EP0143022A1 - Thermal and magnetic circuit breaker tripping mechanism - Google Patents

Abstract

1. A thermal and magnetic tripping mechanism cooperating with the actuating mechanism of a multipole circuit breaker and comprising per pole a first electromagnetic tripping mechanism (38) and a second thermal tripping mechanism with a bimetal strip (36), said first tripping mechanism comprising a magnetic circuit with an air gap through which the induction flux generated by an operating coil flows, and a movable armature (50) capable of being attracted against a polar surface of the magnetic circuit when the current intensity flowing in the coil (42) exceeds a preset threshold causing tripping of the mechanism, said coil comprising one or more turns according to the tripping characteristics, a flexible connecting conductor (62) being securedly united directly by one of its ends to a movable contact arm (23) of the pole, to provide the electrical connection with the coil (42), characterized in that the other end of the flexible conductor (62) is connected by soldering to the bimetal strip (36), and that the intermediate part of the same flexible conductor constitutes the winding of the coil (42), the assembly being arranged to ensure fixed mounting of the electromagnetic tripping mechanism (38) fitted between the contact arm (23) and the thermal tripping mechanism with bimetal strip (36).

Description

The invention relates to a thermomagnetic trip device cooperating with the actuation mechanism of a multipole circuit breaker and comprising by pole a first electromagnetic trip device and a second bi-blade thermal trip device, said first trip device comprising a magnetic circuit with an air gap traversed by the flux induction generated by a control coil, and a movable armature capable of being attracted against a polar surface of the magnetic circuit When the intensity of the current flowing in the coil exceeds a predetermined threshold causing the triggering of the mechanism, Said control coil being formed by the winding of a flexible connection conductor. The setting of the instantaneous tripping threshold of the electromagnetic trip unit generally takes place in the factory by varying the number of turns of the control coil. Figures 7 to 9 of US Patent No. 3,104,297 respectively show coils with three, one and two turns, each coil being constituted by a rigid conductor, in particular enameled wire or a strip, wound on a fixed magnetic core. Each coil has a predetermined instantaneous trip threshold value for protection against short-circuit currents. The presence of these different types of coils complicates the manufacture of the trigger. Welding the ends of the coil to auxiliary conductors or connectors is essential for placing the coil in series with the bimetallic strip and the movable contact of the corresponding pole.

According to another known device (French patent 1,529,259) The trigger threshold of the electromagnetic trigger can be adjusted by the user by varying the air gap formed between the movable armature and the fixed magnetic circuit. The air gap adjustment device is common to all the poles of the circuit breaker, each movable armature being connected by a mechanical connection to a rotary adjustment bar whose anguluire position is determined by a manual adjustment member.

This device is bulky and expensive and is generally used for large-size circuit breakers. The magnetic circuit of the electromagnetic trip device comprises a ferromagnetic stirrup crossed by a rigid rectiligear conductor, in particular a strip, in which the current of the pole circulates.

According to US Patent No. 2,659,783, The conductor passing through The U-shaped magnetic stirrup of the electromagnetic trip device is formed by the braid connecting the moving contact and the bimetallic strip. The trigger threshold is fixed, and the braid extends in a rectilinear direction inside the U-shaped stirrup. The magnetic field generated by a conductive TEL is weak, and the attraction of the movable armature does not intervenes only for high short-circuit currents.

It has already been proposed in US Patent No. 3,189,707 to form the excitation coil of the electromagnetic trip device by means of a flexible conductor, in particular a braid, wound on an insulating support. The coil is nevertheless fixed directly to a part of the moving assembly, and one of the ends of the flexible conductor is welded to the bimetallic strip, LequeL is subject to the movable contact arm. The other end is connected to a fixed terminal. As a result, the bimetallic strip and the electromagnetic trip unit move with the moving equipment.

The object of the invention is to remedy these drawbacks and to allow the production of a highly sensitive magnetothermal trip device allowing simplified factory setting of the instantaneous trip threshold, and good electrodynamic behavior of the bimetallic trip device.

