CH712077B1 - Tourbillon for timepiece movement with improved magnetic resistance. - Google Patents

Abstract

The invention relates to a tourbillon (13) for a timepiece movement, a timepiece movement and a timepiece making it possible to obtain better magnetic resistance while avoiding an increase in bulk. There is provided a cage (41) which is rotatable about an axis (O1) of cage shafts (46 and 47) and in which a regulator-exhaust assembly (45) is mounted; a first magnetic element (63) which extends in a first direction in a plan view obtained looking from the axial direction and which is a functional component selected from a peg holder (63), a racket (65) and a anchor body (92) of a timepiece; and a second magnetic element (100) which extends in a second direction crossing the first direction, in which, in a plan view obtained looking from the axial direction, an angle (θa) between, on the one hand, a first straight line (La) connecting an outermost end surface, in the first direction, of the first magnetic element (63) and the axis (O1) and, on the other hand, a second straight line ( Lb) connecting an outermost end surface, in the second direction, of the second magnetic element (100) and the axis (O1) is chosen to be larger than 60 degrees and smaller than 120 °.

Description

BACKGROUND OF THE INVENTION

1. Field of the invention

The present invention relates to a tourbillon for a timepiece movement, a timepiece movement and a timepiece.

2. Description of Related Art

[0002] It is known that, in a mechanical timepiece, a rate error (positional difference) is different depending on the orientation of the balance-spring relative to the direction of gravity acting on this balance-spring . A structure aimed at preventing the orientation of the timepiece from having an effect on the rate is known and is called the tourbillon. In a tourbillon, the regulator-escapement assembly, which is the main mechanism determining the rate, is mounted in a cage and this cage is driven in rotation on its axis according to a fixed cycle. Consequently, it is possible to make the rate error generated by a change in position of the timepiece uniform, which makes it possible to compensate for a positional difference.

[0003] In the case of the aforementioned timepiece in which a tourbillon is mounted, placing this timepiece in a magnetic field acting in a plane direction orthogonal to the axis of the cage results in the generation , on a magnetic element present in the cage, of a torque tending to accelerate or slow down the cage around its axis. This results in the risk that the tourbillon becomes unable to operate normally.

[0004] For example, patent document 1 (JP-A-50-67169) describes a construction in which a movement housed in a timepiece case is covered with a magnetic material so that the influence of the magnetic field acting on the timepiece.

[0005] It should be considered that, in this construction, a magnetic flux passes through the magnetic material, whereby it is possible to shield the magnetism between the movement and the magnetic material, which makes it possible to suppress the influence of the magnetic field acting on the movement.

[0006] However, in the technique of the prior art described above, the movement itself is covered with magnetic material, which results in an increase in the size of the timepiece. The tourbillon has a complicated constitution and it is arranged to rotate inside the movement, so that it is rather difficult to cover only the tourbillon with magnetic material.

Further, in the prior art technique, when the magnetic field intensity exceeds the saturation magnetic flux density of the magnetic material, the magnetic flux leaking through the magnetic material passes through the magnetic element, inside the movement. Also, it is quite difficult to obtain a satisfactory magnetic resistance.

SUMMARY OF THE INVENTION

The present invention has been made in view of the above problems of the prior art. An object of the present invention is to provide a tourbillon, a movement and a timepiece helping to suppress an increase in size and to achieve a higher magnetic resistance.

In order to achieve the above object, according to one aspect of the present invention, there is provided a tourbillon for a timepiece movement according to claim 1.

According to this aspect, when the vortex is placed in a magnetic field in a direction in a plane orthogonal to the axial direction, the phase between the couples acting in the first magnetic element and in the second magnetic element, around the axis, is greatly separated in the presence of the influence of the magnetic field, so that the torques are easily generated in different directions. Therefore, it is easy for the torque generated in the first magnetic member and that generated in the second magnetic member to act to cancel each other. As a result, the resultant of the torque generated in the first magnetic element and that generated in the second magnetic element (the torque generated in the cage) can be reduced, compared to the torque of each magnetic element.

[0011] In addition, in this construction, the second magnetic element, for example, is added to the cage, that is all, so that it is possible to avoid an increase in size, compared to a conventional construction. in which the tourbillon is itself coated with magnetic material.

[0012] Furthermore, thanks to the construction in which the torques each generated in one of the two magnetic elements are mutually canceled with the influence of the magnetic field, it is possible to obtain a higher magnetic resistance whatever the intensity of the magnetic field, which constitutes a difference compared to the usual construction in which one is satisfied to make pass the magnetic field.

In the above aspect, the tourbillon for a timepiece movement may be according to claim 2.

