FR3034168A1 - LINEAR LIGHT EMITTING DEVICE WITH TWO SIDE LIGHTING LOBES - Google Patents

Abstract

Diode linear illumination device comprising an elongated body (2) carrying a source (E) and a cover (20) closing a chamber (11) and forming a linear lens (21) with an axis parallel to the axis (L ) of the body and symmetrical about a sagittal plane S, with an outer face (22) and an inner face (23), whose outer face has a convex shape, and whose inner face comprises: - two medial diopters (25 ) convexes which define a biconvex lens (26), and at least two lateral prisms (31) which are each adjacent to a medial diopter and which have a medial face (40) and a lateral face (41) connecting at the a vertex (31), the prisms (31) having a height H greater than the thickness of each medial lens (26).

Description

The present invention relates to the technical field of lighting by means of light emitting diode (LED) light-emitting diode (LED) sources for "LightEmitting Diode". The invention relates more particularly to so-called linear LED lighting devices intended to be a substitute for lighting systems using fluorescent linear tubes with mercury vapor or other. [2] Fluorescent tube lighting such as, for example, used inside industrial buildings, particularly in storage warehouses, implements luminaires fixed in height, and aligned to illuminate spans. Each luminaire then comprises one, two or three parallel linear fluorescent tubes. These inexpensive luminaires actually make it possible to produce light, but they do not make it possible to obtain satisfactory illumination at ground level or in a volume between the ground and a height of two meters, given the height at which they are generally located. , from 4 to 10 meters and how the tubes emit light on their entire periphery. Moreover, these luminaires do not make it possible to obtain an optimized electrical energy consumption and induce disturbances of the power supply networks to which they are connected because of their mode of operation and the systems used when they are switched on. [3] With the development of light-emitting diodes, linear fluorescent tube luminaires are replaced by linear light-emitting diode luminaires. In order to ensure quality ground lighting, when the luminaire is located at a great height, it is proposed to associate each diode with an individual optical system, said secondary lens which focuses and focuses the light, for example in a cone having an apex angle of about 20 ° to 30 °, so as to obtain the desired floor lighting.

I041 'However, the implementation of individual optical systems associated with each diode greatly increased the manufacturing cost of the luminaire which can be prohibitive for lighting in industrial environment in particular. Moreover, in some implementation configuration it is not always necessary to illuminate the ground just below and in the axis of the luminaire but it may be desirable to illuminate narrow areas located on the sides and therefore offset laterally in relation to the area above and in line with the luminaire. [05] It therefore appeared the need for a new type of linear lighting device adapted to provide satisfactory illumination, offset from the axis of the luminaire 3034168 from a great height while having a cost manufacturing significantly less than that of the luminaires comprising an optical system of concentration of the light associated with each light emitting diode. [06] In order to achieve this object, the invention relates to a linear light-emitting diode illumination device comprising at least: an elongated body comprising at least one receiving surface of at least one substrate carrying a light source linear array comprising at least one row of light-emitting diodes aligned along a longitudinal axis of the body and at least partially delimiting at least one elongate linear illumination chamber in which the row of diodes is located; at least part of the lighting chamber. According to the invention the hood forms, in relation to the linear source, a linear lens, at least translucent, of longitudinal axis parallel to the longitudinal axis of the body and symmetrical with respect to a sagittal plane S, with an outer face of light emission and an internal light receiving face of the diodes, whose outer face, seen in cross section, has a convex shape, and whose receiving face, seen in cross section, comprises: two adjacent convex medial diopters which are located on either side of the sagittal plane S and each define with the external face a biconvex medial lens, 20 - and at least two parallel lateral prisms which are located opposite one of the other with respect to the medial diopters being each adjacent to a medial diopter and each having a medial and a partially flat at least lateral side connecting at a vertex of the prism c corresponding, the prisms each having a height H, measured between the top of the corresponding premium 