EP2521886A2

EP2521886A2 - Method for the automatic orientation of a solar panel device and device operating according to said method

Info

Publication number: EP2521886A2
Application number: EP10796444A
Authority: EP
Inventors: Antoine Pineau; François BOUDEHENN
Original assignee: Commissariat a lEnergie Atomique CEA; Commissariat a lEnergie Atomique et aux Energies Alternatives CEA
Current assignee: Commissariat a lEnergie Atomique et aux Energies Alternatives CEA
Priority date: 2010-01-04
Filing date: 2010-12-31
Publication date: 2012-11-14
Also published as: WO2011080330A3; US20120279487A1; BR112012016386A2; RU2012133295A; CN102812308A; WO2011080330A2; FR2954972B1; FR2954972A1; JP2013516754A; KR20120112492A; IN2012DN05913A

Abstract

The invention relates to a method for orienting a solar panel device (3), characterised in that the solar panel device is oriented along at least one axis (5) in a first direction and in a second direction, using energy from a first fluid tank (6) or from a second fluid tank (8), said energy being supplied by solar radiation and the two tanks being independent. The invention is further characterised in that the solar panel device is oriented along the aforementioned axis (5) in the first direction or in the second direction until a distributor (13, 14) prevents one of the cylinder chambers from being supplied by one of the chambers of a tank.

Description

Automatic orientation method of a solar panel device and device operating according to this method.

The present invention relates to an automatic method of orienting a solar panel and a device for orienting a solar panel, that is to say an orientation device operating according to such a method. The invention also relates to a solar energy conversion system comprising such a device for orienting a solar panel device and a solar panel device.

As global demand for energy is growing, one of the goals of the coming years is to find reliable and environmentally friendly sources of energy. One of the first steps has been the manufacture of systems that can convert solar energy either into electricity via photovoltaic solar panels or into heat through solar thermal panels. Nevertheless, the installation of such systems remains expensive and productivity is sometimes considered too low in the eyes of the consumer. According to studies, such a system that can follow the course of the sun has a productivity gain averaging between 15 and 30% depending on the technology used. So that the system can follow the course of the sun, it is equipped with an orientation device or "tracker" to automatically orient solar panels according to the position of the sun.

Orientation devices can be classified into two categories:

- The so-called active orientation devices, that is to say using an external energy, including electrical energy, to allow the system to track the course of the sun. These guidance devices often use stepper motors to move the solar panels. the so-called passive orientation devices, that is to say not using any external energy source to allow the solar panels to be held and oriented so that they are positioned at least substantially perpendicular to the radius of the sun.

For medium and large power installations, the energy consumed by an active orientation device is low compared to the amount of energy converted by the solar panels that the orientation device is intended to orient. However, for small power installations, the energy consumed by an active orientation device is no longer negligible compared to the amount of energy converted by the solar panels that the orientation device is intended to guide and in particular, is not negligible compared to the energy savings provided by the orientation device with respect to a fixed solar panel system. In such a context, passive orientation devices are of interest.

Passive orientation devices are already known. In a first orientation device, two identical cylinders and subjected to the same pressure are arranged on each side of a solar panel and at the same distance from the center of rotation of this solar panel. They are filled with a fluid having a low boiling temperature. The device also provides caches arranged judiciously so that if the sun's rays are not perpendicular to the surface of the solar panel, the radiation reaches mainly one of the two cylinders, which causes in the latter the boiling of the fluid and a transfer of fluid from one cylinder to another. It follows that the respective weights of the two cylinders are no longer the same, and that the solar panel tilts accordingly. Although such an orientation device has advantages (in particular, a gain in performance of the solar panel comparable to that obtained with a device active orientation, a simple structure and therefore a low cost), it has certain disadvantages that can be unacceptable:

- the orientation device does not withstand external elements such as gusts of wind, because its balance around the ideal position is precarious and because the efforts it puts into play are weak vis-à-vis the efforts produced by a gust of wind for example;

- There is a risk of occurrence of a phenomenon of oscillations around the ideal position: indeed, because of inertia, during a phase of modification of the orientation of the solar panel, the orientation device goes to exceed the ideal position, then will want to correct this overtaking by a direction in opposite direction but will exceed the ideal orientation again. It follows a phenomenon of oscillations around the ideal position.

