Rocket engine and method for controlling combustion in the rocket engine itself
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F02K-009/58
F02K-009/56
출원번호
US-0975945
(2010-12-22)
등록번호
US-8887483
(2014-11-18)
우선권정보
IT-TV2009A0238 (2009-12-23)
발명자
/ 주소
Petronio, Dino
출원인 / 주소
Selex Galileo S.p.A.
대리인 / 주소
Jenkins, Wilson, Taylor & Hunt, P.A.
인용정보
피인용 횟수 :
0인용 특허 :
4
초록▼
Supply of a liquid component in a combustion chamber of a rocket engine is controlled by a feed valve provided with slide valve mobile between an open position and a closed position of at least one supply pipe, which has an inlet that communicates with a tank for containing the liquid component and
Supply of a liquid component in a combustion chamber of a rocket engine is controlled by a feed valve provided with slide valve mobile between an open position and a closed position of at least one supply pipe, which has an inlet that communicates with a tank for containing the liquid component and an outlet that communicates with the combustion chamber. The displacement of the slide valve from its closed position to its open position is triggered by a pressurized fluid supplied to the outlet of the supply pipe.
대표청구항▼
1. A rocket engine comprising: a combustion chamber for combustion of two components, of which one is a fuel and the other is a comburent and of which at least one is in an initial liquid state;an exhaust nozzle disposed at one end of the combustion chamber for discharging combustion products from t
1. A rocket engine comprising: a combustion chamber for combustion of two components, of which one is a fuel and the other is a comburent and of which at least one is in an initial liquid state;an exhaust nozzle disposed at one end of the combustion chamber for discharging combustion products from the combustion chamber;an injection head disposed at another or at an opposite end of the combustion chamber, the injection head comprising an injection plate having a plurality of holes to enable fluid communication between the injection head and a frustoconical intake chamber;a feed valve interposed between a container tank and the combustion chamber to control a supply of the liquid component from the container tank to the combustion chamber, wherein the feed valve comprises: a tubular valve body defining the frustoconical intake chamber disposed on one end of the feed valve,a sliding cylinder defined by the tubular valve body and having a longitudinal axis, the sliding cylinder comprising a restricted portion, a widened portion and an annular end stop shoulder defined between the restricted portion and the widened portion,at least one inlet for the liquid component to move into the sliding cylinder,an outlet for the liquid component to move from the sliding cylinder into the combustion chamber,a slide valve slidably engaged in the sliding cylinder, the slide valve comprising an annular end flange projecting radially outwards from an outer surface of the slide valve, anda spring, at least a portion of which is disposed within a portion of the slide valve, the spring acting axially on a first side of the slide valve to move and retain the slide valve into a closed position to close the inlet, wherein the slide valve is stopped in the closed position by engagement of the flange with the end stop shoulder; anda primer device mounted through a side wall of the combustion chamber and projecting within to supply a pressurized fluid acting axially on a second side of the slide valve, the second side being opposite to the first side, to move the slide valve against the action of the spring from the closed position into a first open position, where the inlet is partially open for enabling the liquid component to enter the sliding cylinder, to axially act on the second side against the action of the spring, and to move the slide valve from the first open position to a second open position, where the inlet is completely open;wherein the spring is shaped so as to exert on the first side of the slide valve a thrust lower than a thrust exerted by the pressurized fluid on the second side of the slide valve. 2. The rocket engine according to claim 1, wherein the primer device comprises at least one pyrogenic primer to supply the pressurized fluid. 3. The rocket engine according to claim 1, wherein the spring is an elastic thrust spring. 4. The rocket engine according to claim 1, wherein the sliding cylinder is laterally limited by a first side wall extending about the longitudinal axis, the inlet being made through the first side wall. 5. The rocket engine according to claim 1, wherein the outlet is substantially coaxial of the longitudinal axis. 6. The rocket engine according to claim 1, further comprising a gasket inserted between the slide valve and the sliding cylinder to separate in a fluid-tight manner the inlet from the outlet when the slide valve is arranged in the closed position. 7. The rocket engine according to claim 1, wherein the injection head faces the sliding cylinder. 8. The rocket engine according to claim 7, wherein the injection plate faces the outlet. 9. The rocket engine according to claim 1, wherein the combustion of the fuel with the comburent generates within the combustion chamber a first pressure higher than a second pressure generated within the combustion chamber by the pressurized fluid, the combustion chamber further comprising a member for closing the exhaust nozzle, which is shaped so as to break when pressure in the combustion chamber is at least equal to the first pressure. 10. The rocket engine according to claim 1, wherein the combustion chamber is limited by a second side wall. 11. A method to control combustion in a rocket engine, the rocket engine comprising a combustion chamber for combustion of two components, of which one is a fuel and the other is a comburent and of which at least one is in an initial liquid state, an exhaust nozzle disposed at one end of the combustion chamber for discharging combustion products from the combustion chamber; an injection head disposed at another or at an opposite end of the combustion chamber, the injection head comprising an injection plate having a plurality of holes to enable fluid communication between the injection head and a frustoconical intake chamber, a feed valve interposed between the container tank and the combustion chamber to control a supply of the liquid component from the container tank to the combustion chamber, wherein the feed valve comprises: a tubular valve body defining the frustoconical intake chamber disposed on one end of the feed valve, a sliding cylinder defined by the tubular valve body and having a longitudinal axis, the sliding cylinder comprising a restricted portion, a widened portion and an annular end stop shoulder defined between the restricted portion and the widened portion, at least one inlet for the liquid component to move into the sliding cylinder, an outlet for the liquid component to move from the sliding cylinder into the combustion chamber, and a slide valve slidably engaged in the sliding cylinder, the slide valve comprising an annular end flange projecting radially outwards from an outer surface of the slide valve, the method comprising: displacing the slide valve into a closed position to close the inlet and retain the slide valve in the closed position, via a spring, at least a portion of which is disposed within a portion of the slide valve, the spring acting axially on a first side of the slide valve,stopping the slide valve in the closed position by engaging the flange with the end stop shoulder;supplying a pressurized fluid from a primer device mounted through a side wall of the combustion chamber and projecting within, the pressurized fluid acting axially on a second side of the slide valve, the second side being opposite to the first side;moving the slide valve against the action of the spring from the closed position into a first open position, where the inlet is partially open for enabling the liquid component to enter the sliding cylinder and to act axially on the second side against the action of the spring; andmoving the slide valve from the first open position into a second open position, where the inlet is completely open, wherein the spring is shaped so as to exert on the first side of the slide valve a thrust lower than a thrust exerted by the pressurized fluid on the second side of the slide valve. 