EP2331776A1

EP2331776A1 - Remote control device with stowable key, in particular for an automobile

Info

Publication number: EP2331776A1
Application number: EP09809347A
Authority: EP
Inventors: Marc David
Original assignee: Valeo Securite Habitacle SAS
Current assignee: Valeo Comfort and Driving Assistance SAS
Priority date: 2008-09-01
Filing date: 2009-08-28
Publication date: 2011-06-15
Anticipated expiration: 2029-08-28
Also published as: EP2331776B1; FR2935418A1; FR2935419A1; JP5739331B2; WO2010023293A1; US20110179838A1; FR2935418B1; US8770001B2; US20110259064A1; JP2012501392A; EP2331777A1; WO2010023294A1; CN102232134A; FR2935419B1; JP2012501393A; US8763434B2; JP5650645B2; EP2331777B1; CN102216546A; CN102232134B

Abstract

The invention relates to a remote control device with a stowable key, in particular for an automobile, which comprises a remote control casing including two lower (1) and upper (2) shells, an insert (3) defining a key-bit pivotally mounted between an extended use position and a stowed position inside the casing, and an elastic return mechanism for returning the insert to the extended position, which comprises a push button (4) provided on the upper shell (2). According to the invention, the insert (3) rotates directly about said button (4) which is rotatingly connected with the upper shell (2), and includes rotational indexing means with said insert (3) that can be declutched by pushing said button (4).

Description

REMOTE CONTROL DEVICE WITH A RETRACTABLE KEY, ESPECIALLY A MOTOR VEHICLE

The invention relates to a remote control device with retractable key, particularly a motor vehicle.

Such a key comprises a remote control housing comprising two shells, upper and lower, a bit forming a bit pivotally mounted about an axis between an extended position of use and a retracted position internal to the housing and an elastic return mechanism of the insert to the deployed position comprising a circular cylindrical pressing button disposed on the so-called upper shell. It is known from patent document EP 1 609 931 to provide a bell-shaped element comprising an indexing means adapted to cooperate with a corresponding indexing means of the lower shell, so as to preload a spring after assembly of an ejection mechanism including the button, in the housing. The operating knob per se is mounted above this bell on an axis snapped on the lower shell and, completely independent, it does not undergo any effort when deploying the insert.

This type of press button does not rotate during the deployment of the insert, unlike other embodiments where the button is secured in rotation with the insert and rotates with it from the deployed position to the retracted position and vice versa . In these latter cases, braking of the insert may result from the action or friction of the driver's finger on the button during the deployment command. However, the embodiment described in EP 1 609 931 is on the one hand relatively complex constitution with a large number of parts to mount, axis, bell and button per se. On the other hand, it turns out that the bending strength of the insert, in the deployed position, is insufficient because the indexing of the bell on the lower shell is performed on a relatively small surface. However, automobile manufacturers may be required to have a high flexural strength. The invention solves these problems by providing a retractable key remote control device, particularly a motor vehicle, ensuring a better bending strength of the insert, in the deployed position, and particularly simple constitution, while maintaining a non-rotating button when moving the insert. To do this, the invention proposes a retractable key remote control device, particularly a motor vehicle, comprising a remote control housing comprising two shells, upper and lower, a bit insert pivotally mounted between a deployed position of use and a retracted position internal to the housing and an elastic return mechanism of the insert to the deployed position comprising a press button disposed on said upper shell, characterized in that said insert rotates directly around said button, which is secured in rotation with the upper shell and comprises indexing means in rotation with said insert, disengageable by pushing said button.

The button serves as an axis of rotation of the insert, which ensures a minimum number of parts to form an elastic return mechanism. In fact, these parts are two in number, the button and a return spring. This button is secured in rotation with the upper shell which can allow the realization of relatively large contact surfaces, even in the deployed position of the insert. This results in a better bending strength of the insert in the deployed position. The knob being motionless in rotation, the occupied volume which would be occupied by a rotation is then useful to the mechanical resistance.

Moreover, the apparent end of the button may be of any shape, for example ovoidal or parallelepipedal.

