Internal combustion engine with port communication
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F02B-033/44
F02B-029/08
F01C-001/22
F02B-057/04
F02B-053/02
F02B-053/08
F02B-029/02
F02B-025/26
출원번호
US-0887611
(2015-10-20)
등록번호
US-9714604
(2017-07-25)
발명자
/ 주소
Thomassin, Jean
Rousseau, Patrick
Martel, Eric-Pierre
출원인 / 주소
PRATT & WHITNEY CANADA CORP.
대리인 / 주소
Norton Rose Fulbright Canada
인용정보
피인용 횟수 :
0인용 특허 :
18
초록▼
A method of feeding air to an internal combustion engine having at least first and second internal cavities, including: completing the intake phase of the first combustion chamber of the first internal cavity by feeding compressed air into the first combustion chamber until a maximum volume thereof
A method of feeding air to an internal combustion engine having at least first and second internal cavities, including: completing the intake phase of the first combustion chamber of the first internal cavity by feeding compressed air into the first combustion chamber until a maximum volume thereof is reached; during a beginning of the compression phase of the first combustion chamber and a simultaneous beginning of the intake phase of the second combustion chamber of the second internal cavity, feeding compressed air from the first combustion chamber into the second combustion chamber; closing a communication between the first and second combustion chambers and completing the intake phase of the second combustion chamber by feeding compressed air into the second combustion chamber until a maximum volume thereof is reached.
대표청구항▼
1. A method of feeding air to an internal combustion engine having at least first and second internal cavities, the first internal cavity defining at least a first combustion chamber, the second internal cavity defining at least a second combustion chamber, the first and second combustion chambers e
1. A method of feeding air to an internal combustion engine having at least first and second internal cavities, the first internal cavity defining at least a first combustion chamber, the second internal cavity defining at least a second combustion chamber, the first and second combustion chambers each having a variable volume and undergoing a cycle defining successive phases of intake, compression, combustion and exhaust, the method comprising: completing the intake phase of the first combustion chamber by feeding compressed air into the first combustion chamber until a maximum volume thereof is reached;during a beginning of the compression phase of the first combustion chamber and a simultaneous beginning of the intake phase of the second combustion chamber, feeding compressed air from the first combustion chamber into the second combustion chamber;closing a communication between the first and second combustion chambers and completing the intake phase of the second combustion chamber by feeding compressed air into the second combustion chamber until a maximum volume thereof is reached. 2. The method as defined in claim 1, wherein the first and second internal cavities each sealingly and rotationally receive a respective rotor therewithin. 3. The method as defined in claim 1, wherein the beginning of the compression phase of the first combustion chamber is simultaneous with the end of the exhaust phase and the beginning of the intake phase of the second combustion chamber, and compressed air is also fed from the first combustion chamber into the second combustion chamber during the end of the exhaust phase of the second combustion chamber. 4. The method as defined in claim 1, wherein: feeding the compressed air from the first combustion chamber into the second combustion chamber includes feeding the compressed air from the first combustion chamber through a primary inlet port of the first internal cavity and into the second combustion chamber through a secondary inlet port of the second internal cavity; andcompleting the intake phase of the second combustion chamber with the communication between the first and second combustion chambers closed includes feeding the compressed air to the second combustion chamber through a primary inlet port of the second internal cavity. 5. The method as defined in claim 1, wherein the internal combustion engine further includes a third internal cavity defining at least a third combustion chamber with variable volume and undergoing a cycle defining successive phases of intake, compression, combustion and exhaust, the method further comprising: during a beginning of the compression phase of the second combustion chamber and a simultaneous beginning of the intake phase of the third combustion chamber, feeding compressed air from the second combustion chamber into the third combustion chamber;closing a communication between the second and third combustion chambers and completing the intake phase of the third combustion chamber by feeding compressed air into the third combustion chamber until a maximum volume thereof is reached. 6. The method as defined in claim 5, wherein the internal combustion engine further includes a fourth internal cavity defining at least a fourth combustion chamber with variable volume and undergoing a cycle defining successive phases of intake, compression, the method further comprising: during a beginning of the compression phase of the third combustion chamber and a simultaneous beginning of the intake phase of the fourth combustion chamber, feeding compressed air from the third combustion chamber into the fourth combustion chamber;closing a communication between the third and fourth combustion chambers and completing the intake phase of the fourth combustion chamber by feeding compressed air into the fourth combustion chamber until a maximum volume thereof is reached;during a beginning of the compression phase of the fourth combustion chamber and a simultaneous beginning of the intake phase of the first combustion chamber, feeding compressed air from the fourth combustion chamber into the first combustion chamber; andclosing a communication between the fourth and first combustion chambers before completing the intake phase of the first combustion chamber by feeding compressed air into the first combustion chamber until the maximum volume thereof is reached. 7. The method as defined in claim 1, wherein the first internal cavity defines at least a first additional combustion chamber with variable volume and undergoing a cycle defining successive phases of intake, compression, combustion and exhaust, the method further comprising: during a beginning of the compression phase of the second combustion chamber and a simultaneous beginning of the intake phase of the first additional combustion chamber, feeding compressed air from the second combustion chamber into the first additional combustion chamber;closing a communication between the second combustion chamber and the first additional combustion chamber, and completing the intake phase of the first additional combustion chamber by feeding compressed air into the first additional combustion chamber until a maximum volume thereof is reached. 