EP2094062A1 - Lighting device for a home appliance, in particular a exhaust hood - Google Patents

Abstract

The appliance has a lighting device (1) e.g. halogen lamp, formed by LEDs, and a power supply circuit (2) for powering the lighting device. The supply circuit includes a power supply transformer (3) supplying power to a regulatory circuit (4). The regulatory circuit regulates a supply parameter of the lighting device, where the parameter is based on type and/or number of LEDs. The supply circuit includes a limiter circuit (5) mounted between the transformer and the regulatory circuit so as to limit value of electrical output voltage (VST) of the transformer to a predetermined value.

Description

The present invention relates to an appliance and in particular a suction hood.

The present invention is particularly aimed at an illumination device of a household appliance.

Appliances often have lighting or lighting devices.

For example, a fume hood typically includes an illumination device used to illuminate the surface beneath it, usually a hob.

These illumination devices may include incandescent lamps, neon lamps or halogen lamps.

The document WO 03/073009 describes a suction hood having a lighting system by light emitting diodes.

This type of lighting has advantages over other types of lighting.

For example, the lifetime of a lighting system by light-emitting diodes is greater than that of other types of lighting and its maintenance is reduced.

In addition, with this type of lighting, the appliance reduces the risk of burns or electric shock.

Nevertheless, this type of lighting device is expensive.

Indeed, each lighting device comprises a determined number of light-emitting diodes. The electrical parameters (voltage and current) necessary to power the lighting device vary as the number of light-emitting diodes to power varies.

Thus, for each lighting device, it is necessary to have a power transformer adapted to supply the lighting device.

Therefore, a power transformer is specific to each lighting device. Such an implementation is expensive for a manufacturer.

The present invention aims to solve the aforementioned drawbacks and to provide a household appliance comprising an illumination device powered by a simply flexible supply circuit.

For this purpose, the present invention is directed to an appliance, in particular a fume hood, comprising an illumination device by light-emitting diodes, and a supply circuit for the illumination device.

According to the invention, the supply circuit comprises a supply transformer supplying a regulator circuit, the regulator circuit being adapted to regulate at least one supply parameter of the illumination device.

Thus, the same power transformer can be used in power supply circuits of illumination devices whose power parameters have different values.

According to a preferred characteristic of the invention, the power parameter is a function of the type and / or the number of light-emitting diodes.

Thus, the power supply circuit can be used in illumination devices regardless of the type and / or number of light-emitting diodes.

Advantageously, the supply circuit further comprises a limiter circuit, mounted between the supply transformer and the regulator circuit, and adapted to limit the value of the electrical output signal of the supply transformer to a predetermined value.

Consequently, the electrical output signal of the limiter circuit corresponding to the electrical signal at the input of the regulator circuit is limited to a value adequate for the proper functioning of the regulator circuit.

This regulator circuit could be damaged, and even destroyed, if the electrical signal (eg voltage) at the input is higher than this predetermined value.

In practice, the value of an electrical output signal of the limiter circuit is substantially equal to the predetermined value, when the value of the electrical output signal of the supply transformer is greater than the predetermined value.

Thus, when the power transformer, in a particular situation, outputs an electrical signal of higher value than the predetermined value, the electrical signal value is limited, thus being maintained at a value adequate for the regulator circuit.

Therefore, the limiter circuit has a protective role of the regulator circuit.

Moreover, the value of an electrical output signal of the limiting circuit is substantially equal to the value of the electrical output signal of the supply transformer, when the value of the electrical output signal of the supply transformer is less than or equal to the predetermined value.

Thus, since the electrical output signal of the transformer does not need to be limited, the electrical output signal of the limiting circuit is equivalent to the electrical output signal of the transformer.

Other features and advantages of the invention will become apparent in the description below.

• la figure 1 est un schéma représentant un circuit d'alimentation selon un mode de réalisation de l'invention ;
• la figure 2 est un schéma électrique d'un circuit régulateur utilisé dans ce mode de réalisation de l'invention ;
• la figure 3 est un schéma électrique d'un circuit limiteur utilisé dans ce mode de réalisation de l'invention ;
• la figure 4 est un graphique représentant des signaux utilisés par le circuit d'alimentation conforme à l'invention ; et
• la figure 5 est vue en perspective d'une hotte d'aspiration comprenant un dispositif d'illumination conforme à l'invention.

