EP2811812A2 - Circuit and method for supplying diodes, lighting device made up of diodes including such a circuit - Google Patents

Abstract

A circuit for powering an array (102) of diodes with a DC and constant power supply signal, said power supply, said diode array (102) comprising a group (106) of a plurality of diodes ( 106), said series, connected in series, said circuit being characterized in that it comprises a regulation module (300) provided for: - shorting at least one of said series diodes (106) when the feed signal decreases, and - Supply, or supply, at least one of said series diode (106) previously unpowered, or short-circuited, when the supply signal increases. It also relates to a lighting device based on LEDs implementing such a circuit and a method of supplying a set of LEDs.

Description

The invention relates to a circuit for powering a set of diodes. It also relates to a diode supply method and a lighting device comprising such a circuit.

The field of the invention is the field of supplying diodes, and more particularly light-emitting diodes, commonly called LEDs ("light emitting diodes" in English). More generally, the field of the invention is the field of lighting devices based on diodes, and more particularly on LEDs.

State of the art

Currently, LED-based lighting devices have multiple advantages, mainly related to low energy consumption, lifetime, and so on. LEDs. In addition, the lighting obtained by a device based on LEDs is less aggressive because less emitter ultraviolet.

As a result, LED-based lighting devices have been developing strongly in recent years, regardless of the area concerned.

However, as regards the domestic domain, ie the field of lighting devices proposed to the general public and operating on a sector, there are challenges to overcome, in particular because the LEDs are very fragile due to at their reduced operating voltage, of the order of 3V DC, compared to the supply signal supplied by the sector 110V or 220V AC. Consequently, a lighting device based on LEDs intended to be powered directly by the mains requires a so-called power supply block, which performs a filtering / filtering of the signal supplied by the sector.

The power supplies are very often bulky and constitute a barrier to the design of lighting devices based on LEDs of reduced dimensions. In addition, the power supplies have an additional cost, in the manufacture of LED-based lighting devices, reduce the overall efficiency of LED-based lighting devices, increase design complexity, reduce the life of LED-based lighting devices.

The invention aims to overcome the aforementioned drawbacks.

In particular, the object of the invention is to propose a power supply circuit for LEDs, and more generally for diodes, avoiding the use of a power supply unit when powering the sector, and more generally from a source of power. supply providing a non-constant power supply signal over time.

Finally, another object of the invention is to propose a circuit for supplying LEDs, and more generally diodes, enabling the design of lighting devices based on LEDs that are simple to produce, less expensive, operating at a higher efficiency. high, more compact and more robust.

Presentation of the invention

• court-circuiter au moins une desdites diodes série lorsque le signal d'alimentation diminue, en particulier lorsque le courant d'alimentation diminue, et
• alimenter, ou réalimenter, au moins une diode série préalablement non alimentée, ou court-circuitée, lorsque le signal d'alimentation augmente, en particulier lorsque le courant d'alimentation augmente.

The invention makes it possible to achieve at least one of the above-mentioned objects by a circuit for powering a set of diodes, in particular LEDs, with a DC and constant-current electrical signal, said supply signal, said set of diodes comprising a group of a plurality of diodes, called series, connected in series, said circuit being characterized in that it comprises a regulation module provided for:

• shorting at least one of said series diodes when the supply signal decreases, particularly when the supply current decreases, and
• supplying, or re-supplying, at least one pre-energized or short-circuited series diode when the supply signal increases, in particular when the supply current increases.

The circuit according to the invention therefore proposes to modulate the number of diodes supplied as a function of the fluctuations of the supply current. In other words, the circuit according to the invention makes it possible to reduce respectively to increase, the number of diodes actually fed when the supply current decreases, respectively increases. Thus, the circuit according to the invention makes it possible to keep substantially the same voltage at the terminals of powered diodes, or in any case to reduce the fluctuations of the current in the diodes actually fed.

By providing enough diodes in series, which can be short-circuited when the supply current drops and fed (or replenished) when the supply current increases, it is possible to dispense with a power supply. In other words, the circuit according to the invention makes it possible to supply LEDs, particularly from the mains, without using a power supply unit.

The circuit according to the invention thus makes it possible to produce lighting devices based on diodes, and particularly LEDs, which are simpler, less expensive, more compact and more robust.

In addition, the circuit according to the invention provides a higher operating efficiency because it makes it possible to exploit the entire supply signal, and to avoid losses related to a power supply unit.

