EP2602805A1 - Gehäuse für Schutzvorrichtung gegen Überlastspannungen, und entsprechende Schutzvorrichtung gegen Überlastspannungen - Google Patents

Abstract

The housing (1) has two electrical connection elements (11, 12), and an overvoltage protection component (13) i.e. varistor. The protection component is electrically connected to the two connection elements, where temperature of the connection elements increases in the presence of overvoltage. A mechanical switch (17) is connected to a locking unit (15) i.e. low-temperature brazing. The locking unit releases the switch to an open position when a temperature of the protection component exceeds a critical point. The locking unit is arranged electrically independent of the mechanical switch. The critical point lies between 100 and 240 degrees Celsius. An independent claim is also included for an overvoltage protection device.

Description

TECHNICAL AREA

The present invention relates to the general technical field of equipment protection devices or electrical installations against electrical disturbances, in particular against transient overvoltages.

PRIOR ART AND DISADVANTAGES

The use of surge protection devices is known and common. Such devices generally use a varistor as an overvoltage protection component. Indeed, the varistor closes the overvoltage from a predetermined value and limits the propagation of the surge on the power grid.

Such components deteriorate throughout their use, their impedance decreasing gradually, which increases the intensity of their leakage current, and thus creates a significant heating of the varistor by Joule effect. This heating is transmitted to nearby equipment, which can cause fires or short circuits.

In order to avoid any possible deterioration of the equipment or electrical installation connected to the device, it is necessary to be able to disconnect this device at the end of the life of the varistor.

Such a disconnection device, called thermal disconnection, consists of disconnecting the surge protection device comprising the defective varistor, beyond a predetermined critical temperature.

• une unité de protection connectée à l'équipement électrique via un circuit de connexion comprenant un moyen d'interruption de courant électrique, mobile entre une position de rappel correspondant à l'ouverture du circuit et une position de fermeture du circuit, ledit moyen d'interruption étant maintenu en position de fermeture par un moyen de blocage ;
• un moyen d'ouverture du circuit de connexion lorsque la température de l'unité de protection atteint une valeur prédéterminée, comprenant un moyen sensible à la chaleur. Ce moyen sensible à la chaleur est relié à un moyen d'actionnement, pour que lorsque la température prédéterminée est atteinte, le moyen d'actionnement produit une force de désactivation du moyen de blocage. Les moyens sensibles à la chaleur et d'actionnement sont confondus et formés par un bilame.

Thus, the document FR2848353 discloses an electrical surge protection device that includes:

• a protection unit connected to the electrical equipment via a connection circuit comprising an electrical current interruption means, movable between a return position corresponding to the opening of the circuit and a closed position of the circuit, said means of interruption being maintained in the closed position by a locking means;
• means for opening the connection circuit when the temperature of the protection unit reaches a predetermined value, comprising a heat-sensitive means. This heat sensitive means is connected to an actuating means, so that when the predetermined temperature is reached, the actuating means produces a deactivating force of the locking means. The means sensitive to heat and actuation are merged and formed by a bimetallic strip.

Such a device has disadvantages. Indeed, the bimetal, whose nature changes during the temperature rise, is subjected to high mechanical stress, since it is also the actuating element that allows the opening of the circuit. Such a device thus sees its reduced reliability as a result of vibrations or shocks suffered by the device. Moreover, the bimetal can see its temperature detection influenced by the current passing through the thermal disconnection. It is therefore necessary to size the detection means so that the flow of current does not influence the disconnector.

The document FR2925216 discloses an overvoltage protection device comprising a protection component against overvoltages in thermal connection with a thermosensitive member capable of deforming in dependence on its temperature, and a mechanical member intended to cooperate with the thermosensitive member and adapted to cooperate with a device for tripping an electrical breaking device. When the temperature of the overvoltage protection component exceeds a predetermined threshold, the deformation of the thermosensitive member causes a displacement of the mechanical member which protrudes out of the housing, comprising the thermosensitive member and the overvoltage protection component. , and actuates the triggering device of the electric switchgear.

This overvoltage protection device is in mechanical connection with an electrical switching device, so there are two boxes each having specific functions: on one side detection of the critical temperature of malfunction of the overvoltage protection component, and on the other side the connection of the defective protection device is cut off from the rest of the electrical installation.

Such a device has the disadvantage of requiring the use of two boxes, which generates manufacturing costs and a loss of space in the electrical installation. Furthermore, the protection device and the cutoff device are in series on the current path.

Thus, in these two patents, the solutions require that the locking element is an electrical conductor, for example metallic with known mechanical deformation properties, and that it is capable of transforming a thermal effect into a mechanical force.

On the other hand, overvoltage protection devices are known which have a thermal disconnection time which is too long, because the function of detecting the heating of the varistor is too far from the varistor, the reaction time of the The heating element is therefore not weak enough to ensure fast disconnection.

PURPOSE OF THE INVENTION

It would therefore be advantageous to obtain an overvoltage protection device whose thermal disconnection is rapid, the reliability of which is improved by reducing the mechanical stresses experienced by the elements of the device, and which makes it possible to obtain a saving of space in the area. equipment or electrical installation to be protected.

• deux éléments de connexion électrique ;
• un composant de protection contre les surtensions, relié électriquement aux deux éléments de connexion électrique, dont la température augmente en présence d'une surtension ;
• un élément de verrouillage, en contact avec le composant de protection contre les surtensions ;
• un interrupteur mécanique, relié à l'élément de verrouillage, installé en série entre un des deux éléments de connexion électrique et le composant de protection contre les surtensions, l'élément de verrouillage maintenant l'interrupteur en position fermée; et tel que lorsque la température du composant de protection contre les surtensions dépasse un seuil critique, l'élément de verrouillage libère l'interrupteur qui se met en position ouverte. En outre, l'élément de verrouillage est électriquement indépendant de l'interrupteur mécanique.

