Method of improving the pivoting of a wheel set

The invention claimed is: 1. A method of improving the pivoting of a wheel set or of an equipped wheel set for a scientific instrument or timekeeper, including at least one arbor arranged to pivot or oscillate about an axis of oscillation aligned on an wheel set axis formed by the axis of said arbor, wherein: performing static balancing of said wheel set to bring a center of gravity onto said wheel set axis; determining a desired value for a resulting unbalance moment of said wheel set about said wheel set axis, corresponding to a predetermined desired divergence between a first principal longitudinal axis of inertia of said wheel set, and said wheel set axis; setting in rotation said wheel set at a predetermined speed about said wheel set axis, the resulting unbalance moment is measured with regard to said wheel set axis; making an adjustment to a value of the resulting unbalance moment of said wheel set about said wheel set axis within a given determined tolerance with regard to said desired value; performing said adjustment by machining both sides of a median plane including two secondary axes of inertia of said wheel set. 2. The method according to claim 1 , wherein said adjustment is carried out by an asymmetrical addition and/or displacement and/or removal of material in relation to a plane perpendicular to said axis of said wheel set or equipped wheel set. 3. The method according to claim 1 , wherein said adjustment is carried out by an asymmetrical addition and/or displacement and/or removal of material in relation to a plane defined by two secondary axes of inertia of said wheel set or equipped wheel set. 4. The method according to claim 1 , wherein an addition and/or displacement and/or removal of material is carried out on at least one flange comprised in said wheel set or said equipped wheel set, projecting radially in relation to said arbor. 5. The method according to claim 4 , wherein machined portions are formed, on both sides of said median plane, with different volumes with respect to said wheel set axis. 6. The method according to claim 4 , wherein machined portions are formed, on both sides of said median plane, with different radial positioning with respect to said wheel set axis. 7. The method according to claim 4 , wherein machined portions are formed, on both sides of said median plane, axially parallel to said wheel set axis, from a same side of said flange. 8. The method according to claim 4 , wherein machined portions are formed, on both sides of said median plane, axially parallel to said wheel set axis, on opposite sides of said flange. 9. The method according to claim 4 , wherein, prior to said static balancing of said wheel set or of said equipped wheel set, said flange is machined to be out of truth in the flat by a determined value, with a resulting unbalance moment in a specific angular direction and having a predetermined value, and off-center in relation to said median plane. 10. The method according to claim 9 , wherein said flange is made with portions of excess thickness, on both sides of said median plane, which substantially define together a plane passing through said wheel set axis, said portions of excess thickness forming together a controlled unbalance, and correction is forced in a certain area around said plane. 11. The method according to claim 2 , wherein the addition and/or displacement and/or removal of material is carried out on said arbor of said wheel set or of said equipped wheel set. 12. The method according to claim 2 , wherein the addition and/or displacement and/or removal of material is carried out on at least one arm comprised in said wheel set between said arbor and another off-center part of said wheel set or of said equipped wheel set. 13. The method according to claim 1 , wherein said static balancing is performed prior to said adjustment of a value of a dynamic balancing moment. 14. The method according to claim 1 , wherein said static balancing is performed simultaneously with said adjustment of a value of a dynamic balancing moment. 15. The method according to claim 1 , wherein said desired value of the resulting unbalance moment of the wheel set or equipped wheel set about said wheel set axis is set at zero, so as to make said first principal longitudinal axis of inertia of said wheel set or said equipped wheel set coincident with said wheel set axis. 16. The method according to claim 1 , wherein said predetermined speed of rotation is set at a maximum angular speed calculated for said wheel set or equipped wheel set, considered during pivoting or oscillation thereof in service, in combination with at least one drive means, and/or a specific elastic means of return or repulsion, and/or magnetic means of return or repulsion, and/or electrostatic means of return or repulsion. 17. The method according to claim 2 , wherein, prior to said static balancing and dynamic balancing, at least one flange, comprised in said wheel set or equipped wheel set, is machined with cylindrical or fluted housings arranged to receive cylindrical or fluted masses movable in an axial direction parallel to said wheel set axis, and all or part of said adjustment is accomplished by the displacement of said movable masses inserted in said housings in relation to said plane defined by the two secondary axes of inertia of said wheel set or equipped wheel set. 18. The method according to claim 17 , wherein, prior to said static balancing and said dynamic balancing, said movable masses are confined in and made inseparable from said flange, either during a creation of a monobloc of said wheel set or equipped wheel set in a single piece with said movable masses, or by extending at least one end of each said movable mass to prevent an extended area from passing through the corresponding housing for said movable mass. 19. The method according to claim 1 , wherein all or part of said adjustment is accomplished by deformation of at least one flange, comprised in said wheel set or equipped wheel set, in an asymmetrical manner in relation to said plane defined by the two secondary axes of inertia of said wheel set or equipped wheel set. 20. The method according to claim 1 , wherein, prior to said static balancing and dynamic balancing, at least one flange, comprised in said wheel set or equipped wheel set, is machined with internally threaded radial housings, arranged to receive asymmetrical headed screws movable in a radial direction in relation to said wheel set axis, and all or part of said adjustment is accomplished by displacement of said screws screwed into said internally threaded housings. 21. The method according to claim 1 , wherein, when the resulting unbalance moment of said wheel set or equipped wheel set is measured in relation to said wheel set axis, an unbalance is noted in an angular position in relation to an angular guide-mark comprised in said wheel set or equipped wheel set. 22. A wheel set for a scientific instrument or timekeeper, comprising: at least one arbor arranged to pivot or oscillate about an oscillation axis aligned on a wheel set axis formed by an axis of said arbor, and including at least one flange connected to said wheel set arbor and projecting radially in relation to said arbor, said at least one flange being substantially perpendicular to said wheel set axis, wherein said wheel set is manufactured to include a first principal longitudinal axis of inertia close to said wheel set axis or coincident therewith, the two secondary