BE1029721A1 - Louvered roof, terrace covering comprising the same, and a set of parts and a method for assembling the same - Google Patents

Abstract

A slatted roof for a terrace covering. The slatted roof is provided with a set of parallel slats (7, 7'), whereby two adjacent slats have a different bending resistance. The stiffer slat (7') is intended for supporting, e.g. attaching or integrating thereto, one or more desired components. These components then exert an additional load on the stiffer slat so that both slats have virtually the same deflection. In this way, functional elements can be attached to a slat of the slatted roof without obtaining a slat with deviating deflection.

Description

1 BE2021/5684

Louvered roof, terrace covering comprising the same, and a set of parts and a method for assembling the same

Technical field

The present invention relates to a slatted roof. The present invention also relates to a set of parts and a method for building such a louvered roof. The present invention furthermore relates to a terrace covering comprising such a slatted roof.

State of the art

Slatted roofs are usually set up to shield or free up an outdoor area. For example, such terrace coverings are often set up at homes, restaurants, shops, etc. to shield an outdoor terrace or the like from sun rays, precipitation and/or wind or, conversely, to temporarily let in sun rays. These coverings can, for example, take the form of an awning, a pergola, a veranda, a carport, a pavilion, etc.

In the context of a louvre roof, there are typically four orientations (namely above, below, outside and inside) for the frame of the louvre roof. Here, “above” refers to the part of the louvered roof that is or will be oriented towards the upper plane (i.e. the sky, e.g. the open sky), “below” to the part of the louvered roof that is or will be oriented towards the ground plane ( i.e. the earth, e.g. the patio floor), “outside” to the portion of the louvered roof that is or will be oriented away from the roof (i.e. away from the louvers) and “pegs” to the portion of the roof structure that is or will be oriented towards the inside of the louvre roof (i.e. towards the louvres).

A louvre roof typically comprises a frame comprising at least two beams extending parallel to each other and to which several louvres are pivotally connected between an open position and

D BE2021/5684 a closed position. In the open position there is a gap between the slats and in the closed position the slats together form a continuous cover. By rotating the slats between these positions, the incidence of light, radiant heat and ventilation to the space below the slats can be regulated. For example, by directing the slats, sun and/or wind can be shielded or let through. In other words, the louvered roof serves as protection against the sun, precipitation, wind, etc. for a space below.

In addition, in their open position, the slats can optionally be provided slidably in the slatted roof, wherein they are then typically slidable between a position in which they are arranged spread over the slatted roof and a position in which they are arranged mainly on one side of the slatted roof. In addition to rotatable blades, it is also possible to include one or more fixed blades in the blade roof. A fixed slat is a slat that is permanently connected to the beams and is therefore neither rotatable nor slidable.

A problem with such a louvered roof is the integration or attachment of various components in or on louvres that influence the deflection of the louvres. An example of such an integration is disclosed in WO 2021/048773 A1 where a slat is disclosed with an integrated heating element therein.

The fact is that by integrating an additional element in a slat, an extra weight has been added to the slat compared to the other slats in the slatted roof. Adding this additional weight then affects the deflection of the slat and typically causes the slat with integrated component to have a higher deflection than the adjacent slats.

A related problem with such a slatted roof is the manufacturing tolerance of the individual slats. The permitted manufacturing tolerance for aluminum extrusion profiles (typically a slat is a profile extruded from aluminum or an alloy thereof)

3 BE2021/5684 is defined in NBN EN 12020-2:2017. The permitted manufacturing tolerance regarding the straightness of an extrusion profile is a deflection of up to a maximum of 3 mm for a profile with a length between and 6 m. In other words, the maximum manufacturing tolerance allows a deflection difference of 6 mm between adjacent slats. In addition, even higher manufacturing tolerances may be used for profiles with a complex design.

Irrespective of the reason for the different deflection (e.g. an integrated component or manufacturing tolerance), these differences, especially in the closed position of the slats, are undesirable. First of all, this is visually disturbing because the underside of the closed slatted roof does not have a uniformly flat appearance. In addition, this has a negative effect on the watertightness of the louvered roof. The waterproofing between two slats is typically based on hooking and/or fitting parts of the adjacent slats together. However, this interlocking and/or fitting is made more difficult if the deflection is too different.

Description of the invention

It is an object of the present invention to provide a slatted roof in which a difference in deflection between adjacent slats can be minimized when one or more integrated components are present in one of the two adjacent slats.

