BE1025855B1 - ACOUSTIC LIGHTING ELEMENT - Google Patents

Abstract

The present invention relates to an acoustic lighting element for incident sound attenuation, comprising one or more holders for luminous elements, and a shielding structure, wherein the shielding structure has at least a space angle of π, preferably at least 1.5 π, steradials around the one or covering a plurality of holders, the shielding structure comprising an outer layer which is substantially not directed towards the one or more holders, said outer layer providing an equivalent sound-absorbing surface area in m² of at least 0.2 for incident sound with a frequency above approximately 500 Hz, and a provides equivalent sound-absorbing surface in m² with at least 0.3, preferably at least 0.4, for incident sound with a frequency above about 1000 Hz, and preferably provides an equivalent sound-absorbing surface in m² with at least 0.35, preferably 0.5, for incident sound with a frequency t approximately 2000 Hz and 5000 Hz.

Description

ACOUSTIC LIGHTING ELEMENT

TECHNICAL DOMAIN

The invention is situated in the field of lighting elements for private and / or commercial spaces, with sound-damping functionality due to the specific construction, but furthermore also through additional characteristics such as material, internal and / or external structural characteristics and other elements.

The invention relates specifically to a lighting element, and for this purpose thus comprises a so-called fixture (or several) and one or more holders suitable for receiving light-emitting elements, for example lamps (whether or not including in the invention). The lighting element is here provided with an additional functionality, namely the damping of incident sound, and thus extremely suitable for solving problems of acoustic problems in private, public or business spaces (offices, living room, living spaces, desks, etc.). ).

The applicant noticed that in many office and living spaces, acoustics is a major problem, sometimes due to the space itself, but often also due to a poor combination of layout of the space, the shape of the space and the elements therein. This creates an unbalanced level of sounds of different pitches. For example, some spaces will tend to amplify high tones and thus cause an unpleasant work or living situation. Because in many cases it is difficult to adjust the structural factors that influence or determine the acoustic behavior of the room (for example, classification may be necessary, the shape of the room cannot simply be changed without major work), focus on the elements in the room, such as luminaires and other components of lighting systems.

For example, in certain situations it may be necessary to suppress ambient noise, but "speech" to a lesser extent. For that reason, it is possible, for example, to suppress sounds with a frequency of 100 Hz-400 Hz (or other frequency ranges) to a lesser extent. In other circumstances, such as concert halls, other areas of the sound spectrum can be suppressed to a greater or lesser extent.

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To offer a solution in all situations, the applicant therefore focused on the lighting elements in the room, in order to give these a sound-damping functionality in order to (partly) solve the problem.

BACKGROUND ART

In general, a number of lighting elements have already been released in the past to address some aspects of the problem. However, in most cases these are generic solutions that can only solve one aspect of the problem, and even in these cases the currently known solutions are insufficient to adequately solve this aspect.

The lighting elements then opted for simple solutions such as additional constructions with mousse, foam or other soft materials that could possibly absorb sound. However, these additional constructions take up a lot of space in the first place, which is not always possible or desirable, and in the second place are often also a striking aesthetic element, which is not often appreciated, since lighting should actually not be distracted. It must also be said that the efficiency of the structures was strongly correlated with their size, so limited structures had little to no effect, tests showed.

The present invention aims at least to find a solution for some of the above problems or disadvantages. The object of the invention is to provide a method which overcomes these disadvantages.

SUMMARY OF THE INVENTION

In a first aspect, the invention relates to an acoustic lighting element for attenuation of incident sound, comprising one or more holders for luminous elements, and a shielding structure, wherein the shielding structure has at least a space angle of π, preferably at least 1.5 π, steradials around the one or covering a plurality of containers, said shielding structure comprising an outer layer substantially not directed towards the one or more containers, said outer layer comprising a textile layer, and wherein said outer layer provides an equivalent sound-absorbing surface area in m ² of at least 0.2 for incident sound with a frequency above approximately 500 Hz, and an equivalent sound-absorbing surface in m2 provides at least 0.3, preferably at least 0.4, for incident sound with a frequency above approximately 1000 Hz, and at

BE2017 / 6011 preferably provides an equivalent sound-absorbing surface in m ² of at least 0.35, preferably 0.5, for incident sound with a frequency between approximately 2000 Hzen 5000 Hz.

