RU2235384C1 - Sectionalized traveling-wave tube and its design alternates - Google Patents

Abstract

FIELD: microwave engineering; traveling-wave tubes and their hybrids.

SUBSTANCE: proposed traveling-wave tube of first design alternate has sections of chain of intercoupled ferromagnetic-disk resonators and nonmagnetic diaphragms in-between with azimuthal coupling slits turned in disks relative to diaphragm slits through

radians; axes of disks and diaphragms carry drift tubes; section-separating disks are made of ferromagnetic material; annular absorber of inner diameter d_ai ranging within 2r_si

d_ai

d_ti, where r_si is inner radius of coupling slit; d_ti is inner diameter of drift tube, is soldered over outer diameter into longitudinal part of diaphragm; transversal part of diaphragm on absorber end is flat; gap h_g between transversal part of diaphragm and absorber is chosen relative to resonator diameter d_r within 0.05

h_g/d_r

0.01 and its thickness h_a relative to resonator height h_r, within 0.7

h_a/h_r

0.3; ferromagnetic disk of section of interconnected-resonators chain is mounted on drift tube projection at absorber-incorporating diaphragm end of annular nonmagnetic conducting member having inner diameter equal to outer diameter of drift tube; angle

between centers of slits in absorber-incorporating diaphragm and in ferromagnetic disk of section of interconnected-resonators chain abutting against diaphragm is chosen within

, where

is aperture angle of coupling slit in section of interconnected-resonators chain. Other design alternate of traveling-wave tube is characterized in that one more or two conducting members are installed on surface of ferromagnetic disk abutting against absorber-incorporating diaphragm.

EFFECT: ability of dissipation in high-power absorber and matching of the latter with slow-wave structure of low reflectivity.

2 cl, 3 dwg

Description

The invention relates to the field of electronic technology, namely to the design of electric vacuum devices of the type -O and can be used in high-power traveling wave tubes (TWT) and in hybrid devices.

Known sectioned TWTs with retarding systems (ES) such as a chain of coupled resonators [1-3].

In [1], a TWT is described in which intersectional loads are segments of a waveguide with a wedge-shaped absorber placed in them. These loads are installed perpendicular to the axis of the lamp and therefore increase its transverse dimensions, and when using a combined magnetic periodic focusing system, it is difficult to hold the electron beam, because violate uniformity in the distribution of the magnetic field.

In [2], between the sections of the device there is a conductive gasket, equal in length to one ES resonator, in which isolated semicircular resonators with absorbers in the form of a button are inserted into them one above the other. The complexity of the shape of the resonators and absorbers makes it difficult to manufacture the device, the small sizes of the absorbers do not allow for a large attenuation and a high level of dissipated power, and the absence of means outside the absorbing resonators for matching them with the ES does not make it possible to obtain a low level of reflection coefficient.

Closest to the claimed design is a partitioned TWT, proposed in the patent [3].

In this device, continuous conductive disks are installed between sections of ZS type of a chain of coupled resonators, to which ZS resonators adjoin on both sides with absorbing rings inserted into them. The rings are adjacent to the intersection disks, due to which, basically, heat is removed from them. This heat sink is small because the absorber material, alumina porous ceramic impregnated with carbon, has low thermal conductivity.

In the design [3], the absorbing rings are removed from the coupling slots, near which intense electric fields are located, which leads to low attenuation and, in addition, there are no means for matching the absorbing resonators with the sections of the CS after their assembly, as in [2] .

Thus, the object of the invention is to increase the average power level of a partitioned TWT, increase the absorption of loads at the ends of its sections, and improve their coordination with the sections.

