FR2544474A1 - Solar-collector reflector - Google Patents

Abstract

The invention relates to a solar-collector reflector comprising a rigid shell covered with a reflecting surface and fixed on a support structure, the rigid shell consisting of an assembly of attached polygonal elements 22. According to the invention, the shell elements 22 are equipped, along each of their rectilinear sides, with an edge 4 which is turned down in a direction transverse to the bottom 3 of the element and the height h of which, at at least two bearing points 44 which are separated from one another, is equal to the theoretical distance between the side 23 of the polygonal bottom and the corresponding part 11 of the support structure, taking into account the position of the element considered in the shell as a whole.

Description

Solar collector reflector
The subject of the invention is a solar collector reflector which can be used in particular for producing solar collectors having a reflecting surface of several square meters.

 It is known that a solar collector comprises a reflector which collects the light rays and concentrates them towards an absorption member consisting for example of a boiler and placed at its focus. For the energy captured to be appreciable, the reflector must have a relatively large surface area, of the order of several square meters for example. In addition, the reflector is preferably oriented permanently in the direction of the sun. A solar collector reflector therefore normally comprises a rigid shell covered with a reflective surface and fixed on a support structure which can itself be carried by a base by means of a universal joint and connected to means of orientation to maintain the axis of the reflecting surface in the direction of the sun during the day.

 The support structure must therefore have the shape of a cap substantially enveloping the profile of the reflecting surface. In addition1 it must remain rigid whatever its orientation. It can be constituted in any known manner, in particular in metal construction and for example in mechanically welded construction. However, it can also, advantageously, be constituted by an assembly of straight bars intersecting and connected by nodes so as to form a crosslinked assembly which is both rigid and light.

 The support shell of the reflecting surface must also be rigid so as to retain its curvature and it generally consists of a set of elements of polygonal shape chosen so that the elements can be joined together along their rectilinear sides to form a surface having the desired shape. For example, the shell elements may have the shape of substantially equilateral triangles, but other assemblies of polygonal elements can be envisaged.

 The realization of a solar collector poses a certain number of problems. First of all, it is obviously necessary that the support structure and the shell elements are rigid enough to keep the desired shape over time. But the whole should not be too heavy so as not to hinder the orientation and tire the mechanisms. Moreover, solar collectors are often built in isolated, even deserted places, and they must therefore preferably be in the form of removable elements, light enough to be able to be manipulated and assembled on site possibly by hand.

 In addition, the positioning of the shell elements must be carried out fairly precisely if one does not want to reduce the performance of the sensor.

 The invention relates to a new solar collector reflector consisting of elements which can be easily assembled and precisely positioned on a support structure. The invention also has other advantages which will be mentioned during the following description.

 According to the invention, the shell elements are provided along each of their rectilinear side, with an edge folded in a direction transverse to the bottom of the element and the height of which, in at least two spaced apart support points one from the other, is equal to the theoretical distance between the side of the polygonal bottom and the corresponding part of the support structure, taking into account the position of the element considered in the whole of the shell.

 In a preferred embodiment, the structure being constituted by an assembly of intersecting rectilinear bars directed in the directions of at least part of the shell elements and forming a reticulated assembly made up of contiguous triangles themselves formed of three external triangular elements surrounding a central element, the external elements are each supported on two bars of the structure by two folded edges provided with support points and the three folded edges of the central element are joined and fixed each to the third edge of each of the elements surrounding him.

 In this case, each shell element is advantageously fixed to the corresponding bars of the assembly by collars each passing around the bar and in an orifice formed on the folded edge.

 In a preferred embodiment, each shell element comprising the polygonal bottom and the folded edges consists of a single block of molded material. The heights of the edges at the support points being obtained by adjusting the mold before casting. In a first embodiment, the support points consist of short spans formed along each edge and whose height relative to the side of the polygonal bottom is adjusted with precision after demolding.

 In another embodiment, the position of each element of each shell element is adjusted with precision after the positioning of the element by interposing shims of thickness tight between the bar and the support points of the edge of the item.

 The invention will be better understood from the following description of a particular embodiment, given by way of example and shown in the accompanying drawings.

 Figure 1 is a partial perspective view of a solar collector reflector according to the invention.

 Figure 2 is a top view of a shell element.

 FIG. 3 is a side view along line III in FIG. 2.

 FIG. 4 is a side view along IV of FIG. 2.

 FIG. 5 is a partial view in cross section along V of FIG. 2.

 FIG. 6 is a partial view in cross section along VI of FIG. 2.

 In Figure 1 there is shown schematically in perspective, half of a solar collector support structure consisting of an assembly of straight bars. Such a support structure, shown in the figure by way of example, is the subject of patent application No. 81-23156 filed on December 11, 1981 by the same company, but other assemblies are possible.

