Patent Description:
More in detail, the present invention preferably relates to a headlight or taillight for cars and similar vehicles, i.e. a lighting device suitable for being incorporated in a motor vehicle with the function of indicating the position, sudden deceleration and/or turning direction of the vehicle, and/or the function of lighting the area around the vehicle. Use to which the following disclosure will make explicit reference without thereby losing generality.

As is known, a headlight or taillight for cars and similar motor vehicles is conventionally a lighting device that is placed in the front, rear or side of the vehicle, and performs the function of lighting the area around the vehicle and/or indicating the position of the vehicle, the sudden deceleration of the vehicle and/or the turning direction of the vehicle, in accordance with certain photometric type-approval standards.

Most taillights for cars and similar motor vehicles usually comprise: a substantially basin-shaped, rigid rear body, which is structured so as to be firmly recessed in a compartment specially made in the rear part of the vehicle body; a front half-shell, which is arranged to close the mouth of the rear body so as to surface outside of the vehicle body, and generally has a plurality of transparent or semitransparent sectors, usually different in colour from one another; and a series of lighting assemblies that are located inside the rear body, each immediately beneath a respective transparent or semitransparent sector of the front half-shell, so as to selectively backlight the overlying transparent or semitransparent sector of the front half-shell.

Usually, each transparent or semitransparent sector of the front half-shell is moreover uniquely associated with a specific lighting signal, thus each lighting assembly is specifically structured to emit, on command, a light beam that, once exited from the taillight through the corresponding transparent or semitransparent sector of the half-shell, meets the type-approval specifications (colour and light distribution) for the corresponding lighting signal.

Over the last few years, many car manufacturers have chosen to equip their new car models with taillights capable of producing, at night, elaborate light effects allowing the car model to be uniquely identified.

In greater detail, some car manufacturers have equipped their car models with taillights having U- or L- shaped luminous areas, that allow the same car manufacturers to be uniquely identified.

In other words, the light effects produced by the taillights have become characteristic and distinctive elements of the individual car manufacturers.

The lighting assemblies that are used to create the ribbon-like luminous areas, and more particularly the U- or L- shaped luminous areas, usually comprise: a light-guide plate of suitable thickness, which is made of transparent plastic material, is U- or L- bent so that the front sidewall of the plate substantially copies the shape of the U- or L- shaped luminous area to be realized, and is located inside the rear body with its front sidewall grazing the corresponding transparent or semi-transparent sector of the front half-shell; and a series of high power LEDs (acronym for Light Emitting Diode) that instead are located inside the rear body, close to the rear sidewall of the light-guide plate, so as to direct the light produced within the body of the light-guide plate. Once entered into the light-guide plate, the light emitted by the LEDs propagates within the body of the light-guide plate by total internal reflection, up to reach the front sidewall from where it comes out directed towards the facing transparent or semi-transparent sector of the front half-shell.

Clearly, in order to evenly backlight the facing transparent or semi-transparent sector of the front half-shell, the LEDs must be distributed in a substantially regular manner over the whole length of the rear sidewall of the light-guide plate.

Unfortunately, although working very well, the above-described backlighting system requires a large number of LEDs, with the high production costs that this entails.

In fact, in addition to the intrinsic high cost of the LEDs, the taillight must also be structured so that the considerable heat produced by the LEDs during operation can be dissipated outside.

This obligation requires to incorporate, into the taillight, heat dissipation devices that contribute to further increasing the production cost of the taillight.

Document <CIT> discloses an automotive light according to the preamble of claim <NUM>.

Aim of the present invention is to provide a taillight, which is capable of producing U- or L- shaped luminous areas and which is more economical to produce.

In accordance with these aims, according to the present invention there is provided an automotive light as defined in Claim <NUM> and preferably, though not necessarily, in any one of the claims dependent thereon.

The present invention will now be described with reference to the accompanying drawings, which illustrate a non-limiting embodiment thereof, wherein:.

With reference to <FIG> and <FIG>, number <NUM> denotes as a whole an automotive light, i.e. a lighting device adapted to be firmly fixed to the front or rear of the body of a motor vehicle, with the function of emitting light signals adapted to signal/indicate the position of the vehicle and/or the sudden deceleration of the vehicle and/or the turning direction of the vehicle during travel and/or with the function of lighting the area around the vehicle.