25 and the outer face, greater than the thickness E of each medial lens measured between the top of the corresponding medial diopter and the outer face. [07] The implementation of such a linear optic provides two narrow lateral illumination lobes offset from the sagittal plane S of symmetry of the outer face of the hood. The medial lens works to collimate the light in two narrow angular sectors each centered on the optical axis of the corresponding medial lens which forms an acute angle with the sagittal plane. [8] Furthermore, the lateral prisms work in total internal reflection so as to reflect the light in the same direction as the medial lenses or to redirect the light of the diodes to said medial lenses. [9] Thus, the implementation, with each light source comprising at least a row of light-emitting diodes, of such a linear lens makes it possible to obtain for each light-emitting diode two lighting cones each having a transverse plane. to the axis of alignment of the diodes an acute apex angle and, for example, between 10 ° and 30 ° and whose axis forms an acute angle with the sagittal plane. The lighting device according to the invention then makes it possible to provide a laterally satisfactory offset illumination even if it is located at a high height, for example greater than 5 meters and of the order of ten meters. This without the need to implement at each light emitting diode a so-called secondary lens, providing a conditioning light ernise by the diode. The lighting device according to the invention can be used in particular in logistics racks or even in a large area such as a hypermarket in the center of a corridor lined with 2 spokes whose height will be for example between 3.5 m and 5.5m. [10] The linear lens according to the invention formed of the two medial lenses and lateral prisms concentrates more than 85% and of the order of 90% of the light emitted by each diode in two cones each centered on the optical axis of the corresponding medial lens. [11] Generally, a light-emitting diode comprises a semiconductor wafer which emits, when subjected to a suitable potential difference, a most often blue light radiation which is converted to white light or the like by a coated phosphor layer, directly or indirectly. associated with a thickness of silicone, a coating at least translucent and generally transparent forming a primary lens which comprises an outer emitting face of the light generated by the diode. The primary lens of the diode most often emits light on a half-sphere. The linear lens according to the invention allows, without individual secondary lens, to concentrate the light emitted by the lighting device in two directions inclined with respect to the sagittal plane. Thus, according to a preferred but not strictly necessary characteristic of the invention, each light-emitting diode of the lighting device is devoid of individual secondary lens of concentration of the light. For the purposes of the invention, a material or an object is translucent if it allows the light coming from a reception face to pass towards an emission face and beyond this without the elements on the side of the receiving face are visible, clearly distinguishable or identifiable. Still within the meaning of the invention, a material or an object is transparent if it allows the light coming from a reception face to pass to an emission face and beyond this and the elements situated in the side of the receiving face are perfectly visible, clearly distinguishable or identifiable. Thus, an at least translucent object or material is an object or material capable of having one or more gradations in the manner in which it passes light or diffuses it between what would describe it as translucent and what would describe it as transparent. [13] For the purposes of the invention, the sagittal plane is a plane substantially parallel to the longitudinal axis of the row of diodes and parallel to the emission axes of the light emitting diodes or primary lenses thereof. According to the invention, the sagittal plane is furthermore a plane of symmetry of the linear lens. [14] According to one characteristic of the invention, the height H of the lateral prisms is greater than or equal to 1.2 times the thickness e of the medial lenses. This feature ensures optimal collection of light from the diodes. [15] According to another characteristic of the invention, the center of curvature of each medial diopter is situated on a plane containing the optical axis of the corresponding medial lens and forming with the sagittal plane S an angle of between 10 ° and 45 ° in absolute value. According to another characteristic of the invention: the height H of the prisms satisfies 0.11 RH 0.27 R, the thickness e of the medial lenses verifies-b; 07 R e 5 0.24 Where R is the radius of curvature of the outer face. [17] According to one characteristic of the invention, the radius of curvature