 We see that, in this embodiment, the support structure 1 has1 on the side of the reflecting face, a concave face constituted by bars 11 and whose curvature is as close as possible to that which must be given to the reflective surface. In the example shown, the bars 11 form contiguous triangles such as 12 and 13. The rigid shell (2) could consist of triangular elements of shape corresponding to triangles 12 or 13 and resting by their sides on the bars 11. However, if it is desired that the power of the sensor is not too low, it must have an area of several square meters, which would result in giving the corresponding shell elements dimensions too large to be handled by a single man. This is why, it is preferred to cover each triangle 12 or 13 of the support structure with a set of four triangles joined along their edges, a central triangle 21 and three external triangles 22.

 The triangles 12 and 13 have substantially the shape of equilateral triangles, but only in an approximate manner taking into account the concavity of the sensor and therefore of the support structure. The lengths of the bars il which constitute the sides of each triangle therefore depend on the position of the latter in the assembly.

 Likewise, as shown in FIG. 1, the edges of each of the elements 21, 22, which correspond to cuts made in the reflecting surface 20 by vertical planes passing through the bars 11 or parallel to them. , are formed by curves such as 23 which deviate more or less from the corresponding bar depending on the position considered. The sensor however has a certain number of symmetries and that is why, to each element 21 22 of the hull , correspond to identical elements placed at a homologous location in the sensor. It can be seen that the shell will therefore consist of a certain number of types of triangular elements, even as the support structure consists of a certain number of bars. different lengths.

 It is also possible to calculate for each triangular toque element the theoretical distance which separates each point from a bar such as 14 on which it rests, from the corresponding edge 23 of the reflecting surface.

 In addition, an external triangular element such as 22 is supported along two sides on the corresponding bars 11 and is joined along its third side to the corresponding side of the central element 21 which cannot itself press on the bars only by its vertices or else is simply fixed by its edges on the triangular elements 22 which surround it.

 In Figure 2, there is shown in top view by way of example, an external element 22. This is advantageously made of molded material and comprises, according to the invention, a concave bottom 3 and, along on each of its straight sides, three edges 4 which are folded in a transverse direction at the bottom 3, as seen in particular in FIGS. 5 and 6.

 Two of the edges 4 'and 42 of the element are directed along bars 11 of the support structure while the third side 43 extends only from one bar to the other between the vertices of the triangle. One of the sides 42 has been shown from the front in FIG. 3 and in cross section in FIG. 5. It can be seen in this figure that the edge 42 is folded down in a direction substantially perpendicular to the bottom 3, chosen so that the outer face of the folded edge 42 is placed in a plane passing substantially through the axis of the bar 11. This plane is inclined by a few degrees relative to the theoretical plane P passing through the axis 110 of the bar 11 and the focus of the sensor so that the folded edges 421, 422 of two neighboring elements 22 are separated by a slight gap of width e which facilitates their positioning.

 As seen in Figure 3, the height h of each point of the edge 31 of the element relative to the bar 11 varies from one vertex to the other of the element depending on the position of the point considered. According to one of the characteristics of the invention, the triangular element is advantageously made of molded material, which allows the bottom 3 and the folded edges 4 to be produced as a block by adjusting the heights of the walls at the time of casting. of the mold so as to give the height h the desired variation from one vertex to another. This can be easily obtained by known techniques in molding, for example by means of cores of desired shapes, or alternatively, by giving the mold an inclination corresponding to the variation in the height of molding.

 It is thus possible, in a first embodiment, to obtain an approximate height h substantially equal to the theoretical height, the precise height being adjusted by a slight machining.

 However, it is not necessary that the edge 42 rests over its entire length on the corresponding bar 11 and this is why, advantageously, at least two bearing surfaces 44 of length are provided along the edge 42 reduced so as to decrease the adjustment.

 At the height of each bearing surface 44 are formed in the edge 42 of the holes 45 which allow, as can be seen in FIG. 5, to easily fix the shell elements on the corresponding bar 11 by clamps 15 passing in holes 45.

 By tailors, the precise positioning of the element 22 relative to the bar 11 can also be ensured by means of shims 46 which are interposed between the bearing surfaces 44 and the bar 11 and therefore makes it possible to adjust the height h precisely.

 The third edge 43 of the element 22 could bear at its ends on the bars 11 but the positioning of the element 22 is sufficiently ensured by the two edges 41 and 42, as shown in FIG. 4. However, the third edge 43 must maintain the central element 21 and this is why, as shown in FIG. 6, the folded edge 43 is provided at its base with a rib 47 on which can come s 'Support the corresponding edge 48 of the central element 21. In this way, it is perfectly supported by the three ribs 47 of the elements 22 which surround it. In addition, as previously, orifices 45 are formed in the folded edges' and joined 43 and 48 to allow the passage of fastening elements such as bolts 16 which join the two elements together.

 The bottom 3 of each element has a concave profile, the curvature of which depends on the position of the element in the shell and the reflecting surface advantageously consists of an assembly of small mirrors generally of triangular shape and glued to the background.

