The present invention relates in general terms to a lighting device to simulate natural lighting, specifically to simulate the light of the sky and the sun, thus capable of generating at least two light components with different angular distributions and having different correlated colour temperature or CCT. In particular, the present invention relates to a lighting device capable of generating a first highly collimated light component having a lower CCT than the CCT of a second weakly collimated light component, i.e. having an angular aperture of the intensity profile greater than the angular aperture of the highly collimated light component.
State-of-the-art lighting systems are known to simulate natural lighting, specifically the light of the sky and the sun, capable of generating light with chromatic components having different angular distributions, with a first component of directional light, or direct light, having a first correlated colour temperature or lower CCT, and a second diffuse light component having a second greater CCT.
Exemplary embodiments of such lighting systems may use, for example, Rayleigh-type diffusion layers as described in various patent applications of the same Applicant such as WO 2009/156347 A1, WO 2009/156348 A1, WO 2014/076656 A1, and WO 2017/0847561 A1 filed by the same Applicant. Known lighting systems mostly use a light source that produces visible light, and a panel containing nanoparticles. The panel is illuminated by the light source and acts as a so-called chromatic diffuser or Rayleigh-like diffuser, i.e. it diffuses the incident light in a manner similar to the earth's atmosphere under clear sky conditions, thus separating the incident light into a first component of direct light that crosses the panel substantially without being diffused and a second component of light diffused by the panel. In particular, the diffuse light component has a greater CCT than the direct light component, as the Rayleigh-like diffuser has a scattering efficiency that is a function of the wavelength of the light and is greater for shorter wavelengths.
Thanks to the interaction between the direct component with lower CCT that illuminates the objects and projects the shadows thereof, and the diffuse light with higher CCT, which gives the shadows a bluish colouring, the lighting systems are able to faithfully recreate the solar lighting, thus giving the environment a perception of large space.
However, this effect is strongly mitigated when the known lighting systems simulating natural lighting are used in an environment in combination with secondary lighting devices generating traditional white light. The addition of secondary lighting devices is usually aimed at achieving a degree of illumination higher than that provided by the natural lighting system alone, keeping the overall costs for lighting the environment contained.
In such circumstances, the effect of spatial expansion offered by the lighting system simulating natural light is in fact no longer perceptible, since the secondary lighting of the traditional type is not able to generate the contrasts in intensity and colour that are typical of natural light.
The Applicant has therefore observed that, in order not to alter the perception offered by the lighting systems simulating natural light, it is convenient to use secondary lighting devices which are also capable of generating light with chromatic components having different angular distributions with chromatic characteristics and angular aperture of the intensity profile that are comparable to the light components generated by the lighting system simulating natural lighting.
The Applicant has therefore set itself the goal of designing a lighting device to simulate natural lighting that can be used as a secondary lighting device in combination with lighting systems that simulate natural lighting.
In particular, the Applicant has set itself the objective of realising a lighting device to simulate natural lighting that allows to increase the overall lighting offered by a lighting system that simulates natural lighting without altering the perception offered, and that can be realised at a reasonable cost.
Furthermore, the Applicant has set itself the objective of devising a lighting device to simulate natural lighting that can be used to realise a localised natural lighting, for example to illuminate a limited area, such as a work surface, a desk, a table and so on.
In particular, the Applicant wished to study a lighting device to simulate the natural lighting that is able to reproduce the natural lighting without presenting glare effects or unnatural colourings of the ceiling of the room in which it is installed, while offering high lighting efficiency.
In a first aspect, the present invention is directed to a lighting device to simulate natural lighting comprising a first optical unit in turn comprising a primary light source configured to emit primary light in the visible spectrum, and dichroic separation optics configured to intercept at least part of the primary light generated by the primary light source and emit, from a first emission surface, at least one first highly collimated light component having a propagation direction, generated starting from the primary light, and at least one diffuse light component. The at least one first highly collimated light component and the at least one diffuse light component form a light with chromatic components having different angular distributions.
