FR2998656A1 - ORIENTATION SYSTEM FOR SOLAR ENERGY CAPTURE DEVICE - Google Patents

Abstract

The invention relates to an orientation system (101) for a solar energy collecting device (100) comprising at least one solar energy sensor element (102), said orientation system comprising: - a connector (122) disposed along a first axis (123), the connector being adapted to cooperate with the at least one solar energy sensor element, the connector being provided with means (128, 129) for reversibly locking the sensor element solar energy relative to the connector; - means (131) for rotating the connector along the first axis.

Description

The present invention relates to an orientation system for a solar energy capture device. It is known from the state of the art of solar energy collection devices comprising a set of solar energy sensor elements, cylindrical, elongated along an axis, and a means for driving said sensor elements in rotation. solar energy around their axis. The solar energy sensor elements each comprise, in a conventional manner, a duct inside which solar energy collection means are arranged, such as, for example, photovoltaic cells. Such devices make it possible to modify an inclination of the means for collecting solar energy from each of the solar energy sensor elements, by rotation of said elements around their axis. Thus, the solar energy sensor elements can adapt to changes in the inclination of the sun's rays during a day. Such devices are conventionally used in extreme conditions, and therefore require to meet various constraints. Such devices must for example withstand high thermal stresses, but also be protected against foreign bodies, for example sand, which could deteriorate the quality of the rotational drive of the solar energy sensor element. Such devices must also be suitable for rapid replacement of one or more elements, during a malfunction thereof. The present invention aims to solve one or more of these technical problems. More specifically, the subject of the invention is an orientation system for a solar energy collecting device comprising at least one solar energy sensor element, said orientation system comprising: a connector disposed along a first axis; the connector being adapted to cooperate with the at least one solar energy sensor element, the connector being provided with reversible blocking means of the solar energy sensor element relative to the connector; a means for driving the connector in rotation along the first axis. Such an orientation system has the advantage of allowing easy and rapid replacement of a solar energy sensor element. It suffices, with such a system, to disable the locking means, to remove the defective element, to install the new element, then to activate the locking means. According to one embodiment of the invention, the reversible blocking means are able to activate or be activated, at the end of an assembly of the solar energy sensor element and the connector, by translation according to the first axis.

Such an embodiment is advantageous when the solar energy sensor element can hardly be moved perpendicularly to the axis of rotation of the connector. According to another embodiment of the invention, the reversible blocking means are able to activate or to be activated, at the end of an assembly of the solar energy sensor element and the connector, by translation according to a second axis, perpendicular to the first axis. Such an embodiment is advantageous when the solar energy sensor element can hardly be moved along the axis of rotation of the connector.

Preferably, the orientation system further comprises a hollow support member forming a closed interior volume, inside which is disposed the means for rotating the connector along the first axis and the connector. Such an orientation system, in which the rotational drive means is disposed in a closed volume, has the advantage of protecting the rotation drive of the connector against foreign bodies, for example sand, which could deteriorate the quality. Preferably, the support element comprises a removable wall. Such a wall has the advantage of giving access to the internal volume of the support element for, for example, performing maintenance operations. Preferably, the removable wall is disposed substantially perpendicular to a third axis, perpendicular to the first axis, the removable wall being provided with resilient interlocking means cooperating with resilient interlocking means of walls of the support member which are adjacent thereto said means being adapted to engage one another after a translational assembly along the third axis of the removable wall and adjacent walls. Preferably, tabs extend in the extension of the walls adjacent to the removable wall, in a direction opposite to the removable wall. Such tabs have the advantage of allowing the elastic interlocking means of the removable wall to be disengaged from the elastic interlocking means of the walls adjacent to the removable wall, when a force tending to bring the tabs closer to one another. other is applied to the support member. Preferably, the connector comprises a groove cooperating with an element protruding from the removable wall, the projecting element being able to block the connector, in translation along the first axis and in rotation along a fourth axis, perpendicular to the first and third axes. Such a locking system of the connector relative to the support member makes it possible to ensure that the connector remains in place during an operation to replace a defective solar energy sensor element.