8. The method as defined in claim 7, wherein the second internal cavity defines at least a second additional combustion chamber with variable volume and undergoing a cycle defining successive phases of intake, compression, combustion and exhaust, the method further comprising: during a beginning of the compression phase of the first additional combustion chamber and a simultaneous beginning of the intake phase of the second additional combustion chamber, feeding compressed air from the first additional combustion chamber into the second additional combustion chamber;closing a communication between the first and second additional combustion chambers and completing the intake phase of the second additional combustion chamber by feeding compressed air into the second additional combustion chamber until a maximum volume thereof is reached;during a beginning of the compression phase of the second additional combustion chamber and a simultaneous beginning of the intake phase of the first combustion chamber, feeding compressed air from the second additional combustion chamber into the first combustion chamber; andclosing a communication between the second additional combustion chamber and the first combustion chamber before completing the intake phase of the first combustion chamber by feeding compressed air into the first combustion chamber until the maximum volume thereof is reached. 9. The method as defined in claim 8, wherein: feeding compressed air from the second additional combustion chamber into the first combustion chamber includes feeding the compressed air from the second additional combustion chamber through a primary inlet port of the second internal cavity and into the first combustion chamber through a secondary inlet port of the first internal cavity;feeding compressed air to the first combustion chamber with the communication between the second additional combustion chamber and the first combustion chamber closed includes feeding the compressed air to the first combustion chamber through a primary inlet port of the first internal cavity;feeding compressed air from the first combustion chamber into the second combustion chamber includes feeding the compressed air from the first combustion chamber through the primary inlet port of the first internal cavity and into the second combustion chamber through a secondary inlet port of the second internal cavity;feeding compressed air to the second combustion chamber with the communication between the first and second combustion chambers closed includes feeding the compressed air to the second combustion chamber through the primary inlet port of the second internal cavity;feeding compressed air from the second combustion chamber cavity into the first additional combustion chamber includes feeding the compressed air from the second combustion chamber through the primary inlet port of the second internal cavity and into the first additional combustion chamber through the secondary inlet port of the first internal cavity;feeding compressed air to the first additional combustion chamber with the communication between the second combustion chamber and the first additional combustion chamber closed includes feeding the compressed air to the first additional combustion chamber through the primary inlet port of the first internal cavity;feeding compressed air from the first additional combustion chamber into the second additional combustion chamber includes feeding the compressed air from the first additional combustion chamber through the primary inlet port of the first internal cavity and into the second additional combustion chamber through the secondary inlet port of the second internal cavity; andfeeding compressed air to the second additional combustion chamber with the communication between the first and second additional combustion chambers closed includes feeding the compressed air to the second additional combustion chamber through the primary inlet port of the second internal cavity. 10. A method of feeding air to an internal combustion engine having at least first and second internal cavities, the first internal cavity defining at least a first combustion chamber with variable volume, the second internal cavity defining at least a second combustion chamber with variable volume, the method comprising: feeding compressed air to the first combustion chamber while increasing a volume of the first combustion chamber until a maximum volume thereof is reached;while reducing a volume of the first combustion chamber from the maximum volume and while increasing a volume of the second combustion chamber, feeding compressed air from the first combustion chamber into the second combustion chamber;closing a communication between the first and second combustion chambers and further reducing the volume of the first combustion chamber until a minimum volume thereof is reached; andwith the communication between the first and second combustion chambers closed, feeding compressed air to the second combustion chamber while further increasing the volume thereof until a maximum volume thereof is reached. 11. The method as defined in claim 10, wherein the first and second internal cavities each sealingly and rotationally receive a respective rotor therewithin. 12. The method as defined in claim 10, wherein: feeding the compressed air from the first combustion chamber into the second combustion chamber includes feeding the compressed air from the first combustion chamber through a primary inlet port of the first internal cavity and into the second combustion chamber through a secondary inlet port of the second internal cavity; andfeeding the compressed air to the second combustion chamber with the communication between the first and second combustion chambers closed includes feeding the compressed air to the second combustion chamber through a primary inlet port of the second internal cavity. 13. The method as defined in claim 10, wherein the internal combustion engine further includes a third internal cavity defining at least a third combustion chamber with variable volume, the method further comprising: while reducing the volume of the second combustion chamber from the maximum volume thereof and while increasing a volume of the third combustion chamber, feeding compressed air from the second combustion chamber into the third combustion chamber;closing a communication between the second and third combustion chambers and further reducing the volume of the second combustion chamber until a minimum volume thereof is reached; andwith the communication between the second and third combustion chambers closed, feeding compressed air to the third combustion chamber while further increasing the volume thereof until a maximum volume thereof is reached. 