ITAN20090012A1 - AC / DC POWER SUPPLY AND PILOT OF AT LEAST ONE ELECTRIC LOAD - Google Patents

Description

â € œAC / DC power supply device and piloting of at least one electrical loadâ €

DESCRIPTION

The present invention refers to an AC / DC electronic device for powering and driving at least one electrical load according to the preamble of claim 1.

The current state of the art is known at low voltage AC / DC power supply devices (i.e. power supply devices capable of transforming an alternating current into a direct current supply) powered by the half-waves of the alternating mains voltage by means of a ™ capacitive drop impedance (realized through a so-called â € œchargingâ € capacitor). Such power supply devices are known to those skilled in the art in the sector of power supply circuits for electric users such as â € œpower supply with capacitive pumpâ €.

They have the drawback of poor efficiency when used to power driving circuits in which the total current absorption of the driven loads is consistent. In fact, in order for a known type capacitive pump circuit to be able to supply a large number of loads at the same time, it is necessary to use a charging capacitor with a high capacity (higher than 1 µF), which inevitably causes the problems of a significant consumption during stand-by (this being in clear contrast to the current demand for ever more efficient electronic devices) and an inevitable oversizing of the other circuit components (for example of the zener diode and of the resistance in series with the charge), with a consequent increase in costs for which an AC / DC power supply circuit with capacitive pump loses much of its convenience compared to the more performing switching power supply circuits.

The present invention has the purpose of overcoming all the aforementioned drawbacks.

In particular, the present invention proposes to realize an electronic circuit which is capable of powering and driving one or more electrical loads at the same time and which guarantees low consumption during stand-by, as well as a particularly advantageous compromise between costs and performance for allow its mass application on electrical appliances such as a kitchen hood or any different household appliance.

The idea behind the present invention is that of realizing an AC / DC power supply device that also acts as a driving device for one or more electrical loads. This is achieved by arranging in series with respect to the circuits dedicated to the power supply of the electronic components one or more piloting circuits, each of which specific for the power supply of an electrical load. Each of these piloting circuits constitutes an independent module which is used for the activation and subsequent deactivation of an electrical load connected to it. Advantageously, this electric load can be switched from a state in which it is electrically powered to a state in which it is not electrically powered by short-circuiting it by means of switches forming part of each driving circuit.

It should be noted that the term â € œcircuitâ € means, in the course of this description and the claims attached thereto, a functional block comprising one or more electronic components, operably connectable to other circuits having the same or different function . The term â € œelectric loadâ € means any device electrically powered at its ends, in particular any inductive or capacitive or resistive load, such as for example a relay or a LED or an optocoupler or an optotriac or a screen or an electronic circuit or a horn or an electric motor or a lighting device. Finally, the term â € œAC / DC power supplyâ € means any power supply device that receives an AC alternating voltage at its input (for example the 230V AC mains voltage) which is converted into a direct DC voltage at its output (for example example in a direct voltage equal to 5V suitable for the power supply of electronic devices).

The present invention is described in greater detail with reference to an embodiment illustrated, by way of explanation but not of limitation, in the attached Fig. 1, which represents the circuit diagram of an example of an AC / DC power supply device and driving at least one electric load according to the present invention. Inside Fig. 1, the various rectangles with outlines formed by dashed lines serve to define and delimit the various circuits (each of which constitutes a separate functional module or block) included in a device according to the present invention.

Fig. 1 shows an AC / DC power supply and driving device, capable of both generating a direct voltage at its output ends, and driving at least one electrical load LOAD.

The device according to the present invention comprises a first circuit P which constitutes the input circuit which connects the device to an AC power supply network, for example to a power supply network which supplies an alternating voltage of 230V. The first circuit P comprises a first input terminal T1 and a second input terminal T2 for connecting the device to a power supply network which supplies the AC mains voltage.

