RU2149440C1 - Device for actuating medium supply for plasma accelerators - Google Patents

Abstract

FIELD: automatic control, in particular, regulation of actuating medium supply for stationary plasma engines of spacecrafts, supply of plasma for ground technological sources. SUBSTANCE: device has actuating medium source, which is connected to input of device for regulation of actuating medium supply, which has input pipe, which is connected to main and redundant reduction mechanisms, each of which has serial circuit of mechanical pressure regulator, which has actuating medium reset pipe, which also has protection valve, and electromechanical pressure regulator. Output of protection valve is connected to output electromechanical pressure regulator. Outputs of electromechanical pressure regulators of main and redundant reduction mechanisms are joined and are connected to output pipe of device for regulation of actuating medium supply. Output of latter device is connected to pipe for actuating medium supply to plasma accelerator. EFFECT: detection of complete or partial fault of mechanical pressure regulator, when this event happens, decreased losses of actuating medium through protection valve. 1 dwg

Description

 The invention relates to the field of automatic control and can be used in the supply systems of the working fluid (RT) of plasma accelerators, and more specifically for regulating the supply pressure of RT stationary plasma engines (SPD) of spacecraft; in ground conditions - to ensure the operation of technological plasma sources.

 A well-known functional diagram of a propulsion system using SPD, operating on xenon and containing a RT storage system (tank, charger, pressure sensor), RT supply system (pressure reducer, nozzle, receiver, safety valve, pressure sensor) and a common manifold with connected to it by highways supplying RT to SPD [1].

 There is a known functional diagram of a propulsion system using SPD adopted by the authors for a prototype operating on xenon and containing a RT storage system, a supply pressure control unit for the RT and a common collector with RT supply lines to the SPD connected to it [2].

 The RT feed pressure control unit consists of an input line, the output of which is connected to the main and backup RT reduction branches, each of which contains sequentially standing: a mechanical pressure regulator (Mechanical Regulators) containing an emergency relief valve with a safety valve installed on it, and an electromechanical pressure regulator (Electrical Regulators), the outputs of the electromechanical pressure regulators of the main and backup branches of reduction are combined and connected to the output line of devices and adjusting the supply pressure of the RT, the output of which is connected to the RT supply line to the plasma accelerators. The control of the supply pressure control unit of the RT is performed using the power supply and control system (PPU).

 The pressure at the outlet of the mechanical pressure regulator is maintained by means of a mechanical reducer included in its composition.

 The pressure at the outlet of the electromechanical pressure regulator is maintained by feedback between it and the power and control system. The signal about the pressure at the outlet of the electromechanical pressure regulator comes from the pressure recording device (pressure sensor), which is part of the electromechanical pressure regulator, to the power and control system, which automatically controls the electromechanical pressure regulator (closes or opens it) depending on the pressure on his exit.

RT emergency reset according to this scheme is carried out as follows:
- in the event that the pressure is higher than the permissible one at the output of the mechanical pressure regulator, the RT is released through the safety valve into the surrounding space:
- in the event that the pressure is higher than the permissible output of the electromechanical pressure regulator - by a signal from the electromechanical pressure regulator - the power and control system opens the supply valves of the RT of any two oppositely inactive plasma accelerators, and through them the RT will be reset.

However, the above scheme has significant disadvantages:
- RT discharge through a safety valve into the surrounding space leads to an unproductive loss of RT and, consequently, a deterioration in both integral characteristics (total leakage) and specific characteristics (specific effective impulse) of the propulsion system (ДУ);
- the inability to fix a complete or partial failure of the mechanical pressure regulator (for example, an increase in leakage of a mechanical gearbox, an increase in leakage or "departure" of the pressure of the safety valve from the required value) immediately at the time this event occurs, because there is no diagnostic equipment in the supply system that allows you to record the increased leakage of the safety valve or its operation during emergency RT reset. The failure of the mechanical pressure regulator can only be recorded indirectly by the rate of pressure decrease in the RT source, which, in turn, can be fixed only after a certain loss of RT.

