Plasma-vortex engine and method of operation therefor
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F01K-025/08
F01K-025/00
출원번호
US-0077289
(2005-03-09)
발명자
/ 주소
Pekrul,Merton W.
de Vilmorin,Enrique
출원인 / 주소
Fibonacci Anstalt
인용정보
피인용 횟수 :
14인용 특허 :
23
초록▼
A plasma-vortex engine (20), consisting of a plasmatic fluid (22) circulating in a closed loop (44) encompassing a fluid heater (26), an expansion chamber (30), and a condenser (42), is provided. The expansion chamber ( 30) is formed of a housing (64) and two end plates (66, 68), and encompasses a r
A plasma-vortex engine (20), consisting of a plasmatic fluid (22) circulating in a closed loop (44) encompassing a fluid heater (26), an expansion chamber (30), and a condenser (42), is provided. The expansion chamber ( 30) is formed of a housing (64) and two end plates (66, 68), and encompasses a rotor (72) to which a plurality of vanes (74) is coupled. A shaft (36) is coupled to the rotor (72) through the endplates (66, 68). During operation, the fluid heater (26) heats the plasmatic fluid (22) to produce a plasma (86), which is then injected into the expansion chamber (30). The plasma (86) expands both hydraulically and adiabatically and exerts an expansive force (94) against one of the vanes (74). A vortex generator (96) coupled to the expansion chamber generates a vortex (100) within the plasma ( 86), which exerts a vortical force (102) against that one vane (74). The rotor (72) and shaft (36) rotate in response to the expansive and vortical forces (94, 102). The plasma (86) is exhausted from the expansion chamber (30) and is condensed back into the plasmatic fluid (22) by the condenser (42).
대표청구항▼
What is claimed is: 1. A plasma-vortex engine comprising: a plasmatic fluid configured to become a plasma upon vaporization thereof; a fluid heater configured to heat said plasmatic fluid; an expansion chamber comprising: a housing; a first end plate affixed to said housing; and a second end plate
What is claimed is: 1. A plasma-vortex engine comprising: a plasmatic fluid configured to become a plasma upon vaporization thereof; a fluid heater configured to heat said plasmatic fluid; an expansion chamber comprising: a housing; a first end plate affixed to said housing; and a second end plate affixed to said housing in opposition to said first end plate; a shaft incoincidentally coupled to said expansion chamber; a rotor coaxially coupled to said shaft within said expansion chamber; a plurality of vanes coupled to one of: said rotor; said housing; and one of said first and second end plates; and a vortex generator coupled to said expansion chamber and configured to generate a plasma vortex within said expansion chamber. 2. An engine as claimed in claim 1 wherein: said fluid heater heats said plasmatic fluid; said engine additionally comprises an inlet port though which said plasma is introduced to said expansion chamber, wherein said plasmatic fluid is vaporized into said plasma prior to or during said introduction; said plasma expands adiabatically within said expansion chamber and exerts an expansive force against one of said plurality of vanes; said vortex generator generates said plasma vortex within said plasma; said plasma vortex exerts a vortical force against said one vane; one of said rotor and said housing rotates in response to said expansive and vortical forces; and said engine additionally comprises an outlet port through which said plasma is exhausted from said expansion chamber. 3. An engine as claimed in claim 1 additionally comprising a condenser coupled between said outlet port and an inlet to said fluid heater, and configured to condense said plasma into said plasmatic fluid. 4. An engine as claimed in claim 1 wherein said fluid heater comprises an external-combustion chamber configured to heat said plasmatic fluid through the combustion of a fuel. 5. An engine as claimed in claim 1 wherein said fluid heater comprises an energy exchanger configured to heat said plasmatic fluid through the transfer of energy from an external energy source. 6. An engine as claimed in claim 5 wherein said external energy source utilizes energy in the form of heat, radiation, and vibration. 7. An engine as claimed in claim 1 wherein said plasmatic fluid comprises: a non-reactive liquid component; and a paramagnetic solid component. 