WO2020260301A1 - Security device for an electronic switch, and electrical system comprising a device of said kind - Google Patents

Abstract

Autonomous security device and electrical system comprising a device of said kind. Security device comprising: a. a main input terminal (A) intended to be connected to a first DC voltage source (BAT), b. a main output terminal (B) intended to be connected to a first electrical apparatus (Ep1) and to a second electrical apparatus (Ep2), c. a switch device (10) comprising an input terminal (E), an output terminal (S) and a control terminal (G), wherein the input terminal of the switch device (10) is connected to the main input terminal (A), the output terminal of the switch device (10) is connected to the main output terminal (B), the switch device (10) comprises at least one first switch (Q1), the control terminal (G) of the switch device (10) is connected to a control device (30) so as to open or close the at least one first switch (Q1), d. a protective device (20) which is connected between the main input terminal (A) and the main output terminal (B); e. characterized in that: in the ON state, the protective device (20, 200) is controlled in such a way as to create a current path through which the discharge current (Id) runs parallel to the switch device (10, 100) when the switch control device (30) controls the switch device (10, 100) in the open state and when a discharge current (Id) runs through the stray inductance (L) between the first electrical apparatus (Ep1) and the second electrical apparatus (Ep2).

Description

Description

Title of the invention: Safety device for electronic switch and electrical system comprising such a device

[1] The present invention relates generally to a safety device for an electrical system in a motor vehicle.

[2] More particularly, the invention relates to an electrical system comprising a safety device intended to control a switch device allowing the dissipation of a discharge current generated by a parasitic inductance during the disconnection of electrical equipment from the device. electrical network of the motor vehicle. The safety device also makes it possible to filter electrical disturbances superimposed on the vehicle's electrical network so as to prevent any untimely triggering of the switch device.

[3] Electric or hybrid vehicles are equipped with an electrical power supply network supplying all the electrical equipment such as an alternator-starter or direct voltage converter, a switch device connected between the power source and electrical equipment so as to disconnect them from the electrical network. In this type of electrical network, the connections between the various electrical equipment require long cable lengths, thus generating parasitic inductances and also overvoltages.

[4] A known problem is that of the dissipation of an electric current contained in the parasitic inductance during the disconnection of electrical equipment from the electrical network of the motor vehicle.

[5] This problem is particularly difficult to solve when it comes to dissipating a discharge current of the order of 500A or more when disconnecting an electrical equipment supplied for example by a direct voltage of at least 48V , the electrical network comprising switch devices also sensitive to overvoltages caused by parasitic inductances. [6] It is therefore necessary, when disconnecting electrical equipment from the electrical network of the motor vehicle, to dissipate the discharge current so as not to degrade the components of this electrical network.

[7] To do this, it is known from the state of the art an electrical system comprising a safety device such as that shown in [Fig.1]. Such an electrical system SE1 comprises a safety device 40 comprising:

at. a main input terminal A intended to be connected to a first DC voltage source BAT

b. a main output terminal B intended to be connected to a first electrical device Ep1 and to a second electrical device Ep2, c. a switch device 100 comprising an input terminal E, an output terminal S and a control terminal G, the input terminal of the switch device 100 being connected to the main input terminal A, the terminal output of the switch device 100 being connected to the main output terminal B, said switch device 100 comprising at least a first switch Q1 and a second switch Q2, the control terminal G of said switch device 100 being connected to a control device 30 so as to open or close the first switch Q1 or the second switch Q2 d. a TVS protection device connected between the current output terminal S and the electrical ground;

