FR3113114A1 - Photovoltaic system - Google Patents

Abstract

The invention relates to a photovoltaic system (1) comprising a fixed foot (2) configured to be fixed to the ground (3), a vertical arm (5) configured to extend longitudinally from the fixed foot (2) along a main axis (A-A) perpendicular to the ground (3), at least one solar panel (6, 6') fixedly fixed to the vertical arm (5) and extending radially with respect to the main axis (A-A), the system ( 1) further comprising a drive device (10) of the arm (5) for coupling the vertical arm (5) to the fixed foot (2), the drive device (10) being configured for driving the vertical arm (5) around its main axis (A-A). Figure for abstract: Fig. 1

Description

Photovoltaic system

The present invention relates to the photovoltaic field and more particularly to a photovoltaic system.

In order to optimize the electrical efficiency of solar panels, the latter are generally installed on supports equipped with a solar tracking device making it possible to modify their orientation according to the path of the sun so as to maximize the capture of light by the solar panel.

Indeed, the yield of a solar panel is maximum when the solar radiation has an incidence substantially perpendicular to the panel.

In order to be able to best maintain this orientation according to the course of the sun on the horizon throughout a day, the solar panels are installed on follower supports having one or more axes of articulation allowing the orientation of the panel. in one or more directions using one or more motors.

A distinction is made in particular between follower supports with one or two articulation axes.

The two-axis tracking supports allow tracking of the sun according to its azimuth and elevation.

In regions of the globe where the course of the sun varies little in height relative to the horizon according to the seasons, a follower support with one axis may be sufficient.

Single-axis tracking mounts allow tracking of the sun by rotation around a fixed axis.

According to a first known embodiment, the axis of rotation corresponds substantially to the median axis of the panel.

In a first variant, the axis of rotation is substantially horizontal. The panel can then track in elevation but is fixed in azimuth. The support then comprises two lateral end feet defining a substantially horizontal axis on which the solar panel is rotatably mounted using support forks.

In a second optimized variant, the axis of rotation is itself inclined.

This technique allows less good tracking in azimuth than a rotation around a vertical central foot, but better tracking in elevation over the course of a day.

Such a follower support generally comprises three feet forming a triangular base supporting a substantially pyramidal frame. A low foot located at the level of a summit of the triangular base forms, with the high summit of the pyramid, the axis of support and rotation of the solar panel. An example of such a support is described in document DE 20 2004 001 642 U1.

According to a second known embodiment, the axis of rotation is substantially vertical. Such a follower support generally comprises a central foot anchored in a concrete block, at the top of which is installed the mobile solar panel in rotation around the axis of the central foot. A controlled motor provides rotational drive.

This rotation around the central foot allows tracking in azimuth over approximately 270° in general.

It will be noted that the solar panel is installed in an inclined manner with respect to the ground corresponding to an elevation of the sun between 5 and 75 degrees. This tilt can usually be adjusted manually depending on the season and the corresponding average elevation of the sun over most of the day. However, the rotation taking place around a vertical axis, the inclination of the panel does not take into account the elevation of the sun at the beginning and end of the day.

Obviously, such single-axis trackers can also be used in regions of the globe where the variation in elevation of the sun according to the seasons is greater. For example, in French latitudes, the elevation of the sun at noon varies from 18° to 62° at the two solstices. The use of a follower support with an inclined axis will then allow an optimal inclination depending, in particular, on the mutual shading factor of the followers, the seasonality of the sunshine, the refraction of light in the thickness of the panels as well as the surface yield of the land occupied by the solar power plant, among other possible parameters.

Depending on the disparity of sunshine during the year, a plant with a tracker support with a judiciously inclined axis will be able to guarantee an annual yield very close to a plant with two-axis trackers.

A two-axis follower support will also include a vertical central leg constituting an axis of rotation of the panel, and a motorized support allowing the inclination to be varied at the top of the central leg. The panel will then also be able to track the sun according to its elevation.

However, these photovoltaic systems of the prior art have drawbacks.

These photovoltaic systems have low resistance to powerful winds, such as storms for example, due in particular to the large removable surface exposed to the air flow, resulting in the partial or total destruction of these systems and therefore consequent repairs.

In order to best avoid the destruction of these installations, only the construction of very heavy metal photovoltaic systems was considered.

In addition, these photovoltaic systems with one axis of the prior art are cumbersome to transport and require a non-negligible assembly time. Consequently, they are also difficult to re-implant to another location if necessary.

