FR3030022A1 - SOLAR POWER PLANT WITH LINEAR CONCENTRATION COMPRISING A PRIMARY REFLECTOR ASSEMBLY - Google Patents

Abstract

The linear concentration solar power plant comprises a set of so-called primary reflectors (3), such as Fresnel mirrors, integral with a frame (4) and oriented to reflect and focus the solar radiation to a receiver extending longitudinally at the top vertical mats integral with said frame, said receiver comprising at least one absorber tube in which circulates a coolant, a secondary reflector extending above the absorber tube parallel to the latter so as to concentrate the solar radiation from the absorber tube; of the set of primary reflectors. Each primary reflector (3) is at least constituted by a central tube (35) of circular section adapted to bear a plurality of parallel ribs (37) integral with said central tube and extends perpendicularly to said central tube which are supported by mirrors (38), each mirror being secured to at least two successive ribs.

Description

TECHNICAL FIELD The present invention relates to a linear concentration solar power plant and more particularly to a primary reflector for such a linear concentration solar power station.

PRIOR ART In the field of energy production, it is well known thermal solar power plants that are an alternative to power plants operating from fossil fuels such as oil or coal for example. There are several types of solar thermal power plant. The four main plant types are parabolic trough plants, tower plants, parabolic trough plants and Fresnel solar mirror plants. The cylindro-parabolic collector plants consist of parallel rows of long cylindro-parabolic mirrors that rotate around a horizontal axis to follow the course of the sun. The solar rays are concentrated on a horizontal absorber tube, in which circulates a coolant whose temperature generally reaches 400 ° C. This fluid is then pumped through exchangers to produce superheated steam that drives a turbine or electric generator. Tower solar power plants consist of numerous mirrors concentrating the 30 solar rays towards a boiler located at the top of a tower. The uniformly distributed mirrors are called heliostats or primary reflectors. Each heliostat is steerable, and follows the sun individually and reflects it precisely towards the receiver at the top of the solar tower. The concentration factor can exceed 1000, which allows to reach high temperatures, 600 ° C to 1000 ° C. The energy concentrated on the receiver is then either directly transferred to a thermodynamic fluid to generate steam driving a turbine or to heat air supplying a gas turbine, or used to heat an intermediate heat transfer fluid. This heat transfer fluid is then sent to a boiler and the steam generated drives turbines. In all cases, the turbines drive alternators producing electricity. In parabolic power plants, the latter operate autonomously. They automatically orient themselves and follow the sun on two axes in order to reflect and concentrate the sun's rays towards a point of convergence called focus usually consisting in a closed chamber containing gas which is raised in temperature under the effect of the concentration. . This drives a Stirling engine that converts solar thermal energy into mechanical energy and then electricity. The concentration ratio of this system is often greater than 2000 and the receiver can reach a temperature of 1000 ° C. All these types of plant have the disadvantage of being particularly expensive.

The least expensive solar power plants consist of solar power plants known as Fresnel mirrors. Indeed, the latter are similar to parabolic troughs with the exception of the fact that cylindro-parabolic collectors, which are expensive to manufacture, are replaced by a succession of flat mirrors which approximates the parabolic form of the collector. Each of the mirrors can be rotated following the sun's course to constantly redirect and focus the sun's rays to a tube or set of fixed linear absorber tubes. While circulating in this horizontal receiver, the thermodynamic fluid can be vaporized then superheated up to more than 500 ° C. The steam then produced drives a turbine that produces electricity. The thermodynamic cycle is usually direct, which avoids heat exchangers.

Usually, a linear concentration solar power plant comprises a set of mirror modules constituting so-called primary reflectors, in this case Fresnel mirrors, mounted on a fixed frame of the ground so that said mirrors extend in parallel, each line of mirrors comprising a series of several mirrors. This central also comprises a linear receiver supported by a series of masts extending vertically from the central part of the frame so that the linear receiver extends longitudinally over the mirrors which are oriented to reflect and focus the radiation. solar to the linear receiver.

Said linear receiver generally consists of one or more parallel long tubes in each of which circulates a coolant, such as for example water, brought to the vapor state by the focusing of the solar radiation on each tube by the mirrors. It will be noted that the number as well as the size of each of the receiver tubes are determined on the one hand as a function of the characteristics of the coolant and on the other hand as a function of the geometry of the mirrors. The linear receiver receives solar radiation energy in radiative form and converts it into heat energy, which may be used as heat or to generate electricity from a turbo-alternator assembly.

