INSTALLATION FOR COVERING A SURFACE USING ORIENTATABLE BLADES THAT ARE TRANSLATED FLAT

Abstract

The invention relates to an installation including: a series of orientable slats (3);a slat orientation system (3) adapted to ensure the pivoting of the slats in order to occupy a closed position or an open position;a system for moving in translation the slats (3) between a stowed position and a deployed position;and a control device piloting the displacement system and the orientation system, on the one hand to define from the stowed position of the slats a transition area (Ev) in which each of the slats exiting its stowed position switches from its open upright position to its closed position and conversely for each of the slats arriving to its stowed position, and on the other hand to ensure the translational displacement of the slats in the closed position outside the transition area (Ev).

Description

TECHNICAL FIELD

The present invention relates to the technical field of the installations for covering and uncovering a surface using orientable slats extending parallel to each other in order to constitute a screen for protecting or closing a surface in the general sense, these orientable slats having the possibility, in the deployed position relative to the surface, to be opened or closed depending in particular on whether conditions.

The object of the invention aims many applications to constitute particularly a cover of a roof forming part of pergolas or terraces for example, or a protective screen for doors or windows.

PRIOR ART

In the state of the art, it is known, for example from patent FR 3 027 334, an installation for obturating a surface including a series of orientable slats with longitudinal axes parallel to each other along their longitudinal edges and fitted to a pivot axis at each of their end edges. Each slat is supported by its pivot axes using a set of a first carriage and of a second carriage which are guided in translation along two guide tracks arranged on a bearing structure. The installation also includes a slat orientation system adapted to ensure the pivoting of the slats in order to occupy a closed position or an open position of the corresponding surface. The installation also includes a system for moving in translation the slats in their open position. These slats are moved in translation between a stowed position in which the slats are contiguous to each other in their open position and a deployed position in which the slats are deployed above the surface. Sensors allow determining the orientation of the slats and the displacement of the slats. These sensors, the displacement system and the orientation system are connected to a control device piloting the translation of the slats and the orientation of the slats.

Such installations can be subjected to severe weather conditions. Thus, a violent wind or strong gusts of wind can disrupt the operation of the installation and particularly the orientation of the slats and the translation of the slats. It thus turns out that the slat displacement system is either over-dimensioned to overcome the resistance to wind, or under-dimensioned causing malfunction of the installation.

DISCLOSURE OF THE INVENTION

The present invention aims to overcome the drawbacks of the prior art by proposing an installation for covering and uncovering a surface, using orientable slats, adapted to operate even in case of strong winds while remaining of simple design.

Another object of the invention aims to propose an installation that allows quickly covering the surface in case of rain showers.

To achieve such objectives, the installation for covering and uncovering, using adjustable slats, a surface delimited by a bearing structure, includes:

• • a series of orientable slats with longitudinal axes parallel to each other along their longitudinal edges and fitted to a pivot axis at each of their end edges;
  • each slat is supported by its pivot axes using a set of a first carriage and of a second carriage which are guided in translation along guide tracks;
  • two tracks for guiding in translation the carriages, arranged on the bearing structure by being disposed parallel to each other along two opposite sides of the surface;
  • a slat orientation system adapted to ensure the pivoting of at least some of the slats in order to occupy a closed position or an open position of the corresponding surface;
  • a system for moving in translation the slats between a stowed position in which the slats are contiguous to each other in an open upright position and a deployed position in which the slats are deployed above the surface while being separated in pairs by a closing center line;
  • sensors to determine the orientation and the displacement of the slats;
  • and a control device connected to the sensors, to the displacement system and to the orientation system to move in translation at least part of the slats and orient said slats. According to the invention, the control device pilots the displacement system and the orientation system, on the one hand to define from the stowed position of the slats a transition area in which each of the slats exiting its stowed position switches from its open upright position to its closed position and conversely for each of the slats arriving to its stowed position, and on the other hand to ensure the translational displacement of the slats in the closed position outside the transition area.

