EP3568894A1 - Device for protecting electrical equipment - Google Patents

Abstract

The present invention relates to a device for protecting electrical equipment (23), comprising: - a first branch (21) for limiting current including a current source; - a second conduction branch (22) mounted parallel to the limitation branch (21), the impedance of the conduction branch (22) being less than or equal to 10% of the impedance of the limitation branch (21); - a control unit (3) for switching the operating mode of the device between: ⋅ a first operating mode, in which the electric current circulates through the limitation branch (21) without circulating in the conduction branch (22); and ⋅ a second operating mode, in which the electric current circulates through the limitation and conduction branches (21, 22).

Description

 DEVICE FOR PROTECTING AN ELECTRICAL EQUIPMENT

FIELD OF THE INVENTION The present invention relates to the field of protection circuits for electrical equipment, and in particular DC power supply and / or distribution systems.

BACKGROUND OF THE INVENTION

In electrical applications (direct current or alternating current), a current overload can cause an overvoltage, damaging the electrical equipments.

Current overloads, and more generally overcurrents can have several origins:

 - an overcurrent can be caused by a short-circuit, a surge or a lightning,

 - Overcurrent can also occur during the start-up phase or when connecting electrical equipment to the network.

Various types of protection devices are known to reduce the effects of these current overloads, and in particular the risks of deterioration of electrical equipment. Such protection devices may be used, for example, upstream of a storage capacitor connected in parallel with an electrical equipment item to be protected.

1. Resistance of limitation A first solution to reduce the risk of deterioration of electrical equipment is to electrically connect a series of limiting resistance of the equipment to be protected. This limiting resistor is useful for limiting the strong current draw at the start of the equipment to be protected, and more precisely during the pre-charging of the storage capacitor.

However, a disadvantage of this solution is that once the start-up phase is over, this limiting resistor (which has no more utility) heats up and tends to dissipate a lot of energy.

2. Limiting resistance with switch To overcome this drawback, it has already been proposed the assembly illustrated in FIG. 1, in which the limiting resistor 17 is positioned on a limiting branch.

1 1 electrically connected in parallel with a conduction branch 12 - such as an electrical wire. A similar arrangement is described in particular in document EP 2 653 950. In this case, the tilting between the limiting branch 1 1 and the conduction branch

12 is controlled by an electrical switch 13.

The operating principle of such an assembly is as follows. At startup, the electrical switch 13 is connected to the limiting branch 1 1 so that the electric current from the power source 14 flows through the limiting branch 1 January. The passage of the current through the resistor 17 makes it possible to limit the strong current draw at the start of the equipment to be protected 15. The storage capacitor 16 is charged. After a given time (which can vary between a few milliseconds and a few seconds depending on the application), the electrical switch 13 switches the flow of the current of the limiting branch 1 1 to the conduction branch 12. This limits the losses energy related to the use of limiting resistance 17.

However, a disadvantage of the assembly illustrated in FIG. 1 is that it does not make it possible to keep the electronic equipment 15 under tension when the electric switch 13 is switched. In addition to the problems described above, another disadvantage of the protective devices The above mentioned utilities using a limiting resistor 17 are that they do not allow charging of the constant current storage capacitor 16, the limiting resistor 17 combined with the storage capacitor 16 constituting an RC circuit. This induces an accelerated aging of the storage capacitor. Moreover, this does not make it possible to predict the value of a fault current in the event of abnormal operation, which can vary according to the equivalent resistance of the circuit (taking into account the possible resistances of the components upstream and downstream of the circuit). protection device), this uncertainty on the fault current may induce one of the risks on the protection of the electronic equipment downstream of the protection device.

An object of the present invention is to provide a protection device of an electrical equipment to overcome at least one of the aforementioned drawbacks.

BRIEF DESCRIPTION OF THE INVENTION

For this purpose, the invention proposes a protection device for electrical equipment including:

 an input terminal intended to be electrically connected to a source of electrical energy supply,

an output terminal intended to be electrically connected to the electrical equipment, remarkable in that the protective device comprises:

 a first current limiting branch including a current source for producing (i.e. maintaining) a constant electric current for a given voltage range,

 a second conduction branch connected in parallel with the limiting branch,

 a control unit for switching the operating mode of the device between:

 a first mode of operation in which the electric current from the electric power supply source flows through the limiting branch without circulating in the conduction branch, and o a second mode of operation in which the electric current from the the electric power supply source flows through the limiting and conducting branches, the impedance of the conduction branch being less than or equal to 10% of the impedance of the limiting branch in the second mode of operation.