[0014] According to this aspect, the first magnetic element and the second magnetic element are both functional components of the timepiece, so that it is possible to attenuate the influence of the magnetic field by means of the arrangement of the first magnetic element and the second magnetic element, which are existing elements. As a result, it is possible to achieve a reduction in the number of components, etc., compared with the case where a magnetism canceling member is provided separately as the second magnetic member.

In the above aspect, the tourbillon for a timepiece movement may be according to claim 3.

[0016] According to this aspect, the second magnetic element can be mounted on the cage without interacting with other functional components. It follows that the arrangement and the shape of the second magnetic element can be chosen relatively freely, depending on the arrangement, the shape, etc. of the first magnetic element. As a result, it is possible to achieve progress in terms of greater freedom of choice for shape and design and further progress in terms of magnetic strength, compared to the case where the first magnetic element and the second magnetic element are both functional components.

According to one aspect of the present invention, there is provided a timepiece movement equipped with the tourbillon for timepiece movement defined above.

According to one aspect of the present invention, there is provided a timepiece provided with the timepiece movement defined above.

[0019] Thanks to this structure, it is possible to provide a timepiece movement and a timepiece with improved reliability.

[0020] According to one aspect of the present invention, it is possible to obtain improved magnetic resistance while avoiding greater bulk.

BRIEF PRESENTATION OF DRAWINGS

Figure 1 is an external view of a timepiece according to one embodiment. Figure 2 is a plan view of a cage according to a first embodiment. FIG. 3 is a graphic representation of the torque rate as a function of an angle θb between a magnetic field H and a first straight line La (for θa=50 degrees). FIG. 4 is a graphic representation of the torque rate as a function of an angle θb between a magnetic field H and a first straight line La (for θa=60 degrees). FIG. 5 is a graphic representation of the torque rate as a function of an angle θb between a magnetic field H and a first straight line La (for θa=80 degrees). FIG. 6 is a graphic representation of the torque rate as a function of an angle θb between a magnetic field H and a first straight line La (for θa=90 degrees). FIG. 7 is a graphic representation of the torque rate as a function of an angle θb between a magnetic field H and a first straight line La (for θa=110 degrees). FIG. 8 is a graphic representation of the torque rate as a function of an angle θb between a magnetic field H and a first straight line La (for θa=120 degrees). FIG. 9 is a graphic representation of the torque rate as a function of an angle θb between a magnetic field H and a first straight line La (for θa=135 degrees). Figure 10 is a graphical representation of the resulting torque rate as a function of the angle θa. Figure 11 is a plan view of a cage according to a variant of the first embodiment. Figure 12 is a plan view of the cage according to a variant of the first embodiment. Figure 13 is a plan view of a cage according to a second embodiment. Figure 14 is a plan view of a cage according to a variant of the second embodiment. Figure 15 is a plan view of the cage according to a third embodiment.

DESCRIPTION OF EMBODIMENTS

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

First embodiment

timepiece

Figure 1 is an external view of a timepiece. In order to make the drawings easier to examine, the components are partly omitted from the drawings and are shown in a simplified manner.

As shown in Figure 1, in the timepiece 1 of this embodiment, a movement 10, a dial (not shown) bearing a scale, etc., giving information relating to the time, different hands (not shown), etc. are arranged inside a timepiece box 3.

Movement

The movement 10 essentially comprises a plate 11, a front going train 12 and a tourbillon 13. A winding stem 15 is mounted in a winding stem guide hole (not shown) of the plate 11. The stem winding 15 is rotatable on its axis and it is movable in the axial direction. A crown 16 located on the side of the timepiece case 3 is mounted on an end portion (the portion projecting relative to the movement 10) of the winding stem 15. In the following description, the side of the movement 10 located on the dial side with respect to plate 11 is referred to as the "rear side" of movement 10, while the side of movement 10 opposite the dial side is referred to as the "front side" of movement 10. Each of the wheels described below is mounted in such a way that its axial direction is the antero-posterior direction of movement 10.

The front going train 12 comprises a barrel 21, a center wheel set 22, an average wheel set 23 and a second wheel set 24.

The barrel 21 contains a barrel spring (not visible) serving as a power source for the timepiece. This barrel spring is wound by means, for example, of a rotation of the winding stem 15. The barrel 21 is driven by the rotational force during the winding of the barrel spring. A barrel drum constituting the barrel 21 meshes with a center pinion of the center mobile 22.

The center wheel 22 performs one rotation per hour due to the rotation of the barrel 21. A center wheel of the center wheel 22 meshes with an average pinion of the average wheel 23. A roadway 31 is mounted on the center of the center wheel 22. A minute hand (not shown) is mounted on the floor 31.

