RU133973U1 - ELECTRONIC VACUUM DEVICE - Google Patents

Abstract

The utility model relates to the field of electronic vacuum devices. The electronic vacuum device contains a vacuum shell, including a leg with leads, an anode with concentric fins and a radiator, a cathode and two grids located coaxially with the cathode. The cathode and both grids are connected to each other by a dielectric pin, which is rigidly fixed to the blank bottom of the first grid and freely passing through the hole in the cathode and is rigidly fixed to the second grid in order to fix the distance between the grids and the first grid and the cathode. The dielectric pin is made of variable cross section, stepwise and rigidly fixed by the end with a large diameter in the bottom of the second grid, passes freely in the holes located in the bottom of the first grid and the cathode cover, while the hole in the bottom of the first grid is larger than the hole in the cathode, but each of these holes corresponds to the diameter of the pin at the point of contact with the first grid and cathode. The ratio of the pin diameters at the cathode, at the first grid, at the attachment point at the second grid is selected inversely proportional to the temperature coefficients of linear expansion of the materials of which the cathode is made, the first and second grids at their operating temperatures. 3 ill.

Description

The utility model relates to the field of electronic vacuum devices and, in particular, considers the design of the tetrode.

Known electronic vacuum devices with a stratified electron flow, for example, tetrodes - an electronic lamp having 4 electrodes: a thermionic cathode (direct or indirect glow), 2 grids (control and shielding) and the anode. The basis of these lamps (ray tetrode) was the so-called ray principle of electron flow formation: the control and screen grids of the tetrode were identical, that is, from the same wire, with the same pitch and number of turns, differing only in the diameters of the ellipse. In this case, the grids were installed on the mounting traverses in such a way that the turns of the screen mesh were located exactly opposite the turns of the control grid and, as it were, “hid” behind its turns. As a result, the electrons “circled” the turns of the screen grid along the path to the anode without settling on it and without creating a constant screen current. At the same time, the electrons "squeezed" into narrow beams increased the electron flux density so that in the gap between the screen grid and the anode a virtual region was formed that had a potential below the anode and prevented the formation of a counter ("dinatron") electron flux.

In the attachment points of the grids, the traverses seem to block the path of the electron beam, thereby distorting the general “ray” nature of the anode current. To exclude this effect on the overall anode characteristic, in the places where the traverse is installed, special solid metal plates are installed between them and the anode, protecting the traverses from the anode, and the anode itself is made in these places with a U-shaped bend to increase the distance between it and the traverse of the screen mesh . This peculiar shape of the anode is a sure sign of beam lamps. These additional shielding plates are always connected inside the lamp to a cathode with zero potential, which further contributes to the creation of a virtual region between the anode and the screen grid.

Beam tetrodes were created specifically for power amplification cascades and were used in ULF terminal stages, television scans, and transmitters. In modern industrial and amateur practice, output beam tetrodes that are designed specifically for ULF are most common. Special types of beam tetrodes have been optimized for powerful horizontal line cascades and can also work in the output stages of the ULF. Separate low-power beam tetrodes were designed to enhance high frequencies and can work effectively in triode switching.

US 3254258, H01J 19/42, publ. 05/31/1966, an electron-vacuum tube with a grid unit having a dielectric pin for attaching grids is described. The pin is made with a variable diameter conical shape and has an element in the form of a disk. The conical end portion of the pin passes through the hole in the metal insert. When heated, the cathode expands and approaches the disk element of the supporting pin, the metal insert bends, and thereby the distance between the cathode and the control grid is maintained. This device also eliminates noise when the instrument tube is subjected to shock and vibration.

From US 5206565, H01J 19/14; H01J 19/42, H01J 21/14, publ. 04/27/1993, a powerful cathode ray tube in the form of a tetrode is known. The tube contains coaxially arranged electrodes, including a cylindrical indirect heating cathode, cylindrical shielding and control grids and an anode, where the distance between the control grid and the cathode and the distance between the control grid and the shielding grid is less than 1 mm. Small distances between the electrodes with tolerances in the range of 1/100 mm are provided by means of a ceramic mesh mount, consisting of a hollow cylinder and two disks. The control and shielding grids are mounted on a plate supported by the cathode and are held with the help of disks of the ceramic mount. This design allows you to maintain the required distance between the grids. Adopted as a prototype.

