FR3102539A1 - LED lighting system - Google Patents

Abstract

Continuous lighting system comprising at least: an LED lighting device (1) comprising at least two LED modules (6) arranged within the same ribbon or projector, andan electronic system for supplying the device supplying the LED modules (6) sequentially, with a supply duration of at least 0.5 hours for a module before switching to the supply of the next one Figure for abstract: Fig. 1

Description

LED lighting system

The present invention relates to an LED lighting system.

The use of LED projectors and lighting strips tends to grow due to their light output and ease of installation.

Most current LED lighting devices are designed to operate on cycles of 12 hours maximum. Beyond that, there is a risk of deterioration of the LEDs and therefore of loss of luminosity, as well as the risk of overheating, or even of fire.

The invention aims to remedy these problems and relates to a continuous lighting system comprising at least:

an LED lighting device comprising at least two LED modules, arranged within the same ribbon or projector, and

an electronic system for powering the device that powers the LED modules sequentially, with a power supply duration of at least 0.5 hours for one module before switching to the power supply for the next.

For example, the LED modules are alternately powered with a continuous lighting time of at least 0.5 hours for some of the modules before the lighting of the rest of the modules, preferably for the same duration.

The duration of continuous lighting of a module is preferably more than one hour, better still more than 3 hours, before switching to the power supply of another module.

The sequential supply of the modules can be done at a given power, preferably the nominal power, each of the modules illuminating during the sequence when it is its turn, at this power. During the period when a module is not powered at this power, it can be completely switched off, or alternatively be powered at a low power which does not pose a lifespan problem, for example less than 50% of the power nominal. This increases the light output.

The invention makes it possible to obtain a lighting device operating 24 hours a day while reducing the risk of overheating of the LEDs and their rapid deterioration. Consequently, the invention allows an increase in the service life of the lighting device, without this increase being made to the detriment of the ease of installation or of the light output. If the lighting device is a ribbon, its length can be 100m, 200m or more.

The lighting device may comprise two groups of LED modules within the ribbon or projector, the groups of LED modules being powered sequentially.

Each group can form a row extending along a longitudinal direction of the ribbon, and the two rows can be arranged side by side. Alternatively, the two groups form the same row extending along a longitudinal direction of the ribbon. The LED modules of said groups can alternate in the longitudinal direction of the strip. In another variant, at least one group may comprise at least two rows arranged side-by-side and each extends along a longitudinal direction of the ribbon.

The electrical power of a group of LED modules is for example greater than or equal to 100W. The light output of an LED module is, for example, greater than or equal to 800 Lumen.

Preferably, in the presence of two rows of LED modules arranged side by side and powered sequentially, each row of LED modules is a standard component, and the LED modules of the same row are thus advantageously electrically connected in parallel.

All the LED modules of the lighting device can have terminals connected to a common supply conductor of the supply electronics. This can make it possible to reduce the number of electrical supply conductors necessary for supplying the ribbon to N+1, where N is the number of groups, in particular of rows or groups of rows controlled sequentially.

The lighting device can comprise more than two groups supplied sequentially, which makes it possible to further reduce the duration of supply per daily cycle of each group of LEDs.

The lighting device can thus be a ribbon comprising three groups of LED modules and the electronic supply system can be arranged to supply them sequentially.

The tape may comprise at least two rows electrically connected together so as to be powered at the same time. The strip comprises for example at least a first group of two rows of LED modules and a second group of two rows of LED modules, the first group and the second group of LED modules being powered sequentially.

When the ribbon or other lighting device comprises more than two rows of LED modules, for example at least three rows R1, R2 and R3, it is possible to successively power the rows R1, R2 and R3 during a cycle. of operation, so that the continuous duration of use of each row is less than or equal to the duration of the cycle, in particular less than or equal to 50% of this duration, preferably less than or equal to 12 hours. It is still possible to light the two rows R1 and R2 alternately with the third row R3, to benefit for example from additional lighting for a certain period.

In a variant, the ribbon comprises a single row of LED modules comprising at least a first and a second group of LED modules, and the electronic system for supplying the ribbon supplies the groups of LED modules sequentially. The LED modules of these groups can be arranged side by side along the longitudinal direction of the strip.

The supply system can also be configured to allow, on request, to temporarily supply a greater number of groups than that corresponding to a use where the groups are supplied sequentially, for example all the groups of the ribbon. The power supply system may comprise a manual selector making it possible to selectively control each group of LED modules, or to pass from an operating mode with sequential ignition preserving the lifespan of the modules to a mode of more intense lighting or at least two groups normally on successively during sequential mode are on simultaneously.

The electronic power supply system is preferably connected to the network, in particular at 220V AC, or less, for example at 160V, in emergency mode. Alternatively, the power supply is 24V DC or more generally by any other suitable type of power supply. The network can be supplemented by a UPS operating on batteries or by any other backup system.

The power electronics may include one or more sequentially controlled relays to power respective LED modules of the strip. These relays can belong to a PLC or to time or twilight switches. By temporally shifting the latter, it is possible to obtain a sequential ignition of the LED modules, in particular of the rows of LED modules, possibly with a temporal overlap of the ignitions.

