ES1265150U - PHOTOVOLTAIC SYSTEM IN ENVELOPE AND INCLINATION CONFIGURATION ADAPTED TO THE SEASON OF THE YEAR (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Photovoltaic system in an envelope and inclination configuration adapted to the season of the year characterized by its configuration formed by several panels around a central panel to which they are joined jointly by its two longitudinal parallel sides, according to a symmetrical arrangement with respect to a plane perpendicular to the referred central panel by the longitudinal segment that divides it into two halves, as well as by its fixing structure to the floor or roof according to its two fixed front supports provided free angular movement, in combination with two rear supports to be fixed at the same height between the heights available in the corresponding lifting pillars on the floor or roof. (Machine-translation by Google Translate, not legally binding)

Description

DESCRIPTION

Photovoltaic system in envelope and inclination configuration adapted to the season of the year

OBJECT OF THE INVENTION

The following invention, as expressed in the wording of the present specification, refers to a solar energy system in an envelope configuration formed by three or five photovoltaic panels mounted on a structure with an adjustable angle of inclination according to various positions depending on the season of the year, with which it is possible to increase the production of electrical energy generated by the light radiation of the sun that falls on photovoltaic cells.

SCOPE

The present invention falls within the field of photovoltaic solar energy. Specifically, it is included in the sector of structures used to capture photovoltaic solar energy.

BACKGROUND OF THE INVENTION

At present, different systems are known to produce electrical energy, among which it is worth highlighting solar energy systems and among these in turn those that comprise solar panels that integrate photovoltaic cells that receive light radiation from the sun to generate electrical energy, from Thus, when such photovoltaic cells receive the light radiation from the sun perpendicularly, the highest performance is obtained, while when the direction of the light radiation forms an angle different from the perpendicular direction with respect to the photovoltaic cells, the performance decreases, highlighting that the perpendicularity of the light radiation normally only occurs in a short space of time, unless the panel is mobile and follows the relative orientation of the sun throughout the day.

On the other hand, the performance of a normalized solar panel in the different seasons of the year is specified below. Thus, in the summer time, a solar panel will have a daily production capacity in solar time between 90% and 100% of its capacity. On the other hand, in the spring / autumn period in the same period of time, the capacity will be between 50 and 70% capacity. Finally, in winter, in the same period of time, the yield will be between 20 and 35%.

Based on the aforementioned circumstances, photovoltaic installations have evolved in recent years in an accelerated way, in such a way that the first installations of fixed solar panels have given way in a few years to the current installations with the possibility of orientation of the panels. depending on the position of the sun, for which the panels are mounted on different types of movable structures by manual or motorized operation, generically called solar trackers, which can modify the orientation of the panels by moving them around a vertical axis (azimuthal rotation) and varying the inclination of its plane with respect to the horizontal (zenith turn).

In this respect, taking into account the state of the art in the matter, the following inventions are identified, identified by their publication number and title, respectively;

• WO2012146817A1, "Solar energy system".

• WO2009121977A1, "Solar tracker".

• WO2014118394A1, "Structure with baffles for capturing solar energy".

• ES2716850T3, "Support for solar energy collectors".

• ES2492697T3, "Installation with a housing structure adjustable in an axis around a horizontal axis for housing one or more solar panels or photovoltaic modules or similar"

Based on the background described, the "Photovoltaic system in envelope configuration and inclination adapted to the season of the year", provides the following advantages with respect to the state of the art;

• Reduces installation costs, compared to installations with one or two axis trackers.

• Simplifies installation and subsequent maintenance compared to an equivalent installation with one or two axis trackers.

• Improves energy efficiency compared to a fixed solar installation.

• Provides a simple solution for use on roofs that optimizes power generation both in stations with less photovoltaic production and in time slots where the incidence of sunlight is lower; to the dawn or at sunset, acting precisely in the seasons where the sun rises less and rises in a shorter interval.

• The structure with an adjustable angle of inclination according to various positions depending on the season and year that determines the height of the sun, can be adapted to the region of the world in which the installation will be carried out in order to optimize energy efficiency Of the same.

EXPLANATION OF THE INVENTION

In order to achieve the objectives and avoid the drawbacks mentioned in the previous sections, the invention entitled "Photovoltaic system in envelope configuration and inclination adapted to the season of the year" proposes a solar energy system made up of a set of photovoltaic cells. that receive light radiation from the sun to generate and produce electrical energy.