[8] Thus, in an electrical system of the prior art, the safety device comprises a component for suppressing transient voltage (from the English "transient-voltage-suppressor" or TVS, such as a diode arranged to pass in reverse mode (avalanche mode) allows the excess current to be injected to the electrical ground so as to cut off the switch voltage. TVS components have the particularity of presenting an avalanche voltage beyond which the TVS component absorbs the excess current and suppresses the overvoltage. The TVS component being placed between the electrical equipment and the battery, the TVS components must be dimensioned for an avalanche voltage greater than the battery voltage, which can reach several hundred volts. level of electrical equipment during a surge is therefore the avalanche voltage of the TVS component to which is added the battery voltage, the voltage seen by electrical equipment being able to reach around one hundred volts. A voltage of the order of a hundred volts can irreversibly damage electrical equipment. A TVS component whose avalanche voltage is high, of the order of several tens of volts, is an expensive component while having a large bulk. In addition, the TVS component requires a connection to the electrical ground, which brings an additional mechanical constraint during implementation in a motor vehicle.

[9] The aim of the invention is to alleviate at least in part the aforementioned problems.

[10] To this end, it is proposed, according to a first aspect, a safety device comprising:

at. a main input terminal intended to be connected to a first direct voltage source,

b. a main output terminal intended to be connected to a first electrical equipment item and to a second electrical equipment item, c. a switch device comprising an input terminal, an output terminal and a control terminal, the input terminal of the switch device being connected to the main input terminal, the output terminal of the control device switch being connected to the main output terminal, said switch device comprising at least a first switch, the control terminal of said switch device being intended to be connected to a control device so as to open or close the switch. minus a first switch, and d. a protection device connected between the main input terminal A and the main output terminal B,

said safety device being characterized in that said protection device is controlled in the on state so as to create a current path crossed by a discharge current in parallel with the switch device when the control device controls said device. switch in the open state and when the parasitic inductance between the first and the second electrical equipment is crossed by the discharge current. [1 1] The protection device is remarkable in that it is connected in parallel with the switch device, between the battery and the electrical equipment, requiring no connection to the electrical ground. The protection device is also remarkable in that it comprises at least one transient voltage suppression diode, the avalanche voltage of which is lower than the battery voltage. The dissipation of the discharge current of the parasitic inductance is achieved by the protection device when the switch control device is inactive, while avoiding the re-conduction of the switch device.

[12] Thus, the protection device connected in parallel with the switch device dissipates the discharge current when it is controlled to the on state, making it possible to protect electrical equipment against overvoltages. The transient suppressor diode is no longer connected to electrical ground, and it is no longer necessary to use a transient suppressor diode whose avalanche voltage is greater than the battery voltage.

[13] In a particular embodiment of the invention, the parasitic inductance is created by the electrical connection between the first electrical equipment and the second electrical equipment.

[14] In a particular embodiment of the invention, the protection device is intended to be controlled in the state through said control device.

[15] In a particular embodiment of the invention, the protection device is intended to be controlled in the on state by the control device when the control device controls the switch device in the open state so that a discharge current generated by said inductor passes through the current path.

[16] In a particular embodiment of the invention, the protection device is intended to be controlled in the open state by the control device so as to open the current path when the value of the discharge current becomes less than one. threshold, for example positive, or when the discharge current is canceled. [17] In a particular embodiment of the invention, the control device is intended to be connected to the control terminal of the switch device via a first resistor.

[18] In a particular embodiment of the invention, the safety device comprises the first resistance.

[19] In a particular embodiment of the invention, the first switch comprises: a. a current input terminal connected to the input terminal of the

switch device,

b. a current output terminal connected to the output terminal of the

switch device, and c. a control terminal connected to the control terminal of the

switch device.

[20] In a particular embodiment of the invention, the switch device comprises:

at. A first switch comprises: i. a current input terminal connected to the input terminal of the switch device

ii. a current output terminal connected to the output terminal of the switch device

iii. a control terminal connected to the control terminal of the switch device

[21] In a particular embodiment of the invention, the protection device comprises:

at. A third switch comprising a current input terminal, a current output terminal and a control terminal, said current input terminal being connected to the main input terminal;

b. A first transient voltage suppression diode, including

the anode is connected to the main output terminal and the cathode is connected to the output terminal of the third switch.