Preferably, the support element comprises a central wall dividing the internal volume into two sub-volumes isolated from one another, one of the sub-volumes accommodating the connector and the rotating drive means. Such a support element has the advantage of avoiding the transfer of foreign bodies from one sub-volume to another. The use of such a central wall makes it possible to increase the mechanical inertia of the support element, and to prevent it from sagging under the weight of the at least one solar energy sensor element. . According to one embodiment of the invention, the orientation system comprises another connector disposed along an axis substantially parallel or coincident with the first axis, inside the closed volume of the support element, the other connector being able to cooperate with another solar energy sensor element of another solar energy collection device, the other connector being provided with reversible blocking means of the other solar energy sensor element with respect to the solar energy sensor. other connector.

Such an orientation system has the advantage of connecting two sets of solar energy sensor elements to each other. According to one embodiment of the invention, the other connector is traversed right through by an opening disposed along the axis of the other connector, and the support element comprises a central wall splitting the internal volume in two. sub-volumes isolated from each other, one of the sub-volumes hosting the connector and the rotating drive means, and the other sub-volumes hosting the other connector. Such an orientation system has the advantage of including another connector allowing, for example, the passage of electrical cables, from the other solar energy sensor element to the internal volume of the support element. Such an orientation system also has the advantage of isolating the electrical cables in the other of the sub-volumes, so that the electric cables can not interfere with the rotational drive of the connector. According to one embodiment of the invention, the means for rotating the connector is a rack arranged along a fourth axis, substantially perpendicular to the first axis, the rack cooperating with a toothed wheel integral with the connector and arranged along the first axis. . Such an embodiment is particularly advantageous when the solar energy sensing device comprises more than one solar energy sensor element, the rack making it possible to have the same speed of rotation, as well as a synchronous rotation of the elements. Preferably, the rack is in abutment against the support element by means of an elastic compression means. The use of an elastic compression means between the rack and the support member has the advantage of ensuring the contact between the rack and the toothed wheel. The invention also relates to a connector for an orientation system as previously described. The subject of the invention is also an assembly of an orientation system as previously described and of a solar energy collecting device comprising at least one solar energy sensor element, said element being substantially cylindrical, elongated according to a fifth axis, parallel or coincident with the first axis, and comprising a conduit inside which is disposed at least one solar energy collection means, the at least one solar energy sensor element cooperating with the connector. The invention will be better understood on reading the description which follows and on examining the figures which accompany it. These are given as an indication and in no way limitative of the invention. The figures show: FIG. 1: a schematic view, in perspective, of a solar energy collection device and of an orientation system assembled, according to one embodiment of the invention; Figure 2 is a sectional view of a solar energy sensing device and an orientation system, before assembly, according to one embodiment of the invention; - Figure 3: a sectional view of a solar energy collection device and an orientation system, before assembly, according to another embodiment of the invention than that shown in Figure 2; Figure 3a: a perspective view of a closing means of the solar energy collection device, according to the embodiment shown in Figure 3; 3b: a perspective view of a connector of the orientation system, according to the embodiment shown in FIG. 3. FIG. 1 shows a solar energy collection device 100 and an orientation system 101 assembled. according to one embodiment of the invention. Figures 2 and 3 each show, in more detail, the system 101 of orientation, before assembly with the device 100 of solar energy harvesting, according to a different embodiment of the invention. The common elements between the embodiment shown in Figure 2 and that shown in Figure 3 retain the same references. The solar energy collection device 100 comprises at least one solar energy sensor element 102. Element 102 is cylindrical along a first axis 103. Element 102 is preferably configured to pivot about said first axis. Preferably, the device 100 for generating electrical energy comprises an assembly 104 of at least two identical elements 102, arranged substantially parallel to each other and aligned on the same side of a second axis 105 substantially perpendicular to the first axis 103. As illustrated in FIGS. 1, 2 and 3, the device 100 for collecting solar energy is more particularly an electrical energy generation device comprising at least one solar radiation concentrator element 102 and generator of electrical energy. However, all the embodiments of the invention developed in the remainder of the description are applicable to other types of solar energy collection device, such as for example a liquid heating device or a material drying device. . An element 102 according to the invention comprises a cylindrical conduit 106, elongate along the first axis 103. In the example shown in FIG. 1, the conduit 106 is more precisely formed of one or more materials comprising transparent glass.