It is characterized by the fact that it comprises an enveloping structure formed by three or five panels of flat configuration that integrate on their internal faces a set of independent pieces that support the photovoltaic cells that directly receive light radiation from the sun.

The aforementioned enveloping structure is characterized by being shaped according to a central panel, plus one or two contiguous side panels with respect to each of its two longitudinal parallel sides, which provides it with greater use of the sun depending on the variation of its azimuth angle to throughout the day, according to a symmetrical configuration with respect to a plane perpendicular to the central panel itself by the longitudinal segment that divides it into two halves, where the angle formed between adjacent panels is a fixed angle between 15 ° and 45 °.

More specifically, regarding the distribution of surfaces around three or five panels and the angle between them, in a three-panel configuration, the surface of the central panel would be 40%, while the angle between adjacent panels would be between 20 ° and 30 °.

While in the case of using an arrangement in five panels, the surface of the central panel would be 40%, each panel of both ends would have a surface of the 10%, with the remainder to be distributed in two central side panels, while the angle between adjacent side panels would be between 30 ° and 45 °, and of these with the central panel between 15 ° and 25 °.

Another characteristic of the invention is that the base structure on which the unitary photovoltaic system sits has a set of discrete positions as a means to adapt its angle of inclination with respect to the ground depending on the season of the year, according to two front supports fixed with free angular movement, in combination with two rear supports to be fixed at the same height between the heights available in the lifting pillars on the floor or roof.

The system of the invention thus described provides an increase in the productive capacity of the panels that make up the system of the invention, precisely at the moments when production is most critical to satisfy energy demand.

Finally, the proposed system makes use of the technology present in the state of the art to complete the rest of the photovoltaic installation for the generation of electrical energy, such as photovoltaic cells, anchoring system to the roof, connections, wiring, batteries. , converters if applicable, as well as the rest of the elements that make up the installation as a whole.

The proposed photovoltaic system will see its highest performance in fixed bases such as in municipal schools, sports centers, indoor swimming pools, hospitals, town halls, nursing homes, country houses, industrial warehouses, livestock buildings, roofs and walls of new technology parks, lighting of cities with low consumption LED diodes, information panels, traffic light signaling, light signaling in cities and roads, information posts, etc.

DESCRIPTION OF THE DRAWINGS

To complement the description that is being made and in order to help a better understanding of the characteristics of the invention, according to a preferred example of a practical embodiment thereof, a set of drawings is attached as an integral part of said description. For illustrative and non-limiting purposes, the following has been represented:

Figure 1.- Main perspective view of "Photovoltaic system in envelope configuration and inclination adapted to the season of the year" in its configuration in three planes. Figure 2.- Main perspective view of "Photovoltaic system in envelope configuration and inclination adapted to the season of the year" in its configuration in five planes.

Figure 3.- Detail main perspective view of the lifting pillar on the floor or roof provided with three heights available at its junction with the rear support.

In the aforementioned figures the following constituent elements can be highlighted;

1. Central photovoltaic panel.

2. Side photovoltaic panels adjacent to the previous one.

3. Mooring and fixing profiles.

4. Fixed angle between side panels with respect to the central panel.

5. Front supports for anchoring to the floor or deck provided with angular movement of inclination regulation.

6. Rear supports.

7. Lifting pillars on the floor or deck provided with various heights available.

8. Angle of inclination in three positions of the photovoltaic system.

9. End side photovoltaic panels adjacent to two side panels. 10. Fixed angle between end side panels relative to intermediate side panels.

EXAMPLE OF PREFERRED EMBODIMENT

As a preferred embodiment of the "Photovoltaic system in envelope configuration and inclination adapted to the season of the year" in view of the commented Figures 1-2, it can be seen, how the respective configurations can be carried out using a central photovoltaic panel (1) in combination with two side photovoltaic panels adjacent to the previous one (2) as shown in Figure 1, even giving continuity to both end side photovoltaic panels (9) adjacent to both side panels (2) in the case of the five-panel configuration described in Figure 2.

For the assembly of each photovoltaic module in its corresponding panel or plane, use is made of conventional fixing systems to which is added a mooring and fixing profiles (3) around its frame which, in turn, also determines the relative position between two contiguous planes joined by a common side, according to a fixed angle (4) between each side panel (2) with respect to the central panel (1) as seen in Figure 1. Likewise, in the case of Figure 2, the mooring and fixing profiles (3) also incorporates a second fixed angle (10) between end side panels (9), with respect to the intermediate side panels (2).