In other words, the automotive light <NUM> is adapted to be fixed to the front or rear part of the vehicle body of a car, van, truck, motorcycle or other similar motor vehicle, to work as a headlight or taillight.

Clearly, the automotive light <NUM> could also be located on a lateral side of the car or other similar motor vehicle.

Preferably, the automotive light <NUM> is furthermore structured so as to be stably recessed in the vehicle body (not shown) and to surface outside of the vehicle.

In the example shown, in particular, the automotive light <NUM> is preferably structured to be stably recessed in the rear part of the vehicle body of a car or other similar motor vehicle.

In other words, the automotive light <NUM> is preferably a taillight for cars and the like.

Naturally, in a different embodiment, the automotive light <NUM> could also be structured so as to be simply fixed cantilevered to the front, side or rear of the vehicle body (not shown).

With reference to <FIG> and <FIG>, in particular, the automotive light <NUM> comprises: a substantially rigid and preferably made of plastic material, concave rear body <NUM> which is substantially basin-shaped and is structured so as to be firmly fixed to the vehicle body (not shown); and a substantially rigid and preferably made of plastic material, front half-shell <NUM>, traditionally designated as a lens, which is arranged to close the mouth of the rear body <NUM> preferably so as to surface outside of the vehicle body, and has one or more transparent or semitransparent sectors, which are optionally also coloured.

In addition, the automotive light <NUM> also comprises one or more electrically-powered lighting assemblies, each of which emits light on command and is located inside the rear body <NUM>, underneath a corresponding transparent or semi-transparent sector of the front half-shell <NUM>, so as to selectively backlight the same transparent or semitransparent sector of the front half-shell, preferably separately and independently of the other lighting assemblies of the automotive light.

Preferably, the lighting assembly or at least one of the lighting assemblies of automotive light <NUM> is moreover structured so as to direct the light towards the corresponding facing transparent or semitransparent sector of front half-shell <NUM>, with a prevalent component of the light beam substantially parallel to a predetermined reference optical axis, which is preferably substantially parallel to the longitudinal axis of the vehicle when the automotive light <NUM> is correctly mounted/placed on the vehicle body.

In greater detail, the rear body <NUM> is preferably made of an opaque plastic material and is preferably structured so as to be at least partially recessed within a seat specially made in the rear part of the vehicle body.

Obviously, in a different embodiment, the rear body <NUM> could also be structured so as to be at least partially recessed within a seat specially made in the front or lateral part of the vehicle body (not shown), or so as to be simply fixed cantilevered on the front, side or rear part of the vehicle body.

The front half-shell <NUM>, in turn, is preferably made of a transparent or semi-transparent plastic material, such as for example polymethylmethacrylate (PMMA) or polycarbonate (PC), and is preferably provided with a plurality of adjacent transparent or semi-transparent sectors, each of which is separately backlighted by a corresponding lighting assembly.

Clearly, front half-shell <NUM> may additionally include also opaque sectors.

With reference to <FIG>, <FIG> and <FIG>, in addition, the or at least one of the lighting assemblies of the automotive light is moreover structured so as to backlight, on command, the corresponding transparent or semi-transparent sector of front half-shell <NUM> creating a substantially U-shaped luminous area.

In greater detail, in the example shown, the automotive light <NUM> is provided with a first lighting assembly <NUM> structured so as to backlight the facing transparent or semi-transparent sector of front half-shell <NUM> creating a substantially U-shaped luminous area, and optionally also with a second lighting assembly <NUM>.

Preferably, the lighting assembly <NUM> is moreover structured so as to direct the light towards the facing transparent or semi-transparent sector of the front half-shell <NUM>, with a prevalent component of the light beam substantially parallel to a first reference optical axis A, which is preferably substantially parallel to the vehicle longitudinal axis when the automotive light <NUM> is correctly mounted/placed on the vehicle body.

Similarly, the lighting assembly <NUM> is preferably structured so as to direct the light towards the facing transparent or semi-transparent sector of the front half-shell <NUM>, with a prevalent component of the light beam substantially parallel to a second reference optical axis, which is preferably substantially parallel to the vehicle longitudinal axis when the automotive light <NUM> is correctly mounted/placed on the vehicle body.