This problem in the first embodiment is solved by the fact that sections of the chains of coupled resonators are made of ferromagnetic disks and non-magnetic diaphragms installed between them with azimuthal coupling slots. The slots in the diaphragms are rotated relative to the slots in the disks by an angle π radians, and drift tubes are made on the axis of the disks and diaphragms, the conducting sections are made of ferromagnetic metal, the annular absorber is made with an inner diameter of d _pv , enclosed within _{2 r of pv} ≥ d _pv ≥ d _tv , where r _tv is the inner radius of the coupling gap, d _tv is the inner diameter of the drift tube, and soldered into the longitudinal part of the diaphragm along the outer diameter, and the transverse part of the diaphragm is made flat on the side of the absorber, the gap between the surface of the transverse part of the diaphragm and the annular absorber h _z relative to the diameter of the resonator d _{p is} set in the range from 0.01 to 0.05, and its thickness h _p relative to the height of the resonator h _{p is} in the range from 0.3 to 0.7; a ring-shaped non-magnetic conductive element with an inner diameter equal to the outer diameter of the drift tube is installed on the drift tube of the ferromagnetic disk of the chain of coupled resonators, on the side of the diaphragm with an absorber, and the angle β between the middle of the slots in the diaphragm with the absorber and in the adjacent ferromagnetic disk of the chain of coupled resonators performed within 2π - α ≥ β ≥ α, where α is the angle of the bond gap in the section of the chain of coupled resonators.

In the second embodiment, the solution of this problem requires additional installation on the surface of the ferromagnetic disk of a chain of coupled resonators from the side of the diaphragm from the absorber of one or two non-magnetic conductive elements.

The use of two design options to solve this problem is due to the fact that in the process of manufacturing devices there are errors in the manufacture of parts, assembly and soldering sections of chains of coupled resonators. Compensation of these errors and requires the use of two variants of the proposed design.

Figure 1 shows the proposed device partially in longitudinal section.

Figure 2 shows on an enlarged scale a fragment F of the longitudinal section of the device.

Figure 3 shows the left side view of the fragment F of the device.

Figure 1-3: 1 - electron gun, 2 - input, 3 - energy output, 4 - input pipe, 5 - pipe output coolant, 6 - permanent magnet, 7 - ferromagnetic disks of sections of a chain of coupled resonators, 8 - non-magnetic diaphragms of sections of chains of coupled resonators, 9 — ferromagnetic disks separating sections of the device, 10 — non-magnetic rings restricting cooling channels, 11 — drift tubes, 12 — azimuthal coupling slots, 13 — annular absorber, 14 — non-magnetic diaphragm with a flat surface on the side of the annular absorber, 15 - mute magnetic bandage (for example, molybdenum), 16 - ring-shaped non-magnetic conductive element mounted on the drift tube, 17 - non-magnetic conductive element mounted on the surface of the ferromagnetic disk section of the chain of coupled resonators, 18 - channels for the flow of coolant, 19 - electron beam, 20 - electron collector.

The claimed traveling wave lamp contains an electron gun 1, which generates an electron stream 19, an electron collector 20, input 2 and output 3 of energy, sections of chains of coupled resonators formed by ferromagnetic disks 7 and non-magnetic diaphragms 8 with azimuthal coupling slots 12 and drift tubes 11, permanent magnets 6, mounted between ferromagnetic disks 7, ferromagnetic disks 9 with drift tubes 11 separating sections of chains of coupled resonators, non-magnetic diaphragms 14 with ring-shaped soldered into their longitudinal parts will absorb by firs 13, a non-magnetic (for example, molybdenum) bandage 15 mounted on the diaphragm 14 opposite the annular absorber 13, an annular non-magnetic conductive element 16 with an inner diameter equal to the outer diameter of the drift tube 11 mounted on the drift tube of the ferromagnetic disk 7 from the diaphragm 14, one - two non-magnetic conductive element 17 mounted on the surface of the ferromagnetic disk 7 facing the diaphragm 14, a pipe 4 for introducing coolant, channels 18 for its flow, limiting channels 18 non-magnetic tnye ring 10 and pipe 5 to output the coolant.

The proposed device operates as follows.

The electron gun 1 creates a beam 19, which moves along the axis of the device, held by a periodic magnetic field created by permanent magnets 6 between the drift tubes of the ferromagnetic disks. An electromagnetic wave is applied to the input 2 of the device, which slows down in sections of chains of coupled resonators formed by ferromagnetic disks 7 and non-magnetic diaphragms 8 with communication slots 12 and drift tubes 11, to a speed lower than the speed of the electron beam. When a beam decelerates in a wave field, its power is amplified.

