A multiple jump timepiece display mechanism includes a continuously rotating control wheel arranged to drive an indicator wheel carrying a display, either directly by the value of an elementary pitch PE by a direct or indirect continuous cooperation between the control wheel and the indicator wheel, or indirectly through a multiplier mechanism, by the combination of a device for disengaging the elementary pitch drive mechanism, and by driving the indicator wheel, in at least one disengaging position, by this multiplier mechanism driving it by an increased pitch PM greater than the elementary pitch PE or a multiple thereof.

A multiple jump timepiece display mechanism includes a continuously rotating control wheel arranged to drive an indicator wheel carrying a display, either directly by the value of an elementary pitch PE by a direct or indirect continuous cooperation between the control wheel and the indicator wheel, or indirectly through a multiplier mechanism, by the combination of a device for disengaging the elementary pitch drive mechanism, and by driving the indicator wheel, in at least one disengaging position, by this multiplier mechanism driving it by an increased pitch PM greater than the elementary pitch PE or a multiple thereof.

The invention is a two-stage speed increaser arrangement comprising force transmission members having a first, second, third and fourth pitch surface (100A, 100B, 100a, 100b), wherein the first pitch surface (100A) and the third pitch surface (100a) having a common first line segment (102A) and the second pitch surface (100B) and wherein the fourth pitch surface (100b) having a common second line segment (102B).

The two-stage speed increaser arrangement is characterised in that considering as an origin (T1), of an orthogonal coordinate system in a plane (104) perpendicular to the second line segment (102B), a projection of the second line segment (102B) to the plane (104), and considering that the Y axis of the coordinate system is pointing in the direction of a projection point (TO) of a point (D) of the first line segment (102A) to the plane (104), the following Formula 1 is satisfied at all times for the arrangement, in a coordinate system defined for each point (D) of the first line segment (102A):

x(((y′+d)x−x′y)(x.sup.2+y.sup.2−dy)+d.sup.2xy)≥0,  Formula 1

wherein
d is the distance of the projection point (T0) from the origin (T1),
x and y are the coordinates of a projection point (K), as projected to the plane (104), of an arbitrary tooth contact point (P) within any tooth contact region of the first pitch surface (100A) and the third pitch surface (100a), and
x′ and y′ are the coordinates of the projection point (K′), as projected to the plane (104), of an arbitrary tooth contact point (P′) situated along any tooth contact region of the second pitch surface (100B) and the fourth pitch surface (100b).

The invention is furthermore a gear train satisfying the above formula.

The invention is a two-stage speed increaser arrangement comprising force transmission members having a first, second, third and fourth pitch surface (100A, 100B, 100a, 100b), wherein the first pitch surface (100A) and the third pitch surface (100a) having a common first line segment (102A) and the second pitch surface (100B) and wherein the fourth pitch surface (100b) having a common second line segment (102B).

The two-stage speed increaser arrangement is characterised in that considering as an origin (T1), of an orthogonal coordinate system in a plane (104) perpendicular to the second line segment (102B), a projection of the second line segment (102B) to the plane (104), and considering that the Y axis of the coordinate system is pointing in the direction of a projection point (TO) of a point (D) of the first line segment (102A) to the plane (104), the following Formula 1 is satisfied at all times for the arrangement, in a coordinate system defined for each point (D) of the first line segment (102A):

x(((y′+d)x−x′y)(x.sup.2+y.sup.2−dy)+d.sup.2xy)≥0,  Formula 1

wherein
d is the distance of the projection point (T0) from the origin (T1),
x and y are the coordinates of a projection point (K), as projected to the plane (104), of an arbitrary tooth contact point (P) within any tooth contact region of the first pitch surface (100A) and the third pitch surface (100a), and
x′ and y′ are the coordinates of the projection point (K′), as projected to the plane (104), of an arbitrary tooth contact point (P′) situated along any tooth contact region of the second pitch surface (100B) and the fourth pitch surface (100b).

The invention is furthermore a gear train satisfying the above formula.

A watch has a mechanical movement with a force control mechanism arranged in a going train of the mechanical movement between an energy source and an escape wheel set connected to an oscillating oscillator to drive the escape wheel set always in the same direction of rotation. The escape wheel set meshes with a seconds wheel. A rotating locking element is arranged to cooperate with a stop member connected to this seconds wheel in order to lock this going train in a stop mode or to release this going train in a jump mode depending on the angular position of this seconds wheel. A flexure bearing with elastic strips is attached on the one hand to the seconds wheel and on the other hand to the movement support. The pre-wound flexure bearing is arranged to drive in rotation the seconds wheel and the escapement mechanism connected to the oscillator at each half-oscillation of the oscillator in the stop mode.

A watch has a mechanical movement with a force control mechanism arranged in a going train of the mechanical movement between an energy source and an escape wheel set connected to an oscillating oscillator to drive the escape wheel set always in the same direction of rotation. The escape wheel set meshes with a seconds wheel. A rotating locking element is arranged to cooperate with a stop member connected to this seconds wheel in order to lock this going train in a stop mode or to release this going train in a jump mode depending on the angular position of this seconds wheel. A flexure bearing with elastic strips is attached on the one hand to the seconds wheel and on the other hand to the movement support. The pre-wound flexure bearing is arranged to drive in rotation the seconds wheel and the escapement mechanism connected to the oscillator at each half-oscillation of the oscillator in the stop mode.

A method for producing a tube for a friction system comprising the tube and an arbor, in particular a tube provided to rub around a pinion arbor, the method comprising a first stage of plastic deformation of the tube, in particular a first stage of plastic deformation of the tube that is controlled in deformation, followed by a second stage of hardening of the tube, in particular hardening by heat treatment.

Disclosed is a mechanism for displaying the number of the week for fitting to a timepiece movement and including a starwheel for the weeks including 52 or 53 teeth, a rocker for the weeks including a flexible finger cooperating with the toothed arrangement of the weeks starwheel upon actuation of the rocker by a driving mobile, the one driving mobile driven by one step per day by the movement and to actuate the weeks rocker once every seven days upon passing from the last day of the week to the first. The driving mobile is a driving starwheel including seven teeth, six being so-called silent teeth which are arranged not to cooperate with the weeks rocker and one tooth is a driving tooth arranged to actuate the rocker once per week upon passing from the last day of the week to the first day of the week.

Disclosed is a mechanism for displaying the number of the week for fitting to a timepiece movement and including a starwheel for the weeks including 52 or 53 teeth, a rocker for the weeks including a flexible finger cooperating with the toothed arrangement of the weeks starwheel upon actuation of the rocker by a driving mobile, the one driving mobile driven by one step per day by the movement and to actuate the weeks rocker once every seven days upon passing from the last day of the week to the first. The driving mobile is a driving starwheel including seven teeth, six being so-called silent teeth which are arranged not to cooperate with the weeks rocker and one tooth is a driving tooth arranged to actuate the rocker once per week upon passing from the last day of the week to the first day of the week.

A timepiece display mechanism including at least a first retrograde drive device for a first display member displaying a first magnitude, and a second retrograde drive device for a second display member displaying a second magnitude, the first retrograde drive device including a first drive rack to exert on a first wheel set driving the first display member, an opposite force to a resistance force exerted by a first return rack, the second retrograde drive device including a second drive rack to exert on a second wheel set driving the second display member, an opposite force to a resistance force exerted by a second return rack, wherein the pivot axes of the first drive rack and of the first return rack are remote, and/or the pivot axes of the second drive rack and of the second return rack are remote.