Further, an hour wheel 32 is fitted to the roadway 31. The hour wheel 32 is connected to the roadway 31 via a timer wheel 33. Due to the rotation of the roadway 31 , the 32 hour wheel completes one rotation in 12 hours. An hour hand (not shown) is mounted on hour wheel 32.

[0030] The average wheel set 23 rotates by means of the rotation of the center wheel set 22. A middle wheel constituting the average wheel set 23 meshes with the second pinion of the second wheel set 24.

The second mobile 24 rotates by means of the rotation of the average mobile 23.

Tourbillon

[0032] The tourbillon 13 comprises a cage 41, a fixed wheel 42 and a fifth mobile 43 connected to the cage 41 and to the second mobile 24.

[0033] Figure 2 is a plan view of the cage 41.

As shown in Figure 2, the cage 41 comprises a main cage plate 44, a front part of the cage and a rear part of the cage (not visible), as well as a regulator-exhaust assembly 45 mounted on the plate cage main 44.

The main cage plate 44 is configured with an annular shape, the center of which is an axis O1 extending in the antero-posterior direction of the movement 10.

[0036] The front cage part is disposed on the front side (the bottom side of the drawing plane) with respect to the main cage plate 44. The front cage part has a front cage shaft (cage shaft) 46 extending coaxially with the axis O1. Cage front shaft 46 is rotatably supported by a cage front bridge (not shown). A cage pinion 48 (see Figure 1) of the front cage shaft 46 meshes with the fifth mobile 43.

[0037] The cage rear part is disposed on the rear side (the front side of the drawing plane) with respect to the cage main plate 44. The cage rear part has a cage rear shaft (cage shaft) 47 extending coaxially with the axis O1. The rear cage shaft 47 is rotatably supported by a rear cage bridge (not shown). In other words, when the fifth mobile 43 rotates, the cage shafts 46 and 47 of the cage 41 of the present embodiment allow the cage 41 to rotate around the axis O1. In the following description, the direction along the axis O1 may be called the axial direction, while the direction in which the peripheral rotation takes place around the axis O1 may be called the peripheral direction and the direction orthogonal to the axis O1 could be called the radial direction.

As shown in Figure 1, the fixed wheel 42 is fixed to the front bridge of the aforementioned cage.

[0039] The fifth wheel set 43 is rotatably supported by the cage front bridge and the fixed wheel 42. The fifth wheel set 43 meshes with the second wheel of the second wheel set 24. In this way, the fifth wheel set 43 rotates at the average of the rotation of the second mobile 24.

As shown in Figure 2, the regulator-exhaust assembly 45 comprises a balance-spring 51, an escapement wheel set 52 and an anchor 53.

[0041] The balance-spring 51 is rotatably supported by the main cage plate 44 and by a balance bridge 55 arranged on the rear side with respect to the main cage plate 44.

The balance bridge 55 is formed, for example, as a plate extending in a radial direction. The two end portions of the balance bridge 55 are connected to the cage main plate 44 by connecting rods 56. The aforementioned rear cage part is connected to the balance bridge 55.

The balance-spring 51 comprises a balance shaft 61, a balance rim 62, a stud holder 63, a balance spring 64 and a racket 65.

The balance shaft 61 is arranged so as to be coaxial with the axis O1. The balance shaft performs outward and return rotations (back and forth rotations) according to a constant oscillation cycle, around the axis O1, by the power transmitted by the hairspring 64. The front end of balance shaft 61 is rotatably retained by cage main plate 44 via a bearing (not shown). Furthermore, the rear end of the balance shaft 61 is held rotatably by the balance bridge 55, via a bearing 67.

The balance rim 62 is fixed to the balance shaft 61, by driving in or the like.

[0046] Forming what is called the "first magnetic element" in the appended claims, the eyebolt 63 is a magnetic element made of a magnetic material. The eyebolt holder 63 has an eyebolt base 71 and an eyebolt arm 72.

[0047] The eyebolt base 71 is made in an annular shape placed coaxially with the axis O1 in a plan view obtained by looking from the axial direction. The eyebolt base 71 is fitted to the aforementioned bearing 67.

The eyebolt arm 72 projects radially outwards from the base of the eyebolt 71. A eyebolt 73 is carried by the outer end portion, in a radial direction, of the eyebolt arm 72. The outermost end surface in a radial direction of the eyebolt arm 72 is on the inner side in the radial direction of the outer peripheral surface of the cage main plate 44.

[0049] The hairspring 64 is a spiral spring in a plan view obtained looking from the axial direction. The inner end portion of balance spring 64 is connected to balance shaft 61. Conversely, the outer end portion of balance spring 64 is connected to stud 73 mentioned above.

The racket 65 is made of a non-magnetic material. Racquet 65 includes a racquet base 75 and a racquet arm 76.