In a second aspect, the invention relates to a use of an acoustic lighting element according to one of the embodiments of the invention, for the acoustic damping of incident sound.

DESCRIPTION OF THE FIGURES

Figure 1 shows a possible embodiment of a lighting element according to the invention.

Figure 2 shows an alternative possible embodiment of a lighting element according to the invention.

3A-C shows an alternative possible embodiment of a lighting element according to the invention.

Figure 4 shows an alternative possible embodiment of a lighting element according to the invention.

Figure 5 shows an alternative possible embodiment of a lighting element according to the invention.

6A-B shows an alternative possible embodiment of a lighting element according to the invention.

DETAILED DESCRIPTION

Unless defined otherwise, all terms used in the description of the invention, including technical and scientific terms, have the meaning as generally understood by those skilled in the art of the invention. For a better assessment of the description of the invention, the following terms are explicitly explained.

BE2017 / 6011 "One", "de" and "it" in this document refer to both the singular and the plural unless the context clearly presupposes otherwise. For example, "a segment" means one or more than one segment.

When "about" or "round" is used in this document for a measurable quantity, a parameter, a duration or moment, and the like, variations are meant of +/- 20% or less, preferably +/- 10% or less, more preferably +/- 5% or less, even more preferably +/- 1% or less, and even more preferably +/- 0.1% or less than and of the quoted value, insofar as such variations apply are in the described invention. However, this should be understood to mean that the value of the quantity in which the term "about" or "round" is used is itself specifically disclosed.

The terms "include", "comprising", "consist of", "consisting of", "provided with", "contain", "containing", "withhold", "withhold" are "synonymous" and are inclusive or open terms that presence of what follows, and which do not exclude or prevent the presence of other components, features, elements, members, steps, known from or described in the prior art.

The term "SAA" or "sound absorption average" refers to an average sound absorption value of an object, and is suggested by taking the mathematical average of 12 sound absorption coefficients in a diffuse field, which are 1/3 of a mutual octave, over a frequency range of 200 to 2500 Hz.

The term "NRC" or "noise reduction coefficient" is a scalar representation of the amount of sound energy that is absorbed by a certain area. Here a value of 0 represents perfect reflection, and a value of 1 complete absorption.

The term equivalent sound-absorbing area per m ² indicates a 'virtual area' of an object if this would consist solely of perfectly absorbent surfaces.

The expression substantially not directed toward the one or more holders refers to surfaces or sides of a surface that cannot be incident on direct light from a light source in the holders.

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Terms such as "above", "below" and the like should be understood as being applicable to the lighting element in the operative condition, i.e. for example hanging on a ceiling or wall, or standing on the ground.

The citation of numerical intervals by the end points includes all integers, fractions and / or real numbers between the end points, including these end points.

In a first aspect, the invention relates to an acoustic lighting element for attenuation of incident sound, comprising one or more holders for luminous elements, and a shielding structure, wherein the shielding structure has at least a space angle of π, preferably at least 1.5 π, steradials around the one or covering a plurality of containers, said shielding structure comprising an outer layer substantially not directed towards the one or more containers, said outer layer comprising a textile layer, and wherein said outer layer provides an equivalent sound-absorbing surface area in m ² of at least 0.2 for incident sound with a frequency above approximately 500 Hz, and an equivalent sound-absorbing surface in m2 with at least 0.3, preferably at least 0.4, for incident sound with a frequency above approximately 1000 Hz, and preferably an equivalent sound-absorbing surface in m2 with at least 0.35 , e.g. preferably 0.5, for incident sound with a frequency between approximately 2000 Hz and 5000 Hz. Preferably, the shielding structure is positioned at an average distance of at least 10 cm from the nearest container, and more preferably further, for example at least 15 cm, 20 cm or more. More preferably, this average distance to the nearest container is at most 75 cm (more preferably at most 60 cm, or even 50 cm, 40 cm) to keep the lighting elements compact.