The conduit 106 is provided at each of its ends with a means 107 for closing. The means 107 for closing the conduit 106 are substantially identical. The means 107 for closing the conduit 106 each form an end (108, 109) of an element 102. The closure means 107 forming a first end 108 of an element 102, according to one embodiment of the invention, is Figure 2 shows the closure means 107 forming the first end 108 of an element 102, according to another embodiment of the invention, is shown in detail in Figure 3 and Figure 3a. The means 107 for closing the conduit 106 are cylindrical along the first axis 103. The means 107 for closing the conduit 106 each comprise a so-called distal portion 110. In the example shown in FIG. 2, the portion 110 distal from the closing means 107 is a cylinder of revolution. The distal portion 110 of the closing means 107 is inserted inside the conduit 106. An outer diameter of the distal portion 110 is equal to an inner diameter of the conduit 106, so as to form a tight connection. In the example shown in FIG. 3, the portion 110 distal of the closing means 107 is tubular along the first axis 103. The conduit 106 is inserted inside the portion 110 distal of the closure means 107. An outer diameter of the conduit 106 is equal to an inner diameter of the distal portion 110 so as to form a tight connection. The means 107 for closing the conduit 106 also each comprise a so-called proximal portion 111. In the example shown in FIG. 2, the proximal portion 111 of the means 107 for closing the conduit 106 is tubular along the first axis 103. The proximal portion 111 of each of the closure means 107 is provided with an opening 112, preferably threaded, disposed substantially perpendicular to the first axis 103. In the example shown in Figure 3 and Figure 3a, the proximal portion 111 of the means 107 for closing the conduit 106 has a surface 113, preferably flat. The first axis 103 is coincident or parallel with the surface 113. In the example, the first axis 103 coincides with the surface 113. The proximal portion 111 of the means 107 for closing the conduit 106 comprises means 114 of elastic interlocking. In the example, the means 114 of elastic engagement take the form of two tongues extending from the surface 113, substantially parallel to one another. Preferably, the tabs 114 extend substantially perpendicular to the surface 113. The tabs 114 are elastically deformable. The tabs 114 are disposed on either side of the first axis 103, and face each other. A free end 115 of each of the tongues 114 is cut into a single bevel. A flared end of the simple bevel of each of the tabs 114 forms a notch 116 facing the surface 113. In the example, the single bevel of each of the tabs 114 is disposed on one side of the tongue 114, opposite to the other tab 114.

According to another embodiment of the invention, the proximal portion 111 of the means 107 for closing the conduit 106 forms a tenon or a mortise. The tenon or the mortise is for example dovetail or T-shaped. In the example shown in FIG. 1, a solar radiation concentrator element 102 and electrical energy generator is electrically connected between a terminal 117 positive electrical and a negative electrical terminal 118. According to one embodiment of the invention, an element 102 is electrically connected to the electrical terminals (117, 118) by each of its ends (108, 109). According to a variant, an element 102 is electrically connected to the electrical terminals (117, 118) by only one of its ends (108, 109). In the example, the set 104 of the elements 102 is electrically connected between the positive electrical terminal 117 and the negative electrical terminal 118. In the example, a first element 102 of the assembly 104 is connected to the positive electrical terminal 117 at a second 109 of its ends, and a second element 102 of the assembly 104 is connected to the negative electrical terminal 118 at a second 109 of its ends. The elements 102 solar radiation concentrators and electrical energy generators of the assembly 104 are connected together in series, by means of electrically conductive elements arranged at either of their ends (108, 109), or at only one of their ends (108, 109). The electrically conductive elements are, for example, electric cables. In the example shown in FIG. 2, openings 1181 are formed in the distal portion 110 of a closure means 107 forming the first end 108 and / or of a closure means 107 forming a second end 109 of a element 102. The openings 1181 are intended to accommodate the electric cables. Preferably, only the opening in the portion 110 distal of the closure means 107 forming the second end 109 of the element 102 accommodates the electric cables.

In the example shown in Figure 3 and Figure 3a, the surface 113 of the proximal portion 111 of the closure means 107 forming the first end 108 comprises a socket 1182 female electrical connected to the electric cables. According to one embodiment of the invention, the socket 1182 is bipolar. In other words, the socket 1182 is connected to the two electric poles. According to another embodiment of the invention, the socket 1182 is unipolar. In other words, the socket 1182 is connected to a single electrical pole. According to variants, the surface 113 of the proximal portion 111 of the closure means 107 comprises a bipolar or unipolar male electrical outlet, or a female electrical outlet and a male electrical outlet, the two outlets being each unipolar.