An electromagnetic wave amplified in the section of the device enters the resonator in which the annular absorber 13 is mounted. Reflecting from the disk 9 separating the sections, it returns weakened to the section of the chain of coupled resonators. This attenuation is the greater, the stronger the electric field in which the absorbing ceramic is located. Making the transverse part of the diaphragm 14, facing the annular absorber, flat and approaching the absorber to it increases the electric field in which the absorber is located, which allows 1.3-1.4 times increase attenuation. The reflection coefficient of the electromagnetic wave in the section of the chain of coupled resonators, corresponding to the attenuation introduced by the absorber, is achieved by installing only a ring-shaped non-magnetic conductive element 16 on the drift tube in one design variant, and in another one or two non-magnetic conductive elements 17 on its surface.

Thus, both the amplified and the reflected power in the first and intermediate sections of the device are almost completely dissipated in the absorbers 13 at their adjacent ends. Modulation of the electron beam 19 is transmitted from section to section, and a well modulated beam enters the last section of the device. An electromagnetic wave excited in the output section by electron bunches is amplified along its length and passes through the output of energy 3 into an external waveguide path (not shown). The spent electron beam 19 is dissipated in the collector 20. The heat generated in the annular absorbers 13, the junction of which with the transverse part of the diaphragm 14 is protected from cracking by a molybdenum bandage 15, and the heat released in other parts of the device due to current collection and absorption of electromagnetic wave energy is removed coolant (not shown) entering the pipe 4, passing through channels 18, bounded externally by non-magnetic rings 10, and exiting through the pipe 5.

Matching elements (non-magnetic conductive rings and disks) are installed on the ferromagnetic disk, because the disk material (iron) and the material of the matching elements (non-magnetic stainless steel) are well connected by contact and laser welding.

The intervals of axial h _k , h _e , h _p , h _z , radial d _k , d _e , d _pv and azimuthal β sizes (see FIGS. 3 and 4) were obtained on the basis of processing a large amount of experimental data. These intervals have the following boundaries:

2π - α ≥ β ≥ α.

The rather wide intervals of changing the sizes of matching elements and the angle between the middle of the communication slots in the ferromagnetic disk and the adjacent diaphragm with an absorber show that even with deviation of the dimensions of the sections of the devices from the nominal ones caused by inaccuracies in the manufacture of parts, assembly and soldering of sections, the proposed device allows to achieve the coefficient reflection from an absorbing cavity close to ideal (0.001).

An example of a specific implementation of the proposed device can serve TWT, developed for an airborne radar system. The annular absorber is made of ceramic, containing 70% beryllium oxide and 30% titanium oxide, which has high thermal conductivity and high absorption.

The absorber is soldered into the longitudinal part of the copper diaphragm, the thickness of which was 0.5 mm at a distance of 0.5 mm from its transverse part. The outer diameter of the absorber is 15 mm, the inner is 6 mm, and the thickness is 1.9 mm. A molybdenum bandage is installed on the diaphragm opposite the absorber.

Making the transverse part of the diaphragm facing the absorber flat and moving it closer to it made it possible to increase the attenuation of the load by 1.35 times.

The coefficient of reflection from the resonator from the absorber, close to zero, was obtained by installing a non-magnetic ring with an outer diameter of 7 mm, a height of 1 mm on the drift tube adjacent to the diaphragm with an absorber, and installing a non-magnetic disk of 3 mm diameter at a radius of 6 mm and 2 mm high. The angle between the middle of the gap in the ferromagnetic disk and the axis of the non-magnetic disk was 80 °, and the angle between the middle of the gap in the diaphragm with an absorber and the middle of the gap in the ferromagnetic disk was 109 °.

Using the proposed design allows several times to increase the heat dissipation ability of absorbers of traveling wave lamps. The annular absorber is made of a ceramic material, the thermal conductivity of which is 5 times higher than the material used previously (alumina ceramic impregnated with carbon). It is soldered along the outer diameter into a non-magnetic diaphragm (usually made of copper), and it is known that the thermal resistance of a soldered contact is several times lower than the thermal resistance of the pressure contact.

The execution of the side of the diaphragm facing the annular absorber flat and its approach to this side significantly, by 30-40%, increases the absorption in the load resonator. This means that if the absorption in the load of the prototype was 10 dB, which corresponds to a reflection coefficient of 0.01 when perfectly matched, then increasing it to 13 dB when perfectly matched, the reflection coefficient will already be 0.0014, which can significantly increase the resistance to self-excitation of sections device or increase its gain.