Moreover, the circuit according to the invention makes it possible to produce lighting devices based on diodes which can be directly connected to the sector because the variations of the current will be absorbed by the circuit according to the invention, without the use of a block of diodes. 'food.

The circuit according to the invention also makes it possible to design lighting devices based on more robust LEDs, having a longer lifetime in phase with the lifetime of the LEDs.

Finally, the circuit according to the invention operates with any voltage / power / supply current.

• au moins un moyen, dit de court-circuit, qui :
  • ■ dans un premier état, autorise le passage du courant dans au moins une diode série, de sorte que ladite au moins une diode série est alimentée par le signal d'alimentation, et
  • ■ dans un deuxième état, court-circuite ladite au moins une diode série, de sorte que ladite au moins une diode n'est plus alimentée par le signal d'alimentation ; et
• au moins un moyen de commande dudit au moins un moyen de court-circuit, de sorte que :
  • ■ l'au moins un moyen de court-circuit est positionné dans ledit deuxième état lorsque le signal d'alimentation diminue, et donc ladite au moins une diode série qui lui est associée est court-circuitée, et
  • ■ l'au moins un moyen de court-circuit est positionné dans ledit premier état lorsque le signal d'alimentation augmente, et donc ladite au moins une diode série qui lui est associée est alimentée ou réalimentée par le signal d'alimentation.

According to an advantageous embodiment, the regulation module can comprise:

• at least one means, called a short-circuit, which:
  • In a first state, allows the passage of current in at least one series diode, so that said at least one series diode is powered by the supply signal, and
  • In a second state, bypassing said at least one series diode, so that said at least one diode is no longer powered by the supply signal; and
• at least one means for controlling said at least one short-circuit means, so that:
  • The at least one short-circuit means is positioned in said second state when the supply signal decreases, and therefore said at least one associated series diode is short-circuited, and
  • The at least one short-circuit means is positioned in said first state when the supply signal increases, and therefore said at least one associated series diode is powered or fed back by the supply signal.

Thus, the control module has an architecture easy to achieve, using inexpensive elements and small dimensions.

• le nombre de moyens de court-circuit positionnés dans le deuxième état augmente progressivement au fur et à mesure que le signal d'alimentation diminue, et par conséquent le nombre de diodes séries court-circuitées augmente au fur et à mesure que le signal d'alimentation diminue, et
• le nombre de moyens de court-circuit dans le premier état augmente progressivement au fur et à mesure que le signal d'alimentation augmente, et par conséquent le nombre de diodes séries alimentées ou réalimentées augmente au fur et à mesure que le signal d'alimentation augmente.

According to a preferred embodiment, the regulation module may comprise a plurality of short-circuit means, each short-circuit means being designed to be associated with at least one series diode, said at least one control means being arranged to each of said short-circuit means is controlled in turn, so that:

• the number of short-circuit means positioned in the second state gradually increases as the supply signal decreases, and therefore the number of short-circuited series diodes increases as the signal of diet decreases, and
• the number of short-circuit means in the first state gradually increases as the supply signal increases, and therefore the number of supplied or boosted series diodes increases as the power supply signal increases. increases.

Thus, by increasing the number of short-circuit means progressively, the invention makes it possible to achieve a finer modulation of the number of diodes actually supplied by the power supply signal, and therefore a finer regulation of the voltage across the diodes actually fed according to fluctuations in the supply current.

In addition, the use of a larger number of short-circuit means makes it possible to increase the number of series diodes that can be short-circuited or powered according to fluctuations in the supply current, and thus to cover a greater fluctuation of the supply current.

According to a preferred version, each short-circuit means may be provided to be associated with an identical number of diode (s) series (s), in particular two series diodes.

Thus, the series diodes are short-circuited and fed (or replenished) two by two. This characteristic constitutes a very advantageous compromise taking into account on the one hand the manufacturing cost of the circuit in terms of means and manufacturing time, and on the other hand the precision of the regulation.

Of course, in the circuit according to the invention, each short-circuit means may be associated with a single series diode. In this case, the control accuracy is greater.

Similarly, each short-circuit means may be associated with at least three series diodes. In this case, the cost price of the circuit is lower.

Alternatively, at least two shorting means may each be associated with a different number of series diodes. In this case, the accuracy of the regulation will be variable depending on the short circuit means involved.

According to the invention, the circuit may comprise a plurality of regulation modules, each regulation module being provided for regulating through a group of diodes connected in series and forming part of the set of diodes to be powered.

