ES2570998B1 - Single axis solar tracker - Google Patents

Abstract

One-axis solar tracker, comprising one or several rows (1) of photovoltaic modules (2), a support structure (3) on which the photovoltaic modules (2) are arranged which is constituted by a longitudinal axis (4) and transverse profiles (5), a drive unit that causes the rotation of the longitudinal axis (4) and ground support posts (6) that are attached to the longitudinal axis (4), where the photovoltaic modules (2) of each row (1) incorporates on its major sides (2.1), parallel to the longitudinal axis (4), reflective surfaces (11) of the solar radiation that are inclined at an angle to the photovoltaic modules (2), said surfaces going reflectors (11) attached to supports (12) that are arranged on the end parts (5.1) of the transverse profiles (5) that protrude with respect to the photovoltaic modules (2).

Description

SOLAR FOLLOWER OF A SHAFT

Technical sector

The present invention is related to the solar trackers of an axis comprising several rows of foliovaltaieos modules operatively connected to each other, proposing such a solar tracker with an optimized structural configuration provided with reflective surfaces by way of mirrors or the like that allow increasing the

10 solar tracker performance per unit of installed surface.

State of the art

Solar energy is a type of renewable energy that is based on the use of

15 electromagnetic radiation from the sun for conversion into calorific energy, or electrical energy. For the recovery of heat generated by solar radiation, collectors, or thermal collectors are used, which are composed of a set of parabolic mirrors that concentrate all the solar radiation received on a collector through which a fluid to be heated is circulated. On the other hand, for the conversion of solar radiation into

20 electric energy solar trackers are used, which are formed by a set of photovoltaic modules responsible for receiving solar radiation and converting it into electricity.

In the current market there are different types of solar trackers, among which

25 find the double-axis solar trackers and the single-axis solar trackers. In the double-axis trackers, the rotation and inclination of the photovoltaic modules is controlled to continuously monitor the sun, so that the solar radiation affects at all times perpendicular to the photovoltaic modules, thus obtaining maximum radiation uptake solar.

30 On the other hand, in the solar trackers of a single axis, it is sought to obtain a good capture of solar radiation with a simpler assembly, thus reducing manufacturing, installation and maintenance costs. Within the solar followers of an axis, the followers of a horizontal axis are distinguished, where the photovoltaic modules rotate

35 on an axis of horizontal arrangement with respect to the ground that is aligned in north-south direction, and the followers of a polar axis, where the photovoltaic modules

they rotate on an axis that is inclined at a certain angle to the ground and that faces south.

The solar trackers of a polar axis, and the solar trackers of a horizontal axis, such as that described in Patent ES2368402 of the same applicant as the present invention, are composed of a set of rows of photovoltaic modules, wherein the folavoltaic modules of each row are supported on a rotating support structure formed by a longitudinal axis and transverse crossbars to said longitudinal axis. The rows of photovoltaic modules are linked together by means of transmission bars, so that by means of an actuator, all rows of photovoltaic modules are rotated.

One of the biggest problems associated with the performance of the solar trackers of an axis are the shadow zones that are created between rows of consecutive photovoltaic modules of the solar tracker, since a row, depending on its inclination and the position in which the sun is found, it can shade the row that is immediately available, thus decreasing its performance. To avoid this problem, it is known to use control techniques that are based on modifying the inclination of the rows of photovoltaic modules depending on the position of the sun, so that when a row shades the immediately subsequent row, it decreases the inclination of the first row so that the solar radiation reaches the second row that is in shadow. Although this solution allows to increase the performance of the row that is in shadow, it slightly decreases the performance of the first row, since solar radiation does not optimally affect it.

The most common practice to avoid this problem is based on increasing the separation distance between the rows of photovoltaic modules, so that the solar radiation is guaranteed to reach all the photovoltaic modules in an optimal way, thus avoiding shadows between the rows of the solar tracker, at least in the hours of the day in which the solar radiation affects with greater force. Although this solution allows all photovoltaic modules to work optimally, the total performance of the tracker in relation to the surface area occupied decreases, since all the solar radiation that falls between the rows of photovoltaic modules is wasted.

It is therefore necessary a solar tracker of an axis that is an alternative solution to those already existing and that allows to improve the performance of the solar tracker with respect to the total land area that is occupied by it.

Object of the invention

In accordance with the present invention, a single-axis solar tracker is proposed in which the support structure of the photovoltaic modules formed by a longitudinal axis and transverse profiles has been conveniently adapted to support reflective surfaces, as mirrors or the like. , which allow to increase the performance of the solar tracker per unit of installed surface. The invention is applicable to both

10 solar followers of a horizontal axis, like the solar followers of a polar axis.

