CH712574B1 - Device for controlling at least two electronic and / or mechanical functions of a portable object. - Google Patents

Abstract

The invention relates to a device for controlling at least two electronic and / or mechanical functions of a portable object of small dimensions, this device comprising a control rod (4) which is axially movable between at least a first and a second position, said control rod (4) being provided at a first end with an actuating member, and being provided on the side of a second end with a position indexing plate (58) arranged to cooperate with a elastic member for aligning each of the first and second positions of the control rod (4) with one of the mechanical or electronic functions.

Description

Description

TECHNICAL FIELD OF THE INVENTION [0001] The present invention relates to a device for controlling at least two electronic and / or mechanical functions for a portable object of small dimensions. More specifically, the invention relates to such a device comprising a control rod provided with a mechanical position indexing device which makes it possible to make each electronic or mechanical function coincide with a position distinct from the control rod.

BACKGROUND OF THE INVENTION [0002] The present invention relates to the field of control rods which equip small portable objects such as timepieces and which are arranged to control one or more electronic functions and / or mechanical objects.

[0003] In a very simplified manner, the control rods of this type comprise a cylindrical portion whose length is substantially greater than the diameter and at one end of which located outside the portable object is fixed a crown allowing a user to operate the control rod and adjust the electronic or mechanical functions. In the case where these rods control several functions, it is necessary to be able to match each given function with a determined position of the control rod.

An example of such a control rod is shown in FIG. 22 attached to this patent application. Designated as a whole by the general reference numeral 200, this control rod comprises a cylindrical portion 202 terminated at its end located outside the portable object (not shown) which is equipped with an actuating ring 204. Towards its opposite end to the actuating ring 204, the cylindrical portion 202 of the control rod 200 is provided with a cam path 206 formed of three successive annular grooves 208a, 208b and 208c separated from each other by two beads 210a and 210b with substantially rounded profiles. The dimensions of the annular grooves 208a-208c are adapted to those of the elastic arms 212 of a spring 214 for example U-shaped protruding for example in the annular groove 208a of the cam path 206. It is understood that to pass the elastic arms 212 of the spring 214 of the annular groove 208a in the annular groove 208b, it is necessary that the user exerts on the control rod 200 a tensile force greater than the force required for these elastic arms 212 to move and slide on the bead 210a before closing on the annular groove 208b. Conversely, if it is desired to pass the elastic arms 212 of the spring 214 of the annular groove 208b in the annular groove 208a, it is necessary to exert on the control rod 200 a sufficient thrust to allow these elastic arms 212 to deform to cross the bead 210a and fall into the annular groove 208a. The same applies for the transition of the elastic arms 212 of the spring 214 of the annular groove 208b in the annular groove 208c and vice versa.

Thus, by cooperation between the resilient arms of a spring and a cam path which comes from material with the cylindrical portion of a control rod, it is advantageously possible to define for example three stable positions of the rod of which each correspond to the setting of a given function. The disadvantage of this solution lies in the fact that, in order to be able to machine the cam path in the cylindrical portion of the control rod, the diameter of the cylindrical portion of the control rod must be relatively large, which means that makes the use of such a control rod quite difficult or impossible, especially in the field of wristwatches where one does not wish to have to machine holes of large diameters in the caseband, especially for questions of thickness of the middle part. SUMMARY OF THE INVENTION [0006] The object of the present invention is to overcome the problems mentioned above as well as others by providing a device for controlling at least two electronic and / or mechanical functions comprising a rod. whose diameter is small enough that it can be used especially in the field of watchmaking.

For this purpose, the present invention relates to a device for controlling at least two electronic and / or mechanical functions of a portable object of small dimensions, this device comprising a movable control rod axia-lement between at least a first and a second position, this control rod being provided at a first end with an actuating member, and being provided on the side of a second end of a position indexing plate arranged to cooperate with an organ resilient to align each of the first and second positions of the control rod with one of the mechanical or electronic functions.

According to other features of the invention which form the subject of the dependent claims; the indexing plate extends substantially in a horizontal plane in which the control rod extends; the elastic member comprises two resilient arms which cooperate with two identical cam paths which extend symmetrically on either side of a longitudinal axis of symmetry (XX) of the control rod in the indexing plate of position to define the first and second positions of the control rod; the two cam paths define an unstable position and a stable position of the control rod, or the two cam paths define a first and a second stable position of the control rod; in the case where the two cam paths define a first stable position and a second stable position of the control rod, the cam paths comprise a first hollow separated from a second hollow by a vertex, the first and second recesses defining the first and second stable positions of the control rod, the resilient arms of the elastic member passing from the first depression to the second depression and vice versa over the top; in the case where the two cam paths define a stable position and an unstable position of the control rod, the cam paths comprise a recess which defines the stable position and from which the resilient arms of the elastic member extend to engage on a ramp profile that moves the elastic arms away from their rest position and defines the unstable position of the control rod; - The position indexing plate is housed in a groove in the control rod; the position indexing plate is integral with the control rod, or the position indexing plate is detachably coupled to the control rod; in the case where the position indexing plate is releasably coupled to the control rod, the coupling between the position index plate and the control rod is an elastic coupling provided to prevent disengagement between the plate. position indexing and control rod under normal conditions of use.