Document US 2005/284 467 also discloses a passive orientation device for orienting solar panels according to the position of the sun. In this orientation device, a liquid fills a chamber which is connected to a jack. The expansion of the liquid is used to move the cylinder rod and, as a result, to move the solar panels. Thus, in this orientation device, the orientation of the solar panels is a function of the temperature of the liquid and not necessarily a function of the orientation of the solar rays. In particular, during the first part of the day, the chamber is not exposed to the sun's rays and the temperature of the liquid depends only on the temperature of the ambient air. It follows that the sun's rays are not necessarily perpendicular to the solar panels in this first part of the day. Similarly, during the second part of the day, the chamber is gradually exposed to the sun's rays, which is consequently more exposed to sunlight at the end of the day than in the middle of the day. It follows that the solar rays can not have a constant incidence compared to the solar panels during this second part of the day and that the solar rays are not therefore perpendicular to the solar panels. solar panels throughout this second part of the day. Moreover, the ambient temperature necessarily has an influence on the orientation of the solar panels. Therefore, if, under certain conditions, the sun's rays are perpendicular to the solar panels, under the same conditions, but with a different ambient temperature, the solar rays will not be perpendicular to the solar panels. In addition, when the device is completely sheltered from the sun during a cloudy passage, it returns to a position defined solely by the ambient temperature, this position may be very far from the position occupied just before the cloudy passage.

The aim of the invention is to provide an orientation method and an orientation device making it possible to remedy the problems mentioned above and to improve the orientation methods and the orientation devices known from the prior art. In particular, the invention provides an orientation method and an orientation device for improving the orientation accuracy of the solar panels.

According to the invention, the method makes it possible to orient a solar panel device. It is characterized by orienting the solar panel device according to at least one axis, in a first direction and in a second direction, by using an energy of a first fluid reservoir or a second fluid reservoir, the energy being provided by the solar radiation and the two reservoirs being independent. The solar panel device is orientated along the axis in the first direction or in the second direction until a distributor prohibits the supply of one of the jack chambers by one of the chambers. a reservoir.

The solar panel device can be oriented along the axis in the first direction by pneumatically or hydraulically connecting a first chamber of the first tank to a first cylinder chamber and orienting, along the axis, in the second direction, the solar panel device by pneumatically or hydraulically connecting a second chamber of the second tank to a second cylinder chamber. A first distributor and a second distributor can be controlled respectively by the pressure of a fluid contained in a third chamber, in particular in a third chamber included in the first reservoir, and by the pressure of a fluid contained in a fourth chamber, in particular in a fourth chamber included in the second tank.

The solar panel device can be oriented along the axis in the first direction or in the second direction until the third and fourth chambers:

be minimally exposed to the sun's rays, and / or

are exposed in the same way to the sun's rays, or are not exposed to the sun's rays.

According to the invention, the device makes it possible to orient a solar panel device around an axis. The orientation device comprises at least first and second independent tanks and hydraulic or pneumatic connection means for connecting a first chamber of the first tank and a second chamber of the second tank respectively to a first cylinder chamber and a second chamber cylinder so as to power the first cylinder chamber with fluid from the first chamber of the first tank and to be able to supply the second cylinder chamber with fluid from the second chamber of the second tank. The orientation device comprises hydraulic or pneumatic connection means for hydraulically or pneumatically connecting the first chamber of the first tank and the second chamber of the second tank respectively to the second jack chamber and the first chamber of the first chamber. cylinder so as to feed the first chamber of the first tank with fluid from the second cylinder chamber and to be able to feed the second chamber of the second tank with fluid from the first cylinder chamber.

The orientation device may comprise two single acting type cylinders.

The orientation device may comprise a double-acting type cylinder comprising the first cylinder chamber and the second cylinder chamber.

The hydraulic or pneumatic connection means may comprise a first distributor and a second distributor respectively controlled by the pressure of a fluid contained in a third chamber, in particular in a third chamber included in the first reservoir and by the pressure of a contained fluid. in a fourth chamber, in particular in a fourth chamber included in the second tank.

The orientation device may comprise caches arranged so that when the projections of the solar rays in a plane perpendicular to the axis are perpendicular to the solar panel device, the third and fourth chambers:

are minimally exposed to sunlight, and / or

are exposed in the same way to the sun's rays, or - are not exposed to the sun's rays.

