Balance spring stud-holder with secure assembly

Abstract

The present invention concerns an assembly for holding or supporting a timepiece balance spring, comprising a balance spring stud and a balance cock on which is fixed a balance spring stud-holder, wherein said stud-holder comprises a holding means provided with a housing for housing the balance spring stud therein and a gripping means, at least said gripping means being movable with respect to the holding means in order to lock the balance spring stud inside its housing.

Claims

1. An assembly for holding or supporting a timepiece balance spring, comprising a balance spring stud and a balance cock on which is fixed a balance spring stud-holder, comprising: a holding means provided with a housing for housing the balance spring stud therein and a gripping means, at least said gripping means being movable with respect to the holding means in order to lock the balance spring stud inside the housing, wherein the holding means and the gripping means comprise an annular piece arranged to be rotatably mounted on a protuberance, and wherein the holding means comprise a holding ring comprising a resilient arm extending from said ring and forming therewith a housing for accommodating the balance spring stud.

2. The assembly according to claim 1, wherein the gripping means comprise a gripping ring comprising a frame on which a stud is arranged, the frame and the stud being arranged such that the rotation of the gripping ring with respect to the holding ring results in the appearance of a stress exerted by said stud on said resilient arm in order to lock the balance spring stud assembly.

3. The assembly according to claim 2, wherein the frame comprises at least two radially extending arms, connected to each other by a crosspiece, the at least two arms being spaced apart so as to allow the balance spring stud to be set in place and locked without the risk of any contact with said arms.

4. The assembly according to claim 3, wherein the gripping ring and the holding ring each comprise a radially extending positioning extension piece configured to be gripped to rotate the gripping ring and the holding ring, and the positioning extension piece of the gripping ring and of the arms of the frame form only a single piece.

5. The assembly according to claim 1, wherein the gripping means comprise a gripping ring comprising a frame on which is arranged a structure provided with a groove, the groove being arranged such that the resilient arm can be inserted therein so that the rotation of said locking ring with respect to the holding ring causes a deformation of said arm in order to lock the balance spring stud assembly.

6. The assembly according to claim 1, wherein the gripping ring and the holding ring each comprise a radially extending positioning extension piece configured to be gripped to rotate the gripping ring and the holding ring.

7. The assembly according to claim 6, wherein the positioning extension pieces of the gripping ring and of the holding ring are arranged to face each other when the balance spring stud is locked to allow simultaneously gripping thereof to perform an angular adjustment of the position of the balance spring stud with respect to the balance cock.

8. A timepiece movement comprising a main plate on which is mounted an energy source supplying energy to the transmission gear trains, said gear trains cooperating with an escapement system via an escape wheel whose rotation is regulated by a pallet lever of the escapement system whose pulses are provided by a sprung balance, said balance spring being mounted on a holding assembly according to claim 1.

9. The timepiece movement according to claim 8, wherein the gripping means comprise a gripping ring comprising a frame on which a stud is arranged, the frame and the stud being arranged such that the rotation of the gripping ring with respect to the holding ring results in the appearance of a stress exerted by said stud on said resilient arm in order to lock the balance spring stud assembly.

10. The timepiece movement according to claim 8, wherein the gripping means comprise a gripping ring comprising a frame on which is arranged a structure provided with a groove, the groove being arranged such that the resilient arm can be inserted therein so that the rotation of said locking ring with respect to the holding ring causes a deformation of said arm in order to lock the balance spring stud assembly.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The objects, advantages and features of the invention will appear more clearly in the following detailed description of at least one embodiment of the invention, given solely by way of non-limiting example and illustrated by the annexed drawings, in which:

(2) FIGS. 1 to 5 represent a first embodiment of the holding assembly according to the invention.

(3) FIGS. 6 to 10 represent a variant of the first embodiment of the holding assembly according to the invention.

(4) FIGS. 11 to 15 represent a second embodiment of the holding assembly according to the invention.

(5) FIGS. 16 and 17 represent a variant of the second embodiment of the holding assembly according to the invention.

DETAILED DESCRIPTION

(6) The present invention proceeds from the general idea of providing an assembly for holding or supporting a timepiece balance spring permitting simpler assembly/disassembly of the balance spring stud.

(7) FIG. 1 shows the holding or support assembly 1 according to the present invention. This assembly 1 is mounted on a balance cock 2 and comprises a balance spring stud-holder 4 used for holding a balance spring stud 7.

(8) Balance spring stud-holder 4 according to the invention comprises holding means 5 and gripping means 6. Holding means 5 are used to support balance spring stud 7 whereas gripping means 6 are used to lock the position of balance spring stud 7 on holding means 5.