Rd of each medial diopter satisfies 0,30 R 5 Rd 5 0,43 R. [18] According to an alternative embodiment of the invention, the radius of curvature R of the outer face is between 13 mm and 30 mm. [19] According to a feature of the invention, the radius of curvature Rd of each medial diopter is between 8 mm and 25 mm. [20] According to one embodiment of the invention; The radius of curvature R of the external face is between 13 mm and 30 mm, the height H of the prisms is between 3 mm and 7 mm, the thickness e of the medial lenses is between 2 mm and 6 mm. [21] According to a feature of the invention, each medial diopter extends over an angular sector delimited by a plane normal to the outer surface and the sagittal plane which form an angle of between 50 ° to one another. and 120 °. [22] According to another characteristic of the invention, the plane portions of the lateral and medial faces of the same lateral prism form an angle of between 15 ° and 60 °. [23] According to another characteristic of the invention: the flat medial face portion of each prism forms with the sagittal plane S an angle of between 5 ° and 40 ° in absolute value, the flat part of the lateral face. of each prism forming with the sagittal plane S an angle of between 45 ° and 80 ° in absolute value. [24] According to a feature of the invention, the points of the prisms farthest from the apex of the outer face are located on a plane parallel to a plane tangent to the apex of the outer face. [25] According to a characteristic of the invention, each diode comprises a primary lens associated with a convex or plane emission face and the apex of each emission face of each diode is located at a distance d from the apex of the face external 20 less than or equal to 19 mm. [26] According to another characteristic of the invention, each diode comprises a primary lens associated with a convex or plane emission face and in that the apex of each emission face of each diode is located at a distance d of apex of the outer surface, less than or equal to 0.30 R; where R is the radius of curvature of the outer face. [27] According to one embodiment of the invention, the body comprises in the lighting chamber two planar reflectors extending parallel to the longitudinal axis L of the body being situated on either side of the surface. receiving and forming, with each other, an angle of between 100 ° and 170 °. The use of such reflectors makes it possible to increase the luminous efficiency of the lighting device according to the invention. [28] According to one characteristic of the invention, the body is made of metal. Such a metal body ensures good evacuation of the heat generated by the light emitting diodes and their power supply. Preferably, the body is made in the form of a profile obtained by means of a die without this excluding the possibility of making the body in any other suitable manner, such as, for example, by folding. [29] According to one characteristic of the invention, the linear light source comprises several longitudinal rows of parallel light emitting diodes. [30] Of course, the various features, variants and embodiments of the lighting device according to the invention can be associated with each other in various combinations in so far as they are not incompatible or exclusive of any of the other. [31] Furthermore, various other features of the invention will emerge from the attached description with reference to the drawings which illustrate non-limiting embodiments of a lighting device according to the invention. - Figure 1 is a schematic perspective view partially exploded of a lighting device according to the invention. FIG. 2 is a cross-section of the lighting device illustrated in FIG. 1. [32] A lighting device according to the invention, designated as a whole by reference numeral 1 in FIG. 1, may be described as linear lighting device in that it has a linear light source E comprising one or more rows Rg of light-emitting diodes. A linear lighting device according to the invention generally has a length very much greater than the width of the lighting device 20 without the invention excluding an embodiment of the lighting device in which it has a width very close to its length by the implementation of a sufficient amount of row of light emitting diodes. The linear qualifier is nonetheless relevant insofar as it relates to the alignment direction of the rows of light-emitting diodes. [33] The linear lighting device 1 comprises an elongated body 2 which extends along a longitudinal axis L. The elongated body 2 defines at least one receiving surface 3 of at least one substrate 4 carrying at least one row R 5 of electroluminescent diodes 5 aligned along the longitudinal axis L. According to the illustrated example, the elongate body 2 comprises a single receiving surface 3 which is substantially centered with respect to the elongated body 2 and on which a single substrate 4 is