According to another aspect, the device makes it possible to orient a solar panel device about an axis and comprises at least a first and a second independent reservoir and hydraulic or pneumatic connection means for connecting a first chamber of the first reservoir and a reservoir. second chamber of the second tank respectively to a first chamber of cylinder and a second cylinder chamber so as to power the first cylinder chamber with fluid from the first chamber of the first tank and to be able to feed the second cylinder chamber with fluid from the second chamber of the second tank. The hydraulic or pneumatic connection means comprise a first distributor and a second distributor respectively controlled by the pressure of a fluid contained in a third chamber, in particular in a third chamber included in the first reservoir and by the pressure of a fluid contained in a fourth chamber, in particular in a fourth chamber included in the second tank.

According to the invention, the solar energy conversion system comprises a previously defined orientation device and a solar panel device. The solar energy conversion system may comprise a first orientation device defined above, a second orientation device defined above and a solar panel device, the first and second orientation devices being arranged so as to orient the device. solar panel around two non-parallel axes and preferably so as to orient the solar panel device about two orthogonal or substantially orthogonal axes.

The appended drawings represent, by way of example, an embodiment of a solar energy conversion system according to the invention.

FIG. 1 is a mechanical diagram of one embodiment of a solar energy conversion system according to the invention, the orientation device being represented in an equilibrium situation. FIG. 2 is a hydraulic or pneumatic diagram of the embodiment of the solar energy conversion system according to the invention, the orientation device being represented in an equilibrium situation. FIG. 3 is a mechanical diagram of the embodiment of the solar energy conversion system according to the invention, the orientation device being represented in a transient situation.

FIG. 4 is a hydraulic or pneumatic diagram of the embodiment of the solar energy conversion system according to the invention, the orientation device being represented in a transient situation.

The principle of the invention is based on the use of the fluid expansion phenomenon and on the actions that may be produced by the expansion of the fluid in jack chambers used to orient a solar panel around a or several axes.

In general, the principle of the invention is to use the energy of the sun to allow the expansion of a fluid. This expansion makes it possible to generate mechanical actions by means of one or more jacks to orient the solar panel.

It is therefore sought to generate, through solar radiation, pressure differences between several chambers so as to allow movement of at least one cylinder rod and thus move the solar panel.

The pressure difference is created when the fluid trapped in a tank rises in temperature under the effect of the sun. The fluid expands and therefore seeks to take up more space by pushing a cylinder rod. Moreover, the fluid enclosed in another tank is maintained under the same conditions of temperature and pressure to prevent it from exerting antagonistic mechanical action. A pneumatic or hydraulic circuit achieves this goal.

A first embodiment of a solar energy conversion system 1, shown in FIGS. 1 to 4, mainly comprises a solar panel device 3 and an orientation device 2 of this solar panel device. The orientation device is of the passive type and allows the solar panel device to be automatically oriented so that the solar radiation 10 is at least substantially perpendicular to the surface of the solar panel device.

The solar panel device converts solar energy into another energy. It can include several elements of solar energy conversion. In particular, the solar panel device may comprise one or more elements for converting solar energy into electrical energy and / or may comprise one or more elements for converting solar energy into thermal energy transported by a fluid.

The orientation device 2 mainly comprises a support 4 at the end of which the solar panel device is mounted movably relative to an axis 5 and two cylinders 1 1, 12 simple effect, mounted for example symmetrically with respect to the axis 5 on which is articulated the solar panel device. First ends of the cylinders are articulated on the solar panel device and the other ends of the cylinders are articulated on the support or on a structure on which is fixed the support. Thus, a deployment of the rod of the first jack 1 1 causes a rotation of the solar panel device about the axis 5 in a first direction and a withdrawal of the rod of the second cylinder 12. Symmetrically, a deployment of the rod of the second cylinder 12 causes a rotation of the solar panel device about the axis 5 in a second direction and a withdrawal of the rod of the first cylinder January 1. These are the actions of his jacks that allow the solar panel device to be best oriented with respect to the solar radiation, that is to say to be oriented so that the sun rays are as much as possible perpendicular to the surface of the solar panel device. The orientation device 2 also comprises reservoirs 6, 8 and means for hydraulically or pneumatically connecting the reservoirs to the cylinders. Thus, the cylinders are supplied with fluid under pressure by tanks 6, 8 via the hydraulic or pneumatic connection means and the mechanical energy applied by the cylinders on the solar panel device comes from the tanks 6, 8.

