FR3028275A1 - PROTECTION INSTALLATION AGAINST THE SUN - Google Patents

Abstract

Sun protection system (1) comprising a protective roof (3) provided with a supporting structure (5) and a plurality of obscuration plates (11), the protection device (1) being in position further provided with a displacement system (15) of the plurality of obscuration blades (11) comprising a rail (17) and a guide (29), a plurality of carriages (23), a driving system of a carriage (23 ') of the plurality of carriages (23) in the deployment direction (19), a plurality of carriage connecting elements (45) (23), each connecting element (45) being arranged between two carriages (23) adjacent in the deployment direction (19) and being arranged to limit the distance separating said two carriages (23) adjacent to a given distance (47).

Description

The present invention relates to a sun protection installation. More particularly, it is an installation with a protective roof comprising a load-bearing framework and a plurality of obscuration blades.

It is known to have a system for moving the plurality of blades. It is thus possible in an extended position to cover the roof with the plurality of obscuration blades and in a retracted position to group the blades to allow the passage of light through the roof. It is also known to modify the orientation of the blades by rotating the blades around their extension axes. This arrangement allows, in the deployed position, to still let some of the light through the roof according to the need for protection against the sun. The implementation of these two modes of movement of the plurality of blades, the first mode being the transition from the retracted position to the deployed position and the second mode the rotation of the blades, can be tricky and require the installation. of a complex mechanism. This is all the more true when one seeks to make the relocation system reliable, games and links between the various elements of the mechanism that can lead to blockages or even degradations of certain parts. The present invention aims to solve all or some of the disadvantages mentioned above. To this end, the present invention relates to a sun protection system comprising a protective roof provided with a supporting framework and a plurality of obscuration blades, the protective installation being further provided with a system for moving the plurality of obscuration blades comprising: - a rail and a guide each extending in a direction of deployment of the plurality of blades and being each attached to the carrier frame, - a plurality of carriages comprising each a rail fastening element arranged to allow the carriage to move along the rail, a cooperating element with the guide arranged to cooperate in translation with the guide in the direction of deployment and a device for transmitting a movement rotating the guide to the corresponding blade, the rotary movement of the guide being around the direction of extension of the guide and the rotary movement of the blade itself r of the axis of extension of the blade, - a drive system of a carriage of the plurality of carriages in the direction of deployment, - a plurality of carriage connecting elements, each connecting element being arranged between two adjacent trolleys in the direction of deployment and being arranged to limit the distance separating said two adjacent trolleys at a given distance. The combination of the drive system and the plurality of linkage members makes it possible to move all of the plurality of carriages by driving a single carriage. The connection of the drive system with this single carriage is then simple to set up, in comparison with a drive system linked to each carriage and intended to drive the plurality of carriages. The linking elements allow, during the deployment of the plurality of blades to maintain a constant distance between the deployed blades. By deployment is meant moving the plurality of blades 20 to position them so that each blade is separated from the given distance of the adjacent blade. The effect of limiting the separation of two carriages adjacent to the given distance is then to evenly distribute the sun rays passing through the protective roof: the deployed blades are spaced at a constant distance while the blades still deployed are grouped tightly. According to one aspect of the invention, the element for cooperation with the guide is arranged to cooperate in translation with the guide in the direction of extension of the guide and the device for transmitting a rotary movement to the blade comprises an element. rotary member formed in the element of cooperation and arranged to be integral in rotation with the guide around the direction of extension of the guide, the transmission device further comprising a transmission element of the rotational movement of the rotary member to the blade.