The trip device according to the invention is characterized by the fact that one of the ends of the flexible connection conductor is secured directly to a movable contact arm of the pin, and that the other end of the conductor is connected by bimetallic welding, allowing fixed mounting of the trigger electromagnetic heat exchanger arranged between the contact arm and the bimetal thermal trip device, the coil comprising one or more turns of said flexible conductor as a function of the tripping characteristics.

The setting of the instantaneous tripping threshold of the electromagnetic trip unit takes place During the factory mounting of the circuit breaker by choosing The number of turns of the flexible conductor for The constitution of the control coil. The flexible conductor can be a copper braid, bare or coated with a coaxial sheath of insulating material. No interruption of the flexible conductor is necessary at the level of the electromagnetic trip device. In the case of an insulated braid, the latter is wound directly on the fixed core. The use of a bare braid requires the presence of an insulating carcass on the core.

According to a characteristic of the invention, the magnetic circuit of the trigger comprises a U-shaped yoke surrounding the coil of the core, and a non-magnetic flange extends between the opposite branches of the yoke to maintain the turns of the coil on the core. The base of the flange is shaped as a support for the bimetallic strip base and as an exhaust gas deionization grid.

The control coil can be applied to a pivoting vane trigger or a sliding plunger release.

According to a development of the invention, the bimetal thermal trip device is for mixed heating thanks to a driver advantageously having a Lyre structure with two lateral branches. The bimetallic strip extends parallel to the driver, being interposed in song between said branches.

A flexible conductor is soldered to the head of the bimetallic strip and the driver's junction point in lyre on the bimetallic strip can be located near the mounting base of the bimetallic strip, or intermediate position between the foot and the head of the bimetallic strip. In the latter case, only the upper part of the bimetallic strip located between the head and the junction point is traversed by the current.

The position of the driver's junction point on the twin blade allows you to choose the shape of the thermal trip curve. This Lyre structure improves the resistance to electrodynamic forces and avoids the use of reinforcing hoops.

The thermal tripping threshold can be adjusted by means of two devices for adjusting the Interval formed between the head of the bimetallic strip and an active part of the tripping bar. The first adjustment device is adjustable in the factory by means of a screw intended to deform the base of each bimetallic strip. The second adjustment device can be adjusted by the customer Himself using a caliber adjustment button. This button is common to all the blades and is housed in an opening in the housing. The button controls a mechanical device capable of moving in translation. The trigger bar for setting the interval with bimetallic heads. A compensation bimetal strip is incorporated in the mechanical adjustment device and is housed inside the adjustment knob in contact with the ambient air. The compensation bimetal has a spiral structure, the ends of which are secured to the adjustment button and to the actuating rod of the control cam in translation of the trigger bar.

• - La figure 1 est une vue schématique en coupe longitudinale partielle d'un pâle du disjoncteur équipé du déclencheur électromagnétique selon L'invention;
• - La figure 2 montre à échelle agrandie une vue en perspective du déclencheur selon La fig. 1, La bobine ayant une spire de tresse isolée;
• - La figure 3 représente une vue en élévation du déclencheur selon La fig. 1, avec une bobine à trois spires;
• - La figure 4 est une vue identique à La fig. 3, d'une variante de réalisation utilisant une tresse nue;
• - Les figures 5 et 6 montrent respectivement des coupes selon Les lignes V-V et VI-VI des fig. 3 et 4;
• - La figure 7 est une variante de La fig. 4;
• -La figure 8 est une vue schématique en détail du déclencheur thermique à bilame équipant Le déclencheur selon La fig. 2;
• - les figures 9 et 10 montrent respectivement des vues de profil et en plan du déclencheur de La fig. 8;
• - les figures 11 et 12 sont des vues analogues à celles des fig. 8 et 9 d'une variante de réalisation;
• - La figure 13 est une vue partielle en perspective du déclencheur selon La fig. 1, montrant Le dispositif de réglage du seuil de déclenchement thermique;
• - la figure 14 est une coupe selon La Ligne XIV-XIV de La fig. 13.

