WO2018015686A1 - Starter switch comprising a protection device and starter comprising such a switch - Google Patents

Abstract

Starter switch (1) comprising: - a housing (2) with an axis (O) and defining at least one internal space, - at least one coil accommodated in the housing (2), - a core (4) translatably movable along the axis (O), the movable core (4) being accommodated in the coil, - a protection device connected to the movable core (4) and to the housing (2), the protection device being situated around the movable core (4) in order to define a chamber bounded at least by the protection device and by the movable core (4), characterised in that the starter switch (1) comprises at least one fluid communication means (8) connecting the chamber to the internal space. Said invention is applicable to motor vehicles.

Description

 STARTER CONTACTOR COMPRISING A PROTECTION DEVICE, AND STARTER COMPRISING SUCH A CONTACTOR

The field of the present invention is that of motor vehicle engine starters.

According to a known design, a motor starter contactor, in particular a motor vehicle, comprises a cylindrical housing in which is placed an annular coil which generates a magnetic field under the effect of an electric current passing through it. Depending on the polarization of the coil, the magnetic field thus created exerts an attractive or repulsive force on a cylindrical and at least partly magnetic mobile core. The movable core is mounted in an interior space delimited by the annular coil so as to be able to slide in axial translation to close or open an electrical circuit connected to the starter motor power circuit and to push a pinion in a motor crown via a lever. The starter switch generally operates in a polluted environment and / or comprising dust and particles which, if they are introduced into the interior space of the housing or between the movable core and an inner wall of the interior space, can prevent the movable core to slide freely inside the coil, or to seize it completely. The insertion of impurities inside the interior space is also facilitated by the translation movements back and forth of the movable core during operation of the starter contactor. These translational movements generate a piston effect when the movable core leaves the housing, causing suction of the air surrounding the starter switch, and therefore the dust and surrounding particles.

In order to maintain the ability of the movable core to slide freely in the coil, it is known to protect the movable core by an elastic plastic protective sleeve, the protective sleeve surrounding the movable core. This solution has the disadvantage of limiting, or even preventing, the exit of the air contained in the interior of the contactor when the movable core slides towards the interior space. This incoming translation generates an increase in the pressure inside the protective sleeve, causing in turn a swelling of the sleeve of protection. The swelling of the protective sleeve leads to the occurrence of friction against other elements of the starter switch, causing premature wear and / or tearing of the protective sleeve. In order to solve the premature wear of the protective sleeves, it is known to pierce the protective sleeve to form a vent allowing the evacuation of the air towards the outside of the protective sleeve. This vent is axial.

Firstly, when the movable core leaves the starter switch, the air surrounding the starter contactor and its impurities are always sucked between the movable core and the coil via vent. This is particularly the case when the dimensions vent dimensions are too large compared to the average particle and dust dimensions. Second, if the dimensions of the vent are too small, the increase in pressure during the translation of the movable core to the interior deforms the protective sleeve and causes premature wear, as previously described. In addition, in case of closure of the vent, the air in the interior space can no longer be evacuated to the outside and causes an excessive increase in the air pressure in the interior space. This increase in pressure can lead to preventing the movable core from completing its axial translation to the interior space if the magnetic field generated by the coil does not further compress the air located in the interior space. In this case, the mobile core can no longer close the electrical circuit for starting the starter.

It is thus obvious that the solutions provided by the state of the art do not solve the problems identified. The object of the present invention is therefore to provide a new starter contactor comprising a dust protection device limiting or eliminating air exchanges between the outside and inside of the contactor, while avoiding any deformation of the device of protection that may rub against another part of the contactor or starter. Another object of the invention is to limit the wear of the protective device. Another object of the invention is to reduce failures of a starter contactor. Another object of the invention is to reduce the maintenance costs of a starter contactor.

According to a first aspect of the invention, there is provided a starter contactor comprising:

 an axis housing and delimiting at least one interior space,

 at least one coil housed in the housing,

 a core movable in translation along the axis, the mobile core being housed in the coil,

 a protection device connected to the mobile core and the housing, the protection device being situated around the mobile core in order to define a chamber lined at least by the protection device and by the mobile core,

 the starter contactor comprising at least one fluid communication means connecting the chamber to the interior space.