8. An engine as claimed in claim 7 wherein said non-reactive liquid component is diamagnetic. 9. An engine as claimed in claim 7 wherein said paramagnetic solid component is particulate. 10. An engine as claimed in claim 1 wherein each of said plurality of vanes is pivotally coupled to one of: said rotor; said housing; and one of said first and second end plates. 11. An engine as claimed in claim 1 wherein each of said plurality of vanes is slidingly coupled to said rotor. 12. A method of operating a plasma-vortex engine, said method comprising: heating a plasmatic fluid; introducing a plasma derived from said plasmatic fluid into an expansion chamber; expanding said plasma adiabatically; exerting an expansive force upon one of a plurality of vanes within said expansion chamber in response to said expanding activity; rotating one of a rotor and a housing in response to said exerting activity; and exhausting said plasma from said expansion chamber. 13. A method as claimed in claim 12 wherein: said method additionally comprises: generating a vortex within said plasma within said expansion chamber; and applying a vortical force upon said one vane in response to said generating activity; and said rotating activity rotates said one of said rotor and said housing in response to said exerting and applying activities. 14. A method as claimed in claim 12 wherein: said heating activity heats said plasmatic fluid to a temperature greater than or equal to a vapor point of said plasmatic fluid; and said introducing activity comprises: vaporizing said plasmatic fluid to form said plasma in response to said heating activity; and injecting said plasma into said expansion chamber. 15. A method as claimed in claim 12 wherein: said heating activity heats said plasmatic fluid to a temperature less than and proximate a vapor point of said plasmatic fluid; and said introducing activity comprises: injecting said plasmatic fluid into said expansion chamber; and vaporizing said plasmatic fluid to form said plasma in response to said injecting activity. 16. A method as claimed in claim 12 additionally comprising: circulating said plasmatic fluid in a closed loop between said engine and a fluid heater configured to effect said heating activity; and converting said plasmatic fluid to said plasma in response to said heating activity for at least a portion of said closed loop. 17. A method as claimed in claim 12 additionally comprising condensing said plasma into said plasmatic fluid within said closed loop. 18. A method as claimed in claim 12 wherein: said method additionally comprises transferring energy into said plasmatic fluid from an external energy source; said heating activity heats said plasmatic fluid in response to said transferring activity. 19. A method as claimed in claim 18 wherein said external energy source is one of heat, radiation, and vibration. 20. A method as claimed in claim 12 additionally comprising: forming said expansion chamber from said housing, a first end plate, and a second end plate; encompassing a rotor within said expansion chamber; incoincidentally coupling a shaft to said expansion chamber; coaxially coupling said shaft to said rotor; and pivotally coupling said plurality of vanes to one of: said rotor; said housing; and one of said first and second end plates. 21. A plasma-vortex engine comprising: a plasmatic fluid configured to become a plasma upon vaporization thereof; a fluid heater configured to heat said plasmatic fluid; a plurality of expansion chambers, wherein each of said expansion chambers comprises: a housing; a first end plate coupled to said housing; and a second end plate coupled to said housing in opposition to said first end plate; a shaft incoincidentally coupled to each of said plurality of expansion chambers; a plurality of rotors coaxially coupled to said shaft, wherein each of said rotors is encompassed within one of said expansion chambers; a plurality of vanes, wherein for each of said expansion chambers a plural portion of said plurality of vanes is coupled to one of: said rotor; said housing; and one of said first and second end plates; and a vortex generator configured to generate a vortex within each of said expansion chambers. 