With reference to <FIG>, the lighting assembly <NUM> firstly comprises: a light-guide plate <NUM> of suitable thickness, which is made of photoconductive material and is arranged within the rear body <NUM> with a first face, hereinafter referred to as the front face, grazing or in any case facing the front half-shell <NUM>, and with a second face, hereinafter referred to as the rear face, facing the bottom of rear body <NUM>; and a series of LEDs <NUM> (acronym for Light Emitting Diode) that are located inside the rear body <NUM>, close to a first side of the light-guide plate <NUM>, and are oriented so as to direct the light produced into the body of light-guide plate <NUM>, through the facing lateral sidewall <NUM> of the same light-guide plate <NUM>. This light then propagates within the body of the light-guide plate <NUM> by total internal reflection.

Therefore, the lateral sidewall <NUM> is the light-entry sidewall of the light-guide plate <NUM>.

In greater detail, the light-guide plate <NUM> is preferably substantially quadrilateral in shaped and is preferably arranged inside the rear body <NUM> so as to be substantially perpendicular to the optical axis A of lighting assembly <NUM>.

In the example shown, in particular, the light-guide plate <NUM> is preferably provided with four main sides, preferably substantially straight and in pairs substantially parallel to each other.

Furthermore, the LEDs <NUM> are arranged inside the rear body <NUM> close to a sole/single main side of the light-guide plate <NUM>, so as to light up a sole lateral sidewall of the same light-guide plate <NUM>.

In addition, the light-guide plate <NUM> has a substantially ribbon-like light-exit band that extends along the perimeter of the front face of light-guide plate <NUM>, adjacent to the three remaining consecutive and mutually inclined sides of the same light-guide plate <NUM>, and is overall structured so as to cause the light propagating inside itself to come out solely from said perimeter light-exit band.

In other words, the perimeter light-exit band of light-guide plate <NUM> is substantially U-shaped, and the light emitted by the LEDs <NUM> enters the light-guide plate <NUM> through the lateral sidewall <NUM> and exits the light-guide plate <NUM> only along the perimeter light-exit band.

Furthermore, the lateral sidewall <NUM> of light-guide plate <NUM> is aligned with and opposite to the central segment of the perimeter light-exit band of the plate.

In greater detail, with reference to <FIG>, <FIG>, <FIG>, the remaining second, third and fourth sides of light-guide plate <NUM>, i.e. the sides of light-guide plate <NUM> not directly lighted up by the LEDs <NUM>, are preferably L-bent toward the front half-shell <NUM> so as to form, along the perimeter of the front face of light-guide plate <NUM>, a long protruding perimeter rib or shoulder <NUM> which is substantially U-shaped and extends cantilevered from the edge of the front face of light-guide plate <NUM>, towards the front half-shell <NUM>.

Therefore the top of protruding perimeter shoulder or rib <NUM> is substantially grazing, or in any case facing, the front half-shell <NUM> and is structured so as to allow the light propagating within the plate to freely come out of the plate and backlight the front half-shell <NUM>.

With reference to <FIG> and <FIG>, the light-guide plate <NUM> moreover has, on one of its two larger faces, also a large light-distributing recess <NUM> of given shape, which has a depth less than the thickness s of the light-guide plate <NUM> and is shaped so as to distribute the light coming from the lateral sidewall <NUM> of light-guide plate <NUM>, in a predetermined and controlled manner along the whole length of the protruding perimeter rib or shoulder <NUM>. This light then comes out of the light-guide plate <NUM> from the top of the same protruding perimeter rib or shoulder <NUM>.

Therefore, the top of the protruding perimeter shoulder or rib <NUM> forms the perimeter light-exit band of the light-guide plate <NUM>.

In greater detail, the light-distributing recess <NUM> is located in front of the lateral sidewall <NUM> of light-guide plate <NUM> and is adapted to distribute a part of the light coming from the lateral sidewall <NUM> of light-guide plate <NUM> and directed towards the portion of the protruding perimeter rib or shoulder <NUM> immediately aligned with and opposite to the lateral sidewall <NUM>, towards the other portions of the protruding perimeter rib or shoulder <NUM>.

In other words, the light-distributing recess <NUM> is adapted to distribute a part of the light coming from the lateral sidewall <NUM> of light-guide plate <NUM> and directed towards the segment of the perimeter light-exit band of the light-guide plate <NUM> immediately aligned with and opposite the lateral sidewall <NUM>, towards the other segments of the same perimeter light-exit band.

In addition, the light-distributing recess <NUM> is preferably shaped and dimensioned so as to distribute the light coming from the lateral sidewall <NUM> of light-guide plate <NUM> in a substantially even manner along the whole length of the protruding perimeter rib or shoulder <NUM>.

