RU2770072C2 - Test bench for the pumping system for powdered metal supply to the combustion chamber of a rocket engine - Google Patents

Abstract

FIELD: rocket engineering.

SUBSTANCE: invention relates to the field of rocket engine technology and can be used in testing pumping systems for supplying powdered metal to the combustion chamber of a liquid-propellant rocket engine. The bench contains housing equipment, process tanks, a fuel supply system to the combustion chamber and a control system for testing and parameter control processes. The bench is equipped with a gel fuel supply system with a powdered metal additive with a gel fuel viscosity regulator installed in front of the pumping unit. The viscosity regulator contains an activator using a rotating electromagnetic field acting on the fuel. The consumable and storage process tanks are cylindrical, identical in size, shape and interchangeable and installed on the housing equipment with the possibility of reinstalling. The simulator of the combustion chamber is installed after the pumping unit in front of the storage tank during autonomous tests of the supply system and is dismantled during fire tests of the propulsion system.

EFFECT: invention provides for the improvement of the design and technological characteristics of the bench when testing the supply system of the rocket fuel used, taking into account the characteristics of its composition.

5 cl, 3 dwg

Description

The invention relates to the field of rocket engine building and can be used in testing pumping systems for supplying powdered metal to the combustion chamber of a liquid-propellant rocket engine (LPRE).

Bench testing is a mandatory procedure in the development of new propulsion systems, modernization of existing engines and quality control of their production technology /1, 2/.

The design and technological features of the stand for testing the pumping system for supplying powdered metal to the combustion chamber of the rocket engine should take into account the features of work processes in the pumping system for supplying powdered metal. At present, such working processes have not yet been fully identified and studied, so the task of such a stand should not only be to check the performance of the units and the pumping system itself, but to identify and study the accompanying work processes.

Known /3/ stand for testing LRE, which contains a system for supplying fuel components to the engine, including consumable tanks, separating and booster tanks, consumable lines with flow meters, starting lines, fuel fittings, compressed gas lines. Shut-off valves are installed in the separating tanks, and valve drives are installed outside the separating tanks, and the valves and their drives are interconnected by mechanical links.

This design and technology stand does not provide for the performance of work related to testing the performance of the proposed pumping system and identifying and studying the working processes in it.

Known /4/ another closest to the claimed technical solution and more complex compared to analogue /3/ stand for testing power plants with cryogenic fuel components.

This stand includes a fuel supply system, heat-insulated supply tanks, main pipelines with a control system for testing processes and parameters control, connecting the storage tanks with the power plant under test, while the fuel components supply system is equipped with at least one non-heat-insulated high-pressure storage tank equipped with main pipelines with valves connecting it to the inlet and outlet cooling paths of the power plant with the possibility of supplying the remains of the liquid component to it after testing the power plant and supplying this component after its gasification to the input of the power plant for testing.

However, this bench also cannot be used as a bench for testing the pumping system for supplying powdered metal to the combustion chamber, due to the significant difference between the fuel components used, however, some technical features of the prototype bench can be taken into account when solving the problem of the claimed invention.

The objective of the invention is to improve the design and technological characteristics of the stand, providing testing of the supply system, taking into account the characteristics of the composition of the rocket fuel used.

The problem is solved by the fact that in the stand for testing the pumping system for supplying powdered metal to the combustion chamber of a rocket engine, containing body equipment, technological containers, a fuel supply system to the combustion chamber and a control system for testing processes and monitoring parameters, an additional system for supplying gel-like fuel with a powdered metal additive with a gel-like fuel viscosity regulator installed in front of the pumping unit, and the viscosity regulator contains an activator using a rotating electromagnetic field that acts on the fuel, while additionally:

- one of the process tanks is consumable, and the other is storage, and these tanks are made cylindrical, identical in size, shape and interchangeable and installed on the housing equipment with the possibility of reinstallation;

- the stand contains a rocket engine combustion chamber simulator installed after the pumping unit in front of the storage tank during autonomous tests of the pumping system for supplying to the high pressure chamber and dismantled during firing tests of the rocket engine;

- a turbine unit connected to a separate gas generator is used as a pumping unit drive;

- as a drive of the pumping unit, it contains an electric motor connected to an external power supply and connected to the pumping unit by means of an adjustable kinematic connection.

