ES2715508B2 - Adjustable head and monitoring system for photovoltaic panels - Google Patents

Description

DESCRIPTION

Adjustable head and monitoring system for photovoltaic panels

Object of the invention

The present invention relates to the field of mechanics, and more particularly, to support structures for photovoltaic panels.

Background of the Invention

To optimize the energy generated by a photovoltaic system, it is essential to have tracking systems (also known by their English name, "trackers"), capable of reorienting the panels that make up the system. In addition to the difficulty of supporting long horizontal or inclined axes, which in some cases exceed 90 meters, there is the additional problem of installation on uneven terrain and / or slopes. Consequently, adjustable heads are needed capable of compensating for the lack of flatness of the terrain, both in position and at an angle.

However, the heads known in the state of the art have serious limitations in terms of their regulating capacity. There are heads in which a turning tube (also called by its name in English “torque tube”) is hooked or physically attached to the head by means of a screwed, riveted or similar union, so that the deviations in the position of the jacks directly affect the position and correct behavior of the head, thus greatly limiting regulation, the ability to absorb irregularities in the ground, and mounting tolerances.

Additionally, in the photovoltaic sector, solar trackers have a normal useful life of 25 years, frequently subject to contractual guarantee. Therefore, it is desirable to have components capable of guaranteeing their durability throughout this period with minimal maintenance. This problem is especially challenging considering both the rotational resistance of the rotator tube and the deterioration and corrosion typically associated with systems installed outdoors.

In this sense, most of the heads known in the state of the art are based on plastic ball joints, with the drawback that plastic manufacturers do not allow guarantee their durability in the desired 25-year periods, mainly due to the effects of ultraviolet exposure. In addition, the friction between the rotating parts of the heads is caused by sliding, which implies an increase or oversizing of the rotation tube drive system. Finally, these heads are sensitive to the entry of external particles in them, generating marked wear on the kneecap.

Therefore, there is a need in the state of the art for tracking systems for solar panels based on heads with the ability to regulate height, angle and position, including both the north-south direction (longitudinal direction of the turning tube) and the east-west direction (direction perpendicular to the turning tube). Furthermore, it is desirable that the adjustable heads are strong, compact and easy to install.

Description of the Invention

The present invention solves the problems previously described by means of a head that is adjustable in height, angle and position thanks to a set of open parts joined through adjustable holes in multiple axes.

Consider the set consisting of one or more photovoltaic panels, a turning tube or "torque tube" (understood as a tube-shaped element of the tracking system that supports said photovoltaic panels), and a jack (understood as a bar, pillar or any other vertical support element on which the adjustable head is installed.) Depending on these elements, and in order to facilitate the understanding of the morphology and operation of the adjustable head, we will use in this document the following definitions of axes :

- A first axis, which we will call the x axis, parallel to the main axis of the turning tube. - A second axis, which we will call the y axis, mostly perpendicular to the axis of the turning tube. Note that the exact orientation of the y axis can vary between embodiments, always maintaining the perpendicular relationship with the x axis. However, the y axis preferably forms a horizontal plane with the x axis, that is to say mostly parallel to flat terrain.

- A third axis, which we will call the z axis, mostly vertical and parallel to the drive.

Note that the present invention is valid for both horizontal axis and inclined axis photovoltaic systems. Therefore, while in some particular embodiments, the x-axis, y-axis, and z-axis will be orthogonal to each other, they may exist. embodiments that do not meet said orthogonality, establishing different angles of 90 ° between the z axis and the x and y axes.

Also, we will consider the XY plane as a plane containing the x-axis and the y-axis, the XZ plane as a plane containing the x-axis and the z-axis, and the YZ plane as a plane comprising the y-axis and the z-axis.

In a first aspect of the invention, an adjustable head is presented that is installed on a drive (parallel to the z axis) and supports at least one turning tube (parallel to the x axis). The head consists of the following parts:

- A base, with a U-shaped section inverted according to the YZ plane, adapted to be fixed to the jaw by means of first fixing means that go through the first collision holes. Said first slit holes are elongated openings with rounded edges, presenting their greatest length in a direction parallel to the z axis. This allows both adjusting the height of the base (and therefore the head assembly), as well as establishing adjustable angles between the base and the drive.

