DE102018106519B4 - Profile element for covering a building shell - Google Patents

Abstract

Profile element (10) for a device for covering a building shell, in particular for a device for influencing the permeability of light and/or heat radiation as well as air and sound, comprising:- a one-piece body section (12) which has a closed hollow cross-section and which is preferably located in the center of the profile element (10); and- at least a first single wall wing (14,16) depending from and integral with the body section (12), and preferably a second single wall wing (16,14) depending from a location on the body section (12). , which is opposite the point from which the first wing (14, 16) protrudes from the fuselage section (12), in particular the wings (14, 16) being mirror-symmetrical to one another; characterized in that the body section (12) has a rhombic hollow cross-section with two profiles (24) in the form of two V-shaped grooves or recesses running along opposite edges of the body section (12) for detachable attachment of the body section (12) to a supporting structure ( 36) or for receiving a fastening element (42) for fastening the fuselage section (12) to a supporting structure (36).

Description

The present invention relates to a profile element according to the preambles of claims 1 and 2 and a shading device for a building shell.

For background information, please refer to the publications in advance EP 0 249 919 A2 , DE 69 34 219 U , DE 10 2006 005 235 A1 , DE 19 30 174 U , U.S.A. 4,327,795 , U.S. 2010/0 043 292 A1 , U.S. 3,219,104 A , EP 1 980 705 A1 , DE 34 03 920 A1 , U.S. 4,901,537A , DE 298 09 100 U1 and DE 10 2007 003 233 A1 referred.

In order to influence the permeability of enveloping constructions, individual plastic profiles in a wide variety of configurations can be used in corresponding devices such as, for example, roller blinds or window shutters. For example, extruded hollow body profiles with several chambers are widespread as components of roller shutter curtains. Slats made of plastic can also be used for external venetian blinds or rotating/sliding shutters.

In such devices, the profiles can be assembled in a single layer and/or with slight overlaps to form flat components for covering building openings or glass facades in order to prevent or at least reduce the passage of solar radiation.

In order to be able to use such devices to sufficiently reflect or absorb direct solar radiation when the sun is low, such as in winter on south-facing facades, so that there is no glare inside the building and, depending on the season, no heating, vertical or horizontal rotatable slats can be used come into action.

Especially with such slat-based devices, however, there is a risk of damage when used outside in strong wind loads, which is why the profiles or slats have to be brought into a safe position, for example by gathering, in which they are protected from wind attack, which, however, has the consequence that the devices can then no longer fulfill their task of sun and glare protection.

Another problem with these devices is that when they are closed, they block both the view and the passage of air, thus contributing unfavorably to the heating of the elements and the interior spaces to be protected. As a result, the amount of daylight necessary to illuminate the rooms can no longer be guaranteed.

In contrast to these solutions, with other devices, rigid and/or movable rods, slats or profile elements can be arranged at a distance from one another and additionally in several levels, so that at certain or different positions of the sun, on the one hand, the passage of direct solar radiation can be completely or partially prevented, if necessary, however, adequate ventilation and rear ventilation as well as transparency are maintained. Such devices are, for example, in DE 10 2007 003 233 A1 described.

With this principle, the direct passage of solar radiation can be completely or partially prevented if necessary, while light from the sky and solar radiation possibly reflected several times in the device can pass through the same. Depending on the nature and material properties of the individual elements in the form of rods, slats or profile elements, for example, that make up the respective device, effective sun protection and the required level of daylight utilization can be guaranteed. Such a multi-layered arrangement with individual elements placed at a distance allows good ventilation through and through the gaps, as a result of which unwanted additional heat radiation into the interior can be reduced.

The invention is therefore based on the object of specifying a profile element for a device that works according to this principle, which, however, can also be used quite generally as a covering element for a building envelope.

This object is achieved with a profile element for a device for covering a building shell with the features of claim 1 or claim 2 or by a shading device for a building shell.