This object is achieved by a louvered roof for a terrace covering, wherein the louvered roof is provided with a frame and a set of mutually parallel slats attached to the frame, the slats extending in a longitudinal direction, wherein a first slat of said set of slats has a first bending resistance. and a second slat of said set of slats has a second bending resistance

4 BE2021/5684 which is smaller than the first bending resistance, which first and second slats adjoin each other, and wherein the first slat is provided with an additional load such that a deflection of the first slat and the second slat are virtually equal.

The present invention is based on the finding that a stiffer slat (i.e. the first slat having a higher bending resistance) has a lower deflection than a less stiff slat (i.e. the second slat). The deflection of a slat depends on, among other things, the design and the material of the slat. In particular, the deflection is inversely proportional to the moment of inertia of the cross-section of the slat and to the elastic modulus of the material of which the slat is made. The present inventors have realized that a rigid slat can be used to support (e.g. integrated or attached thereto) one or more desired components in such a way that these components then exert an additional load on the stiffer slat such that the first slat and the second slat have almost the same deflection. In other words, by deliberately making the first slat stiffer than the second slat, an additional load can be applied to the first slat in order to achieve virtually equal deflection at each of the slats. In this way, functional elements can be attached to a slat of the slatted roof without obtaining a slat with deviating deflection.

In an embodiment of the present invention, the additional load is formed by a functional component and/or a weight element, wherein the functional component is selected from a plurality of mutually different functional components.

The weight element is advantageous in compensating for the different loads exerted by each of the mutually different functional components. In other words, an end user has the choice to select one or more from a predetermined set of mutually different functional components for his louvered roof. Depending on the choice of the user, an additional weight element is then added so that the total load (ie the sum of the load of the chosen functional components and the weight element) is sufficient to obtain the desired deflection of the stiffer (ie. first) slat. Also, a weight element is not necessary. There is a maximum load that can be carried by the first slat, which depends on how much stiffer this slat is. If the user selects functional components that together exert the maximum load, no additional weight element is required. The reverse situation, ie only a weight element, is also possible. This, for example, if the user does not want any functional components at the moment, but does want the option to add them later and therefore already includes a stiffer slat in the slatted roof.

In a first alternative embodiment, the weight element has a mass that depends on a mass of the functional component, wherein, preferably, the sum of the masses of the weight element and the functional component is constant. Preferably, the weight element has a fixed position in the slat that is independent of the mass of the functional component. This placement is further preferably almost in the middle of the slat, viewed in the longitudinal direction.

This first alternative embodiment uses a variable weight element depending on the weight of the functional components chosen by the end user. In this way, the load exerted by the weight element varies in addition to the load exerted by the selected functional components in order to jointly exert the desired load in order to give the stiff slat the same deflection as the less stiff slat. Preferably, the total mass of the weight element and the chosen functional

6 BE2021/5684 components constant. This is advantageous since the total mass has a direct influence on the load, so that a constant mass more easily gives rise to the desired constant load. Preferably, the placement of the weight element is fixed. This allows predetermined fixing elements to be provided inside the slat for holding the weight element. This placement is preferably in the center of gravity of the slat so that torsional forces are avoided or at least reduced. Torsional forces can also be avoided or at least reduced by providing two (or more) weight elements which are located at virtually the same distance from the center of gravity in the transverse direction of the slat.

In a second alternative embodiment, the weight element has an arrangement in the longitudinal direction of the slat that depends on a mass of the functional component. Preferably, the weight element has a fixed mass that is independent of the mass of the functional component. Displacing means are preferably provided for displacing the weight element relative to the slat in the longitudinal direction of the slat. Alternatively, the first slat can be provided with a removable part (e.g. a removable top wall) that allows the weight element to be moved from the top of the slat. The placement of the weight element is preferably fixed in the width direction and preferably in the center of gravity of the slat so that torsional forces are avoided or at least reduced. Torsional forces can also be avoided or at least reduced by providing two (or more) weight elements which are located at virtually the same distance from the center of gravity in the transverse direction of the slat.

This second alternative embodiment uses a variably positioned weight element depending on the weight of the functional components chosen by the end user. More specifically, the higher the mass of the chosen functional components,

7 BE2021/5684 the less central the weight element should be placed in the longitudinal direction of the slat. The use of a weight element with a fixed mass is advantageous because then only one element has to be provided. The provision of weight element displacement means is advantageous for correctly positioning the weight element and prevents them from having to be pushed manually into a slat that can have a length of 2 to more than 5 m.

