Pneumatic servo valve with adjustable metering members

The invention claimed is: 1. A servo valve comprising: a housing; a sleeve provided within the housing having a plurality of metering holes for communication with a cavity within; and a metering rod provided with metering members on a central rod for metering flow into and out of the cavity through the metering holes, wherein the metering members comprise annular elements which are located axially on the central rod by an interference fit; wherein the annular elements providing the metering members comprise flats or other forms of recess in a perimeter thereof to allow pneumatic fluid to pass from one side of each of the metering members to the other; and wherein the metering rod is suspended within the cavity by a pair of spring seals spaced axially either side of the metering members, the spring seals being sealingly engaged with the metering rod to seal off the cavity. 2. A servo valve as claimed in claim 1 , wherein the metering rod comprises at least a first metering member and a second metering member, and the sleeve comprises at least a first metering hole in communication with a pressure supply port in the housing and at least a second metering hole in communication with an exhaust port in the housing, the first and second metering holes being opened and closed through sealing engagement of the first and second metering members respectively. 3. A servo valve as claimed in claim 2 , wherein the sleeve comprises a pair of first metering holes and a pair of second metering holes, each metering hole being arranged opposite the other of the pair. 4. A servo valve as claimed in claim 3 , wherein the sleeve further includes a hole for communication with a control pressure port in the housing. 5. A servo valve as claimed in claim 2 , wherein the metering rod reciprocates along an axis within the cavity of the servo valve, and the metering members are arranged such that at least one metering hole is being opened while another metering hole is being closed off. 6. A servo valve as claimed in claim 1 , wherein the metering members have substantially the same dimensions. 7. A servo valve as claimed in claim 1 , wherein the metering members have an elongate, stadium-like cross section in an axial direction, each metering member having two opposed flat surfaces following opposed chords of an otherwise circular perimeter. 8. A servo valve as claimed in claim 1 , wherein the servo valve comprises a drive unit to reciprocate the metering rod along the axis. 9. A servo valve as claimed in claim 8 , wherein the drive unit is a direct single solenoid drive. 10. A servo valve as claimed in claim 9 , wherein the servo valve is a three way single stage pneumatic servo valve. 11. A servo valve as claimed in claim 8 , wherein the servo valve is a three way single stage pneumatic servo valve. 12. An air management system comprising an actuator and a servo valve as claimed in claim 1 . 13. A method of making a servo valve comprising: forming a housing; forming a sleeve for location within the housing, the sleeve comprising an axis, an inner surface defining a cavity for the servo valve and a plurality of metering holes for communication with the cavity; and assembling a metering rod which comprises metering members positioned along a central rod for metering flow into and out of the cavity through the metering holes, wherein the metering members comprise annular elements that are slid into position along the central rod and held axially by an interference fit; wherein the annular elements providing the metering members comprise flats or other forms of recess in a perimeter thereof to allow pneumatic fluid to pass from one side of each of the metering members to the other; and wherein the metering rod is suspended within the cavity by a pair of spring seals spaced axially either side of the metering members, the spring seals being sealingly engaged with the metering rod to seal off the cavity. 14. A method of making a servo valve as claimed in claim 13 , wherein the method includes a calibration step where an axial position of one or more of the metering members is adjusted to calibrate the servo valve. 15. A method as claimed in claim 14 , wherein the axial position of the one or more metering members is adjusted through applying mechanical force on the metering member to displace it axially along the central rod, and the axial position of the one or more metering members is adjusted through using heat to thermally expand the metering member relative to the central rod to release the hold of the friction fit, allowing the metering member to be repositioned. 16. A method as claimed in claim 14 , wherein the axial position of the one or more metering members is adjusted through using heat to thermally expand the metering member relative to the central rod to release the hold of the friction fit, allowing the metering member to be repositioned. 17. A method as claimed in claim 14 , wherein during calibration of the servo valve, the metering members are positioned along the metering rod such that a surface of the first metering member closest to a first end of the sleeve and a surface of the metering member closest to a second end are separated by a distance equal to a separation between a mid-point of a first at least one metering hole along the axis and a mid-point of a second at least one metering hole along the axis, and/or such that a distance between a surface of the first metering member closest to a first end of the sleeve and a surface of the metering member closest to a second end is equal to a length of a land extending axially along an inner surface of the sleeve between a first metering hole and a second metering hole plus an axial dimension of the metering holes. 18. A method as claimed in claim 13 , wherein the metering members slide over to occlude and reveal the metering holes, to prevent and allow communication with a supply pressure port and an exhaust pressure port in the housing, wherein the metering members have perpendicular planar faces and the metering holes comprise circumferentially extending slots with planar edges so that the revealed area of the metering holes increases and decreases linearly with reciprocation of the metering rod within the cavity.