WO2024061994A1 - Magnetic connection device for a wiper system - Google Patents

Abstract

The present disclosure relates to a connection device for a system for wiping an optical surface of a motor vehicle, the connection device being configured to be mounted on a wiper blade of the wiper system and being configured to co-operate with a drive arm so as to enable the drive arm and the wiper blade to be assembled, the connection device comprising an adapter element configured to co-operate with the drive arm so as to attach the drive arm to the connection device, the adapter element comprising: - at least one first and one second co-operating member, at least the first co-operating member comprising a magnetic element, and - at least one ferromagnetic element arranged facing an inner surface formed by the first and second co-operating members.

Description

Magnetic connection device for a wiping system FIELD OF INVENTION

This presentation concerns a connection device for a system for wiping an optical surface of a motor vehicle.

TECHNOLOGY BACKGROUND

Generally speaking, wiping devices for motor vehicles comprise at least one drive arm, a wiper blade comprising a wiping blade. The drive arm is removably connected to the wiper blade by a connection device comprising mechanical holding elements for holding the wiper blade mounted on the drive arm during moving movements. angular back and forth of the latter.

Due to wear or in the event of impact, these mechanical holding elements are likely to break. However, the standards in force impose a specific level of resistance to the disengagement of the wiper blade from the drive arm. There is therefore a need in this sense.

The purpose of this presentation is to propose a magnetic connection system for a wiping system of an optical surface of a motor vehicle having a level of resistance to disengagement between the windshield wiper blade and the drive arm sufficient while remaining compact.

PRESENTATION OF THE INVENTION

The present presentation relates to a connection device for a wiping system of an optical surface of a motor vehicle, the connection device being configured to be mounted on a windshield wiper blade of the wiping system and being configured to cooperate with a drive arm so as to allow assembly of the drive arm and the wiper blade, the connection device comprising an adapter element configured to cooperate with the drive arm so to fix the drive arm on the connection device, the adapter element comprising:

- at least a first cooperation member configured to emit a primary magnetic flux towards the drive arm and second cooperation member configured to capture the primary magnetic flux, the first and second cooperation members forming a cooperation surface configured to cooperate with the drive arm, the primary magnetic flux being configured to interact with the drive arm so as to attract it towards the first and second cooperation members, at least the first cooperation member comprises a magnetic element, and

- at least one ferromagnetic element arranged facing an internal surface formed by the first and second cooperation members, the internal surface being opposite the cooperation surface, the ferromagnetic element being configured to guide a secondary magnetic flux emitted by the second cooperation body towards the first cooperation body.

An advantage of the present presentation is to propose a connection device having a sufficiently powerful attractive power to allow the drive arm to be fixed to the windshield wiper blade in a secure manner. Such a connection device also makes it possible to prevent the drive arm from separating from the wiper blade when the function of wiping and/or cleaning the optical surface of the motor vehicle is activated.

The connection device in this presentation also has the advantage of being compact and of securing the attachment of the drive arm to the windshield wiper blade.

Another advantage of the connection device in this presentation is that it makes it possible to improve the ergonomics of mounting and dismounting the wiper blades on the drive arms. Thus, such a connection device makes it easier for users to replace wiper blades in the event of wear.

An additional advantage of the present presentation is that the ferromagnetic element makes it possible to avoid the dispersion of the secondary magnetic flux. In other words, the ferromagnetic element allows the secondary magnetic flux to be “concentrated”.

By magnetic element we mean an element previously magnetized, for example, via its submission to an electromagnetic field.

According to one aspect of this presentation, the first and second cooperation bodies can be distinct elements or be formed as a single piece. By a single piece we mean a one-piece element.

According to one aspect of this presentation, the one-piece element is an element previously magnetized, for example, via its subjection to an electromagnetic field.

For example, the first cooperation member is constituted by a magnetic element.

According to one aspect of the present presentation, the connection device extends in a longitudinal direction, the first and second cooperation members being aligned in the longitudinal direction and forming the cooperation surface configured to cooperate with the drive arm.

According to one aspect of the present presentation, the connection device extends in a direction transverse to the longitudinal direction, the first and second cooperation members being aligned in the transverse direction.

According to one aspect of this presentation, the first cooperation member is a magnetic element which can be made of rare earths, for example neodymium, or any material known to those skilled in the art having similar magnetic properties.

According to one aspect of this presentation, the ferromagnetic element extends in the longitudinal direction.

According to one aspect of the present presentation, the ferromagnetic element extends in the transverse direction.

According to one aspect of this presentation, the ferromagnetic element is made of metallic material, such as steel.