The installation on the ferromagnetic disk adjacent to the diaphragm with an annular absorber, matching elements and setting the angle β between the middle of the coupling slots in the disk and the diaphragm within 2π - α ≥ β ≥ α, allows obtaining close matching of the chains of coupled resonators with the loads.

The considered design represents one of the variants of the claimed invention. Lamps with a traveling wave, created in accordance with it, can have not only liquid cooling, as described above, but also air.

Literature

1. W. Hunt et al. US Pat No. 3181023, March 29, 1962, Cl 315 / 3.5.

2. D.J. Bates et al. US Pat No. 2985791, Oct. 2, 1958, Cl 315 / 3.5.

3. K.E. Zubkin et al. US Pat No. 2939993, Jan. 7, 1957, Cl 315 / 3.5.

Claims (2)

1. A sectioned traveling wave lamp containing an electron gun, an electron collector and a chain of coupled resonators, at the adjacent ends of the sections of which there are mounted resonators with an annular absorber, separating sections of the conducting disks with drift tubes, as well as permanent magnets and energy input and output, characterized in that sections of a chain of coupled resonators are made of ferromagnetic disks and non-magnetic diaphragms installed between them with azimuthal coupling slots, the slots in non-magnetic diaphragms are turned There are flats in the ferromagnetic disks at an angle π radians, and drift tubes are made along the axis of the ferromagnetic and non-magnetic diaphragms, the separating sections of the conductive disks are made of ferromagnetic metal, the annular absorber is made with an internal diameter of d _pv , enclosed within _{2 r of pv} ≥ d _pv ≥ d _tv where r _ShchV - inner radius of coupling slots, d _tv - internal diameter of the drift tube, and the outside diameter soldered into the longitudinal portion of the diaphragm, and by the transverse part of the absorber of the diaphragm is flat, the clearance between Poper hydrochloric portion of the diaphragm and the annular absorber _of h with respect to the cavity diameter d _p is set in the range

and its thickness h _p relative to the height of the resonator h _p within

a ring-shaped non-magnetic conductive element with an inner diameter equal to the outer diameter of the drift tube is installed on the drift tube of the ferromagnetic disk of the chain of coupled resonators on the side of the diaphragm with the absorber, the angle β between the midpoints of the azimuthal coupling slots in the diaphragm with the absorber and in the adjacent section of the chain of the coupled ferromagnetic disk resonators is made in the range 2π - α ≥ β ≥ α, where α is the angle of the bond gap in the section of the chain of coupled resonators. 2. A sectioned traveling wave lamp containing an electron gun, an electron collector and a chain of coupled resonators, at the adjacent ends of the sections of which there are mounted resonators with an annular absorber, separating sections of the conducting disks with drift tubes, as well as input and output of energy and permanent magnets, characterized in that sections of a chain of coupled resonators are made of ferromagnetic disks and non-magnetic diaphragms installed between them with azimuthal coupling slots, the slots in non-magnetic diaphragms are turned There are flats in the ferromagnetic disks at an angle π radians, and drift tubes are made along the axis of the ferromagnetic disks and non-magnetic diaphragms, the separating sections of the conductive disks are made of ferromagnetic metal, the annular absorber is made with an inner diameter d _pv , enclosed within 2r _nv ≥ d _pv ≥ d _tv , where r _tv is the internal radius of the coupling gap, d _tv is the inner diameter of the drift tube, and soldered into the longitudinal part of the diaphragm along the outer diameter, and the transverse part of the diaphragm is made flat on the side of the absorber, the gap between the transverse part of the diaphragm and the annular absorber h _s relative to the diameter of the resonator d _{p is} set in the range

and its thickness h _p relative to the height of the resonator h _p within

on the drift tube of the ferromagnetic disk of the section of the chain of coupled resonators from the side of the diaphragm with an absorber there is a ring-shaped non-magnetic element with an inner diameter equal to the outer diameter of the drift tube, and one or two non-magnetic conductive elements are installed on its surface, the angle β between the middle of the communication slots in the diaphragm with the absorber and in the adjacent ferromagnetic disk of the section of the chain of coupled resonators is made in the range 2π - α ≥ β ≥ α, where α is the angle of the solution of the coupling gap in the section of the chain of coupling OF DATA resonators.

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