With these features, the present invention provides a device for controlling at least two electronic or mechanical functions whose dimensions are contained, which allows to install such a control device in a portable object of small dimensions such as in particular a wristwatch. Indeed, the mechanical structure that indexes the position of the control rod is moved from the actual control rod to a position indexing plate which is machined separately from the control rod. Such a plate is relatively thin and further extends in a substantially horizontal plane, whereas, when the mechanical indexing structure of the position is formed on the control rod, it makes it necessary to increase the diameter of the control rod and therefore the height of the middle part of the portable object, so that the portable object is thicker, which is to be avoided especially in the field of timepieces.

On the other hand, in the control device according to the invention, the friction is virtually eliminated in order to limit wear to the maximum and ensure a longevity of the largest possible control device. In addition, the less friction is important, the easier is the manipulation of the control rod, particularly in unstable thrust position. In order to reduce this friction to the maximum, it is particularly important to note that none of the electrical contacts that are made in the control device according to the invention are made by friction. All electrical contacts are abutting one piece against another. We therefore have much less wear than in the case of parts that rub against each other. The same is true for the position indexing plate whose upward movement is limited by the limiting spring with which the position indexing plate, and therefore the control rod, is not in contact, however. under normal operating conditions. In this case too, no friction is observed.

Finally, the fact that the control rod and the indexing plate are not mounted in an inseparable way ensures the removable nature of the control device, which is advantageous especially in the case where the piece of watchmaker equipped with the control device according to the invention is of a certain price.

Note also that all the electrical contacts that operate in the control device according to the invention are galvanic type, which means that in the absence of electrical contact, the power consumption of the control device is nothing.

BRIEF DESCRIPTION OF THE FIGURES [0013] Other features and advantages of the present invention will emerge more clearly from the following detailed description of an exemplary embodiment of a control device according to the invention, this example being given purely by way of example. illustrative and not limiting only in connection with the accompanying drawing in which: FIG. 1 is a perspective view in the dissociated state of a device for controlling at least one electronic function of a portable object of small dimensions; fig. 2 is a perspective view from above of the lower frame; fig. 3 is a perspective view of the control rod which, from right to left, extends from its rear end to its front end; fig. 4 is a perspective view in the dissociated state of the magnetic assembly consisting of a support ring and a magnetic ring and the plain bearing; fig. 5 is a longitudinal sectional view along a vertical plane of a control device inside which are arranged in particular the sliding bearing and the magnetic assembly formed of the support ring and the magnetic ring; fig. 6 is a perspective bottom view of the upper frame; fig. 7A is a perspective top view of the position indexing plate of the control rod; fig. 7B is a view on a larger scale of the area surrounded by a circle in FIG. 7A; fig. 8 is a perspective view of the positioning spring arranged to cooperate with the index plate of the position of the control rod; fig. 9 is a perspective view from above of the spring for limiting the displacement of the indexing plate of the position of the control rod; fig. 10 is a perspective view of the dislocation plate; fig. 11 is a longitudinal sectional view of a portion of the control device on which is visible the hole in which is introduced a sharp tool to release the control rod of the position indexing plate; fig. 12A is a perspective view on which is visible the control rod cooperating with the indexing plate of the position and the positioning spring, the control rod being in a stable position T1; fig. 12B is a view similar to that of FIG. 12A, the control rod being in a stable position TO; fig. 12C is a view similar to that of FIG. 12A, the control rod being in stable pulled position T2; fig. 13 is a perspective view of the contact springs TO and T2; figs. 14A and 14B are schematic views which illustrate the cooperation between the fingers of the indexing plate of the position of the control rod and the contact springs T2; fig. 15 is a partial perspective view of the flexible printed circuit sheet on which are mated the contact pads of the contact springs TO and T2; fig. 16 is a perspective view of the free portion of the flexible printed circuit sheet to which the inductive sensors are attached; fig. 17A is a perspective view of the control device on a rear side of which the free portion of the flexible printed circuit sheet is folded; fig. 17B is a perspective view of the control device on a rear side of which the flexible printed circuit free portion is folded and held by means of a holding plate secured by screws to the control device; fig. 18 is a perspective view of the controller installed in a portable object; fig. 19 is a view similar to that of FIG. 18, the control rod being extracted from the portable object; fig. 20A is a perspective top view of the control rod position indexing plate which defines two stable positions only; fig. 20B is a view on a larger scale of the area surrounded by a circle in FIG. 20A; fig. 21A is a perspective top view of the control rod position indexing plate which defines a stable position and an unstable thrust position only; fig. 21B is a view on a larger scale of the area surrounded by a circle in FIG. 21A, and FIG. 22, already mentioned, is a perspective view of a control rod according to the prior art.

DETAILED DESCRIPTION OF AN EMBODIMENT OF THE INVENTION [0014] The present invention proceeds from the general inventive idea of transferring an indexing mechanism of the position of a control rod of at least two electronic functions. and / or mechanical small portable object such as a timepiece from this control rod to a plate machined separately from said control rod. By proceeding in this way, it is possible to reduce the diameter of the control rod and therefore reduce concomitantly the thickness of the middle part of the portable object such as a timepiece. This result is achieved by the fact that the indexing mechanism which is typically in the form of two cam paths cooperating with an elastic member, instead of being structured directly on the control rod, is made in a thin plate which constitutes a separate part of the control rod and which is mechanically coupled with the latter. As the control rod is devoid of its indexing mechanism, its diameter can be decreased, and the position indexing plate according to the invention, because of its small thickness, does not cause a significant increase in Congestion of the control rod according to the invention.

