CH712890B1 - Oscillating weight mechanism for measuring physical activity. - Google Patents

Abstract

The invention relates to a mechanism for measuring physical activity, comprising: an oscillating mass (1) about an axis of rotation; a block (2) movable under the action of gravity to limit the oscillations of the oscillating weight in a horizontal position, and to increase the amplitude of these oscillations in a vertical position. Such a mechanism can for example be used to count steps in a pedometer.

Description

Technical area

The present invention relates to a mechanism with an oscillating weight for measuring physical activity, as well as a mechanical watch comprising such a mechanism.

State of the art

[0002] Mechanical watches are usually driven by the energy stored in a barrel. The barrel is wound by means of the crown or, in the case of an automatic watch, thanks to the oscillations of an oscillating weight set in motion by the movements of the wrist.

[0003] Furthermore, in the state of the art, wristwatches and other devices worn on the wrist are known which make it possible to determine the physical activity of the wearer. Some electronic watches are for example equipped with a step counter with an accelerometer which makes it possible to determine the number of steps taken by the wearer. Other sports watches are used to display the distance covered during a race, the altitude difference, or other parameters related to physical activity. These accelerometers are usually produced by means of a MEMS component and therefore require an electrical power source, for example a battery.

[0004] EP0060361 A1 and EP0277011 both relate to an electronic watch comprising a pendulum whose oscillations make it possible to determine the number of steps of the user.

[0005] Mechanical pedometers are also known in the state of the art which measure the number of oscillations of an oscillating weight to determine the number of steps of the wearer. However, the accuracy of this type of pedometer is very limited; in fact, the oscillating mass is put into oscillation by all movements of the wrist, even if the user is not walking. Even activities that only involve limited calorie consumption, such as handwriting or eating, cause the mass to oscillate and are interpreted as steps.

Brief summary of the invention

[0006] An aim of the present invention is therefore to provide an improved mechanism for measuring physical activity.

[0007] In particular, an aim of the present invention is therefore to provide a more appropriate mechanism for measuring the physical activity of a user, and which makes it possible to provide an indication more representative of the physical activity of the user.

[0008] According to the invention, these goals are achieved in particular by means of a mechanism for measuring physical activity, comprising: <tb> <SEP> an oscillating weight; <tb> <SEP> a block that can be moved under the action of gravity to limit the oscillations of the oscillating mass in a horizontal plane, and to increase the amplitude of these oscillations in a vertical plane.

[0009] In wristwatches, the oscillating weight is most often in the plane of the watch movement, that is to say parallel to the plate of the movement and therefore to the outer face of the wrist which wears the watch. It therefore oscillates around an axis substantially perpendicular to the external face of the wrist.

By integrating the above mechanism into a wristwatch or another bracelet, the oscillating weight oscillates when the external face of the wrist is vertical, for example during walking or running, but hardly oscillates when the outer face of the wrist is horizontal, for example during office work or other activities while sitting or lying down.

[0011] This mechanism therefore makes it possible to count the oscillations when the outer face of the wrist is in a substantially vertical position, and not to count them when the outer face of the wrist is in a substantially horizontal position.

The outer face of the wrist is in fact in a substantially vertical position when walking while running, and in a substantially horizontal position during more static activities such as writing, reading or office work.

The center of inertia of the oscillating mass-block assembly moves relative to the axis of rotation when the oscillating mass is tilted. Consequently, the unbalance of the oscillating assembly depends on the orientation of the axis of rotation of this assembly.

[0014] The axis of inertia of the oscillating mass -block assembly is substantially coincident with the axis of rotation when this axis of rotation is vertical, or close to the vertical position. This results in an assembly which is balanced, that is to say devoid of unbalance, and which therefore practically does not oscillate around the axis of rotation, even when it is subjected to accelerations.

When the user walks or runs, the axis of rotation is found in a horizontal or almost horizontal position. In this position, the axis of inertia of the oscillating mass plus block assembly is remote from the axis of rotation; this movement of the block causes an unbalance, which allows the assembly to oscillate around the axis of rotation if it is subjected to accelerations.

In one embodiment, the mechanism for measuring physical activity comprises an elastic return element arranged to push the block back into a first position relative to the mass when the axis of rotation is vertical, and to allow the block to move under the effect of gravity in a second position relative to the oscillating mass when the axis of rotation is horizontal.

The movement of the block against the action of the return springs is possible at least in an orientation of the oscillating weight in the vertical plane. For example, movement of the block is possible when the center of gravity of the block is below the center of rotation.

