CH714266A2 - Control device provided with a module for detecting the axial position of its rod, and a timepiece comprising such a control device. - Google Patents

Abstract

The detection module comprises an elastic conductive blade (5) having first and second ends and a central portion therebetween, the blade being arranged to be driven axially by a control rod (3) to occupy three distinct positions. , respectively a pulled position, an end position and an intermediate position between the pulled position and the end position of the rod. Two electrical contacts (7, 9) are arranged to respectively detect the end position and the position drawn from the rod (3): The blade (5) is arranged to pivot at its first end during a passage of the rod (3). ) from the intermediate position to the pulled position or vice versa. The blade (5) is also arranged to undergo elastic deformation during the passage of the rod (3) between the intermediate position and the end position, so as to participate substantially in the restoring force of the rod (3) towards the intermediate position when releasing the axial activation force applied to the rod by a user. An object of the invention is that the detection module can also detect a rotation of the rod (3). The invention also relates to a timepiece comprising such a control device.

Description

Description

Technical Field [0001] The invention relates to a control device comprising a rod actuatable by a user and a module of the electrical type for detecting the axial position of this rod, which for example forms a push-button crown of a part d watchmaking. In particular, the detection module is arranged to also be able to detect a rotational movement of the rod.

Technological background [0002] In timepieces having electronic type push crowns associated with electrical modules for detecting the axial position of their rod, these electrical modules are generally bulky and often allow the detection of only two positions: a 'rest' position which is stable and a terminal position for a push function, also called 'click position'. Known detection modules generally have a large size and can often detect only two axial positions of the rod. Another drawback of known detection modules is that they generally have rod return means which are weak enough to ensure the return of the rod following activation of the pusher function.

Summary of the invention The object of the present invention is to overcome at least a few drawbacks identified above in connection with the electrical type detection modules which are arranged in particular in timepieces to detect at least the axial position of a rod of a control device.

To this end, the invention relates to a control device arranged to detect several axial positions of its rod according to claim 1.

The detection module according to the invention has been developed with the aim of reducing its size, in order to make its integration possible in the smallest sizes (for watches) while allowing the detection of three axial positions of the rod. To save space, the blade serves as an electrical contactor for detecting the axial position in addition to a return spring function for the click position. In addition, the design of the detection module allows a traditional fitting method because it can be completely integrated into the movement of a timepiece.

The invention also relates to a timepiece comprising the above-mentioned control device. Other aspects of the present invention are to be found in the dependent claims.

Brief description of the figures The invention will be described below in more detail with the aid of the appended drawings, given by way of non-limiting examples, in which:

fig. 1 is a perspective view showing the main elements of the module for detecting the axial position of a control rod according to an embodiment of the present invention;

fig. 2 is a view in horizontal section of the control device according to the invention, illustrating the main elements of FIG. 1 placed inside a frame of the detection module;

fig. 3 is an isometric view illustrating the rod taken between two springs positioning the rod and the elastic blade associated therewith;

fig. 4 is an isometric view of the control device of FIG. 2; and fig. 5a, 5b and 5c are partial top views illustrating three different configurations of the control device which correspond respectively to three different positions of the rod detected by the detection module.

Detailed description of the invention [0009] Referring to the figures, an embodiment in accordance with the present invention will now be explained in more detail. This embodiment will be described in the context of a timepiece. In the present detailed description, the timepiece is in particular a wristwatch, hereinafter called simply a watch, but the present invention is not limited to watches worn on the wrist of a user. In fact, the present invention can be applied to any type of electronic timepiece or to other portable electronic devices provided with a device for controlling at least some of their functions.

CH 714 266 A2 [0010] FIG. 1 shows in perspective the main elements of the electrical detection system of the axial position of a rod 3 of a push-button crown of a watch. This detection system comprises a curved elastic conductive strip 5, also known as a “crossbow” by its shape. The blade 5 therefore has in a top view substantially a crossbow shape when it is not subjected to any external force. In this example, the blade is made of "maraging" steel, which is an alloy known for its high strength and hardness, while retaining good ductility. The blade 5 comprises a first end, a second end opposite the first end, and a central part between the first end and the second end. Between the central part and the first end, the blade 5 comprises a first intermediate part whereas between the central part and the second end, the blade 5 comprises a second intermediate part.

A through hole is provided in the central part of the blade 5 so that the end portion of the rod 3 can partially pass through the blade, which is in abutment against a shoulder 6 provided on the rod 3, as shown in the fig. 2. The rod 3 defines a longitudinal axis so that the blade is arranged with its central part substantially perpendicular to this longitudinal axis so that it is driven axially by this rod during axial displacements in the direction of a terminal position. The blade 5 is arranged in the detection module so that its central part in an undeformed state is located, in projection on the longitudinal axis of the rod 3, on the side of the pulled position relative to its first and second ends. Advantageously, the conductive strip has a variable cross section which decreases from its center, that is to say the central part, in the direction of its two ends. The advantage of this non-constant section will be explained later.