In all that follows, the direction from rear to front is a rectilinear direction which extends horizontally along the longitudinal axis of symmetry XX of the canceled stem from the external actuating ring to the inside of the portable object equipped with the control device. Thus, the control rod will be pushed from the back to the front, and will be pulled from the front to the back. Moreover, the vertical direction z is a direction that extends perpendicularly to the plane in which the control rod extends.

FIG. 1 is a perspective view in the dissociated state of a device for controlling at least one electronic function of a portable object of small dimensions such as a wristwatch. Designated as a whole by the general numerical reference 1, this control device comprises (see FIG 2) a lower frame 2 for example made of an injected plastic material or a non-magnetic metallic material such as brass. This lower frame 2 serves as a cradle for a control rod 4 of preferentially elongate and substantially cylindrical shape, provided with a longitudinal axis of symmetry X-X (see FIG 3). This control rod 4 is arranged to slide back and forth forwards along its longitudinal axis of symmetry XX, and / or to rotate about the same longitudinal axis of symmetry XX in a clockwise and counterclockwise direction. .

At a rear end 6 which will be located outside the portable object once it is equipped with a control device 1, the control rod 4 will receive an actuating ring 8 (see fig. 18).

At a front end 10 which will be located inside the control device 1 once it is assembled, the control rod 4 has a section 12 for example square and successively receives a magnetic assembly 14 and a plain bearing 16.

The magnetic unit 14 comprises a magnetic ring 18 bipolar or multipole and a support ring 20 on which the magnetic ring 18 is fixed typically by gluing (see Figure 4). The support ring 20 is a generally cylindrical piece. As shown in fig. 5, the support ring 20 has, from the rear towards the front, a first section 22a of a first outer diameter D1 on which is engaged the magnetic ring 18, and a second section 22b of a second outer diameter D2 greater than the first outer diameter D1 and which delimits a shoulder 24 against which the magnetic ring 18 bears. The first section 22a of the support ring 20 is pierced with a square hole 26 which is adapted in shape and size to the square section 12 of the control rod 4 and forms with this control rod 4 a pinion type system flowing. In other words, the support ring 20 and the magnetic ring 18 remain motionless when the control rod 4 is slid axially. On the other hand, the control rod 4 drives the support ring 20 and the ring magnet 18 rotating when rotating the control rod 4. It is understood from the foregoing that the magnetic ring 18, carried by the support ring 20, is not in contact with the control rod 4, this which makes it possible to protect it in the event of shocks applied to the portable object equipped with a control device 1.

The sliding bearing 16 defines (see FIG 5) a cylindrical housing 28 whose first internal diameter D3 is slightly greater than the diameter of the circle in which the square section 12 of the control rod 4 fits in order to allow to this control rod 4 to slide axially and / or to rotate inside this cylindrical housing 28. The sliding bearing 16 thus guarantees the perfect axial guidance of the control rod 4.

Note that the square hole 26 formed in the first section 22a of the support ring 20 is extended towards the front of the control device 1 by an annular hole 30 whose second inner diameter D4 is adjusted to the third diameter D5 outer bearing of the sliding bearing 16. The support ring 20 is thus threaded free to rotate on the plain bearing 16 and comes into axial abutment against this sliding bearing 16, which ensures the perfect axial alignment of these two parts and allows to correct the problems of concentricity that can pose a coupling of the type sliding pinion.

It is observed that, for its axial immobilization, the sliding bearing 16 is provided on its outer surface with a circular flange 32 which protrudes into a first groove 34a and into a second groove 34b formed respectively in the lower frame 2 (FIG. see Fig. 2) and in an upper frame 36 (see Fig. 6) arranged to cover the lower frame 2 and for example made of an injected plastic material or a non-magnetic metallic material such as brass. These two lower frames 2 and upper 36 will be described in detail later.

It is important to note that the magnetic assembly 14 and the sliding bearing 16 described above are indicated for purely illustrative purposes only. Indeed, the plain bearing 16, for example made of steel or brass, is provided to prevent the control rod 4, for example made of steel, from rubbing against the lower frame 2 and upper 36 and causes wear of the material plastic in which these two lower frames 2 and upper 36 are typically made. However, in a simplified mode, one can very well consider not using such a sliding bearing 16 and to provide that the control rod 4 is directly carried by the lower frame 2.

Similarly, the magnetic ring 18 and the support ring 20 on which the magnetic ring 18 is fixed are provided for the case where the rotation of the control rod 4 is detected by a local variation of the field Magnetic induced by the pivoting of the magnetic ring 18. However, it is quite possible to replace the magnetic assembly 14 for example by a sliding pinion which, according to its position, for example, will control the winding of a mainspring or setting the time of a watch equipped with the control device 1.

It is also important to note that the example of the control rod 4 provided over a portion of its length with a square section is given for purely illustrative purposes only. Indeed, to drive the magnetic assembly 14 in rotation, the control rod 4 may have any type of section which deviates from a circular section, for example triangular or oval.

The lower frame 2 and the upper frame 36 whose meeting defines the outer geometry of the control device 1 are for example generally parallelepipedal shape. The lower frame 2 forms a cradle which receives the control rod 4 (see Fig. 2). For this purpose, the lower frame 2 comprises forwards a first receiving surface 38 of semicircular profile which serves as a seat for the sliding bearing 16 and in which is formed the first groove 34a which receives the circular flange 32. immobilization of the sliding bearing 16 both axially and rotation is thus ensured.