(9) In a first embodiment seen in FIGS. 1 to 5, holding means 5 take the form of a holding ring 50. This holding ring 50 is closed or open and is dimensioned to be arranged on a protuberance 8. Balance cock 2 can be made to comprise a pivoting device 80, this pivoting device 80 may take the form of a setting 81 provided with a jewel hole and endstone 82 and with a spring 83, or the form of a stud 84 provided with a hole 85 in which the balance staff engages. Protuberance 8 could be this pivoting device 80. The protuberance is circular.

(10) The holding ring is force fitted on pivoting device 8, i.e. on setting 80 or stud 83. A groove extending over the periphery of stud 83 or of setting 80 could be provided to prevent vertical displacement of holding ring 50. Holding ring 50 further comprises balance spring stud receiving means 51. These receiving means 51 comprised two projecting extended portions 52, extended in parallel outwards from holding ring 50. These two extended portions 52 are spaced apart from each other to form a housing space 53 inside which balance spring stud 7 can be housed. It is thus understood that these two extended portions project from holding ring 50 but also from the balance cock.

(11) In this first embodiment, gripping means 6 take the form of a gripping ring 60. Gripping ring 60 is closed or open and is dimensioned to be arranged on pivoting device 8, like the holding ring. Gripping ring 60 is thus forced fitted onto pivoting device 8. A groove extending over the periphery of stud 83 or of setting 80, parallel to that of holding ring 50, could be provided to prevent vertical displacement of the gripping ring. The gripping ring is thus located above the holding ring. Gripping ring 60 further comprises a resilient arm 62. This arm 62 extends from said gripping ring 60 and has a free end 63. Arm 62 extends from gripping ring 60 in a substantially similar direction to that of the curvature of said gripping ring in order to form a space 64 between gripping ring 60 and said arm 62.

(12) To operate this device, balance spring stud 7 is placed inside housing 53 of holding ring 50. Gripping ring 60 is then rotated such that the end 63 of resilient arm 62 moves closer to the balance spring stud. The free end 63 of resilient arm 62 is skillfully arranged to comprise a lug 65 in order to be partially in contact with the balance spring stud. Consequently, the operator responsible for assembly is obliged to apply a slight force when rotating gripping ring 60. Under the effect of this stress, resilient arm 62 is deformed and moves aside. This leaves a larger space for insertion of balance spring stud 7. When balance spring stud 7 passes the free end 63 of resilient arm 62 provided with lug 64, said resilient arm 62 tends to return to its rest or initial position. In this case, it tends to exert a force on the balance spring stud. Since the stud is inside housing 53 of holding ring 50, this force exerted by the resilient arm makes it possible to lock the position of the balance spring stud. Gripping ring 60 and holding ring 50 must be dimensioned such that the friction between them and pivoting means 8 can permit a rotation of the rings while preventing an untimely rotation of the rings. Thus, by unlocking the balance spring stud by means of the gripping means, one can simply remove the balance/balance spring/balance spring stud part from the balance cock/balance spring stud-holder/shock absorber part, without the risk of breaking the balance spring.

(13) In an advantageous variant seen in FIGS. 4 and 5, balance spring stud 7 has a body 71 arranged to allow attachment of the balance spring and a head 72, said head having a conical profile 73 whose diameter is greater than that of body 71. The head of balance spring stud 72 is capable of resting on the two projecting extended portions 52 The resilient arm that comes into contact with the balance spring stud on this conical profile then exerts a force perpendicular to the slope of the cone so as to press the balance spring stud along the z axis against the two projecting extended portions 52 and into its housing along the x, y axes. Housing 53 and/or balance spring stud 7 may comprise flat portions to achieve angular locking.

(14) In an advantageous variant seen in FIG. 2, holding ring 50 and gripping ring 60 each have a positioning extension piece 56, 66. Gripping ring 60 and holding ring 50 thus each comprise a radially extending extension piece, this extension piece allowing for gripping by a tweezer type tool. Cleverly, it will be provided that these extension pieces 56, 66 are arranged such that they face each other when balance spring stud 7 is locked, as seen in FIG. 3. This arrangement makes it possible to rotate gripping means 60 and holding means 50 at the same time.

(15) In a variant of this first embodiment seen in FIGS. 6 to 10, holding ring 50 is made such that balance spring stud receiving means 51 take the form of a single extension piece 52 pierced with an opening forming a housing 53 for balance spring stud 7. In this case, the gripping ring is arranged underneath the holding ring and the head 72 of balance spring stud 7 has an inverted cone profile 73. In this variant configuration, the assembly is similar, so that resilient arm 62 comes into contact with the cone 73 of balance spring stud 7 and generates a force perpendicular to the slope of cone 73. This force presses balance spring stud 7 into its housing 53 along the Z axis and into its housing on the X, Y axis. The housing and/or the balance spring stud may comprise flat portions to achieve angular locking.