Viewed in cross-section, a self-contained, thin-walled and significant hollow cross-section forms the core of the profile element, as a result of which it reacts technically appropriately to torsional and/or bending stresses. In return, this makes it possible to design the wing or wings, which extend from the fuselage section designed as a hollow cross-section on one or two sides, but lying in almost one plane, relatively thin and, if necessary, even so filigree that they are similar to flexible leaves can move in the wind, whereby a facade formed by means of the profile elements according to the invention receives a very natural character.

The design of the profile element according to the invention with a load-bearing fuselage section on the one hand and the wings extending from it on the other hand means that the requirements placed on the profile element for stability on the one hand and filigreeness on the other hand can be met, in that primarily the fuselage section gives the profile element the necessary rigidity, whereas the wings , which serve to influence the permeability of light and/or heat radiation as well as air and sound, can be made relatively thin, with which the profile element is given the desired lightness.

Due to the fact that the at least one wing can be made very filigree, not only can material and thus corresponding costs be saved; Rather, if the material from which the profile element is made has a certain transparency, solar radiation can pass through the profile element by transmission to a certain extent and thus, for example, reach the interior of a building in a scattered manner. By adapting the material thickness of the wing to the radiation permeability of the material used, the degree of radiation permeability of the wing and of the profile element as a whole can be varied according to the tasks of the device. The material thickness of the wing can change continuously over its length or in visible steps.

Preferred embodiments of the invention will now be discussed below. Further embodiments can result from the dependent claims, the description of the figures and the drawings.

The two wings can protrude from the body section of the profile element at a slightly different angle; according to a preferred embodiment, however, the two wings each protrude from the fuselage section at the same angle, so that the two wings are mirror-symmetrical to one another if they have the same shape.

According to a further embodiment, the two wings can lie in a common plane. In particular, the profile element can be mirror-symmetrical in its entirety with respect to a mirror plane which is oriented perpendicularly to the plane in which the two wings lie. The mirror plane preferably divides the body section into two mutually mirror-symmetrical sections, so that the profile element as a whole is symmetrical to the mirror plane.

According to a further embodiment, the at least two wings of the profile element can taper towards their respective free end, which not only saves material, but also gives the profile element as a whole a light and filigree character. If it is mentioned here that the wings taper towards their respective free end, this does not necessarily mean that the wings have to taper continuously over their entire length. Rather, each wing can have several sections of different thicknesses, so that the respective wing tapers in steps towards its freely projecting end. Likewise, it would be conceivable that the respective wing tapers in the direction of its free end only over a specific area, whereas beyond this tapering area it has areas of constant thickness.

According to a further embodiment, the two wings can be arranged eccentrically on the fuselage section, which can prove to be advantageous, for example, with regard to the attachment of the profile element to a supporting structure.

According to yet another embodiment, at least one of the two wings can have a first section and a second section which extends in the continuation of the first section and is slightly angled with respect to the first section. Due to the different orientation of the two sections of such a wing, light incident on the wing is reflected in different directions, which means that interesting light effects and/or multiple reflections can be achieved, particularly with a multi-layer arrangement of the profile elements according to the invention, by which solar radiation is effectively kept away from the building shell and/or or directed in parts to the ceiling or directly into the depths of the room to be illuminated.

According to yet another embodiment, the profile element can also have a web which protrudes from the fuselage section and lies in a plane which divides the angle between the first and the second wing into two preferably equal partial angles. Such a configuration can prove to be advantageous in particular when the profile element is used in a horizontal orientation and is rotatably attached to a supporting structure. The profile element can be very rigid about an axis oriented perpendicular to the two wings due to its large moment of inertia caused by the first two wings, which makes it possible to bridge relatively large horizontal spans with the profile element if the wings are aligned vertically are; the area moment of inertia of the profile element with respect to the axis in which the two first wings lie, is, on the other hand, relatively small, which can result in the profile element undergoing a not inconsiderable deflection when it is in a position in which the two wings lie in a horizontal plane. In order to counteract such an undesired deflection, the corresponding area moment of inertia can be increased by the web without the fuselage section having to be enlarged or reinforced in its entirety, which would otherwise be at the expense of the lightness of the profile element. The overall impression of the profile element is also only slightly impaired by the web in question, since the profile element can be installed in such a way that the web faces the building envelope and is therefore not visible from the outside, or only slightly so.