In this case, the circuit according to the invention comprises several regulation zones, and series diodes will be short-circuited and fed (or replenished) in several zones of the circuit, as a function of the variation of the supply signal.

According to an advantageous embodiment, at least one control module can be positioned at the beginning, respectively at the end circuit according to the invention, namely on the side of a larger, respectively smaller, supply potential.

In this case, as a function of the variation of the supply signal, the series diodes will be short-circuited and supplied at the upstream or downstream ends of the circuit according to the invention, thus allowing more discreet regulation for the user.

Advantageously, at least one, in particular each, short-circuit means may be a MOSFET transistor, intended to be connected to at least one series diode by the drain and the source.

In this case, the variation of the value of the voltage between the gate and the source of the MOSFET transistor, will automatically realize either a short-circuit or a supply (or a feed) of the mounted series diode (s). between the drain and the source of the MOSFET transistor.

Advantageously, the control means may be a bipolar transistor.

In this case, the variation of the voltage between the base and the emitter of the transistor will cause the automatic variation of the value of the current and the potential at the collector of the bipolar transistor, this variation being able to be used as a control signal of a transistor. or short circuit means, such as, for example, a short-circuit means formed by a MOSFET transistor.

According to a preferred embodiment and in no way limiting, the circuit according to the invention may comprise a regulation module positioned at the end of the circuit, that is to say on the side of a lower supply potential. The control module can include several short-circuit means and a single control module.

The control module may comprise a bipolar transistor mounted as a common emitter and whose base is connected / connected downstream of the last diode of the set of diodes, so that the voltage between the base of the bipolar transistor and the emitter of the Bipolar transistor is proportional to the current flowing through each of the diodes connected in series. For this, a resistor can be connected in series with the series diodes and between the base and the emitter of the bipolar transistor. In this configuration, the voltage V _BE between the base and the emitter of the bipolar transistor is directly proportional to the supply current flowing through the diodes. When the voltage V _BE varies, the control current I _C of the collector of the bipolar transistor also varies and is used to control the short-circuit means.

• associé à deux diodes montées en séries, c'est-à-dire court-circuiter et alimenter (ou réalimenter) les diodes séries deux par deux ;
• formé par un transistor MOSFET dont :
  • la grille est reliée/connectée au collecteur du transistor bipolaire,
  • le drain est relié en amont desdites deux diodes montées en série, et
  • la source est reliée en aval desdites deux diodes montées en série.

Each shorting means can be:

• associated with two diodes mounted in series, that is to say, short-circuit and power (or replenish) diodes series two by two;
• formed by a MOSFET transistor of which:
  • the gate is connected / connected to the collector of the bipolar transistor,
  • the drain is connected upstream of said two diodes connected in series, and
  • the source is connected downstream of said two diodes connected in series.

Thus, the current I _C of the bipolar transistor controls the potential of the gate of each MOSFET transistor in turn and progressively.

When the supply current decreases, in turn and starting with the MOSFET transistor closest to the bipolar transistor, the voltage between the gate and the source V _GS of each MOSFET transistor increases and reaches a threshold voltage causing the opening of the MOSFET transistor, and consequently a short circuit appears between the drain and the source of the MOSFET transistor. The opening of the MOSFET transistor bypasses the series diodes placed between the drain and the source of the transistor.

As the supply current increases, reverse operation occurs. In turn and starting with the MOSFET transistor in "short-circuit" operation farthest from the bipolar transistor, each MOSFET transistor leaves the short-circuit operation and closes, and the diodes are between the drain and the source of this transistor are powered or recharged.

The circuit according to the invention can be in the form of an integrated circuit or in the form of a standard electronic card.

The circuit according to the invention may further comprise a constant current regulator arranged upstream of the set of diodes.

Such a constant current regulator may for example be a pre-biased transistor ("pre-biased transistor") mounted in series with the set of diodes.

Such a current regulator is particularly useful when the regulation capacity, provided and obtained by the regulation module, is exceeded.

The circuit according to the invention may further comprise a means of protection against high voltages.

The high voltage protection means may for example be a transil diode connected in parallel with the set of diodes.

The circuit according to the invention may further comprise a current rectifier module, providing the constant current power supply signal from an AC power source, such as the mains.

• un ensemble de diodes comprenant au moins un groupe de diodes montées en série entre-elles, et
• un circuit selon l'invention pour alimenter ledit ensemble de diodes.

