FR2699729A1 - Arc-quenching circuit-breaker with simultaneously opened contacts - Google Patents

Abstract

The electromagnetically or electrothermal activated trip device (1) propels an insulating crossbar (2) from which a number of prods (3) extend parallel to one another in the direction of a row of contacts (C1-C8) arranged in series across the main power contact (Co).When the circuit-breaker is set (F), the majority of current passes through the main contact which has much lower resistance. This contact is opened first and the minor series contacts are broken simultaneously a few milliseconds later.

Description

TECHNICAL DESCRIPTION
The present invention relates to a circuit breaker. It finds its application in all cases where it is necessary to obtain a rapid extinction of the arc which manifests itself when the contact is opened.

The elimination of the arc at the opening of the contact, according to the prior art, is carried out by blowing the plasma column CP on a series of copper strips as shown in FIG. 2. The projection of the plasma column is effected by Laplace forces. The arc is extinguished by the fact that it is fractionated at a certain point by the n copper strips so that all the elementary arcs are put in series. (nl) arcs is at most equal to the voltage Uo of the line so that the voltage across one of its elementary arcs is substantially equal to Uo / n-1. If we took n high enough this voltage may be lower than the voltage U, of arc maintenance, which varies according to the nature of the contacts and which is generally close to 20 volts (see Figure 3)
In other embodiments, the stretching of the arc is simply used. Its projection, under the effect of Laplace forces, lengthens the length of the plasma column CP, hence an increase in the series resistance which it constitutes and, consequently, a decrease in the current which falls below some critical arc hold value.

The devices using these principles have many drawbacks which arise from the fact that the plasma column CP does not have a sufficiently rapid speed of movement because its movement is hindered by atmospheric air. We particularly deplore
- premature wear of the contacts because they are subjected to plasma erosion for quite a long time. This wear degrades the quality of the contact (low series resistance in the closed state)
- poor security in the case where the device is a circuit breaker intended to provide physiological protection such as in the case of a differential circuit breaker for domestic use. Indeed, the cut-out is sometimes not fast enough to avoid electrocution,
- a structure which cannot be waterproof because the arc causes a strong pressure build-up in the circuit breaker box, which requires vent holes.

 - mechanical complexity and bulk that it would be desirable to be able to reduce.

The object of the present invention is to remedy these drawbacks. For this, it offers a provision allowing not to use the phenomenon of projection of the arc. The fractionation is carried out by a series of electrodes driven by a simultaneous opening movement. In this way, a large amount of arc is, by construction, placed in series.

The invention relates to an arc extinguishing circuit breaker by fractionation comprising a certain amount of mechanical contacts C1, C2, ... Cn, arranged in series in the electrical circuit to be cut, said contacts Cl, C2, .... Cn being in sufficient number for the extinction of the arc to occur.

According to another characteristic, the device comprises an additional mechanical contact Co, placed in parallel on the series of the arc C1, C2, .... Cn, said contact
Co animated by suitable means (1), (2), (3), (4), (15), (16), (24), (25) so that its opening occurs slightly before that of the series of contacts C1, C2, .... Cn.

 According to another characteristic, the means used to open the contacts Co, C1, C2 .... Cn, consist of a part (2) set in motion by suitable means (1) and comprising fingers (3) and (4) for pushing said contacts.

According to another characteristic, the means used to open the contacts Co, C1, C2, .... Cn consist of:
- a fixed plate (15) comprising metal contacts according to a drawing
suitable,
- a movable plate (16), driven in a translational movement, comprising
also contacts which can advantageously be constituted by
flexible slats
- guide means (21),
- means (12), (13), (14), (22), (32), making it possible to cause the movement
spacing of the movable plate (16) at the time of separation.

According to another characteristic, the means used to open the contacts Co, C1, C2, .... Cn are constituted by
- a fixed circular plate (24) comprising metal surfaces (26), suitable for ensuring good electrical contact,
a movable circular plate (25), substantially coaxial with (24), capable of oscillating around its axis, by a certain angle 0, comprising metal contacts (27), similar to (26),
means (28), (29), (30), (31) allowing the movable plate (25) to be put into rotation,
According to another characteristic, the means allowing the contacts to move at the time of the disjunction consist of a magnetic circuit made of soft ferromagnetic material (30) comprising a part consisting of a permanent magnet (14), a movable armature (32 ) and a trip coil (12).

The characteristics and advantages of the invention will appear better on reading the description which follows, given by way of explanation, and of course, in no way limiting. This description refers to attached drawings in which
Figure 1 shows the contact of a circuit breaker and its charging circuit.

Figure 2, already mentioned relates to the previous year. It represents an arc circuit breaker projected on fractionation strips.

FIG. 3 represents the characteristic I., V of an arc.

FIG. 4 schematically represents the placing in series of n simultaneous opening contacts making it possible to split the arc.

FIG. 5 schematically represents the preceding series of arcs, shunted by a main contact.

FIG. 6 represents a mechanical system making it possible to ensure the synchronism of the contact openings.

Figure 7 shows the axial section of a practical embodiment of the invention.

