FR2959588A1 - Condenser i.e. self healing type low voltage power condenser, has safety device comprising thermofusible element that cooperates with mobile electrical contact to authorize displacement of electrical contact in closing position - Google Patents

Abstract

The condenser has a self-healing wound winding placed in a sealed individual case. A safety device (15) includes an element i.e. thermofusible element, that is arranged inside the sealed case and cooperates with a mobile electrical contact (21) to authorize displacement of the mobile electrical contact in a closing position, when the temperature of the winding or an interior of the case is higher than a predetermined value. The thermofusible element is arranged between the mobile electrical contact and a fixed part (23) of a short-circuit setting mechanism (19).

Description

TECHNICAL FIELD OF THE INVENTION The invention relates to the field of low voltage power capacitors consisting of self-healing wound windings or self-healing coils, and equipped with a protection device. In particular, the invention relates to a capacitor comprising at least one self-healing wound winding housed in a sealed individual package, said capacitor being equipped with a protection device comprising a short-circuiting mechanism for setting a short-circuit free said winding by means of a movable electrical contact, the closure of said first contact being caused by the presence of an electrical fault of said winding in said housing. STATE OF THE ART The French patent application FR2598024 discloses a low-voltage power capacitor of the self-healing type, comprising wound windings, each of said windings being housed in a sealed individual housing. The capacitor is equipped with a protection device, which comprises a deformable membrane belonging to the wall of the housing and capable of deforming during an overpressure, due to an internal defect of the winding in the housing. The protection device further comprises a contact whose closure is caused by the membrane to short-circuit the self-healing wound coil. In this type of capacitor the activation of the protection device is triggered only by the appearance of an overpressure in the housing. DISCLOSURE OF THE INVENTION The invention aims to remedy the limitations of capacitors of the prior art by proposing a capacitor comprising at least one self-healing wound coil housed in a sealed individual package, said capacitor being equipped with a device of 1 protection comprising a short-circuiting mechanism for short-circuiting said at least one capacitor winding by means of a first movable electrical contact, the closure of said first contact being caused by the presence of a fault of said winding in said housing, characterized in that the protection device further comprises a temperature-sensitive element disposed inside said housing and cooperating with said first electrical contact to allow the displacement of said first movable electrical contact in a position of when the temperature of the winding and / or the inside of said housing is t greater than a predetermined value. Preferably, the temperature sensitive element is a heat fusible element having a melting temperature corresponding to the predetermined value. Advantageously, the heat fusible element is disposed between the first movable electrical contact and a fixed part of the short-circuiting mechanism to maintain said first movable electrical contact in an open position. According to one embodiment, the short-circuiting mechanism comprises biasing means arranged between the first movable electrical contact and a fixed part of said short-circuiting mechanism for biasing said first movable electrical contact in the closed position. when the hot-melt element is melted. Preferably, the fixed portion of the shorting mechanism is traversed by a first and a second electrical conductor connected to the at least one winding, a first end of the first movable electrical contact being pivotally mounted around said first conductor and in contact said first movable electrical contact being arranged so that a second end of said first movable electrical contact comes into contact with said second conductor when the thermo-fusible element is melted. Preferably, the return means are essentially constituted by a tension spring fixed on one side to the second end of the first moving electrical contact and on the other side to the fixed part. According to one embodiment, the heat-fusible element is fixed by welding between a metal pad embedded in the fixed part and the first movable electrical contact.

According to one embodiment, the heat-fusible element has the shape of a pin inserted in a hole formed in the first moving electrical contact and embedded in the fixed part. According to one embodiment, the protection device comprises a fuse element connected in series with the at least one winding to eliminate the short-circuit franc. Preferably, the protection device is capped by a cover comprising at least one internal housing compartment for housing a fuse. Preferably, the protection device comprises a deformable membrane belonging to a sealed wall of the housing and capable of deforming during an overpressure in said housing caused by an internal defect of the self-healing wound coil in said housing, said device protection device comprising, in addition, a second movable electrical contact cooperating with said membrane to be moved into a closed position during a deformation of said membrane. 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 appended figures. Figure 1 is an overall view of a system of three capacitors. Fig. 2 is a view of the three capacitor system shown in Fig. 1 in which one of said capacitors has been shown in section. Figure 3 is an exploded view of the three capacitor system shown in Figure 1. Figure 4 is a sectional view of a protection device. FIG. 5 is a view of the protective devices capping the capacitors of the system shown in FIGS. 1 to 3. FIGS. 6 and 7 are views of an armed shorting mechanism respectively in perspective and from above .

