WO2018015653A1 - Starter contactor comprising a dust protection device, and starter provided with such a contactor - Google Patents

Abstract

Starter contactor (1) comprising: - a casing (2); - at least one coil (3) housed in the casing (2); - a core (4) that is axially translatably movable along an axis (O), the movable core (4) being housed within the coil (3); - a protection device (6) limiting the entry of particles into the starter contactor (1), the protection device (6) comprising a first portion (62) that is rigidly linked to the movable core (4) and a second portion (64) that cooperates with the casing (2) by means of a coupling device (8), characterized in that the coupling device (8) comprises: - a first element (82) of the casing (2); and - a second element (84) of the second portion (64) of the protection device (6), the first element (82) and the second element (84) cooperating in order to create an axial clearance (A) between the second portion (64) of the protection device (6) and the casing (2). Said invention is applicable to motor vehicles.

Description

 STARTER CONTACTOR COMPRISING A DUST PROTECTION DEVICE, AND STARTER EQUIPPED WITH A

 TEL 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 mobile core slides in the direction interior space. This incoming translation generates an increase in the pressure inside the protective sleeve, causing in turn a swelling of the protective sleeve. 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 may be axial.

Firstly, when the movable core exits the starter switch, the air surrounding the starter contactor and its impurities are always sucked between the movable core and the coil via the vent. This is particularly the case when the dimensions vent dimensions are too large compared to the average particle and dust dimensions.

Secondly, if the dimensions of the vent are too small, then the increase in pressure during the translation of the movable core to the interior deforms the protective sleeve and causes its 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 novel starter contactor comprising a dust protection device capable of allowing an air inlet and an outlet in the protection device at a location of the contactor. which is less exposed to dust and particles.

Another object of the invention is to limit the wear of the protective device. Another object of the invention is to reduce the breakdowns 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:

 - a housing,

 at least one coil housed in the housing,

 a mobile core in axial translation of axis, the mobile core being housed in the coil,

 a protection device limiting the entry of particles into the starter contactor, the protection device comprising a first part integrally bonded to the movable core and a second part collaborating with the case by means of a coupling device,

the coupling device comprising:

 a first element of the housing and

 a second element of the second part of the protection device,

the first element and the second element cooperating to provide an axial clearance (A) between the second part of the protective device and the housing.

Thus, the starter contactor according to the first aspect of the invention comprises a protection device whose second element is arranged to take several axial positions. The axial clearance may therefore vary depending on the position of the second part of the protection device which is connected to said second element. 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 protection device can take several positions that allow the protective device to prevent dust and particles present in the air surrounding the starter switch to get inside of the case.

More particularly, the second part of the protective device is movable relative to the first element between an open position in which the air can escape and a closed position. More particularly, the second part of the protection device is arranged to be axially movable. Optionally, or additionally, the second portion of the protective device is arranged to be radially movable. For example, the second element is in contact with the first element in the open position and the protection device is in contact with the contactor housing in the closed position.

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. At least a portion of the first member and at least a portion of the second member are facing each other to alternately allow the closure or opening of a channel. This channel allows the evacuation of air located in a chamber essentially defined by the protective device and the movable core or the suction of the surrounding air in the chamber during sliding of the movable core in the coil. This channel, offset relative to the translation axis of the movable core, acts as a remote vent. It communicates with a part of the system that is less prone to fouling.

According to one embodiment of the invention, the first element of the coupling device comprises an abutment face. By abutment face is meant a face on which comes to bear the second element when closing or opening the channel.

According to one embodiment of the invention, the second element of the coupling device comprises a plating surface. By surface of plating, one hears a face on which comes to contact the first element when closing or opening the channel.

According to one embodiment, the first element has a complementary profile to the second element, taken in an axial section and / or in at least one cross section in order to increase the surfaces facing the first element and the second element. Subsequently, the contact surface is advantageously increased when the protective device is configured in its closed position, to improve the seal between the inside of the housing and the surrounding air.

According to one characteristic of the invention, the coupling device limits the axial clearance between the first element and the second element of the coupling device. Another advantage of this feature of the invention is that it allows to retain the possibility of controlling by the pump effect the speed of penetration of the movable core inside the coil. By way of non-limiting example, the axial clearance is typically between 0.05 and 0.5 mm. Another range of axial games can be 0.1 and 0.4 mm. More specifically, the axial clearance is less than 0.4 mm. Alternatively, the axial clearance is less than 0.3 mm. According to another characteristic of the invention, the coupling device comprises at least one groove and at least one flange of radial extension, the radial extension flank being housed in the groove. The groove has for example a U-shaped section and the radial extension flank has an I-shaped section. The radial extension flank enters the inside of the throat.