To solve one or more of the aforementioned drawbacks, a box for a surge protection device comprises:

• two electrical connection elements;
• an overvoltage protection component, electrically connected to the two electrical connection elements, whose temperature increases in the presence of an overvoltage;
• a locking member in contact with the overvoltage protection component;
• a mechanical switch, connected to the locking element, installed in series between one of the two electrical connection elements and the overvoltage protection component, the locking element holding the switch in the closed position; and such that when the temperature of the overvoltage protection component exceeds a critical threshold, the latch element releases the switch that moves to the open position. In addition, the locking element is electrically independent of the mechanical switch.

Thus, advantageously, the locking element not being part of the current path in which the switch participates, it is possible to position the locking element so that it reacts quickly to the release of heat, to use a material specifically adapted to this locking function and not necessarily conductive.

In addition, when the temperature of the overvoltage protection component exceeds a critical threshold, the locking element releases the switch which goes into the open position.

Such a case for protection device for overvoltages has the advantage of offering a device having a fast thermal disconnection. Indeed, the locking element is in contact with the overvoltage protection component and therefore closer to the heating.

In addition, advantageously, this housing whose mechanical switch, which has the function of disconnecting the housing comprising the defective overvoltage protection component, is different from the locking element, whose function is the opening of the circuit. The mechanical stresses experienced by the locking element are thus reduced, and its reliability is improved.

Advantageously, the fact that all the elements, allowing the protection against overvoltages and the disconnection of the circuit comprising the surge protection element, are grouped together in the same housing, allows to gain space in the equipment or electrical installation to protect.

• le composant de protection contre les surtensions est une varistance ;
• l'élément de verrouillage est en liaison thermique par conduction avec une partie métallique nue d'une électrode du composant de protection contre les surtensions;
• l'élément de verrouillage est une brasure basse température qui fond lorsque la température du composant de protection contre les surtensions dépasse le seuil critique ;
• l'élément de verrouillage est une pièce plastique qui fond lorsque la température du composant de protection contre les surtensions dépasse le seuil critique ;
• le seuil critique est compris entre 100 et 240°C. De façon particulièrement préférentielle, il est compris entre 120°C et 190°C;
• l'interrupteur mécanique comprend :
  • ○ deux lames conductrices connectées respectivement au premier élément de connexion électrique et à l'élément de protection contre les surtensions,
  • ○ une pièce isolante, solidaire d'un élément entraineur,
  • ○ l'élément entraineur relié par une encoche à une pièce mobile,
  • ○ la pièce mobile, reliée à l'élément de verrouillage,
  • ○ un premier ressort en appui, ou en traction, sur la pièce isolante,

tel que, en position fermée de l'interrupteur, les deux lames conductrices sont en contact et, l'élément entraineur, ainsi que le premier ressort hors de sa position d'équilibre, maintiennent la pièce isolante à l'écart des deux lames conductrices, et, lors du déverrouillage, la pièce mobile se déplace et libère l'élément entraineur, la pièce isolante étant entrainée par le premier ressort dans un mouvement de translation pour écarter et se placer entre les deux lames conductrices ;

• les deux lames conductrices sont des lames ressorts et la pièce mobile se déplace en translation sous l'effet d'un second ressort ;
• les deux lames conductrices sont des lames ressorts et la pièce mobile est une lame ressort, maintenue par un ergot, ladite pièce mobile, lors du déverrouillage, effectue un mouvement de rotation qui la libère de l'ergot ;
• une des deux lames conductrices est une lame ressort et la pièce mobile est un levier à bras recourbé, maintenue par un ergot, ladite pièce mobile, lors du déverrouillage, effectue un mouvement de rotation qui la libère de l'ergot.

Particular characteristics or embodiments that can be used alone or in combination are:

• the overvoltage protection component is a varistor;
• the locking element is in heat conduction bonding with a bare metal part of an electrode of the overvoltage protection component;
• the locking element is a low temperature solder which melts when the temperature of the overvoltage protection component exceeds the critical threshold;
• the locking element is a plastic part which melts when the temperature of the overvoltage protection component exceeds the critical threshold;
• the critical threshold is between 100 and 240 ° C. Particularly preferably, it is between 120 ° C and 190 ° C;
• the mechanical switch comprises:
  • Two conductive blades connected respectively to the first electrical connection element and to the overvoltage protection element,
  • ○ an insulating part, integral with a driving element,
  • ○ the entrainment element connected by a notch to a moving part,
  • ○ the moving part, connected to the locking element,
  • A first spring resting on or in traction on the insulating part,

such that, in the closed position of the switch, the two conductive blades are in contact and, the driving element, as well as the first spring out of its equilibrium position, keep the insulating part away from the two conductive blades , and, during unlocking, the moving part moves and releases the driving element, the insulating part being driven by the first spring in a translation movement to spread and be placed between the two conductive blades;

• the two conductive blades are spring blades and the moving part moves in translation under the effect of a second spring;
• the two conductive blades are spring blades and the moving part is a spring blade, held by a lug, said movable part, during unlocking, performs a rotational movement which releases it from the lug;
• one of the two conductive blades is a spring blade and the moving part is a lever with a bent arm, held by a lug, said movable part, upon unlocking, performs a rotational movement which releases it from the lug.

In a second aspect of the invention, an overvoltage protection device comprises a surge protection housing and a base fixed on a rail such that the two electrical connection elements of the housing are electrically connected to the base during racking the case.