Further, the at least one first highly collimated light component has a first correlated colour temperature CCT1, a total flux and a luminous intensity profile characterized by a first angular aperture α which is lower than 30° measured as half width at half maximum (HWHM) with reference to at least one half-plane section of the dichroic separation optics containing the propagation direction.
Again, the at least one diffuse light component has a second correlated colour temperature CCT2 higher than the first correlated colour temperature CCT1 and a non-zero luminous intensity profile even for angles higher than 2 times the first angular aperture α, such as substantially Lambertian luminous intensity profiles.
A substantially Lambertian emission profile is understood to mean an emission profile proportional to the cosine of the emission angle, with emission angle equal to 0° for the normal direction to the emission surface.
According to the present invention, there is also provided a second optical unit comprising secondary collimation optics configured to intercept at least part of the light with chromatic components having different angular distributions emitted by the first emission surface and generate, starting from this light with chromatic components having different angular distributions,
The lighting device to simulate natural lighting thus conceived is able to generate a light with two chromatic components having different angular distributions, however effectively preventing the light at a higher colour temperature (bluish light) from generating glare effects or from giving the environment an unnatural colouring that the natural light of the sky and the sun would not produce. At the same time, the lighting efficiency is substantially maintained unaltered.
In this way, the lighting device according to the invention can be validly used both as a secondary lighting device, to support lighting systems to simulate natural lighting, since the generation of the chromatic components with different angular distributions allows to support the natural lighting effects that these systems reproduce, and as localized natural lighting, capable of providing a good lighting efficiency in the absence of glare effects.
In accordance with a second aspect thereof, the present invention is directed to a lighting system to simulate natural lighting comprising a plurality of lighting devices of the type described above arranged in such a way as to generate a plurality of highly collimated light components, each around a respective propagation direction of a plurality of parallel propagation directions, the lighting devices being arranged in an extended structure on a plane perpendicular to each of the propagation directions.
Advantageously, the lighting system thus configured makes it possible to achieve the same advantages as described with reference to the lighting device to simulate natural lighting according to the invention.
The present invention may have at least one of the following preferred features; the latter may in particular be combined with one another as desired in order to meet specific application needs.
Preferably, the at least one first highly collimated light component has a luminous intensity profile characterized by a first angular aperture α which is lower than 20°, more preferably lower than 15°, measured as half-width at half height (HWHM) with reference to the at least one half-plane section of the dichroic separation optics containing the propagation direction.
Preferably, the attenuation angle γ is equal to at least 2.5 times, more preferably equal to 3 times, the first angular aperture α of the luminous intensity profile of the first highly collimated light component emitted by the first emission surface.
In a variant of the invention, the secondary collimation optics are configured to generate a weakly collimated light component having a luminous intensity profile, referred to the half-plane section, characterized by an average value of less than 60%, preferably less than 40%, more preferably less than 20% of the average value of the luminous intensity profile of the at least one diffuse light component, calculated with reference to the attenuation angular range.
The secondary collimation optics are further preferably configured to substantially not intercept the highly collimated light component and/or not redistribute and/or not redirect the highly collimated light component outside of the first angular aperture α, in particular to intercept and/or redistribute and/or redirect outside the first angular aperture α less than 10% of the total flux of the highly collimated light component exiting the first emission surface 25, preferably less than 5%, more preferably less than 2%.
In a variant of the invention, the secondary collimation optics are embodied as a refractive lens configured so as to intercept and reflect at least part of the at least one diffuse light component and redistribute it so as to generate a weakly collimated light component having a luminous intensity profile, referred to the half-plane section, characterized by an average value which is lower than the average value of the luminous intensity profile of the at least one diffuse light component calculated with respect to the attenuation angular range.
Alternatively or additionally, the secondary collimation optics are embodied as a refractive lens configured so as to intercept and redirect at least part of the at least one diffuse light component and redistribute it so as to generate a weakly collimated light component having a luminous intensity profile, referred to the half-plane section, characterized by an average value which is lower than the average value of the luminous intensity profile of the at least one diffuse light component calculated with respect to the attenuation angular range.