The solar tracker of an axis object of the present invention comprises:

-

one or several rows of photovoltaic modules,

15 -a support structure on which the photovoltaic modules of a row are arranged, where the support structure is constituted by a longitudinal axis and transverse profiles to said longitudinal axis,

20 -a drive unit that causes the rotation of the longitudinal axis of a row of photovoltaic modules, using a transmission bar and a connecting rod to transmit the movement of the drive unit unit to the longitudinal axis, and

-

poles that in their upper part are connected by means of bearings to the longitudinal axis 25 of a row of photovoltaic modules, and in their lower part they are anchored, directly or indirectly, to the ground where the solar tracker is arranged.

The photovoltaic modules of each row incorporate on their major sides, parallel to the longitudinal axis, reflective surfaces of the solar radiation that are inclined

30 a certain angle with respect to the photovoltaic modules, said reflective surfaces being attached to supports that are arranged on the end portions of the transverse profiles that protrude with respect to the photovoltaic modules.

In this way, solar radiation that does not directly affect the modules

35 photovoltaic, and that in the conventional solar trackers strikes between the rows of photovoltaic modules, in the case of the present invention it is collected by the reflective surfaces and is reflected towards the folavoltaic modules, so that the total performance of the solar tracker is increased in relation to the total area occupied by it. Also, by using the cross-sectional profile of the support structure to withstand the reflective surfaces, a low-cost structural solution is achieved in

5 even easy to implement in the solar trackers of an axis already installed.

It is envisioned that the supports of the reflective surfaces are fixed brackets in the form of squares that are directly connected on the end portions of the cross sections. However, it is possible that the surface supports

10 reflective be mobile supports adapted to vary the angle of inclination of the reflective surfaces with respect to the photovoltaic modules.

In any case, the angle with which the reflective surfaces must be inclined with respect to the photovoltaic modules to guarantee optimum reflection of the radiation

15 solar is approximately 609. It is envisaged that the reflective surfaces are mirrors with a flat geometry, although any suitable material could be used for the reflection of solar radiation or other types of geometries that guarantee directing the solar radiation towards the modules photovoltaic

20 A solar tracker is thus obtained which, due to its constructive and functional characteristics, is of preferential application for the function to which it is intended in relation to the use of the incident solar radiation between the rows of photovoltaic modules.

Description of the figures

Figure 1 shows a perspective view of a solar tracker of an axis according to an embodiment of the invention.

Figure 2 shows a side view of the solar tracker shown in the previous figure.

30 Figure 3 shows a partial perspective view of the photovoltaic modules and the reflective surfaces of a row of photovoltaic modules of the solar tracker.

Figure 4 shows a side view of a row of photovoltaic modules.

Figure 5 shows a partial perspective view of the rear of a row of

solar tracker folavoltaic modules, where the support structure on which the photovalt modules and reflective surfaces are arranged is observed.

Figures 6 and 7 show an exemplary embodiment of the solar tracker with the reflective surfaces located on mobile supports.

Detailed description of the invention

By way of exemplary non-limiting embodiment of the invention, a solar tracker of a horizontal axis is shown in the figures comprising a set of rows (1) of photovoltaic modules (2) that are arranged on a ground aligned substantially in a way parallel to each other. The photovoltaic modules (2) of each row (1), responsible for transforming the solar radiation that affects them into electrical energy, are arranged coplanar and adjacent to each other.

The photovoltaic modules (2) of each row (1) are arranged on a support structure

(3)

formed by a longitudinal axis (4), which extends along the entire row (t) of photovoltaic modules (2), and transverse profiles (5) to said longitudinal axis (4). Each row (1) can be formed by one or several groups of photovoltaic modules (2), and the longitudinal axis (4) can be a continuous axis that extends along all the groups of photovoltaic modules (2), or It can be an axis formed by sections properly connected to each other, using an axis section for each group of photovoltaic modules (2). Figure 1 shows a solar tracker with a horizontal axis formed by four rows (1) of photovoltaic modules (2), with two groups of photovoltaic modules (2) for each row (1).

The support structure (3) of the photovoltaic modules (2) is anchored to the ground by means of posts (6) that are connected to the longitudinal axis (4) by means of bearings (7) that allow the longitudinal axis (4) ) rotate freely with respect to the posts

(6)

(see figure 5), but which prevent the longitudinal axis (4) from moving axially or radially. The posts (6) can be directly anchored to the ground, or they can be mounted on a foundation that rests on the ground.

The solar tracker incorporates a drive unit (8) by means of which the rotation of the longitudinal axes (4) is caused, and therefore of the support structures (3) on which the photovoltaic modules (2) are supported for the sun tracking. The drive unit (8) is formed by a linear actuator that transmits its linear drive movement to at least one transmission bar (9) to which a connecting rod (10) connecting the longitudinal axes (4) is connected. to the transmission bar (9), so that the linear drive movement of the transmission bar (9) causes all rows (1) of photovoltaic modules (2) to rotate together. As can be seen in figure 2, the drive unit (8) can be located between rows (1) of photovoltaic modules (2), so that on its front the drive unit (8) is coupled to a first bar of transmission bar (9) that causes the rotation of the rows (1) of photovoltaic modules (2) located in front of the drive unit (8), and from the rear the drive unit (8) is coupled to a second transmission bar (9) that causes the rotation of the rows (1) of photovoltaic modules (2) located behind the drive unit (8).

