EP2449570A1 - Module for protecting against overvoltage and protection assembly including such a module - Google Patents

Abstract

The invention relates to a module (20) for protecting against overvoltage, comprising at least one varistor (1) mechanically connected to driving means (10) by a first thermal separator (P1). The melting of the first separator (P1) enables the movement of the driving means (10). The first thermal separator (P1) has a first melting time constant σ1 and a first melting temperature T1. The varistor (1) is mechanically connected to the driving means (10) by a second thermal separator (P2), and the melting of the second separator (P2) enables the movement of the mobile driving means (10). The second thermal separator (10) has a second melting time constant σ2 and a second melting temperature T2, the second temperature T2 being higher than the first temperature T1, and the first time constant σ1 being higher than the second time constant σ2.

Description

 OVERVOLTAGE PROTECTION MODULE AND PROTECTIVE ASSEMBLY COMPRISING SUCH A MODULE

TECHNICAL FIELD OF THE INVENTION

The invention relates to a surge protection module intended to be connected to an electrical breaking device via mechanical actuation means. Said module comprises at least one varistor mechanically connected to mobile drive means by a first thermal separator. The melting of the first thermal separator in the event of heating of the varistor releases the displacement of the mobile drive means to act on the mechanical actuation means.

Said first thermal separator comprises a first melting time constant and a first melting temperature

The invention also relates to an overvoltage protection assembly comprising a protection module and comprising a breaking device. STATE OF THE PRIOR ART

It is known to associate an overvoltage protection device comprising an overvoltage limiter with variable non-linear elements with the voltage with an electrical switching device actuated by an actuating mechanism. The surge protector and the electrical cut-off device are connected in series.

As described in EP1607995, the electrical breaking device can adopt a trigger position and a latching position respectively corresponding to the open state and the closed state of the electrical contacts. A tripping circuit cooperates with the actuating mechanism to cause the displacement of the contacts of the disconnection device to the open state especially in the event of destruction of the surge protector, especially at the end of life of said non-linear elements. The surge limiter including a varistor connected to a separator thermal. In case of overheating of the varistor due to a malfunction, the melting of the thermal separator acts directly on the actuating mechanism and causes the opening of the electrical contacts of the electrical breaking device. The thermal separator is placed in an environment of the varistor and heats by indirect conduction.

Indirect conduction means that the thermal separator is not crossed by the electric current flowing through the varistor. By direct conduction is meant that the thermal separator is traversed by an electric current. The use of a thermal separator which is heated, in particular by indirect conduction, sometimes has disadvantages. Calibration of the thermal separator in thermal baths of choice of material and thermal of volume of material used to make the separator is binding. The thermal separator is generally calibrated to melt following heating of the varistor which is traversed by leakage currents. However, this same thermal separator is not intended to melt when the varistor heats up following a lightning strike. In case of melting of the thermal separator following a lightning shock would result in unavailability of the surge arrester for future lightning strikes, the latter situation is not desirable. In addition, the synchronization of the melting of the thermal separator with the opening of the contacts of the electrical breaking device by the actuating mechanism is performed by a control kinematic chain comprising a plurality of mechanical means such as transmission shafts or rods. The use of this kinematic control system has the disadvantage of complicating the implementation of the protection device.

When there are temporary surges occurring during a ground fault or a load shedding on the public distribution network, the energy dissipated in the surge arrester can be significant and can rapidly destroy the surge arrester components. These temporary overvoltages appearing on the network are called thereafter TOV (Temporary Over Voltage). The fault current resulting from a TOV causes also a heating of the varistor detected by a thermal separator. The amplitude of the fault current is in this case much greater than in the case of leakage current due to the aging of the varistor. This thermal separator must then theoretically intervene with a relatively short time constant (a few seconds) to counter the influence of TOV and with a relatively long time constant (a few minutes or even a few hours) to counter the defect of the generating varistor. low leakage currents. In addition, this thermal separator must not intervene in the presence of lightning shock. PRESENTATION OF THE INVENTION

The invention therefore aims to overcome the disadvantages of the state of the art, so as to provide a device for protection against overvoltages and having protection means adapted to problems related to TOV (Temporary Over Voltage). Said at least one varistor of the protection module according to the invention is mechanically connected to the drive means by a second thermal separator, the melting of the second thermal separator in case of heating of the varistor releasing the displacement of the drive means mobile, said second thermal separator having a second melting time constant and a second melting temperature, the second melting temperature being greater than the first melting temperature, and the first melting time constant being greater than the second melting constant. melting time.

