Angular velocity stepping and methods of use in turbomachinery
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F04D-025/04
F04D-029/44
F04D-017/12
F01D-001/06
F01D-017/16
출원번호
US-0991487
(2016-01-08)
등록번호
US-9957975
(2018-05-01)
발명자
/ 주소
Kuhns, Corey B.
출원인 / 주소
Kuhns, Corey B.
대리인 / 주소
Merek, Blackmon & Voorhees, LLC
인용정보
피인용 횟수 :
0인용 특허 :
3
초록▼
Provided is an improved architecture for rotary kinetic fluid motors and pumps, in which working fluid gains or loses pressure by flowing through an alternating sequence of radial-flow impellers and radial-flow fluid vortices, the impellers and fluid vortices all rotating around a single axis and in
Provided is an improved architecture for rotary kinetic fluid motors and pumps, in which working fluid gains or loses pressure by flowing through an alternating sequence of radial-flow impellers and radial-flow fluid vortices, the impellers and fluid vortices all rotating around a single axis and in a common direction at staggered speeds, each vortex being the product of rotating fluid that is flowing radially through a bladeless annular volume.
대표청구항▼
1. A method of operating a turbomachine having a compressor and a turbine, comprising: providing a compressor and a turbine having a common rotational axis and being linked together by shafts or similar driving means;said compressor ingesting a fluid flow and directing the flow to enter a first spin
1. A method of operating a turbomachine having a compressor and a turbine, comprising: providing a compressor and a turbine having a common rotational axis and being linked together by shafts or similar driving means;said compressor ingesting a fluid flow and directing the flow to enter a first spin-up impeller at radius A from said rotational axis;the flow then exiting said first spin-up impeller at radius B from said rotational axis, where said radius B is greater than radius A;the flow then entering a first bladeless annular volume at radius B and at angular velocity V1 and exiting said first volume at radius C from said rotational axis and at angular velocity V2, where said radius C is less than radius B and said angular velocity V2 is greater than V1 by action of angular momentum conservation;said first bladeless annular volume being axially adjacent to said first spin-up impeller;the flow then entering a first process impeller at radius C and exiting said first process impeller at radius D from said rotational axis, where said radius D is greater than radius C;said first process impeller being axially adjacent to said first bladeless annular volume. 2. The method of operating a turbomachine of claim 1, further comprising: the flow then entering a second bladeless annular volume at radius D from said rotational axis and at angular velocity V3 and exiting said second volume at radius E from said rotational axis and at angular velocity V4, where said radius E is greater than radius D and said angular velocity V4 is less than V3 by action of angular momentum conservation; said second volume being radially adjacent to said first process impeller. 3. The method of operating a turbomachine of claim 2, where V3 is substantially equal to V2. 4. The method of operating a turbomachine of claim 2, further comprising: the flow then entering a first spin-down impeller at radius E from said rotational axis and exiting said first spin-down impeller at radius F from said rotational axis, where said radius F is less than radius E;said first spin-down impeller being axially adjacent to said second bladeless annular volume. 5. The method of operating a turbomachine of claim 4, further comprising: the flow then entering a third bladeless annular volume at radius F from said rotational axis and at angular velocity V5 and exiting said third volume at radius G from said rotational axis and at angular velocity V6, where said radius G is greater than radius F and said angular velocity V6 is less than V5 by action of angular momentum conservation. 6. The method of operating a turbomachine of claim 5, where V5 is substantially equal to V4. 7. The method of operating a turbomachine of claim 5, further comprising: said third volume being axially adjacent to said first spin-down impeller;the flow then exiting said compressor. 8. The method of operating a turbomachine of claim 5, where said turbine operates in the respective reverse order from said compressor with the fluid flow direction in said turbine being opposite that in said compressor. 9. The method of operating a turbomachine of claim 5, where said turbine is a mirror image of said compressor and operates in the respective reverse order from said compressor. 10. The method of operating a turbomachine of claim 9, wherein each impeller in said turbine is driven by or is driving its counterpart in the compressor. 11. The method of operating a turbomachine of claim 1, further comprising: the flow being directed through one or more additional spin-up impellers after entering said compressor and prior to entering said first process impeller;the flow being directed through a bladeless annular volume in a radially inward direction after exiting each spin-up impeller and prior to entering the next impeller. 12. The method of operating a turbomachine of claim 11, where said turbine is a mirror image of said compressor and operates in the respective reverse flow order from said compressor. 13. The method of operating a turbomachine of claim 2, further comprising: the flow being directed through one or more additional process impellers after exiting said second bladeless annular volume and prior to entering said first spin-down impeller;wherein the flow is directed through a bladeless annular volume in a radially outward direction after exiting each respective process impeller and prior to entering a next subsequent impeller. 14. The method of operating a turbomachine of claim 5, further comprising: the flow being directed through at least one additional spin-down impellers after exiting said third bladeless annular volume and prior to exiting said compressor;wherein the flow is directed through a bladeless annular volume in a radially outward direction after exiting each spin-down impeller and prior to entering a next impeller or prior to exiting said compressor. 15. The method of operating a turbomachine of claim 8, where the radial dimensions of said turbine are a direct linear function of their corresponding respective radial dimensions in said compressor. 16. The method of operating a turbomachine of claim 11, where one or more spin-up impellers are replaced by structural bridges that span axially across one or more bladeless annular volumes to connect two or more sections of a rotating structure. 17. The method of operating a turbomachine of claim 1, where the bearings that carry each impeller and each associated rotating structures are mounted to stationary structure. 18. The method of operating a turbomachine of claim 1, where bearings that carry each impeller and associated rotating structures are mounted to the next slower rotating structure; wherein the bearings carrying the slowest impeller and associated rotating structure is mounted to a stationary structure. 19. The method of operating a turbomachine of claim 10, wherein the flow is directed through angular velocity regulators upon entering said compressor and wherein the flow is directed through angular velocity regulators upon entering said turbine. 20. The method of operating a turbomachine of claim 19, where the flow is directed through a bladeless annular volume after exiting said angular velocity regulator and prior to entering said first spin-up impeller. 21. The method of operating a turbomachine of claim 4, further comprising: the flow exiting said first spin-down impeller is then directed through a bladeless annular volume in a radially inward direction;wherein the flow then enters a second process impeller. 22. The method of operating a turbomachine of claim 21, further comprising: the flow exiting said second process impeller is directed through another radial flow cycle of radially outward bladeless annular volume, then a spin-down impeller, then a radially inward bladeless annular volume to a third process impeller.
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이 특허에 인용된 특허 (3)
Reisdorf Paul W. (Dunlap IL), Journal bearing for use with high speed shafting.
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