FR2968333A1 - Lighting device for use on wall of swimming pool, has heat conducting plate arranged on optics so that LEDs are located in hollow chamber and all or part of rear face of plate is located outside chamber to be in contact with water - Google Patents

Abstract

The device (1) has a glass optics (5) and a support (2) defining a hollow chamber (9), and LEDs (8) arranged on a front face of a heat conducting plate (13). The plate is arranged on the optics so that the LEDs are located in the hollow chamber and all or part of a rear face of the plate is located outside the chamber to be in contact with water in a pool. The LEDs are arranged on the plate so as to emit a light flux (F) in a direction opposite to that of the optics. A reflector (18) is arranged in the hollow chamber to redistribute the light flux in the direction of the optics.

Description

LIGHTING DEVICE FOR SWIMMING POOL. Description Technical Field of the Invention The invention relates to a pool lighting device.

It concerns the technical field of swimming pool equipment and more particularly that of lighting intended to be immersed in the water of a swimming pool. State of the art Document US Pat. No. 6,595,671 (LEFEBVRE) and US Pat. No. 6,315,424 (HUI) disclose aquatic lighting devices comprising one or more light sources fixed on a support and protected from the water by an optic or a coating. transparent resin. The light sources are enclosed in a small space and, in fact, heat up at high temperatures. This overheating is likely to cause rapid degradation of the light sources. To overcome this problem of overheating, the document WO2005 / 108203 (SAVAGE) teaches the use of a heat conducting plate on which light-emitting diodes are mounted. The plate is arranged at the bottom of the support so as to be in contact with a trickle of water from the pool. This trickle of water is used to cool the plate as well as the light-emitting diodes that are mounted on it. However, the small amount 10 15 - 2

water stagnant behind the support does not effectively cool electroluminescent diodes and the latter still end up overheating and degrade.

In view of this state of affairs, the main purpose of the invention is to provide an improved swimming pool lighting device enabling efficient and rapid cooling of the light-emitting diodes so that the latter do not degrade.

Disclosure of the invention. The solution proposed by the invention is a lighting device intended to be immersed in the water of a swimming pool, comprising: a support on which is fixed an optical element, said support and said optic defining a hollow chamber in which are arranged electroluminescent diodes, - a heat conducting plate having a front face on which are arranged the light emitting diodes and a rear face.

This device comprises the following remarkable technical characteristics: the plate is arranged on the optics so that the light-emitting diodes are located in the hollow chamber and all or part of its rear face is located outside said chamber; to be in contact with the pool water, the light-emitting diodes are arranged on the plate so as to emit a luminous flux in a direction opposite to that of the optic; a reflection means is arranged in the hollow chamber; , vis-à-vis the light-emitting diodes, so as to rebroadcast, in the direction of optics, the luminous flux emitted by said diodes. - 3

By being arranged directly on the optics, the plate is now in direct contact with a large volume of non-stagnant water, which promotes heat exchange, so that said plate is cooled sufficiently quickly and efficiently so that the light-emitting diodes do not overheat. not and do not degrade. The reflection means acts as a backlight element, and allows to redirect all or part of the light flux generated by the light emitting diodes to the outside of the optics, and therefore to the water basin.

Other remarkable characteristics of the device which is the subject of the invention are listed below, each of these characteristics being able to be considered alone or in combination with the remarkable characteristics defined above: the optics comprises a central orifice inside of which the plate is sealed. - the plate is directly molded in the optics. the light-emitting diodes are fixed on a printed circuit board itself fixed on the front face of the plate. the rear face of the platen may be flat or comprise elements in hollow and / or in relief, increasing the heat exchange surface with the water of the swimming pool. - The reflection means may consist of a part comprising a reflective frustoconical body whose flared base is provided with a reflecting cupola extending into the hollow chamber, the plate being arranged at the top of said body. - The reflective frustoconical body has a hollow inner portion in which passes the power supply cables of the light emitting diodes. the inner face of the reflective cupola which is located on the same side as the light-emitting diodes is concave and has furrows contiguous and concentric with the axis of said cupola. - 4

- The reflective cupola comprises fixing means to the support. - The reflection means may also consist of a reflective dome arranged vis-à-vis the light emitting diodes, said dome extending into the hollow chamber. - The inner face of the reflective cupola which is located vis-à-vis the light emitting diodes is concave and has furrows contiguous and concentric to the axis of said cupola. - The reflective cupola and optics form a one-piece piece obtained by molding, a reflective coating being applied against the inner face of said dome which is located vis-à-vis the light emitting diodes. - The reflection means may still consist of a reflective coating applied against the inner wall of the support which is located vis-à-vis the light emitting diodes.