The advantage which emerges from this configuration is that the connection device comprises a reduced number of magnetic elements and therefore has a reduced manufacturing cost, while having sufficient attractive power to allow secure attachment of the drive arm to the broom. wiper.

According to one aspect of the present presentation, the first cooperation body comprises a first so-called north polarity partly forming the cooperation surface.

According to one aspect of this presentation, the second cooperation body comprises a second so-called south polarity partly forming the cooperation surface.

According to one aspect of the invention, the first and second polarities are opposite.

We understand that the first cooperation body comprises a first polarity oriented towards the north.

It is also understood that the second cooperation body includes a second polarity oriented towards the south.

According to one aspect of this presentation, the first cooperation member comprises a third polarity called south polarity partly forming the internal surface.

According to one aspect of the present presentation, the second organ comprises a fourth polarity called north, partly forming the internal surface.

According to one aspect of the present disclosure, the first polarity and the third polarity are opposite.

According to one aspect of the present disclosure, the second polarity and the fourth polarity are opposite.

According to one aspect of the present disclosure, the first polarity and the fourth polarity are identical.

According to one aspect of the present disclosure, the second polarity and the third polarity are identical.

According to a characteristic of the present presentation, the first and third polarities of the first cooperation member are aligned in a vertical direction, perpendicular to both the longitudinal direction and the transverse direction.

According to a characteristic presented here, the second and fourth polarities of the second cooperation member are aligned in the vertical direction.

According to an optional characteristic, the first cooperation body is at a distance from the second cooperation body.

For example, a ferromagnetic spacer is placed between the first and second cooperation members. In this configuration, the ferromagnetic spacer extends the effect of the attractive power of the magnetic element at least of the first cooperation member.

Here, the first and second cooperation members have a length of between 4 and 8 mm and a thickness of approximately 1 mm. In this case, the spacer has a width of at most 1mm, preferably the width of the spacer is between 0.5 and 1mm. This makes it possible to reduce manufacturing costs of the connection device by reducing the quantity of magnetic elements used. This characteristic also makes it possible to avoid the loss of magnetic flux between the first and second cooperation members.

For example, the first and second cooperation bodies are separated by a space, making it easier to insert the first cooperation body.

According to a first embodiment, the second cooperation member comprises a magnetic element.

According to a characteristic of the first embodiment, the magnetic element included in the second cooperation member is a magnet made of rare earths, such as ferrites, alnico, samarium, cobalt, iron or even boron, preferably neodymium.

According to a second embodiment, the second cooperation member comprises a ferromagnetic element.

It is understood that the difference between the first embodiment and the second embodiment is the substitution of the magnetic element of the second cooperation member by a ferromagnetic element.

According to an optional characteristic, the second cooperation body is integral with the first cooperation body.

According to an optional characteristic, the first cooperation member is inserted in a housing formed by the ferromagnetic element and the second cooperation member.

For example, the housing is frustoconical, thus forming the space between the first and second cooperation members makes it easier to insert the first cooperation member.

According to a characteristic of the present presentation, the connection device comprises a chassis, the chassis forming a reception zone configured to receive the adapter element. In this configuration, the chassis makes it possible to secure the magnetic elements and protect them from corrosion, which could lead to a loss of the attractive power of the magnetic elements.

According to one aspect of this presentation, the chassis extends in the longitudinal direction and in the transverse direction.

According to a characteristic of this presentation, the chassis is made of a magnetically neutral material.

For example, the chassis is made of plastic.

According to a characteristic of this presentation, the chassis has a general U shape.

According to one aspect of the present presentation, the reception zone is configured to receive the ferromagnetic element.

According to one aspect of this presentation, the ferromagnetic element is glued, overmolded, assembled by elastic interlocking on the chassis. It is also possible to assemble the ferromagnetic element to the chassis by ultrasonic welding.

According to one aspect of this presentation, the ferromagnetic element as well as the first and second cooperation members are overmolded or glued to the chassis.

According to one aspect of this presentation, the ferromagnetic element as well as the first and second cooperation members are held on the chassis by retaining walls.

According to a characteristic of the present presentation, the chassis comprises first and second portions, the first and second portions being respectively adjacent to the first and second cooperation members.

According to one aspect of the present presentation, the first and second portions extend the cooperation surface and the internal surface in the transverse direction.

According to one aspect of the present presentation, the ferromagnetic element extends in the longitudinal direction over a length greater than the length of the first and second cooperation members, the ferromagnetic element abutting against the first and second portions.

According to one aspect of this presentation, the chassis comprises a protective element configured to at least partially cover the cooperation surface, the protective element making it possible to protect the magnetic elements from corrosion, which can lead to the loss of the attractive power of the magnetic elements. .