Such solar concentrating solar power plants are in particular described in international patent applications WO 2009/029277 and WO 2012/156624. International patent application WO 2012/156624 describes a solar plant 25 with a linear concentration and a secondary reflector that can be used in such an installation. According to the invention, the installation is characterized in that at least one absorber tube is supported on each of the masts, independently of the secondary reflector, by means of an anti-friction plate secured to the mast transversely to the absorber tube which is bilaterally maintained on the antifriction plate while resting in a notch of this plate. International patent application WO 2009/029277 discloses examples and variants of solar collector systems comprising a raised linear receiver and first and second reflector fields located on opposite sides of the receiver. These reflector fields are designed and controlled to reflect solar radiation on the receiver. Each reflector comprises a support structure on which a reflector element is mounted. The support structure includes a platform-like platform 5 that is supported by a frame frame structure. The frame structure comprises two circular-shaped end elements, the axis of the circles being substantially coincident with the central axis extending longitudinally of the reflector element. The platform comprises a corrugated metal panel and the reflector element is supported on the ridges of the corrugations. The corrugations 10 extend parallel to the direction of the longitudinal axis of the reflector element. A drive system is provided to impart drive of the support structure and, therefore, of the reflector element. The drive system comprises an electric motor having an output shaft coupled to a pinion via a gearbox. The pinion meshes with a chain which cooperates with one of the circle-shaped end members, said end member forming a toothed wheel. Furthermore, the reflector element is formed of a plurality of glass mirrors, a silicone sealant being used to seal the interstices between the mirrors. Said mirrors are fixed on the peaks of the platform by a urethane adhesive. The mirrors having a thickness of about 3 mm, they can be easily bent in situ to match the curvature of the support platform. In general, the primary reflectors are composed mainly of two elements, namely on the one hand a support that can be obtained either in plates of steel sheets folded and assembled together, or in a steel structure, or in a honeycomb structure or in a mechanically welded assembly thus forming a box, and secondly a reflective surface secured to said support. This reflecting surface may be a glass mirror or a polished aluminum plate. The connection of the two elements is usually carried out using adhesive beads. The reflective surface must have a particular curvature in order to concentrate the solar radiation. This curvature can be obtained either by assembling a cold-curved glass mirror to the desired curvature with a flat support, or by using a support having the right curvature and whose upper face is polished aluminum. On the other hand, the primary reflectors must focus solar radiation on the receiver at each instant. In order to keep track of the sun, each of these reflectors is directly linked to a motion transmission shaft. Primary reflectors have many disadvantages. Indeed, the use of mirrors as reflective surfaces considerably increases the weight of the assembly. The support must then be more rigid so as not to deform under the weight of the mirrors. In addition, such cold bent mirrors generate internal stresses to the mirror which result in a force on the upper surface of the supports. The support must then make it possible to preserve the bending of the mirror. As described above, the assembly of the support with at least one mirror is carried out using adhesive beads, said adhesive beads also ensuring the curvature of the mirrors. In addition, the amount of glue used for this assembly is important and is larger than the bending of the mirrors is large. Finally, the assembly of a steel support with a reflecting glass surface causes problems of relative dilation between these two components. The glue must then compensate for this relative dilation. Another disadvantage appears in the method of assembling a support with a glass mirror. Indeed, the manual or automated handling of the mirrors limits their dimensions. On the other hand, the main disadvantage of using polished aluminum as the reflective surface is the low reflectivity compared to that of a glass mirror. The primary reflectors of the prior art also have the disadvantage of requiring a complete change of the support in the event of breakage or damage of the reflecting surface. Indeed, it is impossible to change only a part of the reflective surface, given the glue used. Furthermore, the corrosion of metal supports in contact with moist air or salt air is detrimental, both from the point of view of performance and that of maintenance costs. Finally, the recess connection between the supports, allowing the movement to be transmitted, causes the addition of the respective expansions of each support, resulting in expansions of up to several meters at the end of the line of primary reflectors.

3030022 6 A thermodynamic solar plant with industrial-scale concentration represents a large number of primary reflectors. This element is an important part of this technology. There is therefore a real need to optimize both technically and economically these primary reflectors.