Preferred but non-limiting aspects of the system according to the invention are the following:

 the control unit can be electrically connected to the conduction branch to control the activation and deactivation of said conduction branch so as to switch the device between the first and second modes of operation, the limitation branch being not controlled by the steering unit;

 the current source may comprise a transistor, such as a JFET transistor or a MOSFET transistor:

 the drain of the transistor being connected to the input terminal, and

 the gate and the source of the transistor being connected to the output terminal;

the current source may comprise a two-terminal current limiting semiconductor element such as a current limiting diode, for example made of silicon, or of silicon carbide, or of any other semiconductor material; the current limiting branch may furthermore comprise an electrical resistance mounted in series with the current source;

 the conduction branch may comprise a switch controlled as a transistor, such as a JFET transistor, a MOSFET transistor (or a bipolar transistor):

 the drain (or the collector) of the transistor being connected to the input terminal, where the source (or emitter) of the transistor is connected to the output terminal,

 the gate (or the base) of the transistor being connected to the control unit; - the steering unit may include:

 a circuit for detecting a voltage variation at the output of the electrical equipment protection device, and / or

 a circuit for detecting a current variation at the output of the electrical equipment protection device;

 the control unit may comprise a self-polarization circuit for delaying the activation of the conduction branch;

 the control unit comprises a control circuit for generating a signal for blocking the conduction branch when the voltage and / or the intensity at the output of the protection device is greater than a threshold value;

 the limiting and conduction branches can be integrated into a monolithic component such as a JFET transistor or a MOSFET transistor.

BRIEF DESCRIPTION OF THE DRAWINGS Other advantages and characteristics of the system according to the invention will emerge more clearly from the following description of several variant embodiments, given by way of non-limiting examples, from the appended drawings in which:

 FIG. 1 is a schematic representation of a device of the prior art for protecting a load,

FIG. 2 is a block diagram of a load protection device according to the present invention, FIG. 3 is a block diagram of a first variant embodiment of the load protection device of the present invention,

 FIG. 4 is a block diagram of a second variant embodiment of the load protection device of the present invention,

 FIG. 5 is a block diagram of a third variant embodiment of the load protection device of the present invention.

 FIG. 6 is a graph illustrating current curves as a function of the voltage across a current limiting branch, including:

 a resistance on the one hand (curve 80), and

 o a source of current on the other hand (curve 81),

 FIG. 7 is a graph illustrating current curves as a function of the voltage at the terminals of the protection device in FIG.

 a first mode of operation where the current flows through a limiting branch (curve 82),

 o a second mode of operation where the current flows simultaneously through a limiting branch and a conduction branch (curve 83).

DETAILED DESCRIPTION OF THE INVENTION

Various examples of charge protection device according to the present invention will now be described with reference to FIGS. 2 to 5. In these different figures, the equivalent elements are designated by the same reference numeral. 1. General information about the protective device

With reference to FIG. 2, the device for protecting an electric charge comprises an input terminal 31 intended to be electrically connected in series with an electric power supply source, and an output terminal 32 intended to be connected. electrically to an electrical charge to be protected 23. Between the input 31 and output 32 terminals, the device comprises two branches each having a respective function:

 - A first branch 21 - called "current limiting branch" - for limiting the current flowing through the load 23 when a malfunction - such as an electrical fault (for example a short circuit) - is detected,

 - A second branch 22 - called "conduction branch" - having a low impedance to limit the voltage drop across the load 23 when the electric current from the electrical power supply source 25 passes through said conduction branch 22 .

The device also comprises a control unit 24 to allow the passage of the current:

 - or through the limitation branch 21 only according to a first mode of operation

 or through the limitation and conduction branches 21, 22 simultaneously according to a second mode of operation.

Thus, and whatever the mode of operation of the device, the limiting branch 21 is always electrically conductive, so that the load 23 to be protected is always powered, even during the transition between the first and second modes of operation. The conduction branch 22 is electrically conductive only in the second mode of operation. The first mode of operation is advantageously activated when an anomaly - such as a current or voltage overload - is detected.

In the variant embodiment illustrated in FIG. 2, the control unit 24 only controls the activation and deactivation of the conduction branch 22, the limitation branch 21 not being controlled by the control unit 24. This simplifies the mounting of the load protection device. The device illustrated in FIG. 2 effectively protects the load 23 of an electric circuit by limiting the current flowing through it when a malfunction is detected.