In the accompanying drawings, given as non-limiting examples:

• the figure 1 is a diagram showing a power supply circuit according to an embodiment of the invention;
• the figure 2 is a circuit diagram of a regulator circuit used in this embodiment of the invention;
• the figure 3 is a circuit diagram of a limiter circuit used in this embodiment of the invention;
• the figure 4 is a graph representing signals used by the power supply circuit according to the invention; and
• the figure 5 is a perspective view of a suction hood comprising an illumination device according to the invention.

We will first describe with reference to the figure 1 , a power supply circuit associated with an illumination device according to one embodiment of the invention.

The illumination device 1 corresponds to a device for illumination or illumination by light-emitting diodes.

This illumination device 1 needs to be powered for its operation.

The supply of the illumination device 1 is implemented by a power supply circuit 2. This power supply circuit has the function of delivering the current and voltage necessary to power the illumination device 1.

Thus, a power supply circuit is a circuit capable of supplying a continuous voltage (and current) from an alternating voltage (and current), for example the voltage (and current) of the sector.

Electronic circuits generally require a continuous supply and low voltage.

Thus, the power supply circuit 2 comprises a supply transformer 3. This power supply transformer 3 outputs a voltage V _ST of value less than the value of the input voltage V _ET .

This input voltage V _AND supply transformer 3 is often, as in our embodiment, the mains voltage, that is to say, a voltage of a value of 230 V.

Of course, the voltage of the sector may have different values, depending on the power grid of the country in which we are located.

In addition, the input voltage V _ET of the power transformer 3 may be from other source than the mains.

By way of non-limiting example, the supply transformer 3 lowers the input voltage V _ET from 230 V to 11.5 V (output voltage V _ST ).

The output voltage V _ST of the power transformer 3 has a value suitable for use by a regulator circuit 4.

The regulator circuit 4 makes it possible to generate the necessary power parameters for the illumination device 1, that is to say, the voltage and the current.

Thus, the regulator circuit 4 generates a control voltage V _led and a control current I _led of a continuous value from the output signal V _ST of the transformer 3.

An example of a regulator circuit is shown in figure 2 .

The main element of the regulator circuit 4 is an integrated circuit 20. This integrated circuit 20 has a DC / DC converter functionality and is for example an LT ^® 3477 reference integrated circuit marketed by Linear Technology Corporation.

Various components are connected to its input / output ports in order to supply it and configure it in the desired operating mode so that the regulator circuit 4 delivers the control current I _led and the control voltage V _led. necessary for the illumination device 1.

The input voltage V _ER of the regulator circuit 4 is applied between a first port 20a of the integrated circuit 20 and the reference potential 13, here the null potential. The output voltage V _LED is taken between a second port 20b of the integrated circuit 20 and the reference potential 13.

The values of the control voltage V _led and the control current I _led are a function of the type and the number of light-emitting diodes of the illumination device 1.

For example, an illumination device 1 comprising a reference module WU-M-W-293 comprising diodes 12, the VS Optoelectronic ^® manufacturer requires a control current I _LED of 350 mA and a control voltage V _LED 3 , 5 V.

An illumination device 1 comprising a reference module WU-M-292-W comprising 60 diodes, of the same manufacturer, requires a control current lied of 700 mA and a control voltage V _LED of 17 V.

An illumination device 1 comprising 12 diodes connected in series, reference ASMT-MW00 from a second manufacturer, Avago ^® , requires a control current I _led of 350 mA and a control voltage of 33.6 V.

When the number or type of light-emitting diodes of the illumination device 1 varies, the regulator circuit 4 can be adapted so simple and fast, so that the control current I _led and the control voltage V _led are in adequation with the power required by the illumination device 1.

Thus, a first resistor 21 makes it possible to adjust the value of the control current I _led .

A first terminal 21a of the first resistor 21 is connected to a third port 20c of the integrated circuit 20, and a second terminal 21b of the first resistor 21 is connected to the second port 20b of the integrated circuit 20.