The displacement carriage can be moved along the guide because the cooperation element has a degree of freedom in translation relative to the guide in the direction of extension of the guide. Independently of this possibility of translation movement of the carriage, a rotation of the guide in its extension direction has the effect of rotating the blade along the axis of extension of the blade. Thus the displacement carriage allows, thanks to a simple structure, to achieve at the same time the movement of the blade along the guide and the rotation of the blade on itself around its axis of extension. According to one aspect of the invention, the rotatable member has a cooperating surface with the guide, the cooperating surface being formally complementary to the guide. Preferably the profile of the cooperation surface is invariant in the direction of extension of the guide. This arrangement allows the translation 15 in the direction of extension of the guide. In particular, the cooperation surface has a portion extending radially relative to the direction of extension of the guide. This arrangement allows a rotational connection between the guide and the rotary member. According to one aspect of the invention, the engagement surface or the guide has a groove adapted to cooperate with a rib of the engagement surface or the guide, the groove and the rib extending in the direction of extension of the guide. . Co-operation of the rib with a groove allows rotation of the rotating member in both directions around the extension direction of the guide. According to one aspect of the invention, the rotary element has a driving surface arranged to cooperate with a complementary surface of the transmission element. The transmission of the movement of the rotary member to the transmission member is achieved by the cooperation of a driving surface with a complementary surface. According to one aspect of the invention, the transmission device comprises a gear system, the driving surface of the rotary element corresponding to a part of said system and the complementary surface of the transmission element corresponding to a complementary part. said system. According to one aspect of the invention, the driving surface of the rotary member has a helical groove shape and the complementary surface of the transmission element has a circular toothing shape. The helical groove thus acts in the manner of a worm which cooperates with the circular toothing. The transmission element thus rotates about an axis transverse to the direction of extension of the guide. According to one aspect of the invention, the circular toothing is oriented along the axis of extension of the blade. The axis of rotation of the circular toothing is aligned with the axis of extension of the blade, which allows transmission of the simple rotational movement by contact between the transmission element and the corresponding blade. According to one aspect of the invention, each connecting element is united to two adjacent carriages of the plurality of carriages. According to one aspect of the invention, each union of the connecting element to a corresponding carriage has a degree of freedom. Preferably the degree of freedom of the connecting element is a rotational degree of freedom. In particular, said rotational degree of freedom is oriented along an axis transverse to the direction of deployment of the plurality of blades. According to one aspect of the invention, each connecting element comprises a first part and a second part, each being provided with a connecting element with a corresponding carriage. According to one aspect of the invention, the first part and the second part cooperate by a link with a degree of freedom, preferably rotational and in particular rotatable along an axis transverse to the direction of deployment of the plurality of blades. According to another aspect of the invention, a cable constitutes the plurality of connecting elements, said cable being fixed to each carriage. Preferably, in the deployed position the cable extends in the direction of deployment. In particular an orifice is provided in each carriage for the passage of said cable. According to one aspect of the invention, the drive system comprises a belt and a pinion, the pinion being arranged to transmit rotational movement to the belt, the belt extending in the direction of deployment of the blades. According to one aspect of the invention the belt comprises a fixing to a carriage of the plurality of carriages. Preferably, the carriage attached to the belt is attached to only one other carriage of the plurality of carriages. In other words, it is an extreme carriage of the plurality of carriages according to the direction of deployment. In any case the invention will be better understood with the aid of the description which follows with reference to the accompanying diagrammatic drawings showing, by way of non-limiting example, an embodiment of this sun protection installation. Figure 1 is a top view of a sun protection installation including a plurality of obscuration blades in the deployed position. Figure 2 is a top view of sun protection installation with the plurality of obscuration blades in the retracted position. Figure 3 is a side view of a plurality of blade displacement system in a first variant with a two-part linkage element; Figure 4 is a front view of a carriage of the Figure 3 displacement system; Figure 5 is a top view of a carriage of the displacement system of Figure 3 Figure 6 is a detail view in perspective of a displacement system according to a second variant with a cable as a connecting element Figure 7 is a view Figure 8 is a front view of a carriage of the displacement system of Figure 6.

Figure 9 is a cross section of a carriage of the displacement system of Figure 6 and a blade.

Figure 10 is a perspective view of the protection device including the plurality of obscuring blades in the deployed position. Figure 11 is a perspective view of the protection apparatus including the plurality of obscuration blades in the retracted position.

Figure 12 is a side view of the displacement system of the plurality of blades of Figure 6. Figure 13 is a wire drawing of a front view of a carriage of the displacement system of Figure 6. Figure 14 is a view Figure 15 is a wired representation of a top view of the carriage of the displacement system of Figure 6. Figure 16 is a top view of the carriage of the figure moving system. 6. As illustrated in FIGS. 1, 2, 10 and 11, a sun protection device 1 comprises a protective roof 3. The protective roof 3 comprises a load-bearing framework 5 provided with a rectangular structure 7 and four feet 9. The protective roof 3 further comprises a plurality of obscuration blades 11. In FIG. 1, the blades 11 are arranged in an extended position in which the protection against the sun is maximum and a retracted position in which an opening 13 is formed in the protective roof 3. The protective installation 1 against the sun also comprises a displacement system 15 of the plurality of blades 11.