According to a particular embodiment, the overvoltage protection device comprises a plurality of overvoltage protection boxes and a plurality of bases fixed on a rail such that the two electrical connection elements of each of said boxes are connected to a terminal. respective base during the racking of the respective case.

FIGURES

• la figure 1 est une vue en coupe d'une première variante de réalisation d'un boitier pour dispositif de protection contre les surtensions, dans une configuration où la température du composant de protection contre les surtensions est inférieure au seuil critique ;
• la figure 2 est une vue en coupe de la première variante de réalisation d'un boitier pour dispositif de protection contre les surtensions, dans une configuration où la température du composant de protection contre les surtensions est supérieure au seuil critique ;
• la figure 3 est une vue 3D de la première variante de réalisation d'un boitier pour dispositif de protection contre les surtensions, dans une configuration où la température du composant de protection contre les surtensions est inférieure au seuil critique ;
• la figure 4 est une vue 3D de la première variante de réalisation d'un boitier pour dispositif de protection contre les surtensions , dans une configuration où la température du composant de protection contre les surtensions est supérieure au seuil critique ;
• la figure 5 est une vue en coupe d'une seconde variante de réalisation d'un boitier pour dispositif de protection contre les surtensions, dans une configuration où la température du composant de protection contre les surtensions est inférieure au seuil critique ;
• la figure 6 est une vue en coupe de la seconde variante de réalisation d'un boitier pour dispositif de protection contre les surtensions, dans une configuration où la température du composant de protection contre les surtensions est supérieure au seuil critique ;
• la figure 7 est une vue en coupe d'une troisième variante de réalisation d'un boitier pour dispositif de protection contre les surtensions , dans une configuration où la température du composant de protection contre les surtensions est inférieure au seuil critique,
• la figure 8 est une vue en coupe de la troisième variante de réalisation d'un boitier pour dispositif de protection contre les surtensions, dans une configuration où la température du composant de protection contre les surtensions est supérieure au seuil critique;
• la figure 9 est une vue en coupe d'une quatrième variante de réalisation d'un boitier pour dispositif de protection contre les surtensions, dans une configuration où la température du composant de protection contre les surtensions est inférieure au seuil critique ;
• la figure 10 est une vue en coupe de la quatrième variante de réalisation d'un boitier pour dispositif de protection contre les surtensions, dans une configuration où la température du composant de protection contre les surtensions est supérieure au seuil critique ;
• la figure 11 est une vue en coupe d'une cinquième variante de réalisation d'un boitier pour dispositif de protection contre les surtensions, dans une configuration où la température du composant de protection contre les surtensions est inférieure au seuil critique ;
• la figure 12 est une vue en coupe de la cinquième variante de réalisation d'un boitier pour dispositif de protection contre les surtensions, dans une configuration où la température du composant de protection contre les surtensions est supérieure au seuil critique ;
• la figure 13 est une vue en coupe d'une sixième variante de réalisation d'un boitier pour dispositif de protection contre les surtensions, dans une configuration où la température du composant de protection contre les surtensions est inférieure au seuil critique ;
• la figure 14 est une vue en coupe de la sixième variante de réalisation d'un boitier pour dispositif de protection contre les surtensions, dans une configuration où la température du composant de protection contre les surtensions est supérieure au seuil critique ;
• la figure 15 est une vue en coupe d'une septième variante de réalisation d'un boitier pour dispositif de protection contre les surtensions, dans une configuration où la température du composant de protection contre les surtensions est inférieure au seuil critique ; et
• la figure 16 est une vue en coupe de la septième variante de réalisation d'un boitier pour dispositif de protection contre les surtensions, dans une configuration où la température du composant de protection contre les surtensions est supérieure au seuil critique.
• la figure 17 est une vue en coupe d'une huitième variante de réalisation d'un boitier pour dispositif de protection contre les surtensions, dans une configuration où la température du composant de protection contre les surtensions est inférieure au seuil critique ; et
• la figure 18 est une vue en coupe de la huitième variante de réalisation d'un boitier pour dispositif de protection contre les surtensions, dans une configuration où la température du composant de protection contre les surtensions est supérieure au seuil critique.
• la figure 19 est une vue en coupe d'une neuvième variante de réalisation d'un boitier pour dispositif de protection contre les surtensions, dans une configuration où la température du composant de protection contre les surtensions est inférieure au seuil critique ; et
• la figure 20 est une vue en coupe de la neuvième variante de réalisation d'un boitier pour dispositif de protection contre les surtensions, dans une configuration où la température du composant de protection contre les surtensions est supérieure au seuil critique.
• la figure 21 représente une première variante de réalisation d'un dispositif de protection contre les surtensions.
• La figure 22 représente une seconde variante de réalisation d'un dispositif de protection contre les surtensions.