The racket base 75 is mounted on the bearing 67 so as to be rotatable around the axis O1. More specifically, when a predetermined rotational torque is applied to it, racket base 75 slides relative to bearing 67 and rotates around axis O1.

The racquet arm 76 projects radially outwards from the racquet base 75. A racquet pin 77 and a racquet key 78 are mounted on the end portion located the outermost, in a radial direction, of the racket arm 76.

[0053] The racket pin 77 and the racket key 78 are opposed to each other in a radial direction, with the hairspring 64 passing between them, a radial space being provided with respect to the part of the portion of outer end of balance spring 64 located closer to the inner end portion than peak 73 mentioned above. More precisely, the racket pin 77 is arranged on the outside, in a radial direction, with respect to the hairspring 64, while the racket key 78 is arranged on the inside in the radial direction. The inner end portion of hairspring 64 can oscillate radially between racket pin 77 and racket key 78, and can come into contact with racket pin 77 and racket key 78.

[0054] The escapement wheel set 52 is rotatably supported by the cage main plate 44 and by a pallet/escape wheel bridge 81 disposed on the rear side of the cage main plate 44. The anchor/escape wheel 81 is arranged between the cage main plate 44 and the balance bridge 55, in the axial direction.

[0055] The escapement wheel set 52 comprises a shaft-forming portion 82, an escapement pinion 83 (see FIG. 1) formed on the shaft-forming portion 82, as well as an escapement wheel 84 fitted to the portion forming tree 82.

The forward end of shaft portion 82 is rotatably retained by cage main plate 44 via a bearing (not shown). In contrast, the rear end of the shaft portion 82 is rotatably retained by the pallet/escape wheel bridge 81, via a bearing 85.

[0057] Several teeth are provided at the outer periphery of escape wheel 84.

The escape pinion 83 meshes with the fixed wheel 42 mentioned above. In this way, the escape wheel set 52 rotates on itself while making revolutions around the fixed wheel 42, due to the rotation of the cage 41.

The anchor 53 makes a connection between the balance-spring 51 and the escapement wheel set 52. The anchor 53 is supported in such a way as to be capable of a reciprocating rotary movement, between the plate carriage main 44 and the anchor/escape wheel bridge 81. Specifically, the anchor 53 includes an anchor shaft 91, an anchor body 92 attached to the anchor shaft 91, as well as as pallets 93 and 94 fixed to the anchor body 92.

The anchor shaft 91 extends along an axis O2 offset radially with respect to the axis O1. The forward end of anchor shaft 91 is rotatably retained by cage main plate 44 via a bearing (not shown). The rear end of the anchor shaft 91 is rotatably retained by the anchor/escape wheel bridge 81, via a bearing 95.

The anchor body 92 is made of a non-magnetic material. The anchor body 92 is shaped like a plate extending in a longitudinal direction, which is a radial direction. The anchor shaft 91 is fixed to the central part, in a radial direction, of the anchor body 92, by driving in or the like. An input vane 93 is mounted at the portion of the anchor body 92 which is located inboard, in a radial direction, relative to the anchor shaft 91. An output vane 94 is mounted at the portion of the anchor body 92 which is located on the outside, in a radial direction, with respect to the anchor shaft 91. By means of a rotation of the anchor 53, the pallets 93 and 94 are engaged with the escape wheel 84 of the escape wheel set 52 and separated from this escape wheel 84.

At the inner end, in a radial direction, of the anchor body 92, there is provided a fork 97 configured to engage with a double plate (not shown) of the sprung balance 51 and to be distance from this double plateau.

[0063] At the level of the outer end, in a radial direction, of the anchor body 92, there is provided an anchor finger 98. The anchor finger 98 can come into abutment against a pair of limiting pins 99 provided on the main cage plate 44 mentioned above. The limit pins 99 stand up from the rear side, from the portions of the cage main plate 44 which are located on both sides of the anchor finger 98 (both sides in the circumferential direction), in a plan view. As anchor 53 pivots, anchor finger 98 abuts limit pins 99. As a result, the rotational travel (angle of operation) of anchor 53 is limited.

[0064] Forming what is referred to as the "second magnetic element" in the appended claims, a magnetism canceling element 100 made of a magnetic material is provided at the portion of the cage main plate 44 which is located between the exhaust mobile 52 and the peak arm 72, in the peripheral direction. The magnetism canceling element 100 is shaped like a plate extending in a longitudinal direction, which is a radial direction. The outermost end surface in a radial direction of the magnetism canceling member 100 is on the outer side in a radial direction of the cage main plate 44. opposite, the end surface positioned most inward, in a radial direction, of the magnetism canceling element 100 is on the inner side, in a radial direction, of the hairspring 64. The magnetism cancellation 100 can have a prismatic shape or a columnar shape as long as it has a shape extending in a longitudinal direction, which is a radial direction.

