CH718022A2 - Mechanical watch movement with power reserve detection. - Google Patents

Abstract

The mechanical clock movement (1) comprises at least a barrel system (2) for driving a set of wheels and power reserve detection means. The power reserve detection means (10) comprise a control wheel (3) arranged facing the cage of the barrel system (2), to rotate around an axis of rotation (23) parallel to the axis center (16) of the barrel system (2). The control wheel is arranged to be driven in rotation by a complementary wheel (8) at the output of the differential to determine a power reserve level. The control wheel comprises an opening (13) having a first end (21) for defining a full charge of the barrel system and a second end (22) for defining a full discharge of the barrel system (2). There is also provided a lever (4) rotatably mounted around a lever axis (14) parallel to the axis of rotation (23) of the control wheel. The lever (4) comprises a contact element (5) arranged in the opening (13) to come into contact with the second end (22) of the opening (13) during a power reserve indication at zero . A portion or an element of the lever (4) comes into contact with a component of the movement in order to stop the operation of the latter when the power reserve indication is at zero.

Description

TECHNICAL AREA

The present invention relates to a mechanical clock movement provided with power reserve detection means.

TECHNOLOGICAL BACKGROUND

[0002] A power reserve of a mechanical watch movement of a mechanical watch makes it possible to display to a person wearing the watch the operating time before the watch movement stops. It has been observed that the power reserve from one watch to another can vary substantially depending mainly on the manufacturing tolerances of the watch, wear, lubrication, roughness.

[0003] In a traditional mechanical clock movement, it is found that the clock movement still operates even after the power reserve indicator already indicates zero. This is a disadvantage that the watch still works even when the power reserve indication is at zero. Thus the instant when the watch stops is not synchronous with the instant when the hand indicates zero.

[0004] A mechanical timepiece movement generally comprises a barrel system driving at least one wheel at the load output and one wheel at the discharge output connected respectively to a load wheel and to an unload wheel of a differential. A set of wheels linked to an intermediate wheel of the differential controls a power reserve display, but no element of the movement is provided for a movement blocking operation when the power reserve is at zero.

[0005] Patent EP 0 568 499 B1 describes a power reserve indicator device for a mechanical watch. The indicator device comprises at least one star wheel with an indicator member, which is driven in rotation when the barrel is loaded or unloaded. The indicator organ makes it possible to display the power reserve of the watch. However, nothing is provided to ensure that the movement is blocked when the power reserve approaches zero.

[0006] Patent CH 698 752 B1 describes a timepiece which includes a mechanism for indicating the power reserve. It comprises two barrels facing each other and connected by a common shaft, which controls the power reserve display mechanism. However, nothing is provided to ensure that the movement is blocked when the power reserve approaches zero.

[0007] Patent application CH 710 320 A2 describes a timepiece, which comprises a source of mechanical energy, such as a barrel and a control member in connection with a control device in the watch case. The control device comprises a power reserve wheel pivotally mounted on the frame and connected to the barrel by a differential so that the angular position of the power reserve wheel is a function of the level of charge of the barrel. A control cam is pivotally mounted on the same axis as the power reserve wheel. The control cam has a slot extending in an arc of a circle in which is housed a pin integral with the power-reserve wheel. A spiral spring is mounted between the power reserve wheel and the cam. In connection with the control device, there is also provided a stop device, which comprises a stop rocker, to block the movement when the power reserve is close to zero.

SUMMARY OF THE INVENTION

[0008] The main purpose of the invention is therefore to overcome the drawbacks of the state of the art by proposing a mechanical watch movement equipped with power reserve detection means and capable of directly blocking the operation of the movement, when the power reserve is close to or equal to zero, using a minimum of components to obtain a compact system.

To this end, the present invention relates to a mechanical timepiece movement provided with power reserve detection means, which comprises the characteristics of independent claim 1.

[0010] Particular embodiments of the mechanical clock movement are defined in dependent claims 2 to 12.

[0011] An advantage of the mechanical timepiece movement with the power reserve detection means resides in the fact that an increase in the power reserve indication precision is achieved. This means that the power reserve detection means are made in such a way that the power reserve indication at zero corresponds to the actual stopping of the mechanical movement of the watch.