- A lower support, with a U-shaped section according to the XZ plane, adapted to be fixed to the base by means of second fixing means that pass through second holes in the hole. Said second collision holes presenting their greatest length in a direction parallel to the y axis. This allows both adjusting a lateral displacement of the turning tube and establishing a rotation angle between the base and the lower support. According to preferred options, the holes can be made both on a face of the base and on a face of the lower support, the opposite element comprising conventional circular holes that do not allow the second fixing means to move. - Preferably, an upper support with a U-shaped section according to the YZ plane, adapted to be fixed to the lower support through third fixing means that pass through third holes. Said third colise holes presenting their greatest length in a direction parallel to the z axis. This allows the size of an opening formed by the assembly of the upper support and the lower support, into which the turning tube is inserted. According to preferred options, the holes can be made both on a face of the lower support and on a face of the upper support, the opposite element comprising conventional circular holes that do not allow the second fixing means to move. Preferably, the upper support is formed by two flat pieces facing each other, although, in other embodiments of the invention, said pieces may be joined by bridges or other connections.

- A few first rollers, parallel to the x-axis and connected to the lower support, which support the turning tube. Preferably, the head also comprises at least a second roller, also parallel to the x axis, and connected to the upper support. Note, however, that the exact number and position of the rollers may vary depending on the particular embodiment.

Regarding the materials that make up the adjustable head, the base, the lower support and the upper support are preferably made of a metallic material, increasing the useful life of the head and its resistance to corrosion. More preferably, said metallic material is chosen from stainless steels; a steel made up of zinc, magnesium and aluminum (commonly known as "ZM steel"), hot-dip galvanized steel and aluminum. On the other hand, the first rollers (and the second at least one roller, if any), are also preferably Manufactured in stainless steels, ZM steel, hot-dip galvanized steel or aluminum, and may be the same material or different from that used for the base and upper and lower supports.In particular, ZM steel has the advantage of being served with a coating, without a post-manufacturing process such as hot-dip galvanizing, which increases production times, and the ZM steel coating acts as protection against drills and cuts.

Note that the possibility of using metallic materials is not an independent feature of the proposed geometry, but is precisely the configuration and morphology of the adjustable head, which allows the use of metallic materials, thus improving its life time and resistance to degradation. for environmental reasons. For example, in the usual solution of the state of the art, a ball joint consisting of two hemispherical pieces, one of which embraces the tube and rotates inside the other, it would be impossible to use metallic materials. This is because to achieve low friction, we would need machining of the patella, increasing its complexity and its difficulty and manufacturing cost. In addition, to avoid oxidation of the metal parts, additional coatings would have to be used, which would be lost during use, because the ball joint works by sliding. On the contrary, the present invention works by rolling, so there is no wear of the coating.

Finally, the first fixing means, the second fixing means and the third fixing means (if any) are preferably selected from screws, pins, rivets and bushings. In the same way, the first rollers (and the second at least one roller, if any), are preferably connected by fourth fixing means also selected from screws, pins, rivets and bushings.

In a second aspect of the invention, a tracking system for photovoltaic panels is presented, comprising at least one adjustable head according to any preferred embodiment and / or option of the first aspect of the invention. Likewise, the system comprises at least one axis or torque tube, which is housed by said adjustable head, and at least one jaw that supports the head. The head and regulation system described provide height, angle and position regulation; being also resistant, compact and easy to install. These and other advantages of the invention will become apparent in light of the detailed description thereof.

Description of the figures

In order to help a better understanding of the characteristics of the invention in accordance with a preferred example of practical embodiment thereof, and to complement this description, the following figures, which are illustrative and non-limiting:

Figure 1 illustrates a possible application scenario for the adjustable head and monitoring system for photovoltaic panels, according to both preferred embodiments.

Figure 2 presents the main parts of a preferred embodiment of the adjustable head of the invention, as well as a jack to which said head is attached.

Figure 3 shows a more detailed extruded view of the base and the lower support of the head, according to a preferred embodiment of the invention.

Figure 4 shows an extruded view in greater detail of the upper support of the head, according to a preferred embodiment of the invention.

Figure 5 illustrates a first height-adjustable movement of the head (Z axis displacement), according to a preferred embodiment thereof.

Figure 6 presents a second angle-adjustable movement of the head (rotation with respect to Y axis), according to a preferred embodiment thereof.

Figure 7 illustrates a third horizontally adjustable movement (Y axis displacement), transverse to the turning tube, according to a preferred embodiment of the head.