The first circuit P comprises inside it means rectifying the AC mains voltage, comprising in particular at least two diodes. In the embodiment shown by way of example in Fig. 1, the rectifying means advantageously comprise four diodes D1, D2, D4, D5 (preferably identical to each other) arranged in a rectifier bridge configuration. The diodes are preferably of the D1N4007 type (the sizing of these diodes is in any case to be carried out on the basis of the currents that pass through them and / or the voltages existing at their ends) and are arranged in such a way that the cathode of D1 is connected to the cathode of D2, the anode of D2 to the cathode of D5, the anode of D5 to the anode of D4 and the cathode of D4 to the anode of D1. Between the cathode of D4 and the anode of D1 and between the anode of D2 and the cathode of D5 there are the points for the operative connection of this rectifier bridge respectively with the first terminal T1, i.e. with the terminal connected with the LINE line, and with the second terminal T2, i.e. with the terminal connected to the NEUTRAL neutral.

The first circuit P comprises a drop impedance of the capacitive type C4 which substantially determines the value of a power supply current absorbed by the network by the device according to the present invention. The drop impedance C4, in the example illustrated in Fig. 1, is a capacitor, preferably of the X2 type having a capacity of 0.68 µF, one armature of which is operatively connected to the second terminal T2, the other armature being operatively connected to the rectifier bridge. Advantageously, the first circuit P also comprises protection means, suitable for limiting the overcurrents inside the device, and / or filtering means, suitable for filtering the output voltage from the rectifier means. In particular, the protection means comprise a protection resistor R12, having in the non-limiting example of Fig. 1 a value of 82 â „¦, which is interposed between the drop impedance C4 and the second terminal T2, while the filtering means comprise a filtering capacitor C1, which in the non-limiting example of Fig.1 has a capacity of 22 µF and is arranged between the cathodes of diodes D1 and D2 and the anodes of diodes D4 and D5.

The device according to the present invention comprises a second circuit S, arranged in series with respect to the first circuit P, since it is possible to take a direct supply voltage at the ends S8-S9 of the second circuit S. The second circuit S advantageously comprises stabilization means, suitable for to stabilize the aforesaid direct supply voltage, and / or filtering means, suitable for filtering the aforesaid direct supply voltage.

In the explanatory embodiment of the invention represented in Fig.1, the second circuit S, at the ends of which it is possible to take a continuous supply voltage equal to 5V for the power supply of one or more electronic devices including a microcontroller uC, is operationally connected to the rectifier bridge of the first circuit P, in particular to the cathodes of the diodes D1 and D2. At the ends of the second circuit S can be connected a 220 µF filtering capacitor C2 and a 5.1 V stabilizing Zener diode D8, arranged in parallel with each other.

Characteristically, the device according to the present invention comprises at least a third circuit X1 which is arranged in series with respect to the first circuit P and the second circuit S and which comprises means for connecting K11, K12 to at least one electrical load LOAD, which is able to assume a first state in which the electrical load LOAD is electrically powered and a second state in which the electrical load LOAD is not electrically powered; electronic or electric type switch means, for switching the state of the electrical load LOAD from said first state to said second state and / or from said second state to said first state; and driving means Z1 for controlling the switching means. The passage of the electric load LOAD from the aforesaid first state to the aforesaid second state advantageously takes place by short-circuiting the electric load LOAD by means of the switch means.

In the embodiment of the present invention which is illustrated in Fig. 1, the switching means of the third circuit X1 comprise a BJT Q5 (for example a BJT of the type BC817-25), the base of which is preferably connected to the driving means Z1 and whose collector and emitter are preferably connected to the connecting means K11, K12. As an alternative to the use of a BJT or more generally of a transistor, the switching means can comprise a MOSFET, the gate of the MOSFET being preferably connected to the driving means Z1 and the drain and source of the MOSFET preferably connected to the connection K11, K12.

The driving means Z1 are able to be controlled by an electronic control device, to which they are operationally connected: for example, in Fig. 1, they are connected to a microcontroller uC, one of which is specifically dedicated to transmission of a logic control signal for the driving means Z1. The driving means Z1 of the third circuit X1 therefore comprise a terminal Y1 for connection to an electronic control device, in particular to the microcontroller uC.

