A supersonic compressor including a rotor to deliver a gas at supersonic conditions to a diffuser. The diffuser includes a plurality of aerodynamic ducts that have converging and diverging portions, for deceleration of gas to subsonic conditions and then for expansion of subsonic gas, to change kine
A supersonic compressor including a rotor to deliver a gas at supersonic conditions to a diffuser. The diffuser includes a plurality of aerodynamic ducts that have converging and diverging portions, for deceleration of gas to subsonic conditions and then for expansion of subsonic gas, to change kinetic energy of the gas to static pressure. The aerodynamic ducts include vortex generating structures for controlling boundary layer, and structures for changing the effective contraction ratio to enable starting even when the aerodynamic ducts are designed for high pressure ratios, and structures for boundary layer control. In an embodiment, aerodynamic ducts are provided having an aspect ratio of in excess of two to one, when viewed in cross-section orthogonal to flow direction at an entrance to the aerodynamic duct.
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1. A compressor, comprising: a rotor having an axis of rotation and a plurality of blades extending into a gas flow passage, said plurality of blades sized and shaped to act on a selected gas to provide a supersonic gas flow; anda stator comprising a diffuser disposed around a longitudinal axis and
1. A compressor, comprising: a rotor having an axis of rotation and a plurality of blades extending into a gas flow passage, said plurality of blades sized and shaped to act on a selected gas to provide a supersonic gas flow; anda stator comprising a diffuser disposed around a longitudinal axis and comprising one or more aerodynamic ducts, wherein said one or more of said aerodynamic ducts are helically arranged at a substantially constant helical angle about said longitudinal axis, said one or more aerodynamic ducts having an effective contraction ratio and comprising a converging portion and a diverging portion, said one or more aerodynamic ducts sized and shaped to decelerate said supersonic gas flow to subsonic conditions from a selected inlet Mach number, said diffuser comprising (a) geometrically adjustable portions operable to adjust said effective contraction ratio; and(b) boundary layer control structures comprising one or more vortex generators, said one or more vortex generators each comprising a base with a forward end and a leading edge extending outward and rearward from said forward end to an outward end, and wherein said leading edge comprises a first angular discontinuity at a height H1 above said base, and a second angular discontinuity at a height H2 above said base, for generating at least two (2) vortices. 2. The compressor as set forth in claim 1, wherein said leading edge comprises a first angular discontinuity at a height H1 above said base, a second angular discontinuity at a height H2 above said base, and a third angular discontinuity at a height H3 above said base, for generating at least three (3) vortices. 3. The compressor as set forth in claim 2, wherein height H2 is about 1.6 times the result of height H3 minus height H2. 4. The compressor as set forth in claim 1, wherein height H1 is about 1.6 times the result of height H2 minus height H1. 5. The compressor as set forth in claim 1, wherein a plurality of vortex generators are provided in each of said aerodynamic ducts. 6. The compressor as set forth in claim 1, wherein one or more of said one or more aerodynamic ducts are helically arranged about said longitudinal axis. 7. The compressor as set forth in claim 1, wherein said diffuser comprises a stationary diffuser. 8. The compressor as set forth in claim 1, wherein said one or more vortex generators are located in said converging portion. 9. The compressor as set forth in claim 1, wherein said one or more vortex generators are located in said diverging portion. 10. The compressor as set forth in claim 1, further comprising outlet bleed ports for boundary layer removal, and bleed sub-chambers adjacent said one or more aerodynamic ducts, said bleed sub-chambers in fluid communication with said outlet bleed ports, said bleed sub-chambers configured for passage therethrough of said selected gas removed through said outlet bleed ports. 11. The compressor as set forth in claim 10, wherein said rotor further comprises a shroud for said plurality of blades. 12. The compressor as set forth in claim 1, wherein said rotor comprises a plurality of impulse blades. 13. The compressor as set forth in claim 1, wherein said rotor is effectively sealed with said diffuser, so as to minimize gas leakage during flow therebetween. 14. The compressor as set forth in claim 12, wherein said selected gas passing through said rotor is turned by an angle alpha (α) of at least ninety (90) degrees. 15. The compressor as set forth in claim 12, wherein said selected gas passing through said rotor is turned by an angle alpha (α) of at least one hundred (100) degrees. 16. The compressor as set forth in claim 12, wherein said selected gas passing through said rotor is turned by an angle alpha (α) of at least one hundred ten (110) degrees. 17. The compressor as set forth in claim 12, wherein said selected gas passing through said rotor is turned by an angle alpha (α) of between ninety (90) degrees and one hundred sixty (160) degrees. 18. The compressor as set forth in claim 12, wherein said selected gas passing through said rotor is turned by an angle alpha (α) of between one hundred twelve (112) degrees and one hundred fourteen (114) degrees. 