By way of non-limiting example, the value of this first resistor 21 is 0.5 Ohm for a control current value I _led of 1.5 A.

A second resistor 22 and a third resistor 23 make it possible to adjust the value of the control voltage V _led .

A first terminal 22a of the second resistor 22 is connected to a fourth port 20d of the integrated circuit 20 and at the same time to a first terminal 23a of the third resistor 23. A second terminal 22b of the second resistor 22 is connected to the reference potential 13. A second terminal 23b of the third resistor 23 is connected to the first terminal 21a of the first resistor 21.

For example, the value of these second 22 and third 23 resistors is 10 kOhm and 150 kOhm respectively to obtain a control voltage V _{led value} of 19.76 V.

Thus, when the number or type of light-emitting diodes of the illumination device 1 varies, the regulator circuit 4 of this embodiment can be adapted by changing the values of the first, second and third resistors 21, 22, 23, so that to supply a reference current I _led and a reference voltage V _led adequate.

The regulator circuit 4 has several capacitors 24, 25, 26, 27.

These capabilities have a purpose of decoupling. In particular, first 24 and second 25 capacitors have a role of energy reservoir for the current calls of the integrated circuit 20, for example during sudden variations of the voltage and have a signal smoothing capability.

A third capacitor 26 forms with a fourth resistor 28 a compensation circuit which is connected in series with a fifth terminal 20e of the integrated circuit 20. This fifth terminal 20e is a compensation terminal 20e of the integrated circuit 20 for compensation for amplifiers operational.

By way of non-limiting example, the resistor 28 and the capacitor 26 have values of 1 kOhm and 4.7 nF.

A fourth capacitor 27 is connected to a sixth terminal 20f of the integrated circuit 20. This fourth capacitor 27 has a function of adjusting a function of the integrated circuit 20 of minimizing the inrush current at the start of the integrated circuit 20.

By way of non-limiting example, the capacity 27 has a value of 10 nF.

Of course, values of other components could be modified, for example a reference voltage value.

Here, for the proper functioning of the regulator circuit 4, the input voltage V _ER must not exceed a value of 20 V.

Nevertheless, the supply transformer 3, when in certain situations, can deliver output voltages V _ST exceeding the nominal values, here 11.5 V.

For example, when the power supply transformer 3 is not charged (as for example when the illumination device 1 is not activated or for a few moments when the supply transformer 3 is turned on), it can deliver voltages of, for example, 40 V or even greater than 40 V.

Voltages of these values at the input of the regulator circuit 4 can deteriorate and even destroy the regulator circuit 4.

Thus, the power supply circuit 2 comprises a limiter circuit 5 adapted to limit the value of the output voltage V _ST of the supply transformer 3 to a predetermined value.

Here, the predetermined value has a maximum value of 20 V.

Of course, the predetermined value may have other values, less than or greater than 20 V.

The limiter circuit 5 is located between the supply transformer 3 and the regulator circuit 4.

Thus, the voltage to be limited V _EL or the input voltage of the limiter circuit 5 corresponds to the output voltage V _ST of the supply transformer 3. The limited voltage V _SL corresponds to the voltage to be regulated V _ER or the input voltage of the regulator circuit 4.

We will then describe, with reference to figures 3 and 4 , the structure and operation of the limiter circuit 5 according to one embodiment.

The figure 3 represents an example of a circuit diagram of a limiting circuit 5.

Of course, other electrical schemes may be used to limit the voltage present at the input of the limiter circuit 5.

This limiter circuit 5 comprises an input voltage or voltage to be limited V _EL and an output voltage or limited voltage V _SL . Thus, the input voltage V _EL is processed by the limiter circuit 5 so that the output voltage V _SL has a predetermined value.

This predetermined value of output voltage V _SL corresponds (as described above) to a voltage value adequate for the proper functioning of the regulator circuit 4.

Here, the output voltage V _SL of the limiter circuit 5 has values of between 10 and 25 V, preferably 20 V.

Of course, these output voltage values V _SL of the limiter circuit 5 are non-limiting examples. This output voltage V _SL may have other values.