In short, both alternative embodiments provide the desired load to obtain the desired deflection.

The first embodiment does this by varying the load via the mass of the weight element that is in a fixed position. The second embodiment does this by varying the load by providing a constant mass weight element but varying the position along the slat. The second embodiment has the additional advantage that the control of the deflection of the rigid vane can be done precisely because the position can typically be adjusted almost continuously, while the addition and/or removal of weight (i.e. the first embodiment) is done in discrete steps .

In an advantageous embodiment of the present invention, the weight element is removably attached to the slat. This allows the weight element to be removed later. This is advantageous for possible repairs, but is especially useful if the end user wishes to change his chosen functional components.

In an advantageous embodiment of the present invention, the first slat is provided with a cavity, wherein the weight element is located in said cavity. In this way, the weight element is protected against weather influences and also hidden from view.

In an advantageous embodiment of the present invention, the weight element is located virtually in the center of gravity of the slat, viewed in a width direction of the slat. This avoids or reduces torsional forces on the slat around the axis of rotation. Also can

8 BE2021/5684 Torsional forces are avoided or at least reduced by providing two (or more) weight elements that are located at virtually the same distance from the center of gravity in the transverse direction of the slat.

In other words, the weight element is preferably evenly distributed with respect to the center of gravity in the width direction of the slat.

In an advantageous embodiment of the present invention, the functional component comprises one or more of: a heating element, lighting, such as LED lighting, an audio element, such as a loudspeaker, an imaging element, such as a screen and/or a projector, communication means, such as Bluetooth or WiFi, a sensor, such as a rain sensor, wind sensor, or a light sensor, a power generating device, such as a solar cell, a ventilation element, such as a fan. This increases the available options that an end user can apply in his louvered roof.

In an embodiment of the present invention, a difference in deflection between the first and the second slats is at most 10 mm, preferably at most 6 mm, more preferably at most 4 mm and most preferably at most 2 mm, wherein the deflection in particular measured is near the center of the slat viewed in the longitudinal direction. The lower this difference, the easier it is to make the louvered roof watertight in its closed position and the tighter the appearance of the underside of the louvered roof.

In an embodiment of the present invention, the first slat has a first moment of inertia and the second slat has a second moment of inertia, the first moment of inertia being at least 25%, preferably at least 75% and more preferably at least 100% greater than the second moment of inertia.

Increasing the moment of inertia is one way to increase the bending resistance of a leaf as the deflection is typically inversely proportional to the moment of inertia. It has been found to allow an increased moment of inertia of at least 25%

9 BE2021/5684 to make the deflection of the first slat with additional load almost equal to that of the second slat. Of course there are other ways to increase the bending resistance of the first ply, such as the choice of material, in particular using a material with a higher elastic modulus, or by reducing the self-load of the first ply.

It is a further object of the present invention to provide a slatted roof in which a difference in deflection between adjacent slats can be minimized in the presence of manufacturing tolerances.

This further object is realized by a louvre roof for a terrace covering, wherein the louvered roof is provided with a frame and a set of mutually parallel slats are attached to the frame, wherein the slats extend in a longitudinal direction and wherein each slat has a deflection and wherein each slat (or each slat except the one with the highest deflection) is provided with an additional load such that the deflection of each slat is virtually equal.

By adding an additional load in each slat, it is possible to bend each slat until it is almost equal to the most deflected slat (i.e. the slat with the highest deflection).

In this way, manufacturing tolerances can be accommodated without the need to dispose of manufactured slats in the waste.

The additional load can be formed by a weight element with a fixed or a variable mass and with a fixed or variable position as already described above for the alternative embodiments.

In an embodiment of the present invention, a difference in deflection between adjacent slats is at most 10 mm, preferably at most 6 mm, more preferably at most 4 mm and most preferably at most 2 mm, the deflection being in particular the measurement is taken almost in the middle of the slat

10 BE2021/5684 seen in the longitudinal direction. The lower this difference, the easier it is to make the louvered roof watertight in its closed position and the tighter the appearance of the underside of the louvered roof.

The advantages described above are also achieved with a terrace covering comprising a slatted roof as described above.

The advantages described above are also achieved with a set of parts for building a louvered roof as described above, in which the set includes the frame, the set of louvers and an additional load formed by one or more of a multitude of mutually different functional components and /or includes a weight element.