In the example shown in FIG. 1, a solar radiation concentrator and electric energy generator element 102 comprises at least one photovoltaic cell 119 disposed inside the duct 106 in a plane substantially parallel to the first axis 103. For example, an element 102 comprises a plurality of photovoltaic cells 119 arranged in the plane. In the example, the set of photovoltaic cells 119 is mounted on an elongated heat conducting element 120 along the first axis 103 and disposed along an inner surface of the conduit 106. The heat conducting element 120 can also be configured to reflect the optical rays. The photovoltaic cells 119 are electrically connected together in series. The set of photovoltaic cells 119 is either electrically connected between the electrically conductive elements disposed at each of the ends (108, 109) of an element 102, or electrically connected between the electrically conductive elements arranged at one end only. (108, 109) of an element 102. In the case where the set of photovoltaic cells 119 is electrically connected to only one of the ends (108, 109), the heat conducting element 120 may be configured to conduct electricity and supply electricity to photovoltaic cells. In the example shown in FIG. 1, a solar radiation concentrator and electric energy generator element 102 further comprises a transparent and elongated optical focusing element 121 along the first axis 103. Preferably, the focusing element 121 Optical is a linear Fresnel lens. The optical focusing element 121 is disposed along the inner surface of the conduit 106, opposite the set of photovoltaic cells 119. In the example, the optical focusing element 121 is disposed opposite the heat conducting element 120. The orientation system 101 comprises a connector 122 capable of cooperating with the first end 108 of an element 102. Preferably, the orientation system 101 comprises a connector 122 for each of the elements 102 of the assembly 104. The connector 122 is cylindrical, elongate along a third axis 123. The third axis 123 is substantially parallel to or coincident with the first axis 103, before the assembly of the connector 122 with an element 102. Preferably, the third axis 123 coincides with the first axis 103, when the connector 122 cooperates with the element 102. The connector 122 comprises a distal portion 124 adapted to cooperate with the proximal portion 111 of the closure means 107 forming the first end 108 of an element 102. In the example shown in Figure 2, the distal portion 124 of the connector 122 is adapted to cooperate with the proximal portion 111 of the closure means 107, after a translation of the element 102 according to the e third axis 123, the element 102 being preferably arranged so that the third axis 123 is coincident with the first axis 103. In the example shown in Figure 3, the distal portion 124 of the connector 122 is adapted to cooperate with the proximal portion 111 of the closure means 107, after a translation of the element 102 along a fourth axis 125, perpendicular to the third axis 123 and the first axis 103. In the example, the fourth axis 125 is also perpendicular to the surface 113. In the example shown in Figure 2, the distal portion 124 of the connector 122 is a cylinder of revolution. An outer diameter of the distal portion 124 of the connector 122 is equal to an inner diameter of the proximal portion 111 of the closure means 107 forming the first end 108 of an element 102. Thus, the distal portion 124 of the connector 122 is adapted to inserted in the proximal portion 111 of the closure means 107 forming the first end 108 of an element 102, by translation of the element 102 along the third axis 123.