[22] In a particular embodiment of the invention, the switch device further comprises a second switch, the output terminal of said first switch being connected to the output terminal of the switch device through said second switch.

[23] In a particular embodiment of the invention, the second switch comprises:

at. an input terminal connected to the output terminal,

b. an output terminal connected to the output terminal of the first

switch, and c. a control terminal connected to the control terminal of the

switch device.

[24] In a particular embodiment of the invention, the control terminal of the switch device is intended to be connected to a control device so as to open or close at least a first switch and the second switch.

[25] In a particular embodiment of the invention, the protection device further comprises a second transient voltage suppression diode, the cathode of the first transient voltage suppression diode is connected to the cathode of said second suppression diode of transient voltages and the anode of the second transient suppressing diode is connected to the current output terminal of the third switch.

[26] In a particular embodiment of the invention, the switch device comprises a first switch and a second switch,

at. said first switch comprising:

i. an input terminal connected to the input terminal, ii. the output terminal is connected to the output terminal of the second switch, and

iii. a control terminal is connected to the control terminal of the switch device.

b. said second switch comprising:

i. an input terminal connected to the output terminal, ii. the output terminal is connected to the current output terminal of the first switch, and iii. a control terminal is connected to the control terminal of the switch device.

[27] In a particular embodiment of the invention, the protection device comprises:

at. A third switch comprising a current input terminal, a current output terminal and a control terminal, said current input terminal being connected to the main input terminal;

b. A first transient voltage suppression diode, including

the anode is connected to the main output terminal and the cathode is connected to the cathode of a second transient voltage suppression diode,

vs. A second transient voltage suppression diode, including

the anode is connected to the current output terminal of the third switch.

[28] In a particular embodiment of the invention, the protection device comprises:

at. a third switch comprising a current input terminal, a current output terminal and a control terminal, said current input terminal being connected to the main input terminal, b. a first transient voltage suppression diode, the anode of which is connected to the main output terminal, and

a second transient suppression diode, the anode of which is connected to the current output terminal of the third switch and the cathode of which is connected to the cathode of the first transient suppression diode.

[29] In a particular embodiment of the invention, the control terminal of the third switch is intended to be connected to the control device so as to open or close said third switch.

[30] In a particular embodiment of the invention, the third transistor is intended to be controlled in the closed state by the control device so as to create said current path. [31] In a particular embodiment of the invention, the third transistor is intended to be controlled in the open state by said control device so as to open said current path.

[32] In a particular embodiment of the invention, the third transistor is intended to be controlled in the open state by the control device so as to eliminate said current path when the discharge current vanishes or becomes less than first threshold.

[33] In a particular embodiment of the invention, the third transistor is intended to be controlled to the open state by the control device when the discharge current vanishes or falls below the first threshold.

[34] In a particular embodiment of the invention, the control device is intended to be connected to the control terminal of the third switch via a second resistor.

[35] In a particular embodiment of the invention, the switch (s) of the switch device are MOSFET transistors, or IGBT transistors, or even bipolar transistors.

[36] In a particular embodiment of the invention, the control terminal of the switch device is intended to be connected to a control device so as to open or close the first switch and the second switch.

[37] Optionally, the switches are transistors using silicon (Si) technology, or gallium nitride (GaN) technology, or even silicon carbide (SiC) technology.

[38] The invention also relates, according to a second aspect, to a voltage converter comprising a safety device according to the first aspect of the invention

[39] In particular the voltage converter is a DC-DC voltage converter or an AC-DC voltage converter

[40] It is also conceivable, in other embodiments, that the protection device and the voltage converter according to the invention have in combination all or part of the aforementioned characteristics.

[41] [Fig. 1] shows an electrical system comprising a safety device according to the prior art. [42] [Fig. 2] shows an electrical system comprising a safety device implementing the invention according to a first embodiment of the invention.

[43] [Fig. 3] shows an electrical system comprising a safety device implementing the invention according to a second embodiment of the invention.