As illustrated in FIG. 3, the displacement system 15 comprises two rails 17, each being attached to one side of the supporting framework 5 and extending in a deployment direction 19 of the plurality of blades 11. The deployment direction 19 is transverse to the extension direction 21 of the plurality of blades 11. The displacement system 15 further comprises a plurality of travel carriages 23. Each carriage 23 comprises a shaft 25 intended to be inserted into a corresponding cavity 27 of one end of a blade 11. Each shaft 25 extends in the direction of extension of the corresponding blade 11. Thus, each blade 11 corresponds to two carriages 23 of displacement. Each shaft 23 is arranged to rotate about its axis of extension and is integral in rotation with the corresponding blade 11. The displacement system 15 further comprises a guide 29 extending in the direction of deployment 19. The displacement system 15 also comprises a rotation system 31 arranged to allow the rotation of the guide 29 around its direction of extension, the rotation system comprising an electric motor 33. The displacement system 15 comprises a drive system 35 of a carriage 23 'of the plurality of carriages 23. It is a carriage 23' extreme in the direction 19. The drive system 35 comprises a belt 37 extending in the deployment direction 19, two pinions 39, an electric motor 41 for moving the gears 39 and an attachment 43 to the carriage 23 'extreme previously mentioned. The end carriage comprises a complementary attachment 44. To enable the plurality of carriages 23 to be moved by the drive system 35, the displacement system 15 comprises a plurality of carriage connecting elements 45. link 45 unites two carriages 23 adjacent and is arranged so that the distance separating these two adjacent carriages 23 is less than or equal to a given distance 47. According to a first variant of the connecting element 45 shown in FIGS. 1 to 5, the union between a connecting element 45 and a carriage 23 is a connection according to a degree of freedom. This is a rotational degree of freedom along a transverse axis 49 to the deployment direction 19. Each connecting element 45 comprises a first portion 45a and a second portion 45b each being connected to a carriage 23. The two parts 45a, 45b are themselves linked according to a degree of freedom in rotation also transverse to the deployment direction 19. Thus the given distance 47 between two adjacent carriages 23 is obtained when the first part 45a and the second part 45b are aligned and form an angle of 1800. On the contrary, when the first portion 45a and the second portion 45b have an angle of less than 180 °, the adjoining carriages 23 approach each other. In the retracted position, the adjacent carriages 23 are in contact, which defines the minimum angle between the first part 45a and the second part 45b, as illustrated in FIG. 2. FIGS. 6 to 9 and 12 to 16 show a second variant of the connecting element 45. According to this second variant, the connecting element 45 is a flexible cable 451 passing through a plurality of orifices 46, each carriage 23 comprising an orifice 46. To maintain the given distance 47 between two In the extended position, the flexible cable 451 is attached to each carriage 23 by means of a locking screw 48a disposed transversely to the corresponding orifice 46. A screw thread 48b corresponding to the locking screw 48a is provided in each carriage 23. Preferably a headless locking screw 48a is used. Whatever the type of connecting element 45 used, the combination of the drive system 35 of the carriage 23 'extreme and the arrangement of the connecting elements 45 has the effect, during the transition from the retracted position to the position deployed, maintain the given distance 47 between the carriages 23 30 deployed while the other carriages 23 are still in the retracted position. The effect is therefore to evenly distribute the sunlight passing through the protective roof, the distance between carriages 23 deployed being constant. As illustrated in FIGS. 4 and 5, each carriage 23 of displacement comprises an attachment element 49 to the corresponding rail 17.

According to the variant shown in these figures, the attachment element 49 comprises two rotary pads 51 arranged on either side of the rail 17. As illustrated in FIGS. 6 to 9 and according to another variant, the attachment element 49 comprises a notch 53 cooperating in complementarity of form with the corresponding rail 17 and a sliding shoe 55 also cooperating with the rail 17. As illustrated in FIG. 9, the profile of the rail 17 may have a shape adapted for a cover protection 57 is arranged on it. The rail 17 may also have a lower extension 59 for various attachment needs specific to the installation and not detailed in this text. FIG. 9 also shows the carriage 23 'which includes an attachment 43 with the belt 37. The other carriages 23 have a similar geometry but without attachment to the belt 37. As illustrated more particularly in FIGS. 6 and 7, each carriage 23 located on the side of the guide 29 comprises a device 61 for transmitting a rotary movement of the guide 29 to the corresponding blade 11. The transmission device 61 comprises a rotary element 63 formed in a cooperation element 65 with the guide of the carriage 23. The rotary element 63 is integral in rotation with the guide 29. The rotary element 63 has a cooperation surface 67 with the guide 29 by complementarity of form. The cooperation surface 67 has a groove 69 of constant profile in the direction of extension of the guide 29. The guide 29 has a rib 71 of complementary shape to the groove 69 of the rotary member 63. Thus the cooperation between the groove 69 and the rib 71 allows a rotational connection of the guide 29 and the rotary member 63. However, the identical profile of the groove 69 and the rib 71 in the direction of extension of the guide 29 allows axial sliding 30 the rotary member 63 relative to the guide 29. Each carriage 23 located on the guide 29 is thus able to slide in the direction of deployment 19 relative to the corresponding rail 17 and the guide 29. The rotary member 63 also comprises a external drive surface 73 having a helical corrugation shape 74 oriented along the axis of extension of the guide 29.

