FR2954792A1 - Balustrade for use on periphery of roof of building to receive e.g. photovoltaic panels, has lower rail and rail fixing unit that are mounted slidingly on posts for choosing raised position of lower rail before fixation of rail - Google Patents

Abstract

The balustrade has a lower rail (14) mounted in a lower part of inclined or vertical posts (5) e.g. square tubes, by a fixing unit e.g. set screw. Another fixing unit fixes solar energy receiving panels (10) on an upper handrail. The latter fixing unit is mounted on the upper handrail in a longitudinally sliding manner. The lower rail and the former fixing unit are mounted slidingly on the posts for choosing a raised position of the lower rail before fixation of the rail. The latter fixing unit comprises a screw/nut assembly (7) with a screw head inserted in a longitudinal fixing groove (4A).

Description

1 GUARD FOR RECEIVING SENSOR PANELS OF SOLAR ENERGY OF DIFFERENT TYPES

DESCRIPTION FIELD OF THE INVENTION The invention relates to guardrails placed on the roofs of buildings and buildings on which must evolve, often temporarily, people. It concerns in particular railings to be equipped with solar energy sensor panels such as photovoltaic panels or solar panels. PRIOR ART AND PROBLEM POSE It is possible to use the railings placed at the top of buildings to fix solar panels, photovoltaic. In addition, in most cases, and with reference to FIG. 1, the guardrails 30 placed on the roof 31 of the buildings 32 are inclined with respect to the vertical so that an upper guardrail 33 of the railing 30 is more towards the interior or the center of the building 32 with respect to the foot of the railing 30 which is more towards the outside of the building 32, or even to the extreme edge thereof. This inclination is from 0 ° to 60 °.

The solar panels 34 or photovoltaic are then placed on the outside of the railing 30 placed on the south side of the building. Indeed, given the inclination of the railing 30, these photovoltaic panels 34 or solar panels 2 are inclined upwards towards the south, that is to say towards the sky, and thus have a favorable orientation to the reception solar rays with satisfactory performance. The standardized height of the railings 30, that is to say, nowadays between 1.00 m and 1.10 m, somewhat limits the number of different types of solar panels 34 or photovoltaic panels thus installed on the guardrails 30. a building 32. Indeed, the number of types of solar or photovoltaic panels is constantly increasing. However, the railings are fixed installations, placed most of the time permanently and whose shape can not be changed to suit the different types and sizes of solar panels or photovoltaic panels to install on the roofs of buildings . The object of the invention is therefore to overcome this disadvantage by proposing a concept of bodyguard for receiving different types of solar panels or photovoltaic and of different sizes, at the request of the customer. SUMMARY OF THE INVENTION To this end, the main object of the invention is a railing intended to be mounted on the periphery of the roof of a building and having at least. vertical or inclined uprights; An upper guardrail mounted in the upper part of the uprights; At least one lower rail, mounted in the lower part of the uprights with fastening means, and solar energy sensor panel fixing means. According to the invention, the means for fixing the solar energy sensor panels are slidably mounted longitudinally on the upper guardrail and the at least one lower rail is slidably mounted on the posts by means of its fastening means which can slide longitudinally in the amounts before fixing. In the preferred embodiment of the railing according to the invention, the solar energy sensor panel fixing means consist of at least one longitudinal fixing groove in the at least one lower rail and the upper guardrail for receiving there tightening screw heads.

In their preferred embodiment, the means for fixing the at least one lower rail and the upper guardrail in the posts consist of a needle screw screwed into a sliding catch in a longitudinal groove for fixing the at least one lower rail or the amount. The tapered end of the needle screw presses, by screwing the needle screw, on one side of a corresponding notch of a fastening bolt inserted longitudinally into the end of the at least one lower rail or the upright and whose head is 4 placed in a longitudinal groove for fixing the corresponding upright or the upper railing. Preferably, the means for fixing the at least one lower rail on the uprights comprise a longitudinal fixing groove in the uprights to receive the head of a connecting bolt pushed into the upright by a spring. If the section of the at least one lower rail and the upper guardrail is round, the invention provides that the means for fixing the solar energy sensor panels using radius compensators with a cylindrical concave surface and a flat surface interposed between these two elements and the upper guardrail and the at least one lower rail so that the solar energy sensor panels can bear on the flat surface of the radiation compensator. In a preferred embodiment of the invention, the upper guardrail is mounted on the upper outer surface of each post with a radius compensator. It is envisaged to use a cover at the ends of the upper guardrail. Preferably, the amounts are aluminum, square section and easily culpable, in order to be made to length on demand, before mounting on site. Finally, it is preferable that the upper rail and the at least one lower rail are also aluminum.