In addition, the orientation device 2 comprises covers 7 and 9. The reservoirs and the covers are in kinematic connection with the solar panel device. Preferably, the tanks and caches are (directly or indirectly) integral with the solar panel device. The covers may consist of simple pieces of sheet metal or metal or synthetic profiles.

The covers are arranged so that the tanks 6, 8 are protected from the sun's rays, when the solar rays have a desired direction with respect to the surface of the solar panel device, that is to say especially when the projections of the rays in a plane perpendicular to the axis 5 are perpendicular or substantially perpendicular to the surface of the solar panel device. Alternatively, the covers are arranged so that the reservoirs are at most protected from the solar rays and / or protected in the same way from the solar rays, when the solar rays have a desired direction with respect to the surface of the solar panel device, that is to say, in particular when the projections of the solar rays in a plane perpendicular to the axis 5 are perpendicular or substantially perpendicular to the surface of the solar panel device. In addition, the covers are arranged so that the tanks are not protected from the same way of the solar rays, when the solar rays do not have the desired direction relative to the surface of the solar panel device, that is to say in particular when the projections of the solar rays in a plane perpendicular to the axis 5 are not perpendicular or substantially perpendicular to the surface of the solar panel device.

Consequently, when the tanks are not protected in the same way from the sun's rays, a heating of one of the tanks with respect to the other takes place, for example the first tank 6 with respect to the second tank 8, having as a consequence, an increase of a fluid pressure in a first chamber 17 of the first tank 6. This pressure increase constitutes an energy which will be used, as explained later, in one of the cylinders to orient the solar panel device so that it has an orientation such that the sun rays are as perpendicular to its surface as possible.

As shown in FIGS. 2 and 4, the hydraulic or pneumatic connection means of the reservoirs to the cylinders comprise lines 21, 22, 23, 24, 25 and 26 and distributors 13 and 14. Line 21 connects the first chamber 17 of the first reservoir 6 to the distributor 13, the pipe 23 connects the distributor 13 to the first chamber 15 of the cylinder 1 1 and the pipe 25 connects the distributor 13 to the second chamber 18 of the second tank 8 via a non-return valve 27 not allowing the fluid flow from the distributor to the second chamber of the second tank. Symmetrically, the pipe 22 connects the second chamber 18 of the second tank 8 to the distributor 14, the pipe 24 connects the distributor 14 to the second chamber 16 of cylinder 12 and the pipe 26 connects the distributor 14 to the first chamber 17 of the first tank 6 via a check valve 28 allowing the flow of fluid from the distributor to the first chamber of the first tank. The first distributor 13 is controlled by a fluid pressure contained in a third chamber 19 of the first reservoir 6 and is returned to a rest position by an elastic means. In the rest position, the flow of fluid between the first chamber 17 of the first reservoir 6 and the first cylinder chamber 15 is prohibited and the flow of fluid between the first cylinder chamber 1 1 and the second chamber 18 of the second reservoir 8 is allowed. When the first reservoir 6 is subjected to the sun's rays, the fluid pressure in the third chamber 19 increases and controls, via a pipe 31, a change of position of the distributor 13, the latter passing from its rest position to a second position in which the circulation of the fluid between the first chamber 17 of the first reservoir 6 and the first cylinder chamber 1 1 is authorized and the circulation of the fluid between the first cylinder chamber 1 1 and the second chamber 18 of the second tank 8 is prohibited.

Symmetrically, the second distributor 14 is controlled by a fluid pressure contained in a fourth chamber 20 of the first reservoir 8 and is returned to a rest position by an elastic means. In the rest position, the flow of fluid between the second chamber 18 of the second reservoir 8 and the second cylinder chamber 12 is prohibited and the flow of fluid between the second cylinder chamber 12 and the first chamber 17 of the first reservoir 6 is allowed. When the second tank 8 is subjected to the sun's rays, the fluid pressure in the fourth chamber 20 increases and controls, via a pipe 32, a change of position of the distributor 14, the latter passing from its rest position to a second position , represented in FIG. 4, in which the circulation of the fluid between the second chamber 18 of the first reservoir 8 and the first cylinder chamber 1 1 is authorized and the circulation of the fluid between the first cylinder chamber 1 1 and the second chamber 18 of the second tank 8 is prohibited. An embodiment of an orientation method according to the invention is described below. This orientation method embodiment corresponds to a mode of execution of a method of operation of a solar panel orientation device.

