RU2392477C1 - Liquid-propellant engine annular chamber - Google Patents

Abstract

FIELD: engines and pumps.

SUBSTANCE: invention refers to rocket engine building industry and can be used during development of alternator-free liquid propellant engines operating on cryogenic components, e.g. oxygen and hydrogen. Annular chamber of liquid-propellant engine includes annular mixing head, regeneratively cooled annular combustion chamber with plate nozzle of external expansion, and shaped central body, which are formed with shaped internal and external covers attached to each other along cooling circuit ribs. Between ribs of cooling circuit there are hollow connection straps attaching tops of ribs to each other; at that, external profile of the above connection straps corresponds to profile of cooling circuit. In order to increase the cover stability, connection straps attach the tops of two adjacent ribs to each other, connection straps attach the tops of all ribs to each other so that common annular surface is formed, and the external profile of which is equally spaced relative to internal profile of external cover at point of contact with external surface of internal cover.

EFFECT: increasing stability of internal cover.

3 cl, 3 dwg

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 the usual 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 circuit 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.

In this annular chamber, the cooler is fed into the cooling paths of the disk nozzle and the profiled central body, formed by the corresponding inner shells, on the outer surface of which there are ribs, which together with the outer shells form the channels of the cooling path, moves along the grooves between the ribs and cools, thus, the working surfaces profiled shells. Due to the connection of the shells with each other only along the tops of the ribs, when the pressure in the cooling path increases above a predetermined limit, the strength and stability of the inner shells are not ensured, which leads to a loss of operability of the annular chamber.

The objective of the invention is to remedy these disadvantages and create an annular chamber of the rocket engine, the design of which allows to increase the stability of the inner shell and realize significantly greater pressure in the chamber with a minimum overall dimensions.

The problem is achieved in that in the proposed annular chamber of a liquid propellant rocket engine containing an annular mixing head, regeneratively cooled annular combustion chamber with a disk nozzle of external expansion and a profiled central body formed by profiled inner and outer shells fastened together along the edges of the cooling path, according to the invention, between the ribs of the cooling path made hollow jumpers connecting the tops of the ribs with each other, while the outer The th profile of these jumpers corresponds to the profile of the cooling path.

To optimize the operating conditions of the inner shell, the jumpers are made in such a way that they connect the vertices of two adjacent ribs to each other. This arrangement of jumpers allows you to get additional contact points between the inner and outer shells, which leads to a decrease in the length of non-supported sections of the tract.

The most optimal conditions for the operation of the chamber are achieved when the jumpers connect the vertices of all the ribs together to form a single annular surface, the outer profile of which is equidistant to the inner profile of the outer shell at the point of contact with the outer surface of the inner shell.

In this case, the annular surfaces of the lintels form additional stiffeners, which increase the stability of the shell when exposed to pressure of the cooler in the grooves of the cooling path. In addition, the annular surface of the jumper allows you to increase the surface area for soldering without increasing the thickness of the ribs and increasing the pressure drop in the path, reduce several times the length of the unsupported part of the ribs due to the formation of additional supports.

The invention is illustrated by drawings, where figure 1 shows a longitudinal axial section of the annular chamber of the rocket engine, figure 2 - part of the cooling path with jumpers in a perspective view.

The annular chamber of the liquid propellant rocket engine contains a regeneratively cooled annular combustion chamber 1 with a mixing head 2 and a disk nozzle 3 of external expansion with an annular critical section 4. The cooling path of the cooled parts, for example, a disk nozzle 3, is formed by an inner shell 5, on the outer surface of which ribs 6 are formed, forming together with the corresponding outer shell 7 cooling channels 8. The tops of the ribs 6 are interconnected using hollow jumpers 9.

The proposed device operates as follows.

The components of the fuel are fed into and out of the mixing head 2 through nozzles into an annular combustion chamber 1, where they ignite. The components of the fuel flow out through the critical annular cross section and enter the inlet of the poppet nozzle 3. In the poppet nozzle 3 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, and with supersonic speed they arrive at the disk section nozzles.

The cooler is fed into the cooling path, moves along the channels 8 between the ribs 6 and cools, for example, the firing surface of the inner profiled shell 5 of the disk nozzle 4. By connecting the shells to each other not only along the tops of the ribs 6, but also along the additional surfaces of the hollow jumpers 9, there is an increase in the stability and strength of the inner shell 5. The increased stability and strength of the inner shell 5 allows you to increase the pressure in the cooling path of the chamber and in the chamber itself, which ultimately allows to increase it workflow efficiency.

Using the proposed technical solution will improve the stability of the inner shell and increase the strength of the annular chamber of the rocket engine as a whole.

Claims (3)

1. An annular chamber of a liquid-propellant rocket engine, comprising an annular mixing head, regeneratively cooled annular combustion chamber with a disk nozzle of external expansion and a profiled central body formed by profiled inner and outer shells fastened together along the edges of the cooling path, characterized in that between the edges of the path cooling, hollow jumpers are made connecting the tops of the ribs with each other, while the outer profile of these jumpers corresponds to the profile of cooling act. 2. The annular chamber of a liquid propellant rocket engine according to claim 1, characterized in that the jumpers connect the vertices of two adjacent ribs to each other. 3. The annular chamber of a liquid propellant rocket engine according to claim 1, characterized in that the jumpers connect the vertices of all the ribs together to form a single annular surface, the outer profile of which is equidistant to the inner profile of the outer shell at the point of contact with the outer surface of the inner shell.

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