The invention concerns a push button system for activating an actuation member.
The invention also concerns a timepiece, particularly a watch, comprising the push button system. This type of push button system is generally used to activate and/or deactivate one or more functionalities of a watch.
In the field of horology, there are known push button systems intended to activate an actuation member arranged inside a case, typically a watch case. Such systems comprise a button head accessible from outside the case and movable in translation with respect to the case, a pusher actuator integral with the button head and mounted to slide through an opening arranged in the case, and a hollow guide member mounted integral with the case and at least partly inserted into said opening arranged in the case and inside which the pusher actuator slides. However, such push button systems are often subject to actuation forces directed in a non-axial direction, which can lead to a risk of jamming the pusher. This type of push button can thus undergo a bending or tilting force outside the sliding axis of the pusher, which may move the actuation axis off centre, thereby increasing the risk of jamming the pusher.
To overcome this drawback, there are also known push button systems wherein, in addition to the first hollow guide member, there is a second hollow guide member for taking up at least part of the operating stresses during actuation of the pusher. Such a push button system is, for example, disclosed in Swiss Patent No CH704691B1. The second hollow guide member is arranged inside the button head, and the system further comprises a pin, mounted to slide inside the second hollow guide member via a sleeve and secured to the case via one of its ends. The second hollow guide member/pin assembly thus makes it possible to mechanically connect the case to the button head to take up part of the operating stresses during actuation of the button head, the latter being able to slide both over the first hollow guide member and over the pin. Such a configuration thus reduces the risk of the pusher jamming, and consequently improves the mechanical reliability of the system.
However, although the push button system proposed in Patent CH704691B1 solves the problem of the pusher jamming, it has a drawback. Indeed, when it is subject to actuation forces directed in a non-axial direction, typically radial forces, the pusher actuator of such a system may bend. This is detrimental to the reliability and overall water resistance of the system, the problem of water resistance being particularly crucial in chronograph watches.
It is therefore an object of the invention to provide a push button system which makes it possible to reduce or eliminate the risk of the pusher bending, and thereby improves the reliability and sealing of the system.
To this end, the invention concerns a push button system, which includes the features mentioned in the independent claim 1.
Specific embodiments of the push button system are defined in the dependent claims 2 to 12.
Owing to the fact that an upper portion of the pusher actuator is provided on its periphery with a collar intended to cooperate with an internal face of the first hollow guide member, the guide length of the pusher in the first hollow guide member is considerably increased. In other words, the play between the pusher and the first hollow guide member is reduced, without thereby making the pusher hyperstatic. This advantageously makes it possible to stiffen the push button system and thereby reduce the risk of the pusher bending, particularly when the latter is subject to radial forces. In particular, when it is actuated with a radial force of 5 N in accordance with the new water resistance test standard, the pusher can no longer bend. The reliability and overall water resistance of the system are thus improved.
According to a first embodiment of the invention, the collar has a height corresponding to at least 1/25th of the total height of the pusher actuator, the height being measured in the main direction of extension of the pusher.
According to a second embodiment of the invention, the collar has a height corresponding to at least 1/10th of the total height of the pusher actuator, the height being measured in the main direction of extension of the pusher. This second embodiment has the advantage of further reducing or even eliminating the risk of the pusher bending, particularly when the latter is subject to radial forces.
According to a particular technical feature of the invention, the first hollow guide member comprises an upper part adjusted to slide inside a head housing provided in the button head.
According to another particular technical feature of the invention, the pusher actuator is an arbor or a screw mounted to slide through the first hollow guide member and a first end of which is fixed in the bottom of the head housing, the other end being configured to cooperate with the actuation member.
Advantageously, the push button system further comprises at least one means of sealing arranged between the pusher actuator and the first hollow guide member. This improves the water resistance of the system.
To this end, the invention also concerns a timepiece comprising at least one actuation member arranged inside a case, and at least one push button system as described above for acting on the actuation member, and which includes the features mentioned in the dependent claim 13.
A particular embodiment of the timepiece is defined in the dependent claim 14.