Figure 8 presents a fourth movement adjustable in height for adjustment to the turning tube, according to a preferred embodiment of the head.

Figure 9 presents a fifth adjustable movement of rotation of the head (rotation with respect to the Z axis), according to a preferred embodiment of the head.

PREFERRED EMBODIMENT OF THE INVENTION

In this text, the term "includes" and its derivations (such as "understanding", etc.) should not be understood in an exclusive sense, that is, these terms should not be interpreted as excluding the possibility that what is described and defined can include more elements, stages, etc.

In the context of the present invention, the terms "approximately" and their derivatives should be understood as indicators of values close to those that accompany the term. That is, a deviation is contemplated within reasonable limits regarding the exact value, since the person skilled in the art will understand that said variations may occur due to manufacturing or measurement limitations, or due to design decisions that do not affect the functionality of the elements. . The same reasoning applies to the term "mostly" and its derivatives.

Figure 1 presents a possible application scenario for the adjustable head (100) of the invention, formed by a plurality of photovoltaic panels (200) controlled by an axis or torque tube (300). The torque tube (300) is connected to the photovoltaic panels (200) through a plurality of rail-torque clamps (400), and to a first drive (600) by means of a rotation unit (500). Along the turning tube (300) the heads (100) are located, which are crossed by said turning tube (300), and which rest on second jacks (600). In this way, when the rotation unit (500) induces a rotation on the rotation tube (300), said rotation tube (300) can rotate inside the head (100) with a minimum friction, and maintaining a firm support, resistant and adaptable to the topology of the terrain.

Figure 2 shows the elements that make up the head (100), according to a preferred embodiment of the invention. The head (100) comprises an inverted U-shaped base (110), that is, it consists of three flat, mostly rectangular faces, joined together by two rounded corners, so that the three flat faces form 90 ° angles to each other . For simplicity, we will call the two sides parallel to each other of the base (110) as lateral faces, and the remaining face as the upper face. The lateral faces comprise first collision holes (141), adapted to face holes in the jaw (600). The relative position between the first holes in the collision (141) and the holes in the jaw is vertically adjustable, being fixed by the first fixing means (140). Said first fixing means (140), like the other fixing means of this embodiment, can be, for example, sets of nuts and bolts.

The head (100) also comprises a lower support (120) and an upper support (130), which when joined form a mostly cylindrical cavity whose axial direction is parallel to the x axis, and in which the turning tube (300) is inserted. ). The bottom bracket 120 has a U-shaped section in the XZ plane. That is, the lower support (120) is formed by three faces that form two 90 ° angles to each other. For simplicity, we will call the two parallel faces of the lower support (120) to each other as lateral faces, and the remaining face as the lower face. The two lateral faces comprise two grooves that make up the lower limit of the cylindrical cavity. For its part, the lower face comprises a second hole collision (151), which, when crossed by second fixing means (150), faces the lower face of the lower support (120) with the upper face of the base (110). .

The upper support (130) is made up of two equal flat pieces, in an inverted U shape. The interior of said inverted U delimits the upper end of the cylindrical cavity. Each piece also includes two third collision holes (171) that, when crossed by third fixing means (170), fix the size of said cylindrical cavity in an adjustable manner. Finally, the head comprises three cylindrical rollers (180), the position of which is fixed by respective fourth fixing means (160): two first rollers (180) whose bases are opposite the parallel faces of the lower support (120), and a third roller whose bases are in front of the pieces of the upper support (130).

Figure 3 presents a first extruded view of the same embodiment of the head (100), in which the interconnections between the base (110) and the lower support (120) can be seen more clearly. In particular, four first circular holes (161) can be seen in the lower support (120), in which the fourth fixing means (160) are inserted. passing through and supporting the first rollers (180). Likewise, a second circular hole (152) can be seen that faces the second hole (151), both being crossed by the second fixing means (150).

Figure 4 presents a second extruded view of the same embodiment of the head (100), in which the elements that make up the upper support (130) can be seen more clearly. In particular, the third circular holes (131) can be seen, one in each piece of said upper support (130), which are crossed by the fourth fixing means (160) that in turn support the third roller (180).

Figures 5 to 9 illustrate some of the adjustable movements allowed by the morphology of the head. In particular, Figure 5 illustrates a first height adjustment movement, achieved by displacing the first fixing means (140) along the first slit holes (141). A relative displacement of the base (110) and the drive (600) is thus achieved along the z axis.