The lower frame 2 further includes a rearward second receiving surface 40 whose semicircular profile is centered on the longitudinal axis of symmetry XX of the control rod 4, but whose diameter is greater than that of this control rod 4. It is important to understand that the control rod 4 bears on the second receiving surface 40 only at the stage where the control device 1, assembled, is tested before be integrated into the portable object. At this stage of the assembly, the control rod 4 is introduced into the control device 1 for testing purposes and extends horizontally while being supported and guided axially by the sliding bearing 16 on the side of its front end 10 and by the second receiving surface 40 on the side of its rear end 6. By cons, once the control device 1 integrated in the portable object, the control rod 4 passes through a hole 42 formed in the middle 48 of the object portable in which it is guided and supported (see Fig. 19).

Third and fourth clearance surfaces 44a and 46a of semicircular profile are also provided in the lower frame 2 and complementary clearance surfaces 44b and 46b (see FIG 6) are provided in the upper frame 36 to receive the magnetic assembly 14 consisting of the magnetic ring 18 and its support ring 20. Note that the magnetic ring 18 and its support ring 20 are not in contact with the third and fourth clearance surfaces 44a, 46a and the complementary clearance surfaces 44b and 46b when the controller 1 is assembled and mounted in the portable object. It is also noted that the third clearance surface 44a and its corresponding complementary clearance surface 44b are delimited by a circular flange 50 for the axial locking of the magnetic assembly 14.

As shown in FIG. 3, behind the square section 12, the control rod 4 has a cylindrical section 52 whose diameter is between the diameter of the circle in which fits the square section 12 of the control rod 4 and the pitch diameter d a rear section 54 of the same control rod 4 at the end of which is fixed the actuating ring 8. This cylindrical section 52 of reduced diameter forms a groove 56 in which is placed a plate 58 indexing the position of control rod 4 (see Fig. 7A and 7B). For this purpose, the position indexing plate 58 has a curved portion 60 which matches the profile of the cylindrical section 52 of reduced diameter and which allows the position indexing plate 58 to extend substantially horizontally. The position indexing plate 58 may for example be obtained by stamping a thin metal sheet electrically conductive. But it is also conceivable to make this position indexing plate 58 for example by molding a hard plastic material loaded with conductive particles. The engagement of the position indexing plate 58 in the groove 56 ensures translation coupling back and forth forwards between the control rod 4 and the position indexing plate 58. , as will be better understood later, the position index plate 58 is free with respect to the control rod 4 in a vertical direction z perpendicular to the longitudinal axis of symmetry XX of the control rod 4.

As shown in FIG. 7A, the position index plate 58 is a substantially flat and generally U-shaped piece. This position indexing plate 58 comprises two substantially rectilinear guide arms 62 which extend parallel to each other and which are connected to each other. The two guide arms 62 are guided axially for example against two studs 64 formed in the lower frame 2. Guided by its two guide arms 62, the position indexing plate 58 slides along a flange 68 formed in the upper frame 36 and whose perimeter corresponds to that of the position index plate 58 (see Figure 6). The position indexing plate 58 also comprises two fingers 66a, 66b which extend vertically downwards on either side of the two guide arms 62. By sliding along the flange 68, the indexing plate of Position 58 has the particular function of guiding the translation in translation of the control rod 4 from front to back and back to front. As for the fingers 66a, 66b, they make it possible in particular to prevent the position indexing plate 58 from bending when it moves in translation.

Two openings 70 having a contour of approximately rectangular shape are formed in the guide arms 62 of the position indexing plate 58. These two openings 70 extend symmetrically on either side of the longitudinal axis. of symmetry XX of the control rod 4. The sides of the two openings 70 closest to the longitudinal axis of symmetry XX of the control rod 4 have a cam path 72 of substantially sinusoidal shape formed of a first and second a second hollow 74a and 74b separated by a vertex 76.

The two openings 70 formed in the guide arms 62 are intended to receive the two ends 78 of a positioning spring 80 (see Figure 8). This positioning spring 80 has a generally U-shaped shape with two rods 82 which extend in a horizontal plane and which are interconnected by a base 84. At their free end, the two rods 82 are extended by two arms 86 substantially rectilinear standing vertically. The positioning spring 80 is intended to be mounted in the control device 1 from below the lower frame 2, so that the ends 78 of the arms 86 project into the openings 70 of the position indexing plate 58. It will be seen below that the cooperation between the position indexing plate 58 and the positioning spring 80 makes it possible to index the position of the control rod 4 between an unstable thrust position TO and two stable positions T1 and T2.

It has been mentioned above that the position index plate 58 is coupled in translation with the control rod 4, but that it is free with respect to the control rod 4 in the vertical direction z. It is therefore necessary to take measures to prevent the position indexing plate 58 from disengaging from the control rod 4 under normal conditions of use, for example under the effect of gravity. For this purpose (see Fig. 9), a spring 88 is provided for limiting the displacement of the position indexing plate 58 in the vertical direction z above and at a short distance from this position indexing plate 58. The displacement limiting spring 88 is trapped between the lower frame 2 and the upper frame 36 of the control device 1, but is not, under normal conditions of use, in contact with the position index plate 58, This avoids the exertion of parasitic friction forces on the control rod 4 which would make handling difficult and cause a phenomenon of wear. The displacement limiting spring 88 is however sufficiently close to the position indexing plate 58 so that it can not decouple from the control rod 4 inadvertently.