Other characteristics and advantages of the invention will emerge clearly from the description which is given hereinafter, by way of indication and in no way limitative, with reference to the appended drawings, in which:

• the figure 1 is a sectional view of a first embodiment of a housing for a surge protection device, in a configuration where the temperature of the Overvoltage protection component is below the critical threshold;
• the figure 2 is a sectional view of the first embodiment of a case for a surge protection device, in a configuration in which the temperature of the overvoltage protection component is greater than the critical threshold;
• the figure 3 is a 3D view of the first embodiment of a case for surge protection device, in a configuration where the temperature of the overvoltage protection component is below the critical threshold;
• the figure 4 is a 3D view of the first embodiment of a case for surge protection device, in a configuration where the temperature of the overvoltage protection component is greater than the critical threshold;
• the figure 5 is a sectional view of a second alternative embodiment of a case for overvoltage protection device, in a configuration where the temperature of the overvoltage protection component is below the critical threshold;
• the figure 6 is a sectional view of the second embodiment of a case for a surge protection device, in a configuration in which the temperature of the overvoltage protection component is greater than the critical threshold;
• the figure 7 is a sectional view of a third embodiment of a housing for a surge protection device, in a configuration where the temperature of the overvoltage protection component is below the critical threshold,
• the figure 8 is a sectional view of the third embodiment of a surge protection device housing, in a configuration where the temperature of the overvoltage protection component is greater than the critical threshold;
• the figure 9 is a sectional view of a fourth alternative embodiment of a case for overvoltage protection device, in a configuration where the temperature of the overvoltage protection component is below the critical threshold;
• the figure 10 is a sectional view of the fourth embodiment of a case for surge protection device, in a configuration where the temperature of the overvoltage protection component is greater than the critical threshold;
• the figure 11 is a sectional view of a fifth embodiment of a box for surge protection device, in a configuration where the temperature of the overvoltage protection component is below the critical threshold;
• the figure 12 is a sectional view of the fifth embodiment of a box for surge protection device, in a configuration where the temperature of the overvoltage protection component is greater than the critical threshold;
• the figure 13 is a sectional view of a sixth alternative embodiment of a box for surge protection device, in a configuration where the temperature of the overvoltage protection component is below the critical threshold;
• the figure 14 is a sectional view of the sixth alternative embodiment of a case for surge protection device, in a configuration where the temperature of the overvoltage protection component is greater than the critical threshold;
• the figure 15 is a sectional view of a seventh embodiment of a case for a surge protection device, in a configuration in which the temperature of the overvoltage protection component is below the critical threshold; and
• the figure 16 is a sectional view of the seventh embodiment of a case for a surge protection device, in a configuration in which the temperature of the overvoltage protection component is greater than the critical threshold.
• the figure 17 is a sectional view of an eighth embodiment of a surge protection device housing in a configuration where the temperature of the overvoltage protection component is below the critical threshold; and
• the figure 18 is a sectional view of the eighth embodiment of a housing for a surge protection device, in a configuration where the temperature of the Overvoltage protection component is above the critical threshold.
• the figure 19 is a sectional view of a ninth embodiment of a surge protection device housing, in a configuration where the temperature of the overvoltage protection component is below the critical threshold; and
• the figure 20 is a sectional view of the ninth embodiment of a surge protection device housing, in a configuration where the temperature of the overvoltage protection component is greater than the critical threshold.
• the figure 21 represents a first variant embodiment of a device for protection against overvoltages.
• The figure 22 represents a second variant embodiment of a device for protection against overvoltages.

MODES OF REALIZATION

The Figures 1 to 20 represent nine variants of a housing 1 for overvoltage protection device.

• deux éléments de connexion électrique 11 et 12;
• un composant de protection contre les surtensions 13, typiquement une varistance, relié électriquement aux deux éléments de connexion électrique 11 et 12, dont la température augmente en présence d'une surtension ;
• un élément de verrouillage 15, en contact avec le composant de protection contre les surtensions 13 ;
• un interrupteur mécanique 17 , relié à l'élément de verrouillage 15 , installé en série entre un des deux éléments 11 de connexion électrique et le composant de protection contre les surtensions 13 , l'élément de verrouillage 15 maintenant l'interrupteur 17 en position fermée.
• L'élément de verrouillage 15 et l'interrupteur 17 sont électriquement indépendants et ainsi l'élément de verrouillage peut n'être pas conducteur électrique. Par électriquement indépendant, on entend que l'élément de verrouillage ne fait pas partie du chemin de courant dont l'interrupteur 17 est un composant.

In these nine variants, the box 1 for a surge protection device comprises:

• two electrical connection elements 11 and 12;
• an overvoltage protection component 13, typically a varistor, electrically connected to the two electrical connection elements 11 and 12, whose temperature increases in the presence of an overvoltage;
• a locking element 15 in contact with the overvoltage protection component 13;
• a mechanical switch 17, connected to the locking element 15, installed in series between one of the two electrical connection elements 11 and the overvoltage protection component 13, the locking element 15 holding the switch 17 in the closed position .
• The locking member 15 and the switch 17 are electrically independent and thus the locking member may not be electrically conductive. By electrically independent means that the locking element is not part of the current path whose switch 17 is a component.

The temperature of the overvoltage protection component 13 increases in the presence of overvoltages. The accumulation, over time, of overvoltages induces an increase in temperature such that the temperature will exceed a critical threshold. This critical threshold is between 100 ° C. and 240 ° C., and particularly preferably between 120 ° C. and 190 ° C. This threshold corresponds to the temperature from which the reliability of the overvoltage protection component is no longer ensured. This temperature is determined in accordance with the safety requirements imposed by the applicable safety standards.

When this critical threshold is reached, the locking element 15, in thermal conduction contact with a bare metal part of an electrode 131 of the overvoltage protection component 13, will melt only under the effect of the heat transmitted by the surge protection component 13.

The locking element 15 may be a low temperature solder or a plastic part. This locking element 15 detects the heating of the overvoltage protection component 13, and melts when the critical temperature threshold is reached.

The melting of the locking element 15 unlocks the mechanical switch 17. When the temperature of the overvoltage protection component is below the critical threshold, the mechanical switch is in closed position. Thus, the casing 1 for overvoltage protection device is electrically connected to the device to be protected.