Thus, the starter contactor according to the first aspect of the invention comprises a protection device whose interior communicates with other voids of the contactor. In this way, depending on the position of the movable core relative to the housing and the direction of the translational movement that animates it, the volume variations in the chamber are negligible compared to the total volume of all the spaces placed in communication. The pressure increase of the air inside the contactor is therefore minimal and is not sufficient to deform the membrane of the protection device.

Thus, the invention according to its first aspect limits the wear of the protective device by limiting the effects of overpressure inside the housing and / or the protective device during operation of the starter contactor.

Consequently, the starter contactor according to the first aspect of the invention makes it possible to reduce the breakdowns and the associated maintenance costs: its reliability is therefore improved.

In addition, according to the invention, the fluid communication means is arranged in the housing and / or in the mobile core. It is therefore not necessary to provide a radial clearance between the housing and the movable core to allow air circulation. Thus, there is no radial spacing between these parts other than a minimum clearance allowing the sliding of the mobile core. This reduces the radial size of the contactor. In addition, it also improves airflow throughout the interior of the contactor. Indeed, a space made between two parts that allows the sliding of said parts relative to each other can be obstructed for example by grease to improve the sliding of the parts and therefore do not allow an optimal evacuation of the air.

According to an exemplary embodiment of the invention, the interior space is delimited radially on the outside by the housing, radially on the inside by the coil, and axially by the fixed core on the one hand and by an axial end of the housing. housing on the other hand. The interior space may advantageously be constituted by a space intended to facilitate the assembly operations of the starter switch or to fulfill any other role useful to the operation of the starter switch according to the invention, or to be dug by design in one or more parts or parts of the starter switch parts. Such an interior space may be formed of a single cavity, but it may also be a plurality of cavities in fluid communication with each other.

Advantageously, the volume of the interior space is greater than the volume included in the chamber. More particularly, the volume of the interior space is 2 to 20 times greater than the space included in the room. Advantageously, the fluid communication means is arranged in the housing. The fluidic communication means may also be arranged in the mobile core. The fluidic communication means joins the chamber to the interior space. The fluidic communication means may comprise a single conduit, or comprise a plurality of conduits, for example radially around the mobile core. In the case of a plurality of ducts, the ducts may be angularly distributed regularly around the axis or not. Alternatively, the fluidic communication means may comprise a plurality of ducts leaving the chamber, this plurality of ducts joining together in a single channel abutting into the interior space. Alternatively, the fluidic communication means may comprise a single duct extending from the chamber and dividing into a plurality of ducts opening into the interior space. Alternatively, the fluidic communication means may extend around the axis. The fluid communication means is arranged in the housing, which means that the housing comprises a bore, in particular a bore or a molding, which forms the duct or ducts of the fluid communication means. In a variant, the fluidic communication means comprises at least one groove formed on an inner peripheral wall of the housing.

In another embodiment of the invention, the interior space is defined radially on the outside by the coil, axially by the mobile core on the one hand and the fixed core on the other hand. According to this embodiment, the fluid communication means is arranged in the mobile core. The fluidic communication means may take the form of a single conduit, or comprise a plurality of conduits, for example radially around the mobile core. In the case of a plurality of ducts, the ducts may be angularly distributed regularly or not. Alternatively, the fluidic communication means may comprise a plurality of ducts leaving the chamber, this plurality of ducts joining together in a single channel abutting into the interior space. Alternatively, the fluidic communication means may comprise a single duct extending from the chamber and dividing into a plurality of ducts opening into the interior space.

In yet another embodiment of the invention, the contactor comprises two interior spaces, a peripheral interior space and a central interior space. The peripheral interior space is delimited radially on the outside by the housing, radially inside by the coil, and axially by the fixed core, on the one hand and by an axial end of the housing, on the other hand. The central interior space is delimited radially on the outside by the coil, axially by the mobile core on the one hand and the fixed core on the other hand. According to this embodiment, at least one fluid communication means is arranged in the housing, and at least one other fluid communication means is arranged in the mobile core. Alternatively, the protection device is airtightly connected to the mobile core on the one hand and the housing on the other hand. Sealed means that the protective device is arranged to prevent air from entering the chamber or contactor.

Advantageously, the protection device is arranged to ensure a seal between the interior space and an environment outside the starter contactor.

According to an exemplary embodiment, the interior space comprises a cavity located between the fixed core and a cover disposed at a longitudinal end of the housing. It will be understood that the housing comprises a first longitudinal end and a second longitudinal end, the second longitudinal end receiving the cover. Alternatively, this cavity may be formed in a radially central zone of the starter contactor, or in a radially peripheral zone of the starter contactor. The cavity can be connected to the interior of the contactor to increase the total volume inside the starter contactor and thus participate in the reduction of the deformations of the membrane of the protection device.

