FR2829869A1 - Electrical relay/contact switch/circuit breaker having switching contact with magnetic reinforcement circuit and magnetic compensation circuit opposition moving support mounted. - Google Patents

Abstract

The electrical switch contact forms a switching contact between a fixed contact (30) and a conductor contact (10) moving from a closed to open position. The switching mechanism has a magnetic reinforcement circuit (26) which cooperates with the moving arm, and a magnetic compensation circuit (25) cooperating with a fixed conductor (31). The magnetic reinforcement and compensation are mounted in opposition on the moving support (20).

Description

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 The present invention relates to an electrical switch device, in particular of the relay, contactor, circuit breaker or contactor / circuit breaker type, comprising at least one magnetic device intended to reinforce the contact pressure between movable contacts and fixed contacts, up to a threshold of determined electric current.

 When a large electric current is likely to flow between a fixed contact and a movable contact in a pole of a switching device, it is known to want to reinforce the pressure exerted on these contacts, to minimize any risk of soldering of the contacts . This reinforcement of contact pressure is essential in particular when the current flowing between the fixed and movable contacts has a value much greater than the nominal current of the device, for example during a fault current. It is indeed necessary to oppose the repulsion force between the contacts, this repulsion force being proportional to the square of the electric current. For that, a usual solution consists in increasing the size of the contact pressure spring so as to dimension it to guarantee a good contact during the circulation not of the nominal current but of the maximum authorized current. However, this solution results in an increase in the size of the electromagnet for controlling the mobile contact, which overall results in an increase in the size of the device, its electrical consumption and its cost.

 Furthermore, the document FR2793090 describes a magnetic circuit intended to increase the pressure between fixed and mobile contacts in an electrical appliance, as the current passing through these contacts increases. This magnetic circuit comprises a first U-shaped element secured to one of the contacts and a second pallet-shaped element secured to the other contact, these elements being made of ferromagnetic material and being positioned in such a way that the passage of an electric current in the contacts creates a resulting magnetic compensation flux. This magnetic flux generates an additional electromagnetic force which increases the pressure of the contacts as the current increases.

Thus, without increasing the size of the contact control electromagnet, it is possible to maintain a satisfactory contact pressure, even for current values a few tens of times greater than the value of the nominal current of the device, during '' an engine start in particular.

 Such a magnetic circuit causes an increase in the contact pressure as the intensity of the electric current increases. However, it becomes more and more difficult to be able to separate the fixed and mobile contacts of a device.

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 light switch. The opening of the contacts can only be ensured by a protective device (of the fuse or circuit breaker type, for example) which, when triggered, will make it possible to drop the current passing through the contacts and therefore cancel the magnetic flux reinforcing the pressure of contact. It will then be easy to open the contacts by the control solenoid.

 This is why it would be particularly advantageous to benefit from the advantages linked to the use of a magnetic circuit making it possible to reinforce the contact pressure up to a certain predetermined switching threshold of the electric current, but for this effect to be canceled. beyond this threshold, so as to easily open the contacts when the current exceeds the tilting threshold. We would then obtain an electrical device capable of withstanding significant intensities of current (during engine starting in particular) thanks to a simple magnetic circuit, but also capable of tripping in the event of the appearance of a current intensity exceeding a threshold of tipping (for example, for a short-circuit current).

 For this, the invention describes an electrical switch device comprising at least one contact switching device between at least one fixed contact and a contact conducting arm which is movable between a closed position and an open position. The switching device comprises a magnetic reinforcement circuit cooperating with the movable contact arm and a magnetic compensation circuit cooperating with at least one fixed conductor of the switching device, the magnetic reinforcement circuit and the magnetic compensation circuit being mounted in opposition on a mobile support.