The advantages described above are also achieved with a method for building a louvre roof as described above, the method comprising: providing the set of parts described above; placing the one or more functional components in the first slat; placing the weight element in the first slat; and placing the set of slats in the frame.

Brief description of the drawings

The invention will hereinafter be explained in further detail with reference to the following description and the accompanying drawings.

Figure 1 shows a schematic view of a covering.

Figure 2 shows an embodiment of the covering in more detail.

Figures 3A and 3B show a perspective view of the top and bottom side, respectively, of a slatted roof not according to the invention, wherein an additional load is exerted on the central slat.

Figures 4A and 4B show a section through planes A and B indicated in Figure 3A.

11 BE2021/5684

Figures 5A and 5B show a perspective view of the top and bottom side, respectively, of a first embodiment of a louvered roof according to the present invention.

Figures 6A and 6B show a section through planes A and B indicated in figure BA.

Figures 7A and 7B show a perspective view of the top and bottom side, respectively, of a second embodiment of a louvered roof according to the present invention.

Figures 8A and 8B show a section through planes À and B indicated in figure 7.

Figure 9 shows the same cross-section as figures 6B and 8B in which no additional load is exerted on the central slat.

Embodiments of the Invention

The present invention will be described below with reference to specific embodiments and with reference to specific drawings, but the invention is not limited thereto and is defined only by the claims. The drawings shown here are only schematic representations and are not limitative. In the drawings, the dimensions of certain parts may be enlarged, which means that the parts in question are not shown to scale, and this is for illustrative purposes only. The dimensions and relative dimensions do not necessarily correspond to the actual practice of the invention.

In addition, terms such as "first", "second", "third", and the like are used in the description and in the claims to distinguish between similar elements and not necessarily to indicate a sequential or chronological order. The terms in question are interchangeable in appropriate circumstances, and the embodiments of the invention may operate in orders other than those described herein

12 BE2021/5684 or illustrated.

In addition, terms such as "top", "bottom", "above", "below", and the like are used in the description and in the claims for descriptive purposes. The terms so used are interchangeable in appropriate circumstances, and the embodiments of the invention may operate in orientations other than those described or illustrated herein.

The term "comprising" and derivative terms, as used in the claims, should and should not be construed as being limited to the means set forth in each case thereafter; the term does not exclude other elements or steps. The term should be interpreted as specifying the listed properties, integers, steps, or components referred to, without, however, excluding the presence or addition of one or more additional properties, integers, steps, or components, or groups thereof. The scope of an expression such as "a device comprising means A and B" is therefore not limited only to devices consisting purely of components A and B. Rather, what is meant is that, with regard to the present invention, the only relevant components are A and B.

The term "substantially" includes variations of +/- 10% or less, preferably +/-5% or less, more preferably +/-1% or less, and more preferably +/-0.1% or less, of the specified state, insofar as the variations are appropriate to function in the present invention. It is to be understood that the term “substantially A” is intended to include “A”.

Figure 1 illustrates a covering 1 for a ground surface, for instance a terrace or garden. The roof comprises a plurality of columns 2 supporting different beams 3, 4, 5. The columns and beams together form frames to which wall infills 6 and/or roof coverings 7 can be attached as described below. The

13 BE2021/5684 covering 1 comprises three types of beams 3, 4, 5, namely: a beam 3 that serves as an external pivot beam 3 on the outside of the covering 1; a girder 4 serving centrally in the covering 1 as a central pivot beam 4; and a girder 5 serving as tension beam 5. It will also be appreciated that the girders 3, 4, 5 can be attached to other structures, e.g. In such a way the covering 1 can generally be used for shielding an outdoor space, as well as for an indoor space.

The roof 1 shown in figure 2 comprises four support columns 2 which support a frame, also called roof frame. The frame is formed from two external pivot beams 3 and two tension beams 5, between which a roof covering 7 is provided. A wall infill 6 can optionally be provided between two support columns 2 and a pivot beam 3 or tension beam 5.

Wall infills 6 are typically intended to screen off openings under the roof 1 between the columns 2. The wall infills 6 can be fixed or movable. Movable side walls include, for example, screens that can be rolled up and down and/or wall elements that are arranged slidably relative to each other, etc. Fixed side walls can be manufactured from various materials, such as plastic, glass, metal, textile, wood, etc. Combinations of different wall infills 6 are also possible. Figure 2 illustrates a wall infill in the form of a screen 6 that can be rolled up and down. The screen 6 extends between two adjacent columns 2 and can be rolled down from the external pivot bar 3. The screen 6 mainly serves as a wind and/or sun screen. .

