Rotary engine exhaust apparatus and method of operation therefor
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F01K-023/06
F01C-001/10
F23C-099/00
F01C-001/344
F01C-021/18
F01C-021/08
F01K-025/08
F01C-021/10
출원번호
US-0415641
(2012-03-08)
등록번호
US-8800286
(2014-08-12)
발명자
/ 주소
Pekrul, Merton W.
출원인 / 주소
Pekrul, Merton W.
대리인 / 주소
Hazen, Kevin
인용정보
피인용 횟수 :
2인용 특허 :
123
초록▼
The invention comprises a rotary engine method and apparatus configured with an exhaust system. The exhaust system includes an exhaust cut or exhaust channel into one or more of a housing or an endplate of the rotary engine, which interrupts the seal surface of the expansion chamber housing. The exh
The invention comprises a rotary engine method and apparatus configured with an exhaust system. The exhaust system includes an exhaust cut or exhaust channel into one or more of a housing or an endplate of the rotary engine, which interrupts the seal surface of the expansion chamber housing. The exhaust cut directs spent fuel from the rotary engine fuel expansion/compression chamber out of the rotary engine either directly or via an optional exhaust port and/or exhaust booster. The exhaust system vents fuel to atmosphere or into a condenser for recirculating of fuel in a closed-loop circulating rotary engine system. Exhausting the engine reduces back pressure on the rotary engine thereby enhancing rotary engine efficiency.
대표청구항▼
1. A method, comprising the steps of: rotating a rotor in a stator, said stator comprising a first substantially elliptical inner wall, said rotor offset along both an x-axis and a y-axis relative to a center of said inner wall of said stator, wherein said x-axis and said y-axis form an x/y plane pe
1. A method, comprising the steps of: rotating a rotor in a stator, said stator comprising a first substantially elliptical inner wall, said rotor offset along both an x-axis and a y-axis relative to a center of said inner wall of said stator, wherein said x-axis and said y-axis form an x/y plane perpendicular to a rotatable shaft extending through said rotor;sealing a first end of said stator using a first endplate;sealing a second end of said stator using a second endplate;spanning a distance between said rotor and said stator using a set of spaced vanes, at least one of said vanes comprising a vane tip proximate said stator, wherein a twelve o'clock position of a rotation of said rotor within said stator comprises a point of rotation of said rotor at first extension of one of said set of spaced vanes;venting an expansion chamber between said rotor and said stator through an exhaust aperture during an exhaust phase of a cycle of said rotor;using a booster element to boost exhaust through said exhaust aperture using a burst of exhaust vapor through a second aperture, said second aperture comprising a cut through at least one of: said stator, said first endplate and said second endplate,said second aperture connected via a booster line to said booster element,said exhaust aperture connected to said booster element via an exhaust line, andwherein a first pressure in said booster line exceeds a second pressure in said exhaust line. 2. A method, comprising the steps of: rotating a rotor in a stator, said stator comprising a first substantially elliptical inner wall, said rotor offset along both an x-axis and a y-axis relative to a center of said inner wall of said stator, wherein said x-axis and said y-axis form an x/y plane perpendicular to a rotatable shaft extending through said rotor;sealing a first end of said stator using a first endplate;sealing a second end of said stator using a second endplate;spanning a distance between said rotor and said stator using a set of spaced vanes, at least one of said vanes comprising a vane tip proximate said stator, wherein a twelve o'clock position of a rotation of said rotor within said stator comprises a point of rotation of said rotor at first extension of one of said set of spaced vanes;venting an expansion chamber between said rotor and said stator through an exhaust aperture during an exhaust phase of a cycle of said rotor; andusing a booster element to boost exhaust through said exhaust aperture using a burst of exhaust vapor through a second aperture, said second aperture comprising a cut through at least one of: said stator, said first endplate, and said second endplate,said second aperture connected via a booster line to said booster element, andsaid exhaust aperture connected to said booster element via an exhaust line; andcontrolling a first temperature in said exhaust line above a second temperature in said booster line. 3. The method of claim 1, said rotor and said stator comprising elements of an expander engine. 