SUMMARY OF THE INVENTION One of the objects of the invention is thus to overcome these drawbacks by proposing that each primary reflector, which comprises a linear concentration solar power plant, is at least constituted of a central tube of circular section. adapted to bear on a plurality of parallel ribs integral with said central tube and extending perpendicularly to said central tube on which mirror supports, each mirror being secured to at least two successive ribs.

According to other features: each rib consists of a folded sheet metal part having a curved plate whose concavity is oriented upwards, a reinforcing wing extending under said plate and having a substantially triangular shape, the apex of the triangle having a substantially semicircular recess bordered by a hemiannular shoulder, the hemi-annular shoulder comprises holes for the passage of screws, said holes being able to extend in line with corresponding holes in the central tube. In order to allow the fixing of the ribs on said tube, - each mirror has a length less than the spacing between at least two consecutive ribs, - the ribs extend at regular intervals along the central tube, the curved plate of each rib comprises means for bonding the mirrors on said ribs, each rib has an arrow between 4 t 6 mm, - the mirrors are made of glass, - each primary reflector comprises a plate) at each end of the central tube.

The solar power plant, according to the invention, is also remarkable in that the receiver consists of a plurality of substantially semicylindrical shells whose concave wall receives a mirror, said mirror consists of a glass mirror whose face 5 rear consists of a reflective silver layer. The receiver comprises stiffeners extending on either side of the hemicellular hulls, said stiffeners consisting of L-shaped pieces whose branches are respectively integral with the outer wall of the semi-cylindrical hulls and the free edge of said hulls, the receiver comprises second stiffeners generally U-shaped whose branches are folded inwards and are integral with the first stiffeners, said second stiffeners being integral with the bar connecting the two arms of the mats. SUMMARY DESCRIPTION OF THE FIGURES Other advantages and features will become more apparent from the following description of several variant embodiments, given as non-limiting examples, of the primary reflector of a linear concentration solar power plant conforming to FIG. 1, a perspective view of a linear concentration solar power plant according to the invention; FIG. 3 is a perspective view of the chassis of the linear concentration solar power plant according to the invention; FIG. 4 is a perspective view of a detail of the chassis; of the linear concentration solar power plant according to the invention, and more particularly of the connection between the base and the mast of said frame, - Figure 5 is a perspective view. In view of a detail of the chassis base of the linear concentrating solar power plant according to the invention, FIG. 6 is a perspective view of the upper end of the mast of the solar power station in linear concentration according to the invention. FIG. 7 is a longitudinal sectional view of a section of the receiver of the linear concentration solar power plant according to the invention; FIG. 8 is a top view of a section of the receiver of the power station; FIG. 9 is a cross-sectional view of the receiver of the linear concentration solar power plant according to the invention, FIG. 10 is a cross-sectional view of a detail of the receiver. of the linear concentration solar power plant according to the invention; FIG. 11 is a perspective view of the anti-reflective canopy of the receiver of the linear concentration solar power station; according to the invention, - Figure 12 is a top view of the anti-reflective canopy of the receiver of the linear concentration solar power plant according to the invention; - Figure 13 is a perspective view from below of a primary reflector; FIG. 14 is a bottom view of a primary reflector of the linear concentration solar power plant according to the invention, FIG. A primary reflector of the linear concentration solar power plant according to the invention - Figure 16 is a longitudinal sectional view of a detail of one of the ends of a primary reflector of the linear concentration solar power plant according to the invention. FIG. 17 is a longitudinal sectional view of a detail of the junction of two mirrors of a primary reflector of the linear concentration solar power plant according to the invention, FIG. 18 is a perspective view of the support of a primary reflector of the linear concentration solar power plant according to the invention; - FIG. 19 is a view from above of the support of a primary reflector of the linear concentration solar power station; According to the invention, FIG. 20 is a side view of the support of a primary reflector of the linear concentration solar power plant according to the invention; FIG. 21 is a perspective view of the tube forming the vertebral column of the support of a primary reflector of the linear concentration solar power plant according to the invention, FIG. 22 is a side view of the means for actuating a plurality of primary reflectors of the linear concentration solar power plant according to FIG. FIG. 23 is a partial perspective view of a primary reflector of the linear concentration solar power plant according to the invention, FIG. 24 is a view of FIG. removed from the variant embodiment of the primary reflector of the linear concentration solar power plant according to the invention, shown in FIG. 23. DETAILED DESCRIPTION OF THE INVENTION In the following description of the primary reflector according to the invention, the same numerical references designate the same elements. In addition, the different views are not necessarily drawn to scale.