Once entered into the light-guide plate <NUM> through the lateral sidewall <NUM> of the plate, therefore, the light emitted by the LEDs <NUM> propagates within the body of light-guide plate <NUM> by total internal reflection, up to reach the crest or top of the protruding perimeter shoulder or rib <NUM> from where it comes out freely, directed towards the front half-shell <NUM>.

In other words, the light emitted by the LEDs <NUM> enters the light-guide plate <NUM> through the lateral sidewall <NUM> and exits the light-guide plate <NUM> only along the perimeter rib or shoulder <NUM>.

The light coming out from the top of the protruding perimeter shoulder or rib <NUM> thus backlights the facing transparent or semi-transparent sector of the front half-shell <NUM>, creating a substantially U-shaped luminous area.

In the example shown, in particular, the light-guide plate <NUM> preferably has a monolithic structure and is preferably made of polymethylmethacrylate (PMMA) or other transparent plastic material, advantageously via an injection moulding process.

Preferably, the light-guide plate <NUM> moreover has a nominal thickness ranging between <NUM> and <NUM> (millimetres).

With reference to <FIG>, in addition, the lateral sidewall <NUM> of light-guide plate <NUM> is preferably substantially straight and is preferably provided with a series of small grooves or indentation <NUM>, each of which accommodates a respective LED <NUM> and is preferably shaped so as to concentrate the light beam coming out of the same LED <NUM>.

The protruding perimeter shoulder or rib <NUM> of light-guide plate <NUM>, on the other hand, is longitudinally divided into three consecutive segments that are substantially straight and are preferably joined to one another substantially seamlessly.

The central segment of protruding perimeter shoulder <NUM> is located on the opposite side of light-guide plate <NUM> with respect to the lateral sidewall <NUM> and is preferably also substantially parallel to the same lateral sidewall <NUM>. The two end segments of protruding perimeter shoulder <NUM>, on the other hand, extend towards the lateral sidewall <NUM>, on opposite sides thereof, preferably while remaining substantially parallel to each other.

With reference to <FIG> and <FIG>, the light-distributing recess <NUM>, in turn, is interposed between the lateral sidewall <NUM> of light-guide plate <NUM>, i.e. the lateral sidewall lighted up by the LEDs <NUM>, and the central segment of the protruding perimeter rib or shoulder <NUM>, so that its lateral walls extend obliquely in front of the lateral sidewall <NUM> of light-guide plate <NUM> and can deflect /reflect the light coming from the lateral sidewall <NUM> towards the two end segments of the protruding perimeter rib or shoulder <NUM>.

Preferably, the reflecting lateral walls of the light-distributing recess <NUM> moreover are substantially perpendicular to the laying plane of the central flat sector of light-guide plate <NUM> and/or are substantially straight.

In greater detail, the light-distributing recess <NUM> is preferably substantially V-shaped and is preferably formed on the rear face of light-guide plate <NUM>, with the vertex of the V facing the lateral sidewall <NUM> of light-guide plate <NUM>, i.e. the lateral sidewall lighted up by the LEDs <NUM>, and with the two arms of the V facing each a respective end segment of the protruding perimeter rib or shoulder <NUM>.

The two lateral walls of the light-distributing recess <NUM> that converge towards the lateral sidewall <NUM> of light-guide plate <NUM>, i.e. towards the lateral sidewall lighted up by the LEDs <NUM>, hereinafter denoted by the numbers 14a and 14b, are interposed between the lateral sidewall <NUM> of the plate and the central segment of the protruding rib or shoulder <NUM> and are adapted to deflect/reflect the incident light towards the two sides of the light-guide plate <NUM> where the end segments of the protruding perimeter rib or shoulder <NUM> are located.

In addition, the reflecting lateral wall 14a is preferably substantially straight, whereas the reflecting lateral wall 14b preferably has a sawtooth profile.

In greater detail, the vertex of the V is preferably located close to the midpoint of the lateral sidewall <NUM> of light-guide plate <NUM>.

In the example shown, in particular, the light-distributing recess <NUM> preferably consists of a depression substantially polygonal in shape, and more specifically substantially triangular in shape, which is formed on the rear face of light-guide plate <NUM>, so that a first vertex of the triangle faces the light-entry lateral sidewall <NUM> of the plate, i.e. the lateral sidewall lighted up by the LEDs <NUM>, and that the two sides of the triangle converging towards the same first vertex face each a respective end segment of the protruding perimeter rib or shoulder <NUM>.