LIST OF FIGURES The invention and its various technical features will be better understood on reading the following description of an embodiment which is accompanied by six figures respectively representing: FIG. 1, already described, in a cavalier view, the context of the use of the invention; FIG. 2, in exploded view, the different elements constituting the railing according to the invention; - Figure 3, a detail of the attachment means of the lower rail on a post; 4, in exploded view, in a slightly more precise manner of different constituent elements of the railing according to the invention; - Figure 5, in a cavalier view, a realization of the railing once installed and equipped with panels; and 20 - Figure 6, a second embodiment of the railing once installed, still equipped with panels. DETAILED DESCRIPTION OF TWO REALIZATIONS OF THE INVENTION With reference to FIG. 2, the main elements constituting the railing according to the invention are uprights 5 and at least two rails, that is to say an upper guardrail 4. and at least one lower rail 14 which is, in this embodiment, similar to the upper guardrail 4. The posts 5 are set in an inclined manner, in this embodiment in a foot 8, consisting of a square section fixed to a fixing plate 6, inclined. The latter makes it possible to fix the assembly on the acroterium of the roof of the building. Of course, the amounts could be mounted less inclined as shown in this Figure 2, or vertically. The uprights 5 are preferably made of aluminum, for example 45 × 45 mm square tube. This makes it easy to cut them, especially at the time of their preparation, in the workshop. The upper guardrail 4, like the lower rail 14 are of round section, in the embodiment described. The upper guard 4 is mounted, preferably on the upper surface 5S of an upright 5, by means of a radius compensator 3. Such a radius compensator 3 therefore makes it possible to obtain very large bearing surfaces. on two contact faces, for example between the upper guard 4 and the solar energy sensor panel 10. A connecting bolt 2, preferably with a system with a needle screw, with the head of the joint bolt 2 placed in a longitudinal groove for fixing the upper guardrail 4. A cover 1 may complete this assembly by being placed at the end of the upper guardrail 4, to plug the opening of the round profile which constitutes this upper guardrail 4.

Such a cover 1 closes the end of the upper guardrail 4 and thus prevent the intrusion 7 of foreign body inside. The upper rail 4 is made preferably of aluminum and has a round section of about 48 mm. The upper guardrail 4 and the uprights 5 each have at least one longitudinal fixing groove, 4A for the upper guard 4, that of the uprights not being visible. The longitudinal groove for fixing the uprights 5 is intended to receive the head of a connecting bolt 2 which is placed longitudinally in the end of the lower rail 14. Each upright 5 of the railing is fitted and fixed, for example with bolts 18, in its base 8. The anchoring of the latter in the acroterium can be achieved by chemical pins which have a resistance to very high loads. The amounts 5, preferably of square shape have very high mechanical characteristics. In addition, this geometric shape allows a very easy assembly and perfect connection with the other elements of the railing that are the top rail 4, the bottom rail 14 and the base 8. The fact that the head of the bolt junction 2 sliding in the corresponding longitudinal mounting groove of the upright 5 allows the lower rail 14 to be positioned, when assembled, in the desired position. The fastening means of the panels 10 on the upper rail 4 and the lower rail 14 are mainly composed, for each of them, of a radius compensator 3 associated with a screw / nut assembly 8 7. The head of the screw is placed in a longitudinal fixing groove 4A of the upper guardrail. The tightening of the not shown nut completes this means for fixing the solar energy sensor panels 10 and will be mounted on the rod of the clamping screw. The fixing screws are preferably made of stainless steel to mitigate the effects of climatic variations which can be responsible for a rust effect and the degradation of the structure.

The lower rail 14 is mounted mainly by means of connecting bolts 2 whose head is inserted into a longitudinal groove for fixing the post 5. Such a connecting bolt 2 is placed at each end of the lower rail 14, central way. It is specified that this bolt is not threaded and that it is only a fastener. It is housed in a central housing of the end of the lower rail 14. It is accompanied by a spring that tends to pull it out.

During assembly of the lower rail 14, the head of the fixing bolt is placed in the longitudinal groove for fixing the corresponding post 5, the spring pushing the head of the bolt on the inside wall of the groove of the post 5. the bottom rail 14 in the chosen position. FIG. 3 shows the head 21 of the joint bolt 2 in the longitudinal groove for fastening a post 5. However, this explanation is the same for the assembly of the upper guardrail 4 on the posts 5 which is also done with a needle screw. It also shows the spring 22 which pushes outwardly of the lower rail 14 the connecting bolt 2. The assembly is completed by a cleat 23, inserted in the longitudinal upper mounting groove 14S of the lower rail. This stop 23 is traversed by a needle screw 26 screwed inside and being able to protrude, through a hole made inside the lower rail 14, onto a notch 27 of the connecting bolt 2, by a conical end 24. A tab 25 projects from the side of the upright 5 to penetrate into the longitudinal groove for fixing the latter so as to lock in rotation the lower rail 14, during its assembly. When the set screw 26 is screwed, it presses its conical end 24 on one side of the notch 27 of the connecting bolt 2 to force it to move to the left, so that the base of the bolt head 21 fastening comes tighten the inner wall most eccentric of the groove of the upright 5 with a determined force and sufficient to achieve a final fixation. FIG. 4 shows in more detail the mounting of a solar energy sensor panel 10 along an upright 5. For the upper railing 4 seen in section, there is a connecting bolt 2 accompanied by a radius compensator 3 resting on the upper end 5S of the amount.

