Patent Grant
6971830
The invention relates to the fixing of a part onto a panel. This could be for example, for an automotive vehicle, fixing a bumper to a body component or a lining to a door.
More specifically, it relates to a device that, for the fixing of the part to the panel, comprises a saddle with an upper arm and a facing lower arm, connected by a plate and drilled with coaxial holes.
To fix the part to the panel, both of which have drillings to this end, the saddle is mounted on the edge of the panel in such a way that its arms are on either side of it, with their respective holes facing the drilling made in the panel, and the plate of the saddle is facing the edge of the panel.
The part to be fixed is then positioned on the lower arm of the saddle, with its drilling placed facing the hole made in the arm.
A screw is then inserted into the drilling in the part, and is pushed successively through the lower arm and then the panel, before being screwed into the upper arm, tightening both the part to the lower arm and the panel between the arms.
The known devices of this type present a number of disadvantages.
Firstly, the positioning of the saddle on the panel is difficult, especially because, as we have seen, it must be placed over the drilling made in the panel. Mounting the saddle is made even more problematic when it is done blind, as there is no means of checking if it is correctly positioned.
Then, the saddle's hold on the panel is often inadequate. It is common, particularly in the automotive field, to mount the saddle some time before the screw is inserted, these two operations being carried out at different stations. It is therefore frequent, particularly under the effect of the vibrations experienced by the vehicle when it is transferred from one station to another, for one or more saddles to move along the edge of the panel, or even fall off it. They therefore have to be repositioned to allow for screwing. This leads to losses in productivity.
In addition, a specific type of saddle generally corresponds to a certain panel thickness, and cannot be mounted either on a thicker panel or a thinner panel.
Moreover, problems are often encountered with the rigidity and hold of the fixing produced.
The invention aims to solve the aforementioned disadvantages in particular, by proposing a fixing device that is both easy and practical to use under all circumstances, including blind, that allows for a part to be fixed to panels of varying thicknesses, and that is more reliable in such a way as to allow for durable, rigid fixing.
To this end, the invention proposes a device for fixing a part to a panel provided with a drilling, the said device comprising a saddle equipped with an upper arm and a facing lower arm that together define an opening opposite which they are connected by a plate. The upper and lower arms respectively have coaxial upper and lower holes, the upper arm having a shank forming a nut in which the upper hole is made, and the arms being able to be placed on either side of the panel with their holes facing the aforementioned drilling whilst the plate is placed facing the edge of the panel. The lower arm is equipped with an elastically flexible lug articulated by a rim located on the side of the opening and in which the lower hole is made, the lug having a ridge that protrudes from the lower arm towards the upper arm and is able to be lodged in the aforementioned drilling to allow for the saddle to be snapped onto and thus fixed to the panel.
Given this specific embodiment of the saddle, its correct positioning on the panel is characterised by an audible click, which assures the user that the ridge has been received in the drilling in the panel, and that the holes in the arms are correctly facing the said drilling.
In this context, the saddle is guaranteed to hold on the panel under any circumstances even before the screw is inserted.
According to one embodiment, the aforementioned ridge has a face that slopes towards the aforementioned opening, in order to allow for the gradual pushing aside of the lug when the saddle is mounted, under the pressure of the panel.
For example, the ridge extends circularly around the edge of the hole made in the lug.
The upper arm has, for example, a ramp that slopes towards the opening, able to guide the panel towards the lower arm when the saddle is mounted.
The lower arm may have, on the side of the aforementioned opening, a chamfered free edge, in order to further guide the panel.
Preferably, the plate is thicker than the arms, whilst the upper arm is thicker than the lower arm, in such a way that the lower arm has a certain flexibility that facilitates the mounting of the saddle onto the panel.
According to one embodiment, the aforementioned lug is delimited by a U-shaped cut-out, the concavity of which faces the aforementioned opening.
For example, the aforementioned shank protrudes at least partly on the outer side of the upper arm, on which side it is preferably ribbed in order to provide increased stiffness, particularly in torsion.
The shank may also protrude partly on the inner side of the upper arm; it may be extended, on this side, by a ridge able to be lodged in the drilling made in the panel when the saddle is mounted on it, which further increases the hold of the saddle on the panel.
In addition, the upper arm may have, on the inner side, a collar protruding radially from the shank, against which the panel may press.
According to one embodiment, the upper arm also has an elastically flexible tongue that protrudes towards the lower arm and is able to push the panel towards the lower arm to improve the hold of the saddle on the panel.
This tongue may, for example, stem from the aforementioned collar, which increases its flexion capacity.