fitted. The substrate 4 may, for example, comprise a printed circuit board, abbreviated to PCB for "ssprinted circuit board", on which the light-emitting diodes 5 are welded. may be made of any other suitable manner to ensure the mechanical strength of the light-emitting diodes 5 as well as their power supply. [34] According to the illustrated example, each The electroluminescent iodine 5 is associated, as is more particularly apparent from FIG. 2, with a primary lens 6 which has a convex emission face 7, it being understood that the emission face 7 could also be flat. In addition, in this case each light-emitting diode 5 is devoid of individual secondary lens or is not associated with any individual secondary lens. According to the illustrated example, the elongate body 2 comprises two planar reflectors 10 located on either side of the receiving face 4. The two planar reflectors 10 extend parallel to the longitudinal axis L and form , with each other, an angle has between 100 ° and 170 °. [36] The elongate body 2 defines with the receiving surface 3 and the planar reflectors 10 a lighting chamber 11 in which the array of light-emitting diodes Rg, constituting the linear source E, is intended to be partly less locked up. According to the illustrated example, the elongate body 2 also comprises, opposite the lighting chamber 11 with respect to the reflectors 10, a chamber 12 capable of receiving a supply system for the light-emitting diodes 5. Of course, the implementation such a chamber 12 is not necessary for producing the elongate body 2 of a linear lighting device according to the invention. [37] The lighting device according to the invention also comprises an elongated linear hood 20 which partially closes at least the lighting chamber 11. According to the invention, the hood 20 is also intended to let in or spread the light emitted by each linear source E. For this purpose, the cover 20 is made of an at least 25 translucent and preferably transparent material such as for example a plastic material such as polymethyl methacrylate (PMMA), polyethylene terephthalate (PET ) or polypropylene (PP) without this list being neither exhaustive nor exhaustive. [38] Hood 20 is also adapted to provide conditioning of the light emitted by each linear source E so as to direct and focus it in two preferred directions D shifted left and right in FIG. , the cover 20 forms, in relation to each linear light source E, a linear lens 21 parallel to the longitudinal axis L of the body 2. According to the example illustrated in FIGS. 1 and 2, the cover 2 comprises a single linear lens 21 [39] According to the invention, each linear lens 21 comprises an outer emitting face 22 of light which is symmetrical with respect to a sagittal plane S substantially parallel to the longitudinal axis L. When the cover 20 is fitted on the body 2, the sagittal plane S forms a plane of symmetry of the illumination chamber 11, the reflectors 10 being then the image of one another with respect to the sagittal plane S. [40] linear lens 21 also has t an internal face 23 for receiving the light of the light-emitting diodes 5, located opposite the outer face 22 of light emission of the light-emitting diodes 5. The linear lens 21 ensures as a whole a transmission of light emitted by said light-emitting diodes 5. [41] As is apparent from FIG. 2, the outer face 22 has, in cross-section, a preferably smooth convex shape with, preferably, a radius of curvature R greater than or equal to at 8 mm and preferably between 13 mm and 30 mm. Preferably, the outer face 22 has the shape of a circular arc. [42] The receiving face 23 is shaped so that the lens 21 forms a sort of linear Fresnel lens. Thus, the receiving face 23 comprises, when seen in transverse cross-section, two adjacent convex medial diopters as well as on either side of the prisms parallel to the longitudinal axis L. According to the example As illustrated, the medial diopters 25 are symmetrical to one another with respect to the sagittal plane S and meet at the latter in a central groove. [43] Each medial diopter 25 is thus offset with respect to the sagittal plane S and defines a biconvex medial lens 26 whose optical axis 0, containing the center of curvature of the medial diopter 25, forms with the sagittal plane S an angle f3 included between 10 ° and 45 ° in absolute value. Each medial diopter 25 extends on an angular sector delimited by the sagittal plane S and a plane P25 normal to the outer face 22 which form with each other an angle y preferably between 45 ° and 120 °. Moreover, each medial diopter 25 has a radius of curvature Rd which satisfies the following relation: 0.30 R Rd 0.43 R 30 where R and the radius of curvature of the external face or emission face 22. Preferably, but not exclusive, the outer face 22 has a radius of curvature R between 13 mm and 30 mm and each medial diopter 25 a radius of curvature Rd between 8 mm and 25 mm.

