Bicycle gearshift with improved precision control

What is claimed is: 1. Bicycle gearshift comprising a kinematic mechanism in the form of a four-bar linkage with a base body and a mobile body connected together through a pair of connecting rods articulated to said base body and to said mobile body at four pin elements, each pair of opposite pin elements of said four pin elements defining a diagonal of said four-bar linkage-kinematic mechanism, said base body comprising a first attachment group to a bicycle frame and said mobile body being connected to a chain guide at a second attachment group, said four-bar linkage-kinematic mechanism being associated with gearshift actuation means suitable for deforming said four-bar linkage-kinematic mechanism so as to determine a displacement of said mobile body with respect to said base body and consequently a primary displacement of said chain guide in the axial direction with respect to the axis (A) of a cogset, at least one from said first attachment group and said second attachment group comprising a chain tensioning spring, said chain tensioning spring determining a set-up of the chain guide when engaged with a chain of a bicycle transmission, further comprising a kinematic mechanism that adjusts the preload of said chain tensioning spring as a function of said primary displacement of said chain guide in the axial direction with respect to the axis (A) of the cogset. 2. Bicycle gearshift according to claim 1 , wherein said first attachment group comprises a first chain tensioning spring and said second attachment group comprises a second chain tensioning spring, said first and said second chain tensioning spring acting in antagonism to determine said set-up of the chain guide, said kinematic mechanism for adjusting the preload acting on at least one of said first and said second chain tensioning spring. 3. Bicycle gearshift according to claim 1 , wherein said kinematic mechanism for adjusting the preload of at least one chain tensioning spring comprises a rotary body with which said chain tensioning spring engages at a first end thereof so that a rotation of said rotary body determines a variation in preload of said chain tensioning spring, a toothed sector formed on said rotary body and at least one pinion engaged with said toothed sector to transfer a controlled rotation to it, said pinion being directly or indirectly set in rotation by said gearshift actuation means. 4. Bicycle gearshift according to claim 3 , wherein the first and the second attachment group comprise: a support body, intended for attachment to the frame of the bicycle or to the chain guide, said chain tensioning spring being constrained at a second end thereof to said support body, said rotary body with said toothed sector being associated with one from the first and the second attachment group, free to rotate with respect to said support body. 5. Bicycle gearshift according to claim 2 , wherein said kinematic mechanism for adjusting the preload adjusts the preload of said first chain tensioning spring. 6. Bicycle gearshift according to claim 2 , wherein said kinematic mechanism for adjusting the preload adjusts the preload of said second chain tensioning spring. 7. Bicycle gearshift according to claim 3 , wherein said pinion is mounted in a fixedly connected manner on a pin element of said four pin elements, said pin element being fixedly connected to one of said connecting rods. 8. Bicycle gearshift according to claim 3 , wherein said pinion is mounted in a fixedly connected manner on an actuation pin substantially parallel to said pin elements, said actuation pin being set in rotation by said gearshift actuation means. 9. Bicycle gearshift according to claim 1 , wherein said gearshift actuation means are of the mechanical type and comprise: a sheath seat for supporting a control cable comprising an outer sheath relative to which an inner cable core is free to slide, said sheath seat fixing said outer sheath in position in order to allow said inner core to slide; a retaining clip of an end of said inner core, said sheath seat and said clip being arranged substantially at pin elements that are diagonally opposite in said four-bar linkage-kinematic mechanism; a return spring arranged at one of said pin elements, to deform said four-bar linkage-kinematic mechanism in contrast to the traction imposed by a relative translation between said outer sheath and said inner core of said control cable. 10. Bicycle gearshift according to claim 1 , wherein said gearshift actuation means are of the motorised type and comprise a motor that drives the displacement of a shaft along a diagonal of said four-bar linkage-kinematic mechanism. 11. Bicycle gearshift according to claim 10 , wherein said motor is supported inside said four-bar linkage-kinematic mechanism through a support shell constrained in a tilting manner at a first pin element of said four pin elements, said shaft acting on a pin element of said four pin elements opposite said first pin element. 12. Bicycle gearshift according to claim 8 , wherein said gearshift actuation means are of the motorised type and comprise a motor that drives the displacement of a shaft along a diagonal of said four-bar linkage-kinematic mechanism, and said motor has an outlet axis perpendicular to said shaft, said motor commanding a rotation of said actuation pin, said actuation pin carrying a toothed spindle rotating as a unit with it in shape coupling with a rack formed on said shaft in order to determine a displacement in translation of said shaft. 13. Bicycle gearshift according to claim 12 , wherein said rack is guided in translation inside a tubular portion of un guide shell idly mounted on said actuation pin, said guide shell enclosing said toothed spindle in order to keep said shape coupling between said toothed spindle and said rack. 14. Bicycle gearshift according to claim 4 , wherein said first attachment group comprises a pair of clamping screws arranged coaxially so as to be able to slide one inside the other and a locking element that is able to rotate with respect to said clamping screws, said locking element being provided with a stop tooth suitable for limiting the rotation thereof with respect to said frame, said first chain tensioning spring engaging at said second end thereof in a hole of said locking element, said clamping screws and said locking element acting as said support body of said first chain tensioning spring. 15. Bicycle gearshift according to claim 4 , wherein said second attachment group comprises a fifth pin element connected, at a second end, in a fixedly connected manner to said chain guide and provided, at a first end, opposite the second end, with a connection interface to said mobile body, said fifth pin element acting as said support body of said second chain tensioning spring. 16. Bicycle gearshift according to claim 1 , wherein said kinematic mechanism for adjusting the preload of at least one chain tensioning spring comprises a rotary body with which said chain tensioning spring engages at a first end thereof so that a rotation of said rotary body determines a variation in preload of said chain tensioning spring, said rotary body being set in rotation by said gearshift actuation means.