When the temperature of the overvoltage protection component 13 is greater than the critical threshold, which corresponds to a possible damage to the electrical equipment due to the heating of the overvoltage protection component 13, the fusion of the locking element releases the mechanical switch, whose movement places it in the open position. Thus, the housing 1 is no longer electrically connected to the device to be protected.

The Figures 1, 2 , 3 and 4 illustrate a first embodiment of a housing 1 for overvoltage protection device.

• deux lames ressort conductrices 171 et 172 connectées respectivement au premier élément 11 de connexion électrique et au composant de protection contre les surtensions 13,
• une pièce isolante 173, solidaire d'un élément entraineur 175,
• l'élément entraineur 175 relié par une encoche 177 à une pièce mobile 179,
• la pièce mobile 179, reliée à l'élément de verrouillage 15,
• un premier ressort 181 en appui sur la pièce isolante 173.

In this embodiment, the mechanical switch 17 comprises:

• two conductive spring blades 171 and 172 respectively connected to the first electrical connection element 11 and to the overvoltage protection component 13,
• an insulating part 173, integral with a driving element 175,
• the drive element 175 connected by a notch 177 to a moving part 179,
• the moving part 179, connected to the locking element 15,
• a first spring 181 resting on the insulating part 173.

The figures 1 and 3 illustrate the housing 1 comprising such a mechanical switch 17, in the case where the temperature of the overvoltage protection component 13 is below the critical threshold and the mechanical switch is in the closed position. The drive member 175 and the first spring 181 maintain in compression the insulating piece 173 away from the two conductive strips 171 and 172 which are in contact.

The moving part is held in a position called normal operation by the locking element 15 and in compression by a second spring 183.

The figures 2 and 4 illustrate the housing 1 comprising such a mechanical switch 17, in the case where the temperature of the overvoltage protection component 13 is greater than the critical threshold.

The locking element 15 has melted under the effect of the rise in temperature of the overvoltage protection component 13, and the moving part, under the effect of the second spring 183 moves in translation and releases the notch 177 connecting it to the trainer element 175.

The drive element 175, released from the notch 177, and integral with the insulating part 173 held by a first spring 181 in compression, then moves in translation in a direction opposite to the two conductive blades 171 and 172.

This displacement of the drive element 175 causes a displacement in translation of the insulating part 173, integral with the drive element 175, which is placed between the two conductive blades 171 and 172.

Thus the electrical contact between the two conductive blades 171 and 172 is open and the box 1 for overvoltage protection device, comprising the defective overvoltage protection component 13 is isolated from the rest of the electrical equipment.

The Figures 5 and 6 illustrate a second embodiment of a housing 1 for overvoltage protection device.

• deux lames ressort conductrices 171 et 172 connectées respectivement au premier élément 11 de connexion électrique et au composant de protection contre les surtensions 13,
• une pièce isolante 173, solidaire d'un élément entraineur 175,
• l'élément entraineur 175 relié par une encoche 177 à une pièce mobile,
• la pièce mobile, reliée à l'élément de verrouillage 15,
• un premier ressort 181 en appui sur la pièce isolante 173.

In this embodiment, the mechanical switch 17 comprises:

• two conductive spring blades 171 and 172 respectively connected to the first electrical connection element 11 and to the overvoltage protection component 13,
• an insulating part 173, integral with a driving element 175,
• the driving element 175 connected by a notch 177 to a moving part,
• the moving part, connected to the locking element 15,
• a first spring 181 resting on the insulating part 173.

In this second embodiment, the moving part is a leaf spring 1791.

The locking member 15 and the switch 17 are electrically independent and thus the locking member may not be electrically conductive.

The figure 5 illustrates the housing 1 comprising such a mechanical switch 17, in the case where the temperature of the overvoltage protection component 13 is below the critical threshold and the mechanical switch is in the closed position.

The leaf spring 1791 is held in a horizontal position, called normal operation, by the locking member 15 and a lug 180, in which one end of the leaf spring 1791 is locked.

The entrainment element, connected to the moving part 1791, keeps the insulating part 173 away from the two conductive strips 171 and 172, which are in contact.

The figure 6 illustrates the housing 1 comprising such a mechanical switch 17, in the case where the temperature of the overvoltage protection component 13 is greater than the critical threshold.

The locking element 15 has melted under the effect of the temperature rise of the overvoltage protection component 13, and the spring blade 1791 is no longer maintained in a horizontal position under the pin 180 by the lock 15. It rotates and moves to a vertical position.

The drive element 175, connected to this leaf spring 1791 by the notch 177, and integral with the insulating part 173 then moves in translation in a direction opposite to the two conductive strips 171 and 172.

This displacement of the drive element 175 causes a displacement in translation of the insulating part 173, integral with the drive element 175, which is placed between the two conductive blades 171 and 172.

Thus the electrical contact between the two conductive blades 171 and 172 is open and the box 1 for overvoltage protection device, comprising the defective overvoltage protection component 13 is isolated from the rest of the electrical equipment.

The Figures 7 and 8 illustrate a third embodiment of a housing 1 for overvoltage protection device.

• deux lames conductrices 171 et 172 connectées respectivement au premier élément 11 de connexion électrique et au composant de protection contre les surtensions 13,
• une pièce isolante 173, solidaire d'un élément entraineur 175,
• l'élément entraineur 175 relié par une encoche 177 à une pièce mobile,
• la pièce mobile, reliée à l'élément de verrouillage 15,
• un premier ressort 181 en appui sur la pièce isolante 173.

In this embodiment, the mechanical switch comprises:

• two conductive strips 171 and 172 respectively connected to the first electrical connection element 11 and to the overvoltage protection component 13,
• an insulating part 173, integral with a driving element 175,
• the driving element 175 connected by a notch 177 to a moving part,
• the moving part, connected to the locking element 15,
• a first spring 181 resting on the insulating part 173.