The electronic power supply system may further comprise one or more relays configured to modify the power supply of the lighting device, for example when the presence of people is detected by a detection system, or in the event of loss of power supply network.

The ribbon conventionally comprises a transparent flexible sheath in which the groups of LED modules are arranged. This sheath provides watertightness and allows installation by unrolling the tape.

Groups of LED modules can share a medium such as a flexible printed circuit. Thus, the lighting device may comprise a printed circuit, flexible or not, common to the LED modules supplied sequentially.

Preferably, the electronic power supply system is configured to supply at least one LED module for an uninterrupted period of between 3 and 12 hours before supplying at least one other module, but this duration can be adapted according to the needs of the work to be lit and recommendations for the use of LED modules.

The invention also relates to a method for lighting a structure, in particular a tunnel, in which a system according to the invention as defined above is used, by supplying sequentially at least two LED modules of the lighting device in such a way that the power supply duration of each group per daily operating cycle is less than or equal to 12 hours. This power supply can be done with temporal recovery or not of the power supplies of the LED modules; for example, one LED module is on at the same time as another LED module is off, or one LED module is on before the other LED module is off. Preferably, the lighting sequence of the LED modules during an operating cycle remains the same from one cycle to another, the duration of the cycle being for example 24 hours or more. The ignition sequence can be programmed in advance.

Each LED module or group of LED modules can be powered by an unfiltered rectified DC voltage between 150 and 250V. Alternatively, the power supply is carried out under another voltage, for example 24V DC depending on the type of LED used.

The structure thus lit can be a tunnel under construction or development, which must be permanently lit.

Other characteristics and advantages of the present invention will become apparent on reading the detailed description which follows, of non-limiting examples of embodiment thereof, and on examining the appended drawing, in which

FIG. 1 schematically represents a lighting system according to the invention;

Figure 2 schematically shows in cross section the tape of Figure 1;

FIG. 3 schematically represents a variant of a lighting system according to the invention;

FIG. 4 schematically represents another variant of a lighting system according to the invention,

FIG. 5 schematically represents another variant of a lighting system according to the invention,

FIG. 6 represents an ignition mode of a variant of a lighting system according to the invention,

FIG. 7 represents an ignition timing diagram for the modules according to FIG. 6,

FIG. 8 represents a variant of an ignition timing diagram for the modules according to FIG. 6,

FIG. 9 schematically represents another variant of a lighting system according to the invention.

There is illustrated in Figure 1 a lighting system 30 comprising a lighting device 1 according to the invention, in the form of a ribbon.

The ribbon comprises two rows 11 of LED modules 6 arranged side by side on a support 9 such as a flexible printed circuit, inside a transparent plastic sheath.

Each row 11 extends along a longitudinal direction X of the strip 1.

The LED modules 6 of the same row 11 are preferably spaced evenly.

The LED modules 6 of the same row 11 are electrically connected in parallel. Each module 6 may include at least one LED diode 2 on a support 3, as shown in Figure 2.

In a variant not shown, each module comprises several LED diodes.

In the embodiment of FIGS. 1 and 2, the LED modules 6 of a row 11 and those of another row 11 have their positive terminals 21 connected to two different supply conductors 7 of an electronic supply system. of the ribbon 1. All the LED modules 6 of the ribbon 1 have their negative terminals 22 connected to a common supply conductor 7 of the electronic supply system.

The electronic power supply system may comprise a rectifier bridge and a set of electrical relays to each control a row 11 of LED modules of the ribbon. These relays are for example driven by a controller or one or more clocks. The electronic power supply system makes it possible to supply the ribbon with an adequate voltage, for example an unfiltered rectified DC voltage between 150 and 250V, preferably around 200V, present at the output of the rectifier bridge.

The power supply system is configured in such a way as to supply each row 11 discontinuously during an operating cycle. For example, each row is supplied for a period less than or equal to 12 hours each day.

In the embodiment illustrated in FIG. 3, the ribbon 1 comprises three rows 11 of LED modules 6 operating sequentially. The electronic power supply system then comprises four output terminals connected to as many supply conductors 7.

The LED modules 6 of each row 11 have for example, as illustrated, their positive terminals 21 connected to a respective supply conductor. All LED modules 6 of ribbon 1 have their negative terminals 22 connected to a common supply conductor.

In the embodiment illustrated in FIG. 4, the ribbon 1 comprises a first group 31 of two rows 11 of LED modules 6 and a second group 32 of two rows 11 of LED modules 6. The LED modules 6 of the rows 11 of the first group 31 have their positive terminals 21 all connected to a first common supply conductor 7 and the LED modules 6 of rows 11 of the second group 32 have their positive terminals 21 all connected to a second common supply conductor 7, different from the first common power conductor. All the LED modules 6 of the strip 1 have their negative terminals 22 connected to a third common supply conductor 7. The first 31 and second 32 groups of LED modules are supplied sequentially.