Preferably, the side of the triangle opposite said first vertex is moreover substantially parallel and opposite to the overlying central segment of the protruding perimeter rib or shoulder <NUM>.

Preferably, the light-distributing recess <NUM>, or rather the substantially triangular-shaped depression, moreover has a depth which is substantially constant and/or ranges between <NUM>% and <NUM>% of the local thickness s of the light-guide plate <NUM>.

Clearly, the light-distributing recess <NUM>, or rather the substantially triangular-shaped depression, could also be formed on the front face of light-guide plate <NUM>.

With reference to <FIG>, in addition, the edges of the rear face of light-guide plate <NUM> that are aligned with the various segments of the perimeter light-exit band, or rather with the various segments of the protruding perimeter rib or shoulder <NUM>, are preferably bevelled.

In addition, the edges of the rear face of light-guide plate <NUM> that are aligned with the various segments of the perimeter light-exit band, or rather with the various segments of the protruding perimeter rib or shoulder <NUM>, preferably also have, on the bevel, a series of reflecting surface structures, which are shaped so as to deflect, towards the top of the protruding perimeter shoulder <NUM>, the light rays r that propagates within the central flat sector of the light-guide plate <NUM> and reach the same reflecting surface structures.

In greater detail, the bevelled edges of the rear face of light-guide plate <NUM> preferably have, on the bevel, a multitude of small deflector prisms <NUM> which are shaped so as to deflect, by total internal reflection and towards the top of the protruding perimeter shoulder <NUM>, the light rays r that propagate within the central flat sector of light-guide plate <NUM> and reach the same deflector prisms <NUM>.

Moreover, the deflector prisms <NUM> are shaped so as to deflect the incident light rays r towards the top of the protruding perimeter rib or shoulder <NUM>, with an incidence angle such that the light can freely come out of the light-guide plate <NUM> along the entire crest/top of the protruding perimeter rib or shoulder <NUM>, and then reach the front half-shell <NUM>.

With reference to <FIG>, in addition, the light-guide plate <NUM> preferably also has, on the top of the protruding perimeter rib or shoulder <NUM>, an optics <NUM> preferably with pillow geometry, which is advantageously distributed in a substantially even manner over the entire top of the protruding perimeter rib or shoulder <NUM>, and is preferably shaped so as to diffuse/scatter the light rays coming out of the protruding perimeter shoulder <NUM>.

Clearly, the optics <NUM> could also be shaped so as to collimate the light rays coming out of the protruding perimeter shoulder <NUM> in a given direction that is preferably substantially perpendicular to the front face of the light-guide plate <NUM> and/or substantially parallel to the optical axis A of lighting assembly <NUM>.

With reference to <FIG> and <FIG>, the row of LEDs <NUM>, on the other hand, is preferably arranged astride of the laying plane of the central flat sector of light-guide plate <NUM>.

Preferably, the LEDs <NUM> are moreover arranged side by side to one another on a preferably oblong-shaped, platelike printed circuit <NUM> which is preferably located inside the rear body <NUM> locally substantially grazing the lateral sidewall <NUM> of light-guide plate <NUM>.

With reference to <FIG> and <FIG>, preferably the automotive light <NUM> additionally also includes a shielding mask <NUM> with a substantially rigid and opaque structure, which is preferably made of plastic material, preferably has a shape substantially complementary to the mouth of the rear body <NUM>, and is located inside the rear body <NUM> immediately beneath the front half-shell <NUM>.

The shielding mask <NUM> is provided with a pass-pass-through opening 6a that has a shape substantially complementary to that of the perimeter light-exit band of light-guide plate <NUM>, i.e. it's U-shape, and is aligned with the same perimeter light-exit band.

In greater detail, the pass-through opening 6a of the shielding mask <NUM> is adapted to be engaged by the protruding perimeter rib or shoulder <NUM> of the light-guide plate <NUM>.

With reference to <FIG> and <FIG>, preferably the second lighting assembly <NUM> in turn comprises: a filament or gas discharge lamp <NUM>, which is at least partially located inside the rear body <NUM>; and a concave reflector body <NUM> with a substantially rigid and opaque cup-like structure, which is preferably made of plastic material, is located within the rear body <NUM>, and is structured so as to surround at least the bulb of lamp <NUM>. The reflector body <NUM>, in addition, is provided with an inner reflecting surface that is shaped so as to direct the light emitted by the lamp <NUM> towards the corresponding and facing transparent or semi-transparent sector of the front half-shell <NUM>.

