RU2382225C1 - Liquid propellant rocket engine - Google Patents

Abstract

FIELD: engines and pumps.

SUBSTANCE: invention relates to rocket engine production and can be used in development of generatorless liquid propellant engines running on cryogenic components, for example oxygen and hydrogen. Liquid propellant engine comprises circular chamber with mixing head, external expansion plate nozzle, shaped central body and circular critical section, gas generator, control and feed units comprising turbopump unit with turbine and fuel component feed pumps arranged in said shaped central body chamber. In compliance with this invention, said shaped central body consists of several parts. Note here that at least one said part is made to effect radial axisymmetric revolution around shaped central body lengthwise axis and is articulated with feed units. Blades are arranged on its outer surface for aforesaid part to rotate. Note also that outlet zone of fixed part, adjoining movable part, has channels communicated with fuel feed system and open to fixed part shaped surface.

EFFECT: higher specific thrust pulse, simplified pneumohydraulic circuit and increased chamber pressure at minimum overall dimensions.

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Description

The invention relates to the field of rocket propulsion and can be used to create generatorless liquid rocket engines running on cryogenic components, such as oxygen and hydrogen.

Currently, one of the main problems in creating liquid-propellant rocket engines is to obtain a high specific thrust impulse while reducing the overall dimensions of the chamber, in particular the nozzle. One of the ways to ensure a sufficiently high specific thrust impulse while reducing the overall dimensions of the chamber is to use ring nozzles instead of ordinary round Laval nozzles. The difference between the Laval nozzle and the annular one is that the annular nozzle has a critical cross-sectional shape not circular, but circular. Annular nozzles allow you to increase the area of the outlet section of the nozzle and place part of the units in the Central part, which leads to a decrease in the linear dimensions of the engine.

A well-known schematic diagram of the annular chamber of a liquid propellant rocket engine that implements this principle (A.P. Vasiliev and others. Fundamentals of the theory and calculation of liquid propellant rocket engines. Moscow, "Higher School", 1967, Fig. X. 186).

A liquid-propellant rocket engine is known, comprising an annular chamber with a mixing head, an external expansion disk nozzle, a profiled central body and an annular critical section, control units and power units including a turbopump unit with a turbine located in the cavity of the profiled central body (M.V.Dobrovolsky and etc. Liquid rocket engines. Fundamentals of design. Moscow, "Higher School", 1968, Fig. 2.32, p. 59 - prototype).

The specified engine operates as follows. The fuel components are fed into the mixing head, ignited and expire through the annular critical section. In a disk-shaped nozzle of external expansion, the combustion products expand, the external boundary of expansion being determined by atmospheric pressure, and the internal boundary by the contour of the profiled central body. The products of combustion with supersonic speed go to the cutting nozzle plate. To supply fuel components to the mixing head, a turbopump unit is used, the turbine of which is driven by a stream of gases flowing from the gas generator.

The main disadvantages of this engine are the significant diametric dimensions and the complexity of the pneumohydraulic circuit, due to the fact that a turbopump unit is used to supply fuel components to the mixing head, the turbine of which is driven by a stream of gases flowing from the gas generator. The use of a gas generator necessitates the organization of pipelines for supplying fuel components to the gas generator, the use of a special stage in a turbopump unit or special pumps for supplying fuel components with increased pressure to the mixing head of the gas generator, which ultimately leads to an increase in mass and deterioration of the overall dimensions of the engine.

The objective of the invention is to eliminate these drawbacks and the creation of a liquid rocket engine, the design of which allows for a sufficiently high value of the specific impulse of thrust, to simplify the pneumohydraulic circuit and realize a much greater pressure in the chamber with a minimum overall dimensions.

The problem is achieved in that in the proposed liquid propellant rocket engine containing an annular chamber with a mixing head, a disk nozzle of external expansion, a profiled central body and an annular critical section, a gas generator, control units and power units, including a turbopump unit with a turbine and pumps for supplying fuel components located in the cavity of the profiled central body, according to the invention, the profiled central body is made up of several x parts, while at least one part of the profiled central body is made with the possibility of axisymmetric radial rotation around the longitudinal axis of the profiled central body, kinematically connected with power units, blades are installed on its outer surface to give it rotational movement, and in the outlet zone fixed part adjacent to the movable, made channels connected to the fuel supply system and opening to the profiled surface of the fixed part.

The invention is illustrated in the drawing, which shows an axial section of the proposed engine.

The engine consists of an annular chamber 1 with a mixing head 2 and a disk nozzle 3 of external expansion with an annular critical section 4. The inner surface of the nozzle 3 forms a profiled central body 5, consisting of at least two parts - a stationary 6 and a movable 7. Movable part 7 of the profiled central body 5 is made with the possibility of radial axisymmetric rotation around the longitudinal axis of the profiled central body and is kinematically connected with the turbopump assembly 8, and on its external rotation Nost installed blade 9 to impart rotational motion.

In the cavity of the profiled central body 5, control units 10 and power units are installed, including a turbopump unit 8 with pumps for supplying components to the mixing head 2, kinematically connected with the moving part 7 of the central body 5. In the output zone of the fixed part 6 of the central body 5, adjacent to the moving 7, channels 11 are made, connected to the fuel supply system and opening onto the profiled surface of the stationary part 6.

The proposed device operates as follows.

The initial start of the engine is carried out by applying to the blades 9 a movable part 7 of the central body, which plays the role of a turbine of a turbopump assembly, a jet of pyrozapalnik gases or gases from a special cylinder for spinning a turbine.

The fuel components are fed into the mixing head 2, ignited and expire through the annular critical section 4. In the disk nozzle of the external expansion, the combustion products expand, the external expansion boundary being determined by atmospheric pressure and the internal boundary by the contour of the profiled central body. The products of combustion with supersonic speed go to the cut of the poppet nozzle 3 and flow around the blades 9 mounted on the movable part 7 of the central body 5. The movable part 7 of the central body begins to rotate around the axis of the central body and rotates the pumps for the supply of fuel components of the turbopump unit 8, which feed the fuel components to the mixing head 2.

The combustion products falling on the blades 9 of the movable part 7 of the central body 5 have a sufficiently high temperature, which affects the performance of the blades and reduce their service life. To reduce the temperature of the combustion products entering the blades 9, through the channels 11 connected to the fuel supply system and opening onto the profiled surface of the stationary part 6, a part of the fuel flow rate having a significantly lower temperature than the temperature of the combustion products is supplied. The supply of fuel leads to a decrease in the temperature of the combustion products, which makes it possible to increase the durability of the blades and improve their working conditions.

Using the proposed technical solution will simplify the pneumohydraulic circuit of the engine and improve its overall dimensions.

Claims (1)

A liquid-propellant rocket engine comprising an annular chamber with a mixing head, an external expansion disk nozzle, a profiled central body and an annular critical section, a gas generator, control units, and power units, including a turbopump unit with a turbine and fuel component supply pumps located in the cavity of the profiled central body, characterized in that the profiled central body is made up of several parts, with at least one part of the profiles of this central body is made with the possibility of radial axisymmetric rotation around the longitudinal axis of the profiled central body, kinematically connected with power units, blades are installed on its outer surface to give it rotational movement, and in the outlet zone of the fixed part adjacent to the moving one, channels are connected to fuel supply system and opening onto the profiled surface of the fixed part.

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