The description below of an embodiment given as a non-exhaustive example highlights other characteristics and advantages of the invention; the description is given with reference to the appended drawings, in which:
The panel 1 and the part 2 to be fixed are, for example, two body components of a vehicle under production or repair, such as, respectively, a chassis component and a bumper component or, respectively, a door component and a lining designed to cover it.
As shown in
The part 2 and the panel 1 are assembled by means of a fixing device 3 comprising a saddle 4 forming a nut, which is mounted on the panel 1, and a screw 5 (
To enable the screw 5 to be passed through, the panel 1 has a circular section drilling 6 with axis A1 located near its edge 7 (
Referring to
The saddle 4 has an upper arm 11 and a lower arm 12, approximately flat and parallel, with a rectangular general outline, which have facing inner faces 13, 14 and opposing outer faces 15, 16.
The arms 11, 12 have free edges 17, 18 respectively between which they define an opening 19 through which the saddle 4 is mounted on the panel 1 (
The upper arm 11 and the lower arm 12 are drilled, respectively, with an upper hole 21 and a lower hole 22 that face each other and are coaxial, and the common axis A3 of which is perpendicular to the arms 11, 12.
As will be seen below, the upper arm 11 has a shank 23 forming a nut in which the upper hole 21 is made and in which the screw 5 (
The lower arm 12 is equipped with an elastically flexible lug 24 that, in the absence of load, extends generally in the plane of the arm 12.
The lug 24, in which the lower hole 22 is made, is articulated to the arm 12 by a rim 25 located on the side of the opening 19 and that extends approximately parallel to the free edge 18 of the arm 12, close to it.
As shown in
On the outer side of the lower arm 12, i.e. on the side of the outer face 16 of the arm, the lug 24 is flush with the external face 16 in the absence of load.
On the other hand, on the inner side of the lower arm 12, i.e. on the side of its internal face 14, the lug 24 has a lower ridge 27 that extends beyond the inner face 14 and protrudes from the lower arm 12 towards the upper arm 11 and is lodged in the drilling 6 in the panel 1 when the saddle 4 is mounted, to enable the saddle 4 to be snapped onto and thus fixed to the panel 1, as will be seen below.
The lower ridge 27, which extends circularly around the lower hole 22 on the edge of the hole, does not have a constant height.
In fact, it has a front section 28 that extends at an angle of approximately 90° from the articulation rim 25, and the height of which, measured from the inner face 14 perpendicular to it, increases towards the plate 20.
This front section 28 thus forms a face 29 that slopes towards the opening 19, the sloping face 29 forming a runway that tends to push the lug 24 outwards under the pressure of the panel 1 when the saddle 4 is mounted on the latter.
This front section 28 is extended by a rear section 30 that extends at an angle of approximately 90°, the height of which is constant.
As can be seen on
Thus, the ridge 27 is asymmetrical and extends mainly on one side only of the hole 22; this specific feature is due to a moulding requirement, in this case to allow for the lateral removal of mould slides from the mould.
In order to increase the area of the lower arm 12, in particular to recover the area lost due to the cut-out 26, the arm 12 has locally, around the lug 24, a circular profile 33 which, through the protrusion it forms, can assist in mounting polarisation when the saddle 4 is mounted on the panel 1 in certain specific cases, as will be seen below.
In addition, in order to assist in guiding the panel 1 into the opening 19 between the arms 11, 12, the edge 18 of the lower arm 12 is chamfered at 34, as shown on
However, the guidance is mainly provided by a sloping ramp 35 formed on the upper arm 11, facing towards the opening 19 and extending from the upper hole 21 to the free edge 17 of the upper arm 11, which is, as can be seen in
Moreover, the upper arm 11 is even curved outwards in the vicinity of its free edge 17.
Thus, working in conjunction with the edge 7 of the panel 1 (
Moreover, as can be seen in
In this way, the angle section formed by the plate 20 and the upper arm 11 presents a certain rigidity that makes it relatively indeformable when the saddle 4 is mounted on the panel 1, whilst the lower arm 12 is relatively deformable and is able to flex elastically under the pressure of the panel 1.
The shank 23 has a generally cylindrical upper section 36 that protrudes from the outer side of the upper arm 11, i.e. on the side of the external face 15 of the upper arm 11. As shown on
The shank 23 also has a lower section 38 that, continuing on from the upper section 36, protrudes beyond the inner side of the upper arm 11, i.e. on the side of the inner face 13 of the upper arm 11.
As shown on
This cooperation between the bearing face 40 and the collar 39, and the panel 1, takes place at least on screwing, which tends to bring the arms 11, 12, between which the panel 1 will be held, closer together.
However, this cooperation may also take place when the saddle 4 is mounted, depending on the thickness of the panel 1 (
In fact, in order to provide, even before the addition of the screw 5, reliable hold of the saddle 4 on the panel 1, however thick it is, the upper arm 11 is equipped with an elastically flexible tongue 41 that protrudes towards to the lower arm 12.
