RU2662795C1 - Hollow cathode - Google Patents

Abstract

FIELD: electrical engineering.SUBSTANCE: invention relates to the field of plasma technology, namely hollow cathodes operating on gaseous working bodies and can be used in electrically reactive engines to neutralize the ion flow, as well as in technological plasma sources intended for ion-plasma treatment of surfaces of various materials in a vacuum, and also as an autonomous functioning plasma source. In the hollow cathode containing hollow capsule 1, where inside emitter 2 is placed, the inlet channel of working body 3, outlet 4 and starting electrode 5, on the output side of the starting electrode, there is cantilever screen 6 that extends to the emitter and forms axial gap 7 relative to the hollow capsule. Starting electrode 5 and console screen 6a are formed integrally. Console screen is preferably made of refractory metals or alloys based on them.EFFECT: wider field of use.3 cl, 2 dwg

Description

The invention relates to plasma technology, in particular to hollow cathodes operating on gaseous working fluids, and can be used both as a part of electric reactive engines to neutralize (or compensate for the space charge of ions) an accelerated ion plasma flow, and as a part of technological plasma sources used for ion-plasma treatment of surfaces of various materials in a vacuum, as well as an autonomously functioning plasma source [RF Patent No. 2219683, cl. 7 H05H 1/24, 1/54, F03H 1/00].

Small spacecraft (SC) have a small onboard power, therefore, all equipment used on them, including the components of the electric propulsion, should at the minimum power consumption provide the necessary parameters and characteristics. In addition, the reserves of the working fluid for the operation of electric propulsion on board a small spacecraft are also limited. Therefore, the electric propulsion used on small spacecraft, including the hollow cathode, must be reliable, efficient and super-efficient, which determines the need to create and develop a low-consumption hollow cathode.

The most widely used in technology are the cathodes of two varieties. Filament-type cathodes in which the emitter is heated to the operating temperature of the emission by a special heater [N.V. Belan, V.P. Kim, A.I. Oransky, V.B. Tikhonov. Stationary plasma engines // Kharkov: Khark. Aviation Institute, 1989, p. 140]. Cathodes without a special heater for heating the emitter are called non-implicit [RF Patent No. 2031472, cl. 6 H01J 37/077, F03H 1/00, H05H 1/54, J.A. Burkhart, G.R. Seikel, J. Spacecraft and Rockets, v. 9, No. 7, 1972], in which the emitter is heated to operating temperature due to the initial heat energy released at the time of starting when a high-voltage starting pulse, for example 800-1000 V and above, is supplied with the help of a starting electrode and its subsequent transition to functioning in the automatic mode of electron thermal emission. In both circuits, the “cathode” electric circuit is the emitter directly, together with its supporting and mating parts.

Known hollow cathode containing a hollow capsule with end walls and passage holes of the working fluid inlet and outlet, inside which is placed an emitter and a starting electrode [RF Patent No. 2030016, cl. 7 H01J 37/077, F03H 1/00].

A disadvantage of such a known hollow cathode is the narrow scope of its application due to inoperability in low flow rate modes.

Known hollow cathode, adopted for the prototype, containing a hollow capsule with end walls, inside which an emitter is placed, which is connected by an outer cylindrical surface to the inner surface of the hollow capsule, the input channel of the working fluid, the outlet and the starting electrode [RF Patent No. 2012946, cl. 7 H01J 37/077, F03H 1/00].

And such a well-known hollow cathode has inherent disadvantages of the analogue due to limitations in working capacity for the permissible minimum flow rate of the working fluid. The functioning of such a known hollow cathode as part of a low power electric propulsion system is difficult due to unreliable starts and additional power consumption during stationary operation to ensure stability.

The main reason is that the mass gas flow in the emitter’s own channel affects the length of the active zone of electron emission as follows: at increased flow rates, the active zone is compressed with a shift to the emitter’s output, while when the flow decreases, the active zone expands away from the output end of the emitter deep into the channel. Thus, at low flow rates of the working gas, the efficiency of core emission decreases due to a more difficult discharge penetrating deep into the emitter channel (especially to the boundary of the beginning of the core) and, therefore, evenly distributed heat transfer of the discharge energy to the entire core, which is necessary to ensure and maintaining the operating temperature of the entire extended core, which is further exacerbated by heat losses back to the structure [Oransky AI, Dolgov AS, Taran AA Gas-discharge hollow high-emission cathodes. Volume 1. Basics of design. National Aerospace Institute. NOT. Zhukovsky, 2011]. Thus, the relatively low consumption of working gas fundamentally complicates the work of the hollow cathode.

When creating the invention, the problem was solved to expand the scope of the hollow cathode.

The specified technical result is achieved by the fact that in the hollow cathode containing a hollow capsule inside which an emitter is placed, an input channel of the working fluid, an outlet and a trigger electrode, according to the invention, a cantilever screen is installed on the outlet side of the trigger electrode, which extends to the emitter and forms axial clearance relative to the hollow capsule. The trigger electrode and the console screen can be made whole. The console screen is preferable to be made of refractory metals or alloys based on them.

