Floating rod seal for a stirling cycle machine
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F02G-001/044
F16J-015/44
F16J-015/52
F02G-001/04
F01K-025/00
F28F-001/40
F28F-001/42
F28F-009/02
F28F-013/06
F28F-027/00
F28D-007/02
F28D-007/06
F28F-001/12
F28F-001/14
F23N-001/02
F23D-014/60
F23D-014/62
F28D-017/02
출원번호
US-0836946
(2013-03-15)
등록번호
US-9822730
(2017-11-21)
발명자
/ 주소
Kamen, Dean
Langenfeld, Christopher C.
Bhat, Prashant
Norris, Michael G.
출원인 / 주소
New Power Concepts, LLC
대리인 / 주소
Norris, Michael George
인용정보
피인용 횟수 :
0인용 특허 :
91
초록
A piston rod seal unit. The piston rod seal unit includes a housing, a cylinder gland, and at least one floating rod seal assembly mounted in the cylinder gland, the floating rod seal assembly comprising at least one rod seal mounted onto the floating rod seal assembly.
대표청구항▼
1. A piston rod seal unit comprising: a housing located between a first volume and a second volume, wherein a pressure difference between the first volume and the second volume varies with time;a cylinder gland; andat least one floating rod seal assembly mounted in the cylinder gland, the floating r
1. A piston rod seal unit comprising: a housing located between a first volume and a second volume, wherein a pressure difference between the first volume and the second volume varies with time;a cylinder gland; andat least one floating rod seal assembly mounted in the cylinder gland, the floating rod seal assembly comprising:a first stationary bushing rigidly mounted to the floating rod seal assembly, the first stationary bushing having a first contacting surface;a second stationary bushing rigidly mounted to the floating rod seal assembly, the second stationary bushing having a second contacting surface, wherein the second stationary bushing is located a first axial distance from the first stationary bushing;a floating bushing, the floating bushing being located between the first and second stationary bushings, the floating bushing comprising a third contacting surface and a fourth contacting surface, the floating bushing having an axial dimension smaller than the first axial distance, only one of the third contacting surface and fourth contacting surface forming a metal to metal seal with one of the first contacting surface and second contacting surface; andat least one rod seal mounted onto the floating bushing. 2. The piston rod seal unit of claim 1, further comprising a scraper ring. 3. The piston rod seal unit of claim 2, further comprising a particle trap located between the scraper ring and at least one floating rod seal assembly, the particle trap having one or more magnets. 4. The piston rod seal unit of claim 2, further comprising a port, the port being configured to minimize a pressure difference across the scraper ring. 5. The piston rod seal unit of claim 4, further comprising a filter on the port, the filter preventing particles from entering the piston rod seal unit associated with a movement of a working fluid. 6. The piston rod seal unit of claim 1, wherein the rod seal comprises a spring energized lip seal. 7. An external combustion engine containing a working fluid comprising: an airlock space, the airlock space separating a working space from a crankcase, wherein the working space is filled with working fluid at an oscillating working fluid pressure and the crankcase is filled with crankcase fluid at a crankcase pressure;an airlock pressure regulator for maintaining a pressure differential between the crankcase fluid and the working fluid; anda piston rod seal unit comprising: a housing located between the working space and the airlock space, wherein a pressure difference between the working space and the airlock space varies with time;a cylinder gland; andat least one floating rod seal assembly mounted in the cylinder gland, the floating rod seal assembly comprising: a first stationary bushing mounted to the floating rod seal assembly, the first stationary bushing having a first contacting surface;a second stationary bushing mounted to the floating rod seal assembly, the second stationary bushing having a second contacting surface;a floating bushing, the floating bushing being located between the first and second stationary bushings, the floating bushing comprising a third contacting surface and a fourth contacting surface, the floating bushing having an axial dimension smaller than the first axial distance, one of the third contacting surface and fourth contacting surface alternatingly forming a metal to metal seal first with the first contacting surface and second with the second contacting surface; andat least one rod seal mounted onto the floating bushing. 