In addition, the installation according to the invention may further include in combination at least either of the following additional characteristics:

• • the control device pilots the displacement system and the orientation system such that for each slat being deployed or stowed, the distance between the pivot axis of the slat during deployment or stowage and the pivot axis of the neighboring slat stowed in the open upright position, changes between a minimum spacing value and a maximum spacing value during its stroke on its transition area;
  • the control device pilots the displacement system and the orientation system such that for each slat being deployed or stowed, the maximum spacing value during its stroke on its transition area is substantially equal to the closing center line;
  • the control device pilots the displacement system such that outside the transition area, the deployed slats are moved by being spaced in pairs by a distance equal to the closing center line;
  • the control device pilots the displacement system and the orientation system such that each slat in the transition area follows a regular orientation stroke to switch from its open position to its closed position and conversely;
  • the control device pilots the orientation system so as to place each slat in the closed position before the translational displacement of said slats;
  • the displacement system includes, for each pair of carriages fitted to a slat, at least one displacement motor, embedded in a carriage and driving in rotation a pinion cooperating with a rack mounted on the bearing structure along a direction parallel to the guide track, each pinion cooperating with a pivot axis to drive in translation the pivot axis of the slat;
  • the displacement motors each drive in rotation a pinion cooperating with a rack mounted on the bearing structure along a direction parallel to the guide track;
  • the orientation system includes, for each pair of carriages fitted to a slat, at least one orientation motor embedded in at least one of said carriages and angularly connected with the pivot axis;
  • for each slat, the displacement motor and the orientation motor are mounted on the same carriage, these carriages fitted to these motors being mounted alternately from one slat to another, depending on each side of the surface to be covered or uncovered;
  • each carriage fitted to a displacement motor and to an orientation motor includes a main support body for the displacement motor and the orientation motor, the main body being provided with a system for guiding in rotation a tubular shaft fitted to a pinion and driven in rotation by the displacement motor, the pivot axis being mounted inside the tubular shaft by being driven in rotation by the orientation motor and mounted secured in rotation to the slat.

Various other characteristics emerge from the description given below with reference to the appended drawings which show, by way of non-limiting examples, embodiments of the object of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of one exemplary embodiment of an installation in accordance with the invention in which the slats are all stowed in the upright position.

FIG. 2 is a perspective view of one exemplary embodiment of an installation in accordance with the invention in which part of the slats is being deployed in the closed position and another part of the slats is still stowed in the closed upright position.

FIG. 3 is a sectional view of the installation showing one example of orientation of the slats in the deployed position.

FIGS. 4A to 4E are sectional elevation views showing the deployment of the head slat switching from a stowed position in an upright position to a closed deployed position.

FIGS. 5A to 5D are sectional elevation views showing the deployment of the second slat switching from a stowed position in an upright position to a closed deployed position.

FIG. 6 is a partial perspective view showing an exemplary embodiment of a slat displacement system and of a slat orientation system.

FIG. 7 is a sectional elevation view showing the displacement system illustrated in FIG. 6.

FIG. 8 is a sectional elevation view showing more specifically the slat orientation system.

DESCRIPTION OF THE EMBODIMENTS

As it emerges more specifically from FIGS. 1 to 3, the object of the invention concerns an installation 1 for covering and uncovering a surface 2 by a series of orientable slats 3 extending one behind the other by being preferably all identical and parallel to each other along their longitudinal axis. Each orientable slat 3 has a generally rectangular shape delimited by a first longitudinal edge 3₁ and a second longitudinal edge 3₂ parallel to each other and connected to each other by first and second end edges 3₃ and 3₄ also parallel to each other. Of course, the number and dimensions of the orientable slats are adapted to the dimensions of the rectangular surface 2 to be covered. Preferably and as it emerges from the drawings, the orientable slats 3 are able to form together a rectangular-shaped screen or curtain delimited on the one hand by the longitudinal edge 3₁ of the first slat 3 and by the longitudinal edge 3₂ of the last slat 3 and on the other hand by all of the first end edges 3₃ of the slats aligned together and by all of the second end edges 3₄ of the slats aligned together.

The slats 3 are provided with a pivot axis 4 at each of their end edges to allow particularly their orientation. The installation 1 includes a mechanism I for orienting the slats 3 along their pivot axis 4 in order to ensure the pivoting of at least some of them and in general all of the slats 3 so that the longitudinal edges 3₁, 3₂ of the neighboring slats are contiguous to close the corresponding surface or are non-contiguous to open the surface 2.

As it emerges from FIG. 3, the orientable slats 3 can take various angular positions. Thus, in an area Z₁, the slats 3 occupy a closed or flat position to form a screen insofar as the longitudinal edges 3₁, 3₂ of the slats are contiguous with the longitudinal edges of the neighboring slats. In one area Z₂, the slats 3 are deployed above the surface by occupying an open upright position that is to say a vertical orientation offset by 90° from the closed or flat position. FIG. 3 also shows, only by way of illustration, slats 3 in the open position in various orientations.