The displacement of the mobile core is only one axis. The movable core being limited in its race inside the starter contactor by a fixed core, it is not retained in the opposite direction. The addition of the radially extending groove / flank cooperation makes it possible to keep in place the coupling device, and therefore the protection device, which will in turn hold the mobile core.

The groove may be material or related to the contactor. By issue of material, it is meant that the groove is formed by an extension of the housing, in particular manufactured simultaneously with the case. In the case where the groove is reported, it is formed by a ring which, in collaboration with the housing, defines the groove.

The first element of the coupling device is attached to the housing by means of any means of attachment or assembly, such as in particular the screwing, gluing, welding or crimping. The first element of the coupling device is a metal ring, and comprises at least one radial extension for receiving a fixing means to the housing. By way of non-limiting example, the fixing means to the housing may be a fixing screw. According to another embodiment, the metal ring comprises at least one additional radial extension intended to collaborate with an axial extension portion of the second element to limit the axial clearance between these two elements. These two embodiments of the groove are applicable to any of the alternatives described below. According to a first alternative of the starter contactor according to the first aspect of the invention, the first housing element forms a groove oriented radially towards the inside of the contactor, the protection device comprising, at its second part, the second element. oriented radially outward of the contactor. The protective device is located radially inside the groove, at least at its second part. More particularly, the protective device is located between the movable core and the groove. The protective device is arranged to prevent dust and particles from entering the housing.

The groove may be formed around the peripheral periphery of the first element or at least a portion of the peripheral periphery. If the groove is not formed around the peripheral periphery, it is formed on at least two parts of the periphery. Part means angular sectors of the same angle. The parts are regularly distributed angularly around the periphery. All parts have the same angular dimensions. Optionally, at least one part is different from the others, whether in shape or size.

The axial dimensions of the groove are adapted to provide the axial clearance previously described as a function of the axial dimensions of the second element. The radial dimensions of the groove are adapted so that there is possibly a radial clearance between an outer edge of the second element and an inner face of the groove. For example, the groove may have a depth of between 0.1 and 2 mm. By depth is meant the radial dimension of the groove. By way of non-limiting example, the groove may have a width of between 0.2 and 1 mm. By width is meant the axial dimension of the groove.

According to a second alternative of the starter contactor according to the first aspect of the invention, the first housing element forms a groove oriented radially outwardly of the contactor, the protection device comprising, at its second part, the second element. oriented radially towards the inside of the contactor. The protection device is located radially outside the groove, at least at its second part. More particularly, the protective device is located between the movable core and the groove. The protective device is arranged to prevent dust and particles from entering the housing.

The groove may be formed around the peripheral periphery of the first element or at least a portion of the peripheral periphery. If the groove is not formed around the peripheral periphery, it is formed on at least two parts of the periphery. Part means angular sectors of the same angle. The parts are regularly distributed angularly around the periphery. All parts have the same angular dimensions. Optionally, at least one part is different from the others, whether in shape or size. The axial dimensions of the groove are adapted to provide the axial clearance previously described as a function of the axial dimensions of the second element. The radial dimensions of the groove are adapted so that there is possibly a radial clearance between an outer face of the second element and an inner face of the groove. For example, the groove may have a depth of between 0.1 and 2 mm. By way of non-limiting example, the groove may have a width of between 0.2 and 1 mm.

According to a third alternative of the starter contactor according to the first aspect of the invention, the protection device, and in particular its second part, forms a groove oriented radially outwardly of the contactor, the housing comprising the first element oriented radially towards the inside of the contactor. The first element is located radially outside the gorge. More particularly, the first element is located between the movable core and the groove. The protective device is arranged to prevent dust and particles from entering the housing.

The groove may be formed all around the perimeter of the protective device or at least a portion of the periphery. If the groove is not formed around the peripheral periphery, it is formed on at least two parts of the periphery. Part means angular sectors of the same angle. The parts may or may not be angularly distributed around the periphery. All parts have the same dimensions. Optionally, at least one part is different from the others, whether in shape or size. The axial dimensions of the groove are adapted to provide the axial clearance previously described as a function of the axial dimensions of the first element. The radial dimensions of the groove are adapted so that there is possibly a radial clearance between an outer face of the first element and an inner face of the groove. For example, the groove may have a depth of between 0.1 and 2 mm. By way of non-limiting example, the groove may have a width of between 0.2 and 1 mm.