 Shell elements had already been made from molded material and until now, a plastic material or a laminated material had been chosen.

 The moldable materials used so far have several drawbacks. First of all, the hull thus produced is not always very rigid. But above all, we found that moisture could slip over time between the mirror and the hull and stagnate there. Both surfaces are airtight. I1 results in a risk of deterioration of the silvering of the mirror over time. This is why we have been led to seek to constitute the molded shell another material which does not have this drawback.

 In a particularly advantageous embodiment, each shell element is formed by molding a product consisting of fibers capable of hanging between them and embedded in a binder permeable to air. Such a product consists for example of a fiber cement, the fibers being asbestos and the binder being cement.

 A shell thus constituted has a set of qualities which are not found in the materials used until now for this application.

 We first of all know that asbestos-cement makes it possible to produce fairly light and sufficiently rigid shells by molding and very economically.

 It is also found that asbestos-cement has the property of having a coefficient of expansion close to that of the mirror and in addition of constituting a surface very suitable for bonding of the mirror by an adhesive. In addition, this product is perfectly rot-proof and very resistant to bad weather.

 It should also be noted that asbestos-cement behaves better over time than most synthetic materials, which exposure to ultra-violet rays can make brittle.

 Thus, thanks to this set of qualities, asbestos cement would already be suitable for constituting a rigid shell retaining the shape of the reflective surface for a long period of time in the open air.

These qualities are due in particular to the solidity and the excellent bonding between them of asbestos fibers. But in addition, the cement which constitutes the binder between the fibers has the additional advantage of being permeable to air. As a result, an asbestos-cement shell, in addition to its rigidity qualities, has the advantage of allowing the evaporation of moisture which could have slipped between the shell and the mirror. Thus the quality of the silvering is maintained for much longer.

 The shell element according to the invention therefore has all the qualities required to constitute a solar collector reflector, but the invention is not limited to the details of the embodiment which has been described.

 This is how the support structure can obviously be of a different type, other arrangements being able to be imagined to constitute a concave cap. Similarly, the shell elements could have other shapes, for example hexagonal.

Claims (9)

REVENDIC TIO S  1. Solar collector reflector comprising a rigid shell (2) covered with a reflective surface (20) and fixed on a support structure (1), the rigid shell consisting of a set of elements (21, 22J having each a bottom (3) of polygonal shape and joined along their rectilinear sides, characterized in that the shell elements (21, 22> are provided, along each of their rectilinear sides with a folded edge in a transverse direction at the bottom (3) of the element and the height (h) of which, at least two support points (44) spaced from each other, is equal to the theoretical distance between the side (23 ) of the polygonal bottom and the corresponding part (11) of the support structure (1) taking into account the position of the element (21, 22) considered in the whole of the shell (2).  2. Reflector according to claim 1, characterized in that the support structure being constituted by an assembly of intersecting straight bars (11), directed in the directions of at least a part of the sides of the shell elements and forming an assembly crosslinked consisting of contiguous triangles and each triangle (12, 13) itself being formed of three external triangular elements (22) surrounding a central element (21) the external elements (22) are each supported on two bars (11) of the support structure (1) by two folded edges (42) provided with support points (44) - and the three folded edges (48) of the central element are joined and each fixed to the third edge (49) of- each of the elements that surround it.  3. Reflector according to one of claims 1 or 2, characterized in that the shell elements (22) are each fixed to the corresponding bars of the assembly by collars (15) each passing around the bar (11 ) and in two orifices (45) formed on the folded edges (42) of the two elements.  4. Reflector according to one of the preceding claims, characterized in that each shell element (21, 22) comprising the polygonal bottom (3) and the folded edges (4) consists of a single block of molded material, the heights of the edges (4) at the support points being obtained by adjusting the mold before casting.  5. Reflector according to one of the preceding claims, characterized in that the support points are constituted by spans (44) of short length formed along each edge (42) and whose height (h) relative the corresponding side (23) of the polygonal bottom (3) is precisely adjusted after demolding.  6. Reflector according to one of the preceding claims, characterized in that the position of each shell element (21, 22) is adjusted with precision after the positioning of the element by interposition of shims (46 ) clamped between the bar (11) and the support points (44) of the edge (42) of the element.  7. Reflector according to one of the preceding claims, characterized in that the bottom (3) of each element has a concave profile whose curvature depends on the position of the element in the shell and that the reflecting surface (20) consists of an assembly of small mirrors glued to the concave bottoms (3) of the elements (21, 22) of the shell.  8. Solar collector reflector according to one of the preceding claims, characterized in that each rigid shell element (21, 22) is formed by molding a product consisting of fibers capable of hanging between them and embedded in a water permeable binder.  9. solar collector reflector according to claim 8, characterized in that the product forming the rigid shell consists of asbestos fibers bonded by cement.