The displacement limitation spring 88 comprises a substantially rectilinear central portion 90 from the ends of which extend two pairs of elastic arms 92 and 94. These elastic arms 92 and 94 extend on either side. of the central portion 90 of the displacement limiting spring 88, moving away from the horizontal plane in which extends this central portion 90. These elastic arms 92 and 94, being compressed when the upper frame 36 is attached at the lower frame 2, give the displacement limiting spring 88 its elasticity in the vertical direction z. Between the pairs of elastic arms 92 and 94 are also provided a pair and, preferably, two pairs of rigid tabs 96 which extend perpendicularly downwards on either side of the central portion 90 of the displacement limitation spring 88 These rigid tabs 96 which bear on the lower frame 2 when the upper frame 36 is placed on the lower frame 2, ensure compliance with a minimum spacing between the position indexing plate 58 and the limiting spring of the displacement 88 under normal operating conditions of the control device 1.

The displacement limitation spring 88 guarantees the dismountability of the control device 1. In fact, in the absence of the movement limitation spring 88, the position indexing plate 58 should be secured to the rod. 4 and, consequently, the control rod 4 could no longer be dismantled. However, if the control rod 4 can not be disassembled, the movement of the timepiece equipped with the control device 1 is also indémontable, which is not possible in particular in the case of a timepiece expensive. Thus, when the control device 1, formed by the reunion of the upper and lower racks 2 2, is mounted in the portable object and the control rod 4 is inserted in the control device 1 from the outside of the the portable object, the control rod 4 slightly raises the position index plate 58 against the elastic force of the displacement limitation spring 88. Continuing to push forward the control rod 4, arrives a when the position indexing plate 58 falls into the groove 56 under the effect of gravity. The control rod 4 and the position indexing plate 58 are then coupled in translation.

A disengagement plate 98 is provided to allow the disassembly of the control rod 4 (see Fig. 10). This disengagement plate 98 is generally H-shaped and comprises a straight segment 100 which extends parallel to the longitudinal axis of symmetry XX of the control rod 4 and to which a first and a second transverse section 102 and 104 are attached. The first transverse section 102 is further provided at its two free ends with two tabs 106 folded at a substantially right angle. The disengagement plate 98 is received in a housing 108 formed in the lower frame 2 and located under the control rod 4. This housing 108 communicates with the outside of the control device 1 via a hole 110 which opens into a lower face 112 of the control device 1 (see Fig. 11). By introducing a pointed tool into the hole 110, it is possible to exert a thrust on the disengaging plate 98 which, via its two lugs 106, in turn pushes the position indexing plate 58 against the elastic force of the movement limiting spring 88. It is then sufficient to exert a slight traction on the control rod 4 in order to extract it from the control device 1.

From its stable rest position T1, the control rod 4 can be pushed forward in an unstable position TO or pulled in a stable position 12. These three positions TO, T1 and T2 of the control rod 4 are indexed by cooperation between the position index plate 58 and the positioning spring 80. More precisely (see Fig. 12A), the stable rest position T1 in which no control can be introduced into the portable object equipped with the control device 1 corresponds to the position in which the ends 78 of the arms 86 of the positioning spring 80 protrude into the first recesses 74a of the two openings 70 formed in the guide arms 62 of the position indexing plate 58. Since this stable rest position T1, the control rod 4 can be pushed forward into an unstable position TO (see Fig. 12B). During this movement, the ends 78 of the arms 86 of the positioning spring 80 leave the first recesses 74a and follow a first ramp profile 114 which progressively deviates from the longitudinal axis of symmetry XX of the control rod 4 according to a first slope steep. To force the ends 78 of the arms 86 of the positioning spring 80 out of the first recesses 74a and to engage on the first ramp profile 114 away from each other, the user must therefore overcome a significant resisting stress.

Arrived at a transition point 116, the ends 78 of the arms 86 engage on a second ramp profile 118 which extends the first ramp profile 114 with a second slope ß less than the first slope of the first profile. ramp 114. At the instant when the ends 78 of the arms 86 of the positioning spring 80 cross the transition point 116 and engage on the second ramp profile 118, the effort that the user must provide to continue to make advance the control rod 4 drops sharply and the user feels a click which indicates the transition of the control rod 4 between its position T1 and its position T0. By following the second ramp profile 118, the arms 86 of the positioning spring 80 continue to move slightly away from their rest position and tend to want to come closer to one another under the effect of their force. resilient bias against the pushing force exerted by the user on the control rod 4. As soon as the user releases its pressure on the control rod 4, the arms 86 of the positioning spring 80 will spontaneously fall down along the first ramp profile 114 and come again to be housed in the first recesses 74a of the two openings 70 formed in the guide arms 62 of the position indexing plate 58. The control rod 4 is thus automatically recalled from its unstable position TO at its first stable position T1.

First and second contact springs 120a and 120b are housed compressed in a first and a second cavity 122a and 122b formed in the lower frame 2. These first and second contact springs 120a and 120b may be at the choice of the springs of helical contacts, spring blades or others. The two cavities 122a, 122b extend preferentially but not necessarily horizontally. Because the two contact springs 120a, 120b are installed in the compressed state, the accuracy of their positioning is conditioned by the tolerance with which the lower frame 2 is manufactured. However, the precision with which the lower frame 2 is manufactured is is greater than the manufacturing accuracy of these two first and second contact springs 120a, 120b. Therefore, the detection accuracy of the TO position of the control rod 4 is high.