According to one aspect of this presentation, the protective element extends in the longitudinal direction.

According to one aspect of this presentation, the protective element extends in the transverse direction.

It is understood that the protection element is configured to close the reception zone so as to protect the adapter element. This configuration has the advantage of protecting the magnetic elements of the adapter element from corrosion and maintaining their positioning in the vertical direction.

According to a characteristic of this presentation, the protective element is made of a magnetically neutral material allowing the passage of magnetic fluxes.

According to a characteristic of this presentation, the protective element is made of plastic material, making it possible to ensure good sealing and to avoid corrosion of the magnetic elements of the adapter element.

The invention and its advantages will be better understood on reading the detailed description which follows, of embodiments of the invention given by way of non-limiting examples. This description refers to the attached drawings, in which: is a representation of an overview of a wiping system of a motor vehicle

is a representation of an overview of an adapter member and a chassis

is a representation of an adapter element

is a representation of a perspective view of a ferromagnetic element

is representation of a vertical section of a connection device according to a first embodiment

is a representation of a vertical section of the connection device according to a variant of the first embodiment

is a representation of a vertical section of a connection device according to a second embodiment

is a representation of a perspective view of the adapter element covered with a protective element

is a representation of a vertical section of the connection device according to a second variant of the second embodiment,

is a representation of a vertical section of the connection device according to a third variant of the second embodiment,

is a representation of a cross section of the connection device according to a fourth variant of the second embodiment,

is a representation of a cross section of the connection device according to a fifth variant of the second embodiment.

DETAILED DESCRIPTION OF THE INVENTION

There is an overview of a wiping system 12 of an optical surface of a motor vehicle. The wiping system 12 comprises a windshield wiper blade 13 and a drive arm 2. The movement of the wiper blade 13 is induced by the drive arm 2. The arm 2 is also connected to an actuator (not shown) such as a motor making it possible to drive the arm 2 in movement. The blade 13 comprises a wiping blade 15 in direct contact with the glass surface of the vehicle so as to allow it to be wiped.

The arm 2 comprises a rod 18 comprising a first end connected to the actuator (not shown) and a second end crimped in a yoke 16 forming an endpiece allowing connection with the brush 13.

There represents a connection device 14 and a connector 19. The connector 19 and the connection device 14 are configured to cooperate and allow the fixing of the brush 13 on the arm 2. The connector 19 is mounted integrally on the brush 13. The connection device connection 14 is pivotally mounted on the connector 19 along an axis T extending in a transverse direction. The transverse direction T is substantially perpendicular to a longitudinal direction L of the blade 13. The connection device 14 is configured to cooperate with the yoke 16 of the drive arm 2 so as to fix the blade 13 on the arm 2.

The connection device 14 comprises an adapter element 1, shown in , a chassis 7, a ferromagnetic element 5 and a plurality of cooperation members 25, here six cooperation members 3,4.

The plurality of cooperation members 25 is mounted on the ferromagnetic element 5. The cooperation members 3, 4 of the plurality of cooperation members 25 are here aligned in the longitudinal direction L. The cooperation members 3, 4 of the plurality of cooperation bodies 25 could also be aligned in the transverse direction T.

The plurality of cooperation members 25 forms a cooperation surface 6 configured to cooperate with the drive arm 2 and an internal surface 9 opposite the cooperation surface 6.

The internal surface 9 of the plurality of cooperation members 25 cooperates with the ferromagnetic element 5 represented in .

The ferromagnetic element 5 is here also configured to allow the maintenance of the plurality of cooperation members 25 via retaining walls 22, allowing the maintenance of the plurality of cooperation members 25 in the longitudinal direction L.

The cooperation members 3, 4 can be fixed to the ferromagnetic element 5 for example by gluing, ultrasonic welding or by elastic nesting, the elastic nesting being made possible for example thanks to the curved shape of the retaining walls 22.

The ferromagnetic element 5 is mounted on the chassis 7. For example, the ferromagnetic element 5 comprises at least one mounting element, here, mounting walls 20 making it possible to mount for example by elastic interlocking the ferromagnetic element 5 on the chassis 7, the chassis 7 forming a slide. To do this, the mounting walls 20 are curved here.

In the remainder of the presentation, a pair of cooperation bodies formed by a first cooperation body 3 and a second cooperation body 4 of the plurality of cooperation bodies 25 will be described. This description is applicable to other pairs of cooperation bodies of the plurality of cooperation bodies 25.