In this third embodiment, one of the two conductive blades 172 is a spring blade and the moving part is a lever with a bent arm 1792.

The locking member 15 and the switch 17 are electrically independent and thus the locking member may not be electrically conductive.

The figure 7 illustrates the case 1 comprising such a mechanical switch, in the case where the temperature of the overvoltage protection component 13 is below the critical threshold and the mechanical switch is in the closed position.

The curved lever 1792 is held in a position, known as normal operation, by the locking member 15 and by a lug 180, in which one end of the lever arm is locked.

The entrainment element 175, connected to the curved arm lever 1792 by the notch 177, keeps the insulating piece 173 away from the two conductive strips 171 and 172, which are in contact.

The figure 8 illustrates the housing 1 comprising such a mechanical switch, in the case where the temperature of the overvoltage protection component 13 is greater than the critical threshold.

The locking element 15 has melted under the effect of the temperature rise of the overvoltage protection component 13, and the curved arm lever 1792 is no longer held under the lug 180 by the locking element 15. It rotates upwards.

The driving element 175, connected to this lever with a curved arm 1792 by the notch 177, and integral with the insulating part 173, then moves in translation in a direction opposite to the two conductive blades 171 and 172, under the action of a spring 181.

This displacement of the drive element 175 causes a displacement in translation of the insulating part 173, integral with the drive element 175, which is placed between the two conductive blades 171 and 172.

Thus the electrical contact between the two conductive blades 171 and 172 is open and the box 1 for overvoltage protection device, comprising the defective overvoltage protection component 13 is isolated from the rest of the electrical equipment.

In the Figures 9 and 10 is illustrated a fourth embodiment of a housing 1 for overvoltage protection device.

• deux lames conductrices 171 et 172 connectées respectivement au second élément 12 de connexion électrique et au composant de protection contre les surtensions (non visible sur les figures 9 et 10),
• une pièce isolante 173, solidaire d'un élément entraineur 175,
• l'élément entraineur 175 relié à un élément de verrouillage 15.

In this embodiment, the mechanical switch comprises:

• two conductive strips 171 and 172 respectively connected to the second element 12 of electrical connection and to the overvoltage protection component (not visible on the Figures 9 and 10 )
• an insulating part 173, integral with a driving element 175,
• the driving element 175 connected to a locking element 15.

When the temperature of the overvoltage protection component is below the critical threshold, that is to say in the case illustrated by the figure 9 , the locking element 15 maintains the insulating part 173, via the driving element 175, away from the two conductive strips 171 and 172. One of the two conductive blades 172 is a spring blade.

As illustrated by figure 10 when the temperature of the overvoltage protection component is higher than the critical threshold, the locking element 15 has melted, causing the drive element 175 to move upwards under the effect of the unlocking and the compression of the a second spring 183. This translation of the driving element 175 causes a translation of the insulating part 173, integral with the driving element 175, which is placed between the two conductive blades; the conductive spring blade 172 deviating from the other conductive blade 171 under the effect of the insulating part.

Thus the electrical contact between the two conductive blades 171 and 172 is open and the box 1 for overvoltage protection device, including the defective overvoltage protection component, is isolated from the rest of the electrical equipment.

In the Figures 11 and 12 is illustrated a fifth embodiment of a housing 1 for overvoltage protection device.

• deux lames conductrices 171 et 172 ; la première lame conductrice 171 étant connectée entre le premier élément 11 de connexion électrique et le composant de protection contre les surtensions (non visible sur les figures 11 et 12) ; la seconde lame conductrice 172 étant connectée entre le second élément 12 de connexion électrique et le composant de protection contre les surtensions,
• une pièce isolante 173, solidaire d'un élément entraineur 175,
• l'élément entraineur 175 relié à un élément de verrouillage 15.

In this embodiment, the mechanical switch comprises:

• two conductive blades 171 and 172; the first conductive blade 171 being connected between the first electrical connection element 11 and the overvoltage protection component (not visible on the Figures 11 and 12 ); the second conductive blade 172 being connected between the second electrical connection element 12 and the overvoltage protection component,
• an insulating part 173, integral with a driving element 175,
• the driving element 175 connected to a locking element 15.

When the temperature of the overvoltage protection component is below the critical threshold, that is to say in the case illustrated by the figure 11 , the locking element 15 maintains the insulating part 173, via the driving element 175, away from the two conductive strips 171 and 172.

As illustrated by figure 12 when the temperature of the overvoltage protection component is higher than the critical threshold, the locking element 15 has melted, causing the driving element 175 to move upwards under the effect of unlocking and extending of a first spring 181. This translation of the driving member 175 causes a translation of the insulating part 173, integral with the driving member 175, which is placed between the two electrical contacts between the first conductive blade 171 and the first element 11 of electrical connection and between the second conductive blade 172 and the second element 12 of electrical connection.

Thus the electrical contact is open and the casing 1 for surge protection device, comprising the protection component Defective overvoltage is isolated from the rest of the electrical equipment.

In the Figures 13 and 14 is illustrated a sixth embodiment of a housing 1 for overvoltage protection device.

• deux lames conductrices 172 et 171 connectées respectivement au second élément 12 de connexion électrique et au composant de protection contre les surtensions (non visible sur les figures 13 et 14),
• une pièce isolante 173, reliée à une pièce mobile 179 par une encoche 177,
• la pièce mobile 179 reliée à un élément de verrouillage 15.

