A constant volume combustion chamber, combustor, and method for constant volume combustion involve combusting a fuel in a chamber sealed by a pintle having a conical portion fitted into a conical nozzle throat and pulling the pintle away from the nozzle throat to allow combustion products to exhaust
A constant volume combustion chamber, combustor, and method for constant volume combustion involve combusting a fuel in a chamber sealed by a pintle having a conical portion fitted into a conical nozzle throat and pulling the pintle away from the nozzle throat to allow combustion products to exhaust through a nozzle outlet. The shapes and surfaces of the pintle and nozzle throat provide for sealing the chamber at high pressures while resisting surface wear. Operational parameters for the combustor may be computer controlled in response to measured pressures and temperatures in the combustor.
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1. A constant volume combustion chamber comprising: an inlet configured to receive a propellant and an outlet comprising a conically shaped nozzle throat and a nozzle outlet configured to allow combustion products to exit the constant volume combustion chamber;a pintle head having a longitudinal axi
1. A constant volume combustion chamber comprising: an inlet configured to receive a propellant and an outlet comprising a conically shaped nozzle throat and a nozzle outlet configured to allow combustion products to exit the constant volume combustion chamber;a pintle head having a longitudinal axis and comprising a conical sealing portion configured to contact the conically shaped nozzle throat;actuation means mechanically coupled to the pintle head and configured for moving said pintle head into and out of contact with the conically shaped nozzle throat;a thermocouple configured to measure temperature in the constant volume combustion chamber; anda pressure transducer configured to measure pressure in the constant volume combustion chamberwherein:the conically shaped nozzle throat comprises an inner throat seat surface configured to form a pressure tight seal when contacted with the conical sealing portion of the pintle head;the conically shaped nozzle throat and conical sealing portion of the pintle head have diameters that taper from an internal volume of the constant volume combustion chamber toward the nozzle outlet with a taper angle of between 30° and 7°;the conical sealing portion of the pintle head comprises a sealing surface configured to seal against the inner throat seat surface to seal the constant volume combustion chamber;the actuation means configured to alternately move the pintle head so as to seal or open the constant volume combustion chamber; andthe roughness of the sealing surface of the pintle head and/or the inner throat seat surface is from 16 microinches to 64 microinches. 2. The constant volume combustion chamber of claim 1, and further comprising: a fuel injector, an oxidizer injector, a fuel valve configured to control fuel flow into the constant volume combustion chamber, an oxidizer valve configured to control oxidizer flow into the constant volume combustion chamber, and means for igniting a mixture of fuel and oxidizer. 3. The constant volume combustion chamber of claim 2, and further comprising a computer controller coupled to the fuel injector, oxidizer injector, actuation means, and means for igniting a mixture of fuel and oxidizer. 4. The constant volume combustion chamber of claim 2, wherein the constant volume combustion chamber comprises an injector-pintle section, a combustion chamber section, and a nozzle section assembled to comprise said constant volume combustor wherein: the injector-pintle section comprises: the fuel injector, the oxidizer injector, the fuel valve, the oxidizer valve, and the actuation means;the combustion chamber section comprises walls enclosing a volume in which fuel and oxidizer mix and are combusted; andthe nozzle section comprises a replaceable impact seal comprising said conically shaped nozzle throat and a nozzle outlet. 5. The constant volume combustion chamber of claim 1, wherein the conically shaped nozzle throat and a distal nozzle outlet are embodied as a replaceable impact seal comprising said conically shaped nozzle throat and a nozzle outlet. 6. The constant volume combustion chamber of claim 1, wherein the actuation means is selected from the group consisting of pneumatic, electric, mechanical, and hydraulic means. 7. The constant volume combustion chamber of claim 1, wherein the pintle head comprises an extension that extends through the nozzle outlet. 8. The constant volume combustion chamber of claim 1, wherein the taper angle of the outlet matches the taper angle of the conical sealing portion of the pintle head. 9. A valve for controlling the flow of a fluid, said valve comprising: a chamber comprising a fluid inlet, a fluid outlet; and a pintle head mechanically coupled to an actuation means for moving said pintle head by a set travel distance into and out of contact with the fluid outlet wherein:said outlet comprises a conically-shaped throat having a maximum inner diameter and a minimum inner diameter and a taper angle,said pintle head comprises a conical portion configured to seal against said conically-shaped throat to close the fluid outlet,said actuation means configured to move the pintle head by the set travel distance to alternately seal against the conically-shaped throat such that the valve is closed and to separate from the conically-shaped throat by said set travel distance,the conically-shaped throat and conical portion of the pintle head have diameters that taper with a taper angle of between 30° and 7°, andthe conically-shaped portion of the pintle head and the conically-shaped throat have surfaces with a roughness of between 16 microinches to 64 microinches. 10. The valve of claim 9, wherein the actuation means is selected from the group consisting of computer-controlled pneumatic, electric, mechanical, and hydraulic means, and is configured to open and close the valve. 11. The valve of claim 9, wherein said chamber is a combustion chamber, said fluid entering through the fluid inlet is an oxidizer and/or a fuel, and said fluid exiting through the fluid outlet comprises combustion products. 12. The valve of claim 9, wherein the taper angle of the fluid outlet matches the taper angle of the conical portion of the pintle head. 13. A valve for controlling the flow of a fluid, said valve comprising: a chamber comprising a fluid inlet, a fluid outlet; and a pintle head mechanically coupled to an actuation means for moving said pintle head by a set travel distance into and out of contact with the fluid outlet wherein:said outlet comprises a conically-shaped throat having a maximum inner diameter and a minimum inner diameter and a taper angle,said pintle head comprises a conical portion configured to seal against said conically-shaped throat to close the fluid outlet,said actuation means configured to move the pintle head by the set travel distance to alternately seal against the conically-shaped throat such that the valve is closed and to separate from the conically-shaped throat by said set travel distance,the conically-shaped throat and conical portion of the pintle head have diameters that taper with a taper angle of between 30° and 7°, andthe taper angle of the fluid outlet matches the taper angle of the conical portion of the pintle head. 14. The valve of claim 13, wherein the actuation means is selected from the group consisting of computer-controlled pneumatic, electric, mechanical, and hydraulic means, and is configured to open and close the valve. 15. The valve of claim 13, wherein said chamber is a combustion chamber, said fluid entering through the fluid inlet is an oxidizer and/or a fuel, and said fluid exiting through the fluid outlet comprises combustion products.
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