 The above factors significantly reduce the reliability of the remote control from the point of view of completeness of the fulfillment of the target task (for example, increasing the leakage of a mechanical pressure regulator or safety valve above the permissible norm will lead to an unproductive loss of RT, and this in turn will lead to failure to fulfill the target task of the remote control to ensure the generation of the required total pulse traction), and can also lead to malfunctions of the RT feed pressure control unit (for example, “leaving” the operating pressure of the valve upwards from the required value can lead to the fact that at the time of a pause between the remote control starts due to a leak in the mechanical pressure regulator in the line between it and the electromechanical pressure regulator, the RT pressure rises above normal, which in turn can lead to a pressure overflow at the outlet of the unit regulating the supply pressure of the RT at the moment of switching on the electromechanical pressure regulator.

 The aim of the invention is to ensure the fixation of a complete or partial failure of the mechanical pressure regulator at the time this event occurs while reducing unproductive losses of the RT through the safety valve.

 This goal is achieved by the fact that in the known supply system containing a source of the working fluid connected to a device for adjusting the supply pressure of the working fluid containing an input line connected to the main and backup branches of the reduction, each of which contains a mechanical pressure regulator containing the emergency release line of the working bodies with a safety valve installed on it, and an electromechanical pressure regulator, the outputs of the electromechanical pressure regulators of the main and backup reduction circuits are combined and connected to the output line of the working fluid supply pressure control device, the output of which is connected to the working fluid supply to plasma accelerators, the power supply and control system, according to the invention, to the working fluid supply pressure control device on each reduction branch (main and backup) an additional line has been introduced connecting the output of the safety valve with the output of the electromechanical pressure regulator.

 The introduction of an additional line connecting the output of the safety valve to the output of the electromechanical pressure regulator will allow the use of an electromechanical pressure regulator to control the operation of the mechanical pressure regulator. It happens as follows.

 In the event of a complete or partial failure of the mechanical pressure regulator due to an increase in leakage, the pressure at the outlet of the electromechanical pressure regulator will increase (due to the overflow of the RT along the newly introduced main) and when it reaches the maximum permissible value, the power supply system automatically and upon the signal from the electromechanical pressure regulator control will open the RT supply valves of two opposite standing idle plasma accelerators and the RT will be reset. At the same time, the power and control system controls the duration of the pause between any two successive pressure drops. If it is less than the predetermined value determined on the basis of the permissible leakage of all functional elements of the supply pressure control unit of the RT, this will serve as a signal about the violation of the normal operation of the main branch of the reduction of the supply pressure control unit of the RT (including the complete or partial failure of the mechanical regulator pressure) and the need for a decision on the transition to the backup branch of reduction. If the duration of the pause between any two consecutive pressure drops will not be less than the predetermined value, then after reducing the pressure to the upper maximum permissible working level, according to the signal from the electromechanical pressure regulator, the power and control system will close the feed valves of the plasma accelerators RT and the feed system will continue in normal mode.

 The invention is illustrated in the drawing.

 The supply system of the working fluid of plasma accelerators contains a working fluid source 1 connected to the input of the supply pressure control device 2 of the RT, containing an input line 3, connected to the main 4 and backup 5 reduction branches, each of which contains a sequentially standing mechanical pressure regulator (MPP) 6 comprising an emergency discharge line RT 7 with a safety valve (PC) 8 installed on it and an electromechanical pressure regulator (EMRD) 9, the output of the safety valve 8 being connected with the output of the electromechanical pressure regulator 9. The outputs of the electromechanical pressure regulators 9 of the main 4 and backup 5 reduction branches are combined and connected to the output line 10 of the supply pressure control device 2 of the RT, the output of which is connected to the supply line 11 of the RT to the plasma accelerators 12. Power and control system 13 is connected by feedback to the supply pressure control device 2 of the RT.

 The system for supplying the working fluid of plasma accelerators can operate both in space and in terrestrial conditions in the following sequence.