According to a development mode of the invention, the protection module comprises elastic means providing a displacement force for moving the drive means from a first position the armed position to a trigger position, the means of driving being mechanically retained in the armed position by said first and second thermal separators, the fusion of one of the two thermal separators releasing the displacement of the drive means. According to a first particular embodiment of the invention, the first thermal separator and the second thermal separator exert respectively a first and a second retaining forces on the drive means, said retaining forces acting in series on the drive means. In practice, the fusion of a thermal separator successively causes the cancellation of one of the retained forces and the release of the displacement of the drive means.

Preferably, the two retaining forces are respectively greater than the displacement force. According to a second particular embodiment of the invention, the first thermal separator and the second thermal separator respectively exert a first and a second retaining forces on the drive means, said retaining forces acting in parallel manner on the drive means. In the drive, the melting of a thermal separator successively causes the cancellation of one of the two holding forces, the cancellation of the other holding force and the displacement of the drive means.

Preferably, the retaining forces are respectively less than the displacement force.

Preferably, the second thermal separator comprises a second melting temperature lower than the maximum operating temperature of the varistor and greater than the temperature of heating of the varistor after a lightning strike type 10/350.

Advantageously, the second thermal separator comprises a melting temperature having a value equal to 195 ° Celsius degrees plus or minus 25 °. Preferably, the first thermal separator comprises a first melting temperature lower than the maximum tolerated temperature of the protection device reduced to level of the varistor.

Advantageously, the first thermal separator fuse connection has a melting temperature of value equal to 125 degrees Celsius plus or minus Advantageously, the first melting time constant is at least five times greater than the second melting time constant.

Advantageously, the first thermal separator is a pin made of plastic material.

Advantageously, the second thermal separator is a low temperature weld.

Advantageously, said at least one protection module comprises coding means intended to collaborate with the breaking device. The surge protection assembly comprises a protection module as defined above and comprises an electrical switching device comprising inputs intended to be connected to a line to be protected, main contacts controlled by a tripping mechanism, and outputs connected to the overvoltage protection module. The mechanical actuation means of said module are interconnected with the triggering means for actuating the opening of the main contacts.

BRIEF DESCRIPTION OF THE FIGURES

Other advantages and features will emerge more clearly from the following description of particular embodiments of the invention, given by way of non-limiting examples, and represented in the accompanying drawings in which:

- Figures 1 and 2 show schematic views of a protection assembly according to one embodiment of the invention;

FIG. 3 represents a perspective view of a protection module of an overvoltage protection assembly according to FIG. 1;

FIGS. 4 to 6 show detailed views of the operation of the protection module according to FIG. 2; FIG. 7 represents a side view of an embodiment of the protection module according to FIG. 3;

FIG. 8 represents a perspective view of an embodiment of the protection module according to FIG. 3; FIG. 9 represents a heating curve of the protection module in the event of rapid heating, linked in particular to the presence of a TOV;

- Figure 10 shows a heating curve of the protection module in case of lightning shock;

- Figure 11 shows a heating curve of the protection module in case of slow heating.

DETAILED DESCRIPTION OF AN EMBODIMENT

As represented in FIGS. 1 and 2, the overvoltage protection assembly according to the invention comprises at least one protection module 20 intended to be connected to an electric switching device 21 via mechanical actuation means 33.

As represented in FIG. 2, the overcurrent protection assembly 20 according to the invention is intended to be connected between on the one hand at least one current line via at least one first connection terminal 22 placed upstream of the cut-off device 21 and, on the other hand, to earth via at least one connector 6 of the protection module 20. The cut-off device 21 comprises at least one second connection terminal 25A downstream intended to be connected to the connection terminal 25B to the protection module 20.

