ITPD20100331A1 - LIGHT EMITTER DEVICE. - Google Patents

Description

LIGHT EMITTER DEVICE

Field of application

The present invention relates to a light emitting device, according to the preamble of the independent claim.

The light emitting device in question is intended to be advantageously used to point out to overhead vehicles the presence of high-height structures, such as chimneys, towers, skyscrapers, bridges, pylons of power lines, etc.

The light emitting device in question can also be used advantageously for the lighting of internal environments such as houses, offices, cinemas, clubs, etc., and external environments such as streets, squares, car parks, parks, gardens, etc. .

More in detail, the light emitting device in question is part of the industrial sector of the production of light indicators and lighting devices equipped with LED light sources.

State of the art

As is well known, the use of light emitting devices equipped with LED light sources is widespread, since the latter demonstrate greater luminous efficiency than most traditional light sources (such as lamps with incandescence, fluorescent lamps, discharge lamps). A known type of light emitting device equipped with LED light sources is, for example, the obstacle light indicator described in the DE 20311169 patent. This light indicator comprises a horizontal support base on which a plurality of LEDs are mounted. facing upwards and arranged around a central reflection body substantially in the shape of a funnel. This reflection body is equipped with a reflection surface which develops above the LEDs and has a concavity facing the outside of the device to reflect the light emitted vertically by the LEDs horizontally, generating a beam of light that is distributed at 360 ° around the device.

Furthermore, the aforementioned light is equipped with a heat sink, fixed under the support base of the LEDs and able to transfer the heat generated by the LEDs during their operation to the external environment. More in detail, the heat sink comprises a metal plate, fixed under the support base of the LEDs, from which a plurality of parallel plate-like fins develop.

The light indicator of the known type described above also comprises an electronic unit for controlling the operation of the LEDs, arranged in a suitable seat obtained inside the heat sink.

This indicator light has proved to be not free from drawbacks in practice. The main drawback of the light briefly described above is linked to the fact that the electronic unit seat is located inside the heat sink. This solution does not allow the heat sink to efficiently dispose of the heat with a consequent increase in the temperature of the LEDs which causes a drop in efficiency and a significant reduction in the average life of the LEDs themselves.

A further drawback is due to the fact that the construction of the electronic unit seat in the heat sink implies a high constructive complexity of the device with consequent high design and construction costs.

Presentation of the invention

In this situation, the essential aim of the present invention is therefore to obviate the drawbacks manifested by known solutions, by providing a light emitting device capable of efficiently disposing of the heat generated by the LEDs.

A further object of the present invention is to provide a light emitting device of particularly compact dimensions.

A further object of the present invention is to provide a light emitting device which is constructively simple and economical to produce.

Brief description of the drawings

The technical characteristics of the invention, according to the aforementioned purposes, are clearly verifiable from the content of the claims reported below and the advantages thereof will become more evident from the detailed description that follows, made with reference to the accompanying drawings, which represent two purely exemplary embodiments and non-limiting, in which:

Figure 1 shows a side perspective view of the light emitting device object of the present invention in accordance with a first embodiment of the invention;

- figure 2 shows a sectional view of the light emitting device illustrated in figure 1 according to trace II - II of the same figure 1;

- figure 3 shows a further sectional view of the light emitting device illustrated in figure 1 along the line III - III of the same figure 1;

- Figure 4 shows a schematic plan view of the light emitting device object of the present invention with some parts removed to better highlight others;

Figure 5 shows a sectional view of the light emitting device object of the present invention in accordance with a second embodiment of the invention.

Detailed description of a preferred embodiment example

With reference to the accompanying drawings, the light emitting device object of the present invention has been indicated as a whole with 1.

More in detail, figures 1 - 4 illustrate a first embodiment of the light emitting device 1 in question relating to a light indicator intended to be advantageously mounted on high buildings (such as skyscrapers, towers, etc.) or on elevated structures (such as bridges, pylons, chimneys, etc.) to signal the presence of aerial obstacles to vehicles such as airplanes and helicopters.

Figure 5 illustrates a second embodiment of the light emitting device 1 in question relating to a lighting device intended to be used to illuminate internal environments (such as houses, offices, cinemas, premises, etc.), or external environments (such as streets , squares, car parks, parks, gardens, etc.).

With reference to both embodiments illustrated in the attached figures, the light emitting device 1 comprises a support body 2, which has a centrally fixed reflecting body 3. More LEDs 4â € ™, 4â € ™ â € ™ are also fixed on the support body 2 around the reflector body 3.