The main essential features, both known (housing equipment, process tanks, fuel supply system to the combustion chamber and control system for testing and parameter control), and distinctive (gel fuel supply system with a powdered metal additive with a gel fuel viscosity regulator installed before the pump unit, the introduction of an activator into the composition of the viscosity regulator, using a rotating electromagnetic field acting on the fuel) are necessary and sufficient to solve the problem and disclose the technical essence of the claimed invention.

So, for example, in /5, p. 223-224/ indicate that in order to ensure the operation of the pumping system, it is possible, as an option, to reduce the viscosity of the gel using its thixotropy before supplying fuel to the combustion chamber.

It is well known that the impact of an alternating electromagnetic field on aqueous solutions intensifies heat and mass transfer processes in them. This is due to the fact that the water molecule H ₂ O is a dipole with positive and negative poles.

Liquid rocket propellants are dielectrics /6, p. 156-275/, so the action of the alternating electromagnetic field on them is weakly expressed. However, the inclusion of an electromagnetically sensitive powder metal in the composition of a gel-like fuel can lead to an increase in the intensity of heat and mass transfer processes in the fuel and the destruction of the gel structure, reducing viscosity and increasing fluidity (eg, /7/).

Additional signs:

a) one of the technological tanks is consumable, and the other is storage, and the execution of these tanks is cylindrical, identical in size, shape and interchangeable and their installation on the body equipment with the possibility of reinstallation;

b) the presence of a rocket engine combustion chamber simulator installed after the pumping unit in front of the storage tank during autonomous tests of the pumping system for supplying to the high pressure chamber and dismantled during fire tests of the rocket engine;

c) the use of a turbine unit connected to a separate gas generator as a drive for the pumping unit;

d) the use of a pumping unit as a drive; it contains an electric motor connected to an external power supply and connected to the pumping unit through an adjustable kinematic connection,

disclose the technical features of the claimed invention with completeness sufficient for its implementation.

The essence of the invention is illustrated in Fig. 1-3, where in Fig. 1 shows the general scheme of the stand for the production of autonomous tests, Fig. 2 - scheme of the stand in relation to the conduct of fire tests, in Fig. 3 - a variant of the design of the regulator with an activator based on the use of a rotating electromagnetic field.

The stand (Fig. 1) contains body equipment 1, consumable tank 2 and storage tank 3. Tank 2 is installed vertically, tank 3 is installed in an arbitrary inclined position. Tanks 2 and 3 are identical in size and shape and contain actually the same cylindrical shells, as well as the top 4 and bottom 5 of the bottom and cover 6.

When preparing the stand for autonomous testing, the supply system is disconnected from the storage tank 3, instead, a combustion chamber simulator 7 is attached to the bottom 4, and the internal cavity of the tank 3 communicates with the atmosphere through the pneumatic tube 8.

The pre-pressurization system of the supply tank 2 contains a pressure accumulator 9, a pneumatic communication line 10 and an adjustable valve 11. Before testing, both autonomous and firing, the tank 2 is filled with gel-like fuel 12 with a powdered metal additive. Such fuel can be aluminum (eg, /5, pp. 223-224/), consisting of hydrazine - 66.5%, aluminum - 33%, gelling agent - 0.5%.

A flow pipe 13 is connected to the lower bottom 5 of the supply tank 2, to which the inlet pipe of the pump 14 is connected. In the storage tank 3, the pipeline 13 is plugged with a cover 15.

On the same axis (shaft) with the pump 14, a turbine unit 16 is installed, which is the drive of the pump 14. The turbine unit 16 operates (communication line 17) from a separate gas generator 18. Homogeneous components (oxidizer-fuel pair) or unitary fuel, e.g. hydrogen peroxide.

An electric generator 19 is installed on the same axis (shaft) with the pump 14 and the turbine unit 16, which generates a multi-phase electric current.

Inside the tanks 2 and 3 in the area of the entrance to the pipeline 13 on the pylons 20 there is a disc funnel suppressor 21, inside which the electric winding 22 is placed.

Another electric winding 23 is installed on the bottom 5, and the windings 22 and 23 are placed and connected to the electric generator in such a way that when they are supplied through the electric communication line 24 of a multiphase electric current in the fuel supply path 12 between the funnel 21 and the bottom 5 and then on some section of the pipeline 13 creates a rotating electromagnetic field.

