RU2588343C1 - Method for simulating process of combustion of products of gasification of liquid rocket fuel component residues and device therefor - Google Patents

Abstract

FIELD: rocket science.

SUBSTANCE: invention relates to aerospace engineering, particularly, to simulation of combustion process of gasification products of unspent residues of liquid components of rocket fuel in tanks of spent stage carrier rocket. Method for simulating, involving introduction to experimental installation of gasification products from every tank, ignition of working mixture, measuring parameters of process, according to invention in simulating combustion process of gasification products of oxidant, analysed composition is prepared by mixing of gaseous oxidant, steam and helium, and when simulating process of combustion of fuel gasification products, analysed composition is prepared by mixing gaseous fuel and helium. Device for implementing method comprises a header, experimental tank, fuel component feed line, wherein it includes cylinders filled with products of gasification of fuel components and connected via controlled valves and throttles with collector, ignition system of gasification products.

EFFECT: invention provides expansion of experimental research methods for combustion of complex compositions, as well as reduction of costs of experimental investigations.

2 cl, 1 dwg

Description

The invention relates to rocket and space technology and can be used to conduct physical modeling in ground conditions in experimental installations (EI) of the process of burning gasification products (GH) of residues of liquid components of rocket fuel (SRT) extracted from the fuel tanks of spent stages of launch vehicles ( LV), after turning off the marching liquid propellant rocket engine (LRE), by supplying hot gases to the tanks during a passive flight.

There is a method of burning gasified SRT in LRE type "gas + gas", shown, for example, on page 14 in [1] book. "Fundamentals of the theory and calculation of liquid rocket engines" A.P. Vasiliev, V.M. Kudryavtsev, V.A. Kuznetsov et al., Ed. V.M. Kudryavtseva. - 4th ed. reslave. and additional.- M .: Higher. Shk., 1993 - 383 pp., based on the use of the gasification process of SRT in special gas generators, one of which produces reducing and the other oxidizing gases with the subsequent supply of these gases to the combustion chamber of the main rocket engine. The chemical compositions of gasified SRT and GHGs are significantly different.

The use of a similar method and device that implements it for laboratory modeling in the ground conditions of GHG combustion processes is associated with the development of special additional equipment.

Closest to the technical nature of the proposed technical solution is a method for simulating combustion of SRT, described on pages 163-164 in [2] book. “Reducing the technogenic impact of rocket launch vehicles on liquid toxic components of rocket fuel on the environment” (monograph edited by V.I. Trushlyakov, Omsk: OmSTU Publishing House, 2004 - 220 pp.), Which simulates the combustion of self-igniting SRT.

The implementation of the method is carried out by feeding atomized asymmetric dimethylhydrazine to the EU, in which there is another SRT - AK-27I (nitric acid 69.8% and 24-28% nitrogen tetraxide). A certain amount of AK-27I is located in the EU in the gas phase; as a result of the interaction of these self-igniting MCTs, heat is released in the gas phase, which leads to intensive evaporation (gasification) of both MCTs and their further combustion. In the process of modeling the combustion process, temperatures and the composition of the combustion products were determined.

The disadvantage of this method when applied to the study of GHG combustion processes extracted from fuel tanks is that the chemical composition of the GHG and the composition of the SRT are significantly different. This is due to the fact that after the marching liquid propellant rocket is turned off, the undeveloped SRT residues are gasified in each tank of the spent LV stage by supplying hot gases (heat carriers (TH)) there, for each tank, its optimal VT with the corresponding chemical and physico-technical properties is determined. As a result of supplying a VT to each fuel tank, a GHG is obtained, which includes evaporated SRT + boost gas, for modern LVs it is helium + corresponding to VT. The study of the obtained GHGs, the selection of the optimal VT for each SRT is a research task during the GHG burning process in the electric power plant, for example, for their subsequent utilization by burning in a gas rocket engine to develop maneuvers for launching the spent LV stages from orbits and launch trajectories.

In [3] US Pat. RU 2518918 F02K 9/42, B64G 1/26 are examples of gasification, the use of a gas rocket engine (GZRD) for maneuvers of the method of removal of the separated (spent) stages of the LV from orbits and launch trajectories.

The claimed technical solution is aimed at expanding experimental methods for researching GHG combustion into more complex compositions, reducing costs during experimental research, the possibility of using the experimental base not only for scientific but also for educational purposes.

The specified technical result is achieved due to the fact that in the method for simulating the process of burning unspent SRT residues in the tanks of the spent PH stage, for example, oxygen and kerosene, including introducing gasification products from each tank into the experimental setup, carrying out measurements of the process parameters according to the claimed invention during modeling the process of burning gasification products from an oxidizer tank (GHG _ok ), which are prepared by mixing, a gaseous oxidizer, such as oxygen, Ars water and helium, and the gasification products of the fuel tank (PG _mountains) is prepared by mixing the coolant, the gaseous fuel, such as kerosene and helium in concentrations corresponding to preliminary analytical estimations.