The shielding mask <NUM>, in turn, is preferably additionally provided with a second pass-through opening 6b, which is complementary in shape to the mouth of the reflector body <NUM> and is adapted to be stably engaged by the mouth of said reflector body <NUM>.

In a different embodiment, however, the concave reflector body <NUM> may be incorporated into the shielding mask <NUM>.

The general operation of automotive light <NUM> is easily inferable from the above description and requires no further explanation.

On the other hand, as regards operation of lighting assembly <NUM>, with reference to <FIG>, the light rays r emitted by the LEDs <NUM> enter the light-guide plate <NUM> via the lateral sidewall <NUM> of the same plate.

In the absence of the light-distributing recess <NUM>, all the light entering from the lateral sidewall <NUM> of light-guide plate <NUM> would be directed towards the central segment of the protruding perimeter rib or shoulder <NUM>, or rather towards the deflector prisms <NUM> located beneath the central segment of the protruding perimeter rib or shoulder <NUM>.

The light-distributing recess <NUM> modifies the propagation of the light in the light-guide plate <NUM>.

More in detail, since the light-distributing recess <NUM> does not take up the entire thickness of the light-guide plate <NUM>, the light rays r that propagate within the central flat sector of light-guide plate <NUM> and do not intersect the light-distributing recess <NUM>, directly reach the deflector prisms <NUM> located beneath the central segment of the protruding rib or shoulder <NUM> of light-guide plate <NUM>, and are there deflected towards the top of the central segment of the protruding perimeter rib or shoulder <NUM>.

The light rays r, in fact, strike the deflector prisms <NUM> with an incidence angle greater than the critical angle (also known as the limit angle) and are reflected by total internal reflection towards the top of the overlying central segment of the protruding rib or shoulder <NUM>.

The light rays r propagating within the central flat sector of light-guide plate <NUM> and striking the reflective lateral walls 14a and 14b of light-distributing recess <NUM>, on the other hand, are deflected/reflected towards the deflector prisms <NUM> located beneath the two opposite end segments of the protruding perimeter rib or shoulder <NUM>, and are there deflected/reflected towards the top of the same end segments of the protruding perimeter rib or shoulder <NUM>.

The light rays r reaching the lateral walls 14a and 14b of light-distributing recess <NUM>, in fact, strike the lateral walls 14a and 14b with an incidence angle greater than the critical angle (also known as the limit angle) and therefore undergo a total internal reflection.

In both cases, the light rays r reach the top of the protruding perimeter rib or shoulder <NUM> with an angle of incidence such that they can freely come out of the light-guide plate <NUM> and proceed towards the front half-shell <NUM>, thereby creating a substantially U-shaped luminous area.

The advantages connected to the particular structure of the lighting assembly <NUM> are noteworthy.

The lighting assembly <NUM> can backlight the front half-shell <NUM> creating a substantially U-shaped luminous area with the aid of a very small number of LEDs <NUM>, with the drastic reduction in production costs that this entails.

In addition, the lighting assembly <NUM> is particularly thin and compact and therefore can be accommodated inside a shallow rear body <NUM>.

It is finally clear that modifications and variations may be made to the automotive light <NUM> without however departing from the scope of the present invention.

For example, the perimeter light-exit band of light-guide plate <NUM> may also be substantially flush/coplanar with the front face of the same light-guide plate <NUM>.

In a not-shown embodiment variation, moreover, the light-distributing recess <NUM> may consist of a substantially V-shaped surface groove, which is formed on the front or rear face of the light-guide plate <NUM> and is oriented so that the vertex of the V faces the lateral sidewall <NUM> of the plate, i.e. the lateral sidewall lighted up by the LEDs <NUM>, and that the two arms of the V face each a respective end segment of the protruding perimeter shoulder <NUM>.

Clearly, the substantially V-shaped groove has a depth locally lower than the thickness s of light-guide plate <NUM>.

In addition, the LEDs <NUM> may be replaced by OLEDs (acronym for Organic Light Emitting Diode) or other electrically-powered light sources preferably of optoelectronic type.

With reference to <FIG> and <FIG>, in a different embodiment, moreover, the lighting assembly <NUM> can be also structured so as to backlight, on command, the facing transparent or semi-transparent sector of front half-shell <NUM>, creating a substantially L-shaped luminous area.

