FR2736990A1 - Portable Support Structure for Solar Panels - has vertical tubular rod with upper circular attachment and rotating support strut - Google Patents

Abstract

The structure has a vertical tubular section (3) which is mounted (30,31) in the ground. The upper part of the section has a circular attachment. A handle like structure fits onto the circular piece, and can rotate through 90 degrees and be locked in a required position. The upper part of the handle has the solar panel (15) mounted on it, so that the solar panel can be moved and locked anywhere between a vertical and a horizontal position.

Description

Support especially for solar panels
The present invention relates to a support in particular for solar panels.

 The solar panels are fixed on a suitable support which is itself fixed on the ground or on a construction. The orientation of the solar panels is fixed once and for all depending on the geographic location of the support. In other words, the position of the solar panels on the support is fixed.

 Supports of different sizes are suitable for different sizes of solar panels.

 In addition, the known supports for solar panels have a large footprint, wind resistance and low rigidity, which limit their installation in easily accessible and protected places.

 The present invention aims to provide a support in particular for solar panels adaptable to different sizes of solar panels by means of which the solar panels can be oriented in a lockable manner relative to the ground, which makes it possible to use the same support for solar panels. , whatever the season and whatever the geographic location of the solar panels.

 To this end, a support in particular for solar panels according to the invention is characterized in that it comprises a support structure inscribed substantially in a convex polyhedron and having a base supporting the solar panels, a foot, and an articulation between a top of the supporting structure and an upper part of the foot for rotating the angular supporting structure around an axis of rotation substantially perpendicular to the foot.

 According to a preferred embodiment of the invention, the joint is easily mounted and dismountable by means of two pairs of coaxial rings on the axis of rotation. Each pair of crowns comprises a fixed crown which is fixed against a respective one of two opposite faces of the upper part of the base and a mobile crown which is linked to the top of the support structure. The fixed and mobile crowns of each pair have opposite toothed faces which mesh with one another.

 The toothed faces of the crowns are teeth with a substantially trapezoidal, or sinusoidal, or round profile extending circularly around the axis of rotation. This type of profile allows both a rotation of the movable crowns in front of the fixed crowns, and a temporary locking in rotation at the desired inclination of the solar panels.

 The axis of rotation comprises a rod integral with the movable crowns and mounted for rotation in the fixed crowns and the upper part of the base, in order to preserve the longevity of the axis of rotation.

 Preferably, the fixed crown of one of the pairs of crowns and the movable crown of the other pair of crown have teeth on their toothed faces aligned in respective radial planes.

 After a change of position by rotation of 1800 of the support structure around the foot, this characteristic offers in practice angular positions of the support structure with a pitch equal to half the angular pitch of rotation of the support structure around the axis of the joint.

 The base of the support structure can rotate around the axis of rotation between a substantially horizontal position and an inclined position of at least 700 relative to the horizontal, in angular steps between 50 and 100 approximately, for example 50 in 50, or 100 in 100.

 According to a preferred embodiment, the support structure is substantially inscribed in a pyramid and is formed by a tube developed and bent along substantially six edges of two opposite faces of the pyramid. This structure is thus light but resistant to the wind, while being space-saving compared to the ground thanks to its top directed downwards.

Preferably, the top of the support structure is formed by two parallel U-bends against the internal peripheries of which half-edges of the movable rings are respectively fixed.