In this example of the electronic circuit of the limiter circuit 5, the value of the limited voltage V _SL will be fixed in particular by a Zener diode 6.

This Zener type diode 6 comprises a voltage called Zener voltage V _Z , having a value predetermined by the Zener diode model.

When this Zener diode 6 is reverse biased, that is to say when the difference between the value of the voltage present at its anode 6a and the value present at its cathode 6b is negative, and this difference exceeds the Zener voltage V _Z , the voltage at the terminals 6a, 6b of the Zener diode 6 remains invariable and substantially equal to the Zener voltage V _Z.

On the other hand, a P-channel MOSFET transistor 7 has a switch function so as to let or not the voltage at the input of the limiter circuit V _EL .

This MOSFET transistor 7 is connected by a first terminal 7a to the cathode 6b of the Zener diode 6. The output voltage V _SL of the limiter circuit is taken between the first terminal 7a of the MOSFET transistor 7 (or the cathode 6b of the Zener diode 6) and the reference potential 13.

In this example, the MOSFET transistor 7 represents a closed switch when the input voltage V _EL is adequate for the circuit connected to its output, that is to say for the regulator circuit 4.

When the input voltage V _EL exceeds the voltage value appropriate for the proper operation of the regulator circuit 4, the MOSFET transistor 7 represents a variable-value resistor.

In practice, the Zener diode 6 represents a detector of the output voltage V _SL delivered to the regulator circuit 4. As a function of the output voltage V _SL delivered detected, the MOSFET transistor 7 is placed in one of the two states. possible (closed switch or variable resistor).

Here, the circuit further comprises two NPN bipolar transistors 8, 9, three resistors 10, 11, 12 and a second diode 14, in order to bias the Zener diode 6, as well as the MOSFET transistor 7.

The resistors 10, 11, 12 have values of 1 kOhm, 100 Ohm and 1 kOhm respectively, calculated experimentally.

Of course, the resistors 10, 11, 12 may have other values and the transistors 8, 9 used to be other types.

The NPN bipolar transistors 8, 9, the three resistors 10, 11, 12 and the second diode 14 represent an interface between the Zener diode 6 and the MOSFET transistor 7. This interface allows the switch (represented by FIG. MOSFET transistor 7) to know the state in which it must be positioned from the output voltage detected by the Zener diode 6.

Thus, this interface is connected to the anode 6a of the Zener diode 6 and to the second and third terminals of the MOSFET transistor 7.

The input voltage V _EL of the limiter circuit 5 is applied between this third terminal 7c of the MOSFET transistor 7 and the reference potential 13.

In the interface, a first terminal 8a of a first bipolar transistor 8 is connected to the anode 6a of the Zener diode 6 and at the same time to a first terminal 12a of a first resistor 12.

A second terminal 8b and a third terminal 8c of the first bipolar transistor 8 are respectively connected to a first terminal 9a of a second bipolar transistor 9, and to the reference potential 13.

Here, the first 8a, second 8b and third 8c terminals of the first bipolar transistor 8 respectively correspond to the base, the collector and the transmitter.

The first terminal 9a of the second bipolar transistor 9 is connected to a first terminal 10a of a third resistor 10.

A second terminal 9b of the second bipolar transistor 9 is connected to a first terminal 11a of a second resistor 11.

A third terminal 9c of the second bipolar transistor 9 is connected to the anode 14a of the second diode 14.

The second terminal 9b of the second bipolar transistor 9 is connected at the same time to the second terminal 7b of the MOSFET transistor 7.

Here, the first 9a, second 9b and third 9c terminals of the second bipolar transistor 9 respectively correspond to the base, the collector and the transmitter.

The second terminals 11b, 10b of the second 11 and third resistors are connected to the third terminal 7c of the MOSFET transistor 7.

Finally, the cathode 14b of the second diode 14 and a second terminal 12b of the first resistor 12 are connected to the reference potential 13.

Here, the first 7a, second 7b and third 7c terminals of the MOSFET transistor 7 respectively correspond to the drain, the gate and the source.

The input voltage V _EL and the output voltage V _SL are then referenced to the zero voltage 13. They are represented on the graph of the figure 3 .