[0065] It is considered here that, in a plan view, the straight line connecting the axis O1 and the outermost end surface, in a radial direction (called "first direction" in the claims appended), of the above-mentioned eyebolt holder 63 (eyebolt arm 72) is a first straight line La, and that the straight line connecting the axis O1 and the end surface lying furthest outwards, in a direction radial (referred to as the "second direction" in the appended claims), of the magnetism canceling element 100 is a second straight line Lb. Then, it is preferable that the eyebolt holder 63 and the magnetism cancellation element 100 are arranged in such a way that the angle θa between the first straight line La and the second straight line Lb is greater than 60 degrees and less at 120 degrees. In the present embodiment, the angle θa is chosen equal to about 90 degrees.

The present inventor has studied the torque acting on the magnetic elements, namely the stud carrier 63 and the magnetism cancellation element 100, when the timepiece 1 is placed in a magnetic field exerting along a direction in a plane orthogonal to the axial direction (for example the magnetic field H in FIG. 2). More specifically, the inventor has studied the relationship between the angle between the magnetic field H and each of the straight lines La, Lb and the torque acting on the stud holder 63 and the magnetism cancellation element 100 due to the presence of the magnetic field H.

[0067] Figures 3 to 9 are graphical representations of the torque rate as a function of the angle θb between the magnetic field H and the first straight line La. The "torque rate" is the rate of the torque acting on the door -eyebolt 63 and the magnetism cancellation element 100 as a function of the angle θb when the maximum torque acting on the eyebolt carrier 63 is 1. The magnetism cancellation element 100 is dimensioned so that the maximum torque is equivalent to the maximum torque acting on stud carrier 63. The dot-and-dash curve in the drawings represents the resulting torque rate (the torque generated in cage 41) of the torque rate of stud carrier 63 and the rate torque of the magnetism canceling element 100.

The conditions with regard to the angle θa in Figures 3 to 9 are as follows: Figure 3: θa = 50° Figure 4: θa = 60° Figure 5: θa = 80° Figure 6: θa = 90 ° Figure 7: θa = 110° Figure 8: θa = 120° Figure 9: θa = 135°

As seen in Figure 3, the torque rate of each of the elements that are the stud holder 63 and the magnetism cancellation element 100 varies according to a sinusoidal curve during a cycle of 180 degrees. In other words, the maximum torque is generated in the stud holder 63 when the angle θb is 45 degrees, 135 degrees, 225 degrees and 315 degrees. On the other hand, the maximum torque is generated in the magnetism canceling element 100 for a position phase shifted by 50 degrees with respect to the eyebolt holder 63. In this case, in the ranges where the torques generated in the eyebolt carrier 63 and in the magnetism cancellation element 100 act in the same direction around the shaft O1, these torques add to each other. On the other hand, in the ranges where the torques generated in the stud carrier 63 and in the magnetism cancellation element 100 act in different directions around the axis O1, these torques act in the direction of s cancel each other. As a result, under the conditions of FIG. 3, the maximum value of the resulting torque rate is higher than the maximum values of the respective torque rates of the stud carrier 63 and of the magnetism cancellation element 100. behaviors described above are the same under the conditions of Figure 9.

Under the conditions of FIG. 4, the respective torque ratios of stud holder 63 and of magnetism cancellation element 100 are maximum in a phase-shifted position of 60 degrees. In this case, the maximum value of the resulting torque rate and the maximum values of the respective torque rate of the stud carrier 63 and the magnetism cancellation element 100 are equivalent to each other. The behavior described above is the same under the conditions of Figure 8.

[0071] On the other hand, under the conditions of FIG. 5, the respective rates of torque of the stud holder 63 and of the magnetism cancellation element 100 are maximum in a position shifted in phase by 90 degrees. In this case, the maximum value of the resulting torque rate is lower than the maximum values of the respective torque rates of the stud holder 63 and of the magnetism cancellation element 100. The behavior described above is the same in the conditions of figure 7.

[0072] Furthermore, in the case where the angle θa is 90 degrees as in FIG. 6, the torque rates generated in the stud holder 63 and the magnetism cancellation element 100 are in phase opposition. . Thus, the resulting torque rate is 0 whatever the angle θb.

[0073] FIG. 10 is a graph illustrating the relationship between the angle θa and the resulting torque rate.