As far as the fuselage section is concerned, it can have a round, oval or also a polygonal hollow cross section. Preferably, the body section can have a regularly polygonal hollow cross section, for example a square, rhombic, kite, triangular or trapezoidal cross section. In the case of a polygonal hollow cross section, it is provided that the two wings protrude from opposite corners or edges of the fuselage section, since in this case the fuselage section already has a relatively large area moment of inertia with respect to an axis oriented perpendicular to the two wings, which is advantageous affects the bending stiffness of the profile element.

According to a further embodiment, it can be provided that the fuselage section is mirror-symmetrical with respect to the common plane in which the two wings extend, or with respect to a plane parallel thereto. Since the profile element is preferably attached to a supporting structure via the fuselage section, this enables the profile element to be attached to the supporting structure in two orientations rotated by 180°, as a result of which the profile element can be used very flexibly.

According to a further embodiment, it can be provided that the profile element is produced by means of an extrusion process from a plastic material, for example. The profile element can thus be an extrudate which, if required, can also be fiber-reinforced, for example by adding glass fibers and/or natural fibers. Such a fiber reinforcement can not only improve the strength properties of the profile element; Rather, the light transmission properties of the profile element can also be influenced by the targeted admixture of fibers.

In general, the profile element can be transparent or translucent, i.e. transparent to radiation but not transparent, by selecting appropriate plastics. In this way it can be ensured that even in the closed state of a device realized by means of the profile element according to the invention with sufficient sun protection function, part of the daylight can still get into the interior of a building or, with transparent plastics, a partial view is still given.

In yet another embodiment, the body portion may have a wall thickness that varies around its circumference. For example, the wall thickness may be less near the main axis of inertia of the fuselage section than in areas further away from the main axis of inertia. This allows the area moment of inertia or section modulus of the fuselage section to be increased disproportionately despite the reduced wall thickness near the main axis of inertia, since the distance to the respective main axis of inertia is included in the calculation of the area moment of inertia or section modulus to the third or second power.

According to yet another embodiment, the body section of the profile element can have a profile which is designed for detachably attaching the body section to a supporting structure or for receiving a fastening element for attaching the body section to a supporting structure. For example, in the event that the body section has a polygonal hollow cross-section, a concave or V-shaped channel or groove can be formed in the shortest side(s) of the respective polygon, which is used to accommodate a corresponding fastening element. In general, by profiling the central fuselage section, form-fitting connections to structurally necessary substructures can be created. Fastening with fasteners such as screws, nails or pins is just as possible as fastening with clips.

Although the opacity of the profile element can be influenced by the material from which the profile element is made; In addition, however, the profile element can be provided with a coating that changes the opacity of the profile element or the material from which it is made. In addition, such a coating also improves the weather resistance and/or the reflective properties of the Profilele affect ments without the profile element itself having to be made of a special material.

• 1 bis 22 unterschiedliche Ausführungsformen eines Profilelements im Querschnitt zeigen;
• 23 bis 25 unterschiedliche Arten der Befestigung des erfindungsgemäßen Profilelements an einer Untertragkonstruktion zeigen; und
• 26 bis 30 unterschiedliche Anordnungsmöglichkeiten des erfindungsgemäßen Profilelements an einer Untertragkonstruktion zur Abdeckung einer Gebäudehülle zeigen.

In the following, the invention will now be described purely by way of example with reference to the drawing, in which:

• 1 until 22 show different embodiments of a profile element in cross section;
• 23 until 25 show different ways of fastening the profile element according to the invention to a supporting structure; and
• 26 until 30 show different options for arranging the profile element according to the invention on a substructure for covering a building envelope.