In certain preferred embodiments, a larger space angle is covered around the holders, for example 2π, or even 2.5π or 3π.

The applicant aims to achieve two objectives with the invention. On the one hand, the goal is to create pleasant lighting in a room, so that the light rays are very consciously focused on an area to be illuminated, without providing a (quasi) omni-directional light source. This is achieved, among other things, by having the shielding structure shield a certain angle of space around the holders. In this way, unwanted light (e.g. towards a ceiling) can be avoided, and reflected towards the area to be illuminated, by optionally adding reflective material on the inside of the shielding structure. As also indicated in a large part of the embodiments, the shielded space angle is significant

BE2017 / 6011 higher than 1π, to easily 2π or more, even above 3π. This effect ensures that the shielding structure forms a fairly large surface area, certainly if this is further elaborated upon by implementing a minimum average distance from the shielding structure to the holders (and therefore also to the light-emitting elements themselves). A large surface area of the shielding structure (on the side that is not substantially directed towards the holders), can be used for acoustic measures to damp incident sound. To this end, the applicant uses a specific choice of materials (including a textile layer) to provide the shielding structure with a damping functionality. On the basis of the orientation of these sides of the screening structure not directed towards the holders, it can thus be guaranteed that the screening structure according to the invention can exert a sufficiently large influence on incident sound. It should also be noted, however, that the positioning of the shielding structure in the room is very important (if it is mainly directed towards the ceiling, this will have a more limited influence on acoustic damping than if it is directed towards the floor), which was also included in the designs.

Based on these measures by the applicant, a minimum equivalent sound-absorbing area in m ² of 0.2 was achieved for the shielding structures for frequencies above approximately 500 Hz, and even a value of at least 0.3, preferably at least 0.4, for frequencies above 1000 Hz. Preferably the value is even at least 0.35 and more preferably 0.5, for sounds with a frequency between approximately 2000 Hzen 5000 Hz. It should be noted here that in human speech the spectrum is typically situated between 500 and 2000 Hz. The applicant therefore specifically focused on this sub-spectrum in the development of the shielding structure, in order to optimally damp these tones.

Since it is difficult in practice to make the surfaces of the shielding structure effectively (approximate) perfectly absorbent (for sound), a balance must therefore be found to create sufficient surface area on the one hand to play a significant role for the acoustic values of the chamber, and on the other hand in the choice of material to make the absorption effectiveness of the surfaces sufficiently high. In this way a sufficiently large effective area is generated.

In a preferred embodiment, the outer layer, which is substantially not directed towards the one or more holders, is made up of at least two layers with a fiber structure.

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The layers with fiber structure are extremely suitable for the two purposes of the applicant for the invention. On the one hand, a suitable outer layer (of the shielding structure, which must be visually attractive) for the lighting elements, to give them a "warm" appearance, as well as to provide a certain softness and user comfort that is desired in the room. In this way there is more and more a tendency to create a warmer atmosphere in offices and in private spaces, in contrast to the sterile currents that prevailed in the past. It is also often opted for a retro look with a tactile effect due to the choice of materials. The applicant makes inventive use of this by also using this choice to achieve the second goal, a sound-damping effect. The multiple layers of materials (different or the same materials) with a fiber structure, such as textiles, ensure that a large part of the incident sound waves are absorbed instead of reflected (due to the flexibility of the fibers), and the energy is then simply dispersed through the layers. By providing several layers, on the one hand the frequency range in which the relaxation element can damp is expanded, but the efficiency of damping (or the degree of absorption) is also increased.