According to a fourth alternative of the starter contactor according to the first aspect of the invention, the protection device, and in particular its second part, forms a groove oriented radially towards the inside of the contactor, the housing comprising the first element oriented radially toward the inside of the contactor. outside the contactor. The first element is located radially inside the groove. More particularly, the first element is located between the movable core and the groove. The protective device is arranged to prevent dust and particles from entering the housing. The groove may be formed around the peripheral periphery of the second element or at least a portion of the peripheral periphery. If the groove is not formed around the peripheral periphery, it is formed on at least two parts of the periphery. Part means angular sectors of the same angle. Alternatively, the parts are angularly distributed around the periphery. All parts have the same dimensions. Optionally, at least one part is different from the others, whether in shape or size. The axial dimensions of the groove are adapted to provide the axial clearance previously described as a function of the axial dimensions of the first protection component. The radial dimensions of the groove are adapted so that there is possibly a radial clearance between an outer face of the first element and an inner face of the groove. For example, the groove may have a depth of between 0.1 and 2 mm. By way of non-limiting example, the groove may have a width of between 0.2 and 1 mm.

According to one embodiment of the invention, the protection 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.

During the translation of the movable core towards the inside of the coil, the first part of the protection device which is connected to the mobile core is moved in translation by the mobile core towards the second part of the protection device which collaborates with the housing by through the coupling device. In other words, the first part of the protective device is then driven by a translation movement which brings it closer to the second part of the protective device.

According to another characteristic of the invention, the first element of the coupling device forms a flat support against a face of the second element of the coupling device. By plane support means contacting a face of the first element with a face of the second element on an annular surface. This embodiment thus has the effect of increasing the contact surface between a face of the first element and a face of the second element of the coupling device, which results in an improvement of the capacity of the protective device to prevent particles. to enter the case. Alternatively, the second element of the coupling device comprises at least one sealing lip projecting from a plane delimiting a face of the second element of the coupling device. The presence of at least one lip makes it possible to generate a point contact of the second element on the first element. This point contact facilitates the separation of the second element to evacuate the air present in the chamber during actuation of the contactor.

By way of non-limiting example, a transverse profile of the sealing lip may be "V", "W", "U" or even slot.

By way of non-limiting example, the height of the sealing lip may be any value between 0.1 and 1 mm. The height of the lip is understood as the distance between the top of the lip and the base of the lip perpendicular to the apex.

The ratio between the height of the lip and the width of its base can be between 0.2 and 2.

The facing face of the housing may be flat or have a complementary or partially complementary profile of the sealing lip.

Alternatively, the sealing lip can be positioned on one of the faces of the first element opposite the second element. The face facing the sealing lip may be flat or have a complementary or partially complementary profile of the sealing lip.

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 attachment means are located on a radially extending portion of the movable core. Advantageously, the protective device is connected to the movable core by clipping or plating due to the pressure exerted by a return spring. Alternatively, the protective device may be bonded to the movable core by gluing, crimping or by any other means suitable for the invention.

According to a first embodiment, the first part of the protective device is integrally bonded to an axial end of the movable core which is farthest away 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 the outer part 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 radial extension of the movable core is integrally bonded to any part of the protection device.

According to one embodiment, the second element of the coupling device comprises at least one stiffening member for increasing its mechanical strength. Alternatively, the stiffening member may be inserted into the second member, or the second member may be overmoulded around the stiffening member. By way of non-limiting example, the stiffening member may be a metal ring.

More particularly, the stiffening member is arranged to prevent the second member from leaving the groove and / or to hold the second member between the first member and the housing.

According to a second aspect of the invention, it is proposed a method of implementation a starter contactor comprising a housing which houses at least one coil and a core which is movable in axial translation, a protection device limiting the entry of particles into the starter contactor, the protection device comprising a first part integrally connected to the movable core and a second portion collaborating with the housing through a coupling device, the coupling device having a first element on the housing and a second element on the protection device, wherein the second element of the coupling device separates from the first element of the coupling device during axial displacement of the movable core. The method according to the second aspect of the invention has the advantage of ensuring optimum sealing of the switch when it is in the initial position. The use of the starter contactor being short, this advantage has the effect of isolating prolonged starter contactor of the external environment charged with particles. According to another characteristic of the invention according to its second aspect, the method of implementation comprises the following steps:

(a) an initial step, defined as the step where the core is located substantially outside the housing, where the second element is pressed against a first face of the first element, the first face of the first element being defined as the face the first element located axially opposite the second element, and which is the furthest axially from the housing.