In the example shown in FIG. 3 and in FIG. 3b, the distal portion 124 of the connector 122 has a surface 126 of complementary shape with the surface 113 of the proximal portion 111 of the closure means 107 forming the first end 108 of FIG. an element 102. The surface 126 of the distal portion 124 of the connector 122 is able to come into contact with the surface 113 of the proximal portion 111 of the closure means 107, at the end of the translation of the element 102 along the fourth axis 125. In the example, the surface 126 of the distal portion 124 of the connector 122 comprises a male electrical plug 127, adapted to cooperate with the female electrical socket 1182 of the closure means 107 forming the first end 108 of an element 102. The receptacles (1182, 127) female and male are able to cooperate together at the end of the translation of the element 102 along the fourth axis 125. According to variants, the surface 126 of the distal portion 124 of the connector 122 has a female electrical socket, adapted to cooperate with the male electrical outlet, or a male electrical outlet and a female electrical socket, respectively adapted to cooperate with the female electrical outlet and the male electrical outlet of the means 107 closing forming the first end 108 of an element 102, at the end of the translation of the element 102 along the fourth axis 125. According to another embodiment of the invention, the distal portion 124 of the connector 122 forms a mortise or tenon. The mortise or tenon forming the distal portion 124 of the connector 122 is for example in the form of a dovetail or T-shaped. The mortise or tenon of the distal portion 124 of the connector 122 is able to cooperate with the post or the mortise forming the proximal portion 111 of the closure means 107, at the end of a translation of the element 102 along an axis perpendicular to the third axis 123 and the first axis 103. The distal portion 124 of the connector 122 comprises means (128 , 129, 130) of reversible blocking of an element 102 relative to the connector 122. The reversible locking means (128, 129, 130) are capable of being activated or activated, at the end of an assembly of an element 102 and the connector 122. In other words, the reversible locking means (128, 129, 130) are capable of being activated or activated, when the distal portion 124 of the connector 122 cooperates with the part 111 proximal of the closure means 107 forming the first extremity The means (128, 129, 130) are considered "activated" when they block the element 102 relative to the connector 122. Thus, a rotation of the connector 122 around the third axis 123 causes a rotation of an element 102 around the third axis 123, when the element 102 and the connector 122 are assembled and the reversible locking means (128, 129, 130) are activated. In the example shown in FIG. 2, the reversible locking means (128, 129) are capable of being activated or activated, after assembly of the element 102 and the connector 122, by translation according to the third axis 123. In the example shown in FIG. 3, the reversible blocking means 130 are able to activate or be activated, after assembly of the element 102 and the connector 122, by translation. along the fourth axis 125. According to this embodiment, it is not necessary to provide space at the second end 109 of the element 102 to be able to disengage the element 102 from the connector 122, as it is the case when the assembly of the element 102 and the connector 122 is made by translation of the element 102 along the third axis 123. In the example shown in Figure 2, the distal portion 124 of the connector 122 is provided with a groove 128 disposed opposite the opening 112 formed in the 111 of the proximal portion of the closure means 107 forming the first end 108 of an element 102, when the distal portion 124 of the connector 122 is inserted into the proximal portion 111 of the closure means 107. The insertion of a screw 129 in the opening 112 formed in the proximal portion 111 of the closure means 107, cooperating with the groove 128 of the connector 122, makes it possible to block in translation and in rotation along the third axis 123, a element 102 with respect to the connector 122.

In the example shown in FIG. 3 and in FIGS. 3a and 3b, the distal portion 124 of the connector 122 is provided with elastic engaging means 130 capable of cooperating with the means 114 for elastic interlocking of the proximal portion 111 of the means. Closing means forming the first end 108 of an element 102. The means (114, 130) of elastic interlocking are able to fit into each other at the end of a translation assembly along the fourth axis 125, of the element 102 and the connector 122. In the example, the elastic interlocking means 130 are openings formed through the distal portion 124 of the connector 122, from the surface 126 to a surface 1301 parallel to the surface 126. The openings 130 are able to receive the tongues 114 disposed on the surface 113 of the proximal portion 111 of the closure means 107 forming the first end 108 of the element 102. During the translation of the element 102, In the fourth axis 125, the beveled free end 115 of each of the tabs 114 engages an edge of the corresponding opening 130 and then slides along said edge. The simple bevel of the free end 115 causes deformation of the tongues 114 as they progress in the opening 130. The tabs 114 deform until the notch 116 formed by the flared end of the simple bevel closes against the surface 1301. The notch 116 then forms a stop blocking the element 102 in translation along the fourth axis 125. An elastic deformation of the tongues 114 to remove the notch 116 of the surface 1301 can unlock the translation of the element 102 along the fourth axis 125, and thus to disassemble the element 102 of the connector 122. According to one variant, the connector 122 is provided with tongues and the closure means 107 is provided with openings.