According to another aspect of the invention there is provided a diode lighting device comprising:

• a set of diodes comprising at least one group of diodes connected in series with each other, and
• a circuit according to the invention for supplying said set of diodes.

Of course, all the diodes of the set of diodes can be connected in series with each other.

• au moins un premier groupe de diodes, dit principal, prévues pour être alimentées à tout moment lorsque ledit dispositif est alimenté par un signal d'alimentation, et
• au moins un deuxième groupe de diodes, dit de régulation, montées en série entre-elles, et dont au moins une est prévue pour être court-circuitée ou alimentée (ou réalimentée), en fonction des variations dudit signal d'alimentation ; et

le circuit pour alimenter les diodes comprenant au moins un module de régulation associé audit au moins un groupe de diodes de régulation.According to a particular version of the device according to the invention, the set of diodes can comprise:

• at least a first group of diodes, said main, designed to be powered at any time when said device is powered by a power signal, and
• at least a second group of diodes, said control, connected in series with each other, and at least one of which is provided to be short-circuited or powered (or recharged), as a function of the variations of said supply signal; and

the circuit for supplying the diodes comprising at least one control module associated with said at least one group of control diodes.

• détecter une variation dudit signal d'alimentation, en particulier du courant d'alimentation, et
• modifier le nombre de diodes série alimentées en fonction de ladite variation, ladite modification comprenant :
  • une mise en court-circuit d'au moins une diode alimentée lorsque le courant d'alimentation diminue, de sorte que ladite au moins une diode n'est plus alimentée, et
  • une connexion audit signal d'alimentation d'au moins une diode série non alimentée lorsque le courant d'alimentation augmente, de sorte que ladite au moins une diode préalablement non alimentée est alimentée par le signal d'alimentation.

According to yet another aspect of the invention, there is provided a method for supplying a set of diodes with a DC and constant current electrical signal, said power supply, said set of diodes comprising a group of a plurality of diodes, said series-connected series, said method comprising the following steps:

• detecting a variation of said supply signal, in particular of the supply current, and
• modifying the number of series diodes energized according to said variation, said modification comprising:
  • short-circuiting at least one energized diode when the supply current decreases, so that said at least one diode is no longer powered, and
  • a connection to said supply signal of at least one unpowered series diode when the supply current increases, so that said at least one previously unpowered diode is powered by the supply signal.

• la FIGURE 1 est une représentation schématique d'un premier mode de réalisation d'un module de régulation d'un circuit selon l'invention ;
• la FIGURE 2 est une représentation schématique d'un deuxième mode de réalisation d'un module de régulation d'un circuit selon l'invention ;
• la FIGURE 3 est une représentation schématique d'un exemple préféré de réalisation d'un module de régulation d'un circuit selon l'invention selon le deuxième mode de réalisation représenté sur la FIGURE 2 ;
• la FIGURE 4 est une représentation schématique d'un premier exemple de réalisation d'un circuit selon l'invention ;
• la FIGURE 5 est une représentation schématique d'un deuxième exemple de réalisation d'un circuit selon l'invention ; et
• la FIGURE 6 est une représentation schématique sous la forme d'un diagramme d'un procédé d'alimentation d'un ensemble de diodes selon l'invention.

Other advantages and characteristics will appear on examining the detailed description of non-limitative examples, and the appended drawings in which:

• the FIGURE 1 is a schematic representation of a first embodiment of a control module of a circuit according to the invention;
• the FIGURE 2 is a schematic representation of a second embodiment of a control module of a circuit according to the invention;
• the FIGURE 3 is a schematic representation of a preferred embodiment of a control module of a circuit according to the invention according to the second embodiment shown in FIG. FIGURE 2 ;
• the FIGURE 4 is a schematic representation of a first exemplary embodiment of a circuit according to the invention;
• the FIGURE 5 is a schematic representation of a second exemplary embodiment of a circuit according to the invention; and
• the FIGURE 6 is a diagrammatic representation in the form of a diagram of a supply method of a set of diodes according to the invention.

It is understood that the embodiments which will be described in the following are in no way limiting. It will be possible, in particular, to imagine variants of the invention comprising only a selection of characteristics described subsequently isolated from the other characteristics described, if this selection of characteristics is sufficient to confer a technical advantage or to differentiate the invention with respect to the state of the art. This selection comprises at least one feature preferably functional without structural detail, or with only a part of the structural details if this part alone is sufficient to confer a technical advantage or to differentiate the invention from the state of the prior art.

