Pressure-balance valve for balancing fluid feed to actuator cylinders of a servo-control for controlling rotor blades of a rotorcraft

What is claimed is: 1. A pressure-balance valve for balancing the pressures of different fluids flowing respectively in a plurality of double-acting actuator cylinders of at least one servo-control suitable for driving a member for varying flight attitude of an aircraft, the valve including a valve cylinder comprising at least: a chamber for guiding a piston to move in translation along an axial extension direction of the chamber; two first ducts opening out into the chamber and each serving to convey a flow of a respective fluid between the outside and the inside of the valve; two second ducts opening out into the chamber and each serving to convey a flow of a respective fluid between the outside and the inside of the valve; two passages, each passage for individually conveying a flow of a respective fluid into the inside of the valve between one of the first ducts and an accompanying one of the second ducts; and at least one bleed duct for the draining fluids admitted into the inside of the chamber; wherein the pressure-balance valve has two fluid flow paths, each fluid flow path for conveying a respective fluid, each fluid flow path including a respective one of the first ducts, one of the passages, and one of the second ducts placed mutually in fluid flow communication; wherein for each of the fluid flow paths, the first duct is provided at its outlet to the chamber with a movable shutter that co-operates with a respective ramp formed on the piston, sliding of the shutter along the ramp caused under the effect of the piston moving in translation inside the chamber disengaging the shutter from the outlet of the first duct and consequently placing the first and second ducts in fluid flow communication with each other via the passage, the first duct and the second duct in fluid flow communication with each other delivering additional fluid through the passage from the first duct to the second duct. 2. A pressure-balance valve according to claim 1 , wherein for each of the fluid flow paths, the passage is formed by an axial end segment of the chamber into which the first and second ducts open out. 3. A pressure-balance valve according to claim 1 , wherein: the valve cylinder is subdivided into two valve cylinder blocks that are axially assembled together, the blocks providing the respective fluid flow paths by including respective chamber segments on a common axis; and the piston is subdivided into two structurally distinct piston segments, the piston segments being housed respectively in the chamber segments and bearing axially one against the other. 4. A pressure-balance valve according to claim 1 , wherein the at least one bleed duct is arranged as a drain isolated from the fluid flow paths by seals interposed between the piston and the chamber, the bleed duct collecting lost fluid and discharging it from the valve, which lost fluid comes from any residue of respective fluids in at least one of the two fluid flow paths that has infiltrated past the seals. 5. A pressure-balance valve according to claim 4 , wherein the bleed duct is common to collecting and discharging lost fluid coming from respective fluids in at least one of the two fluid flow paths. 6. A pressure-balance valve according to claim 4 , wherein the seals comprise gaskets interposed axially between the bleed duct and respective axial ends of the chamber. 7. A pressure-balance valve according to claim 4 , further comprising a warning device for giving a warning concerning malfunctioning of the valve by evaluating the quantity of lost fluid discharged from the bleed duct. 8. A pressure-balance valve according to claim 1 , wherein the valve is configured to hydraulically damp the movement of the piston inside the chamber. 9. A pressure-balance valve according to claim 1 , wherein the valve has hydraulic damper means for damping the movement of the piston inside the chamber, wherein the hydraulic damper means are formed by blind sockets opening out into respective end walls of the axial ends of the chamber and co-operating with respective axial extensions of the piston, the sockets respectively receiving the extensions as a result of the piston moving axially inside the chamber, clearance being arranged respectively between each socket and the extension co-operating therewith to leave controlled discharge channels for discharging the fluids from the sockets to the chamber. 10. A pressure-balance valve according to claim 1 , wherein when the piston is in a stabilized axial position inside the chamber under the effect of balanced thrusts exerted on the axial end faces of the piston by each of the fluids respectively, axial gaps are left between the shutters and the respective ramps with which the shutters co-operate. 11. A pressure-balance valve according to claim 1 , wherein the valve is configured to brake the movement of the piston inside the chamber. 12. A pressure-balance valve according to claim 1 , wherein the valve includes braking means for braking the movement of the piston inside the chamber, wherein the braking means are formed by at least one of the following arrangements: the ramps having slopes at an angle relative to the extension axis of the piston lying in the range 5° to 60°; seals mounted so that they are a tight fit along the piston under the effect of the piston moving axially; and axial gaps are left between the shutters and the respective ramps with which the shutters co-operate. 13. A pressure-balance valve according to claim 1 , wherein the valve is provided with a detector for detecting the position of the piston inside the chamber, the detector generating a warning signal in the event of detecting an axial stroke of the piston greater than a predetermined acceptable stroke. 14. A pressure-balance valve according to claim 13 , wherein the detector generates a variation in the warning signal as a function of the axial position of the piston inside the chamber. 15. A pressure-balance valve according to claim 13 , wherein the detector is formed by at least one set of components that co-operate by exchange of waves, the set of components comprising at least a first component placed at an axial end of the piston that is associated therewith and a second component placed at the end of the chamber facing said any axial end of the piston. 16. A pressure-balance valve according to claim 15 , wherein said at least one first component may be placed equally well at either axial end face of the piston or on either of said extensions. 17. A pressure-balance valve according to claim 15 , wherein the detector is of the type that make use of the Hall effect, the first component and the second component being formed by magnets that generate between them a magnetic field that is crossed by a third component mounted on the cylinder of the valve and producing a voltage that generates said warning signal at a predefined setpoint voltage. 18. A pressure-balance valve according to claim 1 , wherein the shutters are bodies of revolution and wherein the ramps are arranged at respective ends of the piston. 19. A pressure-balance valve according to claim 1 , wherein each of the first ducts is provided with a perforated seat for retaining the shutter with which it is associated against the shutter escaping to the inside of the first duct under the effect of thrust exerted by the fluid present in the chamber at a pressure that is higher than the pressure of the fluid admitted into the first duct. 20. A pressure-balance valve according to claim 1 , wherein the