12. The method according to claim 11, wherein moving the slide valve from the closed position to the first open position is triggered by at least one pyrogenic primer of the primer device to supply the pressurized fluid. 13. The method according to claim 11, wherein moving the slide valve from the closed position into the first open position is accomplished in a first time interval, and moving the slide valve from the first open position into the second open position is accomplished in a second time interval shorter than the first time interval. 14. The method according to claim 11, further comprising moving the slide valve, after the container tank is emptied, from the second open position to the closed position starting from a time in which pressure at the outlet is substantially equal to a first threshold value such as to exert on the second side of the slide valve the thrust lower than the thrust exerted on the first side of the slide valve by the spring. 15. The method according to claim 14, further comprising moving the slide valve from the second open position into a third open position, where the inlet is partially closed, when a total section of passage defined by the plurality of holes is substantially equal to a total section of passage defined by the inlet and the pressure at the outlet is substantially equal to a second threshold value lower than the first threshold value. 16. The method according to claim 15, further comprising moving the slide valve from the third open position into the closed position when the pressure at the outlet is lower than the second threshold value. 17. The method according to claim 15, wherein moving the slide valve from the second open position into the third open position is accomplished in a third time interval, and moving the slide valve from the third open position into the closed position is accomplished in a fourth time interval shorter than the third time interval. 18. The method according to claim 11, further comprising closing the exhaust nozzle with a closing member shaped so as to break when pressure in the combustion chamber is at least equal to a first pressure, wherein the combustion of the fuel with the comburent generates within the combustion chamber the first pressure, which is higher than a second pressure generated within the combustion chamber by the pressurized fluid. 19. A rocket engine comprising: a combustion chamber limited by a second side wall for combustion of two components, of which one is a fuel and the other is a comburent and of which at least one is in an initial liquid state, wherein the combustion of the fuel with the comburent generates within the combustion chamber a first pressure, which is higher than a second pressure generated within the combustion chamber by a pressurized fluid;an exhaust nozzle disposed at one end of the combustion chamber for discharging combustion products from the combustion chamber;an injection head disposed at another or at an opposite end of the combustion chamber, the injection head comprising an injection plate having a plurality of holes to enable fluid communication between the injection head and a frustoconical intake chamber;a member disposed in the combustion chamber for closing the exhaust nozzle and shaped to break when pressure in the combustion chamber is at least equal to the first pressure;a feed valve interposed between a container tank and the combustion chamber to control a supply of the liquid component from the container tank to the combustion chamber, wherein the feed valve comprises: a tubular valve body defining the frustoconical intake chamber disposed on one end of the feed valve,a sliding cylinder defined by the tubular valve body and having a longitudinal axis, the sliding cylinder comprising a restricted portion, a widened portion and an annular end stop shoulder defined between the restricted portion and the widened portion, and being laterally limited by a first side wall extending about the longitudinal axis, wherein the sliding cylinder is faced by the injection head,at least one inlet made through the first side wall for the liquid component to move into the sliding cylinder,an outlet substantially coaxial with the longitudinal axis for the liquid component to move from the sliding cylinder into the combustion chamber, wherein the outlet is faced by the injection plate,a slide valve slidably engaged in the sliding cylinder, the slide valve comprising an annular end flange projecting radially outwards from an outer surface of the slide valve,an elastic thrust spring, at least a portion of which is disposed within a portion of the slide valve, the elastic thrust spring acting axially on a first side of the slide valve to move and retain the slide valve into a closed position to close the inlet, wherein the slide valve is stopped in the closed position by engagement of the flange with the end stop shoulder, anda gasket inserted between the slide valve and the sliding cylinder to separate in a fluid-tight manner the inlet from the outlet when the slide valve is arranged in the closed position; anda primer device comprising at least one pyrogenic primer mounted through the second side wall and projecting within the combustion chamber to supply the pressurized fluid acting axially on a second side of the slide valve, the second side being opposite to the first side, to move the slide valve against the action of the elastic thrust spring from the closed position into a first open position, where the inlet is partially open for enabling the liquid component to enter the sliding cylinder, to axially act on the second side against the action of the elastic thrust spring, and to move the slide valve from the first open position to a second open position, where the inlet is completely open;wherein the elastic thrust spring is shaped so as to exert on the first side of the slide valve a thrust lower than a thrust exerted by the pressurized fluid on the second side of the slide valve.
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이 특허에 인용된 특허 (4)
Oda Noriyuki (Osaka JA) Yoshida Takashi (Osaka JA) Nakanishi Takeshi (Osaka JA) Yoshikawa Kensuke (Osaka JA), Apparatus for generating high-pressure gas.
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