The present invention aims to remedy at least one of the aforementioned drawbacks by providing a photovoltaic system comprising:

-a fixed foot configured to be fixed to the ground,

-a vertical arm configured to extend longitudinally from the fixed foot along a main axis perpendicular to the ground, the arm being mobile in rotation around its main axis,

-at least one solar panel secured in a fixed manner to said vertical arm and extending radially with respect to the main axis,

the system further comprising an arm drive device for coupling the vertical arm to the fixed leg, the drive device being configured to drive the vertical arm about its major axis.

The arrangement of a vertical arm with respect to the ground, mobile in rotation around its main axis and at least one panel secured in a fixed manner to the vertical arm and extending radially with respect to the main axis makes it possible to guarantee a grip wind on a small profile of the photovoltaic system exposed to the air flow.

According to one embodiment, the photovoltaic system comprises at least one panel, called the first solar panel and a second solar panel, the second solar panel being fixedly fixed to said arm and extending radially with respect to the main axis, the first solar panel and the second solar panel being opposed to each other with respect to the main axis so that the radial dimension of the first solar panel is greater than the radial dimension of the second solar panel.

The radial dimension of the first panel being greater than the radial dimension of the second panel, this provides a "weather vane" function to the photovoltaic system as well as a "feathering" of the photovoltaic system, orienting the solar panels so as to offer the least resistance facing the wind.

When the wind takes hold of the solar panels, it is the solar panel with the largest radial dimension that will determine the orientation of the photovoltaic system.

This difference in radial dimension between the first panel and the second panel therefore makes it possible to orient the photovoltaic system more quickly and directly towards the direction of propagation of the air flow linked to the wind, as soon as strong winds appear.

According to one embodiment, the radial dimension of the first solar panel is different from the radial dimension of the second solar panel.

According to one embodiment, the radial dimension of the second solar panel is less than or equal to 70% of the radial dimension of the first solar panel.

According to another embodiment, the radial dimension of the second solar panel is less than or equal to 50% of the radial dimension of the first solar panel.

These values of 70% and 50% make it possible to obtain an effective "feathering" effect while maintaining a minimum surface area of the second solar panel to best capture sufficient solar energy.

According to one embodiment, the drive device comprises a ball table mounted on the fixed foot, the vertical arm being configured to cooperate with said ball table.

The ball table makes it possible to guarantee a minimum speed of rotation of the vertical arm despite the load of the vertical arm supporting at least one solar panel.

According to one embodiment, the drive device comprises a toothed wheel fixed to the vertical arm around its main axis.

According to one embodiment, the drive device comprises an electric motor comprising a servomotor slaved to the azimuthal stroke of the sun, the electric motor being connected to the fixed foot and configured to drive in rotation, by means of a cam, said toothed wheel along an axis of rotation coinciding with the main axis of the vertical arm.

According to one embodiment, a mechanical braking device for the rotation of the vertical arm is connected both to the vertical arm and to the fixed foot.

According to one embodiment, the mechanical braking device comprises a disc or a drum coupled to the toothed wheel of the drive device and at least one brake pad integral with the fixed foot.

According to one embodiment, an electronic braking device for the rotation of the vertical arm is coupled to the drive device.

According to one embodiment, a device for measuring the speed or the pressure of the wind is coupled to the servomotor, the measuring device being configured to send a signal to stop the electric motor to the servomotor, beyond a value threshold measured by said measuring device.

According to one embodiment, a timing device is coupled to the wind speed or pressure measuring device and to the servomotor, the timing device being configured to send an actuation signal of the electric motor to the servomotor, after the receipt of the electric motor stop signal by the servomotor, below the threshold value measured by said measuring device.

According to one embodiment, the at least one solar panel extends perpendicular to the main axis of the vertical arm.

This arrangement of the solar panel in relation to the axis of the vertical arm makes it possible to offer the smallest profile to the photovoltaic system exposed to the air flow.

According to one embodiment, the photovoltaic system comprises at least one row of solar panels, each solar panel being integral with the adjacent solar panel, said at least one row extending along the main axis of the vertical arm.

The at least one row of solar panels maximizes the capture of solar energy for a single photovoltaic system.

The invention will be described in more detail through the figures presented below, which will facilitate its understanding.