As shown in FIGS. 13 and 15, one of the ends of the first and second contact springs 120a, 120b is bent so as to form two contact tabs 124 which will come to bear on two corresponding first contact pads 126 provided on the surface of a flexible printed circuit sheet 128. The moment when the ends 78 of the arms 86 of the positioning spring 80 engage on the second ramp profile 118 of the two openings 70 formed in the position indexing plate 58 coincide with the moment wherein the fingers 66a, 66b of the position indexing plate 58 come into contact with the first and second contact springs 120a, 120b. Since this position indexing plate 58 is electrically conductive, when the fingers 66a, 66b contact the first and second contact springs 120a, 120b, the electrical current passes through the position indexing plate 58 and the the closing of the electrical contact between the first and second contact springs 120a, 120b is detected.

The first and second contact springs 120a, 120b are of the same length. However, preferably, one of the first and second cavities 122a, 122b will be longer than the other in particular to take account of tolerance problems (the difference in length between the two cavities 122a, 122b is a few tenths of a millimeter ). In this way, when pushing the control rod 4 forward into its position TO, the finger 66a of the position indexing plate 58 which is in correspondence with the first contact spring 120a housed in the first cavity 122a the longest will come in contact with it and start compressing it. The control rod 4 will continue to advance and the second finger 66b of the position indexing plate 58 will come into contact with the second contact spring 120b housed in the second cavity 122b the shortest. At this time, the position indexing plate 58 will be in contact with the first and second contact springs 120a, 120b and the electric current will pass through the position index plate 58, allowing detecting the closing of the electrical contact between the two first contact springs 120a, 120b. Note that the fingers 66a, 66b of the position indexing plate 58 come into abutting contact with the first and second contact springs 120a, 120b. There is therefore no friction or wear when the control rod 4 is pushed forward in the TO position and closes the circuit between the first and second contact springs 120a, 120b. Note also that, due to the different length of the first and second cavities 122a and 122b, it is ensured that the closing of the electrical contact and the introduction of the corresponding command in the portable object equipped with the control device 1 n ' intervenes only after the feeling of the click.

When the two fingers 66a, 66b of the position indexing plate 58 are in contact with the first and second contact springs 120a, 120b, the first contact spring 120a housed in the first cavity 122a the longest is in the compressed state. Therefore, when the user releases the pressure on the control rod 4, this first contact spring 120a relaxes and forces the return of the control rod 4 from its unstable thrust position TO to its first stable position T1. The first and second contact springs 120a, 120b thus simultaneously play the role of electrical contact parts and elastic return means of the control rod 4 in its first stable position T1.

From the first stable position T1, it is possible to pull the control rod 4 back into a second stable position T2 (see Fig. 12C). During this movement, the ends 78 of the arms 86 of the positioning spring 80 will pass by elastically deforming first hollow 74a to the second hollow 74b crossing the vertices 76 of the two openings 70 formed in the guide arms 62 of the plate 58. When the control rod 4 reaches its second stable position T2, the two fingers 66a, 66b of the position indexing plate 58 abut against third and fourth contact springs 130a, 130b (FIG. see Fig. 13) which are housed in third and fourth cavities 132a, 132b formed in the lower frame 2. These third and fourth contact springs 130a and 130b may be either helical contact springs, leaf springs or the like. The third and fourth cavities 132a, 132b preferably extend vertically for dimensions of the control device 1. As the position indexing plate 58 is electrically conductive, when the fingers 66a, 66b come into contact with the third and fourth contact springs 130a, 130b, the electric current passes through the position indexing plate 58 and the closure of the electrical contact T2 is detected between these contact springs 130a, 130b.

It will be noted that, in the case of the stable position T2, the fingers 66a, 66b of the position indexing plate 58 also come into abutting contact with the third and fourth contact springs 130a, 130b, so that any risk of chafing is avoided. On the other hand, the third and fourth contact springs 130a, 130b are capable of flexing when the fingers 66a, 66b of the position indexing plate 58 strike them, and thus of absorbing a possible lack of precision in the positioning of the position index plate 58.

Preferably, but not necessarily, the third and fourth contact springs 130a, 130b are arranged to work in bending. Indeed, with contact springs 130a, 130b whose diameter is constant, the fingers 66a, 66b of the position indexing plate 58 come into contact with the contact springs 130a, 130b according to a large surface close to their points anchoring in the lower frame 2 and the upper frame 36. The proximity of the contact surface with the anchor points of the contact springs 130a, 130b induces in these contact springs 130a, 130b shear stresses which can lead to premature wear and breakage of these. To solve this problem, the contact springs 130a, 130b are preferably substantially half-way up in diameter 134 with which the fingers 66a, 66b of the position indexing plate 58 come into contact when the control rod 4 is pulled into its stable position T2 (see Fig. 14A and 14B). At their upper end, the third and fourth contact springs 130a, 130b are guided in two holes 136 formed in the upper frame 36 and come into contact with second contact plates 138 provided on the surface of the flexible printed circuit sheet 128 It is understood that, when the control rod 4 is pulled back to its stable position T2, the fingers 66a, 66b of the position index plate 58 come into contact with a reduced surface with the third and fourth springs. 130a and 130b at their largest diameter 134, which allows these contact springs 130a, 130b to flex between their two anchor points in the lower frame 2 and the upper frame 36.