The light emitting device 1 comprises an electronic unit 5 connected to the LEDs 4â € ™, 4â € ™ â € ™ by means of electrical connection 6 and able to control the operation of the LEDs 4â € ™, 4â € ™ â € ™ themselves, preferably in accordance with programmed operating procedures.

In accordance with the idea underlying the present invention, the reflecting body 3 of the light emitting device 1 is equipped with an internal cavity 7 in which the electronic unit 5 is at least partially housed.

In accordance with the embodiments illustrated in the attached figures, the support body 2 of the light emitting device 1 is made of metal, preferably aluminum by means of a die-casting process, and comprises a disc-shaped portion 60 equipped with a first face 8 , on which the reflecting body 3 and the LEDs 4â € ™, 4â € ™ â € ™ are positioned, and of a second face 9 parallel to the first 8 and facing in the opposite direction to the latter.

The reflecting body 3 has a substantially preferably frusto-conical shape, and develops between its own first end edge 10, in correspondence with which it is fixed to the first face 8 of the discoidal portion 60 of the support body 2, and its own second edge of end 11 larger than the first edge of end 10.

More in detail, the reflecting body 3 is equipped with a side wall 13 which extends between the first and the second end edge 10, 11 of the reflecting body 3 itself, and preferably develops around a central axis X orthogonal to the first face 8 of the discoidal portion 60 of the support body 2.

Furthermore, the reflecting body 3 is preferably provided with a base wall 12 fixed on its first end edge 10 and preferably made in a single body with the side wall 13.

The base wall 12 and the side wall 13 of the reflecting body 3 delimit the internal cavity 7 of the latter, which houses the electronic unit 5 that controls the operation of the LEDs 4â € ™, 4â € ™ â € ™.

Advantageously, the side wall 13 of the reflecting body 3 is provided with an external surface 14 which develops around the central axis X with a generating section of concave shape, in particular parabolic.

Preferably, the generating section of the external surface 14 of the reflecting body 3 has a linear trend in sections which approximates the shape of a conic, in particular of a parabola.

In accordance with the embodiments illustrated in the attached figures, the LEDs 4â € ™, 4â € ™ â € ™ are preferably positioned around the reflecting body 3 substantially along a common positioning line, preferably circular in shape with center on the axis central X. In particular, the positioning line of the LEDs 4â € ™, 4â € ™ â € ™ coincides with the line of focus of the external surface 14 of the reflecting body 3.

More in detail, each LED 4â € ™, 4â € ™ â € ™ is equipped with its own light emission axis Y, which is substantially parallel to the central axis X and intersects the external surface 14 of the body of reflection 3. Functionally, each LED 4â € ™, 4â € ™ â € ™ emits first beams of light rays, in particular with a light emission cone of about 120 °, on the external surface 14 of the reflecting body 3, which it reflects them with second beams of light rays propagating mainly along directions of propagation of light Z orthogonal to the central axis X.

In accordance with the embodiments illustrated in the attached figures, the LEDs 4â € ™, 4â € ™ â € ™ include first LEDs 4â € ™ (for example four) connected together in series, and second LEDs 4â € ™ â € ™ ( for example four) connected to each other in series, with the first LEDs 4â € ™ positioned alternating with the second LEDs 4â € ™ â € ™ along their positioning line around the reflecting body 3.

Advantageously, the electrical connection means 6, which connect the electronic unit 5 to the LEDs 4 ', 4', comprise a power supply circuit 15 of the LEDs 4 ', 4' provided on the first face 8 of the disc-shaped portion 60 of the support body 2, and comprise electrical connection cables 33 which connect the power supply circuit 15 to the electronic unit 5.

Preferably, the power supply circuit 15 is constituted by a first printed circuit 20, on which metal tracks 18, 19 are made to connect the LEDs 4â € ™, 4â € ™ â € ™ to the electrical connection cables 33 coming from the ™ electronic unit 5.

More in detail, the first printed circuit 20 is equipped with a third face 16 fixed above the first face 8 by the discoidal portion 60 of the support body 2, and with a fourth face 17 on which the LEDs 4â € ™, 4â are mounted € ™ â € ™ and on which the aforementioned metal tracks 18, 19 are made.