The pressure pipe of the pump 14 and the simulator of the combustion chamber 7 are interconnected by a pipeline 25, which includes an adjustable valve 26 and other hydraulic devices 27 and sensors 28, thereby representing one of the pipelines with a control system for testing processes and parameters control.

The stand also contains an electric motor 29 connected to an external power source and kinematically connected to the turboelectric pump unit (pump 14, turbine unit 16 and electric generator 19) through an adjustable clutch 30. The clutch 30 can be hydraulic, electrical or mechanical.

In FIG. 2 shows a diagram of the stand for conducting fire tests of supply systems and the LRE itself. Instead of a simulator, a combustion chamber 31 is installed on the stand, to which a fuel supply line 12 is connected from the supply tank through the viscosity regulator, turbopump unit and pipeline 25. Pipelines 32 and 33 for supplying other liquids from process tanks 34 and 35 are connected to the combustion chamber 31, in one of which another fuel can be placed, and in the other - an oxidizer. In addition, a noise suppression pipe 36 can be installed on the stand.

In FIG. 3 shows another version of the design of the electromagnetic activator. In the area of the junction of the pipeline 13 and the inlet pipe of the pump 14 on the pipeline 13, an electric winding 37 is mounted, connected to the electric generator 19 in such a way that when a multi-phase electric current is applied to it, a rotating electromagnetic field is created inside the pipeline 13.

During autonomous tests, the tank 2 is pre-pressurized. Then the pump 14 and the electric generator 19 are unwound, and the electric motor 29 can also be used. 26 and other units, fuel (arrow 38) enters the storage tank 3. Through the devices 27 and sensors 28, the testing process is monitored. After completion of the tests, tanks 2 and 3 are reinstalled in such a way that the tank 3 filled with fuel becomes consumable, and the empty tank 2 becomes accumulative. The cover 15 is removed, the pumping unit and the simulator 7 are re-docked, after which the stand is ready for repeated autonomous tests of the pumping system units.

Fire tests are carried out in a similar way, taking into account the technical characteristics of the stand (Fig. 2), the rocket engine and the technology of the tests themselves.

Bibliography:

1. Zhukovsky A.E. and other Tests of liquid rocket engines. - M.: Mashinostroenie, 1981.

2. Cosmonautics: Little Encyclopedia. / Ed. V.P. Glushko. - M.:SE. 1970. Art. "Rocket Engine Test", p. 180-181.

3. Patent of the Russian Federation No. 2111373 for the invention "Test bench for liquid rocket engines", 1996.

4. Patent of the Russian Federation No. 2445503 for the invention "Test bench for power plants with cryogenic fuel components", 2010.

5. V.E. Alemasov, A.F. Dregalin, A.P. Silence. Theory of rocket engines. Edited by V.P. Glushko, - M.: Mashinostroenie, 1980.

6. Bolshakov G.F. Chemistry and technology of liquid propellant components. - L .: Chemistry, 1983.

7. Zabulonov Yu.L., Kadoshnikov V.M., Litvinenko Yu.V. On the influence of an electromagnetic field on the stability of colloids by the example of iron hydroxide. Collection of Scientific Practices for the Institute of Scientific Research, 2009.17, p. 63-66.

Claims (5)

1. Stand for testing the pumping system for supplying powdered metal to the combustion chamber of a rocket engine, containing body equipment, technological containers, a fuel supply system to the combustion chamber and a control system for testing processes and monitoring parameters, characterized in that the stand is equipped with a system for supplying gel fuel with powdered a metal additive with a gel fuel viscosity regulator installed in front of the pumping unit, and the viscosity regulator contains an activator using a rotating electromagnetic field that acts on the fuel. 2. The stand according to claim 1, characterized in that one of the technological tanks is consumable, and the other is storage, moreover, these tanks are cylindrical, identical in size, shape and interchangeable and installed on the body equipment with the possibility of reinstallation. 3. The stand according to claim 1, characterized in that the stand contains a rocket engine combustion chamber simulator installed after the pumping unit in front of the storage tank during autonomous tests of the pumping system for supplying to the high pressure chamber and dismantled during firing tests of the rocket engine. 4. Stand according to claim 1, characterized in that a turbine unit connected to a separate gas generator is used as a pumping unit drive. 5. The stand according to claim 1, characterized in that, as a drive of the pumping unit, it contains an electric motor connected to an external power supply and connected to the pumping unit by means of an adjustable kinematic connection.

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