Description of the figures.

Other advantages and characteristics of the invention will appear better on reading the description of a preferred embodiment which follows, with reference to the accompanying drawings, made by way of indicative and non-limiting examples and in which: FIG. 1 is a sectional view of a preferred embodiment of the lighting device that is the subject of the invention, FIG. 2 is a sectional view of the lighting device that is the subject of the invention in a variant embodiment. FIG. 3 is a sectional view of the lighting device that is the subject of the invention in another variant embodiment; FIG. 4 is an enlarged view of the detail D of FIG. 1, showing a preferred embodiment of FIG. the heat-conducting plate; - FIG. 5 is an enlarged view of the detail D of FIG. 1, showing the heat-conducting plate in a variant embodiment, 2968333 -5

FIG. 6 is an enlarged view of the detail D of FIG. 1, showing the heat conducting plate in another variant embodiment.

Embodiments of the invention

The lighting device of the invention is intended to be immersed in the water of a swimming pool. In particular, it is intended to be fixed on the wall of a swimming pool. It can be installed in a specific niche made in a wall of the swimming pool or inserted into a brush socket or a pressure outlet. For the purposes of the present invention, the term "pool" should be understood to include not only traditional pools above ground or buried, but also any pools, spas or fountains.

Referring to the preferred embodiment of FIG. 1, the lighting device (1) comprises a support (2) which is a rigid one-piece piece obtained by plastic molding, for example ABS or polycarbonate. The support (2) preferably has a concave parabolic shape whose front portion is open. It comprises an inner wall (20) and an outer wall (21). The support section (2) is preferably circular, but may be square, hexagonal or any other shape. In the case of a circular section, the largest diameter varies from 100 mm to 400 mm, preferably 220 mm. The thickness of the support (2) varies from 2 mm to 6 mm, preferably 4 mm. The inner wall (20) may comprise reinforcing ribs.

The open front part of the support (2) is closed by an optic (5). In this way, the support (2) and the optics (5) delimit a hollow chamber (9). The back of the support (2) is preferably provided with a tubular element (4) opening on either side of said support. The outer wall of this tubular element (4) can be threaded so that the support (2) can be secured to the wall (29).

screw inside an existing discharge nozzle or brush socket already installed in a wall of the pool. According to a particular embodiment shown in FIG. 1, the tubular element (4) delimits a second sealed chamber (11) in which the connection between a power supply cable (10) and the light-emitting diodes (8) is made. ). The first chamber (9) and the second chamber (11) are adjacent, separated by a partition (22) sealed during molding of the support (2). The second chamber (11) is accessible directly from the rear of the support (2). The partition (22) sealingly integrates elements (23) for connecting the power supply cable (10) to the light-emitting diodes (8). These connection elements (23) are typically metal connectors directly molded into the partition (22) or reported, and which open into each of the two chambers (9, 11). In the first chamber (9), the connection elements comprise ends 15 on which are fixed, for example by screwing, lugs electrically connected to the light-emitting diodes (8) via one or more electric cables (24). . In the second chamber (11), the connecting elements (23) have ends on which are fixed, for example by screwing, lugs electrically connected to the power supply cable (10). The inner wall of the second chamber (11) is threaded so as to receive a removable sleeve (26) which seals it tightly. The sheath (26) incorporates a tight seal (28) enclosing the power supply cable (10). This seal (28) seals the passage of the power supply cable (10) in the sleeve (26). In practice, the seal 25 (28) is a deformable piece, typically made of rubber, of conical shape and inside which passes the power supply cable (10). The upper end of the sleeve (26) has an inner housing, also of conical shape but slightly smaller than the seal (28). There is provided a clamping member (29) which deforms the seal (28) so as to seal the passage of the power supply cable (10) in the sleeve (26). The clamping member (29) is preferably a nut screwed to 2968333 -7

the upper end of the sleeve (26). During screwing, this nut crushes the seal (28) in its housing, and by deforming said seal seals between the power supply cable (10) and the sleeve (26).