In the following, first with reference to the 1 discussed the basic design of a non-inventive profile element before then with reference to the 2 until 22 different embodiments are explained.

At this point it should be pointed out that the proportions shown in the figures can vary and can be continuously scaled in various absolute sizes.

The 1 shows a first embodiment of a profile element 10 not according to the invention, which has a body section 12 and two single-walled wings 14, 16 which cantilever from the body section 12 freely. The profile element 10 can, for example, be an extrudate made of a plastic material, so that not only are the wings 14 , 16 formed in one piece with the body section 12 , but the body section 12 itself also represents a one-piece section of the profile element 10 .

The body section 12 is a self-contained, thin-walled hollow cross-section which, viewed in cross-section in the embodiment shown here, forms a circular ring. The wings 14, 16 protrude from opposite sides of the fuselage section 12 and extend in a common plane which is oriented parallel to the Y-axis or normal to the X-axis of the coordinate system shown schematically here. The wings 14, 16 taper continuously, starting from the point at which they merge into the body section 12, up to their free end 18, whereby the wings 14, 16 can be made very filigree, which the profile element 10 in its entirety gives a certain lightness.

At the in the 1 In the illustrated embodiment, the profile element 10 is thus doubly mirror-symmetrical, on the one hand to the plane that is spanned by the two wings 14, 16, and on the other hand to a plane that is perpendicular to the plane of the wings 14, 16 and that divides the fuselage section 12 into two equal divided into halves.

As previously mentioned, the profile element 10 can be an extrudate made of a plastic material; alternatively, however, the profile element 10 can also be made of metal and in particular aluminum or of glass and acrylic glass. Depending on the type of production, the profile element 10 can be available by the metre, in order to be able to cut sections of the desired length as required. Depending on the application, the cross-sectional dimensions of the profile element 10 can vary, but the usual dimensions of the profile element in the direction of the Y-axis can be of the order of about 2 to 30 cm.

That in the 2 shown non-inventive profile element 10 differs from that in FIG 1 illustrated only in that here the wing 14 is shorter than the wing 16, as may be desirable to accommodate special structural requirements. If required, however, the wing 14 can also be omitted entirely, so that there is a single-wing profile element. The profile element 10 can either already be produced with two wings 14, 16 of different lengths. Alternatively, it is also possible in the profile element 10 of 1 to shorten the wing 14, for example, using a circular saw to the profile element 10 of 2 to obtain, or to remove the wing 14 completely. Such a subsequent reduction in the length of at least one wing 14, 16 is easily possible if the profile element 10 is made of a plastic material.

The non-inventive profile element 10 of 3 differs from that in the 1 shown in that both wings 14, 16 have been shortened here.

The non-inventive profile elements 10 according to 4 and 5 differ from that in the 1 shown in that here the body section 12 each has an oval cross-section.

That in the 6 shown non-inventive profile element 10 differs however, from the one in the 1 illustrated in that the fuselage section 12 has a square cross-section, the wings 14 , 16 starting from opposite corners or edges of the fuselage section 12 .

That in the 7 shown non-inventive profile element differs from that in the 6 illustrated by the fact that the wall thickness of the fuselage section 12 continuously decreases in the direction of the corners or edges from which the wings 14, 16 protrude, which can be desirable, for example, in favor of saving material. However, the saving in material is not at the expense of the rigidity of the profile element 10, or only to a small extent, since the section modulus W _y with respect to the Y-axis is decisively determined by those cross-sectional sections that are further away from the plane of the wing. Although taper in the profile element 10 of 7 the wings 14, 16 towards their free end 18; In addition, however, the two wings 14, 16 have a change in thickness 20 on one side, as a result of which additional material can be saved. If required, each wing 14, 16 can have several such jumps in thickness, with such jumps in thickness 20 basically also being able to be formed on both sides of the respective wing 14, 16. In the embodiment shown here, however, the two wings 14, 16 each form a flat surface 21 on the side opposite the jump in thickness 20, which lies in a common plane, so that the two wings 14, 16 can rest flat against a supporting structure, for example.

