FR3036198A1 - CLOCK-CLOCK - Google Patents

Abstract

This pendulum clock (1) defines a main axis (X1) and comprises an external support of non-magnetic material, a clockwise dial (12) integral with the external support, a rod (16) having a first end (24) hinged to the external support , the rod being configured to oscillate, in a plane (P) of oscillations, with respect to this external support, a body (20) of ferromagnetic material mounted on a second end (26) of the rod and oscillating with the rod to near the time dial and an electromagnet (30) secured to the external support and configured to clock the oscillation of the rod. The rod and the body belong to a Foucault pendulum (28) able to oscillate, at axial distance from the hour dial, on the plane of oscillations in apparent rotation with respect to the hour dial. The pendulum clock comprises means (36) for compensating for an offset between, on the one hand, a real angular position of the oscillation plane (P) around the main axis (X1) and, on the other hand, on the other hand, a theoretical angular position of the plane of oscillation around the principal axis in the absence of difference between a solar day and a sidereal day and in the case where the clock-pendulum (1) is installed at a geographical latitude of 90 N.

Description

The present invention relates to a clock-pendulum. In the field of watchmaking, it is known to use a clock-pendulum to measure the time. The clock-pendulum has a Foucault pendulum and a clock face positioned below the pendulum. In a manner known per se, the Foucault pendulum comprises a relatively long oscillation rod and a heavy oscillation body, so that the oscillation of the Foucault pendulum is subjected to negligible friction forces, compared with his inertia. In practice, the Foucault pendulum defines a fixed oscillation plane when the clock is in rotation with the Earth. A user thus observes an apparent rotation of the pendulum, which is associated, with the help of the time dial, with a measurement of time. The installation and maintenance of such a pendulum clock is complex and expensive. In addition, the realization of a clock-pendulum must also take into account two important factors, such as the time difference between the duration of a sidereal day and the duration of a solar day, and the position in latitude on the Earth of the clock-pendulum. Thus, the time dial must be changed according to these factors and chosen during installation. In this regard, it is also known to use a clock-pendulum of reduced size, in order to limit its size. However, such a pendulum clock always requires the adaptation of the time dial according to latitude and time difference. Thus, the clock-pendulum offers a good functioning exclusively at the place of its installation and a relocation of the clock-pendulum can not be provided. In practice, the pendulum clock is not suitable for industrial applications or large-scale marketing to the general public.

It is these disadvantages that the invention intends to remedy more particularly by proposing a new clock-pendulum that allows easier installation and marketing. In this spirit, the invention relates to a clock-pendulum defining a main axis and comprising: an external support of non-magnetic material, a time dial secured to the external support, a rod having a first end articulated to the external support, the rod being configured to oscillating, in a plane of oscillations, with respect to this external support, 3036198 2 - a body of ferromagnetic material mounted on a second end of the rod and oscillating with the rod near the hour dial, and - a solid electromagnet of the external support and configured to clock the oscillation of the rod, the stem and the body belonging to a Foucault pendulum able to oscillate, at axial distance from the hour dial, on the plane of oscillations in apparent rotation relative to the dial time, the pendulum clock being characterized in that it comprises means for compensating for an offset between, on the one hand, an actual angular position of the plane of oscillations about the main axis and, secondly, a theoretical angular position of the plane of oscillations around the main axis in the absence of difference between a solar day and a sidereal day and in the case where the clock is installed at a geographical latitude of 90 ° N. Thanks to the invention, the clock-pendulum compensates for the time difference between the sidereal and solar day and also takes into account the latitude of its geographical position.