In the following description, it is necessary to understand by front face, the face of the photovoltaic system for which solar panels are configured to capture solar energy and by rear face the face of the photovoltaic system opposite to the front face, that is i.e. the side of the photovoltaic system that is not configured to capture solar energy.

illustrates a front view of the front face of the photovoltaic system, in accordance with the invention.

illustrates a front view of the rear face of the photovoltaic system, in accordance with the invention.

illustrates a side view of the driving device and the braking device of the vertical arm, in accordance with the invention.

illustrates a perspective view of the driving device and the braking device of the vertical arm, in accordance with the invention.

Figure 1 shows a front face of a photovoltaic system 1 according to the invention.

The photovoltaic system 1 comprises a fixed foot 2 fixed in the ground 3 inside a base 4, preferably made of reinforced concrete.

The fixed foot 2 is fixed vertically with respect to the ground 3.

A vertical arm 5 is configured to extend longitudinally from the fixed foot 2 along a main axis A-A perpendicular to the ground 3.

At least one solar panel, called the first solar panel 6, is fixedly attached to the vertical arm 5.

In this figure, it is the front face of the first panel 7 of the first solar panel 6 which is represented, that is to say the face of the first solar panel 6 capable of capturing solar energy.

In this figure, a row of first solar panels 6 is shown.

Each first solar panel 6 extends radially with respect to the main axis A-A of the vertical arm 5.

More precisely, each first solar panel 6 extends perpendicular to the main axis A-A of the vertical arm 5.

The front face of the first panel 7 of the first solar panel 6 is arranged and extends perpendicular to the ground 3.

Each first solar panel 6 is integral with the adjacent first solar panel 6 via fastening means 8 of the rivet or fishplate type, for example, the row of first solar panels 6 extending along the main axis A-A of the vertical arm 5 .

In this figure, a second 6' solar panel is shown.

Each second 6' solar panel is fixedly attached to the vertical arm 5.

It is the front face of the second 7' solar panel of the second 6' solar panel that is represented, i.e. the face of the second 6' solar panel capable of capturing solar energy.

We see in this figure, a row of second 6′ solar panels is represented.

Each second 6' solar panel extends radially with respect to the main axis A-A of the vertical arm 5.

More specifically, each second solar panel 6' extends perpendicular to the main axis A-A of the vertical arm 5.

The front face of the second panel 7' of the second solar panel 6' is arranged and extends perpendicular to the ground 3.

Each second solar panel 6' is secured to the adjacent second solar panel 6' by means of fastening means 8 of the rivet or fishplate type, for example, the row of second solar panels 6' extending along the main axis A-A of the vertical arm 5.

The first solar panel 6 and the second solar panel 6' are opposed to each other with respect to the main axis A-A of the vertical arm 5.

The radial dimension of the first solar panel 6 is greater than the radial dimension of the second solar panel 6'.

More precisely, the radial dimension of the second solar panel 6′ is equal to 50% of the radial dimension of the first solar panel 6.

It can be noted that the radial dimension of the second solar panel 6' is preferentially different from the radial dimension of the first solar panel 6 and therefore can be less than or greater than 50% of the radial dimension of the first solar panel 6.

Indeed, according to another embodiment of the invention, the radial dimension of the second solar panel 6′ is less than or equal to 70% of the radial dimension of the first solar panel 6.

The first solar panel 6 and the second solar panel 6' have the same dimensions while the first solar panel 6 extends perpendicularly with respect to the main axis A-A of the vertical arm 5 and the second solar panel 6' extends parallel relative to the main axis A-A of the vertical arm 5.

The vertical arm 5 is configured to be rotatable around its main axis A-A by a drive device 10.

This training device 10 comprises a ball table 11 mounted on the fixed foot 2, so that the vertical arm 5 cooperates with the ball table 11.

The drive device 10 also includes a toothed wheel 12 arranged around the main axis A-A of the vertical arm 5.

The ball table 11 is not limiting in the invention. Indeed, the ball table 11 can be replaced by a thrust bearing.

Finally, the drive device comprises an electric motor 14 connected on the one hand to the fixed foot 2 by a fixing support 15 and to the toothed wheel 12.

The drive device 10 is now detailed with reference to Figures 3 and 4.

Figure 3 shows a side view of the drive device 10 and a mechanical braking device 40 of the rotation of the vertical arm 5.

The training device 10 includes the ball table 11 mounted on the fixed foot 2.

More precisely, the ball table 11 is in the form of a ball crown.