[44] With reference to [Fig. 2] an electrical system SE2 implementing the invention will now be described. The electrical system SE2 is for example integrated into an electrical network of a motor vehicle.

[45] The SE2 electrical system comprising:

at. A first electrical equipment Ep1 and a second electrical equipment Ep2.

b. A safety device 2 comprising:

i. a main input terminal A connected to a first DC voltage source BAT, for example a battery supplying a voltage of 48V.

ii. A main output terminal B connected to the first electrical equipment Ep1 and second electrical equipment Ep2.

iii. a switch device 10 comprising:

1. an input terminal E, connected to the main input terminal A

2.an output terminal S, connected to the main output terminal B

3. a control terminal G, connected to a control device 30 via a resistor R iv. a protection device 20 connected between the main input terminal A and the main output terminal B

v. a switch control device 30 connected to the control terminal G of the switch device 10 via a first resistor R1. [46] The first and second electrical equipment Ep1 and Ep2 are, for example, alternator-starter or voltage converter such as an inverter. The first electrical equipment Ep1 is connected to the electrical ground and has a voltage Vep1 between its terminals, and the second electrical equipment Ep2 is connected to the electrical ground and has a voltage Vep2 between its terminals.

[47] The electrical connection between the first electrical equipment Ep1 and the second electrical equipment Ep2 creates a wiring inductance or also called parasitic inductance L. Thus, when the first Ep1 and second Ep2 electrical equipment are supplied with electrical energy, this parasitic inductance is crossed by current I.

[48] The switch device 10 comprises a first switch Q1, the drain current input terminal of the first switch Q1 is connected to the input terminal E, the current output terminal s1 of the first switch Q1 is connected to output terminal S and control terminal g1 is connected to control terminal G.

[49] In this way, the control device 30 controls the opening or closing of the first switch Q1. A current I being able to flow in the direction of the input terminal E towards the output terminal S when the control device 30 controls the first switch Q1 on closing, no current passing through the input terminal E towards the terminal of output S when the control device 30 controls the first switch Q1 on opening.

[50] The value of the first resistor R1 connected between the control circuit 30 and the control terminal G is chosen so as to protect the control circuit 30.

[51] In other words, the first and second electrical equipment Ep1 and Ep2 are supplied with electrical energy when the first switch Q1 is commanded to close by the control device 30. The state of the first switch Q1 being in a saturated state when 'it is commanded to close, and in the blocked state when the switch Q1 is commanded to open.

[52] The protection device 20 comprises in the example considered:

at. A third switch Q3 comprising a current input terminal d3 being connected to the main input terminal A, an output terminal in current s3 and a control terminal g3 being connected to the control circuit 30 through a second resistor R2; b. A first transient voltage suppression diode Tvs1, the anode of which is connected to the main output terminal B and the cathode is connected to the output terminal s3 of the third switch Q3

[53] Thus, when the control device 30 controls the first switch Q1 on closing, the parasitic inductance L is crossed by the current I. When the control device 30 controls the first switch Q1 on opening, the parasitic inductance L generates a discharge current Id resulting from the current I and a voltage at its terminals, which has the effect of creating an overvoltage between the output terminal S and the input terminal E of the switch system 10. The discharge current Id flowing from the main input terminal A to the main output terminal B.

[54] Indeed, the voltage Vbat - Vb is directly applied to the switch voltage Vds of the first switch Q1 as defined in [Math.1]

[55] [Math.1] V _ds = V _bat - V _B

[56] The protection device 20 is connected in parallel with the switch device 10 between the first DC voltage source BAT and the first and second electrical equipment Ep1 and Ep2 so as to avoid a connection to the electrical ground. The protection device 20 then makes it possible to avoid an overvoltage when opening the first switch Q1 and therefore to prevent the voltage between the output S and input E terminals from exceeding a predetermined threshold. In the example described the voltage between the output terminal S and the input terminal E is the switch voltage Vds of the first switch Q1.

