CH701867A1 - Wrist watch, has mobile mass moved by inertia from rest position in direction opposed to action exerted by elastic unit in order to drive indicating bodies according to displacement whose amplitude is temporary displacement function of mass - Google Patents

Abstract

The wrist watch has a mobile mass (401) i.e. balloon, for driving quantity indicating bodies (406a-406c), where a measuring and indicating device i.e. mechanical accelerometer, measures and indicates quantity relative to acceleration of the wrist watch. The mobile mass is moved by inertia from a rest position in a direction opposed to action exerted by an elastic unit (404) i.e. spiral spring, in order to drive the indicating bodies according to displacement whose amplitude is a function of temporary displacement of the mobile mass.

Description

The present invention relates to the field of watchmaking, more particularly to a wristwatch having a mechanical accelerometer.

There are already wristwatches with an accelerometer for performing different functions. Most of these accelerometers are integrated in electronic watches to fulfill different functions. By way of example, the publication US 2004 186 695 discloses an electronic watch comprising a piezoelectric or capacitive detection accelerometer in order to fulfill the function of a pedometer.

Some electronic wristwatches have an accelerometer that fulfills another function. This can for example control the backlight of the watch by removing the display when no movement is detected by energy saving measure.

However, there are some publications that disclose a mechanical wristwatch having a device for measuring the activity of the wearer. For example, the publication CH 377 738 discloses a portable measuring instrument comprising in a common housing a movement indicating device and a self-winding watch whose mobile winding mass drives the indicator member of the device under the action of the movements of the carrier of the instrument.

These mechanical devices, however, do not allow a measurement of the acceleration experienced by the watch.

Thus, the purpose of the present invention is to provide a wristwatch having a mechanical accelerometer.

According to the invention, this goal is achieved through a wristwatch having a device for measuring and indicating a magnitude relative to an acceleration experienced by the wristwatch. This device comprises an indicator member of said magnitude, a movable mass arranged to be able to drive the indicator member, and an elastic means arranged to be able to act on the displacement of the moving mass. It is mounted to be able to move by inertia when the wristwatch is accelerated and from a rest position in a direction opposite to the action exerted by the elastic means to be able to drive the indicator member according to a displacement whose amplitude is a function of the momentary movement of the mass.

The characteristics of the invention will appear more clearly on reading a description of several embodiments given solely by way of example, in no way limiting with reference to the schematic figures, in which: <tb> fig. 1 <sep> represents a plan view of the dial of the wristwatch according to a first embodiment, <tb> fig. 2 <sep> represents a perspective view of the device according to this first embodiment, <tb> fig. 3 <sep> represents a sectional view of FIG. 1according to A-A, <tb> fig. 4 <sep> represents a sectional view of FIG. 1according to B-B, <tb> fig. <Sep> represents a plan view of the device according to a second embodiment, <tb> fig. 6 <sep> represents a sectional view of FIG. 5according to A-A, <tb> fig. 7 <sep> represents a sectional view of FIG. 5according to B-B, <tb> fig. 8 <sep> represents a plan view of the dial of the wristwatch according to a third embodiment, <tb> fig. 9 <sep> represents a plan view of the device according to this third embodiment, <tb> fig. <Sep> is a partial view of FIG. 9 <tb> fig. 11 <sep> represents a sectional view of FIG. 9according to B-B, <tb> fig. 12 <sep> represents a plan view of the device according to a fourth embodiment, <tb> fig. 13 <sep> is a schematic sectional view of FIG. 12 according to A-A. <tb> fig. 14 <sep> represents a partial plan view of the dial of the watch according to a fifth embodiment, <tb> fig. <Sep> represents a plan view of the device according to this fifth embodiment, <tb> fig. 16 <sep> represents a sectional view of FIG. 15according to A-A, <tb> fig. 17 <sep> represents a view of a system for resetting the device, <tb> fig. 18 <sep> represents a plan view of the device according to a sixth embodiment.

The device for measuring and indicating a magnitude relative to an acceleration experienced by the wristwatch at a specific time will be referred to hereinafter as "mechanical accelerometer."

According to the first embodiment of the present invention, the wristwatch is provided with a mechanical accelerometer comprising an unbalance 101, as illustrated in FIG. 2, arranged to pivot about an axis corresponding to the central axis around which generally turn the hands of a watch. The shape of the unbalance 101 is similar to a pendulum having a substantially rectangular portion 102 whose one end is integral with a predefined mass 101a while the other end is driven on a central shaft 103 (Figure 3). According to FIG. 2, two coil springs 104 are arranged on either side of the rectangular portion 102 so that one of their ends is connected to said portion 102 and the other of their ends is connected to the plate of the movement of the wristwatch by means of a rivet 105 so that these two springs 104 can exert an action opposed to the movement of the unbalance 101. A bridge 107 is arranged on the movement stage and comprises a bearing 108 within which is arranged the upper part of the shaft 103 on which is driven an instantaneous needle 106. Thus, the angular movement of the unbalance 101 caused during an acceleration undergone by the wristwatch rotates the shaft 103 about its axis making to pivot the instantaneous needle 106 by an amplitude proportional to the amplitude of the movement of the unbalance 101. The dial 110 of the wristwatch comprises a display 109 on an angular sector predefined area. The mass 101a of the unbalance 101, the mechanical properties of the two coil springs 104, 104 and the configuration of the display (FIG 1) are determined so that the measurement of the acceleration undergone by the wristwatch can be displayed. in a desired unit, such as m / s <2> or G.