 According to one characteristic, the magnetic compensation circuit comprises an element made of ferromagnetic material of U-shaped cross section fixed to the movable support and surrounding a fixed conductor. In another embodiment, the magnetic compensation circuit comprises two elements of ferromagnetic material of U-shaped section fixed to the movable support and respectively surrounding an upstream fixed conductor and a downstream fixed conductor. During the passage of an electric current in the fixed conductor (s), a magnetic compensation flux circulates in the magnetic compensation circuit creating a compensation force in the mobile support.

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 According to another characteristic, the magnetic reinforcement circuit comprises an element of ferromagnetic material of U-shaped cross section secured to the movable support and surrounding the movable contact arm, as well as a pallet of ferromagnetic material secured to the movable contact arm. During the passage of an electric current in the mobile arm, a magnetic reinforcement flux circulates in the magnetic reinforcement circuit creating a force of attraction of the mobile support against the mobile contact arm.

 Below a determined tilting threshold of the electric current flowing in the movable contact arm, the attraction force is greater than the compensation force. Beyond the switching threshold of the electric current flowing in the movable arm, the attraction force is less than the compensation force.

 Other characteristics and advantages will appear in the detailed description which follows with reference to an embodiment given by way of example and represented by the appended drawings in which: - Figure 1 shows a first embodiment of the invention with a contact pole comprising a fixed contact and a movable contact, in the rest position, - Figure 2 uses the example of Figure 1 in the working position, with an electric current below a tilting threshold, - Figure 3 takes again the example of figure 1 in working position, with an electric current at the limit of the tilting threshold, - figure 4 represents a sectional view of a compensation circuit in a device according to figure 1, - the figures 5a and 5b detail sectional views of two variants of a reinforcement circuit, in a device according to Figure 1, - Figure 6 shows a second embodiment of the invention with a pole contact comprising two fixed contacts and two movable contacts, in the rest position, - Figure 7 uses the example of Figure 6 in the working position, with an electric current below a tilting threshold, - Figure 8 uses the example of FIG. 6 in the working position, with an electric current at the limit of the tilting threshold,

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 FIGS. 9, respectively 10, detail a sectional view of a compensation circuit, respectively of a reinforcement circuit, in a device according to FIG. 6, FIG. 11 shows schematically the simplified evolution of the forces of attraction and of compensation according to the intensity of the electric current.

 With reference to the first embodiment shown in FIGS. 1, 2 and 3, a single-pole or multi-pole electrical switch device comprises, on at least one contact pole, a device for switching contacts between a fixed contact 30 and a conductive arm of contact 10 mobile in rotation to open and close the contacts. The fixed contact 30 has a contact pad placed opposite another contact pad located at one end of the movable contact conductive arm 10. FIG. 1 shows the switching device in the rest position (c (i.e. fixed contact and dissociated mobile contact: open electrical circuit) and Figures 2 and 3 show the same switching device in working position (i.e. fixed contact and movable contact under pressure: electrical circuit closed). The switching device comprises a magnetic reinforcement circuit 26 and a magnetic compensation circuit 25 which are respectively placed in the vicinity of each opposite end of a mobile support 20. The support 20 is mobile in rotation around an axis of rotation 28 passing approximately through the center of the movable support 20 and perpendicular to a direction passing through the two magnetic circuits 25,26. Thus, the two magnetic circuits 25, 26 are mounted in opposition. Preferably, the axis of rotation of the mobile arm 10 is located at the opposite end of the contact pad and merges with the axis of rotation 28 of the support 20. At this axis of rotation, the mobile arm 10 is furthermore electrically connected with a fixed conductor 31 of the switch device.

 In a conventional manner in a relay device of the relay, contactor or contactor / circuit breaker type, the opening and closing of the contacts (movements between the work and rest positions) are carried out by a control member, such as a strip 40, controlled by a control electromagnet eVou a rapid opening mechanism not shown in the figures, and which acts on the movable arm 10. The contact pressure is then obtained by a contact pressure spring 41 placed between the strip 40 and the arm mobile 10.