In FIG. 15, the lower 2 and upper 36 frames have been purposely omitted to facilitate understanding of the drawing. As shown in this fig. 15, the flexible printed circuit sheet 128 is fixed on a plate 140 located on the side of a dial of the portable object. In particular, it has a cutout 142 adapted in shape and size to receive the upper frame 36. A portion 144 of the flexible printed circuit sheet 128 remains free (see Fig. 16). This free portion 144 of the flexible printed circuit sheet 128 carries a plurality of electronic components 146 as well as third contact plates 148 on which two inductive sensors 150 are fixed. By inductive sensor is meant a sensor which transforms a magnetic field which the crossbar in electrical voltage thanks to the phenomenon of induction defined by the law of Lenz-Faraday. For example, it may be a Hall effect sensor or a magnetoresistive component type AMR (Anisostropic Magnetoresistance), GMR (Giant Magnetoresistance) or TMR (Tunneling Magnetoresistance).

The free portion 144 of the flexible printed circuit sheet 128 is connected to the remainder of the flexible printed circuit sheet 128 by two strips 152 which allow to fold the free portion 144 around the assembly of the upper frame 36 and the lower frame 2, then fold down the free portion 144 against a lower surface 112 of the lower frame 2, so that the inductive sensors 150 enter two housings 156 formed in the lower surface 112 of the lower frame 2. Thus positioned in their housing 156 , the inductive sensors 150 are precisely located under the magnetic ring 18, which ensures a reliable detection of the direction of rotation of the control rod 4. Once the free portion 144 of the flexible printed circuit sheet 128 folded against the lower frame 2 (see Fig. 17A), the assembly is covered by a holding plate 158 provided with one or two elastic fingers 160 which plate the inductive sensors 150 at the bottom of their housings 156 (see FIG. 17B). The holding plate 158 is fixed to the plate 140 for example by means of two screws 162.

It goes without saying that the present invention is not limited to the embodiment which has just been described and that various modifications and simple variants can be envisaged by those skilled in the art without departing from the scope of the invention. as defined by the appended claims. In particular, the dimensions of the magnetized ring can be extended to match a hollow cylinder. It will be understood in particular that the position indexing plate 58 can define only two distinct positions, namely two stable positions or a stable position and an unstable position, or it can define three distinct positions or more, namely at least three stable positions or at least two stable positions and an unstable position.

FIG. 20A illustrates the case where the position indexing plate 58 defines two stable positions only. In such a case, two openings 70-1 having a contour of approximately rectangular shape are formed in the guide arms 62 of the position indexing plate 58. These two openings 70-1 extend symmetrically from both sides. other of the longitudinal axis of symmetry XX of the control rod 4. The sides of the two openings 70-1 closest to the longitudinal axis of symmetry XX of the control rod 4 have a cam path 72-1 of substantially sinusoidal shape formed of a first and a second hollow 74a-1 and 74b-1 separated by a vertex 76-1. The two openings 70-1 formed in the guide arms 62 are intended to receive the two ends 78 of the arms of the positioning spring 80 so as to index the position of the control rod 4 between a first and a second stable position T1- 1 and T2-1.

More specifically, the first stable position T1-1 corresponds to the position in which the ends 78 of the arms 86 of the positioning spring 80 protrude into the first recesses 74a-1 of the two openings 70-1 formed in the arms of guidance 62 of the position indexing plate 58. From this first stable position T1-1, the control rod 4 can be pulled back into a second stable position T2-1. During this movement, the ends 78 of the arms 86 of the positioning spring 80 will deform elastically from the first hollow 74a-1 to the second hollow 74b-1 by crossing the vertices 76-1 of the two openings 70-1 formed in the guide arms 62 of the position indexing plate 58.

FIG. 21A illustrates the case where the indexing plate 58 defines a stable position T1-2 and an unstable position TO-2 only. In such a case, two openings 70-2 having a contour of approximately rectangular shape are formed in the guide arms 62 of the position indexing plate 58. These two openings 70-2 extend symmetrically on both sides. other of the longitudinal axis of symmetry XX of the control rod 4. The sides of the two openings 70-2 closest to the longitudinal axis of symmetry XX of the control rod 4 have a cam path 72-2 formed a hollow 74a-2 followed by a ramp profile 114-2 which progressively deviates from the longitudinal axis of symmetry XX of the control rod 4 according to a first steep slope a-2. To force the ends 78 of the arms 86 of the positioning spring 80 out of the recesses 74a-2 and to engage the ramp profile 114-2 away from each other, the user must therefore overcome a significant resisting effort. Arrived at a transition point 116-2, the ends 78 of the arms 86 engage on a second ramp 118-2 profile which extends the first ramp profile 114-2 with a second slope β-2 lower than the first slope a-2 of the first ramp profile 114-2. At the instant when the ends 78 of the arms 86 of the positioning spring 80 cross the transition point 116-2 and engage on the second ramp 118-2 profile, the effort that the user must provide to continue to advance the control rod 4 drops sharply and the user feels a click that indicates the transition of the control rod 4 between its stable position T1-2 and its unstable position TO-2. By following the second ramp profile 118-2, the arms 86 of the positioning spring 80 continue to move slightly away from their rest position and tend to want to come closer to one another again under the effect of their elastic return force opposing the pushing force exerted by the user on the control rod 4. As soon as the user releases its pressure on the control rod 4, the arms 86 of the positioning spring 80 will spontaneously go down again. along the first ramp profile 114-2 and come to be housed again in the recesses 74a-2 of the two openings 70-2 formed in the guide arms 62 of the position index plate 58. The control rod 4 is thus automatically recalled from its unstable position TO-2 to its stable position T1-2.