Preferably, the refractive lens is configured to additionally intercept and redirect at least part of the first highly collimated light component in such a way as to generate a second highly collimated light component having a luminous intensity profile characterized by a second angular aperture α′ measured as half width at half maximum (HWHM) with reference to the half-plane section which is lower than or equal to, preferably lower than, the first angular aperture α.
Alternatively or additionally, the secondary collimation optics are a structure comprising walls having at least a portion made of a material having a diffuse reflectance of at least 50%, preferably at least 55%, more preferably at least 60%.
Alternatively or additionally, the secondary collimation optics are a structure comprising walls having at least a portion made of a material having an absorption coefficient in the visible range equal to at least 70%, more preferably equal to at least 80%, even more preferably equal to at least 90% of the incident light and positioned so as to intercept and absorb at least part of the diffuse light component emitted by the first emission surface at angles greater than the attenuation angle γ.
In the context of this description and subsequent claims, the terms “absorption coefficient”, “regular reflectance” and “diffuse reflectance” refer to the definitions given in the standard E284 regarding the terminology describing the appearance of materials and light sources.
Preferably, the secondary collimation optics are configured to substantially not modify the correlated colour temperature CCT of the light components with chromatic components having different angular distributions emitted by the first optical unit.
Preferably, the secondary collimation optics are configured to generate, starting from the light with chromatic components having different angular distributions emitted by the first emission surface, a weakly collimated light component having a correlated colour temperature substantially equal to the second correlated colour temperature CCT2 of the diffuse light component of the light emitted by the first emission surface, and a second highly collimated light component having a correlated colour temperature substantially equal to the first correlated colour temperature CCT1 of the first highly collimated light component of the light emitted by the first emission surface.
In a variant of the invention, with reference to the half-plane section, the angular aperture β of the weakly collimated light component measured as half width at half maximum (HWHM) of the luminous intensity profile is 1.2 times greater, preferably 1.5 times greater, more preferably 2 times greater than the first angular aperture α measured as half width at half maximum (HWHM) of the intensity profile of the first highly collimated light component.
In a variant of the invention, the dichroic separation optics comprise an optical element for primary collimation configured to generate the highly collimated light component having a luminous intensity profile with the first angular aperture α starting from the primary light, and a diffuse light generator configured to generate the diffuse light component with the second correlated colour temperature.
Preferably, the diffuse light generator is a chromatic scattering element configured to be transparent to at least a first spectral portion of a light incident on the same and to scatter at least a second spectral portion of the incident light.
Alternatively or additionally, the diffuse light generator is a chromatic scattering element of the tunable type, being configured to vary principally the scattering efficiency of the chromatic scattering element in at least the second spectral portion of the incident light, thereby tuning the scattering efficiency of the second spectral portion of the incident light.
Alternatively or additionally, the diffuse light generator is a chromatic scattering element of the tunable type comprising a matrix made of polymeric material in which nanodroplets containing liquid crystals are trapped.
Alternatively or additionally, the diffuse light generator is a chromatic scattering element shaped as a panel, a film, a surface coating layer or a surface anodizing layer.
Alternatively or additionally, the diffuse light generator is a diffuse light generator of the active type, capable of generating diffuse light independently of the primary light source, and made of a material substantially transparent to light, irrespective of the spectrum thereof.
More preferably, the chromatic scattering element is placed at the first emission surface or at least at one surface of interaction between said primary light and said primary collimation element.
In a variant of the invention, at least the optical element for primary collimation of the dichroic separation optics has axial symmetry and the propagation direction is comprised in a symmetry axis of the optical element for primary collimation; and the diffuse light generator has a circular or quadrilateral section—such as for example a square or rectangular—or polygonal section.
In an alternative variant of the invention, the optical element for primary collimation of the dichroic separation optics has an elongated conformation along a development axis of the device, transversal to the propagation axis.