The term "plate" can indifferently designate a plane support from one face to another, a point contact between two points of the coupling device, or a crushing leading to an elastic deformation of a part of the second element.

(b) during a first phase of the axial translation of the movable core towards the inside of the housing, under the effect of the translation of the movable core towards the inside of the housing, the protection device performs the same translational movement; . The second element of the coupling device separates from the first face of the first element and is pressed against a second face of the first element. The second face is defined as the face of the first element situated axially opposite the second element and which is the closest axially of the housing.

(c) during a second phase of the axial translation of the movable core towards the inside of the housing, under the effect of the translation of the movable core towards the inside of the housing, the pressure inside a chamber delimited by the protective device and the mobile core increases. When the pressure inside the chamber is greater than that of the air outside the contactor, and more particularly when the pressure inside the chamber exceeds a certain threshold, more particularly the sum of the pressure inside the chamber and the pressure required to move the second element, then the second element of the coupling device is detached from the second face of the first element. When the pressure inside the chamber is lower than that of the air outside the contactor, then the second element of the coupling device is pressed against the second face of the first element.

(d) during a first phase of the translation of the movable core towards the outside of the housing, under the effect of the translation of the movable core towards the outside of the housing, the pressure inside the chamber decreases. When the pressure inside the chamber is lower than that of the air outside the contactor, and more particularly when the pressure inside the chamber passes below a certain threshold, more particularly the difference between the pressure of the air outside the contactor and the pressure required to move the second element, then the second element of the coupling device remains glued against the second face of the first element. Since the seal is not perfect, the depression inside the chamber is not sufficient to disturb the return movement of the mobile core. In addition, the volume of the chamber increases relatively little because the membrane is pressed against the movable core under the effect of the depression.

When the movable core reaches its rest position, the pressure inside the chamber becomes equal to that of the air outside the contactor, while the second element of the coupling device is pressed against the first face of the first element. Between steps (b) and (c) of the venting process, the translation of the mobile core does not change direction.

The invention also relates to a starter contactor comprising all the means arranged to implement this method.

According to a third 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.

Other characteristics, details and advantages of the invention will emerge more clearly on reading the description given below by way of non-limiting indication in relation to the appended drawings in which:

 FIG. 1 is a view in axial section of a starter contactor according to the invention,

 FIG. 2 is a view in axial section of a protection device according to the invention,

 FIG. 3 is a view in axial section of an alternative device according to the invention,

- Figures 4 (a) to (c) illustrate the coupling device of a starter switch according to the invention.

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, the fixed core, the moving shaft, the housing and the coil, while the radial orientations correspond to concurrent planes, and in particular perpendicular, to the axis (O). For the radial directions, the external or internal denominations are assessed with respect to the same axis (O), the inner denomination corresponding to the part closest to the axis.

The directions mentioned above are also visible in an orthonormal reference OXY shown in the figures.

Figure 1 shows a starter switch 1 fitted to 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 axis (O), and (ii) a protective device 6 limiting the entry of particles into the starter contactor 1, the protection device 6 comprising a first part 62 integrally connected to the movable core 4 and a second part 64 collaborating with the case 2 by means of a coupling device 8.

The housing 2, of generally cylindrical shape, defines an empty interior space 18, of circular cylindrical shape and whose axis (O) is an axis of axial symmetry.

The coil 3 is of annular shape forming an interior space 18 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 space 18 of the coil 3. The movable core 4 comprises a bore radially centered with the axis (O) and extending axially between the 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) allowing to put in position a starter gear (not shown) on a flywheel (not shown). The pinion is driven by the 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 portion thereof, a helical spring 11 is arranged to exert a repulsive force on the movable core 4, oriented along the axis (O) and in a outward direction of the housing 2. The spring 11 allows to push the movable core 4 out of the interior space 18 in the absence of supply of the coil 3. The spring 11 bears axially on the housing 2 on the one hand and on a terminal flange 20 of the movable core 4, on the other hand, the end flange 20 having the shape of an "S" shaped disc in a transverse plane and as illustrated in FIG. 1. The spring 11 compresses when the translation of the movable core 4 towards the interior of the starter contactor 1, and expands when the coil 3 is not polarized, then pushing the mobile core 4 out of the interior space 18 of the coil 3 thus corresponding to a so-called initial 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.