Continuing with the description of the elements that characterize both exemplary embodiments, both are carried out on four seats on the deck or floor, according to two front anchoring supports to the floor or deck provided with angular movement for tilt adjustment (5), plus two other rear supports (6) to be fixed on the lifting pillars on the floor or roof provided with various available heights (7), in order to be able to carry out the selection of the angle of inclination (8) of the photovoltaic system between the three Available positions.

Specifically, as can be seen in the detail of Figure 3, the fixing system to the lateral profiles in discrete positions has been carried out by including, in two subsequent vertical pillars (7), three positions in which to carry out the coupling to the module using screws with a butterfly terminal for connection to the respective rear support (6). Consequently, by regulating the set of panels joined in solidarity, equalizing the height in their attachment to the rear vertical pillars (7) at both ends, the configuration of the photovoltaic system can be adapted according to three inclination angles (8) interspersed as a example between 25 °, 35 ° and 50 °, for each season of the year, optimizing power generation.

Obviously, the base of the pillars (7) also includes the corresponding anchor plates for their fixing to the corresponding ceiling or floor.

Regarding the distribution of surfaces and angle between panels, in a configuration with three panels as shown in Figure 1, the surface of the central panel would be 40%, while the angle between adjacent panels is 25 °. While in a five-panel configuration as in Figure 2, the surface of the central panel would be 40%, each panel of both ends it would have a surface area of 10%, with the rest to be distributed in two central side panels, while the angle between adjacent side panels would be 37 °, and of these with the central panel of 20 °.

To this end, in both configurations Figure 1-2, a smaller surface area has been designed in the end panels with respect to the central one, based on the fact that the solar irradiation is less both during the first hours of the day and the last, although without It renounces direct capture throughout the day, while during peak hours, usually in the interval between 10 a.m. and 4 p.m., it is where the photovoltaic system as a whole has been designed to provide a capacity of older generation.

Thus, in the path that the sun describes on its path from sunrise to sunset, it is estimated that it moves one degree for every four minutes, so that as the sun makes its path from East to West In Spain, the maximum direct solar collection is happening from one panel to the next, starting at one end until it ends at the panel at the opposite end in the vicinity of sunset.

From the "Photovoltaic system in envelope configuration and inclination adapted to the season of the year" described in two examples of realization, as the sun moves throughout the day from sunrise to sunset, changing its angle of view. azimuth, the incidence of its rays on the system will always maintain direct solar capture, passing from one panel to the adjoining panel, from the first to the last regarding its best arrangement with respect to the reception of the sun's rays.

It is not considered necessary to make this description more extensive for any expert in the field to understand the scope of the invention and the advantages derived from it in its different applications, the technology that implements it, its reproduction from a basic system , dimensions, designs, positioning and anchoring systems for adjusting the inclination, will be susceptible to variation as long as this does not imply an alteration in the essentiality of the invention. The terms in which the specification has been described are to be understood in a broad and non-limiting sense.

Claims (3)

1. Photovoltaic system in an envelope and inclination configuration adapted to the season of the year characterized by its configuration formed by several panels around a central panel to which they are joined jointly by its two longitudinal parallel sides, according to a symmetrical arrangement with respect to a plane perpendicular to the referred central panel by the longitudinal segment that divides it into two halves, as well as by its fixing structure to the floor or roof according to its two fixed front supports provided free angular movement, in combination with two rear supports to be fixed at the same height between the heights available in the corresponding lifting pillars on the floor or roof. 2. Photovoltaic system in an envelope and inclination configuration adapted to the season of the year based on claim 1, characterized by its configuration in three planes according to a central panel, plus two side panels, where the surface of the central panel would be 40%, while that the angle between adjacent panels would be between 20 ° and 30 °. 3. Photovoltaic system in an envelope and inclination configuration adapted to the season of the year based on claim 1, characterized by its configuration in five planes, where the surface of the central panel would be 40%, each panel of both ends would have an area of 10 %, with the remainder to be distributed in two central side panels, while the angle between adjacent side panels would be between 30 ° and 45 °, and of these with the central panel between 15 ° and 25 °.