The non-inventive profile element 10 according to 8th differs from that of 7 in that a web 22 is provided here, which protrudes from the body section 12 and is formed in one piece with it. The web 22 is significantly shorter than the other two wings 14, 16, but this is sufficient to increase the section modulus W _y such that the profile element 10 relative to the orientation according to 8th can be rotated 90° without sagging due to its own weight and/or snow load.

The in the 9 , 10 and 11 profile elements 10 shown not according to the invention differ from that in FIG 6 shown essentially in that here the fuselage section 12 has no square but a rhombic cross-section, with the profile of the 11 in addition, the wings 14, 16 are shortened.

At the in the 12 The profile element 10 according to the invention shown in the illustration has the body section 12 likewise an essentially diamond-shaped cross section, but here the diamond dimension in the direction of the Y-axis is smaller than in the direction of the X-axis. Furthermore, the body section 12 has two profiles 24 in the form of two V-shaped grooves or recesses, which are formed along the two free corners or edges of the body section 12 . The possible purpose of such profiles 24 will be discussed in more detail below.

The in the 13 and 14 illustrated profile elements 10 according to the invention differ from that in FIG 12 shown essentially in that the wings 14,16 are shortened to a certain extent. The profile element 10 of 14 is doing from the in the 12 shown that the wings 14, 16 were shortened along the jump in thickness 20, for example by means of a hand-held circular saw, so that the jump in thickness 20 not only serves to save material, but at the same time represents a kind of shortening aid.

In the non-inventive profile element 10 according to 15 the fuselage section 12 has a hexagonal hollow cross-section that is symmetrical both with respect to the Y-axis and with respect to the X-axis, the opposite corners or edges from which the two wings 14, 16 emanate, inside the fuselage section 12 additionally being provided with a Partition 26 are connected to each other for the purpose of additional reinforcement of the profile element 10.

The profile elements 10 according to the invention 16 and 17 in turn represent a further development of the profile element 15 with a double-symmetrical hexagonal polygonal fuselage section 12, in which case profiles 24 with a V-shaped ( 16 ) or concave cross-section ( 17 ) are provided, the purpose of which will be discussed in more detail below.

The 18 shows a profile element 10 not according to the invention with a cross section reminiscent of a bridge cross section. In this embodiment, the body section 12 has a substantially rectangular cross-section, with the wings 14, 16 extending in the extension of the longer side of the rectangular cross-section of the body section 12 and tapering continuously towards their free end 18.

In contrast to the profile element 10 of 18 is in the non-inventive 19 shown, the fuselage section 12 by a trapezium symmetrical with respect to the X-axis formed, with another difference being that here the wings 14, 16 have a constant thickness over their entire length.

The profile element 10 according to the invention 20 represents an evolution of the profile of 19 is, wherein the wings 14, 16 in the direction of their respective free end 18 taper continuously. Strictly speaking, the fuselage section 12 does not have a trapezoidal cross section, since the side surface of the fuselage section 12 between the two wings 14, 16 is formed by two surface sections 28, 30, which together form an obtuse angle of the order of about 160° include, whereby a V-shaped recess is formed. In contrast, the shorter side of the body section 12 similar to that in FIG 17 a profile 24 in the form of a concave recess, the purpose of which will be discussed in more detail below.

The 21 shows a profile element 10 according to the invention, in which the body section 12 essentially has a kite-shaped cross-section which, like the entire profile element, is mirror-symmetrical with respect to the X-axis. Here, too, the fuselage section 12 has a profile 24 with a V-shaped cross section along the corners or edges that lie opposite one another in the direction of the X-axis. The wings 14, 16, on the other hand, protrude from the two corners or edges that are opposite one another in the direction of the Y axis, with each of the two wings 14, 16 having a first section 32 and a second section 34, which is located in of the continuation of the first portion 32 and is angled relative thereto at an acute angle of the order of about 5 to 15°. Light incident on the two wings 14, 16 is reflected differently at the two wing sections 32, 34, as may be desirable to achieve special lighting effects.