In one embodiment, the roof covering 7 is formed by slats which are rotatably attached to the pivot beams 3 at their ends. The slats are rotatable between an open position and a closed position. In the open position there is a gap between them

14 BE2021/5684 the slats through which, for example, air can enter or leave the underlying space. In the closed position, the slats form a closed canopy with which the underlying space can be shielded from wind and/or precipitation, such as rain, hail or snow. Towards the discharge of precipitation, the slats are typically arranged with a sloping angle towards one of the two pivot beams 3. In addition, it is also possible for one or more of the slats to be fixed (i.e. non-rotatable) to the pivot beams 3. Figure 2 illustrates the closed position in which the slats 7 together form a virtually continuous cover. In the open position (not shown) there is an intermediate space between the slats 7.

As further used herein, the term "longitudinal direction of the louvered roof" refers to the direction along which the beams 3 extend, as indicated by arrow 8 in figure 2.

As further used herein, the term "transverse direction of the louvered roof" means the direction along which the louvers 7 extend, as indicated by arrow 9 in figure 2. The longitudinal direction and the transverse direction of the louvered roof are substantially perpendicular to each other.

As further used herein, the term "longitudinal direction of a slat" refers to the direction along which the slats 7 extend as indicated by arrow 36 in Figure 3A.

As used further herein, the term "transverse direction of a slat" means the direction substantially perpendicular to the longitudinal direction of a slat as indicated by arrow 37 in Figure 3A.

The slats are typically made of a rigid material. This can be aluminum, for example. Aluminum has many advantages as a material, as it is robust and light at the same time, resistant to bad weather conditions and requires little maintenance. However, other materials are also suitable and their advantages or disadvantages are assumed to be known to those skilled in the art. A slat can be produced using different techniques depending on it

15 BE2021/5684 material, including extruding, milling, bending, casting, welding, and so on.

The appropriate manufacturing technique is presumed to be known by those skilled in the art. The slats are preferably manufactured by means of an extrusion process. Optionally, filling elements made of, for example, polycarbonate, glass, wood, etc. can be used to at least partially fill the hollow slats, for example to obtain a different appearance of the slat, in particular if the slat is made of a transparent material. like glass.

By rotating the slats 7 between the open position and the closed position, the incidence of light, radiant heat and ventilation to the space below the slats can be controlled. In the open position, there is an intermediate space between the slats 7 through which, for example, air can be introduced into the underlying space or can leave this underlying space. In the closed position, the slats 7 form a closed shelter with which the underlying space can be shielded against, for instance, wind and/or precipitation, such as rain, hail or snow. Towards the discharge of precipitation, the slats 7 are typically arranged with a sloping angle towards one of the two pivot beams 3.

Details regarding the attachment of a slat 7 to the pivot beams 3 are known to a person skilled in the art. Details can be found e.g. in patent application BE 2016/5365. The attachment typically uses a shaft that passes through the slat 7 and connects to an end piece provided with a slat shaft that engages an opening in the pivot beams 5, which opening is typically provided with a bearing. It will be clear that other connections, for instance without an end piece, in which case the lamellar axis is then present directly on the lamellae, are also possible.

With regard to the figures, any reference to an orientation of the beams will be interpreted with reference to the position when mounted in the terrace covering. In this way there are four orientations, namely above, below, outside and inside. Here “top” refers to the part of the beam that is or will be oriented

16 BE2021/5684 towards the upper plane (the sky, e.g. the open sky), “below” to the part of the beam that is or will be oriented towards the ground plane (the earth, e.g. the terrace floor), “outside” to the part of the beam that is or will be oriented towards the roof, i.e. away from the roof infill and "inside" to the portion of the beam that is or will be oriented towards the inside of the roof, i.e. facing the roof infill.

The present reference generally relates to the deflection of the slats 7 and to ways of ensuring that the deflection between adjacent slats 7, particularly in the closed position of the slats, is substantially the same. It is therefore instructive to introduce a number of concepts.