According to one embodiment of the invention, the protection module 20 comprises at least one varistor 1 comprising at least one terminal connected to a terminal terminal 25B of the protection module 20 and a second terminal connected to a connector 6. Said at least one varistor is mechanically connected to moving drive means. Said drive means are connected to the mechanical actuation means 33 are intended to actuate a trigger mechanism 24 of the switchgear 21 in case of malfunction of the varistor 1.

The trigger mechanism 24 of the switchgear 21 then actuates the opening of the electrical contacts 23.

As an exemplary embodiment shown in FIGS. 1 and 2, the overvoltage protection assembly comprises a four-pole cut-off device 21. The protection module 20 of said protection assembly then comprises four varistors 1 connected respectively to a pole of the breaking device 21.

According to one embodiment of the invention, said at least one varistor 1 of the protection module is mechanically connected to moving drive means 10 by a first thermal separator P1.

The melting of the first thermal separator P1 in the event of heating of the varistor releases the displacement of the moving drive means. The displacement of the drive means 10 is intended to act on the mechanical actuating means 33 and cause the opening of the electrical contacts 23 of the switchgear 21.

As represented in FIGS. 4 and 6, according to a preferred embodiment of the invention, the first thermal separator P1 is fixed on the one hand to the varistor 1 and on the other hand to a pivoting arm 11 of the drive means

10 mobile. The pivoting arm 11 is mechanically held by the first thermal separator P1 in a first operating position, called the armed position. Elastic means 12 exert a displacement force Fd on the pivoting arm 11. The displacement force Fd is intended to cause the pivoting arm 11 to move in a second operating position in case of melting of the first thermal separator P1. The first thermal separator P1 exerts a first retention force Fr1 on the drive means 10. The melting of the first thermal separator P1 causes the rupture of a mechanical connection between the first separator P1 and the pivoting arm

11. The first restraining force FR1 being null, under the action of the force of Fd displacement, said arm pivots about an axis of rotation 13 from the armed position to the second operating position, called trigger position. The rotation of the axis of rotation 13 acts on the mechanical actuating means 33. Said first thermal separator P1 comprises a first melting temperature T1 and a first melting time constant σ1.

The first melting temperature T1 of the first thermal separator P1 is determined so as to be lower than the maximum temperature TmaxB tolerated at the outer surfaces of the housing of the protection module 20 brought to the level of the first thermal separator P1. The maximum temperature tolerated at the outer surfaces of the housing is usually set by standards. This temperature is for example equal to 120 degrees Celsius. This maximum temperature brought back to the level of the first thermal separator P1 placed inside the housing makes it possible to establish a first criterion for determining the first melting temperature T1.

In addition, the first melting temperature T1 of the first thermal separator P1 is determined so as to be less than the maximum temperature of heating reached by the varistor 10 in the event of malfunction. The malfunction is for example related to the aging of the varistor, aging causing a start of short circuit. This heating of the varistor makes it possible to establish a second criterion for determining the first melting temperature T1.

The combination of these two criteria makes it possible to determine the first melting temperature T1. As an exemplary embodiment, the first melting temperature T1 of value equal to 125 ° C degrees plus or minus 15 ° C.