In a variant of the invention, the first optical unit comprises a plurality of primary light sources, for example arranged side by side and/or aligned along the development axis, and wherein the dichroic separation optics comprise at least one collimation lens associated with the plurality of primary light sources and configured to collimate the light emitted by each of the primary light sources around a respective propagation direction of a plurality of parallel propagation directions.
The accompanying drawings, which are incorporated herein and form part of the description, illustrate exemplary embodiments of the present invention and, together with the description, are intended to illustrate the principles of the present invention.
In the drawings:
The following is a detailed description of exemplary embodiments of the present invention. The exemplary embodiments described herein and illustrated in the drawings are intended to teach the principles of the present invention, enabling the person skilled in the art to implement and use the invention in different contexts and/or for different applications. Therefore, the exemplary embodiments are not intended, nor should they be considered, to limit the scope of patent protection. Rather, the scope of patent protection is defined by the attached claims.
With reference to
The lighting device 10 comprises a first optical unit 20 and a second optical unit 30 optically coupled to each other in such a way that the second optical unit 30 intercepts at least part of the light emitted by the first optical unit 20.
In detail, the first optical unit 20 comprises at least one primary light source 21 configured to emit a primary light 22 comprising at least one set of electromagnetic radiations having wavelengths comprised in the visible spectrum (i.e., 380 nm≤λ≤740 nm), also referred to by the terms ‘light beam’, ‘light ray’ or ‘light’ hereafter. For example, the primary light source 21 is a solid-state light-emitting device (LED).
The first optical unit 20 further comprises at least dichroic separation optics 23 having a first light-emitting surface 25 from which light 24 is emitted with chromatic components having different angular distributions. The primary light source 21 is positioned so as to substantially introduce the primary light 22 into the dichroic separation optics 23.
The dichroic separating optics 23 are configured to generate, starting from the primary light 22 emitted by the primary light source 21, at least a first highly collimated light component 24a that crosses the first emission surface 25 and propagates along a propagation direction A, with the propagation direction A coinciding with the direction along which the first highly collimated light component 24a exhibits maximum luminous intensity, and a diffuse light component 24b that crosses the first emission surface 25 propagating in substantially all directions. For example, the diffuse light component 24b has a substantially Lambertian luminous intensity profile.
The first highly collimated light component 24a generated by the dichroic separation optics 23 is characterized by a luminous intensity profile—referred to at least one half-plane section X of the dichroic separation optics 23 containing the propagation direction A—having an angular aperture α—measured in terms of half width at half maximum (HWHM)—which is lower than 30°, preferably lower than 20°, more preferably lower than 15°. In addition, the first highly collimated light component 24a is characterized by a first correlated colour temperature or CCT1 and by a total flux.
The dichroic separation optics 23 are further configured to generate the at least one diffuse light component 24b with a second correlated colour temperature or different CCT2, in particular higher, than the correlated colour temperature CCT1 of the first highly collimated light component 24a. Specifically, the first highly collimated light component 24a has a correlated colour temperature CCT1 1.2 times lower, preferably 1.3 times lower, more preferably 1.4 times lower than the correlated colour temperature CCT2 of the diffuse light component 24b.
In exemplary terms, the dichroic separation optics 23 comprise an optical element for primary collimation 23a, for example a total internal reflection (TIR) lens as shown in
“Chromatic diffusing element” means a diffuser element whose light-diffusing properties depend on the wavelength of the light crossing it, such as a Rayleigh diffuser or Rayleigh-like diffuser. This type of diffuser is characterized by being substantially transparent to, or having negligible interaction with, a first spectral portion of the light incident on the same.
The first spectral portion of the incident light therefore crosses the chromatic scattering element 23b substantially unaltered and—being collimated as a result of the action of the optical element for primary collimation 23a—generates, downstream of the chromatic scattering element 23b, the first highly collimated light component 24a of the light 24 with chromatic components having different angular distributions having the lower correlated colour temperature CCT1, wherein “downstream” is understood with respect to the propagation direction A. On the contrary, the chromatic scattering element 23b acts mainly on a second spectral portion of the light incident on the same, scattering it significantly and thus giving rise to the diffuse light component 24b of the light 24 with chromatic components having different angular distributions which has a higher correlated colour temperature CCT2, since it is substantially devoid of the wavelengths belonging to the first spectral portion.