8. The external combustion engine of claim 7, wherein the airlock pressure regulator comprises a bidirectional pressure regulator, the bidirectional pressure regulator maintains a predetermined pressure differential between the crankcase fluid and the working fluid. 9. The external combustion engine of claim 7 wherein the airlock pressure regulator comprises: a filter;a compressor;a pressure regulating spool valve; anda linear position sensor, wherein the linear position sensor produces a signal indicative of a regulating spool valve position. 10. The external combustion engine of claim 9, the airlock pressure regulator further comprising a controller. 11. The external combustion engine of claim 9, wherein the linear position sensor comprises an LVDT. 12. The external combustion engine of claim 10, wherein the controller comprises regulating a compressor speed based on the signal of the linear position sensor. 13. The external combustion engine of claim 9, wherein the compressor is in fluid communication with the crankcase via the filter. 14. The external combustion engine of claim 9, wherein the pressure regulating spool valve is in fluid communication with at least one of the compressor, the airlock space and the crankcase. 15. A piston rod seal unit of claim 1 wherein at least one of the contacting surfaces has a surface finish less than 32 microinches RA. 16. A method to axially seal a reciprocating rod passing through a housing, the housing separating a first volume at a first varying pressure from a second volume at a second varying pressure, the method comprising: mounting a cylinder gland to the housing;mounting a first stationary bushing in the cylinder gland;placing a floating bushing in the cylinder gland substantially axially aligned with the first stationary bushing;mounting a second stationary bushing in the cylinder gland at a first axial distance from the first stationary bushing and substantially aligned with the first stationary bushing;creating an axial seal between the reciprocating rod and the floating bushing with a rod seal mounted to the floating bushing;creating an axial seal between the floating bushing and the first stationary bushing when the first varying pressure is less than the second varying pressure;allowing the floating bushing to move radially when the first varying pressure is substantially equal to the second varying pressure; andreforming an axial seal between the floating bushing and the second stationary bushing when the first varying pressure is greater than the second varying pressure. 17. The method to axially seal a reciprocating piston of claim 16, wherein the axial seal is a metal seal. 18. The method to axially seal a reciprocating piston of claim 16, wherein the first axial distance is greater than an axial dimension of the floating bushing. 19. The method to axially seal a reciprocating piston of claim 16, further comprising mounting a scraper ring in the cylinder gland. 20. The method to axially seal a reciprocating piston of claim 19, further comprising mounting a particle trap between the scraper ring and the first stationary bushing in the cylinder gland, the particle trap having one or more magnets. 21. The method to axially seal a reciprocating piston of claim 19, further comprising installing a filter on a port in the cylinder gland, the port minimizing a pressure difference across the scraper ring. 22. A piston rod seal unit comprising: a housing located between a first volume and a second volume, wherein a pressure difference between the first volume and the second volume varies with time;a cylinder gland; andat least one floating rod seal assembly mounted in the cylinder gland, the floating rod seal assembly comprising:a first stationary bushing rigidly mounted to the floating rod seal assembly, the first stationary bushing haying a first contacting surface;a second stationary bushing rigidly mounted to the floating rod seal assembly, the second stationary bushing having a second contacting surface, the second stationary bushing defining an axial gap relative to the first stationary bushing, the axial gap having a first axial distance;a floating bushing, the floating bushing having a circumferential rib, the circumferential rib being located between the first and second stationary bushings, the circumferential rib having a thickness less than the first axial distance, the circumferential rib comprising a third contacting surface and a fourth contacting surface, only one of the third contacting surface and fourth contacting surface forming a metal to metal seal with one of the first contacting surface and second contacting surface; andat least one rod seal mounted onto the floating bushing. 