22. An engine as claimed in claim 21 wherein: said fluid heater heats said plasmatic fluid; said plasma is introduced to a first expansion chamber when said first expansion chamber is in a first state and a second expansion chamber is in a second state in advance of said first state, wherein said plasmatic fluid is vaporized into said plasma prior to or during said introduction; said plasma exerts a force against one of said plurality of vanes within said first expansion chamber; said shaft rotates in response to said force, thereby causing said first expansion chamber to shift from said first state to a third state in arrears of said first state, and causing said second expansion chamber to shift from said second state to said first state; said plasma is introduced to said second expansion chamber, wherein said plasmatic fluid is vaporized into said plasma prior to or during said introduction; said plasma exerts a force against one of said plurality of vanes within said second expansion chamber; and said shaft rotates in response to said force, thereby causing said second expansion chamber to shift from said first state to said third state. 23. An engine as claimed in claim 21 wherein: said fluid heater heats said plasmatic fluid to produce said plasma; said plasma from said fluid heater is introduced to a first expansion chamber having a first volume, wherein said plasma is expanded within and exhausted by said first expansion chamber; said plasma from said first expansion chamber is introduced to a second expansion chamber having a second volume, wherein said second volume is less than said first volume, and wherein said plasma is expanded within and exhausted by said second expansion chamber; said plasma from said second expansion chamber is introduced to a third expansion chamber having a third volume, wherein said third volume is less than said second volume, and wherein said plasma is expanded within and exhausted by said third expansion chamber; and said plasma from said third expansion chamber is introduced to a fourth expansion chamber having a fourth volume, wherein said fourth volume is less than said third volume, and wherein said plasma is expanded within and exhausted by said fourth expansion chamber.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (23)
Jensen Donald C. (138 Alhambra Pl. West Palm Beach FL 33405), Energy converter using imploding plasma vortex heating.
Curodeau, Marc-Alexandre; Allen, Benoit; Hudon, Rémi; Laflamme Laroche, Jimmy, Belt and support for a rotor mechanism in a rotary apparatus and rotary apparatus comprising same.
Hyde, Roderick A.; Ishikawa, Muriel Y.; Jung, Edward K. Y.; Kare, Jordin T.; Myhrvold, Nathan P.; Tegreene, Clarence T.; Weaver, Thomas A.; Wood, Jr., Lowell L.; Wood, Victoria Y. H., Hybrid propulsive engine including at least one independently rotatable compressor rotor.
Foster, Glenn B.; Hyde, Roderick A.; Ishikawa, Muriel Y.; Jung, Edward K. Y.; Kare, Jordin T.; Myhrvold, Nathan P.; Tegreene, Clarence T.; Weaver, Thomas Allan; Wood, Jr., Lowell L.; Wood, Victoria Y. H., Hybrid propulsive engine including at least one independently rotatable compressor stator.
Hyde, Roderick A.; Ishikawa, Muriel Y.; Jung, Edward K. Y.; Kare, Jordin T.; Myhrvold, Nathan P.; Tegreene, Clarence T.; Weaver, Thomas A.; Wood, Jr., Lowell L.; Wood, Victoria Y. H., Hybrid propulsive engine including at least one independently rotatable compressor stator.
Foster, Glenn B.; Hyde, Roderick A.; Ishikawa, Muriel Y.; Jung, Edward K. Y.; Kare, Jordin T.; Myhrvold, Nathan P.; Tegreene, Clarence T.; Weaver, Thomas Allan; Wood, Jr., Lowell L.; Wood, Victoria Y. H., Hybrid propulsive engine including at least one independently rotatable propeller/fan.
Hyde, Roderick A.; Ishikawa, Muriel Y.; Jung, Edward K. Y.; Kare, Jordin T.; Myhrvold, Nathan P.; Tegreene, Clarence T.; Weaver, Thomas Allan; Wood, Jr., Lowell L.; Wood, Victoria Y. H., Hybrid propulsive engine including at least one independently rotatable propeller/fan.
Foster, Glenn B.; Hyde, Roderick A.; Ishikawa, Muriel Y.; Jung, Edward K. Y.; Kare, Jordin T.; Myhrvold, Nathan P.; Tegreene, Clarence T.; Weaver, Thomas Allan; Wood, Jr., Lowell L.; Wood, Victoria Y. H., Hybrid propulsive engine including at least one independently rotatable turbine stator.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.