RU2683962C1 - Open-chamber for generator of high-frequency pulse based on discharge with hollow cathode - Google Patents

Abstract

FIELD: physics.SUBSTANCE: invention relates to high-frequency hardware and can be used producing high-frequency radiation generators (HFG). Separated chamber for generator of high-frequency pulses based on discharge with hollow cathode contains gas-discharge chamber and auxiliary chamber, gas-discharge chamber includes hollow cathode and anode separated by insulator. Surface of cavity of hollow cathode and surface of anode facing it form working volume of gas-discharge chamber, and between the ends of the hollow cathode and the anode facing each other there is a gap, the gas-discharge chamber is communicated with the auxiliary chamber containing the gas-discharge medium generation system. Insulator is remote from working volume, hollow cathode and anode are structurally spaced relative to each other along longitudinal axis of gas-discharge chamber so that any plane of cross-section of gas-discharge chamber does not cross simultaneously hollow cathode and anode, and the gap is arranged such that the width of the gap near the working volume of the gas-discharge chamber is less than the width of the gap near the surface of the insulator and less than the distance from the working volume to the insulator (that is gap length in gas-discharge chamber longitudinal section). In a particular version of implementation, the width of the gap on the larger part of its length in the longitudinal section of the gas-discharge chamber can be equal to the width of the gap directly near the working volume of the gas-discharge chamber.EFFECT: technical result is reduction of probability of ingress of electrodes erosion products to chamber insulator occurring in process of discharge combustion in chamber.1 cl, 1 dwg

Description

The invention relates to the field of high-frequency technology and can be used to create generators of high-frequency (HF) radiation.

A discharge with a hollow cathode [Moskalev BI, A discharge with a hollow cathode, M: Energy, 1969] has the following feature - under certain conditions (that is, under certain geometric parameters of the cavity, with discharge gas pressures lying in a certain range, and when a certain threshold of the discharge current density is exceeded), RF discharge modulation occurs during its development [Arbel D., Bar-Lev Z., Fekteiner J., Rosenberg A., Slutsker Ya. Z. "Collisionless Instability of the Cathode Sheath in a Hollow-Cathode Discharge", Physical Review Letters. 1993. V. 71. No. 18. p. 2919], while the amplitude of the RF modulations of the discharge voltage can reach 100% of the value of the discharge burning voltage.

Based on this effect, devices generating RF pulses were created [Fekteiner J., Ish-Shalom S., Slutsker Ya. Z, "Optimized performance of a powerful hollow-cathode rf oscillator", Journal of Applied Physics, 1998, vol. 83, num. 6, p. 2940-2943; Bulychev S.V., Vyalykh D.V., Dubinov A.E. et al., “Results of studies of high-frequency RF pulse generators based on a hollow cathode discharge”, Plasma Physics. 2009, t. 35, No. 11, p. 1019; RF patent 134697, Vyalykh D.V., Dubinov A.E., Zhdanov B.C., 11/20/2012, bull. No. 32; Selemir V.D., Dubinov A.E., Zhdanov B.C. et al., “Powerful superminiature beamless microwave generator in gas-discharge microwave electronics”, DAN, 2012, Volume 442, No. 4, p. 465-467]. The main element of this type of generator is a chamber in which a gas discharge with a hollow cathode is ignited. In order to ensure the compactness of the RF generator, the chamber can be sealed off, which avoids the need to use vacuum systems and pumping devices in the generator, which often have significant mass and dimensions.

An example of the design of a sealed chamber for an RF generator based on a hollow cathode discharge is described in [A.E. Dubinov I.Y. Kornilova, I.L. Lvov etc., "Generator of high-power high-frequency pulses based on sealed-off discharge chamber with hollow cathode", IEEE Trans. Plasma Sci., Nov. 2010, vol. 38, no. 11, pp. 3105-3108]. The chamber contains a hollow cathode and anode separated by an insulator. The air from the chamber is evacuated, the exhaust pipe is sealed, so that the working volume of the chamber (the gap between the hollow cathode and the anode where the discharge is lit) is isolated from the atmosphere. An incandescent gas generator is also provided inside the chamber, emitting working gas when heated. When a certain amount of incandescent current is passed through a gas generator in the working volume of the chamber, the corresponding gas pressure is created, which is required to realize a gas discharge in the chamber on the left branch of the Paschen curve (RF modulation of the discharge voltage occurs under conditions of ignition of the discharge corresponding to the left branch of the Paschen curve). When a high voltage pulse is applied to the electrodes of the chamber (hollow cathode and anode), a gas discharge with a hollow cathode is initiated in the working volume of the chamber. The RF component of the oscillations of the discharge voltage is the cause of the RF oscillations of the voltage at the electric load of the RF generator, which, in turn, are the source of electromagnetic RF energy.

A significant drawback of such a chamber was its relatively low working life, due to the formation of a conductive layer on the insulator during the life of the device.

