SU752553A1 - Three-electrode electron gun - Google Patents

Description

The ability to increase the radial and axial dimensions of insulators to achieve the required electrical strength. The dissolution of elements that are sources of contamination (cathode, aperture surfaces of the diaphragms) inside insulators reduces the electrical strength and shortens the service life. Therefore, in the known cathodes, the cathode and the diaphragm, like Irabil, are located outside the insulators in axial and averaging on the cylindrical conductive elements due to an increase in the dimensions of the gun. In some designs, constructive measures are additionally used to protect the insulators from spraying also by increasing the dimensions of the gun. The three-electrode electron gun with the Irodolian komireseia is known, which contains a cathode assembly, accelerating and decelerating diaphragms, and insulators 2. A disadvantage of the known gun is that the structure has large axial and transverse dimensions to provide the necessary electrical strength. At the same time, in most lapses, and especially in microwave devices of the millimeter and submillimeter ranges, in which beam focusing by the magnetic field is mainly used to focus the beams, this factor is significant. The principles for the development of modern compact magnetic focusing systems (MFS) for onboard airborne instrumentation on magneto-rigid materials with permanent magnetization put forward the requirements of minimal gabrints about the device itself. In this case, strengthening the magnetic field in the gap than the gap and reducing the weight and dimensions of the IFS is achieved by placing magnets with different magnetization panels in the immediate vicinity of the instrument case both in the axial and in the transverse directions. In a limescale, the isolator between the first and second diaphragms has an annular shape and is located around the body of the first diaphragm. In this case, the reduction in the transverse dimensions of the gun necessitates an increase in the axial dimensions of the insulator between the cathode assembly and the first diaphragm in order to ensure its surface electrical strength. An increase in the insularer's rift, developed axial direction, in the closed volume of the diaphragm case caused in the lime structure the need for special measures to protect against spraying and the use of parts of complex configuration that increase the axial length of the gun. The axial and transverse dimensions of the known starter are also increased due to the mandatory use of a planting cup in which the body of the first diaphragm is mounted. The pipette design fundamentally allows the insulator to be located between the orifices around the first orifice plate and above its plane, however, the axial dimensions of the gun increase, and the cross sections change due to the presence of the landing sleeve. Reducing the size of the NW gun is also complicated by the fact that in it to the isolator between the cathode node and the nerve nerve, all the equipment between these electrodes, which has the highest value in the electric circuit of guns with radial compression, is more than the sum of the two sources of energy. This causes the need to increase the axial and transverse dimensions of the insulator, and hence the gun. The reduced size of the lime gun is furthermore hampered by the fact that the cylindrical insulator between the cathode assembly and the iridescent diaphragm has large contact surfaces with electrodes on cylindrical surfaces and a large volume, in which (in the radial direction) conduction currents flow. This also leads to an increase in the size of the gun. The increase in the size of the known gun is also due to the fact that for mounting it in an electrovacuum device it is necessary to use a fastening flange, which is part of the second diaphragm and protrudes beyond the limits of the useful volume of the gun. The aim of the invention is to reduce the size of the electron gun while maintaining electrical proc. The goal is set to Dos.;. By the fact that the cathode assembly and the accelerating diaphragm are mounted cantilever on insulators made in the form of rods tucked into the retarding diaphragm in the plane, perpendicular to the axis of the egg, and located on the opposite side of the plane through this axis. The most expedient is such a design of the proposed gun, in which the insulators have the shape of rectangular parallelepipeds and are fixed with ends on the supporting projections of the slowing (second) diaphragm. FIG. 1 - the pusher is shown, cross section; pas figs. 2 - the same, top view; in fig. 3 - the same, side view; in fig. 4 - section bb of FIG. 2; in fig. 5 is a schematic comparison of the proposed design of a gun with a known design for electrical strength; in fig. 6 - an isator of a famous gun (node I to pa of FIG. 5); FIG. 7 shows the potential distribution V about the OZ axis of the electron-optical system with a three-electrode gun and its electric power supply diagram; in fig. 8 - directions applied to lime gun insulators; in fig. 9 - voltages applied to the insulators of the proposed gun; in fig. 10 shows a gun structure for forming axially symmetric beams.

The proposed electron gun consists (Fig. 1) of a cathode assembly 1 comprising a cathode with a heater, a first diaphragm 2, a second diaphragm 3, a psol 4 of the cathode assembly, and an insulator 5 of the first diaphragm. The cathode assembly 1, with the aid of the holder 6, is fixedly fixed on the insulator 4, and the holder 6 also performs the function of the cathode electrode. The first diaphragm 2 is fixedly mounted on the isolator 5.