FIG. 9 represents the flexible contact blades carried by the movable plate.

Figure 8 shows the fixed printed circuit.

FIG. 10 represents the detail of a contact of the method for guiding the movable plate.

FIG. 11 represents the output of the contacts of the fixed printed circuit board.

FIG. 12 represents an embodiment of the invention in which an opening of the contacts is used by rotation of a plate.

With reference to FIG. 1, the function of the contactor C of the circuit breaker which must mechanically cut the circuit supplied with a voltage Rob by any generator, direct or alternating, is described first of all, being able to be the sector or any other source of electrical energy, any load RL of a purely resistive, inductive or capacitive nature.

The prior art is shown in FIG. 2 where the current, before tripping, passes through the contacts C1 and C2 to supply the load which is here symbolized by the resistance RL. The contact C1 is secured to a fixed blade (5) through which the current arrives while the contact C2 is secured to a movable blade (6) set in motion by a coil (9) acting on a plunger core (10 ) or by any other means which directs the current to use. The blades (5) and (6) are extended to a stack of n conductive strips (8) isolated from each other by insulators (7). The shape of (5) and (6) is suitable for guiding the arc which forms between C1 and C2 at the time of opening. The plasma column CP is subjected to a force F, called Laplace force, which propels the plasma column between the conductive strips (8). It follows that, at a certain moment the plasma column is divided into n + 1 sections, which means that the voltage across each section is worth substantially
Uo
n +1
If n is high enough, the voltage across each section becomes low enough so that the arc is no longer maintained, as shown by the arc characteristic given in Figure 3. The condition for breaking the current is therefore
Uo
n +1
Ut depends on the metal used to make the contacts. It is of the order of ten volts, which shows that to cut 220 volts for example, it will be necessary to use about twenty fractionation blades.

The plasma column CP is set in motion at a certain speed v, under the action of Laplace forces which occur each time a current I is subjected to a non-collinear magnetic field B. Field B is created here by the current I flowing in the loop (5), CP, (6). In some cases, the system can be improved by applying an additional magnetic field, for example using a permanent magnet. In other cases, a simple soft iron plate is used which disymmetrizes the field prevailing around the column.
CP, which accentuates Laplace's strength. The opening is carried out for example by means of a coil (9) which attracts an attractive plunger core (10), the flexible blade (6) carrying the contact C2. In other cases, the movement of (6) will take place under.

the effect of a bahdé spring that we release when we want the disjunction.

This principle has, as we have already said, many disadvantages
- the cut-off is not fast, which is very harmful for safety and leads
significant wear of the contacts,
- plasma erodes plastic boxes, which causes fumes
often toxic
- the strong overpressure which manifests itself at the time of cutting requires
the use of enclosures with vents which makes them dangerous in
atmospheres where there is a risk of explosion,
- the bulk is generally quite large.

In the invention, the arc is split directly at the source as shown schematically in FIG. 4. It is easily understood that if, instead of opening a single contact, many contacts C1 are opened simultaneously, C2, .... Cn, connected in series with the load RL, the plasma columns which will appear in each contact at the time of its opening under the known phenomenon of "molten bridge", will naturally be placed in series. This means that the arc has been split without having to be transported to a louvre extinguisher. It is therefore understandable that the opening can be much faster than in conventional systems. It is possible, for example, to obtain opening times of less than 1 ms.

To prevent the contact series Ci, C2, .... Cn from having too much resistance during normal operation of the circuit breaker (which is therefore in the closed position), we place in parallel with the contact series Ci, C2 .... Cn, a power contact Co, as shown diagrammatically in FIG. 5. Thus during the whole time when the circuit breaker is in the service position (that is to say closed contact) most of the current flows through the contact Co which is much less resistive than the derivation C1 Cn.

As soon as an overcurrent or any other cause causing the disjunction occurs, a suitable mechanical system causes the opening of all the contacts. The opening mechanism, such as that shown by way of example in FIG. 6, acts by first opening Co. We then have phenomena which take place in the following chronology
- the current passing through Co is limited to a few points which heat up quickly causing "fused bridges" which explode thus filling the space between the CO contacts with a partially ionized metallic gas. The voltage across the contact is then equal to the product of resistance R1, R2, .... Rn of the n contacts in series by the current 1 of disjunction, which can be weak enough so that an arc can neither be established, nor even be maintained in the metallic vapor -3 from the "melted bridge". For example, with 20 contacts of 10 n and a current of 1000 A the voltage is 20 volts,
- a few milliseconds after the opening of Co, the contacts C1, C2, ... Cn will open almost simultaneously. At this time, all traces of ions in the metallic vapor have disappeared and the latter has partially condensed on the contacts. The voltage can therefore go up to the terminals of Co without an arc appearing. In each contact Cl, C2, ... Cn the phenomenon of "molten bridge" is manifested but the voltage across each is limited to Uo / n ce which may not be enough to strike an arc. There is then extinction of the current which was the aim sought.