Melting time constant means a homogeneous quantity at a time characterizing the speed for a system studied to reach a melting temperature under system operating conditions. The time constant is often related to the response of the studied system to an instantaneous disturbance. Indeed, the constant of fusion time σ1 is dependent on the architecture of the protection module 20 and in particular the position of the first thermal separator P1 with respect to the varistor 10, the nature of the material used to produce said separator, and also of its overall geometry. As shown in FIG. Figure 10, in the event of a lightning strike, heating of the first thermal separator P1 placed in the housing of the protection device reaches a maximum temperature after a time of about 25 seconds. The first curve C1 represents the heating curve of the first thermal separator P1 and the second curve C2 represents the heating curve of the second thermal separator P2. As desired, the first thermal separator P1 does not reach its melting point T1 in the event of a lightning strike. The third curve C3 theoretically represents heating of the varistor in the event of a lightning strike, particularly in the case of a 10/350 type shock. By way of example, the first melting time constant σ1 is equal to 5 seconds. As shown in Figures 4 to 6, according to a particular embodiment of the invention, the first thermal separator P1 consists of a pin of plastic material. The displacement force Fd exerted by the elastic means 12 via the pivoting arm 11 of the drive means 10 then applies a shear force to said pin. According to an alternative embodiment not shown, the displacement force Fd exerted by the elastic means may apply a tensile force on said pin.

As an exemplary embodiment, heating of the first thermal separator

P1 is preferably by indirect conduction. According to a variant not shown, heating of the first thermal separator P1 is by direct conduction, the first thermal separator then being crossed by the electric current which passes through the varistor 1.

According to a preferred embodiment of the invention, the varistor 1 is connected to the drive means 10 by a second thermal separator P2.

The melting of the second thermal separator P2 in the event of heating of the varistor 1 releases the displacement of the moving drive means 10. The displacement of the drive means 10 is intended to act on the mechanical actuating means 33 and cause the opening of the electrical contacts 23 of the switchgear 21.

As shown in FIGS. 4 and 6, according to a preferred embodiment of the invention, the second thermal separator P2 is fixed on the one hand to the varistor and is fixed on the other hand to the pivoting arm 11 of the drive means 10 mobile. The pivot arm 11 is mechanically held by the second thermal separator P2 in the armed position. Elastic means 12 exert a displacement force Fd on the pivoting arm 11. The displacement force Fd is intended to cause the pivoting arm 11 to move in a second operating position in case of melting of the second thermal separator P2. The second thermal separator P2 exerts a second retention force Fr2 on the drive means 10. The melting of the second thermal separator P2 causes the rupture of a mechanical link between said separator P2 and the pivoting arm 11. Under the action of the displacement force Fd, said arm pivots about an axis of rotation 13 from the armed position to the release position. The rotation of the axis of rotation 13 acts on the mechanical actuating means 33.

Said second thermal separator P2 comprises a second melting temperature T2 and a second melting time constant σ2.

The second melting temperature T2 of the second thermal separator P2 depends on three criteria. First, said second melting temperature T2 is determined to be less than the maximum operating temperature TmaxV supported by the varistor 1. The maximum permissible temperature TmaxV is an intrinsic characteristic of the component and is for example equal to 260 ° Celsius.

In addition, the second melting temperature T2 of the second thermal separator P2 is determined so as to be greater than the temperature of heating reached by the varistor in the event of a lightning strike, in particular lightning strikes of the 10/350 type. Finally, the second melting temperature T2 of the second thermal separator P2 is determined so as to be less than the temperature of heating of the varistor 1 reached following a TOV type defect.

The combination of these three criteria makes it possible to determine the second melting temperature T2.

As an exemplary embodiment, the second a melting temperature T2 has a value equal to 195 ° Celsius plus or minus 25 ° C.

As shown in FIG. 10, in the event of a lightning strike, heating of the second thermal separator P2 placed in the housing of the protection module 20 reaches a maximum temperature after a time of about 5 seconds. The first curve C1 represents the heating curve of the first thermal separator P1 and the second curve C2 represents the heating curve of the second thermal separator P2. The third curve C3 theoretically represents heating of the varistor in the event of a lightning strike, particularly in the case of a 10/350 type shock. As desired in the event of a lightning strike, the second thermal separator P2, like the first separator P1, does not reach its melting temperature T2. By way of example, the second melting time constant σ2 is equal to 1 second.

As an exemplary embodiment, heating of the second thermal separator P2 is preferably by indirect conduction. According to a variant not shown, heating of the second thermal separator P2 is by direct conduction, the second thermal separator then being crossed by the electric current which passes through the varistor 1.