The transmission device 61 further comprises a transmission element 75 arranged to cooperate with the rotary element 69. The transmission element 75 is intended to transmit the rotational movement of the rotary element 69 to the corresponding blade 11.

To do this, the transmission element 75 has a complementary surface 77 to the drive surface 73 of the rotary element 69. This complementary surface 77 is in the form of a circular toothing 78. The helical groove 74 and the Circular teeth 78 cooperate and form a gear system. The circular toothing 74 is integral with the shaft 25 of the carriage 23 corresponding. Thus the rotation of the helical groove 74 caused by the rotation of the guide 29 causes the blades 11 to rotate. It should be noted that a blade 11 is connected on one side to a carriage 23 comprising a transmission device 61 and the other side to a carriage 23 not understanding. Thus the carriages 23 located on the side opposite the guide 29 have a shaft 25 which is free to rotate about its axis. The arrangements detailed above make it possible to carry out the transition from the retracted position to the deployed position of the blades 11 and 20 inversely completely independently of the orientation of the blades with respect to their direction of extension. The displacement system 15 of the protection system 1 against the sun thus makes it possible in a simple and reliable manner to adapt the desired protection against the sun either by tilting the blades 11 or by sliding them along the rails 11. As it goes without saying that the invention is not limited to the sole embodiment of this sun protection installation, described above as an example, it encompasses all the variants of embodiment. 30

Claims (10)

REVENDICATIONS1. Sun protection system (1) comprising a protective roof (3) provided with a supporting structure (5) and a plurality of obscuration strips (11), the protection device (1) being further provided with a displacement system (15) of the plurality of obscuration strips (11) comprising: - a rail (17) and a guide (29) each extending in a deployment direction (19) of the plurality of blades (11) and each being attached to the supporting framework (5), - a plurality of carriages (23) each comprising a hooking element (49) to the rail (17) arranged to allow the movement of the carriage (23) along the rail (17), a cooperating element (65) with the guide (29) arranged to cooperate in translation with the guide (29) in the direction of deployment (19) and a transmission device (61) a rotary movement of the guide (29) to the corresponding blade (11), the rotary movement of the guide (29) being around the d extension of the guide (29) and the rotary movement of the blade (11) around the extension axis (21) of the blade (11), - a drive system (35) of a carriage (23 ') of the plurality of carriages (23) in the direction of deployment (19), - a plurality of carriage connecting elements (45) (23), each connecting element (45) being arranged between two carriages (23) adjacent in the deployment direction (19) and being arranged to limit the distance separating said two carriages (23) adjacent to a given distance (47). 2. Protection installation (1) against the sun according to claim 1, wherein the cooperation element (65) with the guide (29) is arranged to cooperate in translation with the guide (29) in the direction 30 of extension of the guide (29) and the transmission device (61) of a rotary movement to the blade (11) comprises a rotary element (63) formed in the cooperation element (65) and arranged to be integral in rotation with the guide (29) around the direction of extension of the guide (29), the transmission device (61) further comprising a transmission element (75) of the rotational movement of the rotary member (63) at the blade (11). 3. Protection installation (1) against the sun according to the preceding claim, wherein the rotary member (63) has a cooperation surface (67) with the guide (29), the cooperation surface (67) having a complementarity shape with the guide (29). 4. Protection installation (1) against the sun according to the preceding claim, wherein the cooperation surface (67) or the guide (29) has a groove (69) adapted to cooperate with a rib (71) of the surface of cooperation (67) or guide (29), the groove (69) and the rib (71) extending in the direction of extension of the guide (29). 5. Sun protection system (1) according to one of the preceding claims, wherein the rotary element (63) has a driving surface (73) arranged to cooperate with a complementary surface (77) of the transmission element (75). 6. Protection installation (1) against the sun according to the preceding claim, wherein the transmission device (61) comprises a gear system, the driving surface (73) of the rotary member (63) corresponding to a part of said system and the complementary surface (77) of the transmission element (75) corresponding to a complementary part of said system. The sun protection system (1) according to the preceding claim, wherein the driving surface (73) of the rotary member (63) has a helical spline shape (74) and the complementary surface (77). ) of the transmission element (75) has a shape of circular toothing (78). 30 8. Protection installation (1) against the sun according to the preceding claim, wherein the circular toothing (78) is oriented along the axis of extension (21) of the blade (11). The sun protection system (1) according to one of the preceding claims, wherein each connecting element (45) is connected to two adjacent carriages (23) of the plurality of carriages (23). 10. Protection installation (1) against the sun according to the preceding claim wherein the drive system (35) comprises a belt (37) and a pinion (39), the pinion (39) being arranged to transmit a movement rotating belt (37), the belt (37) extending in the direction of deployment (19) of the blades (11).