The prototype of the claimed device is a sealed gas discharge chamber used in an RF pulse generator based on a hollow cathode discharge [S.V. Bulychev, A.E. Dubinov, I.L. Lvov etc., "Autonomous portable pulsed-periodical generator of high-power radiofrequency-pulses based on gas discharge with hollow cathode". Rev. of Sci. Instr., 2016, vol. 87, no. 5, p. 054707]. The sealed chamber contains a gas discharge chamber and an auxiliary chamber, the gas discharge chamber contains a hollow cathode and anode separated by an insulator, the surface of the cavity of the hollow cathode and the surface of the anode facing it form the working volume of the gas discharge chamber, and a gap is formed between the ends of the hollow cathode and the anode, the gas discharge chamber is in communication with an auxiliary chamber containing a system for creating a gas discharge medium, that is, a heated gas generator. When a high voltage pulse is applied to the electrodes of the chamber in the working volume of the chamber, a gas discharge with a hollow cathode is initiated. The RF component of the oscillations of the discharge voltage is the cause of the RF oscillations of the voltage at the electric load of the RF generator, which, in turn, are the source of electromagnetic RF energy.

The disadvantage of the sealed chambers created so far for hollow-cathode discharge pulses based on a hollow-cathode discharge is their limited service life. It is caused by irreversible changes in the surface of the insulator during the life of the chamber as a result of deposition on the insulator of erosion products of the chamber electrodes that occur during the combustion of the discharge. The surface of the insulator is covered with a conductive layer, shunting the discharge gap. As a result, the burning pattern of the discharge changes so that RF modulation of the discharge voltage does not occur, and the normal functioning of the generator becomes impossible.

The problem of deposition of erosion products of electrodes on insulators of various gas-discharge devices (dischargers, thyratrons, x-ray tubes) during their operation over time is known - when the conductive layer is formed on the insulator, the electric strength of the discharge gap is impaired, which violates the operability of the device. There are also known methods for solving this problem that contribute to maintaining the electrical strength of the discharge gap: the use of complex geometric configurations of the electrodes and the insulator, protective shields in front of the insulator, as a result of which the inner surface of the insulator is outside the line of sight from the interelectrode gap and is not accessible to erosion products electrodes [RF Patent No. 2300157, V. Bochkov, “Controlled gas-discharge device”; RF patent No. 2089003 Bochkov V.D., Diaghilev V.M., Korolev Yu.D., Ushich V.G., Shemyakin I.A. “Cold cathode discharge device”].

However, as shown by experimental studies of the authors, in sealed chambers for RF generators based on a hollow cathode discharge, the use of such methods does not make sense - RF modulation of the discharge voltage in a discharge with a hollow cathode is possible only with such configurations of the hollow cathode and anode, when the internal the surface of the insulator is directly open towards the working volume due to the fact that the hollow cathode and the anode are spaced relative to each other along the longitudinal axis of the chamber and the ends of the electrodes do not protrude one after another. And when the geometric configuration of the system of electrodes and the insulator is complicated, discharges of such a shape are triggered that RF modulation of the discharge voltage does not occur, that is, the device is non-functional. The organization of a non-conductive protective screen in front of the insulator is also inefficient - such a screen is quickly covered with a conductive layer of erosion products of the electrodes and becomes like an additional electrode, as a result of which the shape of the discharge will change and RF modulation in the discharge will not be initiated. For stable long-term operability of the RF generator, it is required that the hollow cathode and the anode be structurally spaced relative to each other along the longitudinal axis of the gas discharge chamber so that any plane of the cross section of the gas discharge chamber (that is, any plane perpendicular to the longitudinal axis of the gas discharge chamber) intersects or only the hollow cathode, either only the anode, or would not intersect any of the electrodes, but would not intersect the hollow cathode and the anode at the same time.

The technical problem is to increase the working life of the sealed chamber for a high-frequency pulse generator based on a hollow cathode discharge.

This problem can be solved by providing a technical result consisting in a significant reduction in the likelihood of electrode erosion products entering the chamber insulator arising during the combustion of the discharge in the chamber.

This result is achievable due to the fact that, compared with the well-known sealed chamber for a high-frequency pulse generator based on a hollow cathode discharge, which includes a gas discharge chamber and an auxiliary chamber, the gas discharge chamber contains a hollow cathode and an anode separated by an insulator, the surface of the hollow cathode cavity and the anode surface facing it forms the working volume of the gas discharge chamber, and a gap is organized between the ends of the hollow cathode and the anode, the gas discharge chamber is communicated with auxiliary In the proposed device, the insulator is remote from the working volume, the hollow cathode and the anode are structurally spaced relative to each other along the longitudinal axis of the gas discharge chamber so that any plane of the cross section of the gas discharge chamber does not intersect the hollow cathode and anode simultaneously, and the gap is organized so that the width of the gap near the working volume of the gas discharge chamber is less than the width of the gap near the surface of the insulator and less than the distance from the working volume to the insulator torus (i.e., the gap length in a longitudinal section a gas-discharge chamber). In addition, the width of the gap over most of its length in the longitudinal section of the gas discharge chamber may be equal to the width of the gap directly near the working volume of the gas discharge chamber.