According to one embodiment of the invention, the second thermal separator P2 is a low temperature weld. As shown in Figures 4, 5 and 6, as an example of manufacture, the thermal pin of the first thermal separator P1 is nested in a metal bracket. Said metal bracket is connected to the varistor 1 by the low temperature welding of the second thermal separator P2. Thus, according to a preferred embodiment of the invention, the second melting temperature T2 is greater than the first melting temperature T1, and the first melting time constant σ1 is greater than the second melting time constant σ2. As an exemplary embodiment, the first melting time constant σ1 is at least five times greater than the second melting time constant σ2.

As an exemplary embodiment shown in Figures 4 to 6, each pivoting arm 11 has a slot 16 in which is positioned a drive pin 14 fixedly secured to the axis of rotation 13. The displacement of a pivoting arm 11 in case of rupture of a thermal separator P1, P2 moves the drive finger 14 initially placed in abutment on an edge of the light 16 of said arm. The drive fingers 14 placed respectively in the lights of the other pivoting arm move freely in the lights, said other arms remaining stationary. As an exemplary embodiment, as shown in Figures 7 and 8, the mechanical actuating means 33 comprise an actuating arm 35 guided in translation. The rotational movement of the axis of rotation 13 directly or indirectly, via a lever 36, the translation of the actuating arm 35. The actuating arm 35 has at one end a lug 34 projecting from a housing protection device. This lug 34 is intended to actuate a trip bar (not shown) of the switchgear 21.

The operation of the protection module 20 against overvoltages according to the invention in case of rapid heating of the varistor 1 is as follows. The rapid heating is particularly related to the presence of a TOV. By way of example, the first curve C1 in FIG. 9 represents the heating curve of the first thermal separator P1 and the second curve C2 represents the heating curve of the second thermal separator P2. In the presence of TOV, the second thermal separator P2 will heat up quickly because of its low melting time constant σ2. The second curve C2 of heating of the second thermal separator P2 will quickly reach the second melting temperature T2. Concomitantly, as shown on the first curve C1 of Figure 9, the temperature rise of the first thermal separator P1 is relatively low. In practice, the first thermal separator P1 is far from having reached its melting temperature at the moment when the second first thermal separator reaches its melting temperature T2.

The operation of the protection module 20 against overvoltages according to the invention in case of slow heating of the varistor 1 is as follows. By way of example, the first curve C1 in FIG. 11 represents the heating curve of the first thermal separator P1 and the second curve C2 represents the heating curve of the second thermal separator P2. The two thermal separators P1, P2 will heat up slowly. The first and second curves C1, C2 of heating of the two thermal separators P1, P2 are substantially parallel, or even merged. The first heating curve C1 of the first thermal separator P2 will reach the first melting temperature T1 before the case of the protection module has reached its maximum temperature TmaxB acceptable.

Thanks to this series combination of the two thermal separators P1, P2, the thermal protection of the protection module 20 is both operational for fast transient phenomena and slower phenomena. In addition, the operation of the thermal separators ensures a non-triggering of the device during a lightning strike.

According to a first mode of development, the holding forces of the first and second thermal separators P1, P2 are exerted in series on the drive means 10. The melting of a thermal separator successively causes the cancellation of one retained forces Fr1, Fr2 and the displacement of the drive means. The two retained forces Fr1, Fr2 are respectively of greater intensity than that of the displacement force Fd.

According to a second mode of development, the holding forces of the first and second thermal separators P1, P2 are exerted in parallel manner on the drive means 10. The fusion of one of the thermal separators leads to successively the cancellation of one of the two retained forces Fr1, Fr2, then the cancellation of the other retained force Fr1, Fr2 and finally the displacement of the drive means 10. The retained forces FM, Fr2 are respectively of lower intensity than that of the displacement force Fd. According to an alternative embodiment of the embodiments, said protection module 20 preferably comprises polarizing means intended to collaborate with the apparatus 21 of cutoff. By way of example, the coding means comprise protuberances intended to fit into female fingerprints (not shown) placed in the cut-off device 21.