Indeed, when an anomaly (overcurrent and / or overvoltage) is detected, the control unit 24 controls the deactivation of the conduction branch 22 to induce the passage of the electric current (generated upstream of the input terminal) to through the limitation branch 21.

By limiting the current flowing in the load 23 when a fault is detected, the protection device illustrated in Figure 2 reduces the risk of degradation of the electrical components located downstream of the output terminal. 2. Current limiting branch

The current limiting branch 21 makes it possible to limit the current flowing in the load 23 to a target intensity value when the second mode of operation of the device is activated. This target value is provided sufficient to ensure the proper functioning of the load 23.

Advantageously, the limiting branch 21 comprises one (or more) source (s) of current - in particular unidirectional (s) - to allow the passage of the current from the input terminal 31 to the output terminal 32. It is understood, in the context of the present invention, by "current source", one (or more) electrical component (s) arranged (s) to produce a constant electric current for a given voltage range.

More precisely and as illustrated in FIG. 6 ar curve 81, when the voltage V across the limiting branch 21 is within a given voltage range (in particular when the voltage V is greater than "+ V _L IM" , or when the voltage V is less than "-V _L IM"), the current source maintains the intensity I of the current at a constant value (in particular a constant value equal to "+ I _L IM" when V≥ + V _L IM, OR equal to "-I _L IM" when V≤-V _L IM) by dynamically varying its impedance. The dynamic variation of the impedance of the current source corresponds - in the case of a current source consisting of a JFET transistor normally passing (called "Normally-on") - to the passage of a linear conduction mode to a mode of conduction in saturation mode. This occurs when the voltage across the current source transistor becomes greater than a saturation voltage Vsat of said transistor. In saturation mode the impedance varies dynamically with the voltage so that the current is kept constant. The operation is then analogous to that of a current source that produces and maintains a constant current regardless of the voltage at its terminals. The fact that the limiting branch 21 comprises a current source makes it possible to charge a storage capacitor 26 (connected in parallel with the load 23 to be protected) with a constant current. This is not possible in the case of a limiting branch including a resistor, as shown in FIG. 6 by the curve 80. Indeed, if the limiting branch comprises a resistor, then the current I at the terminals of the branch This limitation varies linearly as a function of the voltage V applied across its terminals, so that a storage capacitor disposed at the output of the limiting branch is not charged with constant current.

In the variant embodiment illustrated in FIG. 3, the current source comprises a transistor, such as a JFET transistor or a MOSFET transistor. The drain of the transistor is electrically connected to the input terminal 31 of the device, while the gate and the source of the transistor are electrically connected to the output terminal 32 of the device. The use of a JFET or MOSFET transistor has the advantage of facilitating the implementation of the device. Alternatively, the current source may consist of a silicon carbide current limiting diode. The use of a current limiting diode makes it possible to dispense with the presence of a control electronics. In addition, the fact that the diode is silicon carbide provides a component capable of withstanding high energy levels, of the order of 0.1 J to 50J.

Advantageously, the limiting branch 21 may comprise one (or more) resistive element (s) heat dissipation (s) mounted (s) in series with the (the) source (s) current. This makes it possible to dissipate a greater electrical power by Joule effect in the event of a current overload between the power supply source 25 and the load 23.

3. Conduction branch The conduction branch 22 ensures the flow of electric current in steady state. It preferably has a low impedance to limit voltage drops across the load 23. For example, the impedance of the conduction branch 22 may be less than 1 ohm, preferably less than 0.1 ohm, and even more preferably lower at 0.01 ohms.

The conduction branch 22 may comprise a switch controllable by the control unit 24. This switch may be of any type known to those skilled in the art. In particular, the switch is for example a mechanical switch or a hybrid switch.

However, the switch of the conduction branch 22 must be able to move from a closed state to an open state very quickly after the detection of an anomaly (overcurrent and / or overvoltage). This is why the switch of the conduction branch 22 is preferably a static switch. This has the advantage of switching very quickly between a closed state and an open state (switching time less than or equal to one hundred microseconds). Another advantage of using a static switch is that it can withstand high voltages and currents. In the variant embodiment illustrated in FIG. 3, the switch of the conduction branch consists of a transistor, such as a JFET transistor or a MOSFET transistor (or a bipolar transistor):

 the drain (or collector) of the transistor being connected to the input terminal, the source (or emitter) of the transistor being connected to the output terminal, - the gate (or the base) of the transistor being connected to the 'Control unit.