The chromatic separation and the generation of the diffuse light component 24b with higher CCT2 (bluish light component) can be achieved by using a “thick” panel, as shown for example in
Such a chromatic scattering element may be in the form of a panel, a film, a surface coating layer or even a surface anodizing layer of a metal surface having specific structural characteristics described in detail in Italian patent application No. 1020200008113, filed by the same Applicant, the contents of which are herein fully referred to and incorporated by reference.
Again, the chromatic scattering element may be of the tunable type, whereby the intensity of interaction between the chromatic scattering element and the incident light may be tuned, thereby modifying the diffusion efficiency in particular of the second spectral portion of the incident light, i.e. the portion of the incident light on which the chromatic scattering element mainly acts. The chromatic diffusion elements of the tunable type comprise, for example, a matrix made of polymeric material (host material) in which so-called nanodrops containing liquid crystal (LC) molecules (diffusion nanometric elements) are trapped. The liquid crystals cause an anisotropy in the refractive index, which therefore makes it possible to tune the jump in the refractive index between the liquid crystal nanodroplets and the host material by varying an applied voltage. In general terms, the index variation is due to the fact that the liquid crystal molecules inside each nanodroplet tend to align when an electric field is applied, having a degree of alignment that can be modified according to the magnitude of the applied voltage. For further details, reference is made to International Patent Application No. WO 2018/091150 of the same Applicant and the contents of which are fully referred to and incorporated herein by reference.
Unlike the embodiment of
The second optical unit 30 comprises at least one secondary collimation optics 33 having a light-input surface 36, placed downstream of the first light-emitting surface 25 of the first optical unit 20 and such that it intercepts at least part of the light 24 with chromatic components having different angular distributions emitted by the first optical unit 20, and a second light-emitting surface 35 from which collimated light 34 with chromatic components having different angular distributions is emitted.
In particular, the secondary collimation optics 33 are configured to interact with the diffuse light component 24b of the light 24 emitted by the first optical unit 20 so as to generate, downstream of the second light-emitting surface 35, a weakly collimated light component 34b having a luminous intensity profile, referred to the at least one half-plane section X of the dichroic separation optics 23, characterized by an average value, calculated with reference to an attenuation angular range comprised between an attenuation angle γ and 90°, which is less than the average value of the luminous intensity profile of the at least one diffuse light component 24b, calculated with respect to the same attenuation angular range.
In detail, the attenuation angle γ is measured with respect to the propagation direction A and is equal to at least 2 times, preferably at least 2.5 times or, even more preferably, at least 3 times, the first angular aperture α of the luminous intensity profile of the first highly collimated light component 24a emitted by the first emission surface 25.
For example, the secondary collimation optics 33 are configured to generate a weakly collimated light component 34b having a luminous intensity profile referred to the half-plane section X characterized by an average value of less than 60%, preferably less than 40%, more preferably less than 20% of the average value of the luminous intensity profile of the diffuse light component 24b exiting the first emission surface 25, calculated in the attenuation angular range, i.e. the angular range comprised between the attenuation angle γ and 90°. This ensures that the lighting device 10 is characterized by a minimal glare for angles within the attenuation angular range, with reference to the at least one half-plane section X, while maintaining high luminous efficiency levels of the lighting device.