The fixed foot 2 comprises first support elements 21 extending radially and perpendicularly with respect to the main axis A-A of the vertical arm 5. The ball table 11 rests on these first support elements 21.

The vertical arm 5 comprises second support elements 21' extending radially and perpendicularly with respect to the main axis A-A of the vertical arm 5. These second support elements 21' rest on the ball table 11.

The toothed wheel 12 is integral with the vertical arm 5 via fittings 22 welded to the vertical arm 5 and extending radially and perpendicularly with respect to the main axis A-A.

The electric motor 14 is connected to the fixed foot 2 by a mounting bracket 15.

The fixing support 15 comprises a support element 24 fixed to the fixed foot 2 and extending radially and perpendicularly with respect to the main axis A-A of the vertical arm 5.

The fixing support also comprises a base 25 extending along the main axis A-A of the vertical arm 5 from the support element 24. The electric motor 14 is mounted on the base 25.

A beam 26 additionally connects the support element 24 to the fixed foot 2 so as to form a bracket.

The electric motor 14 comprises a toothed cam 27 configured to be in contact with the toothed wheel 12.

The electric motor 14 is coupled to a servomotor 28.

The mechanical braking device 40 comprises a disk or drum 41 coupled to the toothed wheel 12.

The disc or drum 41 connects the toothed wheel 12 to the vertical arm 5 via fittings 22 welded to the vertical arm 5 and extending radially and perpendicularly with respect to the main axis A-A.

The mechanical braking device 40 also comprises at least one pressure brake pad 42 .

The at least one brake pad 42 is secured to the fixed foot 2 by means of a stem 43 fixed to the fixing support 15 and more precisely fixed to the support element 24.

The at least one brake pad 42 is fixed and suspended from the stem 43 via at least one calibration spring 44.

The at least one brake pad 42 is in contact both with the disc or drum 41 and with the toothed wheel 12.

In another embodiment of the invention, the mechanical braking device 40 can be replaced by an electronic braking device for the rotation of the vertical arm. The electronic braking device can in this case be coupled to the drive device 10.

Figure 4 is a perspective view of the drive device 10 and the mechanical braking device 40.

In this figure, the vertical arm 5 is in the extension of the fixed foot 2.

The ball table 11 rests on four first support elements 21 evenly distributed on either side of the fixed foot 2.

The second support elements 21' are also four in number, distributed evenly on either side of the vertical arm 5.

These four second support elements 21' rest on the ball table 11 and are fixed to the ball table 11 by a screw-nut type connection 45.

The fittings 22 connecting the drum or disc 41 to the vertical arm 5 are also four in number and are evenly distributed on either side of the vertical arm 5.

The fittings 22 are fixed to the vertical arm 5 by welding while the fittings 22 are fixed to the drum or disc 41 by a screw-nut type connection 45'.

The first support elements 21, the second support elements 21' and the fittings 22 could be at least three in number.

The vertical arm 5 further comprises two handles 46.

The toothed cam 27 is configured to cooperate with the toothed wheel 12 as illustrated in this figure.

The electric motor 14 is coupled to the servomotor 28.

The servomotor 28 can be coupled to a device for measuring the speed or the pressure of the wind 29, such as an anemometer and to a timing device.

This wind speed or pressure measuring device 29 is shown in Figures 1 and 2.

This measuring device 29 can be coupled to the booster by an electric cable or wirelessly.

Alternatively, the measuring device 29 can be integrated into the servomotor 28.

Two brake pads 42 are shown in this figure (only one is visible), the force of which is adjustable by two calibration springs 44.

Reference is now made to FIG. 2 illustrating a rear face of the photovoltaic system 1 according to the invention.

In this figure, it is the rear face of the first and second panels 30, 30' of the first and second solar panels 6, 6' which is represented, that is to say the face opposite to the face of the first and second solar panels 6, 6' capable of capturing solar energy.

The first and second solar panels 6, 6' are fixedly attached to the vertical arm 5 at their rear face of the first and second panels 30, 30'.

The rear face of the first and second panels 30, 30' comprises a frame 31 connecting all the first solar panels 6 together belonging to the row of first solar panels 6 and all the second solar panels 6' together belonging to the row of second 6' solar panels.

The first and second solar panels 6, 6' are fixedly attached to the vertical arm 5 via at least one fixing bracket 32 fixed both to the vertical arm 5 and to the frame 31 of the rear face. of first and second panels 30, 30'.