 In the initial state, the source of the working fluid 1 contains a supply of RT with the maximum permissible pressure for the source of RT, the mechanical pressure regulator 6 and the electromechanical pressure regulator 9 are closed.

 When working on the main channel 4 of RT reduction by a signal from the power supply and control system 13, the mechanical pressure regulator 6 opens. In this case, the supply path of the RT between the mechanical pressure regulator 6 and the electromechanical pressure regulator 9 is filled. After a certain period of time (comprising several seconds), a command from the power supply and control system 13 opens the electromechanical pressure regulator 9 and the pressure in the output line 10 begins to increase. The pressure value is controlled by the power and control system 13 by a signal from the electromechanical pressure regulator 9. When the maximum allowable working pressure is reached by command from the power and control system 13, the electromechanical pressure regulator 9 closes. As the RT is consumed through plasma accelerators 12, the pressure in the output line 10 will decrease and, when it reaches the minimum allowable working pressure, upon the command from the power supply and control system 13, the electromechanical pressure regulator 9 will open again and the pressure in the output line 10 will begin to increase.

 With increasing pressure in the output line 10 above the maximum permissible operating level, which may be due to a complete or partial failure of the mechanical pressure regulator 6 or (and) the safety valve 8, or as a result of leakage of the RT due to the permissible leakage of the functional elements of the supply system, by a signal from the electromechanical pressure regulator 9. the power supply and control system 13 will open the valves of two oppositely standing idle plasma accelerators 12 and the RT will be reset to the environment space. In this case, the power and control system 13 controls the duration of the pause between any two successive depressurises. If it is less than the predetermined value, this will serve as a signal about the malfunction of the main 4 branches of the reduction of the supply pressure control unit RT (i.e., a complete or partial failure of the mechanical pressure regulator 6 or (and) the safety valve 8 and the need to accept decisions on switching to the backup 5th branch of reduction). If the duration of the pause between any two consecutive pressure drops will not be less than the predetermined value, then after reducing the pressure to the upper maximum permissible working level, by a signal from the electromechanical pressure regulator 9, the power supply and control system 13 will close the feed valves of the plasma accelerators RT 12 and the system The feed will continue in normal mode.

 Work on the backup channel is carried out in a similar sequence.

Sources of information
[1] N.V. Belan, V.P. Kim and others. "Stationary Plasma Engines" KhAI, Kharkov, 1989, pp. 282-286, Fig. 8.4.

 [2] A. Bober, K. Kozubsky, G. Komarov, N. Maslennikov, FAKEL, Kaliningrad Region, Russia; A.Kozlov, A. Romashko, NPO PM, Krasnoyarsk 26, Russia. Development and Qualification Test of a SPT Electric Propulsion System for "GALS" Spacecraft. Fig. 1, Fig. 2, AIAA, 23-rd International Electric Propulsion Conference (IEPC-93-008), September 13-16, 1993 - prototype.

Claims (1)

 A system for supplying the working fluid of plasma accelerators containing a source of the working fluid connected to a device for adjusting the pressure of the supply of the working fluid containing an input line connected to the main and backup branches of reduction, each of which contains a consecutive line containing an emergency discharge of the working fluid with a safety valve installed on it a mechanical pressure regulator and an electromechanical pressure regulator, while the outputs of the electromechanical pressure regulators the main and backup branches of reduction are combined and connected to the output line of the device for adjusting the supply pressure of the working fluid, the output of which is connected to the supply path of the working fluid to plasma accelerators, and also containing a power and control system configured to control the supply valves of the working fluid, characterized in that in the device for adjusting the supply pressure of the working fluid on each branch of the reduction introduced an additional line connecting the output of the safety valve with the output of the electromechanical pressure regulator, while the power and control system is additionally configured to open the working fluid supply valves of two oppositely standing idle plasma accelerators to reset the working fluid when the pressure at the output of the electromechanical pressure regulator reaches the maximum permissible value and with the possibility of controlling the pause duration between any two sequential discharges to judge the presence of a violation of the normal operation of the main branch of the reduction IAOD and the need for the decision to switch to a backup branch reduction.