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 The magnetic compensation circuit 25 cooperates with the fixed conductor 31 in the following manner: with reference to FIG. 4, the magnetic compensation circuit 25 comprises an element 22 of ferromagnetic material of U-shaped section fixed to the mobile support 20 and surrounding the fixed conductor 31. When an electric current crosses the conductor 31, this creates a magnetic compensating flux which circulates in the element 22 and the conductor 31. This magnetic compensating flux generates an electromagnetic compensating force F2 which has a tendency, as shown in FIG. 2, bring the base of the U-shaped element 22 closer to the fixed conductor 31.

 The magnetic reinforcement circuit 26 cooperates with the movable contact arm 10 in the following manner: with reference to a first variant shown in FIG. 5a, the magnetic reinforcement circuit 26a comprises an element 23a made of ferromagnetic material of U-shaped section , fixed to the movable support 20 and surrounding the movable contact arm 10. The magnetic reinforcement circuit 26a also comprises a pallet 11 a made of ferromagnetic material, of substantially rectangular section secured to the movable contact arm 10. The width of the section of the pallet 11a is practically equal to the width of the U-shaped section of element 23a. Two air gaps 18,19 made of non-magnetic material are positioned between the pallet 11a and the two ends of the U-shaped element 23a of the magnetic reinforcement circuit 26a.

 When an electric current crosses the movable contact arm 10, a magnetic reinforcing flux is created which circulates in the element 23a, the air gaps 18, 19 and the pallet 11 a. This magnetic reinforcing flux generates an electromagnetic force of attraction F3 which tends, as indicated in FIG. 2, to press the pallet 11a against the U-shaped ends of the element 23a.

 In a second variant shown diagrammatically in FIG. 5b, the locations of the pallet and of the U-shaped element can be reversed. In this case, the magnetic reinforcement circuit 26b comprises a pallet 23b of ferromagnetic material fixed to the mobile support 20 and an element 11b of ferromagnetic material of U-shaped section secured to the mobile contact arm 10. Two air gaps 18.19 in non-magnetic material are located between the pallet 23b and the two ends of the U-shaped element 11b. This second variant improves the operation when the electrical circuit is opened: in fact, in this case, like the movable conductive arm 10 is integral with the U-shaped element 11 b, it is not magnetically retained in the central recess of the U-shaped element 23a as in the first variant of FIG. 5a.

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 According to an important characteristic of the invention, the magnetic reinforcement circuit 26 always includes a pallet which closes the path of the magnetic reinforcement flux on the air gaps, while the magnetic compensation circuit 25 does not include such a pallet. This has the consequence that the magnetic reinforcement flux will initially be greater than the compensating magnetic flux when the electric current passing through the fixed conductor 31 and the movable contact bridge 10 is of low value. However, as this electric current increases, the magnetic flux of reinforcement will reach saturation due to the presence of this pallet and the dimensioning of the magnetic circuit of reinforcement, contrary to the magnetic flux of compensation which will continue to grow, so that for a determined value of a tilting threshold Is of the electric current, the magnetic compensation flux will become greater than the magnetic reinforcement flux. This characteristic is shown diagrammatically in FIG. 11 which briefly shows the evolution of the forces F2 and F3 as a function of the current. We see that the attraction force F3 is initially higher than the compensation force F2, as long as the current is lower than the tilting threshold Is. Beyond this, the saturation of the magnetic reinforcement circuit makes that the force of compensation F2 becomes greater than the force of attraction F3.

The operation of the first embodiment of the invention will now be detailed:
During the rest position, the contacts are kept separate by the strip 40. The pallet 11 and the U-shaped element 23 of the magnetic reinforcement circuit 26 are separated. The support 20 is held in an initial position by a return spring 29 of low value placed between the support 20 and a fixed part of the electrical appliance, for example the carcass of the appliance, creating a return force F4. In this initial position, the support 20 may advantageously have, thanks to the return spring 29, a slight inclination having the effect of reducing the distance between the pallet 11 and the U-shaped element 23, which will allow the magnetic reinforcement circuit 26 to close before the current flow is established in the working position.