In particular, with reference to the embodiment illustrated in figure 4, on the fourth face 17 of the first printed circuit 20 there is a first metal track 18 which connects in series the first LEDs 4â € ™ and develops in a ring around the axis central X near the peripheral contour 21 of the first printed circuit 20 between a pair of first terminals 22â € ™, 22â € ™ â € ™ (one positive and one negative). In addition, a second metal track 19 is provided that connects the second LEDs 4â € ™ â € ™ in series and develops in a ring around the central X axis between a pair of terminal seconds 23â € ™, 23â € ™ â € ™ (one positive and one negative). In particular, the second metal track 19 is arranged inside a first area of the fourth face 17 of the first printed circuit 20 delimits from the first metal track 18.

Preferably, the first printed circuit 20 is of the IMS (Insulated Metal Substrates) type and comprises a first support layer made of metallic material, in particular aluminum, provided on the first face 8 of the disc-shaped portion 60 of the support body 2, a second intermediate layer of dielectric and thermally conductive material (in particular of epoxy resin) provided above the first layer, and a third copper layer on which the metal tracks 18, 19 are formed and placed above the second intermediate layer.

Advantageously, on the fourth face 17 of the first printed circuit 20, on which the LEDs 4â € ™, 4â € ™ â € ™ are mounted, there is at least one metal foil 24, 25 thermally coupled to the LEDs 4â € ™, 4â € ™ â € ™ to receive the heat generated by the LEDs 4â € ™, 4â € ™ â € ™ and to transmit it to the support body 2, as described in detail below.

More in detail, there is a first metal sheet 24 thermally coupled to the first LEDs 4â € ™ and extending between the first metal track 18 and the second metal track 19, and a second metal sheet 25 thermally coupled to the second LEDs 4â € ™ â And extending inside a second area of the fourth face 17 of the first printed circuit 20 delimited by the second metal track 19.

Preferably, each first and second LED 4â € ™, 4â € ™ â € ™ is fixed respectively to its own second and third printed circuit, which are in turn fixed on the fourth face 17 of the first printed circuit 20 and are electrically connected respectively to the first and second metal track 18, 19. In particular, on the second printed circuit of each first LED 4â € ™ first metallized holes are made under the first LED 4â € ™ and placed in contact with the first metal sheet 24 to transmit to the latter the heat generated by the first LED 4â € ™. Similarly, on the third printed circuit of each second LED 4â € ™ â € ™ second metallized holes are made under the second LED 4â € ™ â € ™ and placed in contact with the second metal sheet 25 to transmit heat to the latter. generated by the second LED 4â € ™ â € ™.

The heat generated by the LEDs 4â € ™, 4â € ™ â € ™ is transmitted by the metal foils 24, 25, through the second thermally conductive intermediate layer of the first printed circuit 20, to the first support layer of the first printed circuit 20, which in turn it transmits the heat by conduction to the supporting body 2.

Advantageously, the light emitting device 1 comprises thermal dissipation means 26 fixed on the second face 9 of the disc-shaped portion 60 of the support body 2 and capable of receiving by conduction from the support body 2 the heat generated by the LEDs 4â € ™, 4â € ™ â € ™ to transmit it to the external air to the light emitting device 1. More in detail, the heat dissipation means 26 comprise a plurality of elongated metal parts 27, which protrude from the second face 9 of the discoidal portion 60 of the support body 2 orthogonally to said second face 9, and are preferably made in a single body with the disc-shaped portion 60 of the support body 2.

Advantageously, the light emitting device 1 comprises at least one electric power supply cable 28, which passes through the internal cavity 7 of the reflecting body 3 and is connected, at one end, to the electronic unit 5 to connect this Last to a source of electric power (not shown) connected to the other end of the electric power cable 28. In particular, the electric power cable 28 enters the internal cavity 7 of the reflecting body 3 through a first opening 30â € ™ obtained on the base wall 12 of the reflecting body 3.

Advantageously, the electric power supply cable 28 passes through a first channel 29 obtained in the support body 2 and communicating with the internal cavity 7 of the reflecting body 3 through the aforementioned first opening 30â € ™ obtained on the base wall 12 of the reflecting body 3.

Preferably, with reference to the embodiment illustrated in Figures 3 and 4, the first printed circuit 20, on which the LEDs 4 ', 4', are mounted, is equipped with a first through hole 35 'aligned with the first opening 30 'obtained on the base wall 12 of the reflecting body 3 to allow the passage of the electric power cable 28. In accordance with the embodiment illustrated in figure 3, the first channel 29 is mainly obtained at the inside of a central portion 31 of the support body 2 protruding from the second face 9 of the discoidal portion 60 of the support body 2 itself along the central axis X of the light emitting device 1. In particular, the first channel 29 comprises a first section 29 'coaxial to the central axis X, inside which a tightly sealed cable gland 32 is inserted around the electric power cable 28 to seal the first channel 29 preventing infiltration of water, humidity, etc. Furthermore, the first channel 29 is equipped with a second section 29â € ™ â € ™ extending from the first section 29â € ™ laterally with respect to the central axis X until it opens onto the first face 8 of the disc-shaped portion 60 of the support body 2 in correspondence with the first opening 30â € ™ of the base wall 12 of the reflection body 3 and the first through hole 35â € ™ obtained on the first printed circuit 20.