Figure 6 shows a second angle adjustment movement, achieved by rotating the base (110) with respect to the jaw (600) within the XZ plane, keeping the position of the first fixing means (140) constant within the first slit holes (141).

Figure 7 illustrates a third adjustment movement in the axis and, in other words, transverse to the turning tube (300), achieved by moving the second fixing means (150) along the second slit holes (151) .

Figure 8 presents a fourth adjustment movement, which allows the size of the opening formed by the lower support (120) and the upper support (130) to be adapted as a function of the size of the turning tube (300). To do this, the third fixing means (170) are moved along the third slit holes (171).

Figure 9 presents a fifth adjustment movement, which allows the lower support (120) to be rotated with respect to the base (110) in the XY plane, keeping the position of the second fixing means (150) constant within the second slit holes. (151).

In view of this description and figures, the person skilled in the art will understand that the invention has been described according to some preferred embodiments thereof, but that multiple variations can be introduced in said preferred embodiments, without departing from the object of the invention as claimed.

Claims (14)

1. Adjustable head (100) for a turning tube (300) of photovoltaic panels (200), configured to be fixed on a jack (600), considering a first axis (x) parallel to the turning tube (300), a second axis (y) perpendicular to the turning tube (300) and a third axis (z) parallel to the jaw (600), characterized in that the head (100) comprises: - a base (110) with a section in the form of Inverted U according to a plane formed by the second axis (y) and the third axis (z), and with first collision holes (141) parallel to the third axis (z); - a first fixing means (140) configured to fix the base (110) to the jaw (600) through the first slots (141); - a lower support (120) with a mostly U-shaped section along a plane formed by the first axis (x) and the third axis (z), and with first rollers (180) parallel to the first axis (x), the first rollers (180) being adapted to support the turning tube (300); and - second fixing means (150) configured to fix the base (110) to the lower support (120) through at least one second hole (151) parallel to the second axis (y). 2. Head (100) according to claim 1, characterized in that the at least one second hole (151) is located on a face of the lower support (120) parallel to a plane formed by the first axis (x) and the second axis (y). 3. Head (100) according to claim 1 characterized in that the at least one second hole collision (151) is on a face of the base parallel to a plane formed by the first axis (x) and the second axis ( and). Head according to any one of the preceding claims, characterized in that it further comprises: - an upper support (130) with a mostly U-shaped section inverted according to the plane formed by the second axis (y) and the third axis (z); and - third fixing means (170) configured to fix the upper support (130) to the lower support (120) through third collision holes (171) parallel to the third axis (z). 5. Head (100) according to claim 4, characterized in that the third slit holes (171) are on faces of the lower support (120) parallel to the plane formed by the second axis (y) and the third axis (z) . 6. Head (100) according to claim 4 characterized in that the third slit holes (171) are on faces of the upper support (130) parallel to the plane formed by the second axis (y) and the third axis (z) . Head (100) according to any of claims 4 to 6 characterized in that the upper support (130) comprises two flat pieces facing each other, the two flat pieces being parallel to the plane formed by the second axis (y) and the third axis (z). Head (100) according to any of claims 4 to 7 characterized in that the upper support (130) comprises second rollers (180) parallel to the first axis (x), the second rollers (180) being adapted to rest on the turning tube (300). Head (100) according to any of the preceding claims, characterized in that the base (110) and the lower support (120) are made of a metallic material. Head (100) according to claim 9 characterized in that the metallic material is selected from stainless steels, hot-dip galvanized steel and aluminum. Head (100) according to any of the previous claims, characterized in that the first rollers (180) are made of a material selected from stainless steels, hot-dip galvanized steel and aluminum. Head (100) according to any of the preceding claims, characterized in that the first fixing means (140) and the second fixing means (150) are selected from screws, pins, rivets and bushings. Head (100) according to any of the previous claims characterized in that the first rollers (180) are joined to the first rollers (180) by means of fourth fixing means (160) selected from screws, pins, rivets and caps. 14.

Tracking system for photovoltaic panels (200) comprising at least one vertical drive (600) and at least one cylindrical turning tube (300), characterized in that it further comprises an adjustable head (100) according to any of claims 1 to 13, said head (100) being adapted to house the at least one turning tube (300), and the jaw comprising openings adapted to house the first fixing means (140) of the head (100).