[57] When the switch controller 30 controls the first switch Q1 on opening, the switch controller 30 controls the third switch Q3 on closing. The third switch Q3 for switching to the on state the protection device 20.

[58] Thus, the overvoltage caused by the opening of the first switch Q1 is limited by the protection device 20, the first transient voltage suppression diode Tvs1 allowing the clipping of the overvoltage and the dissipation of the discharge current Id. [59] In other words, when the third switch Q3 is controlled in the closed state, the voltage Vb being the voltage at the terminals of the electrical equipment is equal to the avalanche voltage of the component Tvs1 plus the battery voltage Vbat. The first transient voltage suppression diode Tvs1 being chosen so that its avalanche voltage is of the order of several tens of volts, the voltage Vb at the terminals of the electrical equipment is thereby reduced compared to the electrical system SE1 by the prior art which uses a transient voltage suppression diode Tvs of several hundred volts.

[60] Preferably, the overvoltage at the terminals of the electrical equipment of the SE2 system is reduced by 50% compared to the safety device 40 of the SE1 electrical system of the prior art.

[61] Still in other words, the switch control circuit 30 makes it possible to switch the third switch Q3 to the on state and therefore to activate the protection device 20 when the first switch Q1 is opened. The selective activation of the protection device 20 by the third switch Q3 makes it possible to choose a first transient voltage suppression diode Tvs1 having a lower avalanche voltage than those used in the electrical system SE1 of the prior art, and thus reduce the overvoltage at the terminals of electrical equipment Ep1 and Ep2.

[62] The selective activation of the protection device 20 by the third switch Q3 also makes it possible to prevent the re-conduction of the first transient voltage suppression diode Tvs1, the battery voltage being greater than the avalanche voltage of the first transient voltage suppression diode Tvs1.

[63] When the discharge current Id is dissipated in the first transient voltage suppression diode Tvs1, the switch control circuit 30 then controls the third switch Q3 of the protection device 20 on opening so as to make inactive the protective device 20.

[64] We will describe a second embodiment of the invention. The [Fig. 3] illustrates this second embodiment. For the sake of simplicity, identical references are given in this figure to the elements common with the first embodiment and illustrated in [FIG. 2] [65] In the example described, the electrical system SE3 comprises:

at. A first electrical equipment Ep1 and a second electrical equipment Ep2.

b. Safety device 3 comprising:

i. a main input terminal A.

ii. a main output terminal B.

iii. a switch device 100

iv. a protective device 200

v. a switch control device 30

[66] The switch device 100 includes a first switch Q1 and a second switch Q2 connected "head-to-tail", in other words the first switch Q1 and the second switch Q2 are connected so-called "common source". In the example described here, the first switch Q1 and the second switch Q2 are N doped MOSFETs. The current input terminal d1 of the first switch Q1 is connected to the input terminal E, the current output terminal s1 of the first switch Q1 is connected to the current output terminal s2 of the second switch Q2 and the control terminal g1 is connected to the control terminal G, the current input terminal d2 of the second switch Q2 is connected to the output terminal S, the control terminal g2 is connected to the control terminal G. In this way, when one of the first switch Q1 and the second switch Q2 is open, no current can flow between the terminals input E and output S. The control terminals of the first switch Q1 and of the second switch Q2 are also interconnected. Thus, the control device 30 makes it possible to control the opening of the first switch Q1 and of the second switch Q2 and therefore to interrupt any flow of current in both directions between the input terminal E and the output terminal S.

[67] The protection device 200 further comprises in the example considered:

at. A third switch Q3 comprising a current input terminal d3 being connected to the main input terminal A, an output terminal in current s3 and a control terminal g3 being connected to the control circuit 30 through a second resistor R2; b. A first transient voltage suppression diode Tvs1, the anode of which is connected to the main output terminal B and the cathode is connected to the cathode of a second transient voltage suppression diode Tvs2;

vs. A second transient voltage suppression diode Tvs2, the anode of which is connected to the current output terminal s3 of the third switch Q3.