[0018] According to one aspect, the invention relates to a mechanism in which the oscillations of an assembly with a block and an oscillating mass are possible when the center of gravity of the block is below the axis of rotation.

[0019] The position of the block acts on the amplitude of the oscillations of the oscillating weight.

The elastic return element makes it possible to bring the axis of inertia closer to the axis of rotation in a horizontal position, and to reduce the unbalance in this position.

The mechanism may include a guide axis integral with the oscillating weight, the block sliding along this guide axis. This ensures a rectilinear movement of the block.

In a preferred embodiment, the mechanism comprises two guide axes parallel to each other and integral with the oscillating mass. The block slides along these two guide axes. The rectilinear guiding of the block is thus more precise.

[0023] The guide pin (s) may be constituted by rods passing through the block.

The oscillating weight can include a window. In one embodiment, the block can slide in this window between the first and the second position, and vice versa.

The oscillating weight advantageously has a substantially circular periphery. A constant radius facilitates the realization of an assembly without unbalance when the block is in first position.

The window through the oscillating weight modifies the distribution of mass around the center of distribution and therefore creates an unbalance. This unbalance is compensated when the block is in first position, but not when the block is in second position.

[0027] The density of the block is preferably higher than the density of the oscillating weight. The block which has a smaller area than the hollowed-out window is therefore sufficient to compensate for the unbalance created by this window.

[0028] Alternatively, the block is thicker than the oscillating weight.

The block may have the shape of a semicircle.

The window may have the shape of a semicircle with a radius greater than that of the block.

At least one return element of the half block can be housed in the window through the oscillating weight. This return element can push the block back inside the window in the direction of the center of rotation.

A return element can be formed by at least one leaf spring inside the window.

One end of the leaf spring can be linked to the block, the other resting against the inner edge of the window.

Several blocks can be provided, in one or more windows, or even outside the oscillating weight.

In another embodiment, the oscillating unit can be arranged to slow down the oscillations of the oscillating mass in the horizontal position, and to reduce this braking in the vertical position.

The oscillating block can be guided on a rail or a slide linked to an element of the movement other than the oscillating mass. It may not oscillate with the mass. It can exert a friction which attenuates the amplitude of the oscillations of the oscillating mass, the braking being greater in the first position than in the second position.

[0037] The subject of the invention is also a mechanical watch comprising the mechanism according to one of the above embodiments, and a physical activity indicator actuated by the oscillating weight.

The data representative of the physical activity can for example be determined by an integration of the oscillations undergone by the oscillating mass since an instant of zeroing, or per unit of time.

By data representative of physical activity is meant in the present application data whose primary function is to inform the wearer of the watch on the efforts made during a physical activity. Data are said to be representative of the physical activity of a person when they are intended to determine the level of physical activity of the person and to indicate to him whether this activity is sufficient, for example as part of a training or formatting, or whether it needs to be increased. The physical data may for example include an estimate of the number of steps taken, of a distance traveled, of an energy supplied since the start of the measurement, or of an energy per unit of time.

Brief description of the figures

Examples of implementation of the invention are indicated in the description illustrated by the appended figures in which: <tb> • <SEP> FIG. 1 illustrates a perspective view of a mechanism according to the invention. <tb> • <SEP> FIG. 2 illustrates a top view of a mechanism according to the invention. <tb> • <SEP> FIG. 3 illustrates a sectional view of a mechanism according to the invention.

Example (s) of embodiment of the invention

An example of a mechanism is illustrated in Figures 1 to 3. The mechanism is intended to be integrated into a portable device, for example a mechanical wristwatch, a bracelet, a pedometer, etc. The oscillations of this set are used to determine the physical activity of the wearer, for example the number of steps taken. Optionally, these oscillations can be used to charge a barrel and supply the energy necessary for the operation of the device. In a variant, the device may include an additional oscillating weight dedicated to winding the main barrel.

The illustrated mechanism comprises an oscillating mass 1 mounted on an axis C which allows it to oscillate in a plane perpendicular to this axis. A cog not described makes it possible to transmit these oscillations to a watch movement, a pedometer or another device which determines for example the number of oscillations, possibly taking into account their amplitude, to determine and display a quantity representative of the activity physical wearer. This cog is within the abilities of those skilled in the art and will not be described. In one embodiment, the gear train comprises a unidirectional drive system and transmits only the oscillations in one direction, the oscillations in the other direction being free.

The oscillating weight 1 illustrated is of substantially cylindrical shape, with a substantially circular periphery. It comprises a window 10 substantially in the form of a semi-circle in top view. This window modifies the distribution of mass of the oscillating mass 1 around the center of rotation C and thus creates an unbalance on the side opposite the window.