In particular, all the variants and all the embodiments described are combinable with each other if nothing stands in the way of this combination at the technical level.

In the figures, the elements common to several figures retain the same reference.

The FIGURE 1 is a schematic representation of a first embodiment of a control module of a circuit according to the invention.

The regulation module 100 represented on the FIGURE 1 allows to regulate in the context of the power supply of a set 102 of LEDs, connected in series with each other, by a constant DC power supply signal.

• un groupe 104 de LEDs, dit principal, montées en série entre-elles, prévues pour être alimentées à tout moment lorsque l'ensemble 102 de LEDs est alimenté par le signal d'alimentation et comprenant « k » LEDs référencées 104₁ à 104_k ; et
• un groupe 106 de LEDs, dit de régulation, montées en série entre-elles, prévues pour réaliser une régulation lorsque le signal d'alimentation varie, et comprenant « n » LEDs référencées 106₁ à 106_n.

In the embodiment shown on the FIGURE 1 , the set 102 of LEDs comprises:

• a group 104 of LEDs, said main, connected in series with each other, designed to be powered at any time when the set 102 of LEDs is powered by the power supply signal and comprising "k" LEDs referenced 104 ₁ to 104 _k ; and
• a group 106 of LEDs, said regulation, connected in series with each other, provided to achieve a regulation when the supply signal varies, and comprising "n" LEDs referenced 106 ₁ to 106 _n .

The group 104 and the group 106 are also connected in series with each other.

• autoriser le passage du signal d'alimentation, en particulier du courant d'alimentation, dans ladite LED de régulation à laquelle il est associé, dans un premier état : ce premier état sera appelé l'état « bloqué » dans la suite de la description ; et
• court-circuiter ladite LED de régulation à laquelle il est associé de sorte que ladite LED de régulation n'est plus parcourue par le signal d'alimentation, dans un deuxième état : ce deuxième état sera appelé état « court-circuit » dans la suite de la demande.

The regulation module 100 comprises "n" means 108 ₁ -108 _n short circuit, each associated with a control LED 106, and provided for:

• allow the passage of the supply signal, in particular the supply current, in said control LED to which it is associated, in a first state: this first state will be called the "blocked" state in the following description ; and
• bypassing said control LED to which it is associated so that said control LED is no longer traversed by the supply signal, in a second state: this second state will be called "short circuit" state in the following demand.

The control module also comprises a control means 110 for controlling each of the short-circuit means 108 as a function of the variation of the supply signal flowing through the set of LEDs 102.

The control means 110 detects the variations of the supply signal, and more particularly of the supply current, by means of a resistive element 112, which may be a resistor whose value is chosen as a function of the current flowing through the diodes.

The control means 110 is arranged to control each of the short-circuit means 108 in turn and progressively as a function of the variation of the supply signal, and in particular of the supply current.

• lorsque le courant d'alimentation diminue, commander, progressivement et à tour de rôle, le passage dans l'état « court-circuit », d'au moins un moyen de court-circuit 108, en commençant par le moyen de court-circuit 108 le plus proche qui est dans l'état bloqué, c'est-à-dire en commençant par le moyen de court-circuit 108 qui est dans l'état bloqué et qui a la plus grande référence ;
• lorsque le courant d'alimentation augmente, commander, progressivement et à tour de rôle, le passage dans l'état bloqué, d'au moins un moyen de court-circuit 108, en commençant par le moyen de court-circuit 108 le plus éloigné qui est dans l'état court-circuit, c'est-à-dire en commençant par le moyen de court-circuit dans l'état court-circuit qui a la plus petite référence.

In particular, the control means is arranged for:

• when the supply current decreases, control, progressively and in turn, the transition to the "short-circuit" state, of at least one short-circuit means 108, starting with the short-circuit means 108 which is in the off state, i.e. starting with the short circuit means 108 which is in the off state and has the largest reference;
• when the supply current increases, control, progressively and in turn, the transition to the off state, of at least one short-circuit means 108, starting with the farthest short-circuit means 108 which is in the short-circuit state, i.e. starting from the short-circuit means in the short-circuit state which has the smallest reference.

Assume the configuration in which the short-circuit means 108 _{1-108 n-1} are in the off state and the short-circuit means 108 _n is in the short circuit condition. In this configuration all the LEDs 106 are powered except the LED 106 _n associated with the short-circuit means 108 _n , the latter bypassing the LED 106 _n .