Other characteristics and advantages of the present invention will appear more clearly on reading the following description of several preferred embodiments of the invention with reference to the corresponding appended drawings in which
- Figure 1 is a schematic perspective view from the front substantially from below of a support according to the invention supporting solar panels
- Figure 2 is a vertical side view of the support, with rails for supporting the solar panels in a horizontal position
- Figure 3 is a vertical front view of the support of Figure 2
- Figure 4 is a top view of the support of Figure 2
- Figure 5 is a front axial sectional view taken along the line VV of Figure 4, but on a larger scale of a cylindrical articulation in the upper part of a foot of the support according to the invention
- Figure 6 is a partial view in axial section from above of the cylindrical joint with threaded assembly rod taken along the line
VI-VI of figure 5
- Figure 7 is a top view partially in section of the cylindrical joint in the upper part of the support leg without threaded assembly rod
- Figure 8 is a front view of the cylindrical joint without threaded assembly rod and movable toothed crown;
FIG. 9 is a front view in axial section taken along the line IX-IX of FIG. 5 of the upper part of the column,
- Figure 10 is a toothed front view of a crown of the joint shown in Figure 5
- Figure 11 is an axial sectional view of a ring gear taken along the line XI-XI of Figure 10; and
- Figure 12 shows in detail a trapezoidal type of teeth of a crown.

 Referring to Figures 1 to 4, a support for solar panels according to the invention comprises a pivotable structure 1 carrying solar panels 2, a fixed column-shaped foot 3, and a cylindrical joint 4 between an upper end of the column 3 and a lower top of the supporting structure 1. The main elements 1, 3 and 4 of the support are for example made of iron or stainless steel.

 The supporting structure 1 is essentially constituted by a bent tube having ends fitted one inside the other and connected by cross bolt. The tube is substantially developed along the six edges of two opposite lateral faces 10-11-12 and 10-13-14, equilateral or isosceles, of a regular pyramid with a rectangular or square base. Thus the supporting structure 1 has two upper parallel sections of pyramidal base 10 and four identical sections of pyramidal face 11 converging towards the lower vertex of the pyramid.

 Two parallel rails 15 and 16 are welded perpendicularly to the ends of the upper sections 10. The solar panels 2 are fixed in known manner to the rails 15 and 16.

 The supporting structure 1 is capable of supporting solar panels of various sizes up to approximately 4 m2. The supporting structure 1 is articulated above the ground S on the column 3 according to the illustrated embodiment, or on a beam, a bracket or the like according to other embodiments.

 For example, for rails 15 and 16 of length L = 2700 mm and spaced 690 mm covered largely by a set of solar panels 2 as shown in Figure 1, the base of the pyramidal support structure 1 has a side 10 of L / 3 = 900 mm and an HP height of around 800 mm.

 At the top directed downwards of the pyramidal support structure are provided two parallel U-shaped tubular bends 17 and 18 having branches extending perpendicular to the plane of the base of the pyramid materialized by the rails 15 and 16.

These two lower U-shaped elbows are integral with the movable part of the cylindrical joint, as will be seen below.

 The four tubular sections 11, 12, 13 and 14 of the supporting structure concentrate at the top of the pyramid 17-18 the result of all the dynamic stresses exerted on the solar panels 2 and the structure 1.

 According to another embodiment, the supporting structure is inscribed substantially in a cone, the sections of the base of the cone corresponding to the sections 10 being arcs of a circle, and the sections 11 corresponding to generatrices of the cone.

 Column 3 is composed of a vertical tube with square section.

 At the lower end of the column 3 is welded a flat sole 30 which is fixed substantially horizontally to the ground S by means of four anchor bolts 31.

 The upper part of column 3 is terminated by a semi-cylindrical spacer 32, as shown in FIGS. 5, 7 and 9. The length and diameter of the spacer are equal to the side of the square section of column 3. Des semicircular bases 321 and 322 of the spacer 32 are respectively coplanar with two opposite sides 33 and 34 of the column 3. The edge with an axial square outline of the semi-cylindrical spacer 32 is welded to the upper edge with a square outline of the column 3.

 With reference to FIGS. 5 to 9, the cylindrical joint 4 is composed of two pairs of cylindrical toothed rings 41-43 and 42-44 respectively located on the two opposite sides 33321 and 34-322 of the upper part of the column 3.