The detection system also includes a first electrical contact 7, located substantially at the first end of the blade 5, and a second electrical contact 9, located substantially at the second end of the blade 5, which are arranged to come selectively in contact with the blade, as explained below. The first electrical contact 7 is provided on a first side of the blade, while the second electrical contact 9 is provided on a second side of the blade 5, that is to say on the side opposite to the first side. A return spring 11, mounted around a guide element 13 such as a pin, is provided to bear against the first side of the blade on the side of the second end of this blade. It is designed to be in permanent contact with the blade. The return spring 11 has two functions, namely a mechanical function and an electrical function to impose an electrical potential on the blade 5. For example, the blade 5 can be grounded by means of the return spring. The blade 5, the first and second electrical contacts 7, 9 and the return spring 11 are therefore all electrical conductors. They can be made of a conductive material or have a conductive outer layer. For example, the return spring 11 is made of steel.

[0013] FIG. 2 is a horizontal section view showing the control device 1 according to the invention with the elements of the aforementioned detection system inside a frame 15 to form together a detection module 2. This detection module comprises two sensors optics 21 and 23 associated with a sliding pinion 17 rotated by the end portion, of non-circular section, of the rod 3. The sliding pinion 17 is retained axially by a washer 19 and it has reflective facets. Such a rod rotation detection system will not be described here in more detail. He is known to the skilled person. It should be noted that a magnetic or capacitive detection system can also be provided. In the case of a magnetic system, the sliding pinion carries a magnet.

Two springs 25 are also provided for axially positioning the rod 3. These two springs are better illustrated in FIG. 3. For its axial positioning, the rod 3 conventionally comprises two transverse grooves arranged to engage with these two springs which exert transverse pressure on the rod. Thus, the rod can occupy two stable axial positions. Upstream of the two grooves, the rod has a frustoconical section to promote the planned push function. Advantageously, the rod 3 is retained and therefore guided only by the sliding pinion 17 and a middle part of the watch case (not shown). This aspect helps to minimize the size of the proposed solution. Fig. 4 illustrates in isometric view the control device 1 and in particular the detection module 2.

Referring to Figs. 5a to 5c, the indexing of the rod 3 and the operation of the detection module 2 will now be explained in more detail. The rod 3 can occupy three distinct axial main positions, in particular a first stable position illustrated in FIG. 5a, a second stable position illustrated in FIG. 5b and an unstable end position, also called 'click position', which is illustrated in FIG. 5c. To reach these three main positions, the rod 3 conventionally passes through unstable secondary positions. In this example, the first stable position is an intermediate position or rest position, that is to say that this position is not linked to any function of the watch, while the second stable position of the rod allows for example to manipulate watch hands. The end position corresponds to a push-button function which can be used to activate a watch function, such as a chronograph or the date display.

In the rest position, the rod 3 is positioned / held in place by the two rod springs 25 inserted in the first groove of the rod. In this position, the blade is slightly deformed, only a small force of the return spring 11 applying on it. In addition, in this rest position, the first and second electrical contacts 7, 9 are open (not in contact with the blade 5).

If, from the rest position, a user pulls the rod 3 outward, that is to say causes the rod to move back, the latter reaches the second stable position (pulled position), such as shown in fig. 5b. In this position, the rod 3 is positioned / held by the two rod springs 25 inserted in the second groove. The mechanical force then exerted on

CH 714 266 A2 the blade in this pulled position is weak, but not zero to ensure contact with the electrical contact 9. In order to limit the deformation force on the blade when the rod moves back from the rest position towards the pulled position, the blade pivots at its first end under the action of the return spring 11 and finally comes to contact the second electrical contact 9. The pivot axis is located at the first end of the blade 5 which comprises at this point a elbow. This elbow is positioned between a projecting part of the substantially circular frame arranged inside the elbow and a shoe so as to obtain the desired articulation. This particular arrangement allows, on the one hand, to hold the blade laterally in the frame 15 and, on the other hand, its pivoting.

The end position of the rod can be reached by pushing the rod towards the inside of the watch by exerting a relatively large force on it. As illustrated in fig. 5c, in the end position, it is provided that the blade 5 comes to contact the first electrical contact 7, which is flexible in order to be able to absorb a certain pressure from the blade 5. In the end position, the second end of the blade 5 is bearing against a stop of the frame and the blade 5 has a relatively strong elastic deformation since its central part is pressed by the shoulder 6 of the rod in the defined direction from the pulled position towards the end position. The return force in the terminal position is provided mainly by the blade 5 and secondarily by the rod springs 25. The click feeling is ensured by the action of the rod springs 25 coming out of the second groove of the rod 3. To this end, the second groove comprises in the above-mentioned direction a double slope with a steep section 27 and a gently sloping section 29 (clearly visible in FIG. 5b). To obtain a maximum return force in a minimum space requirement, the blade 5 has variable sections in order to distribute the stresses as appropriately as possible. In particular it is expected that the central part has the greatest width so that it remains sufficiently rigid, the rod pressing on this central part. It should be noted that, in the example shown, the blade almost does not pivot between the rest position and the terminal position.