At least the first cooperation member 3 among the plurality of cooperation members 25 is configured to emit a primary magnetic flux in the direction of the drive arm 2 and the second cooperation member 4 is configured to capture the primary magnetic flux, the primary magnetic flux being configured to interact with the drive arm 2 so as to attract it towards the first and second cooperation members 3, 4, at least the first cooperation member 3 comprises a magnetic element, and the ferromagnetic element 5 being configured to guide a secondary magnetic flux emitted by the second cooperation member 4 towards the first cooperation member 3.

Each cooperation body 3, 4 includes two polarities. The first cooperation element 3 comprises a first polarity and a third polarity, aligned in the vertical direction V. The second cooperation member 4 comprises a second and a fourth polarity, aligned in the vertical direction V. The first and the second polarity form partly the cooperation surface 6. The first and second polarities are reversed. For example, the first polarity is oriented to the north and allows the emission of the primary magnetic flux and the second polarity is oriented to the south allowing the capture of the primary magnetic flux.

The third and fourth polarities are oriented towards the ferromagnetic element. The third and fourth polarities are reversed. For example, the fourth polarity is oriented to the north and allows the emission of a secondary magnetic flux and the third polarity is oriented to the south to capture the secondary flux emitted by the fourth polarity.

More particularly, during its movement, the secondary flux is first emitted towards the ferromagnetic element 5, which is configured to capture the secondary flux and guide it towards the third polarity.

We understand that the ferromagnetic element is configured to concentrate the secondary magnetic flux and to guide it from the fourth polarity of the second cooperation element towards the third polarity of the first cooperation element, here.

There is a representation of a vertical section of the connection device 14 according to a first variant of the first embodiment.

Here, the connection device 14 comprises four cooperation members 3, 4.

This first variant differs from what was described above in that the chassis 7 comprises a receiving housing configured to receive the ferromagnetic element 5 and the plurality of cooperation members 25.

This first variant also differs from what was described above in that the cooperation members 3, 4 of the plurality of cooperation members 25 are aligned in the transverse direction T.

In this first variant, the chassis 7 comprises a U-shaped section. The adapter element 1 can be secured to the chassis 7 by any means known to those skilled in the art, for example by gluing. The chassis 7 can be made of a magnetically neutral material such as plastic.

Here, the cooperation surface is configured to be in direct contact with the drive arm 2.

There is a representation of a vertical section of the connection device 14 according to a second variant. The device of the differs from that of the in that the ferromagnetic element is overmolded in the chassis 7. In other words, the chassis 7 comprises a first portion 9a and a second portion 9b, each of the first 9a and second portions 9b extending from the free edges side walls 23 of the U and configured to be overmolded with the ferromagnetic element.

Here, the plurality of cooperation members 25 is arranged between the first 9a and second 9b portions. The cooperation bodies 3, 4 of the plurality of cooperation bodies 25 are aligned in the extension of the first and second portions 9a, 9b.

More particularly, the first 9a and second portions 9b extend the cooperation surface 6 and the internal surface 9.

Here, the ferromagnetic element 5 therefore extends over a length greater than the length of the four cooperative members 3.4 combined in the transverse direction. The ferromagnetic element 5 is therefore retained in the vertical direction by the first and second portions 9a, 9b.

The plurality of cooperation members 25 can be fixed on the ferromagnetic element 5 by any means known to those skilled in the art, for example by bonding.

In a second embodiment, the second cooperation member 4 comprises a ferromagnetic element 5 and is devoid of magnetic element.

There is a representation of a vertical section of the connection device 14 according to a first variant of the second embodiment. This first variant of the second embodiment is similar to the first variant of the first embodiment in that the second cooperation member 4 is made of ferromagnetic material. The second cooperation member 4 can therefore receive the primary magnetic flux emitted by the first cooperation member at the level of the cooperation surface 6, creating its south polarity and emit via its north polarity, which is created at the level of the internal surface 9 , the magnetic flux.

There is a representation of a perspective view of the adapter element 1 which differs from the in that the adapter element 1 comprises a protective element 8 configured to cover the plurality of cooperation members 25. For example, the protective element 8 is formed by a magnetically neutral material, for example plastic. This makes it possible to protect the cooperation bodies 3, 4 from the external environment. Thus, the drive arm 2 is not directly in contact with the cooperation surface 6 but in contact with the protection element 8.

There is a representation of a vertical section of the connection device 14 according to a second variant of the second embodiment. The second variant of the second embodiment differs from the first variant shown in in that the adapter element 1 comprises a protective element 8 covering the cooperation surface 6.