From Figures 3 to 9, etc., the relationship between the angle θa and the resultant torque rate is shown in Figure 10. More specifically, the resultant torque rate decreases as the angle θa approaches 90 degrees. In particular, in the range where the angle θa is greater than 60 degrees and less than 120 degrees, the phases of the torques generated in the stud holder 63 and the magnetism cancellation element 100 are significantly shifted, by so that these couples tend to act in such a way as to cancel each other out. Thus, in the range where the angle θa is greater than 60 degrees and less than 120 degrees, the resulting torque rate is smaller than 1. In other words, in the range where the angle θa is greater than 60 degrees and smaller than 120 degrees, the maximum value of the resulting torque rate is smaller than the maximum values of the respective torque rates of the eyebolt holder 63 and the magnetism canceling element 100.

In this way, in the present embodiment, the angle θa formed by the first straight line La and the second straight line Lb is chosen in the range where it is greater than 60 degrees and less than 120 degrees.

In this arrangement, the phases of the torques generated in the eyebolt holder 63 and in the magnetism cancellation element 100 due to the presence of the magnetic field H are shifted by a large amount, so that these couples tend to act in the direction of canceling each other out. Thus, it is possible to reduce the resulting torque (the torque generated in the cage 41) of the torques acting on the stud holder 63 and the magnetism cancellation element 100.

Furthermore, in the present embodiment, the magnetism cancellation element 100 is simply added to the cage 41, so that it is possible to avoid an increase in size, compared to the prior art technique in which the movement 10 and the tourbillon 13 are themselves covered with magnetic material.

Furthermore, the torques generated in the two magnetic elements in the presence of the magnetic field H cancel each other out, so that, contrary to the usual solution in which the magnetic flux is simply passed, it is possible to obtain superior magnetic strength regardless of the strength of the magnetic field.

Furthermore, in the present embodiment, the magnetism cancellation element 100 is mounted in the cage 41 while being independent of the functional components of the timepiece 1. The functional components of the timepiece timepiece 1 are the components designed to carry out the function of driving the hands of timepiece 1, by cooperating with the other functional components of timepiece 1.

[0080] In this embodiment, the magnetism cancellation element 100 can be mounted in the cage 41 without having to cooperate with other functional components. As a result, it is possible to choose the layout and shape of the magnetism canceling element 100 relatively freely, depending on the layout, shape, etc. of the magnetic element formed by the holder. -piton 63. As a result, it is possible to obtain a progress relating to the properties of the architecture and to the freedom of design and to obtain another progress relating to the magnetic resistance, by comparison with the case where the two magnetic elements , whose torques cancel each other out, are functional components.

Variant

In the timepiece 1 according to the embodiment described above, among the three functional components extending in the radial direction which are the stud carrier 63, the racket 65 and the anchor body 92 , only the eyebolt holder 63 constitutes a magnetic element, but this should not be understood in a restrictive manner. In other words, any other constitution can be suitable provided that at least one of the three functional components mentioned above is a magnetic element. In other words, any arrangement will be suitable as long as the angle between the functional component which is the magnetic element and the magnetic cancellation element (the angle formed by the lines connecting the axis O1 and the end surfaces lying most outward in a radial direction) is chosen to be greater than 60 degrees and less than 120 degrees.

[0082] In the case where two of the three functional components mentioned above are magnetic elements, the angle between the magnetic elements can be chosen to be greater than 60 degrees and less than 120 degrees. More specifically, in the tourbillon 13 represented in FIG. 11, the stud carrier 63 and the anchor body 92 are magnetic elements. The eyebolt carrier 63 and the anchor body 92 are arranged so that an angle θc between the two straight lines Le and Ld connecting their respective end surfaces lying most outward in a radial direction and l axis O1 is 90 degrees. In the example shown in Figure 12, the eyebolt holder 63 and the anchor body 92 are positioned in such a way that an angle θd between the two straight lines Le and Ld connecting their respective end surfaces located more outward in a radial direction and the O1 axis is 75 degrees. No racket 65 is provided in the examples shown in Figures 11 and 12.

In this arrangement, the torques generated in the eyebolt holder 63 and the anchor body 92 in the presence of the magnetic field H can easily be exerted so as to cancel each other out. This produces the same effect as that of the embodiment described above. In particular, in the present embodiment, due to the arrangement of the eyebolt holder 63 and the anchor body 92, which are functional components, it is possible to reduce the influence of the magnetic field H, so that It is possible to achieve a reduction in the number of components, etc., as compared to the case where a magnetism canceling member is provided separately.

[0084] Even in the case where two of the three functional components mentioned above are magnetic elements, the magnetism canceling element can be provided independently. In this case, the angle between one of the two magnetic elements and the magnetism canceling element, and the angle between the other magnetic element and the magnetism canceling element are chosen so as to be greater than 60 degrees and less than 120 degrees (preferably 90 degrees).

Further, the two magnetic elements can be arranged such that the angle between them is greater than 120 degrees and less than 180 degrees, and the magnetism canceling element can be arranged in a dividing position ( for example in two equal parts) the angle between the two magnetic elements.