The driving means Z1, in the embodiment of the invention illustrated by way of explanation but not of limitation in Fig. 1, comprise a BJT Q6 (for example a BJT of the type BC807-25), the base of which is preferably operationally connected to the connection terminal Y1, whose collector is preferably operationally connected to the switching means and whose emitter is preferably operationally connected to the second circuit S, in particular to the end S8 of the second circuit S. As an alternative to a BJT or more generally to a transistor, the driving means Z1 can comprise a MOSFET, having the gate preferably operationally connected to the connection terminal Y1, the drain preferably operationally connected to the switching means and the source operationally preferably connected to the second circuit S, in particular to the end S8 of the second circuit S. Furthermore, the driving means Z1 comprise a first resistor R25 interposed between base of the BJT Q6 and the Y1 connection terminal. If a MOSFET is used in the driving means Z1 instead of a BJT, the first resistance R25 is interposed between the gate of the MOSFET and the connection terminal Y1.

In addition to the aforementioned first resistor R25, which can be dimensioned in particular from 4k7 â „¦, also other resistors can be advantageously applied to the driving means Z1. In particular, in the embodiment of the invention illustrated for explanatory but not limiting purposes in Fig. 1, a second resistor R22, which can be specifically dimensioned from 10k â „¦ and / or a third resistor R26, which can be specifically dimensioned from 47k â „¦, and / or a fourth resistor R23, which can notably be dimensioned from 22k â„ ¦, are included in the driving means Z1 of the third circuit X1. If the driving means Z1 comprise a transistor, as in the case of the example of embodiment of the invention shown in Fig. 1, in which the BJT Q6 is located inside the driving means Z1, the second resistor R22 It is interposed between the emitter of the BJT Q6 and the second circuit S (in particular the head S8 of the second circuit S), the third resistor R26 is interposed between the base of the BJT Q6 and the second circuit S (in particular the head S9 of the second circuit S) and the fourth resistor R23 is interposed between the collector of the BJT Q6 and the emitter of the BJT Q5 (or the source of the MOSFET, if there is a MOSFET in place of the BJT Q5). If instead the driving means Z1 include a MOSFET, the second resistance R22 is interposed between the source of said MOSFET and the second circuit S, the third resistance R26 is interposed between the gate of said MOSFET and the second circuit S and the fourth resistor R23 is interposed between the drain of said MOSFET and the emitter of the BJT Q5 (or the source of the MOSFET, if there is a MOSFET in place of the BJT Q5).

According to a variant of the third circuit X1 (not represented in Fig. 1), the terminals K11 and K12 can be connected together through a Zener diode, should this be necessary to stabilize the voltage across the electrical load LOAD.

An extremely advantageous feature of the present invention is the possibility of driving a plurality of electrical loads by placing a plurality of circuits dedicated to driving together in series. This can be seen, for example, in Fig. 1, where it can be seen that there are n driving circuits arranged in series with each other (the dashed connection lines between the first and the i-th circuit and between this and the n-th circuit symbolize the possible presence of any number of intermediate circuits), being the first of these circuits connected to the second circuit S, the n-th between these circuits connected to the first circuit P and the ith generic circuit connected to the circuit with index i-1 and to the circuit with index i + 1. All n driving circuits also have a connection line with the electronic control device, in particular with the uC microcontroller.

The AC / DC power supply and driving device for at least one electrical load LOAD, in any embodiment of the present invention such as to allow the driving of more than one electrical load, comprises, in addition to the first P, second S and third X1 circuits previously described, also at least a fourth circuit Xn, arranged in series with respect to said first P and third X1 circuit.

This fourth circuit Xn comprises, according to the example of embodiment of the invention illustrated by way of explanation but not of limitation in Fig. 1, means for connecting Kn1, Kn2 to an electrical load RL, which is able to assume a first state in which it is electrically powered and a second state in which it is not electrically powered; electronic or electric type switching means, for switching the state of the electric load RL connected to the fourth circuit Xn from said first state to said second state and / or from said second state to said first state; And

driving means Zn for controlling the switching means of said fourth circuit Xn.