Advantageously, the fluidic communication means is formed in the housing and located axially towards an opposite end of the housing relative to the fixed core.

Advantageously, the protective device comprises a bellows membrane. By way of non-limiting example, the protective device may comprise a bell membrane or any other form of protective membrane.

As previously described, the protection device is linked to the mobile core. More particularly, the protective device is connected to the movable core by means of first fixing means located on the protection device and collaborating with second fixing means located on the movable core. More particularly, the first attachment means are located on the axial end of the protective device furthest from the housing. More particularly, the second fixing means are located on a terminal flange of the mobile core. Advantageously, the protective device is connected to the movable core by plating against the end flange of the movable core by virtue of the pressure exerted by the return spring. Alternatively, the protective device may be connected to the movable core by clipping, gluing, crimping or by any other means adapted to the invention and arranged to seal the connection between the protective device and the movable core.

Alternatively, the protective device is integrally bonded to an axial end of the movable core which is furthest from the housing. In other words, the second attachment means are located at the axial end farthest from the movable core, thus allowing the protection device to cover peripherally all the movable core.

Advantageously, the protective device covers an outer portion of the movable core. By outer part is meant that part of the movable core which is outside the housing when the movable core is in the initial position.

Alternatively, the protective device may cover only a fraction of this outer portion. In another alternative, the end of the end flange of the movable core is integrally bound to any part of the protection device.

According to a second aspect of the invention, there is provided a starter comprising a starter contactor according to the first aspect of the invention or any of its embodiments.

According to a third aspect of the invention, there is provided a method of using the starter switch according to the invention to start a motor vehicle engine.

Other characteristics, details and advantages of the invention will emerge more clearly on reading the description given below as an indication in relation to drawings in which: FIG. 1 is a view in axial section of a contactor according to a first embodiment of the invention,

 FIG. 2 is a perspective view showing features of the first embodiment,

 FIG. 3 is a view in axial section of a contactor according to a second embodiment of the invention,

 FIG. 4 is a perspective view showing features of the second embodiment. The embodiments which are described below are in no way limiting; it will be possible to imagine variants of the invention comprising only a selection of characteristics described hereinafter isolated from the other characteristics described, if this selection of characteristics is sufficient to confer a technical advantage or to differentiate the invention compared to the state of the art.

In particular, all the variants and all the embodiments described are combinable with each other if nothing stands in the way of this combination at the technical level. In such a case, mention would be made in the present description. In the figures, the elements common to several figures retain the same reference.

In the remainder of the description, the axial, radial, external and internal denominations refer to an axis (O) passing through at its center the starter contactor according to the first aspect of the invention. The axial direction corresponds to the axis (O) crossing at their center the mobile core 4, the fixed core 13, the movable shaft 12, the housing 2 and the coil 3, while the radial orientations correspond to concurrent planes, and in particular perpendicular to the axis (O). For the radial directions, the outer or inner denominations are evaluated with respect to the same axis (O), the inner denomination corresponding to an element oriented towards the axis, or closer to the axis with respect to a second element, the external denomination designating a distance from the axis. The directions mentioned above are also visible in an orthonormal frame Oxy shown in the figures.

Figure 1 shows a starter switch 1 according to the invention equipping a motor starter of a vehicle.

The starter contactor 1 comprises (i) a housing 2 housing at least one coil 3, and a movable core 4 in axial translation with axis (O), and (ii) a protection device 6 connected to the mobile core 4 and to the housing 2, the protective device 6 being located around the movable core 4 to create a chamber 9 defined by the protection device 6, the housing 2 and the movable core 4.

The housing 2, of generally annular shape and having the central axis (O), defines an empty interior space 18, of cylindrical shape. The housing 2 has a first longitudinal end 30 which is formed a hole in which the movable core 4 slides in and out of the housing 2, and a second longitudinal end 31 closed by a cover 14.

In the example of FIG. 1, the internal space 18 is more specifically defined radially on the outside by the casing 2, radially inside by the coil 3, axially by an axial end of the casing 2 on the one hand and by a fixed core 13, for example of the general shape of a disk, on the other hand. The fixed core 13 is delimited radially outwards by an inner face of the housing 2. The outer peripheral portion of the fixed core 13 is delimited axially on the one hand by the housing 2 and on the other hand by the cover 14, the form of a cylindrical pot, disposed at the axial end of the housing 2 opposite to that which receives the movable core 4.