 Each pair of crowns 41-43, 42-44 is composed of a fixed crown 41, 42 and a movable crown 43, 44 which are identical and which have toothed faces 411, 421 and 431, 441 applied coaxially the one against the other. Non-toothed faces 412 and 422 of the fixed rings 41 and 42 have peripheries which are welded coaxially to the semi-circular bases 321 and 322 of the spacer 32 and to the opposite sides 33 and 34 of the column 3, as shown in FIGS. 7 and 8. Circular half-peripheries of the movable rings 43 and 44 are welded respectively to the internal peripheries of the U-bends 17 and 18 from the top of the pyramidal support structure 1, as shown in FIGS. 5 and 9.

 Each toothed face 411, 421, 431, 441 of a crown 41, 42, 43, 44 has a toothing regularly distributed axially in a crown, as shown in FIGS. 10 and 11. The teeth have a predetermined number N of small identical radial teeth D. The hollows C between the teeth D are substantially complementary to the teeth. Typically, the number N of teeth or hollows is equal to 36 and the angular pitch P between two consecutive teeth or hollows is equal to 100.

 The teeth of the crowns have a substantially isosceles trapezoidal profile according to a preferred embodiment illustrated in FIG. 12, or a substantially sinusoidal or round profile according to other embodiments. These toothing profiles allow progressive sliding of the teeth of the mobile crowns 43 and 44 respectively on the teeth of the fixed crowns 41 and 42, while allowing the immobilization of the mobile crowns relative to the fixed crowns when the teeth D of the mobile crowns completely fit into the recesses C between the teeth of the fixed crowns respectively, as shown in Figure 7.

 By way of example, for crowns having an outside diameter DE of 135 mm and a thickness EP of 13.5 mm, the teeth D and hollow C have a width LA of 20 mm extending between a circle of diameter 120 mm and a circle with a diameter of 80 mm, and a height HD of 3.5 mm.

 When assembling the supporting structure 1 on the upper part of the column 3, the two U-bends 17 and 18 with the movable crowns 43 and 44 are substantially spaced apart so that the toothed faces 431 and 441 of the crowns mobile 43 and 44 ripent on or pass in front of the toothed faces 411 and 421 of the fixed crowns 41 and 42 until the teeth of the mobile crowns mesh with the teeth of the fixed crowns, respectively. At this stage, central holes 413, 423 and 433, 443 of the fixed rings 41, 42 and mobile 43, 44 are substantially aligned perpendicular to the column 3 and opposite holes 35 and 36 drilled in the two opposite faces 33-321 and 34-322 from the top of column 3, as shown in Figure 5.

 A threaded rod 45 is slidably passed through the central holes of the four crowns and the holes of the opposite faces of the column 3, as shown in FIG. 6. Two sets of nut, lock nut and washer 451 and 452 are screwed to the ends of the threaded rod 45 projecting from the toothed faces 432 and 442 of the movable crowns so as to keep the four crowns coaxial, while maintaining a relative clearance between fixed crown and movable crown in each pair. The threaded rod 45 thus acts as an axis for the cylindrical joint 4 and rotates with the movable rings 43 and 44 in the central holes 413 and 423 of the fixed rings and the holes 35 and 36 of the upper part of the column.

 Thanks to the cooperation by crown teeth, the movable crowns 43 and 44 do not mechanically stress the rod 45. The mechanical stresses due to a rotation of the support structure 1 at its top are in fact taken up by the teeth of the crowns.

 In practice, the mobile crowns can rotate at least up to 700, in angular steps P of 100, so as to position the solar panels 2 as a function of the site of installation of the panels between a horizontal position shown in solid lines in the figure. 2 and an inclined position of at least 700 relative to the horizontal shown in a short dashed line in FIG. 2. Under these conditions, the column 3 has a height preferably greater than the half-length L / 2 of the rails, and more precisely to the half-length of all the solar panels 2 supported.

As shown in Figure 7, the pairs of crowns 41-43 and 42-43 are not arranged strictly symmetrically with respect to the vertical axis of column 3, as regards their teeth. The teeth D of the fixed crown 41 of the first pair of crowns 41-43 are aligned in respective first radial planes with the teeth
D of the movable crown 44 of the second pair of crowns 42-44, and likewise, the teeth D of the fixed crown 42 of said second pair of crowns 42-44 are aligned in respective second radial planes with teeth of the movable crown 43 of said first pair of crowns 41-43. The first radial planes are thus offset by the angular half-step P / 2 relative to the second radial planes.

