ITMI20112331A1 - INDIRECT LIGHT LED LIGHTING DEVICE - Google Patents

Description

DESCRIPTION

of the patent for industrial invention entitled:

"INDIRECT LIGHT LED LIGHTING DEVICE"

The present invention relates to an indirect light LED luminaire, specifically a luminaire for lighting rooms.

As is well known, LED light sources are increasingly used in the room lighting sector.

The practically point-like nature of these sources, together with their still relatively modest intensity of individual illumination, however, pose problems in obtaining satisfactory light effects, distributions and intensities.

Especially in the sector of devices for lighting environments (domestic or work), devices of small dimensions and high performance are increasingly required, both for aesthetic and functional reasons, and are also able to provide particular lighting effects, not always compatible with normal LED solutions. For example, it is very difficult to prevent the emitted light from showing an image of individual point sources.

Known LED lighting devices therefore seem to have room for improvement, above all in terms of performance, simplicity of construction and overall dimensions.

It is an object of the present invention to provide a LED lighting device which allows to overcome, in whole or in part, the problems highlighted herein of the known art; in particular, it is an object of the invention to provide a particularly compact device, simple to manufacture, effective in terms of light performance and thermal dissipation.

The present invention therefore relates to an indirect light LED lighting device as essentially defined in the attached claim 1 and, for its preferred aspects, in the dependent claims.

The invention is described in detail in the following non-limiting example of implementation, with reference to the figures of the attached drawings, in which:

Figure 1 is a schematic front perspective view of an LED lighting device according to the invention, in which some internal parts are also shown which would not be visible in the perspective of Figure 1;

figure 2 is a schematic view in longitudinal section of the device of figure 1;

- figure 3 is a schematic plan view, with parts removed for clarity, of a detail of the device of figure 1.

With reference to the attached figures, an indirect light LED lighting device 1, in particular for lighting rooms, extends along and around a central axis A and comprises a support body 2 and a plurality of LEDs 3 arranged crown on support body 2 around axis A.

In the illustrated non-limiting example, the axis A is a central axis of the device 1, which has central symmetry with respect to the axis A; axis A also defines an optical axis of device 1.

The supporting body 2 is a generally hollow body and comprises a tubular casing 4, having a side wall 5 and extending along the axis A between two opposite axial ends 6, 7, and a cap 8 housed inside the casing 4.

In the illustrated non-limiting example, the casing 4 is substantially cylindrical; the end 6 of the casing 4 has a radially internal flange 9 which defines a substantially annular frame 10, arranged around the axis A and having a light emission opening 11.

The flange 9 (i.e. the frame 10) is for example (but not necessarily) substantially circular and shaped like a flattened annular disk; the flange 9 has two substantially annular opposite faces 12, 13 perpendicular to the axis A, a radially internal perimeter edge 14 which delimits the emission opening 11, and a radially external perimeter edge 15 attached to the casing 4. The face 12 it faces the cap 8, ie towards the inside of the support body 2, and therefore constitutes an internal face of the flange 9; the face 13 faces the environment to be illuminated with the device 1 and therefore constitutes an external face of the flange 9.

The cap 8 is arranged inside the casing 4 and separates a front cavity 16, facing the emission opening 11 and the internal face 12 of the flange 9, from a rear chamber 17.

The cap 8 is generally concave and extends from the flange 9 and around the axis A and faces the flange 9; the cap 8 has an end edge 18 which is joined to the flange 9 and / or to the side wall of the casing 4.

In particular, the flange 9 (ie the frame 10) extends radially inward from the end edge 18 of the cap 8. In other words, the cap 8 protrudes from the radially external peripheral edge 15 of the flange 9.

The cap 8 has a generically concave shape and has a light diffusion surface 19 which is generally concave and faces the internal face 12 of the flange 9 and the LEDs 3.

The shape of the cap 8 and in particular of its diffusion surface 19 can be various: in the illustrated non-limiting example, the diffusion surface 19 is a surface of rotation with respect to the axis A; in particular, the cap 8 and the diffusion surface 19 are substantially hemispherical, but it is understood that they can have another shape (for example parabolic shape, with a spherical or elliptical cap, etc.).

The cap 8 or at least at least its diffusion surface 19 are made of a polymeric material having a diffuse reflectance of the visible light of 90% or more, preferably 95% or more, and a total reflectance of the visible light of 95% or more, preferably 99% or higher.

In other words, the material with which the cap 8 and / or the diffusion surface 19 are made reflects the light (visible light) in a diffused manner for at least 90%, preferably for at least 95%: a ray of light that affects on the diffusion surface 19 it is therefore not reflected at a determined angle, but is diffused, regardless of the angle of incidence, in many directions, substantially in almost every direction, while only a fraction of less than 10% (or, better, 5 %) is mirrored (in a direction determined by the angle of incidence).

In particular, the polymeric material of the diffusion surface 19 is a microcellular expanded polymeric material, having cells having an average size lower than or equal to about 10 µm. Furthermore, indicatively, the material has a cell density comprised between about 10 <9> and 10 <15> cells / cm <3>. Preferably, this material is a microcellular expanded polyethylene terephthalate (MC-PET).

According to a preferred embodiment, the diffusion surface 19 is constituted by a film of polymeric material, in particular expanded microcellular polyethylene terephthalate, having a thickness of about 1 mm, possibly applied on a support substrate defining the cap 8.