Claims

Protection module (20) against overvoltages intended to be connected to an apparatus (21) for electrical shutdown via mechanical actuation means (33) and comprising:

 at least one varistor (1) mechanically connected to means

 driving (10) movable by a first thermal separator (P1), the melting of the first thermal separator (P1) in the event of heating of the varistor releasing the displacement of the moving drive means (10) to act on the means mechanical actuator (33), said first thermal separator (P1) having a first melting time constant (σ1) and a first melting temperature (T1), characterized in that said at least one varistor (1) is mechanically connected to the drive means (10) by a second thermal separator (P2), the melting of the second thermal separator (P2) in the event of heating of the varistor (1) freeing the displacement of the moving drive means (10), said second thermal separator (P2) having a second melting time constant (σ2) and a second melting temperature (T2), the second melting temperature (T2) being greater than the first melting temperature (T1), and thefirst melting time constant (σ1) being greater than the second melting time constant (σ2).

2. Protection module according to claim 1, characterized in that it comprises elastic means (12) providing a displacement force (Fd) for driving in displacement the drive means (10) of a first position the actuating means (10) is mechanically retained in the armed position by said first and second thermal separators (P1, P2), the fusion of one of the two thermal separators releasing the displacement of the means training (10).

3. Protection module according to claim 2, characterized in that the first thermal separator (P1) and the second thermal separator (P2) exert respectively a first and a second retaining forces (Fr1, Fr2) on the drive means (10), said retaining forces acting in series on the drive means (10), the melting of a thermal separator successively causing the cancellation of one of the holding forces ( FM, Fr2) and the release of the displacement of the drive means (10).

4. Protection module according to claim 3, characterized in that the two retained forces (Fr1, Fr2) are respectively greater than the displacement force (Fd)

5. Protection module according to claim 2, characterized in that the first thermal separator (P1) and the second thermal separator (P2) exert respectively a first and a second retaining forces (Fr1, Fr2) on the drive means (10), said retaining forces acting in parallel manner on the driving means (10), the melting of a thermal separator successively causing the cancellation of one of the two retaining forces (Fr1, Fr2), the cancellation of the other retained force (Fr1, Fr2) and the displacement of the drive means (10).

6. Protection module according to claim 5, characterized in that the retaining forces (Fr1, Fr2) are respectively less than the displacement force (Fd).

7. Protection module according to any one of the preceding claims, characterized in that the second thermal separator (P2) comprises a second melting temperature (T2) lower than the maximum operating temperature of the varistor and greater than the temperature of heating of the varistor after a lightning strike type 10/350.

8. Protection module according to claim 7, characterized in that the second thermal separator (P2) comprises a melting temperature (T2) having a value equal to 195 ° C degrees plus or minus 25 ° C.

9. Protection module according to any one of the preceding claims, characterized in that the first thermal separator (P1) comprises a first melting temperature (T1) lower than the maximum permissible temperature of the protection device brought back to the level of the varistor.

10. Protection module according to claim 9, characterized in that the first thermal separator (P1) fuse connection has a melting temperature (T1) of equal value 125 ° C degrees plus or minus 15 ° C.

11. Protection module according to any one of the preceding claims, characterized in that the first melting time constant (σ1) is at least five times greater than the second melting time constant (σ2).

12. Protection module according to any one of the preceding claims, characterized in that the first thermal separator (P1) is a pin of plastic material.

13. Protection module according to any one of the preceding claims, characterized in that the second thermal separator (P2) is a low temperature weld.

14. Protection module according to any one of the preceding claims, characterized in that said at least one protection module (20) comprises polarizing means (35) intended to collaborate with the device (21) cutoff.

15. Overvoltage protection package including a module of

 protection (20) according to any one of the preceding claims, characterized in that it comprises an electrical switching device (21) comprising inputs (22) intended to be connected to a line to be protected, main contacts (23). controlled by a triggering mechanism (24), and outputs (25A) connected to the overvoltage protection module (1, 2), the mechanical actuation means (33) of said module being interconnected with the triggering means (24, 27) to actuate the opening of the main contacts (23).