Even with the non-inventive profile element 10 of 22 the fuselage section 12 essentially has a kite-shaped cross-section, although here it is different from the embodiment according to FIG 21 the wall thickness of the body section 12 does not vary over the circumference of the body section 12, but is constant or of the same size everywhere. Here, too, the wings 14, 16 taper continuously in the direction of their respective free end 18, although here they are different from the embodiment of FIG 21 are not angled in on themselves.

For the sake of completeness, it should be noted here that the 1 until 22 merely represent a variety of exemplary profile elements according to the present invention. However, the invention is not limited to these exemplary profile elements; rather, for example, any body sections according to the 1 until 22 and individual features thereof with any wing configurations according to 1 until 22 and combined with individual features thereof.

Referring to the 23 until 25 are now different mounting options as an example using the in the 17 profile element 10 shown on a substructure 36 is explained.

The supporting structure 36 can be, for example, a transverse or longitudinal beam which has an essentially V-shaped recess 83 for partially accommodating the trunk section 12 of the profile element 10 . A type of mushroom head pin 40 is provided at the bottom of this recess 38, which fits together in a form-fitting manner with a corresponding profile 24, which is formed along the shortest side of the fuselage section 12, so that in this way the profile element 10 is secured to the substructure 36 by means of a type of tilting attachment can.

In the illustration below 23 For example, the profile element 10 is fastened in the V-shaped recess 38 of the supporting structure 36 by screwing a fastening element 42 such as a screw through the body section 12 into the supporting structure 36 .

According to the illustration above 24 profile element 10 is also secured to the supporting structure 36 by means of a fastening element 42, but here the fuselage section 12 rests with one of its long side surfaces over the entire surface on the supporting structure 36 and the fastening element 42 extends both through this and the diametrically opposite side surface of the fuselage section 12 extends.

According to the illustration below 24 half of the fuselage section 12 is again received in a V-shaped recess 38 in the supporting structure 36, the two wings 14, 16 with their side surfaces 21, which do not have any jumps in thickness and lie in a single plane, lying in full contact with the supporting structure 36, here the fastening is effected by means of two screws screwed through the wings 14,16 into the supporting structure 36.

According to 25 can the profile element 10 of 17 on a substructure 26 such as a support 46 by means of two pins 44 are secured, which are welded to the support 46 and project perpendicularly therefrom to extend into the two profiles 24 of the body section 22 inside.

The 26 until 30 ultimately show different possible arrangements of the profile element according to the invention, through which different effects can be achieved, which, however, will not be discussed in detail here. However, as can be seen from these representations, the profile elements in the sense of lamellae in vertical and horizontal arrangements (relative to the axis in the extrusion direction or longitudinal direction) can be added or combined to form surface elements. The profile elements can also be arranged in an overlapping manner or at specific distances in one or more levels. Furthermore, the profile elements can be used in rigid or movable (rotatable and/or displaceable) arrangements in devices of all kinds. In such arrangements, the profile elements viewed in cross section can also be arranged on facades in such a way that the wings of the profile elements are aligned vertically, as a result of which the profile elements are stressed by their own weight or snow load in their strong axis. The drainage of rainwater is also very well guaranteed and dirt and dust from the ambient air can only accumulate with difficulty.

The profile elements can thus be combined with one another in the sense of a modular system in different sizes, materials, degrees of light transmission in different rigid or movable arrangements. When added to surface components, they can be used, for example, in sliding elements and/or folding elements and/or rotating panels and/or folding elements.

Various computationally modeled arrangements and metrological investigations of built prototypes under real outdoor conditions have shown that an above-average overall performance in sun protection in connection with sufficient daylight transmission and air exchange can be achieved using the profile element according to the invention in corresponding surface arrangements in one or more levels. This above-average performance feature helps to reduce heating and cooling energy requirements in residential and administrative buildings.