Advantageously, the third circuit X1 is the same as the fourth circuit Xn. In particular, if both the half-switches of the third circuit X1 and the half-switches of the fourth circuit Xn include a BJT, the emitter of the BJT Q5 inside the third circuit X1 is operatively connected to the collector of the BJT Q15 at the ™ inside the fourth circuit Xn. If, on the other hand, both the switching means of the third circuit X1 and the switching means of the fourth circuit Xn comprise a MOSFET, the source of the MOSFET of the switching means of the third circuit X1 is operatively connected to the drain of the MOSFET of the switching means of the fourth circuit Xn.

One or more circuits Xi can be arranged in series with respect to the third circuit X1 and the fourth circuit Xn. In this case, each of the circuits Xi can be realized in particular in such a way as to include means for connecting Ki1, Ki2 to a respective electric load LED, which is capable of assuming a first state in which it is electrically powered and a second state where it is not electrically powered; electronic or electric type switching means for switching the state of said respective LED electric load from said first state to said second state and / or from said second state to said first state; and driving means Zi for controlling the respective switching means of said one or more circuits Xi.

The one or more circuits Xi are in particular equal to each other and equal to the third circuit X1 and to the fourth circuit Xn. In particular, if the half-switches of one or more circuits Xi all include a BJT, the collector of the BJT of the circuit Xi (the BJT Q7 in Fig. 1) is connected to the emitter of the BJT of the circuit Xi-1 and the € ™ emitter of the BJT of circuit Xi (the BJT Q7 in Fig.1) is connected to the collector of the BJT of circuit Xi + 1. If, on the other hand, the switching means of the one or more circuits Xi all comprise a MOSFET, the drain of the MOSFET of the switching means of the circuit Xi is connected to the source of the MOSFET of the switching means of the circuit Xi-1, while the source of the MOSFET of the switching means of the circuit Xi is connected to the drain of the MOSFET of the half-switches of the circuit Xi + 1.

The AC / DC power supply and driving device for at least one electrical load LOAD according to the present invention can also comprise a voltage measurement circuit M. This circuit has the function of detecting the total voltage drop determined by the switching on of one or more of the electrical loads driven by the device according to the present invention.

The measurement circuit M, in an advantageous embodiment of the invention, comprises a connection terminal M9 to an electronic control device, in particular to an analog-digital conversion port of the microcontroller uC, and is adapted to measure the voltage difference between the input terminal of the third circuit X1 and the output terminal of the fourth circuit Xn, being the input terminal of the third circuit X1 the connection terminal of the third circuit X1 to the second circuit S and being the output terminal of the fourth circuit Xn the terminal connecting the fourth circuit X1 to the first circuit P.

In the embodiment illustrated by way of explanation but not of limitation in Fig.1, the measuring circuit M comprises voltage divider means, in particular the pair of resistors R13, R15; voltage limiting means, in particular the pair of diodes D6 (which in Fig. 1 is represented by way of example in the form of an integrated component known to those skilled in the art of electronic power supply and driving devices such as BAV99) and the resistor R14 ; and filtering means, in particular the capacitor C5. The pair of resistors R13, R15 can be arranged in such a way that the resistor R13, preferably of 10k â „¦, is operationally connected to the connection terminal M9 and to one of the ends of the second circuit S (in particular to the end S8 of the second circuit S), while the resistor R15, preferably 220k â „¦, is operatively connected to the connection terminal M9 and to a connection terminal with the anodes of the diodes D4, D5 of the rectifier means of the first circuit P; the pair of diodes D6 can be arranged in such a way that the first of these diodes D6 has the cathode operatively connected to the end S8 of the second circuit S and the anode operatively connected to the connection terminal M9, while the second of these diodes D6 has the anode operatively connected to the other end S9 of the second circuit S and the cathode operatively connected to the connection terminal M9; the resistor R14, preferably 4k7 â „¦, can be arranged in such a way as to be interposed both between the connection terminal M9 and each of the resistors of the pair R13, R15, and between the connection terminal M9 and each of the diodes of the pair D6; the capacitor C5, preferably having a capacity of 10 nF, can be arranged in such a way as to be operatively connected to the connection terminal M9 and to the end S9 of the second circuit S.

