RU69680U1 - RUNNING WAVE LAMP WITH MAGNETIC PERIODIC FOCUSING SYSTEM - Google Patents

Abstract

Field of use: microwave vacuum devices, in particular, to a traveling-wave lamp (TWT) device of the O-type with a magnetic periodic focusing system (MPFS). The inventive TWT contains combined with a resonant retardation system (ZS) MPFS, consisting of alternating axially magnetized ring magnets, pole pieces with hubs of ferromagnetic material, and non-magnetic diaphragms located between them with capacitive bushings that form a passage channel. At least part of the MPSF, located after the input of RF energy, contains an insert made of ferromagnetic material, which together with adjacent pole tips forms 3S resonators. Another part of the ZS resonator is formed by a diaphragm made in the form of a stepped body of revolution, and an annular element securing the insert in the diaphragm. Diaphragms and ring elements are made of non-magnetic material with high thermal conductivity. By choosing the insert profile of the ferromagnetic material, its size and location between the pole pieces in the TWT with MPFS, a magnetic field is realized with the specified higher harmonic components and a non-sinusoidal distribution. The technical result is to increase the beam current flow in the powerful TWT of the short-wave part of the microwave range by providing focusing of the intense electron beam in the transit channel in the TWT with low ripple.

Description

The utility model relates to microwave microwave devices, in particular, to the device of traveling wave tubes (TWT) used as generators, amplifiers, current switches, and other devices.

A TWT construction is known in which a magnetic periodic focusing system (MPFS) with axially-magnetized ring magnets is used spatially combined with a retardation structure (ZS) like a chain of coupled resonators in which the diaphragms of the RF cavities are made to focus the intense electron beam with an alternating sinusoidal magnetic field. in the form of inserts of a special form of non-magnetic material placed between the pole pieces, as a result of which the MPPS period becomes two p longer period for the AP and the sizes of the magnets are sufficient to provide the desired value of the focusing magnetic field. (US patent No. 4399389, CL 315-3.5, 1983).

The main disadvantage of TWTs with MPFS with an alternating magnetic field is the presence of alternating areas of stable and unstable focusing of the electron beam, characterized by the so-called magnetic field parameter α, the value of which is proportional to the square of the product of the effective focusing value of the magnetic field and its period (I. Alyamovsky and Electron Beams and electronic guns. M: 1966. - 456 s). For some values of the magnetic field parameter α, the amplitude of the flow pulsations can increase unboundedly as the beam moves along the axis of the passage channel and the beam’s current passage sharply deteriorates. In practice, beam focusing by a sinusoidal magnetic field in the first stability zone, for which the magnetic field parameter taking into account the space charge should be less than the critical value α <α _cr = 0.4, is most widely used.

To increase the area of stable focusing of the electron beam, MPPS is used with a non-sinusoidal distribution of the magnetic field, which is ensured by introducing higher harmonic components.

The closest prototype of the proposed utility model is the TWT design with a magnetic periodic focusing system (MPFS), consisting of alternating axially magnetized ring magnets, pole pieces with hubs of ferromagnetic material, spatially aligned with capacitive bushings of resonators, diaphragms made of non-magnetic material with capacitances between the pole pieces (US No. 324339, Cl. 315-3.5, 1967), in which the required magnetic field is achieved by increasing the the magnitude of the magnets in the axial direction and the increase as a result of this period MPFS compared with the period of ZS twice. The spatial compatibility of the MPFS design with the CS is achieved by alternating the pole pieces inside the vacuum shell with the copper diaphragms forming the RF cavity. In addition, in this design, between the pole tips of the MPSF, an annular element of ferromagnetic material is mounted on a thin-walled copper disk of the diaphragm of the RF resonator. Due to this, a non-sinusoidal distribution of the axial component of the magnetic field induction with a significant positive third harmonic is created.