The coil 3, of annular shape, is housed in the housing 2 and defines an internal compartment 22 centered around the axis (O). The movable core 4, of generally cylindrical shape, is actuated by the coil 3.

It slides along the axis (O) in the internal compartment 22 of the coil 3. The movable core 4 comprises a bore radially centered with the axis (O) and extending axially between two ends of the movable core 4. This bore delimits an internal volume 25. In the internal volume 25 is inserted a shaft 10 for controlling a fork (not shown) for putting in position a starter gear (not shown) on a flywheel (not shown). The pinion is rotated by a starter motor, which makes it possible to start the flywheel and start the engine of the vehicle.

Peripherally outside the movable core 4 and on at least a part thereof, a spring 11, for example of helical type, is arranged to exert a repulsive force on the movable core 4, oriented along the axis (O ) and in a direction out of the housing 2. The spring 11 allows to push the movable core 4 out of the inner compartment 22 in the absence of supply of the coil 3. The spring 11 bears axially on the housing 2 of a on the other hand, on the end flange 20 of the mobile core 4, the end flange 20 having the shape of an "S" shaped disc in a transverse plane and as illustrated in FIG. compresses during the translation of the movable core 4 towards the inside of the starter contactor 1, corresponding to a working position of the mobile core 4, and expands when the coil 3 is not polarized, then pushing the mobile core 4 out of the inner compartment 22 of the coil 3, corresponding to if at an initial said position of the mobile core 4.

Radially outside the movable core 4 and the spring 11, the protective device 6 covers at least a portion of the movable core 4 and / or the spring 11. The protective device 6 has the general shape of a cylindrical tube comprising possibly a plurality of bellows 66 placed end to end and arranged to be able to fold side by side when the displacement of the movable core 4 towards the casing 2 causes compression of the protection device 6. The protection device 6 is made in an elastic material capable of withstanding large and / or repeated deformations. By way of non-limiting example, the protective device 6 is at least partially made of deformable material.

The protective device 6 is connected by one of its axial ends 67 farthest from the housing 2 to the end flange 20 of the movable core 4. This connection is arranged to ensure an airtightness between the protective device 6 and the movable core 4. The protective device 6 is connected by another of its axial ends to the housing 2. This connection is arranged to ensure an airtightness between the protection device 6 and the housing 2. The airtightness mentioned here is intended to prevent the entry or exit of air at the contact between the protective device and respectively the housing or the movable core, when the mobile core moves from its initial position to its working position.

The protective device 6 is integrally bonded by its axial end 67 to an axial end 41 of the movable core 4, this axial end 41 being an edge of the end flange 20. The axial end 67 of the protection device 6 is fixed to the axial end 41 of the movable core 4 by cladding with the spring 1 1, by clipping, by gluing, by screwing or by any means able to hold the two elements together. On the other side, the protective device 6 is integrally bonded to the housing 2 by clipping, screwing, gluing or by any means able to hold the two elements together. The protective device 6 may alternatively be fixed on the housing 2 by an additional element attached to the contactor 1.

The chamber 9 is delimited radially outwards by the protection device 6, more precisely by the bellows 66, and inwardly by the movable core 4. Axially, the chamber 9 is delimited by the end flange 20 of the movable core 4 on the one hand and by the axial end of the housing 2 on the other.

A fluidic communication means 8 is arranged in the contactor 1 to connect the chamber 9 with the interior space 18.

In the example of FIG. 1, the fluidic communication means 8 is arranged in the housing 2 of the contactor 1. In a first part, the fluidic communication means 8 extends from the chamber 9 into the housing 2, parallel to the axis (O). In a second part, the fluidic communication means 8 extends in the housing 2, perpendicularly to the axis (O). In a third part, the fluidic communication means 8 extends in the housing 2, parallel to the axis (O), and opens into the interior space 18. In other words, the fluidic communication means comprises two orifices offset radially with respect to each other. This is the consequence of the fact that the interior space 18 is radially outside the chamber 9, which gives it a volume significantly greater than that of the chamber, thus allowing to absorb the volume of air of the chamber 9.

In the example of Figure 1, the fluid communication means 8 has a substantially rectangular section. Alternatively, the fluidic communication means 8 may be circular, square, or any other form useful for carrying out the fluidic communication between the chamber 9 and the interior space 18.