According to these embodiments, the solar panel device is oriented along the axis 5, in a first direction and in a second direction, by using the energy received by the solar radiation from a first fluid reservoir or a second fluid reservoir, the two tanks being independent.

Indeed, as explained above, when the fourth chamber 20 of the second reservoir 8 is subjected to solar radiation (see FIG. 3), the fluid contained in this fourth chamber heats and expands, which causes an increase in pressure in the chamber 20. and a displacement of the distributor 14 towards its second position shown in FIG. 4. This allows the fluid contained in the second chamber 18 of the second reservoir 8 to feed the second cylinder chamber 12, the fluid in the second chamber 18 being at a pressure greater than that of the second chamber 16 because, in the second chamber 18, the fluid is heated by solar radiation and therefore under pressure. Thus, the rod of the jack 12 exits, the solar panel device moves in rotation about the axis 5 and the rod of the cylinder 1 1 enters it. This retraction of the rod of the cylinder 1 1 is made possible by the compression of the fluid contained in the chamber 15 of the cylinder 1 1 and, possibly, by a return of this fluid to the first chamber 18 of the second tank 8 via the distributor 3 and the check valve 27. This operation is maintained until equal pressures in the chambers 18, 16 and 15 or until the distributor returns to its rest position. Symmetrically, when the third chamber 19 of the first reservoir 6 is subjected to solar radiation, the fluid contained in this third The chamber heats and expands, resulting in an increase in pressure in the chamber 19 and a movement of the distributor 13 to its second position. This allows the fluid contained in the first chamber 17 of the first reservoir 6 to feed the first chamber 15 of the cylinder 1 1, the fluid in the first chamber 17 being at a pressure greater than that of the first chamber 15 because, in the first chamber 17, the fluid is heated by solar radiation and therefore under pressure. Thus, the rod of the cylinder 1 1 out, the solar panel device is rotated about the axis 5 and the rod of the cylinder 12 enters it. This retraction of the cylinder rod 12 is made possible by the compression of the fluid contained in the chamber 16 of the cylinder 12 and, possibly, by a return of this fluid to the first chamber 17 of the first tank 6 via the distributor 14 and the valve This operation is maintained until the pressures in the chambers 17, 16 and 15 are equal or until the distributor returns to its rest position.

In the embodiment described above, the fluid used for expansion is a gas. Nevertheless, it is possible to imagine a device for orienting a solar panel device operating on the same principle and in which the dilation of a liquid is used.

Finally, in the embodiment described, the chambers 19 and 20 are part of the tanks 6 and 8. Nevertheless, these chambers may be independent of the tanks, in particular to solve problems of thermal inertia. They are preferably exposed to solar radiation according to an exposure logic similar to the solar radiation exposure logic of the first and second reservoirs.

In an embodiment not shown, the cylinders 1 1 and 12 of the single-acting type are replaced by a single double-acting cylinder type. Preferably, the double-acting cylinder used is of the through-rod type (ie that the rod of the cylinder passes through the entire cylinder so that the surface of the cylinder piston seen from each of the chambers is the same and so that the piston is stationary when the two chambers are subjected to the same pressure).

Preferably, the axis of articulation of the solar panel device and the axes or centers around which the ends of the jacks January 1 and 12 are hinged to the solar panel device are contained in the same plane or substantially contained in the same plan.

The covers may include reflecting surfaces, in particular they may have a parabolic cross section and be arranged so that the focal axis of each cache is located in each of the tanks or near each of them. Thus, the solar rays reaching the inner surface of the covers are reflected back to the tanks.

The invention relates to a solar energy conversion system comprising an orientation device and a solar panel device. It relates in particular to a solar energy conversion system comprising a first orientation device and a second orientation device, the first and second orientation devices being arranged so as to orient the solar panel device around two axes. non-parallel and, preferably, so as to orient the solar panel device about two substantially orthogonal or orthogonal axes. A first axis can allow a daily orientation while a second axis can allow a seasonal orientation.

The orientation device according to the invention makes it possible to remedy the problems posed by the devices known from the prior art. In particular, it ensures a good maintenance of the solar panel device even in case of wind. A prototype made and able to orient the solar panel device with a pressure of three bars withstands winds of 70 km / h.

The responsiveness of the orientation device can be defined by different construction parameters, including the nature of the fluid used.

The orientation device allows a quick return to the ideal position after a cloudy passage or at the beginning of the day. For example, in the case of the prototype made, it takes 7 minutes to return to the ideal position after a cloudy passage of 2 hours.