With reference to FIGS. 1 and 2, the linear concentration solar thermal power plant is of the Fresnel mirror type and comprises several solar concentration collection fields (1), a so-called production unit (2) comprising means for transforming thermal energy in electricity for example. Each solar concentrating collection field (1) comprises a plurality of primary reflectors (3) 20 integral with a metal frame (4) which concentrate the solar rays on an absorber tube (5) in which a coolant circulates, said fluid coolant consisting of a liquid such as oil, a two-phase mixture such as boiling water or a gas such as air for example. Said absorber tube (5) extends in a secondary reflector (6) integral with the upper ends of vertical mats (7) carried by the frame (4) as will be detailed a little further. The term "primary reflector" means a device for tracking the path of the Sun to direct the sun all day to the absorber tube (5) using mirrors. The primary reflectors (3) are articulated to the frame (4) so as to approximate a parabolic shape. Thus, each of the primary reflectors can be rotated along the path of the sun to continuously redirect and focus the sunlight to the tube (5). With reference to FIG. 3, said frame (4) consists of a plurality of horizontally extending sections (8) parallel to each other and comprising, respectively, legs (9), crosspieces (10) connecting said profiles (8), and vertical mats (11) integral with each profile (8) and constituted respectively of two inclined arms (12) connected by a horizontal bar (13) (FIGS. 3 and 6) to form an inverted V, said bar (13) carrying a receiver as it will be detailed a little further.

In this particular embodiment, the profiles (8), the crosspieces (10), the legs (9) and the verticals (11) are made from metal tubes of square or rectangular section. Furthermore, with reference to FIGS. 3 and 5, each base (9) consists of a post (14) and two arrows (15) extending on either side of said post (14) and whose ends are respectively integral with the profile (8) and the upright (14). In this particular embodiment, the uprights (14) and the arrows (15) are made from metal tubes of square or rectangular section. In addition, the free ends of the arrows (15) comprise U-shaped brackets (16) respectively covering the profile (8) and the upright (14) to which they are secured by means of bolts (17). Such a construction allows a quick and easy modular assembly. Incidentally, with reference to Figure 5, the lower ends of the uprights (14) are provided with a foot (18) comprising a pad (19) providing a better stability of said uprights (14).

Similarly, with reference to FIG. 4, the lower ends of the inclined arms (12) of the mats (11) respectively comprise a stirrup (16) covering the profile (8) to which they are secured by means of bolts (17). . It is obvious that the frame (4) could have a different structure without departing from the scope of the invention. Furthermore, with reference to FIGS. 7 to 10, the receiver (6) consists of a plurality of substantially semicylindrical shells (18) obtained, for example, in cellular glass, the concave wall of each cellular glass shell. (18) receiving a mirror (19). Said mirror (19) consists of a glass mirror whose rear face consists of a reflective silver layer. Said hemi-cylindrical shells (18) are obtained in cellular glass preferably having a density of between 110 and 165 kg / m 3 and a thermal conductivity of between 0.040 and 0.055 W / mK. The formation of each cellular glass shell (18) is obtained by molding or cutting in a cellular glass matrix. Said mirror (19) is preferably obtained by gravitational hot bending of a glass mirror whose rear face consists of a reflective silver layer protected by glass obtained by sintering. Said mirror (19) may, for example, consist of a mirror as described in US Pat. No. 8,585,225 filed by Guardian Industries, or in any equivalent mirror. It will be observed that the use of insulating shells made of cellular glass (18) makes it possible to overcome the metal box allowing the mechanical strength of the receiver. Indeed, the cellular glass is very rigid, in comparison with other insulating materials generally used. This makes it possible to limit the weight of the assembly, its cost, as well as the shadow carried by the receiver on the primary reflectors located below. Unlike mineral wools, cellular glass also has a high water and water vapor tightness, which can form when the air temperature rises under high humidity. The choice of secondary glass reflectors makes it possible to reach higher temperatures without any adverse effect associated with the corrosion of the front face, or with the deformation of the mirrors, unlike the secondary reflectors of the prior art. Moreover, the coefficient of expansion being almost identical between the glass and the cellular glass, the effects of the relative dilation are very strongly limited. Finally, glass mirrors have optical characteristics (reflectivity and specularity) much higher than those of polished aluminum sheets.