Thus, the oscillation plane of the pendulum defines an apparent rotation that accurately indicates the time on the time dial, regardless of its geographical position. According to advantageous but non-obligatory aspects of the invention, such a pendulum clock comprises one or more of the following features, taken in any technically permissible combination: The compensating means comprise an electric motor configured to rotate the clock around the main axis and with respect to the oscillation plane of the pendulum. - The compensation means further comprise anti-rotation means secured to the first end of the rod and adapted to block the apparent rotation of the oscillation plane of the pendulum relative to the external support. - The compensation means comprise a clock mechanism equipped with an hour hand on which is mounted at least one permanent magnet configured to define the oscillation plane of the pendulum. - The hour dial is fixed to the external support, and optionally adjustable manually 30 in rotation. - The pendulum is equipped with an additional magnet interposed axially between the body and the electromagnet when the rod is aligned on the main axis. - The first end of the rod is articulated to the external support via at least two permanent magnets. 3036198 3 - The pendulum comprises a permanent magnet interposed between the second end of the rod and the body and configured for mounting the body on the rod. The external support comprises at least one magnetic shielding disk or plate configured to magnetically isolate the pendulum clock from the outside. - The hour dial is a twenty-four hour dial. - The operating conditions of the compensation means 36 are configurable by a user. The invention will be better understood and other advantages thereof will appear more clearly in the light of the following description of three embodiments of a pendulum clock according to the invention, given solely as a nonlimiting example and with reference to the accompanying drawings, in which: - Figure 1 is a perspective view of a pendulum clock according to a first embodiment of the invention; FIG. 2 is a diagrammatic section along the plane P in FIG. 1 which is a plane of oscillations; - Figure 3 is a section similar to Figure 2 of a pendulum clock according to a second embodiment of the invention; and FIG. 4 is a section similar to FIG. 2 of a pendulum clock according to a third embodiment of the invention. FIG. 1 shows a pendulum clock 1, of the Foucault pendulum type, defining a main axis X1. The clock-pendulum 1 comprises an external support 2 made of non-magnetic material, so as not to disturb the smooth operation of the clock-pendulum 1.

The outer support 2 comprises in particular a cover 4 and a base 6. The cover 4 is, in practice, a container of cylindrical shape and made of glass or transparent plastic material, so as to allow a user of the clock -pendula 1 to see through this container 4. The container 4 defines an internal volume V4 and has a circular bottom 8 and a cylindrical wall 10. The cylindrical wall 10 30 has a circular edge which bears against the base 6 of the support external 2. D10 is the internal diameter of the cylindrical wall 10 of the container 4, measured in a plane perpendicular to the main axis X1 of the pendulum clock 1. The clock-pendulum 1 also comprises a time dial 12 secured to the pedestal 6 and thus of the external support 2. The clock face 12 has a circular section in a plane perpendicular to the main axis X1 of the clock-pendulum 1. In practice, the dial 3036198 4 hourly 12 is disk-shaped and realized in m non-magnetic material, for example plastic. D12 denotes the diameter of the time dial 12. The diameter D12 of the time dial 12 is equal to the diameter D10 of the cylindrical wall 10 of the container 4, so that the time dial 12 can be arranged inside the wall circular 10 of the container 4, when the container 4 is mounted on the base 6. According to a variant not shown in the figures, the diameter D12 of the time dial 12 is smaller than the diameter D10 of the cylindrical wall 10 of the container 4, so as to creating a space having a circular crown section between the circular edge of the cylindrical wall 10 and the clock face 12.

According to another variant not shown in the figures, the diameter D12 of the time dial 12 is greater than the diameter D10 of the cylindrical wall 10 of the container 4. The container 4 is thus positioned on the time dial 12 which comprises a groove-like space or centering groove having a circular crown section, to guide and maintain the positioning of the container 4 on the time dial 12, as well as to guarantee the concentricity with the electromagnet 30. The hour dial 12 is a dial of twenty-four hours. The time dial 12 defines a first half-disk DD1 and a second half-disk DD2. In practice, the first half-disc DD1 is defined between six hours and eighteen hours, while the second half-disc DD2 is defined between eighteen hours and six hours. Thus, the first half-disk DD1 is called "day zone" and is in light color, while the second half-disk DD2 is called "night zone" and is in dark color. According to a variant not shown in the figures, the time dial 12 is a twelve-hour dial. The pendulum clock 1 also comprises a first permanent magnet 14A, a second permanent magnet 14B, a rod 16, a third permanent magnet 18, a body 20 and a fourth permanent magnet 22. The first and second magnets 14A and 14B are configured to attach the rod 16 to the cover 4 and to allow articulation of the rod 16 about the axis X1. The magnets 14A and 14B are arranged on either side of the bottom 8 of the container 4, so that the magnetic attraction exerted between the magnets 14A and 14B stabilizes the position of these magnets 14A and 14B on the bottom 8 In particular, the first magnet 14A is disposed outside the volume V4, while the second magnet 14B is disposed inside this volume V4. This arrangement also allows a fine adjustment of the centering of the rod 16 in the container 4, as well as its axial alignment with the electromagnet 30, by simple manual movement of the two magnets 14A and 14B on the bottom 8 of the container 4.