4. An apparatus, comprising: a rotor configured to rotate in a stator, said stator comprising a first substantially elliptical inner wall, said rotor offset along both an x-axis and a y-axis relative to a center of said inner wall of said stator, wherein said x-axis and said y-axis form an x/y plane perpendicular to a rotatable shaft extending through said rotor;a first endplate sealing a first end of said stator;a second endplate sealing a second end of said stator;a set of spaced vanes configured to span a distance between said rotor and said stator, at least one of said vanes comprising a vane tip proximate said stator, wherein a twelve o'clock position of a rotation of said rotor within said stator comprises a point of rotation of said rotor at first extension of said vanes;an exhaust aperture configured to vent an expansion chamber of said apparatus during an exhaust phase of a cycle of said rotor;an exhaust booster aperture through at least one of: said stator, said first endplate, and said second endplate, said exhaust booster positioned in a rotor rotation cycle prior to said exhaust aperture;an exhaust booster line connected at a first end to said exhaust booster aperture and at a second end to a booster; andan exhaust conduit connected at a first end to said exhaust aperture and at a second end to said booster, wherein during use vapor pressure running through said exhaust booster line accelerates exhaust flow through said exhaust conduit. 5. The apparatus of claim 4, said exhaust aperture configured to vent fuel from the expansion chamber through at least one of: said first endplate; andsaid second endplate. 6. The apparatus of claim 4, said exhaust aperture configured to vent fuel from the expansion chamber through at least two of: said stator;said first endplate; andsaid second endplate. 7. The apparatus of claim 4, further comprising: a first exhaust cut initiating at said exhaust aperture, said first exhaust cut comprising at least one of: an elongated channel through said inner wall of said stator;an elongated channel through said inner wall of said first endplate; andan elongated channel through said inner wall of said second endplate. 8. The apparatus of claim 7, further comprising: a second exhaust cut, said first exhaust cut having a first depth axis into said stator, said second exhaust cut comprising a second depth axis into said first endplate, said first depth axis perpendicular to said second depth axis. 9. The apparatus of claim 7, further comprising: a second exhaust cut comprising a second elongated channel cut through at least one of said stator, said first endplate, and said second endplate; andan exhaust ridge formed between said first exhaust cut and said second exhaust cut in at least one of said stator, said first endplate, and said second endplate. 10. The apparatus of claim 9, further comprising: a bearing, said bearing attached to said vane tip, said bearing both configured and aligned to roll over said exhaust ridge and to not substantially cover either of said first exhaust cut and said second exhaust cut. 11. The apparatus of claim 4, wherein said exhaust aperture comprises a seven o′ clock to ten o'clock position. 12. The apparatus of claim 4, wherein at least two vanes of said set of vanes separate said exhaust aperture from said twelve o'clock position. 13. The apparatus of claim 4, said exhaust conduit comprising said first exhaust cut and a substantially enclosed line to said booster, said substantially enclosed line embedded into at least one of: a wall of said stator, said first endplate, and said second endplate. 14. The apparatus of claim 1, further comprising: an exhaust booster aperture through at least one of: said stator, said first endplate, and said second endplate, said exhaust booster positioned in a rotor rotation on one side of a first vane of said set of vanes simultaneously to said exhaust aperture comprising a position on a second side of said first vane;an exhaust booster line connected at a first end to said exhaust booster aperture and at a second end to a booster; andan exhaust line connected at a first end to said first exhaust cut and at a second end to said booster, wherein during use air pressure running through said exhaust booster line accelerates exhaust flow through said exhaust line. 15. The apparatus of claim 4, said exhaust booster line protruding substantially outside of an enclosure formed by said first endplate, said stator, and said second endplate, said exhaust line running substantially within at least one of said stator, said first endplate, and said second endplate. 16. The apparatus of claim 15, further comprising: housing temperature control lines embedded into at least one of said stator, said first endplate, and said second endplate. 17. The apparatus of claim 4, said exhaust aperture positioned at least one-half of a spacing between two adjacent vanes of said set of spaced vanes past a six o'clock position. 18. The apparatus of claim 4, said exhaust aperture positioned one to fifteen degrees past one-half of a spacing between two adjacent vanes of said set of spaced vanes past a six o'clock position.
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