FIGS. 8 and 9 are views of a short-circuiting mechanism tripped respectively in perspective and from above. DETAILED DESCRIPTION OF AN EMBODIMENT With reference to FIGS. 1 to 3, each capacitor of the system 1 of three capacitors 3 comprises a cylindrical housing, in particular of plastic. Inside each housing is housed a coil formed by a winding of metallized plastic films. The coil is encapsulated in a resin in the usual manner and is connected to a first and a second electrical conductor 5, 7. The coil 9 is of the self-healing type. Capacitors 3 are said to be self-healing because the presence of minor defects in a dielectric film causes localized breakdown, which leads to the evaporation of the electrodes in the vicinity of the defect without damage to the adjacent film. This localized breakdown causes evaporation of the metallization at the point of breakdown and thus an insulation of this faulty zone. The coil 9 retains its insulation and the loss of capacity, due to the point evaporation of the metallization, is practically negligible. The plastic film used is advantageously a polypropylene film metallized with a layer of aluminum, zinc or an aluminum-zinc alloy. The system 1, which corresponds to a capacitor, or more precisely to three capacitor elements 3, comprises a protective cover 11 and electrical connection means 13 in a triangle. Each capacitor element 3 comprises a protection device 15. Note that the capacitor elements 3 constitute capacitors as such, in this case each of them being dedicated to each of the phases. In the embodiment shown in FIG. 5, the protection devices 15 of each capacitor of the three capacitor system are formed in a single and independent piece.

With reference to FIGS. 5 to 9, the protection device 15 of each capacitor 3 comprises a short-circuiting mechanism 19 for short-circuiting the self-healing wound winding by means of a first movable electrical contact. 21. The short-circuiting mechanism 19 comprises a fixed portion 23 through which the first and the second electrical conductors 5, 7 connected to the self-healing wound winding pass. A first end 25 of the first movable electrical contact 21 is pivotally mounted around the first conductor 5. In addition, this first end 25 is in electrical contact with the first conductor 5. The first movable electrical contact 21 is designed so that a second end 27 of said first moving electrical contact can come into contact with the second conductor 7. The shorting mechanism 19 comprises a temperature-sensitive element disposed inside the capacitor 3 housing. This temperature-sensitive element co-operates with the first movable electrical contact 21 so as to allow the displacement of this first movable electrical contact in a closed position to short-circuit the self-healing wound coil 9, when the temperature of the self-wound coil winding and / or within said housing is greater than a predetermined value. In the embodiment shown, the temperature sensitive element is a heat fusible element having a melting temperature corresponding to the predetermined value beyond which the first moving electrical contact 21 moves in its closed position. The heat-fusible element is disposed between the first movable electrical contact 21 and the fixed part 23 of the short-circuiting mechanism 19 and thus makes it possible to maintain said first moving electrical contact in an open position, in which the self-healing wound coil 9 is not short-circuited.

In the embodiment shown, the heat-fusible element may be fixed by welding between a metal pad 31 embedded in the fixed part 23 and the first movable electrical contact 21. In this case, the heat-fusible element may be essentially formed by the solder between the metal pad 31 and the first movable electrical contact 21. Alternatively, the heat-fusible element may be in the form of a pin, not shown, which is inserted into a hole 33 formed in the first electrical contact. movable 21 and embedded in a notch 35 of the fixed part 23. In the embodiment shown, the temperature rise at which the heat-fusible element is sensitive is transmitted to said element by heat conduction of the first movable electrical contact. 21, the latter being itself heated through the electrical conductor 5. The heat transmitted by the electrical conductor 5 is all the more representative of the temperature of the self-healing wound coil, since this conductor 5 passes through the self-healing wound coil from one side to the other. This self-healing wound wound coil will thus dissipate part of the heat by means of the electrical conductor 5.