This tongue 41 is located between the upper hole 21 and the plate 20; it has a cylindrical free end 42 that, close to the inner face 13 of the upper arm 11, extends parallel to both the inner face 13 and the plate 20.
When the saddle 4 is mounted on the panel 1, the tongue 41 flexes in the direction of the plate 20 under the pressure of the panel 1, which meets and then slides on its free end 42.
Under the effect of its own elasticity, the tongue 41 pushes the panel 1 towards the lower arm 12, and holds it firmly against it.
As can be seen on
In addition, the lower section 38 of the shank 23 is extended, on the other side of the collar 39 relative to the inner face 13, by an upper ridge 44, similar to the lower ridge 27 described above, but that mainly extends, relative to the lower ridge, on the other side of a plane perpendicular to the plate 20 that passes through the axis A3 of the holes 21, 22, such plane being the general plane of symmetry of the saddle 4.
As previously, this specific shape is due to a moulding requirement with the aim of allowing for the lateral removal of a mould slide from the mould.
In the same way as the lower ridge 27, the upper ridge 44 has a front section 45, which extends at an angle of approximately 90°, and the height of which increases from the ramp 35 towards the plate 20.
This front section 45 forms a sloping face 46 that extends as a continuation of the ramp 35; it is extended by a rear section 47 that has a constant height and extends at an angle of approximately 90°.
When the saddle 4 is mounted on a sufficiently thick panel 1, as can be seen on
Moreover, in order to automatically centre the upper hole 22 relative to the drilling 6, the upper ridge 44 has a tapered outer surface 48 (
In addition, as can be seen on
Referring to FIGS. 4 and 8–11, the part 2 is fixed onto the panel 1 as follows.
First, the saddle 4 is mounted on the panel 1, which has a thickness e (
Thus, in the example shown in
In the example shown in
In the example shown in
The edge 7 of the panel 1 is guided by the ramp 35 and then the sloping face 46. It pushes the tongue 41, which, in reaction, pushes it towards the lower arm 12.
The panel 1 slides on the sloping face 29 formed on the lower ridge 27, which causes the gradual pushing aside of the lug 24 and, possibly, slight flexion in the lower arm 12 when the thickness e of the panel 1 is sufficient (this is particularly the case when the thickness e of the panel 1 is equal to the distance D).
When the axes A1 of the drilling 6 and A3 of the holes 21, 22 are approximately convergent, the inner ridge 27 is lodged in the drilling 6, the lug 24 returning through elasticity to its idle position with an audible click, as shown on
When the thickness e of panel 1 is sufficient, as shown on
Whatever the thickness e of the panel 1, it is then gripped, either between the tongue 41 and the lower arm 12, (
Thus, when the saddle 4 is in mounted position, the arms 11, 12 are on either side of the panel 1, their holes 21, 22 facing the drilling 6 with their respective axes A3, A1 converging, whilst the plate 20 is placed facing its edge 7. The saddle 4 is therefore snapped onto and thus fixed to the panel 1, which is held against the lower arm 12 with the lower ridge 27 only or both ridges 27, 44 in its drilling 6.
The part to be fixed 2 is then held against the outer face 16 of the lower arm 12 by positioning its orifice 8 facing the lower hole 22, their respective axes A2, A3 being approximately convergent.
The screw 5 is inserted into the orifice 8, the aforementioned screw 5 passing successively through the lower hole 22 and the drilling 6 before engaging in the shank 23. As the screw 5 is self-tapping, it works its internal thread in the shank 23, in which the hole 21 has a smaller diameter than the hole 22 in the lug 24, with which the screw 5 does not interfere.
As the screw 5 is rotated, the two arms 11, 12 come closer together (given the relative thickness of the arms 11, 12 and the plate 20, this moving together mainly consists of the flexion of the lower arm 12 towards the upper arm 11) until the panel 1 is gripped between them, whilst the part 2 is gripped between the lower arm 12 and the screw head 10, the fixing of the part 2 thus being achieved.
It is possible that the saddle 4 has to be mounted in a predetermined direction on the panel 1, which may be equipped with mounting polarisation means to this end.
According to an embodiment illustrated in
Thus, when the saddle 4 is being mounted the wrong way round, the circular profile 33 abuts against the ribs 50, which prevents the saddle 4 from being mounted. The saddle 4 must simply be turned around and mounted in place, the upper arm 11 being lodged between the ribs 50.
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| 02 08117 | Jun 2002 | FR | national |
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| Number | Date | Country | |
|---|---|---|---|
| 20040001743 A1 | Jan 2004 | US |
