RU2730544C1 - Sunny house - Google Patents

Abstract

FIELD: solar power engineering.SUBSTANCE: invention relates to solar architecture and solar power engineering, in particular to solar buildings with solar power plants for production of electric energy. Solar house comprises a roof with solar modules made of connected solar cells, the roof is made gable, one of the slopes faces the west, and the second slope faces the east, the roof ridge is made in the meridional direction, and roof slopes are located at an angle of sixty degrees to each other and form an equilateral triangle with the plane of support for them covering the house. Solar modules are made, for example, in the form of known standard silicon photoelectric panels which are connected to solar batteries. In the second version of the solar house during the entire sunny day with direct solar radiation half the solar modules of the connected solar cells on the fixed surface of the cylindrical base with a meridian directed axis are illuminated, wherein the illuminated portion moves from the east side of the cylindrical surface to the west side. At the same time solar modules from connected solar cells on fixed surface of cylindrical base realize the effect of azimuth-zenith tracking of the Sun.EFFECT: technical result consists in increase in electric power production and in elimination of interruptions during operation of solar modules in the morning and evening hours due to mutual shading.2 cl, 2 dwg, 1 tbl

Description

The invention relates to solar architecture and solar energy, in particular to solar buildings with solar power plants for generating electrical energy.

A known analogue is a solar house (Strebkov D.S., Tveryanovich E.V., Irodionov A.E., Polushin S.A. Solar house. Patent RF No. 2303753, Bul. 21 of 27.07.2007), containing the enclosing structures of the walls and the roof, while on the roof two solar modules with concentrators are installed, consisting of two symmetric conjugated semi-parabolic cylindrical mirror reflectors with an aperture angle of 24-72 °, the optical axes of which are directed along the north-south axis and are oriented to the south at an angle (90 ° -φ) to the horizon, and the branches of adjacent semi-parabolic-cylindrical reflectors have one common vertical tangent plane of symmetry, the branches of each reflector are rotated relative to the focal axis in such a way that the angle between the focal planes of each of the branches is 24-70 °, and solar radiation receivers are installed in each reflector between the focal planes of their branches, where φ is the latitude of the terrain. Mirror reflectors can be made in the form of mirrored bezels made of tempered glass with bezel width "a" equal to a = (0.4-1.2) OF, where OF is the focal length of the concentrator.

The disadvantage of the known solar house is the limited operating time of solar modules due to their shading by the branches of semi-parabolic cylindrical reflectors.

The closest in technical essence to the proposed invention is a solar house (Strebkov DS, Kirsanov AI, Panchenko VA Solar house. RF Patent No. 2694066). The invention - the prototype relates to solar architecture and solar energy, in particular to solar buildings with built-in solar power plants for generating electrical energy and heat. In a solar house containing wall enclosing structures and a roof with built-in solar modules made up of connected solar cells enclosed in a glass protective shell, according to the invention, two-sided solar modules are installed on the roof surface in several rows in the meridional direction with the orientation of the working surfaces to the east and west , each module is made of parallel-connected groups of solar cells with a double-sided working surface, each group of solar cells consists of solar cells connected in series in the meridional direction and is equipped with a diode, at the upper and lower ends of the double-sided solar modules are fixed in thermal contact with the glass protective shell of the pipe for coolant pumping connected to the hot water supply and heating circuit of the solar house, solar radiation reflectors are installed on the roof surface around the double-sided solar modules. In fact, the prototype device solves the problem of optimal use of the area of a horizontal roof or roof oriented south at an angle β to the horizontal surface, i.e. remove as much solar energy as possible from a limited horizontal surface area.

The disadvantage of the prototype device is the low utilization factor of the installed power of solar devices in the form of vertical or tilted by 10 ° -20 ° in opposite directions of double-sided solar modules due to underutilization at the agreed values of the cotangent of the angle (ctgα = 2 ÷ 6) of the height of the Sun above the horizon in the morning and evening from one hour to two hours due to shading by neighboring double-sided solar modules.

The technical problem solved by the present invention is to increase the efficiency of using solar energy by solar devices on the surface of the building roof.

The technical result consists in increasing the production of electricity and in reducing the breaks in the operating time of solar modules in the morning and evening hours.

The technical result is achieved by the fact that in a solar house containing a roof with solar modules made of switched solar cells, the roof is made of two slopes, the first slope of which is facing west, the second slope is facing east, and the roof ridge is directed meridionally, while on the indicated roof slopes the modules of solar cells are laid, and the roof slopes are located at an angle of sixty degrees to each other and form an equilateral triangle with the plane of the supporting floor of the house.

In addition, the technical result is achieved by the fact that in a solar house containing a roof with solar modules made of switched solar cells, the solar modules are laid on a fixed surface of a cylindrical base with supports fixed on the roof, while the axis of the cylinder is directed meridionally with an angle to the horizon, ensuring maximum energy production in a given area.