A 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 terminal flange 20 of the mobile core 4 on the one hand and the housing 2 on the other. A cover 14, arranged to form a rear chamber 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. A rear chamber 19 is delimited radially outwardly by the cover 14, and axially by the cover 14 on the one hand and by a fixed core 13 on the other. This fixed core 13 is arranged to separate the interior space 18 of the rear chamber 19. The fixed core 13 has the general shape of a disc. The fixed core 13 is delimited radially outwardly by an inner face of the housing 2. The fixed core 13 is delimited axially by the housing 2 on the one hand and by the cover 14 on the other hand.

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

The rear chamber 19 houses the electrical contact 15 and the electrical pads 16. The electrical pads 16 are disposed 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.

When the coil 3 is energized, the electromagnetic field attracts the movable core 4 into the inner space 18 of the coil 3. The movable core 4 translates axis (O) towards the inside of the housing 2. When entering the internal space 18, the movable core 4 compresses the spring 11 and the protective device 6. When the movable core 4 fits sufficiently in the housing 2, the movable core 4 also moves the movable shaft along the same axis (O) 12. The movable shaft 12 will move the electrical contact 15 disposed on the movable shaft 12 to bring it into 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 protective device 6 comprises a first portion 62 and a second portion 64. The first portion 62 comprises the succession of bellows 66. The first portion 62 extends axially between the second portion 64 and the end flange 20. The first portion 62 is disposed radially outside the movable core 4 and the spring 11. During the translation of the movable core 4, it is this first part 62 which is compressed by the displacement of the movable core 4. The second part 64 extends axially between the first portion 62 and the housing 2, and is delimited radially inwardly by the movable core 4 and the spring 11 and radially outwardly by the housing 2.

Advantageously, the first portion 62 and the second portion 64 of the protective device 6 are bonded together, forming a one-piece protective device. 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 disposed on the first end. part 62 of the protective device 6. The axial end 67 of the protective device 6 is fixed to the axial end 41 of the movable core 4 by overmolding the protective device 6 on the axial end 41 via the end flange 20 of the core mobile 4. Alternatively, the axial end 67 is fixed to the axial end 41 by plating the protective device 6 against the axial end 41 via the return spring 11. On the other side, the protective device 6 is linked integrally to the housing 2 via a coupling device 8. The coupling device 8 is located at the interface of the protection device 6 and the housing 2. This coupling device 8 keeps the protective device 6 in position despite the displacements caused by the movable core 4. It also balances the pressure between the chamber 9 and the outside of the starter switch 1.

The coupling device 8 comprises two parts, a first element 82 and a second element 84. The first element 82 is located on the housing 2 while the second element 84 is located on the second portion 64 of the protection device 6.

The first element 82 and the second element 84 have a profile complementary to each other. In the example of the invention, the second element 84 has the general shape of an annular extension around the second portion 64 of the protection device 6, the first element 82 having a shape complementary to this annular extension. By complementary, it is understood that the first element is housed in the second element or vice versa. Alternatively, the first element 82 may be an annular extension inwards and the second element 84 may have a shape complementary to this annular extension to the outside.

In the example of FIG. 2, the first element 82 is carried by an annular extension of the housing 2, issuing from the face of the housing 2 on the side of the movable core 4. The first element 82 forms an annular groove 83 around the axis (O). The groove 83 is delimited axially by a first abutment face 88 and a second abutment face 89 of the first element 82. The first abutment face 88 is defined as the face farthest from the housing 2 and facing towards the housing 2 while the second stop face 89 of the first element 82 is defined as the face closest to the housing 2 and facing away from the housing 2.

The groove is delimited radially outwards by an edge 92 which connects the two abutment faces 88 and 89 of the first element 82.

In this example of the invention, the first element 82 is shown attached to the housing 2, but the first element 82 may alternatively be made of material with the housing 2. The second element 84, carried by the second portion 64 of the protective device 6, comprises a flank 85 extending radially outwardly. This flank 85 is bounded radially outwards by an outer edge 93, and axially by a first plating surface 94 and a second plating surface 95.