According to a preferred embodiment, said button is secured in rotation with the upper shell by means of several first radial studs nested in corresponding first cavities of the upper shell.

Preferably, said upper shell has an extra thickness at the location of said first cavities. This extra thickness, achievable on the upper shell, improves the bending strength of the insert in the deployed position.

Advantageously, said indexing means consist of at least one second radial stud fitted with a corresponding second cavity of the insert in the retracted position and disengaged by translation during deployment of the insert.

Said second radial tenon may be disposed at the lower end of the button.

Preferably, said knob is substantially cylindrical in shape. Preferably, said elastic return mechanism comprises a helical spring working in torsion and in compression. Advantageously, said spring is disposed inside said button and acts in compression between the insert and the upper closed end of the button.

Said spring may have its ends locked in rotation on the insert and on the button.

The invention also relates to a prefabricated module for the realization of such a retractable key remote control device, characterized in that it comprises a yoke of said insert, said knob and said spring. The invention is described in more detail with the aid of figures representing only preferred embodiments of the invention.

Figure 1 is an exploded perspective view of a retractable key remote control device according to the invention.

Figure 2 is an exploded partial perspective view of the upper shell and the button, a retractable key remote control device according to the invention.

Figure 3 is a partial perspective view of the upper shell and the button, a retractable key remote control device according to the invention. Figure 4 is a partial perspective view of the insert and the spring of a retractable key remote control device according to the invention.

Figure 5 is a partial perspective bottom view of the insert of a retractable key remote control device according to the invention.

As illustrated in FIG. 1, the remote control device with a retractable key, in particular a motor vehicle, complies with the invention comprises a remote control housing comprising two shells, lower 1 and upper 2, an insert 3 forming a bit pivotally mounted between an extended position of use and a retracted position internal to the housing and an elastic return mechanism of the insert towards the deployed position comprising a press button 4 disposed on the upper shell 2.

The housing is intended to receive the constituent parts of remote control and the upper shell 2 is intended to be equipped remote control operating members. The insert 3 consists of a yoke 3A and the bit itself 3B secured by pin.

The button 4 is substantially hollow cylindrical in shape and is inserted into a bore 3C of the yoke 3A.

The insert 3, or more exactly its yoke 3A, is mounted on the knob and rotates directly around the latter, which is secured in rotation with the upper shell 2 and comprises indexing means in rotation with the yoke 3A, disengageable by pressing button 4.

The button 4 is secured in rotation with the upper shell 2 by means of several first radial tenons 4A, here three in number, nested in corresponding first cavities 2A of the upper shell 2, as shown in Figures 2 and 3. The upper shell 2 has an excess thickness 2C at the location of these first cavities. The directional notions of top, bottom, top and bottom used hereinafter relate to the positioning direction shown in FIG. The indexing means consist of at least one second radial pin 4B fitted with a corresponding second cavity of the yoke of the insert in the retracted position and disengaged by translation downward during the deployment of the insert. In the embodiment shown, two such second pins 4B are provided, as well as two such cavities 3B in the yoke 3A visible in FIGS. 4 and 5. These second radial tenons 4B are arranged at the lower end of the button 4.

The elastic return mechanism also comprises a helical spring 5 working in torsion and in compression.

This spring 5 is disposed inside the button 4 and acts in compression between the yoke 3A of the insert and the upper closed end of the button 4, once the closed housing. It therefore pushes, by compression, the button 4 upwards, in a bore 2A of the upper shell, in the rest position.

In this rest position, where the insert 3 is in the retracted position inside the housing, the second tenons 4B of the button are arranged in the second cavities 3B of the yoke 3A of the insert 3 and blocks in rotation the insert. These through cavities 3B are in fact formed between radial ribs 3C internal to the bore 3C of the yoke 3A, arranged at a corresponding height at the lower end of the button, in this rest position.

The spring 5 has its lower end 5A locked in rotation on the yoke 3A of the insert, inserted in a 3D groove arranged on the bottom 3E of the latter, and its upper end 5B locked in rotation at the bottom of the button, on its wall closed 4C. In said rest position, it is thus prestressed in torsion.