The installation according to the invention also includes a system II for moving the slats 3 between a stowed position (FIG. 1) and a deployed position facing the surface 2 (FIGS. 2 and 3). In the stowed position (FIG. 1), the slats 3 are contiguous to each other between a head slat 3a and a stowage edge 5₁ of a bearing structure or mount 5. The head slat 3a is the first slat taken into consideration of the direction of deployment of the slats represented by the arrow F for which the slats switch from the stowed position to the deployed position. The head slat 3a is the slat moved first while all the slats are in the stowed position.

The displacement system II allows the successive deployment of the slats 3 after the exit of the head slat 3a. Thus, as soon as the head slat 3a has been moved by a translation stroke equal to a spacing pitch, the next slat is moved of course with the continuation of the displacement of the head slat 3a. As soon as this second slat has been moved by a translational stroke equal to the spacing pitch, then the next slat is also moved with the continuation of the displacement of the head slat and of the second slat, and so on until the number of slats that must be deployed. From the head slat 3a, only part of the following slats can be deployed to partially cover the surface or all of the slats are deployed to cover the entire surface. Thus, the slats are translated by being separated in pairs by a spacing pitch called closing center line E. Thus, when all the slats are stopped simultaneously in the desired deployed position, the slats are spaced in pairs by one pitch equal to the closing center line allowing the slats to be contiguous when they occupy the closed or flat position.

Of course, the displacement system II also allows the displacement of the slats 3 along a stowage direction represented by the arrow F1, for which the slats 3 switch from the deployed position to the stowed position. In the stowed position, the slats 3 cannot be oriented and the slats 3 occupy the open upright position, i.e. the slats are located in parallel planes substantially perpendicular to the surface 2, namely vertical planes in the illustrated example.

The systems I and II ensure the displacement and orientation of the slats 3 so that they together form at least one protective screen which can be opened and closed at will. Depending on the intended applications, this screen forms a roof or a protective shutter that can completely cover the surface 2 or only part of the surface 2, with the possibility of orientation of the slats on demand when the slats are not in the stowed position.

The installation 1 also includes two guide tracks 8 ensuring the translational guidance for the slats 3 between a stowed position in which the slats are contiguous to each other (FIG. 1) and a deployed position in which at least part or all of the slats 3 are deployed facing the surface 2 (FIG. 3).

The guide tracks 8 are arranged on the bearing structure of the mount 5 made in any suitable manner depending on the intended applications and surrounding the surface 2 to be covered to advantageously form a frame.

This bearing structure 5 advantageously includes two longitudinal profiles 5₂ and 5₃ extending parallel to each other along two opposite sides of the surface 2 and parallel to the guide tracks 8. These two longitudinal profiles 5₂ and 5₃ are connected to each other at their ends, by connecting profiles 5₁ and 5₄ together forming a frame delimiting the surface 2. One of the connecting profiles 5₄ delimits the abutment edge for the longitudinal edge 3₁ of the first slat, namely the head slat 3a while the other profile 5₁ delimits the stowage edge for the longitudinal edge of the last slat 3. The first slat and the last slat are taken into consideration of the direction of deployment of the slats represented by the arrow F for which the slats switch from the stowed position to the deployed position.

The installation 1 according to the invention is intended to be fixed by any appropriate means on a bearing structure adapted to the intended application. In the case where the installation 1 according to the invention is intended to form the roof of a pergola, for example, the bearing structure 5 includes posts 5p supporting the frame formed by the connecting profiles and the longitudinal profiles.

It must be considered that the orientation system I and the displacement system II for ensuring the displacement and orientation of the slats 3 can be made in any suitable manner using motorized systems for moving in translation and in rotation the slats 3. The following description uses the description of the systems described by the patent FR 3 027 334, but it is clear that the displacement and orientation systems can be different in order to comply, for example, with those described by the patent application WO 2017/178757.

Each slat 3 is supported at each of its ends more specifically by its pivot axes 4, by a set of two carriages 10₁, 10₂ guided in translation along the guide tracks 8. As it emerges more specifically from FIGS. 6 to 8, each slat 3 is therefore supported by its pivot axes 4, using two carriages 10₁, 10₂ moving in translation along the guide tracks between the stowed position and the deployed position. To this end, each carriage 10₁, 10₂ is fitted to a guide bearing 11 cooperating with a guide track 8.