Moreover, the three functional components can all form magnetic elements. In this case, it is preferable that the angle between two of the three magnetic elements is chosen so as to be greater than 120 degrees and less than 180 degrees, and that the remaining magnetic element is arranged in a dividing position (for example in two equal parts) the angle between the two magnetic elements. The remaining magnetic element can be arranged within a range of +30 degrees to -30 degrees from the position dividing the angle between the two magnetic elements into two equal parts.

[0087] Further, even in the case where the three aforementioned functional components are all magnetic elements, a magnetism canceling element may be provided separately. In this case, all that is required is that the angle between the two elements of each pair of adjacent elements among the elements that are the three magnetic elements and the magnetism canceling element be arranged within a range of 90 degrees ± 30 degrees.

[0088] In this way, in the present embodiment, any construction will be suitable as long as the angle formed by each pair of magnetic elements which, among the magnetic elements including the magnetism cancellation elements, are adjacent in the peripheral direction (the angle between the straight lines connecting their outermost end surfaces in a radial direction and the axis O1) is chosen to be greater than 60 degrees and less than 120 degrees. In this case, one of the magnetic elements adjacent to each other in the peripheral direction constitutes the first magnetic element, while the other magnetic element among these magnetic elements adjacent to each other in the direction peripheral constitutes the second magnetic element.

Second embodiment

Now, a second embodiment of the present invention will be described. Figure 13 is a plan view of a cage 110 according to the second embodiment. In the following description, components identical to those of the first embodiment described above are designated by the same reference numerals and description thereof will be omitted.

In the cage 110 shown in Figure 13, the anchor body 92, the eyebolt carrier 63 and the racket 65 are all magnetic elements. The anchor body 92 and the eyebolt carrier 63 are arranged such that the angle between the straight lines connecting their outermost end surfaces in a radial direction and the axis O1 is 180 degrees.

The outermost end surface, in a radial direction, of the racket arm 111 of the racket 65 is on the outer side, in a radial direction, of the cage main plate 44.

[0092] Here, in the case where the anchor body 92 and the eyebolt holder 63 are arranged so as to form an angle of 180 degrees, the couples of the anchor body 92 and of the eyebolt holder 63 at the level of the end surfaces lying most outward in a radial direction, around the axis O1, are generated in the same direction and with the same phase. In this way, the maximum value of the torque resulting from the anchor body 92 and the eyebolt holder 63 is approximately of the order of twice the torques generated respectively in the anchor body 92 and in the eyebolt holder 63 (see Figure 10).

Furthermore, the racket 65 is arranged at an angle of 90 degrees with respect to the anchor body 92 and to the eyebolt carrier 63, so that the torque, around the axis O1, of the racket 65, at the outermost end surface in a radial direction is generated with a reverse phase of the phase of the anchor body 92 and the eyebolt carrier 63 in an opposite direction.

[0094] In view of this, in the present embodiment, the length of the racket 65 in a radial direction is chosen so that the torque, around the axis O1, of the racket 65 at the surface of outermost end in a radial direction is equivalent to the torque resulting from the anchor body 92 and the eyebolt carrier 63. As a result, it is possible to cancel, by the torque generated in the racket 65 , the torques generated in the eyebolt carrier and in the anchor body 92.

In addition, due to the arrangement of the eyebolt carrier 63, the anchor body 92 and the racket 65 which are all functional components, it is possible to reduce the influence of the magnetic field H, if although it is possible to achieve a reduction in the number of components, etc., as compared to the case where the magnetism canceling member is provided independently.

Variant

In the second embodiment described above, by means of an elongation of the racket arm 111 on one side in a radial direction, the torque, around the axis O1, of the racket 65 at the level of the outermost end surface in a radial direction is adjusted so as to be equivalent to the torque resulting from the anchor body 92 and the eyebolt carrier 63, but this should not be understood restrictively. For example, as shown in Figure 14, a pair of racquet arms 121 and 122 may project both sides, in radial directions, from racquet base 95.

Specifically, racket arms 121 and 122 protrude from racket base 95 so that the angle between the straight lines connecting the outwardmost end surfaces in a direction radial, racket arms 121 and 122 and the axis O1 is 180 degrees. Thus, the angle between the anchor body 92 and the racquet arm 121 among the racquet arms 121 and 122 is chosen to be 90 degrees. The angle between the other racquet arm 122 and the stud holder 63 is chosen to be 90 degrees. The aforementioned racquet pin 77 and racquet key 78 are mounted on the racquet arm 121.