The photovoltaic modules (2) of each row (1) incorporate on their major sides (2.1), parallel to the longitudinal axis (4), reflective surfaces (11), which reflect the solar radiation towards the photovoltaic modules (2) it falls between the rows (1) of photovoltaic modules (2). Thus, it is guaranteed that the solar radiation that was wasted between the rows (1) is directed towards the photovoltaic modules (2), thereby increasing the performance of the solar tracker with respect to the total surface area occupied. It is envisioned that the reflective surfaces (11) are mirrors, although it could be any type of material that guarantees adequate reflection of solar radiation.

The reflective surfaces (11) are arranged on supports (12) that are directly coupled above the transverse profiles (5) of the support structure (3), more specifically the supports (12) are arranged on the end parts ( 5. 1) of the transverse profiles (5) that protrude with respect to the photovoltaic modules (2). In this way, a simple mounting solution is obtained to support the reflective surfaces (11), which only requires oversizing the transverse profiles (5) of the support structure (3) of a solar tracker of a conventional axis.

As can be seen in detail in Figure 4, the supports (12) on which the reflective surfaces (11) rest are fixed brackets in the form of a square that are jointly joined to the transverse profiles (5), forming between the reflective surface (11) and the transverse profile (5) an angle (13) with an inclination of approximately 602, so that a correct collection of solar radiation that does not directly affect the photovoltaic modules (2) is guaranteed.

However, since the incidence of solar radiation is variable depending on the time of day and depending on the season of the year, it is expected that the supports (t2) of the reflective surfaces (11) are mobile supports, so that the inclination of the angle ([3) of said supports (12) can be adapted in relation to the transverse profiles

(5)

to increase the performance of photovoltaic modules (2). An exemplary non-limiting embodiment of a movable support (12) that allows varying the inclination of the angle (13) is shown in Figures 6 and 7. The support (12) can be made by means of a slide with one, or several, interlocking positions to place the reflective surface (11) with the required inclination, by means of a hydraulic, or pneumatically operated cylinder,

or by any other similar mechanism that allows the support to swing (12). Likewise, if mobile supports (12) are used, their operation could be carried out manually or automatically, and one drive can be incorporated for each support (t2), or a common drive for all supports (t2).

On the other hand, it is envisioned that the geometry of the reflective surfaces (11) is a flat geometry, although they could be other types of geometries, such as parabolic, spherical, concave or similar geometries.

The description and figures have been used in the case of a solar tracker with a horizontal axis, although the invention would be equally applicable for a solar tracker with a polar axis, where instead of using a longitudinal axis (4) aligned in the direction nortesur and arranged horizontally with respect to the ground where the solar tracker is installed, a longitudinal axis facing south is used and inclined a certain angle in relation to the ground.

Claims (6)

1.-Single axis solar tracker, comprising:

-

one or more rows (1) of photovoltaic modules (2),

-

a support structure (3) on which the photovoltaic modules (2) of a row (1) are arranged, where the support structure (3) consists of a longitudinal axis (4) and transverse profiles (5) to said longitudinal axis (4),

-

a drive unit (8) that causes the rotation of the longitudinal axis (4) of a row (1) of photovoltaic modules (2), using a transmission bar (9) and a connecting rod (10) to transmit the movement of the drive unit unit (8) to the longitudinal axis (4), and

-

posts (6) that in their upper part are connected by means of bearings (7) to the longiludinal axis (4) of a row (1) of lotovoltaic modules (2), and in their lower part they are anchored, directly or indirectly, to the ground where the solar tracker is arranged,

characterized in that the photovoltaic modules (2) of each row (1) incorporate, on their major sides (2.1), paragliders to the longiludinal axis (4), some filled-in superticies (11) of the solar radiation that are arranged at an angle (¡3 ) with respect to the photovoltaic modules (2), said reflective surfaces (11) being attached to supports (12) that are arranged on end portions (5.1) of the transverse profiles (5) that protrude with respect to the photovoltaic modules (2) ). 2.-Solar tracker of an axis, according to the first claim, characterized in that the supports (12) of the reflective surfaces (11) are fixed supports in the form of squares that are directly connected on the end parts (5.1) of the profiles transversal (5). 3. Solar tracker of one axis, according to the first claim, characterized in that the supports (12) of the reflective superticies (11) are mobile supports adapted to vary the angle (¡3) of inclination of the reflective surfaces (11) regarding photovoltaic modules (2). 4.-Solar tracker of an axis, according to the first claim characterized in that the angle (~) is approximately 60 '. 5.-Solar tracker of an axis, according to the first claim, characterized by reflective surfaces (11) are mirrors. 6. Solar tracker of an axis, according to the first claim, characterized by the reflective surfaces (11) have a flat geometry.