Nomenclature [0052] 1. Control device 2. Bottom frame 4. X-X control rod. Longitudinal axis of symmetry 6. Rear end 8. Actuating crown 10. Front end 12. Square section 14. Magnetic equipment 16. Plain bearing 18. Magnetic ring 20. Support ring 22a. First section D1. First outer diameter 22b. Second section D2. Second outer diameter 24. Shoulder 26. Square hole 28. Cylindrical housing D3. First inner diameter 30. Annular hole D4. Second internal diameter D5. Third outer diameter 32. Circular collar 34a. First throat 34b. Second groove 36. Upper frame 38. First receiving surface 40. Second receiving surface 42. Hole 44a, 46a. Third and fourth clearance surfaces 44b, 46b. Complementary release surfaces 48. Shoulder 50. Ring collar 52. Cylindrical section 54. Back section 56. Groove 58. Position index plate 60. Curved portion 62. Guide arm 64. Plots 66a, 66b. Fingers 68. Sill 70. Openings 72. Camming path 74a. First hollow 74b. Second hollow 76. Top 78. Ends 80. Positioning spring 82. Rods 84. Base 86. Arm 88. Travel limiting spring 90. Central portion 92. Pair of spring arms 94. Pair of spring arms 96. Rigid legs 98 Dislodging plate 100. Straight segment 102. First cross section 104. Second cross section 106. Legs 108. Slot 110. Hole 112. Bottom 114. First ramp profile a. First slope 116. Transition point 118. Second ramp profile ß. Second slope 120a, 120b. First and second contact spring 122a, 122b. First and second cavity 124. Contact tabs 126. First contact plates 128. Flexible printed circuit sheet 130a, 130b. Third and fourth contact spring 132a, 132b. Third and fourth cavities 134. Increase in diameter 136. Holes 138. Second contact plates 140. Platinum 142. Cutting 144. Free portion 146. Electronic components

Claims (13)

148. Third contact plates 150. Inductive sensors 152. Strips 156. Cavities 158. Holding plate 160. Elastic fingers 162. Screws 70-1. Openings 72-1. Cam path 74a-1. First hollow 74b-1. Second hollow 70-2. Openings 72-2. Cam path 74a-2. Hollow 114-2. First ramp profile a-2. First slope 116-2. Transition point 118-2. Second ramp profile ß-2. Second slope 200. Control rod 202. Cylindrical portion 204. Actuation crown 206. Cam paths 208a, 208b. Hollow 210. Summit 212. Elastic arms 214. Spring Claims Device for controlling at least two electronic and / or mechanical functions of a portable object of small dimensions, this device comprising a control rod (4) which is axially movable between at least a first and a second position, said control rod (4) being provided at one end (6) with an actuating member (8), and being provided with the side of a second end (10) of a position indexing plate ( 58) arranged to cooperate with a resilient member (80) to align each of the first and second positions of the control rod (4) with one of the mechanical or electronic functions. 2. Device according to claim 1, characterized in that the indexing plate (58) extends substantially in a horizontal plane in which the control rod (4) extends. 3. Device according to one of claims 1 and 2, characterized in that the position indexing plate (58) comprises two cam paths (72) identical which extend symmetrically on either side of a longitudinal axis of symmetry (XX) of the control rod (4), and with which two arms (86) of the elastic member (80) cooperate to define the first and the second position of the control rod (4). 4. Device according to claim 3, characterized in that the two cam paths (72) define an unstable position and a stable position of the control rod (4). 5. Device according to claim 4, characterized in that the two cam paths (72) each comprise a recess which defines the stable position of the control rod (4) and which the arms (86) of the elastic member ( 80) extend to engage a ramp profile which moves the arms (86) away from their rest position and which defines the unstable position of the control rod (4). 6. Device according to claim 5, characterized in that the cam paths (72) comprise a first ramp profile (114) which diverges along a first slope a and which is extended by a second ramp profile (118) which diverges at a second slope β less than the first slope a of the first ramp profile (114). 7. Device according to claim 3, characterized in that the two cam paths (72) define a first and a second stable position of the control rod (4). 8. Device according to claim 7, characterized in that the two cam paths (72) comprise a first hollow separated from a second hollow by a vertex, the first and second recesses defining the first and second stable positions of the stem. control (4), the arms (86) of the elastic member (80) passing from the first hollow to the second hollow and vice versa crossing the top. 9. Device according to one of claims 1 to 8, characterized in that the position indexing plate (58) is housed in a groove (56) formed in the control rod (4). 10. Device according to claim 9, characterized in that the position indexing plate (58) is integral with the control rod (4). 11. Device according to claim 9, characterized in that the position indexing plate (58) is detachably coupled with the control rod (4). 12. Device according to claim 11, characterized in that the coupling between the position index plate (58) and the control rod (4) is an elastic coupling arranged to prevent uncoupling between the index plate position (58) and the control rod (4) under normal conditions of use. 13. Device according to claim 12, characterized in that a spring (88) for limiting the displacement of the position indexing plate (58) in a vertical direction (z) perpendicular to the horizontal plane in which extends the control rod (4) is disposed above and at a distance from the position indexing plate (58) such that the displacement limiting spring (88) is not, under normal conditions of use, contact with the position indexing plate (58), but is however sufficiently close to the position indexing plate (58) that it can not decouple from the control rod (4) inadvertently.