Other advantages and characteristics will emerge more clearly from the description which follows of different embodiments of the invention, given by way of nonlimiting examples and represented in the appended drawings, in LesqueLs:

• - Figure 1 is a schematic view in partial longitudinal section of a blade of the circuit breaker equipped with the electromagnetic trip device according to the invention;
• - Figure 2 shows on an enlarged scale a perspective view of the trigger according to fig. 1, The coil having an insulated braid turn;
• - Figure 3 shows an elevational view of the trigger according to fig. 1, with a coil with three turns;
• - Figure 4 is a view identical to FIG. 3, of an alternative embodiment using a bare braid;
• - Figures 5 and 6 respectively show sections along lines VV and VI-VI of Figs. 3 and 4;
• - Figure 7 is a variant of FIG. 4;
• FIG. 8 is a schematic detail view of the bimetal thermal trip device fitted to the trip device according to FIG. 2;
• - Figures 9 and 10 respectively show side views and plan view of the trigger of fig. 8;
• - Figures 11 and 12 are views similar to those of Figs. 8 and 9 of an alternative embodiment;
• - Figure 13 is a partial perspective view of the trigger according to fig. 1, showing the device for adjusting the thermal trip threshold;
• - Figure 14 is a section along Line XIV-XIV of FIG. 13.

In FIG. 1, a pole of a low-voltage multipole electric circuit breaker is shown, comprising a housing 10 of molded insulating material. Each pole has a pair of separable contacts 12, 14 and an arc extinguishing chamber 16 housed in a lower compartment of the insulating housing 10 with the associated thermal magnetic trip device 18. The fixed contact 12 is carried by an end conductor 20 extended externally by a contact pad 22 projecting from the housing 10. The movable contact 14 is arranged at the end of an arm 23 of vertical contact secured by a spring 26 to a multipolar switching bar 24 made of insulating material. The bar 24 is mounted with limited rotation between the open and closed positions of the circuit breaker and extends transversely in the upper part of the housing 10 in a direction perpendicular to the movable contact arms 23 of the poles. The arc extinguishing chamber 16 is constituted by a stack of metal separators or deionization sheets 27 extending perpendicular to the bottom of the housing 10.

The switching bar 24 is actuated by means of an operating mechanism (not shown) coupled to a manual control member, in particular a lever 28, and to an automatic trigger hook or lever 30 cooperating with a lock. 32 of a multipolar trip bar 34. The latter extends above the magneto-thermal trip device 18 of each pole, in a direction parallel to the switching bar 24, and is mounted with limited rotation between an armed position for locking the hooking nose of the hook 30 by the bolt 32 and a triggered position releasing the hook 30 by unlocking the latch 32. The passage from the armed position to the triggered position of the rotary bar 34 is controlled by the magnetothermal trigger 18 or by other triggering auxiliaries causing the automatic triggering of the mechanism and the opening of the contacts 12, 14 by rotation of the common bar 24. The operation of such a circuit breaker is conventional and is well known to specialists.

The magnetothermal trip unit 18 of each pole is formed by a monobloc assembly (fig. 1 and 2), comprising a bimetal thermal trip unit 36 for protection against overload currents, and an electromagnetic trip unit designated by the general reference 38 for protection against short-circuit currents. The electromagnetic trip device 38 is positioned between the arc extinguishing chamber 16 and the bimetallic strip 36, and its magnetic circuit is provided with a U-shaped ferromagnetic carcass or cylinder head 40 which surrounds a control coil 42 mounted on a core 44 fixed magnetic. The core 44 extends perpendicular to the vertical sheets 27 of the chamber 16 while being secured to the internal central part of the vertical core 46 of the cylinder head 40. At the end of the lower branch 48 of the cylinder head 40 is mounted at pivoting a movable armature 50 capable of being actuated against the pole surface 52 of the fixed core 44 when the excitation current of the coil 42 of the trigger 38 exceeds a predetermined threshold. The pivoting stroke of the armature 50 towards the attracted position takes place by magnetic attraction against a polarization spring 54 housed in an axial hole 56 of the cylindrical core 44. The spring 54 of the compression type urges the armature 50 towards the separated position (fig. 2) in support of a stop? formed by the head 57 of a screw 58. The latter passes through the return spring 54 of the "armature 50 and has a threaded end introduced into the core 44 and the core 46 of the cylinder head 40.