The electrical connection cables 33 of the electrical connection means 6, which connect the electronic unit 5 to the LEDs 4â € ™, 4â € ™ â € ™, pass through the internal cavity 7 of the reflecting body 3 and exit from the internal cavity 7 through a second opening 30â € ™ â € ™ obtained on the base wall 12 of the reflecting body 3.

Advantageously, the electric connection cables 33 pass inside a second channel 34 obtained on the first face 8 of the disc-shaped portion 60 of the support body 2 and communicating with the internal cavity 7 of the reflecting body 3 through the second opening 30â € ™ â € ™ obtained on the base wall 12 of the reflecting body 3. More in detail, in accordance with the embodiments illustrated in the attached figures, the second channel 34 is obtained by means of a groove obtained on the first face 8 of the discoidal portion 60 support body 2.

Preferably, with reference to the embodiment illustrated in Figures 2 and 4, the first printed circuit 20, on which the LEDs 4â € ™, 4â € ™ â € ™ are mounted, is equipped with a second through hole 35â € ™ â € ™ aligned with the second opening 30â € ™ â € ™ obtained on the base wall 12 of the reflecting body 3 to allow the passage of the electrical connection cables 33.

Again with reference to the embodiment illustrated in Figures 2 and 4, in which the light emitting device 1 is positioned with the support body 2 facing downwards, the second channel 34 extends with a third initial portion 34 ' (indicated dashed in figure 4) under the first printed circuit 20, and with a fourth terminal portion 34 of it beyond the peripheral contour 21 of the first printed circuit 20. In this way, the electrical connection cables 33 reach the terminals 22â € ™, 22â € ™ â € ™, 23â € ™, 23â € ™ of the metal tracks 18, 19 made on the first printed circuit 20 passing under the latter, and therefore without hindering the propagation of the first beams of rays light emitted by the LEDs 4â € ™, 4â € ™ â € ™ and the second beams of light rays coming from the external surface 14 of the reflecting body 3.

Preferably, the electrical connection cables 33 of the electrical connection means 6 are intercepted by an electrical terminal 36 housed in the internal cavity 7 of the reflecting body 3.

Preferably, the electrical connection means 6 comprise a first pair of electrical connection cables (phase and neutral) which connect the electronic unit 5 to the first terminals 22â € ™, 22â € ™ â € ™ of the first metal track 18 of the first LED 4â € ™, and a second pair of electrical connection cables (phase and neutral) that connect the electronic unit 5 to the second terminals 23â € ™, 23â € ™ â € ™ of the second metal track 19 of the second LED 4â € ™ â € ™. Functionally, the electronic unit 5 enables the passage of current through the first pair or through the second pair of electrical connection cables to activate the first LEDs 4â € ™ or the second LEDs 4â € ™ â € ™. Advantageously, the second LEDs 4â € ™ â € ™ are kept off during the regular operation of the first LEDs 4â € ™, and are activated by the electronic unit 5 in the event that one or more first LEDs 4â € ™ fail, allowing light emitting device 1 to continue to function properly.

Otherwise, the electronic unit can control the activation of all LEDs 4â € ™, 4â € ™ at the same time to allow the light emitting device 1 to emit a particularly intense light.

Advantageously, the electronic unit 5, which controls the operation of the LEDs 4â € ™, 4â € ™ â € ™, comprises an electronic board 37 mounted in correspondence with the second end edge 11 (larger) of the reflecting body 3 .

More in detail, with reference to the embodiment illustrated in Figure 3, the electronic board 37 comprises a fourth printed circuit 61, which is equipped with a fifth face 38, facing the internal cavity 7 of the reflecting body 3, and of a sixth face 39 parallel to the fifth 38 and facing the outside of the reflecting body 3.