23. The piston rod seal unit of claim 22, further comprising a scraper ring. 24. The piston rod seal unit of claim 23, further comprising a particle trap located between the scraper ring and at least one floating rod seal assembly, the particle trap having one or more magnets. 25. The piston rod seal unit of claim 23, further comprising a port, the port being configured to minimize a pressure difference across the scraper ring. 26. The piston rod seal unit of claim 25, further comprising a filter on the port, the filter preventing particles from entering the piston rod seal unit associated with a movement of a working fluid. 27. A piston rod seal unit comprising: a housing located between a first volume and a second volume, wherein a pressure difference between the first volume and the second volume varies with time;a cylinder gland mounted to the housing and located within the first volume;a scraper ring mounted in the cylinder gland, the scraper ring exposed to the first volume;a port in the cylinder gland, the port fluidically connecting the first volume to an interior volume inside the cylinder gland, the interior volume in fluid communication with the scraper ring;a filter on the port; andat least one floating rod seal assembly mounted in the cylinder gland, the floating rod seal assembly comprising:a first stationary bushing rigidly mounted to the floating rod seal assembly, the first stationary bushing having a first contacting surfacea second stationary bushing rigidly mounted to the floating rod seal assembly, the second stationary bushing having a second contacting surface, wherein the second stationary bushing is located a first axial distance from the first stationary bushing;a floating bushing, the floating bushing being located between the first and second stationary bushings, the floating bushing comprising a third contacting surface and a fourth contacting surface, the floating bushing having an axial dimension smaller than the first axial distance, only one of the third contacting surface and fourth contacting surface forming a metal to metal seal with one of the first contacting surface and second contacting surface; andat least one rod seal mounted onto the floating bushing.
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이 특허에 인용된 특허 (91)
Gaucher John J. (Windham NH) Van Vleet Frank (Andover MA) Shannon Daniel (Washington PA), Anti-rotation wiper ring.
Wood James G. (3996 Marion Johnson Rd. Albany OH 45710) Ross Melvin A. (8169 Lake Bluff Ct. Columbus OH 43235), Balancing technique for Ross-type stirling and other machines.
Ross M. Andrew (4195 Mumford Ct. Columbus OH 43220) Beale William T. (Rte. 6 ; Box 73 Athens OH 45701), Compact crank drive mechanism with guided pistons.
Beach Eugene H. (Silver Spring MD), Efficient energy conversion apparatus and method especially arranged to employ a stirling engine or alternately arranged.
Frosch Robert A. Administrator of the National Aeronautics and Space Administration ; with respect to an invention of ( La Crescenta CA) McDougal Allan R. (La Crescenta CA), Hot gas engine with dual crankshafts.
Davies Francis William (3366 Whittier Ave. Victoria ; B.C. CA V8Z 3P9) Walcer Joseph (7160 Veyaness Road Saanichton ; B.C. CA V0S 1M0), Piston machine.
Dean L. Kamen ; Thomas Q. Gurski ; Christopher C. Langenfeld ; Ryan Keith LaRocque ; Michael Norris ; Kingston Owens, Stirling engine thermal system improvements.
Kamen, Dean L.; Gurski, Thomas Q.; Langenfeld, Christopher C.; LaRocque, Ryan Keith; Norris, Michael; Owens, Kingston; Strimling, Jonathan, Stirling engine thermal system improvements.
Kamen, Dean L.; Gurski, Thomas Q.; Langenfeld, Christopher C.; LaRocque, Ryan Keith; Norris, Michael; Owens, Kingston; Strimling, Jonathan, Stirling engine thermal system improvements.
Langenfeld, Christopher C.; Norris, Michael; LaRocque, Ryan Keith; Smith, III, Stanley B.; Strimling, Jonathan, Thermal improvements for an external combustion engine.
Meijer Roelf J. (Ann Arbor MI) Ziph Benjamin (Ann Arbor MI) Godett Ted M. (Ann Arbor MI), Yieldably mounted lubricant control assemblies for piston rods.
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