Hydraulic transmission circuit

The invention claimed is: 1. A hydraulic transmission circuit comprising: at least first and second elementary hydraulic motors that are associated for providing a common drive, each elementary motor having a first and a second secondary enclosures, one for feed and one for discharge; at least two main ducts respectively for fluid feed and for fluid discharge; a fluid distributor for distributing the fluid from said main ducts to said elementary motors via their secondary enclosures; and a control system for controlling the elementary motors; wherein: each of the at least first and second elementary hydraulic motors is either a hydraulic motor or a sub-motor of a hydraulic motor with the sub-motor being a portion of the hydraulic motor, that is capable, when it is fed on its own, of supplying non-zero drive torque to an outlet member of the hydraulic motor, and of doing so regardless of an angular position of said outlet member relative to a stator structure of the hydraulic motor; the fluid distributor has valve means connected to the two secondary enclosures of the first elementary motor; said valve means are configured to put the first secondary enclosure of the first elementary motor into communication with either one of the two main ducts, independently of the second secondary enclosure, and to put the second secondary enclosure of the first elementary motor into communication with either one of the two main ducts, independently of the first secondary enclosure, whereby the first elementary motor can be put, independently of the operating modes of the other elementary motor(s): in inactive operating mode, in which both secondary enclosures of the first elementary motor are connected to a same main duct; in drive operating mode, in which the two secondary enclosures of the first elementary motor are connected respectively to the higher pressure main duct and to the lower pressure main duct so that the first elementary motor delivers a drive torque in a desired drive direction that adds to a torque delivered by the other elementary motor(s); and in opposing operating mode, in which the two secondary enclosures of the first elementary motor are connected respectively to the higher pressure main duct and to the lower pressure main duct so that the first elementary motor delivers an opposing torque in a direction opposite from the desired drive direction, which subtracts from the torque delivered by the other elementary motor(s); and said valve means are configured so that the first elementary motor can be put, independently of the operating modes of the other elementary motor(s): in high-pressure inactive operating mode, in which both secondary enclosures of the first elementary motor are connected to a higher pressure main duct having a higher pressure than the other main duct; and in low-pressure inactive operating mode, in which both secondary enclosures of the first elementary motor are connected to a lower pressure main duct having a lower pressure than the other main duct. 2. A circuit according to claim 1 , wherein the control system includes an activation table that specifies and makes it possible to determine the operating modes of the various elementary motors as a function of a desired cylinder capacity, each operating mode being chosen from among the drive operating mode, the opposing operating mode, and the inactive operating mode. 3. A circuit according to claim 1 , wherein the control system is suitable for automatically effecting a plurality of cylinder capacity changes in a predefined order, as a function at least of a speed of rotation of the motor and of a speed or acceleration setpoint transmitted to the control system. 4. A circuit according to claim 1 , wherein the valve means has at least two first distribution valves, one first distribution valve is connected to one of the two secondary enclosures of the first elementary motor, a second first distribution valve is connected to the other of the two secondary enclosures of the first elementary motor, each first distribution valve being suitable for putting the secondary enclosure to which it is connected into communication with one or the other of the main ducts independently of the other first distribution valve. 5. A circuit according to claim 4 , wherein the secondary enclosures of at least two of the other elementary motors are interconnected and suitable for being connected to the main ducts via a single common distribution valve. 6. A circuit according to claim 4 , wherein said first distribution valves are incorporated into a casing of the first elementary motor. 7. A circuit according to claim 1 , wherein said first and second elementary motors are sub-motors of the same motor, and are secured to a common outlet member. 8. A circuit according to claim 1 , the first and second elementary motors drive respective ones of two distinct outlet members. 9. A circuit according to claim 1 , wherein the first elementary motor has a cylinder capacity that is different from the cylinder capacity of another elementary motor. 10. A circuit according to claim 1 , wherein each elementary motor has exactly said two secondary enclosures, one for feed and one for discharge. 11. A circuit according to claim 1 , wherein the elementary motors are constant-velocity motors. 12. A circuit according to claim 1 , wherein the fluid distributor has, for at least one elementary motor, inactivation means capable of deactivating said elementary motor by connecting said elementary motor in a continuous manner to the main duct having either a lower pressure or a higher pressure. 13. A circuit according to claim 12 , wherein the elementary motors are sub-motors of the same motor, and the inactivation means are configured to detect the direction of rotation of the motor, said chosen pressure being selected as a function of the direction of rotation of the motor and of the direction of a speed command or of an acceleration command that is applied to the motor. 14. A circuit according to claim 1 , further comprising a pump for exchanging feed and discharge fluid with said at least first and second elementary hydraulic motors through said at least two main ducts, wherein the control system is suitable for operating the valve means, in such a manner as to reverse the direction of rotation of an outlet member of the at least first and second elementary motors without reversing the direction of the flow of fluid driven by the pump. 15. A circuit according to claim 1 , further comprising a pump for exchanging feed and discharge fluid with said at least first and second elementary hydraulic motors through said at least two main ducts, wherein the control system is suitable for operating the valve means in such a manner as to maintain the direction of rotation of an outlet member of the at least first and second elementary motors constant, during a reversal of input and output directions of the flow of fluid driven by the pump. 16. A circuit according to claim 1 , wherein the valve means are also connected to the two secondary enclosures of at least one other elementary motor, said valve means being suitable for putting each of the secondary enclosures of said at least one other elementary motor into communication with either one or the other of the main ducts, independently of the other secondary enclosures. 17. A circuit according to claim 1 , wherein: at least one first elementary motor is coupled to a first movement member for moving a vehicle; and at least one second elementary motor is coupled to a second movement member fo