Lighting device for explosive atmospheres

Abstract

The LED lighting device for explosive atmospheres has an optical chamber accommodating an optical system, at least one LED mounted on a printed circuit board, a lens covering the printed circuit board, and a control chamber accommodating a supply device of the printed circuit board and control device of the supply device. The optical chamber and the control chamber extend within a closed enclosure to withstand any impacts coming from the environment outside the lighting device or coming from the optical chamber and/or the control chamber. The lens of the optical system is defined by a silicone lens that is an integral part of the enclosure.

Claims

1. A light emitting diode (LED) lighting device for explosive atmospheres, having an optical chamber accommodating an optical system comprising: at least one LED mounted on a printed circuit board and a lens covering said printed circuit board, as well as a control chamber accommodating supply means of the printed circuit board and control means of the supply means, said optical chamber and said control chamber extending within a closed enclosure to withstand any impacts coming from the environment outside the lighting device or coming from the optical chamber and/or the control chamber, wherein said lens of the optical system is defined by a silicone lens that is an integral part of said enclosure.

2. The device according to claim 1, wherein the enclosure comprises a metal profile molded to have a first cavity where the optical chamber extends, and a second cavity where the control chamber extends, said silicone lens being connected to said profile so as to close said optical chamber.

3. The device according to claim 2, wherein said enclosure further comprises at least one cover connected to the metal profile so as to close said control chamber.

4. The device according to claim 2, wherein the metal profile comprises two side wings between which the control chamber extends, connected to one another by a bottom wall, a portion of which recessed toward the control chamber defines said first cavity.

5. The device according to claim 4, wherein the recessed portion comprises an inner face and an outer face having a central area, against which said printed circuit board is fastened, said central area being bordered by two grooves molded to receive tabs of complementary shape included by said silicone lens covering said printed circuit board.

6. The device according to claim 5, wherein the silicone lens is secured to said metal profile using a metal frame nested in the recessed portion and molded to overlap the tabs of the silicone lens accommodated in said grooves and side areas of the outer face of the recessed portion.

7. The device according to claim 6, wherein the space comprised between the tabs of the silicone lens and said metal frame is filled in using a sealing joint.

8. The device according to claim 7, wherein the sealing joint is comprised of a silicone glue.

9. The device according to claim 6, wherein the metal profile and the metal frame comprised of aluminum and are assembled using screws.

10. The device according to claim 5, wherein the inner face of the recessed portion is molded so as to define means for cooling the printed circuit board.

Description

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

(1) The advantages resulting from the present invention will appear upon reading the following description relative to an exemplary embodiment illustrated in the attached drawings.

(2) FIG. 1 illustrates a cross-sectional view of a lighting device according to the invention.

(3) FIG. 2 illustrates an enlarged view of the optical chamber of the device shown in FIG. 1.

DETAILED DESCRIPTION OF THE INVENTION

(4) As shown in FIG. 1, the present invention relates to an LED lighting device 1 for explosive atmospheres, conventionally having an optical chamber 2 housing an optical system comprising a plurality of LEDs 3 mounted on a printed circuit board 4 and a lens 5 covering the printed circuit board 4, as well as a control chamber 6 accommodating a housing 7 incorporating supply means of the printed circuit board 4 and control means of the supply means.

(5) As illustrated in FIG. 1, the optical chamber 2 and the control chamber 6 are delimited by a closed enclosure 8, the structure of which is specifically studied on the one hand to withstand any impacts that may come from the environment outside the lighting device 1 and on the other hand to allow the retention within the lighting device 1 of any spark coming from the optical chamber 2 and/or the control chamber 6. In short, the enclosure 8 is designed in order to satisfy the ATEX standard and has anti-explosion properties.

(6) In the illustrated embodiment variant, the enclosure 8 comprises a metal profile 9 made from extruded aluminum molded to have a first cavity 10 where the optical chamber 2 extends, and a second cavity 11 where the control chamber 6 extends. More specifically, the profile 9 includes two side wings 12, between which the second cavity 11 accommodating the control chamber 6 extends, and which are connected to one another, at their lower ends, by a bottom wall 13, a portion 14 of which recessed toward the control chamber 10 defines the first cavity 10. A cover 15, connecting the upper ends of the side wings 12 of the profile 9 to one another, makes it possible to close the control chamber 6.

(7) According to the invention, the lens 5 is defined by a silicone lens and covers the optical chamber 2 while being directly integrated into the closed enclosure 8.

(8) To that end, in reference to FIG. 2, the silicone lens 5 and the recessed portion 14 include means for assembling the lens 5 on the profile 9. Indeed, the recessed portion 14 has an outer face 16, including a central zone 17 against which the printed circuit board is fastened, for example using screws, and two grooves 18 bordering the central area 17. As illustrated, the two grooves 18 are molded to accommodate, by nesting, tabs 19 of complementary appearance included by the silicone lens 5 that covers the printed circuit board 4 and closes the optical chamber 2.

(9) Furthermore, the silicone lens 5 is secured to the metal profile 9 using an aluminum frame 20 nested in the recessed portion 14 and molded to overlap the tabs 19 of the silicone lens 5 accommodated in said grooves 18 as well as side areas 21 of the outer face 16 of the recessed portion 14.

(10) In order to strengthen this connection, the tabs 19 each include a slot 22, formed in their outer face intended to be oriented toward the frame 20, in which a sealing joint 23 is deposited that may consist of a silicone glue. This joint 23 makes it possible to fill in the space comprised between the tabs 19 of the silicone glue 5 and said frame 20, and thus contributes to reliably insulating the lighting device 1 from the surrounding environment.

(11) It should be noted in this regard that the profile 9 and the frame 20 are assembled by screwing under controlled pressure, and are each made from an aluminum material with a particular roughness, chosen to obtain a junction 24 with explosionproof properties after they are assembled.

(12) Furthermore, in order to contribute to such characteristics, the inner face 25 of the recessed portion 14 is molded so as to define cooling means 26 of the printed circuit board 4 provided with LEDs 3. It thus emerges from the preceding that the lighting device 1 according to the invention has a structure making it possible to achieve the aims described above. The integration of the lens 5 made from a silicone material into the optical system as component element of the closed enclosure 8 makes it possible to avoid the use of a thick protective glass window. Thus, the efficacy and the lighting precision of the optical system are preserved and a particularly lightweight lighting device 1 is obtained. Such a property further has the effect of simplifying the installation of the lighting device 1 according to the invention and reducing the overall cost thereof. Furthermore, the use of a silicone lens 5 makes it possible to provide, for the optical chamber 2, an inner volume 27 of very small size and therefore minimizing the force of any explosion coming from the optical chamber 2, by confining it and keeping it within the latter.