The displacement system II includes, for each pair of carriages 10₁, 10₂ equipping a slat, at least one displacement motor 12 embedded on a carriage and advantageously two displacement motors 12 each embedded on a carriage. It should be understood that each slat 3 is advantageously motorized by two motors to balance the forces applied to the slats 3. For example, the displacement motors 12 are electric motors, for example brush direct current motors connected to a power supply source via connection cables not represented.

It emerges from the description above that the slats 3 are self-propelled and can be moved independently of each other. Each slat 3 can also be oriented individually. Thus, the orientation system I includes for each pair of carriages fitted to a slat, at least one and in the illustrated example, a single orientation motor 14 embedded on one of the two carriages 10₁ and 10₂ fitted to a slat 3. Each orientation motor 14 is angularly connected with a pivot axis 4 to place the slat 3 in a determined upright angular (perpendicular of the surface 2, namely vertical in the case of a pergola), closed (in a horizontal position) or intermediate position taken between these two vertical and horizontal positions.

According to the preferred exemplary embodiment illustrated in the drawings, each slat 3 is therefore supported, at one of its ends, by a first carriage 10₁ embedding only one displacement motor 12 and, at its opposite end, by a second carriage 10₂ fitted to a displacement motor 12 and an orientation motor 14. The second carriages 10₂ equipped with a displacement motor 12 and an orientation motor 14 on the one hand and the first carriages 10₁ equipped with a displacement motor 12 on the other hand are mounted alternately from one slat to the other on each side of the surface 2 to be covered or uncovered. In other words, the first and second carriages are mounted alternately on each longitudinal side of the bearing structure. Such a disposition allows saving space, in particular in the stowed position, as will be explained in the remainder of the description.

Each carriage 10₁, 10₂ has a main body 15 of generally elongated parallelepiped shape extending mainly along the pivot axis 4. Preferably, the bodies 15 of the first and second carriages are not identical for precisely saving space in the stowed position. As it emerges more specifically from FIGS. 6 and 7, the main body 15 of the second carriages 10₂ has a length taken along the direction of extension of the slats 3 shorter than that of the main body of the first carriages 10₁. Indeed, the displacement motor 12 is mounted at the end of the main body 15 of the first carriages 10₁, thus allowing this main body 15 to have a narrowed shape in order to receive the main body of a second carriage 10₂. Thus, the main bodies 15 of the first and second carriages are nested inside each other in a stowed position.

Of course, each displacement motor 12 is mounted in any suitable manner on the main body 15 of each carriage 10₁, 10₂. Each displacement motor 12 drives in rotation a pinion 17 driving in translation a slat 3. Each pinion 17 cooperates with a rack 18 mounted on the bearing structure 5 along a direction parallel to the guide track 8 and along the entire length of the guide track to allow the translation of the slats between their stowed and deployed positions. According to one advantageous variant, each rack 18 is made by a toothed belt fixed on the bearing structure 5.

In the exemplary embodiment illustrated in the drawings (FIG. 6), each rack 18 is mounted on the upper face of a central partition Sa presented by each longitudinal profile 5₂, 5₃. According to this example, each longitudinal profile 5₂, 5₃ has a core 5b extending horizontally and from which the central partition 5a is raised and on either side, an outer flange 5c and an inner flange 5d. The central partition 5a is fitted to the guide track 8 made below the outer face receiving the rack 18. In the illustrated example, the guide track 8 is made by a circular profile rail extending partly in a housing arranged in the partition to allow the mounting of the bearing of the guidance 11.

According to one characteristic of the invention, each longitudinal profile 5₂, 5₃ is made by extrusion. The profiles can be assembled end to end at will to adapt to the dimensions of the surface 2 to be covered. Advantageously, the central partition 5a and the inner flange 5d delimit therebetween a gutter Se in line of which the end edges of the slats extend to possibly collect rainwater.

Advantageously, each guide bearing 11 is connected to the main body 15 of the carriages 10₁, 10₂ by means of a connecting axis 20 preferably detachable in nature. As it emerges more specifically from FIG. 7, the connecting axis 20 extends substantially perpendicularly to the rail 8. The connecting axis 20 is mounted to pass through the main body 15 and the bearing 11 from one side bearing by a head 21 on the body 15 and by being blocked in translation by a blocking element 22 such as a nut bearing on the lower face of the guide bearing.