Unlike the device described in US 2005/284 467, the presence of a cloudy passage does not result in a change in the orientation of the solar panel device.

In this document, it is mentioned that the two tanks are independent. By "independent" is meant that the two tanks can be subjected to different pressures.

Claims

Claims:

1. Method of orienting a solar panel device (3), characterized in that the solar panel device is oriented in at least one axis (5), in a first direction and in a second direction, using an energy a first reservoir (6) of fluid or a second reservoir (8) of fluid, the energy being provided by the solar radiation and the two reservoirs being independent and in that one orients, along the axis ( 5), in the first direction or in the second direction, the solar panel device until a distributor (13, 14) prohibits the supply of one of the cylinder chambers by one of the chambers of a reservoir.

2. Guidance method according to the preceding claim, characterized in that orienting, along the axis (5), in the first direction, the solar panel device by pneumatically or hydraulically connecting a first chamber (17) of the first reservoir (6) to a first cylinder chamber (15) (1 1) and in that the solar panel device is oriented along the axis (5) in the second direction by pneumatically or hydraulically connecting a second chamber (18) of the second reservoir (8) to a second cylinder chamber (16) (12).

3. Guidance method according to one of the preceding claims, characterized in that a first distributor (13) and a second distributor (14) are respectively controlled by the pressure of a fluid contained in a third chamber (19) , in particular in a third chamber (19) included in the first reservoir (6), and by the pressure of a fluid contained in a fourth chamber (20), in particular in a fourth chamber (20) included in the second reservoir (8) ). Orientation method according to the preceding claim, characterized in that the solar panel device is oriented along the axis (5) in the first direction or in the second direction until the third and fourth chambers :

be minimally exposed to the sun's rays, and / or

Device (2) for orienting a solar panel device (3) around an axis (5), the orientation device comprising at least a first (6) and a second (8) independent reservoir and means hydraulic or pneumatic connection means (13, 14, 21, 22, 23, 24) for connecting a first chamber (17) of the first reservoir and a second chamber (18) of the second reservoir respectively to a first cylinder chamber (15) ( 1 1) and a second chamber (16) of cylinder (12) so as to be able to feed the first cylinder chamber with fluid from the first chamber of the first tank and to be able to feed the second cylinder chamber with fluid from the first second chamber of the second tank, characterized in that it comprises hydraulic or pneumatic connection means (13, 14, 23, 24, 25, 26, 27, 28) for hydraulically or pneumatically connecting the first chamber (17) of the first reservoir (6) and the second chamber (18) of the second tank (8) respectively to the second cylinder chamber (16) (12) and to the first cylinder chamber (15) () so as to be able to feed the first chamber (17) of the first tank (6) with fluid of the second chamber (16) of cylinder (12) and able to feed the second chamber (18) of the second reservoir (8) with fluid from the first chamber (15) of cylinder (1 1). Orientation device according to claim 5, characterized in that it comprises two cylinders (1 1, 12) of simple effect type.

Orientation device according to claim 5 or 6, characterized in that it comprises a double-acting type cylinder comprising the first cylinder chamber and the second cylinder chamber.

Orientation device according to one of claims 5 to 7, characterized in that the hydraulic or pneumatic connection means comprise a first distributor (13) and a second distributor (14) controlled respectively by the pressure of a fluid contained in a third chamber (19), in particular in a third chamber (19) included in the first reservoir (6) and by the pressure of a fluid contained in a fourth chamber (20), in particular in a fourth chamber (20) included in the second tank (8).

Orientation device according to one of claims 5 to 8, characterized in that it comprises covers (7, 9) arranged so that when the projections of the solar rays in a plane perpendicular to the axis (5) are perpendicular to the solar panel device, the third and fourth chambers:

are minimally exposed to sunlight, and / or

are exposed in the same way as the sun's rays, or are not exposed to the sun's rays.

System (1) for converting solar energy comprising an orientation device (2) according to one of Claims 5 to 9 and a solar panel device (3). System (1) for converting solar energy comprising a first orientation device (2) according to one of Claims 5 to 9, a second orientation device (2) according to one of Claims 5 to 9 and a solar panel device (3), the first and second orientation devices being arranged to orient the solar panel device about two non-parallel axes and preferably so as to orient the solar panel device around two orthogonal or substantially orthogonal axes.