The LEDs 3 are arranged in a ring on the internal face 12 of the flange 9 and spaced around the emission opening 11 and the axis A; the LEDs 3, carried for example by an annular plate 20 applied to the face 12, are angularly spaced and regularly spaced from each other.

In the example illustrated, the device 1 also comprises a heat sink 21 for dissipating the heat generated by the LEDs 3.

The heat sink 21 is arranged at the end 7 of the casing 4 and in particular at least partially in the rear chamber 17 of the casing 4, beyond the cap 8.

Preferably, the heat sink 21, made of heat-conducting material (for example, a metallic material), is in contact with the casing 4 and specifically with the side wall 5 and / or the flange 9.

Optionally, the device 1 also comprises a reflector 22 which extends from the outer face 13 of the flange 9 around the axis A.

In particular, the reflector 22 extends from the radially internal perimeter edge 14 of the flange 9 to the outside of the cavity 16, beyond the external face 13 of the flange 9.

The reflector 22 has an internal surface 23 which constitutes a reflection surface and ends with a front edge 24, for example circular.

The reflector 22 and / or the reflecting surface 23 are for example made of polished aluminum.

The shape of the reflector 22 and of its surface 23 can be of various types, also according to the destination or application of the device 1; for example, the reflector 22 and / or the surface 23 have a parabolic shape.

For the sake of simplicity, no connections and electrical power supply and control components of the device 1 are shown, nor any hooking members for fixing the support body 2 in the installation position.

In use, the light emitted by the LEDs 3 does not exit directly from the emission opening 11 but affects the diffusion surface 19; the light is diffused by the diffusion surface 19 and sent through the emission opening 11, from which a diffused light then comes out.

The advantages of the lighting device of the invention appear evident from what has been described.

In the first place, the device according to the invention is particularly simple to make, even in very small dimensions.

The device of the invention, although simple and compact, also has high lighting performance, in particular in terms of distribution and light intensity, allowing to obtain a high uniformity of lighting (despite the point-like nature of the LED sources) and a high efficiency.

The conformation of the device and specifically the position of the LEDs then allows the heat generated by the LEDs to be dissipated even without resorting to very complex or bulky heat dissipation structures. The LEDs, in fact, are not only arranged at a distance from each other (and not grouped as in various known applications), but are also located in the front part of the device, in an area where heat dissipation is generally easier, even in the case of embedded applications. The heat sink, if provided, can therefore have smaller dimensions than similar solutions.

Furthermore, the LEDs are not directly visible through the emission opening, and therefore do not disturb the view of those who, being in the environment illuminated by the device, should look directly at the device.

The light that passes through the emission opening is then substantially diffused, which results in not only efficient lighting, but also a particularly comfortable lighting effect.

Finally, it is understood that further modifications and variations may be made to the lighting device described and illustrated here, which do not depart from the scope of the appended claims.

Claims (14)

CLAIMS 1. Indirect light LED lighting device (1), extending along and around an axis (A) and comprising a support body (2) and a plurality of LEDs (3) arranged in a crown on the body (2) of support around the axis (A); the support body (2) comprising a substantially annular flange (9) arranged around the axis (A) and having a light emitting aperture (11); and a concave cap (8) which extends from the flange (9) around the axis (A) and faces an internal face (12) of the flange (9) on which the LEDs (3) are arranged; in which the cap (8) has a light diffusion surface (19) which is generically concave and facing the internal face (12) of the flange (9) and the LEDs (3) and is made of a polymeric material having diffused reflectance visible light of 90% or more and total reflectance of visible light of 95% or more. Device according to claim 1, wherein the diffusion surface (19) is made of a polymeric material having a diffuse reflectance of visible light of 95% or higher. Device according to claim 1 or 2, wherein the diffusion surface (19) is made of a polymeric material having total visible light reflectance of 99% or greater. Device according to one of the preceding claims, wherein the polymeric material of the diffusion surface (19) is a cellular expanded polymeric material. 5. A device according to claim 4, wherein the microcellular expanded polymeric material has cells of average size less than or equal to about 10 µm. Device according to one of the preceding claims, wherein the polymeric material of the diffusion surface (19) is a microcellular expanded polyethylene terephthalate (MC-PET). Device according to one of the preceding claims, wherein the flange (9) projects radially inward from an end edge (18) of the cap (8). Device according to one of the preceding claims, wherein the diffusion surface (19) is a surface of rotation with respect to the axis (A). Device according to one of the preceding claims, in which the cap (8) is arranged inside a substantially tubular casing (4) and separates a front cavity (16), facing the emission opening (11) and the face (12) internal flange (9), from a rear chamber (17). Device according to claim 9, and comprising a heat sink (21) for dissipating the heat generated by the LEDs (3), which is arranged at least partially in the rear chamber (17) of the housing (4), beyond the cap ( 8). Device according to claim 10, wherein the heat sink (21), made of heat-conducting material, is in contact with a side wall (5) of the housing (4) and / or with the flange (9). Device according to one of the preceding claims, and comprising a reflector (22) which protrudes from an outer face (13), opposite the inner face (12), of the flange (9) around the emission opening (11) and it has a reflection surface (23) around the axis (A). Device according to claim 12, wherein the reflector (22) protrudes from a radially inner peripheral edge (14) of the flange (9) outside the cavity (16), beyond the outer face (13) of the flange ( 9). Device according to claim 12 or 13, wherein the reflector (22) and / or the reflecting surface (23) are made of polished aluminum.