FR2927293A1 - WIPER BLADE FOR MOTOR VEHICLE - Google Patents

Abstract

The invention relates to a wiper blade (17) for a motor vehicle, of the type comprising a support structure (2) of elongate shape and a wiper blade (12) integral with the blade (17) via a heel (4) inserted longitudinally in the support structure (2), characterized in that the heel (4) comprises constraint means able to exert on the support structure (2), in the rest position of the blade (17), a constraint linear greater than or equal to 100 N / m.

Description

The invention relates to a windscreen wiper blade for a motor vehicle. A wiper blade 1 of the flat brush technology, also called flat blades, generally comprises, at its lower part and as shown in FIG. 1, a deformable longitudinal support structure 2, for example made of polypropylene. , extending longitudinally over the entire blade and adapted to receive a wiper blade 3 of rubber. The wiper blade 3 advantageously comprises: an upper part or bead 4 in the form of a longitudinal element having a substantially rectangular cross section with four rounded corners, a lower part 5 in the form of a longitudinal element having a triangular cross section, advantageously in the form of an isosceles triangle whose tip 5a is directly in contact with a window 10 to be wiped, and - an intermediate portion 8 in the form of a longitudinal member 20 having a cross section substantially in an arc whose two ends are directed towards the lower part 5. The upper 4 and intermediate 8 parts are interconnected by an upper said connecting element 11, and the intermediate 8 and lower 5 parts are also connected together by a lower link element 6. The support structure 2 is in the gen form of a hollow parallelepiped of C-shaped section whose corners are rounded and which is of complementary shape and dimensions slightly greater than the dimensions of the heel 4. The support structure 2 thus has two shoulders 7. 30 The heel 4 is fit to be inserted by sliding in the hollow space of the support structure 2. It comprises a lower face 14 and an upper face 15. The lower face 14 of the heel 4 is wedged on the shoulders 7. 2

The broom 1 and the blade 3 have at rest an axis of symmetry X in cross section. During the movement of the blade 1, on either side of the axis of symmetry X, according to the direction of movement of the blade 3, the wedging of the heel 4 is performed alternately on one or the other of the two 7. Simultaneously, one end of the opposite upper part of the heel 4 bears against the upper part of the support structure 2. This is shown in particular in FIG. 1. This rotational movement of the heel 4 in the support structure 2 is due to the game 9 related to the difference in size of the heel 4 and the support structure 2. This movement generates a significant noise, audible from inside the motor vehicle. In the context of the so-called conventional wiper blade technology, where the blade is held only locally on the rudder structure, it has been proposed to reduce the noise associated with this movement of the bead at level of its maintenance zone on the rudder structure, to provide the heel damping elements, intended to cushion the shocks between the heel and the holding zone. Document US 6,115,876 notably presents a solution to this effect.

But, this solution is not entirely satisfactory, because the noise caused is not significantly reduced. The present invention provides a wiper blade to significantly reduce the noise related to the movement of the heel in the support structure.

The invention thus relates to a wiper blade for a motor vehicle of the type comprising an elongate support structure and a wiper blade integral with the wiper via a heel inserted longitudinally into the support structure, characterized in that the heel comprises constraint means capable of exerting on the support structure, in the rest position of the blade, a linear stress greater than or equal to 100 N / m. 3

Thanks to this particular linear stress exerted by the set of the stressing means on the support structure, the heel is locked in the support structure, which prevents any relative movement between the heel and the support structure, and in particular any damping movement. , and thus greatly reduces the noise. In an advantageous application, the linear stress exerted by the stressing means on the support structure is greater than or equal to 150 N / m, and even more preferably greater than or equal to 200 N / m. Moreover, in order to promote the insertion of the heel into the support zone, the stressing means are prestressed. The blocking can thus be ensured by means of a heel provided with constraining means able to be constrained outside the operational configuration of the heel and to exert a stress on the support structure in the operational configuration of the heel. Such constraining means comprise, in the present case, elements projecting from the heel, in particular folding on the heel. Thus, during the prestressing step, the projecting elements are folded on the heel. In the operational configuration of the bead, the projecting elements folded down exert a stress on the support structure, due to the restoring force associated with the folded position. A linear stress greater than or equal to 100 N / m ensures the locking of the heel in the support structure. The heel may be provided with a lower face and an upper face, it may in particular be of substantially rectangular section, and the projecting elements may be derived from the lower face and / or upper of the insertion zone. The projecting elements are preferably derived from the lower face of the heel, for better resistance to tearing the heel during operation of the blade. They are advantageously of elongated shape, in particular of elongated U-shaped section or of rectangular shape whose angles are rounded and 4

