FR2901956A1 - Light source`s e.g. incandescent lamp, LED controlling method for e.g. lantern, involves detecting malfunctioning of LEDs, and short-circuiting defective LED or group of LEDs in series comprising defective LED by bias of derivation - Google Patents

Abstract

The method involves determining a derivation for an LED or a group of limited number of LEDs that are arranged in series to constitute a light source e.g. incandescent lamp, and detecting the malfunctioning of the LEDs by a photosensitive element e.g. photosensitive diode (60). A defective LED or the group of LEDs comprising the defective LED are short-circuited by bias of the associated derivation using a transistor (T2) whose collector and emitter are connected to upstream and downstream of the LEDs, respectively.

Description

METHOD FOR THE MANAGEMENT OF ELECTROLUMINESCENT DIODES ARRANGED IN SERIES AND

  LANTERN INCORPORATING SERIES ELECTROLUMINESCENT DIODES

  The present invention relates to a lantern more particularly intended for public lighting, incorporating light emitting diodes in series as well as a management method of light emitting diodes arranged in series. Public lighting is a sector that consumes a lot of electricity, which represents a large part of a city's electricity budget. For example, the public lighting network can include up to 100,000 light points on the surface for a city like Paris. As illustrated in FIG. 1, a luminous point 10, also called a lantern, is attached to a candelabrum or against a facade and comprises a frame 12 to which an optical block 14, an electric block 16, fastening means 18, are attached. the assembly being disposed in a shell 20 generally comprising in the lower part a transparent mobile cover 22. The shell and the lid can have different shapes depending on the desired aesthetic.

  According to an embodiment of the prior art, the optical unit 14 comprises a reflector 24 and a light source 26 in the form generally of an incandescent lamp powered by an electric current supplied and regulated by the electric block 16. To reduce energy consumption, a first way is to provide better control of the light point, in particular by effectively controlling its operating time and / or by adjusting as needed the light intensity of the light spots. A second way is to reduce the energy consumption of the light spots. Thus, it is known that theoretically the replacement of incandescent bulbs by light-emitting diodes, called LEb for the rest of the description, allows an energy saving of the order of 70% at equal light intensities. However, this substitution is not easy to achieve. Indeed, given the number of light points already in place, the use of LEb must be compatible with existing lanterns. As a LEb produces a low luminous flux, it is necessary to group several LEb to obtain a luminous intensity equivalent to an incandescent bulb. The arrangement of the LEb in parallel provides a safer operation insofar as the malfunction of a LEb does not affect the operation of other LEb. However, this provision complicates the management of the power supply because it requires a much higher intensity than that available in existing devices. The serial arrangement provides simplified power management compatible with existing devices. However, this arrangement is not used to the extent that the malfunction of a single LEb causes the non-operation of the light point. As a result, only hybrid solutions have emerged in which several LEb's are stacked in series on a bar and several bars are arranged in parallel to form the light point. Thus, if a LEb is defective, only one bar does not work, the remaining bars to obtain a degraded operation of the light point, the alteration of the operation of the light point being all the more important as the number of bars is reduced . However, to obtain a simplified power management, it is necessary to reduce the number of bars. Therefore, this embodiment is not fully satisfactory. Also, the present invention aims to overcome the drawbacks of the prior art by providing a light source comprising light emitting diodes in series, compatible with existing lanterns, likely to provide safe operation. For this purpose, the subject of the invention is a method for managing light-emitting diodes arranged in series so as to constitute a light source, characterized in that it consists in providing a bypass for each light-emitting diode and / or each group of a light-emitting diode. a limited number of light emitting diodes in series, detecting the malfunction of a light emitting diode and short-circuiting the defective light-emitting diode or the light-emitting diode group having the defective light-emitting diode through the associated bypass. This solution makes it possible on the one hand to simplify the power supply of the light source and makes it compatible with existing lanterns, and on the other hand, to obtain a safe operation, a defective light-emitting diode being automatically short-circuited and not not altering the operation of the other light emitting diodes arranged in series. Other features and advantages will become apparent from the following description of the invention, a description given by way of example only, with reference to the appended drawings, in which - FIG. 1 is a diagrammatic representation of a lantern according to the art. FIG. 2 is a schematic representation of a lantern according to the invention, FIG. 3 is a view from above illustrating a light source according to the invention, FIGS. 4A to 4C are sections illustrating different optics. each of which can be associated with a light-emitting diode; FIG. 5 is a section illustrating the mounting of a light-emitting diode and an optical element on a frame; FIG. 6 is an electrical diagram illustrating the power supply of a light-emitting diode; series of light-emitting diodes and the short-circuiting of a defective light-emitting diode according to the invention. FIG. 7 is an electrical diagram illustrating the supply of a series of light-emitting diodes and the short-circuiting of a defective light-emitting diode according to an improved variant of the invention; and FIG. 8 is an electrical diagram. of an electrical component corresponding to a stage of the diagram of Figure 7. In Figure 2, there is shown by way of illustration a lantern 30 may be reported on a candelabrum or against the facade of a building. This lantern 30 comprises a frame 32, an optical block 34, an electric block 36, fastening means 38, the assembly being disposed in a shell 40, at least a portion of which is open or transparent to allow the passage of light. The shell may include a movable cover to allow intervention inside the hull, especially for maintenance. It can have different shapes depending on the aesthetics sought.