The system 101 further comprises a means 131 for rotating the connector 122 about the third axis 123. The means 131 for rotating drive cooperates on the one hand with the connector 122, and on the other hand with a motor. electric drive (not shown). When an element 102 is assembled to the connector 122 and the reversible locking means (128, 129, 130) are activated, the means 131 for driving in rotation makes it possible to pivot the element 102 around the third axis 123 by intermediate connector 122, so as to change an angular position of the plane formed by the photovoltaic cells 119, and thus to follow the change of orientation of sunlight occurring during a day. Preferably, the first axis 103 coincides with the third axis 123, so that the element 102 is rotated about the first axis 102. The connector 122 makes it possible to connect the rotation drive means 131 to the element 102. In the examples shown in Figures 2 and 3, the means 131 for driving in rotation is a rack arranged along a fifth axis (not shown) perpendicular to the third axis 123. The rack 131 cooperates with a toothed wheel 132 disposed according to the third axis 123 and installed on a so-called proximal portion 133 of the connector 122. Preferably, the fifth axis is parallel to the second axis 105. The rack 131 is mounted on a rail 134, preferably aluminum. The rack 131 is for example screwed onto the rail 134. The toothed wheel 132 is integral with the proximal portion 133 of the connector 122. In the illustrated examples, the toothed wheel 132 is first fitted elastically and then welded to the proximal portion 133. of the connector 122, so as to prevent the toothed wheel 132 from pivoting about the third axis 123 relative to the connector 122. Thus, the electric motor drives in translation the rack 131 along the fifth axis which, by meshing the toothed wheel 132, transmits a rotational movement along the third axis 123 to the connector 122. If the connector 122 is assembled to an element 102 and the reversible locking means (128, 129, 130) are activated, the connector 122 transmits the rotational movement according to the third axis 123 to the element 102. Such an embodiment makes it possible not only to have a perfect synchronization of the rotation of the elements 102 of the assembly 104, but also of the to ensure that the rotational speeds of each of the elements 102 of the assembly 104 are equal.

According to one embodiment of the invention, the rack 131 cooperates with the toothed wheel 132 of a single connector 122. According to one variant, the rack 131 cooperates with the toothed wheel 132 of several connectors 122 simultaneously. The system 101 further comprises a hollow support member 135 substantially elongated along the second axis 105. Preferably, all the walls (136, 137, 138, 139, 140, 141) of the support element 135 form a closed interior volume 142, so in particular to prevent the introduction of foreign bodies inside the element 135 support. The interior volume 142 of the support element 135 accommodates the connector 122. More specifically, the interior volume 142 of the support element 135 accommodates the proximal portion 133 of the connector 122. Preferably, the interior volume 142 of the element Support 135 accommodates each of the connectors 122 connected to the first end 108 of the elements 102 of the assembly 104. The internal volume 142 of the support member 135 also accommodates the means 131 for driving in rotation.

In the examples presented in FIGS. 2 and 3, the support member 135 substantially forms a parallelepiped. A volume of the walls (136, 137, 138, 139, 140, 141) of the support member 135 is smaller than the interior volume 142. Thus, heat dissipation in the support member 135 is promoted.

Preferably, the support element 135 is made of aluminum. Preferably, the support element 135 has a plane of symmetry disposed substantially perpendicular to the third axis 123. The support element 135 comprises a first wall 136 disposed substantially perpendicular to the third axis 123. The first wall 136 has an opening 143 arranged along the third axis 123. The opening 143 accommodates the proximal portion 133 of the connector 122. In the examples shown in Figures 2 and 3, the opening 143 is circular. Preferably, the first wall 136 has an opening 143 for each of the connectors 122 connected to the first end 108 of the elements 102 of the assembly 104.