In general, each slat 7 is arranged in the roof frame according to the principle of double support. In other words, each slat 7 is connected to the roof frame at both ends. This can be a fixed or a movable, in particular rotatable, attachment. The length

L of a slat 7 is defined as the distance between its ends viewed in the longitudinal direction 36 of the slat 7.

Different types of loads are possible on a slat 7. First, there is the load due to the weight of the slat 7. Such a load results in a deflection f which can be calculated via: f= 5*(Q *L* 384 * E * where Q is the evenly distributed load is due to the weight expressed in N/mm, E is the modulus of elasticity of the material from which the vane is made (e.g. 70 GPa for aluminium) and 7 is the moment of inertia of the vane, which is determined by the design of the vane, in particular by the shape of the cross-section. Those skilled in the art are familiar with ways of calculating the moment of inertia. The product of E*I is also referred to as the bending resistance.

17 BE2021/5684

Another type of load is a point load in the center of the slat 7 viewed in its longitudinal direction. Such a load results in a deflection f which can be calculated via:

P x LS “785551 where P is the point load expressed in N. Other locations for the point load (e.g. not in the center of the slat) are also possible and the skilled person is supposed to be able to calculate the resulting deflection f calculate.

The present invention aims to provide a louvre roof in which a difference in deflection between adjacent louvres can be minimized in the presence of one or more integrated and/or attached components in and/or to one of the two adjacent louvres. Figures 3A to 9 show three adjacent slats 7 in each case. In each case, the central slat is subject to an additional load by the above-mentioned integrated and/or attached components. For the sake of clarity, the slat to be loaded will be indicated with reference numeral 7' to distinguish it from the rest of the slats 7. It should be clear that the slat 7' can be either a fixed slat or a rotatably mounted slat.

Figures 3A to 4B illustrate the problems that occur when integrating and/or fixing additional components in a slat 7.

In figures 3A to 4B, each of the slats 7, 7' are identical to each other.

By integrating and/or attaching one or more components to slat 7', this slat 7' is subject to an additional point load. Due to this additional point load, there is also an additional deflection (additional to the normal deflection as a result of its own weight) of the central slat 7', as a result of which the central slat 7' deflects more than the adjacent slats 7. This is indicated in figure 3B by reference numeral 11 and is also clearly shown

18 BE2021/5684 in figure 4B where the central slat 7' is clearly lower than the adjacent slats 7. As shown in figures 3A to 4B, the problem of deflection is best visible in the middle of the slat 7' in its longitudinal direction 36 while typically no different deflection is visible near the ends of the slat 7”.

The present invention as shown in figures SA to 9 is based on providing a stiffer slat 7' compared to the adjacent slats 7. The higher bending resistance of slat 7' can be achieved in different ways, e.g. moment of inertia increases and/or a different choice of material with a higher elastic modulus and/or an adapted, in particular lower, weight such that the deflection due to the self-load is lower.

Due to the higher bending resistance of slat 7', this slat will, without additional load, bend less than the adjacent slats 7 as shown in figure 9. In this embodiment, the higher bending resistance of slat 7' is partly the result of its modified design.

To illustrate, in a specific example, both the rigid vane 7' and the plain vanes 7 are made of aluminum with a modulus of elasticity of 70 GPa. The ordinary slat 7 has a moment of inertia of 385000 mm* and a weight of 3.1 kg/m. The 7' rigid slat has a moment of inertia of 850000 mm" and a weight of 5 kg/m. Both slats 7, 7' are 4.4 m long in this example.

In this way, the regular slat 7 has a theoretical deflection (at the center of the slat) of 5.51 mm, while the rigid slat 7' has a theoretical deflection of 4.02 mm.

The present invention is furthermore based on additional loading of the rigid slat 7' so that the deflection of the rigid slat 7' is virtually the same as that of the adjacent slats 7. This additional loading typically consists of a sum of two load groups, namely one or more point loads as a result of the integration of functional components in the slat 7' and one or more

19 BE2021/5684 point loads as a result of applying a non-functional weight. Since the slat 7' has a predetermined bending resistance, there is a maximum theoretical load that ensures that the slat 7' has the same deflection as the adjacent slats 7. The idea is that the sum of the two groups of loads together results in the maximum theoretical load obtained.