In this configuration, if the feed signal decreases by a predetermined value, this decrease is detected by means of control 110 through resistor 112. Control means 110 then identifies the nearest short circuit means 108 and is in the off state. This is the short circuit means 108 _n-1 . The control means 108 _n-1 is then commanded to go to the short-circuit state to short-circuit the LED 106 _n-1 associated with it: the decrease in the power signal is then compensated for at the level of the other LEDs. of the set of LEDs 102 which then receive more power. If the decrease of the supply signal continues, then the closest short-circuit means which is in the off state, i.e. the means 108 _n-2 (not shown), is then controlled to to switch to the short-circuit state, and so on the rest of the short-circuit means in turn from the short-circuit means 108 _n-4 to the short-circuit means 108 ₁ .

Suppose now the configuration in which all the short-circuit means 108 ₂ to 108 _n are in the short-circuit state and only the short-circuit means 108 ₁ is in the off state. In this configuration all the LEDs 106 ₂ -106 _n are short-circuited, that is to say non-powered, by the short-circuit means 108 ₂ -108 _n associated with them, except the associated LED 106 ₁ by means of short circuit 108 ₁ , the latter allowing the passage of the power supply signal in LED 106 ₁ .

In this configuration, if the supply signal increases by a predetermined value, this increase is detected by the control means 110 via the resistor 112. The control means 110 then identifies the short-circuit means 108. the farthest and that is in the state short circuit. This is the short circuit means 108 ₂ . The control means 108 ₂ is then controlled to go to the off state and allow the supply of the LED 106 ₂ associated with it, and the LED 106 ₂ is then powered: the increase of the power signal is then compensated at the other LEDs of the set of LEDs 102 which then receive less power. If the increase in the DC power signal, then the far short-circuit means which is in the short circuit condition, that is to say the short-circuit means 108 ₃ (not shown) , is then commanded to go to the off state, and so to continued on the remainder of the short circuit means in turn from the short-circuit means 108 ₄ to the short-circuit means 108 _n .

Thus, the regulation module dynamically regulates the voltage across each diode as a function of the variations in the current supplied, in particular by the sector.

The FIGURE 2 is a schematic representation of a second embodiment of the regulation module according to the invention.

The regulation module 200 represented on the FIGURE 2 includes all the elements of the regulation module 100 of the FIGURE 1 .

The only difference compared to the regulation module 100 of the FIGURE 1 consists in the fact that each short-circuit means 108 ₁ -108 _n is associated with two regulating diodes 106. In other words, each short-circuit means 108 _i makes it possible to short-circuit or supply two regulating diodes serial.

Therefore, as represented on the FIGURE 1 , the control group 106 comprises twice as many LEDs compared to the case of the FIGURE 1 .

Alternatively, it is also possible to keep the same number of LEDs in the control group as that represented on the FIGURE 1 . In this case, the control module will include half as many short circuit means.

Of course, it is also possible to associate a short-circuit means with more than two regulating diodes. Similarly, it is possible to use more than one control means.

The FIGURE 3 is a schematic representation of a preferred embodiment of a regulation module, according to the embodiment shown in FIG. FIGURE 2 .

The regulation module 300 represented on the FIGURE 3 comprises five short-circuit means which are MOSFET transistors 302 ₁ -302 ₅ . Each MOSFET transistor 302 is associated with two regulation diodes connected in series between the drain and the source of the transistor 302. MOSFET transistor 302 ₁ makes it possible to short-circuit or supply the diodes 106 ₁ and 106 ₂ , the MOSFET transistor 302 ₂ makes it possible to short-circuit or supply the diodes 106 ₃ and 106 ₄ , and so on.

• la base du transistor bipolaire 304 est reliée en aval de la dernière diode 106₁₀ de l'ensemble de diodes 102 ;
• le collecteur du transistor bipolaire 304 est relié à la grille de chacun des transistors MOSFET 302₁ à 302₅, et
• la résistance 112 est reliée entre l'émetteur du transistor bipolaire 304 et la base du transistor bipolaire 304 de sorte que :
  • ■ le courant traversant cette résistance 112 est égal au courant traversant les diodes alimentées, et
  • ■ la tension V_BE entre la base et l'émetteur est proportionnelle au courant traversant les diodes alimentées.