In the examples presented in FIGS. 2 and 3, the support element 135 further comprises a second wall 137 disposed substantially perpendicular to the third axis 123. The second wall 137 has an opening 144 disposed along the third axis 123, able to accommodate the proximal portion of another connector (not shown), substantially identical to the connector 122, connected to the second end of another solar radiation concentrator element and electric power generator. The term "other solar radiation concentrator element and electric energy generator" means an element identical to an element 102, disposed along an axis substantially parallel to or coincident with the first axis 103, opposite an element 102 relative to to the second axis 105. The other element may for example be part of another set defined in the same way as the assembly 104. In the examples shown in Figures 2 and 3, the opening 144 is circular. Preferably, the second wall 137 has an opening 144 for each of the other connectors connected to the second end of the other solar radiation concentrator elements and electrical energy generator of the other set. In the examples presented in FIGS. 2 and 3, the support element 135 also comprises a central wall 145 substantially perpendicular to the third axis 123 and disposed between the first wall 136 and the second wall 137. Preferably, the central wall 145 is substantially disposed along the plane of symmetry of the support member 135. The central wall 145 makes it possible, on the one hand, to form a stop to the translation of the connector 122 along the third axis 123, and on the other hand to increase the mechanical inertia of the support element 135, so as to prevent the Support member 135 collapses under the weight of elements 102 of assembly 104. Central wall 145 splits interior volume 142 of support member 135 into two sub-volumes (146, 147) isolated from each other. the other. One of the sub-volumes 146 accommodates the proximal portion 133 of the connector 122 and the means 131 for rotating, and the other of the sub-volumes 147 is adapted to receive the proximal portion of the other connector. The central wall 145 is particularly useful when one or more openings (143, 144) in the first or second wall (136, 137) do not receive a connector. The central wall 145 makes it possible to isolate one of the sub-volumes (146, 147) of foreign bodies, such as for example sand, which would have been introduced into the other of the sub-volumes (147, 146) by the openings (143, 144) not receiving a connector. In the example shown in FIG. 2, the connector 122 and the other connector are traversed right through by an opening 148 disposed along the third axis 123, communicating respectively with the opening 1181 formed in the distal portion 111 of the means 107 closing the first end 108 of an element 102 and the distal portion of the closure means forming the second end of another element. Preferably, the opening of the other connector accommodates the electrical cables emerging from another element through the opening formed in the distal portion of the closure means forming the second end of the other element. Thus, the sub-volume 147, housing the proximal portion of the other connector, also accommodates the electrical cables leaving the opening in the proximal portion of the other connector, so that the electrical cables are not likely to interfere. the rotational drive of the connector 122. The support element 135 comprises a third removable wall 138 disposed substantially perpendicular to a sixth axis 149, substantially perpendicular to the second and third axes (104, 123). The first and second walls (136, 137) of the support member 135 are adjacent the removable third wall 138. In the examples presented in FIGS. 2 and 3, the third removable wall 138 and the first wall 136 are provided with resilient interlocking means (150, 151) cooperating with each other, and the third removable wall 138 and the second wall 137 are provided with means (152, 153) resilient interlocking cooperating with each other. The means (150, 151, 152, 153) are able to fit one into the other at the end of a translation assembly along the sixth axis 149, the third removable wall 138 and the first and second walls (136). , 137). In the examples presented in FIGS. 2 and 3, tabs (154, 155) extend from a fourth wall 139, substantially parallel to the third removable wall 138, in the extension of the first and second walls (136, 137). ). The application of a force tending to bring the tabs (154, 155) closer to each other makes it possible to disengage the means (150, 152) of resilient interlocking of the third wall 138 which are removable from the means ( 151, 153) resilient interlocking of the first and second walls (136, 137) respectively, to remove the third removable wall 138. In the examples shown in Figures 2 and 3, the rack 131 bears against the third wall 138 removable via a means 156 of elastic compression. More specifically, the rail 134 on which the rack 131 is mounted is in abutment against the third wall 138 removable via a means 156 of elastic compression. The rail 134 makes it possible to add inertia to the rack 131. The third removable wall 138 compresses the elastic compression means 156 in the direction of the rail 134, so as to ensure the contact between the rack 131 and the toothed wheel 132. In the example shown in FIG. 2, the third removable wall 138 is further provided with a first projecting element 157 cooperating with a groove 158 formed in a so-called median portion 159 of the connector 122.