  The electrical block is an interface between the optical block and the rest of the power supply network not shown. It can be used to manage the voltage and / or intensity supplied to the optical block, in particular by regulating the intensity. An exemplary embodiment of said electrical block will be described later with reference to FIG. 6. Nevertheless, the invention is not limited to this embodiment. Similarly, the invention is not limited to lanterns and street lighting but covers all applications requiring an economical and reliable light source. The optical unit 34 comprises a light source 42 and light scattering means. According to the invention, the light source 42 comprises a plurality of electroluminescent diodes 44 arranged in series.

  For the rest of the description, a light-emitting diode will be called LEC). According to a distribution mode illustrated in FIG. 3, the LECs 44 are arranged in columns and lines so as to form a grid and constitute a luminous task, the number of LECs being adjusted so as to obtain a luminous intensity. substantially equivalent to that of an incandescent bulb. Diffusion means are provided for diffusing the light emitted by the LECs). Advantageously, the light source comprises means for concentrating the emitted light.

  According to one embodiment, the LECs 44 may be attached to a curable support to form a recessed surface in the manner of a reflector of the prior art. According to another preferred embodiment, a means 46 of diffusion is associated with each LEC) 44, said means 46 of diffusion being in the form of a truncated cone whose small end is contiguous against the LEC). Depending on the arrangement of the ECL 44 in the task, the diffusion means 46 has an angle α adapted to more or less focus the light, as shown in FIGS. 4A-4C. Thus, the diffusion means 46 have an angle α which increases as a function of the distance from the center of the task. In Figure 5, there is shown schematically a mounting of a LEC) according to one embodiment.

  The light source 42 comprises a support in the form of a printed circuit 48 on which the LECs 44 are reported. Each LEC 44 is connected by connection means 50 to the printed circuit 48. These means 50 are not detailed because they are known to those skilled in the art. Cooling means can be provided to evacuate the heat produced by the ECL). According to one embodiment, at least one thermal conductor 52 passes through the support 48 to connect the LEC) with a heat exchanger 54, in particular made of aluminum alloy. The diffusion means 46 is reported against the LEC). To limit the risk of breakage of the electrical connection between the LEC) and the support, means are provided to keep the LEC pressed against the support.

  According to one embodiment, a cover 56 allowing the light beam to pass is attached against the diffusion means 46, at least one tie rod 58 making it possible to connect said cover 56 to said support 48 or to the heat exchanger 54 connected to said support 48. , the cover 56 allows the diffusion means to be pressed against the LEC) and the LEC) against the support 48. This connection mode described for a LEC) can be duplicated for the other LECs forming the light source. According to the invention, the LECs 44 are arranged in series and the light source comprises, for each LEC, means 60 for detecting the malfunction of the associated LEC and means 62 for short-circuiting said LEC using a bypass, when the means 60 have detected a malfunction.

  In addition, the device of the invention comprises a power supply 64. Advantageously, in order to make the light source of the invention compatible with existing installations, the light source comprises a rectifier 66 for rectifying the AC voltage of the sector used previously.

  By following, current regulation means 68 are provided upstream of the LECs arranged in series in order to deliver a substantially constant current and to adjust said current as a function of the desired light intensity. Preferably, a control device as described in patent application FR-0650986 is associated with the light source in order to control the current regulation means 68 in order to adjust the light intensity delivered by said light source. The device may comprise means 70 for measuring the intensity downstream of the LECs) capable of controlling the means 68 for regulating the current as a function of the measured intensity.