[0012] Advantageously, a control element, which may be a wheel or a plate, is preferably linked directly to a wheel of an arrangement of drive wheels at the output of the differential to be driven in rotation or in a rectilinear direction. . Depending on the position of the control element, once the power reserve indication is at zero, there is a direct blocking of the watch movement via the barrel system, or even the mechanical oscillator having a spiral balance in an extreme case.

[0013] Advantageously, the power reserve detection means preferably comprise a control wheel and a lever mounted rotatably about a lever axis and cooperating with the control wheel so as to determine on the one hand that the barrel is completely charged, and on the other hand that the barrel is practically completely discharged for the power reserve indication at zero. The control wheel comprises an opening in the form of an arc of a circle of a determined angle and centered on the axis of the wheel, and the control lever comprises a contact element, such as a rod or a pin or a blade inserted into the opening of the control wheel. The axis of the wheel is arranged parallel to the central axis of the barrel system.

Advantageously, the opening of the control wheel comprises a first end for determining a 100% power reserve of the barrel and a second end for determining a 0% power reserve of the barrel system. The first and second ends have circular portions. Preferably, the circular portions at the ends define half of a circle with a radius corresponding to half the width of the opening. The power reserve is at 100%, i.e. the barrel system is fully charged, when the stem or the pin, or when a complementary stem or complementary pin which may be the central axis of the barrel between the rod or pin of the lever and the first end, comes into contact with the first end. The power reserve is at zero when the rod or the pin or the blade of the lever comes into contact with the second end. In this case, the lever pivots around its axis of rotation in such a way as to allow a blocking part of the lever to come and block any element of the movement causing the complete and instantaneous stoppage of the movement.

In a first embodiment, the lever comprises a blocking piece at one end of the lever coming into frictional contact with a peripheral edge of the cage of the barrel system to block the watch movement. The locking piece is at an opposite end to that of the contact element, which is the rod or pin inserted into the opening of the wheel. The axis of rotation of the lever is close to the blocking part and arranged in such a way that in the blocking position, the rotation of the lever brings the blocking part against the peripheral edge of the barrel system.

In a second embodiment, the lever comprises a locking part in the form of a tooth at one end of the lever to be inserted between two teeth of a toothed wheel on the periphery of the barrel system. As before, the blocking piece is at an end opposite that of the rod or the pin inserted in the opening of the wheel. The axis of rotation of the lever is close to the rod where the pin of the lever is arranged in such a way that in the locking position, the rotation of the lever brings the tooth into the peripheral toothing of the barrel system.

[0017] In a third embodiment, the lever comprises a blocking piece at an end remote from the lever to come into contact with a rim of a spiral balance wheel as a mechanical oscillator. The axis of rotation of the lever is at an end opposite to the locking piece, while the rod or the pin inserted in the opening of the wheel is in an intermediate position, but close to the axis of rotation of the lever.

[0018] Advantageously, the power reserve detection means may comprise a control element in the form of a plate, which comprises a rectilinear opening with a first end and a second end, and a control lever rotatably mounted with a rod or a pin at one end of the lever, and inserted into the straight opening. The control element can be moved rectilinearly between guide portions by means of a toothed wheel at the barrel outlet meshing with a toothed rectilinear portion on one side of the control element. When the rod or the pin of the lever comes into contact in particular with the second end of the rectilinear opening, the watch movement is blocked by the blocking part of the lever in direct contact with the rim of the balance-spring with an indication of the power reserve to zero.

BRIEF DESCRIPTION OF FIGURES

[0019] The aims, advantages and characteristics of a mechanical watch movement provided with power reserve detection means will appear better in the following description in a non-limiting manner with regard to the drawings in which: FIGS. 1a, 1b and 1c show two three-dimensional views from above and a top view of the position shown in FIG. 1b of a first simplified embodiment of the mechanical timepiece movement fitted with power reserve detection means according to the invention, FIGS. 2a, 2b and 2c represent two three-dimensional views from above and a top view of the position represented in FIG. 2b of a second simplified embodiment of the mechanical timepiece movement fitted with power reserve detection means according to the invention, and FIGS. 3a, 3b and 3c represent two three-dimensional views from above and a top view of the position represented in FIG. 3b of a third simplified embodiment of the mechanical timepiece movement fitted with power reserve detection means according to the invention.

DETAILED DESCRIPTION OF THE INVENTION

[0020] In the following description, all the components of a mechanical watch movement provided with power reserve detection means, which are well known to a person skilled in the art in this technical field, are only described in a simplified manner. .