The regulation module 300 comprises a control means common to all the short-circuit means 302, which is a bipolar transistor 304 mounted downstream of the common emitter diodes 106. The bipolar transistor 304 is positioned so that:

• the base of the bipolar transistor 304 is connected downstream of the last diode ₁₀ 106 of the diode array 102;
• the collector of the bipolar transistor 304 is connected to the gate of each of the MOSFET transistors 302 ₁ to 302 ₅ , and
• the resistor 112 is connected between the emitter of the bipolar transistor 304 and the base of the bipolar transistor 304 so that:
  • The current flowing through this resistor 112 is equal to the current flowing through the powered diodes, and
  • The voltage V _BE between the base and the emitter is proportional to the current flowing through the diodes fed.

A resistor 306 connected on the one hand upstream of the group 106 of regulation diodes and on the other hand to the collector of the bipolar transistor 304 and the base of each of the MOSFET transistors 302 makes it possible to polarize all the transistors, and in particular the bipolar transistor 304 .

The operation of this regulation module 300 is as follows.

When the supply current supplying the set 102 of LEDs decreases, the voltage V _BE also decreases. When the voltage V _BE of the bipolar transistor 304 then decreases the current I _C of the collector of the bipolar transistor 304 decreases, and the potential V _C of the collector of the bipolar transistor 304 increases. The increase of the potential V _C of the collector of the bipolar transistor 304 is accompanied by the increase of the potential V _G of the gate of the closest MOSFET transistor, namely the MOSFET transistor 302 ₅ , and the voltage V _GS between the gate and the source of the MOSFET 302 ₅ also increases. When the voltage V _GS between the gate and the source of the MOSFET transistor 302 ₅ passes beyond a predetermined threshold (depending on the MOSFET transistor), this MOSFET transistor 302 ₅ opens and operates as if there was a short circuit between its drain and its source: this state corresponds to the state "short circuit" described above with reference to Figures 1 and 2 . Therefore, the control diodes 106 ₉ and 106 ₁₀ are shorted, and are no longer supplied.

Thus, the current I _C of the bipolar transistor 304 comes to control the potential of the gate of each MOSFET transistor 302 in turn and progressively.

When the supply current decreases, starting with the MOSFET transistor 302 which is the closest to the bipolar transistor 304, and which is in a closed state (this closed state corresponding to the blocked state described above with reference to FIGS. Figures 1 and 2 ), each MOSFET transistor 302 is short-circuited by the current I _C , in turn, that is to say that the transistor opens, and until the power signal stop decreasing.

As the supply current increases, reverse operation occurs. In turn and starting with the MOSFET transistor 302 which is furthest from the bipolar transistor 304, and which is in a short-circuit or open state, the MOSFET transistors 302 are turned on (or off) by the current I _C , that is to say in an operation in which there is no short circuit between the drain and the source, and until the supply current stops increasing.

This embodiment is particularly interesting because it enables automated regulation as a function of the variation of the supply signal, without software intelligence, without means of specific measurement of the current or the supply voltage, according to a very simplified architecture. involving standard and inexpensive components.

Of course, this embodiment can be implemented according to the embodiment of the FIGURE 1 , or whatever the number of control diodes associated with each short-circuit means.

The FIGURE 4 is a schematic representation of a first embodiment of a circuit according to the invention.

The circuit 400, represented on the FIGURE 4 includes the regulation module 300 of the FIGURE 3 .

The circuit 400 includes two ports 402, 404 for connection to an electrical source providing an AC power signal such as the mains.

The circuit 400 includes a resettable fuse 406.

The circuit 400 further comprises a pre-biased transistor 408 as constant current regulator, arranged upstream of the set 102 of diodes and in series with the set 102 of diodes.

The circuit 400 further comprises a current rectifier module 410, providing from the AC power signal a DC power signal. This module is arranged in parallel with the set 102 of LEDs and upstream of the pre-polarization transistor 408.

Finally, the circuit 400 comprises a transile 412. This transil, in conjunction with the resettable fuse 406, protects the circuit against very high voltages, such as voltages greater than or equal to 400V.

In the example shown on the FIGURE 4 , the circuit comprises a single regulation module operating with a single group of control LEDs, disposed at a downstream end of the set 102 of LEDs, relative to the port 402.

The FIGURE 5 is a schematic representation of a second embodiment of a circuit according to the invention.

The circuit 500 includes all the elements of the circuit 400 of the FIGURE 4 . In addition, the circuit 500 comprises a second regulation module 502 operating with a second group 504 of control LEDs, positioned at an end downstream of the set 102 of LEDs relative to the port 402.