More specifically, an end user has the choice of selecting one or more from a predetermined set of mutually different functional components for his louvered roof. Each component has its own weight and placement in or on the slat 7' and therefore exerts an additional point load which causes additional deflection of the slat 7'. If this load/deflection is even lower than desired, an additional non-functional weight 10 is fitted in the slat 7'. A weight element 10 is not necessary if the user selects functional components that together exert the maximum load. The reverse situation, viz. only a weight element 10, is also possible. This, for example, if the end user does not want any functional components at the moment, but does want the option to add them later and therefore already includes a stiffer slat 7' in the slatted roof.

A number of possible functional components are: a heating element, lighting, such as LED lighting, an audio element, such as a loudspeaker, an imaging element, such as a screen and/or a projector, means of communication, such as Bluetooth or Wi-Fi, a sensor, such as a rain sensor, wind sensor, or a light sensor, a power generating device, such as a solar cell, a ventilation element, such as a fan, etc.

Figures SA to 8B illustrate two different embodiments for placing a weight element 10 in the slat 7' to obtain the desired deflection.

In the embodiment of Figures 5A to 6B is used

20 BE2021/5684 of a weight element 10 with a fixed position in the slat 7' but with a variable mass. The placement is preferably centrally in the slat 7' and this preferably in the longitudinal direction 36 and/or in the center of gravity in the transverse direction 37 or evenly distributed at a substantially equal distance from the center of gravity in the transverse direction 37. In the longitudinal direction direction 36 this is advantageous because the influence on the deflection is then maximal and in the transverse direction 37 this is advantageous for avoiding torsional effects on the slat 7'. Adding more or less mass to the weight element 10 increases or decreases the deflection. In other words, depending on the functional components chosen by the end user, more or less mass is added to the weight element 10 until the desired deflection is achieved.

In the embodiment of Figures 7A to 8B, two weight elements 10 are used with a variable placement in the longitudinal direction 36 in the slat 7' but with a fixed mass. In the transverse direction 37, the weight elements 10 are preferably placed nearly at the center of gravity or nearly evenly spaced substantially equidistant from the center of gravity in the transverse direction 37 to avoid torsional effects on the vane 7'. Placing the weight elements 10 more towards the center of the slat 7' in the longitudinal direction 36 increases the deflection and vice versa when moving the weight elements 10 towards the ends of the slat 7. In the embodiment shown there are two symmetrical ( weight elements 10) placed relative to the center of the slat 7' in the longitudinal direction 36). This contributes to a symmetrical deflection of the slat 7' around the center thereof in the longitudinal direction 36. However, it should be clear that only one movable weight element 10 is also possible or that more than two weight elements 10 can be provided.

Of course, a combination of both embodiments is also possible. Furthermore, the invention can also be used for a slat that is loaded asymmetrically by several functional components, which

21 BE2021/5684 asymmetrical load gives rise to torsional forces around the unloaded center of gravity (in the transverse direction) of the slat. This is because the weight element can be divided into several separate elements, which in turn are arranged asymmetrically to compensate for the torsional forces caused by the functional components.

Hence the invention allows to load the slat 7' additionally (i.e. in addition to the load caused by the functional components) to ensure that the slat 7' has the desired deflection (i.e. the same as the adjacent slats) and to ensure that no (or little) torsional forces act on the slat 7' in the transverse direction of the slat.

The use of several (movable) weight elements 10 is advantageous because it has more degrees of freedom (e.g. the placement in the longitudinal direction of the slat, the placement in the transverse direction of the slat and/or the mass of each weight element) and thus a finer adjustment. For example, when using several functional components at different places in the slat, several weight elements 10 allow to compensate for the necessary deflection, while the influence on the center of gravity of the slat (both in transverse and longitudinal direction) is reduced to a minimum can be reduced.

In an example, an overview is available in which, for each possible combination of functional components, it is indicated how much mass should be used in the weight element 10 (execution of figures 5A to 6B) and/or where the weight elements 10 should be placed ( embodiment of Figures 7A to 8B).

In the embodiments shown in figures 5A to 8B, the central slat 7' is still open at its top. This opening makes it possible to weigh down and/or move the weight element 10. It is preferable to close this opening at the end of the assembly, e.g. with a finishing profile, to protect the internal components in the 7' slat.

29 BE2021/5684 against external influences, e.g. weather conditions.

The present inventors have also realized that the weight element described above can also be used to compensate for manufacturing tolerances of the slats 7. In particular, a weight element can be placed in each slat 7 until the deflection of each slat 7 in the slatted roof is substantially the same. is.

For this purpose, both the placement and/or the mass of the weight element can be adjusted.