To deploy the insert, the driver presses the press button 4 which is translated downwards, compressing the spring 5. Given the height of the first tenons 4A and the excess thickness 2C, these tenons remain engaged in the first cavities 2A and the button remains locked in rotation by connection with the upper shell 2. The second pins 4B are moved downwards and reach a level below the ribs 3C of the yoke of the insert, which is then released in rotation. The spring 5 then releases its torsional prestressing energy and drives this yoke in rotation to the deployed position. In this deployed position, the second tenons 4B of the button are each vis-à-vis with a non-through cavity 3F arranged under each of the radial ribs 3C. Under the compression effect of the spring 5, the button is pushed upwards, the second tenons 4B being housed in these non-through cavities 3F. The insert 3 is then again locked in rotation with the button which is also locked in rotation with the upper shell IB with a large abutment surface of the first tenons 4A, ensuring a good resistance to bending.

During a retraction of the insert, the driver presses the press button 4 which is translated downwards, compressing the spring 5.

The second tenons 4B are moved downwards, out of the non-through cavities 3F and reach a level below the ribs 3C of the yoke of the insert, which is then released in rotation. The insert 3 can therefore be brought back manually in the retracted position, the spring 5 then being prestressed in torsion. In this retracted position, the second tenons 4B of the button are each vis-à-vis with a through cavity 3B arranged between the radial ribs 3C. Under the compression effect of the spring 5, once released, the button is pushed upwards, the second tenons 4B being housed in these through cavities 3B. The insert 3 is then locked again in rotation with the button which is also locked in rotation with the upper shell IB.

During its rotation, the yoke 3A is guided by abutment against a rib IA arranged on the lower shell 1 and by guiding a post in a semicircular groove IB also arranged on the lower shell.

The assembly of the clevis 3A of the insert, the button 4 and the spring

5 can be pre-assembled, with the spring prestressed. The arrangement according to the invention thus allows a prefabrication of such a module that can be produced and delivered by a supplier to the manufacturer of the remote control device.

Claims

1. Remote control device with retractable key, in particular of a motor vehicle, comprising a remote control housing comprising two shells, lower (1) and upper (2), an insert (3) forming a bit pivotally mounted between an extended position of use and a retracted position internal to the housing and an elastic return mechanism of the insert to the deployed position comprising a press button (4) disposed on the so-called upper shell (2), characterized in that said insert (3) rotates directly around said button (4), which is secured in rotation with the upper shell (2) and comprises indexing means in rotation with said insert (3), releasable by pushing said button (4).

2. Device according to claim 1, characterized in that said knob (4) is secured in rotation with the upper shell (2) by means of several first radial tenons (4A) nested in corresponding first cavities (2A) of the hull higher.

3. Device according to claim 2, characterized in that said upper shell (2) has an extra thickness (2C) at the location of said first cavities (2A).

4. Device according to one of the preceding claims, characterized in that said indexing means are constituted by at least a second radial pin (4B) fitted with a corresponding second cavity (3B) of the insert (3). position retracted and disengaged by translation during the deployment of the insert.

5. Device according to claim 4, characterized in that said second radial lug (4B) is disposed at the lower end of the button (4).

6. Device according to one of the preceding claims, characterized said knob (4) is substantially cylindrical shape.

7. Device according to one of the preceding claims, characterized in that said elastic return mechanism comprises a helical spring (5) working in torsion and compression.

8. Device according to claim 7, characterized in that said spring (5) is disposed inside said button (4) and acts in compression between the insert (3) and the closed end (4C) upper button .

9. Device according to claim 8, characterized in that said spring has its ends (5A, 5B) locked in rotation on the insert (3) and on the button (4).

10. Prefabricated module for the realization of a retractable key remote control device according to one of claims 1 to 6 and according to one of claims 7 to 9, characterized in that it comprises a yoke (3A) of said insert , said knob (4) and said spring (5).