In addition, each medial lens 26 has a thickness e, measured between two planes perpendicular to its optical axis and tangent, on the one hand, to the corresponding medial diopter 25 and, on the other hand, to the emission face 22. which preferably, but not necessarily, has the relationship 0.07 R e 0.24 R [44] Preferably, but not exclusively, the thickness of the medial lens 26 is between 2 mm and 6 mm. [45] The receiving face 23 also has, at the lateral edges of each medial diopter 25, at least one lateral prism 31. According to the illustrated example, the receiving face 23 comprises two lateral prisms 31 which are arranged at a distance from each other. oppositely to each other relative to the sagittal plane S. [46] Each lateral prism 31 comprises a medial face 40, partly in relation to the medial dioptres 25 and which are symmetrical to each other relative to the sagittal plane S. [46] less plane, located on the side of the sagittal plane S and a lateral face 41, at least partly flat, located opposite the sagittal plane with respect to the medial face 40. The medial and lateral faces of each prism are substantially parallel to the longitudinal axis L. The medial faces 40 and lateral 41 of the same prism join to form the apex 42 of the corresponding prism. [47] Preferably the plane portions of the lateral 41 and medial 40 faces of the same lateral prism form an angle of between 15 ° and 60 °. In addition, the flat portion of the medial face 40 of each prism forms with the sagittal plane S an angle of between 5 ° and 45 ° in absolute value. Similarly, the flat portion of the lateral face of each prism forms with the sagittal plane S an angle of between 45 ° and 80 ° in absolute value [48] Moreover, according to the illustrated example and so that the linear lens 21 collecting a maximum of the light emitted by the linear source E to concentrate it in the preferred directions D, the height H of the lateral prisms 31 is greater than the thickness e of the medial lenses 26 and preferably greater than or equal to 1.2 e. The height H of each prism is measured between the apex of the corresponding prism and the outer face 22, along a bisecting plane of the plane portions of the medial and lateral faces of said prism [49]. More particularly preferably, but not exclusively, the height H of each prime satisfies the following relation: 0.11 RH 0.27 R 3034168 10 where R corresponds to the radius of curvature of the outer face 22. [50] Moreover, according to the illustrated example, the top of the face 7 of emission of each light emitting diode 5 is located at a distance d from the top of the outer face 22 less than or equal to 0.30 R where R is the radius of curvature of the outer face. This makes it possible to optimize the luminous efficiency of the linear lighting device. In the context of the example illustrated, the apex of the emission face 7 of the primary lens of each light emitting diode 5 is furthermore located between, on the one hand, a plane P 42 passing through the points, two lateral prisms 31, the farthest 32 from the top of the outer face and, on the other hand, a plane tangential to the apex of the outer face 22 at which the plane P42 is parallel. [51] In the present case, the top of the emission face 7 of the primary lens of each light-emitting diode 5 is also located between a plane P10 passing through the lateral edges of the reflectors 10 and a plane tangent to the apex of the face In addition, the top of the emission face 7 of the primary lens of each light emitting diode 5 is preferably, but not necessarily, located at a distance d from the apex of the outer face 22 less than or equal to 19 mm. [52] A linear lighting device, according to the invention and as thus achieved, can redirect at least 80% or even 90% of the light emitted by the diodes in the two preferred directions D. Indeed, each lens The linear biconvex linear 26 collimates the light from the diodes 5 in the preferred direction D corresponding to a narrow cone centered on its optical axis O while the linear prisms allow, after total reflection internal to the linear lens 21, to redirect the light in privileged directions. In addition, the planar reflectors ensure a recycling of the light possibly reflected by the receiving face 23 and the light coming from the light-emitting diodes 5 which would not have directly reached the reception face 23. [53] The device of FIG. lighting described above in connection with Figures 1 and 2, comprises a linear light source E formed of a single row Rg of light emitting diodes R. However, according to the invention, the linear light source E could comprise several rows of diodes electroluminescent Rg juxtaposed. [54] Of course, various other variants of the lighting device according to the invention may be envisaged within the scope of the appended claims.