In such devices, as a rule, to obtain high performance and their stability, the first grid is installed at small distances within a few tenths of a millimeter, and in shape it is a cylinder with a diameter to height ratio of 1: (1.2-2). The second grid is also located quite close, within 0.5: 0.6 mm from the first.

Such an arrangement of the cathode and grids requires the preservation of their relative position during the entire time of operation and changes in the temperature of the cathode when it is heated and enters the operating mode. The design of the known device is presented in figure 1 - prototype.

To ensure the above requirements, the cathode 1, the first grid 2 and the second grid 3 (Fig. 1) are installed, adjusted in a certain position and rigidly fixed on one rigid base - leg 4, which also serves as the node providing insulation of the heater 5 and the anode 6 and all of the listed elements of the electronic device from each other. Leg 4 together with the anode 6 form a vacuum shell of the entire device.

Fixing the cathode and the grid on one base does not guarantee the preservation of their original position when the cathode is heated, therefore, in known structures, the upper part of these elements is connected to each other by a dielectric element - pin 7 as follows. The pin is soldered with a high-temperature solder to the first grid, the element-average element through the flange 8, then inserted into the hole made in the center of the upper part of the cathode with a small gap, a significantly smaller distance between the cathode and the first grid.

This is due to the fact that the first grid is located closer to the cathode, at which the temperature reaches 800 ° C or more, and is, in fact, a heat shield and is heated to a high temperature, up to about 650 ° C. The second grid, farther from the cathode and located in the shadow of the first, heats up less than the first.

The mechanical strength of the two nets is different, since their geometric dimensions are different from each other, their temperature is different and, as a result, the dimensional changes due to the temperature of the two nets are different.

The ceramic pin 7 connecting them, rigidly fixed to the bottoms of the nets, does not allow them to occupy the position that the nets would occupy while in a free state. As a result, mechanical stresses arise, which lead to deformation of the first grid, distortion of its shape, the rods forming it are bent, the distance between them and the cathode is reduced, as a result of which a short circuit occurs.

The change in the relative position of the cathode and the first grid is also affected by the size of the gap between the pin and the walls of the cathode hole, the size of this gap increases with temperature and reaches a maximum value in the working state. This leads to an additional displacement of the first grid and increases the likelihood of a short circuit.

This utility model is aimed at achieving a technical result consisting in increasing the durability and operational reliability by eliminating the tendency to short circuit the cathode-first grid and output. Also, a useful model is aimed at achieving a technical result, which consists in increasing the stability of the device, simplifying the manufacture of the device as a whole and increasing reliability.

The specified technical result is achieved in that in an electronic vacuum device containing a vacuum shell, including a leg with leads, an anode with concentric fins and a radiator, a cathode and two grids located coaxially with the cathode, while the cathode and both grids are connected to each other by a dielectric pin, which is rigidly fixed to the blank bottom of the first grid and freely passing through the hole in the cathode and is rigidly fixed to the second grid in order to fix and maintain the distance between the grids and the first grid and the cathode, with the whole to increase the stability of the operation of the device, simplify the manufacture of the device as a whole, eliminate short circuits between the cathode and the first grid and increase reliability, the dielectric pin is made of variable cross-section stepwise and rigidly fixed by the end with a large diameter in the bottom of the second grid, passes freely in the holes located in the bottom the first grid and the cathode cover, while the hole in the bottom of the first grid is larger than the hole in the cathode, but each of these holes corresponds to the diameter of the pin at the point of contact with the first grid and a cathode, wherein the ratio of the pin diameter at the cathode, at the first mesh in place at fixing the second grid are selected inversely proportional to the temperature coefficients of linear expansion of the materials making up the cathode first and second grids at their operating temperatures.

These features are significant and interconnected with the formation of a stable set of essential features sufficient to obtain the desired technical result.

The present useful model is illustrated by specific examples, which, however, are not the only possible ones, but clearly demonstrate the possibility of achieving the required technical result by the given set of features.

Figure 1 presents a schematic diagram of a tetrode of the prototype;

figure 2 is a schematic diagram of a tetrode according to a utility model;

figure 3 - design of the pin.

In the framework of this utility model, the design of a tetrode with a layered electron beam is considered, free from the lack of a prototype: the tendency to short circuit the cathode-first grid and the output, resulting, as a result, in the failure of the device.