The AC / DC power supply and driving device for at least one electrical load LOAD according to the present invention may advantageously also comprise a power reducing circuit W, which acts as a device suitable for eliminating or reducing the overvoltages on the electrical load LOAD. The power reducer circuit W comprises a connection terminal W9 to an electronic control device, in particular to the microcontroller uC.

In the embodiment illustrated by way of explanation but not of limitation in Fig.1, the power reducing circuit W comprises connection means W11, W12, in particular a pair of terminals, for the operative connection with the first circuit P; electronic or electric type switching means operatively connected to said connection means W11, W12, in particular a BJT Q2, whose collector and emitter are operatively connected to the connection means W11, W12; and driving means W1, suitable for controlling said switch means and operatively connected both to said switch means (for example to the base of the BJT Q2), and to the connection terminal W9.

The operative connection between the power reducing circuit W and the first circuit P is in particular made in such a way that one of the diodes (for example the diode D5 in Fig. 1) of the rectifying means of the first circuit P can be short-circuited by means of the switching means of the power reducing circuit W, so as to halve the output power from the first circuit P, for example in stand-by conditions, so that the consumption of power drawn from the network by the device according to the present is reduced invention. In addition, the power reducer circuit W can act as a voltage stabilization device at the ends of the electrical load LOAD and of the other electrical loads RL and LED.

According to a preferred embodiment of the present invention which is illustrated by way of non-limiting way in Fig. 1, the power reducing circuit W is equal to the third circuit X1, being connected across a diode of the rectifying means of the first circuit P instead of at the ends of an electrical load LOAD.

Therefore, alongside the illustrated version of the power reducing circuit W with the BJT Q2, it is also possible to provide a version of the same circuit in which the switching means comprise a MOSFET.

The power reducer circuit W can be conveniently used to regulate the voltage across the electrical load LOAD. In particular, if the LOAD electrical load requires the application of a rather stable voltage value across it, the voltage across the LOAD electrical load can be adjusted until a predetermined value is obtained. The architecture of the device according to the present invention illustrated by way of explanation but not of limitation in Fig. 1 allows to obtain this fine regulation of the voltage applied to the load LOAD, for example being the driving means W1 driven by the microcontroller uC in an impulsive way ( for this fine regulation of the voltage, the driving can take place with the Pulse Width Modulation or PWM technique, according to which the value of the voltage across the electrical load (LOAD) depends on the amplitude of the pulses of the driving signal).

Numerous and important advantages derive from the present invention.

In particular, it is particularly suitable to be applied to obtain low cost and high performance power supply and driving devices, which can be used by allowing the creation of a single electronic device for the simultaneous power supply and driving of one or more electrical loads. conveniently on a wide range of electrical users preferably suitable for use in a domestic environment.

Furthermore, the electronic device according to the present invention has proved to have, on the basis of tests carried out by the Applicant, a particularly limited consumption in stand-by conditions, so that the present invention achieves the important result of reducing the overall energy consumption of the € ™ electrical user in which the device according to the present invention is installed.

The present invention is clearly capable of being applied industrially. The object of the present invention is also an electrical user, comprising an AC / DC power supply device and driving at least one electrical load LOAD according to the present invention. This electrical user can be of any type and include any electrical, electronic or electromechanical components (electric motors, pumps, lamps, fans, tag readers, sensors, actuators, filtering or purification devices, electrical resistors, inductors, screens, speakers, and so on). For example, the electrical user can include an extractor hood or a filter hood. In this case, the electrical loads driven by the device according to the present invention can be a series of relays (which serve to interrupt and restore the power supply to hood components such as the electric motor for moving the suction impeller at different speeds or the lamps usually present on board a hood) and / or a series of LEDs designed to be used to explain to the user information relating to the operating status of the electrical user (for example the activation of the motor at a preset speed). Alternatively, the electrical utility can be a heating device such as a water heater.

The electrical user according to the present invention can also be a user adapted to be used specifically as a sensor device and / or as a control device.

As an example of an electrical user of this type, an electrical user including an electronic thermostat can be mentioned.