The disadvantage of this design is that when switching to the short-wave part of the microwave range, the elements of the surroundings become miniature and the performance of the design becomes problematic. So, for TWT operation in the 3 cm wavelength range at an accelerating voltage level of less than 20,000 V, the annular sleeve of ferromagnetic material has the following typical dimensions: thickness 0.25-0.5 mm, inner diameter of the sleeve 2.0-3.0 mm, the length of the sleeve in the axial direction of 3-4 mm The thickness of the thin-walled copper disk is ~ 0.8-1.2 mm. The amplitude of the magnetic field required for focusing an intense beam can be ~ 0.3 T. With such dimensions, the material of the capacitive ring bushings is saturated and the required magnetic field distribution is not provided. Placing a large number (up to several tens) of ferromagnetic annular sleeves located in the ZS, with their axes skewed relative to each other, leads to a decrease in the actual cross section of the passage channel, as well as to the appearance of transverse components of the magnetic field, to a decrease in the fraction of the beam current passing through the passage channel ZS, as well as to reduce the output power and efficiency of the device and thermal overload of the ZS.

The task to which the proposed utility model is directed is to increase the power and efficiency of TWT with MPFS.

The technical result of using the utility model is to improve the flow of intense flux through the passage channel of the powerful TWT of the short-wave part of the microwave range by reducing ripple of the beam boundary in static and dynamic modes of operation.

The problem is solved in such a way that in TWT with a magnetic periodic focusing system (MPFS), consisting of alternating axially magnetized ring magnets, pole tips with hubs of ferromagnetic material, spatially aligned with capacitive bushings of resonators, diaphragms of non-magnetic material with capacitive bushings installed between the pole pieces, at least in the part of the MPFS located after the input of RF energy, capacitive bushings and parts of the diaphragms that form the wall resonator and adjacent to the capacitive bushings, combined into an insert made of ferromagnetic material, and fixed in the diaphragms at the same distance from the pole pieces with ring elements made of non-magnetic material. The diaphragms of non-magnetic material are made in the form of stepped bodies of revolution, consisting of at least two cylindrical parts, the smaller inner diameter of the diaphragm equal to the inner diameter of the cavity of the resonators, and the larger inner diameter of the diaphragm equal to the outer diameter of the ring elements, the length in the axial direction of the capacitive bushings pole pieces and diaphragms same and determined by the condition 0,15 <l _W / L <0,2, and the thickness of sleeves in the radial direction is at least half the thickness of the article APIS resonators. In addition, the diaphragms and ring elements are made of a material with high thermal conductivity, for example, copper.

Figure 1 schematically shows a preferred embodiment of TWT in accordance with a utility model. Figure 2 presents an embodiment of TWT with MPFS. Figure 3 shows the experimental dependences of the current transmission k on the magnetic field parameter α for a conventional TWT (1) and for a TWT with MPPS of the proposed design (2).

TWT contains an electron gun 1, which forms an intense electron beam, MPPS, consisting of cells of alternating ring magnets 2, pole tips 3, composite RF diaphragms 4, with an insert of ferromagnetic material 5. Composite RF diaphragms 4, inserts of ferromagnetic material 5 and pole tips 3 form the resonators of the delay system and the vacuum

TWT shell located after the input of HF energy 6. The inner part of the composite HF diaphragm is made in the form of a stepped body of revolution 7, consisting of at least two cylindrical parts, and an annular element 8, between which at the same distance from the pole pieces there is an insert from ferromagnetic material 5.

This TWT design corresponds to the distribution of the absolute value of the longitudinal component of magnetic induction along the axis of the device in the MPPS cells, which provides focusing of the intense electron beam with small ripples in a wide range of TWT parameters with MPPS.

The calculations and experimental measurements of the current deposition showed that the choice of the size and location of the insert made of ferromagnetic material in the TWT with MPFS of the proposed design ensures the transport of the electron beam in the passage channel with significantly lower pulsation amplitudes compared to the usual TWT with MPFS, and the beam passes through the transit channel of the ZS for TWT of the claimed design is significantly higher than the beam passage in the passage channel of a conventional TWT.