As mentioned above, when the input voltage V _EL is adequate for the proper operation of the regulator circuit 4, the MOSFET transistor 7 is in the closed or on switch state. The description below verifies this hypothesis.

In this case, the output voltage V _SL is equal to the input voltage V _EL .

As a result, the input voltage V _EL is smaller than the value of the Zener voltage V _Z. Thus, the current I _Z which passes through the Zener diode 6 is substantially zero and consequently the current flowing in the base of a first transistor 8 is substantially zero. Thus, this first transistor 8 is blocked. Therefore, the base of the second transistor 9 is traversed by a current from the input voltage V _EL via a first resistor 10. The second transistor 9 is therefore passing.

Thus, the voltage at the collector V _M of the second transistor 9 is substantially zero. As a result, the potential difference between the gate and the source of the MOSFET transistor 7 has a high value, close to the input voltage V _EL .

This high potential difference is greater than the potential difference equivalent to the on / off switchover point of the MOSFET transistor 7. Therefore, the MOSFET transistor 7 is on, that is to say represents a closed switch. . This confirms the initial hypothesis and proves that the circuit is stable under these conditions.

Consequently, the MOSFET transistor 7 passes the voltage at the input V _EL to the output of the limiter circuit 5, the output voltage V _SL being thus identical to the input voltage V _EL .

On the contrary, when the input voltage V _EL is not adequate for the proper functioning of the regulator circuit 4, ie it is greater than the Zener voltage V _Z , it causes a current I _{Z to} appear _. crossing the Zener diode 6.

This current I _Z increases the value of the potential difference across a second resistor 12, which reveals a current flowing through the first transistor 8 between the base and the emitter.

Therefore, the first transistor 8 is on.

When the first transistor (bipolar NPN type) 8 is on, a collector current I _C appears, which decreases the base current of the second transistor 9 from the first resistor 10.

The second transistor 9 thus starts to block gradually, increasing the value of the voltage at its collector V _M. Thus, the potential difference between the gate and the source of the MOSFET transistor 7 decreases.

As a result, the MOSFET transistor 7 begins to turn on and a current begins to flow through the channel formed between its source and its drain.

The channel becomes more and more resistive and consequently, the output voltage V _SL decreases and remains stable and of value close to the Zener voltage V _Z of the Zener diode 6.

The second diode 14 makes it possible to increase the level of the on / off switching threshold of the second transistor 9.

Therefore, even if the supply transformer 3 delivers values greater than a predetermined value (Zener voltage value V _Z ), the voltage to be regulated V _ER is not greater than this predetermined value, and the regulator circuit 4 n is not damaged.

In addition, the consumption of the limiter circuit 5 is very low.

Indeed, when the transformer 3 is loaded, the MOSFET transistor type 7 is in saturation state or passing, passing current. In this state, the potential difference between its drain and its source is substantially zero. As a result, the heat dissipation is substantially zero.

When the transformer 3 is not loaded, the MOSFET transistor 7 represents an open switch and consequently the current flowing through it is substantially zero. This substantially zero current causes a heat dissipation substantially zero.

Thus, the dissipation of a power supply circuit comprising a limiter circuit 5 according to this embodiment does not have a high value, and therefore it does not require cooling systems.

The lack of cooling system also reduces the price and bulk of the power supply circuit.

The figure 5 represents a suction hood 30 comprising an illumination device 1 by light-emitting diodes.

The number of electroluminescent diodes necessary to obtain the same light power 1 is a function of the type of diode.

By way of non-limiting example, a suction hood delivering a luminous flux corresponding to a luminous power of 700 lm is satisfactory for its use.

For example, to deliver such light output, when the illumination device 1 comprises a first type of module comprising LEDs, WU-M-293-W reference and sold by the manufacturer VS Optoelectronic ^®, the device Illumination 1 requires about 200 light-emitting diodes.

When the module comprising light-emitting diodes is of a second type, referenced WU-M-292-W and marketed by the same manufacturer, the illumination device 1 requires about 120 light-emitting diodes.

When the light emitting diodes used are light emitting diodes referenced ASMT-MW00 and marketed by the manufacturer Avago ^®, the illumination device 1 must contain about 12 LEDs.