4. Steering Unit

The control unit 24 makes it possible to control the activation and deactivation of the conduction branch 22.

More precisely, the control unit 24 makes it possible to open or close the conduction branch 22 so that the current flowing in the protection device passes through:

 either the limiting branch only according to a first operating mode represented by the curve 82 of FIG. 7,

 or the limiting and conduction branches jointly according to a second operating mode represented by the curve 83 of FIG. 7.

Preferably, the impedance of the conduction branch 22 is chosen to be less than or equal to 10% of the impedance of the limiting branch 21 in the second mode of operation. The passage of the current through the conduction branch 22 is thus favored in the second mode of operation. This makes it possible to limit the losses by Joule effect when the second mode of operation of the protection device is activated. In the variant embodiment illustrated in FIG. 3, the control unit 24 comprises a detection circuit 242 for a voltage variation at the output of the load protection device. As a variant or in combination, the control unit may comprise a circuit for detecting a variation in current at the output of the protection device. This (or these) circuit (s) of detection makes it possible to identify an anomaly (overvoltage and / or overcurrent) likely to damage the load 23.

When a voltage variation detected by the detection circuit 242 exceeds a threshold voltage defined by an avalanche component D4 such as a Zener diode, a control circuit 243 of the control unit 24 transmits a blocking signal on the gate of the controllable switch of the conduction branch 22.

This blocking signal induces the opening of the controllable switch so as to deactivate the conduction branch 22. The current then flows exclusively through the current limiting branch 21.

When the voltage variation detected by the detection circuit 242 becomes lower than the threshold voltage, the control circuit 243 no longer emits a blocking signal. The controllable switch returns to a conducting state so as to activate the conduction branch 22. The current then flows both through the limiting branch 21 and the conduction branch 22.

Advantageously, the control unit 24 may comprise a self-biasing circuit 241 between the detection circuit 242 and the gate of the controllable switch. The self-biasing circuit 241 delays the reactivation of the controllable switch. More precisely, the self-biasing circuit 241 makes it possible to delay the closing of the controllable switch by a non-zero delay corresponding to the discharge time of a capacitor C1 of the self-biasing circuit 241. This makes it possible to limit the risks of degradation of the load, in particular in the case of impulse-type current overloads. We will now describe the operating principle of the control unit 24 illustrated in Figure 3 in the case of an electrical assembly including a storage capacitor 26 as shown in Figure 2. In this case, an overload of current can be caused when pre-charging the storage capacitor.

At the start of the electrical equipment 23 to be protected, the storage capacitor 26 causes a strong current draw. This induces the appearance of a current overload in the electrical circuit. Detection circuit 242 detects a voltage change at the output terminals of the charge protection device. When this voltage variation becomes greater than the threshold voltage defined by the Zener diode D4, the control circuit 243 transmits a blocking signal to the gate of the controllable switch of the conduction branch 22.

The blocking signal passes through the self-biasing circuit 241. The capacitor C1 of the self-biasing circuit 241 loads. Simultaneously with the charging of the capacitor C1, the application of the blocking signal to the gate induces the opening of the controllable switch: the conduction branch 22 is deactivated.

The charge protection device then operates according to its first mode of operation: the entire current from the electric power supply source 25 is transmitted to the load 23 via the limiting branch 21 so that the current received by the load 23 is limited to the target intensity value to protect the load 23. When the storage capacitor 26 is charged, a steady state of the electrical circuit is established. The voltage variation at the output of the protection device decreases, the detection circuit 242 detecting this decrease. When the output voltage difference becomes lower than the threshold voltage defined by the avalanche component D4, the blocking signal is interrupted. The capacitor C1 of the self-biasing circuit 241 discharges towards the gate of the controllable switch so as to keep the latter in a locked state for a few moments. This makes it possible to delay the closing of the controllable switch. When the capacitor C1 is discharged, the gate of the controllable switch is no longer powered. The controllable switch then goes from a blocked state (ie open) to a on state (ie closed).

The conduction branch 22 is reactivated. The charge protection device then operates according to its second mode of operation: the current coming from the electric power supply source 25 is transmitted to the load 23 via the limiting branch 21 on the one hand and the conduction branch 22 on the other hand.

In the event of a permanent current overload (for example if a lightning strike strikes the electric circuit), the detection circuit 242 detects an output voltage variation greater than the threshold voltage defined by the Zener diode D4. The control circuit 243 transmits to the gate of the controllable switch a blocking signal through the self-biasing circuit 241. This blocking signal opens the controllable switch to deactivate the conduction branch 22.