The rod 16 is made of ferromagnetic material, for example steel, and is configured to oscillate with respect to the container 4 of the external support 2. The length of the rod 16 measured along the main axis X1 is noted L16 when the rod 16 is in the rest position, that is to say parallel to the axis X1. The metal rod 16 has a first end 24 and a second end 26. The first end 24 of the rod 16 is in contact with the magnet 14B positioned on the bottom 8 of the container 4. In practice, the first end 24 of the rod 16 is articulated to the external support 2 via the cooperation of the two magnets 14A and 14B. The second end 26 of the rod 16 is in contact with the third magnet 18.

The permanent magnet 18 is thus interposed between the second end 26 of the rod 16 and the body 20. The permanent magnet 18 is configured for mounting the body 20 on the rod 16. According to a variant not shown in the figures, the body 20 is directly mounted on the second end 26 of the rod 16, via an assembly system, for example screw-type, or via a magnetic system, the body 20 then being in the latter case also a permanent magnet. The body 20 is of ferromagnetic material and oscillates with the rod 16 near the time dial 12. The body 20 is, for example, a spherical ball. Alternatively, the body 20 may take any other geometrical shape, for example an oval, a pyramid or an inverted cone. The permanent magnet 22 is an additional magnet interposed axially between the body 20 and the electromagnet 30 when the rod 16 is aligned on the main axis X1. The additional magnet 22 is thus integral with the spherical body 20 and, for example, of elongated shape to form an indicator mark facilitating the reading time.

According to a variant not shown in the figures, the clock-pendulum does not include the additional magnet 22. The rod 16, the spherical body 20 and the permanent magnets 14A, 14B, 18 and 22 thus belong to a Foucault pendulum 28 The pendulum 28 is able to oscillate, at an axial distance from the time dial 12 along the axis X1, on an oscillation plane P which is parallel to the plane of FIGS. 2 to 4. The oscillation plane P of the pendulum 28 is in apparent rotation with respect to the time dial 12. The main axis X1 of the clock-pendulum 1 belongs to the oscillation plane. The pendulum clock further comprises an electromagnet 30 configured to clock the oscillation of the rod 16 of the pendulum 28. The electromagnet 30 is integral with the external support 2, in particular fixed to the base 6. In practice, the The electromagnet 30 is arranged parallel to the axis X1 of the clock-pendulum 1 and in the center of the time dial 12. Alternatively, the electromagnet 30 is fixedly disposed below the time dial 12.