The bimetallic strip heater 36 is connected to a contact pad 60 aligned with the opposite pad 22 in the longitudinal direction of the pole. The contact arm 23 is electrically connected to the bimetallic strip 36 by means of a flexible conductor 62 continuous, the intermediate part of which is wound around the core 44 to constitute the coil 42 for controlling the electromagnetic trip device 38. The coil 42 may comprise a single turn (fig. 1 and 2) or several turns (fig. 3, 4) in as a function of the size of the device and of the setting of the instantaneous trigger threshold of the trigger 38. The single or multiple passage of the flexible conductor 62 inside the cylinder head 40 takes place during assembly of the device without any interruption of the conductor 62 and without welding points at the level of the coil 42. One end of the flexible conductor 62 is welded to the contact arm 23 and the end opposite to the head of the bimetallic strip 36.

The flexible conductor 62 is generally formed by a conductive braid 64, in particular made of copper, which can be insulated by a coaxial outer sheath 65 made of plastic insulating material (fig. 5) or be devoid of insulator (fig. 6). The insulated braid 64 can be wound directly on the magnetic core 44 (fig. 1 to 3) without insulating intermediate piece, while the use of a bare braid 64 requires the use of an insulating carcass 66 (fig. 4) positioned between the core 44 and the yoke 40. The insulating carcass 66 has grooves 68 for positioning the turns of the coil 42, and partition walls 70 for the isolation of the turns of the bare braid 64.

In FIGS. 1 to 4, the turns of the coil 42 on the core 44 are maintained by means of a metal flange 72 for closing the U of the cylinder head 40. The flange 72 is made of non-magnetic material, in particular stainless steel , brass or bronze, and has a curved tab 74 which serves as a support for the bimetallic strip 36. The factory setting of the trigger threshold for the bimetallic strip 36 is carried out by means of an adjustment screw 76 capable of deforming the foot of the bimetallic strip 36 fixed to the flange 74 of flange 72.

The base of the flange 72 of the trigger 38 rests on the bottom of the insulating box 20 and is located on the path of the exhaust gas from the arc extinguishing chamber 16. A plurality of slots 78 is arranged in the base of the flange 72 to facilitate the escape of the cut gases expelled to the outside through an opening 80 of the housing 20, located under the contact pad 60. The metal flange 72 also plays the role of an exhaust gas cooling grid during their passage through the slots 78.

In the variant of FIG. 7, the non-magnetic flange 72 is eliminated, and the ferromagnetic yoke 40 is limited to a simple support bracket for the fixed core 44. The excitation coil 42 is formed by three turns of the flexible conductor 62 wound on the insulating carcass 66 of the magnetic core 44. The latter is hollow for the housing of the return spring 54 of the pivoting frame 50, the end-of-travel stop being formed by a stop 82 integral with the carcass 66. The bimetal foot 36 is fixed directly to a lower tab 84 of the ferromagnetic yoke 40.

The movable armature 50 of the electromagnetic trip device 38 of FIGS. 1 to 4 and 7 is shaped as a ii-tercalée pivoting pallet between the pole surface 52 of the core 44 and the bimetallic actuator 36. The lower end of the pallet constitutes the pivot point on the branch 48 of the cylinder head 40, and the upper end actuates a projection 86 (FIG. 1) of the trigger bar 34 so as to release the hook 30 when the pallet is pressed against the pole surface 52 of the core 44 by magnetic attraction.

Note in FIG. 7 that the fulcrum of the pallet against the stop 82 is between the return spring 54 and the pivot point on the branch 48 of the cylinder head 40. This assembly makes it possible to eliminate any air gap parasitic to the joint.