To summarize, the electronic detection module 2 therefore comprises the curved elastic conductive strip 5, arranged in the frame 15 of the detection module 2, and two electrical contacts 7, 9 arranged so as to come into contact with the conductive strip respectively in the pulled position and the end position of the rod. The first electrical contact 7 is arranged on the downstream side of the blade 5 relative to a defined direction from the pulled position towards its end position, while the second electrical contact 9 is arranged on the upstream side thereof. Advantageously, the curved elastic blade is mounted so as to pivot at its first end when the rod passes from the rest position to the pulled position, and vice versa. In particular, this pivoting is generated by the return spring 11 while the shoulder 6 of the rod is withdrawn. Preferably, this pivoting is carried out substantially without elastic deformation of the blade 5, while the blade 5 is arranged so as to undergo a relatively large elastic deformation during the passage of the rod between the rest position and the end position, to participate substantially to the return force of this rod towards the rest position when the axial activation force exerted on it by a user is released. More specifically, the blade comprises a first intermediate part between the central part and the first end and a second intermediate part between the central part and the second end, and in which the blade has a variable cross section which decreases from its central part in the direction from its first end and also towards its second end so as to substantially concentrate the elastic deformation of the blade in its first and second intermediate parts, located respectively between the central part and the two ends, during the passage of the rod between the intermediate position and terminal position. Advantageously, the conductive strip has a variable section which decreases from its center towards its two ends so as to allow a relatively large deformation of the two intermediate parts of this strip 5 located between its central part and its first and second ends.

The present invention therefore provides an electronic detection module having a reduced size, to obtain a smaller footprint, while including means for detecting three axial positions and means for effective return of the rod from its terminal position, after actuation thereof by a user for the pusher function, when the axial force exerted by this user is released.

Claims (12)

claims 1. A control device comprising a rod (3) operable by a user and an electric type detection module (1) for detecting several distinct axial positions of the rod, which defines a longitudinal axis and is capable of being moved axially , the detection module comprising: - an elastic conductive strip (5) comprising a first end, a second end and a central part between the first and second ends, this strip being arranged so that its central part is substantially perpendicular to the longitudinal axis of the rod and capable of to be moved axially in particular by this rod and so as to be able to occupy three distinct positions to make it possible to detect respectively a pulled position, a terminal position and an intermediate position, between the pulled position and the terminal position, of the rod, a first electrical contact (7) arranged so as to come into contact with the blade (5) only in the end position of the rod, and - a second electrical contact (9) arranged so as to come into contact with the blade (5) only in the position pulled from the rod; CH 714 266 A2 in which the blade (5) is arranged to pivot at its first end when the rod (3) passes from the intermediate position to the pulled position and vice versa; and in which the blade (5) is arranged so as to undergo an elastic deformation during the passage of the rod (3) between the intermediate position and the end position, so as to participate substantially in the restoring force of the rod (3 ) to the intermediate position when an axial actuation force applied to the rod (3) is released by a user. 2. Control device according to claim 1, wherein the blade (5) has a curved shape in the absence of a deformation force. 3. Control device according to claim 2, wherein the blade (5) has, in the absence of a deformation force, substantially a crossbow shape, this blade being arranged in the detection module so that its central part in an undeformed state is located, in projection on the longitudinal axis of the rod (3), on the side of the pulled position relative to its first and second ends. 4. Control device according to any one of the preceding claims, in which the blade (5) comprises a first intermediate part between the central part and the first end, and a second intermediate part between the central part and the second end, and wherein the blade (5) has a variable cross section which decreases from the central part towards its two ends so as to substantially concentrate the elastic deformation of the blade (5) in the first and second intermediate parts during the passage of the rod (3) between the intermediate position and the end position. 5. Control device according to any one of the preceding claims, in which the first electrical contact (7) is arranged at the first end of the blade (5) on the downstream side thereof relative to a defined direction of position. pulled towards the end position. 6. Control device according to any one of the preceding claims, in which the second electrical contact (9) is arranged at the second end of the blade (5) on the upstream side thereof relative to a defined direction of position. pulled towards the end position. 7. Control device according to any one of the preceding claims, in which the detection module further comprises a return spring (11) which is engaged with the second end of the blade (5) to effect the pivoting of the blade (5). 8. Control device according to claim 7, wherein the return spring (11) is arranged on the downstream side of the second end of the blade relative to a defined direction from the pulled position towards the end position. 9. Control device according to claim 7 or 8, wherein the return spring (11) is an electrical conductor arranged to impose an electrical potential on the blade (5). 10. Control device according to any one of the preceding claims, in which the pivoting of the blade (5) between the intermediate position and the pulled position is provided substantially without elastic deformation of this blade. 11. Control device according to any one of the preceding claims, in which the blade (5) comprises a hole passing through its central part and in which the rod (3) is inserted, this rod comprising a shoulder (6) against which abuts the central part of the blade (5) at least when the rod is moved from its intermediate position towards its end position. 12. A timepiece comprising the remote-controlled device according to any one of the preceding claims and in which said rod (3) forms a control member for several functions of the timepiece.