The first mode of operation is implemented. When the output voltage of the protection device becomes lower than the threshold voltage, the control unit 24 controls the reactivation of the conduction branch 22 as described above. 5. Monolithic component

In an alternative embodiment, the limiting 21 and conduction branches 22 may be integrated in a monolithic unitary component made of silicon or silicon carbide (or another semiconductor material, preferably with a wide bandgap) such that a JFET transistor or a MOSFET transistor or a bipolar transistor. This limits the space occupied by the second branch, and therefore the size of the protective device.

With reference to FIGS. 4 and 5, two exemplary embodiments of a monolithic component incorporating the limiting 21 and conduction branches 22 on the same substrate are illustrated.

With reference to FIG. 4, the monolithic component has a JFET type structure. It comprises a substrate 61 common to the limiting 21 and conduction branches 22. The rear face of the N-type doped substrate 61 comprises a lower N-doped lower layer 62 covered with a metal layer 63 forming the drain. The front face of the substrate 61 comprises P-doped buried regions 64 on which is disposed an N-type top layer 70 forming a lateral channel of the limiting and conduction branches 22. On this upper layer 70 are arranged upper regions 68 of type P. These regions partially overlap the upper layer 70

Above the upper regions 68 and the upper layer 70, first and second metal electrodes 65a, 65b are disposed. These first and second electrodes 65a, 65b form a control gate of the branch 22 and define the characteristics of the limiting branch 21.

The monolithic component comprises a first separation trench for defining the limiting 21 and conduction branches 22. This first trench extends through the upper layer 70 of the component to the buried regions 64 to allow their connection.

More specifically, the first separation trench extends to a depth at least equal to that of the upper layer 70. A layer of electrically insulating material 66 covers the first metal electrode 65a forming a grid of the branch 21, while no layer of electrically insulating material covers the second electrode 65b forming a gate. A source metal layer 67 covers the entire surface of the monolithic component. So :

 the first electrode 65a forming a gate is electrically isolated from the source metal layer 67: this first stack of layers of the monolithic component constitutes the conduction branch whose gate (first electrode) is intended to be electrically connected to the transmission unit; control 24, while the drain 63 and the source 67 are intended to be respectively connected to the input terminal 31 and the output terminal 32 of the load protection device;

 the second electrode 65b forming a gate is in electrical contact with the source metal layer 67: this second stack of layers of the monolithic component constitutes the current limiting branch 21 whose gate 65b and the source 67 are intended to be connected to the output terminal 32 of the load protection device, while the drain 63 is intended to be connected to the input terminal 31 of the device.

The peculiarity of the monolithic structure component JFET illustrated in FIG. 4 is that the conduction branch 22 is activated unless an electric voltage is applied to the gate electrode (known under the standard name "NORMALLY ON"). the limitation branch is permanently activated.

The monolithic component illustrated in FIG. 5 differs from the component illustrated in FIG. 4 in that its structure is of the MOSFET type. The peculiarity of the monolithic structure component MOSFET illustrated in FIG. 5 is that the conduction branch 22 is deactivated unless an electric voltage is applied to the gate electrode, the limiting branch being permanently activated. It comprises a substrate 73 common to the limiting 21 and conduction branches 22. The rear face of the N-type doped substrate 73 comprises a lower N-doped lower layer 72 covered with a metal layer 71 forming a drain. The substrate 73 comprises first P-doped buried regions 74 at its upper face. The front face of the substrate 73 is covered by an upper layer 82 of N.

The upper layer 82 of the conduction branch 22 comprises:

 second regions buried at depth 75 with a lower doping P, and

third superficially buried deep-doped N-type 76 regions.

The monolithic component comprises a first MOSFET trench extending through the upper layer 82 to the substrate 73. It also includes a fourth P-type buried region 83 in the bottom of the trench, the fourth buried region 83 and the first buried regions 74 defining N-type channels in the substrate 73.

The monolithic component comprises a second separation trench for defining the limiting branches 21 and conduction 22. This second trench extends through a second central zone 76 of the component to the first buried regions 74 to allow their connection.

More specifically, the second separation trench extends to a depth at least equal to that of the upper layer 82.