FIG. 1 general view of the solar house.

FIG. 2 roof of a solar house with solar modules laid on a fixed surface of a cylindrical base.

According to Fig. 1, a solar house containing a roof with solar modules made of switched solar cells, a gable roof, slope 1 of which is facing west, and slope 2 is facing east, roof ridge 3 is directed meridionally, while modules 4 are laid on these roof slopes solar cells, and the slopes 1 and 2 of the roof are located at an angle of sixty degrees to each other and form an equilateral triangle with the plane 5 of the supporting overlap of the house. In this case, the solar modules are made, for example, in the form of known standard silicon photovoltaic panels, which are laid on the roof slopes and connected to form solar panels.

According to Fig. 2, in a solar house containing a roof with solar modules made of switched solar cells, the solar modules 4 are laid on a fixed surface of a cylindrical base 6 with supports 8 fixed on the roof 7, while the axis 9 of the cylinder is directed meridionally with an inclination to the horizon at an angle that provides maximum energy production in a given area.

The solar house, according to fig. 1 operates as follows. At sunrise, solar radiation illuminates 4 solar modules on the east slope 2 of the roof. At noon, solar radiation arrives at solar modules 4 of both slopes 1 and 2. At sunset, solar radiation illuminates solar modules 4 on the western slope 1 of the roof. Computer modeling of well-known equations was carried out (Twidell J., Weir A. Renewable energy sources. Transl. From English. - M .: Energoatomizdat. 1990. - 392 p.: Ill. See pp. 77-83). Table 1 shows the results of computer simulation. The calculations were carried out for an area located at a northern latitude, for example, Moscow (ϕ = 56 ° N) at different values (see Table 1) of the inclination angles β ° and angles γ ° of the azimuthal orientation of slopes 1 and 2 roofs for the 134th day of the year, when in clear weather a sunny day from sunrise to sunset lasts 16 hours. For ease of comparison, it was assumed in the calculations that solar modules are made in the form of panels with an area of 1 m ² . Then the results can be multiplied by the area of real roof slopes 1 and 2.

For example, according to row 2 of the table, if a solar panel with an area of S = 1 m ^{2 is} oriented strictly to the south (γ ° = 0) and is tilted to the horizon at an angle β ° = 37 °, which is optimal for a given latitude, then during a sunny day of 16 hours it will generate electricity E = 7324 Wh. In a prototype device according to line 12 of the table, if a double-sided solar module has two working surfaces with an area of S = 1 m ² each, one is oriented strictly to the west (γ ° = -90 °), and the second is oriented strictly to the east (γ ° = + 90 °), and the double-sided solar module itself is placed vertically (β ° = 90 °), then during a sunny day of 16 hours they will generate electricity E = 9775 Wh.

In the proposed invention, according to line 9 of the table, if on two roof slopes, of two solar panels with an area of S = 1 m ² each, one is oriented strictly to the west (γ ° = -90 °), and the second is oriented strictly to the east (γ ° = + 90 °), while the roof slopes are located at an angle of sixty degrees to each other and form an equilateral triangle with the plane 5 of the floor of the house supporting them, then during a sunny day of 16 hours they will generate electricity E = 12590 Wh., those. a third more than a prototype device.

The proposed version of the arrangement of solar modules on the roof of the house, shown in Fig. 2 operates as follows. At sunrise, solar radiation illuminates solar modules 4 of switched solar cells on the eastern side of the fixed surface of the cylindrical base 6, i.e. illuminates half of the cylindrical surface. At noon and at sunset, solar radiation also illuminates solar modules 4 over half the cylindrical surface. Thus, during the entire sunny day, solar modules 4 of switched solar cells on half of the fixed surface of the cylindrical base 6 are illuminated, and the illuminated area moves from the east side of the cylindrical surface to the west. In this case, essentially solar modules 4 of switched solar cells on a fixed surface of a cylindrical base 6 implement azimuth-zenith tracking of the Sun. Then, in the proposed invention, according to line 4 of the table, during a sunny day with a duration of 16 hours, electricity will be generated E = 14400 Wh.

Claims (2)

1. A solar house containing a roof with solar modules made of switched solar cells, characterized in that the roof is gable, the first slope of which is facing west, the second slope is facing east, and the ridge of the roof is directed meridionally, while the roofs are laid on these slopes modules of solar cells, and the roof slopes are located at an angle of sixty degrees to each other and form an equilateral triangle with the plane of the supporting floor of the house. 2. A solar house containing a roof with solar modules made of switched solar cells, characterized in that the solar modules are laid on a fixed surface of a cylindrical base with supports fixed on the roof, while the axis of the cylinder is directed meridionally with an inclination to the horizon at an angle of β °, which provides maximum energy production in a given area.

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