Reference List

10

profile element

12

fuselage section

14

first wing

16

second wing

18

free end

20

jump in thickness

21

flat surface

22

web

24

profiling

26

partition

28

area section

30

area section

32

wing section

34

wing section

36

substructure

38

recess

40

mushroom head cone

42

fastener

44

cones

46

support

Claims (14)

Profile element (10) for a device for covering a building envelope, in particular for a device for influencing the permeability of light and/or heat radiation as well as air and sound, comprising: - a one-piece body section (12) which has a closed hollow cross section and which is preferably located in the center of the profile element (10); and - at least a first single-walled wing (14, 16) depending from and integral with the body section (12), and preferably a second single-walled wing (16, 14) depending from a location on the body section (12). , which is opposite the point from which the first wing (14, 16) protrudes from the fuselage section (12), in particular the wings (14, 16) being mirror-symmetrical to one another; characterized in that the body section (12) has a rhombic hollow cross-section with two profiles (24) in the form of two V-shaped grooves or recesses running along opposite edges of the body section (12) for detachable attachment of the body section (12) to a supporting structure ( 36) or for receiving a fastening element (42) for fastening the fuselage section (12) to a supporting structure (36). Profile element (10) for a device for covering a building shell, in particular for a device for influencing the permeability bility for light and / or heat radiation as well as air and sound, comprising: - a one-piece body section (12), which has a closed hollow cross-section and which is preferably located in the center of the profile element (10); and - at least a first single-walled wing (14, 16) depending from and integral with the body section (12), and preferably a second single-walled wing (16, 14) depending from a location on the body section (12). , which is opposite the point from which the first wing (14, 16) protrudes from the fuselage section (12), in particular the wings (14, 16) being mirror-symmetrical to one another; characterized in that the body section (12) has a polygonal hollow cross-section with a profile (24) in the form of a V-shaped groove or recess running along an edge of the body section (12) for detachable attachment of the body section (12) to a supporting structure ( 36) or for receiving a fastening element (42) for fastening the fuselage section (12) to a supporting structure (36). profile element claim 1 , characterized in that the profile element comprises two wings (14, 16) which lie in a common plane, with the profile element (10) in particular being mirror-symmetrical with respect to a mirror plane oriented perpendicularly to the common plane, which preferably includes the fuselage section (12) in divided into two mutually mirror-symmetrical sections. Profile element according to at least one of the preceding claims, characterized in that the profile element comprises two wings (14, 16) which taper towards their respective free end (18), preferably continuously and/or stepwise. Profile element according to at least one of the preceding claims, characterized in that the profile element comprises two wings (14, 16) which are arranged eccentrically on the body section (12). Profile element according to at least one of the preceding claims, characterized in that at least one of the wings (14, 16) has a first section (32) and at least one second section (34) which extends in the continuation of the first section (32) and is angled relative to the first section (32). Profile element according to at least one of the preceding claims, characterized in that the body section (12) has a regularly polygonal hollow cross section. profile element claim 2 , characterized in that the profile element comprises two wings (14, 16) projecting from opposite corners of the body section (12). Profile element according to at least one of claims 2 until 8th , characterized in that the fuselage section (12) is mirror-symmetrical with respect to the common plane in which the wing or wings (14, 16) lie, or with respect to a plane parallel thereto. Profile element according to at least one of the preceding claims, characterized in that the body section (12) has a wall thickness which changes over its circumference. Profile element according to at least one of the preceding claims, characterized in that the profile element (10) is an extrudate which is preferably manufactured from a plastic material and/or is fibre-reinforced. Profile element according to at least one of the preceding claims, characterized in that the profile element (10) is not or to different degrees radiation-transmissive and in particular transparent or translucent. Profile element according to at least one of the preceding claims, characterized in that the profile element (10) has a coating which changes the weather resistance, the reflection properties and/or the opacity of the profile element (10). Shading device for a building shell with a plurality of profile elements (10) according to at least one of the preceding claims, in which the individual profile elements (10) are arranged rigidly or movably in one or more planes.

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