According to the second embodiment of the invention, the elastic member used is a spiral spring 204 as shown in Figs. 5, 6 and 7. One end of this spring 204 is secured to a central shaft 203 by means of a ferrule 211 while the other end of this spring 204 is connected to a pin 212 maintained by a bolt carrier 213 by means of a screw 214, the latter being secured to a bridge 207 arranged on the platen of the movement. Like the previous embodiment, an instantaneous needle 206 is driven on the shaft 203, the latter being capable of being driven by an unbalance 201 similar to a pendulum having a substantially rectangular portion 202 of which one end is secured to a predefined mass 201a while the other end is driven on the shaft 203.

According to the third embodiment of the invention as illustrated in FIGS. 8 to 11, the mechanical accelerometer is provided with a first and a second instantaneous needle 306, 306 arranged so that there is an angle of 90 ° between them relative to their common axis of rotation when they are in their rest position. This first and second instantaneous needle 306, 306 is capable of scanning an angular sector respectively corresponding to a first and a second display 309, 309 arranged on the dial 310. These two needles 306, 306 are driven respectively on a first and a second shaft 303, 303 coaxially mounted at the center of the movement, the second shaft 303 being arranged to freely rotate about the first shaft 303. A first bridge 307 is arranged on the stage of the movement and has a bearing 308. traversed by the upper part of the two coaxial shafts 303, 303.

A first unbalance 301 is integral with the lower portion of the first shaft 303, while a second unbalance 301 is secured to the second shaft 303 so that there is an angle of 90 ° between them relative to their common axis of rotation (Fig. 10). A first ferrule 311 is mounted on first shaft 303 between the first unbalance 301 and the lower end of the second shaft 303 to receive one end of a first spiral spring 304 while the other end of the first spiral spring 304 is connected to a first stud 312 mounted on a second bridge 307 arranged on the plate of the movement.

A second ferrule 311 is mounted on the second shaft 303 above the second unbalance 301 to receive an end of a second spiral spring 304 while the other end of the second spiral spring 304 is connected to a second stud 312 mounted on the first bridge 307.

According to a fourth embodiment of the invention as shown in Figures 12 and 13, the mechanical accelerometer comprises an unbalance 401 arranged to be able to rotate a first shaft 403a on which is driven an instantaneous needle 406a. A first memory needle 406b is driven on a second shaft 403b arranged coaxially on the first shaft 403a. The lower end of this second shaft 403b has an arm 415 having at its end a first pin 416 arranged to be in contact with a second pin 417 integral with the unbalance 401. A second memory needle 406c is driven on a third shaft 403c arranged to rotate freely around the second shaft 403b. The lower end of this second shaft 403b has an arm 420 having at its end a third pin 418 arranged to be in contact with the second pin 417 integral with the unbalance 401. Two coil springs 404 are arranged on either side of the unbalance 401 so that one of their ends is connected to the unbalance 401 and the other of their ends is connected to the plate of the movement.

Thus, the angular movement of the unbalance 401, caused during an acceleration undergone by the wristwatch, rotates the shaft 403a about its axis in order to rotate the instantaneous needle 406a of a proportional amplitude. the amplitude of the displacement of the unbalance 401. According to the direction of acceleration experienced by the wristwatch, the first or the second memory needle 406b, 406c is also rotated by the unbalance 401 by means of its pin 417.

The second and third needles 406b, 406c each comprise an arcuate portion 430b, 430c located in the plane of displacement of the needle and stretching along a curvature having a concentric radius to the axis of rotation 406b needles , 406c. The arcuate portion 430b, 430c is provided with serrated toothing to collaborate with a finger 440b, 440c.

When one or other of the memory needles 406b, 406c has reached its maximum stroke during an acceleration undergone by the wristwatch, this needle 406b, 406c is immobilized by means of the finger 440b, 440c sou l ' action of a spring 450b, 450c. A pusher 460b, 460c is arranged to actuate the finger 440b, 440c to disengage it from the toothing of the arcuate portion 430b, 430c to allow the memory needle 406b, 406c to resume its initial position under the action of a return spring 480 (only one of the two springs of each memory needle 406b, 406c is illustrated in Fig. 12).

According to a fifth embodiment of the invention, the mechanical accelerometer comprises an instantaneous needle 506a arranged to move rectilinearly during an acceleration undergone by the wristwatch. In this configuration, the needle 506a measures the acceleration in a given direction. This needle is mounted on a first mass 501a having the shape of a prism with a rectangular base. This first mass 501a is arranged to slide along a rod 520a which passes through it from side to side. A coil spring 504a is arranged around this rod 520a on either side of the mass 501a.