The base 6 of the external support 2 of the clock-pendulum 1 is, for example, of cylindrical shape and made of non-magnetic material, for example wood, glass, resin, plastic ... We note D6 the external diameter of the base 6 measured in a plane perpendicular to the main axis X1 of the clock-pendulum 1. The diameter D6 of the base 6 is greater than or equal to the diameters D10 and D12 of the container 4 and the time dial 12 10 whatever the arrangement of these last two. The base 6 includes a microcontroller 32 and compensation means 36. The clock-pendulum 1 further comprises means 34 for power supply. The microcontroller 32 is configured to define the pulsation frequency of the electromagnet 30 and to drive the compensation means 36. The microcontroller 32 15 comprises an input-output, for example of the USB type. The power supply means 34 are configured to supply electrical power to the microcontroller 32 and, indirectly, the compensation means 36, for example, with a voltage of 5V. The electrical supply means 34 thus extend from the inside of the base 6 to the outside of the base 6 and the clock-pendulum 1. The means 34 comprise, for example, a cable equipped with a connector USB type at a first end. The cable 34 is thus configured to connect to the USB input / output of the microcontroller 32. At a second end, the cable 34 is equipped with an adapter 38 able to connect to a wall outlet of a distribution electrical network which is not shown in the figures. The adapter 38 is thus configured to transform the AC 220V electrical voltage of the distribution network into a DC voltage 5V needed to power the microcontroller 32. Alternatively, the cable 34 has at its second end a USB type connector adapted to connect to a USB type input-output, for example, a computer. Thus, the cable 34 is a line-type current-carrying cable capable of performing a computer communication on the supply voltage. Thus, the user can modify parameters of the microcontroller 32 using a computer and the cable 34. The compensation means 36 are configured to compensate for an offset between, on the one hand, a real angular position of the plane d oscillations P around the main axis X1 and, on the other hand, a theoretical angular position of the oscillation plane P 35 around the main axis X1 in the case where there is no difference between a day 3036198 7 and a sidereal day and in the event that the clock-pendulum 1 is installed at a geographical latitude of 90 ° N. In practice, there is a first difference between, on the one hand, the duration of a sidereal day and, on the other hand, the duration of a solar day. The duration of a sidereal day, which corresponds to a complete turn of the Earth on itself, is different from the duration of a solar day, which corresponds to 24 hours. In particular, the sidereal day has a duration slightly shorter than the duration of the solar day, the difference being quantifiable in about 4 minutes. In addition, there is a second offset due to the latitude position of the pendulum clock in the earth. In fact, in a manner known per se, a pendulum clock using the principle of the Foucault pendulum only functions correctly. 'at the North Pole of the Earth, that is to say, at a latitude of 90 ° N, where the Coriolis force causes the pendulum oscillations plane to make a complete clockwise turn and a lapse of time corresponding to the sidereal day. Thus, the only offset present at the North Pole is that described above between solar and sidereal day. On the contrary, a Foucault pendulum installed at a latitude different from that of the North Pole is also subject to the second shift. In particular, the oscillation plane of the pendulum performs a complete revolution in one direction and in a time which depends on the sine of its latitude on the Earth and which can be calculated by the following equation: 24h T = sin a where T is the period of the pendulum and a is the geographical latitude, in degrees. For example, at a latitude of 30 ° N, the pendulum period is 2 sidereal days in a clockwise direction, while at a latitude of 45 ° S, the period is 1.4 sidereal days in the anti direction. -Schedule. The compensation means 36 are therefore indispensable for indicating the time, in particular at the equator where the period of rotation of the Foucault pendulum is zero, which means that it oscillates on a fixed plane, thus preventing any time indication, as well as in the southern hemisphere where this period is reversed, which means that the Foucault pendulum turns this time in the anti-clockwise direction, that is to say contrary to the conventional time reading direction. For these reasons, the actual angular position of the oscillation plane P differs from the theoretical angular position and the means 36 are necessary for the smooth operation of the pendulum clock 1. (1) The means 36 comprise a motor 40 electrical, a shaft 42, driven by the motor 40, and a pinion 44. The electric motor 40 is configured to cause the rotation of the shaft 42 about a longitudinal axis X42 of the shaft 42 which is parallel to the Main axis X1 of the clock-pendulum 1. The electric motor 40 is, for example, a stepper motor requiring a power supply of five volts. An electrical connection 46 is established between the microcontroller 32 and the electric motor 40. The electrical connection 46 is configured to supply electrical energy to the electric motor 40 and to transmit a command to it in order to operate it. In practice, the electric motor 40 is powered by the power supply means 34 via the microcontroller 32. In a variant, the electric motor 40 is powered directly by the power supply means 34. In this case, the first end of the cable 34 is bipartite and has a USB type connector for the microcontroller 32 and a dedicated connector 15 for the electric motor 40. The rotational speed of the shaft 42 driven by the electric motor 40 is defined by the microcontroller 32 and is in function of the shift described above. The pinion 44 is mounted on the shaft 42 and rotated with the shaft 42 by the motor 40, about the axis X42. The pinion 44 forms a toothed gear with an inner edge 48 of the time dial 12. In practice, the inner edge 48 of the time dial 12 has a toothed surface adapted to the pinion gear 44 so that the rotation of the pinion 44 around the X42 axis induces a mechanical transmission of the movement at the time dial 12. Given the schematic nature of Figure 2, the teeth of the pinion 44 and the teeth of the edge 48 are not shown.