Reducing the likelihood of erosion fragments of electrodes from the working volume where the discharge is burning on the surface of the insulator can be achieved by moving the insulator away from the working volume and narrowing the gap between the ends of the electrodes. In this case, it is not necessary to reduce the width of the gap near the surface of the insulator, since this can lead to the appearance of discharges in the gas discharge chamber along the surface of the dielectric (insulator), i.e., to a violation of the electric strength of the cathode-anode gap.

The probability that the erosion products of the electrodes from the working volume into the gap will decrease if the width is reduced) 'of the gap directly near the working volume, i.e. the width of the gap near the working volume of the gas discharge chamber should be less than the width of the gap near the surface of the insulator. The narrower (less wide) the gap will be near the working volume, the smaller the number of electrode erosion products will penetrate from the working volume into the gap.

Also, the probability of electrode erosion products entering the insulator will decrease if the insulator is distant from the working volume. The greater the distance from the working volume to the insulator, that is, the greater the length of the gap in the longitudinal section of the gas discharge chamber, the more erosion products of the electrodes will settle on the walls of the gap before reaching the insulator. But, of course, the insulator cannot be assigned to an infinitely large distance from the working volume because of the requirements for maintaining the compactness of the sealed chamber.

If, according to an additional condition, the gap is narrow for most of its length in the longitudinal section of the gas discharge chamber, that is, the width of the gap for most of its length is equal to the width of the gap directly near the working volume of the gas discharge chamber, this will increase the likelihood of deposition of erosion products of electrodes on the walls of the gap.

Under these conditions, the path of the products of erosion of the electrodes between the working volume of the chamber and the surface of the insulator is possible only through a narrow extended channel. The narrower and longer the channel, the greater the likelihood of deposition of electrode fragments on its walls, the smaller the number of electrode fragments reached by the insulator, the more difficult it will be to form a conductive layer on the surface of the insulator during the life of a sealed chamber.

In FIG. An example of the design of a sealed chamber for a high-frequency pulse generator based on a hollow cathode discharge is shown. The chamber contains a gas discharge chamber and an auxiliary chamber. The gas discharge chamber contains a hollow cathode 1 and anode 2, separated by an insulator 3, and is in communication with an auxiliary chamber containing a heated gas generator 4 (gas discharge medium creation system). The surface of the cavity of the hollow cathode 1 and the surface of the anode 2 facing it form the working volume of the gas discharge chamber (shown by a dashed line), and a gap is arranged between the ends of the hollow cathode 1 and the anode 2. The hollow cathode 1 and the anode 2 are structurally spaced relative to each other along the longitudinal axis of the discharge chamber so that any plane of the cross section of the discharge chamber does not intersect the hollow cathode 1 and anode 2. At the same time, the gap between the ends of the hollow cathode 1 and anode 2 is arranged so that the width the gap on most of its length in the longitudinal section of the gas discharge chamber (indicated by h), including near the working volume of the gas discharge chamber, is less than the width of the gap near the surface of the insulator (indicated by H), and less than the length of the gap in longitudinal section, or the distance from the working volume to the insulator (marked l). In a specific embodiment, the diameter of the cathode cavity is 30 mm, the depth of the cavity is 50 mm. The width of the gap between the ends of the electrodes near the insulator - H - is equal to 8 mm, the length of the gap in the cross section of the gas discharge chamber - l - is 15 mm, the width of the gap over most of its length - h - is 1 mm (less than H = 8 mm and less than l = 15 mm).

Using a gas generator 4, a certain pressure of the working gas (in particular, deuterium) is created inside the chamber, which corresponds to the left side of the Paschen curve. When creating a potential difference between the hollow cathode 1 and the anode 2 corresponding to the breakdown conditions, a discharge is ignited in the working volume of the chamber. When the discharge is burning, the erosion products of the chamber electrodes fall into a narrow long gap between the electrodes and, with a high degree of probability, do not reach the surface of the insulator 3, settling on one of the electrodes.

Thus, the probability that the erosion products of the electrodes occurring during the discharge burning in the chamber get on the chamber insulator is significantly reduced, the occurrence of a conductive layer on the surface of the insulator during the life of the sealed chamber is difficult, which contributes to an increase in the working life of the sealed chamber and the solution of the technical problem posed.

Claims (2)

1. A sealed chamber for a high-frequency pulse generator based on a hollow cathode discharge containing a gas discharge chamber and an auxiliary chamber, the gas discharge chamber contains a hollow cathode and anode separated by an insulator, the surface of the hollow cathode cavity and the anode surface facing it form the working volume of the gas discharge chamber, and between the ends of the hollow cathode and the anode facing each other, a gap is organized, the gas discharge chamber is in communication with an auxiliary chamber containing a system for creating a gas discharge medium characterized in that the insulator is remote from the working volume, the hollow cathode and the anode are structurally spaced relative to each other along the longitudinal axis of the gas discharge chamber so that any plane of the cross section of the gas discharge chamber does not intersect the hollow cathode and anode at the same time, and the gap is arranged so that the width the gap near the working volume of the gas discharge chamber is less than the width of the gap near the surface of the insulator and less than the distance from the working volume to the insulator 2. The sealed chamber according to claim 1, characterized in that the width of the gap over most of its length in the longitudinal section of the gas discharge chamber is equal to the width of the gap near the working volume of the gas discharge chamber

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