In Figures 8 to 10 The driver 90 of the bi-blade trip unit 36 is made of electrically conductive or resistant material. The deflection of the bimetallic strip 36 depends on the intensity of the current flowing in the bimetallic strip 36 and in the driver 90 and the thermal trip threshold is adjustable by the adjusting screw 76 according to the size of the circuit breaker.

The bimetallic strip 36 has an elongated structure, the base of which is provided with a fixing foot 91 and the opposite end of which comprises a head 92 capable of actuating the trigger bar 34 for a predetermined deflection of the bimetallic strip 36 corresponding to an overshoot of the trigger point. The foot 91 of the bimetallic strip 36 is fixed to a tab or flange 72 support integral with the cylinder head 40 fixed to the electromagnetic trip device 38. The flexible conductor 62, in particular a braid, is welded to the active head 92 of the bimetallic strip 36 to form an electrical connection with The pole's mobile contact. The adjusting screw 76 passes through The foot 91 for fixing the bimetallic strip 36 and The associated flange 72, the latter being folded into two deformable and / or elastic branches under the action of The screw 76. The setting of the trigger point of the thermal trigger is carried out in the factory by means of the screw 76, causing mechanical deformation of the base of the bimetallic strip 36.

• Le courant I de Ligne (fig. 8 et 9) entre dans Le déclencheur par La tresse 62, circule selon Le sens de La flèche dans La partie supérieure du bilame 36 jusqu'au point 96 de jonction du chauffeur 90 en Lyre. Le courant I s'inverse au point 96 en se partageant en deux courants élémentaires 1/2 qui empruntent les deux branches 93, 94 latérales en parallète du chauffeur 90 pour sortir du pôle par La plage 60. Chaque branche 93, 94 de La Lyre est ainsi parcourue par La moitié de l'intensité du courant circulant en sens inverse dans Le bilame 36. La disposition de chant (fig. 10) du bilame 36 entre Les branches 93, 94 latérales du chauffeur 90 en Lyre place les sections selon leur plus grande inertie de flexion et permet d'augmenter la distance moyenne qui sépare les courants circulant en sens inverse dans le bilame 36 et Les branches 93, 94 du chauffeur 90. IL en résulte une réduction et un équilibrage des efforts électrodynamiques de répulsion, même en présence de courants de surcharge importants.

The driver 90 extends parallel to the bimetallic strip 36 and has a general lyre structure provided with two branches 93, 94 LatéraLes joined to a central core 95 coplanar. The bimetallic strip 36 is interposed between the two arms 93, 94 in U of La Lyre, and the core 95 is superimposed and then fixed by welding to the bimetallic strip 36 at an intermediate point 96 located longitudinally between the foot 91 and the end 92 of the bimetallic strip 36. The width of the core 95 corresponds substantially to that of the bimetallic strip 36, and the ends of the lateral branches 93, 94 of La Lyre are connected by welding and crimping to the contact area 60 of the pole. The range 60 extends perpendicularly to the bimetallic strip 36 and to the driver 90, and engages in the cage of a connection terminal (not shown), formed in a housing of the insulating housing 10. The operation of the mixed heating thermal release of the bimetallic strip 36 of each pole is as follows:

• The current I of Line (fig. 8 and 9) enters in the trigger by the braid 62, circulates according to the direction of the arrow in the upper part of the bimetallic strip 36 to the point 96 of junction of the driver 90 in Lyre. The current I reverses at point 96, dividing into two elementary currents 1/2 which take the two lateral branches 93, 94 in parallel with the driver 90 to exit the pole via the track 60. Each branch 93, 94 of La Lyre Half the intensity of the current flowing in the opposite direction is thus traversed in the bimetallic strip 36. The edge arrangement (fig. 10) of the bimetallic strip 36 between the branches 93, 94 lateral of the driver 90 in Lyre places the sections according to their greater bending inertia and makes it possible to increase the average distance which separates the currents flowing in the opposite direction in the bimetallic strip 36 and the branches 93, 94 of the driver 90. This results in a reduction and a balancing of the electrodynamic efforts of repulsion, even in the presence of large overload currents.