[0021] Figures 1a, 1b and 1c represent three-dimensional top views of some components of the mechanical timepiece movement 1 with the means 10 for detecting the power reserve, as well as a top plan view in the position of the power reserve means illustrated in Figure 1b of a first embodiment. The mechanical timepiece movement 1 for a watch is in the normal operating position in FIG. 1a and in the movement blocking position in FIG. 1b with a power reserve equal to zero, as well as in FIG. 1c.

[0022] The mechanical timepiece movement 1 comprises at least the barrel system 2, which is arranged for example on one face of a watch plate of the movement (not shown) or on another support plate. This barrel system 2 can be with a single barrel or with two barrels or more than two well-known barrels and having a charge output and a discharge output, as well as a differential to drive a base train of time. In the case presented in FIGS. 1a, 1b and 1c, a differential barrel system 2 can be used with a toothed wheel 24 peripheral to the cage of the barrel system 2 to drive at least one large medium wheel of the finishing gear train and /or a drive train starting from the axis or shaft 16 of the barrel system 2.

[0023] In general, there is provided at least one drive wheel linked to the axis or central shaft 16 of the barrel system 2. Preferably, as shown in FIGS. 1a, 1b and 1c, there is at least a first arrangement of drive wheels 7, 7', of which a base wheel 7 is fixed either to the cage of the barrel system 2 to rotate with the cage, or linked to the axis or central shaft 16 of the barrel system 2. Normally, the cage of the barrel system 2 rotates in the same direction as the central axis or shaft 16 of the barrel system 2.

[0024] Preferably according to the first embodiment, there is provided the first arrangement of drive wheels 7, 7' and also a second arrangement of drive wheels 6, 6', 6" as it is used a differential barrel system 2. The first arrangement of drive wheels 7, 7' is linked to a discharge inlet of the differential, while the second arrangement of drive wheels 6, 6', 6" is linked to a differential load input. In this first embodiment, the first arrangement of drive wheels 7, 7' comprises a first base wheel 7 fixed to the cage of the barrel system 2, while the second arrangement of drive wheels 6, 6 ', 6" comprises a first base wheel 6 linked directly to the axis or to the central shaft 16 of the barrel system 2.

The means 10 for detecting the power reserve of the mechanical watch movement 1 comprise a control element 3, which can be a control wheel as shown in this first embodiment, or also a control plate that can be moved in a straight direction. The control wheel 3 is arranged facing the cage of the barrel system 2, and can be arranged to rotate around an axis of rotation 23 parallel to the central axis 16 of the barrel system 2. A complementary member 8 under the form of a complementary wheel 8 in this case drives the control wheel 3 in a direction of charging or discharging the barrel system 2 in particular at the output of a differential.

In this embodiment, the control wheel 3 comprises an opening 13 as a control portion, said opening 13 having a first end 21 to define a full load of the barrel system 2 and a second end 22 to set a complete discharge of the barrel system 2 for the indication of the power reserve to zero. The opening 13 is in the form of an arc of a circle of a determined angle and centered on the axis 23 of the control wheel 3 while being parallel to the axis or central shaft 16 of the barrel system 2. The first end 21 of opening 13 and second end 22 of opening 13 have the shape of circular portions. These circular portions at both ends define half of a circle with a radius corresponding to half the width of the opening 13.

The means 10 for detecting the power reserve of the mechanical watch movement 1 further comprise a lever 4, which can preferably be rotatably mounted around a lever axis 14 parallel to the axis of rotation 23 of the wheel. control 3 and/or parallel to the central axis 16 of the barrel system 2. The lever 4 comprises a contact element 5 arranged in the opening 13 of the control element 3, which is the control wheel 3 in this first embodiment, to come into contact with the second end 22 of the opening 13 during a power reserve indication at zero. The lever 4 is pushed in rotation about its lever axis 14 by the second end 22 so that a blocking part 15 of the lever 4 comes into contact with the cage of the barrel system 2 is preferably in contact with an edge 12 of the cage of the barrel system 2. The axis of rotation 14 of the lever is arranged close to the blocking part 15 which can be a wedge or a stud fixed under a surface of the lever 4 or coming directly from the material with the lever 4 in general. The wedge or stud normally does not include any ribs on its periphery in order to bear only against the edge 12 of the barrel system 2 in order to block the movement by friction.