In an electronic vacuum device, the cathode 1, the first grid 2 and the second grid 3 (Fig. 2), located coaxially with the cathode, are rigidly fixed to one rigid base - leg 4, which also serves as a node that insulates the heater 5 and the anode 6 with concentric fins and radiator and all the listed elements of the electronic device from each other. Leg 4 with leads together with the anode 6 form a vacuum shell of the entire device. To preserve their initial position, the cathode and both grids are connected to each other by a dielectric element - dielectric pin 7. The cathode and both grids are made of material with a close or identical temperature coefficient of linear expansion, and their diameters in the sections of contact with the cathode, the first grid, the second grid selected from a ratio of 1: 1.1: 1.2.

In the framework of this utility model, the problem of eliminating the tendency to short circuits of the cathode-first grid and output is solved. This is achieved by a constructive solution, the essence of which is illustrated in Fig.2. In this figure, the same notation is used as in Fig. 1. Significant differences of the proposed design is that the shape of the pin and its fastening are changed.

The pin 7 is made with a variable cross-section (Fig. 3), while its diameter Dk in the part of the cathode entering the hole is substantially smaller than the diameter at the point of contact with the grid of the first Dc ₁ , and in the area of contact with the second grid, the diameter of Dc _{2 is} even larger than in contact with the net first. The ratio of the diameters is established depending on the coefficients of thermal expansion of the materials from which the cathode and grids of the device are made, taking into account the temperature of these elements in the operating mode of the device. The pin is made with three different diameters in the ratio 1: (1.8-2.2) :( 2.5-3). The pin is rigidly fixed to the blank bottom of the first grid and freely passing through the hole in the cathode and is rigidly fixed to the second grid in order to fix and maintain the distance between the grids and the first grid and the cathode.

Another significant difference of the proposed design is that

Rigid fastening of the dielectric pin is made only with the second grid, and it is carried out by soldering through an increased diameter by means of a cup 9, which in turn is connected by welding to the second grid.

This design solution allows you to install the pin strictly along the axis of the grid of the second and, when assembling the cathode-grid assembly, make it strictly coaxial and symmetrical, which significantly increases the thermomechanical stability of the entire structure.

When changing the temperature of the cathode and the entire device as a whole in the proposed design, the mutual movement of the cathode and grids is allowed along the axis of the pin and due to the fact that the grid first lost its rigid connection with the pin and the second grid, the movement of the cathode and grids along the common axis excludes the possibility of changing the distance between them and the occurrence of short circuits. In addition, the thermomechanical stability of the device increases the stability of the electrical parameters of the device, since during operation only movement along the axis occurs and the gaps between them do not change, which determine the initial values of the parameters.

Thus, our proposed design eliminates the disadvantages of the known and allows to provide better stability of parameters and the absence of short circuits and, therefore, higher reliability of the entire device.

Claims (3)

1. An electronic vacuum device containing a vacuum shell, a leg with leads, an anode with concentric fins and a radiator, a cathode and first and second grids located coaxially with the cathode, while the cathode and both grids are connected to each other by a dielectric pin that is rigidly fixed to the blind bottom of the first grid and freely passing through the hole in the cathode and is rigidly fixed to the second grid in order to fix and maintain the distance between the grids and the first grid and the cathode, characterized in that the dielectric pin is made cross section with a stepped and rigidly fixed end with a large step diameter in the bottom of the second grid, passes freely in the holes located in the bottom of the first grid and the cathode cover, while the hole in the bottom of the first grid is larger than the hole in the cathode, each of these holes corresponds to the diameter of the pin in the place of its contact with the first grid and the cathode, and the ratio of the pin diameters at the cathode, at the first grid, at the fastening point at the second grid, is inversely proportional to the temperature coefficients of linear expansion of materials of which the cathode is made, the first and second grids at their operating temperatures. 2. The electronic vacuum device according to claim 1, characterized in that the pin is made with three different diameters in a ratio of 1: (1.8-2.2) :( 2.5-3). 3. The electronic vacuum device according to claim 2, characterized in that the cathode and the grids are made of a material with a close or matching temperature coefficient of linear expansion, and their diameters in the sections of contact with the cathode, the first grid, the second grid are selected from a ratio of 1: 1, 1: 1.2.

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