In this embodiment, the mechanical switch comprises:

• two conductive blades 172 and 171 respectively connected to the second element 12 of electrical connection and to the overvoltage protection component (not visible on the Figures 13 and 14 )
• an insulating part 173, connected to a moving part 179 by a notch 177,
• the moving part 179 connected to a locking element 15.

When the temperature of the overvoltage protection component is below the critical threshold, that is to say in the case illustrated by the figure 13 , the locking element 15 keeps the moving part 179 provided with a notch 177. By means of this notch 177, the insulating part 173 is kept away from the two conductive strips 171 and 172. One of the two conductive blades 172 is a spring blade.

As illustrated by figure 14 when the temperature of the overvoltage protection component is higher than the critical threshold, the locking element 15 has melted, resulting in a translation of the moving part 179 in order to release the insulating part 173 from the notch 177. The insulating part 173, thus released from the notch, moves in translation upwards, under the effect of the extension of a first spring 181. The insulating part 173, by this translational movement, is placed between the two conductive blades 171 and 172; the conductive spring blade 172 deviating from the other conductive blade 171 under the effect of the insulating part.

Thus the electrical contact is open and the case 1 for overvoltage protection device, including the faulty overvoltage protection component is isolated from the rest of the electrical equipment.

In the Figures 15 and 16 is illustrated a seventh embodiment of a housing 1 for overvoltage protection device.

• deux lames conductrices 172 et 171 connectées respectivement au second élément 12 de connexion électrique et au composant de protection contre les surtensions 13,
• une pièce isolante 173, reliée à une pièce mobile 179 par une encoche 177,
• la pièce mobile 179 reliée à un élément de verrouillage 15.

In this embodiment, the mechanical switch comprises:

• two conductive blades 172 and 171 respectively connected to the second electrical connection element 12 and to the overvoltage protection component 13,
• an insulating part 173, connected to a moving part 179 by a notch 177,
• the moving part 179 connected to a locking element 15.

When the temperature of the overvoltage protection component is below the critical threshold, that is to say in the case illustrated by the figure 15 , the locking element 15 holds the moving part 179 provided with a notch 177. By means of this notch 177, the insulating part 173 is kept away from the two conductive strips 171 and 172. The two blades 171 and 172 conductive are spring blades.

As illustrated by figure 16 when the temperature of the overvoltage protection component 13 is greater than the critical threshold, the locking element 15 has melted, resulting in an upward translation of the moving part 179 in order to release the insulating part 173 from the notch 177 The insulating part 173, thus released from the notch, moves in horizontal translation, under the effect of the extension of the first spring 181. The insulating part 173, by this translational movement, is placed between the two conductive blades 171 and 172, which by their nature of blade spring deviate under the action of the insulating part 173.

Thus the electrical contact is open and the case 1 for overvoltage protection device, including the faulty overvoltage protection component is isolated from the rest of the electrical equipment.

In the Figures 17 and 18 is illustrated an eighth embodiment of a housing 1 for overvoltage protection device.

• deux lames conductrices 172 et 171 connectées respectivement au premier élément 11 de connexion électrique et au composant de protection contre les surtensions 13,
• une pièce isolante 173, reliée à une pièce mobile 179 par une encoche 177,
• la pièce mobile 179 reliée à un élément de verrouillage 15.

In this embodiment, the mechanical switch comprises:

• two conductive blades 172 and 171 respectively connected to the first electrical connection element 11 and to the overvoltage protection component 13,
• an insulating part 173, connected to a moving part 179 by a notch 177,
• the moving part 179 connected to a locking element 15.

When the temperature of the overvoltage protection component is below the critical threshold, that is to say in the case illustrated by the figure 17 , the locking element 15 holds the moving part 179 provided with a notch 177. By means of this notch 177, the insulating part 173 is kept away from the two conductive strips 171 and 172. spring blade.

As illustrated by figure 18 when the temperature of the overvoltage protection component 13 is greater than the critical threshold, the locking element 15 has melted, resulting in a downward rotation of the moving part 179 to release the insulating member 173 from the notch 177 The insulating part 173, thus released from the notch, moves in horizontal translation, under the effect of the extension of the first spring 181. The insulating part 173, by this translational movement, is placed between the two conductive blades 171 and 172, which deviate under the action of the insulating part 173.

Thus the electrical contact is open and the case 1 for overvoltage protection device, including the faulty overvoltage protection component is isolated from the rest of the electrical equipment.

In the Figures 19 and 20 is illustrated a ninth embodiment of a housing 1 for overvoltage protection device.

• deux lames conductrices 172 et 171 connectées respectivement au premier élément 11 de connexion électrique et au composant de protection contre les surtensions 13,
• une pièce isolante mobile 173, reliée à la varistance 13 par un chemin thermique 131 et l'élément de verrouillage 15.

In this embodiment, the mechanical switch comprises:

• two conductive blades 172 and 171 respectively connected to the first electrical connection element 11 and to the overvoltage protection component 13,
• a movable insulating part 173, connected to the varistor 13 by a thermal path 131 and the locking element 15.

When the temperature of the overvoltage protection component is below the critical threshold, that is to say in the case illustrated by the figure 19 , the locking element 15 holds the moving part 173. The insulating part 173 is kept away from the two conductive strips 171 and 172. The conductive blade 171 is a spring blade.

As illustrated by figure 20 when the temperature of the overvoltage protection component 13 is greater than the critical threshold, the locking element 15 has melted, causing a horizontal translation, under the effect of the extension of the first spring 181 of the insulating part 173. This, by this translation movement, is placed between the two conductive blades 171 and 172, which deviate under the action of the insulating part 173.