Advantageously, a spring 23 is engaged on the connecting axis 20 and interposed between the main body 15 and the guide bearing 11 to compensate for the manufacturing and mounting tolerances.

FIG. 7 illustrates more specifically an exemplary embodiment of the first carriages 10₁ each embedding only a displacement motor 12. Each first carriage 10₁ includes a central bore 30 fitted to a system 31 for guiding in rotation the pivot axis 4 of the slat. The pivot axis 4 is driven in rotation by the displacement motor 12 whose output shaft cooperates with a toothed wheel 33 angularly fixed on the pivot axis 4. The pinion 17 is angularly linked to the pivot axis 4 and cooperates with the rack 18. The pivot axis 4 is freely engaged inside a housing 32 arranged in the slat 3. The rotation of the displacement motor 12 in one direction or the other allows moving in translation, along the guide track 8, the carriage 10₁ by the pinion 17/rack 18 connection. The translation of the carriage 10₁ causes the displacement of the corresponding slat 3, because of the translational connection between the pivot axis 4 and the slat 3 by the free engagement of the pivot axis 4 in the housing 32 of the slat. Each pinion 17 cooperates directly with a pivot axis 4 (since they are secured to each other) so as to drive in translation the pivot axis 4 of the slat 3, by the pivot connection made between the slat 3 and the pivot axis 4.

FIGS. 7 and 8 illustrate more specifically an exemplary embodiment of the second carriages 10₂ embedding both a displacement motor 12 and an orientation motor 14. Each second carriage 10₂ includes a bore 40 fitted to a rotational guide system 41 for a tubular shaft 42 inside which a pivot axis 4 is freely engaged. A pinion 17 which cooperates with the rack 18 is angularly linked to this tubular shaft 42 which is driven in rotation by a toothed wheel 44 fixed on the tubular shaft 42 and meshing with the output shaft of the displacement motor 12.

The rotation of the tubular shaft 42 leads to the translation of the second carriage 10₂ causing the translation of the slat whose pivot axis 4 is pushed during the translation of the carriage. Each pinion 17 cooperates indirectly with a pivot axis 4 to drive in translation the pivot axis 4 of the slat 3, by the pivot connection made between the tubular shaft 42 and the pivot axis 4.

Furthermore, the pivot axis 4 is driven in rotation by the orientation motor 14 whose output shaft cooperates with a toothed wheel 47 locked in rotation with the pivot axis 4 whose opposite end is engaged inside the housing 32 and angularly linked to the slat using, for example, connecting pins 48. The pivot pin 4 is thus mounted freely in rotation inside the tubular shaft 42 and can be oriented at will in a stable position determined using the orientation motor 14.

The installation 1 also includes sensors 50 for detecting the position and displacement of the slats 3. Such sensors 50 allow knowing the position of each of the slats 3 at any time throughout their journey on the guide track. Such position and displacement sensors 50 can be produced in any suitable manner.

In the example illustrated and as it emerges more specifically from FIG. 6, the position and displacement sensors 50 include contact sensors each mounted on a carriage 10₁, 10₂ and capable of being actuated by an abutment carried by the carriage located upstream in the exit direction of the slats or by the bearing structure for the carriage of the last slat in the exit direction. These contact sensors allow identifying the position of the slats and particularly in their stowed position. The displacement sensor 50 also includes sensors (not represented) for measuring the rotation of the displacement motors 12, such as encoders. These displacement sensors allow knowing the linear displacement of the carriages 10₁, 10₂ along their guide track 8.

The position and displacement sensors 50 also include sensors for measuring the rotation of the orientation motors 14 allowing knowing the angular orientation of the slats 3. The position and displacement sensors 50 also include sensors for detecting the direction of orientation of the slats.

The installation 1 according to the invention also includes a control device 60 connected to the position and displacement sensors 50, to the displacement system II and to the orientation system I allowing moving in translation at least part of the slats 3 and orienting said translated slats. Such a control device 60 thus allows piloting the operation of the displacement motors 12 and of the orientation motors 14 so as to allow covering and uncovering one or more areas of the surface 2 either on demand or according to pre-recorded programs.