In one embodiment not shown, the lever 4 can be movable in rotation or in a rectilinear manner. The lever 4 can comprise a contact element 5, which is arranged facing a control portion 13 of the control element 3 or in a control portion 13 of the control element 3. The control element 3 can be a wheel with a control portion in the form of a cam with a blocking member on the cam defining a zero power reserve. The contact element 5 in the form of a feeler or a wedge comes into direct contact with the blocking member when the power reserve is at zero to block the movement by the blocking part 15 of the lever 4.

[0029] The first arrangement of drive wheels also comprises a second wheel 7′ mounted coaxially on the axis of the complementary member 8 in the form of a wheel, and a first wheel 7 for rotating the second wheel 7′, said first wheel 7 being fixed on the cage of the barrel system 2 at the level of the central axis 16 of the barrel system 2. Preferably, the first wheel 7 is crossed by the axis or central shaft 16 of the barrel system 2 The two wheels 7, 7' and the complementary wheel 8 are toothed wheels to allow at least the first wheel 7 to drive said second wheel 7' by gearing. The contact between the second wheel 7' and the complementary wheel 8, as well as the contact between the third wheel 6" and the complementary wheel 8 passes through balls. There is a differential effect between the second wheel 7' and the third wheel 6" by sandwich contact of said balls. The complementary toothed wheel 8 meshes with the control wheel 3 which comprises a toothing on the periphery.

[0030] The second arrangement of drive wheels 6, 6', 6" for the load of the barrel system 2 comprises a first wheel 6 directly linked to the axis or central shaft 16 of the barrel system 2. This first wheel toothed wheel 6 meshes with a second toothed wheel 6' disposed in the same plane as the first wheel 6 and rotating around an axis of rotation 18. This second toothed wheel 6' is also provided to mesh with a third wheel 6" disposed between the complementary wheel 8 and the second wheel 7' of the first arrangement of driving wheels and coaxially.

[0031] Depending on the rotation of the third wheel 6″ of the second arrangement and of the second wheel 7′ of the first arrangement, the complementary wheel 8 will turn in one direction or in another direction.

It should be noted that the wheel arrangements described above make it possible to connect the charging and discharging of the barrel system 2, as an energy reservoir, to the display of the reserve indication of walking. The second arrangement of drive wheels 6, 6', 6" transmits with a good transmission ratio the load of the barrel system 2 (winding), whereas the first arrangement of drive wheels 7, 7' transmits with the good transmission ratio the discharge of the barrel system 2 (normal discharge during operation) The differential is designed to average these two pieces of information and transmit them to the display.

[0033] It should also be noted that the first end 21 of the opening 13 corresponding to the full load of the barrel system 2 comes into contact either with the contact element 5 of the lever 4 or in this case with a part linked to the central axis 16 of the barrel system 2.

[0034] Figures 2a, 2b and 2c show two three-dimensional views from above and a top view of the position shown in Figure 2b of a second simplified embodiment of the mechanical clock movement provided with the detection means of power reserve according to the invention.

In this second embodiment which includes components similar to what has been described with reference to Figures 1a, 1b and 1c. Under these conditions, the entire description of these components will not be repeated. Reference is only made to the different components.

In this second embodiment, the essential difference is at the level of the blocking part 15 of the lever 4 which is a tooth capable of coming into the teeth of a peripheral toothed wheel 24 of the cage of the barrel system 2 as the power reserve is at zero to block the movement.

The third embodiment shown in Figures 3a, 3b and 3c differ from the other two embodiments, because it is not a blockage at the level of the cage of the barrel system which takes place when the reserve of walking is at zero, but a blocking of a serge 30 of a mechanical oscillator. However, the blocking of the movement takes place in the same way as the embodiments described above by the blocking piece 15 in contact with the rim 30. The entire description of these elements will therefore not be repeated.

The various components described above can take other forms while guaranteeing direct blocking of the movement when the power reserve is at zero.

[0039] From the description which has just been given, several variant embodiments of the mechanical watch movement with power reserve detection means can be designed by those skilled in the art without departing from the scope of the invention. defined by the claims.