The electronic board 37, moreover, comprises electronic components 40 preferably fixed on the fifth face 38 of the aforementioned fourth printed circuit 61 and powered by the electric power supply cable 28. In particular, the electronic components 40 comprise a CPU, which is programmed to control operation of the LEDs 4â € ™, 4â € ™ â € ™ by means of a current controller module connected to the electrical connection cables 33 which connect the electronic unit 5 to the power supply circuit 15 of the LEDs 4â € ™, 4â € ™ â € ™.

Preferably, a brightness sensor 41 is provided, which is fixed to the fourth printed circuit 61 of the electronic board 37 and is electrically connected to the CPU of the electronic unit 5 to signal the intensity of the ambient light and consequently control the activation or not of the light emitting device 1.

More in detail, with reference to the embodiment illustrated in Figure 3, the brightness sensor 41 is fixed on the fifth face 38 of the fourth printed circuit 61, facing the internal cavity 7 of the reflecting body 3, in correspondence with a third hole loop 42 obtained on the fourth printed circuit 61 itself to allow the ambient light to reach the brightness sensor 41.

Advantageously, the electronic card 37 of the electronic unit 5 is fixed to the reflecting body 3 by means of first fixing means 43, which comprise a tie rod 44 connected between the support body 2 and the electronic card 37 to retain this last on the second end edge 11 of the reflecting body 3 and to hold the reflecting body 3 fixed to the supporting body 2.

With reference to the embodiment illustrated in Figure 3, the tie rod 44 of the first fixing means 43 comprises a threaded rod 45 which is mechanically fixed, to its own first terminal part 46, to the electronic board 37, and is mechanically fixed, to its own second end part 47, to the support body 2.

More in detail, the threaded rod 45 is screwed to its second end part 47 in a corresponding fourth threaded hole 48 obtained on the first face 8 of the disc-shaped portion 60 of the support body 2, and is inserted with its first part terminal 46 in a corresponding fifth through hole 49 obtained on the electronic board 37. Furthermore, the first fixing means 43 comprise a first nut 50, which is screwed to the threaded rod 45 in correspondence with its first terminal part 46 and acts on the sixth face 39 of the fourth printed circuit 61 of the electronic board 37 (facing towards the outside of the reflecting body 3), and a first lock nut 62, which acts on the fifth face 38 of the fourth printed circuit 61 to hold the electronic board 37 fixed to the reflector body 3.

Preferably, the first fixing means 43 comprise a second lock nut 51 screwed to the threaded rod 45 at its second end part 47 and acting on the internal face of the base wall 12 of the reflecting body 3.

In accordance with the embodiments illustrated in the attached figures, the reflecting body 3 rests with its base wall 12 on a central part of the first printed circuit 20 on which the LEDs 4â € ™, 4â € ™ â € ™ are mounted. The first printed circuit 20 is equipped in correspondence with this central part with a sixth through hole 52 aligned with the fourth threaded hole 48 obtained on the first face 8 of the disc-shaped portion 60 of the support body 2 and crossed by the threaded rod 45 of the first fastening means 43.

Advantageously, the first printed circuit 20 on which the LEDs 4â € ™, 4â € ™ â € ™ are mounted is fixed to the first face 8 of the disc-shaped portion 60 of the support body 2 by means of second fixing means, which comprise several screws 53 screwed into corresponding seventh threaded holes 54 obtained on the first face 8 of the disc-shaped portion 60 and aligned with corresponding eighth through holes 55 obtained on the printed circuit 20 itself. In particular, with reference to the embodiment illustrated in Figure 2, the seventh threaded holes 54 partially extend into the corresponding elongated metal parts 27 of the heat dissipation means 26 which protrude from the second face 9 of the disc-shaped portion 60 of the support body 2.

In accordance with the embodiments illustrated in the attached figures, the light emitting device 1 comprises a closing cap 56, which is fixed resting on the first face 8 of the discoidal portion 60 of the support body 2 defining with the latter a sealed chamber 57 which houses the LEDs 4â € ™, 4â € ™ â € ™ and the reflecting body 3 with the electronic unit 5.

More in detail, with reference to Figure 3, the cap 56 is made of transparent material, preferably of Plexiglas, and is equipped with an enlarged base 58, preferably circular in shape, which rests on the first face 8 of the disc-shaped portion 60 of the support body 2 at a peripheral edge of the latter.

Preferably, the enlarged base 58 of the cap 56 is fixed to the first face 8 of the discoidal portion 60 of the support body 2 by means of an adhesive glue interposed between the latter and the enlarged base 58 of the cap 56 itself.