In addition, the secondary collimation optics 33 are configured to interact with the first highly collimated light component 24a of the light 24 emitted by the first emission surface 25 so as to generate a second highly collimated light component 34a having substantially the same total flux as the first highly collimated light component 24a and a second angular aperture α′ of the luminous intensity profile which is equal or less than the first angular aperture α of the luminous intensity profile of the first highly collimated light component 24a emitted by the first emission surface 25, e.g., by not intercepting the first highly collimated light component 24a, as shown in
Still, the secondary collimation optics 33 is configured to substantially not modify the correlated colour temperature CCT of the light components 24 with chromatic components having different angular distributions emitted by the first optical unit 20. At the exit from the second light-emitting surface 35, a weakly collimated light component 34b having a correlated colour temperature substantially equal to the second correlated colour temperature CCT2 of the diffuse light component 24b of the light 24 emitted by the first optical unit 20 and a second highly collimated light component 34a having a correlated colour temperature substantially equal to the first correlated colour temperature CCT1 of the first highly collimated light component 24a of the light 24 emitted by the first emission surface 25 are thus generated. The combination of these light components 34a,34b forms the collimated light 34 with chromatic components having different angular distributions emitted by the second light-emitting surface 35 of the second optical unit 30.
In particular, the weakly collimated light component 34b is characterized by a luminous intensity profile with an angular aperture β greater than the angular aperture α′ of the intensity profile of the second highly collimated light component 34a, wherein both intensity profiles are referred to the at least one half-plane section X of the dichroic separation optics 23.
For example, the angular aperture β of the weakly collimated light component 34b has a half width at half maximum (HWHM) 1.2 times greater, preferably 1.5 times greater, plus preferably 2 times greater than the half width at half maximum (HWHM) of the angular aperture α′ of the intensity profile of the second highly collimated light component 34a.
In the embodiment of
With reference to
In the embodiment of
With reference to
In detail, in the embodiment of
Furthermore, the secondary collimation optics 33 are configured to further collimate the first highly collimated light component 24a of the light emitted by the first emission surface 25, thereby obtaining downstream of the second emission surface 35 a second highly collimated light component 34a having a second angular aperture α′ of the luminous intensity profile which is lower than the first angular aperture α of the luminous intensity profile of the first highly collimated light component 24a emitted by the first emission surface 25. In other words, the secondary collimation optics 33 are configured to generate the second highly collimated light component 34a starting from the first highly collimated light component 24a emitted by the first emission surface 25, keeping its total flux substantially unaltered and reducing the angular aperture of the luminous intensity profile in the reference half-plane.
Thus, at the exit of the second light-emitting surface 35 there are therefore the weakly collimated light component 34b with higher correlated colour temperature CCT2 and the second highly collimated light component 34a with lower correlated colour temperature CCT1—the latter being characterized by a second angular aperture α′ of the luminous intensity profile which is lower than the first angular aperture α of the luminous intensity profile of the first highly collimated light component 24a exiting the first optical unit 20 and a total flux substantially equal to the flux of this first highly collimated light component 24a. The combination of these light components 34a,34b forms the collimated light 34 emitted by the second light-emitting surface 35 of the second optical unit 30.
With reference to
In this case, the light 22 emitted by the primary light source 21, incident on the internal walls of the reflector 23a, is partly collimated and partly diffused. In particular, a first spectral portion of the incident light crosses the chromatic scattering layer 23b″ two times (incident beam and reflected beam) in a substantially unaltered manner, thus undergoing almost exclusively the collimation action caused by the reflector 23a. On the contrary, a second spectral portion of the incident light interacts significantly with the chromatic scattering layer 23b″, which covers the internal walls of the reflector 23a, and is thus mainly scattered.
In this way, two chromatic components with different angular distributions exiting the dichroic separation optics 23 are generated: the first highly collimated light component 24a with lower colour correlated temperature CCT1 and the diffuse light component 24b with higher colour correlated temperature CCT2.
In order to ensure that almost all of the second spectral portion of the emitted primary light 22 interacts with the chromatic scattering layer 23b″, thereby generating the diffuse light component 24b, the lighting device 10 may comprise a screen 27 positioned downstream of the primary light source 21 with respect to the propagation direction A so as to block a direct exit of the light emitted by the primary light source 21 through the first emission surface 25.
In this case, the light 22 emitted by the primary light source 21, crossing the portion of the light entry surface 26, is partly collimated and partly diffused. In particular, a first spectral portion of the light crosses the portion of the light input surface 26—and so also the chromatic scattering layer 23b″—substantially unaltered, thereby undergoing the collimation action given by the lens 23a. A second spectral portion of the light incident on the chromatic scattering layer 23b″, on the contrary, interacts significantly with the same, thus being mainly scattered.