In a preferred embodiment, the outer layer, which is substantially not directed to the one or more holders, comprises felt.

In a preferred embodiment, the outer layer, which is substantially not directed to the one or more containers, has a noise reduction coefficient (NRC) of at least 0.5, preferably at least 0.7.

In a preferred embodiment, said outer layer has an average sound absorption (SAA) of 0.7, preferably at least 0.75, wherein the SAA is a mathematical average of 12 mutually 1/3 of an octave spread sound absorption coefficients in a diffuse field for a frequency range of 200 up to 2500 Hz.

Both the aforementioned parameters, NRC and SAA, are extremely suitable for displaying the acoustic effects of an object, since they focus on the behavior at everyday frequencies (around speech and the like), and as such are particularly relevant to the performance of an object. can be predicted on an acoustic level. The applicant intends to guarantee a lower limit for these acoustic values of the shielding structures, namely 0.5 for NRC or 0.7 for SAA, in order to optimally damp these everyday noises in the frequency range referred to for SAA, and thus the most problematic disturbing noises ( problematic

BE2017 / 6011 (omnipresence in office and private spaces). These minimum values have been specifically chosen to be achievable on the one hand without having a too drastic influence on the device in a room, and thus to be easy to place, and on the other hand high enough to have a noticeable influence on the sound comfort for a person in the room. space. To this end, the applicant noted that the chosen minimum values in almost every configuration of a room have a quantifiable effect, both objectively (measurements) and subjectively (experience of a person in the room). As such, this strongly indicates that the chosen minimum values have an inventive aspect.

In a preferred embodiment, the outer layer comprises polyethylene terephthalate (PETP). One of the advantages of using PETP is its good workability and application-friendliness, in terms of touch and appearance, as well as its relatively low weight. Because it can be easily extracted (recycling PET bottles, for example), it is also a particularly good economic choice. The outer layer preferably comprises a layer of PET felt.

In a preferred embodiment, the outer layer comprises fire-retardant fibers. Given the proximity of luminous elements that typically generate heat, this is particularly useful. Moreover, the luminous elements are often not extinguished when no people are present in the room, which can quickly lead to dangerous situations in terms of fire safety. Finally, it should be noted that in today's offices and private living spaces, there are a multitude of electrical appliances that are often not switched off at weekends, at night or in the event of absence. Statistics indicate that such systems present a particularly high fire hazard, greatly improving the use of fire-retardant fibers in order to allow emergency services more time to intervene. Because these fibers can easily be incorporated into the fiber structure of the materials that are used, this can even be used extra advantageously. Alternatively (or additionally), a separate layer of fire-retardant fibers can be used.

In a preferred embodiment, the outer layer comprises polyester fibers, the polyester fibers comprising copolymers composed of a main monomer and a phosphorus-organic comonomer. The presence of the phosphorus-organic comonomer in the fibers themselves ensures an excellent fire-retardant effect. Prior art solutions to achieve a fire-retardant effect always fall back on providing a fire-retardant coating around the fibers, which can wear off quickly

BE2017 / 6011 or washed off, causing the fire-retardant properties to be lost. Because the comonomer is part of the fibers themselves, the property is inherent in the fiber, and can only be lost when the fibers are lost, and the product can in fact no longer be used, unlike the coating that is lost much faster can go.

In a preferred embodiment, the screening structure is provided below the outer layer with a foam layer with a maximum specific weight of approximately 50 kg / m ³ and preferably with a minimum specific weight of approximately 15 kg / m 3, more preferably with a maximum specific weight of approximately 25 kg / m3 and a minimum specific weight of approximately 40 kg / m3.