Informative and/or advertising panels 33 are integral with the frame 31.

These informative and/or advertising panels 33 may include lighting means.

In the following paragraphs, the operation of the present invention is explained.

In normal operation of the present invention, that is to say when the environmental conditions are optimal, in particular when the intensity of the wind is zero or weak, the electric motor 14 makes it possible to rotate the vertical arm 5 around of its main axis A-A, via the ball table 11 and the toothed wheel 12.

The electric motor 14 is controlled by the servomotor 28 for a speed of rotation of the vertical arm 5 around its main axis A-A as a function of the azimuthal path of the sun, for example via solar sensors or a tracking algorithm solar.

The first and second solar panels 6, 6' and more precisely the front face of the first and second solar panels 7, 7' is oriented in the direction of the sun and follows the sun according to its azimuthal course.

In the case where the speed of rotation of the vertical arm 5 accelerates slightly, due to a non-violent wind for example, the tracking of the first and second solar panels 6, 6' as a function of the azimuthal course of the sun is no longer ideal for capturing solar energy. If necessary, the mechanical braking device 40 makes it possible to slow down the speed of rotation of the vertical arm 5 by friction.

The calibration spring 44 makes it possible to adjust the braking force of the rotation of the vertical arm 5.

In the case where the photovoltaic system 1 comprises an electric braking device, it is the servomotor 28 which will send a signal to reduce the speed of rotation of the vertical arm 5 to the electric motor 14.

In the event of strong wind, the wind speed or pressure measuring device 29 sends a signal to stop the electric motor 14 to the servomotor 28, beyond a threshold value measured by said measuring device 29 .

This measuring device 29 sends the signal to stop the electric motor 14 beyond a measured threshold value.

The photovoltaic system 1 will then take on a “weather vane” function and the rotation of the vertical arm 5 will be subject to the wind. Depending on the position of the first and second solar panels 6, 6', the wind will orient these first and second solar panels 6, 6' according to its direction. Once the first and second solar panels 6, 6' are oriented in the direction of the wind, the photovoltaic system 1 will only present its smallest profile exposed to the air flow.

When the violent winds dissipate, that is to say when the wind speed or pressure measuring device 29 measures a value below the threshold value, the time delay device sends a signal for actuating the electric motor 14 to the servomotor 28, making it possible to resume the capture of solar energy by the first and second solar panels 6, 6' depending on the azimuth course of the sun.

The advantages of the present invention are now mentioned.

While the front face of the first and second solar panels 7, 7' captures solar energy, the rear face of the first and second solar panels 30, 30' incorporates informative and/or advertising panels that can be read by people in his field of vision.

Indeed, each first and second solar panel 6, 6 'extending radially with respect to the main axis A-A of the vertical arm 5 and more precisely perpendicularly with respect to the main axis A-A of the vertical arm 5 and perpendicular with respect to the floor 3, the information panels are therefore arranged so as to be visible and understandable by anyone in their field of vision, day and night thanks in particular to the lighting means.

These first and second 6, 6' solar panels therefore have a dual function of capturing solar energy and providing information and/or advertising.

In the event of light wind, the rotation of the vertical arm 5 around its axis is not stopped and the capture of solar energy by the first and second solar panels 6, 6' depending on the azimuth course remains optimal thanks to compensation for the acceleration of the rotational speed of the vertical arm 5 by the mechanical 40 or electrical braking device of the vertical arm 5.

In the event of violent wind, and when the direction of the wind carries the photovoltaic system 1 in a direction where it will present only its smallest profile exposed to the air flow, the risks of partial or total destruction of the photovoltaic system 1 are avoided.

This advantage for the photovoltaic system 1 to present that its smaller profile exposed to the flow of air in the event of violent wind, also makes it possible to considerably reduce the calculations of descents of loads in the fixed foot 2 and therefore therefore the calculations of the foundations making it possible to fix the fixed foot 2 in the ground 3 and the various structures making up the photovoltaic system 1.

In addition, this photovoltaic system 1 produces more energy than single-axis photovoltaic systems in winter while maintaining good energy efficiency in summer.