A block 2 is mounted in this window 10 on two guide rails 4A, 4B which allow it to slide so as to approach the center of rotation (in the first position) or on the contrary to move away from it under the effect of gravity (in second position). Return springs, here leaf springs 3A, 3B, are fixed by a screw or a pin on the periphery of the block 2. The opposite end of the leaf spring rests on the internal edge of the window 10 so as to exert a restoring force which pushes the oscillating mass towards the center of rotation C.

The block 2 illustrated in this example has a shape substantially of a semi-circle; thanks to a higher density, and / or an increased thickness, its moment of inertia compensates for the unbalance created by the window 10 when the block is in the first position, that is to say close to the center of rotation. In this position, the oscillating mass 1 plus unit 2 assembly is balanced, so that acceleration on this assembly does not cause rotation around the C axis.

When the mechanism is in a substantially vertical position, that is to say when the axis of rotation C is substantially horizontal, and the window 10 is towards the bottom of the oscillating mass, the weight of the block 2 s 'opposes the return force of the springs 3A, 3B, which allows the block 2 to descend and move away from the center of rotation C. The moment of inertia I of the assembly is then away from the axis of rotation C, which creates an unbalance and allows the assembly to oscillate if it is subjected to accelerations.

This arrangement thus allows the assembly 1, 2 to oscillate under the effect of accelerations when the oscillating weight 1 is in a substantially vertical plane with the window 10 downwards, and to hardly oscillate under the effect of accelerations when the oscillating mass 1 is in a horizontal plane. More generally, the oscillating assembly has an unbalance as soon as the center of gravity of the body 2 is below the axis of rotation c, which allows the body 2 to move in the window 10 under the effect of gravity.

The return force of the return leaf springs 3A, 3B is preferably chosen so as to create a progressive displacement of the oscillating weight 1 between these two positions, and thus to modify the amplitude of the oscillations caused by a given acceleration according to the inclination of the plane of the oscillating weight.

It is thus possible to produce a watch movement or a pedometer which reacts to movements of the wrist when the external face of the wrist is vertical (for example during walking or running), and which does not react, or less, when the outside of the wrist is horizontal.

Claims (12)

1. Mechanism for measuring physical activity, comprising: an oscillating mass (1) around an axis of rotation (C); a block (2) subjected to the action of gravity so as to move and limit the oscillations of the oscillating mass (1) when the axis of rotation (C) is vertical, and to increase the amplitude of these oscillations when the axis of rotation (C) is horizontal, the axis of inertia of the oscillating mass - block assembly being substantially coincident with the axis of rotation (C) when this axis of rotation is vertical, the axis d the inertia of the oscillating mass - block assembly being away from the axis of rotation (C) when this axis of rotation (C) is horizontal, this movement of the block (2) causing an unbalance. 2. Mechanism according to claim 1, comprising: an elastic return element (3A, 3B) arranged to push the block (2) back into a first position relative to the oscillating mass (1) when the axis of rotation (C) is vertical, and to allow the block to stand moving under the effect of gravity into a second position relative to the oscillating mass when said axis of rotation is horizontal, the position of the block acting on the amplitude of the oscillations of the oscillating mass. 3. Mechanism according to claim 2, comprising a guide axis (4A, 4B) integral with said oscillating weight (1), the block (2) sliding along said guide axis. 4. Mechanism according to claim 3, comprising two guide axes (4A, 4B) mutually parallel and integral with said oscillating mass (1), the block (2) sliding along said guide axes. 5. Mechanism according to claim 3 or 4, the guide pin or pins (4A, 4B) passing through said block (2). 6. Mechanism according to one of claims 3 to 5, said oscillating weight (1) comprising a window (10), said block sliding in said window. 7. Mechanism according to claim 6, the periphery of the oscillating weight (1) being substantially circular, said window (10) having the shape of a semi-circle. 8. Mechanism according to claim 6 or 7, said return element (3A, 3B) being housed in said window (10). 9. Mechanism according to claim 8, said return element being constituted by at least one leaf spring (3A, 3B). 10. Mechanism according to claim 9, one end of said leaf spring (3A, 3B) being linked to the block (2), the other resting against the inner edge of the window (10). 11. Mechanism according to claim 2, said block (2) being arranged to brake the oscillations of the oscillating weight (1) in the first position, and to reduce this braking in the second position. 12. Mechanical watch comprising the mechanism according to one of claims 1 to 11 and a physical activity indicator actuated by said oscillating weight.