The applicant noted that the foam further contributed to the sound-damping nature of the invention due to the cell structure with "gas bubbles." The gas bubbles and elasticity of the foam can optimally absorb incident vibrations (noise) and subsequently absorb them, whereby only a fraction is reflected back. By keeping the specific weight in an appropriate range, it is ensured on the one hand that the lighting element is too heavy, and therefore causes practical problems (for example suspension), but on the other hand that it is of sufficient quality (resistance to movement, pressure, forces) to last long to come along. The foam layer preferably further has a specific weight of at least 20 kg / m3 and at most 45 kg / m3. Even more preferably, the specific weight is at least 25 kg / m3 or even 30 kg / m3, and at most 40 kg / m3. Most preferably, the specific gravity is comprised between 34 kg / m3 and 37 kg / m3.

In a preferred embodiment, the outer layer, which is substantially not directed towards the one or more holders, is made up of at least two layers with a fiber structure, wherein the fiber structure of at least two of the two layers is oriented differently relative to each other.

In a preferred embodiment, the shielding structure comprises a, preferably elliptical, paraboloidal roof, wherein the one or more containers are positioned completely within the paraboloidal roof, and preferably the paraboloidal roof on the outside of the paraboloidal roof merges into a substantially flat spur on the convex side of the roof, which spur extends from the convex side of the roof in the direction of the axis of symmetry of the roof, and wherein the flat spur lies in a plane of symmetry of the roof.

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In an alternative embodiment, the shielding structure comprises at least two concentric rollers of different diameter, an inner roll and an outer roll, optionally wherein the rollers are provided with an open pattern, and wherein a first part of the one or more holders is positioned within the outer roll, a second part of the one or more holders is positioned within the outer and the inner roll, and a third part of the one or more holders is positioned within the inner roll.

In an alternative embodiment, the shielding structure is essentially plate-shaped, wherein the one or more light emitting elements are positioned on a first side of the shield-shaped shielding structure, and wherein the acoustic lighting element on the first side of the shielding structure comprises a frame adapted to to be attached to a wall.

In an alternative embodiment, the shielding structure has a disc-shaped structure with a central recess on a first side which is closed on the opposite side of the disc-shaped structure, the one or more holders being positioned in the central recess.

In an alternative embodiment, the shielding structure has a truncated onion shape, wherein the onion shape is provided with a roll-shaped spur on the top and bottom of the onion shape, and wherein the onion shape comprises a plurality of narrow, strip-shaped openings extending from the top to the bottom of the onion shape.

In an alternative embodiment, the shielding structure has a truncated cone shape, which is open at the top and bottom, and wherein the containers are in the shielding structure, preferably with the truncated cone shape oblique.

The foregoing embodiments are further discussed under the Examples, and are shown in a possible embodiment in the Figures.

In a preferred embodiment, the one or more holders are positioned to hold light-emitting elements, the light-emitting elements being completely within the shielding structure.

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As indicated earlier, it is desirable to keep the lighting as natural as possible, and to avoid overexposure. For that reason it is chosen to keep the light-emitting elements completely within the shielding structure (at least understood as within the convex spatial structure defined by the shielding structure).

In a second aspect the invention relates to the use of the acoustic lighting element as described in this document for the acoustic damping of incident sound.

EXAMPLES

The invention will now be further elucidated with reference to the following example, without however being limited thereto.

EXAMPLE 1

Example 1, represented in Figure 1, represents a so-called bell-shaped roof. This includes an (elliptical) paraboloidal roof that is continued upwards (on the convex side) by a flat spur. The shielding structure comprises two or more suspension elements (for example cables) for easy attachment to a support, and preferably a separate cable for supplying current and control signals to the light-emitting elements.

EXAMPLE 2

This example relates to an alternative lighting element, as shown in Figure 2, in which two concentric rollers (with the same axis) of different diameter, the holder being positioned to hold the light-emitting elements along the axis of the rollers. The smallest roll is partially comprised within the largest role, and partially protrudes downwards. Optionally, the largest roll may partially protrude relative to the smallest roll upwards. The shielding structure and holders are held together by a frame (metal or plastic). Furthermore, the lighting element is provided with at least three cables for its suspension and a separate cable for the power supply (and control signals).

