Hydraulic actuator and multi-cylinder hydraulic actuator system

The invention claimed is: 1. An aircraft actuator system comprising: an aircraft flight control surface; and a multi-cylinder hydraulic actuator system for actuation of the aircraft flight control surface comprising multiple hydraulic actuators, with each of the multiple hydraulic actuators being linked with others of the multiple hydraulic actuators via a simultaneous transmission line, each of the multiple hydraulic actuators comprising: a hydraulic cylinder; a piston within the hydraulic cylinder and movable in response to movement of hydraulic fluid in a hydraulic circuit coupled to the hydraulic cylinder; a synchronisation connection that is joined to or integral with the simultaneous transmission line and is for receiving an input from the simultaneous transmission line; and a valve for controlling the flow of hydraulic fluid in the hydraulic circuit; wherein the valve is a rotary valve comprising: a first valve section arranged to rotate in either a first rotational direction or a second rotational direction in response to input from the simultaneous transmission line in order to open a hydraulic flow path to the cylinder and urge the piston to move along the hydraulic cylinder in a corresponding first linear direction or second linear direction; and a second valve section arranged to rotate in either the first rotational direction or the second rotational direction; wherein the second valve section is coupled to the piston such that movement of the piston results in movement of the second valve section to follow the first valve section and to close the hydraulic flow path when the rotation of the first valve section is stopped; and wherein the rotary valve includes a resilient biasing mechanism between the first valve section and the second valve section, wherein the resilient biasing mechanism provides a torque acting to bias the relative position of the first valve section and the second valve section to a closed position. 2. The aircraft actuator system as claimed in claim 1 , wherein the synchronisation connection is for receiving a rotational input from the simultaneous transmission line in order to rotate the first valve section to move the first valve section in the first rotational direction or the second rotational direction as required. 3. The aircraft actuator system as claimed in claim 1 , wherein the resilient biasing mechanism comprises a torsion bar arranged to apply a torque to react against rotational forces applied via the first valve section and/or the second valve section, wherein the torsion bar is pre-stressed in order to apply a torque to urge the valve sections toward the closed position. 4. The aircraft actuator system as claimed in claim 3 , wherein the first valve section and the second valve section are arranged concentrically and the torsion bar is placed at the centre of the concentric arrangement, inside an inner valve section of the two valve sections. 5. The aircraft actuator system as claimed in claim 4 , wherein the inner valve section is the first valve section that rotates in response to the input from the simultaneous transmission line and an outer valve section in the concentric arrangement is hence the second valve section that is coupled to the piston and rotates due to movement of the piston. 6. The aircraft actuator system as claimed in claim 4 , wherein the torsion bar is held within the two concentric valve sections via pins extending through slots provided in each of the valve sections. 7. The aircraft actuator system as claimed in claim 6 , wherein the pins comprise a first pin or first set of pins connected to a first end of the torsion bar and extending through first slots in the valve sections and a second pin or second set of pins connected to a second end of the torsion bar and extending through second slots in the valve sections; wherein the slots extend around a part of the circumference of the valve sections in order to allow for relative rotational movement of the valve sections in accordance with the extent of the slots. 8. The aircraft actuator system as claimed in claim 6 , wherein the rotary valve is arranged such that the rotary valve is closed when slots of the first valve section and the second valve section are aligned. 9. The aircraft actuator system as claimed in claim 1 , wherein the second valve section is coupled to the piston by a coupling that includes a screw shaft that rotates with movement of the piston and a nut connected with the piston and held on a thread of the screw shaft. 10. The aircraft actuator system as claimed in claim 9 , wherein the screw shaft is joined to the second valve section via gears. 11. A method for controlling an aircraft actuator system comprising an aircraft flight control surface and a multi-cylinder hydraulic actuator system for actuation of the aircraft flight control surface comprising multiple hydraulic actuators, each of the multiple hydraulic actuators being linked to others of the multiple hydraulic actuators via a simultaneous transmission line, each of the multiple hydraulic actuators comprising: a hydraulic cylinder; a piston within the hydraulic cylinder and movable in response to movement of hydraulic fluid in a hydraulic circuit coupled to the hydraulic cylinder; a synchronisation connection that is joined to or integral with the simultaneous transmission line and is for receiving an input from the simultaneous transmission line; and a valve for controlling the flow of hydraulic fluid in the hydraulic circuit; wherein the valve is a rotary valve comprising a first valve section and a second valve section wherein the rotary valve includes a resilient biasing mechanism between the first valve section and the second valve section, wherein the resilient biasing mechanism provides a torque acting to bias the relative position of the first valve section and the second valve section to a closed position; wherein the method comprises: rotating the first valve section in either a first rotational direction or a second rotational direction in response to input from the simultaneous transmission line in order to open a hydraulic flow path to the cylinder and urge the piston to move along the hydraulic cylinder in a corresponding first linear direction or second linear direction; and rotating the second valve section in the same rotational direction as the first valve section via a coupling between the second valve section and the piston, such that movement of the piston results in movement of the second valve section to follow the first valve section and to close the hydraulic flow path when the rotation of the first valve section is stopped.