In accordance with the invention, the control device 60 pilots the displacement system II and the orientation system I so that each slat, exiting its stowed position, can switch from its open upright position to its closed position, considering that this passage between its two orientation positions is made in a transition area Ev. FIGS. 4A to 4E explain this operating mode when the head slat 3a is deployed. FIG. 4A illustrates by way of example four slats 3 in the stowed position oriented in the open upright position. For the deployment of the head slat 3a, the control device 60 pilots the operation of the displacement motor 12 and of the orientation motor 14 fitted to this head slat 3a to simultaneously ensure, as illustrated by FIGS. 4B to 4E, the translation of the slat 3a and its tilting to bring it into its closed or flat position. Between its initial open upright position and its closed position, the head slat 3a has been pivoted by an angle alpha equal to approximately 90° and translated on an area called transition area Ev.

It should be noted that the distance or center line Ei between the pivot axis 4 of the head slat 3a and the pivot axis 4 of the neighboring row slat 3 changes during the stroke of the slat on the transition area Ev. When the head slat 3a is stowed in the open upright position, the distance Ei has a minimum spacing value while when the head slat 3a reaches a closed position, the distance Ei has a maximum spacing value. According to one advantageous characteristic, when the head slat 3a reaches its closed position, the distance Ei has a maximum spacing value equal to the closing center line E. It is recalled that the closing center line E corresponds to the spacing between the axes of two deployed neighboring slats allowing these slats to be contiguous when they occupy the closed or flat position. As illustrated in FIG. 4E, the distance Ei is equal to the closing center line E when the head slat is in its closed position.

When the head slat 3a reaches the end of its transition area Ev (FIG. 4E), the control device 60 pilots the operation, on the one hand of the displacement motor 12 of the head slat 3a so that this head slat 3a continues its displacement in its closed position, and on the other hand of the displacement motor 12 and of the orientation motor 14 of the following slat in the stowed position. For the deployment of this second slat 3, the control device 60 pilots the operation of the displacement motor 12 and of the orientation motor 14 fitted to this second slat to ensure, as illustrated in FIGS. 5A to 5D, the translation of the slat 3 and its tilting in order to bring it into its closed position. Between its initial open upright position and its closed position, this second slat 3 has been translated on its transition area Ev. The center line Ei between the pivot axis 4 of the second slat 3 stowed in the open upright position and the pivot axis 4 of the third neighboring stowed slat 3, changes on the transition area Ev between a minimum spacing value and a maximum spacing value advantageously equal to the closing center line E. Thus, in the closed position, the second slat is distant from the third stowed slat, by a value equal to the closing center line. It should be noted that this second slat 3 always remains distant from the head slat 3a by a distance equal to the closing center line E.

The deployment of each of the slats occupying the stowed position is made successively according to the same principle described above in relation to the head slat and to the first slat. At the end of the transition area, the slats are thus translated into the closed position by being separated in pairs by the closing center line E.

When the slats to be deployed according to a chosen number are effectively deployed, the control device 60 stops the control of the displacement motors 12 so that the slats are deployed above the surface. The control device 60 can then optionally control the orientation motors 14 fitted to the deployed slats to allow an individual orientation of said slats. Of course, the slats can be kept oriented in the closed position to together form a screen or a closing shutter.

It emerges from the preceding description that each slat exiting its stowed position is, at the end of its transition position, moved in flat translation up to its final position, each slat having reached its final position possibly being oriented along a determined angulation.

Of course, the stowage of the deployed slats is made according to the reverse principle to the deployment principle described above.

According to one characteristic of the invention, the control device 60 pilots the orientation system I so as to place each deployed slat in the closed position before the translational displacement along the direction of stowage of said slats. Indeed, the stowage of the deployed slats is made only if the deployed slats occupy the closed or flat position.

Thus, the control device 60 pilots the displacement system II, that is to say the displacement motors 12 for moving the slats deployed to ensure the translation of the slats along the direction of stowage while these slats are in the closed position. In addition, the control device 60 pilots the operation of the orientation motor 14 fitted to the deployed slat furthest from the head slat 3a, to ensure at the start of the transition area Ev, its tilting and bring it into its open upright position at the end of the transition area Ev. Each next slat is successively stowed according to the same principle.

According to one advantageous characteristic of the embodiment, the control device pilots the displacement system II and the orientation system I so that each slat in the transition area Ev follows a regular orientation stroke to switch from its open position to its closed position and conversely.