In the embodiment shown, return means 37 arranged between the first movable electrical contact 21 and the fixed part 23 of the short-circuiting mechanism 19 make it possible to return said first movable electrical contact to the closed position when the thermofusible element is melted. In this case, the return means 37 consist essentially of a tension spring fixed on one side to the second end 27 of the first movable electrical contact 21 and on the other side to the fixed part 23. In another embodiment embodiment not shown, the temperature sensitive element could be formed in a shape memory alloy and arranged to move the free end of the first movable contact to short-circuit the self-healing wound coil 9 when the predetermined value of the temperature has been reached. As can be seen in FIGS. 4 and 5, the protection device 15 of each capacitor 3 comprises a deformable membrane 51 belonging to a sealed wall of the housing of each capacitor 3. In this case, the housing has a cylindrical shape comprising a open bottom capped by this membrane 51, or more precisely by a cover 53 of rigid plastic material of the protective device 15 on which is mounted said membrane. This deformable membrane 51 is therefore mounted on the cover 53 of the protection device 15, and said cover engages the outer periphery of the open bottom of the housing so as to ensure good sealing by a resin.

In the embodiment shown, the deformable membrane 51 has on its periphery a flange 55 snapping into a first circular groove 57 of the cover 53. The short-circuiting mechanism 19 is disposed on the side of the diaphragm 51 to the inside of the housing, which allows the temperature sensitive element to be exposed to the temperature in said housing. The fixed portion 23 of the short-circuiting mechanism 19 comprises flanges 61 snapping into a second circular groove 59 of the cover 53 so as to maintain the deformable membrane 51 between the short-circuiting mechanism and said cover 53. Once the deformable diaphragm 51 and the short-circuiting mechanism 19 are mounted on the cover 53 of the protection device 15, said cover is fitted over the periphery of the open bottom of the housing so as to ensure a good seal by the resin. The deformable membrane 51 is often made of flexible plastic material and is liable to deform upon the occurrence of an overpressure in the housing caused by an internal defect in the self-healing wound coil. The protection device 15 furthermore comprises a second movable electrical contact 71 mounted on the central part of the deformable membrane 51. The mobility of this second movable contact 71 is ensured by the deformations of the deformable membrane 51. Fixed contacts 73 respectively connected to the first and second electrical conductors 5, 7, are arranged to both be in contact with the second movable contact 71, when the deformable membrane is deformed by an increase in the pressure in the housing. In this way, the appearance of a fault in the self-healing wound coil 9 leading to an increase in the pressure in the housing makes it possible to deform the deformable membrane 51 to move the second movable electrical contact 71 in a position closing device for short-circuiting the self-healing wound coil 9.

As can be seen in FIGS. 3 and 5, the protection device 15 comprises a fuse 81 connected in series with the self-healing wound winding, said fuse making it possible to eliminate any short-circuiting. The central portion of the cover 53 is hollow to form a chamber, one of the funds is constituted by the deformable membrane 51 and the other bottom is closed by the resin not shown. The cover 53 of the protection device 15 also comprises an internal housing compartment 83 for housing a fuse of different size. In normal operation, the first and second movable electrical contacts 21, 71 are both open. As can be seen in FIGS. 6 and 7, the second end 27 of the first movable contact 21 is moved away from the second conductor 7. The first movable electrical contact 21 is held in this open position thanks to the heat-fusible element that constitutes the welding between the first movable contact 21 and the pellet 31 embedded in the fixed part 23 of the shorting mechanism 19. Alternatively, the first movable contact 21 could be held in this open position by means of a pin formed by a heat-fusible element which would be inserted in the hole 33 formed in the first movable contact 21 and embedded in the notch 35 of the fixed part 23. The second movable contact 71 is also in the open position as shown on FIG. 4, that is to say remote from the fixed contacts 73 connected to the first and second conductors 5, 7. The fuse 81 which is connected in series with the first or the second conductor 5 , 7 ensures, meanwhile, the electrical connection with the self-healing wound coil 9.