The fluidic communication means 8 may be formed by a channel or a duct formed in the material of the casing 2. It may thus be a single duct, but it may also be a plurality of ducts distributed around it. of the axis (O). Alternatively, the fluidic communication means 8 can also be divided into several branches all of which open into the interior space 18, or several fluidic communication means 8 can meet from the chamber 9 and open into the interior space 18 together.

The cover 14, designed to delimit a cavity 19, is disposed at the axial end of the housing 2 opposite the movable core 4. The cover 14 has the shape of a cylindrical pot. The cavity 19 is defined radially outwardly by the cover 14, and axially by the cover 14 on the one hand and by the fixed core 13 on the other hand. This fixed core 13 is arranged to separate the interior space 18 of the cavity 19. The cavity 19 can be arranged in a radially central zone 26 and / or a radially peripheral zone 27 inside the starter contactor 1.

The mobile core 4 exerts a translational force on a movable shaft 12 when the movable core 4 enters the housing 2. The movable shaft 12 further comprises an electrical contact 15 between two positions, intended to cooperate with electrical pads 16 for close or open an electrical circuit intended for the power supply of the starter motor. The movable shaft 12 passes through the fixed core 13 at its center.

The cavity 19 houses the electrical contact 15 and the electrical pads 16. The electrical pads 16 are arranged on an inner face of the cover 14. A helical spring 17 is arranged to push the movable shaft 12 towards the movable core 4 when the coil 3 is not powered. The movable shaft 12 is provided in its central region 23 with a shoulder 24 on which a first axial end of the return spring 17 is supported. A second axial end of the return spring 17 bears on the cover 14.

The cavity 19 may form part of the interior space 18 and thus be used to receive the air present in the chamber 9. When the coil 3 is energized, an electromagnetic field attracts the mobile core 4 into the interior space 18 of the coil 3. The movable core 4 performs a translation axis (O) to the inside of the housing 2. In entering the inner space 18, the movable core 4 compresses the spring 11 and the protective device 6. When the movable core 4 fits sufficiently into the casing 2, the movable core 4 also displaces the movable shaft 12 along the same axis (O). The movable shaft 12 will move the electrical contact 15 disposed on the movable shaft 12 for the put in contact with the electrical pads 16. The contact between the electrical contact 15 and the electrical pads 16 will close the starter motor power supply circuit and allow its launch. By the same axis translation movement (O), the movable shaft 12 will compress the return spring 17. When the coil 3 is no longer fed, the spring 11 pushes the movable core 4 out of the interior space 18, the protective device 6 returns to its position and its initial shape. The return spring 17 pushes the moving shaft 12 back to its original position. The displacement of the movable core 4 along the axis (O) towards the inside of the coil 3, by driving with it the protective device 6, will reduce the volume available in the chamber 9. However, the chamber 9 and the internal space 18 communicating via the fluidic communication means 8, the volume that will be compressed will be the sum of the volumes of the chamber 9, the inner space 18, the fluid communication means 8 and any empty space forming an interior space 18 inside the contactor 1 in fluid communication. It can in particular be the cavity 19. Thanks to this provision of volume significantly greater than the volume of the chamber 9, it limits the deformation of the protection means 6 while preventing the penetration of particles and dust in the starter contactor 1. The increase in air pressure is not large enough to deform the protection device 6, which will not rub on other parts of the contactor 1. This absence of deformation allows the extension of the service life of the protection device 6.

Figure 2 shows the arrangement of the fluid communication means 8 in the housing 2. The protective device 6 is not shown here.

Figure 3 shows a starter switch according to a second embodiment of the invention.

In the example of Figure 3, the communication means 8 is arranged differently. The other features and elements of the invention are identical or substantially identical to those set forth in the description of the first embodiment.

A fluid communication means 8 is arranged in the contactor 1 to connect the chamber 9 and the interior space 18. In the example of Figure 3, the fluids communication means 8 is arranged in the movable core 4 of the contactor 1. More particularly, it is formed in an outer peripheral wall 33 of the movable core 4.