Note that the lower part of the bimetallic strip 36 located between the painted surface 96 of the junction of the driver 90 and the foot 91 is not traversed by the current, the circulation of the latter taking place exclusively in the upper part of the bimetallic strip 36 between head 92 and point 96.

According to the variant of FIGS. 11 and 12, in LesqueLLes The same references designate identical or similar parts, The junction point 96 of the driver 90 in lyre is substantially at the level of the foot 91 of the bimetallic strip 36. The current flows throughout the length of the bimetallic strip 36, between the head 92 and the foot 91, and this results in an increase in direct heating.

The longitudinal position of the point 96 where the driver 90 joins the bimetallic strip 36 can be arbitrary as a function of the thermal tripping curve, and the tripping time varies as a function of the position of said point 96.

The driver 90 in lyre may include a twist stack metal quants of different materials intended to adjust the electrical resistance of the driver to a predetermined value.

The flexible conductor 62 is formed by a copper braid for devices of higher ratings, and by a resistant braid for devices of lower ratings. In the latter case, the braid is made for example of stainless steel or cupro-nickel and its connection to the head 92 makes it possible to increase the indirect heating and the temperature difference in the bimetallic strip 36. The thermal resistance is also improved by Limitation of the presumed current. The braid can also be bimetallic, for example copper and stainless steel.

In FIGS. 13 and 14, the heads of the three bimetallic strips 36 of a three-pole circuit breaker each have a ramp 150 coming into contact with a stop 152 of the trigger bar 34. The hook 30 for triggering the mechanism is locked in the armed position by a lock 32 integral with the bar 34. A mechanical device makes it possible to adjust the thermal trigger threshold by bidirectional translation according to the arrow F of the trigger bar 34 according to the direction of arrangement of the bimetallic strips 36. This device comprises a cam 160 cooperating with one end of the trigger bar 34. The cam 160 is rotated by a control rod 162 secured to an adjustment button 164. A return spring 166 cooperates opposite the cam 160 with L other end of the trigger bar 34. The operation of the mechanical device for adjusting the thermal trigger threshold is well known to specialists, and it suffices to recall that The translation of e The trigger bar 34 by rotation of the adjustment knob 164 adjusts the gap between the stops 152 of the bar 34 and the ramps 150 of the bimetallic strips 36. The button 164 is positioned in an opening 167 of the insulating housing 10.

A compensation bimetal 168, common to all the Poles, is inserted in the mechanical adjustment device to take into account the variation of the ambient temperature. The compensation bi-blade 168 has a spiral structure and is housed inside the adjustment knob 164 in contact with the ambient air. The ends of the bimetallic strip 168 in a spiral are secured to the adjustment knob 164 and to the rod 162 for actuating the cam 160.

Claims (12)