14. The method as defined in claim 13, wherein the internal combustion engine further includes a fourth internal cavity defining at least a fourth combustion chamber with variable volume, the method further comprising: while reducing the volume of the third combustion chamber from the maximum volume thereof and while increasing a volume of the fourth combustion chamber, feeding compressed air from the third combustion chamber into the fourth combustion chamber;closing a communication between the third and fourth combustion chambers and further reducing the volume of the third combustion chamber until a minimum volume thereof is reached;with the communication between the third and fourth combustion chambers closed, feeding compressed air to the fourth combustion chamber while further increasing the volume thereof until a maximum volume thereof is reached; andwhile reducing the volume of the fourth combustion chamber from the maximum volume thereof and while increasing a volume of the first combustion chamber, feeding compressed air from the fourth combustion chamber into the first combustion chamber. 15. The method as defined in claim 10, wherein the first internal cavity defines at least a first additional combustion chamber with variable volume, the method further comprising: while reducing the volume of the second combustion chamber from the maximum volume thereof and while increasing a volume of the first additional combustion chamber, feeding compressed air from the second combustion chamber into the first additional combustion chamber;closing a communication between the second combustion chamber and the first additional combustion chamber, and further reducing the volume of the second combustion chamber until a minimum volume thereof is reached; andwith the communication between the second combustion chamber and the first additional combustion chamber closed, feeding compressed air to the first additional combustion chamber while increasing the volume of the first additional combustion chamber until a maximum volume thereof is reached. 16. The method as defined in claim 15, wherein the second internal cavity defines at least a second additional combustion chamber with variable volume, the method further comprising: while reducing the volume of the first additional combustion chamber from the maximum volume thereof and while increasing a volume of the second additional combustion chamber, feeding compressed air from the first additional combustion chamber into the second additional combustion chamber;closing a communication between the first and second additional combustion chambers, and further reducing the volume of the first additional combustion chamber until a minimum volume thereof is reached; andwith the communication between the first and second additional combustion chambers closed, feeding compressed air to the second additional combustion chamber while increasing the volume of the second additional combustion chamber until a maximum volume thereof is reached;wherein feeding the compressed air to the first combustion chamber while increasing the volume of the first combustion chamber until the maximum volume thereof is reached includes: feeding compressed air from the second additional combustion chamber into the first combustion chamber while reducing the volume of the second additional combustion chamber of from the maximum volume thereof and while increasing the volume of the first combustion chamber,closing the communication between the second additional combustion chamber and the first combustion chamber, andwith the communication between the second additional combustion chamber and the first combustion chamber closed, feeding compressed air to the first combustion chamber while further increasing the volume thereof until the maximum volume thereof is reached. 17. The method as defined in claim 16, wherein: feeding compressed air from the second additional combustion chamber into the first combustion chamber includes feeding the compressed air from the second additional combustion chamber through a primary inlet port of the second internal cavity and into the first combustion chamber through a secondary inlet port of the first internal cavity;feeding compressed air to the first combustion chamber with the communication between the second additional combustion chamber and the first combustion chamber closed includes feeding the compressed air to the first combustion chamber through a primary inlet port of the first internal cavity;feeding compressed air from the first combustion chamber into the second combustion chamber includes feeding the compressed air from the first combustion chamber through the primary inlet port of the first internal cavity and into the second combustion chamber through a secondary inlet port of the second internal cavity;feeding compressed air to the second combustion chamber with the communication between the first and second combustion chambers closed includes feeding the compressed air to the second combustion chamber through the primary inlet port of the second internal cavity;feeding compressed air from the second combustion chamber into the first additional combustion chamber includes feeding the compressed air from the second combustion chamber through the primary inlet port of the second internal cavity and into the first additional combustion chamber through the secondary inlet port of the first internal cavity;feeding compressed air to the first additional combustion chamber with the communication between the second combustion chamber and the first additional combustion chamber closed includes feeding the compressed air to the first additional combustion chamber through the primary inlet port of the first internal cavity;feeding compressed air from the first additional combustion chamber into the second additional combustion chamber includes feeding the compressed air from the first additional combustion chamber through the primary inlet port of the first internal cavity and into the second additional combustion chamber through the secondary inlet port of the second internal cavity; andfeeding compressed air to the second additional combustion chamber with the communication between the first and second additional combustion chambers closed includes feeding the compressed air to the second additional combustion chamber through the primary inlet port of the second internal cavity.
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이 특허에 인용된 특허 (18)
Coleman, Gerald N.; Duffy, Kevin P.; Faulkner, Stephen A.; Fluga, Eric C.; Kilkenny, Jonathan P.; Leman, Scott A.; Opris, Cornelius N.; Verkiel, Maarten; Weber, James R., Air and fuel supply system for combustion engine.
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