 When the electromagnet for controlling the switching device controls the slide 40 to switch to the working position, the mobile arm 10 is pressed against the fixed contact 30 with a pressure force Fp exerted by the contact pressure spring 41 on the arm mobile 10. An electric current In can then pass through the fixed conductor 31, the mobile contact arm 10 and the fixed contact 30. As

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 shown diagrammatically in FIG. 2, the current In creates a magnetic compensation flux in the magnetic compensation circuit 25, generating a compensation force F2. The current In also creates a magnetic reinforcement flux in the magnetic reinforcement circuit 26, generating an attraction force F3. The current In finally creates a repulsion force Fr between the pads of the fixed and movable contacts.

 The attraction force F3 tends to press the pallet 11 against the U-shaped element 23 of the magnetic reinforcement circuit 26 while the compensating force F2 is in opposition and tends to separate the pallet 11 from the element 23.

As long as the current In is less than the tilting threshold Is described above, the attraction force F3 is greater than the compensation force F2. Consequently, the pallet 11 is kept pressed against the element 23. The compensating force F2 then indirectly contributes to reinforcing the contact pressure because, as F2 tends to spread the U-shaped element 23 away from the pallet 11, the force F3 is applied to the pallet 11 to hold the latter against the element 23, and therefore applies to the mobile arm 10, thus notably increasing the pressure of the mobile contact arm 10 on the fixed contact 30.

 As the electric current ln increases, the repulsion force Fr will increase as a function of the square of the current and will become greater than the pressure force Fp. However, as long as F3 is greater than F2, the switching device of the invention will have the effect of reinforcing the contact pressure and therefore will be added to the pressure force Fp to oppose the repulsion force Fr.

 The moment when the current In reaches the tilting threshold value Is is represented in FIG. 3. When the electric current In passing through the contacts reaches this switching threshold Is, the magnetic compensation flux becomes greater than the magnetic reinforcement flux, as indicated previously. This implies that the force F2 becomes greater than the force F3. A tilting movement then occurs on the support 20 which has the effect on the one hand of bringing the base of the U-shaped element 22 of the magnetic compensation circuit 25 towards the fixed conductor 31, under the effect of the force F2 , and on the other hand to separate the pallet 11 and the U-shaped element 23 from the magnetic reinforcement circuit 26. This separation will cause a very strong reduction in the force F3, since the magnetic reinforcement circuit 26 will no longer be closed. Consequently, only the pressing force Fp will exert pressure on the contacts. As this force is less than the repulsion force Fr, the contacts will open faster than in a conventional device because the pressure force Fp is weaker than that which would have been necessary in a device without

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 magnetic reinforcement circuit. The opening of the contacts must be confirmed by usual means (lock, striker, ...) acting on the strip 40.

 In a second embodiment shown in FIGS. 6,7 and 8, each contact pole of a single-pole or multi-pole switch electrical appliance has a device for switching contacts between two fixed contacts and two movable contacts. The switching device comprises a first fixed conductor 31 ', called for example upstream fixed conductor 31', provided with a contact pad at one end and a second fixed conductor 30 ', called downstream fixed conductor 30', also having a pad contact at one end. The switching device comprises a conductive contact arm 10 ′ movable in translation to open and close the contacts and provided at each end with a contact pad located respectively opposite a contact pad of the fixed conductors 30 ', 31'. FIG. 6 shows such a switching device in the rest position (that is to say fixed contacts and dissociated movable contacts: open electrical circuit) and FIGS. 7 and 8 show the same switching device in the working position (that is to say fixed contacts and moving contacts under pressure: closed electrical circuit). The switching device also includes a magnetic reinforcement circuit 26 ′ and a magnetic compensation circuit 25 ′ which are positioned on a mobile support 20 ′ common to the two circuits. The support 20 is movable in translation in the same direction as the movement of the contact arm 10 '. According to the embodiment presented, the support 20 ′ comprises a central branch and two lateral branches. The central branch of the support 20 'supports the magnetic reinforcement circuit 26' and the side branches support the two parts of the magnetic compensation circuit 25 '.