While certain aspects of the present invention have been described with respect to specific embodiments, it is to be understood that these aspects may be implemented in other forms within the scope of protection as defined by the claims.

Claims (19)

23 BE2021/5684 Conclusions 1. A louvered roof for a terrace covering (1), where the louvered roof is provided with a frame (3, 5) and a set of mutually parallel slats (7) attached to the frame, the slats extending in a longitudinal direction (36), characterized in that a first slat (7') of said set of slats has a first bending resistance and a second slat (7) of said set of slats has a second bending resistance which is smaller than the first bending resistance, which first and second slats adjoin each other, and that the first slat is provided with an additional load such that a deflection of the first slat and the second slat are virtually equal. A louvered roof according to claim 1, characterized in that the additional load is formed by a functional component and/or a weight element (10), the functional component being selected from a plurality of mutually different functional components. A louvre roof according to claim 2, characterized in that the weight element has a mass that depends on a mass of the functional component, wherein, preferably, the sum of the masses of the weight element and the functional component is constant. A slat roof according to claim 3, characterized in that the weight element has a fixed position in the slat that is independent of the mass of the functional component. A louvered roof according to claim 4, characterized in that the weight element is located almost in the center of the louvre, viewed in the longitudinal direction. 24 BE2021/5684 A louvered roof according to claim 2, characterized in that the weight element has an arrangement in the longitudinal direction of the louver that depends on a mass of the functional component. A louvered roof according to claim 6, characterized in that the weight element has a fixed mass that is independent of the mass of the functional component. A slatted roof according to claim 6 or 7, characterized in that displacement means are provided for displacing the weight element relative to the slat in the longitudinal direction of the slat. A louvered roof according to any one of claims 2 to 8, characterized in that the weight element is removably attached to the louver. A louvre roof according to any one of claims 2 to 9, characterized in that the first louver is provided with a cavity, the weight element being located in said cavity. A louvered roof according to any one of claims 2 to 10, characterized in that the weight element is located almost in the center of gravity of the louver viewed in a width direction (37) of the louver or that the weight element is divided into two or more substantially equal parts , each part being at substantially the same distance from the center of gravity of the slat as viewed in a width direction (37) of the slat. A louvre roof according to any one of claims 2 to 11, characterized in that the functional component comprises one or more of: 95 BE2021/5684 a heating element, lighting, such as LED lighting, an audio element, such as a loudspeaker, an imaging element, such as a screen and/or a projector, means of communication, such as Bluetooth or Wi-Fi, a sensor, such as a rain sensor, wind sensor, or a light sensor, a power generating device, such as a solar cell, a ventilation element, such as a fan. A louvered roof according to any one of the preceding claims, characterized in that a difference in deflection between the first and the second louver is at most 10 mm, preferably at most 6 mm, more preferably at most 4 mm and most preferably at most maximum is 2 mm, whereby the deflection is measured in particular almost in the middle of the slat, seen in the longitudinal direction. A louvre roof according to any one of the preceding claims, characterized in that the first louver has a first moment of inertia and that the second louvre has a second moment of inertia, the first moment of inertia being at least 25%, preferably at least 75% and more preferably at least 100%, exceeds the second moment of inertia. 15. A louvered roof for a terrace covering (1), in which the louvered roof is provided with a frame (3, 5) and a set of mutually parallel slats (7) attached to the frame, the slats extending in a longitudinal direction (36) and wherein each slat has a deflection, characterized in that each slat or each slat, except the one with the highest deflection, is provided with an additional load such that the deflection of each slat is substantially equal. A slatted roof according to claim 15, characterized in that 26 BE2021/5684 a difference in deflection between each pair of adjacent slats amounts to a maximum of 10 mm, preferably a maximum of 6 mm, more preferably a maximum of 4 mm and most preferably a maximum of 2 mm, the deflection being measured in particular is seen almost in the center of the slat in the longitudinal direction. A terrace covering (1) comprising a slatted roof according to one of the preceding claims. A set of parts for building a louvered roof according to any one of claims 1 to 14, the kit comprising: the frame (3, 5), the set of louvres (7) and an additional load formed by one or more of a plurality of mutually different functional components and/or a weight element (10). A method for building a louvered roof according to any one of claims 1 to 14, the method comprising: - providing a set according to claim 18; - placing the one or more functional components in the first slat (7”); - placing the weight element (10) in the first slat; and - placing the set of slats in the frame (3, 5).