The invention relates to the field of electric arc breaker devices.
When breaking a circuit, an electric arc is struck between electrical contacts. The arc creates a back electromotive force (emf) in the network that tends to oppose the source of the network. In an alternating current (AC) network, the magnitude of the current passing through the terminals of the breaker equipment passes periodically through zero. For example, these passages of the current through zero take place every 10 milliseconds (ms) in a 50 hertz (Hz) network. When the current passes through zero, the conductive arc cools down suddenly and the ions of the plasma of the arc then recombine. This recombination takes place more or less quickly depending on the extinction technique (splitting or lengthening), on the degree of pollution, and on the type of plasma. This recombination enables the break to withstand the network voltage that is still present at its terminals. If that is not so, then a electrical breakdown restarts the arc in the break, until the next time current passes through zero.
An arc voltage greater than the network voltage enables this dielectric recombination phenomenon to be started sooner than the natural passage of the current through zero, thereby increasing the chances of breaking the current.
Nevertheless, a problem arises for existing breaker devices resulting from the possible erosion of electrical contacts by the electric arcs that are generated. This erosion can affect the lifetime of such breaker devices.
There therefore exists a need to have novel breaker devices available with improved lifetime, in which the erosion of contacts due to the electric arc is limited.
To this end, in a first aspect, the invention proposes an electric arc breaker device comprising:
a contact zone in which there are present at least one stationary contact and at least one movable contact that is movable relative to the stationary contact, the contacts being capable of being put into contact with each other and of being separated from each other; and
an arcing horn present facing the stationary contact, the height of the arcing horn being greater than or equal to the height of the stationary contact, and the arcing horn presenting a folded-back arc switching portion extending in a direction away from the stationary contact.
Because of the presence of a folded-back switching portion, the arcing horn serves to push the arc back to the back of the breaker device, to improve splitting of the arc, and to move the arc away from the stationary contact. The movement of the arc from the stationary contact towards the arcing horn also serves to reduce erosion of the stationary contact because of limited contact between the electric arc and the stationary contact, thereby enabling the lifetime of the breaker device to be improved. The arc switching portion constitutes a sacrificial element that is consumed by the arc instead of consuming the stationary contact, thereby enabling the lifetime of the stationary contact to be improved and thus increasing the lifetime of the breaker device.
In an embodiment, the material forming the arc switching portion may have a change-of-state temperature that is higher than the change-of-state temperature of the material forming the stationary contact. This applies for example when the arcing horn is made of steel and the stationary contact is made of copper.
Thus, the material forming the arc switching portion may have a melting temperature or a vaporization temperature that is higher than the melting temperature, or respectively the vaporization temperature, of the material forming the stationary contact.
Using such an arcing horn is advantageous for reducing arc erosion both of the stationary contact and of the arcing horn since the arcing horn is made of a material that withstands arc erosion. Consequently, such a configuration makes it possible to further lengthen the lifetime of the breaker device.
In an embodiment, the breaker device may be present in a box, with the arcing horn having a width L equal to the inside width of said box.
Using such an arcing horn makes it possible to reduce, or even to avoid, the gas of the plasma passing laterally around it. As a result, this enables the path followed by the gas to be lengthened and thus enables the gas to be cooled better before being discharged to the outside of the breaker device. Such a configuration advantageously serves to minimize potential arcing outside the breaker device.
In an embodiment, the breaker device may also further include an extinction chamber containing a stack of electric arc splitting plates present facing the arcing horn.
Such a device serves to further improve the breaking capacity of the device and thus further limit erosion of the electrical contacts due to the arc.
In a variant, the breaker device need not have a stack of electric arc splitting plates.
Such a device advantageously makes it possible to have a solution for extinguishing an electric arc that is simple and inexpensive.
Other characteristics and advantages of the invention appear from the following description of particular embodiments of the invention, given as non-limiting examples and with reference to the accompanying drawings, in which:
The breaker device shown is a double-break rotary breaker device having two blades and extinguishing two arcs (see
In addition, the breaker device 1 includes an arcing horn 10 present facing the contact head 3 on the stationary support 15. The arcing horn 10 is fastened to the stationary support 15 by a mechanical connection. The arcing horn 10 has a tab 14 and an arc switching portion 12. The arcing horn is made of an electrically conductive material, for example the arcing horn 10 may be made out of a metal material, e.g. steel. In the example shown, the tab 14 is in contact with the stationary support 15, but it would not go beyond the ambit of the invention for the arcing horn 10 not to be in contact with the stationary support 15 but to be fastened to the box constituting the outer casing of the breaker device. Under such circumstances, the distance between the arcing horn 10 and the stationary support 15 may be less than or equal to 1 millimeter (mm) for example. An electric arc generated from the movable contact 4 is to be made to move over the arc switching portion 12, as described in detail below.
As shown, the height hc of the arcing horn 10 corresponding to the height at which the end 13 of the arc switching portion 12 is present, is greater than the height ht of the contact head 3. The arc switching portion 12 is folded back and extends in a direction opposite from the stationary contact 3 (i.e. it extends away from the stationary contact 3). As shown, the switching portion 12 forms a bend 12a. The height hc of the arcing horn 10 and the height h′c at which the bend 12a is present are both greater than the height ht of the contact head 3 in the example shown. The heights hc, h′c, and ht are measured from the surface S of the stationary support 15 facing the arcing horn 10, and perpendicularly to the surface S.
The breaker device 1 is present in a box 35. In the example shown, the box comprises the combination of two half-boxes (see
In addition, the breaker device 1 in the example shown in
As shown in
There follows a description of the behavior of the arc 30 generated between the contacts 3 and 4.
The contacts continue their separation movement. The arc 30 then moves to the end 3a of the contact head 3 and to the end 4a of the movable contact 4 (see
The contacts continue their separation movement. The arc at the end of the contact head (configuration P1 shown diagrammatically in
After switching, the root of the arc beside the arcing horn is subjected to a Laplace force (arrow shown in
The contacts still continue their separation movement. The arc penetrates into the extinction chamber and is split. As a result, it maintains a certain fixed voltage level (cathode voltage drops and anode voltage drops at the various arc roots) and it cools (exchanges between the arc and the splitting plates serving to increase impedance). After the contacts are completely separated, the arc is totally split in the extinction chamber (see
This extinction principle can also apply without splitting plates, thus making it possible to provide a simplified breaker device 50, as shown in
The breaker device of the invention can be used for breaking direct current (DC), or alternating current (AC). Breaker devices of the invention can be used in the low voltage range (U_AC≦1000 volts (V) and U_DC≦1500 V).
The term “including/containing/comprising a” should be understood as “including/containing/comprising at least one”.
The term “in the range . . . to . . . ” should be understood as including the bounds.
Number | Date | Country | Kind |
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1460150 | Oct 2014 | FR | national |
Filing Document | Filing Date | Country | Kind |
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PCT/FR2015/052807 | 10/20/2015 | WO | 00 |