1. Magnetothermic trip device cooperating with the actuation mechanism of a multipole circuit breaker and comprising by pole a first electromagnetic trip device (38) and a second bimetal thermal trip device (36), Said first trip device comprising a magnetic circuit with an air gap traversed by The induction flux generated by a control coil (42), and a movable armature (50) capable of being attracted against a polar surface of the magnetic circuit When the intensity of the current flowing in the coil (42) exceeds a predetermined threshold causing the triggering of the mechanism, said control coil being formed by the winding of a flexible connection conductor (62), characterized in that one of the ends of the flexible connection conductor (62) is secured directly to an arm contact (23) mobile pole, and that the other end of the conductor (62) is connected by welding to the bimetallic strip (36), allowing a fixed mounting of the electromagnetic trip device ic (38), arranged between the contact arm (23) and the bimetal thermal trip device (36), the coil (42) comprising one or more turns of said conductor (62) flexible according to the tripping characteristics. 2. Trigger according to claim 1, characterized in that the magnetic circuit comprises a yoke (40) formed by a U-shaped stirrup surrounding the coil (42) for controlling the core (44), and that the frame (50) mobile is pivotally mounted on a branch (48) of the cylinder head (40) being biased towards the position separated by an elastic return means (54) housed in a hole (56) of the core (44). 3. Trigger according to claim 2, characterized by the fact that a flange (72) of non-magnetic metallic material extends between the two opposite branches of the U-shaped bracket for maintaining the turns of the coil (42) on the core (44), and that the base of the flange (72) is shaped as a support for the bimetallic foot (36) and as an exhaust gas deionization grid. 4. Trigger according to claim 3, characterized by the fact that the base of the flange (72) bears on the bottom of the insulating housing (10) being situated between the arc extinguishing chamber (16) and an opening ( 80) of the housing (10), and that slots (78) are provided in the base of the flange (72) to improve the escape of gases to the outside opposite the fixed contact (12). 5. Trigger according to one of claims 2, 3 or 4, characterized in that the elastic means (54) for returning the movable frame (50) is formed by a compression spring, and that a screw ( 58) crosses the spring (54) inside the hole (56), the head (57) of the screw (53) serving as an adjustable limit stop for the frame (50) placed in the separated position. 6. Trigger according to claim 2, characterized in that the movable armature (50) is formed by a pallet abutting in a position separated against a stop (82), and that said stop (82) is arranged between the means elastic (54) return and the articulation point of the pivoting pallet on the branch (48) of the cylinder head (40) to eliminate any parasitic air gap at said articulation point. 7. Trip device according to one of the preceding claims, in which the second bimetal thermal trip device is for mixed heating, comprising per pole: - a bimetallic strip (36) having an elongated structure extending longitudinally between a fixing foot (91) and an actuating head (92) becoming active for a predetermined deflection corresponding to the thermal tripping threshold, - And a heating element or driver equipped with a radiant surface arranged near the bimetallic strip, and a mechanical and electrical junction point intended for fixing the driver to the bimetallic strip, and for the passage of current between the latter and the driver, characterized in that the driver (90) has a lyre structure comprising two lateral branches (93, 94) and that the bimetallic strip (36) extends parallel to the driver (90) while being interposed between the said branches (93, 94), which are joined on the one hand to a central core (95) copLanaire.fixé au bimetal ( 36) to form said junction point (96), and on the other hand, to a contact pad (60), each elementary branch (93, 94) being traversed by a fraction of the current flowing in the opposite direction in the bimetallic strip ( 36). 8. Trigger according to claim 7, characterized in that each branch (93, 94) of the driver (90) in Lyre extends in the LongitudinaLe direction of the bimetallic strip (36) and is traversed by half the intensity of the current flowing in the bimetallic strip (36). 9. Trigger according to claim 8, characterized in that the point (96) of the driver's junction (90) in lyre is located either in the vicinity of the foot (91) for fixing the bi-blade (36), or in an intermediate position between the foot (91) and the head (92) of the bimetallic strip (36). 10. Trigger according to one of claims 3 to 9, characterized in that the foot (91) for fixing the bimetallic strip (36) is integral with the flange (72) formed by a sheet folded into two deformable and / or elastic branches , and that an adjustment screw (76) passes through said foot (91) and flange (72), so as to ensure mechanical deformation of the base of the bimetallic strip (36) allowing factory adjustment of the thermal tripping threshold. 11. Trigger according to one of claims 1 to 10, characterized in that the flexible conductor (62) is formed by a braid produced by means of a conductive material having an electrical resistivity greater than that of copper, in particular steel stainless or cupro-nickel. 12. Trigger according to one of claims 1 to 11, further comprising a mechanical device for adjusting the threshold thermal release by bidirectional translation of the trip bar, a mechanical device adjustment button and a temperature compensation bimetal inserted in the mechanical device for taking into account the variation of the ambient temperature, characterized by the fact that the temperature compensation bimetal (168) has a spiral structure, arranged inside the adjustment button (164), and that the latter is housed in an opening (167) of the housing while being in contact with the ambient air .

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