The present invention has been described with reference to a particular embodiment, but it is necessary to underline how the inventive scope of the present invention is wider and must be understood as defined by the scope of protection of the claims annexed to this description. In particular, the sizing of the components used for the realization of an AC / DC power supply device and for driving at least one electrical load according to the present invention can be any, depending on the characteristics of the electrical load or piloted electrical loads and the design specifications. . The architecture of the embodiment of the present invention illustrated in Fig. 1 is therefore to be understood purely by way of non-limiting example.

Claims (10)

CLAIMS 1) AC / DC power supply device and driving of at least one electrical load (LOAD) comprising: i) a first circuit (P) comprising â € ¢ a first (T1) and a second input terminal (T2) for connecting said device to a power supply network which supplies the AC network voltage; ii) a second circuit (S) at the ends of which it is possible to take a direct supply voltage, said second circuit (S) being arranged in series with respect to said first circuit (P), and iii) at least a third circuit (XI) arranged in series with respect to said first (P) and second (S) circuit, comprising: â € ¢ connection means (K 1 1, K I2) to said at least one electric load (LOAD), said at least one electric load (LOAD) being able to assume a first state in which said at least one electric load (LOAD) It is electrically powered with a second state in which said at least one electrical load (LOAD) is not electrically powered; â € ¢ electronic or electrical switch means for switching the state of said at least one electrical load (LOAD) from said first state to said second state and / or from said second state to said first state and â € ¢ driving means (ZI) for controlling said switching means; characterized by the fact that: A) said first circuit (P) comprises: â € ¢ means rectifying said AC mains voltage e â € ¢ a capacitive drop impedance (C4) which substantially determines the value of a power supply current absorbed by the network by said device; B) said device also comprises a power reducing circuit (W) comprising a connection terminal (W9) to an electronic control device, in particular a microcontroller (uC), and able to eliminate or reduce overvoltages on said at least one electrical load (LOAD) e C) said power reducer circuit (W) includes: â € ¢ connection means (W1 1, W12), for the operative connection with said first circuit (P); - switching means of the electronic or electric type operatively connected to said connection means (W 1 1, W 12) e â € ¢ driving means (W1), suitable for controlling said switch means and operatively connected both to said switch means and to said connection terminal (W9). 2) Device for supplying AC / DC and driving at least one electric load (LOAD) according to claim 1, in which the passage of said electric load (LOAD) from said first state to said second state occurs by short-circuiting said at least one electric load ( LOAD) by means of said switch means. 3) Device for supplying AC / DC and driving at least one electric load (LOAD) according to claim 1 or 2, in which the switching means of said third circuit (X I) comprise a BJT (Q5), being the basis of said BJT (Q5) preferably connected to said driving means (ZI) and the collector and emitter of said BJT (Q5) preferably connected to said connection means (K.1 1, K12), or a MOSFET, being the gate of said MOSFET preferably connected to said driving means (ZI) and the drain and source of said MOSFET preferably connected to said connection means (K 11, K.12), the driving means (ZI) of said third circuit ( XI) including in particular: â € ¢ a connection terminal (Yl) to an electronic control device, in particular a microcontroller (uC); â € ¢ a BJT (Q6), being the base of said BJT (Q6) preferably connected to said connection terminal (Yl), the collector of said BJT (Q6) preferably connected to said switching means and the emitter of said BJT (Q6) preferably connected to said second circuit (S), or a MOSFET, the gate of said MOSFET being preferably connected to said connection terminal (Y 1), the drain of said MOSFET preferably connected to said switching means and the source of said MOSFET preferably connected to said second circuit (S) e â € ¢ a first resistance (R25) interposed between the base of said BJT (Q6) or the gate of said MOSFET and said connection terminal (Yl). 4) AC / DC power supply device and driving of at least one electrical load (LOAU) according to any one of the preceding claims, said electrical load (LOAD) being a relay or a LED or an optocoupler or an optotriac or a screen or a circuit electronic or a horn or an electric motor or a lighting device. 