EXAMPLE 3

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Example 3 relates to an alternative embodiment of a lighting element according to the invention, as illustrated in Figures 3A-3C. The holders are in this case part of a rectangular frame that can be hung on a wall or ceiling. The shielding structure is also rectangular (and typically with constant thickness, or a varying thickness that runs along the one axis, depending on the design). The shielding structure is dimensioned to completely cover the frame on one side, thus creating only side-radiating light. It is particularly clear here that such a structure is exceptionally efficient in absorption, since almost the entire surface of the screening structure is directed to what is usually the center of a room, and can thus process a lot of incident sound.

EXAMPLE 4

Another embodiment is shown in Figure 4, wherein the light emitting element is embedded in the disc-shaped shield structure. Again, the formal choice ensures that the shielding structure offers a large absorption area when placed. The radius of the disc can be adjusted for the specific situation (living room, office, concert hall, etc.), but typically varies between 30 cm to 2 m. Most versions will be in between, for example with a radius of 60 cm, 50 cm 40 cm, the central lighting element also being circular, with a radius comprised between 10 cm and 40 cm, for example 15 cm, 22.5 cm, 30 cm, or other. The disc has a thickness between 2 cm and 20 cm, but is preferably of limited thickness, for example 5 cm, 6 cm, 7 cm. Furthermore, the lighting element comprises one or more cables for suspension, and a separate cable for power supply (and transmission of control signals).

EXAMPLE 5

Figure 5 shows an alternative embodiment, in which the light-emitting elements (and the holders) are positioned within an onion-shaped shielding structure, with the top and bottom open, the side walls being provided with strip-shaped openings to allow for the lateral appearance of light.

EXAMPLE 6

Figure 6A-B shows another embodiment, wherein the shielding structure is a truncated cone shell. Hereby the intersection surfaces of the truncated

BE2017 / 6011 mantle may or may not be parallel. In Figure 6A, for example, parallel cutting surfaces are involved, and the cone shell is a so-called "straight" cone shell, with the lower cutting surface perpendicular to the axis of the cone. Note that in a slightly different embodiment, the upper cutting surface may be non-parallel to the lower cutting surface. Figure 6B shows a shielding structure that is a truncated cone shell with two non-parallel cutting surfaces, the lower cutting surface not being perpendicular to the axis of the cone. In Figure 6B, the truncated cone shell is thus a so-called "slanted" cone shell. Note that the upper cutting surface can in principle be parallel to the lower cutting surface in a different embodiment. The lighting elements can be adapted as a standing lamp or as a suspended structure.

Claims (18)