The screw / nut assembly 7 for fixing the upper part of solar energy panel 10 10 is shown exploded, together with a spoke adapter 3. The location of the fastener is symbolized by an axis A. The fixing of the lower part of the solar energy panel 10 on the lower rail 14, seen in section, is also detailed. The same screw / nut assembly 7, together with a radius compensator 3 is used in the same way, the head of the screw being placed the corresponding groove 14A of the lower rail 14. The screw / nut assembly 7 allowing assembling each solar energy sensor panel 10 in the railing structure has toothed and self-braking bases to obtain a solid fixation and thus prevent the theft of these solar energy sensor panels 10. FIG. a first way to install solar energy sensor panels 10 on the parapet 50 of the roof of a building. There are included bases 8 in which the uprights 5 are fixed. In this embodiment, the upper guard 4 is oriented towards the inside of the roof surface. In the installation described in Figure 6, the base 68 has a horizontal beam 69 which connects to the parapet 60 of the roof of the building. In this case, the upper guard 4 is oriented towards the outside of the roof surface, almost above the acroterium 60, each base 68 being offset towards the inside of the roof.

Such an assembly is very simple and fast and has a self-positioning during assembly. The locking in rotation of the profile such as the lower rail 14 is thus ensured. In addition, it can benefit from an anti-slip footprint. Such an assembly system is conductive and requires very little machining in the profile to be mounted. The upper guardrail 4 and the lower rail 14 make it possible to adapt any kind of solar energy sensor panels to the guardrail. Their reversibility, that is to say the presence of several longitudinal fixing grooves, leaves the possibility of placing the latter inside or outside the railing. Finally, the visual aspect of the whole structure is very clean. It is envisaged to use several smooth such as the lower rail 14 in the case where the height of the panels is relatively large.

Claims (9)

REVENDICATIONS1. Railing intended to be mounted on the periphery of the roof of a building and possessing at least. - uprights (5) vertical or inclined; - an upper guardrail (4) mounted in the upper part of the uprights (5); at least one lower rail (14) mounted in the lower part of the uprights (5) with fixing means, and means for fixing solar energy sensor panels (10), characterized in that the fixing means solar energy sensor panels (10) are slidably mounted longitudinally on the upper guardrail (4) and the at least one lower rail (14) and the means for attaching the at least one lower rail (14) to the posts (5) are slidably mounted on the uprights (5) so as to select the height position of the at least one lower rail (4) before attachment. 2. Railing according to claim 1, characterized in that the fixing means of the solar energy sensor panels (10) consist of: - at least one longitudinal fixing groove (4A) in the upper railing (4). ), and- a screw / nut assembly (7), the screw head of which is inserted in the longitudinal fixing groove (4A). 3. Railing according to claim 1, characterized in that the means for fixing the at least one lower rail (14) or the upper guardrail (4) in the uprights (5) consist of a needle screw ( 26) screwed into a catch (23) sliding in a longitudinal groove for fixing the at least one lower rail (14) or the post (5), the conical end (24) of the set screw (26) pressing, by screwing the needle screw (26), on one side of a corresponding notch (27) of a connecting bolt (2) inserted longitudinally into the end of the at least one lower rail (14) or the post (5). ) and whose head is placed in a longitudinal groove for fixing the corresponding upright (5) or the upper guardrail (4). 4. Guardrail according to claim 3, characterized in that the means for fixing the at least one lower rail (14) on the uprights (5) are complemented by a spring (22) pushing the connecting bolt (2). ) in the upright (5) during the sliding of the at least one lower rail (14) in the uprights (5). 5. Guardrail according to claim 3, characterized in that the upper guardrail (4) and the at least one lower rail (14) are of round section 14, and the solar energy sensor panel fastening means ( 10) are constituted by a screw / nut assembly (7) and a radius compensator (3) with a cylindrical concave surface and a flat surface, the radius compensator (3) being placed between the sensor panel of the solar energy (10) and the upper guardrail (4) and the at least one lower rail (14) for the solar energy sensor panels (10) to rest on the flat surface of the beam compensator (3). Guardrail according to claim 1, characterized in that the upper guardrail (4) is mounted on the upper surface (5S) of each post (5) by means of a radius compensator (3) and a connecting bolt (2) with set screw. 7. Guardrail according to claim 1, characterized in that a cover (1) is used at the ends of the upper guardrail (4). 8. Guardrail according to claim 1, characterized in that the uprights (5) are of aluminum and square section, and can be made to length in advance before mounting. 9. Guardrail according to claim 1, characterized in that the guardrail (4) and the at least one rail (14) are aluminum.30.