  The provision of LECs in series makes it possible to simplify the power supply and the regulation means 68 in contrast to a light source with LECs or LEC groups in parallel. According to a preferred embodiment and illustrated in FIG. 6, the means 60 for detecting a dysfunction of a LEC) are in the form of a photosensitive element, in particular a photosensitive diode, capable of detecting whether the associated LEC emits no light radiation. According to one embodiment, the element making it possible to detect the dysfunction of the LEC) can be in the form of a light-emitting diode called for the LEC) suite to differentiate it from the LECs. 44 Indeed, as a function of the light received, the voltage across the receiving light-emitting diode varies. In addition there is a threshold effect when light is important, in this case when the associated LEC 44 operates and illuminates.

  The means 62 for short-circuiting a LEC) comprise at least one transistor T2 whose collector is connected upstream of the LEC) and the emitter is connected downstream of the LEC), the base of the transistor being connected to the light-sensitive diode 60. Thus, when a LEC) no longer emits light radiation, the photosensitive diode 60 changes state which causes the tilt of the transistor T2 which then bypasses the LEC). Thus, according to the assembly of the invention, even if a LEC) is defective, the other LECs of the light source continue to emit, said defective LEC being short-circuited.

  Preferably, the means 62 comprise two transistors T2 and Ti, Ti being interposed between the photosensitive diode 60 and the transistor T2 and making it possible to amplify the signal emitted by the said photosensitive diode. According to one embodiment, resistors R in series are provided in parallel with the LEC series). Control means 72 and regulation 74 of the voltage are provided to regulate the voltage at each end of the series of resistors R. In addition, a resistor R 'is interposed between on the one hand the base of the transistor T2 and secondly, a point connecting two resistors R to constitute with each resistor R a voltage divider. Thus, the resistors R connected in series make it possible to obtain a reference voltage equivalent to that of the LECs 44, the resistors R 'making it possible to obtain the biasing of the transistor T2 by obtaining a voltage greater than that of the LEC) 44. The defective LEC (s) can be replaced by new LECs that emit light again without disturbing the operation of the other LECs). To detect the malfunction of certain LECs), it is possible to associate with the light source a device as described in the patent application FR-0650986 capable of measuring the light intensity emitted by the source.

  When the latter falls below a predetermined threshold corresponding to a predetermined number of defective LECs, an alert is transmitted. Thus warned, the operators in charge of the maintenance replace the LECs) not working anymore.

  The presence of a new LEC) 44 which lights up the associated sensing element 60 again makes it possible to switch back the transistors and no longer short-circuit the new LEC) instead of a defective LEC). As a variant, instead of providing a single LEC) associated with a photosensitive diode and a bypass circuit controlled by a transistor T2 for short-circuiting said LEC, two or three LECs could be provided arranged in series associated with a light-sensitive diode. and a bypass circuit controlled by a transistor T2 for short-circuiting said LECs). Thus, as soon as the photosensitive diode detects the malfunction of at least one LEC), the transistor T2 switches and bypasses the series of LECs associated with the light-sensitive diode.

  It is difficult to foresee more than three LECs associated with a light-sensitive diode, otherwise the dysfunction of a single LEC would lead to too many LECs short-circuited and therefore to excessive alteration of the light source. In addition, the operator in charge of maintenance should in this case change the series of LECs) short-circuited including the LEC) defective which would lead to a loss of time and to change LECs in perfect condition. In Figure 7, there is shown an improved variant. According to this arrangement, a Zener diode 64 may be arranged in parallel with each LEC) 44. This arrangement allows start-up when the LECs 44 do not work and do not illuminate the element 60 to prevent the transistor T2 from tilting. According to another improvement, the means 62 for short-circuiting a LEC) comprise three transistors Ti, T2, T3 whose base is connected to that of the transistor T2 to avoid too much voltage when several LEb 44 no longer work. This arrangement makes it possible to avoid oversizing the components, in particular transistors T1 and T2. In FIG. 7, only two stages are shown, the latter being able to be multiplied as a function of the number of LEb 44 required. In Figure 8, there is shown an electrical component corresponding to a protected LEb, allowing when several components are arranged in series to operate LEb in series. Thus, the application of this component is not limited to public lighting but it can be used when it is necessary to operate light emitting diodes in series. This component may include in its minimalist version a LEb 44, means 60 for detecting a malfunction of said LEb and means 62 for short-circuiting the LEb when the latter is defective.