Claims (12)

1. Mechanical timepiece movement (1) provided with power reserve detection means (10) for a watch, the movement comprising at least one barrel system (2) with at least one first arrangement of drive wheels ( 7, 7') connected at the output of the central axis (16) of the barrel system (2) and a second arrangement of drive wheels (6, 6', 6") connected to a cage of the barrel system ( 2) at the axis (16), characterized in that the power reserve detection means (10) comprise a control element (3) arranged facing the cage of the barrel system (2), and intended to rotate around an axis of rotation (23 ) parallel to the central axis (16) of the barrel system (2), or to move in a rectilinear direction, being driven by a complementary member (8) at the output of a differential, and a lever (4) comprising a contact element (5), which is arranged facing a control portion (13) of the control element (3) or in a control portion (13) of the control element (3) , and to move the lever (4) so that a blocking part (15) of the lever (4) comes into contact with an element of the gear train, whether it is directly or indirectly linked to the going train or to the movement oscillator to directly stop the mechanical clock movement when the power reserve indication is at zero. 2. Mechanical clock movement (1) according to claim 1, characterized in that the control element (3) comprises an opening (13) as a control portion, the opening (13) having a first end (21) to define a complete charge of the barrel system and a second end (22) to define a complete discharge of the barrel system (2) for the indication of the power reserve at zero, and the lever (4) mounted rotatable around a lever axis (14) parallel to the axis of rotation (23) or parallel to the central axis (16) of the barrel system (2), the lever (4) comprising the contact element (5) arranged in the opening (13) of the control element (3) to come into contact with the second end (22) of the opening (13) when the power reserve indication is at zero. 3. Mechanical clock movement (1) according to claim 2, characterized in that the control element (3) is a control wheel (3), and in that the opening (13) is an opening under form of an arc of a circle at a determined angle and centered on the axis (23) of the control wheel (3). 4. Mechanical clock movement (1) according to claim 3, characterized in that the first end (21) of the opening (13) and the second end (22) of the opening (13) have the shape of circular sections. 5. Mechanical clock movement (1) according to claim 4, characterized in that the circular portions at the ends define half of a circle with a radius corresponding to half the width of the opening (13). 6. Mechanical clock movement (1) according to claim 3, characterized in that the contact element (5) of the lever (4) is a pin or a rod or a blade arranged through the opening (13) . 7. Mechanical clock movement (1) according to claim 1, characterized in that the blocking part (15) is intended to come into contact with an edge (12) of the cage of the barrel system (2), when the power reserve is at zero, to block the movement. 8. Mechanical clock movement (1) according to claim 1, characterized in that the blocking part (15) comprises a tooth at an end opposite to an axis of rotation (14) of the lever (4) to be housed in the toothing of a toothed wheel (24) peripheral to the cage of the barrel system (2), when the power reserve is at zero, to block the movement. 9. Mechanical clock movement (1) according to claim 1, characterized in that the blocking part (15) comprises a rod or a stud (14) of the lever (4) to come into contact with a rim (31 ) of a mechanical oscillator (30) in order to block the movement, when the power reserve is at zero. 10. Mechanical timepiece movement (1) according to one of claims 1 to 3, characterized in that the movement comprises the first arrangement of drive wheels (7, 7') connected to a discharge outlet of the system at differential barrel (2), and a second arrangement of drive wheels (6, 6', 6") linked to a load output of the differential barrel (2) system, in that a first drive wheel drive wheel (7) of the first drive wheel arrangement (7, 7') is fixed to the cage of the barrel system (2), while a first drive wheel (6) of the second drive wheel arrangement drive (6, 6', 6") is linked directly to the central axis (16) of the barrel system (2), and in that the output of the differential type rotates the control element (3), which is a control wheel (3). 11. Mechanical clock movement (1) according to claim 10, characterized in that the complementary member (8) at the output of the differential type is a complementary toothed wheel (8) for meshing with the toothed control wheel (3) . 12. Mechanical clock movement (1) according to claim 1, characterized in that the lever (4) can be movable in rotation or in a rectilinear manner, in that the lever (4) comprises a contact element (5) , which is arranged facing a control portion (13) of the control element (3) or in a control portion (13) of the control element (3), which is a wheel with a portion control (13) in the form of a cam with a blocking member on the cam defining a power reserve at zero, and in that the contact element (5) in the form of a feeler or a wedge comes into direct contact with the blocking member when the power reserve is at zero to block the movement by the blocking piece (15) of the lever (4).