The optic (5) is made of translucent or transparent glass or plastic. It has a convex parabolic shape and can incorporate facets allowing the homogeneous diffusion of the light and the mixture of the colors in the water. The optic (5) has a section that corresponds to that of the support (2). It is sealingly attached to the open front portion 10 of the support (2). This fixation is achieved by screwing combined with one or more joints, by ultrasonic welding, by bonding, or any other technique suitable for the skilled person.

The light-emitting diodes (8) are arranged on the front face (130) of at least one heat conducting plate (13). In the accompanying figures, only one plate (13) is shown, but the device of the invention may comprise several. The plate (13) can have a circular, square, hexagonal or other shape and be composed of one or more pieces. It is made of metal, ceramic or any other heat conducting material suitable for those skilled in the art. Its rear face (131) may be coated with a layer of corrosion-resistant material such as paint layer, plastic layer, or the like, or else undergo a surface treatment such nitriding, chromating, plasma spraying, or other. In practice, the plate (13) consists of a flat cylindrical piece, having a diameter which may for example vary from 10 mm to 100 mm and a thickness which may for example range from 1 mm to 10 mm. The light emitting diodes (8) are preferably previously fixed, typically by welding, on a printed circuit (14) itself fixed on the front face (130) of the plate (13). The printed circuit board (14) and the board (13) can be fixed against each other by soldering, gluing, screwing, riveting, or the like. The light-emitting diodes (8) can, however, be directly attached to the face 2968333 -8

before (130) of the plate (13). In all cases, the heat emitted by the light-emitting diodes (8) is discharged by the plate (13).

The light-emitting diodes (8) (or LEDs) can be monochrome or polychrome. Thanks to the invention, it is possible to use so-called power diodes that generate a luminous flux much higher than conventional light emitting diodes. These power diodes generally have an electrical power greater than or equal to 0.1 Watt, some up to several tens of Watts. The illumination of the light-emitting diodes (8) is preferably controlled via an electronic management unit attached to the printed circuit (14). This management unit, which is in the form of a processor or a microprocessor, can be activated by remote control or directly programmed. The user thus has the possibility of generating according to his desire or in a programmed manner, numerous luminous effects possibly combined with color schemes. Conventionally, the light-emitting diodes (8) operate at 12 V. Depending on the available power source, it is therefore necessary to provide a transformer for transforming the 100 V or the 220 V into 12 V. For safety reasons, this transformer is disposed outside the device object of the invention and outside the water basin. Although a battery or electric batteries can be used, the light-emitting diodes (8) and in particular the management unit are preferably fed via the power supply cable (10). The end of this cable is connected to a power source, typically the mains. When a transformer is used, the transformer can either be integrated directly into the power supply cable (10) or be attached. In the latter case, the power supply cable (10) connects to the transformer and it is the latter which is connected to the mains.

According to the invention, the plate (13) is arranged directly on the optics (5) so that the light-emitting diodes (8) are made

located in the hollow chamber (9) and all or part of its rear face (131) is located outside said chamber to be directly in contact with the pool water. The plate (13) and the diodes (8) can thus be effectively cooled. The optic (5) has an orifice which is preferentially, but not necessarily, positioned in the center of said optic. A central hole provides a symmetrical and homogeneous illumination inside the optics. This orifice serves as a housing for the plate (13). Referring to Figures 4 and 5, the orifice may comprise a shoulder (50) ensuring the positioning of the plate (13). The holding in position is obtained by welding, gluing or screwing. A seal (51) seals the connection between the plate (13) and the optic (5). In the case where the optical (5) integrates several plates (13), several similar orifices are provided. In the variant embodiment of FIG. 6, the plate (13) is directly molded in the optic (5) so that it is not necessary to provide a seal.

The rear face (131) of the plate (13) can be flat (Figure 4) or have elements (135) recessed and / or raised (Figure 5). In this latter case, the heat exchange surface with the pool water is increased and the cooling of the light-emitting diodes (8) more efficient. In the exemplary embodiments of FIGS. 4 and 5 in which the plate (13) is attached in the otic (5), the entire rear face (131) of the plate (13) is in contact with the water of the swimming pool. In the embodiment of Figure 6 where the plate (13) is directly molded in otic (5), only a portion of the rear face (131) may be in contact with the pool water.