The fluid communication means 8 is delimited radially inwards by the mobile core 4 and radially outwardly by the chamber 9 and the housing 2. Axially, the fluids communication means 8 can extend to one end. axial of the mobile core 4, in particular to the terminal flask 20 when the mobile core 4 is provided. The fluid communication means 8 thus opens on one side into the chamber 9 and on the other into the interior space 18. In the example of FIG. 3, the fluid communication means 8 has a rectangular section. Alternatively, the fluids communication means 8 may be circular, square, or any other form useful for carrying out the fluid communication between the chamber 9 and the interior space 18. According to an exemplary embodiment of the invention, the fluidic communication means 8 is a groove 32 arranged longitudinally in the wall of the movable core 4. The fluidic communication means 8 may also be a groove formed longitudinally in the hole of the housing 2.

The displacement of the movable core 4 along the axis (O) towards the inside of the coil 3, by driving with it the protective device 6, will reduce the volume available in the chamber 9. However, the chamber 9 and the internal space 18 communicating via the fluidic communication means 8, the volume that will be compressed will be the sum of the volumes of the chamber 9, the internal space 18, the fluid communication means 8 and any empty space forming an interior space 18 to the interior of the contactor 1 in fluid communication. It can in particular be the cavity 19. Thanks to this volume provision significantly greater than the volume of the chamber 9, the deformation of the protection means 6 is limited while preventing the penetration of particles and dust into the chamber. the starter contactor 1. The increase of the air pressure is not important enough to deform the protection device 6, which will therefore not rub on other parts of the contactor 1. This absence of deformation allows the 6 extends the life of the protective device 6. FIG. 4 shows the arrangement of the fluidic communication means 8 in the mobile core 4. The protective device 6 is not represented here.

If the two examples each reveal an embodiment of the invention, it is also possible to implement both embodiments simultaneously in a single starter contactor.

The invention described above allows a sealing of the contactor 1 by a means which limits the introduction of particles and dust therein. The mobile core 4 is thus particularly well protected during its input and output movements inside the coil 3.

Claims

1. Starter switch (1) comprising:

 a housing (2) with axis (O) and delimiting at least one interior space (18),

 at least one coil (3) housed in the housing (2),

 a mobile core (4) in translation along the axis (O), the mobile core (4) being housed in the coil (3),

 - a protection device (6) connected to the movable core (4) and to the housing (2), the protection device (6) being located around the movable core (4) in order to define a chamber (9) bordered at least by the protection device (6) and the movable core (4), characterized in that the starter contactor (1) comprises at least one fluidic communication means (8) connecting the chamber (9) to the interior space ( 18) and in that said means (8) is arranged in the housing (2) and / or in the movable core (4).

2. starter contactor (1) according to the preceding claim, characterized in that the interior space is delimited by the housing (2), the movable core (4) and a fixed core (13) housed in the housing (2) .

Starter contactor (1) according to one of the preceding claims, characterized in that the protective device (6) is airtightly connected to the movable core (4) on the one hand and to the housing (2) secondly.

4. starter switch (1) according to any one of claims 2 to 3, characterized in that the inner space (18) comprises a cavity (19) located between the fixed core (13) and a cover (14) disposed at a longitudinal end of the housing (2).

5. Starter contactor (1) according to the preceding claim, characterized in that the cavity (19) is formed in a radially central zone (26) inside the starter switch (1).

Starter contactor (1) according to claim 4 or 5, characterized in that the cavity (19) is formed in a radially peripheral zone (27) inside the starter contactor (1).

7. Starter contactor (1) according to any one of the preceding claims, characterized in that the housing (2) comprises a first longitudinal end (30) where extends the movable core (4) and a second longitudinal end ( 31) wherein the fixed core (13) extends, the fluid communication means (8) being provided at the first longitudinal end (30) of the housing (2).

8. Starter contactor (1) according to any one of the preceding claims, characterized in that the fluidic communication means (8) comprises at least one channel connecting the chamber (9) to the inner space (18).

Starter contactor (1) according to any one of the preceding claims, characterized in that the fluidic communication means (8) comprises at least one groove (32) formed on an outer peripheral wall (33) of the movable core ( 4).

10. starter contactor (1) according to any one of the preceding claims, characterized in that the fluidic communication means (8) comprises at least one groove formed on an inner peripheral wall of the housing (2).

11. starter switch (1) according to any one of the preceding claims, characterized in that the protection device (6) comprises a bellows membrane (66).

12. starter switch (1) according to any one of the preceding claims, characterized in that the volume of the interior space (18) is larger than the volume of the chamber (9).

13. Starter characterized in that it comprises a starter switch (1) according to any one of the preceding claims.