The installation of an additional cantilever screen on the starting electrode allows us to solve the problem of expanding the scope of application of the hollow cathode, in particular, for operating modes at extremely low gas flow rates, by, on the one hand, reducing the breakdown gap between the cathode electric circuit and the starting electrode, a, s on the other hand, local provision in the working zone of electric breakdown of increased gas density due to the separate functions of the cantilever hollow screen, which limits the exit zone of gas and electrons to a minimum ceiling elements volume, thus preventing dissipation of the working part of the body around the internal construction volume. The formation in the working zone in front of the emitter of the local region of increased density of the working gas increases the probability and helps to improve the conditions for electrical breakdown [M.D. Gurevich, M.D. Gurevich. Vacuum devices. M .: Military Publishing House of the Ministry of Defense of the USSR, 1960, p. 330-338].

The manufacture of the starting electrode and the cantilever screen in the form of a single integral design will allow to avoid excessive electrical contact resistance, reduce losses and ensure the integrity of the electric circuit in this section.

The manufacture of a cantilever screen from refractory metals or alloys based on them allows us to solve the problem of increasing reliability and durability under conditions of high temperatures and ion bombardment of the jet.

Thus, the hollow cathode made according to the invention, in which the starting electrode is additionally equipped with a cantilever screen, the free edge of which is located in front of the hollow capsule with an emitter with axial clearance, thereby reducing the breakdown gap in the working area, allows for reliable start-up and stable operation in the modes ultra-low costs (less than 0.1 mg / s), thereby expanding its functionality.

The invention is illustrated by drawings.

In FIG. 1 shows a longitudinal section of a hollow cathode, which also conventionally shows an electric power source and a circuit for connecting it to the conductive elements of the hollow cathode.

In FIG. 2 shows a remote element A, which shows a variant of the integral design of the trigger electrode with a cantilever screen.

в окружающее пространство и пусковой электрод 5. На пусковом электроде установлен консольный экран 6, который обращен к эмиттеру 2, так что между свободным концом консольного экрана 6 и полой капсулой 1 образован осевой зазор 7. Источник электрического питания подключается к элементам полого катода следующим образом: токоподводящая линия подачи импульса запуска (клемма "+" источника электрического питания) присоединяется к токопроводящим элементам пускового электрода 5, а другой токоподвод (клемма "-" источника электрического питания) осуществляется к токопроводящим элементам полой капсулы 1 с эмиттером 2. При другом варианте конструкции пусковой электрод 5 и консольный экран 6а могут быть сделаны в виде частей одной цельной детали.The hollow cathode contains a hollow capsule 1, inside of which there is an emitter 2, an input channel for supplying a working fluid 3, an outlet 4 for the exit of emitted electrons

into the surrounding space and the starting electrode 5. A console screen 6 is installed on the starting electrode, which faces the emitter 2, so that an axial clearance is formed between the free end of the console screen 6 and the hollow capsule 1. The electric power source is connected to the hollow cathode elements as follows: the lead-in current supply line (terminal "+" of the electric power source) is connected to the conductive elements of the start electrode 5, and the other current path (terminal "-" electric power source) is tvlyaetsya to the conductive elements of the capsule 1 with a hollow emitter 2. In another embodiment, the trigger electrode 5 and the console screen 6a may be made in the form of parts of a single integral piece.

The hollow cathode operates as follows.

The working fluid (for example, gaseous xenon) entering the hollow cathode is ionized by an electric discharge in a gaseous medium when voltage is applied via the current supply line of the start pulse supply (terminal "+" of the electric power source) through the start electrode 5 to the console screen 6, while the "-" terminal of the electric power source is connected to the conductive elements of the hollow capsule 1 with the emitter 2, which is a source of electrons in a heated state at an operating temperature of the order of 1500 ° C-1700 ° C. The working gas is supplied to the hollow cathode through an inlet channel 3, hermetically connected to the cavity of the hollow capsule 1. Next, the gas enters the internal cavity of the hollow capsule 1, in which the emitter 2 is located. Due to the released electric discharge energy in the axial clearance 7 at the time of starting the emitter 2 is heated, mainly from the side of the outlet 4, to a working temperature that causes the emission of electrons. In the stationary operation mode of the electric propulsion system, the level of electron emission from the hollow cathode should be sufficient to maintain an electric discharge between the working cavity of the emitter 2 and the electric propulsion anode (not shown). Under such conditions, the initial initialization of the plasma occurs. After starting, the hollow cathode goes into stationary mode with automatic operation, at which the necessary temperature level of emitter 2 is maintained due to the energy coming from the steady-state plasma discharge.

The industrial feasibility of the proposed invention is confirmed by testing prototypes of a hollow cathode during surface mining both autonomously and as a part of electric propulsion, in which the following positive results were obtained:

- the test results demonstrated the reliability of launches with improved dynamics of reaching the stationary mode of operation;

- circuit voltage "cathode-to-ground» U _k-s (the potential difference in a concentrated plasma clot connected between the emitter of the hollow cathode and the area of contact of the plasma clot to plasma jet issuing from the ERE, a parameter characterizing the power requirement on the electron transport from the cathode to the plasma jet and anode of the electric propulsion), when operating as part of the electric propulsion is relatively low (the actual value of U _to-z is 13-17 V) and stable during stationary operation.

Claims (3)

1. A hollow cathode containing a hollow capsule, inside which an emitter is placed, an input channel of the working fluid, an outlet and a trigger electrode, characterized in that a console screen is installed on the exit side of the trigger electrode, which extends to the emitter and forms an axial clearance relative to the hollow capsule . 2. The hollow cathode according to claim 1, characterized in that the starting electrode and the cantilever screen are made integrally. 3. The hollow cathode according to claim 1, characterized in that the cantilever screen is made of refractory metals or alloys based on them.

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