The radially outward extending flank 85 is inserted into the groove 83 formed by the first element 82. An axial clearance (A) is provided between the second portion 64 of the protection device 6 and the housing 2. The elongation axial direction of the flank 85, measured between the first plating surface 94 and the second plating surface 95, is less than the axial dimension of the groove 83, measured between the first abutment face 88 and the second abutment face 89, so that there remains a residual space on one side or on both sides of the sidewall 85 with respect to the groove 83. Axial backlash is understood to mean a space in which the second portion 64 of the protection device 6 can perform an axis translation. (O). By way of non-limiting example, the axial clearance (A) is between 0.05 and 0.5 mm. Another range of axial clearances (A) can be between 0.1 and 0.4 mm. More specifically, the axial clearance (A) is less than 0.4 mm. Alternatively, the axial clearance (A) is less than 0.3 mm.

In this exemplary embodiment of the invention, the collaboration is done by a plane support of the second element 84 on the first element 82, in particular a support of the first plating surface 94 on the first abutment face 88. Referring now to Figure 3, we see an embodiment of the invention with a sealing lip 90 projecting from the second plating surface 95 of the second element 84 of the coupling device 8. The sealing lip 90 has a triangular section. At the tip of the triangular section, there is a punctual support of the sealing lip 90 on the second abutment face 89. This punctual support has an interest in facilitating the displacement of the second element 84 when the pressure inside of the chamber 9 increases, in order to limit the swelling phenomena of the protective device 6 According to one embodiment, the second element 84 of the coupling device 8 comprises at least one stiffening element intended to increase its mechanical strength. Alternatively, the stiffening member may be inserted into the second element 84, or the second element 84 may be overmoulded around the stiffening member. The stiffening member may be a metal ring.

Figures 4 (a) to (c) show the different states of the protection device 6 when using the starter switch 1 according to the invention. FIG. 4 (a) shows the initial state of the starter switch 1. The second element 84 is in contact with the first stop face 88 of the first element 82, the protection device 6 sealing the assembly. A channel 96, for balancing the pressure inside the chamber 9, is here open, the coupling device 8 is in the closed position and the starter switch 1 is in the initial position.

FIG. 4 (b) shows an active state of the starter contactor 1. The second element 84 is in contact with the second abutment face 89 of the first element 82. The channel 96 is here closed and the coupling device 8 is in position closure.

FIG. 4 (c) shows the active state of the starter contactor 1. The second element 84 is not in contact with the second abutment face 89 of the first element 82, the first abutment face 88 possibly being in contact separated from the first plating surface 94.

In this position, between the second abutment face 89 and the second plating surface 95, the channel 96 is open and it can be borrowed by the air escaping or entering the chamber 9. The coupling device 8 is in opening position. In the initial position, the starter switch 1 is in the state described in FIG. 4

(at). In the absence of supply of the coil 3, the spring 11 pushes the movable core 4, as well as the protective device 6 connected to the movable core 4, out of the interior space 18. The second element 84, located on the protection device 6 is also pushed back. This pushing will cause a contact between the first abutment face 88 of the first element 82 and the first plating surface 94 of the second element 84. The contact between the first element 82 and the second element 84 limits the entry of particles inside. of the chamber 9. Once pushed out of the inner space 18, the movable core 4 is stationary as the coil 3 is not powered.

During a phase of translation of the movable core 4 along the axis (O) towards the fixed core 13, the state of the starter contactor 1 is that described in FIG. 4 (b). The translation of the movable core 4 towards the interior of the starter contactor 1 causes the displacement of the protection device 6. The second element 84 leaves the first stop face 88 of the first element 82 and comes into contact with the second stop face 89 of the first element 82.

During this phase of translation of the movable core 4 along the axis (O) towards the fixed core 13, the starter contactor 1 can also be in the state described in FIG. 4 (c). The decrease in the volume in the chamber 9 causes an increase in the pressure of the air in the chamber 9. When the air pressure inside the chamber 9 exceeds the air pressure outside the chamber 9 the chamber 9, the second element 84 of the coupling device 8 separates from the second abutment face 89, which allows a balancing of the pressure between the chamber 9 and the outside of the chamber 9. When the pressure of the air has returned below the threshold, the second element 84 is again plated on the second abutment face 89 of the first element 82. This step of separating and plating the second element 84 on the different faces 88, 89 of the first element 82, allowing the pressure to be equalized between the chamber 9 and the outside of the starter switch 4, can be repeated one or more times during the translation of the movable core 4 towards the inside of the starter switch 1 if the pressure at inside the cham 9 exceeds the pressure outside the starter contactor 1.

