Rotating resonator with flexure bearing maintained by a detached lever escapement

The invention claimed is: 1. A timepiece regulating mechanism, comprising: arranged on a main plate, a resonator mechanism, and an escapement mechanism that is subjected to the torque of drive means comprised in a movement, said resonator mechanism comprising an inertia element arranged to oscillate with respect to said plate, said inertia element being subjected to the action of elastic return means directly or indirectly attached to said plate, and said inertia element being arranged to cooperate indirectly with an escape wheel set comprised in said escapement mechanism, wherein said resonator mechanism is a resonator with a virtual pivot rotating about a main axis, with a flexure bearing including at least two flexible strips, and including an impulse pin integral with said inertia element, wherein said escapement mechanism includes a lever pivoting about a secondary axis at a center of the lever, said lever including: a first arm and a second arm, the first arm and the second arm extending outward from the center of the lever in opposite directions, a first lever fork positioned on a distal end of the first arm, said first lever fork including two horns that are spaced apart and directly contact said impulse pin, and a first pallet positioned on the first arm between the distal end and a proximal end at the center of the lever, the first pallet being configured to directly contact teeth of the escape wheel set, wherein said escapement mechanism is a detached escapement mechanism, wherein, during the operating cycle, said resonator mechanism has at least one phase of freedom in which said impulse pin is at a distance from said first lever fork, and wherein said lever is in a single layer of silicon, placed on an arbor pivoted with respect to said plate. 2. The timepiece regulating mechanism according to claim 1 , wherein a lift angle β of the resonator, during which said impulse pin is in contact with said first lever fork, is less than 10°. 3. The timepiece regulating mechanism according to claim 2 , wherein an inertia I B of said inertia element with respect to said main axis, and an inertia I A of said lever with respect to said secondary axis, are such that the ratio I B /I A is greater than 2Q·α 2 /(0.1·π·β 2 ), where α is a lift angle of the lever which corresponds to a total angular travel of said first lever fork from one side to the other and Q is a quality factor of the resonator mechanism. 4. The timepiece regulating mechanism according to claim 2 , wherein said lift angle β of the resonator is less than twice an angle of amplitude by which said inertia element deviates furthest, in only one direction of motion, from a rest position. 5. The timepiece regulating mechanism according to claim 1 , wherein an angle of amplitude, by which said inertia element deviates furthest from a rest position, is between 5° and 40°. 6. The timepiece regulating mechanism according to claim 1 , wherein, during each vibration, in a contact phase, said impulse pin penetrates said first lever fork with a depth of travel P greater than 100 micrometres, and in an unlocking phase, said impulse pin remains at a distance from said first lever fork with a safety distance S greater than 25 micrometres, and wherein said impulse pin and said first lever fork are dimensioned such that a width of said first lever fork is greater than (P+S)/sin(α/2±β/2), where β is a lift angle of the resonator during which said impulse pin is in contact with said first lever fork and α is a lift angle of the lever which corresponds to a total angular travel of said first lever fork from one side to the other, and said depth of travel P and said safety distance S being measured radially with respect to said main axis. 7. The timepiece regulating mechanism according to claim 1 , wherein said lever is in a single layer of silicon, placed on an arbor pivoted with respect to said plate. 8. The timepiece regulating mechanism according to claim 1 , wherein said escape wheel set is a silicon escape wheel. 9. The timepiece regulating mechanism according to claim 1 , wherein said escape wheel set is an escape wheel which is perforated to minimize inertia with respect to an axis of pivoting. 10. The timepiece regulating mechanism according to claim 1 , wherein said lever is perforated to minimize inertia with respect to said secondary axis. 11. The timepiece regulating mechanism according to claim 1 , wherein said lever is symmetrical with respect to said secondary axis. 12. The timepiece regulating mechanism according to claim 1 , wherein a largest dimension of said inertia element is greater than half of a largest dimension of said plate. 13. The timepiece regulating mechanism according to claim 1 , wherein said main axis, said secondary axis, and an axis of pivoting of said escape wheel set, are arranged to be centered at a right angle whose apex is on said secondary axis within a plane defined perpendicular to the main axis, the secondary axis, and the axis of pivoting of said escape wheel set. 14. The timepiece regulating mechanism according to claim 1 , wherein said flexure bearing includes two flexible strips which are crossed in projection onto a plane perpendicular to said main axis, at said virtual pivot defining said main axis, and said two flexible strips are located in two parallel and distinct levels. 15. The timepiece regulating mechanism according to claim 14 , wherein said two flexible strips, in projection onto a plane perpendicular to said main axis, form therebetween an angle comprised between 59.5° and 69.5°, and intersect at between 10.75% and 14.75% of their length, such that said resonator mechanism has a deliberate isochronism error which is the additive inverse of the loss error at the escapement of said escapement mechanism. 16. The timepiece regulating mechanism according to claim 14 , wherein said two flexible strips are identical and are positioned in symmetry. 17. The timepiece regulating mechanism according to claim 14 , wherein each said flexible strip forms part of a one-piece assembly in one piece with means thereof for alignment and attachment to said plate or to an intermediate elastic suspension strip attached to said plate and arranged to allow a displacement of said flexure bearing and of said inertia element in the direction of said main axis. 18. The timepiece regulating mechanism according to claim 1 , wherein at least said resonator mechanism is attached to an intermediate, elastic suspension strip attached to said plate and arranged to allow a displacement of said resonator mechanism in the direction of said main axis, and wherein said plate includes at least one shock absorber stop at least in the direction of said main axis, arranged to cooperate with at least one stiff element of said inertia element. 19. The timepiece regulating mechanism according to claim 1 , wherein said inertia element includes inertia blocks for adjusting rate and unbalance. 20. The timepiece regulating mechanism according to claim 1 , wherein said impulse pin is in one-piece with one of said flexible strips. 21. The timepiece regulating mechanism according to claim 1 , wherein said flexure bearing is made of oxidised silicon to compensate for the effects of temperature on the rate of said regulating mechanism. 22. The timepiece regulating mechanism according to claim 1 , wherein said balance is made from a heavy alloy, containing gold, and/or platinum, and/or tungsten and includes inertia blocks of t