It emerges from the description above that the displacement of the slats in the closed or flat position allows reducing the resistance to displacement relative to the wind. The first of the slats stowed in the open upright position acts as a deflector for the wind. Furthermore, the deployment of the slats in the closed or flat position allows a faster surface coverage compared to a deployment of the slats in the upright position followed by a pivoting of the deployed slats.

Of course, the control device includes a calibration mode allowing the installation to position the slats 3 in a defined position in order to identify their position. In general, the control system pilots the motors 12, 14 before any first use in order to place the different slats 3 in the stowed position with an upright orientation. The identification of the position of the slats 3 in the stowed position is ensured by the contact sensors. The invention is not limited to the described and represented examples because various modifications can be made without departing from its scope.

Claims

1. An installation for covering and uncovering, using orientable slats (3), a surface (2) delimited by a bearing structure (5), the installation including: a series of orientable slats (3) with longitudinal axes parallel to each other along their longitudinal edges and fitted to a pivot axis (4) at each of their end edges;each slat (3) is supported by its pivot axes (4) using a set of a first carriage (10i) and of a second carriage (102) which are guided in translation along guide tracks (8);two tracks (8) for guiding in translation the carriages, arranged on the bearing structure (5) by being disposed parallel to each other along two opposite sides of the surface;a slat (3) orientation system (I) adapted to ensure the pivoting of at least some of the slats in order to occupy a closed position or an open position of the corresponding surface;a system for moving in translation (II) the slats (3) between a stowed position in which the slats are contiguous to each other in an open upright position and a deployed position in which the slats are deployed above the surface by being separated in pairs by a closing center line;sensors to determine the orientation and the displacement of the slats (3);and a control device (60) connected to the sensors, to the displacement system (II) and to the orientation system (I) to move in translation at least part of the slats and orient said slats

2. The installation according to claim 1, characterized in that the control device pilots the displacement system (II) and the orientation system (I) such that for each slat being deployed or stowed, the distance (Evi) between the pivot axis (4) of the slat during deployment or stowage and the pivot axis (4) of the neighboring slat stowed in the open upright position, changes between a minimum spacing value and a maximum spacing value during its stroke on its transition area.

3. The installation according to claim 2, characterized in that the control device pilots the displacement system (II) and the orientation system (I) such that for each slat being deployed or stowed, the maximum spacing value during its stroke over its transition area is substantially equal to the closing center line (E).

4. The installation according to claim 1, characterized in that the control device pilots the displacement system (II) such that outside the transition area, the deployed slats are moved by being spaced in pairs at a distance equal to the closing center line (E).

5. The installation according to claim 1, characterized in that the control device pilots the displacement system (II) and the orientation system (I) such that each slat in the transition area follows a regular orientation stroke to switch from its open position to its closed position and conversely.

6. The installation according to claim 1, characterized in that the control device pilots the orientation system (I) so as to place each slat in the closed position before the translational displacement of said slats.

7. The installation according to claim 1, characterized in that the displacement system (II) includes, for each pair of carriages (101, 102) fitted to a slat, at least one displacement motor (12) embedded in a carriage and driving in rotation a pinion (17) cooperating with a rack (18) mounted on the bearing structure along a direction parallel to the guide track, each pinion (17) cooperating with a pivot axis (4) to drive in translation the pivot axis (4) of the slat (3).

8. The installation according to claim 7, characterized in that the displacement motors (12) each drive in rotation a pinion (17) cooperating with a rack (18) mounted on the bearing structure along a direction parallel to the guide track.

9. The installation according to claim 6, characterized in that the orientation system (I) includes, for each pair of carriages fitted to a slat, at least one orientation motor (14) embedded in at least one of said carriages and angularly connected with the pivot axis (4).

10. The installation according to claim 9, characterized in that for each slat, the displacement motor (12) and the orientation motor (14) are mounted on the same carriage, these carriages fitted to these motors being mounted alternately from one slat to another, depending on each side of the surface to be covered or uncovered.

11. The installation according to claim 9, characterized in that each carriage (102) fitted to a displacement motor (12) and to an orientation motor (14) includes a main support body (15) for the displacement motor and the orientation motor, the main body (15) being provided with a system (41) for guiding in rotation a tubular shaft (42) fitted to a pinion (17) and driven in rotation by the displacement motor, the pivot axis (4) being mounted inside the tubular shaft (42) by being driven in rotation by the orientation motor (14) and mounted secured in rotation to the slat.