In the presence of a minor defect producing localized breakdown, the defect is eliminated by the self-healing effect of the self-healing wound coil 9 resulting from the evaporation of the electrodes in the vicinity of the defect. In this case, the rise in temperature or the increase of the pressure in the capacitor housing resulting from this defect is not sufficient to trigger the closing of the first or second movable electrical contact 21, 71, or for in this case, the protection is provided by the self-healing wound coil 9 thanks to the self-healing properties of said element. As a result of a large number of localized breakdowns or the aging of the self-healing wound coil 9, the self-healing properties of the coil 20 forming said winding can be deteriorated. This deterioration of the self-healing properties of the self-healing wound coil 9 can also be caused by a significant dielectric breakdown, during abnormal stresses, generating a fault current. Note that the value of this fault current may not be high enough to melt the fuse 81. Thus, the protection is in this case ensured, depending on the type of fault, either by closing the first or second contact. movable electric 21, 71, and consecutively by the melting of the fuse 81. In the case of a fault generating a rise in temperature of the winding and / or the inside of the housing exceeding the melting temperature of the thermo element. -fusible, the first movable electrical contact 21 is detached from the fixed portion 23 of the short-circuiting mechanism 19. The spring 37 disposed between the first movable electrical contact 21 and the fixed part 23 thus allows to recall said first contact movable electrical device in the closed position to short-circuit the self-healing wound coil 9. In the case of a fault generating a rise in pressure in the housing beyond a limit e resulting in the deformation of the deformable membrane 51, the second movable electrical contact 71 is driven into its closed position to be brought into contact with the fixed contacts 73 connected to the first and second electrical conductors 5, 7. The self-winding coil is Healing 9 is thus short-circuited by means of the second movable electrical contact 71. In the two previous cases, the closing of the first or second movable contact 21, 71 generates a short-circuit franc. It follows that the fuse 81, which is sensitive to this type of short-circuit, will make it possible to ensure the isolation of the capacitor by disconnection of the self-healing wound coil 9. The protection device is therefore autonomous and acts, in all cases, before any significant deformation of the housing, thus avoiding any external effect. The housing can thus be made of plastic. Capacitor 3 provided with such a protective device 15 may also be protected by an external circuit breaker.

Claims (11)

REVENDICATIONS1. Capacitor (3) comprising at least one self-healing wound coil (9) housed in a sealed individual housing, said capacitor being provided with a protection device (15) including a short-circuiting mechanism (19) for in short-circuiting said at least one capacitor winding by means of a first moving electrical contact (21), the closing of said first contact being caused by the presence of a fault of said winding in said casing, characterized in that the protection device further comprises a temperature-sensitive element disposed inside said housing and cooperating with said first electrical contact (21) to allow the displacement of said first moving electrical contact in a closed position, when the temperature of the the winding and / or the inside of said housing is greater than a predetermined value. 2. Capacitor according to claim 1, characterized in that the temperature-sensitive element is a heat-fusible element having a melting temperature corresponding to the predetermined value. 3. Capacitor according to claim 2, characterized in that the heat fusible element is disposed between the first movable electrical contact (21) and a fixed portion (23) of the short-circuiting mechanism (19) to maintain said first movable electrical contact in an open position. 4. Capacitor according to any one of claims 2 or 3, characterized in that the short-circuiting mechanism (19) comprises biasing means (37) arranged between the first movable electrical contact (21) and a part fixed (23) of said short-circuit mechanism for biasing said first movable electrical contact in the closed position, when the heat-fusible element is melted. 5. Capacitor according to claim 4, characterized in that the fixed part (23) of the short-circuiting mechanism (19) is crossed by a first and a second electrical conductor (5, 7) connected to the at least one winding (9), a first end (25) of the first movable electrical contact (21) being pivotally mounted around said first conductor (5) and in electrical contact with said first conductor, said first movable electrical contact (21) being adapted to a second end (27) of said first moving electrical contact comes into contact with said second conductor (7) when the heat fusible element is melted. 6. Capacitor according to claim 5, characterized in that the return means (37) consist essentially of a tension spring fixed on one side to the second end (27) of the first movable electrical contact (21) and the the other side to the fixed part (23). 7. Capacitor according to any one of claims 5 or 6, characterized in that the heat-fusible element is fixed by welding between a metal pad (31) embedded in the fixed part (23) and the first movable electrical contact ( 21). 15 8. Capacitor according to any one of claims 5 or 6, characterized in that the heat-fusible element has the shape of a pin inserted into a hole (33) formed in the first movable electrical contact (21) and recessed in the fixed part (23). 9. Capacitor according to any one of claims 1 to 8, characterized in that the protection device (15) comprises a fuse element (81) connected in series with the at least one winding (9) to eliminate the short circuit. free circuit. 10. Capacitor according to claim 9, characterized in that the protective device (15) is capped by a cover (53) comprising at least one inner housing compartment (83) for housing a fuse. 11. Capacitor according to any one of claims 1 to 10, characterized in that the protection device (15) comprises a deformable membrane (51) belonging to a sealed wall of the housing and capable of deforming during an overpressure in Said housing caused by an internal defect of the self-healing wound coil in said housing, said protection device further comprising a movable second movable contact (71) cooperating with said membrane to be moved into a closed position when deformation of said membrane.