5) AC / DC power supply and driving device for at least one electrical load (LOAD) according to any one of the preceding claims, also comprising at least a fourth circuit (Xn), arranged in series with respect to said first (P) and third (XI) circuit and comprising: â € ¢ means of connection (Knl, Kn2) to an electrical load (RL) which is able to assume a first state in which it is electrically powered and a second state in which it is not electrically powered ; â € ¢ electronic or electrical switch means for switching the state of the electric load (RL) connected to said fourth circuit (Xn) from said first state to said second state and / or from said second state to said first state and â € ¢ driving means (Zn) for controlling the switching means of said fourth circuit (Xn), said third circuit (XI) being in particular equal to said fourth circuit (Xn). 6) AC / DC power supply and driving device for at least one electrical load (LOAD) according to claim 5, in which one or more circuits (Xi) are arranged in series with respect to said third (X 1) and fourth (Xn) circuits circuit and each include: â € ¢ means of connection (KM, Ki2) to a respective electrical load (LED) which is able to assume a first state in which it is electrically powered and a second stage in which it is not electrically powered; â € ¢ electronic or electrical switch means for switching the state of said respective electric load (LED) from said first state to said second state and / or from said second state to said first state and â € ¢ driving means (Zi) for controlling the respective switching means of said one or more circuits (Xi), said one or more circuits (Xi) being in particular equal to each other and equal to said third (X I) and fourth (Xn) circuits. 7) AC / DC power supply and driving device for at least one electrical load (LOAD) according to claim 6, also comprising a voltage measuring circuit (M), comprising a connection terminal (M9) to an electronic control device, in particular a microcontroller (uC), and able to measure the voltage difference between the input terminal of said third circuit (XI) and the output terminal of said fourth circuit (Xn), being the input terminal of said third circuit (XI) the connection terminal of said third circuit (X I) to said second circuit (S) and being the output terminal of said fourth circuit (Xn) the connection terminal of said fourth circuit (X 1) to said first circuit (P). 8) AC / DC power supply device and driving of at least one electrical load (LOAD) comprising: i) a first circuit (P) comprising a first (Tl) and a second input terminal (T2) for connecting said device to a power supply network which supplies the AC network voltage; ii) a second circuit (S) at the ends of which it is possible to take a direct supply voltage, said second circuit (S) being arranged in series with respect to said first circuit (P), and iii) at least a third circuit (X I) arranged in series with respect to said first (P) and second (S) circuit, comprising: â € ¢ connection means (K l l, K I2) to said at least one electric load (LOAD), called at least one electric load (LOAD) being able to assume a first state in which said at least one electric load (LOAD) Ã ̈ electrically power it and a second state in which said at least one electrical load (LOAD) is not electrically powered; â € ¢ electronic or electrical switch means for switching the state of said at least one electrical load (LOAD) from said first state to said second state and / or from said second state to said first state and â € ¢ driving means (ZI) for controlling said switching means; characterized by the fact that: A) said first circuit (P) comprises: â € ¢ means rectifying said AC mains voltage e â € ¢ a capacitive drop impedance (C4) which substantially determines the value of a power supply current absorbed by the network by said device; B) the switching means of said third circuit (XI) comprise a BJT (Q5), the base of said BJT (Q5) being connected to said driving means (ZI) and the collector and emitter of said BJT (Q5) connected to said connection means (K 1 1, K I 2), or a MOSFET, the gate of said MOSFET being connected to said driving means (ZI) and the drain and source of said MOSFET connected to said connection means (K 1 1, K 12), and C) the driving means (ZI) of said third circuit (XI) comprise: â € ¢ a connection terminal (Y 1) to an electronic control device, in particular a microcontroller (uC); â € ¢ a BJT (Q6), being the base of said BJT (Q6) connected to said connection terminal (Y 1), the collector of said BJT (Q6) connected to said switching means and the emitter of said BJT (Q6) connected to said second circuit (S), or a MOSFET, the gate of said MOSFET being connected to said connection terminal (Y 1), the drain of said MOSFET connected to said switching means and the source of said MOSFET connected to said second circuit (S) e â € ¢ a first resistance (R25) interposed between the base of said B.IT (Q6) or the gate of said MOSFET and said connection terminal (Y 1). 9) Electric user comprising an AC / DC power supply device and driving at least one electric load (LOAD) according to any one of the preceding claims. 10) Electric user according to claim 9, comprising a suction hood or a filtering hood.