[68] Thus, the control device 30 is able to control the opening or closing of the first switch Q1 and the second switch Q2. The current I is said to be positive when the DC voltage source BAT supplies the current I, the current I flowing through the switch device 100 in the direction of the input terminal E towards the output terminal S so as to supply the first Ep1 or the second Ep2 electrical equipment. The current I is said to be negative when the first Ep1 or the second Ep2 electrical equipment supply the current I, the current I flowing through the switch device 100 in the direction of the output terminal S towards the input terminal E so as to supply the DC voltage source BAT.

[69] When opening the first switch Q1 or the second switch Q2, the parasitic inductance L generates a discharge current Id and a voltage at its terminals, which has the effect of creating an overvoltage between the output terminal S and the input terminal E of the switch system 100. Indeed, the voltage Vbat - Vb is directly applied to the voltage between the input terminal E and the output terminal S.

[70] In other words, when the direction of the current I is said to be positive, when the first transistor Q1 is opened, the overvoltage Vbat-Vb is directly applied to the switch voltage Vds1 of the first switch Q1, the current I being able to flow through the intrinsic diode of the second switch Q2. When the current I is said to be negative, when the second switch Q2 is opened, the overvoltage Vbat-Vb is directly applied to the switch voltage Vds2 of the second switch Q2. [71] The protection device 200 therefore makes it possible to limit an overvoltage during the opening of the first switch Q1 or of the second switch Q2, therefore to control the overvoltage and ensure that the voltage between the output S and input terminals E does not exceed a predetermined threshold. The protection device 200 also makes it possible to dissipate the discharge current Id, whether in the positive or negative direction.

[72] Indeed, during the opening of the first switch Q1 and the closing of the third switch Q3 by the switch control circuit 30, the discharge current Id being said to be positive, passes through the protection device 200 in the direction from the main input terminal A to the main output terminal B, the first transient voltage suppression diode Tvs1 making it possible to stop the overvoltage as well as to dissipate the discharge current Id.

[73] When the first switch Q2 opens and the third switch Q3 is closed by the switch control circuit 30, the discharge current Id being said to be negative, passes through the protection device 200 in the direction of the main output terminal B to the main input terminal A, the second transient voltage suppression diode Tvs2 making it possible to clip the overvoltage as well as to dissipate the discharge current Id.

[74] As a variant, the first and second transient voltage suppression diodes Tvs1 and Tvs2 can be replaced by a single so-called "bidirectional" transient voltage suppression diode, in other words, the bidirectional transient voltage suppression diode makes it possible to d 'clipping a surge and dissipating the discharge current Id, whether the discharge current Id is positive or negative.

[75] The selective activation of the protection device 200 by the third switch Q3 also making it possible to prevent the re-conduction of the first and second transient voltage suppression diodes Tvs1 and Tvs2, the battery voltage being greater than the voltage d avalanche of the first transient voltage suppression diode Tvs1 or of the second transient voltage suppression diode Tvs2.

When the magnetic energy contained in the inductor L is dissipated, the discharge current Id is canceled in the first suppression diode. transient voltages Tvs1 or in the second transient voltage suppression diode Tvs2, the switch control circuit 30 then controls the third switch Q3 of the protection device 200 on opening so as to make the protection device 200 inactive.

Claims

Claims

[Claim 1] Safety device (2,3) comprising:

at. a main input terminal (A) intended to be connected to a first direct voltage source (BAT),

b. a main output terminal (B) intended to be connected to a first electrical device (Ep1) and to a second electrical device (Ep2), c. a switch device (10,100) comprising an input terminal (E), an output terminal (S) and a control terminal (G), the input terminal of the switch device (10,100) being connected to the main input terminal (A), the output terminal of the switch device (10,100) being connected to the main output terminal (B), said switch device (10,100) comprising at least a first switch (Q1 ), the control terminal (G) of said switch device (10,100) being intended to be connected to a control device (30) so as to open or close the at least one first switch (Q1), and

d. a protection device (20,200) connected between the main input terminal (A) and the main output terminal (B),

said safety device (2,3) being characterized in that said protection device (20,200) is controlled in the on state so as to create a current path crossed by a discharge current (Id) in parallel with the device d 'switch (10,100) when the control device (30) controls said switch device (10,100) in the open state and when the parasitic inductance (L) between the first (Ep1) and the second (Ep2) electrical equipment is crossed by the discharge current (Id).