may be inclined relative to the plane of the face, in the rest position of the blade. The blade generally has at rest an axis of symmetry in a cross section. In this case, the protruding elements are preferably two in number and are arranged symmetrically with respect to the axis of symmetry of the blade. In the case of flat brushes, the heel is mounted in the support structure along the entire length of the blade. The support structure is preferably deformable, so as to facilitate the insertion of the heel provided with stressing means, prestressed or not, in the support structure. It is possible to use all the shapes and / or dimensions of the stressing means and / or all the shapes and / or dimensions of the support structure providing a linear stress greater than or equal to 100 N / m. To facilitate the insertion of the heel of the blade into the support structure, especially in the case where the heel is lubricated, it advantageously comprises one or more ribs, arranged in the example presented longitudinally and able to be in contact with the the support structure. Other advantages and features of the invention will become apparent on reading the following description, given solely by way of non-limiting example, and with reference to the accompanying drawings, which are cross-sectional views, and in which: FIG. 1, already described, illustrates a portion of a wiper blade of the state of the art; FIG. 2 illustrates a wiper blade used in a wiper blade; according to the invention, according to a first embodiment, - Figure 3 illustrates a step of mounting the assembly of the blade, - Figure 4 illustrates a portion of the blade, during the scan, and - Figure 5 illustrates a part of a brush according to the invention, during the sweeping, according to a second embodiment.

The blade 12 illustrated in Figure 2, in which the elements identical to those of Figure 1 have the same references, comprises a heel 4 provided with two projecting elements 13 from the lower face 14 of the heel 4. The upper face 15 of the heel 4 comprises two ribs or pads 16. The ribs 16 are arranged in the direction of the length of the heel 4, so as to reduce the contact area between the heel 4 and the support structure 2 during the insertion of the heel 4 in the support zone, especially when lubricating the heel 4 during this insertion step. The projecting elements 13 are derived from the lower face 14 and are elongated U-shaped. They are inclined with respect to the axis of symmetry X and form an angle of about 45 ° with it. The projecting elements 13 are furthermore arranged symmetrically with respect to the axis of symmetry X of the blade 12. Each projecting element 13 delimits two parts of the lower face 14, namely a part close to the axis of symmetry X and a portion remote from the axis of symmetry X. The portion of the lower face 14 remote from the axis of symmetry X is preferably raised relative to the portion of the lower face 14 close to the axis of symmetry X, so as to favor the folded position of the projecting element 13 during the step illustrated in FIG. 3. Moreover, the projecting elements 13 extend continuously along the heel 4, in order to ensure a continuous blockage of the heel 4. FIG. 3, in which the elements identical to those of FIGS. 1 and 2 bear the same references, illustrates a step of mounting the blade 12 in the support zone 4. During this step, the so-called prestressing step, we do to the elements projecting ts 13 a preload A, the linear value of which is greater than or equal to 100 N / m, by compressing the projecting elements 13 towards the raised part of the lower face 14 of the heel 4. The projecting elements 13 are then in the folded position on the raised portion of the lower face 14. If necessary, any type of known device may be used to perform the preload A on the protruding elements 13. 6