Based on the calculated and experimental studies, the main dimensions of the capacitive bushings of the resonators are determined. In the absence of saturation of the material at a given thickness of the walls of the resonators, the choice of the thickness of the bushings in the radial direction equal to at least half the wall thickness of the resonators, saturation of the material of the bushings does not occur, and the required magnetic field structure is realized in the TWT of the claimed design. When choosing the length of the capacitive bushings in the range 0.15 <l _W / L <0.2 in TWT with the MPFS of the proposed design, a gap between the capacitive bushings is realized, which ensures the optimal efficiency of the interaction of the electron beam with the rf field (Danovich I.A. periodic magnetic fields with a non-sinusoidal axial law of distribution of induction // Electronic Engineering. Ser.1. Microwave Electronics, 1966, Issue 9, C.20), and in the distribution of the magnetic field of the MPPS, the required values of the higher harmonics of the magnetic field appear which provide stable focusing of the beam with small pulsations up to α≤1.4 (Arkhipov A.V., Glotov E.P., Darmaev A.N., Morev S.P. Transportation of electron fluxes in MPFS with an inharmonic magnetic distribution fields // Radio engineering and electronics, 2007, vol. 52, No. 7, pp. 1-10).

When choosing the length of the capacitive bushings of the pole pieces and diaphragms in the axial direction of less than 0.15 L or more than 0.2 L, the gap between

the resonator sleeves becomes non-optimal for the interaction of the beam with the electromagnetic wave and the TWT output parameters degrade. In addition, as shown by experimental measurements of the magnetic field, when the axial extension of the capacitive bushings of the pole pieces and diaphragms is less than 0.15 L or more than 0.2 L, the resulting magnetic field structure in the MPPS cells increases the pulsations of the electron flow and to a decrease in the magnitude of the magnetic field parameter at which stable beam focusing is obtained. With asymmetric axial fastening relative to the pole tips of the ferromagnetic material insert with ring elements of non-magnetic material, even harmonics appear in the distribution of the magnetic field, and the amplitude of the pulsations of the beam boundary sharply increases.

In the proposed design, when moving to the short-wave part of the microwave range, the insert made of ferromagnetic material remains coarse-grained, can be placed in the composite high-frequency diaphragm with the required accuracy and provides the magnetic field distribution necessary for focusing the intense flux. A decrease in the focusing magnetic field in the proposed construction of TWT with MPFS as compared with a conventional TWT with MPFS, as shown by experimental measurements, does not exceed units of percent for identical sizes of ferromagnetic elements and magnets.

The number of soldered joints needed to create a vacuum shell in the TWT with MPPS of the claimed design does not increase compared to the conventional TWT design.

The practical manufacture of a composite RF diaphragm and an insert of ferromagnetic material in the proposed design does not require numerous technological operations and is performed on standard metal-working equipment, which facilitates industrial applicability.

The application of the proposed TWT design with MPFS allowed us to reduce the beam current loss and to reduce the thermal load on the retarding system in the static mode of operation at lower values of accelerating potentials, as well as at higher levels of the effective focusing magnetic field during dynamic operation,

Thus, the proposed TWT design has the following advantages:

improved current flow in O-type devices in a static mode of operation, due to a decrease in the magnitude of the pulsations of the beam;

decrease in dynamic defocus due to the ability to increase the value of the effective focusing magnetic field.

Claims (3)

1. A traveling wave lamp (TWT) with a magnetic periodic focusing system (MPFS), consisting of alternating axially magnetized ring magnets, pole pieces with hubs of ferromagnetic material, spatially aligned with capacitive bushings of resonators, diaphragms made of non-magnetic material with mounted capacitive bushings, between the pole pieces, characterized in that at least in the part of the MPPS located after the input of the RF energy, the capacitive bushings and the diaphragm parts adjacent to the capacitive bushings m forming the wall of the resonator, combined in the insert made of ferromagnetic material which are secured in the apertures equidistant from the pole pieces of the annular elements of a nonmagnetic material. 2. TWT according to claim 1, characterized in that the diaphragms are made in the form of stepped bodies of revolution, consisting of at least two cylindrical parts, the smaller inner diameter of the diaphragm equal to the inner diameter of the cavity of the resonators, the larger inner diameter of the diaphragm equal to the outer diameter of the ring elements, the axial extension of the capacitive bushings of the pole pieces and diaphragms is the same and is determined from the condition 0.15 <l _W / L <0.2, and the thickness of the bushings in the radial direction is at least half the thickness the walls of the resonators. 3. TWT according to any one of claims 1 or 2, characterized in that the diaphragms and ring elements are made of a material with high thermal conductivity, for example, copper.