Insulators 4 and 5 have an iridesh form in the direction perpendicular to the longitudinal axis 7 of the gun, which coincides with the axis of the beam. The insulators 4 and 5 are located but different sides from an imaginary plane passing through the axis 7 of the gun, while the projections of the insulators 4 and 5 onto the second diaphragm 3 do not intersect. The ends of each of insulators 4 and 5 are fixed on the second diaphragm 3 by means of corner lamellae 8 (Fig. 2). In the second diaphragm 3, holes 9 are made to fasten the gun in the instrument. Ia isolator 4 cathodic node 1, located incandescent conclusion 10.

The most optimal for achieving the goal is to construct a gun, in which insulators 4 and 5 have the form of an ir-rectangular parallelepiped, parallel to each other, and rest on a wide diaphragm projection 11 of the second diaphragm 3. Each protrusion 11 has two supporting planes, each One of the insulators is 4 or 5. The reference ploies of the protrusions 11 are perpendicular to the axis 7 of the gun.

In the proposed electro-icing, the co-fastening of the electrodes to the sockets 4, 5, extended in a direction that is not suitable for the gun axis 7, makes it possible to reduce its axial and lateral dimensions. The possibility of such thinking is due to several factors (Fig. 5).

In the known construction, the volume electrical strength of the insulator 4 between the cathode assembly e and the iricathode electrode (holder) 6 and the iridescent diaphragm 2 is determined by the distance L. The volume strength of the total solver 4 of the proposed fuzz is distance / 4, and A is always much greater than A. Prot The insulator 4 is designed in the form of a cantilever mount of the cathode assembly 1, and it is possible to use insulator 4 with a cross-section of 10 to 50 times smaller than in the known gun. This reduces the surface of contact between the insulator and the electrodes in the places of attachment, increases the resistance of the insulator 4 and increases its electrical strength, so that the possibility of reducing the transverse size of the gun with the same electric stability arises. In this case, the surface electrical strength, determined in the known construction by a distance, is approximately equal to (+ c, remains the irege or increases (Fig. 6).

In the known gun, the insulation strength between the first and second diaphragms 2 and 6 is determined by size B. From FIG. 5 shows

that in the proposed construction, the size C of the insulator 5 of the first diaphragm 2 can be several times larger than the size B, provided that the dielectric strength is maintained or increased. Wherein

an increase in the electrical circuit strength (volumetric due to a decrease in cross section and surface due to an increased size) is achieved with a decrease in the axial length of the gun, since the insulator is elongated in a direction perpendicular to its axis.

Umeikshenpe sizes in the proposed gun compared with the known is achieved with a console mount electrodes and

The distance between the insulators 4 and 5 and the opposite sides of the imaginary iloskos passing through the axis 7 of the gun. In this case, the projections of insulators 4 and 5 to the second diaphragm 3 do not intersect and become

it is possible to locate them at a minimum distance from the second diaphragm 3 at one or close levels. In this case, insulators do not protrude axially beyond the limit of the cushion nushchk node. Therefore, in contrast to the axial dimensions known in the proposed gun, the axial dimensions are determined only by the axial dimensions of the electrodes, the cathode assembly and the interelectrode gaps.

The dimensions of the proposed gun are reduced in comparison with the well-known also because insulators 4 and 5 in it are moved away from the assemblies and parts that are the sources of the products and the cathode

node 1, the aerials of the diaphragms 2, 3), and all the details of the cannon and their specified location are in the volume open for pumping gases and gases. Therefore, in the proposed design with the same electrical

There is no need for anti-dowel elements, which increase the dimensions in the famous gun.

Console mounting electrodes 1 and 2

The iris and the shape of the insulators 4 and 5 make it possible to reduce the lateral dimensions of the iris by fixing it in the instruments with holes 9 located within the second floor (in the known

cannon - special f | lanets).

A significant factor in reducing the size of the proposed gun, compared with the known one, is that each of the insulators 4 and B is fixed with ends on

The second aperture is 3 guns.

To clarify this factor, it is necessary to consider the distribution of electric potential along the axis in the proposed gun and the scheme of its electrical supply (Fig. 7).

The second iris diaphragm 3 is connected to the body of the device or the collector 12 and grounded. A positive potential (Ki-Vo) is supplied to the first diaphragm 2 of the otospellio of the earth from a low-power high-voltage power source (since the current in the circuit of the first diaphragm is approximately zero). A negative potential is applied to the cathode 1 of the gun relative to the earth - 1/2 of the powerful source IPa. The energy of the electrons is determined by the value e-1/2, where e is the electron charge, and the useful power of the beam is / e-1/2. The beam current / s depends on the sum of the voltages generated by both sources. Such a scheme of electric power supply of guns with longitudinal compression is most appropriate from an energy point of view and the only practically used scheme, since all the useful power is provided by a low-voltage source.