Claims (18)

  1. A method for managing light-emitting diodes (44) arranged in series so as to constitute a light source (42), characterized in that it consists in providing a bypass for each light-emitting diode (44) and / or each group of one a limited number of light-emitting diodes in series, detecting the malfunction of a light-emitting diode (44) and short-circuiting the defective light-emitting diode or the light-emitting diode group having the defective light-emitting diode through the associated bypass.   2. A method for managing light-emitting diodes (44) arranged in series so as to constitute a light source (42) according to claim 1, characterized in that it consists for each light-emitting diode and / or each group of a limited number series of light-emitting diodes for detecting the malfunction of one or more associated light-emitting diode (s) with a photosensitive member (60), particularly a diode.   3. A method for managing light-emitting diodes (44) arranged in series so as to form a light source (42) according to claim 1 or 2, characterized in that it consists for each light-emitting diode and / or each group of a limited number of light-emitting diodes in series to short-circuit the defective light-emitting diode or the group of light-emitting diodes including the defective light-emitting diode by at least one transistor T2 whose collector is connected upstream of the light-emitting diode or the group of light-emitting diodes associated and the transmitter is connected downstream of the light emitting diode or group of associated light emitting diodes.   4. A light source comprising light-emitting diodes in series, characterized in that it comprises, for each light-emitting diode (44) and / or each group of a small number of light-emitting diodes in series, means (60) for detecting the malfunction of the light-emitting diode. a light-emitting diode (44) and means (62) for short-circuiting the defective light-emitting diode or the light-emitting diode array having the defective light-emitting diode when the means (60) has detected a malfunction.   5. A light source comprising light emitting diodes in series according to claim 4, characterized in that it comprises a photosensitive element (60), in particular a diode, for each light-emitting diode (44) and / or each group of a limited number electroluminescent diodes in series, for detecting the malfunction of a light emitting diode (44).   6. Light source comprising light emitting diodes in series according to claim 4 or 5, characterized in that it comprises at least one transistor T2 whose collector is connected upstream of the light emitting diode or the group of associated light emitting diodes and the electroluminescent light emitting diode. The emitter is connected downstream of the associated light emitting diode or light emitting diode array to short circuit a defective light emitting diode or a group of light emitting diodes having a defective light emitting diode when the means (60) has detected a malfunction.   7. Light source comprising light emitting diodes in series according to claim 6, characterized in that it comprises two transistors T2 and Ti, Ti for amplifying the signal emitted by the photosensitive element (60) and received by the transistor T2 .   8. Light source comprising light emitting diodes in series according to any one of claims 4 to 7, characterized in that it comprises means (68) for regulating the current upstream of the light emitting diodes arranged in series in order to deliver a current. substantially constant and adjust said current as a function of the desired light intensity.   9. Light source comprising light emitting diodes in series according to any one of claims 4 to 8, characterized in that it comprises, associated with each light emitting diode (46), a means (46) of diffusion in the form of a truncated cone whose small end is contiguous against the associated light-emitting diode.   10. Light source comprising light emitting diodes in series according to claim 9, characterized in that the means (46) of diffusion has an angle a adapted to focus more or less light, which increases as a function of the distance from the center of the task formed by said light source.   11. Light source comprising light emitting diodes in series according to any one of claims 4 to 10, characterized in that it comprises a support (48) on which are reported the light emitting diodes (44) and associated with each light emitting diode (44), means (56, 58) for holding the light emitting diode against said support (48).   12. An electrical component for operating light-emitting diodes in series, characterized in that it comprises a light-emitting diode (44), means (60) for detecting the malfunction of said light-emitting diode (44) and means (62) for bypassing said defective light-emitting diode when the means (60) has detected a malfunction.   13. Electrical component according to claim 12, characterized in that it comprises a photosensitive member (60) for detecting the malfunction of the light emitting diode (44).   14. The electrical component according to claim 13, characterized in that the photosensitive element (60) is a light-emitting diode.   15. An electrical component according to claim 12, 13 or 14, characterized in that it comprises at least one transistor T2 whose collector is connected upstream of the light-emitting diode, the emitter is connected downstream of the light-emitting diode, the means (60) being connected to the base of the transistor T2.   16. Electrical component according to claim 15, characterized in that it comprises a transistor Ti interposed between the transistor T2 and the means (60) for detecting the malfunction of the light emitting diode (44).   17. Electrical component according to claim 16, characterized in that it comprises three transistors, the transistor T3 having its base connected to that of the transistor T2.   18. Electrical component according to any one of claims 12 to 17, characterized in that it comprises a Zener diode in parallel with the light emitting diode (44).