CONCLUSIONS Acoustic lighting element for incident sound attenuation, comprising one or more holders for luminous elements, and a shielding structure, the shielding structure covering at least a specific room angle of π, preferably at least 1.5 π, steradials around the one or more holders, wherein the determined space angle is less than 4 π star radials, characterized in that the shielding structure comprises an outer layer which is substantially not directed towards the one or more holders, said outer layer comprising a textile layer, and wherein said outer layer has an equivalent sound-absorbing surface in m ² provides at least 0.2 for incident sound with a frequency above about 500 Hz, and an equivalent sound-absorbing surface in m2 provides at least 0.3, preferably at least 0.4, for incident sound with a frequency above about 1000 Hz, and preferably a equivalent sound-absorbing surface plain in m2 provides at least 0.35, preferably 0.5, for incident sound with a frequency between approximately 2000 Hz and 5000 Hz. Acoustic lighting element according to claim 1, characterized in that the outer layer, which is substantially not directed to the one or more holders, is made up of at least two layers with a fiber structure. Acoustic lighting element according to claim 1 or 2, characterized in that the outer layer, which is substantially not directed towards the one or more holders, comprises felt. Acoustic lighting element according to one of the preceding claims 1 to 3, characterized in that the outer layer, which is not substantially directed towards the one or more holders, has a noise reduction coefficient (NRC) of at least 0.5, preferably at least 0.7. Acoustic lighting element according to one of the preceding claims 1 to 4, characterized in that said outer layer has an average sound absorption (SAA) of 0.7, preferably at least 0.75, wherein the SAA is a mathematical average of 12 mutually 1/3 of an octave spread sound absorption coefficients in a diffuse field for a frequency range of 200 to 2500 Hz. BE2017 / 6011 Acoustic lighting element according to one of the preceding claims 1 to 5, characterized in that the outer layer comprises polyethylene terephthalate (PETP). Acoustic lighting element according to one of the preceding claims 1 to 6, characterized in that the outer layer comprises fire-retardant fibers. Acoustic lighting element according to one of the preceding claims 1 to 7, characterized in that the outer layer comprises polyester fibers, the polyester fibers comprising copolymers composed of a main monomer and a phosphorus-organic comonomer. 9. Acoustic lighting element as claimed in any of the foregoing claims 1 to 8, characterized in that the shielding structure under the outer layer is provided with a foam layer with a maximum specific weight of approximately 50 kg / m ³ and preferably with a minimum specific weight of approximately 15 kg / m3, more preferably with a maximum specific weight of approximately 25 kg / m3 and a minimum specific weight of approximately 40 kg / m3. 10. Acoustic lighting element as claimed in any of the foregoing claims 1 to 9, characterized in that the outer layer, which is substantially not directed to the one or more holders, is made up of at least two layers with a fiber structure, the fiber structure of at least two of the two layers are differently oriented with respect to each other. Acoustic lighting element as claimed in any of the foregoing claims 1 to 10, characterized in that the shielding structure comprises a, preferably elliptical, paraboloidal roof, wherein the one or more holders are positioned completely within the paraboloidal roof, and wherein preferably the paraboloidal roof on the outside of the paraboloidal roof merges into a substantially flat spur on the convex side of the roof, which spur extends from the convex side of the roof in the direction of the axis of symmetry of the roof, and wherein the flat spur in a plane of symmetry lies from the roof. 12. Acoustic lighting element as claimed in any of the foregoing claims 1 to 10, characterized in that the shielding structure comprises at least two concentric rollers of different diameter, an inner roll and an outer roll, optionally wherein the rollers are provided with an open pattern, and BE2017 / 6011 wherein a first part of the one or more holders is positioned within the outer roll, a second part of the one or more holders is positioned within the outer and the inner roll, and a third part of the one or more holders is within the inner role. Acoustic lighting element according to one of the preceding claims 1 to 10, characterized in that the shielding structure is essentially plate-shaped, wherein the one or more light-emitting elements are positioned on a first side of the plate-shaped shielding structure, and wherein the acoustic lighting element comprises a frame on the first side of the screening structure which is adapted to be fixed to a wall. Acoustic lighting element according to one of the preceding claims 1 to 10, characterized in that the shielding structure has a disc-shaped structure with a central recess on a first side which is closed on the opposite side of the disc-shaped structure, the one or a plurality of holders are positioned in the central recess. Acoustic lighting element according to one of the preceding claims 1 to 10, characterized in that the shielding structure has a truncated onion shape, wherein the onion shape is provided with a roll-shaped spur on the top and bottom of the onion shape, and wherein the onion shape comprises a plurality of narrow, strip-shaped openings extending from the top to the bottom of the onion shape. Acoustic lighting element as claimed in any of the foregoing claims 1 to 10, characterized in that the shielding structure has a truncated cone shape, which is open at the top and bottom, and wherein the holders are located in the shielding structure, preferably wherein the truncated cone shape is slanted. 17. Acoustic lighting element according to one of the preceding claims 1 to 16, wherein the one or more holders are positioned to hold light-emitting elements which are completely within the shielding structure. Use of the acoustic lighting element according to one of claims 1 to 17 for the acoustic damping of incident sound.