 Conventionally, the opening and closing of the contacts (movements between the working and rest positions) are carried out for example by a control member (for example a strip) not shown in the figures, controlled by a control electromagnet and / or a rapid opening mechanism, and acting on the movable arm 10 '. The contact pressure is then obtained by a contact pressure spring 41 'placed between this control member and the movable arm 10'.

 The magnetic compensation circuit 25 is made up of two similar parts situated at the ends of each lateral branch of the support 20 '. The first part cooperates with the upstream fixed conductor 31 ′ and the second part cooperates with the downstream fixed conductor 30 ′ in the following manner: with reference to the figure

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 9, each part of the magnetic compensation circuit 25 'consists of an element 21', respectively 22 ', of ferromagnetic material of U-shaped section fixed to the movable support 20' and surrounding the upstream fixed conductor 31 ', respectively downstream 30'. When an electric current crosses the fixed conductor 31 ', respectively 30', this creates a magnetic compensation flux which circulates in the element 21 ', respectively 22', and the conductor 31 ', respectively 30'. This magnetic compensating flux generates an electromagnetic compensating force, formed of two components F1 ', respectively F2', this force tending, as indicated in FIG. 7, to bring the base of the element 21 ', respectively 22', in U shape towards the fixed conductor 31 ', respectively 30'.

 The magnetic reinforcement circuit 26 'co-operates with the movable contact arm 10' in the following manner: with reference to FIG. 10, the magnetic reinforcement circuit 26 'comprises an element 23' made of ferromagnetic material of U-shaped cross section, fixed to the mobile support 20 ′ and surrounding the mobile contact arm 10 ′. The magnetic reinforcement circuit 26 ′ also includes a pallet 11 ′ made of ferromagnetic material, of substantially rectangular section secured to the movable contact arm 10 ′. The width of the section of the pallet 11 is practically equal to the width of the U-shaped section of the element 23 '. Two air gaps 18 ', 19' made of non-magnetic material are positioned between the pallet 11 'and the two ends of the U-shaped element 23' of the magnetic reinforcement circuit 26 '.

 When an electric current flows through the movable contact arm 10 ', a magnetic reinforcing flux is created which circulates in the element 23', the air gaps 18 ', 19' and the pallet 11 '. This magnetic reinforcing flux generates an electromagnetic force of attraction F3 ′ which tends, as indicated in FIG. 7, to press the pallet 11 ′ against the U-shaped ends of the element 23 ′.

 In an equivalent variant, not shown diagrammatically, the locations of the pallet 11 ′ and of the U-shaped element 23 ′ can be reversed. This variant incorporates the characteristics and advantages of that shown diagrammatically in FIG. 5b. In this case, the magnetic reinforcement circuit 26 ′ comprises a pallet of ferromagnetic material fixed to the mobile support 20 ′ and an element of ferromagnetic material of U-shaped cross section secured to the mobile contact arm 10 ′. Two nonmagnetic material air gaps are located between the pallet and the two ends of the U-shaped element.

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 In the same way as in the first embodiment, the magnetic reinforcement circuit 26 ′ always includes a pallet which closes the path of the magnetic reinforcement flux over the air gaps, while the two parts of the magnetic compensation circuit 25 ′ do not include such pallets. This has the consequence that the magnetic reinforcement flux will initially be greater than the compensating magnetic flux when the electric current passing through the fixed conductors 31 ′, 30 ′ and the movable contact bridge 10 ′ will be of low value. However, as this electric current increases, the magnetic flux of reinforcement will reach saturation due to the presence of this pallet and the dimensioning of this magnetic circuit of reinforcement, contrary to the magnetic flux of compensation which will continue to grow, in such a way that for a determined value of tilting threshold Is of the electric current, the magnetic flux of compensation will become greater than the magnetic flux of reinforcement.