The objects, advantages and features of the push button system and the timepiece comprising the same, will appear more clearly in the following description, based on at least one non-limiting embodiment illustrated by the drawings, in which:
Push button system 1 comprises a button head 2, a pusher actuator 4 integral with button head 2, a first hollow guide member 6, a second hollow guide member 8 and a pin 10. Preferably, as illustrated in
Preferably, as illustrated in
Pusher actuator 4 has a lower end 18a intended to cooperate with the actuation member. In particular, lower end 18a of pusher actuator 4 is configured to enter into contact with the member in question, in order to actuate the latter. As represented in
Pusher actuator 4 extends in a main direction of extension A-A′, which corresponds to the direction of sliding of pusher 4 inside first hollow guide member 6. This direction A-A′ also corresponds to the direction of translational movement of button head 2. In the following description, the dimension measured along the main direction of extension A-A′ of pusher 4 will be referred to as the ‘height’. According to an example embodiment of the invention, and in a non-limiting manner, pusher actuator 4 is an arbor or a screw mounted to slide through first hollow guide member 6 and an upper end 18b of which is fixed in the bottom of head housing 15. Upper end 18b of pusher actuator 4 is, for example, pressed into a hollow sleeve 23 forming the bottom of head housing 15. In the particular example embodiments illustrated in
Collar 22 is capable of cooperating with an internal face 24 of first hollow guide member 6 to guide pusher 4 inside member 6. Collar 22 extends radially over the periphery of upper portion 20 of pusher actuator 4. In the particular example embodiments of
In a first embodiment of the invention, collar 22 has a height corresponding to at least 1/25th of the total height of the pusher actuator. In the illustrative example represented in
In a second embodiment of the invention, collar 22 has a height corresponding to at least 1/10th of the total height of the pusher actuator. In the illustrative example represented in
Preferably, and as illustrated in
First hollow guide member 6 is intended to be secured to a fixed element relative to button head 2 and to pusher actuator 4. In the particular case where push button system 1 is fitted to a timepiece, the fixed element is the timepiece case, and first hollow guide member 6 is secured to the case, as will be explained in detail below.
According to a particular example embodiment represented in
First hollow guide member 6, delimits, for example, an internal sliding opening 28a leading to an internal cylindrical gasket housing 28b. Internal cylindrical gasket housing 28b leads to an internal cylindrical cavity 28c. The diameter of internal cylindrical gasket housing 28b is greater than the diameter of internal sliding opening 28a and the diameter of internal cylindrical cavity 28c is greater than the diameter of internal cylindrical gasket housing 28b. This configuration is advantageously obtained by machining. Internal cylindrical gasket housing 28b is, for example, delimited by a first shoulder 30a, and internal cylindrical cavity 28c is delimited by a second shoulder 30b.
In the particular case where pusher button system 1 is fitted to a timepiece, first hollow guide member 6 can be force-fitted onto the timepiece case. More specifically, lower outer part 26a of first hollow guide member 6 can be pressed into the opening provided in the case, and first hollow guide member 6 can be welded onto the case. Such an assembly process makes it possible to obtain a definitive and water resistant mechanical connection between the case and first hollow guide member 6.
As illustrated in
Compression spring 12 rests, on the one hand, on the bottom of collar 22 and, on the other hand, on first hollow guide member 6. More precisely, according to a particular embodiment example illustrated in
Each sealing means 14a, 14b is arranged between pusher actuator 4 and first hollow guide member 6. One of the sealing means 14a is, for example, formed of an O ring type seal arranged in the internal cylindrical gasket housing 28b resting on first shoulder 30a. The other sealing means 14b is, for example, formed of a pressure ring type seal arranged in internal cylindrical joint housing 28b.
During operation, pressure on the external face of button head 2 compresses compression spring 12 and moves pusher actuator 4 inside first hollow guide member 6. In doing so, collar 22 cooperates with internal face 24 of first hollow guide member 6, guiding pusher 4 inside first hollow guide member 6. The lower end 18a of pusher actuator 4 then acts on the actuation member, such as a chronograph control lever or a switch in the case of application to an electronic watch.
It is thus understood that push button system 1 according to the invention allows improved guidance of pusher 4 inside first hollow guide member 6, thereby stiffening the entire assembly and thus reducing the risk of pusher 4 bending, particularly when the latter is subject to radial stresses. The reliability and overall water resistance of system 1 are thus advantageously improved.
Number | Date | Country | Kind |
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19176219.4 | May 2019 | EP | regional |