Furthermore, the receiver (6) comprises stiffeners (20) extending on either side of the semi-cylindrical hulls (18), said stiffeners (20) consisting of L-shaped parts whose branches are respectively secured to each other. the outer wall of the semi-cylindrical shells (18) and the free edge of said shells (18). It also comprises second generally U-shaped stiffeners (21) whose branches are folded inwards and are integral with the first stiffener (20), said second stiffeners (21) being secured to the bar (13) connecting the two arms (12) of the mats (11) by means of bolts (17).

It will be noted that the receiver according to the invention may be used in a concentrating solar power plant independently of the structure of the frame (4).

With reference to FIGS. 7 to 9, the absorber tube (5) extends into the receiver (6) while resting on a support (22) integral with the bar connecting the upper ends of the inclined arms (12) of the vertical mats. (11). Said support (22) consists of a roller (23) having a cylindrical central body (24) provided with an annular groove (25) so that the contact surface of the absorber tube (5) on the annular groove (25) the roller (23) is reduced to two points and the shafts (26) mounted free to rotate in slots in the legs (27) of a U-shaped yoke (28). Particularly advantageously, the coefficient of friction between the axes (26) of the roller (23) and the stirrup (28) is less than or equal to the coefficient of friction between the roller (23) and the absorber tube (5). For example, the roller (23) and its axes (26) as well as the stirrup (28) are made of stainless steel and / or alumina silicate. In this particular embodiment, the annular groove (25) has a substantially trapezoidal cross section with a flat bottom (29) and two inclined walls (30) on either side of said bottom (29). However, it is obvious that the annular groove (25) may have a substantially semi-circular section whose concavity has a radius of curvature less than the radius of curvature of the absorber tube (5) without departing from the scope of the invention. It will be noted that the invention thus has many advantages. Firstly, the small contact area between the roll (23) and the absorber tube (5) limits the frictional forces between said tube (5) and the roll (23). This low friction reduces the wear of the thin selective layer of the tube (5) during its expansion. In addition, the rotation of the roller allows the free longitudinal expansion of the tube (5). Indeed, the absorber tube (5) is irradiated by the concentrated radiation of the sun; the higher the temperature of its selective layer 30, the more it is sensitive to abrasion. A coolant circulates inside the tube (5), which generates a temperature gradient along its longitudinal axis. By fixing the hot end of the absorber tube (5), the expansion is forced to proceed towards the cold end. The relative movement of the hot part 3030022 13 relative to its support will then be lower, the selective layer on the outer surface of the tube will thus be preserved. Furthermore, it will be observed that the support (22) of the absorber tube (5) according to the invention can be used in a solar power station independently of the structure of the frame (4), in particular regardless of the shape of the masts ( 11). Referring to Figures 7, 9, 10, 11 and 12, the solar power plant according to the invention also comprises anti-reflective panes (31) extending between two mats (11) 10 under the receiver (6). The anti-reflective panes (31) are carried by a metal frame (32) that is substantially rectangular and whose ends are provided with a shoulder (33) adapted to be secured to the bar (13) connecting the two arms (12) of the mats (11). The metal frame (32) is obtained from generally L-shaped metal profile, the base of the L forming a shoulder on which the anti-reflective panes whose edges are provided with an expansion joint are supported. sealing (34). A single metal frame (32) supports a plurality of anti-reflective panes joined in pairs by an expansion and sealing joint (34). With reference to FIGS. 13 to 21, the solar power plant also comprises primary reflectors (3) which consist respectively of a central tube (35) of circular section able to bear on a plurality of parallel ribs (37) integral with said central tube (35), extending perpendicularly to said central tube (35), and on which support mirrors (38), each mirror being secured to at least two successive ribs (37). Each rib (37) consists of a folded sheet metal part having a curved plate (39) whose concavity is oriented upwards, a reinforcing wing (40) extending under said plate (39) and having a substantially triangular shape, the apex of the triangle having a substantially semicircular recess (41) bordered by a hemi-annular shoulder (42). Said hemiannular shoulder (42) has holes (43) for the passage of screws, said holes (43) being able to extend in line with corresponding holes (44) formed in the central tube (35) in order to allow the fixing the ribs (37) on said tube (35). Each mirror (38) has a length just below the spacing between at least two consecutive ribs (37) so that there is between two mirrors (38) a spacing of a few millimeters (Figure 17) ). Preferably, said ribs (37) extend at regular intervals along the central tube (35) and each rib (37) has an arrow of between 4 and 6 mm. Furthermore, the bent plate (39) of each rib (37) comprises means, such as a double-sided adhesive tape (45), for bonding the mirrors (38) to said ribs (37). Said mirrors (38) are advantageously made of glass. Each rib has an arrow of between 4 and 6 mm. Furthermore, each primary reflector (3) comprises at each end of the central tube (35) a plate (46). Each plate (46) has a substantially rectangular shape whose two lower corners are beveled. Each plate is embedded in the free end of the central tube (35). The primary reflectors are interconnected by a transmission shaft, also equipped at each end of a plate, said shaft rests on the rollers (48). In addition, with reference to FIG. 4, each servant (36), on which the transmission shaft is pivotable, consists of a generally U-shaped yoke (47) carrying two rollers (48) mounted free in rotation at the free ends of the arms of the yoke (47), the axes of the rollers (48) extending parallel to the longitudinal axis of the central tube (35) of the primary reflector (3).