Thus the electrical contact is open and the case 1 for overvoltage protection device, including the faulty overvoltage protection component is isolated from the rest of the electrical equipment.

The invention also relates to a device for protection against overvoltages. The Figures 21 and 22 represent two variants of an overvoltage protection device.

• un boitier 1 de protection contre les surtensions selon un des modes de réalisations précédemment décrits,
• une embase fixée sur un rail 23.

The figure 21 illustrates a first alternative embodiment of a surge protection device comprising:

• a box 1 of overvoltage protection according to one of the embodiments described above,
• a base fixed on a rail 23.

The connection of the surge protection device is made during the plugging of the surge protection box 1 on the base. This connection is made by electrically connecting the two electrical connection elements and the housing 1 to the base. Thus, the device 2 for overvoltage protection is electrically connected to the equipment or electrical installation to be protected.

When the temperature of the overvoltage protection component reaches the predefined critical threshold, the breaking of the electrical contact between the conductive blades isolates the overvoltage protection device from the equipment or electrical installation to be protected.

• une pluralité de boitiers pour dispositif de protection contre les surtensions selon un des modes de réalisation précédemment décrits,
• une pluralité d'embase fixée sur un rail 23.

The figure 22 illustrates a second variant embodiment of an overvoltage protection device comprising:

• a plurality of boxes for overvoltage protection device according to one of the previously described embodiments,
• a plurality of base fixed on a rail 23.

The connection of the surge protection device being done during the plugging of each of said surge protection boxes on each of said respective bases.

This connection is made by electrically connecting the two electrical connection elements and each housing to the respectively associated base. Thus, the surge protection device is electrically connected to the equipment or electrical installation to be protected.

When the temperature of the overvoltage protection component reaches the predefined critical threshold, the breaking of the electrical contact between the conductive blades of each of said housings isolates the overvoltage protection device of the equipment or electrical installation to be protected.

The invention has been illustrated and described in detail in the drawings and the foregoing description. This must be considered as illustrative and given by way of example and not as limiting the invention to this description alone. Many alternative embodiments are possible.

In the claims, the word "comprising" does not exclude other elements and the indefinite article "a" does not exclude a plurality.

Claims (13)

Case (1) for a surge protection device comprising: Two electrical connection elements (11) and (12); An overvoltage protection component (13), electrically connected to the two electrical connection elements (11) and (12), whose temperature increases in the presence of an overvoltage; A locking element (15) in contact with the overvoltage protection component (13); A mechanical switch (17), connected to the locking element (15), connected in series between one of the two electrical connection elements (11) and the overvoltage protection component (13), the locking element (15) holding the switch (17) in the closed position; and such that when the temperature of the overvoltage protection component (13) exceeds a critical threshold, the locking element (15) releases the switch (17) which moves to the open position,
characterized in that the locking element is electrically independent of the mechanical switch. Housing (1) according to claim 1, characterized in that the overvoltage protection component (13) is a varistor. Housing (1) according to claim 1, characterized in that the locking element (15) is in thermal connection by conduction with a bare metal part of an electrode (131) of the overvoltage protection component (13). Housing (1) according to claim 3, characterized in that the locking element (15) is a low temperature solder which melts when the temperature of the overvoltage protection component (13) exceeds the critical threshold. Housing (1) according to claim 3, characterized in that the locking element (15) is a plastic part which melts when the temperature of the overvoltage protection component (13) exceeds the critical threshold. Housing (1) according to any one of the preceding claims, characterized in that the critical threshold is between 100 and 240 ° C. Housing (1) according to any one of the preceding claims, characterized in that the mechanical switch (17) comprises: Two conductive blades (171) and (172) respectively connected to the first electrical connection element (11) and to the overvoltage protection component (13), An insulating part (173), integral with a driving element (175), The entrainment element (175) connected by a notch (177) to a moving part (179), The movable part (179), connected to the locking element (15), A first spring (171) bearing, or in tension, on the insulating part (173),
such that, in the closed position of the switch, the two conductive blades (171) and (172) are in contact and the driving element (175) and the first spring (181) out of its equilibrium position. , keep the insulating part (173) away from the two conductive blades (171) and (172), and upon unlocking, the moving part (179) moves and releases the drive element (175), the workpiece isolator (173) being driven by the first spring (181) in a translational motion to spread and be placed between the two conductive blades (171) and (172). Housing (1) according to claim 7, characterized in that the two conductive blades are spring blades and the movable part (179) moves in translation under the effect of a second spring (183). Housing (1) according to claim 7, characterized in that the two conductive blades are leaf springs and the movable part (179) is a leaf spring (1791), held by a lug (180), said movable part (179) when unlocking, performs a rotational movement which releases it from the lug (180). Housing (1) according to claim 7, characterized in that one of the two conductive blades (172) is a spring blade and the moving part (179) is a lever with a bent arm (1792), held by a lug (180) said movable part (179), upon unlocking, makes a rotational movement which releases it from the lug (180). Boltier (1) according to claim 1, characterized in that the locking element is out of the current path formed by one of the two elements (11) of electrical connection, the mechanical switch (17) and the component overvoltage protection (13). Device (2) for overvoltage protection comprising a housing (1) according to one of the preceding claims and a base (21) fixed on a rail (23), characterized in that the two electrical connection elements (11) and ( 12) of the housing (1) are electrically connected to the base during the racking of the housing (1). Device (2) for surge protection comprising a plurality of boxes according to one of claims 1 to 11 and a plurality of bases fixed on a rail (23) characterized in that the two electrical connection elements of each of said boxes are connected to a respective base during the racking of the respective housing.

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