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A rotary pressure production turbine for pressurizing a hydraulic fluid is disclosed comprising a plurality of piston assemblies. Each piston assembly comprises a hollow needle piston shaft having through which hydraulic fluid is moved from a low pressure volume to a high pressure volume as the pist

A rotary pressure production turbine for pressurizing a hydraulic fluid is disclosed comprising a plurality of piston assemblies. Each piston assembly comprises a hollow needle piston shaft having through which hydraulic fluid is moved from a low pressure volume to a high pressure volume as the piston shaft moves in a first direction. A rotary actuator actuates each piston shaft. From the high pressure volume, hydraulic fluid is moved to a common high pressure header and delivered to an aspirated accumulator where the fluid can be stored and subsequently utilized. In some embodiments, the fluid is utilized to operate an electric generator for use in a hybrid-electric vehicle. In some embodiments, the rotary actuator is driven by an internal combustion engine, while in others the rotary actuator is driven by a vehicle drive train in a regenerative braking application.

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1. A pressure production system for pressurizing a hydraulic fluid, the system comprising a rotary pressure production device comprising: (a) a plurality of piston assemblies, each comprising:i. a hollow needle piston shaft through which hydraulic fluid is moved from a low pressure volume to a high

1. A pressure production system for pressurizing a hydraulic fluid, the system comprising a rotary pressure production device comprising: (a) a plurality of piston assemblies, each comprising:i. a hollow needle piston shaft through which hydraulic fluid is moved from a low pressure volume to a high pressure volume as the piston shaft moves in a first direction;ii. a high pressure header in fluid communication with the high pressure volume;iii. a vacuum check valve in fluid communication with the low and high pressure volumes, the vacuum check valve being closed as the hollow needle piston shaft moves in the first direction and open as the hollow needle piston shaft moves in a second, opposite direction;(b) a rotary actuator constructed and arranged to move each hollow needle piston shaft in the first direction;(c) a discharge check valve in fluid communication with the high pressure volume and the high pressure header, the discharge check valve being open when the hollow needle piston shaft is moving in the first direction, and when fluid pressure in the high pressure volume exceeds fluid pressure in the high pressure header, the discharge check valve being closed when the hollow needle piston shaft is moving in the second direction;(d) a first aspirated accumulator including:i. a spherical shell;ii. a diaphragm operably positioned within the spherical shell defining a gas volume and a hydraulic fluid volume, the hydraulic fluid volume being in fluid communication with the high pressure header;iii. a compressed gas within the gas volume;iv. a compressed gas conduit winding in fluid communication with the gas volume, the gas conduit winding being wound about the spherical shell;v. a gas compressor to deliver compressed gas to the gas volume via the gas conduit winding. 2. The pressure production system of claim 1, further comprising a concentrator in fluid communication with the gas volume. 3. The pressure production system of claim 1, further comprising at least one check valve to prevent the diaphragm from rupturing. 4. The pressure production system of claim 3, wherein one check valve is operably positioned within the hydraulic fluid volume and one check valve is operably positioned within the gas volume. 5. The pressure production system of claim 1, further comprising a second aspirated accumulator piped in parallel arrangement with the first aspirated accumulator, the second aspirated accumulator including: (a) a spherical shell;(b) a diaphragm operably positioned within the spherical shell defining a gas volume and a hydraulic fluid volume, the hydraulic fluid volume being in fluid communication with the high pressure header;(c) a compressed gas within the gas volume;(d) a compressed gas conduit winding in fluid communication with the gas volume, the gas conduit winding being wound about the spherical shell; and(e) a gas compressor to deliver compressed gas to the gas volume via the gas conduit winding. 6. The pressure production system of claim 5, further comprising at least one check valve to prevent the diaphragms of the first and second aspirated accumulators from rupturing. 7. The pressure production system of claim 5, wherein one check valve is operably positioned within the hydraulic fluid volume and one check valve is operably positioned within the gas volume of the first and second aspirated accumulators. 8. The pressure production system of claim 1 wherein fluid pressure in the first accumulator is maintained at no less than 2,000 psi. 9. The pressure production system of claim 5 wherein fluid pressure in the first and second accumulators is maintained at no less than 2,000 psi. 10. The pressure production system of claim 1, further comprising an electric generator configured and arranged to be driven by the hydraulic fluid stored in the first aspirated accumulator. 11. The pressure production system of claim 5, further comprising an electric generator configured and arranged to be driven by the hydraulic fluid stored in the first and second aspirated accumulator. 12. The pressure production system of claim 1, wherein the rotary actuator is driven by an internal combustion engine. 13. The pressure production system of claim 5, wherein the rotary actuator is driven by an internal combustion engine. 14. The pressure production system of claim 1, wherein the rotary actuator is driven by a vehicle drive train in a regenerative braking application. 15. The pressure production system of claim 5, wherein the rotary actuator is driven by a vehicle drive train in a regenerative braking application. 16. A method for pressurizing hydraulic fluid, the method comprising the steps of: (a) drawing hydraulic fluid from a low pressure volume into a hollow needle piston shaft;(b) using a rotary actuator to move moving the hollow needle piston shaft and the hydraulic fluid within the hollow needle piston shaft in a first direction and into a high pressure volume;(c) closing fluid communication between the high pressure volume and the low pressure volume;(d) compressing the hydraulic fluid in the high pressure volume with the hydraulic fluid in the hollow needle piston such that the fluid is moved into a common high pressure header, the high pressure header being in fluid communication with the high pressure volume and with a hydraulic fluid volume of an aspirated accumulator, the aspirated accumulator having a spherical shell, the spherical shell containing a gas volume separated from the hydraulic fluid volume by a diaphragm, the gas volume receiving compressed gas from a compressed gas conduit winding, the compressed gas conduit winding being wound around the spherical shell;(e) moving the hollow needle piston shaft in a second direction opposite the first direction; and(f) closing fluid communication between the high pressure volume and the high pressure header. 17. The method for pressurizing hydraulic fluid of claim 16, wherein the steps are repeated continuously. 18. The method for pressurizing hydraulic fluid of claim 16, wherein a plurality of hollow needle piston shafts repeat the steps of claim 18 continuously. 19. The method of pressurizing hydraulic fluid of claim 18, wherein some of the hollow needle piston shafts compress the hydraulic fluid at different times than other hollow needle piston shafts.