This mechanical accelerometer further comprises a first and a second memory needle 506b, 506c which are superimposed in their rest position and which are further arranged to be able to move parallel to the rectilinear movement of the first needle 506a and in one direction opposite. Each of these two needles 506b, 506c is mounted on a second and a third mass 506a, 506b, which are slidably arranged along a second and a third rod 520b, 520c respectively. Each of these two masses 506a, 506b comprises a blade 530b, 530c whose end collaborates with a part 540 having a sawtooth profile.

When each memory needle 506b, 506c has reached its maximum stroke during an acceleration undergone by the wristwatch, this needle 506b, 506c is immobilized by blocking the second and the third mass 501b, 501c by means of the blade 530b, 530c whose end bears against a tooth of the part 540. This part 540 is arranged to be actuated in a direction perpendicular to the displacement of the masses in order to be able to disengage the blades 530b, 530c of the teeth of this part 540 to allow the return of the second and the third mass 501b, 501c in its initial position thus resetting the memory needles. This part 540 is actuated by a pusher 550 and by means of a rocker 560 intended to move a pin 580 driven-in said part 540.

It goes without saying that certain features of any embodiment may be substituted and / or added to some features of one of the other embodiments. By way of example, FIG. 18illustrates a variant combining the characteristics of the first and fifth modes of execution.

Claims (12)

A wristwatch having a device for measuring and indicating a magnitude relative to an acceleration experienced by the wristwatch, the device comprising an indicator member (106, 206, 306, 306, 406a, 406b, 406c, 506a, 506b 506c) of said magnitude, a moving mass (101, 201, 301, 301, 401, 501a, 501b, 501c) arranged to drive the indicator member, and resilient means (104, 204, 304, 304 , 404, 404, 504) arranged to act on the displacement of the moving mass, said mass being mounted to move: - by inertia when the wristwatch is accelerated; - from a rest position in a direction opposite to the action exerted by the elastic means; for driving the indicator member (106, 206, 306, 306, 406a, 406b, 406c, 506a, 506b, 506c) in a displacement the magnitude of which is a function of the momentary displacement of the mass (101, 201, 301, 301, 401, 501a, 501b, 501c). 2. Wristwatch according to claim 1, wherein the moving mass (101, 201, 301, 301, 401, 501a, 501b, 501c) is arranged to be able to move linearly or angularly. 3. Wristwatch according to claim 1 or 2, wherein the moving mass is an unbalance (101, 201, 301, 301, 401) arranged to be able to actuate in rotation a shaft (103, 203, 303, 303, 403a, 403b, 403c), on which the indicator member (106, 206, 306, 306, 406a, 406b, 406c) is arranged. 4. Wristwatch according to claim 1, 2 or 3 wherein the elastic means is constituted by two springs (104, 404) arranged on either side of the mass (101, 401) so that each spring (104, 404) exerts a counteraction to the movement of the latter. 5. Wristwatch according to one of claims 1 to 4, wherein the resilient elastic means is a spiral spring (204, 304, 304). The wristwatch according to claim 3, 4 or 5, further comprising a second and a third shaft (403b, 403c) arranged coaxially with the first shaft (403a) and on which a second and a third member are respectively arranged. indicator (406b, 406c), the second and third shafts (403b, 403c) being arranged to be actuable by the unbalance (401). The wristwatch according to claim 2, wherein the mass (501a) has a prism shape on which is mounted the indicator member (506a), said mass (501a) being arranged to be able to slide along a rod. (520a) and wherein the elastic member consists of two coil springs (504a) arranged around the rod (520a) on either side of the mass (501a). The wristwatch according to claim 7, further comprising a second and a third mass (501b, 501c) in the form of a prism on which a second and a third indicator member (506b, 506c) are respectively mounted, said masses (501b). , 501c) being slidably arranged along a second and a third rod (520b, 520c), respectively, two coil springs (504b, 504c) being arranged around the second and third rods (520b, 520c) on either side of the second and third masses respectively (501b, 501c). 9. A wristwatch according to claim 8 or 9, further comprising a device for immobilizing the second and the third indicator member (406b, 406c, 506b, 506c) when they have reached their respective maximum stroke during a acceleration undergone by the wristwatch, the second and third indicator members (406b, 406c, 506b, 506c) being arranged to be operable in an opposite direction. 10. Wristwatch according to any one of claims 3 to 6, further comprising a second movable mass (301, 501b) and a second elastic member (304, 504b) arranged to exert an action opposite to the displacement of the second mass (301, 501b) to be able to drive and move a second indicator member (306, 406b, 506b) in an amplitude relative to the momentary displacement of the second mass (301, 501b). 11. Wristwatch according to claim 10, wherein the second mobile mass is an unbalance (301) arranged to be able to actuate in rotation a second shaft (303, 403b) on which is arranged the second indicator member (306, 406b), the first and second shafts (303, 303) being arranged coaxially. The wristwatch of claim 10 or 11, wherein the first and second indicator members (306, 306) are arranged to have an angle of 90 ° between them when in the home position.