Of course, these values of light power and the number of light-emitting diodes are for illustrative purposes and in no way limitative.

Thus, thanks to the presence of the regulator circuit 4 and the associated limiter circuit 5, it is possible to simply adapt a supply circuit of an illumination device according to the number of light-emitting diodes present in the device. illumination.

Therefore, the same power transformer can be used in power supply circuits of the illumination devices comprising different numbers of light-emitting diodes.

In addition, the electronic circuits connected to the output of the power transformer are protected against any overvoltages of the power transformer thanks to the limiting circuit.

Of course, many modifications can be made to the embodiment described above without departing from the scope of the invention.

Thus, the structures of the limiter circuit, as well as the regulator circuit used may be different.

Claims (10)

Domestic appliance, in particular a suction hood, comprising an illumination device (1) by light-emitting diodes, and a supply circuit (2) for said illumination device (1), characterized in that said supply circuit (2) comprises a power transformer (3) supplying a regulator circuit (4), said regulator circuit (4) being adapted to regulate at least one power parameter of said illumination device (1). Domestic appliance according to claim 1, characterized in that said power parameter is a function of the type and / or the number of light-emitting diodes. Domestic appliance according to one of claims 1 or 2, characterized in that the supply circuit further comprises a limiter circuit (5), mounted between said supply transformer (3) and said regulator circuit (4), and adapted to limit the value of said electrical output signal (V _ST ) of said power transformer (3) to a predetermined value. Domestic appliance according to claim 3, characterized in that the value of an electrical output signal (V _SL ) of said limiter circuit (5) is substantially equal to said predetermined value, when the value of said electrical output signal (V _ST ) of said supply transformer (3) is greater than said predetermined value. Domestic appliance according to one of claims 3 or 4, characterized in that the value of an electrical output signal (V _SL ) of said limiter circuit (5) is substantially equal to the value of said electrical output signal (V _ST ) of said supply transformer (3), when the value of said output electrical signal (V _ST ) of said supply transformer (3) is less than or equal to said predetermined value. Domestic appliance according to one of claims 3 to 5, characterized in that said electrical output signal (V _SL ) of said limiter circuit (5) is a voltage having values between 10 and 25 V. Domestic appliance according to one of Claims 3 to 6, characterized in that the limiter circuit comprises a Zener diode (6), a transistor MOSFET type (7) and an interface connected between said Zener diode (6) and said MOSFET transistor (7); said interface comprising two bipolar transistors (8, 9), three resistors (10, 11, 12) and a second diode (14). Domestic appliance according to claim 7, characterized in that the cathode (6b) of said Zener diode (6) is connected to a first terminal (7a) of said MOSFET transistor (7), and said interface is connected to the anode (6a) of said Zener diode (6) and second (7b) and third (7c) terminals of said MOSFET transistor (7). Domestic appliance according to one of claims 7 or 8, characterized in that said input voltage of the limiting circuit (V _EL ) is applied between said third terminal (7c) of said MOSFET transistor (7) and a reference potential (13), and said output voltage of said limiter circuit (V _SL ) is taken between the cathode (6b) of said Zener diode (6) and said reference potential (13). Domestic appliance according to one of claims 7 to 9, characterized in that a first terminal (8a) of a first bipolar transistor (8) is connected to the anode (6a) of said Zener diode (6) and at a first terminal (12a) of a first resistor (12); a second terminal (8b) of said first bipolar transistor (8) is connected to a first terminal (9a) of a second bipolar transistor (9); a second terminal (9b) of a second bipolar transistor (9) is connected to a first terminal (11a) of a second resistor (11) and a second terminal (7b) of said MOSFET transistor (7); the first terminal (9a) of said second bipolar transistor (9) is connected to a first terminal (10a) of a third resistor (10); the third terminal (9c) of said second bipolar transistor (9) is connected to the anode (14a) of said second diode (14); a third terminal (7c) of the MOSFET transistor (7) is connected to second terminals (11b, 10b) of the second (11) and third resistor (10); a third terminal (8c) of said first bipolar transistor (8), the cathode (14b) of said second diode (14) and a second terminal (12b) of said first resistor (12) being connected to a reference potential (13) .

Images