In order to simultaneously drive several primary reflectors (3), with reference to FIG. 22, the solar power plant according to the invention comprises a rod (49) hinged, on the one hand, to the free ends of arms (50) integral respectively a plate (46) of a primary reflector (3) and, secondly, a cylinder (51) hinged to the frame (4), and more specifically to an amount (14) of the base (9) of the built (4). The arms (50) integral with the plates (46) are articulated to the rod (49) so that the mirrors (38) of each primary reflector (3) extend at a different angle relative to the horizontal. According to an alternative embodiment of the solar power plant according to the invention, with reference to FIGS. 23 and 24, the latter comprises primary reflectors (3) which consist respectively of a profiled support (52) made of composite pultrusion comprising a concave upper wall (53), a convex lower wall (54) and longitudinal struts (55) connecting the concave upper wall (53) to the convex lower wall (54). A mirror (38) of organic polymer, composed of a stack of thin layers including a thin layer of silver allowing excellent reflectivity, is adhered to the upper face of the concave upper wall (53) of the shaped support (52). ) by means of adhesive strips (56), thus leaving the possibility of simply taking off the mirrors if necessary. Furthermore, at each end of the profiled support 5 (52) is fixed a reception plate (57), also composite, made by SMC molding. This reception plate (57) is embedded in the central portion of said profiled support (52) and comprises a cradle (58) substantially semi-cylindrical whose opening is oriented downwards and in which is adapted to extend a integral axis of the frame (4) to allow the rotation of the primary reflector (3), once assembled with a transmission shaft. Said receiving plate (57) also allows a longitudinal translation of the support, in order to locally tolerate the expansion of the primary reflector (3) without influencing the adjacent primary reflectors. It will be appreciated that, by its shape, the shaped support (52) resists bending under its own weight, resists torsion during solar tracking, and has sufficient inertia to combat the dynamic forces of wind gusts. The material used for this shaped support (52) is a composite of long glass fibers and thermosetting resin. This manufacture makes it possible to reduce the weight of the assembly and to reduce the production costs, while ensuring a mechanical maintenance and an essential precision in the optical field. It goes without saying that the glass fibers may be substituted by carbon fibers or polyethylene without departing from the scope of the invention.

Furthermore, it should be noted that this invention may also be used in the technology of parabolic troughs also as a primary reflector, where the shape of the support will be adapted to this technology. In addition, it is conceivable to use this invention as a receiver element in low temperature Fresnel technology. The composite support associated with a reflective surface of organic polymer may then form a secondary reflector for the purpose of increasing the optical efficiency of the system.

Finally, it is obvious that the examples which have just been given are only particular illustrations and in no way limiting as to the field of application of the invention.

Claims (21)