Indeed, the adaptation of the servomotor 28 to the climatology of the site is synchronous with the meteorological factors: when there is a lot of wind, the cloud cover is often very heavy and the solar irradiation at these times is low, from 50 at 200 W/m², the solar energy is 100% diffuse. Therefore, the position of the solar panels 6, 6′ is then irrelevant with respect to the position of the sun. Conversely, when there is sunshine, solar irradiation is strong, up to 1000W/m² and more, mainly made up of direct irradiation (60 to 80%) and diffuse irradiation (20 to 40 %). Direct energy is then preponderant and it is profitable in these conditions to ensure solar monitoring as closely as possible. Note that when it is sunny, the wind speed is generally average or rather low.

Finally, the layout of the photovoltaic system 1 has the advantage of being compact on the ground.

Claims (14)

Photovoltaic system (1) characterized in that it comprises:
-a fixed foot (2) configured to be fixed to the ground (3),
-a vertical arm (5) configured to extend longitudinally from the fixed foot (2) along a main axis (AA) perpendicular to the ground (3),
-at least one solar panel (6, 6') secured in a fixed manner to said vertical arm (5) and extending radially with respect to the main axis (AA),
the system (1) further comprising a drive device (10) of the arm (5) for coupling the vertical arm (5) to the fixed foot (2), the drive device (10) being configured for driving of the vertical arm (5) around its main axis (AA). Photovoltaic system (1) according to claim 1, characterized in that the photovoltaic system (1) comprises the at least one panel (6, 6'), said first solar panel (6) and a second solar panel (6') , the second solar panel (6') being fixedly fixed to said arm (5) and extending radially with respect to the main axis (A-A), the first solar panel (6) and the second solar panel (6' ) being opposed to each other with respect to the main axis (A-A) so that the radial dimension of the first solar panel (6) is greater than the radial dimension of the second solar panel (6'). Photovoltaic system (1) according to Claim 2, characterized in that the radial dimension of the first solar panel (6) is different from the radial dimension of the second solar panel (6'). Photovoltaic system (1) according to Claim 3, characterized in that the radial dimension of the second solar panel (6') is less than or equal to 70% of the radial dimension of the first solar panel (6). Photovoltaic system (1) according to any one of the preceding claims, characterized in that the drive device (10) comprises a ball table (11) mounted on the fixed foot (2), the vertical arm (5) being configured to cooperate with said ball table (11). Photovoltaic system (1) according to Claim 5, characterized in that the drive device (10) comprises a toothed wheel (12) fixed to the vertical arm (5) around its main axis (A-A). Photovoltaic system (1) according to Claim 6, characterized in that the drive device (10) comprises an electric motor (14) comprising a servomotor (28) slaved to the azimuthal path of the sun, the electric motor (14) being connected to the fixed foot (2) and configured to drive in rotation, via a cam (27), said toothed wheel (12) according to an axis of rotation coinciding with the main axis (A-A) of the vertical arm ( 5). Photovoltaic system (1) according to any one of the preceding claims, characterized in that a mechanical braking device (40) for the rotation of the vertical arm (5) is connected both to the vertical arm (5) and to the foot fixed (2). Photovoltaic system (1) according to Claim 8, taken in combination with any one of Claims 6 or 7, characterized in that the mechanical braking device (40) comprises a disc or drum (41) coupled to the toothed wheel ( 12) of the drive device (10) and at least one brake pad (42) integral with the fixed foot (2). Photovoltaic system (1) according to any one of Claims 1 to 7, characterized in that an electronic braking device for the rotation of the vertical arm (5) is coupled to the drive device (10). Photovoltaic system (1) according to any one of the preceding claims, taken in combination with claim 7, characterized in that a wind speed or pressure measuring device (29) is coupled to the servomotor (28) , the measuring device (29) being configured to send a signal to stop the electric motor (14) to the servomotor (28), beyond a threshold value measured by said measuring device (29). Photovoltaic system (1) according to Claim 11, characterized in that a delay device is coupled to the wind speed or pressure measuring device (29) and to the servomotor (28), the delay device being configured to send a signal for actuating the electric motor (14) to the servomotor (28), after the reception of the signal to stop the electric motor (14) by the servomotor (28), below the threshold value measured by said measuring device (29). Photovoltaic system (1) according to any one of the preceding claims, characterized in that the at least one solar panel (6, 6') extends perpendicularly with respect to the main axis (A-A) of the vertical arm (5 ). Photovoltaic system (1) according to any one of the preceding claims, characterized in that it comprises at least one row of solar panels (6, 6'), each solar panel (6, 6') being integral with the solar panel ( 6, 6') adjacent, said at least one row extending along the main axis (A-A) of the vertical arm (5).