Various compositions can be used as a heat carrier for gasification of kerosene, the selection criteria of which are the parameters of the combustion process, for example, temperature.

The technical result in terms of the device is achieved due to the fact that the device according to [2], which includes a collector, an experimental tank, and SRT supply lines, additionally introduces cylinders filled with SRT gasification products, for example, oxygen and kerosene, and connected through adjustable valves , and manifold chokes, ignition system for gasification products.

Given the fact that the concentration of the constituents in the GHG is _ok , the GHG of the _mountains varies in time, the adjustable valves installed on each cylinder at each moment of time provide the corresponding second mass flow rate of the components of the _{mountains of} TH, TH _approx .

The achievement of the goals is ensured as follows.

In [4], Art. Trushlyakov V.I., Lempert D.B., Belkova M.E., Study of the possibility of evaporation of liquid fuel residues in tanks of rocket stages // Omsk Scientific Bulletin. - 2014, No. 2 (130), p. 52-57, the choice of gas-generating compositions (GHS) for obtaining VT of _mountains , TN _{ok is considered} on the example of an oxygen oxidizer and combustible kerosene from the conditions of the effectiveness of the active on-board system for lowering the spent LV stage, which includes a gasification system for undeveloped SRT residues, for example, the maximum the impulse received due to GHG combustion _ok , GHG _mountains .

It has been shown that the most acceptable composition of TH _ok for oxygen is the products of the pyrolysis of hydrogen peroxide, therefore, in the composition of the GH _{ok there} will be water vapor, gasified oxygen and helium.

Possible HGSs for producing TN _mountains is a fairly wide range: numerous solid fuel compositions, liquid, including oxygen-kerosene, “hydrogen peroxide-kerosene” fuel pairs, hybrid.

The composition of the GHGs of the _mountains , the GHGs _ok according to the time of the flight of the spent LV stage will be variable and determined by the conditions of the gasification process in the tanks, including the boundary conditions of liquid MCT in the tanks (evaporation surface area), the flight conditions of the spent LV stage (gravity, external thermal effect) etc.).

In [5], Art. Shalai VV, Kudentsov V.Yu., Trushlyakov VI, Modeling of heat and mass transfer during gasification of liquid fuel residues in rocket tanks // Thermal processes in technology, 2014. No. 2. S. 67-75,

In [6], Art. Trushlyakov V.I., Lavruk S.A., Theoretical and experimental study of the interaction of hot gases with a liquid in a closed model tank // Thermal processes in engineering, 2014. No. (6), p. 246-253, theoretical and experimental materials are presented confirming the technical feasibility of gasification of undeveloped SRT residues and the variability of GHG composition in the gasification process.

The essence of the technical solution is illustrated by the drawing, where the pneumohydraulic diagram of the experimental stand is shown in the drawing.

In the tank 1 (combustion chamber), the products of gasification of the fuel and the GHG oxidizer _ok , GHG of the _mountains with the given parameters (pressure, flow rate, temperature) are introduced. To do this, launch the experimental stand (Fig. 1). Open valves 2-6 and electro-pneumatic valves 7-11. When the gases to produce _hot PG PG _approx 12-16 from the cylinders (12 - cylinder oxygen gas, 13 - balloon with water vapor, 14 - balloon with helium 15 - coolant cylinder 16 - cylinder kerosene vapor) are fed into the collector 17, where they are mixed. The pressure and second mass flow rate of gases coming from cylinders 12-16 are set by gearboxes 18-22 and valves 23-27.

The obtained GHGs _ok and GHGs of _mountains with a given flow rate through the electro-pneumatic valve 28 from the collector 17 enter the combustion chamber 1, where they are ignited by the ignition system 29. The pressure and temperature in the combustion chamber 1 are determined using a pressure sensor 30 and a temperature sensor 31. The resulting combustion products removed from the combustion chamber 1 through the outlet pipe 32.

The proposed technical solutions allow us to expand the range of experimental studies of the combustion of gasified SRT oxygen, kerosene, hydrogen, liquefied natural gas at various VT.

The ability to conduct autonomous tests of the combustion process of gasified SRT allows to reduce the cost of exploratory research and development on the creation of active on-board systems for launching the separating parts of LV stages from orbits and launch trajectories.

Claims (2)

1. A method for simulating the process of burning gasification products of unspent residual liquid components of rocket fuel in the tanks of the spent stage of the launch vehicle, including introducing gasification products from each tank into the experimental setup, igniting the working mixture, performing process measurements, characterized in that when simulating the combustion process oxidizer gasification products, the test composition is prepared by mixing a gaseous oxidizer, water vapor and helium, and when simulated and gasification products of combustion of fuel, the analyzed composition was prepared by mixing the coolant, the gaseous fuel and helium. 2. A device for implementing the method, comprising a collector, an experimental tank, fuel component supply lines, characterized in that it contains cylinders filled with gasification products of fuel components and connected via adjustable valves, and chokes with a collector, a product ignition system gasification.

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