The electric motor 40 is configured to rotate the time dial 12 relative to the oscillation plane P of the pendulum 28. Thus, the electric motor 40 is driven by the microcontroller 32, so as to compensate for the difference between, on the one hand, the actual angular position and, on the other hand, the theoretical angular position of the oscillation plane P about the axis X1. As explained above, this offset is due to the difference between solar day and sidereal day and the position in geographic latitude of the pendulum clock 1. In particular, the microcontroller 32 calculates the rotation to be applied to the time dial 12 , for example using the following equation: N = [(24h -sin a) -24h] + [(24h-T5) - I sin al] (2) 35 3036198 9 where N is the number of turns per 24h to be applied to the dial 12, a is the geographical latitude in degrees, Ts is the duration of a sidereal day and X is the number of hours of the dial 12. In the case X is equal to 24 hours. The user can modify by himself one or more parameters of the microcontroller 32 described in equation (2) via the USB computer communication described above, or via a GPS type link to automatically adjust these parameters. Thus, the operating conditions of the microcontroller 32, and hence of the compensation means 36, can be parameterized by a user. According to a variant which is not shown in the figures, the compensation means 36 are further supplemented by anti-rotation means. The anti-rotation means are, for example, stops, guides, hinges for limiting the oscillation of the pendulum on a single plane. These anti-rotation means are integral with the first end 24 of the rod 16 and are able to block the apparent rotation of the oscillation plane P of the pendulum 28 with respect to the cover 4. In practice, the oscillation plane P 15 of the The pendulum 28 remains stationary relative to the external support 2 of the clock-pendulum 1, the oscillation being clocked with the aid of the electromagnet 30, and the compensation means 36 rotate the clock face 12 at the rate of a turn in the clockwise direction in 24 hours since the oscillation plane P of the pendulum is fixed, as in the specific case described above where the clock-pendulum 1 is installed at the equator. In this variant, the compensating means 36 may be constituted, for example, by a simple 24-hour clock mechanism that directly actuates the clock face 12. FIGS. 3 and 4 show two other embodiments of the invention. The elements of the pendulum clock 1 of these embodiments which are analogous to those of the first embodiment bear the same references and are not described in detail to the extent that the above description can be transposed to them. In the second embodiment of the invention shown in FIG. 3, the compensation means 36 comprise a clock mechanism 50. The clock mechanism 50 is, for example, a quartz watch mechanism at twenty-four hours. The watch mechanism 50 is powered by the microcontroller 32 via the electrical connection 46. The watchmaking mechanism 50 is equipped with a hand 52 hours on which is mounted, with the aid of a rod 54, a permanent magnet 56. According to a variant of the second embodiment of the invention, on the rod 54 are mounted two or more permanent magnets.

The needle 52 is driven by the watch mechanism 50. The needle 52 is rotated by the watch mechanism 50 about an axis X52 which coincides with the main axis X1 of the clock-pendulum 1. In practice, the permanent magnet 56 is positioned near the time dial 12, above which oscillates the Foucault pendulum 28. Thus, the permanent magnet 56 exerts a magnetic attraction on the additional magnet 22 and on the body 20 of the pendulum 28. The permanent magnet 56 is thus configured to define the oscillation plane P of the pendulum 28. Indeed, the pendulum 28 is forced to oscillate in correspondence of the permanent magnet 56. In addition, the magnet Since the permanent assembly 56 is rotatably connected to the needle 52, the oscillation plane P of the pendulum 28 is also rotated relative to the clock face 12 in a rotation according to the clock mechanism 50 at twenty-four hours. This also makes it possible to compensate for an offset of the apparent rotation of the oscillation plane P with respect to the time dial 12. In this second embodiment, the time dial 12 is not rotated by the compensation means 36 of the first embodiment. The time dial 12 can then be fixed to the base 6 of the external support 2. According to a variant which is not shown in the figures, the watchmaking mechanism 50 is exclusively of the mechanical type and is only clocked and supplied with energy for its operation. by strictly mechanical means, for example of the 20-spring type, reassembled by weight systems, temperature difference, atmospheric pressure difference. According to another variant which is not shown in the figures, and alternatively to the watch mechanism 50, the compensation means 36 are provided by positioning the electromagnet 30 below the clock face 12, on a turntable, and in a 25 direction inclined, or off-axis, with respect to the axis X1 of the clock-pendulum 1, so as to define the oscillation plane P of the pendulum 28 and compensate for an offset of the apparent rotation of the oscillation plane P relative to at the time dial 12. The turntable is configured to be rotated by an electric motor contained in the base 6. According to another variant which is not shown in the figures, the time dial 30 12 is manually movable in rotation relative to to the external support 2 around the main axis X1. Thus, the user can, if he wishes, rotate the time dial 12 manually to correct the time indicated by the clock-pendulum 1. To facilitate this manual adjustment, the clock-pendulum 1 can optionally comprise an additional disk interposed between the time dial 12 and the base 6, this disk having for example a diameter equal to the diameter D12 of the time dial 12, or higher to allow a better grip by the user. According to the third embodiment of the invention, represented in FIG. 4, the compensation means 36 comprise the electric motor 40, the shaft 42, the pinion 44 and the watchmaking mechanism 50 equipped with the needle 52, the rod 54 and the permanent magnet 56. In practice, the third embodiment of the invention can be considered as the union of the first and second embodiments of the invention. Thus, the microcontroller 32 is configured to drive the electric motor 40 in order to rotate the time dial 12, via the shaft 42 and the pinion 44. In addition, the microcontroller 32 is configured to supply electrical energy to the electric motor. and the watch mechanism 50. According to a variant which is not shown in the figures, the external support 2 comprises one or more magnetic shielding disks or plates configured to magnetically isolate the clock-pendulum 1, in particular the movement of the pendulum of Foucault 28 and the permanent magnets 14A and 14B, vis-à-vis any ferromagnetic external source, magnetized or not. The modes and variants envisaged above can be combined with one another to generate new embodiments of the invention. 20