According to a first embodiment, shown diagrammatically in FIG. 6, the opening of the contacts is done by means of pushers (3) and (4), supported by a bar (2), which can be insulating, which bar is set in motion by a mechanism (1), which can either be a banded spring released at the time of tripping by an electromagnetic or electrothermal device, or a coil with a plunger core. FIG. 6 represents the system at the time when the contacts Ci, C2. .. They will open. To arm the system, simply apply force F.

According to a second embodiment, also given by way of indication and of course in no way limiting, the device adopts the arrangement of FIG. 7. A sealed shell of injected plastic (11) is closed by an elastomeric membrane (18).

It contains
- a magnetic circuit made of high permeability material (13) comprising a permanent polarization magnet (14). The circuit is closed by a movable armature (32) and includes a coil (12). To arm the circuit breaker, simply press the rod forming a button (17), the coil (12) not being supplied, until the movable armature (32) sticks to the magnetic circuit (13 ), (14), by compressing the springs (22) (see FIG. 10) which exert an opposing force.

A printed circuit crown (15) is fixed around the magnetic circuit (13).

It comprises conductive tracks (20) as shown in left view in FIG. 8, as well as rods (21), riveted or welded on the periphery.

A movable plate (16) can slide on the rods (21) so as to compress the spring (22) shown in the figure (10). This plate includes spring blades (19), capable of coming to bear on the tracks (20) as shown diagrammatically in FIG. 10, thus making the contacts Cl, C2, ... Cn. One of the tabs is different from the others; it makes it possible to make the Co contact. The curvature is less important than the others, which causes the Co contact to come off earlier than the others.

In the case shown in Figures 7, 8, and 9 there are 14 contacts in series.

According to a last embodiment shown diagrammatically in FIG. 12 in exploded view, the switching is no longer carried out by a translational movement as previously but by a rotational movement of the plates (24) and (25) which respectively carry the contacts (26) and (27).

By applying a force F to the end of the armature (28) which is integral with the movable disc (25), a rotation is caused which causes said armature (28) to close the magnetic circuit (30) which is fixed. This one is of a conception analogous to what has been seen above; a permanent magnet keeps the magnetic circuit closed despite the opposing force exerted by the spring (31). The disjunction will be obtained by applying a pulse on the coil (29), canceling the magnetic attraction, which causes a rotation a in the opposite direction.

Another disc (24) is applied to the movable disc (25), fixes this one, with a suitable pressure so that the metallized parts of these two discs make good contact.

FIG. 12 c represents a section of the contact line, in an unrolled view in order to better understand the mechanism and the chronology of the contacts.

The figure shows the position of the movable disc (25) when the contacts C1, C2 Cn will open.

 We can see that the supply and the departure of the current on the circuit breaker which is carried out by the wires (23), arrive on two plates (26) which were previously short-circuited by another opposite plate (27), belonging to the movable disc. (25) thus realizing the contact Co. The other contacts were also closed in a similar manner, thus realizing a chain of contacts C1, C2, .... Cn which comes to be bypassed on the contact Co according to the principle already mentioned of the invention.

The invention can be used as a safety circuit breaker, in homes, workshops, stores, etc. It can also be used as a relay in all cases where it is desired to cut a direct current, avoid interference, make a quick cut.

Claims (6)

 1. Arc extinguishing circuit breaker by fractionation characterized in that it comprises a certain amount of mechanical contacts Cl, C2, .... Cn, arranged in series in the electrical circuit to be cut, said contacts Cl, C2 ,. ... Cn being in sufficient number for the extinction of the arc to occur.  2. Device according to claim 1, characterized in that it comprises an additional mechanical contact Co, placed in parallel on the series of contacts Cl, C2 ... Cn, said contact Co being animated by suitable means (1), (2), (3), (4), (15), (16), (24), (25) .. .for its opening to occur slightly before that of the series of contacts Cl, C2, .... Cn.  3. Device according to claim 1 or 2, characterized in that the means used to open the contacts Co, Ci, C2 .... Cn, consist of a part (2) set in motion by suitable means ( 1) and comprising fingers (3) and (4) for pushing said contacts.  4. Device according to claim 1 or 2, characterized in that the means used to open the contacts Co, C1, C2, .... Cn, are constituted by  - a fixed plate (15) comprising metal contacts according to a drawing  suitable,  - a movable plate (16) driven by a translational movement, comprising  also contacts which can advantageously be constituted by  flexible strips,  - guide means (21),  - means (12), (13), (14), (22), (32) enabling the  movement of the movable plate (16) at the time of separation. 5. Device according to claims 1 or 2, characterized in that the means used to open the contacts Co, C1, C2 Cn are constituted by  - a fixed circular plate (24) comprising metal surfaces (26), suitable for ensuring good electrical contact,  a mobile circular plate (25), substantially coaxial with (24), capable of oscillating around its axis by a certain angle a, comprising metal contacts (27), similar to (26),  - Means (28), (29), (30), (31) allowing the movable plate (25) to move in rotation.  6. Device according to claims 3, 4 or 5, characterized in that the means allowing the setting in motion of the contacts at the time of the disjunction consist of a magnetic circuit made of soft ferromagnetic material (30) comprising a part consisting of a permanent magnet (14), a movable armature (32) and a trip coil (12).