 These arrangements have the consequence of offering first and second angular positions of the support structure 1 with the solar panels 2 offset by P / 2. For example, by choosing a reference position of the solar panels merged with the horizontal, the first positions corresponding to the assembly in FIG. 7 where the movable rings 43 and 44 are respectively arranged on the left and on the right, are 00, 100, 200 , 300, 400, 500, 600 and 700 with a pitch P = 10. After disassembly of the support structure 1 and of the column 3 and a rotation of 1800 of the support structure 1 around the vertical axis of the column 1, the mobile crown 44 now on the left is opposite the fixed crown 41 and the movable crown 43 now on the right is opposite the fixed crown 42 ;; the teeth of the movable crowns 44 and 43 are then respectively opposite the teeth of the crowns 41 and 42. To obtain the gear between these crowns, it is then necessary to turn the movable crowns by P / 2 = 50. say the supporting structure with the solar panels, around the axis of the rod 45 of the cylindrical joint 4. The second angular positions then correspond to 50, 150, 250, 350, 450, 550, 650 and 750 with a step P = 10.

 Thus, the reversibility of the cylindrical joint makes it possible to offer first and second angular positions of the supporting structure 1 with an angular offset of P / 2 = 50 relative to a reference position, using the same support for solar panels. .

 According to another application of the invention, the rails 15 and 16 are replaced by the base or the fixing axis of a telecommunications antenna, such as a parabola, so that by rotation of the antenna with the support structure 1 around the threaded rod 45 of the cylindrical joint 4, the antenna is pointed in elevation towards one (or more) predetermined satellite (s).

Claims (8)

 1 - Support in particular for solar panels (2), characterized in that it comprises  - a support structure (1) inscribed substantially in a convex polyhedron and having a base (10) supporting the solar panels (2),  - a foot (3), and t  - an articulation (4) between a top (17, 18) of the support structure and an upper part (32) of the foot (3) to turn the support structure by angular step (P) around an axis of rotation (45 ) substantially perpendicular to the foot (3).  2 - Support according to claim 1, wherein the articulation comprises two pairs of crowns (41-43, 42-44) coaxial with the axis of rotation (45), each pair of crowns comprising a fixed crown (41, 42) fixed against a respective one of two opposite faces (33-321, 34-322) of the upper part of the foot and a movable crown (43,44) linked to the top (17,18) of the supporting structure, the fixed and movable crowns of each pair having toothed faces (411-431, 421-441) facing each other meshing with one another.  3 - Support according to claim 2, wherein the toothed faces (411, 421, 431, 441) of the crowns are teeth (D, C) with a substantially trapezoidal, or sinusoidal, or round profile extending circularly around the 'axis of rotation (45).  4 - Support according to claim 2 or 3, wherein the axis of rotation comprises a rod (45) integral with the movable crowns (43, 44) and rotatably mounted in the fixed crowns (41, 42) and the upper part (32) of the foot (3).  5 - Support according to any one of claims 2 to 4, wherein the fixed crown (41,42) of one of the pairs of crowns and the movable crown (44,43) of the other pair of crown have teeth (D) on their toothed faces aligned in respective radial planes.  6 - Support according to any one of claims 1 to 5, wherein the supporting structure (1) is substantially inscribed in a pyramid and is formed by a tube developed and bent along substantially six edges (10 to 14) on two sides opposite of the pyramid.  7 - Support according to any one of claims 2 to 5 and to claim 6, wherein the top of the supporting structure (1) is formed by two parallel U-bends (17, 18) against the internal peripheries of which half-edges of the movable crowns (43, 44) are respectively fixed.  8 - Support according to any one of claims 1 to 7, wherein the base (10) of the support structure (1) rotates around the axis of rotation (45) between a substantially horizontal position and an inclined position d '' at least 700 from the horizontal.