[0098] Here, the radial length of the racquet arm 121 is chosen so that the torque, around the axis O1, at its outermost surface in a radial direction is equivalent to the torque generated in the anchor body 92. In addition, the radial length of the other racket arm 121 is chosen so that the torque, about the axis O1, at its outermost end surface in a radial direction is equivalent to the torque generated in the stud carrier 63.

In this construction, it is possible to prevent the racket arms 121 and 122 from projecting and protruding from the cage main plate 44 in a radial direction, so that an increase in congestion.

Third embodiment

Now, the third embodiment of the present invention will be described. The present embodiment differs from the embodiments described above in that the axes of the cage shafts 46 and 47 are placed in off-axis positions with respect to the axis O1 of the main cage plate 44. In the present mode of embodiment, the stud holder 63 and a magnetism cancellation element 130 are magnetic elements.

[0101] In the cage 131 shown in Figure 15, the cage shafts 46 and 47 are arranged coaxially with an axis 02 of the anchor shaft 91. In addition, the magnetism canceling element 130 is provided on the balance bridge 55. The magnetism canceling element 130 is shaped as a plate extending in a radial direction.

[0102] Here, it is considered that the straight line connecting the outermost end surface, in a radial direction, of the aforementioned eyebolt carrier 63 (eyebolt arm 72) and the axis O2 is a first line straight line Lf and that the straight line connecting the outermost end surface, in a radial direction, of the magnetism canceling member 130 and the axis 02 is a second straight line Lg. Then, it is preferable that the eyebolt carrier 63 and the magnetism cancellation element 130 are arranged in such a way that an angle θf between the first straight line Lf and the second straight line Lg is greater than 60 degrees and less than at 120 degrees. In the present embodiment, the angle θf is chosen to be approximately 90 degrees.

As in the present embodiment, it is not always necessary for the magnetic element including the magnetism canceling element 130 to extend in a direction radial to the axes of the cage shafts 46 and 47. as it extends in one direction in a plan view obtained by looking from the axial direction of the cage shafts 46 and 47.

In this construction also, it is possible to obtain the same effect as with the embodiments described above.

The technical scope of the present invention is not limited to the embodiments described above, but allows various modifications without departing from the general scope of the present invention.

In the embodiments described above, at least one element among the anchor body 92, the stud holder 63 and the racket 65 is a magnetic element; however, this should not be interpreted restrictively; other functional components may be magnetic elements.

[0107] While in the embodiments described above, the axes of the cage shafts 46 and 47 are arranged coaxially with the axis O1 of the main cage plate 44 or with the axis O2 of the anchor 53, the axes of the cage shafts 46 and 47 can be placed in arbitrary positions.

[0108] Several magnetism cancellation elements can be provided provided that at least one of the magnetic elements is a functional component of the timepiece chosen from among a stud holder, a racket and an anchor body.

[0109] Furthermore, each magnetic element can extend while being inclined with respect to the axial direction in a side view obtained by looking from a radial direction, since it extends in a direction which is a direction longitudinal, in a plan view obtained looking from the axial direction.

[0110] The components of the embodiments described above can be replaced by well-known components, as appropriate, without departing from the most general scope of the present invention. Moreover, the previously described variants can be combined with each other in a suitable way.

Claims (5)

1. Tourbillon (13) for a timepiece movement, comprising: – a cage (41; 110; 131) which is rotatable around an axis (O1; O2) of a cage shaft (46, 47) and in which a regulator-exhaust assembly (45) is mounted; – a first magnetic element (63; 65) which extends along a first direction in a plan view obtained by looking from is the axial direction of the cage shaft and which is a functional component of the selected timepiece among a piton holder (63), a racket (65) and an anchor body (92); and – a second magnetic element (100; 92; 130) which extends in a second direction crossing the first direction in plan view, in which, in the plan view, an angle (θa; θc; θd; θf) between, on the one hand, a first straight line (La; Lc; Lf) connecting the axis (O1; O2) and a surface end of the first magnetic element (63; 65), namely its end surface lying most outward in the first direction, and, on the other hand, a second straight line (Lb; Ld; Lg ) connecting the axis (O1; O2) and an end surface of the second magnetic element (100; 92; 130), namely its end surface lying most outward in the second direction, is more larger than 60 degrees and smaller than 120 degrees. 2. Tourbillon according to claim 1, in which the second magnetic element is a functional component of the timepiece chosen from among a stud holder (63), a racket (65) and an anchor body (92). 3. Tourbillon according to claim 1, in which the second magnetic element (100; 130) is a magnetism cancellation element mounted in the cage (41; 131) independently of the functional components of the timepiece chosen from among the eyebolt holder (63), the racket (65) and the anchor body (92). 4. Movement (10) of a timepiece, comprising a tourbillon (13) according to one of claims 1 to 3. 5. Timepiece comprising a movement (10) according to claim 4.