CLAIMS1 - Linear concentration solar power plant comprising a set of so-called primary reflectors (3), such as Fresnel mirrors, integral with a frame (4) and oriented to reflect and focus the solar radiation to a receiver extending longitudinally to top of vertical mats integral with said frame, said receiver comprising at least one absorber tube in which circulates a coolant, a secondary reflector extending above the absorber tube parallel to the latter so as to concentrate the solar radiation towards the absorber tube from the set of primary reflectors, characterized in that each primary reflector (3) is at least constituted by a central tube (35) of circular section able to bear a plurality of parallel ribs (37) integral with said central tube and extending perpendicularly to said central tube supported by mirrors (38), each mirror so integral with at least two successive ribs. 2 - solar power station according to claim 1, characterized in that each rib (37) consists of a folded sheet metal part having a curved plate (39) whose concavity is oriented upwards, a reinforcing wing (40) extending under said plate (39) and having a substantially triangular shape, the apex of the triangle having a substantially semicircular recess (41) bordered by a hemi-annular shoulder (42). 3 - solar power plant according to claim 2 characterized in that the hemi-annular shoulder (42) has holes (43) for the passage of screws, said holes being adapted to extend in line with corresponding holes (44) practiced in the central tube (35) to allow the ribs (37) to be attached to said tube (35). 4 - solar power plant according to any one of claims 1 to 3 characterized in that each mirror (38) has a length less than the spacing between at least two consecutive ribs (37). 5 - solar power plant according to any one of claims 1 to 4 characterized in that the ribs (37) extend at regular intervals along the central tube (35). 3030022 18 6 - solar power plant according to any one of claims 2 to 5 characterized in that the bent plate (39) of each rib (37) comprises means for bonding the mirrors on said ribs. 5 7 - solar power plant according to any one of claims 1 to 6 characterized in that each rib (37) has an arrow of between 4 and 6 mm. 8 - solar power plant according to any one of claims 1 to 7 characterized in that the mirrors (38) are glass. 9 - solar power plant according to any one of claims 1 to 8 characterized in that each primary reflector (3) comprises a plate (46) at each end of the central tube (35). 15 10 - solar power plant according to claim 9 characterized in that each plate (46) is embedded in the free end of the central tube. 11 - solar power plant according to any one of claims 9 or 10 20 characterized in that it comprises a rod (49) articulated on the one hand to arms (50) integral respectively a plate (46) d a primary reflector (3) and, secondly, a cylinder (51) hinged to the frame (4). 12 - solar power plant according to claim 11 characterized in that the arms (50) integral with the plates (46) are articulated to the rod (49) so that the mirrors (38) of each primary reflector (3) s' extend at a different angle to the horizontal. 13 - solar power plant according to any one of claims 1 to 12 characterized in that each servante (36) with rollers consists of a stirrup (47) generally U-shaped carrying two rollers (48) mounted free in rotation at the free ends of the arms of the stirrup (47), the axes of the rollers extending parallel to the longitudinal axis of the central tube (35) of the primary reflector (3), said primary reflectors being connected to each other by a shaft of transmission which rests on said rollers (48). 3030022 19 14 - solar power station according to any one of claims 1 to 13 characterized in that the frame (4) consists of a plurality of profiles (8) extending horizontally, parallel to each other and respectively comprising legs ( 9), crosspieces (10) connecting said profiles (8), and vertical mats 5 integral with each profile and constituted respectively of two inclined arms (12) connected by a horizontal bar (13) to form an inverted V, said bearing bar the receiver. 15 - solar power station according to claim 14 characterized in that each base (9) consists of an upright (14) and two arrows (15) extending on either side of said upright and whose ends are respectively secured to the profile (8) and the upright (14). 16 - solar power plant according to any one of claims 1 to 15 characterized in that the receiver (6) consists of a plurality of substantially semi-cylindrical shells (18) 15whose the concave wall receives a mirror (19). 17 - solar power station according to claim 16 characterized in that said mirror (19) consists of a glass mirror whose rear face consists of a reflective silver layer. 20 18 - solar power station according to any one of claims 16 or 17 characterized in that the receiver (6) comprises stiffeners (20) extending on either side of the semi-cylindrical shells (18), said stiffeners consisting in parts L whose branches are respectively integral with the outer wall of the semi-cylindrical shells (18) and the free edge of said shells. 19 - solar power station according to claim 18 characterized in that the receiver (6) comprises second stiffeners (21) generally U-shaped whose branches are folded inwardly and are integral with the first stiffeners, said second 30 stiffeners being integral with the bar (13) connecting the two arms (12) of the mats (11). 20 - solar power station according to any one of claims 14 to 19 characterized in that it comprises anti-reflective panes (31) extending between two mats under the receiver. 3030022 20 21 - solar power plant according to claim 20, characterized in that the anti-reflective glass panes (31) are carried by a metal frame (32) which is substantially rectangular and whose ends are provided with a shoulder (33) capable of being secured to the bar (13) connecting the two arms (12) of the mats (11).