Servo valve assembly

The invention claimed is: 1. A servo valve assembly, comprising: a first nozzle opposing a second nozzle, wherein the first and second nozzles are spaced apart by a gap and each nozzle has an outlet opening; and a shaft positioned in the gap between the first and second nozzles, wherein: the shaft defines a diameter (D) and a circumferential surface and is rotatable about an axis of rotation (R-R); the shaft defines first and second reduced radial portions around its circumferential surface, and the first and second reduced radial portions are in fluid communication with the first and second nozzle outlet openings, respectively; the shaft is configured to rotate between a first position where the first nozzle outlet opening is more occluded by the shaft circumferential surface than the second nozzle outlet opening, and a second position where the first nozzle outlet opening is less occluded by the shaft circumferential surface than the second nozzle outlet opening; wherein the first and second reduced radial portions each comprise a groove in the circumferential surface of the shaft; and wherein the first and second reduced radial portions each comprise a curved surface of continuously decreasing radius that terminates at the groove. 2. The servo valve assembly of claim 1 , wherein the axis of rotation (R-R) is perpendicular to a central axis (N-N) of each nozzle outlet opening. 3. The servo valve assembly of claim 1 , wherein: in the first position, the first nozzle outlet opening is fully occluded by the shaft circumferential surface such that the first reduced radial portion is prevented from being in fluid communication therewith, and the second nozzle outlet opening is fully open such that none of the second nozzle outlet opening is occluded by the shaft circumferential surface; and in the second position, the second nozzle outlet opening is fully occluded by the shaft circumferential surface such that the second reduced radial portion is prevented from being in fluid communication therewith, and the first nozzle outlet opening is fully open such that none of the first nozzle outlet opening is occluded by the shaft circumferential surface. 4. The servo valve assembly of claim 1 , further comprising a biasing member configured to provide a biasing force that opposes rotation of the shaft towards a third position where the first nozzle outlet opening and the second nozzle outlet opening are equally occluded by the shaft circumferential surface. 5. The servo valve assembly of claim 4 , wherein the shaft further comprises a slot extending along its diameter (D), and the biasing member is received in the slot to apply the biasing force to the shaft. 6. The servo valve assembly of claim 5 , wherein the biasing member comprises a pair of S-shaped springs that are fixed in the slot. 7. The servo valve assembly of claim 1 , further comprising a coil arranged around at least a portion of the shaft, wherein when the coil is energized the shaft is caused to rotate. 8. The servo valve assembly of claim 7 , wherein the shaft further comprises a driving member extending perpendicular to the axis of rotation (R-R). 9. The servo valve assembly of claim 8 , wherein the driving member includes a permanent magnet attached thereto to interact with the coil. 10. The servo valve assembly of claim 7 , wherein the coil comprises a pair of coils on opposite sides across the diameter (D) of the shaft. 11. A method of controlling the servo valve assembly of claim 7 , the method comprising: applying an electric current to the coil to generate an electromagnetic force that rotates the shaft about the axis of rotation (R-R) in a first rotational direction towards the first position; reversing the polarity of the electric current; and applying the reversed polarity electric current to the coil to generate an electromagnetic force that rotates the shaft about the axis of rotation (R-R) in a second rotational direction opposite the first rotational direction towards the second position. 12. A servo valve assembly, comprising: a first nozzle opposing a second nozzle, wherein the first and second nozzles are spaced apart by a gap and each nozzle has an outlet opening; a shaft positioned in the gap between the first and second nozzles, wherein: the shaft defines a diameter (D) and a circumferential surface and is rotatable about an axis of rotation (R-R); the shaft defines first and second reduced radial portions around its circumferential surface, and the first and second reduced radial portions are in fluid communication with the first and second nozzle outlet openings, respectively; and the shaft is configured to rotate between a first position where the first nozzle outlet opening is more occluded by the shaft circumferential surface than the second nozzle outlet opening, and a second position where the first nozzle outlet opening is less occluded by the shaft circumferential surface than the second nozzle outlet opening; and a biasing member configured to provide a biasing force that opposes rotation of the shaft towards a third position where the first nozzle outlet opening and the second nozzle outlet opening are equally occluded by the shaft circumferential surface; wherein the shaft further comprises a slot extending along its diameter (D), and the biasing member is received in the slot to apply the biasing force to the shaft; wherein the biasing member comprises a pair of S-shaped springs that are fixed in the slot.