (see drawing) contains a hollow cylindrical support 1, a hollow shaft 2 with a drive 3 and a thrust bearing 4, mounted for rotation in the cavity of the cylindrical support 1, a solar battery 5 with a solar radiation concentrator on a heat-removing base 6, mounted on the top end of the hollow shaft 2. Cylindrical support 1 is made with the possibility of partial immersion in the soil 7 of the installation site of a photoelectric power station on the Moon. The optical axis 8 of the solar battery 5 is installed orthogonally to the axis 9 of the hollow shaft 2. The hot part of the heat pipe 10 adjoins the heat sink base 6, and the cold part of the heat pipe 10, equipped with a heat exchanger 11, is located in the cavity of the heat exchanger 12, located on the upper end of the hollow shaft 2 The cavity of the heat exchanger 12 through a system of coaxial channels 13, 14, equipped with a pump 15, placed in the cavity of the shaft 2, is connected to an expansion tank 16, made of a material with high thermal conductivity, installed adjacent to the lower part 17 of the hollow cylindrical support 1 through a hermetic seal 18. A hermetic seal 19 is installed between the outer cylindrical surface of the hollow shaft 2 and the end of the hollow cylindrical support 1. In this case, the expansion tank 16 can be made of copper or aluminum alloy.

When placing a solar photovoltaic power plant on the surface of the Moon, the lower part of the hollow cylindrical support 1 with a coaxially mounted hollow shaft 2 and with the expansion tank 16 adjacent to the lower part of the hollow cylindrical support 1 is installed in the lunar soil 7 inclined to the lunar horizon 20 at an angle<p equal to the selenographic latitude station base locations on the Moon, with an inclination towards the lunar North when the station is based in the northern lunar hemisphere and with an inclination towards the lunar South when the station is based in the southern lunar hemisphere. When the optical axis 8 of the solar battery 5 is installed orthogonally to the axis 9 of the hollow shaft 2, the rotation of the hollow shaft 2 with the solar battery 5 installed at its upper end occurs around the axis 9, parallel to the axis of rotation of the Moon, at a rate of one revolution per one sidereal (stellar) month in direction opposite to the direction of rotation of the Moon around its axis, which ensures that the orientation of the solar battery 5 to the Sun during the lunar days of the entire life of the station. In this case, the depth W of the lower part 17 of the cylindrical support 1 with the expansion tank 16 in the lunar soil 7 is set in the range from 1.0 to 1.6 m. at the same time, the temperature of lunar rocks lying at a depth of more than (0.8-1.0) m is practically constant and equal to minus 35°C. During the operation of a solar photoelectric power station on the surface of the Moon, to remove heat, the internal cavities of the heat exchanger 12, expansion tank 16 and channels 13, 14 are filled with a coolant with a freezing temperature below minus (40-50)°C. The heat removed by the heat pipe 10 with a radiator 11 from the heat sink base 6 of the solar battery 5 installed on the upper end of the hollow shaft 2 is transferred by the coolant through the channel 13 by the pump 15 to the expansion tank 16 and dissipated in the lunar soil. The coolant cooled in the expansion tank 16 through channel 14, coaxial channel 13, enters the cavity of the heat exchanger 12, cooling the radiator 11 of the heat pipe 10.

The use of the present invention makes it possible, regardless of the temperature of the lunar surface, to lower and stabilize the temperature of the photovoltaic converters of the solar battery during the lunar day to the optimal value for the maximum efficiency of converting solar radiation into electrical energy and provides a high specific energy output in conditions of long-term autonomous operation of a solar photoelectric power station on the surface Moon.

Claims (3)

1. A solar photovoltaic power plant, including a hollow cylindrical support, a shaft with a drive and a thrust bearing mounted for rotation in the cavity of the cylindrical support, a solar battery with a solar radiation concentrator on a heat-removing base mounted on the upper end of the shaft, while the cylindrical support is made with the possibility of partial immersion in the soil of the installation site of a photoelectric power station on the Moon, characterized in that the optical axis of the solar battery is installed orthogonally to the axis of the shaft, which is made hollow, the heat-removing base is equipped with a heat pipe, the hot part of which is adjacent to the heat-removing base, and the cold part of the heat pipe, equipped with a heat exchange radiator, located in the cavity of the heat exchanger located at the upper end of the hollow shaft, the cavity of the heat exchanger through a system of coaxial channels equipped with a pump installed in the hollow shaft is connected to an expansion tank made of a material with high thermal conductivity an awn attached to the bottom of the cylindrical support through a hermetic seal. 2. Photoelectric power plant according to claim 1, characterized in that the expansion tank is made of copper. 3. Photoelectric power plant according to claim 1, characterized in that the expansion tank is made of aluminum alloy.

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