To further facilitate the insertion of the heel 4 in the support structure 2, it can be subjected to a stretching B to enlarge the receiving zone of the heel 4. Always to facilitate the insertion of the heel 4 in the structure support 2, 5 the heel 4 is coated with a lubricant. In a variant, the bead 4 is inserted, without prestressing step, into the support structure 2 thus deformed by stretching. At the end of the insertion by sliding of the heel 4 in the support structure 2, we obtain the brush 17 shown in Figure 4. The heel 4 is blocked in the support structure 2 by the projecting elements 13. The elements protruding 13 are supported on the shoulders 7 and exert a restoring force on the support zone 2. The linear stress value greater than or equal to 100 N / m exerted by the protruding elements 13 on the support structure 2 can be obtained by adapting the length and width of the projecting elements 13, or alternatively the inclination angle at rest of the projecting elements 13 with respect to the axis of symmetry X. It can be easily measured by any known method of the invention. skilled in the art, for example using a dynamometer, or piezoelectric pressure sensors. Thus, for a support structure 2 defining a hollow space of height 2 mm and width 5 mm, and a heel provided with projecting elements 13 of width 0.4 mm, length 0.6 mm and forming at rest an angle 45 ° with the axis of symmetry X, the projecting elements 13 exert a linear stress of 150 N / m on the support structure 2. The heel 4 is thus immobilized in the support structure 2, in operational configuration of the blade 17 , without there being play or damping between the heel 4 and the support structure 2. This has the effect of stopping the rotational movement of the heel 4 in the support structure 2, and therefore the noise associated with this movement. 7

According to a second embodiment illustrated in FIG. 5, the projecting elements 13 are disposed on the upper face 15 of the heel 14. The projecting elements 13 are elongated U-shaped and are arranged symmetrically with respect to the X axis. , one towards the other. Each projecting element 13 delimits two parts of the upper face 15, namely a part close to the axis of symmetry X and a part remote from the axis of symmetry X. The part of the upper face 15 close to the axis of symmetry X is preferably lowered relative to the portion of the upper face 15 remote from the axis of symmetry X, so as to promote the folded position of the projecting element 13 during the prestressing step. In this embodiment, the ribs 16 are arranged longitudinally on the lower face 14 and are able to be in contact with the shoulders 7 of the support structure 2. Thus, the blade 17 allows a simple locking of the heel 4 in the support structure 2, without the need for complex structures with additional parts. The heel 4 is also easy to remove from the support structure 2. The brush 17 further allows a continuous blocking along the length of the heel 4. The blocking can thus be ensured in traditional brushes with pedals, but also advantageously in the brooms plats.20

Claims (10)

1. Wiper blade (17) for a motor vehicle, of the type comprising a support structure (2) of elongated shape and a wiper blade (12) integral with the blade (17) via a heel (4) inserted longitudinally in the support structure (2), characterized in that the heel (4) comprises stressing means (13) able to exert on the support structure (2), in the rest position of the brush (17), a higher linear stress or equal to 100 N / m. 2. wiper blade (17) according to claim 1, characterized in that the linear stress is greater than or equal to 150 N / m. 3. wiper blade (17) according to claim 1 or 2, characterized in that the constraining means (13) are prestressed. 4. Wiper blade (17) according to one of claims 1 to 3, characterized in that the constraining means (13) comprise projecting elements (13) of the heel (4). Windscreen wiper (17) according to claim 4, characterized in that the bead (4) is provided with a lower face (14) and an upper face (15), and that protruding elements (13) are derived from the underside (14) and / or upper (15). Wiper blade (17) according to Claim 5, characterized in that the projecting elements (13) have an elongated U-shaped section and are inclined with respect to the plane of the face (14, 15). in the rest position of the blade (12). Windscreen wiper (17) according to one of claims 4 to 6, characterized in that the blade (12) has at rest an axis of symmetry (X) in a cross-section, and that the projecting elements (13) are two in number and are arranged symmetrically with respect to the axis of symmetry (X) of the blade (12). 8. wiper blade (17) according to one of claims 1 to 7, characterized in that the heel (4) is mounted in the support structure (2) over the entire length of the blade (17). 9. Wiper blade (17) according to one of claims 1 to 8, characterized in that the support structure (2) is deformable. 10. Wiper blade (17) according to one of claims 1 to 9, characterized in that the heel (4) further comprises one or more ribs (16) arranged longitudinally and adapted to be in contact with the support structure (2). 10