In the accompanying figures, the light-emitting diodes (8) are arranged perpendicularly to the front face (130) of the plate (1). In this configuration, the entire luminous flux (F) emitted by the diodes (8) is directed towards the rear of the support (2), that is to say in a direction opposite to

that of optics (5). The light-emitting diodes (8) can also be arranged parallel to the front face (130) of the plate (1) or obliquely. In this case, only a part of the luminous flux (F) is directed towards the rear of the support (2). In order to redistribute the luminous flux (F) towards the optics (5), and thus into the water basin, a reflection means is arranged in the hollow chamber (9), with respect to electroluminescent diodes (8).

Referring to FIG. 1, this means of reflection preferably consists of a piece (18) comprising a reflective frustoconical body (180) whose flared base is provided with a reflecting cupola (181) extending into the chamber hollow (9). The plate (13) is arranged at the top of the frustoconical body (180), and more particularly at its narrow end. With reference to FIGS. 4 and 5, this end is advantageously provided with a centering pin (184) capable of being inserted into a complementary housing provided in the printed circuit (14) and / or in the plate (13). . The piece (18) is fixed on the support (2) by screwing, gluing, welding, or other. In practice, the reflective dome (181) has attachment means (183). This is for example pins lodged in complementary housing provided on the inner wall of the support (2). The parabolic curvature of the frustoconical body (180) is such as to redistribute all or part of the luminous flux (F) towards the optics (5) and thus towards the water basin. The frustoconical body (180) may be made of metal, composite material or the like, its outer surface being covered with a layer of a reflective material of the type chrome, aluminum, silver, etc. It can, however, be made directly in a reflective material of the aluminum, silver, or other type. In practice, the height of the frustoconical body (180) varies from 10 mm to 100 mm. It has a hollow interior (184) in which the power supply cables (24) pass.

The reflective dome (181) is made of the same material as the frustoconical body (180). It can be attached to the base of the latter or formed a one-piece piece with said body. In practice, the diameter of the dome (181) is such that its outer edge is substantially in contact with the inner wall of the support (2) and / or with the inner wall of the optic (5). It has an outer diameter ranging from 100 mm to 400 mm, preferably about 220 mm. The dome (181) may have a conical shape of straight or curved profile, a hyperbolic shape, or any other profile suitable for the skilled person. To obtain optimum reflection of the luminous flux (F), the inner face of the dome (181) which is situated on the same side as the light-emitting diodes (8) is advantageously concave and comprises grooves (182) contiguous and concentric with the axis (A) of said dome. In the accompanying figures, this axis (A) is coaxial with the axis of the frustoconical body (180) and that of the optics (5). The grooves (182) provide a homogeneous reflow of the luminous flux (F) to the optics (5) and thus to the pelvis, with a large angle of reflection. In practice, the grooves (182) are of circular section, their radius varying from 1 mm to 20 mm. Their number varies for example from 3 to 50 depending on their radius and the diameter of the dome (181). The inner face of the dome (181) may comprise other facet type reflection means or hollow reflection elements and / or reliefs ensuring a homogeneous and diffuse reflection of the luminous flux (F).

In an alternative embodiment shown in Figure 2, the reflection means consists of a reflective dome (18 ') arranged vis-à-vis the light emitting diodes (8). In practice, the diameter of the dome (18 ') corresponds to that of the optic (5) so that it extends throughout the chamber (9). The cupola (18 ') may have a conical shape of straight or curved profile, a hyperbolic shape, or any other profile suitable for those skilled in the art. In order to obtain optimal reflection of the luminous flux (F), the inner face of the cupola (18 ') which is located opposite the light-emitting diodes (8) is advantageously concave and comprises furrows (182') contiguous and 2968333 -12-

concentric to the axis (A) of said dome. The grooves (182 ') are similar to those previously described with reference to Figure 1 and are arranged in the same way. The inner face of the dome (18 ') may comprise other reflection means of the facet type or recessed reflection elements 5 and / or reliefs ensuring a homogeneous and diffuse reflection of the luminous flux (F). One or more orifices (184 '), preferably arranged in the center of said reflecting cupola, ensure the passage of the power supply cables (24) of the light-emitting diodes (8). The dome (18 ') may be attached to the support (2) or formed in one piece with the optic (5) and be obtained during the molding of said optics. In the latter case, a reflective coating (185 ') is applied against the inner face of said cupola which is located vis-à-vis the light-emitting diodes (8). This coating (185 ') is typically based on chromium, aluminum, silver or any other reflective material. It may be in the form of a paint, a flexible sheet, or any other form suitable to those skilled in the art.