19. The compressor as set forth in claim 1, wherein each of said plurality of blades has a hub end, a tip end, and a trailing edge, and said supersonic gas flow is provided at said trailing edge of each of said plurality of blades from said hub end to said tip end. 20. The compressor as set forth in claim 1, wherein said diffuser further comprises bypass gas passageways positionable between an open, startup condition wherein discharge gas is passed therethrough, and a closed, operating condition which minimizes or stops passage of said discharge gas therethrough. 21. The compressor as set forth in claim 20, wherein said bypass gas passageways comprise external passageways fluidly connected with said one or more aerodynamic ducts. 22. The compressor as set forth in claim 1, wherein said geometrically adjustable portions are positionable between an open, startup condition wherein said converging portion allows sufficient flow of said selected gas through said one or more aerodynamic ducts to establish and position a normal shock within said one or more aerodynamic ducts, and a closed, operating condition in which said converging portion is set to a selected operating position. 23. The compressor as set forth in claim 1, wherein said geometrically adjustable portions, by change in position, change the contraction ratio of one or more of said one or more aerodynamic ducts. 24. The compressor as set forth in claim 23, wherein said geometrically adjustable portions further comprise pivotable members and actuators, said pivotable members driven by said actuators, and wherein said geometrically adjustable portions are sized and shaped to change the shape of said converging portion of said one or more of said one or more aerodynamic ducts when said geometrically adjustable portions are moved with said actuators. 25. A supersonic gas compressor for compressing a selected gas, comprising: a casing comprising a low pressure gas inlet and a high pressure gas exit;a rotor comprising a plurality of blades and configured to act on a selected gas to impart axial and tangential velocity thereto to provide a supersonic gas flow;a stator comprising a diffuser including one or more aerodynamic ducts configured for diffusing a gas received therein, said one or more aerodynamic ducts each having a converging portion, a diverging portion, and an effective contraction ratio, such that, with input of a supersonic gas flow, each aerodynamic duct generates a plurality of shock waves (S1 to Sx) in said selected gas as said selected gas passes therethrough, said one or more aerodynamic ducts having an inlet relative Mach number for operation associated with a design operating point selected within a design operating envelope for a selected gas composition, gas quantity, and gas compression ratio, wherein said one or more of said aerodynamic ducts are helically arranged around a longitudinal axis, said one or more aerodynamic ducts comprising(a) a geometrically adjustable portion, operable to adjust said effective contraction ratio, and(b) boundary layer control structures, said boundary layer control structures comprising one or more of (1) outlet bleed ports for boundary layer removal, (2) inlet jets for energizing a boundary layer by gas injection, and (3) one or more vortex generators, said one or more vortex generators each comprising a base with a forward end and a leading edge extending outward and rearward from said forward end to an outward end, wherein said leading edge comprises a first angular discontinuity at a height H1 above said base, and a second angular discontinuity at a height H2 above said base, for generating at least two (2) vortices. 26. The compressor as set forth in claim 25, wherein each of said one or more aerodynamic ducts has a centerline, and wherein orthogonal to said centerline, one or more of said one or more aerodynamic ducts have a generally parallelogram cross-sectional shape. 27. The compressor as set forth in claim 26, wherein associated with said cross-sectional shape, said one or more aerodynamic ducts have an average aspect ratio, expressed as width to height, of two to one (2:1), or more. 28. The compressor as set forth in claim 26, wherein associated with said cross-sectional shape, said one or more of aerodynamic ducts have an average aspect ratio, expressed as width to height, of three to one (3:1), or more. 29. The compressor as set forth in claim 26, wherein associated with said cross-sectional shape, said one or more aerodynamic ducts have an average aspect ratio, expressed as width to height, of four to one (4:1), or more. 30. The compressor as set forth in claim 1 or in claim 25, wherein said inlet relative Mach number of said one or more aerodynamic ducts is in excess of 1.5. 31. The compressor as set forth in claim 1, or in claim 25, wherein said inlet relative Mach number of said one or more aerodynamic ducts is in excess of 1.8. 32. The compressor as set forth in claim 1, or in claim 25, wherein said inlet relative Mach number of said one or more aerodynamic ducts is at least 2. 33. The compressor as set forth in claim 1, or in claim 25, wherein said inlet relative Mach number of said one or more aerodynamic ducts is at least 2.5. 34. The compressor as set forth in claim 1, or in claim 25, wherein said inlet relative Mach number of said one or more aerodynamic ducts is in excess of 2.5. 35. The compressor as set forth in claim 1, or in claim 25, wherein said inlet relative Mach number of said one or more aerodynamic ducts is between 2 and 2.5. 36. The compressor as set forth in claim 1, or in claim 25, wherein said inlet relative Mach number of said one or more aerodynamic ducts is between 2.5 and 2.8.
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