Claims (11)

1. Pendulum clock (1) defining a main axis (X1) and comprising: an external support (2) of non-magnetic material, a clockwise dial (12) integral with the external support, a rod (16) having a first end ( 24) articulated to the external support, the rod being configured to oscillate, in a plane (P) of oscillations, with respect to this external support, a body (20) of ferromagnetic material mounted on a second end (26) of the rod and oscillating with the rod near the time dial, and an electromagnet (30) integral with the external support and configured to clock the oscillation of the rod, the rod and the body belonging to a Foucault pendulum (28) able to oscillate, at axial distance from the hour dial, on the plane (P) of oscillations in apparent rotation with respect to the hour dial, the clock-pendulum being characterized in that it comprises means (36) for compensating for a difference between on the one hand, a position real ngular plane of oscillation (P) around the main axis (X1) and, secondly, a theoretical angular position of the plane of oscillations around the main axis in the absence of difference between a solar day and one sidereal day and in the case where the clock-pendulum (1) is installed at a geographical latitude of 90 ° N. 2. Clock-pendulum according to claim 1, characterized in that the compensation means (36) comprise an electric motor (40) configured to rotate the clock (12) around the main axis (X1) and relative to the oscillation plane (P) of the pendulum (28). 3. Clock-pendulum according to claim 2, characterized in that the compensation means (36) further comprise anti-rotation means integral with the first end (24) of the rod (16) and able to block the apparent rotation of the oscillation plane (P) of the pendulum (28) with respect to the external support (2). 4. Clock-pendulum according to one of the preceding claims, characterized in that the compensation means (36) comprise a clock mechanism (50) equipped with a hand (52) hours on which is mounted at least one magnet permanent sensor (56) configured to define the oscillation plane (P) of the pendulum (28). 3036198 13 5.- pendulum clock according to claim 4, characterized in that the time dial (12) is fixed to the outer support (2) and optionally manually adjustable in rotation. 5 6. Clock-pendulum according to one of the preceding claims, characterized in that the pendulum (28) is equipped with an additional magnet (22) interposed axially between the body (20) and the electromagnet (30) when the rod (16) is aligned with the main axis (X1). 10 7. Clock-pendulum according to one of the preceding claims, characterized in that the first end (24) of the rod (16) is articulated to the outer support (2) via at least two permanent magnets (14A, 14B). 15 8. Clock-pendulum according to one of the preceding claims, characterized in that the pendulum (28) comprises a permanent magnet (18) interposed between the second end (26) of the rod (16) and the body (20). and configured to mount the body on the rod. 20 9. Clock-pendulum according to one of the preceding claims, characterized in that the outer support (2) comprises at least one disk or magnetic shielding plate configured to magnetically isolate the clock-pendulum (1) vis-à- screw from the outside. 25 10. Clock-pendulum according to one of the preceding claims, characterized in that the time dial (12) is a dial of twenty-four hours. 11. Clock-pendulum according to one of the preceding claims, characterized in that the operating conditions of the compensation means (36) are configurable by a user.