More in detail, in this embodiment the light-guide plate <NUM> is replaced by a light-guide plate <NUM> preferably having four main sides, which is provided with a substantially L-shaped, perimeter light-exit band that extends along the perimeter of the front face of the plate, adjacent solely to two consecutive and mutually inclined sides of the same light-guide plate <NUM>.

Even more in detail, two main and consecutive sides of the light-guide plate <NUM> are L-bent toward the front half-shell <NUM>, so as to form, along the perimeter of the front face of light-guide plate <NUM>, a long protruding rib or shoulder <NUM>, which is substantially L-shaped and extends cantilevered from the edge of the front face of light-guide plate <NUM>, towards the front half-shell <NUM>.

In other words, the protruding perimeter rib or shoulder <NUM> is longitudinally divided into two consecutive segments, which are substantially straight and inclined relative to each other.

The LEDs <NUM>, in turn, are located inside the rear body <NUM> so as to light up a first side of the light-guide plate <NUM> opposite one of the segments of the protruding perimeter rib or shoulder <NUM>.

In other words, similarly to the first embodiment, the light produced by the LEDs <NUM> enters the light-guide plate <NUM> via a lateral sidewall <NUM> of the plate opposite one of the two segments of the protruding perimeter rib or shoulder <NUM>.

In addition, the light-guide plate <NUM> has, on one of its two larger faces, a large light-distributing recess <NUM> of given shape, which has a depth less than the thickness s of the light-guide plate <NUM> and is shaped so as to distribute the light coming from the lateral sidewall <NUM> of light-guide plate <NUM> in a predetermined and controlled manner along the whole length of the protruding perimeter rib or shoulder <NUM>.

Also in this embodiment, therefore, once it has entered the light-guide plate <NUM> via the lateral sidewall <NUM> of the plate, the light emitted by the LEDs <NUM> propagates within the body of the light-guide plate <NUM> by total internal reflection, up to reach the crest or top of the protruding perimeter shoulder or rib <NUM> from where it comes out freely, directed towards the front half-shell <NUM>.

In greater detail, with reference to <FIG>, the light-distributing recess <NUM> is interposed between the lateral sidewall <NUM> of light-guide plate <NUM>, i.e. the lateral sidewall lighted up by the LEDs <NUM>, and one of the two segments of the protruding perimeter rib or shoulder <NUM>, and its lateral wall facing the lateral sidewall <NUM> of light-guide plate <NUM> is adapted to deflect/reflect the incident light towards the other segment of the protruding rib or shoulder <NUM>.

In other words, the reflecting lateral wall 114a of the light-distributing recess <NUM> extends over the rear face of light-guide plate <NUM> along a straight line which roughly connects the elbow of the L-shaped protruding perimeter rib or shoulder <NUM> with the opposite end/vertex of the lateral sidewall <NUM> of light-guide plate <NUM>. Preferably, the reflecting lateral wall 114a of the light-distributing recess <NUM> is moreover substantially straight.

In the example shown in <FIG>, in particular, the light-distributing recess <NUM> preferably consists of a substantially triangular-shaped depression, which is formed on the rear face of light-guide plate <NUM> so that a first vertex of the triangle is located close to one of the ends/vertices of the lateral sidewall <NUM> of light-guide plate <NUM>, and so that one of the two sides of the triangle converging towards the same first vertex extends obliquely in front of the lateral sidewall <NUM> of light-guide plate <NUM>.

Alternatively, the light-distributing recess <NUM> may consist of a substantially straight surface groove, which has a depth less than the thickness s of the light-guide plate <NUM> and extends obliquely in front of the lateral sidewall <NUM> of light-guide plate <NUM>.

Also in this embodiment, the edges of the rear face of light-guide plate <NUM> that are aligned to the two segments of the protruding perimeter rib or shoulder <NUM>, are preferably bevelled and are preferably provided, on the bevel, with a multitude of small deflector prisms <NUM> or other reflecting surface structures that are shaped so as to deflect, towards the top of the protruding perimeter shoulder <NUM>, the light rays r propagating inside the central flat sector of light-guide plate <NUM> and reaching the same deflector prisms <NUM>.