[Claim 2] A safety device (2,3) according to claim 1 wherein the first switch (Q1) comprises:

at. a current input terminal (d1) connected to the input terminal (E) of the switch device (10,100),

b. a current output terminal (s1) connected to the output terminal (S) of the switch device (10,100), and vs. a control terminal (g1) connected to the control terminal (G) of the switch device (10,100).

[Claim 3] A safety device (2,3) according to claims 1 to 2 in which the protection device (20,200) comprises:

at. a third switch (Q3) comprising a current input terminal (d3), a current output terminal (s3) and a control terminal (g3), said current input terminal (d3) being connected to the main input terminal (A); and

b. a first transient voltage suppression diode (Tvs1), the anode of which is connected to the main output terminal (B) and the cathode is connected to the output terminal (s3) of the third switch (Q3).

[Claim 4] A safety device (3) according to one of claims 1 to 3 wherein the switch device (100) further comprises a second switch (Q2), the output terminal (s1) of said first switch being connected to the output terminal (S) of the switch device (100) through said second switch (Q2).

[Claim 5] A safety device (3) according to the preceding claim wherein said second switch (Q2) comprises:

at. an input terminal (d2) connected to the output terminal (S),

b. an output terminal (s2) connected to the output terminal (s1) of the first switch (Q1), and

vs. a control terminal (g2) connected to the control terminal (G) of the switch device (100).

[Claim 6] A safety device (3) according to claim 5 taken together with claim 3 wherein the protection device (200) further comprises a second transient voltage suppression diode (Tvs2) and wherein the cathode of the first transient voltage suppression diode (Tvs1) is connected to the cathode of said second transient voltage suppression diode (Tvs2) and wherein the anode of the second transient voltage suppressor diode suppression of transient voltages (Tvs2) is connected to the current output terminal (s3) of the third switch (Q3).

[Claim 7] A safety device (3) according to claim 1 wherein the switch device (100) comprises a first switch (Q1) and a second switch (Q2),

at. said first switch (Q1) comprising:

i. an input terminal (d1) connected to the input terminal (E), ii. the output terminal (s1) is connected to the output terminal (s2) of the second switch (Q2), and

iii. a control terminal (g1) is connected to the control terminal (G) of the switch device (100),

b. said second switch (Q2) comprising:

i. an input terminal (d2) connected to the output terminal (S), ii. the output terminal (s2) is connected to the current output terminal (S) of the first switch (Q1), and

iii. a control terminal (g2) is connected to the control terminal (G) of the switch device (100).

[Claim 8] A safety device (3) according to the preceding claim in which the protection device (200) comprises:

at. a third switch (Q3) comprising a current input terminal (d3), a current output terminal (s3) and a control terminal (g3), said current input terminal (d3) being connected to the main input terminal (A);

b. a first transient voltage suppression diode (Tvs1) whose anode is connected to the main output terminal (B),

vs. a second transient voltage suppression diode (Tvs2), whose anode is connected to the current output terminal (s3) of the third switch (Q3) and whose cathode is connected to the cathode of the first suppressor diode transient voltages (Tvs1).

[Claim 9] Safety device (2,3) according to one of claims 1 to 8 wherein the switch (s) of the switch device (10,100) are MOSFET transistors, or IGBT transistors, or bipolar transistors.

[Claim 10] Voltage converter comprising a safety device (2, 3) according to one of claims 1 to 9.

[Claim 1 1] A voltage converter according to claim 10 wherein said voltage converter is a DC-DC voltage converter or an AC-DC voltage converter.