In other words, the circuit 500 comprises a regulation module and an LED control unit at each of the ends of the set of LEDs 102.

The regulation module 502 comprises a control module which is a bipolar transistor as for the regulation module 302. The regulation module 502 also comprises four short-circuit means and each short-circuit means is a MOSFET transistor such as for the regulation module 302. Each MOSFET transistor is associated with two regulating diodes.

Of course, the circuit according to the invention can comprise as many regulation modules as desired, each regulation module operating with a group of control LEDs.

The FIGURE 6 is a schematic representation in the form of a diagram of an exemplary method according to the invention.

The method 600 comprises a step 602 for detecting a variation of the supply signal.

Next, a step 604 determines whether the variation is an increase or a decrease in the power signal.

If the variation is an increase, a step 606 provides power to an additional diode that was not powered before detecting the increase of the power signal.

If the variation is a decrease, a step 608 short circuits a diode that was energized before detecting the decrease in the power signal, so that it is no longer powered.

Of course, steps 604 and each of steps 606 and 608 can be performed at the same time.

The method 600 may include an optional step 610 measuring the amount of variation of the power signal and comparing that amount to a predetermined amount. Steps 606 and 608 can then be performed or not depending on this comparison.

Naturally, the invention is not limited to the examples which have just been described.

Claims (11)

A circuit (400; 500) for supplying a set (102) of diodes with a DC and constant power supply signal, said power supply, said plurality of diodes (102) comprising a group (106; 504) of a plurality of diodes (106), said series, connected in series, said circuit (400; 500) being characterized in that it comprises a control module (100; 300; 502) provided for: - shorting at least one of said series diodes (106) when the feed signal decreases, and - Supply, or supply, at least one of said series diode (106) previously unpowered, or short-circuited, when the supply signal increases. said regulation module comprising: a plurality of short-circuit means; a control module arranged to control said short circuit means in turn, said module controls: - being common to all of said control means, and - comprising a bipolar transistor detecting the variation of the current flowing through said diodes. Circuit (400; 500) according to the preceding claim, characterized in that each short-circuit means (108; 302) is designed to be associated with an identical number of diode (s) series (s) (106), in particular with two series diodes (106). Circuit (400; 500) according to any one of the preceding claims, characterized in that at least one, in particular each, short-circuit means is a MOSFET (302), provided to be connected to at least one diode series (106) through the drain and the source. Circuit according to (500) any one of the preceding claims, characterized in that it comprises a plurality of control modules (300; 502), each control module (300; 502) being provided for a group of diodes (106; 504). ) connected in series forming part of the set of diodes (102) to supply. Circuit (500) according to any one of the preceding claims, characterized in that at least one regulating module (502; 300) is positioned at the beginning, respectively at the end of said circuit (500), on the side of a potential d larger power supply, respectively smaller. Circuit (500) according to one of the preceding claims, characterized in that it is in the form of an integrated circuit. Circuit (500) according to any one of the preceding claims, characterized in that it comprises at least one regulation module (300) positioned at the end of said circuit (500) and comprising several short-circuit means (302), and in that : - The control means of said control module comprises a bipolar transistor (304) mounted as a common emitter and whose base is connected / connected downstream of the last diode of the set of diodes; each short-circuit means of said regulation module (300) is: - associated with two diodes (106) mounted in series, and formed by a MOSFET transistor (302) of which: the gate is connected to / connected to the collector of the bipolar transistor (304), the drain is connected upstream of said two diodes connected in series (106), and - The source is connected downstream of said two diodes connected in series (106). Circuit (400; 500) according to one of the preceding claims, characterized in that it comprises a regulator (408) of constant current arranged upstream of the set of diodes (102). A circuit (400; 500) as claimed in any one of the preceding claims, characterized in that it comprises a current rectifier module (410) supplying the constant current power supply signal from an AC power source. Diode lighting device comprising: a set of diodes (102) comprising at least one group (106; 504) of diodes connected in series with each other, and a circuit (400; 500) according to any one of the preceding claims for supplying said set of diodes (102). Device according to the preceding claim, characterized in that the set of diodes (102) comprises: at least a first group of diodes (104), said to be main, designed to be powered at any time when said device is powered by a supply signal, and - At least a second group of diodes (106; 504), said control, connected in series with each other, and at least one is provided to be short-circuited or powered (or recharged), depending on the variations of said signal feeding; and the circuit (400; 500) comprising at least one control module (300; 502) associated with said at least one control diode group (106; 504).

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