First and second thin oxide layers 78a and 78b defining the gate oxide of the MOSFETs partially cover the upper face of the first buried regions 74, the second zones 76, the fourth buried regions 83 and the upper layer 82. The component comprises a first metal electrode 79 forming the control gate of the branch 22 on the first layer 78a.

A layer of electrically insulating material 80 covers the first metal electrode 79 forming a grid of the branch 21. While no layer of electrically insulating material covers the second layer 78b forming the gate of the MOSFET limitation branch.

Metal layers 77 contact the first buried regions 74 and the second zones 76 of the limiting and conduction branches 21, 22.

A source metal layer 81 covers the entire surface of the monolithic component. So :

 the first electrode 79 forming a gate is electrically isolated from the source metal layer 81: this first stack of layers of the monolithic component constitutes the conduction branch whose gate (first electrode) is intended to be electrically connected to the control 24, while the drain 71 and the source 81 are intended to be respectively connected to the input terminal 31 and the output terminal 32 of the load protection device;

 - The layer 81 covers the area 78b forming a gate is in electrical contact with the source metal layer 77: this second stack of layers of the monolithic component constitutes the current limiting branch 21 whose source 81 are intended to be connected to the terminal output 32 of the load protection device, while the drain 71 is intended to be connected to the input terminal 31 of the device.

6. Conclusions The circuit described above is suitable for use in a DC or AC power grid. It protects electrical equipment from overloads of current likely to appear in the electrical network in the event of a start-up phase of the equipment to be protected, pre-charging of a storage capacitor or lightning shock. It can be used as a current regulator function, delivering a constant current to any AC or DC load, or to detect and limit any inrush current on the AC or DC network in case of overvoltage.

The reader will have understood that many modifications can be made to the invention described above without physically going out of the new teachings and advantages described herein.

Therefore, all such modifications are intended to be incorporated within the scope of the appended claims.

Claims

1. Device for protecting an electrical equipment (23) including:

 an input terminal (31) intended to be electrically connected to an electric power source (25),

 an output terminal (32) intended to be electrically connected to the electrical equipment (23),

 characterized in that the protection device comprises:

 a first current limiting branch (21) including a current source for producing a constant electric current for a given voltage range,

 a second conduction branch (22) connected in parallel with the limiting branch (21),

 a control unit (24) for switching the operating mode of the device between:

 a first mode of operation in which the electric current from the electric power supply source (25) flows through the limiting branch (21) without circulating in the conduction branch (22), and

 a second mode of operation in which the electric current from the electric power supply source (25) flows through the limiting and conduction branches (21, 22), the impedance of the conduction branch (22); ) being less than or equal to 10% of the impedance of the limiting branch (21) in the second mode of operation.

2. Protection device according to claim 1, wherein the control unit (24) is electrically connected to the conduction branch (22) to control the activation and deactivation of said conduction branch (22) so as to to switch the device between the first and second operating modes, the limiting branch (21) not being controlled by the control unit (24).

Protective device according to any one of claims 1 or 2, wherein the current source comprises a transistor, such as a JFET transistor or a MOSFET transistor:

 the drain of the transistor being connected to the input terminal (31), and

 the gate and the source of the transistor being connected to the output terminal (32).

Protective device according to any one of claims 1 or 2, wherein the current source comprises a current limiting diode, for example silicon, or silicon carbide, or any other semiconductor material.

A protection device according to any of claims 1 to 4, wherein the current limiting branch (21) further comprises an electrical resistor connected in series with the power source.

Protective device according to any one of claims 1 to 5, wherein the conduction branch (22) comprises a transistor, such as a JFET transistor or a MOSFET transistor:

 the drain of the transistor being connected to the input terminal (31),

 the source of the transistor being connected to the output terminal (32),

 the gate of the transistor being connected to the control unit (24).

Protective device according to any one of claims 1 to 6, wherein the control unit (24) comprises:

 a detection circuit (242) for a voltage variation at the output of the electrical equipment protection device, and / or

a circuit for detecting a current variation at the output of the electrical equipment protection device.

8. Protection device according to any one of claims 1 to 7, wherein the control unit (24) comprises a self-biasing circuit (241) for delaying the activation of the conduction branch (22).

The protective device according to any one of claims 1 to 8, wherein the control unit (24) comprises a control circuit (243) for generating a conduction branch lock signal (22) when the voltage and / or the output intensity of the protection device is greater than a threshold value.

10. Protection device according to any one of the preceding claims, wherein the limiting limbs (21) and conduction (22) are integrated in a monolithic component such as a JFET transistor or a MOSFET transistor.