There is a representation of a vertical section of the connection device 14 according to a third variant of the second embodiment previously described for the . This variant differs from the embodiment described for the in that the protective element 8 is made of ferromagnetic material or of non-ferromagnetic material . In the case of a protection element 8 made of ferromagnetic material, the thickness of the protection element 8 does not exceed 1 mm. In the case of a protection element 8 made of non-ferromagnetic material, the thickness of the protection element 8 does not exceed 0.2 mm. This characteristic prevents the magnetic flux from losing its intensity.

There is a representation of a vertical section of the connection device 14 according to a fourth variant of the second embodiment, which differs from that shown on the by the presence of a space 10 between the cooperation bodies 3, 4 of the plurality of cooperation bodies 25. This makes it possible to facilitate the assembly of the cooperation bodies 3, 4 of the plurality of cooperation bodies 25.

There is a representation of a vertical section of the connection device 14 according to a fifth variant of the second embodiment.

As illustrated on the , this variant differs from that described for the in that the cooperation members 3, 4 of the plurality of cooperation members 25 are frustoconical in shape. The adjacent cooperation members 3, 4 are mounted in an inverted manner. In the variant shown in , the second cooperation member 4 can be made integrally with the ferromagnetic element 5. In this case, the frustoconical shape of the cooperation members 3, 4 makes it possible to facilitate the insertion of the first cooperation member 3.

The second cooperation member 4 can also be distinct from the ferromagnetic element 5. This makes it easier to mount the plurality of cooperation members 25 and to reinforce the maintenance of the cooperation members 3, 4 of the plurality of members. cooperation 25 with each other.

There concerns the second embodiment but the frustoconical shape of the cooperation members 3, 4 of the plurality of cooperation members 25 is also applicable to the first embodiment.

Although the present invention has been described with reference to specific embodiments, modifications may be made to these examples without departing from the general scope of the invention as defined by the claims. In particular, individual features of the different illustrated/mentioned embodiments can be combined in additional embodiments. Therefore, the description and drawings should be considered in an illustrative rather than a restrictive sense.

Claims (9)

1. Connection device (14) for a system for wiping an optical surface of a motor vehicle, the connection device (14) being configured to be mounted on a windscreen wiper blade (13) of the system. wiping and being configured to cooperate with a drive arm (2) so as to allow the assembly of the drive arm (2) and the wiper blade (13), the connection device (14) comprising an adapter element (1) configured to cooperate with the drive arm so as to fix the drive arm (2) on the connection device, the adapter element (1) comprising:
   at least a first cooperation member (3) configured to emit a primary magnetic flux towards the drive arm (2) and second cooperation member (4) configured to capture the primary magnetic flux, the first and second members (3) ,4) of cooperation forming a cooperation surface (6) configured to cooperate with the drive arm (2), the magnetic flux being configured to interact with the drive arm so as to attract it towards the first (3 ) and second cooperation members (4), at least the first cooperation member (3) comprises a magnetic element, and
   at least one ferromagnetic element (5) arranged facing an internal surface (9) formed by the first (3) and second cooperation members (4), the internal surface (9) being opposite the cooperation surface (6 ), the ferromagnetic element (5) being configured to guide a secondary magnetic flux emitted by the second cooperation member (4) towards the first cooperation member (3).
2. Connection device according to claim 1, extending in a longitudinal direction (L), the first and second cooperation members (3,4) being aligned in the longitudinal direction (L).
3. Connection device according to any one of the preceding claims, comprising a frame (7), the frame (7) forming a receiving area configured to receive the adapter element (1).
   [Claim 4]: Connection device according to any one of the preceding claims, in which the frame (7) comprises a protective element 8 configured to cover the cooperation surface (6).
4. Connection device according to any one of the preceding claims, characterized in that the first cooperation member (3) comprises a first polarity called north at the level of the cooperation surface and the second cooperation member (4) comprises a second polarity said south forming at least partly the cooperation surface (6), the first and second polarities are opposite.
5. Connection device according to any one of the preceding claims, characterized in that the first cooperation member (3) comprises a third polarity called south at the level of the internal surface and the second cooperation member (4) comprises a fourth polarity called north forming at least partly the internal surface (9), the third and fourth polarities being opposite.
6. Connection device according to any one of the preceding claims, characterized in that the second cooperation member 4 comprises a magnetic element.
7. Connection device according to any one of claims 1 to 6, characterized in that the second cooperation member (4) comprises a ferromagnetic element (5).
8. Connection device according to any one of the preceding claims, characterized in that the first and second cooperation members 4 are arranged at a distance from each other.
9. Connection device according to claim according to any one of the preceding claims, characterized in that the magnetic element is formed by a material chosen from rare earths.