In the known gun (Fig. 8), the entire voltage 1/1 between the cathode i and the first diaphragm 2 from both power sources PI and IP2, is the highest in the circuit, applied to insulator 4. Voltage () is applied to insulator 5 . This is due to the fact that insulator 4 in a known construction is located inside the body of the first diaphragm 2.

In the proposed gun (Fig. 9), the voltage V is applied to two series-connected insulators 4 and 5, since the cathode 1 and the first diaphragm 2 are separately isolated from the second diaphragm 3. Only part of the voltage Ui is applied to the insulator 4 1/2, and to insulator 5 is the same as in the known construction, the voltage (V, -T / C)

It should be noted that, from the point of view of the electrical strength, the insulation of the cathode 1 from the first diaphragm 2 is the most important factor in the design of the circuit. This is due both to the greatest magnitude of the applied voltage and to the fact that the insulator 4 is in contact with the high-temperature component of the cathode assembly 1 and is located closest to the cathode.

Thus, in the proposed gun, by reducing the amount of voltage applied to insulator 4, the dimensions of the gun can be significantly reduced. This leads mainly to a reduction in its transverse dimensions.

Thus, the combination of these factors in the proposed gun compared to the known one allows to reduce its axial and lateral dimensions while maintaining the electrical strength.

The most optimal from the point of view of reducing the size and manufacturability is the design of the proposed gun, in which insulators 4 and 5 are shaped

rectangular parallelepipeds, and on the edges of the second diaphragm 3, supporting protrusions 11 are located for fastening insulators. The projections of the protrusions are perpendicular to the smallpox 7 guns, and the insulators

4 and 5 are fixed on them with the ends of wide edges. Compared to other possible cross-sectional configurations of insulators 4 and 5, rectangular provides for obtaining minimum axial dimensions of the gun. The thickness of the insulators 4 and 5 in this case turns out to be minimal while ensuring reliable fixation of the gun elements relative to each other without the use of special parts that increase the dimensions of the gun. The wide faces of the insulators 4 and 5 are basic areas and, when mounted on the projections 1, ensure the parallelism of the axes of the apertures of the diaphragms 2 and 3 and the cathode with

the axis of the gun. This simplifies the assembly process and increases its accuracy. The use of insulators 4, 5 in the form of rectangular parallelepipeds and P.1OSK protrusions of the second diaphragm allows, with minimum transverse dimensions of the gun, to ensure the displacement of insulators assembled with electrodes in axial directions perpendicular to the axis during alignment. In connection with this, the requirements on the accuracy of the location of apertures (rectangular and round) relative to the seating parts are significantly reduced. For the same reason, large areas remain within the transverse dimensions of the gun on the second diaphragm to accommodate fasteners and other fixing elements. The thickness of the protrusions of the second diaphragm defines the gaps between the gun electrodes. At the same time, in comparison with other possible PFjiMn variants, such as, the complex configuration of insulators with P1LPFORKI operations with high accuracy classes is eliminated.

Designs of electron guns to form axially symmetric and

Langal beam types differ only in the geometry of the electrodes and the distances between them. FIG. 10 shows a cross section of the proposed gun for forming an axially symmetrical beam.

The use of three-electrode guns with longitudinal compression in microwave vacuum devices, as is well known, makes it possible to significantly increase the output power and efficiency, and to reduce the operating voltages.

The use of the proposed baking in these devices by reducing its size provides a significant reduction in the dimensions of the devices, and therefore, and the size of the working gap of the MFS. it

allows to reduce the weight and dimensions of the MFS and to obtain an economic effect both due to the cost of the flight weight of the device, and by saving expensive magnetic hard materials.

Claims (3)

1. Three-electrode electron gun with longitudinal compression, containing a cathode assembly, accelerating and retarding diaphragms, and insulators, characterized in that, in order to reduce the dimensions of the gun while maintaining its electrical strength, the cathode assembly and the accelerating diaphragm are fixed to the console tori, made in the form of rods, mounted on a slowing down diaphragm in a plane, perpendicular to the axis of the gun, and located on opposite sides of a plane passing through this axis. 2. A gun according to claim 1, characterized in that the rods are made in the form of rectangular parallelepipeds. 3. The gun according to claim 1, differing from the fact that at the edges of the retarding diaphragm there are support lugs for attaching insulators. Sources of information taken into account in the examination 1. Zinchenko, N.S., et al. A high-current pulse gun with a high perveance. - “Instruments and Experimental Technique, 1969, No. 3, p. 22 2. Zinchenko N. S., Lopatin I. V. Vysokoperveanska three-electrode electron gun with an increased service life. - Lime in higher educational institutions. Radio electronics, t. KhI1, 11, 1970, p. 1379-1381 (prototype). (Pig 7 (rig 4 cpus.f