High gain servo valve

The invention claimed is: 1. A servo valve comprising: a movable throttling member disposed between a first opening and an opposing second opening; a first inlet port and a second inlet port to convey a fluid flow toward the first and second opening, respectively; a first inlet orifice disposed between and in fluid communication with the first inlet port and the first opening, the first inlet orifice defined between the first inlet port and a first pressure reaction member; and a second inlet orifice disposed between and in fluid communication with the second inlet port and the second opening, the second inlet orifice defined between the second inlet port and a second pressure reaction member, the second pressure reaction member secured to the first pressure reaction member at a substantially fixed distance; wherein each of the first inlet orifice and the second inlet orifice is variable via a change in a pressure of the fluid flow downstream of the first inlet orifice and the second inlet orifice, resulting in a change in pressure of a fluid urged downstream; wherein the first pressure reaction member and the second pressure reaction member are a first and second bellows. 2. The servo valve of each claim 1 , wherein each bellows of the first and second bellows includes: a fixed end secured in a bellows chamber; a bellows face disposed at the first or second inlet port to define the first or second inlet orifice; and a plurality of convolutions extending between the fixed end and the bellows face. 3. The servo valve of claim 2 , wherein the bellows face of the first bellows is connected to the bellows face of the second bellows via a tie rod. 4. The servo valve of claim 2 , wherein the first bellows and second bellows are fixed via a retainer and seal arrangement to prevent flow around the first bellows and second bellows. 5. The servo valve of claim 1 , further comprising: a valve spool; and the first spool line and the second spool line in fluid communication with the first inlet orifice and the second inlet orifice, respectively; wherein a difference in a first fluid pressure of a first spool line and a second fluid pressure of a second spool line urges movement of the valve spool. 6. The servo valve of claim 1 , wherein in the throttling member is a flapper rotatable about a flapper pivot. 7. The servo valve of claim 6 , wherein the movable flapper is in magnetic communication with a torque motor to urge movement of the flapper. 8. The servo valve of claim 1 , wherein at least one of the first opening and the second opening is a flapper nozzle. 9. A method of operating a servo valve comprising: urging a first fluid flow through a first inlet port at an inlet pressure; urging a second fluid flow through a second inlet port at the inlet pressure; directing the first fluid flow through a first variable inlet orifice defined by the first inlet port and a first pressure reaction member toward a first opening disposed at a first side of a throttling member; directing the second fluid flow through a second variable inlet orifice defined by the second inlet port and a second pressure reaction member toward a second opening disposed at an opposing side of the throttling member, the second pressure reaction member secured to the first pressure reaction member at a substantially fixed distance; and increasing a size of the first inlet orifice via a change in pressure of the fluid flow downstream of the first inlet orifice and the second inlet orifice, resulting in a change in pressure of the first fluid flow urged downstream; wherein the first pressure reaction member and the second pressure reaction member are a first bellows and a second bellows. 10. The method of claim 9 , wherein increasing a size of the first inlet orifice comprises compressing the first bellows via increased pressure at the first inlet orifice. 11. The method of claim 9 , wherein the first bellows and the second bellows are connected via a tie rod. 12. The method of claim 9 , wherein the throttling member is a movable flapper rotatable about a flapper pivot. 13. The method of claim 12 , further comprising: energizing an electrical coil in magnetic communication with the movable flapper; rotating the movable flapper about the flapper pivot in response to a magnetic field generated by energizing the coil; and decreasing a first opening gap between the flapper and the first opening via the rotation, thereby increasing the pressure downstream of the first inlet orifice. 14. A actuator system comprising: an actuator having an actuator piston; a valve spool in fluid communication with the actuator to urge movement of the actuator piston; and a servo valve in fluid communication with the valve spool including: a movable throttling member disposed between a first opening and an opposing second opening; a first inlet port and a second inlet port to convey a fluid flow toward the first and second opening, respectively; a first inlet orifice disposed between and in fluid communication with the first inlet port and the first opening, the first inlet orifice defined between the first inlet port and a first pressure reaction member; and a second inlet orifice disposed between and in fluid communication with the second inlet port and the second opening, the second inlet orifice defined between the second inlet port and a second pressure reaction member, the second pressure reaction member secured to the first pressure reaction member at a substantially fixed distance; wherein each of the first inlet orifice and the second inlet orifice is variable via a change in a pressure of the fluid flow downstream of the first inlet orifice and the second inlet orifice, resulting in a change in pressure of a fluid urged to the valve spool; wherein the first pressure reaction member and the second pressure reaction member are a first and second bellows. 15. The actuator system of each claim 14 , wherein each bellows of the first and second bellows includes: a fixed end secured in a bellows chamber; a bellows face disposed at the first or second inlet port to define the first or second inlet orifice; and a plurality of convolutions extending between the fixed end and the bellows face. 16. The actuator system of claim 15 , wherein the first bellows and second bellows are fixed via a retainer and seal arrangement to prevent flow around the first bellows and second bellows. 17. The actuator system of claim 14 , wherein at least one of the first opening and the second opening is a flapper nozzle.