In another alternative embodiment shown in FIG. 3, the reflection means consists of a reflective coating (18 ") applied directly against the inner wall (20) of the support (2) which is located opposite the light-emitting diodes (8) This coating (18 ") is typically based on chromium, aluminum, silver or any other reflective material. It may be in the form of a paint, a flexible sheet, or any other form suitable to those skilled in the art. The inner wall (20) of the support (2) may comprise other facet-type reflection means or hollow reflection elements and / or reliefs ensuring a homogeneous and diffuse reflection of the luminous flux (F). 30

Claims (14)

REVENDICATIONS1. Lighting device adapted to be immersed in the water of a swimming pool, comprising: - a support (2) on which is fixed an optic (5), said support and said optic defining a hollow chamber (9) in which are arranged on the light-emitting diodes (8), - a heat-conducting plate (13) having a front face (130) on which the light-emitting diodes (8) and a rear face (131) are arranged, characterized in that: the plate (13) is arranged on the optic (5) so that the light-emitting diodes (8) are located in the hollow chamber (9) and all or part of its rear face (131) is located at the outside of said chamber to be in contact with the pool water, the light-emitting diodes (8) are arranged on the plate (13) so as to emit a luminous flux (F) in a direction opposite to that of the optics (5), - a reflection means (18, 18 ', 18 ") is arranged d in the hollow chamber (9), opposite the light-emitting diodes (8), so as to redistribute, in the direction of the optics (5), the luminous flux (F) emitted by said diodes. 2. Device according to claim 1, wherein the optic (5) comprises a central orifice inside which is fixed sealingly the plate (13). 30 2968333 -14- 3. Device according to claim 1, wherein the plate (13) is directly molded in the optics (5). 4. Device according to one of the preceding claims, wherein 5 the light-emitting diodes (8) are fixed on a printed circuit (14) itself fixed on the front face (130) of the plate (13). 5. Device according to one of the preceding claims, wherein the rear face (131) of the plate (13) is flat. 6. Device according to one of claims 1 to 4, wherein the rear face (131) of the plate (13) comprises elements (135) recessed and / or raised, increasing the heat exchange surface with the pool water. 15 7. Device according to one of claims 1 to 6, wherein the reflection means consists of a part (18) comprising a reflective frustoconical body (180) whose flared base is provided with a reflective dome (181) s extending into the hollow chamber (9), the plate (13) being arranged at the top of said body. 8. Device according to claim 7, wherein the frustoconical reflective body (180) has a hollow inner portion (184) in which the power supply cables (24) of the electroluminescent diodes (8). 9. Device according to one of claims 7 to 9, wherein the inner face of the reflective dome (181) which is located on the same side as the light emitting diodes (8) is concave and comprises grooves (182) contiguous and concentric to the axis (A) of said dome. 2968333 -15- 10. Device according to one of claims 7 to 10, wherein the reflective cupola (181) comprises fixing means (183) to the support (2). 5 11. Device according to one of claims 1 to 6, wherein the reflection means consists of a reflective dome (18 ') arranged vis-à-vis the light emitting diodes (8), said dome extending into the chamber hollow (9). 10 12. Device according to claim 11, wherein the inner face of the reflective dome (18 ') which is located vis-à-vis the light-emitting diodes (8) is concave and comprises furrows (182') contiguous and concentric to the axis (A) of said dome. 13. Device according to one of claims 11 or 12, wherein the reflective cupola (18 ') and the optic (5) form a one-piece piece obtained by molding, a reflective coating (185') being applied against the inner face of said dome which is located vis-à-vis the light emitting diodes (8). 14. Device according to one of claims 1 to 6, wherein the reflecting means consists of a reflective coating (18 ") applied against the inner wall (20) of the support (2) which is located vis-à-vis electroluminescent diodes (8).