This results in the generation of two chromatic components with different angular distributions exiting the dichroic separation optics 23: the first highly collimated light component 24a with lower colour correlated temperature CCT1 and the diffuse light component 24b with higher colour correlated temperature CCT2.
Furthermore, in the embodiment of
With reference to
In detail, the first optical unit 20 of the device of
The first highly collimated light component 24a generated by the dichroic separation optics 23 is characterized by a luminous intensity profile with an angular aperture α of less than 30°, preferably less than 20°, more preferably less than 15°, with reference to the at least one half-plane section X of the dichroic separation optics 23 containing the propagation direction A.
In view of the non-axial symmetry of the lighting device 10′ with elongated development, it is to be considered that the first highly collimated light component 24a generated by the dichroic separation optics 23 has a luminous intensity profile with an angular aperture of less than or equal to 30° (20° or 15°, respectively) with respect to a subset of half-plane sections X of the dichroic separation optics 23 containing the propagation direction A, inclined to each other around the propagation direction A. In particular, the subset of half-plane sections X for which this condition is satisfied comprises half-planes that are inclined to each other within an angular range of at least 20°.
The second optical unit 30 of
In addition, the secondary collimation optics 33 are configured so as to maintain substantially unaltered the first highly collimated light component 24a emitted by the first optical unit 20, substantially by not varying or at most reducing the angular aperture α of the luminous intensity profile and by not modifying the total flux.
Thus, a weakly collimated light component 34b and a second highly collimated light component 34a exiting the second light-emitting surface 35 are thus generated which form the collimated light 34 emitted by the second optical unit 30, thus exiting the lighting device 10′ according to the invention. In particular, the highly collimated light component 34a exiting the second optical unit 30 has an angular aperture α′ of the luminous intensity profile equal or less than the angular aperture α of the intensity profile of the first highly collimated light component 24a exiting the first optical unit 20 and the total flux substantially equal to that of this first highly collimated light component 24a.
In particular, the weakly collimated light component 34b is characterized by a luminous intensity profile with an angular aperture β greater than the angular aperture α′ of the intensity profile of the second highly collimated light component 23a, wherein both intensity profiles are referred to the at least one half-plane section X of the dichroic separation optics 23.
The invention thus conceived is susceptible to several modifications and variations, all falling within the scope of the inventive concept. For example, the secondary collimation optics 33 may be realised as a structure comprising partly absorbing and partly reflecting internal walls, or partly opaque and partly reflecting or again, partly opaque and partly absorbing, being in any case configured so as to absorb at least part of the diffuse light component 24b intercepted by the optics 33, and to reflect at least another part of the diffuse light component 24b intercepted by the optics 33, so as to attenuate the luminous intensity of the diffuse light component 24b for angles higher than the attenuation angle γ in the at least one half-plane section X.
In conclusion, all the details can be replaced with other technically-equivalent elements.
Number | Date | Country | Kind |
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102020000018418 | Jul 2020 | IT | national |
Filing Document | Filing Date | Country | Kind |
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PCT/IB2021/056498 | 7/19/2021 | WO |
Publishing Document | Publishing Date | Country | Kind |
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WO2022/023868 | 2/3/2022 | WO | A |
Number | Name | Date | Kind |
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9709245 | Di Trapani | Jul 2017 | B2 |
20170153021 | Di Trapani | Jun 2017 | A1 |
20180246270 | Di Trapani | Aug 2018 | A1 |
20190024874 | Van Bommel | Jan 2019 | A1 |
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109027798 | Dec 2018 | CN |
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Entry |
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Eric Prevot, European International Searching Authority, International Search Report and Written Opinion, counterpart PCT Application No. PCT/IB2021/056498, dated Jan. 10, 2022, 11 total pages. |
Number | Date | Country | |
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20230341107 A1 | Oct 2023 | US |