The first element 157 protruding is able to lock the connector 122 in translation along the third axis 123 and in rotation along the second axis 105. In the example, the first element 157 projecting extends substantially parallel to the sixth axis 149, in the direction of the connector 122. In the example shown in FIG. 3, the median portion 159 of the connector 122 is able to form, with the distal portion 110 of the closure means 107 forming the first end 108 of an element 102, the groove 158. when the connector 122 and the element 102 are assembled. According to one embodiment of the invention, the groove 158 of each of the connectors 122 connected to elements 102 of the assembly 104 or formed by each of the connectors 122 and elements 102 cooperates with a first separate salient element 157. According to one variant, the groove 158 of several of the connectors 122 connected to elements 102 of the assembly 104 co-operates with the same first element 157 projecting. In the examples presented in FIGS. 2 and 3, the third removable wall 138 is further provided with a second projecting element 160 capable of cooperating with a groove formed in the median part of another connector or formed by the middle part of another connector and the distal portion of the closure means of the other element assembled to the other connector. The second salient element 160 is able to lock in translation and in rotation the other connector along the third axis 123. In the examples, the second salient element 160 is substantially identical to the first element 157 projecting. The orientation system 101 allows an easy and quick replacement of an element 102. Such a replacement operation firstly requires deactivating the reversible locking means (128, 129, 130) and then displacing the element 102. in translation along the third axis 123 or the fourth axis 125, according to the embodiment of the invention chosen, so as to disengage the element 102 from the connector 122. The element 102 can then be repaired and reconnected to the connector 122 or simply replaced by a new element 102. The element 102 is then positioned so that the first axis 103 is coincident or parallel with the third axis 123. Then, the element 102 is displaced in translation along the third axis 123 or the fourth axis 125, so as to come to fit the connector 122. Finally, the reversible locking means (128, 129, 130) are activated, so as to ensure the transmission of the rotational movement according to the third axis 123, of the rack 131 to the element 102.

Claims (13)

CLAIMS1.- System (101) for orientation of a device (100) of solar energy capture comprising at least one element (102) solar energy sensor, said orientation system comprising: - a connector (122) disposed along a first axis (123), the connector being able to cooperate with the at least one solar energy sensor element, the connector being provided with reversible locking means (128, 129, 130) for the sensor element of solar energy relative to the connector; - means (131) for rotating the connector along the first axis. 2.- System according to claim 1, wherein the reversible locking means (128, 129) are able to activate or be activated, after an assembly of the element (102) solar energy sensor and the connector (122), by translation along the first axis (123). 3.- System according to claim 1, wherein the reversible locking means (130) are able to activate or to be activated, after an assembly of the element (102) solar energy sensor and the connector (122), by translation along a second axis (125), perpendicular to the first axis (123). 4.- System according to one of claims 1 to 3, comprising a hollow support member (135) forming a closed internal volume (142), inside which is disposed the means (131) for driving in rotation of the connector (122) along the first axis (123) and the connector. The system of claim 4, wherein the support member (135) has a removable wall (138). 6. The system of claim 5, wherein the removable wall (138) is disposed substantially perpendicular to a third axis (149), perpendicular to the first axis (123), the removable wall being provided with means (150, 152) of resilient interlocking cooperating with resilient interlocking means (151, 153) of walls (136, 137) of the support member adjacent thereto, said means being adapted to engage each other at the end of an assembly by translation along the third axis, of the removable wall and adjacent walls. 7. The system of claim 6, wherein tabs (154, 155) extend in the extension of the walls (136, 137) adjacent to the wall (138) removable, in a direction opposite to the removable wall. 8.- System according to claim 6 or claim 7, wherein the connector (122) comprises a groove (158) cooperating with a member (157) projecting from the wall (138) removable, the projecting element being able to block the connector, in translation along the first axis (123) and in rotation along a fourth axis (105), perpendicular to the first and third axes (123, 149). 9.- System according to one of claims 4 to 8, wherein the support member (135) comprises a wall (145) central separating the volume (142) inside two isolated sub-volumes (146, 147) l one of the other, one of the sub-volumes hosting the connector (122) and the means (131) for rotating drive. 10.- System according to one of claims 4 to 9, comprising another connector disposed along an axis substantially parallel or coincident with the first axis (123), inside the volume (142) closed of the element (135). ), the other connector being adapted to cooperate with another solar energy sensor element of another solar energy collection device, the other connector being provided with reversible locking means of the other sensor element of solar energy compared to the other connector. 11.- System according to one of the preceding claims, wherein the means (131) for rotating the connector is a rack arranged along a fourth axis (105), substantially perpendicular to the first axis (123), the rack cooperating with a toothed wheel (132) integral with the connector (122) and arranged along the first axis. 12.- System according to claim 11, wherein the rack (131) bears against the support member (135) via means (156) elastic compression. 13.- connector (122) for system (101) orientation according to one of claims 1 to 12.