In accordance with the second embodiment of the light emitting device 1 illustrated in figure 5 and relating to a lighting device, the light emitting device 1 comprises a reflecting bell 59 fixed to the support body 2 and extending around the first body of reflection 3 to intercept the second beams of light rays coming from the external surface 14 of the first reflecting body 3 itself. Functionally, the reflection bell 59 reflects the second beams of light rays coming from the external surface 14 of the reflecting body 3 with third beams of light rays turned towards the environment to be illuminated. In particular, in the second embodiment illustrated in Figure 5, the light emitting device 1 is positioned with the concavity of the reflection bell 59 facing downwards to illuminate, for example, the floor of a room.

The invention thus conceived therefore achieves the intended aim and objects.

Obviously, in its practical implementation, it may also assume forms and configurations other than those illustrated above, without thereby departing from the present scope of protection. Furthermore, all the details may be replaced by technically equivalent elements and the shapes, dimensions and materials used may be any according to requirements.

Claims (10)

CLAIMS 1. Light emitting device (1), which comprises: ∠’a support body (2); ∠’a reflection body (3) which is fixed to said support body (2); ∠’several LEDs (4â € ™, 4â € ™ â € ™) fixed to said support body (2) and positioned around said reflection body (3); ∠’at least one electronic unit (5) connected to said LEDs (4â € ™, 4â € ™ â € ™) by means of electrical connection (6) to control its operation; said light emitting device (1) being characterized in that: â ’said reflection body (3) is equipped with an internal cavity (7); â ’said at least one electronic unit (5) is housed at least partially in said at least one internal cavity (7). 2. Light emitting device (1) according to claim 1, characterized in that said reflection body (3) develops between its own first end edge (10), in correspondence with which it is fixed to said support body (2), and a proper second end edge (11) larger than said first end edge (10); said electronic unit (5) comprising at least one electronic card (37) mounted in correspondence with the second end edge (11) of said reflecting body (3). 3. Light emitting device (1) according to claim 2, characterized in that said reflecting body (3) is provided with at least one base wall (12) fixed on the first end edge (10) of said reflecting body reflection (3); said light emitting device (1) comprising at least one electric power cable (28), which is connected to said electronic unit (5) and enters the internal cavity (7) of said reflecting body (3) through at least one opening (30â € ™, 30â € ™ â € ™) obtained on the base wall (12) of said reflection body (3). 4. Light emitting device (1) according to claim 3, characterized in that said electrical connection means (6) comprise electrical connection cables (33), which pass through the internal cavity (7) of said reflecting body (3), and exit from the internal cavity (7) of said reflection body (3) through said at least one opening (30â € ™, 30â € ™ â € ™). 5. Light emitting device (1) according to claim 3, characterized in that said at least one electric power cable (28) passes through a first channel (29) obtained in said support body (2) and communicates with said cavity internal (7) through said at least one opening (30â € ™, 30â € ™ â € ™) made on the base wall (12) of said reflection body (3). 6. Light emitting device (1) according to claim 4, characterized in that the electrical connection cables (33) of said electrical connection means (6) pass through a second channel (34), which is obtained on a first face (8) of said support body (2), on which said LEDs (4â € ™, 4â € ™ â € ™) are positioned, and is connected with the internal cavity (7) of said reflection body (3) by means of said at least one opening (30â € ™, 30â € ™ â € ™) made on the base wall (12) of said reflection body (3). 7. Light emitting device (1) according to claim 4, characterized in that the electrical connection cables (33) of said electrical connection means (6) are intercepted by at least one electrical terminal (36) housed in the internal cavity ( 7) of said reflection body (3). 8. Light emitting device (1) according to claim 6, characterized in that it comprises thermal dissipation means (26) fixed on a second face (9) thereof of said support body (2), substantially parallel to said first face (8) and turned in the opposite direction to the latter. 9. Light emitting device (1) according to claim 2, characterized in that said electronic board (37) is fixed to said reflecting body (3) by means of first fixing means (43), which comprise at least one tie rod (44) connected between said support body (2) and said electronic card (37) to hold the latter on the second end edge (11) of said reflection body (3). 10. Light emitting device (1) according to claim 6, characterized in that said electrical connection means (6) comprise a first printed circuit (20) fixed to said support body (2), and equipped with a third face (16) fixed above the first face (8) of said support body (2), and of a fourth face (17) on which said LEDs (4â € ™, 4â € ™ â € ™) are mounted; on the fourth face (17) of said first printed circuit (20) there being at least one metal sheet (24, 25) thermally coupled to said LEDs (4â € ™, 4â € ™ â € ™).