Claims (15)

REVENDICATIONS1. Light-emitting diode linear illumination device comprising at least: an elongated body (2) comprising at least one receiving surface (3) of at least one substrate (4) carrying a linear light source (E) comprising at least one row (Rg) of light-emitting diodes aligned along a longitudinal axis (L) of the body and at least partially delimiting at least one elongate linear illumination chamber (11) in which the diodes are located; 20) closing the lighting chamber (11), characterized in that the cover (20) forms, in relation to the linear source, a linear lens (21), at least translucent, of longitudinal axis parallel to the longitudinal axis (L) of the body and symmetrical with respect to a sagittal plane S, with an outer surface (22) for transmitting light and an inner face (23) for receiving light from the diodes, the outer face of which ( 22), cross sectional view, pos a convex shape, and whose receiving face (23), seen in transverse cross-section, comprises: two adjacent medial (25) convex diopters which are located on either side of the sagittal plane S and each define with the outer face (22) a biconvex medial lens (26), and at least two parallel lateral prisms (31) which are located opposite each other with respect to the medial dioptres (25) each being adjacent to a medial diopter (25) and which each has a medial side (40) and a lateral surface (41) at least partially planar connecting at a vertex of the corresponding prism (31), the prisms (31) ) each having a height (H), measured between the top of the corresponding prime and the outer face (22), greater than the thickness (e) of each medial lens (26) measured between the apex of the medial diopter (25) corresponding and the outer face (22). 2. Linear lighting device according to the preceding claim, characterized in that the height H of the lateral prisms (31) is greater than or equal to 1.2 times the thickness (e) of the medial lenses. 30 3. Linear lighting device according to one of the preceding claims, characterized in that the center of curvature of each medial diopter (25) is located on a plane (0) forming with the sagittal plane (S) an angle ([ 3) between 10 ° and 45 ° in absolute value. 3034168 12 4. Linear lighting device according to one of the preceding claims, characterized in that - the height (H) of the prisms (31) verifies 0.11 RH 0.27 R, - the thickness (e) of the lenses medial checks 0.07 R e 5 0.24 R where R is the radius of curvature of the outer face (22). 5. Linear lighting device according to one of the preceding claims, characterized in that the radius of curvature (Rd) of each medial diopter (25) verifies: 0.30 R s Rd s 0.43 R, where R is the radius of curvature of the outer face (22). 6. Linear lighting device according to one of the preceding claims, characterized in that the radius of curvature (R) of the outer face (22) is between 13 mm and 30 mm. 7. Linear lighting device according to one of the preceding claims, characterized in that the radius of curvature Rd of each medial diopter (25) is between 8 mm and 25 mm. 8. Linear lighting device according to one of the preceding claims, characterized in that - the height (H) of the prisms is between 3 mm and 7 mm, - the thickness (e) of the medial lens is between 2 mm and 6 mm. 9. Linear lighting device according to one of the preceding claims, characterized in that each medial diopter (25) extends over an angular sector defined by a plane (P25) normal to the outer surface (22) and the plane sagittal (S) which form with each other an angle (y) between 50 ° and 120 °. 10. Linear lighting device according to one of the preceding claims, characterized in that the plane portions of the lateral faces (41) and medial (40) of the same side prism (31) forms an angle of between 15 ° and 60 °. 11. Linear lighting device according to one of the preceding claims, characterized in that - the medial face plane portion (40) of each prism (31) forms with the sagittal plane (S) an angle of between 5 ° and 40 ° in absolute value, - the flat part of the lateral face (41) of each prism (31) forming with the sagittal plane S an angle of between 45 ° and 80 ° in absolute value. 12. Linear lighting device according to one of the preceding claims, characterized in that each diode (5) comprises a primary lens (6) associated with a convex or plane transmission face (7) and in that the top of each emission face (7) of each diode is located at a distance (d) from the top of the outer face (22) less than or equal to 19 mm. 13. Linear lighting device according to one of the preceding claims, characterized in that each diode comprises a primary lens (6) associated with a convex or flat transmission face (7) and in that the apex of each emission face (7) of each diode is located at a distance (d) from the apex of the outer face (22) less than or equal to 0.30 R, where R is the radius of curvature of the outer face (22) . 14. Linear lighting device according to the preceding claim, characterized in that the top of the primary lens of each diode is located between a plane passing the points of the prisms farthest from the top of the outer face (22) and a plane tangent to the top of the top of the outer face (22). 15. Linear lighting device according to one of the preceding claims, characterized in that the body comprises in the lighting chamber (11) two planar reflectors (10) 15 extending parallel to the longitudinal axis (L). the body being located on either side of the receiving surface (3) and forming, with each other, an angle (a) between 100 ° and 170 °.