The operation of the second embodiment of the invention will now be detailed:
During the rest position, the contacts are kept separate by a non-diagrammatic control member. The pallet 1 ′ and the U-shaped element 23 ′ of the magnetic reinforcement circuit 26 ′ are separated. The support 20 is held in an initial position by a return spring 29 ′ of low value placed between the support 20 ′ and a fixed part of the electrical appliance, for example the carcass of the appliance, creating a return force F4. In the initial position, the fixed conductors 31 ', respectively 30' are engaged at least partially in the U-shape of the elements 22 ', respectively 21', of the magnetic compensation circuit 25 '.

 When the electromagnet of control of the switching device actuates the control member to pass into working position, the movable arm 10 is pressed against the fixed contacts of the conductors 31 ′ and 30 ′ with a pressure force Fp ′ exerted by the contact pressure spring 41 'on the movable arm 10'. An electric current n can then pass through the upstream fixed conductor 31 ', the movable contact arm 10' and the downstream fixed conductor 30 '. As shown diagrammatically in FIG. 7, the current ln creates a magnetic compensation flux in the magnetic compensation circuit 25 ', generating the compensation force F1', F2 '. The current In also creates a magnetic reinforcement flux in the magnetic reinforcement circuit 26 ', generating an attraction force F3'. The current n finally creates a repulsive force Fr 'between the pads of the fixed and movable contacts.

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 The attraction force F3 tends to press the pallet 11 'against the U-shaped element 23' of the magnetic reinforcement circuit 26 'while the compensating force F1', F2 'is in opposition and tends to separate the pallet 11 'of element 23'. As long as n is less than the tilting threshold Is described above, the attraction force F3 is greater than the sum of the two components F1 ', F2' of the compensation force. Consequently, the pallet 11 is kept pressed against the element 23 '. The compensating force F1 ′, F2 ′ then indirectly contributes to reinforcing the contact pressure because, as this force tends to spread the U-shaped element 23 ′ from the pallet 11 ′, the force F3 ′ applies to the pallet 11 ′ to maintain the latter against the element 23 ′, and therefore applies to the mobile arm 10 ′, thus notably increasing the pressure of the mobile contact arm 10 ′ on the contacts of the fixed conductors 31 ′ and 30 ′.

 As the electric current in will increase, the repulsion force Fr 'will increase as a function of the square of the current and will become greater than the pressure force Fp'. However, as long as the attraction force F3 'is greater than the sum of the two components F1', F2 'of the compensation force, the switching device of the invention will have the effect of increasing the contact pressure and therefore s 'will add to the pressure force Fp' to oppose the repulsion force Fr '.

 The moment when the current n reaches the tilting threshold value Is is represented in FIG. 8. When the electric current In passing through the contacts reaches this tilting threshold Is, the magnetic compensation flux becomes greater than the magnetic reinforcement flux, as indicated previously. This implies that the sum of the two components F1 ', F2' of the compensation force becomes greater than the attraction force F3 '. A translational movement then takes place on the mobile support 20 ′ which has the effect, on the one hand, of bringing the base of the elements 22 ′, respectively 21 ′, in U of the magnetic compensation circuit 25 ′ towards the fixed conductors 31 ′, respectively 30 ', and on the other hand to separate the pallet 11' and the U-shaped element 23 'from the magnetic reinforcement circuit 26'. This separation will lead to a very strong decrease in the force F3 ', since the magnetic reinforcement circuit 26'will no longer be closed. Consequently, only the pressing force Fp 'will exert pressure on the contacts. As this force is less than the repulsion force Fr ', the contacts will open faster than in a conventional device because the pressure force Fp is weaker than that which would have been necessary in a device without a magnetic circuit reinforcement. The opening of the contacts must be confirmed by usual means (lock, striker, ...).