Also the light-guide plate <NUM>, moreover, is preferably provided, on the top of the L-shaped protruding rib or shoulder <NUM>, with an optics <NUM> preferably with pillow geometry, which is advantageously distributed in a substantially even manner over the entire top of the protruding perimeter rib or shoulder <NUM>, and is preferably shaped so as to diffuse/scatter the light rays coming out of the protruding perimeter shoulder <NUM>.

Clearly, also in this case, the optics <NUM> may be shaped so as to collimate the light rays coming out of the protruding perimeter shoulder <NUM> in a given direction that is preferably substantially perpendicular to the front face of light-guide plate <NUM> and/or substantially parallel to the optical axis A of lighting assembly <NUM>.

With reference to <FIG>, as an alternative, the light-distributing recess <NUM> may be formed by a succession of small straight grooves, which have a depth less than the thickness s of the light-guide plate <NUM> and extend over the rear face of the light-guide plate <NUM> spaced one after the other, aligned along the straight line connecting the elbow of the L-shaped protruding perimeter rib or shoulder <NUM> with the opposite end/vertex of the lateral sidewall <NUM> of light-guide plate <NUM>.

Preferably, said straight grooves are additionally staggered and partially superimposed on each other so as to form a sawtooth profile.

With reference to <FIG>, in a more sophisticated embodiment, lastly, the lighting assembly <NUM> can also be structured so as to backlight, on command, the facing transparent or semi-transparent sector of the front half-shell <NUM>, creating a substantially E-shaped luminous area.

More in detail, the lighting assembly <NUM> includes a light-guide plate <NUM> and a light-guide plate <NUM> arranged adjacent and substantially coplanar to each other, so that one of the two straight segments of the protruding perimeter rib or shoulder <NUM> is aligned and adjacent to the central straight segment of the protruding perimeter rib or shoulder <NUM>, thereby forming a substantially E-shaped protruding rib.

In other words, the light-guide plate <NUM> and the light-guide plate <NUM> are arranged adjacent and substantially coplanar to each other, so that one of the two straight segments of the L-shaped perimeter light-exit band is aligned with and adjacent to the central straight segment of the U-shaped perimeter light-exit band, thereby forming a substantially E-shaped perimeter light-exit band.

Claim 1:
An automotive light (<NUM>) comprising: a rear body (<NUM>) adapted to be fixed to the vehicle; a front half-shell (<NUM>) arranged to close the mouth of said rear body (<NUM>); and at least one lighting assembly (<NUM>) that is located inside the rear body (<NUM>) and is adapted to backlight a corresponding transparent or semi-transparent sector of the front half-shell (<NUM>);
said lighting assembly (<NUM>) comprising: at least one light-guide plate (<NUM>, <NUM>) of suitable thickness, which is made of photoconductive material; and a set of electrically -powered light sources (<NUM>) that are located close to a first side of the light-guide plate (<NUM>, <NUM>) and direct the light produced into the body of the same light-guide plate (<NUM>, <NUM>) via a facing first lateral sidewall (<NUM>, <NUM>) of the same plate so that said light propagates within the body of the light-guide plate (<NUM>, <NUM>) by total internal reflection;
wherein said light-guide plate (<NUM>, <NUM>) is located inside the rear body (<NUM>) with a first face facing the front half-shell (<NUM>) and a second face facing the bottom of the rear body (<NUM>);
wherein said light-guide plate (<NUM>, <NUM>) has a perimeter light-exit band (<NUM>, <NUM>) extending along the perimeter of the first face of the light-guide plate (<NUM>, <NUM>), for at least two consecutive sides of the same light-guide plate (<NUM>, <NUM>), and is structured so as to cause the light to come out of the same light-guide plate (<NUM>, <NUM>);
wherein the first lateral sidewall (<NUM>, <NUM>) of said light-guide plate (<NUM>, <NUM>) is opposite to a first segment of said perimeter light-exit band (<NUM>, <NUM>); said automotive light being characterized in that said light-guide plate (<NUM>, <NUM>) also has, on its first or second face, a light-distributing recess (<NUM>, <NUM>) of given shape, which has a depth less than the local thickness (s) of the light-guide plate (<NUM>, <NUM>), is interposed between said first lateral sidewall (<NUM>, <NUM>) and said first segment of the perimeter light-exit band (<NUM>, <NUM>), and is shaped so as to distribute part of the light coming from the first lateral sidewall (<NUM>, <NUM>) of the light-guide plate (<NUM>, <NUM>) substantially along the whole length of said perimeter light-exit band (<NUM>, <NUM>).