(16) In a second embodiment seen in FIGS. 11 to 15, holding means 5 take the form of a holding ring 500. Holding ring 500 is closed or open and is dimensioned to be arranged on pivoting device 8, which is of substantially circular shape. The holding ring is force fitted on pivoting device 8, i.e. on setting 80 or stud 83. A groove extending over the periphery of stud 83 or of setting 80 could be provided to prevent vertical displacement of holding ring 500. Holding ring 500 further comprises balance spring stud receiving means 510. These receiving means 510 comprise a resilient arm 512 extending from said ring and forming therewith a housing 514 for accommodating the balance spring stud.

(17) In this second embodiment, gripping means 6 take the form of a gripping ring 600. Gripping ring 600 is closed or open and is dimensioned to be arranged on pivoting device 8, like the holding ring. Gripping ring 600 is thus forced fitted onto pivoting device 8. A groove extending over the periphery of stud 83 or of setting 80, parallel to that of holding ring 500, could be provided to prevent vertical displacement of gripping ring 600. Gripping ring 600 is thus located above holding ring 500.

(18) Gripping ring 600 comprises a stud 602 mounted on a frame 604. In fact, the operating principle of this second embodiment uses this stud 602 to exert a stress on resilient arm 512 in order to lock balance spring stud 7. Gripping ring 600 is then rotated such that stud 602 enters into contact with resilient arm 512. As the rotation of the gripping ring continues, the stress exerted on resilient arm 51 causes the deformation of the arm and thus locks the balance spring stud. Frame 604 thus allows stud 602 to be moved off centre. In a conventional manner, frame 604 could be an arm 604 whose free end 605 is provided with said stud 602. The latter could be in one piece with frame 604, or free end 605 could be provided with a hole in which stud 602 could be placed and secured.

(19) In an advantageous version, the frame comprises at least two arms 605a, 605b extending radially from ring 600, these arms 605 being connected to each other by a bar or cross-piece 606. Bar 606 is provided with a protuberance on which the stud is arranged. This configuration allows for better rigidity than a frame comprising only one arm.

(20) In this frame configuration seen in FIG. 11, it is provided that the spacing between at least two arms 605 is sufficient to allow balance spring stud 7 to be housed therein without entering into contact with said arms during rotation of the gripping ring. Advantageously, one of arms 605 of frame 604 will be arranged such that, when balance spring stud 7 is locked, said arm is facing a positioning extension piece 516 of holding ring 500. This configuration thus provides the possibility of the operator grasping arm 605 and extension piece 516 by means of tweezers in order to change the angular position of the two rings 500 and 600. This therefore offers the possibility of angular adjustment without changing the locking of balance spring stud 7.

(21) In a preferred configuration, frame 604 comprises four arms 605. The spacing between the second arm 605 and the third arm 605 is chosen for accommodating balance spring stud 7. The fourth arm 605 is arranged to be able to be used in cooperation with an extension piece 516 to change the angular position of the two rings 500, 600.

(22) It could be envisaged that balance spring stud 7 has a body 710 arranged to allow attachment of the balance spring and a head 720, said head 720 having a cylindrical profile 730. Body 710 further comprises a projecting portion 740 forming a platform for resilient arm 512, as seen in FIG. 14.

(23) In a variant of the second embodiment seen in FIGS. 16 and 17, frame 604 comprises one arm 609 whose free end 609 ends in a structure 610. This structure 610 takes the form of a part 611 having a groove 612 similar to a guide groove inside which resilient arm 512 of holding ring 500 is housed. The tension of resilient arm 512 allows the latter to be in permanent contact with one of the walls of groove 612 of structure 610. Consequently, during the rotation of gripping ring 600 carrying frame 604, resilient arm 512, guided by the groove of structure 610, is thus deformed. This deformation allows resilient arm 512 to grip balance spring stud 7 and thus to lock the position of the latter.

(24) It will be clear that various alterations and/or improvements and/or combinations evident to those skilled in the art may be made to the various embodiments of the invention set out above without departing from the scope of the invention defined by the annexed claims.

(25) For example, it could be envisaged that the balance spring is of smaller diameter than the dimension of the balance spring stud-holder, such that it is protected by said stud-holder. Indeed, it has become common to use silicon balance springs, as this material has advantageous amagnetic properties. However, silicon is a brittle material which breaks in the event of excessive shocks. By configuring the balance spring stud-holder and the balance spring so that the balance spring is of smaller dimensions than the balance spring stud-holder, the stud-holder is used as protection for the silicon balance spring against any shocks that may occur during timing of the watch or after sales servicing.