In the embodiment illustrated in FIG. 5, the LED lighting device 1, in the form of a projector, comprises a first group 31 and a second group 32 of LED modules arranged within the projector and each comprising three rows 11 of LED modules 6. Unlike FIG. 4, the rows 11 of the two groups 31, 32 are arranged in an interleaved manner in this example. Any other way of arranging the groups of LED modules does not depart from the scope of the present invention.

The groups 31, 32 are supplied sequentially according to the invention, that is to say the rows 11 of the first group 31 are supplied for a supply duration of at least 0.5 h before switching to the supply rows 11 of the second group 32 and vice versa.

Figure 6 illustrates an ignition sequence of the modules 6 of a system according to the invention. The system comprises a first group 31 and a second group 32 of two rows 11 of LED modules 6 supplied alternately.

FIG. 7 illustrates the ignition timing diagram of two modules belonging respectively to the first and second groups 31, 32.

As illustrated in FIG. 6, initially, the LED modules 6 of the first group 31 are supplied continuously at their nominal voltage U0 for a supply duration T0. During this time, the LED modules 6 of the second group 32 are off. The timing diagram G1 of FIG. 7 represents the variation of the supply voltage over time of a module 6 belonging to the first group 31 and the timing diagram G2 represents the variation of the supply voltage over time of a module 6 apartment in the second group 32. T0 is at least 0.5h, preferably at least 3h.

As illustrated in FIGS. 6 and 7, at the end of the supply duration T0, the modules 6 of the first group 31 are switched off and the modules 6 of the second group 32 are in turn supplied continuously at their nominal voltage U0, for the same supply duration T0, and so on.

In the variant illustrated in FIG. 8, while the LED modules 6 of the first group 31 are supplied continuously at their nominal voltage U0 during the supply duration T0, the LED modules 6 of the second group 32 are supplied continuously. at reduced voltage, and vice versa. In the example shown, the reduced voltage is for example equal to half the nominal voltage U0.

In the embodiment illustrated in Figure 9, the strip comprises four groups 31, 32, 33, 34 of modules 6 forming the same row extending in a longitudinal direction X of the strip. The modules 6 of these groups 31, 32, 33, 34 are intended to be powered sequentially.

The invention is not limited to the illustrated embodiments.

For example, the modules in the first group may have a nominal voltage when powered that is different from that of the modules in the second group.

The modules of the first group can be supplied continuously at their nominal voltage for a supply duration which is different from that during which the modules of the second group are supplied continuously at their nominal voltage.

The system can consist of LED modules with different lighting properties or supplied with voltage. The ribbon may comprise two groups whose respective LED modules alternate in the longitudinal direction, the modules of these groups being intended to be powered sequentially.

Claims (12)

Continuous lighting system (30) comprising at least:
an LED lighting device (1) comprising at least two LED modules (6) arranged within the same ribbon or projector, and
an electronic system for supplying the device supplying the LED modules (6) sequentially, with a supply duration of at least 0.5 hours for one module before switching to supplying the next one. System according to claim 1, the lighting device comprising two groups of LED modules (6) within the strip or the projector, the groups of LED modules being powered sequentially. System according to claim 2, the LED modules of the same group being electrically connected in parallel. System according to any one of Claims 1 to 3, all the LED modules (6) of the lighting device having terminals (22) connected to a common supply conductor (7) of the electronic supply system. System according to any one of Claims 1 to 3, the lighting device comprising three groups of LED modules (6) and the electronic supply system being arranged to supply them sequentially. System according to any one of Claims 1 to 3, the lighting device being a strip comprising at least two groups of LED modules (6) supplied sequentially, each group forming a row (11) extending in a direction longitudinal (X) of the tape, the rows being arranged side by side. System according to any one of Claims 1 to 3, the lighting device being a strip comprising at least a first group (31) of two rows (11) of LED modules (6) arranged side-by-side and each extending along a longitudinal direction (X) of the strip (1) and a second group (32) of two rows (11) of LED modules (6) arranged side-by-side and each extending along a longitudinal direction (X ) of the ribbon (1), the first group (31) and the second group (32) of LED modules (6) being powered sequentially. System according to any one of Claims 1 to 3, the lighting device being a strip comprising at least two groups (31, 32, 33, 34) of LED modules (6) forming the same row (11) extending along a longitudinal direction (X) of the tape, the modules (6) of these groups (31, 32, 33, 34) being intended to be fed sequentially. A system according to any preceding claim, the power electronics comprising one or more sequentially controlled relays to power respective LED modules of the lighting device. System according to any one of the preceding claims, the lighting device comprising a flexible printed circuit (3) common to the LED modules supplied sequentially. System according to any one of the preceding claims, the electronic supply system being configured to supply power to at least one LED module for an uninterrupted period of between 3 and 12 hours before supplying power to at least one other LED module. Method of lighting a structure, in particular a tunnel, in which a system is used according to any one of Claims 1 to 11, by supplying sequentially at least two LED modules of the lighting device (3) in such a way that the power supply duration of each LED module per daily operating cycle is less than or equal to 12h.