During a phase of the translation of the movable core 4 along the axis (O) outside the coil 3, the state of the starter contactor 1 is that described in FIG. 4 (c). The translation of the movable core 4 towards the outside of the starter switch 1 causes a decrease in the pressure in the chamber 9. When the pressure inside the chamber 9 is lower than that of the air outside the contactor 1, then the second element 84 of the coupling device 6 remains stuck against the second abutment face 89 of the first element 82.

The invention described above allows a venting of the chamber 9 by a means that 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)

 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) limiting the entry of particles into the starter contactor (1), the protection device (6) comprising a first part (62) solidly connected to the movable core (4) and a second part ( 64) collaborating with the housing (2) via a coupling device (8),

characterized in that the coupling device (8) comprises:

 a first element (82) of the housing (2) and

 a second element (84) of the second part (64) of the protection device (6), the first element (82) and the second element (84) cooperating to provide axial clearance

(A) between the second portion (64) of the protection device (6) and the housing (2).

2. Starter contactor according to claim 1, characterized in that the coupling device (8) comprises at least one groove (83) in which is housed a flange (85) of radial extension.

Starter contactor according to claim 2, characterized in that the groove (83) is formed on the first element (82), while the side (85) of radial extension is provided at least on a part of a peripheral contour of the second part (64) of the protective device (6).

4. Starter contactor according to any one of the preceding claims, characterized in that the protection device (6) comprises a bellows membrane (66).

Starter contactor according to any one of the preceding claims, characterized in that the second element (84) of the coupling device (8) forms a flat support against a face (88, 89) of the first element (82) of the coupling device (8).

Starter contactor according to any one of the preceding claims, characterized in that the second element (84) of the coupling device (8) comprises at least one sealing lip (90) projecting from a plane (VV). ) delimiting a surface (95) of the second element (84) of the coupling device (8).

7. Starter contactor according to any one of the preceding claims, characterized in that the first element (82) of the coupling device (8) is made of material with the housing (2).

8. Starter contactor according to any one of claims 1 to 6, characterized in that the first element (82) of the coupling device (8) is attached to the housing (2).

9. Starter contactor according to any one of the preceding claims, characterized in that the axial play (A) is between 0.05 mm and 0.5 mm.

10. starter contactor according to any one of the preceding claims, characterized in that the first portion (62) of the protective device (6) is integrally bonded to the movable core (4) by an axial end (67) of the first part (62) of the protection device (6) furthest from the housing (2).

11. starter contactor according to any one of the preceding claims, characterized in that the first portion (62) of the protective device (6) is integrally bonded to an axial end (41) of the movable core (4) which is the further away from the housing (2).

12. starter contactor according to any one of the preceding claims, characterized in that the second element (84) of the coupling device (8) comprises at least one stiffening member for increasing its mechanical strength.

13. Method of implementing a starter contactor (1) comprising a housing (2) which houses at least one coil (3) and a movable core (4) in axial translation in the coil (3), a protection device (6) limiting the entry of particles into the starter contactor (1). ), the protection device (6) comprising a first portion (62) integrally connected to the movable core (4) and a second portion (64) collaborating with the housing (2) via a coupling device (8) , the coupling device (8) comprising a first element (82) located on the housing (2) and a second element (84) located on the protection device (6), in which process the second element (84) of the coupling device (8) separates from the first element (82) of the coupling device (8) during axial displacement of the movable core (4).

The method of claim 13, comprising the steps of:

(a) in the initial position, the second element (84) is pressed against a first face (88) of the first element (82),

(b) during a phase of axial translation of the movable core (4) towards the inside of the coil (3), the second element (84) of the coupling device (8) is pressed against a second face (89) of the first element (82) of the coupling device (8), (c) during the phase of axial translation of the movable core (4) towards the inside of the coil (3), the second element (84) of the coupling device (8) separates from the second face (89) under the effect of a pressure increase of the air present in a chamber (9) delimited at least in part by the protective device (6) and the movable core (4).

15. A starter characterized in that it comprises a starter contactor (1) as defined in any one of claims 1 to 12.