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 Thus, thanks to this switching device, an electrical switching device according to the invention will have the advantage, in contactor mode, of having a lower contact pressure spring and therefore of requiring a smaller control electromagnet. and, in circuit breaker mode, to be able to open the contacts more quickly due to the lower contact pressure spring.

 It is understood that one can, without departing from the scope of the invention, imagine other variants and improvements of detail and even consider the use of equivalent means.

Claims (11)

1. Electrical switch device comprising at least one contact switching device between at least one fixed contact (30,30 ', 31') and a conductive contact arm (10,10 ') which is movable between a closed position and a open position, characterized in that the switching device comprises a magnetic reinforcement circuit (26,26 ') cooperating with the movable contact arm (10,10') and a magnetic compensation circuit (25,25 ') cooperating with at least one fixed conductor (31.30 ', 31') of the switching device, the magnetic reinforcement circuit (26.26 ') and the magnetic compensation circuit (25.25') being mounted in opposition on a support mobile (20,20 ').  2. An electrical switch device according to claim 1, characterized in that the magnetic compensation circuit (25) comprises an element (22) of ferromagnetic material of U-shaped cross section fixed to the mobile support (20) and surrounding a fixed conductor ( 31).  3. An electrical switch device according to claim 1, characterized in that the magnetic compensation circuit (25 ') comprises two elements (21', 22 ') of ferromagnetic material of U-shaped section fixed to the movable support (20') and respectively surrounding an upstream fixed conductor (31 ') and a downstream fixed conductor (30').  4. Electrical switch device according to claim 2 or 3, characterized in that, during the passage of an electric current in the fixed conductor (s) (31,30 ', 31'), a magnetic compensating flux circulates in the circuit magnetic compensation (25.25 ') creating a compensation force (F2, F1', F2 ') in the mobile support (20.20').  5. An electrical switch device according to claim 1, characterized in that the magnetic reinforcement circuit (26,26 ') comprises an element (23,23') made of ferromagnetic material of U-shaped cross section secured to the movable support (20, 20 ') and surrounding the movable contact arm (10,10'), as well as a pallet (11, 11 ') made of ferromagnetic material secured to the movable contact arm (10,10'). <Desc / Clms Page number 14>  6. Electrical switch device according to claim 1, characterized in that the magnetic reinforcement circuit (26,26 ') comprises a pallet (11, 11') made of ferromagnetic material secured to the movable support (20,20 ') as well as an element (23,23 ') of ferromagnetic material of U-shaped section surrounding the movable contact arm (10,10') and integral with the movable contact arm (10,10 ').  7. An electrical switch device according to claim 5 or 6, characterized in that the magnetic reinforcement circuit (26,26 ') comprises two air gaps (18,19, 18', 19 ') made of non-magnetic material between the pallet (11, 11 ') and the ends of the U-shaped element (23,23') of the magnetic reinforcement circuit.  8. An electrical switch device according to claim 5 or 6, characterized in that, during the passage of an electric current through the movable contact arm (10, 10 '), a magnetic reinforcement flux circulates in the magnetic reinforcement circuit. (26, 26 ') creating an attractive force (F3, F3') of the mobile support (20,20 ') against the mobile contact arm (10,10').  9. Electrical switch device according to claim 1, characterized in that it comprises a return spring (29,29 ') of the mobile support (20,20') in the open position, positioned between the mobile support (20,20 ' ) and a fixed part of the electrical appliance.  10. Electric switch device according to claim 4 or 8, characterized in that, below a tilting threshold (is) of the electric current flowing in the movable contact arm (10, 10 '), the force of attraction (F3, F3 ') is greater than the compensation force (F2, F1', F2 ').  11. Electric switch device according to claim 10, characterized in that, beyond the tilting threshold (Is) of the electric current flowing in the movable contact arm (10, 10 ′), the force of attraction (F3, F3 ') is less than the compensation force (F2, F1', F2 ').